SMITHSONIAN    CONTRIBUTIONS    TO    PALEOBIOLOGY     •      NUMBER    90
Geology and Paleontology
of the
Lee Creek Mine, North Carolina, III
Clayton E. Ray and David J. Bohaska
EDITORS
ISSUED
MAY 112001
SMITHSONIAN INSTITUTION
Smithsonian Institution Press
Washington, D.C.
2001
ABSTRACT
Ray, Clayton E., and David J. Bohaska, editors. Geology and Paleontology of the Lee Creek
Mine, North Carolina, III. Smithsonian Contributions to Paleobiology, number 90, 365 pages,
127 figures, 45 plates, 32 tables, 2001.—This volume on the geology and paleontology of the
Lee Creek Mine is the third of four to be dedicated to the late Remington Kellogg. It includes
a prodromus and six papers on nonmammalian vertebrate paleontology. The prodromus con-
tinues the historical theme of the introductions to volumes I and II, reviewing and resuscitat-
ing additional early reports of Atlantic Coastal Plain fossils. Harry L. Fierstine identifies five
species of the billfish family Istiophoridae from some 500 bones collected in the Yorktown
Formation. These include the only record of Makairapurdyi Fierstine, the first fossil record of
the genus Tetrapturus, specifically T. albidus Poey, the second fossil record of Istiophorus
platypterus (Shaw and Nodder) and Makaira indica (Cuvier), and the first fossil record of/.
platypterus, M. indica, M. nigricans Lacepede, and T. albidus from fossil deposits bordering
the Atlantic Ocean. Robert W. Purdy and five coauthors identify 104 taxa from 52 families of
cartilaginous and bony fishes from the Pungo River and Yorktown formations. The 10 teleosts
and 44 selachians from the Pungo River Formation indicate correlation with the Burdigalian
and Langhian stages. The 37 cartilaginous and 40 bony fishes, mostly from the Sunken
Meadow member of the Yorktown Formation, are compatible with assignment to the early
Pliocene planktonic foraminiferal zones N18 or N19. The Pungo River fish fauna is domi-
nated by warm water taxa; the Yorktown fauna includes warm and cool water species. These
changes are attributed to increased upwelling waters in Yorktown time. The abundant fossils
provide the basis for several changes in selachian taxonomy and for two new species of bony
fishes. George R. Zug records 11 taxa of turtles from the Yorktown Formation: a sideneck
(Bothremys); six sea turtles (Caretta, IChelonia, Lepidochelys, Procolpochelys, Psephopho-
rus, Syllomus); a softshell turtle (trionychid); two pond turtles (probably Pseudemys and Tra-
chemys); and a giant tortoise (Geochelone). Albert C. Myrick, Jr., records the crocodylian
Thecachampsa antiqua (Leidy) on the basis of fragmentary float material from the Pungo
River or Yorktown Formation, or both. Robert W. Storer describes a new species of grebe of
the genus Podiceps from the Yorktown Formation. Storrs L. Olson and Pamela C. Rasmussen
record some 112 species of birds from the Pungo River and Yorktown formations. Apart from
an undetermined number of shearwaters, only a few species are thought to come from the
Pungo River Formation. The marine species from the Yorktown Formation include three
loons, two grebes, five albatrosses, at least 16 shearwaters and petrels, one pelican, two
pseudodontorns, three gannets, two cormorants, 9-11 auks and puffins, one skua, three
jaegers, five gulls, two terns, and 20 ducks, geese, and swans. The less common land and
shore birds are represented by 29 species, including three cranes, one rail, two oystercatchers,
one plover, four scolopacids, one flamingo, one ibis, one heron, three storks, one condor, five
accipitrids, one osprey, one phasianid, one turkey, one pigeon, and one crow. The fauna is
dominated by a radiation of auks of the genus Alca. The early Pliocene fauna is very modem
in aspect, suggesting that most modern lineages of birds were already in existence.
Official PUBLICATION date is handstamped in a limited number of initial copies and is
recorded in the Institution's annual report, Annals of the Smithsonian Institution. SERIES COVER
DESIGN: The trilobite Phaecops rana Green.
Library of Congress Cataloging-in-Publication Data
Main entry under title:
Geology and Paleontology of the Lee Creek Mine, North Carolina.
(Smithsonian contributions to paleobiology ; no. 53-        )
Includes bibliographies.
1. Geology, Stratigraphic—Tertiary—Addresses, essays, lectures.    2. Geology—Stratigraphic—Pleistocene—
Addresses, essays, lectures.    3. Geology—North Carolina—Addresses, essays,
lectures.    4. Paleontology—North Carolina—Addresses, essays, lectures.    I. Ray, Clayton
Edward.    II. Series: Smithsonian contributions to paleobiology ; no. 53, etc.
QE701.S56 no. 53, etc. 560s [551.7'8'09756] 82-600265 [QE691]
© The paper used in this publication meets the minimum requirements of the American
National Standard for Permanence of Paper for Printed Library Materials    Z39.48—1984.
Contents
Page
Prodromus, by Clayton E. Ray........................................       1
Analysis and New Records of Billfish (Teleostei: Perciformes: Istio-
phor1dae) from the yorktown formation, early pliocene of eastern
North Carolina at Lee Creek Mine, by Harry L. Fierstine .............     21
The Neogene Sharks, Rays, and Bony Fishes from Lee Creek Mine,
Aurora, North Carolina, by Robert W. Purdy, Vincent P. Schneider,
Shelton P. Applegate, Jack H. McLellan, Robert L. Meyer, and Bob H.
Slaughter................................................     71
Turtles of the Lee Creek Mine (Pliocene: North Carolina), by
George R. Zug............................................   203
Thecachampsa antiqua (Leidy, 1852) (Crocodylidae: Thoracosaurinae),
from Fossil Marine Deposits at Lee Creek Mine, Aurora, North
CAROLINA, USA, by Albert C. Myrick, Jr........................   219
A New Pliocene Grebe from the Lee Creek Deposits, by Robert W. Storer
...........................................................   227
Miocene and Pliocene Birds from the Lee Creek Mine, North Carolina, by
Storrs L. Olson and Pamela C. Rasmussen  ..........................   233
ni
Dedicated to
Remington Kellogg
1892-1969
Geology and Paleontology
of the
Lee Creek Mine, North Carolina, III
Prodromus
Clayton E. Ray
Prodromus... a preliminary publication or introductory work.
Webster's Third New
International Dictionary, 1964
The archaic title is intended to reflect the antiquarian nature
of this paper and to emphasize my conviction that our work on
the Lee Creek Mine project, a quarter century of effort by many
people, is decidedly preliminary. Publication began with vol-
ume I (Ray, 1983), which included papers on Remington
Kellogg (to whom the series is dedicated), on the Lee Creek
phosphate mine itself, and on stratigraphy and correlation,
plants, and microfossils. The only paper specifically devoted to
vertebrate fossils was that on otoliths of bony fish, included
therein as "microfossils." That was primarily an unsuccessful
effort to see the paper in print before the death of its senior au-
thor, John Fitch, who was then terminally ill. Volume II (Ray,
1987) was devoted exclusively to mollusks, the most conspicu-
ously abundant and well-preserved fossils in the mine. Initially,
it was planned that all vertebrate fossils, other than otoliths,
would be included in a third, concluding volume (Ray,
1983:3); however, subsequent productive collecting, especially
that by able and devoted amateurs, has resulted in great accu-
mulation of more and better fossils. These have been subjected
to thorough research by the contributors and, combined, ex-
pand the vertebrate papers beyond the reasonable confines of a
single volume. The papers divide themselves conveniently into
two sets, all groups other than mammals in this, volume III, to
be followed by mammals, volume IV, which will include a tax-
Clayton E. Ray, Department of Paleobiology, National Museum of
Natural History, Smithsonian Institution, Washington, D.C. 20560-
0121.
onomic index to the publications of Remington Kellogg, pre-
dominantly on mammals.
This prefatory note continues the historical theme of those
introducing volumes I and II, in which I attempted to review
the early history of paleontological discovery and publication
on the middle Atlantic Coastal Plain of British America. Hav-
ing flattered myself that I had unearthed essentially everything,
it is salutary to be reminded through several oversights that in
antiquarian, as in paleontological, research one can never do
too much digging. Returns in each are apt to be unpredictable
and to be meager in relation to time invested (hardly "cost ef-
fective"), but there will always be something new, and, to com-
prehend it when found, one must be steeped in the subject.
Thus, my primary objective is to rescue from obscurity or
oblivion the additional early history that I have learned; not
only to give credit to the pioneers, but to add to the foundation
that may enable and inspire others to find out more, especially
about American fossils surviving in European collections, and
to dig further into the early literature. Thus, the present paper is
an extension of those introducing volumes I and II and should
be used in conjunction with them, as I have tried to avoid un-
due repetition of text and literature cited.
Although a full explication is beyond my scope herein and
beyond my competence anywhere, I hope in reviewing these
records to give some inkling of their importance, not only in
the development of paleontology, but also in the broader intel-
lectual concerns of the times. Fossils were more prominent in
general scholarly discussions of the seventeenth and eighteenth
centuries than at any time since. Although debate as to their na-
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
ture and significance has long since dropped from the forefront
of general investigation, we have by no means won the day. In
western culture many educated people, including scientists, ei-
ther ignore fossils or reject them as evidence of organic evolu-
tion, and humankind as a whole knows nothing of fossils
(Mclver, 1992; Lemonick, 1996).
No paleontologist can claim to be literate without thorough
attention, not merely a perfunctory bow, to the role of fossils in
western thought. Neglect of history is inexcusable in a histori-
cal science such as paleontology, but its literature in English is
very skimpy, and that written by practicing paleontologists is
generally narrow and shallow (although not universally so;
e.g., see Ward, 1990), much devoted to "correcting" past mis-
takes and concepts in the light of present knowledge and fads.
Of course we are obligated to correct objective errors in striv-
ing to approach truth ever more closely, but this is less and less
specifically useful as we delve deeper into the ontogeny of our
science. Much more satisfying is to understand the thoughts on
fossils in the context and constraints of the times and the rele-
vance of those thoughts to subsequent developments. The best
primers on this subject in English are Rudwick (1976), espe-
cially the first 100 pages, and Drake (1996), the latter focused
on Robert Hooke but with uncommon explication of context.
Also very instructive are Challinor (1953), Morello (1979,
1981), and Young (1992). Davidson (2000:333) outlined the
otherwise neglected role of Richard Verstegan in the early sev-
enteenth century; however, she is mistaken in attributing the
first published illustration, in 1605, of a shark's tooth to him.
That distinction almost certainly belongs to Gesner (see Rud-
wick, 1976:30, fig. 1.9), who in 1558 even included a modern
comparative specimen alongside his fossil. Davidson
(2000:343) cited Gesner's work as probably available to Ver-
stegan but mentioned neither Gesner's figure nor the work of
Kentmann of 1565 in Gesner (see Rudwick, 1976:11-17).
These and other sources cited herein provide essential back-
ground on the principal players in the founding of paleontolo-
gy, including, among others, da Vinci, Colonna, Scilla, Steno,
and Hooke, and those in the interrelated development of collec-
tions, including Aldrovandi, Cospi, Giganti, Kircher, Mercati,
Worm, and others. I refer to their work and its broader implica-
tions only in the course of resurrecting the primary reports on
American fossils. These allusions should be sufficient to show
that these reports are not mere curiosities of antiquarian delight
but were integral to cutting-edge (see Maienschein, 1994, re-
garding this trendy term) intellectual concerns.
Although there is no universal agreement as to what or when
the Renaissance was, few would disagree that it was earlier,
stronger, wider, and deeper in Italy than it was anywhere else.
It is no accident that Italian names, notably those mentioned
above, dominate the earliest stages in the history of paleontolo-
gy and museums, and that Italian influence extended strongly
into northern Europe and the British Isles.
For example, Steno, or Niels Stensen, was a Danish cleric,
but his scientific career was mostly Italian in locale, patronage,
and material (Scherz, 1969, 1971); Olaus Worm, also Danish,
probably was influenced by Aldrovandi in forming his museum
(Schepelem, 1990:82); Aldrovandi's pioneering catalogs of his
collection were emulated and cited frequently in much later
catalogs in England (Grew, 1681; Sloane, see Thackray,
1994:125); and John Ray visited and was much impressed by
Aldrovandi's collection (Torrens, 1985:206). Steno's work was
immediately translated into English by Oldenburg, and it be-
came the subject of great interest in the Royal Society (Eyles,
1958; Stokes, 1969:16). (Hooke accused Oldenburg and Steno
of conspiring to plagiarize his ideas (Oldroyd, 1989:217);
Drake (1996:116-117), especially, supported Hooke's claims,
and, more importantly, documented his widely undersung con-
tributions.)
It has been suggested (e.g., Rudwick, 1976:39^11; Torrens,
1985:207) that recognition of fossils as remains of once-living
organisms occurred in Italy before it did in northern Europe
and England because the Italian fossils were "easy," being geo-
logically young, little altered, and close to the sea and to living
relatives, whereas those elsewhere were much older, in de-
formed inland rocks, and the most conspicuous fossils were not
closely related to living forms. Unfortunately, these factors can
at best only partially explain away the Italian preeminence.
Surely at least as important was the existence of an affluent so-
ciety, with concomitant cultural sophistication, ready to under-
write research and to accept truth through logical argument.
Gould (1997) presented a convenient and timely analysis of
Leonardo's brilliant and prescient insights on fossils, well fixed
in the context of time and place. Both geologic and human his-
tory preadapted Italy as the scene of these breakthroughs, and
just as they were interwoven with a rich tapestry of culture, art,
learning, and patronage, so also was the interrelated develop-
ment of natural history collections. The literature in English re-
veals little comprehension of the fact that natural history muse-
ums developed (and survived in some cases) in continental
Europe, especially in Italy, in some semblance of modem form,
a century earlier than in the English-speaking world. It seems
altogether too revealing that in 1995 I found the pages uncut in
the Smithsonian Institution Library copy of MacGillivray's
(1838) life of Aldrovandi. This neglect has been partially cor-
rected in some excellent recent publications, including Impey
and MacGregor (1985) and Findlen (1994). Ethnological and
zoological objects from the Latin New World (then including
Florida) have been well documented in these early collections
(e.g., see Heikamp, 1976:458; Laurencich-Minelli, 1985), but
to my knowledge no fossils have as yet been recognized. Nev-
ertheless, the search for the beginnings of paleontology of the
New World should begin in sixteenth century Italy, through di-
rect examination of collections by appropriate specialists. The
best hope might well be the collections of the great Ulisse (La-
tinized as Ulyssis) Aldrovandi (1522-1605), who was known
to have had a strong interest in the New World (Heikamp,
1976:458; Laurencich-Minelli and Serra, 1988). His catalogs,
largely compiled during his lifetime but published posthu-
mously (Ambrosinus, 1648; Figure 1), remained a powerful in-
fluence long afterward in England (see above).
NUMBER 90
onofonw F,
FIGURE 1.—Title page (much reduced) of Aldrovandi's 1648 monumental catalog of his museum. It was com-
piled and was widely known during his lifetime (1522-1605) but was published by Ambrosinus more than 40
years after Aldrovandi's death (Findlen, 1994:25).
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Some Early Records
This brings me to the first instances to be added to early re-
ports of fossils from the Atlantic coast of North America. As
early as 1669 an allusion was made to natural history speci-
mens from Virginia in a collection, long since forgotten and ir-
retrievably lost, maintained by the East India Company at its
headquarters in London (Hunter, 1985:162). The first explicit
record to be added is that by Nehemiah Grew, who in 1681
published by subscription under auspices of the Royal Society
a catalog of its collections, the title page of which is repro-
duced herein (Figure 2; see Hunter, 1989, especially p. 142 et
sqq., for genesis and nature of the catalog; see LeFanu, 1990,
for Grew's life and contributions; see Clark, 1992, for an au-
thoritative guide to histories of the society, its periodical publi-
cations, and indices thereto). Included are two entries for fos-
sils specifically stated to have come from the New World.
A sort of MUSCUL1TES fill'd with Earth like Tobacco-Pipe Clay or Marie.
Found amongst the earth of a Hill that was overturn'd at Kenebank in New
England. (Grew, 1681:264)
A great petrify'd SCALLOP. Figur'd by Ambrosinus {b) with the Name of
Hippopectiniles. Given with several more of the same bigness, by Mr.______
Wicks. 'Tis half a foot over. Many of the same kind were taken out of a great
Rock in Virginia, forty miles from Sea or River. (Grew, 1681:262)
(b) Aldrov. Mus. Metall. (Grew, 1681:262, marginal citation)
The first of these undoubtedly was a mussel shell, common
in the late Pleistocene marine clays of the Presumpscot Forma-
tion of coastal Maine, including the vicinity of Kennebunk
(Stuiver and Borns, 1975; Thompson, 1982:212, 226). John
Winthrop, Jr. (1606-1676), an original fellow and major con-
tributor to the society's repository (Lyons, 1944:50, 64;
Stearns, 1951:196,212,246, 1970:117-139), undoubtedly was
the source of the specimen in question. In letters of 11 October
1670, printed in part in Birch (1756(2):473^t74) and quoted in
part by Steams (1970:137), he alluded to "small shells" among
the objects sent from a "hill near Kennebeck, Me, that turned
over in summer last (June or July) into the River." The mysteri-
ous "blowing-up" of the hill was reported also by John Josse-
lyn (1674:210; see also White, 1956:180).
The second entry is potentially of much greater interest. The
marginal bibliographic citation is to Aldrovandi's monumental,
classic illustrated catalog (Ambrosinus, 1648), which Grew cit-
ed repeatedly, in this case alluding to a giant pecten illustrated
on page 832 of volume 4. This raised the intriguing possibility
that Aldrovandi's specimen might conceivably be a previously
unsuspected and much earlier example from the New World.
Unfortunately, my limited investigation to date has revealed no
positive evidence that the giant pecten or any of Aldrovandi's
fossils came from America; rather, Grew's allusion seems to be
only an obsolete, broadly conceived synonymy, understandable
for the time. The specimen has not been found among surviv-
ing collections in Bologna, but it is thought to have come from
the vicinity of the city (Sarti, in litt., 1993).
Returning to Grew's specimens from Virginia, I had previ-
ously been inclined to accept the argument that the specimen of
giant pecten, Chesapecten jeffersonius, described and illustrat-
ed by Lister, the first fossil so far known of any kind from the
New World to be described and illustrated, probably had been
collected by John Banister and sent directly to Lister, Petiver,
or Sloane (see Ray, 1987:2), but now the Royal Society's Re-
pository seems at least as likely. Not only was Lister's speci-
men "half a foot over," but also Lister (1639-1712) and Grew
(1641-1712) coincided in their activities in the Society (Hunt-
er, 1994:188-189), and Lister is known to have used other
specimens from the repository.
The history of the repository is of great interest, not only in
attempting to locate a potential historical treasure such as the
giant pecten but also for its cautionary lessons to museologists
in general. Early impetus to the establishment and support of
the collection came from the need for a substantive rallying
point for the struggling Royal Society and for a source of pub-
lic prestige (Hunter, 1985, 1989:127, 128). Explicit and strik-
ingly modem statements of the purposes of natural history col-
lections were made by Grew (1681, preface), who advocated
collections as an inventory of nature and as documentation of
the ordinary, and by Hooke (1635-1703), who also took an ac-
tive and at times official role in connection with the collections
(see especially Hunter, 1989:125, 127, 139-141), and whose
pioneering studies of fossil cephalopods stimulated his follow-
ing statements (1705:338; also in Drake, 1996:236-237):
And indeed it is not only in the description of this Species of Shells and Fishes,
that a very great Defect or Imperfection may be found among Natural Histori-
ans, but in the Description of most other things; so that without inspection of
the things themselves, a Man is but a very little wiser.... It were therefore much
to be wisht for and indeavoured that there might be made and kept in some Re-
pository as full and compleat a Collection of all varieties of Natural Bodies as
could be obtained, where an Inquirer might be able to have recourse, where he
might peruse, and turn over, and spell, and read the Book of Nature, and ob-
serve the Orlbographv. Etymologia, Synlaxis and Prosodia of Nature's Gram-
mar, and by which, as with a Dictionary, he might readily turn to and find the
true Figure, Composition, Derivation and Use of the Characters, Words, Phras-
es and Sentences of Nature written with indelible, and most exact, and most ex-
pressive Letters, without which Books it will be very difficult to be thoroughly
a Literalus in the Language and Sense of Nature. The use of such a Collection
is not for Divertisement, and Wonder, and Gazing, as 'tis for the most part
thought and esteemed, and like Pictures for Children to admire and be pleased
with, but for the most serious and diligent study of the most able Proficient in
Natural Philosophy. And upon this occasion tho' it be a digression, I could
heartily wish that a Collection were made in this Repository of as many variet-
ies as could be produced of these kinds of Fossile-Shells and Petrifactions,
which would be no very difficult matter to be done if anyone made it his care.
Despite these and other resounding statements within the so-
ciety, the reality (dictated largely by its dilettante membership)
was that its collection continued to be much like that of a pri-
vate cabinet of curiosities—devoted to the rare and bizarre
rather than being a microcosm of what exists, ordinary as well
as extraordinary (Hunter, 1989:150). This tension has yet to be
resolved in museums, although the "inventory of nature"
movement seems to be gaining ascendancy at last. Further, the
society found that although establishing a museum is easy,
maintaining it in the long term ("perpetuity") is almost impos-
sible. From the beginning, much of the society's attention was
NUMBER 90
MVSMVM REGALIS SOCIETATIS.
O R   A
Catalogue &c Defcription
Of the Natural and Artificial
RARITIES
Belonging to the
ROYAL SOCIETY
And preferved at
Grefliam Colledge.
MADE
BytJS(ehemjab (jrewM. D. Fellow of the Royal Society,
and of the Colledge of Thyfitiam.
Whereunto is Subjoyned the
Comparative Anatomy
O F
^tomatljs ana (guts.
"By the fame oJVTHOR.
L0&CJD0N,
Printed by W. prelim, for the Author, i68i.
FIGURE 2.—Title page (reduced) of Grew's 1681 catalog of the repository of the Royal Society.
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
usurped by monetary problems, including difficulty in collect-
ing dues and shortfall in funds to pay support staff. After years
of vicissitudes in the care of its collections that entailed repeat-
ed efforts at revitalization, and finally faced with a critical
problem in space to house the collection, the society offered its
collections to the British Museum in 1779 (Hunter,
1989:153-155), which accepted in 1781 (Lyons, 1944:211).
Now, a mere two centuries later, the heir to that collection, The
Natural History Museum (BMNH), London, the Gibralter of its
kind, itself faces an uncertain future (e.g., see Nature. 1990), as
do its counterparts elsewhere (Trescott, 1996; Butler, 1997).
In any case, the "several" giant pecten(s) from Virginia
should have gone in 1781 to the British Museum. Although it
seems unlikely that such large, conspicuous shells would have
been lost, sold, or destroyed, even in the vandalous "crema-
tions" of curator Shaw (Steam, 1981:17), they have not as yet
been recognized in the existing collections of BMNH (Nuttall,
inlitt., 1993).
The specimens in all probability represent Chesapecten jef-
fersonius (see Ray, 1987), since 1993 the official fossil of the
Commonwealth of Virginia (Anonymous, 1993) and thus of
great historic and current interest if found.
This leaves only the matter of the donor, "Mr._____Wicks,"
who turns out to be a subject of specific and general interest in
spite of the paucity of information about him. The person in
question undoubtedly is Michael Wicks, clerk of the Royal So-
ciety for at least 20 years (Thomson, 1812:15, lists his years in
office as 23), from the first meeting of the council on 13 May
1663 (Birch, 1756(1):236) at least until 27 November 1683,
when it was resolved that "Mr. Cramer be clerk to the society
in Wicks's place" and that "Mr. Wicks be told, that his atten-
dance is of no farther use" (Birch, 1757(4):229). This resolu-
tion seems however not to have had the finality that it implied,
as Mr. Wicks was given orders at the meeting of 2 April 1684,
and the treasurer was ordered on 14 January 1685 to pay him
"fifteen pounds for a year and a half's salary" (Birch,
1757(4):277, 355). Robinson (1946:194-195) gave a summary
of Wicks' employment by the society, indicating that the last
mention of him is that of 13 November 1695, when a gratuity
was voted him by the Council; however, Hunter (1994:235)
noted a substantial payment to him as late as 1696. It should be
noted that Robinson refers to Wicks as "Weeks," that he ap-
pears as "John Weeks" in Weld (1848:562), secondarily as
"Weekes" in Hunter (1994:235), and is omitted altogether by
Lyons (1940:344).
Apparently prior to Wicks' appointment with the society, Dr.
Jonathan Goddard (1617-1675, professor at Gresham College)
had employed "Mr. Mich. Weekes, who looked to his stills"
(Aubrey, 1898(1 ):268). In this case, the stills were for produc-
tion of ingredients to various secret medicinal nostra. It is
thought that Wicks got the job as clerk through Goddard's in-
fluence (Robinson, 1946:194). This seems plausible in view of
Goddard's major role in the birth and early development of the
society, from its unchartered gestation, beginning in 1645
(Copeman, 1960; McKie, 1960), through the turbulent period
of the Civil War, Commonwealth, and Protectorate (inauspi-
cious for the founding of anything "Royal").
In John Aubrey's (1626-1697) notes (dated 12 March 1689)
for his brief life of Walter Raleigh, in connection with Ra-
leigh's role in introducing tobacco to England, he states
(Aubrey, 1898(2): 181-182),
Mr. [Michael] Weekes, register" of the Royal Society and an officer of the cus-
tome-house, does assure me that the customes of tobacco over all England is
four hundred thousand pounds per annum.
aSubst. for 'clerk.'
There can be no doubt that Weekes and Michael Wicks are one
and the same person. In response to my queries regarding
Wicks, Mary Sampson (pers. comm., 1993), archivist to the
Royal Society, found only one written communication by
Wicks in the society's unpublished Classified Papers series
(CL. P. XXIV.56), a brief undated note of some 13 lines, ad-
dressed to Henry Oldenburg (his boss). I have been unable to
decipher the handwritten note entirely, but the gist of it is that
he put out some papers for Oldenburg stating, "I am sorry I
could not wait upon you sooner, my business at Custome
House being much more than ordinary."
In 1993, Gillian Hughes, an independent researcher, under-
took on my behalf a preliminary search in the Public Record
Office for evidence of Michael Wicks in the Customs Estab-
lishment. The earliest certain indication found by her lists
Michael Wicks as Receiver for the Plantations among officers
of his majesty's customes for 1673 and 1675 (PRO 30/32/15
and 17), and his name was last seen in those lists for 1693
(PRO, CUST 18/28). In the published Calendar of Treasury
Books (Shaw, 1935:584), allusion is made under the date 17
April 1694 to "Mich. Wicks, late Receiver of the Plantation
Duties and of the new impositions on tobacco and
sugar... lately discharged from that service." The Calendar of
Treasury Papers (Redington, 1868:338) indicates "confusion
in the accounts of Mr. Wicks," and the Commissioners of Cus-
toms "describe their perplexities about his accounts, and that to
prevent further enlargement they had dispensed with his atten-
dance at the Custom House__Dated 5 Jan. 1693 [now 1694]."
Thus it seems clear that Michael Wicks (up to his dismissal
under a cloud) was in an unusually favorable position for di-
rect, frequent communication with merchant ships sailing to
and from British America. At the meeting of the Royal Society
on 13 June 1683, "Mr. WICKS was desired to procure from the
East-India ships a quantity of the shining sand of St. Christo-
pher's and James river in Virginia" (Birch, 1757(4):209). This
request would hardly have been made had it not been anticipat-
ed that Wicks could accommodate it.
Interestingly, this is the only instance in the long employ-
ment of Wicks by the society in which he was "desired" to do
something, rather than "ordered" or "directed." This is proba-
bly not accidental, but reflects a momentary deference to his
position with the custom house. Otherwise, paid subordinates
were addressed in the imperative, whereas the gentlemen Fel-
NUMBER 90
lows were "requested" or "desired" to do something. Pumfrey
(1991:12-16; Drake, 1996:17-18, 104-105, not withstanding)
has made a persuasive case for this distinction in connection
with his study of Robert Hooke's precarious position betwixt
and between, which may have contributed to Hooke's appar-
ently atypical egalitarian attitude toward subordinates (e.g., see
Shapin, 1989:269), as well as to his prickly attitude toward the
establishment.
It should be recognized that the society's treatment of Wicks
was not cruel and unusual but was in general correct for the so-
cial system of the time and place. Even allowing for the free-
wheeling attitude toward spelling in those days, it apparently
was not important to get his name right or even to include it
consistently in society records, nor perhaps was it important for
Grew to remember or later insert Wicks's given name in the
manuscript for the society's catalog.
The next explicit report of specimens from the Atlantic
Coastal Plain is that of Sloane (1697). He borrowed the speci-
mens from his friend, Dr. Tancred Robinson, who had just re-
ceived them from Maryland (most likely from the Rev. Hugh
Jones, who arrived there in 1696 and was accused by Wood-
ward of sending specimens to "rogues and rascalls," including
Sloane, Petiver, Lister, and Robinson (Stearns, 1952:292,
306)). These specimens included at least three isolated tooth
plates of the ray Aetobatis, illustrated in Sloane's figs. 7-12; it
is unclear from his text whether the articulated partial tooth
battery shown in his figs. 13 and 14 also is from Maryland (see
Figure 3). At least the fragmental plate shown in his figs. 7 and
10 is among the very small number of the founder's specimens
known to survive in BMNH, where it was featured in an exhi-
bition on the history of paleontology (Edwards, 1931:61) and
where it apparently is still to be found (Thackray, 1994:132).
Obviously Robinson must have allowed Sloane to retain at
least one of the fossils. Some or all of the others may be pre-
served in Woodward's collection at Cambridge. In an appendix
to his primary catalog of English "extraneous" fossils (catalog
B of Price, 1989:94), however, Woodward (1728-1729) listed
modem specimens preserved for comparison to his fossils, and
on page 111, under his entry number 25, a modern ray denti-
tion, he expressly stated that his ray tooth plates sent by Jones
from Maryland "were digg'd up, together with those" reported
by Sloane (see catalog B of Price, 1989).
Sir Hans Sloane (1650-1753) is best known as a prodigious
collector who provided the foundation for the collections of the
British Museum and its offshoots. He also was a man of parts
who was a successful doctor of medicine, an olympian letter
writer, and a major force in the Royal Society, although he was
not without his detractors, most notably John Woodward (e.g.,
see MacGregor, 1994:19). Most have made light of his abilities
as a thinker and researcher. Nevertheless, his little paper on the
fossil ray plates is an elegant example of modernity produced
before any pattern was established. He placed the isolated un-
knowns (considered by some to be bits of petrified mush-
rooms) alongside the most appropriate specimens of known
identity, articulated and disarticulated modem ray tooth batter-
ies, found them to be similar in detail, illustrated them accu-
rately in comparable orientations, and concluded that they de-
rived from identical or closely related organisms. One's first
impulse today might be to dismiss this approach as routine, but
it was not such in the context of the time. Although spectacular
examples of brilliant comparative methodology are known here
and there from the sixteenth century onward (note that Grew
used the approach and the term, "comparative anatomy," in
1681, see Figure 2), the techniques were not codified and uni-
versally applied until the nineteenth century under the influ-
ence of Cuvier, Owen, and Agassiz. This could not have oc-
curred prior to the Age of Enlightenment/Reason, with the
spread of the notion that all problems could be successfully
solved through intensive inspection and that ordinary humans
could rely on their own careful observations irrespective of au-
thority. This approach was the cornerstone of the Royal Soci-
ety. Until recently, this reliance was taken for granted, so much
so that the sublime notion could be expressed profanely, if I
may be permitted one homely example: Remington Kellogg,
once asked by a colleague what criteria allowed him to con-
clude that a certain fragmentary whale vertebra was in fact
identifiable to a particular species, immediately replied re-
soundingly, "because it looks like it, goddamit it!" He did not
live to experience the postmodern entry of doubt introduced by
phylogenetic systematics and social constructivism, in which
we question the meaning of all our observations.
Further, Sloane's (1697) note was written when the nature of
fossils as vestiges of once-living organisms had by no means
been universally accepted by serious scholars. This topic brings
us conveniently to the next known report and illustration of
fossils from the Atlantic Coastal Plain, that of a bone fragment
and a shark tooth by Scheuchzer (1708), whose title page and
figures are reproduced herein (Figures 4-6). Both specimens
are preserved in the Paleontological Museum of Zurich (Leu, in
litt., 1997; see also Furrer and Lev, 1998:33).
Johann Jacob Scheuchzer (1672-1733), little familiar to the
English-speaking scientific community, is known primarily as
an object of derision for his Homo diluvii test is faux pas, based
on a fossil salamander (see Jahn, 1969, for this and for a good
thumbnail biography of Scheuchzer in English). Scheuchzer
was actually a very substantial scientist who translated Wood-
ward into Latin and promoted his ideas (notably organic origin
of fossils) on the continent. Scheuchzer was in close contact
with Sloane and other leading naturalists of the Royal Society.
His historical significance would unquestionably be better ap-
preciated had Jahn's (1975) promised bio-bibliography of
Scheuchzer and translations of his major works materialized.
The bone fragment from Maryland was attributed by
Scheuchzer (1708:22) to the acetabular region of the innomi-
nate bone of a mammal ("Animalis"), not a farfetched supposi-
tion. This fragment, however, matches very well the portion of
a small cetacean atlas vertebra that characteristically remains
after the vertebra breaks at the weak points and rolls on the
beach; it is illustrated (Figure 5) alongside a typical float speci-
men and a well-preserved atlas from the Miocene of Chesa-
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
!Philojoz>h- (Transact- A~°. 2312
FIGURE 3.—Plate accompanying Sloane's 1697 report on fossil ray teeth from Maryland (xl). His figures 1-6
are of modern species, figures 7-12 are of fossil species from Maryland, and figures 13-14 are of fossils from an
unknown locality, possibly Maryland.
peake Bay in Maryland. This is probably the first cetacean (and
mammalian) fossil from America to be illustrated.
This Maryland specimen, especially if received by
Scheuchzer from Petiver, probably was sent by Hugh Jones.
Lhwyd (1660-1709) complained that Petiver and his pal Doo-
dy got aboard ship and rifled collections from Jones intended
for him (Gunther, 1945:343,462). Among specimens cataloged
by Sloane that came to him in Petiver's collection were "shark
NUMBER 90
PISCIUM
QUERELAE
ET
VINDICIAE
Expofit*
Johanne Jacobo Scheuchzero
Med. D> Acad. Lcopoldin. & So-
cietatum Regg. Anglican, ac Pruk
ficae Membro.
¦
TIGURI.
SumtibusAuthoris, Typis Geffnerianis..
—            M D feCr ¥llk.----
• \10S,
FIGURE 4.—Title page of Scheuchzer's 1708 classic, Piscium Querelae et Vindiciae (x 1).
teeth and other fossils sent from Maryland by the Revd Hugh       his job as chaplain to the governor of Maryland through the ini-
Jones" (Thackray, 1994:126). Jones communicated especially      tial recommendation of Lhwyd, furthered by the Temple Cof-
with Petiver and sent specimens from Maryland at least from       fee House group that included Sloane, Petiver, Doody, Lister,
1696 to 1702, although he became ill in 1700. Jones had gotten      and Robinson (Steams, 1952:292-294; Jessop, 1989).
10
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 5.—Cetacean atlas vertebrae in cranial aspect (x0.82), a. Scheuchzer's figure reproduced; b. similar
waterworn fragment, Lophocetus sp., probably collected on beach in Calvert County, Maryland, USNM
449525 (National Museum of Natural History, Smithsonian Institution, which houses collections of the former
United States National Museum); c. complete atlas. Cove Point, Calvert County, Maryland, St. Marys Forma-
tion, collected by Francis Markoe, Jr., 1841, part of the holotype oi Lophocetus calvertensis (Harlan), itself a
historic specimen (Gilmore, 1941:311-312, 377; Simpson, 1942:162, 176). (Scale bar=l cm.)
The second specimen, an incomplete tooth of Carcharodon
megalodon Agassiz from the Carolinas (Figure 6a), is de-
scribed by Scheuchzer (1708:20) as lacking serrations. The ab-
sence of serrations is of no taxonomic significance because the
tooth is clearly waterworn and is typical of the rolled speci-
mens so abundant in the lower reaches of several rivers in
South Carolina.
Scheuchzer's comparison was to Luid number 1259, a simi-
larly waterworn specimen from the British Crag (Figure 6c).
The number refers to the collection of Edward Lhwyd, Lati-
nized as Luid, among the many variations of the surname (see
Gunther, 1945:vii) (see Roberts, 1989, for a succinct biogra-
phy), whose specimen survives in the geological collections at
the University Museum, Oxford (Powell, in litt., 1993).
Scheuchzer's inferred outline of his incomplete specimen is a
very early example of paleontological restoration, however
modest.
Jacob (or James) Petiver (71663-1718), identified as the do-
nor, was a London pharmacist and perhaps second only to
Sloane as a natural history collector and letter writer (see
Stearns, 1952, for the fullest account of Petiver). Of course,
Lhwyd and Woodward outdid Petiver in their geological col-
lections (Torrens, 1985).
Petiver's most productive correspondent in South Carolina
was the Rev. Joseph Lord, who began sending him speci-
mens in 1701 and continued at least until 1713 (Stearns,
1952:346, 362). Especially relevant may be Petiver's
(1705:1960) account of two fossil shark teeth sent by Lord
NUMBER 90
11
FIGURE 6.—Teeth of Carcharodon megalodon (x0.82), a, Scheuchzer's figure reproduced; b, well-preserved
tooth, showing serrations, collected by P.J. Harmatuk, from Yorktown Formation spoil, Lee Creek Mine, North
Carolina, USNM 350941; c, waterworn specimen, probably from the bone bed at the base of the Red Crag, Suf-
folk, England (H.P. Powell, in litt., 1993), Lhwyd collection number 1259, Oxford University Museum, photo-
graph courtesy of Oxford University Museum of Natural History. (Scale bar=I cm.)
12
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
the first of which could possibly be the very one illustrated
by Scheuchzer.
Here may be mentioned what is probably the earliest allusion
to a fossil of a bony fish from the New World, other than Win-
throp's 1636 allusion to "Fishes' bones" from the James River
(Ray, 1983:4). In a letter to Petiver from his home at Dorches-
ter (this would have been old Dorchester on the Ashley River),
South Carolina, dated 1 September 1707, Lord writes:
Herewith comes a small box with divers Fossils.... In a part of my land where
some were digging after a sort of Marl... a stone was digged, somewhat flat &
broad, but looking like ye marl among which it lay, on which was ye tail of a
small fish & ye body near as far as ye Navel, of a brown colour, shewing fins &
scales very apparently, but all Stone; & it seemed so distinct that I had a con-
ceit I might separate it from ye rest of ye Stone, which I endeavoured to no pur-
pose, but in trying much defaced ye Impress; & since, only lying in my Study
made it more obscure: but however I have put it into ye Box.
The letter was marked as received on 26 January 1708, as
was presumably the accompanying small box. The original let-
ter is preserved among the Sloane manuscripts (Sloane 4064,
folio 150) in the British Library (permission to quote not re-
quired; Taylor, in litt., 25 April 1994) as a result of Sloane's
having purchased Petiver's papers and collections after the lat-
ter's death (Steams, 1952:244; MacGregor, 1994:23). The fos-
sil fish should have been among the Sloane specimens that ini-
tiated the British Museum, but if it survives in the BMNH, it
has not as yet been recognized (Thackray, 1994:132).
In striking contrast to the loss or unknown fate of most North
American fossils from the colonial era is the survival of those
in the Scheuchzer collection and in the incomparable collection
of his correspondent, John Woodward (1665-1728), preserved
essentially intact, with data, at the University of Cambridge.
The essential background to this collection can be learned from
Woodward's own catalogs (Woodward, 1728-1729), Gunther
(1937:424^133), and especially Price (1989). A measure of its
volume and significance can be gained from the catalog entries.
The North American fossils are contained in catalogs K and M
of Price's notation (1989:93-94; table 1). Of 655 catalog en-
tries for foreign fossils (only fossils in the modem sense, ex-
cluding rocks and minerals), 74 are North American; these rep-
resent a minimum of 127 of the total 1210 specimens. Thus, the
North American material constitutes more than 10 percent of
both total catalog numbers and specimens. Of the 127 speci-
mens, 74 are invertebrates, mostly mollusks, and 53 are verte-
brates, mostly sharks' teeth. Of the 74 catalog entries, 51 are
from Maryland and 23 are from Virginia. Among the Maryland
entries, at least 27 are attributed to William Vernon, 18 to
Hugh Jones, and three to David Krieg, the three most important
names in seventeenth-century natural history collecting in
Maryland. Although focused primarily on their botanical col-
lecting, the account of their activities in Maryland by Frick et
al. (1987) is a convenient and authoritative source (see also
Stearns, 1970:264-274). Jones, as previously noted, spanned
the years 1696-1702 but was largely incapacitated for the last
two. Vernon and Krieg overlapped almost exactly in their brief
visits, during the spring and summer of 1698. There was keen
interest and competition, in part unfriendly, among British nat-
uralists for the specimens. Woodward, generally at odds with
most of his contemporaries, boasted that "Mr. Doody had given
him all or the greatest part of those fossils you [Jones] sent
him" (Petiver to Jones, 10 March 1698; quoted in Frick et al.,
1987:19; see also Steams, 1970:265).
Of three catalog entries for Virginia specimens attributed to
John Banister, two are explicitly stated to have been given by
Doody, clearly a continuing benefactor of Woodward. Banis-
ter's collecting could not have been later than 1692, the year of
his death (see Ewan and Ewan, 1970, for a definitive account
of Banister).
All of the 20 North American entries (19 mollusks, 1 barna-
cle) in Woodward's additional list (catalog M of Price, 1989)
pertain to what was probably a single locality near the James
River, 20 miles (-32 km) above its mouth. One specimen was
found "by Lyons-Creek" (now Lawnes Creek, reverting to the
place names of Christopher Lawne's Plantation, established in
1619), which empties into the James River just below Hog Is-
land, opposite Williamsburg, some 20 miles (-32 km) up the
James. All are attributed to a "Mr. Miller," who is probably the
Mr. Miller described by Heame (Salter, 1915:148) as Wood-
ward's "neighbor & particular Acquaintance for 30 years past,
who often went abroad with him to gather Fossils, and assisted
him often in packing up boxes, to be sent abroad to Professors
& curious persons, & presented him himself with a Drawer or
two from the West Indies."
With the possible exception of the Miller specimens from the
James River, all North American specimens in the Woodward
collection were collected prior to 1700. Judging from the iden-
tity of the collectors, their time, and Woodward's annotations,
it seems highly probable that some of the specimens may have
been studied or illustrated by Banister, Lister, Sloane, or con-
temporaries. Price's valuable studies, cut short by his untimely
death, were only just beginning to reveal the value of this
unique resource, and it has not been feasible to examine the
collection firsthand for the present project. Close study of the
specimens with relevant literature at hand could scarcely fail to
yield interesting results. Some of the shark teeth have been ex-
amined recently by Shelton P. Applegate of the Universidad
Nacional Autonoma de Mexico.
The majority of the remaining entries for foreign fossils in
Woodward's catalogs (catalogs K and M of Price, 1989) are
from the extremely important collections of Scilla and
Scheuchzer. Woodward appears to have been meticulous in cit-
ing their specimens, but as yet none of his entries for them can
be identified as pertaining to North American specimens. The
collection should, of course, be searched for them.
The next instance of early collecting that I wish to note is
from a letter to Peter Collinson from John Custis of Williams-
burg, Virginia, believed to have been written on 28 August
1737. In it Custis alludes to the extreme drought of that sum-
mer, which necessitated his digging a deep well to water his
garden. The letter is quoted in part from Swem (1957:47):
As you are a very curious gentleman I send you some things which I took
out of the bottom of A well 40 feet deep; The one seems to bee a cockle petre-
NUMBER 90
13
fyd one a bone petrefyd; [this?] seems to have been the under beak of some
large antediluvian fowl. Wish they may bee acceptable.
In a letter of 5 December 1737, Collinson thanked Custis for
"the Curious Fossils that you sent Mee last year" (Swem,
1957:60); again, in a letter of 5 March 1741 (Swem, 1957:71),
Collinson alludes to fossils sent by Custis as "shells that was
found so Deep when you was Makeing the Mill Dam." At least
some of these fossils were on exhibit at Mill Hill School, on the
site of Collinson's home, near London, in the early 1930s, but
they have been lost sight of since (Swem, 1957:172; Hume,
1994:22). Interestingly, the 1964 archaeological reexcavation
of Custis' 40-foot (-12 m) well in Colonial Williamsburg, Vir-
ginia, yielded fossil shells and whale bones (Hume, 1994:20,
22). All of these specimens undoubtedly derive from the
Pliocene Yorktown Formation.
John Custis (1678-1749), educated in England, was a promi-
nent citizen of Virginia and an avid horticulturist, which led to
his association with Peter Collinson (Swem, 1957:11-20). Col-
linson (1694-1768) was a successful business man with exten-
sive interests in the American colonies, including a lifelong av-
ocation to botany (Swem, 1957:1-9). He was singled out by
Stearns (1951:194-195) as one of the most active fellows of
the Royal Society in encouraging North American naturalists.
He is perhaps best known in North America in connection with
the vertebrate fossils of Big Bone Lick, Kentucky (Jillson,
1936; Simpson, 1943). Although Collinson was especially ac-
tive in adding to Sloane's collection (Swem, 1957:3), no evi-
dence has yet emerged to identify any fossils from Custis' dig-
ging in Williamsburg in the surviving collections of BMNH.
Lastly, although much later than the other reports cited here-
in, I wish to supplement my earlier account (Ray, 1983:6-7) of
Latrobe's 1799 report of vertebrate fossils from Richmond,
Virginia, including sharks' teeth, fish vertebrae, a large bird fe-
mur, and a partial porpoise flipper. Latrobe (1809:283-284) re-
turned to this subject as follows:
It was my intention then, to have offered to the [American Philosophical] Soci-
ety, a series of geological papers, the materials of which I had collected, and of
which this memoir [Latrobe, 1799] was the first. But my intention was delayed
and partly defeated by the loss of a very large collection of all the principal fos-
sils, necessary to elucidate my observations, in their passage by water, from
Fredericksburg to Philadelphia.—This collection, intended for the American
Philosophical Society, was made by the industry of my excellent friends, Mr.
William Maclure now at Paris, of the late Dr. Scandella whose untimely death
in 1798 science and friendship equally have to deplore, and of myself.—It con-
sisted of specimens of loose and undecayed fossil shells, found on and near the
surface, from the coast to the falls of the rivers of Virginia, of the shell rocks of
York river, of the clays with impressions of shells in every fracture, but which
shew no remaining evidence of any calcareous matter when subjected to chem-
ical tests; of the exuviae of sea animals', bones of fishes, sharks' teeth, marsh
mud, fossil wood and coral rock, dug from the deep wells about Richmond, of
the marles of Pamunkey and Mattapony, of all the strata of the coal mines on
James's river, of the varieties of the granite of Virginia, of the free stone of
James's river and the Rappahannoc, with the vegetable petrefactions and coal
belong to it; and of a variety of miscellaneous fossils. ...The loss of this collec-
tion dispirited me, and the occupations of a most labourious profession de-
prived me of time.
"Drawings of some of the exuviae accompanied my memoir, to which refer.—
The bones of the foot there represented, are probably those of a sea tortoise....
Had those collections survived and become available for re-
search in Philadelphia, paleontology of the Atlantic Coastal
Plain might have been advanced by some decades. In the same
report Latrobe went on to discuss other geologic phenomena
including delineation of the fall line and its significance in rela-
tion to building stones. He was a practical man whose job at
that time was "Surveyor of the Public buildings of the U.
States," (Latrobe, 1809:293), which makes his closing observa-
tion (Latrobe, 1809:292) regarding the geologic problems dis-
cussed all the more revealing:
It is fortunate that the solution of these aenigmas of nature are of no conse-
quence whatever to our happiness, or of use to our enjoyments.—But the plea-
sures of investigation, and of wonder, the offspring of ignorance, are not with-
out a charm, which often entices the mere speculative philosopher into
researches that produce results beneficial to mankind.
We continue to vacillate in the unresolved and unresolvable
stress between applied and pure research. In the most recent cy-
cle, support for pure research probably reached a peak in the
expansive mood of prosperity during the 1960s, when science
could save us. We may hope that the retrenchment of the
1990s, with its demand for quick returns and the rise of pseu-
doscience, is the nadir of the curve and not the precipitous
slope of descent into continuing decay and rejection of science
(see Sagan, 1995, especially chapters 14, 23, and 25, and Gross
et al., 1996, for timely, accessible examinations of the problem;
see Maull, 1997, for an example of the widespread and disas-
trous confounding of science and scientists by social construe -
tivists).
Conclusions
Review of these additional early publications on fossils from
the Atlantic Coastal Plain leads to a few observations of seem-
ingly wider relevance. These may be grouped conveniently for
present purposes under the topics of "Firsts" for North America
and for paleontology and of "Sharks' Teeth."
Firsts.—Simpson (1942, 1943) was among the very few
practicing vertebrate paleontologists in the modem era to have
looked seriously into the early history of the subject in North
America. Here, too, should be mentioned the historical re-
search by Helen Ann Warren, under the aegis of Henry Fair-
field Osborn (in Osbom, 1931 :ix, 1-33), which was similar in
content and emphasis, if not in depth, to that of Simpson.
Simpson was more than casually involved with preparation of
the book (on Edward Drinker Cope) of which Warren's work
was part, overlapped completely with her at the American Mu-
seum of Natural History (Osborn, 1931:ix), and may have re-
lied too heavily on her spadework. Be that as it may, he
brought together a great deal of scattered information and quite
correctly contrasted casual or inconsequent early finds (such as
those by early Indians—interesting but not contributing to sci-
ence) with those that were to become factors in the advance-
ment of knowledge in western culture. In his words, "true dis-
covery [is] that leading by a traceable route, however devious,
to eventual elucidation of the problems concerned" (Simpson,
14
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
1942:135), and again, "merely seeing a fossil bone or picking it
up in idle curiosity is hardly discovery__scientific discovery
was that which initiated continuous consciousness and record
of the occurrence of fossil animals in America and had the first
scientific studies as its sequel" (Simpson, 1943:26-27).
Although these definitions are meaningful, Simpson was
mistaken in every instance in applying them toward identifica-
tion of firsts for North America, thus making his papers not the
definitive work that he supposed (Simpson, 1943:26). Taking
caution from his example, I do not propose that my candidates
are in truth firsts, only that they are the earliest known to me
(as indicated, I suspect, even hope, that there are still earlier
ones, especially Italian, and thus I believe that the present ac-
count is not the last word). It must be emphasized that Simpson
provides a large target only because he had the rare insight to
see the value of history and the ability to draw so much togeth-
er from scratch. His well-earned stature and authority make
doubly important the correction of his objective errors. Further,
those errors reflect what I believe to be a pervasive lack of
comprehension among American paleontologists of the sophis-
ticated nature of natural history investigations by western Eu-
ropeans in the late seventeenth and early eighteenth centuries.
Simpson (1942:131) defined six periods in the history of ver-
tebrate paleontology in America, the first two of which are of
interest here.
1.  Pre-scientific Period.—From the earliest times to about 1762. The first
fossil discoveries were made. Toward the end of the period bones were collect-
ed and sent to Europe. No truly scientific study of them had been made.
2.  Proto-scienlific Period.—From about 1762 to about 1799. In 1762
Daubenton read a paper on American fossils treating them for the first time in
what deserves to be called a scientific way.
In reference to Lord's 1707 letter to Petiver about the fossil
fish tail (see "Some Early Records," above) Simpson stated
(1942:135), "The incident is...unique for its date, and for a
long time there after, in involving a small fossil vertebrate.
Most of the eighteenth century naturalists overlooked bones of
animals smaller than the mastodon...." Simpson (1943:27) re-
garded letters from Cotton Mather as the "first publication on
American fossil vertebrates" (published in 1714 in the Royal
Society's Philosophical Transactions), and Simpson thought
they probably were based on mastodon remains. In allusion to
Catesby's 1743 report of African slaves' recognition of fossil
proboscidean teeth, Simpson (1942:134) credited them with the
"first technical identification of an American fossil vertebrate,"
assuming the incident to have occurred prior to 1739. Based on
the collection from Big Bone Lick, primarily of mastodon re-
mains, Simpson stated (1942:135), "If Columbus discovered
America in 1492, Charles Le Moyne, second Baron de
Longueuil, discovered American fossil vertebrates in 1739."
Simpson (1942:144-145) added that "Guettard (1756, read in
1752) published the first illustration of an American vertebrate
fossil... [and] a decade later Daubenton (1764, read in
1762)... [provided]... an excellent example of the comparative
method... one of the four most basic... principles in the rise of
vertebrate paleontology and it may fairly be dated from
Daubenton...." Both Guettard's and Daubenton's contribu-
tions stemmed from the 1739 Longueuil collection of mast-
odon remains.
Both Sloane (1697) and Scheuchzer (1708) conspicuously
antedate Guettard for the first description and illustration of
North American fossil vertebrates. Sloane's paper in particular
meets every possible criterion: the fossils reported were col-
lected through a purposive scientific program (about which
more beyond); Sloane was among the most prominent natural
historians of his or any other era; he published in the premier
scientific journal in English; his title alone reveals the signifi-
cance of his subject; the specimens are small, and at least one
survives today; and the paper is a model of comparative meth-
odology.
The larger point to be emphasized is the nature of the natural
history enterprise in western Europe in the late seventeenth and
early eighteenth centuries, for present purposes especially in
England, and especially centered among fellows of the Royal
Society. Their sustained, intensive, extensive interest in North
America is well recognized and is woven into the modem liter-
ature of zoology and especially of botany (Steams, 1970, and
Frick et al., 1987, are superb examples) but is reflected hardly
at all in that of paleontology (among notable exceptions is Ger-
mon et al., 1987), especially of vertebrates.
There was nothing in the least casual or chancy in the collec-
tion of North American fossils; rather, they resulted from a pur-
posive campaign. In fact, it is a little surprising that the results
were so meager for fossils in light of the effort expended.
Much of the voluminous correspondence of Sloane, Petiver,
Woodward, and others was devoted to creating and maintain-
ing a network of collectors, not least in the New World.
A very good taste of the flavor of time and place can be had
from Stearns' (1952:293-303) account of how the group
cooked up a collector in cleric's clothing. The Bishop of Lon-
don, in 1694, sought advice from Martin Lister in recommend-
ing a candidate for chaplain to the governor of Maryland. This
eventuated in Edward Lhwyd's putting forward his assistant,
Hugh Jones, whose specific qualification was that he would be
a worthy successor to John Banister. Jones was groomed in nat-
ural history, run hastily through religious orders, and rushed off
to Maryland. Besides Lister and Lhwyd, James Petiver, Samuel
Doody, Jacob Bobart, and Tancred Robinson are known to
have had specific roles in the care and feeding of Jones; Petiver
quite literally—besides equipment, supplies, and literature, he
sent Jones a Cheshire cheese and English beer, plus medicine
and medical advice (Steams, 1952:297, 299, 303).
John Woodward (1696) provided "brief instructions" to geo-
logical collectors (see Eyles, 1971:403; Price, 1989:93, foot-
note 7). Petiver also prepared instructions, which were sent out
with travellers and to correspondents. These were highly so-
phisticated, even to the point of recommending the stomach
contents of sharks, and other great fish, as a source of "divers
strange animals not easily to be met with elsewhere" (Steams
NUMBER 90
15
1952:363). As to fossils (his "formed Stones), Petiver instruct-
ed, "These must be got as intire as you can, the like to be ob-
served in marbled Flints, Slates, or other Stones, that have the
Impression of Plants, Fishes, Insects, or other Bodies in them;
these are to be found in Quarries, Mines, Stone or Gravel Pitts,
Caves, Cliffs, and Rocks, on the Sea shoar, or wherever the
Earth is laid open" (Stearns, 1952:364).
Thus, these natural historians knew exactly what they want-
ed and devoted much thought, energy, and money toward get-
ting it. Much of their massive correspondence concerns details
of instructing, inducing, exhorting, even bribing others to col-
lect (e.g., see MacGregor, 1995, on Sloane's correspondence
and Steams, 1952, on Petiver's).
SHARKS' TEETH.—Sharks' teeth are the quintessential enig-
mas of nature, whose charm has inspired wonder, and finally
researches, more widely and continuously than perhaps any
other fossil. It would scarcely be possible to overemphasize
their importance in cutting-edge debate on the meaning, nature,
and definition of fossils in the sixteenth and seventeenth centu-
ries. As indicated earlier, Rudwick (1976) has done a masterful
job in laying out the major features of the story as it unfolded in
the pioneering works of Colonna, Scilla, Steno, and Hooke;
these need not be retold, but some essential points may be em-
phasized.
First, "fossil" continued for many years to encompass almost
any, usually natural, object "dug-up" from the earth, notably
mineral specimens. "Figured stones" was a common term for
what we now understand as fossils. Until there was general ac-
knowledgment that objects resembling living animals or plants
actually were remains of once-living things, there was no logi-
cal basis to require a distinction from other interesting things
dug up.
Sharks' teeth, as glossopetrae or tongue-stones, were widely
and deeply embedded in European pre-scientific culture, ema-
nating especially from Malta, where the fossils are abundant
and are conveniently intertwined with the religious and magi-
cal lore of St. Paul, serpents, and poison (for a sampling of this
lore, see Zammit-Maempel, 1975, 1989, and Bassett, 1982).
From our present god-like heights of sophistication we have
tended to dismiss the seeming wrongheaded reluctance to rec-
ognize sharks' teeth and other fossils for what they are as the
ridiculous ignorance of benighted times; however, these gentle-
men were no simpletons but rather the greatest minds of that or
any other age. Even after presentation of the careful, logical ar-
guments of Steno and Hooke, widely circulated in the Royal
Society, that community of scholars did not rise as one in ac-
ceptance. Instead, the subject was hotly contested for some 30
years before being laid to rest pretty much by the early 1700s.
Grew, Hooke, Lhwyd, Woodward, Ray, Lister, Newton, and
Scheuchzer all weighed in on the issue (e.g., see Stokes, 1969).
Some, including Hooke, Woodward, and Scheuchzer, were de-
cisive in their support of organic origin. In this group only List-
er was adamant in his opposition. His views have been charac-
terized as ridiculous in hindsight, but his problem, in part, may
have been that he knew too much. Lister knew mollusks as per-
haps none other of the time, and demanded, but did not find,
exact correspondence between fossil and living forms. He was
no fool—witness his coming close to "inventing" geologic
mapping (Lyons, 1944:99; Steams, 1970:168). He might well
be the Agassiz to Hooke's Darwin in this debate. Further, rec-
ognition of fossils as such created serious problems in the
frame of reference of the time. From it followed almost inevita-
bly the problem of extinction of forms without modem coun-
terpart, and this was unacceptable in a perfectly economical
universe, whether divine or natural. It was in relation to this
problem that fossil and modern natural history specimens from
far off places, such as America, held special appeal. Locally
extinct organisms might well survive elsewhere.
With the possible exception of Lister, it might be observed
that the practices of those who equivocated on the nature of
fossils made sense only if they in fact accepted their organic or-
igin. For example, Grew (1681:257) extrapolated (pretty suc-
cessfully) on the size of shark (36 feet; -11m) from which
large glossopetrae originated; Sloane's (1697) paper on ray
teeth was based solidly on comparative methodology—his per-
functory allusion to God's wisdom seems all too much like
covering his flank. One is tempted to suspect persistence of a
certain measure of accommodation to authority through lip ser-
vice while proceeding operationally on the basis of persuasive
new insights.
Another fascinating aspect in which sharks' teeth illustrate
how scientific discovery works is the fact that Steno, Scilla,
Hooke, and Woodward were essentially coeval in their re-
searches. Barring some more persuasive evidence of intellectu-
al piracy than has thus far materialized, the interesting point is
that this was an idea whose time had come. Hooke was a great
and wide-ranging idea man, and there is no need to detract
from his astounding originality. His geologic insights and pri-
orities have at last been well presented (Drake, 1996). Never-
theless, he clearly had a tendency toward jealousy of priority—
whatever the topic, he thought of it first (which contributed
strongly to his irreparable schism with Newton). Even if Steno
was aware of Hooke's and/or Scilla's ideas, he has to be ac-
corded primacy because he developed the idea fully with step-
by-step logical procedure, which has been brought out best by
Scherz (1969, 1971). Woodward clashed with almost everyone,
was a thoroughly unsympathetic character, and was accused of
pirating Scilla's ideas, but he probably was not a plagiarist
(Jahn, 1972:210) (useful and accessible insights into Wood-
ward's activities and character may be found in Eyles, 1971,
and Levine, 1977).
Another great truth illustrated by this history is that discover-
ies do not stay discovered; they must be tended like a garden.
Scilla (1670) illustrated what turned out to be the first known
specimen of a sharktoothed porpoise, family Squalodontidae, a
nice piece of a mandible with three teeth. This historic speci-
men, preserved in the Woodward Collection at Cambridge, has
since been the object of repeated attention in the paleontologi-
16
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
cal literature of the modern era. Although first formally de-
scribed as a seal, and in one aberrant view regarded as a hippo-
potamus (Owen, 1840-1845:564-565, pl. 142: fig. 3), it has
long since become securely and correctly embedded in the lit-
erature as a squalodont cetacean, the holotype of Squalodon
melitensis (Blainville), where it has been alluded to and figured
repeatedly (e.g., see McCoy, 1867:145; Kellogg, 1923:24;
Gunther, 1937:433, unnumbered figure, p. 432; Fabiani
1949:26-29, figs. 9, 10; Rothausen, 1968:92). Then, in 1992,
Gould (in Purcell and Gould, 1992:93-94, figs. 64, 65) misi-
dentified the specimen as the jaw of a shark, invalid support for
the valid interpretation of glossopetrae. Although as always we
have a duty to correct objective mistakes, especially by con-
temporary and influential authorities (I wrote to Gould imme-
diately upon discovering the error, 8 March 1993), the signifi-
cant point is hardly that even the greatest living spokesperson
for paleontology to the world at large is fallible, but that ap-
proach to truth is a fragile dynamic that requires continual vigi-
lance. There may be some validity to Gould's (1996:110) claim
that "persistent minor errors of pure ignorance are galling to
perfectionistic professionals," but this has no bearing on the
overriding requirement that each professional strive assiduous-
ly to get things right and never knowingly let even "minor er-
rors" persist.
Finally, the history of sharks' teeth in relation to humans is a
powerful cautionary tale against fashion in science. Fortunate-
ly, people in general have maintained a seemingly innate curi-
osity and interest in them throughout time. In professional pale-
ontology, however, when I was a student some four decades
ago at a prestigious university, only a naive beginner would
risk being labelled childish, or worse, "amateurish," by betray-
ing any interest in sharks' teeth (or dinosaurs). Now dinosaurs
are the hottest topic in vertebrate paleontology, and even sharks
are respectable subjects of investigation (Klimley and Ainley,
1996). Scientists are probably no more foolish as a group than
the citizenry at large in lurching to extremes, but they may tend
to appear so in retrospect because they put extreme views on
record in emphatic terms. More reflective attention to the histo-
ry of our science would undoubtedly tend to mitigate our most
embarrassing emanations and perhaps damp down fadism. I
hope that these few modest historical nuggets are enough to
persuade readers that ancient specimens, many lost or mislaid,
and the thinking and writing surrounding them are not mere
quaint curiosities but are landmarks that can and should have
meaning today.
Secord (1996:459) has made a forceful case for the value of
history not merely as entertainment or nostalgia but as an ac-
tive force in research, concluding:
Rather, a bold enquiry into the past can uncover the basic structures and
large-scale patterns of change which lie behind our current dilemmas. We have
inherited not just our institutions and practices, but our problems: and these can
only be understood as products of history. A new culture of natural history will
flourish only if it is effectively rooted in—and draws upon—a critical under-
standing of the past.
Acknowledgments
This is perhaps the last seemly opportunity to thank David J.
Bohaska, National Museum of Natural History (NMNH),
Smithsonian Institution, Washington, D.C, for his steadfast
and effective assistance not only in all aspects of my research
but in preparation of volumes III and IV, as he now has the
thankless status of coeditor in recognition of the reality of his
indispensable contributions. In preparation and repreparation
of illustrations, it has been our good fortune to have had the un-
flagging, even enthusiastic, support and initiative of Irina Ko-
retsky, Victor E. Krantz, and Mary Parrish (all of the NMNH).
Long after our golden prose has tarnished, the pictures will re-
main as new.
For the substantive content of these volumes, we are of
course indebted to two groups, in part overlapping. First, the
collectors, mostly unpaid volunteers, without whom there
could be no science of paleontology. They are named as ap-
propriate in the individual papers. Second, the researchers
who have contributed the papers that give meaning to the
specimens. Many of them have waited, not totally with pa-
tience, but they have waited, a quarter century, for my unreal-
istic expectations of early conclusion to become reality. This
delay has required the greatest forbearance from the most
prompt authors, in that they have had to revise and update re-
peatedly.
Numerous individuals have aided generously in preparation
of this small historical paper, with information and advice on
specimens, records, and literature. These include, alphabetical-
ly by surname, Vanessa J.A. Carr (Public Record Office, Chan-
cery Lane, London), Mike Dorling (Department of Earth Sci-
ences, Cambridge), Burkart Engesser (Naturhistorisches
Museum, Basel), Paula Findlen (History Department, Universi-
ty of California, Davis), Gerald M. Friedman (City University
of New York), Ivor Noel Hume (Colonial Williamsburg, Vir-
ginia), Michael Hunter (Department of History, Birkbeck Col-
lege, University of London), Laura Laurencich-Minelli (Dipar-
timento di Paleografia e Medievistica, Universita Degli studi di
Bologna), Urs B. Leu (Zentralbibliothek, Zurich), Arthur
MacGregor (Ashmolean Museum, Oxford), Patrick Nuttall
(The Natural History Museum, London), H. Philip Powell
(Geological Collections, University Museum, Oxford), Christa
Riedl-Dorn (Archiv-Leitung, Naturhistorisches Museum,
Wien), Mary Sampson (The Royal Society, London), Carlo
Sarti (Dipartimento di Scienze Geologiche, Universita degli
Studi di Bologna), Antony J. Sutcliffe (The Natural History
Museum, London). G. Taylor (The British Library, London),
K.J. Wallace (Central Archives, The British Museum, Lon-
don), and George Zammit-Maempel (Birkirkara, Malta).
For critical review and improvement of the manuscript I
thank David J. Bohaska and I thank Ellen Compton-Gooding
(now retired) and Lauck W. Ward (both Virginia Museum of
Natural History, Martinsville).
NUMBER 90
17
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Analysis and New Records of Billfish
(Teleostei: Perciformes: Istiophoridae)
from the Yorktown Formation, Early Pliocene
of Eastern North Carolina
at Lee Creek Mine
Harry L. Fierstine
ABSTRACT
Five species of the billfish family Istiophoridae (Istiophorus
platypterus (Shaw and Nodder), Makaira indica (Cuvier),
M. nigricans Lacepede, M. purdyi Fierstine, Tetrapturus
albidus Poey) were identified from approximately 500 separate
bones collected in the Yorktown Formation (early Pliocene) at Lee
Creek Mine, North Carolina. This is the only record of M. purdyi,
the first fossil record of the genus Tetrapturus (specifically T.
albidus), the second fossil record of /. platypterus and M.
indica, and the first record of I. platypterus, M. indica, M. nig-
ricans, and T. albidus from fossil deposits bordering the Atlantic
Ocean.
Identification was accomplished by converting length and width
measurements of individual fossil elements to ratios (proportions),
treating them as variables, and comparing them to ratios computed
from a large series of bones from extant istiophorid species. Ratios
of a fossil specimen that fell outside the range of ratios computed
for extant species, or that were equivocal as to genus or species,
were identified as one of the following: Istiophoridae, genus and
species indeterminate; Istiophorus cf. /. platypterus; Makaira
cf. M. indica; M. cf. M. nigricans; M. purdyi; cf. Makaira sp.;
or Tetrapturus cf. T. albidus. Fifty-three percent of the fossil
elements were identified as Istiophoridae, genus and species inde-
terminate, or as M. nigricans.
Significant differences (P<0.05) exist between the predentary,
rostrum, scapula, and vertebrae 1 and 23 of extant Makaira nig-
ricans and M. nigricans from Lee Creek Mine. Features at the
extremely significant level (P<0.001) are predentaries that are
deeper and rounder, rostra that have rounder cross sections and
more ventrally placed nutrient canals, and first vertebrae that have
a narrower transverse diameter anteriorly.
Harry L. Fierstine, Biological Sciences Department, California Poly-
technic State University, San Luis Obispo, California 93407.
A review of the natural history and zoogeography of the extant
Istiophoridae was used to draw inferences about Lee Creek bill-
fish. The presence of Makaira indica at Lee Creek Mine suggests
that the Panama seaway may have been a migration route for bill-
fish during the early Pliocene. The concentration of billfish at the
mine supports the contention that the Yorktown Formation repre-
sents a tropical to warm temperate (21°-28°C) oceanic environ-
ment that was deposited at depths greater than 100 m. Using the
width of the rostrum as an estimate of body size, M. nigricans at
Lee Creek Mine probably had a sex ratio of a nonspawning popu-
lation; therefore, I hypothesize that by Yorktown time M. nigri-
cans had already established the present pattern of migrating
northward in the western North Atlantic Ocean during the summer
to feed after spawning in more southern waters.
The fossil history of billfish relevant to the Lee Creek Mine
fauna is reviewed and in some cases specimens are reidentified.
The family Istiophoridae has a fossil history from the middle
Miocene to recent, with the qualification that "Istiophorus" soli-
dus (Van Beneden) (late Eocene, Ghent, Belgium) may be an istio-
phorid. Makaira belgicus (Leriche) (middle Miocene, Anvers,
Belgium), /. cf. /. platypterus (late Miocene, Eastover Forma-
tion, Virginia, United States), and Tetrapturus albidus (early
Pliocene, Yorktown Formation, North Carolina, United States) are
the oldest known species within their respective genera.
Introduction
Lee Creek Mine, located near Aurora, Beaufort County, east-
em North Carolina, is a large phosphate deposit mined by Tex-
asgulf, Inc. The Yorktown Formation (early Pliocene) at the
mine has yielded the world's largest collection of fossils of the
family Istiophoridae (billfish). Billfish are usually found as
partial remains of one or two individuals at any one site (nu-
merous references in Fierstine, 1990, and Schultz, 1987), but at
Lee Creek Mine approximately 500 separate bones have been
21
22
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
collected (mostly segments of rostra and vertebral centra).
Based on past studies, the fragmentary nature of Lee Creek
specimens would be expected to contribute little to our knowl-
edge of extant billfish. Recently, however, Fierstine and Voigt
(1996) examined intra- and interspecific variation in recent
billfish skeletons and demonstrated that adult billfish could be
identified using rostral characters alone. They suggested that
their technique of identification could be applied to partial ros-
tra, whether fossil or recent. Herein I employ methods de-
scribed in their paper to establish the presence of four species
of extant billfish among the skeletal elements at Lee Creek
Mine and to relate these data to the natural history and zooge-
ography of living billfish species.
ACKNOWLEDGMENTS.—Without the contributions of many
visionary amateurs, especially Peter Harmatuk and Becky and
Frank Hyne, who donated fossil specimens to the National
Museum of Natural History (NMNH; containing collections
of the former United States National Museum (USNM)),
Smithsonian Institution, there would have been few speci-
mens to study. R. Bisbee and family were gracious hosts dur-
ing the 1995 Bisbee Black and Blue Marlin Tournament,
Cabo San Lucas, Baja California Sur, Mexico. Special thanks
are extended to the following individuals for allowing exami-
nation of specimens in their custody: B. Brown (American
Museum of Natural History), D. Catania (California Academy
of Sciences), R. Feeney (Los Angeles County Museum of
Natural History), S. Jewett (NMNH), M. McGrouther (Aus-
tralian Museum, Sydney), R. Purdy (NMNH), R. Rosenblatt
(Scripps Institute of Oceanography, University of California,
San Diego), V. Schneider (North Carolina State Museum),
and J.D. Stewart (Los Angeles County Museum of Natural
History). R.E. Weems (United States Geological Survey, Re-
ston, Virginia) and L.W. Ward (Virginia Museum of Natural
History, Martinsville) provided valuable information on the
collection site of Istiophorus calvertensis Berry (=7. cf. 7.
platypterus). R. Purdy led me on an informative field trip to
Lee Creek Mine and was exceedingly helpful in sending me
specimens and references and in keeping me informed on var-
ious aspects of the Lee Creek Mine project. M. Gottfried
(Michigan State University Museum), J.D. Stewart (Los An-
geles County Museum of Natural History), and D. Tyler
(Smithsonian Institution Press) made valuable suggestions on
an earlier version of the manuscript. L.G. Barnes (Los Ange-
les County Museum of Natural History) reviewed part of the
paleogeographic section and brought Metaxytherium arcto-
dites Aranda-Manteca, Domning, and Barnes to my attention.
Finally, A. Fierstine deserves special recognition for her as-
sistance and encouragement throughout this study.
Materials and Methods
Following Fierstine and Voigt (1996), I use the scientific and
common names of Robins et al. (1991) for recent species of
fish, the institutional abbreviations of Leviton et al. (1985), and
a combination of the osteological terminology of Davie (1990),
Gregory (1933), Gregory and Conrad (1937), Jollie (1986),
Rojo (1991), and Schultz (1987). Linear measurements of
bones or structures were made to the nearest 0.5 mm with dial
calipers or metric rule.
Lee Creek Mine Specimens.—Billfish fossils were collect-
ed primarily by amateurs over the past 20 years from the
weathered surface of spoil windrows from zones 1 and 2
(Yorktown Formation), a by-product of dredging operations.
Gibson (1983) concluded that both zones were deposited in
early Pliocene time, and Hazel (1983:97) dated both zones at
4.4-5.0 Ma based on planktonic foraminifers and radiometric
dating of a stratigraphically equivalent site. Zone 1 contains
sediments of open marine, inner- to middle-shelf environments
that were deposited at depths of 80 to 100 m, and zone 2 con-
tains sediments of regressive, marginal marine environments
that accumulated at 30 m or less (Gibson, 1983).
Approximately 500 individual elements were examined, in-
cluding 183 vertebrae (mostly centra), 97 rostral fragments, 51
predentaries, 30 scapulae, 28 quadrates, 26 first pectoral rays,
21 maxillaries, 18 articulars, 17 dentaries, 13 parasphenoids,
six epurals, four pterygiophores, two median-fin spines, and
one vomer. The material is housed at NCSM and NMNH.
Recent Comparative Specimens.—Whole and partial
skeletons were examined. The number of specimens studied,
their size range (length from lower jaw to fork of caudal fin,
in mm), and the general collecting locality for each species are
as follows. Sailfish, Istiophorus platypterus (Shaw and Nod-
der): 29 (1437-1830) western Atlantic Ocean, 16
(1770-2175) eastern Pacific Ocean, 5 (1365-2025) off eastern
Australia; black marlin, Makaira indica (Cuvier): 3
(2457-3054) eastern Pacific Ocean, 8 (1325-2120) off eastern
Australia; blue marlin, Makaira nigricans Lacepede: 41
(1727-3283) central Pacific Ocean, 1 (3280) Indian Ocean, 11
(2210-2432) western Atlantic Ocean, 1 (size and locality un-
known); white marlin, Tetrapturus albidus Poey: 21
(1530-1765) western Atlantic Ocean; shortbill spearfish, Tet-
rapturus angustirostris Tanaka: 5 (1486-1619) central Pacific
Ocean; striped marlin, Tetrapturus audax Philippi: 11
(1924-2463) eastern Pacific Ocean, 1 (2500) off eastern Aus-
tralia, 2 (2420-2650) off New Zealand, 1 (1990) Indian
Ocean, 1 (size and locality unknown); Mediterranean
spearfish, Tetrapturus belone Rafinesque: 1 (size unknown)
Mediterranean Sea; longbill spearfish, Tetrapturus pfluegeri
Robins and de Sylva: 3 (1690-1740) western Atlantic Ocean.
The material is housed at the following institutions: AMNH,
AMS, CAS, GMBL, LACM, NCSM, UF, and NMNH.
Fossil Comparative Specimens.—The museum number,
osteological material, geological age, and locality are given in
the text for each relevant, non-Lee Creek Mine fossil speci-
men. The material is housed at The Natural History Museum,
London (which houses collections of the former British Muse-
um (Natural History) (BMNH)), IRSNB, LACM, MNHNP,
UCMP, and NMNH (collections are cataloged under USNM
numbers).
NUMBER 90
23
Characters
The characters and their definitions for each bone or struc-
ture are as follows.
ARTICULAR (Figure \a,b).—Five characters occur in the re-
gion of the socket (main jaw joint) for articulation with the
quadrate bone: length from the anterior margin of the socket to
the posterior edge of the articular (ASM); length of the socket
from its anterior to its posterior margin (AL); length from the
apex of the socket to the posterior margin of the socket (AAL);
width of the socket region from the medial process to the outer
margin of the socket (ATW); and width of the socket proper
(AW).
Dentary (Figure 2a).—Two characters are in the region of
the interdentary joint: depth from the anteriormost denticles
perpendicular to the ventral margin of the dentary (not to the
distalmost margin of the dentary, which often has a projection)
(DAD); and length of the interdentary joint from the mandibu-
lar foramen to the anteriormost denticles (DJL).
First Pectoral-Fin Ray (Figure 2e).—Two characters oc-
cur on the surface of the first pectoral-fin ray that articulates
with the scapula: greatest width from the outer margin of the
flange to the outer margin of the ray (FW); and width of FW
that crosses the scapular facet (FAW).
Maxilla (Figures \e,f 3a,c).—Five characters occur in the
"triangular region" that articulates with the nasal, premaxilla,
con
con
^QAW
FIGURE 1.—Bones of a generalized istiophorid: a.
left articular, lateral view of posterior region; b, left
articular, dorsal view of joint with quadrate; c, left
quadrate, lateral view; d, left quadrate, ventral view
of joint with articular; e, left maxilla, lateral view of
triangular region;/ left maxilla, dorsal view of trian-
gular region. Abbreviations: con=condyle, fv=facet
for articulation with vomer, i pr=internal process, m
pr = maxillary process, Q-A = socket of quadrate-
articular joint, sn = symplectic notch, tr=triangular
region of maxilla. See "Characters" for definition of
other abbreviations.
24
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
DJL
FIGURE 2.—Bones of a generalized istiophorid: a, left
dentary, medial view of interdentary joint; b, predentary,
left lateral view; c, predentary, dorsal view; d, left pecto-
ral girdle, lateral view emphasizing articular surface for
first pectoral-fin ray of scapula; e, left first pectoral-fin
ray, proximal view emphasizing articular facet for scap-
ula. Abbreviation: mf=mandibular foramen. See "Charac-
ters" for definition of other abbreviations.
DAD
FW
prenasal, and vomer bones: length of the "triangle" (ML);
height of the triangle (MH); width from lateral surface of the
triangle to the medial margin of the facet for articulation with
the vomer (MW); and height (MVH) and width of the facet
(MVW) for the vomer.
Although the maxilla in whole specimens is an elongate bone
with an anteromedially projecting internal process and a poste-
rolaterally projecting maxillary process, only the triangular re-
gion was preserved in Lee Creek specimens.
PARASPHENOlD (Figure Sa,b).—Four characters are in the
central region: distance between the left carotid foramen and
the orbital margin of the left dorsal wing (PAF); width between
the carotid foramina (PAFW); depth between the ventral mar-
gin of the parasphenoid and the notch posterior to the basisphe-
noid process (PAD); and narrowest width of the anterior pro-
cess (PAW).
PREDENTARY (Figure 2b,c).—Three characters were mea-
sured: length along the ventral midline (PL); width across the
widest expanse of the denticulated surface (PW); and depth
perpendicular to the long axis from the widest expanse of the
denticulated surface to the ventral surface of the bone (PD).
The posterior extensions of the predentary usually form wing-
like processes that are wider than PW, but because the exten-
sions often are missing in the fossils and broken in the recent
specimens, this measurement was omitted.
Quadrate (Figure \c,d).—Five characters were measured:
greatest height from the condyle for articulation with the artic-
ular to the tip of the dorsal process (QH); height from the
condyle to the notch for the symplectic bone (QHS); greatest
width (medial to lateral) in the region of the condyle (QAW);
width of the condyle (QMW); and length of the condyle
(QML).
Rostrum (Figures 3, 4).—Rostra were measured according
to the methods of Fierstine and Voigt (1996). Two regions
were emphasized in recent specimens: 0.5L, or one-half the
distance between the distal tip and the orbital margin of the lat-
NUMBER 90
25
H-
Bill   Length   (L)
0.5L
-H
0.25L
t
Premaxilla
Predentary        Maxj||a
(m pr)          Lateral
Ethmoid
FIGURE 3.—A generalized istiophorid rostrum (modi-
fied from Fierstine and Voigt, 1996): a. left lateral
view; b, dorsal view; c, ventral view. Abbreviations:
DE=dermethmoid bone, i pr=internal process, m
pr = maxillary process, ORB = orbital region,
PS=parasphenoid bone, tr=triangular region of max-
illa. See "Characters" for definition of other abbrevia-
tions.
m pr
0.25L
L Premaxilla -i
eral ethmoid bone, and 0.25L, or one-fourth the distance be-
tween the distal tip and the orbital margin of the lateral ethmoid
bone. Characters studied (Figures 3, 4) in each region (0.5L
and 0.25L, respectively) were depth (DI, D2) and width (Wl,
W2) of the rostrum, height (HI, H2) of the left nutrient canal
(as seen in cross section), and distance (DD1, DD2) of the nu-
trient canal from the dorsal surface (as seen in cross section).
Characters studied without reference to region were distribu-
tion of denticles on the dorsal surface of the rostrum measured
from the distal tip (DZ), length from the distal tip of the ros-
trum to the distal extremity of the prenasal bone (P), presence
or absence of denticles on the prenasal bone, and length from
tip to where the fused premaxillaries divide (VSPM) into sepa-
rate bones.
In Lee Creek Mine specimens, the exact position of 0.5L or
0.25L was unknown, and cross sections were studied at the
broken end(s). No transverse cuts were made. Using the tech-
nique of Fierstine and Crimmen (1996), a cross section was
estimated to be at 0.5L if the prenasal bone was large and to
be at 0.25L if the prenasal bone was tiny or absent. Characters
26
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
studied in each estimated region were identical to those stud-
ied in recent species.
Scapula (Figure 2d).—Three characters occur on the sur-
face that articulates with the first pectoral-fin ray: length from
the flange to the dorsal margin (SL); greatest width (SGW);
and narrowest width (SNW). The articular surface also was
judged to be "flat" or "curved."
VERTEBRAE (Figures 5c-/ 6).—All members of the Istio-
phoridae have 24 vertebrae, with the genera Istiophorus and
Tetrapturus having 12 precaudals and 12 caudals and the genus
Makaira having 11 precaudals and 13 caudals (Nakamura,
1983, 1985). Most vertebral remains from Lee Creek Mine are
incomplete, consisting only of centra without processes. Each
vertebra's general position in the vertebral column (e.g., anteri-
or precaudal or anterior caudal) usually can be determined, but
not its specific position (e.g., first caudal). In contrast, the first,
twenty-second, twenty-third, and twenty-fourth (hypural) ver-
tebrae are distinctive enough to be identified consistently
among the fossil vertebrae and, therefore, were chosen for de-
tailed examination.
Eight characters occur on the first, twenty-second, and
twenty-third vertebrae (Figure 5c—f): length from the anteri-
or edge to the posterior edge of the centrum (CL); length from
the anterior edge of the centrum to the anterior margin of the
spinal foramen (AS); length from the posterior edge of the
centrum to the posterior margin of the spinal foramen (PS);
lateral diameter of the anterior surface of the centrum (LAD);
dorsoventral diameter of the anterior surface of the centrum
(VAD); lateral diameter of the posterior surface of the cen-
trum (LPD); dorsoventral diameter of the posterior surface of
the centrum (VPD); and narrowest width of the centrum as
seen from the ventral surface (NW). An additional measure-
ment was made of the greatest width across the articular sur-
faces for the exoccipital bones (ASW) on the first vertebra
(Figure 5/).
Five characters occur on the hypural (Figure 6): length from
the anterior edge of the centrum to the hypural notch (HL); dor-
soventral diameter of the anterior surface of the centrum
(HDD); length from the dorsal tip of the hypural plate to the
ventral tip (HH); greatest width across the hypurapophyses
(HW); and length of the hypural notch (HNL).
Data Analysis
Species Identification and Comparison.—This paper
basically builds on methods developed by Fierstine and Voigt
(1996) for identifying recent billfish using rostral characters. I
believe ratios (proportions) help reduce size effects and facili-
tate identification of isolated bones or bone fragments; thus, ra-
tios were used as variables rather than direct measurements.
Ratios were usually formed by dividing a shorter measurement
(e.g., width) by a longer measurement (e.g., length). For exam-
ple, for the predentary bone (Figure 2b,c), width (PW) was di-
vided by length (PL) to obtain the ratio PW/PL, depth (PD)
was divided by length (PL) to obtain PD/PL, and depth (PD)
H-Width   (W1)-H
T    T
DD1          I
i Depth   (D1)
1
Nutrient   Canal
Midline   Suture
Premaxilla
H-Width   (W2)-*|
DD2   /                          \            I
if                              \ Depth   (D2)
Nutrient   Canal
Midline   Suture
6
Figure 4.—A generalized istiophorid rostrum (modified from Fierstine and
Voigt, 1996): a. cross section at one-half bill length (0.5L); b. cross section at
one-fourth bill length (0.25L). See "Characters" for definition of abbreviations.
was divided by width (PW) to obtain PD/PW. A table of ob-
served ranges for each ratio was constructed for each recent
species (Tables 1, 2).
Each Lee Creek Mine specimen was measured, the measure-
ments were converted to ratios (Tables 3, 4), and the ratios
were compared to the observed ranges of recent species (see
Table 5 for examples using selected predentary bones). If a ra-
tio fell within the range of the recent species, then it was so
scored. If a specimen had more scores of one species than an-
other, it was identified as belonging to that species. A specimen
was identified only to genus if its score overlapped two or more
species of the same genus; it was identified to family if its
score overlapped two or more genera. If some ratios fell out-
side the observed ranges for recent species, the specimen was
identified as a variant of a known recent (e.g., cf. Makaira sp.)
or fossil taxon.
Where possible, measurements of non-Lee Creek Mine fossil
specimens were converted to ratios (Table 6) and were com-
pared with both Lee Creek and recent specimens.
NUMBER 90
27
PAF
PAD
T.      ff
Iw
a pr
PAFW
P pr
i                 nPS,
NW
VAD
f
FIGURE 5.—Bones of a generalized istiophorid: a, parasphenoid, left lateral view of posterior region; h, parasphe-
noid, ventral view of posterior region; c, twenty-second vertebra, left lateral view; d. twenty-second vertebra,
anterior view; e, twenty-second vertebra, dorsal view;/ first vertebra, anterior view. Abbreviations: a pr=anterior
process, b pr=basisphenoid process, cf=carotid foramen, lw=lateral wing, p pr=posterior process, sf=spinal
foramen. See "Characters" for definition of other abbreviations.
Statistical Methodology.—As described above, sim-
ple descriptive statistics were used to identify fossil speci-
mens, that is, each ratio from a Lee Creek Mine specimen was
compared to the range of values for that ratio in all recent is-
tiophorid species (Tables 1, 2). After the identifications were
finalized, the unpaired Mest (Welch's modification, InStat®
statistical software (GraphPad Software, 1993)) was used to
compare variables (ratios) of Makaira nigricans from Lee
Creek Mine to those of recent M. nigricans (Table 7) and M
indica (Table 8). Other species from Lee Creek Mine were
28
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
HNL
[*— HW—?]
FIGURE 6.—Hypural of a generalized istiophorid: a. left lateral view; b, ante-
rior view. See "Characters" for definition of abbreviations.
not included in the statistical analysis because of their small
sample sizes.
Systematic Paleontology
Class Actinopterygii sensu Nelson, 1994
Division TELEOSTEl sensu Nelson, 1994
Order Perciforjvies sensu Johnson and Patterson, 1993
Suborder Scombroidei sensu Carpenter et al., 1995
Family ISTIOPHORIDAE sensu Robins and de Sylva, 1960,
genus and species indeterminate
Plates \a-k, 2a-j. 3d-h
Material.—14 articulars (NCSM 5576; USNM 284817,
284888, 290195, 291204, 475433, 481894, 481902, 481913,
481917, 488016, 488062, 488099, 488113); 8 dentaries (NC-
SM 2126; USNM 381941, 475394, 475417, 476373, 481980,
488025, 488084); 26 first pectoral-fin rays (NCSM 5297;
USNM 284901, 284918, 284919, 290147-290149, 290202,
475435, 475436, 481904-481907, 488026, 488028,
488030^88032, 488041, 488053, 488054, 488061, 488083, 2
USNM uncataloged); 5 maxillae (USNM 475425, 481983,
481989, 488038, 488039); 1 parasphenoid (USNM 284815);
26 predentaries (USNM 286961, 286966, 286967, 286970,
286977, 475398, 475403, 475404, 475412-475414, 481952,
481953, 481955-^81958, 481960, 481961, 481964^181966,
488010, 488012, 488013, 488015); 17 quadrates (NCSM 6966,
7901, 8324; USNM 475426, 475427,475429^175432, 481915,
488042, 488051, 488081, 488090, 488108, 488114, 488115);
37 rostra (NCSM 2972, 8657, 11224; USNM 286900, 286947,
286994, 286995, 475400, 475409, 475422, 476329, 476331,
476332, 476334, 481934, 481939,481945, 481946,481950,
481951, 481970,481975, 481978, 481984, 488017-488019,
488021, 488022, 488119, 7 USNM uncataloged); 12 scapulae
(NCSM 7902; USNM 290205, 290206, 475428, 475434,
481925, 481926, 488034, 488109, 488111, 2 USNM uncata-
loged); 9 vertebra number 1 (NCSM 4914, 6920, 11187;
USNM 286178, 488058, 488074, 488077, 488087, 1 USNM
uncataloged); 1 vertebra number 23 (USNM 488094); 11 hy-
purals (USNM 282946, 283731, 290542, 290594, 481982,
488091, 488092, 488103, 488105, 2 USNM uncataloged).
Remarks.—Specimens range in size from small to large and
have the morphology of a generalized istiophorid with the ex-
ception that some specimens have one or more ratios that lie
outside the range of values measured for extant istiophorids
(Tables 1, 2). Some of these unique specimens are as follows:
articular NCSM 5576 (Plate \a,b), with an AAL/AL ratio
(1.24) indicating an unusual-shaped socket for articulation with
the quadrate; dentary USNM 488084 (Plate lc), a very small
specimen, with a DAD/DJL ratio (0.32) indicating a shallow
interdentary joint; first pectoral-fin ray USNM 290202 (Plate
\d), with a FAW/FW ratio (0.80) demonstrating a large articu-
lar surface for the scapula; maxilla USNM 475425 (Plate \f,g),
with three unique ratios (MVW/MVH = 0.66, MVW/
MW=0.37, MVW/MH=0.43) indicating a very small articular
surface for the vomer bone; predentary USNM 481956 (Plate
\j,k), with two ratios (PW/PL=1.54, PD/PL=1.02) indicating
the bone is very short relative to its width and depth, yet it does
not appear abnormally developed; quadrate USNM 481915
(Plate 2a,b), with a QAW/QHS ratio (0.55) indicating a wide
surface for articulation with the articular; 17 rostra having ei-
ther one or both ratios Dl/Wl, D2/W2 with values greater than
0.83, suggesting a rounder cross section; first vertebra USNM
286178, with three ratios (LAD/CL = 0.36, LPD/CL=0.36,
LAD/LPD=1.0) indicating a centrum having a small diameter
for its length.
Parasphenoid bone USNM 284815 (Plate \h,i) is provision-
ally placed here because it has a confusing array of ratios: one
(PAF/PAD) scores only for Tetrapturus albidus and another
(PAD/PAFW) scores only for Makaira nigricans. Several pre-
dentaries (e.g., USNM 286961, 481955, 481957, 481960,
481961) are from large individuals, much larger than any ex-
tant Istiophorus platypterus or T. albidus examined. Fifteen of
the quadrates are so fragmentary that only two out of a possible
five ratios can be used for identification. All scapulas have
curved surfaces for articulation with the first pectoral-fin ray.
Some specimens are larger than any scapulas examined of ex-
tant /. platypterus and Tetrapturus spp. (e.g., USNM 475428),
whereas others are smaller (e.g., NCSM 7902, Plate id).
Nine of the 37 rostra have denticles on the prenasal bone
(Table 3), whereas the remainder either do not have denticles
or the presence or absence of denticles is unknown. Twelve of
the rostra are so poorly preserved that they have only one ratio
that can be used for identification. Rostrum USNM 481946
shares all of its ratios with extant M. indica as well as with one
of the species of extant Tetrapturus. Several rostra (e.g.,
NUMBER 90
29
Table 1.—Mean (x), observed range, and number of specimens examined (n) for each of 10 rostral variables (ra-
tios), and presence (P) or absence (A) of denticles on the prenasal bone for six extant species of the family Istio-
phoridae. Abbreviations for ratios are explained in the text and in the legends to figures 3 and 4.
	/. platypterus (x) (range) n	M. indica	M. nigricans (x) (range) n	T. albidus	T. anguslirostris	T. audax	T. pfluegeri
		(x) (range) n		(x)(range)n	(x) (range) n	(x) (range) n	(x) (range) n
Ratio Dl/Wl	.68(.58-.78)31	.72(.66-.78)10	.70(.59-.80)41	,62(.56-.66)13	.64(.57-.70)3	.68(.59-.80)13	.62(.59-.64)2
Hl/Dl	.24(.15-.35)28	.16(.13-.20) 9	.14(.07-.20)36	,13(.09-.15) 7	-	.I4(.I0-.I7) 8	-
DD1/D1	.32(.21-.41)28	.43(.38-.49) 9	,46(.33-.62)36	.40(.35-.45) 7	-	.11(.08-.14)  7	-
D2/W2	.64(.55-.75)30	,68(.58-.77)10	.64(.54-.83)41	.53(.47-.61)14	.61(.58-.64)3	.6I(.52-.67)13	.65(.65)2
H2/D2	.l8(.ll-.26)28	,10(.08-.12) 9	.12(.06-.21)32	,12(.09-.14) 7	.11(.07-.14)2	.12(.09-.14) 8	-(.15)1
DD2/D2	.38(.28-.46)28	.46(.38-.51) 9	.47(.22-.64)32	.40(.32-.43) 7	.63(.62-.63)2	,46(.41-.55) 8	.49(.48-.50)2
D2/VSPM	.03(.03-.04)25	.06(.05-.08) 8	.04(.04-.05)35	.04(.03-.05)12	.15(.13-.19)3	.04(.03-.05)12	.05(.05-.06)2
W2/VSPM	.05(.04-.06)24	.09(.07-.IO) 8	.07(.05-.08)35	,07(.06-.09)l2	.24(.20-.30)3	.06(.05-.08)12	.08(.07-.09)2
P/VSPM	,58(.45-.83)17	.53(.48-.60) 8	.51(.38-.87)33	,53(.42-.66)ll	.39(.30-.45)3	.48(.38-.57)l2	.55(.55-.56)2
DZ/P	1.4(.76-2.5)18	.30(.10-.50) 9	.04(0-.ll)37	2.4(1.5-3.3) 9	0(0)3	.93 (.30-2.0) 9	0(0)2
Denticles on	(P/A) n	(P/A) n (0/10) 10	(P/A) n (1/36) 37	(P/A) n (9/1) 10	(P/A) n	(P/A) n (2/8) 10	(P/A) n
prenasal bone	(8/23) 31				(0/3) 3		(0/2) 2
USNM 286994, 476334, 481939) have a naturally shortened
distal tip (Plate 2c,d). Two specimens have unequal-sized nu-
trient canals: USNM 475400 has the right canal more narrow
than the left, and the left canal of USNM 475409 (Plate 2h) is
larger in diameter than the right. The left prenasal of USNM
476329 extends more distally than the right.
Genus Istiophorus Lacepede, 1801
Istiophorus platypterus (Shaw and Nodder, 1792)
Plate Aa-k
Material.—2 maxillae (USNM 290198, 488082); 5 rostra
(USNM 286949, 286972, 481967, 481968, 481973).
Remarks.—Both maxillae are large and probably come
from specimens of greater body length than any extant Istio-
phorus platypterus examined. In fact, maxilla USNM 290198
(Plate 4a, b) is much larger than any maxilla examined for Ma-
kaira nigricans. All rostra are small and fit within the body
length expected for /. platypterus. All rostra have three or more
ratios on which to base an identification and have ratios Hl/Dl
and H2/D2 within the range of extant sailfish. Rostrum USNM
481973 (Plate 4e) has asymmetrically sized nutrient canals.
Istiophorus cf. /. platypterus (Shaw and Nodder, 1792)
Plate 5a-e
Material.—1 rostrum (USNM 286950); 1 hypural (USNM
488093).
Remarks.—Specimens are placed in this taxon because one
or more ratios fall outside the range of values measured for ex-
tant istiophorids (Tables 1, 2), whereas other ratios fall within
the characteristics of Istiophorus platypterus. Rostrum USNM
286950 (Plate 5c) has a H2/D2 ratio (0.27) greater than any ex-
tant /. platypterus examined (Table 1).
Genus Makaira Lacepede, 1802
Makaira indica (Cuvier, 1832)
Plate 5f-k
MATERIAL.—4 predentaries (USNM 475399, 475411,
488009, 488014); 2 scapulas (USNM 481927, 488112).
REMARKS.—The predentaries (Plate 5h-k) are distinguished
by having PD/PL ratios that only encompass Makaira indica
and M. nigricans and by having PD/PW ratios that fall outside
the observed range for M. nigricans (>0.61) but within the
range of other istiophorids. Both scapulas have a narrow, flat
articular surface for the first pectoral-fin ray (Plate 5f,g). A nar-
row width with a flat articular surface is characteristic of M. in-
dica (Wapenaar and Talbot, 1964) (SNW/SL, Table 2).
Makaira cf. M. indica (Cuvier, 1832)
Plate 5/
Material.—1 scapula (USNM 488100).
Remarks.—Scapula USNM 488100 (Plate 5/) has a narrow,
curved surface for articulation with the first pectoral-fin ray.
Makaira nigricans Lacepede, 1802
Plates da-m, 7a-m
Material.—4 dentaries (NCSM 2124, 2125; USNM
475396, 475423); 8 parasphenoids (NCSM 5159, 11248;
USNM 2855370, 421526, 481990, 488047, 488048, 488050);
13 predentaries (USNM 25741, 291066, 291114, 475415,
481935-481938, 481954, 481959, 481962, 481963, 488011);
38 rostra (NCSM 2129; USNM 286973, 286986, 286996,
290614, 297407, 475397, 475401, 475405, 475406, 475408,
475410,475419-475421, 476330, 476333, 481941—481943,
481947^181949, 481971, 481972, 481976, 481977, 488020,
488023, 488024, 8 USNM uncataloged); 5 scapulae (USNM
30
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Table 2.—Mean (i), observed range, and number of bones examined (n) tor variables (ratios) on 12 bones of
eight extant species of the family Istiophoridae. Abbreviations for ratios are explained in the text and in the leg-
ends to figures 1, 2, and 5.
Ratio	/. platypterus	M. indica	M. nigricans	T. albidus	T. angustirostri.	T. audax		T he/one	T. pfluegeri
	(x) (range) n	(x) (range) n	(x) (range) n	(x) (range) n	(x) (range) «	(x) (range)	/;	(x) (range) n	(x) (range) n
Articular									
AL/ASM	.70(.59-.80)22	.90(.85-.94)2	.80(.66-.93)23	.71(.58-.91)15	-	.78(.68-.88)	9	-	-(.81)1
AW/AL	.74(.53-.94)22	.70(.69-.70)2	,84(.68-l.l)23	.91 (.65-1.3) 15	-	.71(.58-.85)	9	-	-(.89)1
AAL/AL	.74(.59-.92)22	.59(.59-.60)2	.68(.47-.9l)23	.70(.54-.97)I5	-	,66(.55-.79)	9	-	-(.29)1
ATW/AL	1.1 (.91-1.4)21	,94(.94-.95)2	1.2(.98-1.6)22	1.3 (.96-1.9) 15	-	1.1 (.87-1.3)	9	-	-(1.1)1
AW/ATW	.67(.54-.78)26	.74(.74-.74)2	.71(.55-.78)22	.71(.57-.86)15	-	.63(.58-.70)10		-	-(.81)1
Dentary									
DAD/DJL	.44(.33-.55)l5	-(.86)1	,76(.55-.89)12	53(.47-.60)10	-	.56(.39-.74)	7	-	.26 (.22-30)2
First pectoral-fin ray									
(dorsal segment)									
FAW/FW	.65(.55-.71)17	.27(.18-.37)8	.65(.5I-.72)20	,66(.61-.72)14	-(.62)1	.62(.58-.67)	4	-(.72)1	-(.65)1
Maxilla									
MW/ML	.39(.25-.57)14	-	.64(.60-.70)  5	.47(.44-.5l)  8	-	.47(.45-,49)	2	-	.24(.23-.24)2
MH/ML	.33(.26-.47)14	-	,43(.38-.49)14	.38(.34-.45)10	-	.37(.36-.37)	2	-	.33 (.31-.34) 2
MVW/MVH	1.4(.95-2.4) 9	-	1.2(1.1-1.3)  3	1.2(.80-1.8)  3	-	1.2(.96-1.5)	2	-	-
MVW/ML	.22(.17-.36)  9	-	.36(.35-.37) 3	.20(.18-.24)  3	-	.28(.25-.3I)	2	-	-
MVW/MW	.55(.48-.63)  9	-	,56(.53-.60)  3	.44(.40-.48) 3	-	.60(.51-.69)	2	-	-
MVW/MH	,64(.59-.75)  9	-	.90(.81-.96)  3	.54(.50-.58) 3	-	.77(.68-.85)	2	-	-
Parasphenoid									
PAF/PAFW	.58(.39-.67) 9	-(•32)1	,41(.32-.52) 8	.51 (45-.60) 9	-	.68(.63-.72)	2	-	-(.63)1
PAF/PAD	.55(.47-.67) 9	-(.54)1	.64(.57-.73)  8	.60(.47-.83) 9	-	.62(.57-.68)	2	-	-(.49)1
PAD/PAFW	1.1 (.74-1.4) 9	-(59)1	.63(.55-.79)  8	.86(.73-.98) 9	-	1.1(1.1-1.1)	2	-	-(1.3)1
PAW/PAFW	.70(.62-.86)  9	-(.85)1	.84(.67-1.0)  8	.53(.4l-.73) 9	-	.58 (.47-68)	2	-	-(.89)1
PAD/PAW	1.6(1.2-2.2) 9	-(.70)1	.77(.62-.97)  8	1.7(1.0-2.1) 9	-	2.0(1.6-2.4)	2	-	-(15)1
Predentary									
PW/PL	.50(.23-.63)21	,54(.48-.62)5	.65(.45-l.I)23	.41(.34-.57)I5	.60(.54-.69)4	,42(.33-.51)13		-(59)1	-(.65)1
PD/PL	.27(.20-.37)21	,38(.30-.41)5	.36(.26-.58)23	,24(.20-.33)l5	.59(.52-.69)4	,26(.22-.30)13		-(¦53)1	-(.60)1
PD/PW	.56(48-1.0)21	.70(.63-.81)5	.56(.48-.61)23	,59(.53-.65)15	.99(.97-1.0)4	.60(.53-.72)l3		-(.90)1	-(.92)1
Quadrate									
QAW/QH	.17(.15-.20)11	.29(.28-.31)2	.23(.l9-.27)22	.21 (.18-24) 17	-(.16)1	.21(.20-.22)	4	-	-(.17)1
QMW/QAW	.68(.58-.8l)ll	.85(.83-.88)2	.77(.57-.92)22	.73(.48-.88)18	-(.65)1	,71(.67-.77)	4	-	-(62)1
QAW/QHS	.29(.24-.39) 11	.44(.44-.45)2	.36(.30-.43)2I	.35(.30-.40)18	-	.38(.37-.39)	2	-	-(.30)1
QMW/QHS	.I9(.17-.23)ll	.38(.38-.38)2	.27(.22-.35)2I	,25(.19-.30)18	-	.28(.27-.28)	2	-	-(.18)1
QMW/QML	.73(.62-.80)ll	1.1(1.1-1.1)2	.86(.63-1.0)22	.83 (.53-1.0)18	-(.56)1	.79(.65-1.0)	4	-	-(.71)1
Scapula									
SGW/SL	,67(.55-.81)13	.44(.36-.53)8	.58(.51-.76)20	.64(.54-.72)l3	.70(.68-.71)2	,63(.60-.64)	4	-	64(.64-.64)2
SNW/SL	.44(.30-.53)l3	.16(.11-.19)8	.35(.22-.51)20	.42(.30-.55)13	.60(.53-.68)2	.56(.49-.63)	4	-	,56(.54-.57)2
SNW/SGW	.65(.53-.78)l3	.36(.26-.47)8	.60(.37-1.0)20	.67(.50-.84)13	.87 (.74-1.0) 2	.89(.82-1.0)	4	-	.87(.85-.90)2
Vertebra 1									
AN/CL	.61(.53-.69)  7	-	.64(.51-.74) 6	.67(.57-.77)  4	-	.64(.59-.70)	2	-	-(.65)1
PN/CL	.46(.40-.52)10	-	,41(.38-.47) 9	.37(.26-,42) 4	-	.43(.39-.45)	5	-	-(.41)1
ASW/VAD	.82(.6I-1.0)  9	-	1.0(.79-1.6)  9	.89(.85-.96) 4	-	,90(.81-.97)	5	-	-(.86)1
ASW/CL	.62(.50-.78)  9	-	,95(.77-1.2) 9	.69(.64-.76) 4	-	.8l(.76-.88)	5	-	-(48)1
LAD/CL	.68(.60-.77) 9	-	,92(.84-I.0) 9	.69(.62-.75) 4	-	.78(.70-,87)	5	-	-(.53)1
VAD/CL	,77(.62-.91)I0	-	.94(.74-I.O) 9	,77(.74-.79) 4	-	.91(.82-.99)	5	-	-(56)1
VAD/LAD	1.1 (.88—1.3) 9	-	1.0(.80-1.2) 9	1.1(1.1-1.2) 4	-	1.2(1.1-1.2)	5	-	-(1.1)1
LPD/CL	,78(.72-.89)l0	-	1.0(.92-1.1) 8	.74(.69-.78) 4	-	.86(.80-.90)	5	-	-
VPD/CL	.76(.70-.83)I0	-	.95(.86-l.0) 9	.73(.69-.76) 4	-	,85(.78-.91)	4	-	-
VPD/LPD	.97(93-1.0)10	-	.93 (.86-1.0) 8	,98(.97-1.0) 4	-	.98(93-1.0)	4	-	-
LAD/LPD	,89(.82-.97) 9	-	,9l(.86-.96) 8	.93(.9l-.96) 4	-	.91(.88-.96)	5	-	-
VAD/VPD	1.0C.76—1.1)10	-	.99(.76-1.1) 9	1.1(1.0-1.1) 4	-	1.1(1.1-1.2)	4	-	-
NW/CL	.37(.22-.47)l0	-	.63(.57-.74) 9	.41 (.39-.47) 4	-	.45(.42-.52)	5	-	-(•22)1
NW/LPD	.47(.30-.56)10	-	.62(.55-.68) 8	.56(.5l-.60) 4	-	.52(.47-.58)	5	-	-
Vertebra 22									
AN/CL	.60(.57-.64) 11	-(.56)1	.60(.57-.62) 7	,58(.55-.62) 5	-	.60(.59-.60)	2	-	-(.62)1
PN/CL	.38(.32-.42)ll	-(.38)1	.39(.36-.43) 7	.39(.36-.45) 5	-	,40(.40-.41)	2	-	-(38)1
LAD/CL	,58(.45-.66)ll	-(.68)1	.77(.58-.87) 7	.58(.54-.63) 5	-	.61(.61-.61)	2	-	-(48)1
VAD/CL	.53(.47-.57)ll	-(.50)1	.50(.42-.54) 7	.50(.46-.53) 5	-	.52(.51-.52)	2	-	-(.45)1
VAD/LAD	.91 (.78-1.1) 11	-(.73)1	.66(.62-.73) 7	.87(.84-.92) 5	-	,85(.83-.87)	2	-	-(.94)1
LPD/CL	,54(.48-.62)IO	-(.74)1	,74(.56-.84) 7	,54(.5l-.57) 4	-	.64(.63-.66)	2	-	-(.46)1
NUMBER 90
31
			TABLE 2.—Continued.				
Ratio	/. platypterus (x) (range) «	M. indica	M. nigricans (x) (range) n	T. albidus	T. angustirostris (x) (range) n	T. audax            T. belone          T. pfluegeri	
		(x) (range) n		(x) (range) n		(x) (range) n     (x) (range) n     (x) (range) n	
VPD/CL	.49(.45-.54)ll	-(.50)1	,48(.45-.51) 7	,48(.46-.50) 4	-	.54(.51-.57) 2	-(.40)1
VPD/LPD	,90(.80-.97)10	-(.68)1	.65(.60-.81) 7	.89(.83-.93) 4	-	,84(.77-.9l) 2	-(.87)1
LAD/LPD	1.1 (.92-1.2) 10	-(.92)1	1.0(99-1.1) 7	1.0(99-1.1) 4	-	.95(.93-.97) 2	-(1.0)1
VAD/VPD	1.1(1.0-1.1)11	-(1.0)1	1.0(.94-l.l) 7	1.0(.98-1.1) 4	-	.96(.93-1.0) 2	-(1.1)1
NW/CL	.32(.26-.42)ll	-(.41)1	.49(.34-.56) 7	,32(.29-.34) 4	-	.33(.33-.34) 2	-(.68)1
NW/LPD	.58(.54-.62)10	-(.55)1	.66(.59-.72)  7	.60(.53-.67) 4	-	.52(.51-.53) 2	-(1.5)1
Vertebra 23							
AN/CL	.69(.67-.75) 8	-(.69)1	.59(.50-.68) 7	.58(.56-.94) 6	-(.66)1	.61 (.61-.62) 2	-(.72)1
PN/CL	.28(.20-.31)58	-(.24)1	,36(.28-.47) 7	.32(.30-.35) 6	-(.29)1	.31(.30-.31) 2	-(.28)1
LAD/CL	,62(.56-,71) 9	-(.83)1	.88(.64-l.l) 7	.64(.57-.71) 6	-(.56)1	.72(.69-.75) 2	-(.52)1
VAD/CL	.58(.48-.73)10	-(.56)1	.57(.52-,64) 7	,57(.53-.62) 6	-(¦53)1	.62(.60-,64) 2	-(.48)1
VAD/LAD	.90(.82-.98) 9	-(.68)1	,65(.57-.82)  7	.89(.86-.94) 6	-(.94)1	,86(.81-,92) 2	-(.92)1
LPD/CL	.56(.48-.82)I0	-(.63)1	.68(.53-,83) 7	.57(.52-.66) 6	-(.48)1	.65(.63-.67) 2	-(.47)1
VPD/CL	.50(.42-.63)10	-(•50)1	,52(.44-.59) 6	.53(.48-.59) 6	-(.43)1	.54(.52-.56) 2	-(.42)1
VPD/LPD	.90(.76-.99)IO	-(.79)1	.77(.71-.88)  6	,92(.88-.95) 6	-(.89)1	.83(.77-,89) 2	-(.91)1
LAD/LPD	1.2(1.1-1.2) 9	-(1.3)1	1.3(1.2-1.4)  7	1.1(1.1-1.1) 6	-(1.2)1	1.1(1.1-1.1) 2	-(1.1)1
VAD/VPD	1.2(1.1-1.2)10	-(1.1)1	1.1(1.0-1.2)  6	1.1(1.0-1.2) 6	-(1.2)1	1.2(1.1-1.2) 2	-(1.1)1
NW/CL	.53(.38-.81)10	-(.53)1	.61(.44-.76)  7	.5I(.46-.59) 6	-(.41)1	.53 (.51-.54) 2	-(.45)1
NW/LPD	.95(.76-l.l)10	-(.84)1	.90(.83-.92) 7	,89(.84-.95) 6	-(.86)1	.81(.80-.82) 2	-(.97)1
Hypural							
HDD/HL	.46(.38-.55)I0	-(.34)1	.38(.29-.43) 6	.47(.44-.49)  6	-(.47)1	.45(.41-.48) 3	-(•44)1
HDD/HH	.24(.22-.26)10	-(.20)1	.21(.15-.25) 6	.26(.24-.28)  6	-(.24)1	.24(.23-.25) 3	-(.24)1
HDD/HW	.41(.36-.47)10	-(•36)1	.39(.28-.46) 6	,45(.44-.47)  5	-(.46)1	.45(.40-.52)  3	-(.44)1
HL/HH	.53(.47-.58)10	-(¦58)1	.55(.52-.58) 6	.55(.52-.58) 6	-(.51)1	.53(.51-.56) 3	-(.55)1
HW/HL	1.1 (.94-1.4) 10	-(.96)1	.97 (.89-1.0) 6	1.0(1.0-1.1)  5	-(1.0)1	1.0(.94-1.1)  3	-(1.0)1
HW/HH	.59(.51-.66)10	-(.55)1	,54(.5O-.60) 6	.56(.54-.60)  5	-(.51)1	.54(.49-,57) 3	-(¦55)1
HNL/HL	.37(.30-.47)10	-(.22)1	.28(.22-.31) 6	.34(.29-.40) 6	-(.41)1	.32(.31-.33)  3	-(.37)1
290197, 290211, 421527, 481929, 488110); 6 vertebra number
1 (USNM 481923,488059, 488071, 488078, 488088, 1 USNM
uncataloged); 8 vertebra number 22 (USNM 286181, 488056,
488066, 488076, 488089, 488098, 2 USNM uncataloged); 16
vertebra number 23 (USNM 286179, 288000,488044, 488045,
488055, 488063, 488064, 488067, 488068, 488070,
488094-488096, 3 USNM uncataloged); 3 hypurals (NCSM
4938; USNM 488069, 488104).
Remarks.—All specimens have one or more ratios only
within the range of values measured for extant Makaira nigri-
cans (Tables 1, 2). Seven of the eight parasphenoids have only
one or two ratios out of a possible five used for identification.
Most predentaries were assigned to this taxon on the basis of
ratio PW/PL; however, four predentaries (USNM 475415,
481936 (Plate 6g,i), 481938, 488011) have two ratios (PW/PL,
PD/PL) characteristic only of M. nigricans (Table 2). All scap-
ulas have curved articular surfaces for the first pectoral-fin ray.
Eight of the 38 rostra have only one ratio (either Dl/Wl or
D2/W2) on which to base an identification. Two specimens
have denticles on the prenasal bone, six lack denticles, and the
presence or absence of denticles for the other 30 rostra is not
known. Specimens range in size from moderate (USNM
475421) to huge (USNM 475405, 481941 (Plate 6fh,j)). Some
specimens (e.g., USNM 297407, 475406, 481943, 481949,
481976,481977) have a naturally worn tip, sometimes with the
nutrient canals exposed at the distal end (e.g., USNM 481976,
Plate la-c). USNM 290614 has a small abnormal growth
(keel) on the dorsal tip of the bill.
All vertebrae 1, 22, and 23 have at least two or three ratios
with values that are characteristic of M. nigricans.
Makaira cf. M. nigricans Lacepede, 1802
Plates Za-j, 9a-f
Material.—2 parasphenoids (USNM 488049, 488116); 3
quadrates (NCSM 6944; USNM 476372, 481903); 5 rostra
(NCSM 7427; USNM 286958, 481944, 481974, 1 USNM un-
cataloged); 5 vertebra number 1 (USNM 481897, 481910,
488057, 488072, 488073); 5 vertebra number 22 (USNM
286177, 488033, 488079, 488080, 488086); 7 vertebra number
23 (USNM 476371, 481909, 488065, 488097, 3 USNM uncat-
aloged); 4 hypurals (USNM 283735,481979, 2 USNM uncata-
loged).
Remarks.—Specimens having one or more ratios that lie
outside the range of values measured for extant istiophorids
(Tables 1, 2) are placed here because the values for some of the
other ratios fall within the range characteristic of only Makaira
nigricans. Some of these unusual specimens include the fol-
lowing: parasphenoid USNM 488116 (Plate %d,f) with a PAT/
PAD ratio of 0.94, indicating a shallower depth of the paras-
phenoid bone; quadrate NCSM 6944 (Plate Sa,j) with three ra-
tios (QAW/QH=0.37, QAW/QHS=0.52, QMW/QML=1.1),
32
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Table 3.—Mean (x), observed range, and number of specimens examined (n) for each of eight rostral variables
(ratios), and presence (P) or absence (A) of denticles on prenasal bone for seven istiophorid taxa from Lee Creek
Mine. Abbreviations for ratios are explained in the text and in the legends to figures 3 and 4.
	Istiophoridae, gen. and	Istiophorus	Istiophorus cf. /.				
Character	sp. indeterminate	platypterus (x) (range) n	platypterus (x) (range) n	Makaira nigricans (x) (range) n	Makaira cf. M. nigricans (x) (range) n	Makaira purdyi (x) (range) n	Makaira sp.
	(x) (range) n						(x) (range) n
Ratio Dl/WI	.79(.65-.89)12	.73(.72-.75)3	_	,79(.77-.80) 3	-(.86)1		-
Hl/Dl	17(.10-.24) 6	.22(.21-.23)3	-	,15(.09-.19)14	.14(.1I-.I9)3	-	-(•20)1
DD1/D1	.48(.39-.64) 6	.37(.35-.42)3	-	.52(.41-.59)I4	,59(.47-.80)3	-	-(.43)1
D2/W2	.77(.61-.91)27	-(.69)1	-(.75)1	,76(.66-.83)36	.90(.86-1.0)4	(.95)1	.76(.73-.77)5
H2/D2	,14(.09-.22)16	.24(.22-.25)2	-(.27)1	.15(.06-.22)I6	.09(.06-.12)2	(.16)1	,17(.16-.17)2
DD2/D2	49(.32-.53)16	.44(.43-.45)2	-(.39)1	.52(.40-.62)I6	-(.57)1	(.57)1	.51(.47-.55)2
P/VSPM	-(.39)1	-	-	-	-	(.38)1	-
DZ/P	.31(.15-.41) 4	-	-	.49(.38-.59) 3	-(.81)1	(1.4)1	-(.35)1
Denticles on	(P/A/?) n	(P/A/?) n	(P/A/?) n	(P/A/?) n	(P/A/?) n	(P/A/?) n	(P/A/?) n
prenasal bone	(8/6/22) 36	(0/1/4) 5	(0/1/0)  1	(2/6/30) 38	(2/0/3) 5	(1/0/0)  1	(1/2/2) 5
quadrate USNM 476372 with two ratios (QAW/QH=0.37,
QAW/QHS=0.54), and quadrate USNM 481903 with one ratio
(QAW/QHS=0.51) indicating a wide surface for articulation
with the articular; five rostra having either one or both ratios
Dl/WI, D2/W2, with values greater than 0.83, indicating a
rounder cross section; five vertebra number 1 each with a NW/
LPD ratio greater than 0.70, indicating a more hourglass-
shaped centrum; five vertebra number 22 with a mixture of
unique ratios, two with a NW/LPD ratio greater than 0.74, indi-
cating a more hourglass-shaped centrum; seven vertebra num-
ber 23 with an array of unique ratios, including three with
VPD/LPD ratios less than 0.69, two with LAD/LPD ratios
greater than 1.39, and one with VAD/CL and VAD/LAD ratios
less than any other istiophorids; and four hypurals (USNM
283735, 481979 (Plate 9d,e), 2 USNM uncataloged), have HL/
HH ratios (0.72, 0.61, 0.63, and 0.62, respectively) indicating a
shorter height from tip to tip.
All vertebrae 1, 22, and 23 have a minimum of two ratios
(except one USNM uncataloged vertebra 23 with one ratio)
with values that are characteristic of M. nigricans. Hypurals
USNM 283735 and two USNM uncataloged specimens have
only three ratios out of a possible seven on which to base an
identification, and they have just one ratio characteristic of M.
nigricans.
Makaira purdyi Fierstine, 1999a
PLATE ia-c
Material.—1 rostrum (holotype, USNM 481933).
Remarks.—The rostrum is morphologically distinct from
any extant istiophorid in the following combination of charac-
ters: (1) the fused portion of the premaxillae is short and stout
with denticles covering at least the distal one-half of its dorsal
surface; (2) at 0.25L, the cross section is nearly round (D2/
W2=0.95) (Fierstine, 1999a).
Makaira sp.
Plates 9g-l, \0a-d.g-i
MATERIAL.—2 dentaries (USNM 286997, 475418); 1 pre-
dentary (USNM 481931); 2 quadrates (USNM 488006,
488075); 5 rostra (NCSM 11223; USNM 285384, 475390,
481969, 1 USNM uncataloged); 1 scapula (USNM 290204); 1
vertebra 23 (USNM 290542); 2 hypurals (USNM 481981,
488102).
Remarks.—These specimens have one or more ratios that
fall within the observed range of values measured for both Ma-
kaira indica and M. nigricans (Tables 1, 2). Both dentaries are
from large individuals. Predentary USNM 481931 (Plate
\0a,b) is massive, much larger than any extant istiophorid ex-
amined. Four of the five quadrates have four of five possible
ratios on which to base an identification, and all are from large
individuals. Rostrum USNM 285384 has an eroded tip with
both nutrient canals exposed. All rostra are from small- to
moderate-sized individuals with the exception of USNM
475390 (Plate 9g-i), which came from a very large fish. The
scapula has a curved articular surface and is from a very large-
sized individual. The hypurals (USNM 481981 (Plate \0h.i),
488102) came from large-sized individuals and have HNL/HL
ratios within the range of both M. indica and M. nigricans.
cf. Makaira sp.
Plate \0e,fj-l
Material.—2 dentaries (NCSM 2990; USNM 475395); 2
quadrates (USNM 481916, 481919); 1 hypural (USNM
488007).
Remarks.—These specimens have at least one ratio near
the observed ranges of values measured for Makaira indica
and M. nigricans, but they have one or more ratios that lie out-
side the ranges of values measured for extant istiophorids (Ta-
bles 1, 2). Some of these unusual specimens include the fol-
lowing: dentaries NCSM 2990 (Plate 10/) and USNM 475395
with DAD/DJL ratios (0.96 and 1.04, respectively) indicating a
NUMBER 90
33
deep interdentary joint; quadrates USNM 481916 (Plate lOk.l)
and 481919 with QAW/QHS ratios (0.47 and 0.53, respective-
ly) indicating a wider joint surface for articulation with the ar-
ticular; and hypural USNM 488007 (Plate lOef) with three ra-
tios (HL/HH=0.71, HW/HL=0.85, HNL/HL=0.11) indicating
both a longer centrum length and that it came from a small-
sized specimen.
Genus Tetrapturus Raflnesque, 1810
Tetrapturus albidus Poey, 1860
Plates \\a-j, \2a-d
Material.—3 articulars (USNM 290193, 488029, 488043);
7 maxillae (USNM 290203, 475393, 475402, 475424, 488036,
488037, 488040); 2 parasphenoids (USNM 488027, 488046); 2
quadrates (USNM 481908, 488008).
REMARKS.—I have reservations about recognizing Tetraptu-
rus albidus at Lee Creek Mine because its identification is
based on poorly preserved features of fragmentary material.
Articulars USNM 290193 (Plate 1 la.b) and 488043, all seven
maxillae, both parasphenoids, and quadrate USNM 488008 are
from individuals of greater body length than any extant species
of Tetrapturus measured. Five of the seven maxillae are poorly
preserved, with only two ratios available for identification.
Both parasphenoids are incomplete and have only ratio, PAD/
PAW, on which to base an identification. Quadrate USNM
481908 (Plate I2a,b) has a QAW/QH ratio (0.31) that falls
only within the range of values for Makaira indica, but its
QMW/QAW ratio (0.53) is only within the range of values for
T albidus. The other three ratios encompass an extant species
of Tetrapturus. Quadrate USNM 488008 (Plate 12c,d) has two
ratios (QMW/QAW=0.53, QMW/QML=0.61) characteristic
only of values measured for T. albidus.
Tetrapturus cf. T. albidus Poey, 1860
Plate \2e,f
Material.—2 maxillae (USNM 488035, 488085).
Remarks.—Both maxillae have MVW/MH ratios (0.46 and
0.47, respectively) outside the range of values measured for ex-
tant istiophorids (Tables 1, 2); however, other ratios are within
the observed range of values for Tetrapturus albidus.
Discussion
Comparison of Lee Creek Specimens to Other Fossil
AND RECENT SPECIES.—Because fossil billfish have been re-
viewed previously (Fierstine, 1974, 1978, 1990; Schultz,
1987), only specimens with direct relevance to Lee Creek and
recent istiophorids are discussed herein. There are three widely
recognized families of billfishes, each defined in part by its ros-
trum. The Istiophoridae (marlin, sailfish, and spearfish) have
an oval to round bill with paired nutrient foramina and have
both fossil and recent representatives. The Xiphiidae (sword-
fish) have a flattened bill with paired nutrient canals as well as
a central chamber and have both fossil and recent representa-
tives. The extinct Xiphiorhynchidae have an oval to round bill
with one or more pairs of nutrient foramina and a central canal.
Schultz (1987) recognized three questionable families of
billfish, the extinct Blochiidae, extinct Paleorhynchidae, and
extant Tetrapturidae. Too little is known about the first two
families to determine if they are billfish (Fierstine, 1974), and
the third should not be recognized (Fierstine and Voigt, 1996).
Carroll (1988) placed many of these questionable billfish in the
Xiphiidae, a decision that has no merit.
Most early workers (see references in Fierstine, 1978, and
Schultz, 1987) placed fossil specimens of Istiophoridae into
new or existing fossil species of Istiophorus. Perhaps other
genera and extant species were not considered because the sys-
tematics of the recent Istiophoridae was poorly understood.
Robins and de Sylva (1960, 1963), Nakamura et al. (1968), and
Nakamura (1983, 1985) revised the extant Istiophoridae and
recognized three genera, Istiophorus, Makaira, and Tetraptu-
rus, although the number of species in Istiophorus and Makaira
was equivocal. I follow Robins and de Sylva (1960, 1963) and
Robins et al. (1991), and not Nakamura (1983, 1985), in treat-
ing both the sailfish and blue marlin as single, world-wide spe-
cies (/. platypterus and M. nigricans, respectively) and not as
separate Atlantic Ocean (/. albicans and M. nigricans) and
Indo-Pacific Ocean (/. platypterus and M. mazara) forms. Ge-
netic studies support the status of a single, world-wide species
each of sailfish and blue marlin (Graves and McDowell, 1995).
Because most early workers placed fossil billfish of disparate
morphologies in Istiophorus (sailfish genus), I have reclassi-
fied specimens into other genera where warranted. If data to
make an accurate identification were lacking, I left the speci-
mens in Istiophorus but put quotes around the generic name.
"Istiophorus" robustus (Leidy, 1860) (AMNH 5684, holo-
type, ?Pleistocene, Ashley River, South Carolina) is a short
(140 mm) distal rostral fragment that was refigured by Hussa-
kof (1908). Based on published accounts, the specimen is oval
in cross section (long axis is dorsoventral) for most of its
length. Nutrient canals were not discussed or figured. Denticles
are probably restricted to the ventral surface (dorsal surface in
Leidy's figure, but the specimen is probably upside down)
(Fierstine, 1974). Schultz (1987) placed the specimen in Aglyp-
torhynchus Casier, 1967 (questionable billfish), and considered
it to have been collected in the Eocene. Without reexamining
the specimen I do not think it is relevant to Lee Creek istio-
phorids.
"Istiophorus" rotundus Woodward, 1901 (BMNH P8799,
holotype, Tertiary phosphate beds of South Carolina), is a
very stout and round rostral fragment that is extremely mas-
sive for its length (313 mm). Due to poor preservation, I mea-
sured the specimen's width and depth 95 mm distal from its
proximal end (W=93.8 mm, D=78.5 mm, D/W=0.84). The
rostrum has never been sectioned to determine the presence,
number, position, and size of nutrient canals. No denticles or
alveoli are visible, and I was unable to determine which sur-
34
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
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36
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Table 5.—Sample score sheet for species identification of selected predentary bones from Lee Creek Mine. Spe-
cies score code: 0=outlier, 1= Istiophorus platypterus, 2-Makaira indica, 3=M. nigricans, 4=Tetrapturus albidus,
5=T. angustirostris, 6=T. audax, 7=T. belone.
Catalog number		PW/PL		PD/PL		PD/PW	
	Value	Score	Value	Score	Value	Score	Species
USNM 291066	.83	3	.50	3	.60	1,3,4,6	Makaira nigricans
USNM 475399	.62	1,2,3,5	.40	2,3	.64	1,2,4,6	Makaira indica
USNM 475412	.59	1,2,3,5,7	.35	1,2,3	.59	1,3,4,6	Istiophoridae
USNM 481931	.58	1,2,3,5	45	3	.76	1,2	Makaira sp.
USNM 481956	1.54	0	1.02	0	.67	1,2,6	Istiophoridae
face is dorsal or ventral. Schultz (1987) placed /. rotundus in
Xiphiorhynchus, but it probably belongs to the genus Ma-
kaira. Until more is known about the morphology of /. rotun-
dus, meaningful comparison with Lee Creek and recent istio-
phorids is fruitless.
"Istiophorus" solidus (Van Beneden, 1871) (IRSNB P643,
holotype, late Eocene, Ghent, Belgium) is a poorly preserved
rostral fragment with one pair of round nutrient canals that are
placed more toward the lateral periphery than in other istio-
phorids. The specimen is 17 mm long, 27.3 mm wide, and 17.3
mm deep at its proximal end (D/W=0.63). The exact position
and size of the nutrient canals have not been recorded. Paired
grooves run the length of the dorsal surface and indicate the
presence of paired prenasal bones. Schultz (1987) placed /.
solidus in Xiphiorhynchus, but because of the lack of a central
canal and the presence of prenasal bones, I believe the speci-
men is an istiophorid. Its morphology is unlike any species of
recent billfish or billfish found at Lee Creek Mine, but the
specimen is poorly preserved.
Istiophorus calvertensis Berry, 1917 (USNM 9344, holo-
type, late Miocene, Eastover Formation, Tar Bay, James River,
Virginia), is a distal rostral fragment 310 mm long. Berry
(1917) originally thought the specimen was collected in the
Calvert Formation, but according to both R.E Weems (pers.
comm., 1996) and L.W Ward (pers. comm., 1996) there is
very little, if any, Calvert Formation at Tar Bay, and chances
are very strong that it was collected in the late Miocene Easto-
ver Formation of Ward and Blackwelder (1980). Both Weems
and Ward admit, however, that the specimen could have been
collected in the Yorktown Formation, although it is unlikely
due to the Yorktown Formation's minor presence at Tar Bay.
The specimen is 25.8 mm deep (DI) and 36.0 mm wide (Wl)
at its proximal end, which approximates 0.5L. A pair of nutri-
ent canals are exposed, each measuring 7.0 mm high (HI) and
located 11.0 mm from the dorsal surface of the rostrum (DD1).
The anterior extension of the prenasal groove (P) is 170 mm
from the distal tip; 0.25L is estimated to be 134 mm from the
distal tip. The rostrum is 21.2 mm deep (D2) and 30.8 mm high
(W2) at 0.25L. On the dorsal surface of the rostrum, denticles
extend posteriorly from the distal tip for 57.3 mm (DZ).
Based on ratios computed from these measurements (Table
6) and on reexamination of the specimen (Fierstine, 1998), I
identify this specimen as Istiophorus cf. /. platypterus. It has
relatively large nutrient foramina (Hl/Dl) similar only to re-
cent /. platypterus (Table 1), but the placement of the canals
(DD1/D1) and area of the dorsal surface covered with denticles
(DZ/P) are not sailfish-like. These latter two features are dis-
counted because the dorsal denticular pattern may not have
been completely preserved, and ratio DD1/D1 is nearly within
the range of values for recent /. platypterus. Comparison of
USNM 9344 to rostra from Lee Creek Mine (Table 3) shows
that the Dl/WI ratio is similar to that in specimens identified
as /. platypterus, the Hl/Dl ratio is unlike that in any specimen
studied, and the DZ/P ratio is similar to that in specimens iden-
tified as Makaira sp.
On the basis of its large nutrient canals, Schultz (1987) clas-
sified /. calvertensis in Pseudohistiophorus De Buen, 1950, a
genus that Nakamura (1983) synonymized with Tetrapturus.
Schultz made an erroneous decision because, as noted above,
Table 6.—Eight rostral variables (ratios) for six fossil istiophorid taxa from localities other than Lee Creek Mine. The
presence or absence of denticles on the prenasal bone is unknown for these taxa. Abbreviations for ratios are explained
in the text and in the legends to figures 3 and 4.
	Istiophorus cf. /.					
	platypterus.	Makaira helgicus,	Makaira courcelli,	Makaira panamensis,	Makaira teretirostris.	
	type of /. calvertensis	type specimen	type specimen	type specimen	type specimen	Makaira nigricans
	(USNM 9344)	(IRSNB Pl 117)	(MNHNP 250)	(USNM 181710)	(depository unknown)	(LACM 17693)
Dl/WI	.72	-	.67	-	.87	-
Hl/Dl	.27	-	-	-	.10	-
DD1/D1	.43	-	-	-	.58	-
D2/W2	.69	.80	.66	.76	.84	.76
H2/D2	-	.15	-	.27	.11	.17
DD2/D2	-	.34	-	-	.56	.56
P/VSPM	-	-	-	-	-	-
DZ/P	.34	-	-	-	-	-
NUMBER 90
37
the size of the canals relative to the depth of the rostrum fits
solely within the observed range of values for /. platypterus
(Table 1). Fierstine (1990) thought critical review would syn-
onymize /. calvertensis with M. nigricans; however, based on
the information presented herein, the specimen belongs to the
genus Istiophorus.
Istiophorus platypterus (Shaw and Nodder, 1792) was iden-
tified from a single, partial trunk vertebra (UCMP 125228) in
upper Pliocene sediments, San Diego Formation, San Diego
County, California, by Gottfried (1982). Until now, this verte-
bra was the only fossil record of a sailfish in the literature since
the revision of the extant Istiophoridae (Robins and de Sylva,
1960, 1963; Nakamura, 1983, 1985). Because the specimen's
exact position in the vertebral column is unknown, and because
I studied only vertebrae from Lee Creek Mine that could be ac-
curately identified to position 1, 22, 23, or 24 (hypural), I was
unable to compare it to Lee Creek material.
Makaira belgicus (Leriche, 1926) (IRSNB Pl 117, holotype,
middle Miocene, Anvers, Belgium) is a distal rostral fragment
measuring 200 mm long, 32.3 mm wide (W2), and 25.9 mm
deep (D2) at its proximal end. Prenasal bones are indicated by
grooves, and paired nutrient canals are visible in cross section.
Based on ratios in Table 6, the specimen falls within the range
of values of recent M. nigricans (Table 1) and of M. nigricans
from Lee Creek Mine (Table 3, except for the nutrient canals
being closer to the dorsal surface of the rostrum (DD2/D2)).
Makaira courcelli (Arambourg, 1927) (MNHNP 250, holo-
type, early Pliocene, Algeria) consists of two rostra and several
fragments. One well-preserved rostrum is 287 mm long, with
the following widths and depths in mm: Dl=21.7, Wl=32.6,
D2=16.4, W2=24.8. Ratios for this specimen are listed in Ta-
ble 6. The other rostrum is crushed at its proximal end and
measurements were not taken. Each rostrum contains one pair
of nutrient canals, but their size and position have not been
measured. Denticles are restricted to the ventral and lateral sur-
faces of the well-preserved specimen, and paired prenasal
grooves are present. Arambourg (1927) originally placed the
specimens in Xiphiorhynchus; however, Schultz (1987) placed
the specimens in Makaira and gave the age of the locality as
late Miocene. Based on the ratios given in Table 6 and the dis-
tribution of the denticles, I agree with Schultz's identification.
The lack of other morphological information precludes a mean-
ingful comparison between M. courcelli and other fossil and
extant istiophorids.
Makaira indica (Cuvier, 1832) was identified from a nearly
complete head (including pectoral and pelvic girdles and fins)
from the early Pleistocene, ?Cabatuan Formation, Luzon, Phil-
ippines, by Fierstine and Welton (1983). The specimen was
identified by its rigid pectoral fin, a diagnostic feature of the
black marlin. Until the present study, this specimen was the
only record of a black marlin in the paleontological literature.
Makaira cf. M. nigricans Lacepede, 1802, was identified
from an incomplete, disarticulated skull (USNM 375733) in the
Eastover Formation, late Miocene, Virginia (Fierstine, 1998),
and from a nearly complete rostrum (USNM 358534) in the
Gatun Formation, late Miocene, Panama (Fierstine, 1999b).
The Eastover specimen is similar to recent M. nigricans in 15
of 19 ratios, but it is dissimilar in four, three of which are out-
side the observed range of all extant istiophorids. The Gatun
specimen is similar to recent M. indica in 15 of 18 ratios, and it
is similar to recent M. nigricans in 16 of 18 ratios. Two ratios
that are similar to recent M. indica, but not M. nigricans, are
discounted because they involve the denticular pattern on the
dorsal surface of the rostrum, features that may have been in-
completely presereved.
Makaira panamensis Fierstine, 1978 (USNM 181710, holo-
type, late Miocene or early Pliocene, Chagres Sandstone, At-
lantic coast of Panama), was described from a large neurocrani-
um with a poorly preserved rostrum attached. Except for its
unique features (size of myodome, length of orbit, and relative
size of nutrient canals), the specimen is most similar to recent
blue marlin and black marlin; hence, the rationale for recogniz-
ing it as a new species of Makaira. If the rostrum without the
neurocranium had been among material collected at Lee Creek,
it would have been listed under "cf. Makaira sp." Fierstine
(1978) believed the Chagres Sandstone was late Miocene based
on Woodring (1957, 1970, 1973), but its age is now considered
to be late Miocene or early Pliocene (Woodring, 1982) or
Pliocene (Coates et al., 1992).
Makaira sp. was identified from several bones from late Mi-
ocene localities in Southern California. Fierstine and Applegate
(1968) studied a distal rostrum (LACM 17693) and predentary
bone (LACM 16074) from separate localities in Orange Coun-
ty, California, and Fierstine and Welton (1988) examined sev-
eral associated bones (articular, dentary, preoperculum, ptery-
giophores) of a single individual marlin (UCMP 118559) from
the San Mateo Formation, San Diego County, California. The
specimens were originally identified as Makaira sp. because of
a lack of recent comparative material, but now that skeletal ma-
terial is available, I have reexamined them with the following
results.
Extant Makaira nigricans (Table 1) is the common identifica-
tion for all three ratios computed for the rostrum (Table 6). Be-
cause the ratios of the predentary (PW/PL=0.62, PD/PL=0.37,
PD/PW=0.60) fall within the observed range of values (Table
2) for both Istiophorus platypterus and M. nigricans, it is identi-
fied as Istiophoridae, genus and species indeterminate.
Analysis of the articular and dentary bones separately, as in
the Lee Creek fossils, yields an identification of Istiophoridae,
genus and species indeterminate, for both; however, when they
are considered as skeletal elements from a single fish, then M.
nigricans becomes the obvious choice. The ratios of the articu-
lar are within the observed values for sailfish, blue marlin, and
white marlin, whereas the ratio of the dentary is within the ob-
served values for blue marlin and striped marlin; therefore, the
common identification for the two bones is M. nigricans.
Makaira teretirostris (Van Beneden, 1871) (?middle Mi-
ocene, Belgium, exact locality unknown) is a large, distal ros-
tral fragment (520 mm long) with paired nutrient canals and
prenasal bones. Denticles and alveoli are neither mentioned nor
38
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
figured. The original description of the specimen was based on
a cast and an artist's drawing, and disposition of the type is un-
known. Schultz (1987) synonymized the specimen with M. bel-
gicus and gave the type locality as southern France and the age
as Pliocene. I made measurements from the drawing in Van
Beneden (1871) and computed ratios (Table 6). Based on this
analysis, M. teretirostris is slightly outside the observed range
of ratios of recent M. nigricans (compare Tables 1, 6) but is
within the range of values of M. cf. M. nigricans from Lee
Creek Mine (Table 3). Without more information about the
specimen, I recognize M. teretirostris and do not synonymize it
with M. belgicus.
Lawley (1876) described a well-worn, elongate, slender ros-
trum from lower Pliocene rocks, Orciano, Italy, as Brachyrhyn-
chus vanbenedensis. The specimen was redescribed, refigured,
and placed into the living Histiophorus herschelii (Gray, 1838)
by Barbolani (1910). Nakamura et al. (1968) synonymized H.
herschelii with M. nigricans, and more recently Schultz (1987)
placed B. vanbenedensis in synonymy with M. teretirostris.
Until the specimen is studied further, I follow Schultz (1987).
In summary, the family Istiophoridae has a fossil history
from middle Miocene to recent, with the qualification that "Is-
tiophorus" solidus (late Eocene, Ghent, Belgium) may be an is-
tiophorid. Makaira belgicus (middle Miocene, Anvers, Bel-
gium), Istiophorus cf. /. platypterus (late Miocene, Eastover
Formation, Virginia, United States), and Tetrapturus albidus
(early Pliocene, Yorktown Formation, North Carolina, United
States) are the oldest known species within their respective
genera. The temporal distribution of the Istiophoridae is given
in Figure 7.
Interspecific and Intraspecific Variation.—Any study
of variation at Lee Creek Mine is dependent upon two factors:
the number of fossil bones identified to species and the number
of bones examined for each extant species. Only Makaira nig-
ricans is sufficiently represented at Lee Creek to make a statis-
tically meaningful comparison, and then only for a few bones.
Significant differences exist only between the predentary,
rostrum, scapula, and vertebrae 1 and 23 of extant M. nigricans
and M. nigricans from Lee Creek Mine (Table 7). The preden-
tary in the Lee Creek specimens tends to be wider (PW/PL),
deeper (PD/PL), and rounder in cross section (PD/PW). The
rostra from Lee Creek tend to have rounder cross sections
throughout their length, and the nutrient canals are smaller dis-
tally (H2/D2) and are more ventrally placed both proximally
(DD1/D1) and distally (DD2/D2). In addition, the distal dorsal
surface of the rostrum (DZ/P) is covered with more denticles
than in the extant blue marlin. The scapulae from Lee Creek
Mine have a narrower articular surface (SNW/SL, SNW/
SGW). First vertebrae from Lee Creek Mine exhibit a narrower
anterior articular surface (LAD/CL) and a more constricted
centrum (NW/LPD) with respect to their length. Twenty-third
vertebrae of the blue marlin from Lee Creek have centra that
are less depressed anteriorly (VAD/CL) and more constricted
(NW/LPD) with respect to their posterior width.
Blue marlin from Lee Creek Mine are more similar to extant
black marlin than to extant blue marlin in two features (Table
8). The predentary bone in Lee Creek material is rounder (PD/
PW) than in extant blue marlin, and the dorsal surface of the
distal rostrum has more denticles (DZ/P). So few vertebrae of
extant black marlin were examined that no meaningful compar-
ison with Lee Creek specimens was undertaken.
Table 7.—Results of the unpaired /-test (Welch's modification) to determine
significant differences between the means of variables (ratios) of the preden-
tary, rostrum, scapula, and two vertebrae among Makaira nigricans from Lee
Creek Mine and extant M. nigricans. Abbreviations for ratios are explained in
the text and in the legends to figures 2-5. (*=P<0.05; **=P<0.01;
»**=p<0.001.)
	Extant M. nigricans
Ratio	compared with
	Lee Creek M. nigricans
Predentary	
PW/PL	*
PD/PL	*«*
PD/PW	***
Rostrum	
Dl/WI	«*
DD1/D1	***
D2/W2	***
H2/D2	«*
DD2/D2	**
DZ/P	*
Scapula	
SNW/SL	••
SNW/SGW	*
Vertebra 1	
LAD/CL	***
NW/LPD	*
Vertebra 23	
VAD/CL	•
NW/LPD	*
Table 8.—Results of the unpaired /-test (Welch's modification) to determine
significant differences in the means of the same variables (ratios) listed in Ta-
ble 7 for the predentary, rostrum, and scapula among Makaira nigricans from
Lee Creek Mine and extant M. indica. Abbreviations for ratios are explained in
the text and in the legends to figures 2-5. (n.s.=not significant (P>0.05);
*=P<0.05; **=P<0.01; ***=P<0.001.)
	Extant M. indica
Ratio	compared with
	Lee Creek M. nigricans
Predentary	
PW/PL	***
PD/PL	**
PD/PW	n.s.
Rostrum	
Dl/WI	*
DDI/DI	• *•
D2/W2	***
H2/D2	*»?
DD2/D2	• *
DZ/P	n.s.
Scapula	
SNW/SL	**
SNW/SGW	*
NUMBER 90
39
Epoch
MYA
Species
Pleistocene
Pliocene
M
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t
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-11.0
-12.0
.13.0
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I
FIGURE 7.—Temporal distribution of the family Istiophoridae. Arrow indicates species that exist in recent time.
Time scale is from Gibson (1983:38 (uncopyrighted)).
Some of the rostra at Lee Creek Mine demonstrate abnormal-
ities found in extant billfish (Gudger, 1940; Morrow, 1951; Fi-
erstine and Voigt, 1996). For example, rostrum USNM 481976
(Plate la-c) has a foreshortened tip with nutrient canals ex-
posed distally, and rostrum USNM 475409 (Plate 2h) has un-
equal-sized nutrient canals. Rostrum USNM 481984 (Plate
2i,j) and a few others appear eroded, possibly by stomach acids
after being consumed by a predator.
Distribution and Life History of Recent Species.—
The following information was taken liberally from Nakamura
(1983, 1985) unless otherwise indicated. Emphasis is placed on
species that inhabit the Atlantic Ocean and are found at Lee
Creek Mine. In general, istiophorids are distributed throughout
tropical and subtropical waters, some entering temperate cli-
mates. All are oceanic and epipelagic species that usually favor
waters greater than 20°C. Sexes are separate and are indistin-
guishable externally. Each species has a distinct reproductive
season and spawning ground, and mature individuals spawn
several times each season by broadcasting gametes (Hopper,
1986). Adults are opportunistic predators, consuming cephalo-
pods (squids) and many different species of pelagic fishes, in-
cluding members of the Carangidae (jacks), Clupeidae (her-
rings, pilchards, sardines), Coryphaenidae (dolphin-fish),
Scombridae (mackerels, tunas, and allies), and Trichiuridae
(snake mackerels, cutlass fishes). Although age estimates are
given below for some species, aging of billfish is imprecise be-
cause of the difficulty in establishing annual growth patterns in
calcified structures (Hill et al., 1989). Frazier et al. (1995) con-
cluded the function of the rostrum was unclear. It may serve in
one or more capacities, possibly in hydrodynamics, food cap-
ture (spearing/slashing), or defense/aggression, but the fish can
get along without its bill because there are numerous records of
apparently healthy billfishes with damaged, malformed, or
missing rostra.
Istiophorus platypterus (sailfish) inhabits the Atlantic, Indi-
an, and Pacific oceans, possibly the Mediterranean Sea, and
40
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
sometimes enters the Red Sea through the Suez Canal. It is
considered to be the least oceanic of the billfishes, often mi-
grating to near-shore waters. Its distribution is influenced by
wind and water temperature, favoring temperatures of
21°-28°C. In the western North Atlantic and western Pacific
oceans, /. platypterus migrates northward in an extension of
warm water during the summer and migrates southward with
the onset of cold weather to form loose schools of up to 30 in-
dividuals. The sailfish reaches a total length of around 3.2 m
(tip of bill to tip of tail) and a weight of 58 kg in the Atlantic
Ocean and reaches around 3.4 m total length and 100 kg in
weight in the Indo-Pacific Ocean. Females are consistently
larger than males (Jolley, 1974). Tagged sailfish are generally
recaptured near their original release site; however, one speci-
men caught off Isla Mujeres, Mexico, in the Caribbean was
recaptured 2596 km distant off La Guiria, Venezuela (Nation-
al Marine Fisheries Service, 1994). De Sylva (1957) reported
that sailfish grow rapidly, attaining a weight of 9.1 kg within
one year and having an estimated life span of two to three
years. Jolley (1974), using a different aging method, found
that sailfish in the Atlantic Ocean reached an age of seven
years, with ages two to four being the most numerous.
Makaira indica (black marlin) is restricted to tropical and
subtropical waters of the Indian and Pacific oceans, except for
occasional strays into the Atlantic Ocean via the Cape of
Good Hope. It is found in waters with surface temperatures
ranging from 15°-30°C and is often found as close to land
masses as is Istiophorus platypterus. The distribution and
abundance of M. indica off Natal are positively influenced by
the presence of submarine canyons, some reaching a depth of
600 m within one km of shore (van der Elst, 1990). The black
marlin reaches a total length of 4.48 m and a weight of 708
kg. Females grow more rapidly than males so that at any giv-
en age males are much smaller than females (Hopper, 1986).
Fish tagged off northern Queensland, Australia, generally are
recaptured north or south of their point of release. One speci-
men released off Baja California was recaptured north of New
Zealand, thereby making a trans-Pacific and trans-equatorial
migration of 5700 km (Pepperell, 1990).
Makaira nigricans (blue marlin) inhabits the tropical and
temperate waters of the Atlantic, Indian, and Pacific oceans. It
is the most tropical of all billfishes, favoring blue water
(depths greater than 100 m) at surface temperatures around
24°C (22°-31°C). The blue marlin in the Atlantic Ocean
reaches a total length of approximately 4.0 m and a weight of
580 kg, whereas in the Pacific Ocean it reaches a total length
of approximately 4.5 m and a weight of 906 kg. Although
most tagged blue marlin are recaptured near their point of re-
lease, one fish traveled at least 16,871 km from the North At-
lantic Ocean off Delaware, across the equator to the Indian
Ocean near Madagascar, presumably via the Cape of Good
Hope (National Marine Fisheries Service, 1994). As in M. in-
dica, females grow more rapidly than males, so that at the
same age females are much larger than males (Hopper, 1986).
Both sexes become sexually mature at around six to eight
years of age. During the reproductive season (usually sum-
mer), smaller males outnumber the larger females by as much
as six to one (Hopper, 1990). Based on preliminary estimates
from blue marlin caught off Kona, Hawaii, longevity is at
least 18 years for males and at least 27 years for females (Hill
etal., 1989).
According to Browder and Prince (1990), blue marlin are
most abundant off the mid-Atlantic coast in the summer. May
and June are probably spawning months for blue marlin off
Florida and the Bahamas. Adult fish off Cape Hatteras in June
appeared to have already spawned.
Tetrapturus albidus (white marlin) inhabits much of the At-
lantic Ocean, including the Gulf of Mexico and Caribbean
Sea, from 45°N to 45°S in the western South Atlantic and to
35°S in the eastern South Atlantic. A few individuals are
known from the Mediterranean Sea and from off Brittany,
France. The white marlin is usually found in blue water and
favors surface temperatures greater than 22°C. Steep drop-
offs, submarine canyons, and shoals are often scenes of im-
portant feeding concentrations. They migrate to subtropical
waters to spawn, with peak spawning in the summer. Females
become larger than males, and during the spawning season
males outnumber females on the spawning grounds. Most
tagged white marlin were recaptured nearby, some after two
or more years at large. Individuals, however, can travel long
distances. One fish released in the United States Virgin Is-
lands in 1991 was recaptured one year later off Mohammedia,
Morocco, a transoceanic and transequatorial movement of
5840 km (National Marine Fisheries Service, 1994). White
marlin attain a maximum size of 2.0 m (lower jaw to fork of
caudal fin) and a weight of 79 kg.
Tetrapturus audax (striped marlin) and T angustirostris
(shortbill spearfish) inhabit mainly the tropical, subtropical,
and temperate waters of the Pacific and Indian oceans, occa-
sionally straying into the Atlantic Ocean via the Cape of Good
Hope. Striped marlin prefer more temperate water than other
billfishes, and shortbill spearfish are more oceanic, favoring
waters greater than 900 m in depth. Tetrapturus belone (Medi-
terranean spearfish) is limited in distribution to the Mediterra-
nean Sea, and T. pfluegeri (longbill spearfish) is widely distrib-
uted in the Atlantic Ocean from approximately 40°N to 35°S.
Striped marlin attain the largest size and weight of any species
of Tetrapturus, reaching a length (tip of bill to fork of caudal
fin) of 3.5 m and a weight of 200 kg. Maxiumum body lengths
(tip of lower jaw to fork of caudal fin) and weights, respective-
ly, are approximately 2.4 m and 70 kg for the Mediterranean
spearfish, 2.0 m and 52 kg for the shortbill spearfish, and 2.0 m
and 45 kg for the longbill spearfish. A striped marlin tagged off
Cabo San Lucas, Baja California Sur, Mexico, was recaptured
near Norfolk Island in the South Pacific, a distance of 9600 km
(Squire and Suzuki, 1990). Movement patterns of spearfishes
are poorly understood.
Implications of Distribution and Life History of Re-
cent Species for Lee Creek Mine Fossils.—The presence
of Makaira indica at Lee Creek Mine is unexpected based on
NUMBER 90
41
its present distribution. During or prior to the early Pliocene,
the black marlin may have had access to the North Atlantic
Ocean via a more favorable environment than the Cape of
Good Hope. According to Coates et al. (1992), the final clo-
sure of the Isthmus of Panama occurred around 3.5 Ma BP,
1.0-1.5 Ma after Yorktown time at Lee Creek (Hazel, 1983).
Coates et al. (1992) also believed that depths prior to closure
ranged from shallow to shallow inner shelf (<200 m) and up-
per slope (200-800 m) on the Caribbean side of Panama to a
trench-slope environment on the Pacific side. Makaira indica
is often found near land masses, islands, and coral reef areas
(Nakamura, 1985). Therefore, during and prior to Yorktown
time the Panama region was not a barrier but was a route for
black marlin migrating between the Atlantic and Pacific
oceans. Whitmore and Stewart (1965) believed the Canal
Zone was the site of a narrow seaway throughout most of the
Tertiary.
There is other evidence that the Panama seaway was a migra-
tion route for vertebrates. According to Purdy et al. (this vol-
ume), the sharks Carcharhinus macloti and Triaenodon obesus
are present at Lee Creek Mine. Both species inhabit only the
tropical Indo-Pacific Ocean today (Compagno, 1984). Gillette
(1984) concluded that the ichthyofauna of the Miocene Gatun
Formation (Panama) resembles the marine faunas of North
Carolina (Pungo Formation), Ecuador, and the Antilles. Final-
ly, the presence of the sirenian Metaxytherium calvertense
Kellogg in both the middle Miocene Calvert Formation (Mary-
land, United States) and the correlative Montera Formation in
Peru (de Muizon and Domning, 1985) and the presence of Met-
axytherium arctodites Aranda-Manteca, Domning, and Barnes,
1994, in Mexico and California, further suggests there were
faunistic exchanges between the Atlantic and Pacific oceans
during the mid-Neogene.
The presence of Istiophorus platypterus, Makaira nigri-
cans, and Tetrapturus albidus at Lee Creek Mine fits the dis-
tribution of extant species in the northwestern Atlantic Ocean
today. The blue marlin is much more abundant at Lee Creek
Mine than are the other two species, but this may be due to
collection bias or to difficulty in identifying isolated and frag-
mentary elements.
Recent Makaira nigricans and most other billfish favor blue
water (>100 m depth) and water temperatures of 22°-31°C, so
it is likely that billfish during Lee Creek time preferred the
same environments. Based on Gibson's (1983) conclusion that
zone 1 of the Yorktown Formation was deposited at water
depths of 80 m to 100 m and zone 2 was deposited at depths of
less than 30 m, I believe that most, if not all, adult billfish spec-
imens were collected in zone 1 (basal Yorktown Formation).
If one assumes, based on my sample of 38 recent blue marlin
where sex was known, that all fish with a rostrum width greater
than 23.0 mm (measured at one-fourth bill length, or 0.25L) are
female, then blue marlin at Lee Creek Mine have a sex ratio of
approximately one male to two females. The ratio of males to
females would be much larger in a spawning population (Hop-
per, 1990); therefore, I hypothesize that the present pattern of
blue marlin migrating northward in the western North Atlantic
Ocean during the summer to feed after spawning was estab-
lished during Yorktown time or earlier.
Frazier et al. (1995) and Fierstine and Crimmen (1996)
have reviewed the literature of extant istiophorids impaling
inanimate and animate objects with their rostrum. They noted
that healthy billfish have been captured with shortened bills
and assumed damage occurred when the fish broke away from
its impalement. Although the reasons for spearing behavior
are unclear, foreshortened bills at Lee Creek Mine is evidence
that the behavior was established during Yorktown times or
earlier.
Study Limitations.—Purdy et al. (this volume) have point-
ed out many of the pitfalls that reduce understanding of the Lee
Creek Mine fauna. They believed careful excavation of units
1-3 of the Yorktown Formation, rather than surface collecting
from spoil piles, would have produced articulated skeletons and
less fragmentary material. Strict stratigraphic control is critical
for exploration of changes in species composition (seasonal or
throughout Yorktown time) and for collecting paleoecological
data. Partial or whole, articulated skeletons would have made
identification more convincing because identification would
have been based on measurements of several elements, not just
those from one fragmentary bone. Also, more complete skeletal
material from recent species, especially black marlin and most
of the species of Tetrapturus, would have increased our knowl-
edge of interspecific and intraspecific variation of the Istio-
phoridae and would have made comparisons more certain.
Conclusions
The identification of Istiophorus platypterus, Makaira indi-
ca, M. nigricans, M. purdyi, and Tetrapturus albidus at Lee
Creek Mine is very significant. It is the only record of Makaira
purdyi, the first fossil record of the genus Tetrapturus, specifi-
cally T. albidus, the second fossil record of /. platypterus and
M. indica, and the first record of /. platypterus, M. indica, M.
nigricans, and T. albidus from fossil deposits bordering the At-
lantic Ocean.
The presence of M. indica at Lee Creek suggests that the
Panama seaway may have been a migration route for billfish
during the early Pliocene. The concentration of billfish at Lee
Creek Mine supports the contention that the Yorktown Forma-
tion represents a tropical to warm temperate (21°-28°C) ocean-
ic environment that was deposited at depths greater than 100 m.
Based on the size of isolated bones at Lee Creek Mine, /.
platypterus and T. albidus are estimated to have reached much
larger sizes and weights than their living representatives. Ma-
kaira nigricans from Lee Creek are more similar to extant M.
indica than to extant M. nigricans in two features, a more
round predentary and a greater area of denticles on the dorsal
surface of the distal rostrum.
42
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
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Plates
46                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 1
Istiophoridae, genus and species indeterminate
Yorktown Formation, Lee Creek Mine
a.b.  NCSM 5576, right articular: a. lateral view; b, dorsal view of joint with quadrate.
c.   USNM 488084, left dentary, medial view of interdentary joint.
d.   USNM 290202, first pectoral-fin ray, view of articular facet for scapula.
e.   NCSM 5297, first pectoral-fin ray, view of articular facet for scapula.
f,g.  USNM 475425, left maxilla:/ lateral view; g, dorsal view.
h,i.  USNM 284815, parasphenoid: h, ventral view; /, left lateral view.
j,k. USNM 481956, predentary: j, right lateral view; k, dorsal view.
Each scale bar=2 cm
NUMBER 90
48                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 2
Istiophoridae, genus and species indeterminate
Yorktown Formation, Lee Creek Mine
a,b.  USNM 481915, left quadrate: a. lateral view; b, view of articular condyle for articular.
c-e.  USNM 481939, rostrum: c, left lateral view; d. dorsal view; e, cross section.
f-h.  USNM 475409, rostrum:/ left lateral view; g, dorsal view; h, cross section.
i.j.  USNM 481984, rostrum: /, left lateral view;/ dorsal view.
Each scale bar=2 cm
NUMBER 90
50                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 3
Makaira purdyi Fierstine, 1999a
Yorktown Formation, Lee Creek Mine
o-c  USNM 481933 (holotype), rostrum: a. left lateral view; b, dorsal view; c, ventral view.
Istiophoridae, genus and species indeterminate
Yorktown Formation, Lee Creek Mine
d. NCSM 7902, right scapula, view of articular surface for first pectoral-fin ray.
e.f. NCSM 4914, vertebra 1: e. left lateral view;/ anterior view.
g.h.  USNM 481982, hypural: g, left lateral view; h, anterior view.
Each scale bar=2 cm
NUMBER 90
51
52                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 4
Istiophorus platypterus (Shaw and Nodder, 1792)
Yorktown Formation, Lee Creek Mine
a,b.  USNM 290198, left maxilla: a, dorsal view; b, lateral view.
c—e.  USNM 481973, rostrum: c, left lateral view; d, dorsal view; e, cross section.
f-h.  USNM 286949, rostrum:/ dorsal view; g, left lateral view; h, cross section.
i-k.  USNM 481967, rostrum: ;', left lateral view;/ cross section; k, dorsal view.
Each scale bar =2 cm
NUMBER 90
54                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 5
Istiophorus cf. /. platypterus (Shaw and Nodder, 1792)
Yorktown Formation, Lee Creek Mine
a-c. USNM 286950, rostrum: a, left lateral view; b, dorsal view; c, cross section.
d,e. USNM 488093, hypural: d, left lateral view; e, anterior view.
Makaira indica (Cuvier, 1832)
Yorktown Formation, Lee Creek Mine
/  USNM 481927, right scapula, view of articular surface for first pectoral-fin ray.
g.  USNM 488112, right scapula, view of articular surface for first pectoral-fin ray.
h.i.  USNM 475399, predentary: h. right lateral view;;', dorsal view.
j.k.  USNM 488009, predentary:/ right lateral view; k, dorsal view.
Makaira ci. M. indica (Cuvier, 1832)
Yorktown Formation, Lee Creek Mine
/.  USNM 488100, left scapula, view of articular surface for first pectoral-fin ray.
Each scale bar=2 cm
NUMBER 90
56                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 6
Makaira nigricans Lacepede, 1802
Yorktown Formation, Lee Creek Mine
a.  NCSM 2125, left dentary, medial view of interdentary joint.
b,d.  NCSM 5159, parasphenoid: b, left lateral view; d, ventral view.
c.e.  USNM 291066, predentary: c, dorsal view; e, left lateral view.
f.h.j.  USNM 481941, rostrum:/ left lateral view; h, dorsal view;/ cross section.
g.i.  USNM 481936, predentary: g. dorsal view; I, left lateral view.
k-m.  USNM 481943, rostrum: k. cross section; /, left lateral view; m, dorsal view.
Each scale bar =2 cm
NUMBER 90
58                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 7
Makaira nigricans Lacepede, 1802
Yorktown Formation, Lee Creek Mine
a-c. USNM 481976, rostrum: a, left lateral view; b, dorsal view; c, view of nutrient canals exposed at distal
tip.
d.   USNM 421527, right scapula, view of articular surface for first pectoral-fin ray.
e.   USNM 290197, right scapula, view of articular surface for first pectoral-fin ray.
fih.  USNM 286179, vertebra 23:/ left lateral view; h. anterior view.
g.l.  USNM 286181, vertebra 22: g. anterior view; /, left lateral view.
i,k. USNM 481923, vertebra 1: ;', anterior view; k. left lateral view.
j.m.  NCSM 4938, hypural:/ anterior view; m, left lateral view.
Each scale bar =2 cm
NUMBER 90
60                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 8
Makaira cf. M. nigricans Lacepede, 1802
Yorktown Formation, Lee Creek Mine
aj.  NCSM 6944, left quadrate: a, lateral view;/ view of articular condyle for the articular.
b.c.  NCSM 7427, rostrum: b, left lateral view; c, dorsal view.
d,f.  USNM 488116, parasphenoid: d, right lateral view;/ ventral view.
e.g.  USNM 481944, rostrum: e, left lateral view;g, dorsal view.
h,i.  USNM 481897, vertebra 1: h, left lateral view; /, anterior view.
Each scale bar =2 cm
NUMBER 90
62                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 9
Makaira cf. M. nigricans Lacepede, 1802
Yorktown Formation, Lee Creek Mine
a.b. USNM 286177, vertebra 22: a, left lateral view; b, anterior view.
c,f USNM 481909, vertebra 23: c, left lateral view;/ anterior view.
d,e. USNM 481979, hypural: d. right lateral view; e, anterior view.
Makaira sp.
Yorktown Formation, Lee Creek Mine
g-i. USNM 475390, rostrum: g, dorsal view; h, cross section; f, left lateral view.
//.  USNM 290542, vertebra 23:/ left lateral view; /, anterior view.
k.  USNM 286997, right dentary, medial view of interdentary joint.
Each scale bar=2 cm
NUMBER 90
64                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 10
Makaira sp.
Yorktown Formation, Lee Creek Mine
a,b.  USNM 481931, predentary: a, left lateral view; b, dorsal view.
c,d.  USNM 488006, left quadrate: c, view of articular condyle for articular; d, lateral view.
g.   USNM 290204, left scapula, view of articular surface for first pectoral-fin ray.
h.i.  USNM 481981, hypural: h, right lateral view; /, anterior view.
cf. Makaira indica sp.
Yorktown Formation, Lee Creek Mine
e.f USNM 488007, hypural: e, left lateral view;/ anterior view.
/  NCSM 2990, right dentary, medial view of interdentary joint.
k.l.  USNM 481916, left quadrate: k, view of articular condyle for the articular; /. lateral view.
Each scale bar=2 cm
NUMBER 90
66                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 11
Tetrapturus albidus Poey, 1860
Yorktown Formation, Lee Creek Mine
a,b.  USNM 290193, left articular: a. lateral view; b, dorsal view of joint with quadrate.
c,d.  USNM 475393, right maxilla: c, lateral view; d, dorsal view.
e.f.  USNM 488046, parasphenoid: e. left lateral view;/ ventral view.
g.h.  USNM 290203, right maxilla: g, lateral view; h, dorsal view.
i.j.  USNM 488027, parasphenoid: /. left lateral view;/ ventral view.
Each scale bar=2 cn
NUMBER 90
68                                                                                                                                         SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Plate 12
Tetrapturus albidus Poey, 1860
Yorktown Formation, Lee Creek Mine
a.b.  USNM 481908, right quadrate: a, lateral view; b, view of articular condyle for the articular.
c.d.  USNM 488008, left quadrate: c, lateral view; d, view of articular condyle for the articular.
Tetrapturus cf. T. albidus Poey, 1860
Yorktown Formation, Lee Creek Mine
e.f.  USNM 488085, left maxilla: e, lateral view;/ dorsal view.
Each scale bar=2 cm
NUMBER 90
69
The Neogene Sharks, Rays, and Bony Fishes from
Lee Creek Mine, Aurora, North Carolina
Robert W. Purdy, Vincent P. Schneider, Shelton P. Applegate,
JackH. McLellan, Robert L. Meyer, and Bob H. Slaughter
ABSTRACT
The fish remains, including 104 species from 52 families, col-
lected at the Lee Creek Mine near Aurora, Beaufort County, North
Carolina, constitute the largest fossil marine fish assemblages
known from the Coastal Plain of the eastern United States. The
fish faunas came principally from the Pungo River Formation
(Burdigalian, planktonic foraminifera zones N6-7) and the York-
town Formation (Zanclian, planktonic foraminifera zone N18 and
younger). A few specimens were obtained from the James City
Formation (early-middle Pleistocene).
As an assemblage, the fishes found in the Pungo River Forma-
tion, including 44 species of selachians and 10 species of teleosts,
are most similar to those from the "Muschelsandstein" of the
Swiss Molasse.
The Yorktown Formation fish assemblage includes 37 species of
selachians and 40 species of teleosts, derived mostly from the base
of the Sunken Meadow Member.
Although the Pungo River Formation fish fauna is dominated by
warm-water (18°-25°C) taxa, the Yorktown Formation fossil fish
fauna includes warm and cool water species. Both fish assem-
blages occur with a cool-temperate invertebrate fauna.
The abundant remains in both faunas permit us to make the fol-
lowing interpretations concerning shark taxonomy. We reassign
Megascyliorhinus to the family Parascyllidae and Parotodus bene-
denii (Le Hon) to the Lamnidae. Among the mako sharks, we des-
ignate the lectotype of Isurus desori (Agassiz) and synonymize it
with /. oxyrinchus Rafinesque and separate Isurus xiphodon
(Agassiz) from /. hastalis (Agassiz). Palaeocarcharodon, Procar-
Robert W. Purdy, Department of Paleobiology, National Museum of
Natural History, Smithsonian Institution, Washington, D.C. 20560-
0121. Vincent P. Schneider, Paleontology Department, North Caro-
lina Museum of Natural History, P. O. Box 27647, Raleigh, North
Carolina 27611. Shelton P. Applegate, Instituto de Geologia, Apar-
tado Postal 70-296, Cuidad Universitaria, 20 D.F., Mexico. Jack H.
McLellan, 112 Shoveler Court, Georgetown, Kentucky 40324. Robert
L. Meyer, Union Oil Company of California, 500 Executive Plaza
East, 4615 Southwest Freeway, Houston, Texas 77027. Bob H.
Slaughter (deceased).
charodon, Megaselachus, and Carcharocles art synonymized with
Carcharodon. Sphyrna laevissima (Cope) is synonymized with S.
zygaena (Linnaeus), and Galeocerdo triqueter Cope is synony-
mized with Alopias cf. A. vulpinus (Bonnaterre).
This fauna produced four new records and two new species.
Among the selachians, we note the first records of Megascyliorhi-
nus, Rhincodon, Megachasma, and Isistius from the Atlantic
Coastal Plain, and among the bony fishes, the first occurrences in
the fossil record of Caulolatilus and Pomatomus. We also describe
two new species of bony fishes, Lopholatilus rayus and Pagrus
hyneus.
Introduction
The fossil faunas of both bony fishes and elasmobranchs at
Lee Creek Mine are among the largest in the world, and the
Pliocene remains represent one of the most abundant and di-
verse fossil vertebrate faunas yet recorded in the scientific liter-
ature (see Table 1). This fossil fish fauna consists of tens of
thousands of selachian teeth (including six associated denti-
tions) and bony fish remains (including teeth, cranial frag-
ments, an articulated skull, several associated skeletons, verte-
brae, fin spines, otoliths). This fauna extends the record of
many extant fishes into the Neogene of the United States. We
identify more than 35 species not previously recognized from
this province (excluding the otolith record; see Fitch and
Lavenberg, 1983) and provide the first thorough account of this
faunal diversity and its paleoecological implications.
PREVIOUS Work.—The literature concerning fossil fishes of
the Atlantic Coast of North America is rather meager. Leriche
(1942) provided one of the most comprehensive accounts of
the fossil fishes of the area with a list of 50 Miocene and
Pliocene species, and he also reviewed work previous to his
own. The most useful of these works are illustrated papers by
Gibbes (1848-1849) and Leidy (1877), concerning the phos-
phate beds of South Carolina, and Eastman's (1904) summary
of the fishes of the Chesapeake Group in Maryland.
71
72
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Fowler's (1911) lengthy work on the fossil fishes of New
Jersey is useful as a catalog, but the specimen locality data are
so poor that the informational value of the paper is seriously
marred. Case's (1980) paper on the lower Miocene sharks of
the Belgrade Formation is the only recent work about the Neo-
gene fishes of the Atlantic Coast of North America.
North Carolina fossil fishes are especially poorly known.
Emmons (1858) included some species now known to occur
prolifically at the Lee Creek locality. Cope (1869, 1871, 1875)
made additions to this fauna, and Leriche's (1942) Duplin Marl
occurrences are primarily from North Carolina.
Project History.—A first manuscript describing the fossil
fish fauna of Lee Creek Mine was completed in the mid-1970s.
It reflected largely the work of Robert L. Meyer (sharks and
rays) and Bob H. Slaughter (bony fishes). In the early 1980s
Jack H. McLellan revised the manuscript and added to it addi-
tional taxa that he and Robert W. Purdy had identified subse-
quent to the first manuscript. Due to other commitments, Mey-
er, Slaughter, and McLellan relinquished responsibility for
final revisions to Purdy. Purdy, who revised the Chondrich-
thyes and the geological portions of the manuscript, sought the
help of Vincent P. Schneider to do the fossil bony fishes.
Shelton P. Applegate reconstructed composite dentitions of
the common Lee Creek shark taxa; he and Purdy subsequently
refined these to reflect, as accurately as possible, the dentitions
of these sharks. They are illustrated herein.
We must state here that Applegate disagrees with Purdy's as-
signment of Parotodus to the Lamnidae, Purdy's identification
of the first upper anterior tooth of Parotodus and Carcharodon
as the second anterior tooth, and Purdy's recognition of Galeo-
cerdo contortus as a species separate from G aduncus Agassiz
(= G. sp. herein).
Since the completion of the McLellan manuscript in the early
1980s, much new information has been published about the pa-
leoecology and paleooceanography of the Atlantic Coastal
Plain, the ecology of extant fishes, and the taxonomy of fossil
and extant fishes. Many additional specimens were added to
the collections, including two associated dentitions of fossil
sharks. Also, Gordon Hubbell made available to us his impor-
tant collection of extant sharks' dentitions. This manuscript,
therefore, represents a major revision of the earlier ones.
ACKNOWLEDGMENTS
We express special thanks to Peter J. Harmatuk and to Becky
and Frank Hyne, who collected and generously donated several
thousand specimens to the National Museum of Natural Histo-
ry (NMNH), Smithsonian Institution, including many of the
specimens cited below. We extend special thanks as well to
Wayne and Aura Baker, who also donated many specimens to
the Smithsonian. The Hynes and the Bakers also were instru-
mental in encouraging collectors at the mine to donate impor-
tant specimens to the Smithsonian. We also express gratitude to
Kate and Gordon Hubbell, who graciously provided Bob Purdy
with room and board during his several visits to their home to
study shark dentitions in the Hubbell collection.
R.W.P. extends sincere thanks to Jann Thompson and Clay-
ton E. Ray for their encouragement and support of this research
project.
For the presentation of specimens to the Smithsonian Institu-
tion we thank Wayne and Aura Baker, William Bean, Jim
Bourdon, Tom and Pat Burns, Rann Carpenter, Gerard R. Case,
Ralph Chamness, N.E. Cowell, Raymond Douglas, George C.
Fonger, Harvey A. Franz, Jr., Tex Gilmore, David W. Grabda,
Chris Harmatuk, Jack M. Hird, Jerry Hughes, Jeremy Jacobs,
Geoffry Keel, Royal H. and Gene Mapes, the late Earl M. Ma-
son, Vance McCollum, Gregory McKee, Arnold Powell,
George Powell, George Prinsen, Norm Riker, Judy Schneider,
Clyde Swindell, the late Charles Wells, the late Edgar A.
Womble, and many members of the Calvert Marine Museum
Fossil Club, the Myrtle Beach Fossil Club, the National Muse-
um of Natural History field parties, and the North Carolina
Fossil Club.
Examination of collections or specimens of modern and fos-
sil fishes was made possible with the assistance of Shelton P.
Applegate and Camm Swift (Los Angeles County Museum of
Natural History), Leonard Compagno (then at Stanford Uni-
versity), M.N. Feinberg, (Department of Ichthyology, Ameri-
can Museum of Natural History), W.I. Follett (Department of
Ichthyology, California Academy of Science), Joseph Gregory
(Department of Paleontology, University of California at Ber-
keley), Gordon Hubbell (Key Biscayne, Florida), Alvaro Mon-
es (Museo Nacional de Historia Natural, Montevideo, Uru-
guay), Kazuhiro Nakaya (Hokkaido University), Dirk Nolf
and Paul Sartenaer (Institut Royal des Sciences Naturelles de
Belgique), Harold Wes Pratt, Jr. (National Marine Fisheries
Service, National Oceanographic and Atmospheric Adminis-
tration), Martin Sander (Palaontologisches Institut und Muse-
um der Universitat Zurich), Earl Shapiro (Academy of Natural
Sciences of Philadelphia), Scott Snyder (Department of Geol-
ogy, East Carolina State University), Torn Taniuchi (Universi-
ty of Tokyo), Giancarlo Tondi (Universita degli Studi di Roma
"La Sapienza"), Stanley H. Weitzman and Victor Springer
(Division of Fishes, NMNH), and Elizabeth Wing (Florida
Museum of Natural History).
Our research efforts were supported by the Smithsonian In-
stitution through the Remington and Marguerite Kellogg Fund,
the Research Opportunity Fund, and the Short-Term Visitors
Fund.
Leonard J.V. Compagno, David A. Ebert, Harry Fierstine,
Bill Heim, Gordon Hubbell, James C. Tyler (NMNH), and
David Ward aided us in the identification of several fossil fish-
es. Leonard J.V. Compagno also reviewed portions of the
manuscript; Michael Gottfried and Lance Grande reviewed the
finished manuscript.
We are grateful to the following individuals for translating
into English papers in French, German, Italian, and Japanese:
NUMBER 90
73
Steve Johnson, Marilyn Lebson, Albert Roland, Jeannette
Saquet, and Hans Sues.
National Science Foundation Grant GB 28598-1 supported
the Southern Methodist University's field work at Lee Creek
Mine. National Science Foundation Grant GB 36727 and a
Smithsonian Institution research grant supported travel to mu-
seums. Field work conducted by Smithsonian staff was sup-
ported by the Smithsonian Institution through the Walcott Fund
and the Remington and Marguerite Kellogg Fund.
Methods
The lack of adequate skeletal collections of extant western
Atlantic fishes hampered our identification of the bony-fish re-
mains. We identified the more tropical species of the fauna at
the University of Florida, where Elizabeth Wing maintains an
excellent synoptic skeletal collection of Florida fishes. One of
us (V.P.S.), with the assistance of members of the North Caro-
lina Division of Marine Fisheries, especially Fritz Rhode and
Jim Franesconi, assembled a synoptic collection of the fishes
presently living off the coast of North Carolina; this collection
now resides in the North Carolina State Museum. Gordon Hub-
bell's extensive private collection of extant sharks' dentitions
assisted in our identification of the fossil teeth. We also exam-
ined specimens from the private collections of Chris Harmatuk
(Bridgeton, North Carolina) and Leonard Compagno (Cape
Town, South Africa). These collections and the osteological
specimens available in the Division of Fishes, NMNH, were
used as the comparative basis for identifying the Lee Creek
Mine material.
To avoid the erection and perpetuation of unnecessary taxa,
Leriche (1905, 1910, 1936b) advocated using reconstructed
tooth sets for the study of fossil shark species. For lamnoid
sharks, Applegate (1965, in prep.) supplemented Leriche's
work by refining Leriche's tooth terminology and by identify-
ing the morphological characters of the anterior teeth. These
characters identify them to jaw position even when they occur
as isolated teeth. For taxa with dentitions that are not easily dif-
ferentiated into anteriors and laterals, Applegate recommended
that the dentitions of closely related extant taxa be used as
models for the reconstructions. Leriche's and Applegate's
methods were employed in our study of the Lee Creek Mine
sharks.
The abundance and diversity of elasmobranch teeth in the
Miocene and Pliocene sediments at Lee Creek Mine allowed us
to reconstruct the dentitions of the common shark taxa. By
comparing these reconstructions with the dentitions of extant
sharks, we believe we have unraveled ambiguities that have
plagued the study of fossil sharks.
The unrecognized high degree of variation in dental mor-
phology in extant sharks fostered this ambiguity. Compagno
(1988:26) noted that "the general scarcity of comparative data
for teeth of living sharks has led to many errors in the paleonto-
logical literature. Unawareness of patterns of positional, devel-
opmental, and sexual heterodonty have led both paleontologists
and neontologists astray." In our attempts to establish the iden-
tities of the Lee Creek Mine sharks, we examined as many den-
titions of extant sharks as possible, both from different age
groups and sexes and from different parts of the world. For
most taxa, only a few specimens were available, and some of
these were not sized or sexed and were from the same popula-
tion.
At this time, cladistic analyses of the taxa are not possible
because of the fragmentary nature of the material and the un-
availability of comparative osteological data for phylogenetic
analysis. Where possible we have identified potential synapo-
morphies, but we qualify them as tentative for the reasons giv-
en above.
The taxonomic classifications and nomenclature used in this
paper follow Compagno (1977, 1984) and Carroll (1988). De-
scriptions of taxa are from these sources unless noted other-
wise. Dates for taxa published by Agassiz (1833-1843) were
taken from Jeannet (1928, 1929), who published a schedule of
publication dates for Agassis's work.
Synonyms are provided only for fossil taxa whose identifica-
tions are being changed.
Due to the great number of fossil fish specimens recovered at
Lee Creek Mine, only figured or measured specimens were cat-
aloged. Thus, although the total number of specimens referred
to each taxon is cited, with few exceptions, only the cataloged
specimens are listed. Figured specimens are from Lee Creek
Mine unless otherwise noted.
All measurements were made in millimeters or centimeters.
For shark teeth, tooth height was measured from the apex of
the crown to a line tangential to the basal margin of the root,
tooth width was measured at the greatest lateral extent of the
tooth, and tooth thickness was measured in the area of the cen-
tral foramen of the root. Total length is abbreviated as TL.
Because the specimens were not collected in place, we made
special efforts to collect from spoil areas where there was the
least chance of mixing taxa from different horizons. We sifted
large quantities of the Pungo River Formation, particularly the
ore zone (unit 3) and units 4 and 5. Our principal source for
ore-zone material was the coarse tailings found at the mill, and
even in this material we occasionally found waifs from the
Yorktown or James City formations. Despite these problems of
mixing, we believe our collection techniques were careful
enough to allow us to decide the stratigraphic occurrence of
most of the taxa in this study.
A field party from the Shuler Museum of Paleontology of
Southern Methodist University undertook the initial bulk pro-
cessing of sediments for fossils, especially microvertebrate re-
mains. Subsequent bulk collecting was conducted by McLel-
lan, Applegate, Schneider, and Purdy. We also collected on the
spoil piles from areas that did not appear to be contaminated by
mixed sediments and fossil invertebrates. Because we could
not collect on the working face of the mine, we made special
efforts to bulk sample uncontaminated piles of units 1 to 3 of
74
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
the Yorktown Formation. Some specimens were found in
lumps of matrix or had matrix in cavities or grooves in the
specimen; this associated material was submitted to Thomas G.
Gibson (United States Geological Survey) for analysis of any
foraminifera present. Gibson's reports helped us to stratigraph-
ically place many of these specimens.
The Lee Creek Mine collection has accumulated since the
opening of the mine test pit in 1963. Field parties under the di-
rection of Clayton E. Ray (NMNH) began actively prospecting
the locality in August 1971. Bob Slaughter and a party from
Southern Methodist University, Dallas, Texas, collected bulk
samples for screen washing in July 1972.
The cataloged specimens are housed in the collections of the
North Carolina State Museum of Natural Sciences and the
NMNH.
ABBREVIATIONS.—Institutional abbreviations used in the
text are as follows.
AMNH           American Museum of Natural History
ANSP            Academy of Natural Sciences of Philadelphia
CAS              California Academy of Science
CMM             Calvert Marine Museum
ETHGI           Palaontologisches Institut Universitat Zurich
IG                  Brussels Museum of Natural History
NCSM           North Carolina State Museum of Natural Sciences
TE-PLI           Staatliches Museum fur Naturkunde Karlsruhe
UNIG             Universitat Neuchatel, Institut fur Geologie
NMNH           National Museum of Natural History collections (including col-
lections of the former United States National Museum),
Smithsonian Institution
Stratigraphy
The section exposed at Lee Creek Mine includes more than
30 m of fossiliferous marine sedimentary rocks assigned to the
Pungo River and Yorktown formations. Gibson (1967, 1983)
described these exposures in detail; unless otherwise noted,
stratigraphic units herein are those of Gibson.
The Pungo River Formation, a subsurface unit, is exposed in
the lower part of the mine pit. The upper 3.7 m of this forma-
tion consists of thin limestone layers interbedded with thin
phosphate sand layers (units 4-7). Below this lies the ore bed, a
phosphate sand layer about 12 m thick (units 1-3). Within the
ore bed, a thin but persistent indurated sand layer containing
diatomite occurs (unit 2). Below the main ore layer, about 3 m
of low-grade indurated phosphatic sand occurs that is not
mined. This layer rests unconformably on the Castle Hayne
Formation of middle Eocene age. Gibson's units 1 to 3 corre-
late with the lower Miocene Dunkirk beds of the Calvert For-
mation of the Chesapeake Group to the north, which are Burdi-
galian (Hoffman and Ward, 1989:55), and units 4 to 7 correlate
with the Fairhaven Member of the Calvert Formation, which
are Langhian (Hoffman and Ward, 1989:55).
The Yorktown Formation, which at Lee Creek Mine uncon-
formably overlies the Pungo River Formation, consists of blue
clayey, fossiliferous sand. Ward and Blackwelder (1980) sub-
divided the Yorktown Formation into four members; beginning
with the oldest, they are the Sunken Meadow Member, the
Rushmere Member, the Morgarts Beach Member, and the
Moore House Member. Only the first three members occur at
Lee Creek Mine. Hazel (1983) presented evidence that the
Yorktown Formation at the Lee Creek locality is planktonic
foraminifera zone N19 (early Pliocene). Riggs et al. (1982),
Gibson (1983), Snyder et al. (1983), and others have confirmed
this age assignment. At Lee Creek Mine, the Sunken Meadow
Member is the source of most of the vertebrate fossils.
Sources of the Fish Fossils
Vertebrate fossils occur in both the Yorktown and the Pungo
River formations. A few fish fossils were found in situ, in ex-
posures along the pit walls. Most specimens, however, were
obtained by searching piles of overburden in mined-out parts
of the pit. Other sources of fossils were the piles of ore waiting
to be slurried and pumped to the mill, the residue of coarse
rubble left behind at the ore pumping sites, and the reject piles
at the mill.
The overburden consists of the Pleistocene sediments, York-
town Formation, and the top 3.7 m or so of the Pungo River
Formation. During mining the draglines cast the overburden
aside into a previously mined cut, stacking this material in
windrows or spoil piles. Rains wash finer sediments down the
slopes of the spoil piles leaving the fossils behind. Fish teeth
and bones and other fossils are common in this lag material.
As the draglines cast the overburden aside, inevitable mixing
of the overburden layers occurs. Because, however, the dra-
gline buckets are very large and the sediments are cohesive,
large masses of homogeneous material from identifiable hori-
zons survive the drop from the bucket onto the spoil piles.
Pungo River Formation.—Much of the Pungo River ma-
terial studied herein was collected from the ore layers (units
1-3). We obtained this material at the active mining sites
where the draglines stack thousands of tons of ore to await
transport to the mill. By screening bulk samples of this unproc-
essed ore through size 30 mesh screens, we collected many
small bones and teeth.
Smaller draglines move the ore to sumps; there it is mixed
with water, screened to remove coarse particles, and pumped
through pipelines to the mill. When all of the ore at a site has
been pumped to the mill, large piles of particles too coarse for
slurrying remain. These piles yielded many fossils.
When the ore slurry reaches the washer section of the mill it
is screened, and particles coarser than sand size are discarded.
These piles of mill rejects, which we screened, also yield Pun-
go River fossils; the pumping and screening, however, abrades
the specimens.
The upper 3.7 m of the Pungo River Formation (units 4-7) is
cast upon the spoil piles along with the nonphosphatic York-
town Formation. After weathering, these upper Pungo River
sediments are easily recognized by their characteristic litholo-
gies. Shark teeth and osteichthyan vertebrae occur embedded in
NUMBER 90
75
the thin limestone layers, but the phosphatic sands that alter-
nate with the limestones (unit 4) are a more prolific source of
fossils. It was from these sources that we obtained the Pungo
River fish assemblage. Although we did not collect them in
place, we assign them with some confidence to the lower and
middle parts of the formation (units 1-3) and to the upper part
(units 4-7).
Yorktown Formation.—The blue gray, silty sands con-
taining some phosphate pellets, cetacean bone fragments, and
Placopecten clintonius (Gibson, 1983), the invertebrate guide
fossil for the basal part of the Yorktown Formation, identify
sediments of the lowest 1.2 m of the Yorktown Formation.
These sediments yielded many fish fossils.
In the basal layer of the Yorktown Formation, fish fossils oc-
cur in two states of preservation. They either are well preserved
and unabraded or are blackened, broken, worn, and heavily
etched. Intermediately worn specimens are uncommon.
The dark, wom specimens are themselves divisible into two
groups: (1) fossils that are common in the Pungo River Forma-
tion and occur only in the basal layer of the Yorktown Forma-
tion as redeposited specimens, and (2) fossil teeth known to oc-
cur only in the basal layer of the Yorktown Formation. We
believe they originated in post-Pungo River beds that were
eroded completely before or during the Yorktown transgres-
sion.
The well-preserved component of the fossil fish assemblage
accumulated after the initial high-energy transgression. We be-
lieve that most of the identifiable bony-fish remains found on
the spoil piles came from the bottom 4 m of the Yorktown For-
mation (units 1-3). Sediments representing unit 3 occur only as
small patches on the spoil piles, as the unit is only 0.6 m thick.
These patches are readily identified by an abundance of fish
otoliths, well-preserved small shark teeth, chalky crab chelae,
and other characteristic fossils.
Biostratigraphic Implications of the Fish Faunas
Based on fish remains alone, the biostratigraphic position of
this fish fauna is difficult to assess. Many of the Lee Creek
Mine taxa cannot be distinguished from the extant species.
Another problem is that many species of extant sharks segre-
gate by size and/or by sex, and in some species the growth rates
vary such that individuals of the same age in two different pop-
ulations of the same species will be of measurably different siz-
es. The effects of these distributions and size differences on the
fossil record of sharks have not yet been assessed. Until they
are, we believe that the usefulness of fossil shark teeth as guide
fossils is questionable.
The stratigraphic ranges of several large shark genera, such
as Galeocerdo and Carcharodon, suggest the maximum ages
of the deposits. Galeocerdo sp. (=G. aduncus of Agassiz, Cap-
petta, Leriche, and others) and G. contortus, frequently used
as guide fossils, have broad stratigraphic ranges: Rupelian to
Serravalian for the former and Chattian to Tortonian for the
latter (Cappetta, 1987:123). Based on specimens from a strati-
graphically controlled collection he made from the Neogene of
Belgium, Leriche (1926) extended the range of Galeocerdo
aduncus into the Zanclian; these teeth, however, may be from
juveniles of G. cf. G. cuvier. De Stefano (1909) questionably
referred a tooth frm the Pliocene of Tuscany to G. aduncus;
however, this is apparently referable to G. cf. G. cuvier and
definitely is not G. aduncus. Galeocerdo contortus has a more
restricted stratigraphic range than does G. sp., and along with
the presence of Carcharodon subauriculatus, which ranges
from the Chattian to the Burdigalian and possibly the Lang-
hian, it suggests a maximum age of Chattian for the Pungo
River fauna.
In the Yorktown Formation the absence of Galeocerdo sp.
and G. contortus and the presence of G. cf. G. cuvier corre-
sponds with the occurrence of these sharks in Europe. The
large Galeocerdo from the lower part of the Yorktown Forma-
tion is quite modern in aspect. The only fossil teeth that to our
knowledge are similar are those from the Ashley phosphate
beds of South Carolina (now thought to be of Pliocene age,
Sanders, pers. comm., 16 Jun 1990) and the Galeocerdo from
the Orciano beds of Pliocene age in Italy (Lawley, 1876; De
Stefano, 1909). Espinosa-Arrubarrena and Applegate (1981)
also reported the occurrence of this shark as G. rosaliensis in
the basal late Pliocene of Baja California, which may also be a
synonym of G. capellini. The absence of Galeocerdo sp. in
the basal Yorktown Formation and the presence of the more
modern G. cf. G. cuvier supports an early Pliocene age for
these beds.
Fossil Shark Teeth
From the beginnings of shark paleontology, most paleontolo-
gists have identified the different morphotypes of shark teeth as
belonging to different species, but within a species, tooth mor-
phology varies considerably; the dentitions of one species may
contain several different morphotypes. This practice for nam-
ing fossil shark species has led to much taxonomic confusion.
Agassiz (1833-1843) published the first extensive work on
fossil shark teeth. Many of his species were based on incom-
plete teeth or on teeth from different jaw positions of species he
described earlier in his work; nevertheless, his classic work laid
the foundation for the study of fossil shark taxonomy.
Maurice Leriche, who studied fossil sharks for the first half
of this century, revised many of Agassiz's species and those of
other earlier workers. As the basis of his taxonomic studies,
Leriche created artificial tooth sets for fossil species. He was
the first fossil shark specialist to do this, and although many
fossil shark specialists ignored Leriche's method of study, he
made many significant contributions to the study of fossil
sharks.
Despite Leriche's work, the naming of new species seemed
to be more important than scientific accuracy. As a result of
this, common fossil shark taxa have appeared in the literature
many times under many different names. Today, a morass of
76
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Table   1.—Faunal  list of Lee  Creek  Mine  fishes  (l-6=stratigraphic  unit,  A=abundant,  C=Common,
U=uncommon, R=redeposited).
Taxon
Pungo River Formation
Yorktown Formation
1                2               3
James City Formation
Class CONDRICHTHYES
HEXANCHIDAE
Notorynchus cepedianus
Hexanchus sp.
ECH1NORHINIDAE
Echinorhinus cf. E. blakei
Squalidae
Squalus sp.
Isistius sp.
Pristiophoridae
Pristiophorus sp.
RHINOBATIDAE
Rhinobatos sp.
Pristidae
Pristis sp.
P. cf. P. pectinatus
Rajidae
Raja sp.
Dasyatidae
Dasyatis say
D. centroura
D. cf. D. americana
Myliobatidae
Pteromylaeus sp.
Aetobatus sp.
Rhinopteridae
Rhinoptera sp.
Plinthicus stenodon
Mobulidae
Mobula sp.
Mania sp.
Squatinidae
Squatina sp.
Parascyllidae
Megascyliorhinus miocaenicus
Ginglymostomatidae
Glnglymostoma sp.
Rhincodontidae
Rhincodon sp.
Odontaspididae
Carcharias taurus
C. cuspidata
C. sp.
Odonlaspis ferox
O. cf. O. aculissima
Megachasmidae
Megachasma sp.
Alopiidae
Alopias ci. A. superciliosus
A. ci. A. vulpinus
Cetorhinidae
Cetorhinus sp.
Lamnidae
Parotodus benedenii
Isurus oxyrinchus
I. haslalis
I. xiphodon
Lamna sp.
Carcharodon subauriculalus
C. megalodon
C. carcharias
u          u          u
c
A
c
A
c
A
C
u
u          u
C	c	c	c	c
u	u	u		
u	u	u	u c	u c
C	c	c	c	c
c	c	c	c	c
c
A
c
U
c
A
C
u
u
u
U7
U?
U?
R?
U
						c
A	A	A	A	A		c
c	c	c	c	c		
u	u	u	u	u	u	
c	c	c	c	c	u?	
c
u
u
u
u	u
C	c
A	A
A	A
U?	
C	
u	
u
NUMBER 90
77
			Table	1.—Continued.					
Taxon			Pungo River Formation				Yorktown Forn 1             2		lation
	1	2	3	4	5	6			3       James City Formation
SCYLIORHINIDAE									
Scyliorhinus sp.	C	C	C	C	C		R?		
Triakidae									
Galeorhinus cf. G. affinis	U	u	U	U	U		R?	R?	
Hypogaleus sp.	U								
Mustelus sp.	u	u	u	u	U				
HEMIGALEIDAE									
Paragaleus sp.	A	A	A	A	A		R?		
Hemipristis serra	A	A	A	A	A	C	C	C	U?
CARCHARHIN1DAE									
Galeocerdo sp.	A	A	A	A	A	c			
G. contortus	A	A	A	A	A	C			
G. cf. G. cuvier							A	C	U
Carcharhinus brachyurus	A	A	A	A	A				
C.falciformis		u	U	U					
C. leucas	U	U	U	U	u		C	C	C
C. macloti	A	A	A	A	C		R		
C. obscurus							C	C	c
C. perezi			A	A	A		C		
C. plumbeus				U	U		U		
Rhizoprionodonl sp.	U	U	U	U	U				
Negaprion brevirostris				U	u		u	U	
Triaenodon obesus	U	u	U						
Sphyrnidae
Sphyrna lewini
S. cf. 5. media
S. zygaena
Class Osteichthyes
Acipenseridae
Acipenser ci.A. oxyrhynchus
Lepisosteidae
Lepisosteus osseus
Elopidae
Megalops cf. M. atlanticus
CONGRIDAE
Conger cf. C. oceanicus
CLUPE1DAE
Alosa cf. A. sapidissima
ARIIDAE
Bagre sp.
Batrachoididae
Opsanus lau
LOPH1IDAE
Lophius cf. L. americanus
MERLUCCIDAE
Merluccius bilinearis
TR1GLIDAE
Prionotus cf. P. evolans
SERRANIDAE
Epinephelus sp.
Mycteroperca sp.
BRANCHIOSTEG1DAE
Caulolatilus cf. C. cyanops
Lopholatilus rayus
POMATOM1DAE
Pomatomus saltatrix
CARANG1DAE
Seriola sp.
Sparidae
Archosargus cf. A. probatocephalus
Lagodon cf. L. rhomboides
Pagrus hyneus
C
u
C
u
c
u
c
u
c
u
		u
u	u	
u	u	u
u
u?
c
u
c?
A
c
c
u
u
A
c
u
c
c?
c
A
c
c
c
u
c?
78
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Table 1.—Continued.
Taxon
P.sp
Stenotomus cf. S. chrysops
SCIAENIDAE
Sciaenops sp.
5. ocellatus
Pogonias cf. P. cromis
LABRIDAE
Tautoga cf. T. on His
URANOSCOP1DAE
Astroscopus sp.
SPHYRAEN1DAE
Sphyraena cf. S. barracuda
SCOMBRIDAE
Sarda sp. aff. S. sarda
Auxis sp.
Thunnus sp.
Acanthocybium solandri
Xiphiidae
Xiphias gladius
Istiophoridae
Istiophorus cf. /. platypterus
Makaira cf. M. indica
M. nigricans
Tetrapturus cf. T albidus
Hemirhabdorhynchus sp.
BOTHIDAE
Paralichthys sp.
Monacanthidae
Aluterus sp.
TEtraodontidae
Sphoeroides hyperostosus
DlODONTlDAE
Chilomyclerus schoepfi
MOLIDAE
Mola chelonopsis
Indeterminate
Emmon's fish tooth
Pungo River Formation
C
C
c
C
c
U             U             u             u
C           c
u         u
Yorktown Formation
1          T~       3
C
c
c
A
U
li
c
A
U
A
C
U
u
A
U
H
A
A
A
U
James City Formation
C?
c
A
u
C
A
U
u
A
U
u
A
A
A
C?
U?
c?
A
A
A
scientific names exists in shark paleontology, and more new
fossil taxa are described each year.
Many of the type specimens for the species described in Eu-
rope during the nineteenth century have yet to be rediscovered.
Some were destroyed by the ravages of wars; others remained
in private collections, many of which have been lost or de-
stroyed. Even the type specimens that were not lost were rarely
redescribed and refigured. These problems have further hin-
dered fossil shark taxonomy.
The lack of good museum collections of dentitions from ex-
tant sharks and the paucity of scientific papers describing den-
tal variation in extant sharks also have hampered the study of
fossil sharks. In extant species, the extent of dental variation re-
mains undocumented. Without knowing the range of dental
variation, paleontologists cannot make sound judgements about
the taxonomy of fossil sharks.
In studying the Lee Creek Mine sharks, we attempted to
make the most parsimonious interpretation possible of the fos-
sil evidence. We compared the fossil teeth with those of as
many related extant species as possible, looking for characters
to separate or synonomize the fossil species. Where studies of
extant species indicated that great variability in dental mor-
phology existed but that variability was not defined, we identi-
fied these taxa to genera only. In instances where no informa-
tion exists about dental variability in the extant species, we
identified the fossil teeth to the fossil species. For fossil teeth
that we could not separate from those of the extant species, we
give ecological information on the extant species and the prob-
able total length of the fossil species. The latter we estimated
from the measurements of the largest tooth in the upper jaw of
extant sharks of known length.
Tooth Terminology
An extensive terminology, including many synonymous
terms, has arisen for the description of shark teeth. Compagno
(1988) called for a standardization of this terminology, and we
NUMBER 90
79
cusplets
distal
apical
mesial
apical
primary
cusp
mesial
apex of crown
basal
lateral
cusplet
central foramen
basal
distal
crown foot
labial recurvature
of tip
labial             \       lingual
transverse groove
cutting
edge
deep notch
shoulder
central foramen
FIGURE 1.—Tooth terminology used in this paper.
use the terms he suggested, which incorporate those of Apple-
gate (1965a, 1967). See Compagno (1988:27-30) and Figure 1
for the definitions of these terms. In view of the importance of
reconstructing tooth sets of fossil shark species, Applegate and
Compagno's tooth terminology is reviewed below.
Among the lamniform sharks, which include Alopias, Car-
charias, Carcharodon, and Isurus, among others, several basic
tooth types occur. Leriche (1905) and Applegate (1965a) iden-
tified these tooth types as median (medial), symphysial, alter-
nate, anterior, intermediate, lateral, and posterior (Figures 2,
5a; Compagno, 1988, fig. 3.4). These names indicate position
in the shark's jaws. Compagno (1988:32-33) defined shark
teeth that cannot be differentiated into anteriors and laterals as
follows:
When anteriors are not differentiated (as is often the case in the lower jaw) but
posteriors are, the more mesial teeth are termed ANTEROLATERALS; when
posteriors are not differentiated but anteriors are, the more distal teeth are
LATEROPOSTERIORS; and when neither anteriors or posteriors are differen-
tiated, the parasymphysial teeth are ANTEROPOSTERIORS.
Small symmetrical and asymmetrical teeth occur in the sym-
physial region of many species of sharks; Applegate recog-
nized three types of teeth in this region: median (medial), sym-
physial, and alternate (definitions from Compagno, 1988;
occurrence of teeth in taxa from Applegate, 1965a). The lamni-
form tooth types are described below.
Upper and Lower Teeth.—The lower teeth are not as
compressed as the upper teeth; their tips usually recurve toward
the more convex side of the tooth or lingually. A straight-edged
area parallel to the long axis of the flat or labial face of the
crown and tangent to the base of the crown facilitates seeing
this relationship (in upper teeth as well). (Exceptions to this are
the upper anterior teeth. Except in Alopias, the tips of these
teeth bend lingually, but this lingual bend is not as great as that
of the lower anterior teeth). In the area of the central foramen,
in the lower anterior teeth and the first two or three laterals, the
root possesses a noticeable bulge or torus. In the lower lateral
teeth, the angle formed by the root lobes is not as obtuse as that
in the upper laterals.
In the upper teeth, the tip of the crown in profile or lateral
view is straight, or it may recurve labially, and the crown is
more compressed or blade-like than are those of corresponding
teeth of the lower jaw. The torus on the lingual face of the root
is noticeably developed only in the anterior and intermediate
teeth; the roots of the upper lateral teeth are flatter than those of
the lowers.
Exceptions, however, do occur. In the extant Lamna and in
Isurus paucus we observed upper lateral teeth with slight lin-
gual bends, and in two juvenile /. paucus dentitions from the
same locality, the same upper lateral tooth in each dentition has
a strong lingual bend.
Medial Teeth.—Medial teeth are small, often symmetrical
but may be asymmetrical, and occur at the juncture of the left
and right jaws. These teeth are found in the Scyliorhinidae, Tri-
80
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NUMBER 90
81
akidae, Pseudotriakidae, Carcharhinidae, Sphyrnidae, Hexan-
chidae, Squalidae, and Heterodontidae.
Symphysial Teeth.—These teeth, which usually look like
miniatures of the first anterior teeth, have asymmetrical roots
and occur on either side of the symphysis. They are usually in
the lower jaw but also may occur in the upper jaw. Symphysi-
als are found in the Odontaspididae, Cretolamnidae, Carchar-
hinidae, Sphyrnidae, Hemigaleidae, and the Mitsukurinidae.
Alternate Teeth.—These are "small teeth with asymmet-
rical crowns that form two interdigitated rows on the symphys-
is, with the cusps of each row hooked mesially towards the op-
posite row" (Compagno, 1988:32). They are found in the
Carcharhinidae and Hemigaleidae. We did not recover alter-
nate teeth at Lee Creek Mine.
ANTERIOR Teeth.—Two upper (three in Carcharias and
Mitsukurina) and three lower anterior teeth occur in the denti-
tions of lamnoid sharks. These teeth usually have erect, awl-
like crowns; their tips may curve slightly toward the corner of
the jaw (distally). The width of an anterior tooth is less than
80% of the tooth's height. In Odontaspis, Carcharias, Mitsuku-
rina, Scapanorhynchus, and small individuals of Isurus, the an-
terior teeth have a sigmoidal curvature in lateral view, but in
upper teeth the sigmoidal curvature is not as great, and the root
is not as thick in lateral view as it is in the lower anterior teeth
(Figure 3). A shallow to deep hollowing of the labial face of
the root occurs in these teeth to accommodate the torus of the
next-forming tooth. This hollowing or concavity has its great-
est development in the lower anterior teeth,
which have the most prominent toruses, and in
which the crown of the tooth overhangs the root.
In upper anterior teeth, where the torus is less
developed, the labial face of the root may be
slightly recessed or flush with the labial face of
the crown.
Some exceptions to these characters do occur. ;
In the upper teeth of Carcharodon, Isurus xiph-
odon, and large individuals of I. paucus, the an-
terior teeth lose their awl-like appearance, and in
Carcharodon and /. xiphodon the angles of the
root lobes are broader than in those of other lam-
noid species.
Because each anterior tooth exhibits a basic
morphological pattern, the identification of the
characters that define them is most important, I
but one of these characters alone, such as the an-
gle formed by the root lobes, is not sufficient for
identifying this tooth type. One of us (R.W.P.)
measured the angles of the root lobes (see Table
2) of the anterior teeth in dentitions from extant
Figure 3.—Upper and lower anterior teeth in lateral view to
show sigmoidal curvature of crown: a, upper; b, lower.
Table 2.—Variation in the angle of the root lobes in the first two upper (Al,
A2) and lower (al, a2) anterior teeth of extant lamnoid sharks. («=number of
specimens.)
Taxon	n	Al	A2	al	a2
Carcharias	2	38o^10°	44°-92°	37°-51°	48°-67°
Lamna nasus	9	-	82°-143°	60°-120°	106°-141°
L. ditropis	3	-	86°-125°	83°-135°	100°-!30°
Isurus paucus	8	-	86°-137°	34°-60°	74°-lll°
I. oxyrinchus	4	-	76°-91°	30°-50°	45°-75°
Carcharodon	28	-	116°-156°	62°-108°	81°-115°
lamnoid species; he found that these angles broaden as the
shark increases in size and that the angles differ noticeably for
the same tooth position in the left and right jaws. In identifying
anterior teeth, then, the attitudes of the crowns and the propor-
tional development of the root lobes are the most constant and
the most important features (Figure 4). Even these features are
variable, and they should be used with prudence.
First Upper Anterior Tooth (Applegate's type A
tooth): This is the most symmetrical tooth among the upper
anteriors, and the root lobes are nearly equal in size and form
an acute angle. The crown may appear to be symmetrical or
slightly asymmetrical, but it remains erect.
Second Upper Anterior Tooth (Applegate's type C
tooth): The root lobes of this tooth form a wide acute to right
angle, and the lobes are not equal in size (the longer root lobe
is usually on the mesial side of the tooth). The crown has a
slight distal slant, and the mesial cutting edge is slightly to
very convex.
Third Upper Anterior Tooth (Applegate's type E
tooth): This is the shortest tooth in the upper anterior series.
The mesial root lobe is onger than the distal lobe, and the crown
leans distally; the distal cutting edge is slightly to very convex.
First Lower Anterior Tooth (Applegate's type B
tooth): The root lobes of this tooth are nearly equal or equal
in length, form an acute angle, and are almost U-shaped in ap-
pearance; one lobe may be somewhat flattened. The torus or
swollen area surrounding the transverse groove and/or central
foramen attains its greatest development in this tooth. In some
species the roots of these teeth are elongated. The crown of
this tooth, the most symmetrical of the lowers, has the least
amount of distal curvature.
Second Lower Anterior Tooth (Applegate's type D
tooth): The root lobes of this tooth form an acute to small ob-
tuse angle, and the mesial lobe is usually longer than the distal
lobe. The curvature of the crown is similar to that of the first
lower anterior tooth. Except in Carcharodon, this tooth is usu-
ally the greatest in height.
Third Lower Anterior Tooth (Applegate's type F tooth):
This is the shortest tooth in the lower anterior series. The root
lobes form a right to obtuse angle, and the mesial root lobe is
noticeably longer than the distal one and may be pointed. The
torus is more noticeable in this tooth than it is in its upper
82
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
counterpart. The tooth's crown has a strong distal lean to it; its
mesial edge is almost straight or is concave.
Intermediate Teeth.—Intermediate teeth occur in the up-
per jaws between the anterior and lateral teeth. Although they
are usually small, they may be almost as large as the neighbor-
ing teeth. Two sharks of the same size and species can have in-
termediate teeth of markedly differing sizes. These teeth, ex-
cept in Carcharodon and Isurus xiphodon, have U-shaped
roots, and their crowns, except in Carcharodon, slant toward
the corner of the jaws. The mesial edge of the crown is slightly
concave to convex, and the distal edge is concave. In Carchar-
odon these teeth may be broad- or narrow-crowned, with root
lobes that form right to obtuse angles. In Isurus xiphodon the
intermediates have triangular crowns and have root lobes that
form obtuse angles.
LATERAL Teeth.—The root lobes in the lateral teeth form
obtuse angles. These angles are usually smaller in the lower
teeth than they are in the corresponding upper teeth, which are
usually more blade-like than the lower teeth. In the upper teeth
the crowns curve toward the angle of the jaws, whereas in the
lower teeth they usually tend to be erect; however, we have
seen strongly curved lower lateral teeth in Isurus oxyrinchus.
Posterior Teeth.—In the posterior teeth, the crowns are
small and are not well developed.
Systematic Paleontology
Class Chondrichthyes
Order Hexanchiformes
Family Hexanchidae
(cowsharks, sixgill sharks, and sevengill sharks)
Maisey and Wolfram (1984:172) identified three dental char-
acters that, in addition to nondental characters, they considered
to unite the living hexanchids: (1) "teeth compressed labiolin-
gually; lateral teeth bladelike but with several cusps in a recti-
linear series along the cutting edge;" (2) "upper and lower teeth
distinctly different, the lowers generally being longer and hav-
ing more cusps;" and (3) "posteriormost upper and lower teeth
are small button-like, unserrated and lacking cusps."
Maisey (1986:101) revised these characters and reduced the
number of dental characters to one: "Labio-lingually flattened
teeth, with the root and crown lying in the same plane and the
basal surface enlarged to form the 'lingual' side of the root."
His character, however, also may be applied to the Echi-
norhinidae.
Thies (1987:197) modified Maisey's dental character to
read: "Lower lateral teeth flattened labiolingually and elongat-
ed mesiodistally, producing a sawblade-like appearance to the
tooth (Maisey and Wolfram 1984, in part)." His modification
restricts the application of this character to the Hexanchidae.
Thies (1987:197) also added the following two additional den-
tal synapomorphies: "Main cusp of lower lateral teeth with a
serration on the lower portion of its mesial edge or, alternative-
ly, with mesial cusplets," and "tooth root of lateral teeth flat-
tened labiolingually and rectangular in shape, with a straight
basal edge."
Compagno (1984:13) also identified elongate, comb-like,
lower lateral teeth, which he called anterolaterals, as a charac-
teristic of the family. These dental synapomorphies define the
family Hexanchidae.
Maisey and Wolfram (1984:173) stated that the lower medial
tooth of Notorynchus has a vertical median cusp that is strongly
inclined, whereas in Hexanchus it is almost vertical. The medi-
an teeth in three dentitions, however, two ofH. griseus (USNM
176566, 188048) and one ofH. vitulus (USNM 110900), all
with strongly inclined median cusps, contradict their observa-
tions about this tooth; Thies (1987:195) also confirmed that
their character is not taxonomically useful.
Using the lower anterolateral teeth, Applegate (1965b: 124)
identified characters for separating the genera of this family,
stating, "Hexanchus possesses serrations on the front [mesial]
edge of its most anterior crownlet. Notorhynchus [sic] has
small unequal denticles [which increase in size apically] and
the third genus in the family Hexanchidae, Heptranchus [sic]
has one or two distinct narrow anterior denticles." Maisey and
Wolfram (1984:173) and Compagno (1984:17, 19, 22) added
that there are eight to 10 distal cusplets in the teeth of adult
Hexanchus, five to six distal cusplets in the teeth of adult Noto-
rynchus, and "an abruptly high cusp, and up to 7 or 8 distal cus-
plets" in the teeth of adult Heptranchias. Applegate did not
identify the taxonomic characters of the upper anterolateral
teeth.
Kemp (1978) was the first paleontologist to try to distin-
guish the upper anterolateral teeth of Notorynchus from those
of Hexanchus, with the following observations: "Teeth [of
Notorynchus] in first rows a little higher than broad ranging
through to a little broader than high in last rows. Teeth of
Hexanchus are lower and broader in comparison. Primary
cusp similar to H. griseus but with fewer crownlets distally,
ranging from only 1 in first row to 4 to 5 or 6 in the last row."
In the dentitions of the extant hexanchid genera available to
us, Kemp's relationship of tooth height to breadth was vari-
able in both genera; the Notorynchus condition was found in
the upper anterolaterals of Hexanchus and the converse in No-
torynchus. In addition to Kemp's character of the number of
distal cusplets, the upper teeth of Notorynchus are distin-
guished from those of Hexanchus by the presence of one or
more cusplets on the mesial cutting edge of the anteriormost
teeth and by the presence at the base of the mesial cutting
edge of a small shoulder. Because only a small number of
dentitions of the living species were available to us, we can-
not ascertain the validity of these characters. Using these
characters and those identified by Applegate (1965b), we
NUMBER 90
83
identified only the genera Notorynchus and Hexanchus among
the Lee Creek Mine fossil teeth.
Herman et al. (1987:43-56), in their comparative morpholog-
ical study of the posterior teeth of the Hexanchidae, found that
these teeth possess characters that allow generic identification.
These teeth, however, were not recovered at Lee Creek Mine.
In the Hexanchidae, ontogenetic variation is known to occur
in two genera, Hexanchus and Notorynchus. In juveniles of
Hexanchus, Bigelow and Schroeder (1948:82) reported that in
the lower lateral teeth "the inner [mesial] margins [are] smooth
in newborn specimens, but finely serrate in large, with interme-
diate sizes showing intermediate states." Concerning Notoryn-
chus, Kemp (1978) noted, "As in Hexanchus the number of
crownlets, especially in the lower laterals and the degree of
denticulation of mesial margin of all teeth increases with age,
and thus the size of the tooth."
According to Ward and Thies (1987), the dental formula
for each upper jaw is one to two symphysial, five to six ante-
rolateral, and six to 13 posterior teeth; in the lower jaws it is
one medial tooth; and in each jaw, it is five to six anterolater-
al and four to 12 posterior teeth. They did not mention, how-
ever, the upper medial tooth that is present in Notorynchus
(Kemp, 1978). Kemp (1978) gave the dental formula for the
upper jaw (one side) of Notorynchus cepedianus as two medi-
al (one medial, one symphysial), six to seven lateral (antero-
lateral), and 11 to 13 posterior teeth, and for the lower jaw
(one side), one medial, six lateral (anterolateral), and eight to
nine posterior teeth. He gave the dental formula for the upper
jaw (one side) of Hexanchus griseus as two medial (both
symphysial), nine lateral, and eight posterior teeth, and for
the lower jaw (one side), one medial, six lateral, and eight to
nine posterior teeth.
Notorynchus cepedianus (Peron, 1807)
Figure 4
Notidanusplectrodon Cope, 1867:141 [Miocene, Maryland].
Notidanus primigenius Agassiz, 1843:303, pl. 27: figs. 6-8, 13-17 [Miocene,
Switzerland].—Eastman, 1904:77, pl. 29: fig. 6 [Miocene, Maryland].—Ler-
iche, 1942:63-64, pl. 4: figs. 7-9 [Miocene, Maryland],
Horizon.—Pungo River Formation (units 1-5); Yorktown
Formation (units 1, 2).
Referred Material.—Some 300 teeth, USNM 205296,
256290, 256312, 256315, 256316, 282771, 282776, 391921,
459874^459915, 474814-474857, 474871, 474872.
Remarks.—Although these teeth are often assigned to the
species Notorynchus primigenius, they are identical to those
of the living N. cepedianus from the Pacific Coast of North
America. Like the extant species, the attitudes of the primary
cusps and cusplets range from almost erect to more recum-
bent, with the latter attitude being more predominant.
Figure 4a shows our reconstruction of this dentition. As
noted above, the posterior teeth were not recovered at Lee
Creek Mine. In the upper dentition, the first two mesial sym-
physial teeth lack a shoulder at the basal extremity of the cut-
ting edge, but in comparison to extant hexanchid dentitions,
these teeth are most similar to those of Notorynchus. The first
of these two teeth, the first symphysial, has a squarish root in
labial view; in Hexanchus the root of this tooth appears to be
triangular to rhomboidal. As in Notorynchus, in the second of
these two teeth the mesial and apical edges of the root form a
right angle. In Hexanchus this angle is absent, and the slanted
contour of the cutting edge continues down to the base of the
root. The remaining teeth in the upper jaw are characteristic
of Notorynchus.
{0 99 S© fiP ^P 9t {
mm ^1P Wm <GBm ^* ^m w
a —
b—     c-
Figure 4.—Notorynchus cepedianus: a, lingual view of composite dentition; b, lingual view of lower lateral
tooth, USNM 474871, with enlarged serrations on mesial edge; c, lingual view of lower lateral tooth, USNM
474872, with mesial serrations absent. (Scale bars= 1.0 cm.)
84
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
In the lower jaw, the medial tooth has a nearly erect median
cusp with lateral cusplets that are slightly recurved, which is
characteristic of Notorynchus teeth rather than those of Hex-
anchus. All the other teeth in the dentition are identical to
those of Notorynchus cepedianus.
In his review of the fossil Hexanchidae, Kemp (1978) identi-
fied the more erect primary cusp and cusplets as a character for
separating the teeth of N. primigenius from those ofN. cepedi-
anus; however, Kemp's character occurs in the extant species
(Guzman and Campodonico, 1976:208), and Agassiz
(1833-1843, pl. 27: figs. 16, 17) included in his type suite two
teeth with more recumbent primary cusps and cusplets, which
Kemp stated was characteristic of the extant species. Kemp's
characters, therefore, cannot be used for separating N. primige-
nius from N. cepedianus, and the fossil species is a junior syn-
onym of the extant species.
Two teeth from Lee Creek Mine exhibit morphological vari-
ations not previously noted in Notorynchus. In USNM 474871
(Figure 4b) the recurved serrations on the mesial shoulder of
the cutting edge are greatly enlarged, and in USNM 474872
(Figure 4c) the serrations are almost completely absent; at the
mesial end of the shoulder of this tooth only three very small
serrations are present. In Mesozoic deposits, specimens with
enlarged mesial serrations, which are yet to be observed in the
extant species, have been assigned to the genus Notidaniodon
(Cappetta, 1975; Ward and Thies, 1987), but because this en-
largement also occurs in the Lee Creek Hexanchus teeth (see
below), we believe this enlargement of the mesial serrations
may fall within the range of variation in the extant species and
does not warrant generic separation.
Available lower anterolateral teeth range from 14 to 30 mm
in length and from 19 to 21 mm in maximum height. The larg-
est of these teeth are twice the size of those from two extant
dentitions that we measured, which were from males 2 m in
length. These larger fossil teeth came from individuals between
3 and 4 m TL.
According to Ebert (1986:439), Notorynchus inhabits rela-
tively shallow (< 100 m in depth), open coastal, temperate hab-
itats. Compagno (1984:23) reported that they often occupy wa-
ter less than 1 m in depth. They feed principally on sharks and
rays, but marine mammals and bony fishes also are important
prey, and they also eat mollusks and crustaceans (Ebert,
1986:444, 1991).
Hexanchus sp.
Figure 5
HORIZON.—Yorktown Formation (units 1, 2).
REFERRED Material.—22 teeth, USNM 256275, 256289,
256313, 256314, 282780,437771,474859-474870.
Remarks.—These teeth are so similar to those of the living
Hexanchus griseus that specific segregation of the two is ques-
tionable. This applies as well to Sismonda's type specimen
(1861, fig. 13) of H. gigas. All of Leriche's (1926:391) criteria
for distinguishing these two species, such as size of mesial ser-
rations, point of maximum root height, and absolute size, are
subject to ontogenetic variation and do not work with large
samples, a problem also noted by Cione and Reguero (1994:6).
Arambourg (1927:223) suggested one character, overlooked by
Leriche and by Cione and Reguero, that may be sufficient to
separate the fossil form. In the lower anterolateral teeth, the
cusps ofH. gigas are separated by notches that nearly reach the
coronal-root boundary and thus make the cusps appear well de-
veloped and separate. These notches are much shallower in H.
griseus and H. vitulus (e.g., see Bigelow and Schroeder, 1948,
fig. 8; Kemp, 1978, pl. 12: fig. 5). Teeth with both types of
notches occur in about equal numbers in the Pliocene sedi-
ments of Peru, where Hexanchus is more abundant than it is at
Lee Creek Mine. Because adequate samples of H gigas and the
extant species were unavailable for this study, we cannot assess
the taxonomic value of this character; therefore, we believe it is
premature to assign the Lee Creek Mine teeth to a species.
Two forms of lower anterolateral teeth occur at Lee Creek
Mine. In one the cusplets diminish gradually in size toward
the distal end of the tooth (Figure 5a), and in the other the
principal cusp is significantly higher than the distal cusplets
(Figure 5b); Ward (1979:115) identified these forms as grisi-
form and vituliform, respectively, representing two evolution-
ary lines leading to the extant species. He based his definition
of vituliform on a male dentition published by Bass et al.
(1975d, pl. 2), which he must have assumed was characteristic
for the species. In the dentition of the holotype ofH. vitulus (a
female) published by Springer and Waller (1969, fig. 2A), the
lower anterolateral teeth are grisiform. According to David A.
Ebert (pers. comm., 10 Dec 1990), this type of sexual dimor-
phism also occurs in H. griseus. The grisiform teeth are,
therefore, those of females, and the vituliform teeth are those
of males.
Lower anterolateral teeth in the Lee Creek Mine collection
range from 42.7 to 55.0 mm in width and from 24.1 to 32.2 mm
in maximum height. USNM 256289 (Figure 5e), from the
Yorktown Formation, is the largest of these, with 11 distal cus-
plets; it measures 55 mm in width and 32 mm in height. This
tooth is 20%-30% larger than the largest lower anterolateral
tooth in the largest dentition available to us, USNM 188048
(female Hexanchus griseus, 433 cm TL), which measures 42.6
mm in width and 22.6 mm in height.
Another large specimen from this formation is a symmetrical
lower medial tooth, USNM 474860 (Figure 5/), which mea-
sures 24 mm in width and 26 mm in height. As is often found
in the medial teeth of the extant species of Hexanchus, the me-
dian cusp of this tooth is greatly developed, with shallow me-
sial and distal notches in the cutting edge; the mesial and distal
shoulders are serrated with coarse, erect serrations. In some ex-
tant Hexanchus these serrations are large enough to be consid-
ered cusplets (height > 1.0 mm).
NUMBER 90
Figure 5.—Hexanchus sp.: a, USNM 256313, lingual view of lower anterolateral tooth with gradually diminish-
ing distal cusplets; b, USNM 474859, lingual view of lower anterolateral tooth with principal cusp much taller
than distal cusplets; c, lingual view of seven upper anterior teeth; d. USNM 437771, lingual view of lower lateral
tooth with enlarged serrations on its mesial edge; e, USNM 256289, lingual view of largest lower anterolateral
tooth from Lee Creek Mine in USNM collections;/ USNM 474860, symmetrical lower medial tooth. (Scale
bars: a.b=0.5> cm; c-f=\.0 cm.)
Eight of the 22 teeth from Lee Creek Mine are from the an-
terior portion of the upper jaw; these teeth possess one to two
distal cusplets (Figure 5c). In the extant H. griseus the first
two teeth usually do not have distal cusplets; in the teeth that
follow these, the number of distal cusplets varies from denti-
tion to dentition. In USNM 188048 (female, 433 cm TL),
these teeth possess two to three distal cusplets. Ebert (pers.
comm., 10 Dec 1990, 17 Apr 1992) has a male dentition from
an individual of 333 cm TL having upper teeth with one to
two cusplets, and he has examined another dentition from a
female of 421 cm TL with two to three distal cusplets on the
upper anterior teeth. As also noted by Kemp (1978), the num-
ber of distal cusplets increases as the shark grows larger. This
variation in the number of distal cusplets evidently is ontoge-
netic and not sexually dimorphic.
In four comparative dentitions and in dentitions illustrated in
published accounts of both extant species, we noticed signifi-
cant variation in the morphology of the teeth. The tips of the
cusplets are either straight or recurved, and the cusplets of
some teeth appear to be more erect than are those of others. In
86
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
dentitions where the mesial and distal ends of the teeth do not
abut, the mesial edges of the roots are straight rather than con-
cave, and in abutting teeth this concavity ranges from slight to
deep.
One fossil lower anterolateral tooth with eight distal cusplets
(USNM 437771) exhibits a morphology that we have not ob-
served in the teeth of the extant species; the mesial serrations,
which are not recurved, are greatly enlarged, being as large as
some of the distal cusplets (Figure 5d). Nothing about this
tooth suggests that it is pathologic.
Compagno (1984:20, 21) reported that the extant species in-
habit continental and insular shelves in temperate and tropical
seas in water depths exceeding 90 m; they feed on other sharks,
bony fishes, carrion, seals, and crustaceans. Ebert (1994:216)
noted that in the extant species, the young feed principally on
cephalopods, and that as they mature, bony fishes and chon-
drichthyans become an increasingly important part of their diet.
The few individuals greater than 200 cm TL that he examined
fed on cetaceans and on larger, more active teleosts, such as
marlin and swordfish.
Order Squaliformes
Family Echinorhinidae
(bramble sharks)
Echinorhinus blakei Agassiz, 1856
Figure 6
Echinorhinus blakei Agassiz, 1856:272, pl. 1: figs. 7, 8, 17 [Miocene, Califor-
nia].—[Not Echinorhinus blakei Jordan and Hannibal, 1923, pl. 4: figs. c,d.]
HORIZON.—Pungo River Formation (units 4, 5).
Referred Material.—13 complete teeth and fragments of
teeth, USNM 207608, 207609, 280334, 281317, 281331,
287739, 287740, 412221, 457232^*57236.
Remarks.—The upper and lower teeth of bramble sharks
are alike (dignathic homodonty). This small to medium-sized
shark has smooth-edged teeth, with the strongly oblique central
cusp sloping toward the corners of the mouth. In published
dentitions of Echinorhinus brucus (Bigelow and Schroeder,
1948, fig. 102; Bass etal., 1976, pl. 11; Herman et al., 1989, pi.
1) this obliquity varies noticeably. The greatest obliquity oc-
curs in Bigelow and Schroeder's dentition of an unsexed indi-
FlGURE 6 —Echinorhinus blakei: a. USNM 412221, posterolat-
eral tooth, lingual view; b, USNM 207609, upper posterolateral
tooth, lingual view; c. USNM 207608, posterolateral tooth. Echi-
norhinus blakei. Miocene, California: d.e. views of holotype.
Echinorhinus richiardi. Pliocene, Tuscany:/-A, syntypes. Echi-
norhinus caspius, Oligocene, Armenia: i, lingual view. Echi-
norhinus priscus. Eocene, Morocco: j,k. lingual views. Echi-
norhinus brucus: l.m. outlines of partial dentitions of the extant
Atlantic species, after Bigelow and Schroeder (1948); n. USNM
287739, lower posterolateral tooth, lingual view; o. same speci-
men, labial view;/;, USNM 457235, upper posterolateral tooth,
lingual view; q. same specimen, labial view; r. USNM 457236,
upper posterolateral tooth, lingual view; s, same specimen, labial
view. (Scale bars= I 0 cm.)
m
*
n
gfc
J^jMin                *VwS&gpB>               ^^WJHf
NUMBER 90
87
vidual, and the least occurs in Herman et al.'s dentition from a
228 cm female. In these dentitions the mesial edges of the teeth
also exhibit noticeable variation; those of Herman et al.'s denti-
tion are very convex, whereas in the other dentitions they are
straight to slightly convex. In adults, one to three lateral cus-
plets may be present on the mesial side of the central cusp, and
one to two lateral cusplets may be present on the distal side;
some of these cusplets may occur unpaired. In juveniles only
the main cusp is present (Compagno, 1984:25).
We refer 12 teeth from the Pungo River Formation to Echi-
norhinus. They show considerable variation in the number of
accessory cusplets and in the degree of curvature of the edges
of the central cusp (Figure 6n-s). One tooth (Figure 6n,o; cf.
Figure 6d,e) strongly resembles the holotype of E. blakei from
the Miocene Temblor Formation of California. Of two extant
species recognized by Compagno (1984), E. brucus (Bonna-
terre, 1788) and E. cookei Pietschmann, 1928, the fossil teeth
bear a closer resemblance to those of the latter species; how-
ever, this comparison is based on the pubished dentitions of E.
brucus cited above and on one of E. cookei (Garrick, 1960,
fig. 3).
The earliest known echinorhinid teeth, E. caspius Glikman
(1964) from the early Oligocene of Armenia (Figure 6/) and E.
priscus Arambourg (1952) from the early Eocene of Morocco
(Figure 6j,k), are simple, lacking well-developed cusplets. In
the extant species, the juvenile teeth (Figure 6m) and the adult
posterior teeth also lack cusplets (Garrick, 1960; Compagno,
1984; Herman et al., 1989), and the type specimens of Glikman
and Arambourg are very similar to the juvenile teeth of the ex-
tant species. Without examining the types of the fossil species
and many dentitions of the extant species, the affinities of these
Paleogene species cannot be determined.
Echinorhinus richiardi from the Pliocene of Tuscany (Figure
(>f~h), with well-developed lateral cusplets, may belong to the
extant species E. brucus.
The teeth identified as Echinorhinus blakei by Jordan and
Hannibal (1923) are fragmentary hexanchid teeth. The tooth in
their pl. 4: fig. d is a median tooth of Hexanchus; the generic
identity of the other tooth figured is indeterminate.
We provisionally assign the teeth from Lee Creek Mine to E.
blakei; without an extensive series of dentitions from the extant
species we cannot determine if the teeth of the fossil and extant
species are separable. The fossil teeth may be identical to those
of E. cookei, and this latter species may be a junior synonym of
E. blakei.
The height of the teeth ranges from 9.4 to 11.8 mm, and the
width ranges from 11.8 to 15.8 mm.
The living species of this shark (Compagno, 1984:26, 27) are
bottom dwellers in temperate to tropical seas, sometimes oc-
curring in shallow water but primarily in deep water. Echi-
norhinus brucus occurs in waters from 18 to 90 m deep, and E.
cookei occurs in waters from 11 m to at least 424 m in depth.
They feed on other sharks and on bony fishes, including cat-
fish, hake, and flounder.
Family Squalidae
(dogfish sharks)
Squalus sp.
Figure 7a,b
HORIZON.—Yorktown Formation (units 1, 2).
Referred Material.—1 tooth, USNM 207546.
REMARKS.—Unlike Squalus acanthias, the common North
Atlantic dogfish, but like S. almeidae, this tooth is rather ro-
bust. Its cutting edges are smooth but irregular. On its labial
face (Figure la) the crown foot is slightly convex and extends
basally to form a peg; this peg extends well below the basal
margin of the root. Like S. almeidae, the lateral edges of the
peg converge but become parallel near the peg's basal end. Lat-
eral to the peg the boundary between the crown foot and the
root is sinuous.
On the lingual face of the tooth (Figure 7b), the crown foot
extends basally to form a prominent process; this process has a
deep central depression (also observable in S. acanthias), mak-
ing it V-shaped. On either side of this process the root is exca-
vated, and clearly marked foramina open into these depres-
sions. The basal margin of the root forms a ridge, which is
bisected by a transverse groove.
In the extant species the teeth are alike in both jaws, being
low crowned, blade-like, interlocked teeth with a single cusp
and a distal enamel shoulder on a low root; the cutting edges
are smooth in living species but are serrated in some fossil spe-
cies (Compagno 1984:109). Bass et al. (1976:13) noted that in
Squalus acanthias "slight sexual dimorphism is apparent, the
male having teeth with more erect and pointed cusps."
Although the teeth from Lee Creek Mine share characters
with Squalus almeidae from the middle Miocene of Portugal,
USNM 207546 differs from this species in the sinuosity of the
mesial cutting edge, which is rectilinear in S. almeidae. Because
at this time we cannot assess the taxonomic value of this charac-
ter, we do not assign the Lee Creek Mine specimen to a species.
This specimen measures 2.9 mm in height and 4.2 mm in
width; its size falls within the size range of the extant Squalus
acanthias. According to Compagno (1984), the latter species
ranges in size from 22 cm at birth to 160 cm TL.
The extant Squalus acanthias inhabits boreal to warm tem-
perate waters from the intertidal zone to 900 m in depth. This
shark feeds primarily on bony fishes (Compagno, 1984:112).
Isistius sp.
(cookiecutter sharks)
Figure 7f,g
HORIZON.—Yorktown Formation (units 1-3).
Referred Material.—5 teeth, NCSM 11287, 11288,
11291, 11292, USNM 475362.
Remarks.—While bulk sampling a Yorktown Formation
spoil pile, one of us (V.P.S.) recovered five lower teeth of this
88
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
species. These teeth compare favorably with those illustrated
by Bigelow and Schroeder (1948:510). All of the teeth have
broad, flat, triangular crowns with smooth, very thin, transpar-
ent cutting edges. Of the five teeth, NCSM 11287 (Figure If)
and NCSM 11292 (Figure Ig) are nearly complete. NCSM
11287 is the largest, measuring 8.3 mm in height and 5.3 mm
in width; a central foramen and shallow transverse groove are
present on the lingual face of the root. In NCSM 11292 the root
basal to the central foramen is missing; this tooth measures 3.7
mm in height and 2.4 mm in width.
These teeth compare favorably with the types of Scymnus tri-
angulus (Probst, 1879:175), which Cappetta (1970) rightly re-
ferred to Isistius. The Lee Creek Mine teeth, however, differ
from Probst's species and the living species in lacking the me-
dian groove. With the lack of ample comparative extant and
fossil material, we cannot judge the validity of this character or
the validity of I. triangulus Probst. Of the two living species, /.
brasiliensis, which has moderately large teeth, and /. plutodus,
which has enormous teeth (Compagno 1984:93-95), the Lee
Creek Mine species appears to be more closely related to /.
brasiliensis.
Although teeth of Isistius have been found in the Miocene
and Pliocene sediments of Europe and South America (Ecua-
dor) (Cappetta, 1987:64), the specimens from Lee Creek Mine
represent the first occurrence of this taxon in North America.
According to Compagno (1984:94), the extant I. brasiliensis
is a tropical, oceanic shark, epipelagic to bathypelagic in distri-
bution. In addition to feeding on squid, gonostomatids, and
crustaceans, this shark "has highly specialized suctorial lips
and a strongly modified pharynx that allow it to attach to the
sides of large bony fishes such as marlin, tuna, albacore, wa-
hoo, and dolphinfishes, as well as dolphins and other cetaceans
and even the megamouth shark (Megachasma). The shark then
drives its razor-sharp sawlike lower dentition into the skin and
flesh of its victim, twists about to cut out a conical plug of
flesh, then pulls free with the plug cradled by its scooplike low-
er jaw and held by the hooklike upper teeth" (Compagno,
1984:94).
Order PR1STIOPHOR1FORMES
Family PRISTIOPHORIDAE
(saw sharks)
FIGURE 7.—Squalus sp.: a. USNM 207546, labial view; b. same specimen, lin-
gual view. Pristiophorus sp.: c, USNM 207583, rostral spine, lateral view. Rhi-
nobatos sp.: d, USNM 207544, lingual view; e. USNM 207545, lingual-
occlusal view. Isistius sp.:/ NCSM 11287, lower tooth, lingual view; g.
NCSM 11292, lower tooth, labial view. (Scale bars=0.25 cm.)
Pristiophorus sp.
Figure 7c
HORIZON.—Pungo River Formation (units 1-3).
Referred Material.—6 rostral teeth, USNM 207583,
299481, 467554-467556,467587.
Remarks.—We assign these teeth to this genus rather than
to Pliotrema because their dorsoventrally compressed and
enameled crowns are not serrated on the distal edges. In
Pliotrema (Fowler, 1941:283) these distal edges are serrated.
The largest tooth in this sample measures 19.2 mm in length
(Figure 7c). Because large samples of the dentitions of the ex-
tant species were not available, we believe it is not prudent to
identify these specimens beyond genus.
According to Compagno (1984:137), the extant Atlantic spe-
cies is "a little known, deep-water, tropical sawshark of the
continental and insular slopes of the Bahamas region, occurring
on or near the bottom at depths from 640 to 915 m." Its pres-
ence in the shallower Pungo River seas may have been through
the excretions or the regurgitated hard parts from a predator
shark.
NUMBER 90
89
Order Rhinobatiformes
Family Rhinobatidae
(guitarfishes)
Rhinobatos sp.
Figure ld,e
HORIZON.—Pungo River Formation (units 4, 5).
Referred Material.—9 teeth, USNM 207544, 207545.
REMARKS.—In occlusal view, these teeth are oval to tetrago-
nal (Figure 7e); a peg extends down from the lingual surface of
the crown onto the surface of the root (Figure Id), which is lin-
gually deflected. A transverse groove bisects the root. Because
the range of dental variation in the extant species is not yet
known and because we were unable to examine any specimens
of the extant species, we believe it is unwise at this time to at-
tempt a taxonomic evaluation of the fossil species or to attempt
a more precise identification of the Lee Creek Mine specimens.
The extant species, Rhinobatos lentiginosus, inhabits sub-
tropical to tropical waters of the western Atlantic Ocean (Big-
elow and Schroeder 1953:66-67); it occasionally reaches as far
north as Cape Hatteras, North Carolina. Little is known about
its range and habits.
Order Pristi FORMES
Family Pristidae
(sawfishes)
Pristis sp.
Figure 8a, b
Horizon.—Yorktown Formation (unit 1?).
Referred Material.—3 rostral teeth, USNM 281389,
281390,412220.
Remarks.—These teeth may be those of juveniles because
they lack a groove along their posterior edges; this condition
also is found in an extant species with rostral teeth of similar
form (Pristis sp., USNM 232696). All three specimens are
slightly abraded, and their surfaces exhibit bite marks. Teeth
from Lee Creek Mine are relatively short (23.5-25.5 mm in
length) and thin (2.6-2.9 mm in thickness; ratio of width to
thickness 2.1-2.7). They show no trace of a subbasal barb.
Bigelow and Schroeder (1953:28-29) reported that the ex-
tant common sawfish (P pectinatus) inhabits warm temperate
to tropical coastal waters and feeds on bony fishes and bottom-
dwelling animals.
Pristis cf. P. pectinatus Latham, 1794
Figure Sc.d
HORIZON.—Yorktown Formation (unit 1?).
Referred Material.—1 rostral tooth, USNM 412219.
Remarks.—This rostral tooth does not differ appreciably
from those of the extant Pristis pectinatus. The exserted part of
FIGURE 8.—Pristis sp.: a, USNM 412220, dorsal view; b, same specimen, dis-
tal view. Pristis cf. P. pectinatus: c, USNM 412219, dorsal view showing reg-
ularly tapering exserted portion; d, same specimen, posterior view showing
position of groove. (Scale bar= 1.0 cm.)
the tooth is moderately short, being about equal to the inserted
part. The apex of the crown is aligned with the mesial axis rath-
er than being displaced distally. On the exserted portion of the
tooth, the distal margin is straight (Figure 8c), with a noticeable
groove (Figure Sd) that extends to the tip of the tooth, rather
than a cutting edge. On the inserted portion of the tooth the dis-
tal margin bends mesially. The outline of the mesial margin of
the tooth is obliterated by wear and breakage, but the exserted
portion was probably convex and rounded in cross section. The
tooth is 52.7 mm in proximodistal length, 12 mm in anteropos-
terior length, and 7.5 mm thick at the proximal end, tapering to
2.0 mm at the worn apex.
Oral teeth, which also are important for the identification of
fossil pristid remains, were not recovered at Lee Creek Mine.
Order Rajiformes
Family Rajidae
(skates)
Raja sp.
Figure 9
HORIZON.—Yorktown Formation (unit 1).
Referred Material.—2 teeth, USNM 476398,476399.
Remarks.—Two teeth recovered from the spoil piles of
principally Yorktown matrix compare favorably with those in
a dentition of a male of the extant species Raja laevis (USNM
110962). USNM 476398 (Figure 9a,b), from the anterior por-
tion of the jaw, has an awl-like crown that inclines strongly
lingually; the crown foot extends laterally, creating a shelf
that circumscribes the crown. Basal to the crown foot the root
is constricted but flares basally. On its labial side the root is
flattened, which gives it a semicircular cross section. A deep
90
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 9.—Raja sp.: a, USNM 476398, labial view; b, same specimen, lateral view; c, USNM 476399, labial
view; d, same specimen, lateral view. (Scale bar=0.l cm.)
transverse groove bisects the root, giving it a bipedal appear-
ance. This tooth measures 7.25 mm in height and 5.35 mm in
width. In USNM 476399 (Figure 9c,d) the crown is stubby
and rounded by wear; the root is similar to that of the above
specimen. This tooth measures 5.20 mm in height and 5.40
mm in width.
The extant Raja laevis feeds chiefly on larger crustaceans,
but it also eats bony fishes, including tautog and hake (Bigelow
and Schroeder, 1953:223). According to McEachran and Mu-
sick (1975:119), this skate ranges from the Gulf of St.
Lawrence to Cape Hatteras and occurs to depths of 375 m.
Order Myliobatiformes
Family Dasyatidae
(stingrays)
Dasyatis say (Lesueur, 1817)
Figure 10a-r
Horizon.—Pungo River Formation (units 1-5); Yorktown
Formation (units 1, 2).
Referred Material.—433 isolated teeth, USNM
207584-207588, 301684-302045.
NUMBER 90
91
FIGURE 10.—Dasyatis say, male and female teeth: a, USNM 207584, Yorktown Formation, female tooth,
occlusal view; b, same specimen, lateral view; c, same specimen, labial view; d, same specimen, lingual view; e,
USNM 207585, Yorktown Formation, female lateral tooth, occlusal view (lingual side down);/ same specimen,
lateral view; g, same specimen, labial view; h, same specimen, lingual view; /, USNM 207586, Yorktown Forma-
tion, male tooth, occlusal view;/ same specimen, lateral view; k, same specimen, labial view; /, USNM 207587,
Pungo River Formation, male tooth, occlusal view; m, same specimen, lateral view; n, same specimen, labial
view; o, USNM 207588, Pungo River Formation, male medial? tooth, occlusal view; p, same specimen, lateral
view; q, same specimen, labial view; r, same specimen, lingual view. Dasyatis cf. D. americana, USNM 207548,
Pungo River Formation: s, lateral view; t, labial view; u, occlusal view. (Scale bars: a-r=0.5 cm; s-u=0.25 cm.)
Remarks.—The Lee Creek Mine teeth are morphologically
identical to those of the modern Dasyatis say. They both dis-
play a punctate occlusal surface, a well-defined cutting edge di-
viding the occlusal surface and lingual apron, and abbreviated
striations that extend a short distance down the lingual apron
from the cutting edge.
Bigelow and Schroeder (1953:382) and Taniuchi and Shimi-
zu (1993) reported that the teeth of D. say exhibit sexual di-
morphism. The teeth of females and immature males are "qua-
drangular with blunted corners, about as broad (transversely) as
long (anteroposteriorly), the functional surface weakly rounded
or more or less irregular from wear; those of mature males with
low and broadly triangular cusps, largest in youngest rows"
(Taniuchi and Shimizu, 1993:54). Teeth from both sexes occur
at Lee Creek Mine; those of females are illustrated in Figure
IQa-h, and those of males are illustrated in Figure 10/-r. The
teeth range in height from 2.6 to 3.8 mm (mean=3.2 mm, «=5)
and range in width from 2.8 to 3.9 mm (mean=3.3 mm, n=5).
Although the extant species normally inhabits subtropical to
tropical waters, it ventures into more temperate waters during
the summer. Bigelow and Schroeder (1953:358-359) reported
that D. say "has been reported as deep as 6-20 fathoms; and
some may summer where the depth is as great as 20-30 fath-
oms, if reports of their occurrence on Georges Bank are well
92
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
founded." The extant species probably feeds on crustaceans and
mollusks.
Dasyatis centroura (Mitchill, 1814)
Figure Wa-d, g-i
HORIZON.—Yorktown Formation (units 1, 2).
Referred Material.—About 350 dermal denticles,
USNM 182122, 182123, 182129-182135, 182137, 182139,
182141, 280071-280305, 353680, 353684, 445534,445544,
476402, 476403, 482224^182229.
Remarks.—Numerous dermal denticles were recovered
from the spoil piles, particularly in the Yorktown matrix, that
are very similar to those found along the tail and back of the
extant species Dasyatis centroura. These denticles are circular
to oval in outline, with one or more centrally located conical
points. Silas and Selvaraj (1985:252) reported that the sharp-
ness of the conical points decreases as the base of the denticle
Figure 11 .—Dasyatis centroura: a, USNM 353684, dorsal view of dermal denticle marked by radiating rugosi-
ties with enameloid caps missing; b. USNM 280071, dorsal view of dermal denticle with three conical points
with enameloid caps preserved; c, USNM 353680, dorsal view of dermal denticle with triangular enameloid cap
Recent D. centroura: d, USNM 197504, dorsal view of caudal denticles. Ceratopterus unios, holotype, ANSP
8069, dermal denticle: e, dorsal view;/ lateral view. Dasyatis centroura: g, USNM 482224, dorsal view'of der-
mal denticle; h. same specimen, lateral view; /, USNM 482225, dorsal view of dermal denticle with serrate
enameloid cap. (Scale bars= 1.0 cm.)
NUMBER 90
93
increases in size. Unlike D. centroura, which is known to have
denticles that support only two or three conical points (Bigelow
and Schroeder, 1953:355), the Lee Creek Mine specimens sup-
port up to 10 conical points, which may be the result of the Lee
Creek Mine denticles coming from specimens larger than those
available to Bigelow and Schroeder.
The external surfaces of these denticles may have fragile, tri-
angular (narrow to wide) to conical enameloid caps (Figure
1 \b,c) (terminology of Reif, 1979). Basal to these caps, the ex-
ternal surface of the denticle may be smooth to strongly striat-
ed. According to Bigelow and Schroeder (1953:355), those
with striated bases occur only on the tail. On the dermal denti-
cles of a tail of a recent D. centroura (USNM 197504) (Figure
1 \d) and in a Lee Creek Mine specimen (USNM 280071, Fig-
ure 1 lb), these striations extend under the enameloid cap. In
Lee Creek Mine specimens that lack enameloid caps, these stri-
ations extend almost to the apex of the denticle (Figure 1 \a).
Paleontologists (Larrazet, 1886; Zittel, 1887-1890; Reif, 1979)
have identified fossil specimens without their enameloid caps
as Acanthobatis; these should be referred to Dasyatis.
Figure 11/ shows a narrow denticle, USNM 482225, that we
believe also belongs to Dasyatis centroura. The edges of the
enameloid cap are serrated in the same manner as the caudal
spines.
According to Stehmann (1981), the extant species inhabits
tropical latitudes, occurring in waters to depths of 300 m, and it
feeds principally on bivalves, crustaceans, and worms.
Dasyatis cf. D. americana Hildebrand
and Schroeder, 1928
Figure \0s-u
Horizon.—Pungo River Formation (units 1-3).
Referred Material.—1 isolated tooth, USNM 207548.
Remarks.—The root is dasyatid except that the specimen il-
lustrated has two grooves rather than the usual one. The root
constricts to one-third of the basal diameter at the crown-root
boundary. Like most male dasyatid teeth, the crown is acumi-
nate but asymmetrical, the occlusal surface is convex labially
and divided into two ridges by a deep medial sulcus, and the
basal margin is accentuated by a cingulum-like irregular ridge.
The Lee Creek Mine specimen is 3.5 mm in maximum height
and 1.9 mm in width (mesial-distal diameter).
Except for the tripartite root, this tooth, which has a medial
sulcus on the occlusal surface, resembles those of the male
Dasyatis americana.
According to Bigelow and Schroeder (1953:350-351), the
extant species prefers warm-temperate to tropical coastal wa-
ters. It is not known to occur at the depths represented by the
Pungo River Formation; their presence there may be the result
of regurgitation by sharks that fed on them. The extant Dasyat-
is americana feeds on blue crabs, clams, shrimp, worms, and
small bony fishes.
Nota Bene
Leidy (1876:86) described as a new species of manta ray
(Ceratoptera unios) a large, thick, dermal denticle (length=8.2
cm, width=5.4 cm, thickness=3.6 cm) of Dasyatis. The holo-
type (ANSP 8069), which Leidy mistook for a caudal spine,
has an elongate, oval enameloid cap. Basal to this cap the den-
ticle surface is striated. At one extremity of its long axis, a facet
indicates that this denticle abutted another one. This specimen
(Figure 1 le,/), which was found in the phosphate beds along
the Ashley River, South Carolina, and may be from the
Pliocene, is more massive than any found at Lee Creek Mine.
Two fused denticles from Lee Creek Mine, USNM 482224,
which together measure 4.8 cm in length (width=2.4 cm,
thickness=1.4 cm), are similar in morphology (Figure \\g,h).
These fused denticles support our assignment of Ceratoptera
unios to Dasyatis. At this time we cannot ascertain the specific
identity of Leidy's holotype.
Family Myliobatidae
(eagle rays)
Pteromylaeus sp.
Figure 12a,*
Horizon.—Pungo River Formation (units 1-5).
Referred Material.—7 partial dental pavements, USNM
24758, 25448,297760,464159.
Remarks.—These specimens may be indistinguishable
from the extant species, Pteromylaeus bovinus, which is pres-
ently found in the eastern Atlantic Ocean and the Mediterra-
nean Sea. With only one specimen of the extant species avail-
able to us, we cannot confirm the identity of the fossil species;
thus, we identify the teeth from Lee Creek Mine to genus only.
The largest specimen of this species from Lee Creek Mine is
USNM 464159 (Figure 12A:).
We refer the Lee Creek Mine specimens to Pteromylaeus be-
cause the length of the median teeth is seven times greater than
their width, a character that McEachran and Capape (1984:206)
and Capape and Quignard (1975:1335) used to separate the
teeth of Pteromylaeus and Myliobatis. Garman (1913:438)
characterized the teeth of Pteromylaeus as having three rows of
very narrow lateral teeth; however, the width of the teeth ap-
pears to be variable because Capape and Quignard (1975:1331)
figured a dentition with lateral teeth that are identical to those
of Myliobatis. Nishida (1990), who studied the phylogeny of
the myliobatoids, stated that the size and shape of these teeth
are highly variable. When large suites of dentitions of mylio-
batids become available for study, our generic assignment for
the fossil species may have to be revised.
The extant species inhabits warm-temperate to tropical wa-
ters (McEachran and Capape, 1984:205) and feeds on bottom-
dwelling crustaceans and mollusks.
94
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 12.—Pteromylaeus sp.: a. USNM 24758, lower dental battery, occlusal view. Aetobatus sp.: b, USNM
312263, lower dental battery, occlusal view; c, USNM 312264, upper dental battery, occlusal view. Rhinoptera
sp.: d. USNM 24745, lower medial tooth, occlusal view; e, same specimen, anterior view. Plinthicus stenodon.fi
USNM 207591, incomplete medial tooth showing narrow occlusal surface; g. same specimen, lingual view
showing bifurcating grooves on crown and multilobed root; h. same specimen, labial view;y, same specimen, lat-
eral view. (', USNM 207592, lateral tooth, occlusal view. Pteromylaeus sp.: k, USNM 464159, lower dental bat-
tery, occlusal view. (Scale bars= 1.0 cm.)
Aetobatus sp.
Figures \2b.c, 13
Horizon.—Pungo River Formation (units 4, 5); Yorktown
Formation (units 1, 2).
Referred Material.— 3 uncataloged incomplete upper
dental plates (Pungo River Formation phosphatic limestone);
numerous uncataloged incomplete isolated teeth; 2 lower and
upper dental batteries, USNM 312263, 312264; cast of 1 re-
stored upper dental pavement, USNM 489120 (Yorktown For-
mation).
Remarks.—Most of the specimens from Lee Creek Mine
are incomplete, isolated teeth. They include chevron-shaped
lower teeth and gently arching upper teeth that are characteris-
tic of Aetobatus. The largest and only specimen with complete
teeth from Lee Creek Mine is in the collection of George W.
Powell, Jr., who donated an excellent cast of this specimen to
the Smithsonian Institution (USNM 489120, Figure 13). This
specimen, which is 24.2 cm long and 12.5 cm wide, has the lin-
gual portion of the dentition nearly complete; the labial portion
of the dentition consists of teeth with large fragments missing.
NUMBER 90
Figure 13.—Aetobatus sp., USNM 489120, Yorktown Formation, cast of
upper dental battery collected and restored by George W. Powell, Jr., occlusal
view. (Scale bar= 1 cm.)
In form, the teeth are gently arcuate, with no lateral tooth rows
present, which is characteristic of the genus (Bigelow and
Schroeder, 1953:452). On the right lateral extremity of the den-
tition, each tooth tapers to a rounded point. On the left side, the
teeth are truncated and have rounded corners. Because denti-
tions from large individuals of the extant species of Aetobatus
were not available to us, we believe that at this time it is pru-
dent not to identify this specimen to species.
According Bigelow and Schroeder (1953:461), the extant
species inhabits shallow to deep, warm temperate to tropical
waters. It feeds on bivalve mollusks.
95
Family Rhinopteridae
(cownose rays)
Rhinoptera sp.
Figure \2d,e
HORIZON.—Pungo River Formation (units 1-5).
Referred Material.—Approximately 200 fragments of
teeth; 52 isolated teeth, USNM 24745, 284831, 312262.
Garman (1913), Gudger (1933), and Nishida (1990) reported
that the size, shape, and number of rows of these teeth (5-19)
are highly variable. Because sufficient samples of the denti-
tions of the extant species were unavailable to us, we believe it
is premature to assign the Lee Creek Mine specimens to a fossil
species or to evaluate the validity of the fossil species.
Remarks (isolated teeth).—The crown height of unworn
teeth is approximately equal to the width of the crown (crown
height/width=0.9-1.3, mean=1.06, n=6). In medial teeth the
crown heights are uniform from one side of the tooth to the
other, but in the first rows lateral to the medial teeth, the
crowns are higher on the mesial side than on the distal side. In
unworn teeth, the occlusal surfaces either are smooth or are
covered with faint and irregular depressions. The transverse
edges of the crown show irregular vertical ridges; on the labi-
al side of the tooth, the surface is smooth and shiny, but on the
lingual side of the tooth, it usually has a finely pebbled tex-
ture. On this same side of the tooth just below the crown, a
prominent transverse ridge extends the full length of the
tooth.
The crown overhangs the root on all but the lingual side,
where the root margin is even with or projects beyond the base
of the crown. As the teeth grew, the number of grooves in the
root decreased; for example, the number of grooves per cm
(spacing of grooves) decreased from a maximum of 13.6 (small
median tooth, transverse width=14 mm) to 7.5 (intermediate-
sized upper medial tooth, transverse width=23 mm). The larg-
est specimens have 7.5 to 8.5 grooves per cm.
The extant cownose ray inhabits coastal to deep, warm-tem-
perate to tropical waters, but it migrates into more temperate
waters during the summer (Rogers et al., 1990). It feeds on bi-
valve mollusks.
Plinthicus stenodon Cope, 1869
Figure !2/-y
HORIZON.—Pungo River Formation (units 1-6).
Referred Material.—Several hundred isolated teeth,
USNM 207591, 207592.
Remarks.—This species, known only from isolated teeth, is
easily recognized. The occlusal face is concave and is covered
with labiolingually oriented rounded ridges and grooves. On all
specimens the width of the occlusal surface is about 2.5 mm, or
about one-third the height of the medial teeth and about one-
half the height of the teeth of the presumed second lateral row.
96
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Labial and lingual articulating surfaces bear closely spaced (20
per cm) vertical ridges that often split and divide. When viewed
laterally, the laminae on the root (which is the myliobatid type)
are subcircular and are unusually thin (0.3 mm) and fairly
widely spaced (6 per cm).
Three types of teeth are present in the sample: (1) asymmet-
rical teeth about 1 cm in length, higher mesially than distally;
(2) symmetrical short teeth also about 1 cm in length; and (3)
symmetrical long teeth. Teeth of the third type are almost al-
ways broken, but the contacting pieces of a complete tooth
sometimes can be recovered by careful collecting. Two such
teeth, each 42 mm in length, were collected from the sandy
layers of units 4 and 5 of the Pungo River Formation. When
arranged in a rhinopterid pattern, the short teeth of types one
and two would represent the second and first lateral rows, re-
spectively, and the long teeth of type three would represent
the medial row. This series formed a rather coarsely ridged
pavement that, judging from the seemingly little wear that ap-
pears on the occlusal surfaces, was not used for heavy-duty
crushing.
Cappetta (1970, 1987) assigned Plinthicus to the mobulids
because the tooth is high and thin and little wear appears on the
occlusal surface and because of the osteodentine histology;
however, his sample was too small to reconstruct the dentition.
When we reconstructed the dentition of this ray, the teeth best
fit in a typical Rhinoptera pattern, with a transversely convex
upper pavement and a nearly flat or only slightly transversely
concave lower pavement. Both of the dental pavements were
longitudinally convex, the upper more so than the lower. Each
dental pavement appears to have consisted of seven rows of
teeth: three distinct sets of transversely elongated teeth, a medi-
al and two lateral rows, and four rows of lateralmost teeth with
nearly equal transverse and longitudinal widths, the condition
in the extant species.
The specimens that Fowler (1911) attributed to Plinthicus
belong in part to Myliobatis and in part to Aetobatus.
A few teeth with lower crowns were found in the same lay-
ers as the above specimens; these have a similar root pattern
but a distinctly different occlusal surface. This surface is less
rugose, and it inclines sharply downward toward the labial
edge. It is uncertain if this represents a different form or is a
result of wear. The occlusal surface does not appear to be
abraded.
Family MOBULIDAE
(manta rays)
Mobula sp.
Figure Ha-p
Horizon.—Pungo River Formation (units 1-5); ?Yorktown
Formation (unit 1, possibly redeposited).
Referred Material.—40 isolated teeth, USNM 207549,
207579-207582; 7 caudal spines, USNM 285372, 285381,
291226, 421695, 467584, 467585.
Remarks.—Notarbartolo-di-Sciara (1987:9) reported that
ontogenetic variation and sexual dimorphism occur in the teeth
of Mobula, stating, "Heterodonty is one of the most salient
mobulid characteristics. Sexual dental dimorphism, as well as
ontogenetic, dignathic, and monognathic heterodonty, all occur
in most Mobula species. One cause of such a high degree of
variability may be that teeth often appear to grow in width,
therefore increasing the number of cusps and of root lobes, pri-
or to the branching of one row into two. As a consequence of
the variety of tooth shapes which can be found within the same
toothband, the use of tooth morphology as a systematic tool
may be misleading in living forms, and quite problematical in
palaeontological [sic] studies. An effort should be made of
identifying tooth characters which remain constant within each
species, if tooth morphology is to be used as a taxonomic aid in
defining the systematics of the genus Mobula."
In view of the above, we herein identify the three morpho-
types that occur at Lee Creek Mine to genus only.
The teeth of the first morphotype (USNM 207549, 207579,
207580; Figure 14o-i) have flat, triangular, ovoid, or rectangu-
lar occlusal surfaces and one to four lingual cusplets. A row of
tubercles may occur on the occlusal surface along the labial
edge or along the labiolingually directed shallow striations. In
sagittal section the root is wedge-shaped to trapezoidal and is
basally divided into one to four grooves, the number of grooves
increasing with an increase in the length of the tooth.
Teeth of the second morphotype (USNM 207581; Figure
\4m-o) are small (1.5 mm total height), with a prominent, me-
dian, lingually directed cusplet bordered on either side by a pair
of much shorter lateral cusplets. The occlusal surface is marked
by relatively deep and labiolingually directed sulci that extend
from the labial edge of the tooth, where they are best devel-
oped, partly onto the median cusplet. The lateral edges of the
crown are usually higher than the middle of the occlusal sur-
face, making the latter concave. The root is either bipartite or
tripartite.
In the third morphotype (USNM 207582; Figure 14/'-/), the
teeth have broad, labiolingually compressed crowns. The labial
and lingual faces appear corrugated, with strong, vertical ridges
separated by deep grooves; the ridges may bifurcate or end part
way up the crown face. The occlusal face is flattened; this sur-
face is triangular in occlusal view on narrow specimens but
zig-zags on more elongate specimens, an effect caused by the
jagged lingual edge. The root is small and is divided basally
into two to five lobes.
Seven caudal spines from the spoil piles at the Lee Creek
Mine are referred to this genus. They compare favorably with
the spine illustrated by Notarbartolo-di-Sciara (1987:58), ex-
cept that just basal to where the exserted spine inserts into the
bulbous base there are two thin, lobate structures (Figure \4p).
NUMBER 90
97
The extant species (Bigelow and Schroeder, 1953:493) in-
habits warm temperate to tropical coastal waters, feeding on
small shrimp and minnows.
Manta sp.
Figure 14<?
Horizon.—Yorktown Formation (units 1, 2).
Referred Material.—30 osseous masses partially enclos-
ing diminutive caudal spines, USNM 280595, 467557^167583.
Remarks.—Holmes (1859) first described and published
the only illustration of these caudal spines. In their discussion
of the extant giant devil ray, Manta birostris, Bigelow and
Schroeder (1953:504) noted that some specimens have one or
two small caudal spines. Other specimens lack emergent spines
but may have a prominent hard protuberance on the dorsal side
of the base of the tail, close behind the dorsal fin. This knob is
formed by a fusiform mass of bony material that is attached to
the muscular tissue of the tail. On the sloping posterior surface
of the bony mass, a stubby spine is often present, the spine and
the bone being completely covered by skin.
A number of fusiform osseous masses, some with very small
caudal spines, were collected at Lee Creek Mine from the low-
er beds of the Yorktown Formation (e.g., Figure 14^). These
agree very closely with Holmes's description and figure.
Extant devil rays (Bigelow and Schroeder, 1953:501,
509-510) inhabit subtropical to tropical shallow waters, and
they also may be found in deeper waters. Little is known about
their feeding habits.
Batoidei
Genus and species undetermined
Figure 15a
Horizon.—Pungo River Formation (units 1-5); Yorktown
Formation (units 1, 2).
Referred Material.—1 caudal spine, USNM 476297; nu-
merous uncataloged caudal spines.
Remarks.—Imbricated caudal spines are common fossils at
Lee Creek Mine, especially in Pungo River sediments. Al-
though they are frequently referred to Dasyatis (stingray) in the
Lee Creek fauna, at least four families of batoid fishes have
members that bear one or more of these spines on the dorsal
surface of the tail. It is not possible now to assign these spines
to genus or species.
Order Squatiniformes
Family Squatinidae
(angel sharks)
Squatina sp.
Figure 156-/
Horizon.—Pungo River Formation (units 4, 5); Yorktown
Formation (units 1, 2).
Referred Material.—17 teeth, USNM 207541-207543,
475000; 14 vertebrae, USNM 464226^164240.
FIGURE 14.—Mobula sp., tooth type 1: a, USNM 207549, lin-
gual view; b, same specimen, occlusal view; c, same specimen,
lateral view; d, USNM 207579, tooth lacking posterior cusplets,
labial view; e, same specimen, occlusal view;/ same specimen,
lateral view; g, USNM 207580, tooth with prominent posterior
cusplets and tripartite root, lingual view; h, same specimen,
occlusal view; i, same specimen, lateral view. Mobula sp., tooth
type 2:j, USNM 207581, lateral view of high-crowned tooth
with bipartite root; k, same specimen, occlusal view; /, same
specimen, lingual view. Mobula sp., tooth type 3: m, USNM
207582, labial view of anterolateral tooth; n, same specimen,
occlusal view; o, same specimen, lateral view. Mobula sp., cau-
dal spine: p. USNM 291226, dorsal view. Manta sp., caudal
spine: q, USNM 280595, dorsal view. (Scale bars: a-/=0.25
cm; g-i=0.30 cm;/-o=0.20 cm; p,q=2.0 cm.)
98
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Remarks.—The teeth have broad roots that appear thin or
very compressed when viewed labially or lingually. In basal
view, the root is hollowed out and protrudes lingually, more so
in the lower teeth than in the upper teeth. On the labial face of
the crown, an enameloid peg extends basally; on the lingual
face, the crown foot extends like an apron out onto the root.
These dental characters are characteristic of Squatina (Cappet-
ta, 1987).
An anterior tooth from the Pungo River Formation (USNM
207543, 6.8 mm high x 6.5 mm wide) is distinctive because of
the robustness of the crown relative to the root (Figure \5h-j).
The crown is smooth on the labial face (Figure 15/'), and it is
slightly less convex on the labial face than on the lingual face.
The mesial cutting edge of the crown is absent, possibly due to
wear. Mesial and distal enamel shoulders are short and concave
rather than convex toward the root. The root is marked basally
by a deep sulcus.
USNM 207542 (5.8 mm high x 1.1 mm wide; Figure \Se-g)
and USNM 475000 (6.7 mm high x 8.0 mm wide), from the
Yorktown Formation, also are anterior teeth as indicated by
their convex roots, which are concave in basal view. They dif-
fer from the other specimens in having a central, well-marked
ridge on the lower half of the labial face of the crown, which
forms an apron over the labial face of the root. The enamel
shoulders extend almost to the lateral extremities of their roots.
A small Yorktown Formation specimen, USNM 207541 (3.5
mm high x 3.7 mm wide; Figure \5b-d), shows a faint indica-
tion of the coronal ridge that characterizes the aforementioned
Yorktown Formation specimens. It differs from both of the oth-
er teeth in having low but distinct lateral denticles on each
enamel shoulder.
Fourteen vertebrae were found that are identical to those of
the extant Squatina squatina. They are aseptate centra that in
cranial or caudal view are oval in outline (Figure \5k,l). The
largest centrum measures 18.2 mm in height and 24.9 mm in
width.
The extant western Atlantic species, Squatina dumeril, in-
habits temperate to subtropical waters (Compagno, 1984:146).
It feeds on small bottom fishes, crustaceans, and shellfish.
Order Orectolobiformes
Family Parascyllidae
(collared carpetsharks)
Genus Megascyliorhinus Cappetta and Ward, 1977
When it was first described, Megascyliorhinus was assigned
to the Scyliorhinidae. Later, Cappetta (1987:113) noted that the
teeth of this genus lack a pulp cavity and possess a core of os-
teodentine in the lower half of the cusp and that this genus,
therefore, may not be a scyliorhinid.
Pfeil (1984:112) erected a new family, Megascyliorhinidae,
for this genus, noting that "the apico-basal transverse ridges of
the lingual and labial crown faces and the morphology of the
root with its characteristic system of vascularisation" distin-
guish this family from the Scyliorhinidae. Because these char-
acters occur in other orectilobiform families and do not estab-
lish a unique identity for Pfeil's taxon, we believe his erection
of a new family is incorrect.
Cione (1986) identified a new species, Megascyliorhinus
trelewensis, from the late Oligocene-early Miocene sediments
of Patagonia. His specimens differ, however, from all others
assigned to this genus in two ways: (1) they lack an osteoden-
tine core, and (2) the transverse groove of the root does not di-
vide the basal face of the root into two "pedestals." When we
compared the illustrations of his type suite to the juvenile teeth
of the extant species, the nature of the transverse groove, the
position of the central foramen, and the occurrence of lateral
foramina were very similar. We believe, therefore, that Cione's
species is not assignable to Megascyliorhinus and may be
based on juvenile teeth of an already described species of
Hemipristis, which in fossil form has orthodont teeth (Compag-
no, 1988:35).
Nishimoto and Karasawa (1991) noted that unlike the
Scyliorhinidae, the root of Megascyliorhinus miocaenicus
lacks labial marginal foramina, and it bears a pair of large, lin-
gual marginal foramina. Further, the flattened basal face of the
root with a central foramen and a pair of large, lingual marginal
foramina suggested to them that this genus belongs in the Orec-
tolobiformes, family indeterminate.
We agree with Nishimoto and Karasawa (1991) that this ge-
nus is an orectolobiform, but we also believe that it is a mem-
ber of the family Parascyllidae. Of the orectolobiforms, only
the teeth of the Parascyllidae have roots with broad, flat bases
divided by median grooves. Also, in basal view, the roots of
the teeth of Megascyliorhinus have the same shape as those of
the parascyllids. Similarities between parascyllids (illustrated
by Herman et al., 1992) and Megascyliorhinus also can be
found in the crown, dentitions of both have teeth that are elon-
gate, and both lack labial aprons or pegs. Unlike the teeth of
the Parascyllidae, lateral cusplets are absent or are not as large
as those in the extant members of this family, and the coronal-
root boundary is not constricted. Despite these differences, we
believe Megascyliorhinus should be assigned to the Parascyl-
lidae.
Megascyliorhinus miocaenicus (Antunes and
Jonet, 1969-1970)
Figure \5p,r
Horizon.—Pungo River Formation (unit 1).
Referred Material.—1 tooth, USNM 475364.
Remarks.—David Ward donated to the USNM one tooth of
this species, which he recovered from the "basal black sand" of
the Pungo River Formation, Gibson's (1967) dark greenish
brown phosphatic sands (unit 1). This tooth lacks its tip and
lacks lateral cusplets, and the very convex labial face obscures
the cutting edge. Unlike other teeth of this species, which are
NUMBER 90
99
FIGURE 15.—Batoid: a, USNM 476297, caudal spine, dorsal view. Squatina sp.: b, USNM 207541, incomplete
anterolateral tooth, labial view; c, same specimen, lateral view; d, same specimen, lingual view; e, USNM
207542,  anterior tooth, labial view;/ same specimen, lateral view; g, same specimen, lingual view; h, USNM
207543, anterior tooth, lingual view; ;', same specimen, lateral view;/ same specimen, labial view; k, USNM
464235, vertebra, dorsal view; /, same specimen, ventral view. Ginglymostoma sp.: m, USNM 457231, lingual
view; n, same specimen, labial view. Rhincodon sp.: o, USNM 467537, lateral view. Megascyliorhinus miocaen-
icus, USNM 475364:/), lingual view; r, labial view. (Scale bars: a=1.0 cm; b-d,h-j,m,p,r=0.2 cm; e-g=0.9 cm;
k,l=0.75 cm; n=0.15 cm; o=0.175 cm.)
striated on the labial and lingual faces, only the base of the la-
bial crown foot has faint striations, and the lingual face is
smooth. Striations, a primitive character, also are absent on the
teeth of the extant species of this family. With the exception of
the striations, this specimen compares favorably with the holo-
type of Megascyliorhinus miocaenicus. The tooth measures 7.2
mm in height and 6.4 mm in width.
Antunes and Jonet (1969-1970) assigned this species to
Rhincodon, but Cappetta (1987:113) correctly assigned it to
Megascyliorhinus.
The Lee Creek tooth is the first record of this genus from
North America and is the first record of this species in the
western Atlantic basin. Megascyliorhinus miocaenicus has
been found in the Miocene and Pliocene sediments of France,
Tunisia, and Japan and in the Oligocene of Czechoslovakia
(Cappetta, 1987:113).
From the Miocene-Pleistocene sediments of New Zealand
and Australia, Keyes (1984) identified more elongate teeth
with striated crowns that also lacked lateral denticles as M.
cooperi Cappetta and Ward, a species previously known only
from the Paleogene. In differentiating his specimens from M.
miocaenicus, Keyes (1984:205) noted that the teeth of the lat-
ter species were "more robustly crowned with pronounced,
elongate denticles." His description does not agree with that
of Antunes and Jonet's holotype (1969-1970:153, fig. 205, pl.
9: figs. 42—44). This specimen has a stockier appearance than
those illustrated by Keyes, and it lacks lateral denticles. In the
extant parascyllids, the more slender teeth come from the an-
100
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
terior portions of the jaws. Antunes and Jonet's holotype
probably came from a more distal position in the jaw than
those illustrated by Kemp. Like the lamniform and carchar-
hiniform sharks, elongation of teeth also may be an intraspe-
cific variation in Parascyllids. Kemp's basis for assigning the
New Zealand and Australian Neogene teeth to M. cooperi
seems tenuous.
Family GlNGLYMOSTOMATIDAE
(nurse sharks)
Ginglymostoma sp.
Figure I5m,«
Horizon.—Pungo River Formation (unit 3).
Referred Material.—1 tooth, USNM 457231.
Remarks.—One tooth of a nurse shark was recovered from
the Lee Creek Mine. It has a stocky principal cusp with one
pair of lateral cusplets (Figure 15m,«). The root is well devel-
oped, and it is bisected by a transverse groove that penetrates
its lingual edge. It measures 2.6 mm in height and 4.3 mm in
width.
The teeth of Nebrius, which have more than two pairs of lat-
eral cusplets and have cusplets that occur more apically along
the cutting edge than in Ginglymostoma, have been misidenti-
fied as Ginglymostoma (see Arambourg, 1935, pl. 20: figs. 5,
6; Cappetta, 1970, pl. 7: figs. 1-6). According to Compagno
(1984:207), the teeth of Nebrius are "more or less compressed
in the sides of the jaws," whereas those of Ginglymostoma are
not.
Nurse sharks are inshore, bottom sharks (Compagno,
1984:206) that inhabit subtropical to tropical waters from less
than 1 m to at least 12 m in depth. These sharks feed on bot-
tom-dwelling invertebrates and on sea catfishes, mullets, puff-
ers, and stingrays.
Family Rhincodontidae
(whale sharks)
Rhincodon sp.
Figure I5o
Horizon.—Pungo River Formation (units 1-3).
Referred Material.—17 teeth, USNM 467536,467537,
467539^167553.
Remarks.—Compagno (1984:209) characterized the minute
teeth of this genus as "not strongly differentiated in jaws, with
a medial cusp, no cusplets and no labial root lobes; tooth rows
extremely numerous, in over 300 rows in either jaw of adults
and subadults."
The crown of the Lee Creek Mine tooth (Figure 15o) is
sharp, slightly curved lingually, and has a perfectly smooth sur-
face. It is compressed laterally, and the cutting edges are dis-
tinct but dull. A narrow and relatively long apron descends
onto the lingual face of the root.
The roots of these teeth are bulbous and are wider at the me-
sial and distal sides than at the crowns, and they possess a well-
marked central foramen and transverse groove. A pair of prom-
inent lateral foramina are located high on the mesial and distal
sides of the root, and the basal area of the root is marked by
small, irregular vascular openings. These teeth are identical to
those of the extant species, Rhincodon typus Smith.
The largest tooth collected has a maximum dimension of 6.3
mm; other specimens range in maximum dimension from 5.5
mm to 3.0 mm.
Cappetta (1987:81) reported the only other occurrence of
Rhincodon in the fossil record as coming from the middle Mi-
ocene of southern France (see Cappetta, 1970, fig. 72A-C).
The Lee Creek Mine specimens are the first occurrence of this
genus in the Atlantic Coastal Plain.
According to Bigelow and Schroeder (1948), the extant
whale shark reaches a length of 18.3 m TL, and may have over
3600 small teeth. A sampling of the ore reject gravels indicates
that these fossil teeth are quite abundant.
According to Compagno (1984:210-211), the living whale
shark is a "tropical and warm-temperate shark, often seen far
offshore but coming close inshore and sometimes entering la-
goons of coral atolls....It apparently prefers areas where the
surface temperature is 21° to 25°C with cold water of 17°C or
less upwelling into it....The whale shark is a versatile suction
filter-feeder, and feeds on a wide variety of planktonic and nek-
tonic organisms. Masses of small crustaceans are regularly re-
ported, along with small and not so small fishes such as sar-
dines, anchovies, mackerels, and even small tunas and albacore
as well as squids."
Order Lamniformes
Compagno (1990a:370-372) identified synapomorphies for
the Lamniformes, which include the following dental charac-
ters: (1) excluding Cetorhinus and Megachasma, teeth are dif-
ferentiated into anteriors, intermediates, laterals, and posteri-
ors; (2) excluding Mitsukurina, transverse ridges are lost on
tooth cusps in the anterolateral teeth, and reduced ridges are
sometimes present on basal ledges; (3) excluding Mitsukurina
and Carcharias, the first upper anterior tooth is lost or replaced
by a symphysial tooth; and (4) excluding Mitsukurina and the
Odontaspididae, the third lower anterior tooth is reduced to the
size and shape of a lateral tooth.
We amend these with the following. In associated dentitions
of Carcharodon subauriculatus and C. megalodon, the third
lower anterior tooth shows little or no lateralization. This con-
dition often persists in the dentitions of C. carcharias, and this
condition is not as great as that found in the two extant species
of Isurus and in two associated dentitions of Isurus xiphodon,
the putative precursor of C. carcharias.
NUMBER 90
101
Family Odontaspididae
(sand tigers)
In the past, all species of Odontaspididae were assigned to
the genus Odontaspis, but Compagno (1977) recognized char-
acters to identify two genera in this family: Odontaspis and
Carcharias. Because, however, the latter name had been sup-
pressed by Opinion 723 of the International Commission on
Zoological Nomenclature (1965), Compagno assigned Odon-
taspis taurus to the next available junior synonym of Car-
charias, Eugomphodus. Cappetta (1987:91), using Rule 23b
of the 1964 edition of the International Code of Zoological
Nomenclature (ICZN), rejected Eugomphodus as a nomen
oblitum, but he did so without the required approval of the In-
ternational Commission on Zoological Nomenclature, and for
the senior synonym he selected Synodontaspis White, 1931.
With the publication of the 1985 edition of the ICZN, howev-
er, Rule 23b can no longer be used to suppress taxonomic
names; therefore, Cappetta's (1987) suppression of Eugom-
phodus was unjustified. In 1986 Compagno and Follett's ap-
peal for the conservation of Carcharias Rafinesque, 1810,
was published and in 1987 the commission (Opinion 1459)
conserved Carcharias (International Commision on Zoologial
Nomenclature, 1987).
Both Carcharias and Odontaspis occur at Lee Creek Mine.
Compagno and Follett (1986:89-90) described the following
dental characters, which separate these two genera:
[Carcharias with] three rows of upper anterior teeth on either side of the sym-
physis; heterodonty strong along jaws, lateral teeth compressed and bladelike,
with flattened cusps, and posterior teeth strongly differentiated as carinate, mo-
lariform crushers; cusplets on anterior teeth short and strongly hooked and
cusps stout and broad-tipped; teeth larger, second lower anterior tooth 1.3 to
1.5 times the height of comparable tooth in Odontaspis....
...[Odontaspis with] two rows of upper anterior teeth on either side of sym-
physis; heterodonty weaker along jaws, lateral teeth little compressed and not
bladelike, with cusps little flattened, and posterior teeth not differentiated as
molariform crushers; cusplets on anterior teeth long and straight or weakly
curved, not hooked, and cusps slender and narrow-tipped; teeth smaller, sec-
ond lower anterior tooth 0.6 to 0.8 times height of comparable tooth in Car-
charias.
In the Lee Creek Mine fauna we identified three species of
Carcharias: C. taurus, C cuspidata, and C. contortidens; and
we identified two species of Odontaspis: O.ferox and O. cf. O.
acutissima.
Carcharias taurus Rafinesque, 1810
Figures 16, Ylc.d
HORIZON.—Yorktown Formation (units 1, 2); James City
Formation.
Referred Material.—About 200 teeth, USNM
453082^153084, 453086, 453087, 453089, 453091, 453092,
453094-453097, 453100-453107, 453110-453112,
453114-453116, 453118-453122, 453124, 453126^153130,
453133,453135, 454400-454404, 454407, 454410-454412,
454414, 454416-454418, 476344^76346, 476348, 476349,
489143; 1 vertebra, USNM 464242.
Remarks.—The anterior teeth (Figure 16) are identical to
those of the extant Carcharias taurus. The main cusps of the
teeth are slender and awl-like, with convex but slightly flat-
tened lingual faces. On the lingual face of the crown, faint and
irregular striae occur as they do in some teeth of C. taurus and
in some specimens attributed to Odontaspis acutissima Agas-
siz. In the fossil teeth and in the dentition of the extant Car-
charias taurus, the cutting edges of the lower first anterior
tooth end higher (apically) on the crown (about one-third up
FIGURE 16.—Carcharias taurus, anterior teeth: a, USNM 476344, first upper anterior, lingual view; b, USNM 476345, first
lower anterior, lingual view; c, USNM 476346, second upper anterior, lingual view; d, USNM 489143, second lower ante-
rior, lingual view; e, USNM 476348, third upper anterior, lingual view;/ USNM 476349, third lower anterior, lingual view.
(Scale bars: a-d,ef-1.0 cm.)
102
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
the crown) than do those of the other anterior teeth; this condi-
tion of the lower first anterior tooth exists also in the anterior
teeth of Odontaspis. In the second and third anterior teeth, the
mesial and distal cutting edges are complete.
The lateral teeth of this species and those of the more abun-
dant Carcharias cuspidata are identical. None of the lateral
teeth from the Yorktown Formation are striated.
Two studies, one by Sadowsky (1970) and the other by Tani-
uchi (1970), provide some information about variation in the
dentitions of the extant species. Sadowsky noted that one pair
of lateral denticles was present in 93% of the dentitions he ex-
amined («=528); the remaining dentitions had from zero to two
pairs of lateral denticles. Other observations from his suite of
specimens pertinent to the study of fossil shark teeth include
the following: (1) the number of symphysial tooth positions
varies; the number of anterior tooth positions (three) is con-
stant; (2) great variability exists in the number, size, and shape
of the lateral teeth; (3) there is no sexual dimorphism in these
dentitions; (4) embryonic teeth lack lateral denticles; and (5)
the number of intermediate teeth varies from one to four.
Taniuchi, who studied 24 specimens, added (1) the number
of lateral denticles correlates closely with the size of the shark;
(2) in sharks under 100 cm TL, lateral denticles are absent; (3)
in some specimens the first through fourth lateral teeth have
two pairs of lateral denticles; and (4) the number of intermedi-
ate teeth varies from one to five. He also reported a fourth up-
per anterior in one specimen, but from his illustration, this
tooth appears to be a symphysial tooth, which may occur in up-
per jaws of Carcharias taurus.
In the living species, we observed the following variations in
tooth morphology. A dentition from South Africa (Hubbell col-
lection, ML 102387) exhibits considerable variation in tooth
morphology. The second upper anterior and the third lower an-
terior teeth (as well as the first and second upper laterals), on
the labial faces, have shallow V-shaped depressions in the
crown foot, and the lower first and second anteriors have deep
V-shaped depressions in the crown foot, causing the enamel to
overhang the root. On the labial face of the lower lateral teeth,
starting with the first, the crown foot is adorned with vertical
plications; these plications extend down onto the dentine of the
basal groove. Leriche (1910:271) also noticed these plications
and stated, "This character has no specific or even individual
value." In contrast, in another adult specimen, USNM 110298,
the V-shaped grooves in the crown foot are absent, and the pli-
cations are finer and are confined to the basal groove. In USNM
110939, from a juvenile, the plications are absent. These obser-
vations, based on a small number of dentitions, suggest that de-
pressions and ornamentation on the labial face of the crown
foot are variable and are taxonomically insignificant.
The anterior teeth range from 18.0 to 41.0 mm in total height
(mean=31.9 mm, «=51), from 15.0 to 21.0 mm in maximum
width (mean=18.0 mm), and from 2.4 to 1.4 in height to width
ratio (mean=1.8).
One vertebra found on the spoil piles is identical to those of
Carcharias taurus (Figure \lc,d). It is septate and of medium
size, with thick rims; the oval ventral and dorsal foramina ex-
tend to the rims of the vertebra (Kozuch and Fitzgerald, 1989).
Compagno (1984:217) reported that this shark inhabits shal-
low, temperate to tropical waters from the surf zone to 191 m
in depth. It feeds on a wide variety of bony fishes, including
bluefish, bonitos, hakes, searobins, sea basses, and porgies, as
well as on small sharks, rays, and invertebrates.
Carcharias cuspidata (Agassiz), 1843
Figures \7a,b. 18
HORIZON.—Pungo River Formation (units 1-3); Yorktown
Formation (units 1, 2).
REFERRED MATERIAL.—331 teeth, USNM 207611, 451255,
451257^151273, 454631, 476350.
Remarks.—Agassiz (1843:290) distinguished this species
from Carcharias elegans by the smoothness of its labial and
lingual tooth faces, and he distinguished it from other odon-
taspids by the greater development of the tooth's root. Of the
specimens he figured (pl. 37a: figs. 43-50), the second upper
anterior teeth in figs. 46 and 48 and a second lower anterior
tooth in fig. 49 are of Carcharias; the teeth in his figs. 43^45,
which were still in matrix at the time of illustration, also may
belong to this genus, but the tooth in his fig. 47 is indetermi-
nate. The tooth in his fig. 50 may belong to Odontaspis.
Leriche (1910:270) further characterized this species as fol-
lows:
The teeth oi Odontaspis cuspidata ...ire large and robust. Their crown is
completely smooth, very sharp along the edges, flat on the external face,
strongly convex on the internal face.
The lateral denticles are in the anterior teeth, relatively small and very acumi-
nate. In the lateral teeth, they are much enlarged, becoming often very obtuse
and sometimes seem to form a prolonging of the enamel of the crown. Their
crest is itself denticulated. One observes generally an external, rather large den-
ticle and, between this last and the crown, much smaller denticles.
The root is rather developed. The furrow in which the nutritive foramen
opens, on the internal face, is shallow; it is hardly indicated in the anterior
teeth. (Translated from French by R.W.P.)
Most of these characters occur in C. taurus; the two excep-
tions are the greater development of the root and the the wider
crowns of the anterior teeth, which do not occur in teeth of sim-
ilar size in the living species.
Comparing anterior teeth of similar size, the crowns in C.
taurus are more elongate and have a narrower appearance than
in C. cuspidata, and the roots of the second upper anterior tooth
of C. cuspidata are longer and the crown is shorter than in C.
taurus (see Figure \la,b, cf. Figure 16c).
Another character that may prove taxonomically significant
is that the angle of the root lobes in the lower first anterior teeth
is greater in C. cuspidata (mean=72°, range=63°-82°, n=\\)
than in C. contorlidens (mean=63°, range=54°-70°, n=18)
and in C. taurus (mean=62°, range 53°-75°, n=ll). Before
NUMBER 90
FIGURE 17.—Carcharias cuspidata: a, USNM 476350, second upper anterior
tooth, lingual view; b, USNM 454631, second upper anterior tooth, lingual
view. Carcharias taurus, vertebra, USNM 464242: c, slightly oblique dorsal
view; d, lateral view. (Scale bar=1.0 cm.)
these angles can be used with confidence, they must be tested
on larger populations of all three species.
In Figure 1 Sa, using teeth from the Pungo River Formation,
we reconstructed a composite dentition of this species. As
mentioned earlier, because of their identical morphology,
some of the lateral teeth may be those of Carcharius taurus.
103
It is surprising to find Carcharias cuspidata as late as the
early Pliocene (Figure ISb-d), but there is little doubt as to the
identity of the Yorktown form, and the teeth are so well pre-
served that reworking from a lower horizon is very improbable.
Only 11 teeth of this species were found in Yorktown sedi-
ments. Three of these are first lower anteriors and have a mean
height of 3.2 cm (range=3.0-3.8 cm), a mean width of 2.0 cm
(range= 1.8-2.3 cm), and a mean root angle of 79° (range =
69°-85°).
The first lower anterior teeth range from 2.4 to 3.2 cm in
height (mean = 2.8 cm, «=11), 1.6 to 2.1 cm in width
(mean=1.8 cm, n=\ 1), and 63° to 82° in root-lobes angle
(mean=72°, n=\\).
Carcharias sp.
Figure 19
Horizon.—Pungo River Formation (units 1-5).
REFERRED MATERIAL.—About 100 teeth, USNM 454419,
454420, 454565-454571, 454573-454579, 454618, 454619,
454628, 454632-454635, 454643, 454651, 454655, 454657.
454689.
Remarks.—The Lee Creek Mine specimens are very simi-
lar to those described by Agassiz (1843:294-295) as Carchar-
ias contortidens. Of the specimens in his type suite, only
those in his pl. 37a: figs. 21-23 have lateral cusplets and can
be assigned to the genus Carcharias. The specimen in his fig.
21 appears to be an incomplete, second upper anterior tooth;
those in figs. 22 and 23 are first lower and upper anterior
teeth, respectively. Agassiz (1843:294-295) characterized a
tooth of this species by "its subulate form, irregular and re-
— a
AAAAAAAA
FIGURE 18.—Carcharias cuspidata: a, composite dentition
from the Pungo River Formation; b, USNM 207611, second
upper anterior tooth, lingual view; c, same specimen, labial
view; d, same specimen, lateral view. (Scale bars: a=1.0
cm; 6-c/=0.75 cm.)
b   -   c
104
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
curved inside; its internal face is distinctly folded, and the
folds continue over all the length of the cone even near the tip,
assuming the form of more or less undulated, small veins,
very numerous and strongly distinct at the base of the enamel,
but of which the number diminishes higher proportionally as
they become mixed up." As in the teeth from Lee Creek Mine
(Figure 19), the type teeth are more slender than those of C.
cuspidata of similar size, and in comparison to C taurus, the
teeth of C. contortidens are striated or partially so on the lin-
gual faces of their crowns, whereas in the living species they
are usually smooth.
Leriche (1910) synonymized C. contortidens with Odontas-
pis acutissima Agassiz; he believed that these two species were
based on teeth from different jaws of the same dentition. Odon-
taspis acutissima, however, is a separate species and belongs in
the genus Odontaspis (see below).
The teeth of C. contortidens compare more favorably with
those of C. taurus than do those of C. cuspidata. In the extant
and fossil species, the range of dental variation is unknown;
therefore, the validity of the characters used to identify the fos-
sil species cannot be assessed as yet, and we believe it is not
prudent to identify the Lee Creek Mine teeth to species.
The first lower anterior teeth of C. contortidens range from
2.8 to 3.7 cm in height (mean=3.3 cm, «=18), 1.4 to 1.9 cm in
width (mean 1.6 cm, «=18), and 54° to 70° in root-lobes angle
(mean=63°, «= 18).
Odontaspis ferox Risso, 1826
Figure 20a-c
HORIZON.—Pungo River Formation (units 1-6).
REFERRED MATERIAL.—35 teeth, USNM 278545, 453065,
453067-453081.
Remarks.—The teeth of this species are rare in the Lee
Creek Mine fauna; they are identical to those of the living
Odontaspis ferox. As in the extant species, the cutting edges of
the teeth do not reach the base of the crown. The lateral cus-
plets are longer than those in teeth of comparable size of Car-
charias. In the extant and the fossil species, the number of pairs
of lateral cusplets varies from one to three.
As in Carcharias taurus, the teeth of O. ferox exhibit mor-
phological variations. In a dentition from an individual 2.75 m
TL long and of unknown sex (Hubbell collection, MRD2), the
anterior teeth have only one pair of lateral cusplets, whereas the
lateral teeth have two pairs. In another dentition from a larger
individual of unknown size and sex (Hubbell collection,
MRD1), the anterior and lateral teeth possess two to three pairs
of lateral cusplets. On the labial faces of the crowns of the up-
per and lower teeth of this latter dentition, plications occur on
the crown foot basal to the lateral cusplets but not between
them, but in the teeth of the 2.75 m individual, these plications
are absent. The labial faces of these plicated teeth are moder-
ately convex, whereas those of the unplicated dentition are only
slightly convex.
Only two first lower anterior teeth were found in the Pungo
River Formation: USNM 453079, which measures 3.4 cm in
height and 1.6 cm in width, and USNM 453065 (Figure 20a),
which measures 3.0 cm in height and 1.5 cm in width. The
Yorktown occurrence is represented by one first lower anterior
tooth, USNM 278545 (Figure 20c), which measures 3.9 cm in
height and 2.0 cm in width. These teeth are from individuals
with total lengths of greater than 3 m TL.
Compagno (1984:220) reported that this little-known shark
inhabits "deepish water in warm-temperate to tropical seas...at
depths of 13 to 420 m.... It feeds on small bony fishes, squids
and shrimps."
Odontaspis cf. O. acutissima (Agassiz, 1843)
Figure 20d-h
Horizon.—Pungo River Formation (units 1-5, ?6).
Referred Material.—180 teeth, USNM 451147-451180,
454526^54538.
Remarks.—We tentatively identify the small Pungo River
odontaspid as Odontaspis acutissima (Figure 20d-h). The syn-
types of this species have long lateral cusplets, which are char-
acteristic of Odontaspis. The second tooth in the type suite
(Agassiz, 1843, pl. 37a: fig. 34), from the Miocene of Switzer-
land, is embedded in matrix except for the tip of its crown, with
only its labial face exposed. Agassiz (1843:294) provisionally
assigned this specimen to Lamna acutissima. The first speci-
men (his fig. 33), a lower lateral tooth with elongate lateral cus-
plets of unknown provenance, therefore must be considered the
holotype of this species. If this specimen still exists, it must be
reexamined because it resembles a Paleogene form rather than
one from the Miocene. The Miocene teeth identified as O.
acutissima may have to be assigned to the next available junior
synonym.
Agassiz characterized the teeth of this species as having
distinct striations on the lingual faces of the crowns. In the
Lee Creek Mine teeth, the striations are weakly developed,
and they are best seen under magnification with a raking light.
Because the taxonomic significance of these striations cannot
now be assessed, we tentatively assign the teeth from Lee
Creek Mine to a species. Questions about these teeth, such as
whether they should be referred to juveniles of O cf. O. ferox
or whether they fall within the range of variation of the teeth
of the extant species cannot be answered until large samples
of teeth from the fossil and extant species are available for
study.
The first lower anterior teeth of this species range from 1.5 to
1.9 cm in height (mean= 1.7 cm, w=10) and from 0.8 to 1.2cm
in width (mean=0.9 cm, n=\0).
NUMBER 90
105
Figure 19.—Carcharias sp., anterior teeth: a, USNM 454566, first upper anterior, lingual view; b, USNM
454573, first lower anterior, lingual view; c, USNM 454628, second upper anterior, lingual view; d. USNM
454643, second lower anterior, lingual view; e, USNM 454635, third upper anterior, lingual view;/ USNM
454632, third lower anterior, lingual view. (Scale bar= 1.0 cm.)
FIGURE 20.—Odontaspis ferox, anterior teeth: a, USNM 453065, first lower anterior, lingual view; b, USNM
453078, second lower anterior, lingual view; c, USNM 278545, first lower anterior, lingual view. Odontaspis cf.
O. acutissima: d, USNM 451148, second upper anterior, lingual view; e, USNM 451150, third upper anterior,
lingual view;/ USNM 451147, first lower anterior, lingual view;g, USNM 451149, second lower anterior, lin-
gual view; h, USNM 451151, third lower anterior, lingual view. (Scale bars: a,b,d-h=\.0 cm; c=1.4 cm.)
Family Megachasmidae
(megamouth sharks)
Megachasma sp.
FIGURE 21
Horizon.—Pungo River Formation (units 1-3); ?Yorktown
Formation.
Referred Material.—9 teeth, NCSM 8796, 9560, USNM
457237, 457238, 459821, 459822, 464062, 475475, 482303.
Remarks.—The larger specimens of this species are from
the Yorktown Formation. The largest of these (NCSM 8796) is
17.0 mm high, 15.0 mm thick, and 11.9 mm wide (Figure
21e,/). It and the two following specimens were collected by
Frank and Becky Hyne, who are experienced collectors at Lee
Creek Mine and who are familiar with the stratigraphy of the
site. USNM 457237 is 15.2 mm high, 12.5 mm thick, and 13.1
mm wide (Figure 2\a,b), and USNM 457238, a lower tooth, is
9.6 mm high, 5.2 mm thick, and 7 mm wide (Figure 2\g,h).
The Hynes are confident that they collected these specimens on
the Yorktown spoil piles, where they concentrate most of their
collecting effort. USNM 475475 (Figure 2\n-p) is 14.3 mm
high, 10.8 mm thick, and 16.1 mm wide; NCSM 9560 is 15.7
mm high, 10.0 mm thick, and 10.8 mm wide. With the excep-
tion of USNM 457238, these specimens have elongate, slender
crowns. USNM 457238 is more like the Pungo River speci-
mens, and it may be from that formation.
The Pungo River specimens are smaller (Figure 2\i-m), with
USNM 459821 measuring 8.1 mm in height, 6.2 mm in thick-
ness, and 6.8 mm in width, and USNM 459822 measuring 8.7
106
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOG
FIGURE 21.—Megachasma sp. teeth: a, USNM 457237, Yorktown Formation, lingual view; b, same specimen,
lateral view; c, USNM 464062, Yorktown Formation, lingual view; d, same specimen, lateral view; e, NCSM
8796, Yorktown Formation, lingual view;/ same specimen, lateral view; g, USNM 457238, Yorktown Forma-
tion?, lingual view; h, same specimen, lateral view; i, USNM 459821, Pungo River Formation, lingual view;y,
same specimen, lateral view; k, USNM 459822, Pungo River Formation, lingual view; /, same specimen, lateral
view; m, same specimen, labial view; n, USNM 475475, ?Yorktown Formation, lingual view; o, same specimen,
labial view; p, same specimen, lateral view. (Scale bars: a-k= 1.0 cm; l,m= 1.11 cm; n-p= 1.25 cm.)
NUMBER 90
107
mm in height, 5.4 mm in thickness, and 7.0 mm in width. Un-
like the Yorktown specimens, these teeth have stocky crowns.
We do not know enough about the dentitions of the extant spe-
cies to determine if these size differences are of ontogenetic or
taxonomic significance.
The Lee Creek Mine specimens are similar to the teeth of
the extant Megachasmapelagios (Compagno, 1990a:359, fig.
2; Herman et al., 1993:195, pis. 45-48) but differ from them in
one respect. In two of the eight Lee Creek Mine specimens, the
lateral edges of the roots protrude slightly more than those of
the illustrated teeth of M. pelagios. They differ also from other
megachasmid teeth from the Miocene of California by the less-
er development of the lateral protrusion of the roots and by the
absence of lateral cusplets, which also are present in some of
the teeth of the extant species (Herman et al., 1993, pis.
45-47). The small sample size of teeth from Lee Creek Mine
does not allow us to assess the taxonomic significance of these
differences.
The teeth from Lee Creek Mine exhibit considerable mor-
phological variation: crowns may have incomplete cutting
edges, transverse grooves may be absent or in varying stages
of development even though they appear to be functional
teeth, a callosity on the labial crown foot may be smooth or
grooved, and the size and the position of the central foramen
on the torus of the root may vary. In the larger, Yorktown For-
mation specimens, the cutting edges of the crown are usually
incomplete, but in one of these larger teeth (NCSM 8796), the
cutting edges extend to the base of the crown. Punctae on the
labial face of the root are present only on these larger teeth.
The living species is a slow-swimming plankton feeder that
normally inhabits mesopelagic waters, but it may return to
shallow waters to mate (Lavenberg, 1991).
Family Alopiidae
(thresher sharks)
Genus Alopias Rafinesque, 1810
In Alopias the third upper anterior tooth, second from the
symphysis, is usually the largest anterior tooth, although in A.
superciliosus the second upper anterior tooth is occasionally
the largest. The lower anterior teeth are 10% to 20% smaller
than the upper anteriors. In both jaws, the anterior teeth are not
much larger than the first two lateral teeth, which Gruber and
Compagno (1981:626) noted is characteristic of Alopias.
Two species of thresher shark have been found at Lee Creek
Mine, Alopias cf. A. superciliosus (Lowe) and A. cf. vulpinus
(Bonnaterre).
Alopias cf. A. superciliosus (Lowe, 1840)
Figure 22h
Horizon.—Pungo River Formation (unit 3).
Referred Material.—1 tooth, USNM 475448.
Remarks.—A tooth from the Pungo River Formation ore-
coarse fraction is almost identical to some of the lower first an-
terior teeth found in males of the extant bigeye thresher shark.
The crown is elongate, and on its lingual face the basal callosi-
ty is smooth. A shallow transverse groove is present on the lin-
gual face of the root. This tooth measures 13 mm in height and
9 mm in width.
In the paleontological literature, this species has been identi-
fied from the lower Miocene of North Carolina (Case,
1980:83); from the middle Miocene of Maryland (Kent,
1994:72), Parma, Italy (Cigala-Fulgosi, 1983:224-226), and
Lisbon, Portugal (Antunes, 1970); and from the Pliocene of
Tuscany, Italy (Cigala-Fulgosi, 1988).
According to Compagno (1984:231), the extant species in-
habits circumtropical coastal and oceanic waters from the sur-
face to depths of at least 500 m. It feeds on bony fishes and
squids.
Alopias cf. A. vulpinus (Bonnaterre, 1788)
Figure 22a, b. fig
Galeocerdo triqueter Eastman, 1904:89, pl. 32: fig. 12 [holotype, ANSP 1214,
Calvert Formation, Maryland].
HORIZON.—Pungo River Formation (units 4, 5); Yorktown
Formation (units 1, 2).
Referred Material.—About 70 teeth, USNM 282471,
289095, 289106, 297466, 312441, 312447, 324928, 421917,
421919, 421921, 437885, 451181-451211, 451328, 451329,
457241, 457242; 1 vertebra, USNM 464241.
REMARKS.—Middle Tertiary alopiid teeth have been as-
signed to two species, Alopias exigua (Probst, 1879) and A.
latidens Leriche, 1908. Probst (1879), who did not give a di-
agnosis for his species, described as a new species of mako
shark a suite of teeth that he believed were from different po-
sitions in the jaws. His figs. 20 and 21, which he identified as
anterior teeth, represent incomplete teeth with erect, slender
crowns and cannot be identified with confidence to genus;
however, Leriche (1927:76) indicated that fig. 20 may repre-
sent a tooth of Lamna cattica. This tooth, which consists of
only the crown, is not that of an Alopias. Probst's fig. 21 re-
sembles the tooth of a carcharhinid rather than that of Alo-
pias; nevertheless, the teeth in his figs. 22 to 25 possess roots
that are more characteristic of Alopias than ofIsurus. Because
the location of Probst's type specimens is unknown, they can-
not be compared with those of A. vulpinus; therefore, the va-
lidity of A. exigua cannot be determined.
Leriche (1908:379) separated A. latidens from A. exigua "by
its greater size and stockier form," but stocky teeth occur in the
extant A. vulpinus. In USNM 110941 (sex not indicated) the
lower teeth are stockier than those of another individual of ap-
proximately the same size, USNM 232639; therefore, the
stockiness of the crown, which also is a sexually dimorphic
character in A. superciliosus (see Cigala-Fulgosi 1983), is not a
useful character for separating species of Alopias.
108
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
V f '•&>  yy *& ^   i&         >x*f ^ V
¦¦&&
FIGURE 22.—Alopias cf. A. vulpinus: a. composite dentition, with intermediate tooth, fourth to sixth and tenth to
seventeenth upper lateral teeth, third lower anterior tooth, and sixth to seventeenth lower lateral teeth missing; b,
USNM 464241, vertebra. Celorhinus sp.: c, USNM 312269, tooth, lateral view; d, same specimen, lingual view,
e, USNM 467556, clasper spine, dorsal view. Holotype oi Alopias triqueter (=A. cf. A. vulpinus), ANSP 1214:/
lingual view; g, labial view. Alopias cf. A. superciliosus: h, USNM 475448. tooth, lingual view. (Scale bars:
a,b,e,h=\.0 cm; c,rf=0.25 cm;/g=0.33 cm.)
Leriche (1927:76) and Cappetta (1970:23) also identified
incomplete cutting edges as a character to distinguish A. ex-
igua from A latidens. In Probst's type suite for A exigua, the
two non-Alopias teeth are the only ones with incomplete cut-
ting edges; therefore, both species have teeth with complete
cutting edges.
The validity of A. latidens will have to await the restudy of
Probst's types, if they still exist, study of Leriche's type spec-
imens, and study of dental variation in a large population of A
vulpinus and large, synchronous populations of the fossil spe-
cies. In view of the above and the limited number of fossil and
extant specimens, we cannot find characters to separate the
Lee Creek Mine specimens from the extant species, and we
believe the assignment of the Lee Creek Mine allopiid to a
species is unwarranted at this time.
The teeth from Lee Creek Mine (Figure 22a) have wide,
stocky crowns with complete cutting edges, and the callosity
on the labial face of the crown foot is rounded, sometimes
NUMBER 90
109
forming a ridge, and is plicated. Of the three extant species of
Alopias, these characters occur in the teeth of A. vulpinus.
In the five dentitions available to us, the teeth of Alopias
vulpinus exhibit considerable variation and characters not not-
ed in the paleontological literature. The lower medial tooth var-
ies in size and may be absent. The lower anterior teeth are 10%
to 20% smaller than the upper anteriors. Among the upper ante-
rior teeth, the third upper anterior (second from the symphysis)
tooth is the largest. The tips of the intermediate teeth bend lin-
gually rather than labially or being straight. In the lower lateral
teeth, the attitudes of the crowns range from inclined with a
straight distal cutting edge to hooked with a concave distal cut-
ting edge. The tips of some of the upper lateral teeth, in lateral
view, do not curve labially but rather curve slightly lingually.
Mesial and/or distal cusplets may be present.
Galeocerdo triqueter was established on the basis of an
abraded lower anterior tooth. Eastman (1904:89) characterized
the species as follows: "Teeth very robust, with elevated
crowns, smaller and less twisted than those of G. contortus,
and more faintly serrated along the coronal edges. Anterior
margin only slightly arched, posterior notch inconspicuous." In
examining the holotype of this species, ANSP 1214 (Figure
22f,g), we noticed that the faint serrations are confined to the
basal portion of the distal cutting edge; the remainder of the
cutting edge is smooth. We synonymize Galeocerdo triqueter
with Alopias cf. A. vulpinus because the type specimen lacks
the well-developed distal enamel shoulder characteristic of Ga-
leocerdo and because there is a callosity on the labial face of
the root that extends well onto the root. This tooth is almost
identical to the first lower anterior tooth of Alopias vulpinus,
and we believe it represents the same species as the specimens
from Lee Creek Mine.
The anterolateral teeth from Lee Creek Mine range in height
from 0.8 to 1.5 cm (mean=1.2 cm, «=18). These sharks were
probably 4.5 to 6 m TL.
The vertebrae of this shark also are found at Lee Creek Mine.
Their craniocaudal length is short (see Kozuch and Fitzgerald,
1989), and in side view they are septate, with the septa diverg-
ing toward the rims of the vertebrae (Figure 22b). Their dorsal
and ventral foramina vary in shape from oval to rectangular.
These vertebrae are identical to those of a specimen of A. vulpi-
nus (USNM 110242).
Compagno (1984:233) reported that A. vulpinus inhabits
coastal to oceanic temperate to tropical waters; the young are
often found close inshore and in shallow bays. They feed main-
ly on schooling fishes, such as mackerels and bluefish.
Family CETORHINIDAE
(basking sharks)
Cetorhinus sp.
FIGURE 22c-e
Horizon.—Pungo River Formation (unit 3).
REFERRED Material.—1 tooth, USNM 312269; 1 calcified
clasper spine, USNM 467556.
Remarks.—The single-cusped crown is nearly recumbent
(Figure 22c,d); near the apex of the crown the labial face is al-
most parallel to the basal face of the root. In cross section, the
crown is triangular basally to oval apically. The labial face
forms the short side of this triangular crown foot; the lingual
faces are wider than the labial face and meet at an acute angle
near the crown-root boundary.
The root forms a pedestal for the crown. In basal view it has
a triangular outline; a lingually placed central foramen occurs
in a shallow transverse groove that bisects this face. The labial
face protrudes somewhat, but it is flush with the crown; the la-
bial end of the transverse groove divides this face. Both on the
mesial face and the distal face of the root, three lateral canals
open into a depression. The tooth measures 3.1 mm in total
height, and the root is 3.3 mm in width, and 2.1 mm thick.
In morphology, except for its strongly lingually directed
crown, this tooth compares well with adult teeth of extant Ce-
torhinus maximus, but it differs in its much smaller size, which
is about half that of the extant species (compare with Herman
et al., 1993, pl. 43). The strong lingual inclination of the crown
is more characteristic of juvenile than of adult basking sharks
(Herman et al., 1993:194-195), but unlike the teeth of the juve-
niles, the crowns of the teeth from Lee Creek Mine are unoma-
mented. Sufficient specimens of the extant species have not
been examined to determine if ornamentation is a variable
character in juveniles.
In addition to the tooth, a calcified clasper spine (Figure
22e), was recovered from the spoil piles. This specimen is
identical in morphology to those illustrated by Leriche (1926,
fig. 195, pl. 37: figs. 6, 7).
The living basking sharks are plankton feeders and inhabit
boreal to warm-temperate coastal to pelagic waters (Compag-
no, 1984:235). Along the Atlantic coast of North America they
have been reported as far south as the Florida coast.
Family Lamnidae
(mackerel sharks, mako sharks, white sharks)
There are three extant genera in this family, Carcharodon,
Isurus, and Lamna. Of these, Lamna has the most primitive
teeth1, which are very similar to those of Cretolamna appen-
diculata. Lamna, however, has teeth with reduced, tapered lat-
eral cusplets and root lobes that are not very lobate, and it has a
first anterior tooth with root lobes that form an angle of 90° or
'in their phylogenetic analysis based on dental morphology, Long and
Waggoner (1996) selected Mitsukurina as the outgroup. In comparison to Hy-
bodus and Cretolamna, however, the teeth of Mitsukurina are very derived.
Several of their synapomorphies, such as absence of diastem, short root lobes,
multiple pairs of lateral cusplets, and moderate lateral cusplets, are plesio-
morphic characters.
110
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
greater rather than the acute angle of those of Cretolamna. We
identify these characters as autapomorphies for Lamna. For
Carcharodon and Isurus, Compagno (1990a:372) identified as
dental synapomorphies the characters "jaws and anterior teeth
enlarged; lateral cusplets lost on teeth or present only in very
young (?)," and as a synapomorphy of Isurus, he identified the
flexed anterior teeth. This synapomorphy is absent in Isurus xi-
phodon (see below). Only one of the synapomorphies Compag-
no (1990a:372) identified for Lamna is found as a fossil: a cal-
cified rostral node without lateral fenestra.
In addition to these genera, we tentatively assign, as Kemp
(1991) did, Parotodus to this family. The teeth of this genus
exhibit characters that prompted Cappetta (1980) to assign it to
the Otodontidae. Our comparisons lead us to assign Parotodus
to the Lamnidae for the reasons discussed below.
Cappetta (1980) included Parotodus in the Otodontidae be-
cause of its very globular root, particularly in the lateral teeth,
and because of the presence, in the Oligocene form, of lateral
denticles. These characters, however, are not taxonomically
useful. As in other lamnids, the globular roots are confined to
the lower teeth where the toruses are well developed. Lateral
cusplets, a primitive character, also occur in Lamna, the Odon-
taspididae, the Alopiidae, Triaenodon (which have very broad
lateral cusplets), and occasionally in the adult teeth of Isurus
(Bass et al., 1975c:28) and Carcharodon. We did not find any
derived characters to justify the assignment of Parotodus to the
Otodontidae.
At first we assigned Parotodus to the Alopiidae because al-
though some individuals of living makos may have stocky teeth,
their anterior teeth are more elongate than their lateral teeth. In
our sample of P. benedenii, however, the heights of the largest
lateral teeth (5.6-6.0 cm) and those of the anterior teeth (5.8-6.6
cm) overlap. This overlap in height, which does not occur in ex-
tant Isurus or in Otodus, agrees with the observations on Alo-
pias of Gruber and Compagno (1981:626): "Anterior teeth of
threshers differ from lateral and posterior teeth in having nar-
rower crowns relative to their height and more erect cusps, they
are less well differentiated in Alopias than in lamnids, odontas-
pidids, pseudocarchariids." Compagno (1990a:371) identified
the reduced size of the anterior teeth as a synapomorphy of Alo-
pias; this synapomorphy also pertains to Parotodus.
Other characters, however, suggest that Parotodus is not an
alopiid. While examining the Lee Creek Mine specimens,
Compagno (pers. comm., 14 Apr 1993) noted that the morphol-
ogies of the roots of Parotodus were like those of a mako rather
than those of a thresher. We reexamined these teeth and those
of Isurus and Alopias to verify his observation, and we found
the following. (1) Unlike alopiids, in labial view, the lateral
teeth of Parotodus do not have broad, shallow roots with
enamel shoulders extending to the extremities of the root lobes.
Like lamnids, in Parotodus the root lobes extend slightly be-
yond the basal boundary of the crown foot, and the roots are
deep. (2) Like lamnids and unlike alopiids, the lower anterior
teeth are not 10% to 20% smaller in height than the upper oc-
cluding teeth. (3) Like lamnids and unlike alopiids, the heights
of the first three or four lateral teeth exceed their respective
widths. These findings suggest to us that the less differentiated
anterior teeth (see Compagno, 1990a:371) were derived inde-
pendently of Alopias, and we assign Parotodus tentatively to
the Lamnidae.
Genus Parotodus Cappetta, 1980
Until 1980, paleontologists assigned the sole species of this
genus, Parotodus benedenii, to the genus Isurus; in that year
Cappetta erected a new genus for this species, Parotodus,
which he characterized as having "very great thickness of the
crown and a very globular root" (Cappetta, 1980:35). We re-
vise his diagnosis to read as follows: upper and lower laterals
with hooked, mako-like crowns; heights of first three or four
lateral teeth exceed their respective tooth widths; anterior teeth
not well differentiated from lateral teeth.
Antunes and Jonet (1969-1970) and Antunes (1978) stated
that the teeth identified as Isurus benedenii were the intermedi-
ate teeth of Isurus hastalis. Cappetta (1980), however, correct-
ly argued that the teeth of Parotodus benedenii represented dif-
ferent jaw positions and that their thicknesses were
proportionally greater than the intermediate teeth of I. hastalis.
Despite their stocky crowns, the teeth of Parotodus bear
some similarities to Isurus oxyrinchus. Like /. oxyrinchus, the
lower anterior teeth have well-developed toruses and robust
crowns, which in the Lamnidae are peculiar to Isurus oxyrin-
chus. Also like /. oxyrinchus, the tips of the lower teeth, in lat-
eral view, recurve labially. Unlike /. oxyrinchus, the sharply
defined cutting edges on the anterior teeth extend to the crown
foot. The roundness of the lingual crown foot, noticeable from
the labial side in /. oxyrinchus, is not visible from this side. We
do not believe, however, that these similarities warrant synony-
mizing Parotodus with Isurus.
Kuga (1985:14-16), apparently unaware of Cappetta's pa-
per, erected the genus Uyenoa for this species, which he kept in
the family Lamnidae; however, the senior name for this species
is Parotodus.
Parotodus benedenii (Le Hon, 1871)
Figures 23,24
Isurus moniwaensis Hatai, Masuda, and Noda, 1974:19-20, pl. 2: figs. 20, 22
[Miocene, Japan].
Uyenoya benedenii Kuga, 1985:14-16 [Neogene, Japan].
Horizon.—Yorktown Formation (units 1, 2).
Referred Material.—85 isolated teeth, USNM 24757,
279254, 279320, 281382, 282471, 283598, 289044, 289088,
289095, 289104, 289106, 293759, 293762,297466-297468,
302442, 312441, 312447, 324928, 421612, 421629,
421917-421921, 437885, 454539^154563, 457258-457285.
NUMBER 90
111
Remarks.—Le Hon (1871:6) characterized this species as
follows: "Species of enormous thickness that resembles the
Cretaceous Oxyrhina crassidens of Dixon. The neck of the
tooth is very wide and the gum imprint exceedingly pro-
nounced as in all teeth with thick roots. The crown is incurved
more or less, and some curved and hooked teeth having the
same characters it seems to me to have belonged to the same
animal" (translated from French by R.W.P.). The type speci-
men that Le Hon illustrated is a second lower anterior tooth,
which he noted was found in Pliocene sediments during the ex-
cavation of the fortifications around Anvers, Belgium.
Leriche (1910:281-283) reported the earliest occurrence of
this species in the early Oligocene, Rupelian, of Belgium.
These teeth are much smaller than those of the Pliocene form.
In his suite of illustrated specimens, Leriche (1910) also in-
cluded two teeth of Lamna rupeliensis (his pl. 16: figs. 5, 6),
which he identified as Oxyrhina benedenii. Leriche (1910:282)
noted that "the transformation of the heels of the crown into
lateral cusplets is observed mainly in the lateral teeth of the up-
per jaw (Fig. 5, 6, 8, 9)" (translated from French by R.W.P.).
Although the teeth in his figs. 5 and 6 were not found in associ-
ation with the others, his identification of them was not chal-
lenged by subsequent workers.
The sample of 85 teeth from Lee Creek Mine permitted us to
reconstruct the dentition of this shark (Figure 23). As in lamni-
form sharks, the upper and lower anterior teeth exhibit the
same morphological characters that permit their differentiation:
their crowns are more erect, and the angle formed by the root
lobes is more acute than in the lateral teeth. In the lower anteri-
or teeth there is a greater development of the torus.
Only the second and third upper anterior teeth are present
from Lee Creek Mine. The first anterior tooth may be absent in
this genus; no teeth were recovered that were nearly symmetri-
cal and with root lobes forming an acute angle. In the second
anterior tooth, the crown inclines distally, the distal cutting
edge is concave, the root lobes intersect at a right or slightly
obtuse angle, and the distal root lobe has a greater mass than
the mesial one. In the third upper anterior tooth, along the me-
sial edge, the arc of the distal curvature is almost continuous
from the tip of the crown to the base of the root. The distal cut-
ting edge is nearly straight. The root lobes intersect at an ob-
tuse angle, and as in the second anterior tooth, the distal root
lobe has the greatest development.
We identified three intermediate teeth: USNM 289088,
293762, and 312447 (Figure 24a-e). As in the anterior teeth,
these teeth are much higher than they are wide, but they are
smaller than the anterior and lateral teeth in our suite of speci-
mens. Their root lobes form an acute to right angle, and as in
the third upper anterior, their crowns have a distal curvature
and, in lateral view, a very pronounced labial curvature.
In the lower jaw, the anterior teeth possess toruses (lingual
protusion of the root) (Figure 24/) with a much greater devel-
opment than those of the lateral teeth. The first anterior tooth
has an erect crown, with the root lobes forming an acute or
right angle. In the second anterior tooth the erect crown has a
slight distal curvature; the root lobes form a right or obtuse an-
gle. In the third anterior tooth, which has a distally inclined
crown, the mesial root lobe is longer than the distal one.
In Parotodus, except for their size, the lateral teeth of both
jaws have hooked crowns very similar to those of two denti-
tions of an Isurus oxyrinchus in the Hubbell collection
FIGURE 23.—Parotodus benedenii, composite dentition, lingual view. (Scale bar= 1.0 cm.)
112
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 24.—Parotodus benedenii: a, USNM 289088, intermediate tooth, lingual view; b, USNM 293762, inter-
mediate tooth, lingual view; c, USNM 312447, second lower intermediate tooth, lingual view; d, same specimen,
lateral view; e, same specimen, labial view;/ USNM 457258, lower anterior tooth, lateral view showing devel-
opment of torus. (Scale bars: a,b= 1.0 cm; c-e=0.9 cm;/=0.5 cm.)
(D052188, MD62287). In both species the lower teeth are
more erect than the upper teeth.
Kemp (1991, pl. 32) noted and illustrated a specimen of this
species consisting of 30 detached teeth in matrix from the ear-
ly Miocene Batesford Limestone, Batesford, Australia, in-
cluding the upper and lower anteriors and two symphysial
teeth. The symphysial teeth appear to be from the upper and
lower jaws; the tooth in his fig. El,2 is more compressed than
the symphysial tooth in his fig. D; therefore, we concur with
Kemp's identification of them as upper and lower symphysial
teeth. We did not find any comparable teeth at Lee Creek
Mine. The presence of symphysial teeth in the Batesford spec-
NUMBER 90
113
imen may be the retention or reappearance of a primitive
character.
Davis (1888:26-27) described the species Oxyrhina von-
haastii from the Oligocene of New Zealand and included in his
type suite a mass of about 20 teeth in limestone. Although we
have not seen his type suite, we believe that this species should
be assigned to Parotodus, and it may be a junior synonym of P.
benedenii.
In the fall of 1992, Clyde Swindell and George Powell re-
covered an associated, partial dentition of this shark from Lee
Creek Mine (Kent and Powell, 1999). This dentition confirms
the presence of two upper anterior teeth. Until this specimen
can be compared with those from Australia and New Zealand,
we believe it is premature to assess the relationship of this spe-
cies to the Oligocene and early Miocene specimens and to oth-
er lamnids.
The anterior teeth of this shark range from 5.8 to 6.3 cm in
height (mean=6.2 cm, «=6) and from 3.7 to 5.0 cm in width
(mean=4.3 cm, «=6). Because their lateral and anterior teeth
are not well differentiated by tooth height, there is no living
lamnid that can be used as a model for estimating the total
length of Parotodus benedenii, but we guess that large adults
were between 6 and 7.5 m long.
Hatai, Masuda, and Noda (1974:19-20, pl. 2: figs. 20, 22)
described a new species, Isurus moniwaensis, from the Mi-
ocene of Japan; their type specimen is identical to specimens
identified herein as Parotodus benedenii.
Roux and Geistodoerfer (1988) reported the occurrence of
teeth of this species in the Pleistocene deposits in the Indian
Ocean off New Caledonia (see "Carcharodon megalodon
(Agassiz, 1835)," below, for further discussion).
Compagno (pers. comm., 14 Apr 1993) suggested that this
shark fed by grabbing prey, such as seabirds, porpoises, and
seals, with its teeth and swallowing it whole.
Genus Isurus Rafinesque, 1810
The teeth of Isurus have smooth cutting edges, have smooth
labial and lingual coronal faces, usually lack lateral cusplets,
and the central foramen usually does not open into a well-de-
fined transverse groove. In both jaws the teeth are differentiat-
ed into anteriors, intermediates (upper jaw only), laterals, and
posteriors. Espinosa-Arrubarrena (1987:26) gave the formula
for fossil and living makos as follows: (upper jaw) two anteri-
ors, one intermediate, five to seven laterals, three to four pos-
teriors; (lower jaw) three anteriors, five to seven laterals, three
to four posteriors. Of these tooth types, the anteriors are the
most important taxonomically; in the dentitions we have ex-
amined so far, they exhibit the least amount of variation within
a species.
Ontogenetic heterodonty occurs in the extant species of
Isurus. In individuals over 3 m TL, the teeth broaden and be-
come thinner, even in the lower laterals, which normally have
robust crowns, and the attitudes of the crowns may change
considerably, becoming strongly arched distally. Espinosa-
Arrubarrena (1987) noted that lateral cusplets occurred in the
lateral and posterior teeth of juveniles, but in the available ju-
venile dentitions of I. oxyrinchus (USNM 232652, TL=1901
mm?; USNM 232650, TL=1310 mm), Isurus paucus (USNM
196024, TL=1251 mm; USNM 196039, TL=1801 mm), and
in numerous juvenile /. xiphodon teeth, we did not observe
any lateral cusplets. Bass et al. (1975c:28), however, reported
that in large individuals of I. oxyrinchus, minute lateral cus-
plets occur on the distal shoulder of the more posterior lateral
teeth. To date no sexual heterodonty has been noted.
In the upper and lower jaws, differences in morphology ex-
ist between teeth of the same jaw positions. The upper teeth
have broader, thinner crowns, and their roots are not as well
developed as are their counterparts in the lower jaw. In the
lower teeth, in the area of the central foramen, the torus is
well developed; the greatest development of the torus occurs
in the lower first anterior tooth and diminishes in each succes-
sive tooth until it is not discernible in the second or third later-
al tooth.
Espinosa-Arrubarrena (1987:110-117) recognized three
groups of makos based on the elongate and cylindrical shape of
the crowns of the anterior teeth and on the lengths of the root
lobes of the upper anterior teeth. To facilitate discussion, we
call his groups the oxyrinchus-paucus group, the desori group,
and the hastalis group.
He defined the oxyrinchus-paucus group as containing spe-
cies with "small to medium-sized teeth, that have cylindrical to
slightly flattened and very narrow crowns in the upper anterior
teeth" (Espinosa-Arrubarrena, 1987:110-113). He subdivided
this group into three lineages: the /. oxyrinchus lineage, the /.
paucus lineage, and the /. sp. D-I. sp. E lineage. His /. oxyrin-
chus lineage is characterized by having anterior teeth "with
root branches that are unequally long [the mesial side is long-
er]." His second subgroup, the /. paucus lineage, is character-
ized by having "root branches that are equally long," and his
third subgroup, the /. sp. D-I. sp. E lineage, is characterized by
unequal root branches but with the distal branch longer than the
mesial one (Espinosa-Arrubarrena, 1987:113).
The desori group was defined as "isurid species with large
and very robust teeth that represent an intermediate stage be-
tween the narrow or cylindrical crowns of the uppers of group
one [oxyrinchus-paucus group] and the wide and totally flat-
tened upper teeth of the /. hastalis and /. planus lineages. The
species included in this category are /. desori, I. retroflexus,
and /. sp. F The upper anterior morphotypes in /. desori tend to
be unequal (longer mesial side [root lobes]), and in /. retroflex-
us and I. sp. F, the same elements tend to be equal in size" (Es-
pinosa-Arrubarrena, 1987:113-114).
Finally, his hastalis group was defined as "isurid species
with wide crowns and totally labiolingually flattened upper
teeth (triangular shaped crowns). The species groups of/.
hastalis and /. planus (with /. sp. G and /. sp. H respectively)
obviously represent the opposite end of the grasping-cutting se-
114
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
ries. These are teeth of very large size, the cylindrical (rounded
cross section) shape of the crown has been completely lost.
And the root branches of the upper anteriors are unequal in /.
hastalis and very symmetrical (mesial and distal sides of the
same size) in /. planus" (Espinosa-Arrubarrena,
1987:116-117). Espinosa-Arrubarrena and others have identi-
fied as I. hastalis teeth that Agassiz named / xiphodon, which
is not a junior synonym of I. hastalis (see below).
When we applied these characters to recent and Lee Creek
Mine specimens, we found the following exceptions to Espi-
nosa-Arrubarrena 's groupings. (1) In a dentition from a 3.9 m
TL female /. paucus (Hubbell collection, JG5379), the third up-
per left anterior tooth has a mesial root lobe that is longer than
the distal one. In another dentition from a 4 m TL female of the
same species (Hubbell collection, NA91690), in all of the teeth
except the upper intermediate and the third through fifth upper
laterals, the mesial root lobes are longer than the distal root
lobes. (2) In a dentition of a large /. oxyrinchus of over 3.7 m
TL (USNM 309253), the second upper anterior tooth has a dis-
tal root lobe that is longer than the mesial one. (3) In dentitions
of/, paucus from individuals of over 3.7 m TL, the anterior
teeth become broader and flatter, losing their cylindrical or
rounded cross section. Compared to /. paucus, in /. oxyrinchus
the compression of the anterior teeth occurs to a much lesser
degree in some individuals (USNM 309253), and no compres-
sion occurs in others (LJVC 901119). (4) The teeth in the type
suite for I. desori (Agassiz, 1843:282), in size and roundness of
cross section, can only be assigned to Espinosa-Arrubarrena's
oxyrinchus-paucus group. (5) The broadness and flatness of the
holotype of/, planus falls within the range of variation occur-
ring in the extant /. oxyrinchus and /. paucus, particularly in in-
dividuals of 3.7 m TL or more.
In summary, the lengths of the root lobes and the roundness
of the crowns of the anterior teeth in cross section are charac-
ters that vary within a species.
We believe, however, that there are three species of mako
sharks represented at Lee Creek Mine. Those with more flex-
uous, awl-like anterior teeth with a labial recurvature at the
tips we identify as /. oxyrinchus; those with less flexuous an-
terior teeth with more compressed crowns and with straight-
tipped lower anterior teeth we identify as /. hastalis; and
those with triangular, compressed upper anterior teeth with
tips that may become labially recurved as they become larger
and with straight-tipped lower anterior teeth we identify as /.
xiphodon.
Isurus oxyrinchus Rafinesque, 1810
Figures 25,26
Oxyrhina desori Agassiz, 1843:282, pl. 37: figs. 8, 9 [figs. 10-13 indetermi-
nate; lectotype: ETHG1 P145, selected herein; Miocene, Switzerland],—Ler-
iche, 1927:68, pl. 10: figs. 1-10 [Miocene, Switzerland].
Oxyrhina desori Gibbes, 1848-1849:203, pl. 27: figs. 169, 170 [Pliocene,
South Carolina].
HORIZON.—Pungo River Formation (units 1-5); Yorktown
Formation (units 1, 2).
REFERRED MATERIAL.—115 teeth, USNM 207619, 207620,
207622, 207626, 207628-207630, 279119, 279136,279155,
293736, 312442, 312443, 312448, 312449, 312452, 336759,
339897, 421619, 421884, 421983, 425494, 425502, 425558,
425851, 425856, 425862-425872, 452469, 452481, 452483,
452487, 452488, 452491, 452494^52497, 452499^152501,
452505-452507, 452510, 452512, 452514, 452530,
452541-452543, 452550, 452563, 452565, 452566,
452572-452574, 452579, 452583, 452612, 452620, 453142,
453146, 453147, 453152, 453153, 453156, 453158,
453160^153162, 453164, 453170, 453174, 453175, 453184,
454280, 454281, 454283, 454286, 454302-454304, 454336,
454355, 454358, 454360, 454378, 454383, 454385,
454387^154389, 474966^*74975, 476296.
REMARKS.—Agassiz (1843:282) characterized Oxyrhina
desori as follows: "Relative to their height, the teeth of our
Oxyrh. desori are much less broad than those of Oxyrh. hasta-
lis; moreover they are thicker and nearly semicylindrical; and
the cone of the tooth, instead of being straight, curves at first
a little to the outside in order to turn back next to the inside;
and when the tip, from its side, recurves in turn to the outside,
the profile of the tooth takes on a very wavy appearance,
which contrasts with the straight form and uniform bend to
the outside of Oxyrh. hastalis" (translated from French by
R.W.P.).
Except for two, the syntypes are indeterminate, and Gibbes
(1848-1849:203) related that Agassiz, subsequent to the pub-
lication of his opus, felt that /. desori was identical to Lamna
cuspidata. Gibbes, therefore, named a new species of fossil
mako as O. desori to preserve Agassiz's name; the three teeth
of his type suite are referable to Isurus oxyrinchus and /. xiph-
odon (Gibbes, 1848-1849, pl. 27 figs. 169, 170, and fig. 171,
respectively). Oxyrhina desori Gibbes, however, is a junior
homonym of Oxyrhina desori Agassiz, and it is unavailable
for use as a species name.
Leriche (1910) also considered the syntypes of Agassiz's
species to be indeterminate. Rather than abandon the name,
Leriche (1910, 1927) referred his own specimens to "Oxyrhi-
na desori" as identified by Sismonda (1849), which is pre-
sumably, but not necessarily, also referable to Oxyrhina des-
ori sensu stricto. Leriche's concept of this species, which is
based on teeth that are similar to those of/, paucus, has pre-
vailed until now even though, according to the rules of zoo-
logical nomenclature, his redefinition of the species was in-
valid.
Had Agassiz and Leriche been correct about the type suite
of O. desori, this species would be a nomen dubium and
would be unavailable as a species name; however, one of
Agassiz's syntypes is a diagnostic anterior tooth of Isurus. We
obtained casts of three of Agassiz's (1843) syntypes, the spec-
imens figured in his pl. 37: figs. 8-10. Of the three, the tooth
NUMBER 90
115
	»* "	^^^!?^|	%		«U*"-*	^^Sm	iu?^*^^^|
%              ^ »^1		¦       ^1		V	4	^ \	*
A      1 1	^*	v		\ ~	ol	A	
v ^		\			'		
	L	i	/	fc J	A	Ij	/-'-*,..
^ *	^ •		#	i 1	l^JM 1		
a —		#?	^	r	I	k	
. A	1 '•-.«	r	p	1 1	Vt «f/i	¦ <A	
		)	u	?	F ~ r	w«	
#P^							
							
FIGURE 25.—Isurus oxyrinchus: a, composite dentition, lingual view; b, USNM 312443, first lower anterior
tooth, lateral view; c, USNM 474966, second lower anterior tooth, lateral view; d, USNM 452530, second upper
anterior tooth, lateral view; e, USNM 453175, third upper anterior tooth, lateral view. (Scale bars: a,c-e= 1.0 cm;
A=0.5cm.)
in fig. 9 (ETHGI P145) is the second upper anterior of Isurus;
this specimen lacks lateral cusplets and lacks any indication
that they were ever present, and it possesses a sufficient por-
tion of the root to show the absence of a well-developed trans-
verse groove, which is present in odontaspids. Agassiz's fig. 8
also may be the same tooth of Isurus, but the tooth in fig. 10
and the teeth illustrated in figs. 11-13 are indeterminate. Be-
cause ETHGI P145 (Figure 26a-c) is the only tooth of the
type suite that can be definitely identified as Isurus, we desig-
nate this specimen the lectotype, and Oxyrhina desori is not a
nomen dubium.
Oxyrhina desori is, however, a junior synonym of Isurus
oxyrinchus Rafinesque, 1810. The morphology of the lecto-
type is identical to a right, upper second anterior tooth of al-
most equivalent size in the dentition of/, oxyrinchus (USNM
309253). The widths of the crowns and the development of
the distal cutting edges are the same in both. Therefore, we
place Oxyrhina desori Agassiz in synonymy with Isurus
oxyrinchus.
In the anterior teeth of/, oxyrinchus (Figure 25b-e), the tips
of the crowns usually exhibit a labial recurvature; this is more
noticeable in the upper anteriors. This recurvature also occurs
in the tips of the upper and lower lateral teeth, but it is not al-
ways present.
In the extant /. oxyrinchus, as in the Lee Creek Mine speci-
mens, the upper anterior teeth exhibit morphological variation.
The mesial cutting edge of the second upper anterior (first
tooth in jaw) is straight to strongly convex, whereas the distal
cutting edge may be gently sinuous to nearly straight. The root
lobes intersect at acute to obtuse angles, and their lateral ex-
tremities may be pointed to rounded.
In the third upper anterior tooth, as in the second upper ante-
rior, the mesial cutting edge is straight to strongly convex.
These strongly convex cutting edges may not form the usual
continuous arc with the mesial margin of the root. The root
lobes intersect at right to obtuse angles.
Intermediate teeth have distally hooked crowns, and the
root lobes are often pointed, with the basal margin of the root
arcuate.
The lower anterior teeth are more robust and are more flexu-
ous than those of similar-sized individuals of Isurus paucus
and /. hastalis, and in labial view, the roundness of the crown
foot obscures the definition of the mesial or distal (or both) cut-
ting edges; this condition also exists in the upper anteriors.
116
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
			fl			
p^H						
Hi   ¦ ¦1  •. M		1  ¦   v,a			Wwi j	
¦CH	BjHH		Be^mBB	F?l		El
FIGURE 26.—Isurus oxyrinchus, cast of ETHGI P145, lectotype oi Oxyrhina desori, USNM 476355: a, lingual
view; b, lateral view; c, labial view. Isurus oxyrinchus: d, USNM 452483, first lower anterior tooth with elongate
root lobes, lingual view; e, USNM 312448, lower lateral tooth with mesial cusplet, labial view;/ USNM
476296, lower lateral tooth with broad lateral cusplets, labial view; g, USNM uncataloged, lower lateral tooth
from extant species with lateral cusplets, labial view. (Scale bars= 1.0 cm.)
These anterior teeth incline distally. In one dentition (Hubbell
collection, 11191), plications are present on the labial crown
feet of the lower anterior teeth. Like /. hastalis but unlike /. xi-
phodon, the teeth usually have elongate root lobes (Figure
26d), particularly in the first and second anterior teeth, that
taper to a point, but they also may be rounded.
Garrick (1967:679) noted that in juveniles and small adults,
the distal cutting edge of the second upper anterior and the
first lower anterior teeth are incomplete. In larger adults these
cutting edges are complete.
In the lateral teeth of the extant species (Figure 26g), the
crowns are erect to strongly hooked. Often the enameloid
does not extend down to the basal margin of the crown foot,
giving the crown foot a dull appearance. Ridges may be
present on the labial crown feet. In large adults, the crowns
become very thin. The root lobes are angular to lobate. On the
lingual surface a shallow transverse groove may occur, which
also occurs in anterior teeth.
In addition to the above morphological variations, we note
the following. In the first lower anterior tooth (USNM 452483,
height of tooth=46.0 mm, labial height of root=20.2 mm), the
root lobes are longer than those of a larger first anterior of the
extant species (Compagno collection, LJVC-901119, height of
tooth=50.8 mm, labial height ofroot=19.8 mm). Also, two lat-
eral teeth exhibit a pair of broad, low, rounded lateral cusplets
(USNM 312448, 476296, Figure 26c/).
Anterior teeth from the Pungo River Formation ranged from
2.7 to 5.0 cm in height (mean=3.8 cm, 77 = 8) and from 1.7 to
2.9 cm in width (mean = 2.2 cm). Anterior teeth from the
Yorktown Formation ranged from 2.8 to 5.8 cm in height
(mean = 3.9 cm, « = 50) and from 1.1 to 3.2 cm in width
(mean=2.2 cm). On the basis of measurements of teeth from
extant sharks of this species of known size, the shortfinned
makos of the Pungo River and Yorktown seas ranged in size
from 2.4 to 4.6 m TL.
The extant shortfin mako shark (Compagno, 1984:243) is
common in coastal and oceanic waters in warm-temperate and
tropical seas. It feeds on a wide variety of bony fishes, includ-
ing tunas, bonitos, carangids, sea basses, porgies, and sword-
fish, and on other sharks, sea turtles, and, occasionally, ma-
rine mammals.
Isurus hastalis (Agassiz, 1838)
Figures 27, 28o-c
Oxyrhina hastalis Agassiz, 1838: pl. 34: figs. 3, 5, 13, 16, 17; 1843:277 [figs.
4, 7-10, 12, 15, indeterminate; early Miocene, Switzerland].—Leriche,
1926:399, pl. 31: figs. 3,4, 7, 8, 11, 12,20-23; 1927:71, pl. 11: figs. 1-3,5-7
[not fig. 4; early Miocene, Switzerland]; 1942:69-71, pl. 5: figs. 11-20 [Cal-
vert Formation, Maryland].
Oxyrhina xiphodon Agassiz, 1838, atlas volume 3, pl. 33: figs. 11, 12.
NUMBER 90
117
HORIZON.—Pungo River Formation (units 1-5); Yorktown
Formation (units 1-3).
Referred Material.—About 500 teeth, USNM
207632-207635, 278592, 281043, 293598, 293610, 293705,
336748, 336750, 336761, 421883, 421885, 425491, 425553,
425644, 425857, 425858, 425860, 425861, 425873-425880,
437446, 452431, 452468, 452482, 452484-452486, 452489,
452498, 452503, 452504, 452508, 452511, 452513, 452515,
452516, 452518-452529, 452532-452540, 452544^152549,
452551-452556, 452561-452564, 452578, 452580, 452582,
452591-452593, 452596, 452598, 452601, 452602,
452604-452607, 452609-452611, 452613, 452614,
452616-452622, 452625, 452626, 452628-452631, 452634,
452635, 452638-452640, 453140, 453141, 453143, 453145,
453149, 453153, 453155, 453159, 453165-453171, 453173,
453176-453183, 453185-453187, 454284, 454285,
454287-454289, 454314-454321, 454324, 454326, 454335,
454337-454339, 454342-454344, 454349^154354, 454356,
454357, 454359, 454361-454363, 454366, 454369,
454374^154377, 454379, 454380, 454382, 454393, 454520,
474976-474993.
Remarks.—Agassiz's type suite (1838, pl. 34: figs. 3-13,
15-17) consists of mainly upper anterior teeth; his fig. 3 is a
lower lateral, and his figs. 4 (UNIG 240), 5 (UNIG 243), and 7
are upper laterals. Although most of his remaining specimens
are incomplete, the size and the broadness of the crowns sug-
gest that they are all mako teeth. With the possible exceptions
of the specimens in his figs. 6 and 11 (UNIG 244), these upper
teeth all appear to belong to the same species. Agassiz
(1843:277) characterized them as "teeth with rather great stat-
ure, elongated and in the form of a lance." The tips of the upper
anterior teeth in the type suite exhibit a strong labial curvature,
a character that we believe is taxonomically significant (see be-
low). Of Agassiz's syntypes, the specimen in his fig. 16, if it is
still in the collections of the Universitat Neuchatel, should be
declared the lectotype for this species.
In morphology, the teeth of Isurus hastalis (Figure 27) are
almost identical to those from large individuals (TL=3.7-4.3
m) of/, paucus. The tips of the upper anterior teeth of the latter
species, however (TL=2.3^1.2 m, n=9), usually lack the labial
recurvature that is so well developed in /. hastalis (Figure 28a).
In the small number of/, paucus dentitions available to us
(n=9), only one dentition (Hubbell collection, JF91980, 2.6 m
TL, female) had upper anterior teeth with tips that exhibited a
strong labial recurvature. At present, we do not know how
common this recurvature is in the extant species.
The upper anterior teeth of Leriche's (1910:275-280, figs.
78-86, pl. 16: figs. 16-31) sample of teeth from the Oligocene
of Belgium, which he identified as Oxyrhina desori and O. des-
ori flandrica, are identical to those of the extant Isurus paucus.
They lack a labial recurvature. This suggests that /. paucus may
be a junior synonym of/, hastalis, but because of the small
number of dentitions available of/ paucus, we hesitate in syn-
onymizing the two species.
In / hastalis and / paucus, the cutting edges of the anterior
teeth are sharply defined to the base of the crown. The lower
anterior teeth of these two species are difficult to distinguish,
but in /. paucus the more prominent development of the lingual
torus of the roots may prove to be a useful character; although
its consistent occurrence in a large sample of this species can-
not yet be determined. In /. hastalis the mesial cutting edges of
the lower anterior teeth are convex, whereas they are straight in
/. xiphodon, and the root lobes, particularly in the first anterior
tooth, are more elongate and are not as massive as those of/.
xiphodon.
FIGURE 27.—Isurus hastalis, composite right dentition, lingual view. (Scale bar= 1.0 cm.)
118
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 28.—Isurus hastalis: a, USNM 452545, second upper anterior tooth, lateral view showing labial recurva-
ture; b, USNM 454285, first lower anterior tooth, lingual view showing rounded torus with transverse groove; c,
IG 27385, lower Miocene, Antwerp, Belgium, close-up of serrated cutting edge. Isurus xiphodon: d, USNM
476356, Yorktown Formation, unit 4, close-up of mesial cutting edge with incipient serrations; e, USNM 457248,
first upper lateral tooth, lingual view showing ear-like structures on root;/ USNM 457251, lower lateral tooth,
lingual view showing transverse groove on root. (Scale bars: a,b= 1.0 cm; c/=0.33 cm; d=0.25 cm; e=0.5 cm.)
NUMBER 90
119
Unlike Isurus oxyrinchus, the upper and lower lateral teeth
of /. hastalis have tips that lack the labial recurvature. Their
crowns are usually broader than those of I. oxyrinchus, but the
upper lateral teeth are not as broad as those of/, xiphodon. The
lower lateral teeth are asymmetrical and are broader than those
of/, xiphodon.
One morphological variation in the teeth of/, hastalis should
be mentioned. In a first lower anterior tooth (USNM 454285),
the torus of the root is bisected by a broadly rounded transverse
groove (Figure 28b).
Isurus hastalis is the most common mako at Lee Creek
Mine. The anterior teeth from the Pungo River Formation
range from 2.3 to 5.2 cm in height (mean=4.1 cm, n-58) and
from 1.3 to 3.8 cm in width (mean=2.6 cm, «=58). Those from
the Yorktown Formation range from 1.7 to 5.7 cm in height
(mean=4.1 cm, « = 76) and from 1.1 to 3.8 cm in width
(mean=2.6 cm, n=75). Anterior teeth within these size ranges
in the extant /. paucus are found in individuals of 1.8 to 4.6 m
TL.
Recently, dentitions from both species of extant makos over
3.7 m TL became available for study. Dental characters used to
identify / retroflexa also occur in these dentitions. The com-
pressed tooth crown that Agassiz (1843:281) said distinguished
/. retroflexa from all other species of Isurus is found in /. ox-
yrinchus (USNM 309253) and in /. paucus (Hubbell collection,
JG5379). In a dentition from an /. paucus of 3.9 m, the com-
pressed upper and lower teeth have rounded tips identical to
those identified by Leriche (1926, 1927) and Cappetta (1970,
pl. 6: fig. 1) as /. retroflexa. Agassiz's holotype and only speci-
men of/, retroflexa, an incomplete lower lateral with a rounded
tip, lacks the labial recurvature that usually occurs in /. oxyrin-
chus. The nature of this specimen does not permit its assign-
ment with confidence to /. hastalis, I. oxyrinchus, or /. paucus;
therefore, we consider /. retroflexa a nomen dubium.
Isurus xiphodon (Agassiz, 1838)
Figures 28^-/29-31
Oxyrhina trigonodon Agassiz,   1843:279, pl.  37:  figs.   17,  18  [Neogene,
Germany].
Oxyrhinaplicatilis Agassiz, 1843:279, pl. 37: figs. 14, 15 [Neogene, Italy].
Oxyrhina crassa Agassiz, 1843:283, pl. 37: fig. 16.
Oxyrhina desori Gibbes, 1848-1849:203, fig. 171 [Pliocene, South Carolina].
Anotodus agassizii Le Hon, 1871:8-9 [Neogene, Belgium],
Oxyrhina hastalis Agassiz.—Leriche, 1926, pl. 31: figs. 5, 6, 9, 10, 13-19, 24,
26-30 [Neogene, Belgium].
Isurus hastalis (Agassiz).—Menesini, 1969:15-17, pl. 2: figs. 1-3,5,9, 11, 12.
HORIZON.—Yorktown Formation (units 1, 2).
Referred Material.—About 400 teeth, USNM 278765,
278766,278771, 278774, 278792, 278799, 278801, 278814,
279059, 279060, 279062, 279188, 279200, 279963, 279964,
279967, 287485, 287694, 293599, 293609, 293710,293713,
293714,302447, 312646, 324933, 336738, 336739, 336746,
421613, 421618, 421769-421772, 421776, 421777,
421910-421913, 421916, 421923, 421977, 425592, 425854,
425859, 437443, 437444, 437447, 452557, 452571, 452576,
452577, 452927-452930, 452937, 452945, 452946,
452948-452950, 452955, 453144, 453150, 453157, 454307,
454313, 454325, 454345, 454347, 454348, 454364, 454368,
454370,454371, 457245-457251, 474918, 474919, 476356,
476416-476422, 482198^182211, 482214, 482218, 482219,
482221.
Revised Diagnosis.—Upper anterior and lateral teeth
broad, triangular; juvenile teeth like those of adults in form;
FIGURE 29.—Isurus xiphodon, composite dentition of an adult, lingual view. (Scale bar= 1.0 cm.)
120
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Figure 30.—hums xiphodon, composite dentition of a juvenile, lingual view. (Scale bar=1.0cm.)
lower teeth with erect crowns; lower anterior teeth with short,
massive root lobes.
Remarks.—Agassiz (1843:278) separated this species from
Isurus hastalis on the basis of a "noticeable flattening" of the
lingual crown foot. This flattening, however, is not always
present, and it is insignificant taxonomically. The broadness of
the teeth of/, xiphodon, a character that Agassiz (1843:278)
believed was too vague, does, however, separate the two spe-
cies.
Two of the seven specimens in the type suite for /. xiphodon
(Agassiz, 1838, pl. 33: figs. 11, 12) are teeth of/, hastalis. The
remainder of the specimens, figured in pl. 33: figs. 14—17, are
broad, triangular, upper-jaw teeth of/, xiphodon. The speci-
mens in figs. 16 and 17 are anterior teeth, but only the speci-
men in fig. 17 is complete. If this specimen (listed by Agassiz
as in the collection of "Mr. Bronn") still exists, it should be
designated the lectotype of this species.
Agassiz attributed two upper teeth and one lower tooth of
this mako to three different species, Oxyrhina trigonodon, O.
plicatilis, and O. crassa, respectively. Lawley (1878), on the
basis of 140 associated teeth from the Pliocene of Tuscany,
synonymized Agassiz's species, which were based on upper
teeth, with Le Hon's newly described A. agassizi. Leriche
(1926) synonymized O. trigonodon, O. plicatilis, and O. cras-
sa with what he believed was the same species as the senior
name, /. hastalis.
Lawley (1878, pl. 5: fig. 1) reconstructed from 140 associat-
ed teeth the first dentition of this species, but the upper anterior
teeth are from the opposite jaw; their tips are pointing in the
wrong direction, and the positions of the first and second lower
anterior teeth are reversed.
Based on unassociated teeth from the Neogene of Belgium,
Leriche (1926, pis. 31, 32) published the first accurate recon-
struction of this dentition, but he considered the broad, triangu-
lar teeth to be those of an old individual of/, hastalis. Because,
however, the general form of the upper and lower teeth of juve-
niles and young adults of /. xiphodon are identical to those of
large adults (Figures 29, 30), /. xiphodon cannot be synony-
mized with / hastalis.
In addition to the above illustrated specimens, two associated
dentitions were available to us, one nearly complete, from the
Pisco Formation of Peru, and the other consisting of 27 teeth,
including the anteriors, from the Calvert Formation of Mary-
land. Our reconstructions (Figures 29, 30) are based on these
specimens.
The upper teeth have broad, triangular crowns that become
more asymmetrical toward the corners of the mouth. Unlike
any other species of mako, the upper anterior teeth have very
broad, flattened crowns. In the second upper anterior tooth,
which is the first tooth from the symphysis, the crown is usu-
ally asymmetrical, with a broadly convex mesial cutting edge
and a concave distal cutting edge. The angle of the root lobes
is smaller in the second upper anterior tooth, and the root
lobes are almost equal in size. The crown is more asymmetri-
cal in the third upper anterior tooth than in the second tooth,
and the mesial root lobe is longer than the distal root lobe. In
the morphology of the crown and in the angle of the root
lobes, the intermediate tooth of our reconstruction compares
NUMBER 90
121
favorably with the form of those of other mako species. Its
crown is erect, and it has a strong labial curvature. In the lat-
eral teeth the mesial and distal root lobes form nearly a 180°
angle.
The lower teeth have erect crowns that in labial or lingual
view appear almost symmetrical. Unlike those in other species
of mako, the lower anterior teeth exhibit very little distal curva-
ture or labiolingual sinuosity. (Note that in our reconstruction
(Figure 29), the undersized first and third anterior teeth were
the only ones available to us for these tooth positions). In all
the lower teeth, unlike in /. oxyrinchus, the tips are straight,
which suggests that /. xiphodon is more closely related to /
paucus. As in the extant makos, the lower teeth of this mako
often have compressed crowns; paleontologists often identify
these as /. retroflexa.
In teeth identified as Isurus hastalis, from the late Miocene
of Peru, Muizon and De Vries (1985:553-555) noticed that
incipient to very fine serrations were present on the cutting
edges, the latter type coming from youngest beds of the late
Miocene. They interpreted this occurrence as documenting a
transition from this species to Carcharodon carcharias,
which is abundant in the early Pliocene. Carcharodon car-
charias teeth, however, occur in the middle Miocene of Mary-
land, and white-shark teeth that may be from ancestors of C.
carcharias were collected in older Tertiary sediments (Purdy,
1996:69). Does the Peruvian record represent a transition? We
think not.
Serrations do occur in different mako species groups. Agas-
siz (1843) first noticed mako-type teeth with very fine serra-
tions. His syntypes of Carcharodon escheri from the middle
Miocene of Switzerland, an upper and a lower lateral tooth,
compare more favorably with those of Isurus oxyrinchus than
they do with those of/, xiphodon. In labial or lingual view the
crown of the lower lateral tooth has a distal curvature, and the
coronal tip exhibits a labial recurvature, which is characteristic
of the lower laterals of I. oxyrinchus. The crown of the upper
lateral syntype is characteristic of both /. oxyrinchus and /.
paucus, but the tip of its crown also exhibits a labial recurva-
ture, which is characteristic of the former species. Carcharo-
don escheri, therefore, is not a species intermediate between /.
xiphodon and C. carcharias.
The teeth identified by Leriche (1926:409, pl. 33: figs. 1-8)
as Isurus hastalis escheri from the early Miocene of Antwerp
are teeth of/, xiphodon (his figs. 3, 6, 8) and /. hastalis (his
figs. 1, 2, 4, 5). Figure 28c shows the partially serrated edges of
the tooth in Leriche's fig. 5 and another tooth, a second upper
anterior, both cataloged as IG 27385. Serrations, therefore,
may appear in any of the three mako groups, and they are not
useful for establishing phylogenetic relationships.
From the matrix of Gibson's (1967, 1983) zone 4 of the
Yorktown Formation (Rushmere Member), one of us (J.H.M.)
collected a tooth (USNM 476356) of I. xiphodon on which the
basal third of the distal cutting edge bears incipient serrations
(see Figure 28d).
Although the forms of Isurus xiphodon and Carcharodon
carcharias are similar, differences exist between them to sug-
gest that the former did not give rise to the latter. First, in /. xi-
phodon, the juvenile lower first anterior teeth possess root
lobes of equal length (Figure 30), and the angle formed by
them is acute; this character is present in seven of the teeth
present in the USNM collections. In the same teeth in juvenile
Carcharodon carcharias, however, the mesial root lobe is
longer, and the angle between the root lobes is obtuse (Figure
33a). In juvenile dentitions in the Compagno and Hubbell col-
lections, these two characters are consistent in teeth of C. car-
charias. Second, unlike C carcharias, which exhibits strong
ontogenetic heterodonty, ontogenetic heterodonty was weak or
absent in /. xiphodon. Third, unlike Carcharodon, in the two
associated dentitions of I. xiphodon available to us, the second
lower anterior is the largest tooth in the anterior series. The
heights of the anterior teeth are as follows.
Second lower anterior tooth         Second upper anterior tooth
CMM V-245
Hubbell/Peru
6.6 cm
6.0 cm
6.3 cm
5.8 cm
Finally, in his comparative analysis of mitochondrial DNA se-
quences of the Lamnidae, Martin (1996:52) estimated that the
time of origin of Carcharodon occurred perhaps in the Pale-
ocene or early Eocene; this estimate is supported by the fossil
evidence (Purdy 1996:69).
In view of the above, we cannot agree with Casier (1960),
Cappetta (1987), and Muizon and De Vries (1985) that Car-
charodon carcharias evolved from /. hastalis (herein identified
as /. xiphodon). We believe that the similar tooth morphologies
of these two species are due to parallel evolution rather than to
a direct phylogenetic relationship.
Several teeth from Lee Creek Mine exhibit morphological
variations worth mentioning. Below the basal margin of the
crown on the lingual face, ear-like structures occur on the roots
of four upper teeth (USNM 454345, 457245, 457248, 457250)
at their mesial and distal extremities (Figure 28e). In two lower
teeth the roots appear swollen (USNM 457247, 457249; Figure
2>\b), and one of these, USNM 457247, has the appearance of
buttocks, with a broad transverse groove. Another lower tooth,
USNM 457251, the root of which is not swollen, has a deep
transverse groove that is offset from the center of the lingual
face of the root and which extends to the basal margin of the
root (Figure 28/).
Although the teeth of this species have been recovered from
the Calvert Formation (middle Miocene), we did not find them
in the Pungo River Formation. We suspect that this may be due
to the absence or rarity of pinnipeds and cetotheres in the Pun-
go River sea.
In Figure 3lc-e, several examples of pathologic teeth are
shown. One of them, USNM 457246, exhibits the same con-
striction of the crown that Uyeno and Hasegawa (1974:258)
used to diagnose a new species, Carcharodon akitaensis. Caus-
es of tooth pathologies in mako sharks are not yet known.
122
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
v&r-"*-%

FIGURE 31— Isurus xiphodon: a, USNM 278799, lingual view of right upper lateral tooth with swollen root; b,
USNM 457247, lower lateral tooth with swollen root, lingual view; c, USNM 457246, pathologic upper lateral
tooth, lingual view; d, USNM 474918, pathologic upper lateral tooth, lingual view; e, USNM 474919, pathologic
upper lateral tooth, lingual view. (Scale bars= 1.0 cm.)
NUMBER 90
123
The anterior teeth of this species range from 2.5 to 8.1 cm in
height (mean=4.1 cm, «=46) and from 1.7 to 5.5 cm in width
(mean=3.2 cm, «=46).
We thought we could use the relationship between tooth size
and total length in Carcharodon carcharias to estimate the size
of/, xiphodon. In the extant species, however, we discovered
that in individuals of nearly the same size, the anterior teeth of
Isurus are greater in height than those of Carcharodon; the
teeth of a 3.96 m TL /. oxyrinchus (Compagno collection,
LJVC-901119) are equivalent in height to those of a 5.2 m TL
Carcharodon carcharias (Hubbell collection, XI1384A).
Therefore, on the basis of these data, we estimate that /. xiph-
odon at Lee Creek attained 6 to 7.6 m TL.
In one specimen of Callophoca obscura Van Beneden from
the Yorktown Formation of Lee Creek Mine, USNM 467592,
the distal portion of a right humerus exhibits long, straight, un-
serrated bite marks (Figure 31 b), inflicted most likely by /. xi-
phodon. Could this shark have had a dietary preference for
warm-water phocid seals?
Lamna sp.
FIGURE 32
HORIZON.—Yorktown Formation (?unit 1).
Referred Material.—6 rostral nodes, USNM
474994^174999.
REMARKS.—Six rostral nodes collected from the spoil piles
at Lee Creek Mine compare favorably with those of Lamna dit-
ropis (Matsubara, 1955:115, fig. 15A-C; Compagno, 1988:69,
fig. 7.1 A) and L. nasus (Parker, 1887, pl. 4: fig. 4, pl. 5: fig. 11;
Garman, 1913, pl. 62). Concerning the Lee Creek Mine speci-
mens, Compagno (pers. comm., 1982) stated that the calcifica-
tion of these rostra is more characteristic of Lamna ditropis
than of L. nasus, and that L. nasus has rostral cartilage less ex-
tremely developed than that of L. ditropis. Figure 32a shows
the hypercalcified development of the rostrum in L. ditropis
(USNM 313874); comparable specimens of L. nasus were not
available to us. Therefore, we are reluctant to make a specific
identification of these specimens at this time.
In more than 20 years of collecting at Lee Creek Mine, we
have seen no teeth that can be identified definitely as Lamna,
and in this time only six rostral nodes were found. Thus, this
species is one of the rarest to occur here.
In comparison to carcharhiniform calcified rostra (Figure
61a-a"), the only other group with tripodal rostra (Compagno,
1988:48), those of Lamna have dorsolateral rostral cartilages
that, in dorsal view, attach to the anterior rostral node at a very
acute angle rather than at a wide angle as in those of the car-
charhiniform sharks, and on the dorsal surface of the rostral
node, there is no median groove or fossa. These rostral nodes
range in size (lateral width) from 1.9 to 3.6 cm.
The extant species of Lamna inhabit shallow to epipelagic,
cold waters and feed on schooling fishes (Compagno,
1984:247-249).
Genus Carcharodon Smith in Miiller and Henle, 1838
Carcharocles Jordan and Hannibal, 1923:56.
Procarcharodon Casier, 1960:13.
Palaeocarcharodon Casier, 1960:13.
Megaselachus Glikman, 1964:231.
Until recently, the genus Carcharodon included C. carchar-
ias, the extant great white shark; C. orientalis, a small Pale-
ocene species; and the group of very large white sharks, the gi-
ant-toothed species C. auriculatus, C. angustidens, and C.
megalodon. The apparent absence of small-toothed species of
Carcharodon from the end of the Paleocene to the middle Mi-
ocene suggested to Casier (1960) that the giant-toothed species
and the extant species had separate origins in the Tertiary, and
the origin of the extant species from C. megalodon did not
seem plausible. He concluded that the C. auriculatus-C. mega-
lodon line was not related to C carcharias; therefore, he erect-
ed the genus Procarcharodon (type species Carcharodon an-
gustidens Agassiz, 1835, Oligocene of Europe) for these large
sharks with finely serrated teeth and the genus Palaeocarchar-
odon for the Paleocene species with coarsely serrated teeth.
Casier (1960:13) characterized Procarcharodon as follows:
"Teeth large and broad slightly compressed, with margins gen-
erally regularly serrated, sometimes pectinate; with denticles
present in the Eocene and the Oligocene, disappearing as a rule
in later forms. Root well developed." His reason, however, for
erecting these genera, the absence of small-toothed species in
the middle Tertiary, was based on an inadequately sampled and
biased fossil record.
In his scenario for the evolution of these forms, Casier con-
sidered the two most important characters to be the loss of lat-
eral denticles and the appearance of marginal serrations. He
stated (1960:15), "In their evolution one is assisted thus by the
appearance, several times, of [these] two dental characters fol-
lowing in succession__1. In the branch of Palaeocarcharo-
don, where it [the appearance of marginal serrations] does not
accompany the disappearance, nor even reduction of denticles;
2. in those of Procarcharodon, where it accompanies the loss
of denticles, but only secondarily (the appearance of marginal
serrations has preceded, in this case, the disappearance of later-
al denticles); [and] 3. in the branch of Carcharodon s. str.,
where the appearance of marginal serrations has, on the con-
trary, been preceded by the loss of lateral denticles (already lost
even in the ancestral form: Oxyrhina hastalis)."
Casier believed that two species, Otodus obliquus subserra-
tus Agassiz and Isurus hastalis escheri (Agassiz), confirmed
this hypothesis. The teeth of these species exhibit incipient
marginal serrations, and both occur prior to the appearance in
the fossil record of C. auriculatus and C. carcharias. Casier
surmised, therefore, that these earlier species represented tran-
sitional forms, O. o. subserratus to Carcharodon auriculatus
and /. h. escheri to C. carcharias.
Both of Casier's characters, however, occur widely in the ga-
leomorph sharks. Applegate (1967:49) and Compagno
(1988:28) reported that serrations have evolved several times
in sharks (Paleozoic cladodonts, hexanchoids, squaloids, lam-
124
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 32.—Lamna ditropis: a, USNM 313874, extant species with calcified rostral node. Lamna sp.: b, USNM
474998, rostral node, lateral view; c, same specimen, ventral view. (Scale bars: a=2.0 cm; b,c=\.0 cm.)
NUMBER 90
125
noids, and carcharhinoids), and Compagno suggested that they
may have evolved at least three times in the Carcharhiniformes.
Likewise, among the lamnoid and carcharhinoid sharks, the
loss of lateral cusplets represents a general evolutionary trend.
Therefore, neither character can be used with confidence for
developing phylogenetic scenarios.
In 1969 Janvier and Welcomme reviewed the phylogeny of
these sharks. They restricted the definition of Procarcharodon,
with no documentation for this change, to include only the
Eocene Carcharodon angustidens, but they placed the Oli-
gocene form of this species back in the genus Carcharodon.
Casier's concept of the genus Procarcharodon was chal-
lenged by Glikman (1964), who found a greater resemblance
between Otodus obliquus Agassiz and Carcharodon auricula-
tus and C. angustidens (teeth with lateral cusplets) than be-
tween the latter two species and C. megalodon. Glikman
(1964:231) proposed to include C. auriculatus and C. angus-
tidens in Otodus and characterized the teeth as "smooth mar-
gined in Paleocene forms, sometimes serrate on the upper jaw
of early Eocene forms and serrate on both jaws from the middle
Eocene onwards. Neck well developed in the anterior and ante-
rolateral teeth only. One pair of large accessory denticles." For
teeth without lateral cusplets, he created the genus Megasela-
chus, type species C. megalodon Agassiz, characterized by
having "all teeth with serrate crowns; neck well developed;
[and] most teeth without accessory denticles" (Glikman,
1964:231). Well-developed neck areas also occur in the teeth
of Cretoxrhina mantelli, Parotodus benedenii, Carcharhinus
leucas, C. longimanus, Carcharodon orientalis, C. auriculatus,
C. angustidens, C subauriculatus, and, in a lesser degree of
development, in the juvenile teeth of C. carcharias (see be-
low). Accessory denticles occur in the juvenile teeth of C. meg-
alodon and C. carcharias and may be retained in the teeth of
adults. Glikman's characters are not useful for establishing the
generic identity of these sharks.
We believe Glikman's inclusion of Carcharodon auricula-
tus (sensu lato) and C. angustidens in Otodus is unjustified.
From a large suite of Otodus obliquus teeth from Morocco,
one of us (R.W.P.) reconstructed a dentition of this shark and
identified three upper anterior tooth positions, as opposed to
two in Carcharodon. Also, unlike Carcharodon (including
the giant-toothed species), the third lower anterior tooth
points distally. A cast of a newly discovered associated denti-
tion of this shark (Hubbell collection, uncataloged) from the
Moroccan Eocene confirmed the presence of the first upper
anterior tooth. In this dentition, one of us (R.W.P.) identified
an intermediate tooth that points distally. This orientation is
opposite to that found in Carcharodon, including the giant-
toothed line. Rather than decreasing perceptibly in size, step
fashion, as in Carcharodon, the second through sixth upper
lateral teeth have similar heights, as they do in Lamna. Final-
ly, the second lower anterior tooth is the largest tooth in the
dentition. These characters of Otodus suggest that there is a
greater morphological difference between teeth of Otodus and
Carcharodon than has been assumed by previous workers,
and that Otodus is not the ancestor of Carcharodon.
Jordan and Hannibal (1923:56) created the genus Carcharo-
cles with Carcharodon auriculatus (Blainville) as the type spe-
cies, characterizing it as follows: "[Teeth] similar to Carcharo-
don, but with a strong denticle on each side on the base of the
tooth. Teeth narrower and more erect than in Carcharodon,
their edges finely serrated." These characters also occur in an
associated dentition that we identify as Carcharodon subauric-
ulatus and in some juvenile teeth of C megalodon. Until re-
cently, Jordan and Hannibal's genus was largely assumed to be
a junior synonym of Carcharodon.
Finally, Cappetta (1987) synonymized Procarcharodon
Casier (1960) and Megaselachus Glikman (1964) with Car-
charocles Jordan and Hannibal (1923), which of these three is
the senior name.
In two sets of associated teeth from the Rupelian of Bel-
gium, Siverson (1989) observed two additional characters for
separating Carcharocles from Carcharodon: the absence of
dignathic heterodonty and the absence of an intermediate
tooth. Dignathic heterodonty, however, is present in Carchar-
odon auriculatus (see Dockery and Manning, 1986, pis. 2, 3),
and it is very marked in the associated tooth sets from Lee
Creek Mine (see below), which are from young individuals of
Carcharodon subauriculatus. Like C. carcharias, dignathic
heterodonty in the giant-toothed line becomes less marked in
older individuals.
In extant Carcharodon the intermediate teeth are highly
variable in size and morphology (morphological variation is
particularly evident in juveniles); they can range in height
from about one-half to almost equal the height of the teeth in
the adjacent tooth positions. Agassiz (1835, pl. F, 1843:91)
and Leriche (1910:287, footnote 3, fig. 89) figured and de-
scribed dentitions of C. carcharias with intermediate teeth the
same size or almost the same size as the teeth of adjacent
files. The form of the crown may range from being like that of
a lower lateral tooth to like that of a broad, upper anterior
tooth. Two characters, however, are consistent: the distal cut-
ting edge is longer than the mesial one, causing the tip of the
tooth to be erect or to point mesially rather than distally as in
the lateral teeth, and the tooth has a strong labial curvature,
stronger than any other tooth in the jaw. Uyeno et al.'s (1989,
fig. 4) associated dentition shows the crown orientations of
the teeth from the upper right jaw. Their tooth number three,
which also is the position in the jaw of the intermediate tooth,
has a tip that bends mesially. In their pl. 4, it also has a strong
labial curvature. This tooth is undoubtedly an intermediate
tooth (Gottfried et al., 1996, independently identified this
character of the intermediate tooth as a synapomorphy for the
genus Carcharodon). Also, in the associated tooth sets of C.
subauriculatus, based on the above characters, we identified
teeth that we are certain are intermediates. In detached tooth
sets, these teeth may be mistaken for lower lateral teeth. In the
Belgian specimens, the intermediate teeth may be absent or
misidentified.
126
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Several researchers have expressed opinions contrary to
those of the above workers, synonymizing the genera of Casier,
Glikman, Jordan, and Hannibal with Carcharodon. Keyes
(1972:239-240) disputed Casier's erection of Procarcharodon
for the large-toothed species of these sharks and the derivation
of C. carcharias from Isurus hastalis, but he did not document
his position.
Welton and Zinsmeister (1980:7) also questioned Casier's
interpretations: "We do not find Casier's interpretations con-
vincing, and we agree with Keyes (1972) that the similarities
between / hastalis and Carcharodon (in the restricted sense of
Casier 1960) might be convergence rather than phylogenetic
relationship. The phylogeny of Carcharodon is best interpreted
through detailed analysis of tooth morphology and dental for-
mulae using specimens collected only under conditions of de-
monstrable superpositional control. A detailed study of ontoge-
netic heterodonty in the living C. carcharias and Isurus spp.
would be extremely useful in resolving these problems."
In 1983 Bendix-Almgreen stated that the structure of the
coronoi'n fibrous architecture of Carcharodon carcharias and
C. megalodon was too similar to be of divergent origins, and on
the basis of this character, he synonymized Procarcharodon
with Carcharodon. He did not, however, compare the coronoi'n
of these sharks with that in the teeth of other lamnoids, and the
usefulness of the coronoi'n fibrous architecture as a taxonomic
tool for neoselachians has yet to be demonstrated.
Uyeno and Sakamoto (1984:52) noted the similarity between
the juvenile teeth, particularly the serrations, of Carcharodon
megalodon from the middle Miocene sediments in the Chichi-
bu Basin, Japan, and those of C. carcharias. Although they did
not elaborate on them, they found that the characters used to
identify Procarcharodon also occur in Carcharodon carchar-
ias. They reiterated Welton and Zinsmeister's (1980) call for
an extensive study of recent and fossil Carcharodon teeth to
help to resolve the problem.
In their report on Carcharodon auriculatus, Dockery and
Manning (1986:16) stated that they did not use Procarcharo-
don "because it appears to have been erected on the basis of the
shared primitive characters of its component species," adding
that "despite its huge size, considered a unique derived charac-
ter here, C. megalodon shares with C. carcharias a reduction of
the accessory cusps that are so prominent in C. auriculatus."
But, the loss of lateral cusplets has occurred in other lamniform
and carcharhiniform sharks earlier in their histories; therefore,
Dockery and Manning's shared character for these two species,
the loss of lateral cusplets, cannot be considered to be unique to
them.
Uyeno et al. (1989:83) reported on an associated dentition of
Carcharodon megalodon, consisting principally of upper teeth,
from the middle Miocene sediments of the Saitama Prefecture,
Japan, and remarked, "In examining the teeth rows contained
in the male great white shark (full length 3.9 meters), it can be
seen that the teeth closely resemble C. megalodon." They did
not illustrate, however, the teeth of the extant great white shark.
The foregoing shows the diversity of opinion that exists
about the taxonomy of the extinct great white sharks. Of these
opinions, we agree with Welton and Zinsmeister (1980) about
the need for an extensive study of the dentitions of the living
and extinct species. The abundance of Carcharodon megal-
odon at the Lee Creek Mine and Gordon Hubbell's excellent
private collection of C. carcharias dentitions, including as well
those of other lamnids, facilitated our study of this problem.
Hubbell's collection and the collections of the CAS and the
NMNH permitted us to study dental variation in 35 complete
dentitions, ranging from neonates to very large adults, and in
28 partial dentitions consisting of anterior teeth. Although we
would be more confident with larger samples of the living and
fossil species, we believe that the specimens presently avail-
able to us in these collections provide sufficient evidence to
suggest that the genera of Casier, Glikman, and Jordan and
Hannibal are indeed junior synonyms of Carcharodon.
In the fossil and the extant species of Carcharodon, the juve-
nile and adult teeth of both lines share similarities suggesting
that they belong to a single genus. First, unlike other galeomor-
ph sharks, in both lines of Carcharodon the cutting edges of ju-
venile teeth are coarsely serrated, and they become finer in the
larger replacement teeth. Second, unlike Isurus (including /. xi-
phodon), in a juvenile C. carcharias (CAS 40905), as in C.
megalodon, the upper anterior teeth have on their lingual crown
feet a chevron-shaped neck area (Figure 33a). This character,
which also was observed in juvenile dentitions of C. carcharias
in the Hubbell collection, is lost in later generations of teeth.
Finally, the juvenile teeth of C. carcharias, with their coarse
serrations and lateral cusplets, resemble closely those of C. ori-
entalis (Figure 33ft). These similarities are not found in Isurus
and Otodus (see above).
In addition to these similarities, these two lines of Carcharo-
don share three derived characters that are not found in any
other lamnids, including two associated dentitions of Isurus xi-
phodon. (1) The mesial cutting edge of the first tooth from the
symphysis in the upper jaw, a second upper anterior, rather
than being convex for 50% or more of its length, is straight or
nearly so from the lateral extremity of the crown foot to the
apex of the crown or to within one-eighth of its total length of
the apex (it may be convex in this area). This straightness is
unique to Carcharodon. (2) This second upper anterior tooth,
rather than the second lower anterior, as in other lamnids, is the
largest tooth in the dentition. (3) The intermediate tooth has a
distal cutting edge that is longer than the mesial cutting edge,
causing the tip to be erect or to point mesially rather than point-
ing distally. Thus, the tooth has a reversed appearance (Got-
tfried et al., 1996) that is unlike all other lamnoid intermediate
teeth, which have longer mesial cutting edges and distally
pointing crowns. These three characters were present in the as-
sociated fossil dentitions with complete sets of anterior teeth
available to us, one of C. subauriculatus and two of C. megal-
odon, and in Uyeno et al.'s (1989, fig. 4) associated dentition
of C. megalodon.
NUMBER 90
127
fs^jf »^,Jf W ^^^ \ 3 \^J ^y^ ^jap ^? %|r

b —
FIGURE 33.—Carcharodon carcharias: a, CAS 40905, dentition of juvenile. Carcharodon orientalis: b. USNM
412184, Aquia Formation, Prince Georges County, Maryland, upper anterior tooth, lingual view. (Scale
bars=1.0 cm.)
In view of the above, C. megalodon and C. carcharias and
their respective Tertiary predecessors, including C. orientalis,
share more morphologic characters in common with one anoth-
er than with any other lamnoid shark. Consequently, we be-
lieve that Palaeocarcharodon, Procarcharodon, Megasela-
chus, and Carcharocles are junior synonyms of Carcharodon.
The first upper anterior tooth, present in Carcharias taurus,
is absent from the associated dentitions of Carcharodon subau-
riculatus and C. megalodon from Lee Creek Mine, the associ-
ated dentition of C. megalodon reported on by Uyeno et al.
(1989), and another of this species, from the Bone Valley For-
mation, in the Hubbell collection.
In both the extant and the fossil species, a wide range of den-
tal variation exists. In the anterior teeth, the first upper tooth
(the second anterior) is predominantly symmetrical, but those
of juveniles and sometimes those of adults are often slightly
asymmetrical, and in the extant species, this asymmetry existed
in 22 (35%) of the 63 dentitions that we examined2. These
asymmetrical teeth are prevalent in white sharks with narrow
2Purdy (1996:69) identified the symmetry of this tooth as a synapomor-
phy, but in view of its variability in the living species, we think this is a weak
character.
teeth. Because these asymmetrical teeth exhibited morphologi-
cal characters found in the second upper anterior teeth of Car-
charias taurus, we disagree with Applegate and Espinosa-Ar-
rubarrena's (1996) assertion that this tooth is the first and not
the second tooth position, which they stated is missing in Car-
charodon. Our position that the first upper anterior tooth is ac-
tually a second upper anterior agrees with Compagno's (1990a)
conclusion.
The intermediate teeth of both the giant-toothed and small-
toothed Carcharodon may have slightly concave or straight
distal cutting edges, with the mesial ones being convex or
straight apically and concave or straight basally. In individuals
of great size, the cutting edges may become nearly equal in
length.
In the extant species, tooth width varies widely. For exam-
ple, six second upper anterior teeth measuring 5.8 cm in height
had widths ranging from 3.8 to 5.0 cm, and a 6.1 cm tooth had
a width of 3.6 cm. These variations in width occur in both
males and females, and they are present in the teeth of Car-
charodon megalodon.
The number of central foramina in the teeth of C. subauricu-
latus and C. megalodon varies from one large foramen to four
smaller foramina.
128
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Compagno (1984:238) characterized the teeth of this genus
as follows: "Flat, triangular, with broad, serrated, nearly
straight cusps, and lateral cusplets only in juveniles below 2 m
long (which may have at least some smooth-edged or partially
smooth); intermediate teeth in upper jaw very large, over half
height of upper anteriors." We would add that in early Tertiary
species, lateral cusplets persist into adulthood.
In the Lee Creek Mine fauna we recognize three species of
Carcharodon: C. subauriculatus from the Pungo River Forma-
tion, C. megalodon from the Yorktown Formation, and C car-
charias from the Yorktown and James City formations.
Carcharodon subauriculatus Agassiz, 1839
Figures 34-36
1 Carcharodon polygyrus Agassiz, 1838, pl. 30: figs. 9-12 [Miocene, Switzer-
land]; 1843:253.
Carcharodon auriculatus de Blainville.—Ameghino, 1906:181-182, fig. 48
[Miocene, Argentina].
ICarcharodon chubutensis Ameghino, 1906:183, fig. 49 [Miocene, Argentina].
Carcharodon megalodon (Agassiz).—Leriche, 1926:412-422, pis. 35, 36 Mi-
ocene, Belgium].
Carcharodon megalodon var. chubutensis Ameghino.—Leriche, 1927: 80, pl.
12, pl. 13: figs. 1-3 [Miocene, Switzerland].
Horizon.—Pungo River Formation (units 1-5).
Referred Material.—2 associated dentitions, USNM
299832, 411881; several hundred teeth, USNM 244350,
256331, 256333, 256334, 280557, 280564, 282356, 282457,
295331, 295339, 298362, 336370, 339920, 348132, 348185,
348186, 348201, 348206, 348210, 348228, 348230, 348237,
356965, 356968-356971, 356974.
Remarks.—We distinguished this species from Carcharo-
don megalodon by the presence of lateral cusplets on the ante-
rior teeth of subadults and usually adults; these cusplets are not
separated from the crown by a deep notch as they are in C. an-
gustidens and C. auriculatus. Juvenile, anterior teeth of C.
megalodon may possess well-defined lateral cusplets.
Agassiz based Carcharodon subauriculatus on a suite of
three anterior teeth, two of which (Agassiz, 1839, pl. 30a:
figs. 11, 12) bear lateral cusplets. In the specimen in his fig.
11,  the notches that separate the lateral cusplets from the
crown have all but disappeared, and in the specimen in his fig.
12, a shallow notch separates the mesial lateral cusplet from
the crown; the distal portion of the tooth is not shown. Agas-
siz described three other species to which the Pungo River
teeth might be referred: C. heterodon, C. polygrus, and C.
megalotis. These species, however, are based on lateral teeth,
which could belong to either C. subauriculatus or juvenile C.
megalodon.
Leriche (1926:420) synonymized the teeth of C. subauricu-
latus with C. megalodon, and he assigned the early Miocene
teeth with lateral cusplets to C. chubutensis Ameghino, which
Ameghino (1906, fig. 49) based on a lateral tooth. Ameghino
(1906, fig. 48) identified an anterior tooth as C. auriculatus,
which Leriche (1926:420) synonymized with C. chubutensis.
Both of these, however, are referable to C subauriculatus, the
senior name.
Peter J. Harmatuk recovered two sets of what appear to be
associated teeth of this species, USNM 299832 (27 teeth) and
USNM 411881 (106 teeth), concentrated in two separate
small areas on the spoil piles. Both sets include the enameloid
shells of partially formed teeth, and both sets possess morpho-
logical peculiarities that suggest they represent associated
dentitions. All of the teeth in USNM 299832 possess small
"denticles," composed of osteodentine rather than the ortho-
dentine and enameloid of cusplets, on the lateral extremities
of the roots at the base of the crown. In USNM 411881, on the
Figure 34.—Carcharodon subauriculatus. USNM 299832, Pungo River Formation, associated dentition from
the right jaws, lingual view. (Scale bar= 1.0 cm.)
NUMBER 90
129
FIGURE 35.—Carcharodon subauriculatus, USNM 4118
the left jaws, lingual view. (Scale bar= 1.0 cm.)
II, Pungo River Formation, associated dentition from
lingual face of the root lobes, a small slit or slits occur in ex-
actly the same positions on each tooth. Some teeth possess a
slit on one lobe only, which may be either the mesial or distal
lobe. In both sets these teeth fit the sizes anticipated for the
different tooth positions in a dentition of Carcharodon. These
features suggest strongly to us that these tooth sets represent
associated dentitions.
Neither tooth set represents a complete dentition. In USNM
299832 (Figure 34), which consists of teeth from mainly the
right side, the second upper anterior tooth, the upper interme-
diate tooth, and the lower right anterior teeth are present.
From the upper jaws, the right second through fifth lateral
teeth are present; from the lower jaws, the first through third
lateral teeth from both sides and the left fourth through fifth
lateral teeth are present.
In the second tooth set, USNM 411881 (Figure 35), the den-
tition from the left jaw is nearly complete; only the second up-
per anterior tooth and one upper and two lower posterior teeth
are missing. From the right jaw, the dentition includes most of
the upper lateral teeth, several lower lateral teeth, and an in-
complete first anterior tooth.
These tooth sets furnished us with information not available
from isolated teeth. Like C. carcharias, the height of the sec-
ond upper anterior tooth in USNM 299832 (8.9 cm) is greater
than the height of the second lower anterior tooth (8.5 cm). In
USNM 411881, which is from a slightly smaller individual
(height of second lower anterior=6.8 cm), the second upper
anterior tooth is missing; therefore, we were unable to make
the same comparison for this specimen. Another similarity
with C. carcharias is the nearly symmetrical second lower an-
terior tooth in each tooth set (Figures 34, 35).
In both tooth sets dignathic heterodonty is present. The up-
per teeth are broader than the lowers, the lower anterior teeth
and the anteriormost lateral teeth have better-developed torus-
es than their upper-jaw counterparts, and the cutting edges of
the lower teeth are more concave than those of the upper
teeth.
In both tooth sets, the third lower anterior tooth is neither
reduced in size nor is it the shape of a lateral. In an associated
dentition of C. megalodon from the Bone Valley Formation in
the Hubbell collection, this condition also exists. Uyeno et al.
(1989) noted, however, that the third lower anterior tooth in
their associated dentition of C. megalodon from Japan was al-
most the same size as the first lateral tooth, both teeth being
only slightly smaller than the lower anterior teeth. At present,
due to the very small number of associated tooth sets for these
sharks, we cannot determine if the lack of lateralization of the
third lower anterior tooth is a retention of a primitive charac-
ter or a variable character in these sharks.
The second upper anterior tooth (present only in USNM
299832), which is the first tooth from the symphysis, is slight-
ly asymmetrical. Its mesial cutting edge is nearly straight,
130
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
whereas the distal cutting edge is slightly concave. In this
specimen the second and third upper anteriors are very similar,
having only minor differences in tooth height and width,
crown width, shape of the cutting edges, and shape of the root.
In USNM 411881 the crown is strongly inclined distally; its
mesial cutting edge is strongly convex, and the distal one is
concave.
The intermediate teeth of both dentitions were easily identi-
fied by their strong labial curvature. With concave cutting
edges, both of these intermediate teeth resemble lower lateral
teeth, but their crowns, which point mesially, are wider than
those of the lower laterals of their respective dentitions. In
both intermediate teeth the lateral cusplets are almost lost,
and on the lingual face of the root, they have three central fo-
ramina.
The upper lateral teeth of USNM 299832 (five present) are
broader than those of USNM 411881 (eight present) and have
nearly straight cutting edges, whereas the upper lateral teeth of
USNM 411881 have concave cutting edges. In USNM 299832
the crowns of the upper lateral teeth are more erect than are
those of USNM 411881. The first upper lateral tooth has a
stronger labial curvature than in the other upper lateral teeth.
This tooth is distally inclined, and its mesial cutting edge is
straight, whereas the distal one is strongly concave. Its mesial
root lobe is usually more tapered than its distal one. Of the up-
per lateral teeth, the second tooth usually has the greatest
height in this series. Its crown is broader than that of the first
lateral tooth, and the cutting edges are slightly concave to near-
ly straight, giving the tooth a symmetrical appearance. The
width of this tooth is usually 85% to 95% of its height. In the
remaining lateral teeth, the crowns diminish perceptibly in size
and have a slight distal inclination.
The three lower anterior teeth have erect crowns. The mesial
and distal cutting edges are slightly concave in the first and
second teeth and are more so in the third, giving the crown of
this tooth a narrower appearance than those of the first two. In
USNM 299832 the distal root lobes of these anterior teeth are
more rounded than the mesial lobes are, but in USNM 411881
the mesial and distal root lobes of the second tooth both are
rounded, and in the third tooth, the mesial root lobe is tapered.
In USNM 411881, the crown of this last tooth points straight
up, but in USNM 299832, it has a slight mesial bend. On the
lingual face, in the central portion of the root, the torus is prom-
inent in USNM 299832 and forms a ridge concentric to the bas-
al edge in USNM 411881.
In both dentitions the width of the first lower lateral tooth
slightly exceeds its height (Table 3), but in the Japanese (Uy-
eno et al., 1989), Peruvian, and Bone Valley associated denti-
tions, these teeth are higher than they are wide. Too few associ-
ated dentitions of these sharks are available to show whether or
not this difference between the Lee Creek Mine teeth and those
in the Japanese, Peruvian, and Bone Valley dentitions is onto-
genetic.
In both sets the lateral cusplets are absent or are the least de-
veloped in the anterior teeth and are the most developed in the
more posterior lateral teeth. In USNM 411881 the three teeth in
upper lateral file number three show the transition from well-
developed lateral cusplets to almost none (Figure 36), which
indicates that they are lost quickly.
Among the various fossil faunas with Carcharodon megal-
odon-iype teeth, teeth with lateral cusplets occur commonly in
the Burdigalian, Aquitanian, and perhaps the Chattian stages.
These teeth also are common in the Fairhaven Member of the
Calvert Formation in Maryland and at the base of the Calvert
Formation in Virginia. In the Chesapeake Group, the percent-
age of such teeth drops sharply above Zone 4 (Shattuck, 1904)
of the Calvert Formation.
During the Chattian, Carcharodon subauriculatus may have
had a nursery area in what is now South Carolina (Purdy, 1996,
and in prep.). In a stratigraphically controlled sample recovered
from the Chandler Bridge Formation (Sanders, 1980), juvenile
teeth (m=98) of this shark are very common, with the anterior
teeth ranging from 4.4 to 5.7 cm in height. Only five teeth from
very large adults were recovered. Of these specimens, a first
lower lateral tooth, the most anterior tooth in this size range
found, measured 9.5 cm in height. This tooth is equivalent in
size to those from the Yorktown Formation. These large teeth
may be from females that came to the Chandler Bridge area, an
area of subtropical waters during the Chattian, to bear their
young.
We have not seen any large teeth from the Pungo River For-
mation. Anterior teeth from this area range in height from 1.8
Table 3.—Measurements (in cm) of associated dentitions of Carcharodon subauriculatus from Lee Creek Mine.
(A2-A3=upper anterior teeth, I = intermediate tooth, Ll-L9=upper lateral teeth, al-a3 = lower anterior teeth,
I l-l9=lower lateral teeth, B=incomplete tooth, M = tooth missing from dentition.)
Specimen					Upper		lentition										Lower dentition							
	A2	A3	I	LI	L2	L3	L4	L5	L6	L7	L8	L9	al	a2	a3	11	12	13	14	15	16	17	18	19
USNM 299832																								
height	8.9	8.8	7.1	8.5	8.3	7.3	6.2	5.2	M	M	M	M	B	8.5	8.2	6.1	6.6	M	M	M	M	M	M	M
width	6.9	6.8	6,4	7.6	7.9	7.9	7.0	4.7						6.5	6.3	6.2	6.0							
USNM 411881																								
height	M	7.1	6.5	6.7	6.6	5.9	5.5	4.6	4.0	3.2	2.2	M	6.2	6.8	6.4	5.3	5.7	5.4	4.6	M	M	M	M	M
width	-	5.6	6.3	6.3	6.4	6.2	5.8	5.1	4.5	3.7	2.9	-	4.9	5.0	5.3	5.4	5.4	5.2	4.7	-	-	-	-	-
NUMBER 90
131
FIGURE 36—Carcharodon subauriculatus, USNM 411881, lingual view of
third upper lateral file showing loss of lateral cusplets. (Scale bar= 1.0 cm.)
to 8.4 cm (mean=4.6 cm, «=56) and probably came from indi-
viduals between 3 and 10 m in total length.
In the extant Carcharodon carcharias, Klimley (1985) ob-
served along the western coast of North America that adult fe-
males give birth to pups south of Point Conception, California,
and then move north to their feeding areas where there is an
abundance of pinnipeds. The young white sharks, which feed
principally on fish, move northward as they grow larger. Dur-
ing the Neogene along the Atlantic coast of North America,
Carcharodon subauriculatus may have pupped in the warm
waters of the area of present-day Charleston, South Carolina,
and as the juveniles increased in size, they may have moved
northward to principal feeding areas where larger prey were
probably more abundant. The distribution of Carcharodon sub-
auriculatus in the Neogene of the Atlantic Coastal Plain, then,
could have been governed by their size and the availability of
prey. This might explain the absence of large C. subauriculatus
in the Pungo River Formation.
Carcharodon megalodon (Agassiz, 1835)
Figures 37-42
Carcharodon akilaensis Uyeno and Hasegawa, 1974:257-260, figs. 1-3 [Mi-
ocene, Japan].
Horizon.—Upper Pungo River Formation (units 4-6)?;
Yorktown Formation (unit 1).
Referred Material.— 1 associated dentition, NCSM
13073; several hundred isolated teeth, USNM 182108, 214947,
244350, 256331, 256333, 256334, 278515, 279338, 279353,
280509, 280557, 280564, 281392, 289087, 295331, 295339,
298362,298368, 299766, 336257, 336370, 339917, 348169,
348178, 348247, 348265, 348338, 348344, 348366, 348375,
350923, 350924, 355736, 355762, 355766, 355822, 355884,
355888,356965,356968-356975, 356981-357010, 445500,
474915, 474916, 475360, 476358.
Remarks.—We distinguish these teeth from those of Car-
charodon subauriculatus by the lack of lateral cusplets on sub-
adult and adult teeth and often on the anterior teeth of juveniles.
Agassiz (1835, pl. 29: figs. 1-6, 1843:247-248) founded this
species on six teeth, three of which were from Malta; the prov-
enance of the others is unknown. He characterized the species
as follows: "Its general form is perceptibly equilateral....The
marginal serrations are uniform on each edge of the tooth. The
enamel overlaps scarcely the root at the limit of the latter; it is
indented at an almost right angle on the internal face (fig. 2),
while it is simply concave on the external face (fig. 3). The
thickness of the tooth is not very considerable (fig. 2a); the in-
ternal face is convex; the external face on the other hand is flat
even a little concave. The root is very heavy; it forms alone
more than a third of the total height of the tooth; in the other
specimens these proportions are able to vary according to their
position in the jaw" (Agassiz, 1843:247-248; translated from
French by R.W.P.).
Agassiz's (1835, pl. 29: figs. 2, 3) type specimen is a second
upper anterior tooth preserved in the Staatliches Museum fur
Naturkunde in Karlsruhe, Germany (TE-PLI 18) (Figure 39a").
Teeth satisfying this description occur in the upper layers of
the Pungo River Formation, but they may be examples of adult
C. subauriculatus that lack lateral cusplets. Some of the dark,
worn teeth from the basal Yorktown Formation may be rede-
posited from the Pungo River Formation or may be relicts from
the hiatus. Other teeth from the lower Yorktown layer are beau-
tifully preserved and are relatively light in color, and most cer-
tainly they are contemporaneous. These large teeth are the most
sought-after fossils in the Lee Creek Mine, and collecting expe-
rience indicates that they are found only in the lower portion of
the Yorktown Formation.
The associated dentition (NCSM 13073) consists of the sec-
ond and third anterior teeth from both upper jaws, a right inter-
mediate tooth, the first through fourth lateral teeth from both
upper jaws (Figure 37), and three incomplete lower lateral
teeth. Another tooth under this number (13073.23) is a third an-
terior tooth from a smaller individual.
132
The second anterior teeth (first tooth postion) are nearly
symmetrical, the right more so than the left. Their cutting edges
are convex, and there are four central foramina on the lingual
faces of the roots.
The third anterior teeth are asymmetrical; their mesial cut-
ting edges are nearly straight but are convex apically, and their
distal cutting edges are concave basally and convex apically.
The crowns of these teeth have a labial curvature. There are
three central foramina on the lingual faces of the roots. The
mesial root lobes are rounded and are longer than the more lo-
bate distal lobe.
The intermediate tooth has the proportions (height/width) of
an intermediate tooth rather than those of a lateral tooth; its
crown bends labially, and its tip points mesially, but only
slightly. The mesial cutting edge is nearly straight, whereas the
distal one is concave. Four central foramina are present on the
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
lingual face of the root. The mesial root is rounded, whereas
the distal root is somewhat lobate.
The crowns of the lateral teeth are mainly asymmetrical with
the exception of the tooth from the second position. On the lin-
gual faces of the root lobes of these teeth, two to three central
foramina are present. The mesial root lobes are usually round-
ed, whereas the distal ones are lobate.
The first lateral tooth has a nearly straight mesial cutting edge
and a concave distal one. Its crown has a strong labial curvature.
The second lateral teeth, which are the largest of the lateral
series, have crowns that are nearly symmetrical, and the teeth as
a whole are equilateral. The crown has a slight labial curvature.
The third and fourth lateral teeth are similar to the first in
general form.
Only incomplete lower lateral teeth were present in this den-
tition, and these had narrower crowns than did their upper
FIGURE 37.—Carcharodon megalodon. NCSM 13073, associated upper dentition, lingual view. (Scale bar=5.0 cm.)
Aaaaa
FIGURE 38.—Carcharodon megalodon, composite lower dentition, lingual view. (Scale bar=5.0 cm.)
NUMBER 90
FIGURE 39.—Carcharodon megalodon: a, USNM 445500, heart-shaped fourth or fifth upper lateral tooth, lin-
gual view; b, USNM 474915, same type of tooth, lingual view; c, USNM 355822, third upper anterior tooth with
noticeable torus, basal view; d, USNM 476358, cast of holotype (Staatliches Museum TE-PLI 18), lingual view.
(Scale bars= 1.0 cm.)
134
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
counterparts. Their cutting edges were concave, and their roots
were incomplete. These teeth were not measured.
As points of reference, we used some 40 dentitions of the liv-
ing species, mostly uncataloged, in the USNM, CAS, and Hub-
bell collections; the two associated dentitions of C subauricu-
latus (USNM 299832, 411881); and the associated dentition of
C. megalodon from the Bone Valley Formation (Hubbell col-
lection) to identify the lower teeth (Figure 38) among the iso-
lated Lee Creek Mine teeth. The crowns of all lower teeth bend
lingually, and in most lower teeth the mesial root lobe is point-
ed, and the distal one is lobate. The prominence of the root
torus, which may be round or ridge-like, decreases progressive-
ly in more distal tooth positions.
The first anterior teeth are symmetrical, with concave to
nearly straight cutting edges. The root lobes form a right or
slightly obtuse angle.
The second anterior teeth are slightly asymmetrical, pointing
distally, with concave cutting edges. The angle of the root
lobes is slightly broader than that of the first anterior tooth.
In the third anterior tooth, the tip of the crown points mesial-
ly. Near the apex, the mesial cutting edge is more convex than
the distal one. Below this point the cutting edges are straight to
slightly concave. The angle of the root lobes is broader than
that of the second anterior teeth.
Among the lateral teeth, the first or second is the largest; the
remaining teeth decrease in size and become more asymmetri-
cal toward the angle of the jaws. The distal cutting edges are
more concave than are the mesial ones. The root lobes form ob-
tuse angles ranging from 114° to 140°.
We observed some tooth variations in C. megalodon that we
have also observed in C. carcharias. The upper teeth are trian-
gular (ranging from equilateral to isosceles) in outline. In some
upper lateral teeth of C. megalodon, the mesial root lobe may
be lobate, but this is not its usual form, which, unlike the distal
lobe, is slightly tapered. The mesial cutting edge is convex
(USNM 445500, 474915) (Figure 39a,b), which gives the teeth
a heart-shaped appearance. The labial faces of the crowns of
these teeth are convex, and the crown tips bend lingually
slightly. Aside from their slightly pathologic appearance, these
teeth agree in morphology with those of C. carcharias from the
fourth and fifth upper lateral files. The torus is well developed
(Figure 39c) on the lingual face of the root in a second upper
anterior tooth (USNM 355822).
Pathologies occur in many of the teeth; examples of these are
illustrated in Figure 40a-c. The tooth germs of the two teeth in
Figure 40a,b, USNM 474916 and 339917, respectively, were
injured on their distal edges; these injuries caused the teeth to
buckle lingually and distally. In USNM 339917, which re-
ceived the greater injury, the distal cutting edge is distorted.
The tooth germ of the tooth in Figure 40c, USNM 475360, was
injured near its apex, which distorted its distal cutting edge.
Cadenat (1962) noted that these deformities are caused by inju-
a
FIGURE 40.—Carcharodon megalodon, pathologic teeth: a, USNM 474916, lingual view;
b, USNM 339917, lingual view; c, USNM 475360, third upper anterior tooth, lingual
view. (Scale bar= 1.0 cm.)
NUMBER 90
135
ries to the tooth germs on the insides of the jaws, usually
caused by stingray spines or sea catfish spines. Once injured
these tooth germs continually produce deformed teeth.
Uyeno and Hasegawa (1974) described Carcharodon aki-
taensis on the basis of a pathologic tooth of C. megalodon. This
type of pathology also occurs in Isurus xiphodon.
Another specimen worth noting is a tooth of this species
with bite marks on it (USNM 336257, Figure 41a). When
viewed under magnification (Figure 4\b), it is clear that these
bites were made by a serrated tooth. Is it evidence of a shark
eating a shark or of a loose tooth becoming lodged in the prey
during feeding and then being bitten as the shark bit off a
chunk of its prey?
In the USNM collections, the largest tooth (USNM 214947),
a second upper anterior tooth from Lee Creek Mine, measures
15.0 cm (5.9 in) in height and probably came from a 15 m TL
shark. Larger teeth have been found in the Yorktown Forma-
tion at New Bern (15.6 cm, Harmatuk collection, uncataloged)
and from the Cooper River, South Carolina (16.2 cm, Hubbell
collection, uncataloged). The teeth from the Yorktown Forma-
FlGURE 41— Carcharodon megalodon, USNM 336257: a, lingual view of bitten tooth; b, close-up of bite mark
showing serrations. (Scale bars: a=1.0 cm; 6=0.3 cm.)
136
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOG
NUMBER 90
137
FIGURE 42 (opposite).—Carcharodon megalodon, composite dentition,
USNM, reconstruction by John G. Maisey, AMNM. From left, top row: Robert
J. Emry, Curator, Department of Paleobiology; Victor G. Springer, Curator,
Department of Vertebrate Zoology; Peter J. Harmatuk, Collaborator, Depart-
ment of Paleobiology; Ian G. Maclntyre, former Chairperson, Department of
Paleobiology. Middle row: Sue Nell Voss, former Writer/Editor, Department
of Exhibits; Clayton E. Ray, Curator, retired, Department of Paleobiology.
Bottom row: Walter Erick Hock, Sr., former Modelmaker, Exhibits Central;
Robert Purdy, Museum Specialist, Department of Paleobiology (all NMNH).
(Photograph by Chip Clark, NMNH.)
tion at Lee Creek Mine range in size from 5.6 to 15.0 cm
(mean= 11.2 cm, n=25).
A reconstruction of the jaws of C. megalodon (Figure 42) in-
cludes as functional teeth specimens from Lee Creek Mine. The
tooth in the left second lower anterior position is a left second
upper anterior tooth. Several other teeth also are misplaced, in-
cluding the right second lower anterior tooth, which is a right
third upper anterior tooth; the right second lower and left third
lateral teeth, which are upper intermediate teeth; and the right
and left third lower anterior teeth, which are left third upper an-
terior teeth from a smaller individual. Gottfried et al. (1996)
published a corrected dental reconstruction of this shark.
The earliest records of this species were reported from New
Zealand, from the Oligocene sediments at Weka Pass (Davis,
1888:13) and from the early Oligocene sediments (Keyes,
1972:233). Keyes (1972:234) suggested that Davis' Weka Pass
specimen was collected in the Pliocene "Greta Beds" that also
occur at this locality. Many of the Oligocene specimens report-
ed by Keyes were collected without precise stratigraphic data,
and some of these are incomplete specimens, which in several
instances lack the lateral cusplet area of the tooth; therefore,
their stratigraphic position and in some instances their taxo-
nomic identity cannot be ascertained. One specimen, however,
with matrix adhering to it (Keyes, 1972: 235, figs. 10, 11), con-
tains an imprint of a Venericardia, which Keyes matched with
the sediments of the Chatton Marine Formation (middle Oli-
gocene). This tooth, which is 12.0 cm in height, lacks the distal
portion of the root and the mesial lateral cusplet, but we believe
that it is from an adult C. subauriculatus and that other speci-
mens from the Oligocene and early Miocene identified as C.
megalodon also are C. subauriculatus.
Roux and Geistodoerfer (1988:137) reported manganese-en-
crusted specimens in Pleistocene sediments dating from 20,000
to 120,000 years ago dredged in the Indian Ocean off Madagas-
car that may be the latest occurrence of C. megalodon. Based
on the rates of accretion of manganese calculated by Burnett
and Piper (1977), they estimated that the minimum age for
these teeth is 10,000 years. Seret (1987) also reported dredged
specimens from off New Caledonia in the southwestern Pacific
Ocean; he estimated the age of these specimens at 1 Ma.
Whether or not these specimens were continually exposed to
conditions that permitted the accretion of manganese at a con-
stant rate is not known, and they could be as old as Miocene or
Pliocene.
Several large cetacean bones with large, serrated bite marks,
collected at Lee Creek Mine, confirm that this shark preyed
and/or scavenged on large whales (see Purdy, 1996).
Compagno (1990b:57) hypothesized that Carcharodon meg-
alodon "may have been capable of preying on large baleen
whales without the cooperative pack-hunting tactics that the
smaller killer whale apparently needs to use to subdue difficult
prey....Various reconstructions of the jaws of C. megal-
odon... suggest that this shark had a predatory apparatus capa-
ble of inflicting mortal injuries on even a fin whale or blue
whale."
Carcharodon carcharias (Linnaeus, 1758)
Figures 33a, 43
HORIZON.—Yorktown Formation? (unit 1); James City For-
mation.
Referred Material.—22 teeth, USNM 214465, 214466,
256337,279304, 279311, 280579, 281051, 281055, 281059,
285623, 476340.
Remarks.—These teeth are more compressed than are those
of Carcharodon megalodon of equivalent size. The teeth of C.
carcharias also have less massive roots and often have coarser
serrations (Figure 43).
Teeth of the extant species exhibit considerable variation in
their morphology. The serrations of the cutting edges range
from fine, as in Carcharodon megalodon, to coarse, with the
finer serrations being more evident in the teeth of adults. In the
upper anterior teeth, the tips of the second anterior teeth may
be symmetrical, point distally, or (sometimes) point mesially.
The third anterior tooth also may be symmetrical or nearly so.
In the lower anterior teeth, the root lobes may arch labially.
The intermediate teeth may have symmetrical or asymmetrical
crowns, and in the same dentition, the morphology of the right
and left intermediate teeth can be very dissimiliar. Like the in-
termediate teeth, the upper first lateral tooth may have a strong
labial curvature. The attitudes of the crowns of the upper later-
al teeth may be erect or distally inclined. In the lower lateral
teeth the extremities of the root lobes may be straight or
rounded.
Three juvenile dentitions of the extant species available to us
for this study provided further information about variation in
these teeth. In CAS 40905 (female, 1.6 m TL; Figure 33a) and
in dentitions from a female (1.2 m TL) and a male (1.4 m TL)
from the Hubbell collection, the upper teeth, rather than being
erect, are inclined distally. The cutting edges of these teeth
range from smooth near the tip to coarsely serrated basally. The
cutting edges of the lateral cusplets range from smooth to
coarsely serrated, particularly in the posterior lateral teeth. In all
three dentitions the second upper anterior teeth are symmetrical;
in the 1.2 m female, the distal root lobe tapers to a point and the
mesial one is lobate, and in CAS 40905, the opposite condition
exists. Unlike teeth of adults, the second lower anterior tooth is
equivalent to or larger than the second upper anterior tooth
138
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Figure 43.—Carcharodon carcharias: a, USNM 285623, Yorktown Formation?, upper lateral tooth, lingual
view; b, USNM 279311, Yorktown Formation?, upper lateral tooth, lingual view; c, USNM 281055, James City
Formation, upper lateral tooth, lingual view; d, USNM 281059, upper anterior tooth, lingual view; e, USNM
476340, second upper anterior tooth, lingual view. (Scale bars: a= 1.0 cm; b-d= 1.25 cm; e=0.5 cm.)
(CAS 40905 tooth heights: upper second anterior (A2)=1.56
cm, lower A2 = 1.61 cm; 1.2 m female, upper A2 = 1.48 cm, low-
er A2= 1.54 cm; 1.4 m male, upper A2= 1.66 cm, lower
A2= 1.66 cm). Among the intermediate teeth, the tip of the tooth
points mesially in CAS 40905, is almost symmetrical in the 1.2
m female, and is erect but asymmetrical in the 1.4 m male.
At Lee Creek Mine, most specimens are jet black, and the
roots are very corroded. On the spoil piles, these teeth were
found intermingled with masses of large molluscan shells of
the James City Formation. A few teeth, however, compare in
preservation to those from the basal Yorktown Formation (Fig-
ure 43a,b). Because they have been found in early Pliocene
beds elsewhere, this occurrence is not unusual (Leriche,
1936b:746; Muizon and De Vries, 1985:554).
Their rarity in the basal Yorktown Formation may be related
to the abundance of large teeth of C. megalodon; at Peruvian
localities of equivalent age where C megalodon is uncommon,
C. carcharias is abundant, and it is rare in Miocene sediments
that yield the teeth of C. megalodon. Leriche (1927:82) also
noted that C. carcharias "appears in the Miocene, where it is
exceedingly rare. It is more widespread in the Pliocene, where
it tends to replace C. megalodon." In the late Pliocene sedi-
ments of Baja California, Espinosa-Arrubarrena and Applegate
(1981) report that these two species do occur together. The
stratigraphic resolution of the Baja California occurrence is not
fine enough to determine if the two species occurred in the area
at the same time of the year or at different times. With the ex-
ception of this last, these occurrences suggests to us that these
two species may have had allopatric distributions (For further
discussions of the distribution and paleoecology of Carcharo-
don, see Purdy, 1996).
In their study of white sharks from along the coast of Califor-
nia, Tricas and McCosker (1984:232-233) reported that "fish
prey predominated in the diet of sharks [Carcharodon carchar-
ias] approximately 3 m or less (TL), while pinnipeds and ceta-
ceans predominated in those of larger sharks." Casey and Pratt
(1985:10) made similar observations about white sharks occur-
ring off the east coast of the United States. Compagno
(1984:240; see also Cliff et al., 1989) noted the following:
"Larger white sharks above 3 m long tend to prey heavily on
marine mammals, while smaller sharks below 2 m long feed
heavily on bony fishes and small sharks, but even large sharks
are capable of eating smaller prey such as the 150 crabs, salmo-
ns, hakes, and rockfishes found in a 4.4 m specimen from
NUMBER 90
139
Washington State, USA. Pinnipeds may be especially impor-
tant prey for white sharks where they occur together, but in
tropical areas without these mammals the white shark is proba-
bly capable of subsisting on other sharks, bony fishes, turtles
and cetaceans."
According to Compagno (1984:239-240), white sharks are
primarily coastal and offshore inhabitants of continental and
insular shelves. They are most commonly recorded in cold and
warm-temperate seas.
The Lee Creek great white sharks were between 4 and 5 m in
total length.
Order Carcharhiniformes
Family Scyliorhinidae
(cat sharks)
Scyliorhinus sp.
Figure 44a-h
HORIZON.—Pungo River Formation (units 1-5); Yorktown
Formation? (unit 1 ? probably redeposited from underlying sed-
iments).
Referred Material.—12 isolated teeth, 1 from Yorktown
Formation, USNM 312266-312268.
Remarks.—Compagno (1988:121) described the teeth of
Scyliorhinus as follows: "[Teeth] similar in upper and lower
jaws, cusps more oblique in upper jaw__Sexual heterodonty
absent or poorly developed.... Anterolateral teeth have erect or
semioblique, moderately high cusps and mesial and distal cus-
plets, lower on posterior teeth; transverse ridges are confined to
the basal ledges and do not extend onto the cusps." The Lee
Creek Mine teeth match his description.
The teeth from Lee Creek Mine are small (mean total height
3.1 mm (Figure 44a-h); mean maximum mesial-distal length
2.5 mm) and have a prominent, lingually inclined central cusp
bordered on either side by a single lateral cusplet. The central
cusp is conical apically, but its lower part is divided into labial
and lingual faces by mesial and distal cutting edges. These ex-
tend from one-third to one-half the height of the main cusp
through a notch formed between the main cusp and the lateral
cusplets, and then ascend onto the lateral cusplets. On the labial
face, the main cusp and the lateral cusplets are moderately con-
vex. This face of the crown is smooth apically, but it is some-
times striated along the crown-root boundary. These striations
are usually absent on the convex, lingual face of the central
cusp, but they may be present on the lateral cusplets. The root
has a prominent planar basilar face divided by an open trans-
verse groove.
The Lee Creek Mine specimens and those identified by An-
tunes and Jonet (1969-1970) and Cappetta (1970) as Scyliorhi-
nus distans (Probst, 1879) may represent the same species, but
because little is known about the dental morphology of the ex-
tant spotted cat sharks, of which there are 13 species, it is not
prudent at this time to assign the fossil teeth to a species.
Compagno (1984:366) reported that the extant chain cat
shark inhabits waters of 73 to 550 m in depth from off southern
New England to Florida and from the northern Gulf of Mexico
to Nicaragua; its feeding habits are unknown.
Family Triakidae
(tope sharks)
Galeorhinus cf. G. affinis (Probst, 1878)
Figure 44i-m
Horizon.—Pungo River Formation (units 1-5); Yorktown
Formation (units 1, 2, possibly redeposited).
Referred Material.—37 teeth, USNM 207450, 207451,
207453, 207454, 312270-312272.
Remarks.—For the genus Galeorhinus, Compagno
(1988:248) described the teeth as exhibiting weak dignathic
heterodonty, and except for two upper and lower medials, the
anterior and posterior teeth cannot be differentiated (anteropos-
teriors). The medial teeth differ from the "anteroposteriors in
having erect cusps and both mesial and distal cusplets, whereas
anteroposteriors have oblique cusps and well-developed distal
cusplets. Mesial cusplets are well developed in the fossil
Eocene species Galeus rectoconus Winkler, 1873 [Cappetta as-
signed this species to his genus Abdounia], and occasional
adults of the living Galeorhinus galeus. Pegs absent from tooth
crowns. Tooth roots with strong transverse notches" (Compag-
no, 1988:248). In the seven dentitions of Galeorhinus galeus
(Hubbell collection) available to us, the mesial edges are
straight or dog-legged. In larger males, the teeth have broader
crowns than do those of females, and the distal cusplets are
saw-toothed. The teeth from Lee Creek Mine resemble those of
females (Figure 44i-m).
Probst's (1878:139, pl. 1: figs. 64-67) type suite for G. affi-
nis contains four teeth of two different genera; only the two
teeth in his figs. 66 and 67 belong to Galeorhinus; the other
two teeth (figs. 64, 65) appear to be symphysials of
Paragaleus. The specimens in his figs. 66 and 67 are very
close in morphology to those illustrated by Compagno (1988,
pis. 20: fig. J, 21: fig. J) and Herman et al. (1988:106, pl. 13).
Because Probst's type specimens are lost and a large sample
of dentitions from the extant species is not available to us, we
cannot at this time assess the validity of his species. If it is
valid, then the Lee Creek Mine teeth, which resemble those in
Probst's figs. 66 and 67, should be assigned to Galeorhinus
affinis.
The Lee Creek Mine specimens are small; tooth height rang-
es from 2.0 to 7.5 mm, width ranges from 2.1 to 9.9 mm, thick-
ness ranges from 0.9 to 3.0 mm, and the number of distal cus-
plets ranges from two to four. Compagno (1988:33) reported
that the number of distal cusplets in Galeorhinus increases with
the growth of the shark.
This shark no longer inhabits the coastal waters off eastern
North America. It is found in cold to warm-temperate continen-
140
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
tal seas in the eastern Pacific, the eastern North Atlantic, the
South Atlantic, and off southern Australia, where it frequents
depths from 2 to 471 m. It feeds on bony fishes and inverte-
brates (Compagno 1984:387-388).
Hypogaleus sp.
Figure 44q
HORIZON.—Pungo River Formation (unit 1).
Referred Material.—1 tooth, USNM 207452.
Remarks.—This tooth from the lower Pungo River Forma-
tion compares favorably with the lower teeth figured by
Compagno (1988, pl. 21: fig. I) and Herman et al. (1988, pl.
14). In the living species and in the Lee Creek specimen, the
mesial edge of the crown is convex, and the distal cutting edge
is concave on the apical half of the crown. This specimen mea-
sures 4.1 mm in height and 5.5 mm in width.
According to Compagno (1988:394), this shark inhabits
deepish water in the tropical and subtropical western Indian
and western North Pacific oceans; it eats bony fishes.
Mustelus sp.
Figure A4n-p
Horizon.—Pungo River Formation (units 1-5).
Referred Material.—5 isolated teeth, USNM 207589,
207590.
Remarks.—These diminutive durophagous teeth are con-
vergently similar to those of certain rhinobatids and pristids.
The mesiodistal diameter (range= 1-1.3 mm) is twice that of
the labiolingual diameter and is one and one-half times the
maximum tooth height; the labiolingual diameter is approxi-
mately equal to the medial height of the crown measured on the
lingual side. In apical view, the occlusal surface is elliptical,
more or less flattened, but rising slightly above the lingual peg
and restricted from the lingual surface by a cutting edge. On
the labial face (Figure 44c), the crown overhangs the root and
is vertically striated. These striations, or more accurately, ver-
miculating ridges, continue a short distance onto the occlusal
surface of unworn teeth. These ridges also occur on the lingual
surface of the crown and extend higher there than on the labial
surface. On the lingual face (Figure 44p) the medial portion of
the crown foot expands to form a relatively prominent, rhino-
batid-like process or peg. The root is bipartite, with a flattened
attachment face that is inclined at about a 30° angle to the plane
of the occlusal surface.
Compagno (1984:399), for purposes of identification, sepa-
rated Mustelus into three groups, those with "cusps high on
teeth," those with "no cusps on teeth," and those with "low
blunt cusps present on teeth, crowns asymmetrical." The Lee
Creek Mine specimens belong to the last category, and they are
similar to those of M. canis, which inhabits the temperate and
tropical continental waters of the western Atlantic and the Gulf
of Mexico (Compagno 1984:405). It is found from the intertid-
al zone to 200 m in depth and feeds mainly on crustaceans, al-
though it also feeds on small bony fishes (Compagno
1984:406).
Sffli
ci     bed     e    f       g--------h            ;
nop
Figure 44.—Scyliorhinus sp.: a, USNM 312266, incomplete, anteroposterior tooth, labial view; b, same
specimen, lingual view; c, USNM 312267, anteroposterior tooth, lingual view; d, same specimen, lateral
view; e, same specimen, labial view;/ USNM 312268, anteroposterior tooth, lateral view; g, same specimen,
lingual view; h, same specimen, labial view. Galeorhinus cf. G. affinis: i, USNM 312270, lower anteroposte-
rior tooth, lingual view;/ USNM 312271, upper anterior anteroposterior tooth, labial view; k, USNM
312272, upper anterior anteroposterior tooth, labial view; /, USNM 207450, upper medial tooth, labial view;
m, USNM 207453, lower anteroposterior tooth, labial view. Mustelus sp.: n, USNM 207589, anteroposterior
tooth, lateral view; o, same specimen, labial view; p, USNM 207590, anteroposterior tooth, lingual view.
Hypogaleus sp.: q, USNM 207452, anterior tooth, lingual view. (Scale bars: a-e=0.s cm;f-h=0.25 cm;
1=0.5 cm;y-/=0.5 cm; m-^=0.1 cm.)
NUMBER 90
141
Family HEMIGALEIDAE
(weasel and snaggletooth sharks)
Paragaleus sp.
Figure 45
HORIZON.—Pungo River Formation (units 1-5); Yorktown
Formation (unit 1, probably redeposited).
Referred Material.—About 50 teeth, USNM
207455-207461, 475446, 475447, 476288-476292.
Remarks.—Teeth from the Pungo River Formation (Figure
45) compare favorably with those of the extant species.
Compagno (1988:258) described these teeth as follows: "Up-
per anterolateral teeth with moderately long cusps that are no-
ticeably longer than the distal cusplets. Lower anterolateral
teeth slightly smaller than uppers. Cusps of lower anterolaterals
short, stout, straight or slightly hooked, and differentiated from
the crown foot by distal sometimes mesial notches. Some or al-
most all cusps on lower anterolaterals oblique or semioblique.
Distal and sometimes mesial cusplets on some lower anterolat-
eral teeth.... Ventral edges of root lobes and crown feet straight
or nearly so and horizontal on anterolaterals of lower jaw, giv-
ing teeth an inverted T shape." In his description, Compagno
does not mention the mesial cusplets that may occur on the up-
per anterior tooth as illustrated by Bigelow and Schroeder
(1948:277). Otherwise, the Lee Creek Mine teeth agree with
Compagno's description.
FIGURE 45.—Paragaleus sp., Pungo River Formation: a, USNM 207455, upper medial tooth, lingual view; b,
USNM 207456, upper anterior tooth, lingual view; c, USNM 207457, lower anterior tooth, lingual view; d,
USNM 207458, lower anterior tooth, lingual view; e, USNM 207459, lower anterolateral tooth, lingual view;/
USNM 207460, upper anterolateral tooth, lingual view; g, same specimen, labial view (reversed); h, USNM
207461, upper lateral tooth, labial view; i, same specimen, lingual view (reversed). (Scale bars=0.25 cm.)
142
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
The upper teeth from Lee Creek Mine have crowns that in-
cline distally, with smooth cutting edges that become serrated
basally on the distal enamel shoulder; the shoulder is separated
from the crown by a deep notch. Their crowns are elongate,
with convex distal and concave mesial cutting edges. As in the
extant species, often the tips of the crowns bend lingually but
not as much as those of the lower teeth. The upper teeth have
more compressed roots than do those of the lower teeth. On the
lingual face of the root there is a well-developed transverse
groove that penetrates the basal margin of the root.
In the lower jaw, the most anterior teeth lack the distal serra-
tions, and their crowns may be slightly contorted. In the region
of the transverse groove, their roots are thicker than those of
occluding upper teeth. The more distal anterolateral teeth pos-
sess serrated enamel shoulders.
Although Jonet (1966:81-83; emended in Antunes and Jo-
net, 1969-1970:169-171) described a new species, Paragaleus
pulchellus, for his specimens, insufficient specimens of the
four extant species are available to assess the validity of Jonet's
species; therefore, we refrain from identifying the Lee Creek
Mine specimens to a species.
The anterolateral teeth from Lee Creek Mine are 6.4 to 8.5
mm in height (mean=7.4 mm, n=6) and 6.6 to 9.2 mm in width
(mean=7.9 mm, n=6); they probably came from night sharks
between 1.5 and 1.7 m in total length.
According to Compagno (1984:442-444), Paragaleus inhab-
its tropical and warm-temperate waters off western Africa, the
northwestern India Ocean, and the western Pacific Ocean.
Paragaleus pectoralis preferentially feeds on squids but will
also take small bony fishes.
Genus Hemipristis, Agassiz, 1843
Compagno (1988:269-270) characterized the teeth of this
genus as follows: "The medials are very small, clawlike teeth
with very narrow roots and strongly hooked cusps; symphys-
ials are similar but larger, with broader symmetrical roots. Up-
per anteriors are abruptly larger, broader, and flatter than the
symphysials and differ from the laterals in having much nar-
rower roots and crowns. The lower anteriors are very high, nar-
row, deep-rooted and hook-cusped teeth having serrations or
cusplets, if any, confined to the crown foot, and form a spike-
studded impaling pad__The lower anteriors grade into the lat-
erals by becoming lower-crowned, broader, shorter-cusped,
and by having serrations or fine cusplets extending onto the
distal crown feet. Upper laterals are very broad, wide, triangu-
lar teeth, with compressed, horizontal-edged roots, broadly
convex mesial edges, and arcuate distal edges having coarse
serrations or cusplets. In small specimens the cusps of all the
teeth are slightly more oblique than those of adults and sub-
adults. In the young a few distal cusplets are present on upper
laterals (five on fifth upper laterals of a 532 mm. specimen) but
these become more numerous on adults and subadults (10 or
more on fifth upper lateral) and turn into coarse serrations."
Hemipristis serra Agassiz, 1835
Figures 46-48a
Horizon.—Pungo River Formation (units 1-6); Yorktown
Formation (units 1, 2, 3?).
Referred Material.—About 700 teeth, USNM 278198,
435197, 444191, 451274-451327, 474917, 474920-474940; 6
vertebrae, USNM 467528^67532.
Remarks.—The teeth of this species are among the most
common large-selachian remains occurring at the Lee Creek
Mine in both formations; their abundance permitted us to re-
construct their dentitions (Figures 46, 47).
The upper and lower symphysial teeth, the lower anterior
teeth, and the first two laterals from the lower jaw are awl-
like, with a few serrations or cusplets near the base of the
crown. The more distal lower lateral teeth have coarsely ser-
rated cutting edges and are much narrower than the upper lat-
eral teeth. The upper anterior and lateral teeth are subtriangu-
lar, labiolingually compressed, broad, and with coarsely
serrated cutting edges. One of the more characteristic features
of these teeth and of Hemipristis is the prominent lingual torus
of the root.
Hemipristis seems to increase in size through its evolution-
ary history as do some of the other large sharks of the Neogene.
At Lee Creek Mine, the largest teeth of Hemipristis, which are
30% larger than those from the Pungo River Formation, occur
in the lower Yorktown Formation. These teeth are the largest
yet reported in the literature. In the Tertiary sediments of Baja
California, Applegate (1986) also noticed this increase in tooth
size in Hemipristis; his tooth sizes correspond with those from
Lee Creek Mine and those (measured by R.W.P.) from the ear-
ly Miocene to early Pliocene of Florida. But is this size in-
crease an evolutionary change?
One exception to this increase in size through time does ex-
ist: the teeth of Hemipristis, collected in place with late Oli-
gocene whales and invertebrates (Sanders, 1980), range in
height from 12.2 to 25.8 cm (mean=19.4 cm, «=21). These
teeth compare in size with those from the middle and late Mi-
ocene. We question, therefore, whether this size increase is re-
lated to the evolution of Hemipristis; it may be due to ecologi-
cal changes favoring increasingly larger sharks, which in
earlier epochs may have inhabited areas not represented in the
available fossil record.
Are the Pungo River Hemipristis teeth those of juveniles?
As noted above, Compagno (1988:269-270) reported the oc-
currence of ontogenetic variation in the upper lateral teeth of
the extant species, namely, that the number of cusplets on the
distal cutting edge increases with age. In comparing the fifth
upper laterals of the reconstructed Hemipristis dentitions from
the Pungo River (tooth height=2.04 cm) and the Yorktown
(tooth height = 3.41 cm) formations, both teeth possess 14
coarse, distal serrations. Therefore, the smaller, Pungo River
Hemipristis teeth are from adults, possibly young adults. The
apparent size difference between the Pungo River and York-
NUMBER 90
143
FIGURE 46.—Hemipristis serra, Pungo River Formation, composite dentition, lingual view; second symphysial
and last lateral tooth of upper series and last three lateral teeth of lower series missing. (Scale bar=2.0 cm.)
FIGURE 47.—Hemipristis serra, Yorktown Formation, composite dentition, lingual view; two symphysials and
two posterior lateral teeth of upper series and one symphysial and 10 lateral teeth of lower series missing. (Scale
bar=1.0 cm.)
town populations of this shark (see Branstetter et al., 1987)
also may reflect different rates of growth.
Compared to the extant species, the crowns of the upper
teeth in both fossil dentitions are more erect than are those of
the adult female ofH. elongatus illustrated by Compagno
(1988, pl. 20N), whereas the attitudes of the crowns of the low-
er teeth of the fossil species are similar to those of H. elongatus
inhispl. 21N.
The sizes of the Hemipristis teeth from the Pungo River and
the Yorktown formations are contrasted below. Most of the
Pungo River specimens are from the ore horizons, units 1-3,
but some material from the upper Pungo River Formation is in-
cluded as well. The measured Yorktown specimens are from
units 1 and 2.
Pungo River Formation
Height
Width
Yorktown Formation
Height
Width
Range (mm)
14.1-29.1
12.3-35.5
16.4-^1.0
14.0^13.5
Mean
20.3
21.4
29.1
25.9
Number
20
20
27
27
Six vertebrae (Figure 48a) from Lee Creek Mine are identi-
cal with those associated with a dentition of Hemipristis serra
from the Calvert Formation. These are short, aseptate centra
144
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
with rectangular to suboval dorsal and ventral foramina; diago-
nal laminae bisect these foramina. In the vicinity of the forami-
na and along the rims of the centra, pores are usually present.
The extant species is a tropical coastal shark that inhabits
waters from 1 to 30 m in depth in the Red Sea and Indian
Ocean. It feeds on birds, sea catfish, mackerel, croakers, grey
sharks, and other fish (Compagno, 1984:441).
Family CARCHARHINIDAE
(requiem sharks)
Genus Galeocerdo Miiller and Henle, 1837
(tiger sharks)
Compagno (1988:279-280) described these teeth as follows:
"Dignathic heterodonty weak, but monognathic heterodonty
well-developed, with strongly differentiated medials and an-
teroposteriors in both jaws (anterolaterals grade into posteri-
ors), and lower symphysial. Sexual heterodonty absent. Onto-
genic heterodonty weak, with young having fewer cusplets,
narrower, longer, and more oblique cusps, and more angular
mesial edges on their anteroposterior teeth than adults.
... Anteroposterior teeth with characteristic cockscomb shape,
with oblique primary cusps and strongly notched distal edges.
Teeth secondarily anaulacorhizous, with no transverse groove
and notch [in basal margin of root]."
We would modify the above because the "strongly notched
distal edges" are not predominant in some fossil species (e.g.,
Galeocerdo latidens).
We tentatively identify three species of Galeocerdo from
Lee Creek Mine: Galeocerdo sp. (identified by others as G.
aduncus), G. contortus, and G. cf. G. cuvier. Our uncertainty
regarding G. sp. and G. cuvier arises from the wide range of
variability in tooth shape that exists in these sharks; our identi-
fication of G. contortus is uncertain because its anterior teeth
are unlike those of Galeocerdo.
During the Tertiary history of Galeocerdo, two basic tooth
forms reoccur and persist into the living species. In the earliest
known form, Galeocerdo latidens, the distal notch of the cut-
ting edge is not well developed. This tooth form, which is com-
mon in the middle Eocene, recurs in abundance in the early Mi-
ocene of Africa and in the late Miocene of Florida and
occasionally in the teeth of the extant species (Hubbell, private
collection; Alvaro Mones, pers. comm., 11 Jun 1991). The sec-
ond tooth form, with a deeply notched distal cutting edge, oc-
curs at widespread localities from the late Eocene (G clarken-
sis White from Alabama) to the present; this tooth form is
abundant in the late Oligocene of South Carolina, the middle
Miocene of the Chesapeake Group, and most Pliocene marine
deposits where Galeocerdo occurs. Rather than representing
taxonomic differences, because both tooth types occur in the
extant species, this patchwork distribution suggests to us that
the teeth of the fossil species and possibly the extant species
are highly variable in the development of the distal notch. Be-
cause of this variability, we believe that the taxonomy of this
genus needs revision and that the fossil species should be de-
fined on the basis of the predominant tooth morphotype of sev-
eral widely distributed, synchronous populations.
None of these tooth morphotypes, however, matches exactly
that of the teeth from the Pungo River Formation at Lee Creek
Mine, which have a well-developed distal notch and the lateral
extremities of the roots turned apically as in G. latidens. This
last character is not present in the teeth of Galeocerdo from
younger sediments.
Concerning the Pliocene teeth that we identify as G. cf. cuvi-
er, we believe that large samples of these teeth must be com-
pared with large samples of teeth from the extant tiger shark,
which are not presently available, to ascertain the identity of
the Pliocene teeth; this also applies to ascertaining the validity
of Applegate's G. rosaliensis.
Our uncertainty with Galeocerdo contortus concerns its ge-
neric identity. The teeth of G contortus differ markedly from
all other species of Galeocerdo. By comparing the teeth of G.
contortus to those of G. latidens and G. cuvier, we can contrast
these differences.
Like Galeocerdo cuvier, G. latidens has nearly homodont
teeth, and on the lingual face of the root, the lower anterior
teeth possess a slight but noticeable torus with a very shallow
transverse groove; this character is harder to discern in the ex-
tant species. In G. contortus, however, the lower anterior teeth
have well-developed toruses with deep transverse grooves
(Figure 48a"). Also, in the anterior anteroposterior teeth of G.
cuvier and G. latidens, the width of the tooth exceeds its
height, and in G contortus the opposite is true. In morphology,
the teeth of G contortus do not fit the pattern for this genus.
Both Leriche (1942) and Applegate (1978) proposed that the
teeth of G contortus were the lowers of G. aduncus. If they
are, for a carcharhinid, this shark had a very unusual dentition
because the heights of the lower anteriors (mean=15.7 mm,
«=136, range=12.0-19.4 mm) exceed those of the upper ante-
riors (mean= 14.0 mm, «=65, range= 10.7-16.8 mm), which is
the opposite of the condition in G. latidens and G. cuvier,
where the height of the upper teeth exceeds that of their lower
counterparts.
Also, in screen-wash samples of shark teeth from the Eocene
Castle Hayne Formation at Rose Hill, North Carolina, the teeth
of G. latidens (w=100) exhibit the weak dignathic heterodonty
seen in G. cuvier. Both uppers and lowers of the Eocene teeth
can be identified, and no G. contortus-type teeth of comparable
size (1.2-2.0 cm, anterolaterals) were found (G. contortus has
not yet been found in the Eocene). Therefore, we cannot agree
with the proposals of Leriche (1942) and Applegate (1978).
Cappetta (1980) placed teeth from the Paleocene and Eocene
similar to those of Galeocerdo contortus in his new genus
Physogaleus and assigned them to P. secundus (Winkler,
1874), which he made the type species of the genus. Unlike
Galeocerdo contortus, Cappetta's (1980, fig. 5A) specimens
possess a deep distal notch. Also, Winkler's two syntypes,
which are illustrated in lateral view only, are quite different in
morphology. Winkler's specimens possess orectilobiform rath-
NUMBER 90
145
er than carcharhiniform roots. Winkler described the root of the
type specimen as "a wide and robust root, of a remarkable
form: it presents a kind of a mound or a pyramid with three fac-
es, and with a wide base, that forms below a triangle with
rounded angles. In the middle of this lower face of the root one
observes a circular depression, while the enamel of the crown
forms a kind of ribbon, it terminates in a small tubercule on the
internal face of the root." Winkler did not mention the presence
of a transverse groove on the root, which is characteristic of
carcharhiniform teeth, and his "enamel ribbon" may be the peg
that is often found on the teeth of orectilobiform sharks. Until
Winkler's syntypes are found, the identity of Physogaleus re-
mains in doubt.
The characters of G. contortus are not characteristic of Gale-
ocerdo, but we feel that generic reassignment of these teeth
should await the discovery of an associated dentition and a
more thorough study of the Paleogene forms.
Size is often used to separate fossil and extant species of Ga-
leocerdo (Antunes, 1963; Antunes and Jonet, 1969-1970; Ap-
plegate, 1978, 1986). A recent study by Branstetter et al.
(1987) found that two populations of the extant species, one in
the Gulf of Mexico and the other in the Atlantic Ocean off the
coast of the southeastern United States, had different rates of
growth and that tiger sharks of known age from the Gulf of
Mexico were larger than individuals of equivalent age from the
Atlantic population. Also, Hubbell (pers. comm., 1990) noted
that the largest individuals of this species do not come from
these two populations but from the Pacific Ocean off Panama,
an area of upwelling and high food availability. Another study
by Lowe et al. (1996:209) indicated that tiger sharks segregate
by size—smaller ones live in shallow, nearshore waters,
whereas larger ones are more pelagic. If these distributions also
were true for fossil tiger sharks, then, except for nursery areas,
large teeth would occur in sediments deposited in pelagic wa-
ters, and small teeth would occur in sediments deposited in
shallow, nearshore waters. If this hypothesis is correct, then the
Neogene record of a size increase in tiger sharks may reflect an
increase in water depth and in the availability of prey in the ba-
sins of deposition rather than an evolutionary change.
In identifying the Lee Creek Mine tiger shark teeth, we be-
lieve that there is a wide range of variation in tooth morpholo-
gy within a species and that two species are represented in the
Miocene and another in the Pliocene. More extensive sampling
of Miocene and Pliocene shark tooth horizons may prove us
wrong.
Galeocerdo sp.
Figures 48b,e, 49
Horizon.—Pungo River Formation (units 1-6).
Referred Material.—About 200 teeth, USNM
451233-451251,464118, 464119, 476376.
Remarks.—Agassiz (1835, pl. 26: figs. 24-28, 1843:231)
characterized Galeocerdo aduncus as having a greater con-
FlGURE 48.—Hemipristis serra: a, USNM 467531, vertebra, dorsal view.
Galeocerdo sp.: b. USNM 476376, pointed serrations on mesial edge of tooth;
e, USNM 451240, basal view of root. Galeocerdo cuvier: c, USNM 476377,
pointed, compound serrations on mesial edge of tooth. Galeocerdo contortus:
d, USNM 451226, basal view of lower anterior tooth showing well-developed
torus. (Scale bars: a=0.5 cm; b,c=0.5 mm; d,e=033 cm.)
vexity in the distal enamel shoulder than exists in the living
species; this character, however, is variable in the fossil and
extant species. Cigala-Fulgosi and Mori (1979) described the
only character that may separate middle Miocene teeth identi-
fied traditionally as G. aduncus (=G. sp. herein) from G. cuvi-
146
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
er; they noticed that unlike the extant species, on the basal
half of the mesial edge of the tooth the serrations are simple
rather than compound (cf. Figures 48b, 48c). Incipient com-
pound serrations, however, may be present. We do not know
if these compound serrations are present or absent on Agas-
siz's holotype, which was deposited at the Staatliches Muse-
um fur Naturkunde, Karlsruhe, but is now lost. According to
Agassiz, the holotype was found in the Schwabia region of
southwestern Germany, where marine sediments were depos-
ited from the Burdigalian into the Zanclian. Because the exact
age of the type specimen cannot be determined, it may repre-
sent a juvenile of G. cf. cuvier, or it may be the species identi-
fied until now as G. aduncus by vertebrate paleontologists.
Without examining the type specimen, the identity of G.
aduncus cannot be ascertained. We believe, therefore, that
Galeocerdo aduncus is a nomen dubium and is not available
for use as a scientific name.
At this time, however, we hesitate to identify the next avail-
able junior synonym because the types of the subsequently de-
scribed species are not now available to us, and we do not
know their whereabouts. We believe that the resolution of this
problem must await a major revision of the fossil species of
this genus.
Figure 49 illustrates a reconstructed dentition of this spe-
cies. For illustration purposes, these teeth were separated by
spaces; the lingual recurvature of the lateral extremities of the
roots indicates that these teeth overlapped (Figure 48c), a con-
dition termed alternate-imbricate overlap by Compagno
(1988:31). The crowns of the upper teeth have a strong labial
curvature, and as in the extant species, they are slightly more
elongate than their lower-jaw counterparts. In our reconstruc-
tion, the lower medial, an upper posterior, and a lower poste-
rior tooth are missing; they were not found in the USNM col-
lections.
Well-preserved specimens of this species are found embed-
ded in the mold and cast limestones in the upper part of the
Pungo River Formation. The species also is common in ore-
sump residues and from the reject gravels screened from the
ore during processing. The condition of the few specimens
found on spoil piles of lower Yorktown Formation sediments
suggests that they were redeposited.
We have not seen the specimens described by Leriche (1942)
as Galeocerdo aduncus, but on the basis of his illustrations (pl.
7: figs. 33^12), the teeth appear to be the same as Galeocerdo
contortus Gibbes (see discussion of G contortus).
The anterior and anterolateral teeth range from 10.7 to 16.8
mm in height (mean=14.0 mm, «=65) and from 12.4 to 20.0
mm in width (mean= 16.2 mm, «=65). In the extant tiger sharks,
teeth of these sizes are found in individuals of 1.8-3 m TL.
Galeocerdo contortus Gibbes, 1848-1849
Figures 484 50
Galeocerdo acutus Storms, 1894:81-82, pl. 6: fig. 18 [Rupelian, Belgium].
Galeocerdo triqueter Eastman, 1904:89, pl. 32: fig. 12 [Calvert Formation,
Maryland].
Physodon triqueter Leriche, 1942:79 [Calvert Formation, Maryland].
Galeocerdo aduncus Agassiz.—Leriche, 1927:88, pl. 14: figs. 1-3, 6 [middle
Miocene, Switzerland]; 1942:87-88, pl. 7: figs. 33^12 [Calvert Formation,
Maryland].—Caretta,  1972:54-57, pl.  11: figs.  1, 2, 4 [middle Miocene,
Italy].
Horizon.—Pungo River Formation (units 1-6).
Referred Material.—About 600 teeth, USNM
451212^51232, 476386-476393.
REMARKS.—Galeocerdo contortus is distinguished from the
other small tiger shark of the Pungo River Formation, G. sp.
(see above), by the following criteria.
Galeocerdo sp.
Galeocerdo contortus
crown relatively thin, flat; margins
nearly in same plane
mesial margin of crown uniformly
curved in profile
serrations on enamel shoulder com-
pound, coarse
apex angle of crown 35°-50°
(mean=43°, n=16)
root relatively thin; like G. cuvier, lacks
prominent torus on lingual face
width of anterior anteroposterior teeth
exceeds height of tooth
crown thick, twisted; mesial margin
warped
mesial margin of crown flexuous in
profile
serrations on enamel shoulder simple,
fine
apex angle of crown 22°—40°
(mean=31°, n=40)
root thick, with prominent torus on
lingual face as in Hemipristis
height of anterior anteroposterior
teeth exceeds width of tooth
%g§  *$E0&
^    ^0
%j^     \*&    \f
** A> 3B*  ^*^ J& J^ J^ J^
FIGURE 49.—Galeocerdo sp., composite dentition, lingual view. (Scale bar= 1.0 cm.)
NUMBER 90
147
Galeocerdo contortus always occurs with G. sp. in Neogene
localities on the East Coast of the United States. Counts of
teeth collected by screen washing at Lee Creek Mine indicate it
is twice as common as G. sp. This ratio has been constant in
several separately collected samples.
Figure 50 represents a reconstructed dentition of this species.
In sorting the teeth, we identified both uppers and lowers. In
the lower teeth, a prominent, lingual torus is present, particular-
ly in the more anterior teeth (Figure 48a"), which becomes less
prominent in the more posterior teeth. The tips of the crowns of
these teeth exhibit the characteristic lingual bend. In the upper
teeth, the root is more compressed, and the tips of the crowns
have a noticeable labial curvature. Our reconstruction, based
on G. cuvier, includes all tooth positions except the upper me-
dial, if one is present, and one or two of the posterior teeth in
each jaw.
Cappetta (1987:123) stated that this species does not occur in
Europe, but specimens identified by Storms (1894) as Galeo-
cerdo acutus and by Leriche (1927) and Caretto (1972) as Ga-
leocerdo aduncus are the teeth of G. contortus.
In separating Galeocerdo contortus from G. sp. we asked
ourselves how the Pungo River environment supported two
such top predators. We compared the reconstructed dentition of
G. contortus with those of other carcharhinids; the narrow up-
per teeth are similar to those of Negaprion, which feeds on
bony fishes and rays. Unlike G. sp., which has broad-bladed
teeth for biting off chunks of flesh from larger animals, but like
Negaprion, G contortus had teeth for feeding on smaller bony
fishes and rays. Therefore, the dentitions of G. sp. and G. con-
tortus suggest that these two sharks did not compete for the
same prey.
Tooth height of the anterior and anterolateral teeth ranges
from 12.0 to 19.4 mm (mean=15.7 mm, «=136). Mesial-distal
width of these teeth ranges from 12.0 to 19.5 mm (mean=15.5
mm, n=136). The average tooth size of G. contortus is larger
than that of G sp.
Galeocerdo cf. G. cuvier Peron and LeSueur, 1822
FIGURES 51, 52a,b
Galeocerdo arcticus.—Leriche, 1942:88, pl. 7: figs. 1, 2 [Ashley phosphates
(=Goose Creek Formation), middle Pliocene].—[Not G arcticus Faber,
1829=G. cuvier Peron and LeSueur, 1822.]
Horizon.—Yorktown Formation (units 1-3).
Referred Material.—649 teeth, USNM 451213^151218,
451225^151230, 456327, 457287, 457288, 474941^174960; 1
vertebra, USNM 467534.
Remarks.—These teeth are as large as some of those of the
largest individuals of the extant species and are twice as large
as those of Galeocerdo aduncus (=G. sp. herein). They are
identical in many respects to the teeth of G. cuvier, but unlike
those of the extant species, the basal and apical portions of the
mesial cutting edge are straight; this edge presents a distinct
obtuse angle. In the extant species (Compagno, 1988:279) this
obtuse angle is predominant in the juveniles rather than in the
adults.
Lawley (1876:16-17) erected Galeocerdo capellini on the
basis of an isolated tooth from the Pliocene of Tuscany, Italy,
but he did not illustrate the holotype. He first illustrated two
teeth of this species from the type locality without referring to
either of them as the holotype (Lawley, 1881:145-146, pl. 1:
fig. 6, pl. 2: fig. 5). De Stefano (1909:578) synonymized this
species with G. aduncus. The tooth, however, in Lawley's pl.
2: fig. 5, which is enlarged, has compound serrations on its
mesial edge; therefore, it cannot be synonymized with G.
aduncus. Landini (1976:115-116) and Cigala-Fulgosi and
Mori (1979:125) noted that the Galeocerdo teeth from the
Mediterranean Pliocene are indistinguishable from the extant
species, and they synonymized the Pliocene species G. capel-
lini with G. cuvier. A decision, however, about the synonymy
of these two species must await the study of dental variation
in a larger sample of G. cuvier from various parts of the
world.
*xy ytw^^ttt
* *
^CiAiJC j*.
Figure 50—Galeocerdo contortus, composite dentition, lingual view. (Scale bar-1.0 cm.)
148
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

a —
«
y
f
«/
*a
Figure 51.—Galeocerdo cf. C. cuvier: o, composite dentition, lingual view; b, USNM 457287, pathologic
tooth, lingual view; c, same specimen, labial view; d, same specimen, lateral view; e, USNM 457288, pathologic
tooth, lingual view;/ same specimen, labial view. (Scale bars: a=I.O cm; fr-/=0.33 cm.)
NUMBER 90
149
Applegate (1978) erected the species Galeocerdo rosaliaen-
sis for Pliocene teeth from Baja California, Mexico, and stated
that this species is distinguished "by having the combination of
large size and shape similar to G. cuvier, but with the upper
half of the anterior border flattened" (Applegate, 1978:59).
These characters also occur in G. capellini and G. cuvier;
therefore, we believe that Applegate's species is a junior syn-
onym of G. capellini Lawley.
A reconstruction of a dentition of this species (Figure 51a)
shows that, as in the extant species, the tips of the crowns of the
lower teeth have a slight lingual bend, whereas the tips of the
upper teeth have a noticeable labial curvature; however, this la-
bial curvature is obscured in teeth that have convex, labial,
coronal surfaces. In the lower teeth, a slightly developed torus
is present on the lingual surface of the root, and the arch
formed by the root is often asymmetrical (skewed distally),
whereas the arch of an upper-tooth root is usually more sym-
metrical.
Two pathologic teeth, USNM 457287 and 457288, were col-
lected by Frank and Becky Hyne (Figure 5\b-f). Gudger
(1937) and Cadenat (1962) noticed these pathologies in the ex-
tant species, but they were unable to identify their cause. In
other species of sharks, Cadenat (1962) found that similar de-
formities were due to the tooth germs being damaged by sting-
ray or sea catfish spines, and Compagno (1984:505) reported
that tiger sharks prey on these animals.
Tooth height ranges from 13.5 to 29.1 mm (mean=22.2 mm,
«=38). Mesial-distal width ranges from 24.4 to 33.0 mm
(mean=28.9 mm, n=38). Apical angle, the angle between the
mesial and distal margins at the apex, ranges from 45° to 65°
(mean=52°, «=33).
One vertebra (Figure 52a, b) from Lee Creek Mine, probably
from the Yorktown Formation, exhibits the characters identi-
fied by Kozuch and Fitzgerald (1989) as belonging to Galeo-
cerdo. The centrum is aseptate with scattered pores, and the
dorsal and ventral foramina are oval and do not extend to the
rims of the centrum.
According to Compagno (1984:504), the extant tiger shark is
a "wide-ranging coastal-pelagic tropical and warm-temperate
shark. ...It often occurs in river estuaries, close inshore off
wharves and jetties in harbours." He reported (1984:505) that it
preys on a variety of fishes (including sea catfish, tarpon,
mackerel, porcupine fishes, and puffers), marine reptiles, sea
birds (including shearwaters, frigate birds, pelicans, and cor-
morants), marine mammals (including seals, monk seals, and
odontocete whales), carrion, and mollusks. Compagno
(1984:505) reported that "this shark takes marine reptiles more
than any species, and frequently preys on sea turtles (green,
loggerhead, and ridley turtles) and is one of the most important
predators on sea snakes."
Genus Carcharhinus Blainville, 1816
Until recently, the taxonomic confusion that existed in the
extant sharks of this genus hampered identification of the fossil
teeth. Many paleontologists assigned the fossil teeth of Car-
charhinus to different genera and assigned teeth now attribut-
able to two or more species to one fossil species. Garrick
(1982, 1985), however, revised the taxonomy of this genus and
included descriptions and illustrations of the teeth of each spe-
cies. Compagno's work (1984, 1988) also has added important
information about the identity of these sharks on the basis of
teeth. These works and the available dentitions of the extant
species suggest that the differences in dental characters be-
tween species is often subtle.
Naylor and Marcus (1994) developed a morphometric meth-
od for analyzing the variation in the upper teeth of Carcharhi-
nus that segregates the teeth of the many extant species of this
genus, and at present Naylor is developing this technique for
the study of fossil species of this genus. When developed, his
method may facilitate the identification of the Lee Creek Mine
species.
The tooth types present in this genus include upper and lower
medials or alternates, usually lower symphysials, upper anteri-
ors, upper lateroposteriors, lower anteroposteriors, and upper
and lower posteriors. Compagno (1988:310) provided some ge-
neric characteristics for the teeth, noting,
[The anterior teeth of the lower jaw are] absent or poorly differentiated. Upper
anteriors are usually abruptly narrower based than adjacent laterals. Sexual het-
erodonty usually absent or weak,... ontogenic heterodonty very variable in dif-
ferent species. Teeth often have thicker, less oblique cusps, and more numer-
ous, less course [sic], and stronger serrations in adults than young. Cusplets,
where present, are often better developed in young than adults, where they may
disappear entirely or become coarse serrations. [In adults] crowns moderately
high and cusps variably short to very long on teeth of both jaws. Cusps variably
erect or oblique on the upper teeth, usually more or less erect on lower teeth but
oblique in some species. Most species have well-developed serrations along
the entire edges of the upper teeth. Some either lack them at all stages (C. ma-
cloti) or have them poorly developed or absent in young (C. brevipinna, C. is-
odon and C. leiodon) and poorly to well-developed in adults (C. brevipinna and
C. isodon). Cusplets are entirely lacking from lower teeth but are variably de-
veloped on upper teeth. Some species have distal cusplets on their upper teeth
when young but lose them when adult (C. melanopterus); in others these per-
sist throughout life (C. dussumieri, C. sealei, C. signatus and C. macloti). Me-
sial cusplets are sometimes present on upper teeth (as in C. falciformis, C. sig-
natus adults, and C. macloti). Roots of lower anterolateral teeth usually with
nearly straight ventral edges but these are moderately to deeply arched in a few
large-toothed species (such as C. leucas and C. ambionensis). Teeth usually
holaulacorhizous, with transverse notches and grooves, but these are some-
times absent. Basal ledges and grooves are vestigial or absent on tooth crowns.
Hundreds of vertebrae assignable to this genus were found
at the mine; five different morphotypes, which may be found
in one or several species, are illustrated herein (Figure 52c-/).
In cranial or caudal view, these aseptate vertebrae may be
round or oval in outline; the ventral edge may be concave, and
the dorsal edge may be slightly pointed (see Kozuch and
Fitzgerald, 1989). The dorsal and ventral foramina also vary
in shape, being square, rectangular, or oval. Too few speci-
150
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 52.—Galeocerdo cf. G cuvier. USNM 467534, vertebra: a. dorsal view; b, ventral
view. Carcharhinus spp., vertebrae: c. USNM 467600, ventral view; d. same specimen, view
of articular surface; e, USNM 467360, dorsal view;/ same specimen, view of articular sur-
face; g, USNM 467602, ventral view; h, same specimen, view of articular surface; i, USNM
467601, dorsal view;/ same specimen, view of articular surface; k, USNM 467599, dorsal
view; /, same specimen, view of articular surface. (Scale bars=I.O cm.)
mens of the extant species are available to identify them to
species.
At least seven species of Carcharhinus may be distinguished
tentatively among the Lee Creek Mine teeth: C brachyurus, C.
falciformis, C leucas, C macloti, C. obscurus, C. perezi, and
C. plumbeus. Because tooth morphology varies greatly in the
small number of dentitions now available from the extant spe-
cies, the characters that we use to identify them may, after ex-
amination of larger numbers of dentitions, fall within the range
of intraspecific variation in two or more species.
NUMBER 90
151
Carcharhinus brachyurus (Giinther, 1870)
Figure 53a
Corax egertoni Agassiz, 1843:228, pl. 36: fig. 6 [Miocene, Maryland].
Carcharhinus egertoni (Agassiz).—Antunes and Jonet, 1969-1970:189-190,
pl. 15: figs. 110, 111 [middle Miocene, Portugal].
Carcharhinus priscus (Agassiz).—Cappetta, 1970:54-57, pl. 13: figs. 8-19
[middle Miocene, France].
Prionodon egertoni (Agassiz).—Leriche, 1942:80-82, pl. 7: fig. 4 [middle Mi-
ocene, Maryland].
Sphyrna americana Leriche, 1942:86, pl. 6: figs. 7, 8 [fig. 6=C. cf. limbatus;
early Pliocene, South Carolina].
Sphyrna prisca eastmani Leriche, 1942:85, fig. 7, pl. 7: figs. 28-32a [middle
Miocene, Maryland].
HORIZON.—Pungo River Formation (units 1-5).
Referred Material.—About 500 teeth, USNM
463978-463998,474888^174902.
Remarks.—These teeth (Figure 53a) compare favorably
with those of mature females of the extant species. Compagno
(1984:465) characterized the upper teeth of the living species
as having "narrow, strongly serrated, semierect to oblique
[crowns], high bent cusps and transverse roots." All of these
characters exist in teeth identified to this species from Lee
Creek Mine. In our examination of dentitions (e.g., USNM
197665) from the recent species, we found that the upper teeth
may be finely serrated rather than strongly serrated as indicated
by Compagno. Although these teeth may be confused with
those of Carcharhinus perezi, the convexity or angle of the me-
sial cutting edge gives the tooth a truncated appearance, and the
teeth are narrower than those of C. perezi.
According to Bass et al. (1973:24), the upper teeth of "large
males are distinctly hooked near the tips as compared to those
of females." Garrick (1982:175) added that compared to fe-
males, the upper teeth of males are proportionately longer and
narrower, are more oblique to curved laterally, and have finer
serrations. In females, hooked upper teeth do occur in the more
posterior regions of the jaws but not in the anterior regions; it is
in the posterior region of the jaw that this sexual dimorphism is
more pronounced. None of the upper teeth of this species ex-
amined from Lee Creek Mine exhibit the characteristics found
in the teeth of males.
Although the two syntypes of Corax egertoni were not avail-
able to us for this study, one of them (Agassiz, 1843, pl. 36: fig.
6) is identical to those of the extant C. brachyurus. According
to Agassiz (1843:228), these specimens are from the Tertiary
of Maryland. The teeth of C. brachyurus are common in the
Calvert Formation of Maryland and Virginia.
At Lee Creek Mine, the anterolateral teeth range from 1.2 to
1.5 cm in height (mean=1.4 cm, n=2\) and from 1.3 to 1.8 cm
in width (mean=1.6 cm, «=21); in the extant species, teeth of
this size are found in individuals of 2 to 3 m TL.
According to Compagno (1984:465), the extant species is
poorly known; it inhabits inshore to offshore warm-temperate
waters from the surfline to at least 100 m in depth. It eats a va-
riety of bony fishes, including sea catfish, porgies, and hake, as
well as spiny dogfish, rays, squid, and cuttlefish.
Carcharhinus falciformis (Bibron, 1841, in Miiller and
Henle, 1839-1841)
Figure 5sb-f
Prionodon egertoni (Agassiz).—Leriche, 1942:80-82, pl. 7: fig. 3 [Piocene,
North Carolina, South Carolina],
HORIZON.—Pungo River Formation (units 2-4).
Referred Material.—5 teeth, USNM 476244-476248.
Remarks.—Among the teeth from Lee Creek Mine (Figure
53b-f), we were able to identify only the uppers, which are
identical with those of the extant species. On the lingual face of
the root and penetrating its basal margin there is a well-devel-
oped transverse groove. The distal cutting edges of these mod-
erately broad-bladed teeth have a shallow, angular notch; api-
cal to this notch the cutting edge is perpendicular to a line
tangent to the basal margin of the root; basal to this notch, there
is an enamel blade, which is finely serrated like the apical por-
tion of the cutting edge. On their mesial cutting edges, at about
the midpoint between the tip and the base of the cutting edge,
there is a gap in the serrations. Basal to this gap the serrations
are larger and therefore coarser. With the exception of this gap,
the mesial cutting edge is fairly straight from the base to the tip
of the crown. This gap in serrations and the straightness of the
mesial cutting edge are characteristic of Carcharhinus falcifor-
mis.
In the extant species, the upper teeth vary somewhat in mor-
phology. In USNM 232776, from a 2 m TL female, the tips of
the crowns are slightly hooked, and in USNM 196026, from a
2.27 m TL female, the teeth are not hooked but are more distal-
ly inclined. The mesial gap in the serrations is absent. In
USNM 232780, from an unsized male, the mesial edge has a
dog-leg turn as in C. brachyurus, and in USNM 112584, from
2.3 m TL male, the shallow, distal notch is rounded rather than
angular.
Among the Lee Creek Mine specimens, the only anterior an-
terolateral tooth present measures 14.2 mm in height and 15.0
mm in width; it came from an individual of probably 3 m TL.
The extant silky shark inhabits warm, nearshore waters from
depths of 18 to 500 m. It feeds primarily on bony fishes, in-
cluding sea catfish, yellowfin tuna, albacore, and porcupine
fish (Compagno, 1984:471^472).
Carcharhinus leucas (Valenciennes, 1839,
in Miiller and Henle, 1839-1841)
Figure 54a
Corax egertoni Agassiz, 1843:228, pl. 36: fig. 7 [Miocene, Maryland].
Prionodon egertoni (Agassiz).—Leriche, 1942:80-82, pl. 7: figs. 11,12.
Horizon.—Pungo River Formation (units 1-5); Yorktown
Formation (units 1-3).
Referred Material.—About 200 teeth, USNM 278376,
278379, 278381, 278386, 278398, 278411, 278428, 278436,
282953,457079, 457084,459778^159820,474961.
REMARKS.—These teeth (Figure 54a), abundant in the York-
town Formation and very rare in the Pungo River Formation at
152
FIGURE 53.—Carcharhinus brachyurus: a, compos-
ite dentition. Carcharhinus falciformis: b, USNM
476244, upper anterolateral tooth, lingual view; c,
USNM 476245, upper anterolateral tooth, lingual
view; d, USNM 476246, upper anterolateral tooth,
lingual view; e, USNM 476247, upper anterior
tooth, lingual view;/ USNM 476248, upper sym-
physial tooth, lingual view. (Scale bars: a= 1.0 cm;
b-f= 1.0 cm.)
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
JEW J^ -^ As fisfl^- *"**
^T      c       d— e     f
Lee Creek Mine, are identical to those of the extant species.
The lower teeth have thick crowns and roots, and the cutting
edges are finely serrated. In some lower teeth the transverse
groove is well developed and penetrates the basal margin of the
root so as to be visible from the labial side of the tooth; in oth-
ers, which appear to be functional teeth, the transverse groove
is only partially developed or is absent. The basal margin of the
root is arcuate. Punctae may be present on the labial face of the
root and also on the roots of the upper teeth.
The form of the upper teeth tends to be equilateral rather
than elongate. Both cutting edges are finely serrated, with
coarser serrations basally. The mesial cutting edge of the
crown is straight, wavy, or slightly convex apically; the shal-
low, angular notch is absent. The distal cutting edge is usually
concave, but a shallow, angular notch may be present. The
basal margin of the root is usually arcuate but may be angular.
In one recent dentition (USNM uncataloged, vertebrate pale-
ontology synoptic collection) the roots of the upper teeth are
nearly lobate.
The upper teeth of this species are very similar to those of
Carcharhinus longimanus. Although the teeth of the latter spe-
cies are usually more elongate than are those of C. leucas, one
dentition (USNM 183804) has teeth that are equilateral in
form, giving them a stocky appearance. These teeth, however,
have broader crowns than do those of C. leucas, and in C. leu-
cas the distal cutting edge in the area of the crown foot usually
forms a noticeable blade.
The lower teeth also are similar to those of C longimanus. In
the latter species the crowns of the anteriors and the anterior
laterals are asymmetrical; in C. leucas they are almost symmet-
rical, but for both species, these observations were made on a
small number of dentitions, and in larger populations of these
species they may not be valid.
One of Agassiz's two syntypes (1843, pl. 36: fig. 7) for Co-
rax egertoni compares favorably with a lateral tooth of Car-
charhinus leucas.
The teeth identified and figured by Leriche (1942) as Prion-
odon egertoni represent several species of Carcharhinus, but
his figs. 11 and 12 of pl. 7 compare favorably with the teeth of
the extant C. leucas.
Cappetta (1987:125-126, fig. 106D) identified a tooth from
the Yorktown Formation at Lee Creek Mine as Pterolamiops
longimanus; Pterolamiops is a junior synonym of Carcharhi-
nus (Compagno, 1988), and Cappetta's tooth also may belong
to C. leucas.
The anterolateral teeth from the Pungo River Formation
range from 1.7 to 2.0 cm in height (mean height= 1.9 cm, n=8)
and from 1.6 to 2.2 cm in width (mean width=1.9 cm, «=8),
which falls in the range of teeth sizes in the extant species
from individuals of 2 to 3 m TL. Those from the Yorktown
Formation range from 1.9 to 2.4 cm in height (mean
height=2.1 cm, «=16) and from 1.9 to 2.5 cm in width (mean
width=2.3 cm, n= 16) and probably came from individuals of
2 to 4 m TL.
Compagno (1984:479) stated that the extant species inhab-
its shallow, tropical and subtropical waters "less than 30 m
deep and occasionally less than a meter deep, but ranging into
deeper water close to shore down to at least 152 m depth."
The extant shark feeds on bony fishes, including tarpon, sea
catfish, tuna, sea bass, and bluefish, and on sharks, rays, sea
turtles, birds, whales, and invertebrates (Compagno,
1984:480).
Carcharhinus macloti (Miiller and Henle, 1839)
Figure 546
Hypoprion acanthodon (Le Hon).—Antunes and Jonet, 1969-1970:187, pl. 15:
figs. 100-108 [Miocene, Portugal].
Horizon.—Extremely abundant in the ore layers of the Pun-
go River Formation (units 1-3); less abundant but still the
dominant carcharhinid in units 4 and 5; uncommon and proba-
bly redeposited in the base of the Yorktown Formation (unit 1).
Referred Material.—More than 400 isolated teeth,
USNM 207464, 464164-464179, 464181, 464183-464185,
474903-474914.
NUMBER 90
153
FIGURE 54.—a, Carcharhinus leucas, composite dentition; b, Carcharhinus macloti, composite upper dentition.
(Scale bars= 1.0 cm.)
Remarks.—Until recently this species was assigned to the
genus Hypoprion, but Raschi et al. (1982) have shown that this
genus is a junior synonym of Carcharhinus. Compagno (1984,
1988) and Garrick (1985) concurred with their decision.
The upper teeth (Figure 54b) are small (3-7 mm in height,
3-8 mm in width), triangular, acutely pointed, and, except on
the mesial and distal enamel blades, have smooth cutting edg-
es. In two-thirds of the sample, the mesial enamel blade is ser-
rated with one to five cusplets (mean=1.6; «=320). These ser-
rations, which are unevenly developed, range from distinct,
well-differentiated cusplets to indistinct, wavy interruptions of
the mesial cutting edge. The distal enamel blade is rounded or
rectilinear, with one to seven poorly to well-developed cusplets
(mean=3.1; «=309). The anterior teeth tend to be erect and bi-
laterally symmetrical, with short, convex, mesial and distal
enamel blades. Toward the commissure of the jaws, the more
posterior teeth become increasingly inclined, with a correlated
deepening of the distal notch formed between the main cusp
and its enamel blade. The root's rounded, lingual face is divid-
ed by a rather broad transverse groove, which penetrates the
basal margin of the root.
According to Garrick (1985:17), the number of large serra-
tions present on the upper teeth is variable; he reported that "in
four juveniles and subadults (both sexes)... there were 1-2 ser-
rae laterally and 0-1 medially, whereas in a mature
female... there were up to 4 laterally and 3 medially; contrast-
ing this with a mature male... [the male] had not more than 2 or
3 laterally (and these poorly defined) and 0 medially; the dif-
ference between these two adults may reflect either sexual di-
morphism or geographic variation."
The lower teeth are smaller than the upper teeth and are sym-
metrical and broad based, have narrow principal cusps, and
lack cusplets and serrations.
The anterolateral teeth of this species range from 5.0 to 7.3
mm in height (mean height=5.6 mm, «=21) and from 5.0 to
9.1 mm in width (mean width=6.6 mm, «=21). Although we
did not have any dentitions from individuals of known size,
these measurements fall within the size range for the extant
species, 69-100 cm TL (Compagno 1984:487).
According to Compagno (1984:487), this tropical, little-
known, inshore shark inhabits continental and insular shelves.
Carcharhinus obscurus (Le Sueur, 1818)
Figure 55a
Horizon.—Yorktown Formation (units 1-3).
Referred Material.—About 110 teeth, USNM
456596^156635, 457077^157089.
REMARKS.—These teeth (Figure 55a) compare very closely
with those of the extant species. The upper teeth of this species
are identified by their vertical to almost vertical distal cutting
edges and by their apically convex mesial cutting edges; the tip
of the tooth appears to be deflected distally. We could not iden-
tify the lower teeth with certainty.
In three dentitions of the extant species, we observed the fol-
lowing morphological variations. The number of rows of sym-
physial teeth varies from one to three in the lower jaws and
from one to two in the upper jaws. In AMNH 89233 SD, in the
anteriormost upper teeth near the apex, the mesial cutting edge
is straight rather than convex. In both the upper and lower teeth
of the same dentition, the root lobes of the teeth form obtuse
rather than straight angles, and in the lower teeth the basal con-
striction of the cutting edges is absent. A juvenile dentition
(AMNH 89269 SD) has lower teeth with smooth to incipiently
serrated cutting edges and has upper teeth with incipient serra-
tions present.
The upper anterolateral teeth from Lee Creek Mine range in
height from 1.7 to 2.2 cm (mean=1.9 cm, n=32) and from 1.8
to 2.5 cm in width (mean=2.1, «=32). In the extant species,
teeth of this size are found in sharks of 3 m TL.
154
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
T"y yp
-^ -^
Figure 55.—a, Carcharhinus obscurus. composite denti-
tion; b. Carcharhinus perezi. composite upper dentition.
(Scale bars=1.0 cm.)
According to Compagno (1984:490^191), the extant dusky
shark is "a common, coastal-pelagic, inshore and offshore
warm-temperate and tropical shark of the continental and insu-
lar shelves and oceanic waters adjacent to them." This species
feeds on bony fishes, such as tunas, barracuda, jacks, and blue-
fish; sharks, as well as sawsharks, angelfish, and dogfish; and
invertebrates.
Carcharhinus perezi (Poey, 1876)
Figure 556
Horizon.—Pungo River Formation (units 3-5); Yorktown
Formation (unit 1).
Referred Material.—50 teeth, USNM 463977,
464007-464010, 464012, 464014-464026, 464028-464046,
474874^174887.
Remarks.—The teeth from Lee Creek Mine (Figure 55b)
compare favorably with those of the extant species. In the ex-
tant species, the crowns of the upper teeth are fairly narrow,
and except for the teeth in the two anteriormost positions,
they incline distally; the distal angular notch may be well de-
veloped, or it may be rounded. The mesial cutting edge ranges
from being slightly convex to being nearly straight. In the
lower teeth, the erect crowns have complete, smooth cutting
edges. These same characters are found in the Lee Creek
Mine teeth.
The Lee Creek Mine teeth range in height from 1.3 to 1.8 cm
(mean=1.4 cm, «=40) and in width from 1.3 to 2.2 cm
(mean=1.7 cm, «=37); in the extant species teeth of this size
are found in individuals of about 2 m TL.
Compagno (1984:493) reported that this tropical shark is
found inshore on "continental and insular shelves, at depths
down to at least 30 m." This shark eats bony fishes.
Carcharhinus plumbeus (Nardo, 1827)
Figure 56
Horizon.—Pungo River Formation (units 4, 5); Yorktown
Formation (unit 1).
Referred Material.—6 specimens, USNM 459788,
474962^174965, 476293.
Remarks.—The upper teeth of this species are of moderate
width; they are narrower and more elongate than those of Car-
charhinus obscurus, and they lack the apical convexity of the
cutting edge that characterizes the latter species. They may be
confused with the elongate teeth of C. albimarginatus, but in
this last species the tips of the teeth are hooked, and midway
between the tip and the root on both cutting edges there is a no-
ticeable, shallow notch. After the seventh tooth from the sym-
physis, the mesial notch is lost.
An amateur collector, Bill Heim, first identified a tooth from
Lee Creek Mine that matches perfectly with the first upper an-
terolateral tooth in the dentition (Figure 56a) of the extant spe-
cies. Five other teeth (Figure 566-e) were recovered from the
spoil piles; in one of these, which may not be a fully functional
tooth, the transverse groove is absent.
The three teeth that are from the anterior part of the jaw mea-
sure 1.4 cm, 1.6 cm, and 1.9 cm in height. Extant sandbar
sharks with teeth of this size are about 2 m in total length.
Compagno (1984:494) stated that the extant species is a
"coastal-pelagic shark, of temperate and tropical waters, found
on continental insular shelves and in deep water adjacent to
them." It feeds on "relatively small bottom fishes" (Compagno,
1984:495), including porgies and searobins, and on mollusks
and crustaceans.
NUMBER 90
155
FIGURE 56.—Carcharhinus plumbeus, upper antero-
lateral teeth: a, USNM 459788, lingual view; b,
USNM 474962, lingual view; c, USNM 474963, lin-
gual view; d, USNM 474964, lingual view; e,
USNM 476293, lingual view. (Scale bars: a-d= 1.0
cm; e= 1.0 cm.)
Rhizoprionodon? sp.
Figure 57a-g
HORIZON.—Pungo River Formation (units 1-5).
Referred Material.—About 50 isolated teeth, USNM
207535-207540.
REMARKS.—In the extant Rhizoprionodon, Compagno
(1988:295-296) noted the following: "Dignathic heterodonty
weak and best developed in anteroposteriors closest to the sym-
physis, these teeth having higher roots and crowns and more
arched root edges in the upper jaw than in the lower. Upper lat-
erals have slightly higher crowns, slightly stouter cusps, and
less concave mesial edges than the lowers. Tooth row groups
include small, weakly differentiated, and often double-bladed
and erect-cusped medials, 2-3 rows of weakly differentiated
upper anteriors, sometimes a lower symphyseal, and poorly
differentiated posteriors. The anteriors differ from adjacent lat-
erals in having narrower and higher crowns__Fine serrations
present on teeth of adults of larger species__Tooth roots and
crowns relatively low and deep. Teeth holaulacorhizous, with
transverse notches and grooves. Basal ledges and grooves ab-
sent or poorly defined on teeth."
Springer (1964) revised and redivided the genus Scoliodon
into three genera: Rhizoprionodon, Loxodon, and Scoliodon
sensu stricto. Each has very similar teeth, all of which are con-
vergent or parallel to those of some species of Sphyrna. Conse-
quently, Springer was pessimistic about identifying the isolated
teeth of these genera.
Compagno (1984, 1988) included tooth characters in his di-
agnoses for the species of Rhizoprionodon, but with one ex-
ception, he also listed these as characters for Scoliodon and
Loxodon. The one exception is the presence of serrations in
the teeth of Rhizoprionodon. The Lee Creek Mine teeth,
which have smooth or weakly serrated cutting edges, are iden-
tical in form to those Compagno (1988, pl. 22G, 23G) illus-
trated, but until more is known about the usefulness of these
dental characters, we assign fossil teeth to this genus only ten-
tatively.
These fossil teeth (Figure 57a-g) are characterized by a com-
bination of concave mesial cutting edges both on upper and
lower teeth, smooth or indistinctly serrated cutting edges, deep-
ly notched distal cutting edges, erect crowns, and distinct
enamel shoulders. These characters, except for the notch on the
distal enamel shoulder, are shared more or less by all species of
Sphyrna with nonserrated teeth. Teeth from the lower jaw of
these species of Sphyrna (e.g., 5". tiburo) are similar to those
from the upper jaw of Rhizoprionodon, but differences exist in
their proportions. Relative to their width, the crowns in
sphyrnid teeth are higher than those of Rhizoprionodon, and the
primary cusp is relatively wider. The Lee Creek Mine teeth
closely resemble the more distinctive lower teeth of the extant
Rhizoprionodon terraenovae. We found no certain criteria to
eliminate Loxodon or Scoliodon.
European Miocene representatives of the Scoliodon group
have been referred to Rhizoprionodon taxandriae (Leriche,
1926; Antunes and Jonet, 1969-1970; Cappetta, 1970). Ler-
iche's (1926, pl. 28: figs. 7-10) specimens of Carcharias
(Scoliodon) taxandriae are poorly preserved, and certainly not
all of them are Scoliodon sensu lato. The specimen in Leriche's
fig. 7 is indeterminate; Cappetta (1970:62) thought it was Gale-
orhinus affinis. Leriche's fig. 10 probably represents a small
sphyrnid, and the specimens in his figs. 8 and 9 are either upper
teeth of Rhizoprionodon or lower teeth from a smooth-toothed
sphyrnid. Until these latter two specimens can be compared to
the teeth of the extant species of Rhizoprionodon and Sphyrna,
the validity of R. taxandriae remains in doubt.
Three of the fossil teeth are from the more anterior portion of
the jaw; they range in height from 3.2 to 5.2 mm (mean=4.1)
and in width from 4.3 to 5.7 mm (mean=4.3).
The extant species, Rhizoprionodon terraenovae, inhabits
coastal warm-temperate to tropical seas from the intertidal
zone to a depth of possibly 280 m (Compagno, 1984:533); it
feeds on small bony fishes, including small jacks and tilefish.
Genus Negaprion Whitley, 1940
(lemon sharks)
Compagno (1988:342) characterized the teeth of this genus as
follows: "Tooth row groups include upper and lower medials,
lower symphysials [sic], upper anteriors, upper lateroposteriors,
and lower anteroposteriors (or upper laterals, lower anterolater-
als, and lower posteriors). Anteriors differ from adjacent later-
als only in being smaller and narrower relative to their heights.
Sexual heterodonty apparently little developed. Ontogenic het-
156
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
erodonty moderate: small specimens of 500-600 mm. total
length have more oblique cusps, weaker mesial blades, and lack
serrations on the blades of their upper lateroposterior teeth, but
larger examples between 1-2 meters length have more erect
cusps, stronger mesial blades and basal serrations.... Cusplets
present on upper teeth of individuals below 650 mm. but lost in
larger specimens. Roots of lower anterolateral teeth with nearly
straight to slightly arched ventral edges. Teeth holaula-
corhizous, with very weak transverse grooves and transverse
notches weak or absent. Basal ledges very weak but faintly indi-
cated even in teeth of adults, sometimes with nodular edge rep-
resenting vestigial transverse ridges."
Negaprion eurybathrodon (Blake, 1862)
Figure 57/i-y
Carcharias collata Eastman, 1904:85-86, pl. 32: figs. 3-5 [Miocene, Mary-
land],
Carcharias magna (Cope).—Eastman, 1904:86, pl. 32: figs. 6, 7 [Calvert For-
mation, Maryland].
Sphyrna magna (Cope).—Leriche, 1942:85 [citation].
lAprionodon cf. collata (Eastman).—Leriche and Signeux, 1957:35, pl. 11:
figs. 12, 13 [Miocene, France].
Negaprion cf. eurybathrodon (Blake).—Antunes and Jonet, 1969-1970:
175-177, pi. 13: figs. 80, 81 [middle Miocene].
Negaprion kraussi (Probst).—Cappetta, 1970:52-53, pl. 15: figs. 1-10, ?11,
12, 14-17 [early Miocene, France].
Horizon.—Pungo River Formation (unit 4 or 5; 1 tooth);
Yorktown Formation (units 1, 2).
Referred Material.—31 teeth, USNM 207490-207492,
451333-451340.
Remarks.—Blake (1862) described a Miocene tooth of this
species as that of Lamna eurybathrodon. White (1955) ob-
served that the carcharhinid tooth recorded by Blake was ac-
tually a Negaprion upper tooth and that teeth of the same gen-
eral form were widely distributed in Miocene deposits. In the
same paper he noted correctly that the teeth described by
Eastman (1904) as Carcharias collata were the lower teeth of
Negaprion, and that the teeth figured by Eastman (1904) and
referred to C. magna (Cope) also should be referred to Negap-
rion, but he hesitated to synonymize C. magna and N. eury-
bathrodon. More recently, Antunes and Jonet (1969-1970)
have rightly synonymized the two species. Cappetta
(1970:52) referred his specimens of Negaprion to N. kraussi
(Probst), but Antunes and Jonet (1969-1970:176) pointed out
that the specimens that Probst described as Carcharias (Scoli-
odon) kraussi were in poor condition and may be either
Sphyrna or Negaprion. If they are Negaprion they are a junior
synonym of N. eurybathrodon; thus TV. kraussi of Cappetta,
but not necessarily C. (Scoliodon) kraussi Probst, is a junior
synonym of N. eurybathrodon (Blake). If, however, these
teeth are identical to those of TV. brevirostris (Poey), as they
appear to be, N. brevirostris must be synonymized with
Negaprion eurybathrodon.
The anterolateral teeth from Lee Creek Mine range in size
from 1.4 to 2.1 cm (mean=1.6 cm, «=9). In the extant lemon
shark, teeth in this size range are found in sharks of 2.1-3 m
TL, which is the size range for mature adults (Compagno
1984:520).
According to Compagno (1984:519-520), this shark inhab-
its inshore, tropical waters from the intertidal zone down to at
least 92 m; it feeds on bony fishes, including sea catfishes,
jacks, and porcupine fishes, on stingrays, occasionally on sea-
birds, and on invertebrates.
Genus Triaenodon Miiller and Henle, 1837
(whitetip reef sharks)
In the extant species of this shark, the upper teeth can be dif-
ferentiated into two medials, one symphysial, three anteriors,
15 to 18 laterals, and one or two posteriors; in the lower jaw,
aside from two medials, one symphysial, and (sometimes) one
or two posteriors, anterior and lateral teeth cannot be differenti-
ated (Compagno 1988:352). When the posterior teeth can be
identified, the remaining lower teeth are called anterolaterals,
and when the posterior teeth cannot be differentiated, they are
called anteroposteriors.
Compagno (1988:352) characterized the teeth of this genus
as follows: "Sexual heterodonty apparently weak or absent.
Ontogenic heterodonty moderately developed, with adults hav-
ing narrower and more differentiated medials than young.
Young also have mesial cusplets absent from a few more rows
of teeth adjacent to the ends of the dental bands than adults and
have slightly more oblique cusps." Returning to the description
of adult teeth, he continued, "Mesial edges differentiated into
cusplets on most teeth except for a variable number of rows
near the ends of the dental bands. Primary cusps present on all
teeth, erect towards the symphysis but becoming oblique to-
wards the ends of the dental bands. Primary cusps narrow-
based and high. Distal edges strongly notched on all teeth, but
serrations are absent. Tooth roots and crowns relatively high
and moderately compressed. Teeth holaulacorhizous, with
well-developed transverse grooves and notches. Basal ledges
and grooves absent from teeth."
Triaenodon obesus (Riippell, 1835)
Figure 57A-n
Otodus catticus Philippi, 1846:24, pl. 2: figs. 5-7 [early Miocene, Cassel],
Lamna cattica (Philippi).—Leriche, 1926:395-397, pl. 28: figs. 50-52 ["Bold-
erian," Belgium]; 1927:65-68, pl. 7: figs. 12-15, 17, 18 [Miocene, Switzer-
land].—Cappetta, 1970:23-25, pl. 4: figs. 5-8 [Helvetian, France].
Horizon.—Pungo River Formation (units 1-3).
Referred Material.—5 teeth, USNM 283497, 312434,
312436,459824,459825.
Remarks.—The five teeth recovered from the Pungo River
Formation (Figure 51k-n) are the typical upper lateral teeth of
Triaenodon. These teeth are extremely labiolingually com-
pressed and have tall, distally inclined and broad-based crowns
that are bordered by lingually bent, large, lateral cusplets; at the
NUMBER 90
157
FIGURE 57.—Rhizoprionodon? sp.: a, USNM
207535, lower lateral tooth, lingual view; b, same
specimen, labial view; c, USNM 207536, lower
anterior tooth, lingual view; d, USNM 207537,
lower anterior tooth, labial view; e, USNM
207538, lower anterior tooth, labial view;/
USNM 207539, male? lower anterior tooth, lin-
gual view; g, USNM 207540, lower lateral tooth,
lingual view. Negaprion eurybathrodon: h,
USNM 207490, upper anterior tooth, labial view;
i, USNM 207491, upper lateral tooth, lingual
view;/ USNM 451338, lower lateral tooth, lin-
gual view. Triaenodon obesus: k, USNM 312436,
upper lateral tooth, labial view; /, USNM 312434,
upper lateral tooth, lingual view; m, USNM
459824, upper anterolateral tooth, lingual view; n,
USNM 459825, lower lateral tooth, lingual view.
(Scale bars: a-g,I = 0.5 cm; h-k,m = l.O cm;
n=1.25 cm.)
base of the crown there is a basal ledge. On the lingual face of
the root, a transverse groove is usually present.
Philippi's holotype (1846, pl. 2: figs. 5-7) of Otodus cattica
is identical to an upper lateral of Triaenodon obesus, with its
extremely labiolingually compressed, distally inclined crown,
large lateral cusplets, and shallow root. A transverse groove,
which Philippi did not mention, is not evident in his fig. 6, but
if this tooth was not functional or if the groove was not well de-
fined by its tooth germ, the groove would be absent.
Antunes (1969-1970) used teeth from two genera to recon-
struct a tooth set of Lamna cattica totuserrata from the Mi-
ocene of Angola. The anterior teeth illustrated by Antunes
(1969-1970, pl. 1: fig. 1, pl. 2: figs. 17-19, pl. 3: figs. 20-24)
are identical to the upper and lower anterior teeth of Carchar-
ias cuspidata, and the lower lateral teeth (his pl. 3: figs. 25,
26) also are identical to those of Carcharias cuspidata. Those
that Antunes (1969-1970) identified as upper symphysial
teeth, which are symphysial (his pl. 1: fig. 2) and intermediate
(his pl. 1: fig. 3) teeth, also belong to C. cuspidata. (Some of
these teeth bear on their cutting edges what appear to be in-
cipient serrations, which are not as well developed as those
on the other teeth in his reconstruction that are assignable to
Triaenodon. The cutting edges of the functional teeth of the
extant Carcharias taurus are often nicked, giving them the
appearance of bearing incipient serrations.) The specimens
Antunes (1969-1970, pl. 2: figs. 10-16) identified as upper
lateral teeth, except for their finely serrated cutting edges, are
identical to those of Triaenodon obesus. Antunes's recon-
structed tooth set, therefore, includes teeth from two different
genera.
We do not think that serrations warrant separating the fossil
teeth from Triaenodon because at least two genera in the Car-
charhiniformes, Carcharhinus and Sphyrna, contain species
with smooth and serrated teeth. We believe, therefore, that ser-
rations are not a valid criterion for assigning these teeth to a ge-
nus other than Triaenodon.
On the basis of Antunes's reconstruction, Cappetta
(1987:95) assigned Lamna cattica and L. totuserratus to the
genus Carcharoides Ameghino, 1901. In view of the above, we
believe this assignment is unwarranted.
The referred teeth measure as follows (USNM 312434 is in-
complete).
Catalog number	Height (mm)	Width (mm)
USNM 283497	10.2	10.1
USNM 312436	10.2	8.9
USNM 459824	13.4	13.2
USNM 459825	6.5	7.2
Compagno (1984:537) reported that the extant species is a
bottom-oriented shark that inhabits tropical, shallow, clear wa-
ter on or near coral reefs; it usually is found in waters of 8 to 40
m in depth, but it has been found occasionally as deep as 110 to
330 m.
Family Sphyrnidae
(hammerhead sharks)
Genus Sphyrna Rafinesque, 1810
Compagno (1988:363) characterized these teeth as having
weak ontogenic heterodonty, with the heights of the cusps
and crowns relative to root width lower in juveniles than in
158
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
adults. Under the subgenus Sphyrna, which includes all of the
Lee Creek Mine hammerheads, Compano (1988:366) de-
scribed the teeth as follows: "Cusps of anterolateral teeth
[lowers] slender and almost needlelike. Posterior teeth mostly
cuspidate, not modified as molariform crushers. Basal ledges
and grooves obsolete." Three species of hammerhead sharks
occur at Lee Creek Mine, Sphyrna lewini, S. cf. S. media, and
S. zygaena.
¦
H        e"     f^^
Sphyrna lewini (Griffith and Smith, 1834)
Figure 58a-c
Horizon.—Yorktown Formation (unit 3).
Referred Material.—4 teeth, USNM 459728-459731.
Remarks.—The teeth from Lee Creek Mine (Figure 58a-c)
fit Compagno's (1984:545) description of teeth from the extant
species: "Anterior teeth with moderately long, stout to slender
cusps, smooth or weakly serrated, posterior teeth mostly cuspi-
date and not keeled and [not] molariform."
The anterior teeth of this shark range from 7.3 to 7.8 mm in
height (mean=7.5 mm, n=4) and from 6.5 to 9.6 mm in width
(mean=8.2 mm, «=4).
Compagno (1984:546) reported that this species is "probably
the most abundant hammerhead, a coastal-pelagic, semioceanic
warm-temperate and tropical species occurring over continen-
tal and insular shelves... [ranging] from the intertidal... to at
least 275 m depth." He reported its principal prey as a wide va-
riety offish, including sea catfish, bluefish, jacks, porgies, and
other sharks.
Sphyrna cf. S. media Springer, 1940
Figure 58<7-g
-Pungo River Formation (units
-5); Yorktown
Horizon.
Formation (units 1, 2).
Referred Material.—111 teeth, USNM 207526-207529,
207533, 207534, 451341-451346.
Remarks.—The upper teeth have triangular, distally in-
clined crowns with smooth cutting edges (Figure 58o». The
crowns are deeply notched distally, setting off a distinct,
vaguely serrated, convex enamel blade. They are similar to
those teeth referred to 1 Rhizoprionodon sp. but may be distin-
guished by their wider-based crown, blunter point, and less
concave mesial cutting edge. Of the sphyrnids, they resemble
closely the teeth of Sphyrna media (Gilbert, 1967, fig. 14), but
because dentitions of this species were not available to us for
this study, we could not make direct comparisons between
them and the fossil teeth. The teeth identified by Cappetta
(1970:70-72, pl. 19: figs. 1-18) from the lower Miocene of
France also closely resemble those of S. media.
In size, the anterior teeth range from 4.8 to 7.8 mm in height
(mean=6.3 mm, n=l) and from 5.6 to 8.0 mm in width (mean
=7.8 mm, n=l).
FIGURE 58.—Sphyrna lewini: a, USNM 459728, lower lateral tooth, lingual
view; b, USNM 459729, upper lateral tooth, lingual view; c. USNM 459730,
lower lateral tooth, lingual view. Sphyrna cf. S. media: d, USNM 207527,
upper lateral tooth, lingual view; e, USNM 207534, upper lateral tooth, labial
view;/ USNM 207529, lower anterior tooth, labial view; g, USNM 207533,
lower lateral tooth, lingual view. (Scale bars: a-c= 1.0 cm; d-g=0.ss cm.)
According to Compagno (1984:548), Sphyrna media, a little-
known, inshore, tropical hammerhead, is found in the eastern
Pacific Ocean, the southern Caribbean Sea, and the south At-
lantic Ocean. The Lee Creek Mine occurrence, if it is Sphyrna
media, indicates that this shark had a wider distribution during
the Neogene.
Sphyrna zygaena (Linnaeus, 1758)
Figures 59, 60
Galeocerdo laevissimus Cope, 1867:141-142 [Calvert Formation, Maryland].
Carcharias laevissimus (Cope).—Eastman, 1904:84-85, pl. 32: fig. 2 [Calvert
Formation, Maryland].
Carcharias (Scoliodon) kraussi Probst.—Leriche, 1927:83, pl. 14: fig. 16 [Mi-
ocene, Switzerland]
Sphyrna laevissima (Cope).—Leriche, 1942:84, pl. 7: figs. 23-27 [Calvert For-
mation, Maryland].—Casier, 1958:40, pl. 1: fig. 23 [Miocene, Trinidad].
HORIZON.—Pungo River Formation (units 1-5); Yorktown
Formation (units 1-3).
REFERRED MATERIAL.—55 teeth, USNM 207520-207525,
459716-459719, 459721-459729.
Remarks.—The Pungo River specimens (Figure 59a-e)
are identical in size and form to teeth of juveniles and adults
of the extant Sphyrna zygaena. In juveniles and young adults
of the extant species, the teeth have smooth cutting edges, but
in large individuals, they become weakly serrated (Gilbert,
1967:36). On the basal portions of their cutting edges, several
teeth from the Pungo River Formation exhibit incipient serra-
tions. These are similar in form to those found on the upper
teeth from a 302 cm TL individual of the extant species
(USNM 232633).
Cope's (1867) type suite for S. laevissimus consists of 19
teeth (ANSP 1195-1213) (Figure 60), two of which are not
Sphyrna. The remaining teeth compare favorably with those
of 5. zygaena; therefore, we place S. laevissimus in synonymy
NUMBER 90
159
FIGURE 59.—Sphyrna zygaena: a, USNM 207522, Pungo River Formation, lower anterolateral tooth, labial
view; b, USNM 207524, Pungo River Formation, lower anterolateral tooth, labial view; c, USNM 207520,
Pungo River Formation, upper lateral tooth, lingual view; d, USNM 207523, Pungo River Formation, incom-
plete upper lateral tooth, labial view showing distinctive shape of mesial edge of larger teeth; e, USNM
207525, Pungo River Formation, upper lateral tooth, labial view;/ USNM 459716, Yorktown Formation, unit
3, upper lateral tooth, lingual view. (Scale bars: a-c,e=\.0 cm; <7=0.5 cm;/=0.33 cm.)
with it. Although cataloged, the teeth were never numbered;
in Figure 60 we give to each specimen a catalog number from
the assigned series.
The few specimens from the Yorktown Formation (Figure
59/) (mean height=1.3 cm, range= 1.2-1.4 cm, n=4), which
are larger than the Pungo River Formation specimens (mean
height=1.0 cm, range=0.8-l.l cm, «=10), are more serrate
than those from the latter formation.
FIGURE 60.—Type suite oi Sphyrna laevissimus: a, ANSP 1195, upper antero-
lateral tooth, lingual view; b, ANSP 1196, lower anterolateral tooth, lingual
view; c, ANSP 1197, lower anterolateral tooth, lingual view; d, ANSP 1198,
lectotype, upper anterolateral tooth, lingual view; e, ANSP 1200, upper antero-
lateral tooth, lingual view;/ ANSP 1201, upper anterolateral tooth, lingual
view; g, ANSP 1202, upper anterolateral tooth, lingual view; h, ANSP 1203,
upper anterolateral tooth, lingual view; i, ANSP 1204, lower anterolateral
tooth, lingual view;/ ANSP 1205, upper anterolateral tooth, lingual view; k,
ANSP 1206, upper anterolateral tooth, lingual view; /, ANSP 1207, upper ante-
rolateral tooth, lingual view; m, ANSP 1208, upper anterolateral tooth, lingual
view; n, ANSP 1209, upper anterolateral tooth, lingual view; o, ANSP 1210,
lower anterolateral tooth, lingual view; p, ANSP 1211, lower anterolateral
tooth, lingual view; q, ANSP 1213, lower anterolateral tooth, lingual view.
(Scale bar= 1.0 cm.)
160
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
The extant species is a coastal-pelagic and semioceanic shark
that inhabits temperate to tropical waters; it feeds on bony fish-
es, including sea catfishes, sea bass, and porgies, and on sting-
rays (Compagno, 1984:554).
CARCHARHINIFORMES
Figure 61
HORIZON.—Yorktown Formation (units 1?, 2?).
Referred Material.—About 100 rostral nodes, USNM
476299^176302; about 20 postorbital and preorbital processes,
USNM 476303-476306; 6 hypercalcified ?suprascapulae,
USNM 476307, 476308.
REMARKS.—The Lee Creek Mine carcharhiniform rostral
nodes occur in three forms: broad dish-shaped (USNM 476299,
Figure 61a), T-shaped (USNM 476301, Figure 61*), and bar-
shaped (USNM 476302, Figure 6^,0"). In the first form, the
two dorsal and one ventral rostral cartilages meet anteriorly to
form a broad, unperforated, triangular dish. In the second form,
in cranial or caudal view, the rostral cartilages form a "T,"
which may be perforated at the point of juncture of the rostral
cartilages. In the last form, the two dorsal rostral cartilages
meet anterior to the ventral one, forming a lateral bar in anteri-
or view. Anterior to the juncture with the ventral rostral carti-
lage, the dorsal cartilages are perforated.
According to Compagno (1988:69), these types of rostral
nodes occur in Mustelus mosis, Rhizoprionodon acutus, and
Carcharhinus macloti, but without comparative material, we
could not identify the Lee Creek Mine specimens, which may
be too large to belong to these species.
Hypercalcified postorbital (Figure 61c) and preorbital pro-
cesses (Figure 61/g) similar to those found in the extant
Rhizoprionodon and Mustelus also occur at Lee Creek Mine;
however, these specimens are from individuals larger than the
largest extant form, and the Lee Creek Mine teeth for these
genera fall within the size range for the extant forms. Because
of this size discrepancy and the lack of comparative material
at this time, we cannot identify the Lee Creek Mine speci-
mens.
Finally, some bulbous specimens, which may represent su-
prascapulae, also were recovered from the mine (Figure 6I/1).
The largest, USNM 476307, has a maximum diameter of 5.3
cm. Again, due to the lack of comparative material, we could
not identify these.
FIGURE 61.—Carcharhiniform: a, USNM 476299, ros-
tral node, ventral view; b, USNM 476301, rostral node,
ventral view; c, USNM 476302, rostral node, ventral
view; d, same specimen, ventral view; e, USNM
476306, postorbital process, dorsal view;/ same speci-
men, ventral view; g, USNM 476303, preorbital pro-
cess, dorsal view; h, USNM 476307, hypercalcified
?suprascapula, lateral view. (Scale bar= 1.0 cm.)
NUMBER 90
161
Class Holocephali
Order Chimaeriformes, family indeterminate
Figure (>2a-d
Horizon.—Pungo River Formation?
REFERRED MATERIAL.—1 dentary fragment, USNM
282334; 1 tritor, USNM 476310; 1 partial dorsal spine, USNM
476309.
REMARKS.—Only three specimens of chimaeroid have been
recovered from the Lee Creek Mine; none of these possess any
characters that would allow their identification to genus. The
dentary fragment (Figure 62a), which is the anterior portion
and is badly abraded, lacks any evidence for the positions of
the tritors. The tritor (Figure 62b) is 7.3 cm long and 1.7 cm
wide.
In cross section the dorsal spine is triangular and has a dou-
ble row of serrations caudally, which are separated by a
groove; the cranial edge is smooth and sharp (Figure 62c,d). Its
lateral surfaces are striated. This fragment is 3.9 cm in length
and 1.5 cm in width.
Chimaeroids are deepwater fishes that feed on invertebrates
and small fishes.
Class Osteichthyes
Bone terminology herein follows Collette and Russo (1984)
and Tyler (1980).
Order ACIPENSERIFORMES
Family Acipenseridae
(sturgeons)
Acipenser cf. A. oxyrhynchus Mitchell, 1814
Figures 62e-h, 63
HORIZON.—Yorktown Formation (units 1, 2).
REFERRED Material.—Several thousand fragments, in-
cluding bony scutes, USNM 207602, 207603, 207607,286998,
286999, 290533, 290645; pectoral spines, USNM 207604,
284823, 284908; neural spines, USNM 285375, 285384; skull
bones, NCSM 9045, USNM 464059.
Remarks.—The fossil sturgeon material from Lee Creek
Mine consists of thick bony scutes or dermal plates with deeply
ornamented outer surfaces (Figure 62c,/) and smooth inner
surfaces. The pectoral spine (Figure 62g,h) is striated along its
length and is ornamented at its proximal end. Among the skull
bones we identified an intertemporal-supratemporal (Figure
63a) and a suborbital (Figure 63b).
From the Atlantic Coastal Plain of the United States, fossil
sturgeon remains have been reported from the Miocene Calvert
Formations of Virginia (Leidy, 1873) and Maryland (Kimmel
and Purdy, 1984) and from the Pleistocene of Florida (Swift
and Wing, 1968). Based on a lateral scute from the Virginia
Miocene, Leidy (1873) established a new species of fossil stur-
geon, Acipenser ornatus. About this specimen, Leidy
(1873:350) said, "Though exhibiting no positive distinctive
character, it most probably pertained to a species now extinct."
The type specimen was in a private collection and is now lost,
but based on Leidy's description and illustration (Leidy, 1873,
pl. 32: fig. 58), the scutes of Acipenser ornatus do not differ
from those of Acipenser oxyrhynchus.
In morphology, the Lee Creek Mine scutes are very similar
to USNM specimens from the Miocene sediments of Virginia,
Maryland, and Delaware and to those of the extant Atlantic
sturgeon, Acipenser oxyrhynchus. They closely resemble those
from a 183 kg specimen of the extant species (USNM 260347)
except that the Lee Creek Mine specimens are more massive.
This difference in thickness between the fossil and modern der-
mal elements, however, may fall within the size range of Aci-
penser oxyrhynchus, which reaches a length of 4.2 m TL and a
weight exceeding 370 kg (Manooch, 1984).
Acipenser oxyrhynchus is an anadromous species that occurs
in the shallow waters of the Atlantic continental shelf from La-
brador south to the northern coast of South America (Robins
and Ray, 1986). Presently, it occurs off North Carolina in shal-
low (to 20 m), nearshore waters from the late fall to the early
spring (Holland and Yelverton, 1973). Ross et al. (1988) stated
that in North Carolina in the spring, the American Atlantic
sturgeon is common in the ocean near the mouth of the Cape
Fear River. The abundance of sturgeon fossils in the Lee Creek
Mine fauna suggests that this fauna may have existed near the
mouth of a large river.
The American Atlantic sturgeon is a bottom feeder, consum-
ing worms, crabs, and small fishes (Manooch, 1984).
Order LEPISOSTEIFORMES
Family Lepisosteidae
(gars)
Lepisosteus osseus (Linnaeus, 1758)
Figure (Aa-d
Horizon.—James City Formation.
Referred Material.—1 partial skeleton, USNM 279492.
Remarks.—A partial skeleton consisting of eight vertebrae,
a rostral fragment, and numerous scales are referred to Lepisos-
teus osseus. The vertebrae are identical to those of the extant
gar.
Lepisosteus osseus, a freshwater and estuarine species, oc-
curs on the Atlantic slope of the United States from New Jersey
to Florida; it is also found in the Mississippi, Great Lakes, and
Rio Grande drainages (Page and Burr, 1991).
The gar feeds primarily on bony fishes, such as shiners, sun-
fish, shads, and catfish (Manooch, 1984).
162
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 62—Chimaeroid: a, USNM 282334, fragment
of dentary, lateral view; b, USNM 476310, tritor, lateral
view; c, USNM 476309, fragment of dorsal spine, lat-
eral view; d, same specimen, caudal view. Acipenser cf.
A. oxyrhynchus: e, USNM 207603, lateral dermal scute,
external view;/ USNM 207607, ventrolateral dermal
scute, external view; g, USNM 207604, incomplete pec-
toral spine, dorsal view; h, same specimen, posterior
view. (Scale bar= 1.0 cm.)
Order Elopiformes
Family Elopidae
(tarpons)
Megalops cf. M. atlanticus Valenciennes
in Cuvier and Valenciennes, 1847
Figure (Aef
HORIZON.—Pungo River Formation (units 5, 6).
Referred Material.—9 large, worn vertebrae, USNM
290630, 291256, 459863-459867,476382, 476394.
Remarks.—The Lee Creek Mine specimens, which range
from 41.5 to 47.5 mm in length, closely resemble the vertebrae
of the living tarpon, Megalops atlanticus. Like the extant spe-
cies, the vertebral lateral surfaces are slightly concave (Figure
64/) and are striated. In axial view (Figure 64c) the vertebrae
are oval, with the lateral axis being slightly greater than the
dorsoventral one.
Megalops atlanticus is a nearshore species that occurs from
Virginia to Brazil (Robins and Ray, 1986). It feeds primarily
on crabs and bony fishes, such as sardines, anchovies, mul-
lets, silversides, hardhead catfish, and Atlantic Cutlassfish
(Manooch, 1984).
Order Anguilliformes
Family Congridae
(conger eels)
Conger cf. C. oceanicus (Mitchill, 1818)
Figure 65a,b
HORIZON.—Yorktown Formation (unit 1).
NUMBER 90
163
FIGURE 63.—Acipenser cf. A. oxyrhynchus: a, USNM 464059, partial left intertemporal-supratemporal, dorsal
view; 6, NCSM 9045, partial right suborbital, dorsal view. (Scale bars= 1.0 cm.)

f
FIGURE 64.—Lepisosteus osseus, portions of partial associated skeleton, USNM 279492: a, partial premaxilla,
labial view; b, vertebra, dorsal view; c, same specimen, articular view; d, scale. Megalops cf. M. atlanticus: e,
USNM 290630, vertebra, articular view; / same specimen, dorsal view. (Scale bars: o=0.9 cm; b-d=0.75 cm;
e,/=0.9 cm.)
Referred Material.—1 partial left dentary without teeth,
USNM 411948.
Remarks.—This dentary compares favorably with that of
the extant Conger oceanicus. Along its labial edge, the position
of the main tooth row is indicated by oval alveoli, and lingual
to the alveoli there is a row of alveoli for villiform teeth (Figure
65a). At its anterior end, the dentary widens labially to form a
small tooth patch with 12 small alveoli in two rows. In this area
164
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
of the dentary, several extant specimens of Conger oceanicus
(USNM 30710, 265105, 265109) exhibited variable numbers
of tooth rows (one to four). Kanazana (1958) stated that the
number of teeth in the jaw of the genus Conger increases di-
rectly with age. The Lee Creek Mine specimen may be from a
juvenile or a young adult.
Conger oceanicus is a benthic species that occurs from Cape
Cod south to the Gulf of Mexico (Robins and Ray, 1986). This
species has been recorded in depths from 1 to 520 m (Kanaza-
na, 1958). It feeds primarily on bony fishes (Hildebrand and
Schroeder, 1928) but also has been reported feeding on shrimp
and mollusks (Thomson et al., 1978).
Order Clupeiformes
Family Clupeidae
(shads and herrings)
Alosa cf. A. sapidissima (Wilson, 1811)
Figure 65c,d
Horizon.—Yorktown Formation (unit 1?).
Referred Material.—Partial skull, USNM 411950.
REMARKS.—This partial skull has a posteriorly extending,
enlarged epiotic as seen in the genus Alosa. The posterior ex-
tent of the epiotic is greater in the Lee Creek Mine specimen
and in A. sapidissima than it is in the other species of Alosa.
Also, the epiotics intersect at the midline of the skull to form a
90° V-shaped notch. In other species of Alosa (A. aetivalis, A.
pseudoharengus, A. mediocris) these notches are greater than
90°. In this specimen, the preepiotic forms a depression at the
side of the cranium, bounded by the epiotic, squamosal, and
parietal bones, which also is characteristic of clupeids (Ridge-
wood, 1904).
Alosa sapidissima is an anadromous species that occurs from
Newfoundland and the Gulf of St. Lawrence south to northern
Florida (Robins and Ray, 1986). They are found off North
Carolina in nearshore waters (0-20 m), but they have been cap-
tured at depths of 160 to 250 m (Holland and Yelverton, 1973).
It is a planktivore, feeding primarily on small crustaceans, in-
sects, fish eggs, and algae (Manooch, 1984).
Order Siluriformes
Family Ariidae
(sea catfish)
Bagre sp.
Figure 65e,/
Horizon.—Pungo River Formation (units 4, 5); Yorktown
Formation (units 1, 2).
Referred Material.—30 pectoral-fin spines, USNM
256274, 284106, 284107,284111-284113,284151, 284152
(Pungo River Formation); 6 dorsal-fin spines, USNM
284098-284100, 476375 (Pungo River Formation, unit 4 or 5),
USNM 284114 (Yorktown Formation); about 100 vertebrae,
USNM 285646, 286142, 286147, 286161, 290517, 290947
(Yorktown Formation).
Remarks.—The fossil pectoral-fin spines from Lee Creek
Mine are similar to those of Bagre marinus (Mitchill), the gaff-
FlGURE 65.—Conger cf. C. oceanicus: a, USNM
411948, partial left dentary without teeth, occlusal view;
b, same specimen, lingual view. Alosa cf. A. sapidis-
sima: c, USNM 411950, skull, dorsal view; d, same
specimen, ventral view. Bagre sp.: e, USNM 256274,
partial pectoral-fin spine, posterior view. Opsanus tau:
f, USNM 411949, partial right dentary, occlusal view; g,
same specimen, labial view; h, NCSM 4285, partial
right dentary, occlusal view. Bagre sp.: /', USNM
476375, dorsal-fin spine, anterior view. (Scale bars:
a-g,i= 1.0 cm; A=0.25 cm.)
NUMBER 90
165
topsail catfish, especially with regard to the shape of the proxi-
mal articulating surface. This surface, which articulates with
the coracoid, is useful for identifying genera of catfishes. In
Bagre, the central hinge process is flattened ventrally and later-
ally to form the outside part of the hinge, and medially it rises
to form the hook-like hinge (Figure 65e). This differs from the
pectoral attachment found in the genus Arius, which does not
have its medial process ventrally flattened or hooked.
Several dorsal-fin spines from Lee Creek Mine, which are
referable to Bagre, have an outer surface that is notched with
rows of cross ridges, each ridge consisting of one or two peaks
(Figure 65/'). The serrae are very worn on both the dorsal- and
pectoral-fin spines.
Among the numerous fossil fish vertebrae from Lee Creek
Mine, we were able to identify those of Bagre. The precaudal
vertebrae are easily recognizable by the smooth lateral surfaces
of their centra, which are perforated by a large and a smaller
foramen, and by the strong, caudally curving haemal arches on
the ventral surfaces.
Other occurrences of sea catfish remains from sediments of
the Chesapeake Group include a spine attributed to Arius (Ler-
iche, 1942) and a skull with a left utricular otolith (Lynn and
Melland, 1939), the holotype of Bagre stauroforus (Lynn and
Melland), both from the Plum Point Member of the Calvert
Formation. The spine assigned to Arius is incomplete and is too
worn for generic identification. Because the skull and otolith of
Bagre stauroforus were not associated with any pectoral-fin
spines, comparison with the Lee Creek Bagre pectoral-fin
spines is not possible.
Bagre marinus occurs from Cape Cod to Venezuela (Robins
and Ray, 1986) in shallow coastal and bay areas and seasonally
in estuaries (Boschung et al., 1983). It feeds primarily on crabs,
supplemented by shrimp and fishes (Gudger, 1918).
Order Batrachoidiformes
Family Batrachoididae
(toadfishes)
Opsanus tau (Linnaeus, 1766)
FIGURE 65/-A
HORIZON.—Yorktown Formation (unit 1).
Referred Material.—2 partial right dentaries, NCSM
4285, USNM 411949.
Remarks.—Both of these partial right dentaries can be re-
ferred to the extant oyster toadfish, Opsanus tau. The first
specimen, USNM 411949 (Figure 65fg), which is 26 mm in
length and broken at both ends, has a single row of alveoli
stretching from the posterior end of the dentary to the anterior
tooth patch, half of which is present. The second specimen,
NCSM 4285 (Figure 65/z), is 28 mm in length and is broken
only at the distal end. Unlike the first specimen, several super-
numerary teeth occur on either side of the single tooth row at
two locations. Several of the teeth are displaced from the line
of this row. Other than these differences, the dentaries are iden-
tical to those of the extant species.
Ray et al. (1968) reported Opsanus sp. from the Pleistocene
Kempsville Formation of Virginia; these specimens, the first
fossil record for Opsanus, consist of a neurocranium and a right
lower jaw and compare favorably with those from Lee Creek
Mine. The Lee Creek specimens extend the fossil record for the
genus Opsanus to the early Pliocene.
Opsanus tau is a benthic species that occurs from Cape Cod
south to Florida (Robins and Ray, 1986). The primary habitats
for this species are areas that are rocky or have some form of
reef habitat. It has been recorded in depths of 1 to 50 m (Ma-
nooch, 1984). There is some evidence that this species migrates
offshore during cold weather (Thomson et al., 1978). It feeds
primarily on crabs, fishes, shrimp, amphipods, and worms
(Manooch, 1984).
Order Lophiiformes
Family Lophiidae
(goosefishes)
Lophius cf. L. americanus Valenciennes, 1837
Figure 66a-d
HORIZON.—Yorktown Formation (unit 1?).
Referred Material.—21 dentaries, USNM 290214,
290625, 291101, 476362; 50 premaxillaries, USNM 291116,
295340; 3 palatines, USNM 285259, 291188, 476361; 4 verte-
brae, USNM 290493.
Remarks.—In both size and shape of the various elements,
the Lee Creek Mine specimens are very similar to those of
Lophius americanus. On the lingual ventral surface at the sym-
physial end, the fossil premaxillaries (Figure 66a) bear several
rugose, caniniform teeth. These teeth point lingually, and they
are followed distally by up to 12 smaller, caniniform teeth with
triangular bases that decrease in size distally. The labial ventral
surface has four to five large alveoli; after a short gap, these are
followed distally by a row of smaller, triangular teeth. At the
symphysial end of the premaxillary, the articulating surface is
square-shaped and slightly concave, whereas the articulating
process is blade-like and nearly perpendicular to the ventral
and articulating surfaces; this process is heavily striated on its
lingual and labial surfaces.
The fossil dentary (Figure 66b) has a central tooth row of ca-
nine-like teeth with triangular bases. On the labial edge of the
dorsal surface, a row of smaller teeth originates about one-
quarter of the distance from the symphysial end and extends to
the distal end of the dentary. On the dorsal surface, the numer-
ous alveoli give a pitted appearance to the bone. At the sym-
physial margin of the dentary, there is a ventral, rectangular
process, which is striated on its distal surface.
The fossil palatine (Figure 66c) has several rugose, canini-
form teeth followed by a row of smaller caniniform teeth. The
symphysial surface is squarish, and the ethmoid process has two
166
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
tooth-like projections that point lingually. The fossil vertebrae
(Figure 66a") that we assign to Lophius are the anteriormost ver-
tebrae in the vertebral column; they are dorsoventrally com-
pressed, with striations on the external surface of the centra.
The genus Lophius was recorded previously from the Pleis-
tocene of Virginia (Ray et al., 1968) and the Oligocene of Bel-
gium (Leriche, 1908, 1910). The Virginia specimens, a frag-
mentary left dentary and a right scapulocoracoid, were
identified to family only. The Belgian specimens were identi-
fied as a new species of goosefish, Lophius dolloi, by Leriche
(1908).
Lophius americanus, a benthic species, occurs from Quebec
south to northern Florida (Robins and Ray, 1986). It inhabits
areas with sand, mud, and broken-shell substrates in waters
ranging in temperature from 0°C to 24°C (Manooch, 1984).
The goosefish has been recorded at depths of 1 to 200 m (Big-
elow and Schroeder, 1953). It feeds on small sharks, skates,
eels, herring, weakfish, tautog, butterfish, puffers, cod, had-
dock, flounders, seabirds, lobsters, crabs, worms, shellfish,
sand dollars, and starfish (Manooch, 1984).
Order Gadiformes
Family Merluccidae
(hakes)
Merluccius bilinearis (Mitchill, 1814)
Figures 66e-/, 67
HORIZON.—Yorktown Formation (units 1, 2).
Referred Material.—About 1000 dentaries, USNM
285254, 285273, 285291, 286875, 290546, 290553, 290561,
290584, 290603, 290613, 290617, 290635, 290640, 290660,
291102,298293,298302, 476311-476313; about 1000 pre-
maxillae, USNM 290543, 290545, 290602, 290606, 290644,
290656, 291096, 291123, 291193, 291673, 476324-476326; 1
partial maxilla, USNM 476363; about 100 maxillae
476314^176320; 1 partial left angular, USNM 476321; 1 left
angular, USNM 459851; 1 associated dentary, maxilla, and
partial premaxilla, USNM 476322; 1 vomer, NCSM 10916;
several hundred vertebrae, USNM 286131-286135, 286144,
286145, 286160, 286162, 290222-290229, 290231, 290238,
290240, 290242, 290243, 290251, 290253, 290255, 290256,
290259, 290264, 290272, 290275, 290326-290328, 290497,
290517, 290518, 290559, 291109, 291687, 291694, 476323;
about 100 hyperostosed vertebrae, USNM 460120, 476351,
476352; 1 partial cleithrum, USNM 459849; about 100 hyper-
ostosed cleithra, USNM 283825, 283869, 283905, 283960,
284012, 284043, 284045; 1 urohyal, USNM 476364; about 100
hyperostosed urohyals, USNM 421524, 421525.
Remarks.—The Lee Creek Mine specimens are identical to
those of Merluccius bilinearis. The presence of biserial teeth
on both the dentary and premaxilla separates the genus Merluc-
cius from all other gadiforms, which have single or multiple
rows of teeth on the maxilla, dentary, or both. Although Mer-
luccius differs from most gadoids in having a prognathous low-
er jaw (Rosen and Patterson, 1969), this feature is difficult to
prove in unarticulated fossils.
In the Lee Creek dentaries, as in the extant Merluccius, the
alveoli of the biserial tooth rows, which support medium-sized,
triangular teeth, occupy approximately one-third of the depth
of the dentary (Figure 66ef). The tooth-row surface slants lin-
gually so that the alveoli of the uppermost labial tooth row are
higher than those of the lingual row. In the fossil specimens,
the labial row of teeth is more securely attached to the dentary
than is the lingual row of teeth, which is absent. On the ventral,
FIGURE 66.—Lophius cf. L. americanus: a, USNM
295340, premaxillary, labial view; b, USNM 476362,
fragment of dentary, labial view; c, USNM 476361,
fragment of palatine, ventral view; d, USNM 290493,
vertebra, lateral view. Merluccius bilinearis: e,
USNM 476313, left dentary, external view;/ same
specimen, internal view; g, USNM 476326, right pre-
maxilla, external view; h, same specimen, occlusal
view; /', USNM 476363, partial maxilla, dorsal view.
(Scale bar= 1.0 cm.)


NUMBER 90
167
FIGURE 67.—Merluccius bilinearis: a, USNM 459851,
left angular, external view; b, NCSM 10916, vomer, ven-
tral view; c, USNM 459849, partial cleithrum, lateral
view; d, USNM 290559, precaudal vertebra, articular
view; e, USNM 291109, precaudal vertebra, articular
view;/ USNM 460120, four hyperostosed caudal verte-
brae, dorsal? view; g, same specimen, axial view; h,
USNM 476351, five hyperostosed caudal vertebrae, dor-
sal? view; /. USNM 476364, urohyal, lateral view. (Scale
bars: a,c~g,h=1.0cm; 6=0.33 cm; /'=0.5 cm.)
lingual surface of the dentary, a ridge extends from a notch in
the ventral edge of the symphysial end down the entire length
of the dentary. The ridge is thickest just posterior to the notch
and then thins abruptly. On the ventral, labial surface of the
dentary, a large groove extends from above the ventral notch to
the posterior end of the dentary. The largest of these incom-
plete dentaries measures 5.8 cm in length and 1.5 cm in depth
at the symphysis.
In the premaxillae (Figure 66g,h) the lingual row of teeth
originates at a slightly more dorsal elevation than does the labi-
al row. The much shallower dorsoventral depth of the premax-
illae gives the teeth, which are in the same size range as those
of the dentaries, a larger appearance. At the symphysial end,
the premaxilla flares out to form the slightly concave articular
surface; on its lingual edge is a small process that articulates
with the maxilla. The dorsal surface of the premaxilla is
smooth and rounded, whereas the lingual and symphysial sur-
faces are sculptured.
The maxilla is edentulous (Figure 66;). Its symphysial end,
which articulates with the symphysial end of the premaxilla,
has an elongated internal process dorsal to the shallow groove
that accepts the articular process of the premaxilla. The shal-
lowness of this groove is unlike the glove-shaped socket found
in the maxillae of other teleosts at Lee Creek Mine. Mesial to
this shallow groove there is a process that extends toward the
symphysis. The distal end of the maxilla is flattened on its ven-
tral surface but with a slight concavity; the more mesial distal
surface is smooth and rounded and has a half-oval cross sec-
tion.
The vomer, angular, cleithrum, urohyal, and vertebrae are
figured (Figure 67). With the exception of the urohyal and the
precaudal vertebrae, these compare well with those of Merluc-
cius bilinearis. The urohyal is hyperostosed (Figure 67/), giv-
ing it an inflated appearance, but its morphology is close to that
of the extant species, which is not hyperostosed. Although the
precaudal vertebrae (Figure 61d,e) are very similar to those of
the extant species, they are more strongly ossified, which may
be hyperostosis, and on their ventral surfaces a central groove
rather than a central ridge is present.
Numerous hyperostosed vertebrae (Figure 61f-h) occurring
in the basal Yorktown Formation are tentatively assigned to
Merluccius. Although the hyperostoses give the vertebrae a
large size, the centra they surround have a very small diameter
(Figure 61 g). In adults of the extant Merluccius productus, the
precaudal vertebrae have diameters (9 mm) three times larger
than that of the second caudal (3.0 mm), and the diameters of
168
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
the third (3.2 mm) and fourth (3.5 mm) caudal vertebrae are
slightly greater than the diameter of the second caudal vertebra.
Of the taxa we have identified at Lee Creek Mine, only Meluc-
cius has caudal vertebrae with very small diameters (mean=5.0
mm, range=3.6-5.9 mm, n=l). The Lee Creek Mine speci-
mens represent three to five caudal vertebrae fused by hyperos-
tosis (Figure 61 h); the greatest development (mean width= 15.1
mm, range= 11.6-25.5 mm, «=8) of this hyperostosis is along
the lateral axis of the vertebrae, and as shown below, its devel-
opment is independent of the diameter of the vertebral centra.
Centrum diameter (mm)       Width of hyperostosis (mm)
USNM 460120	5.7	12.2
USNM 476351	4.8	18.6
USNM 476352	5.8	25.5
Because specimens of extant Merluccius bilinearis with hy-
perostosis were not available to us, we cannot ascertain the
identity of these vertebrae.
The hake is a benthic species that occurs from the Gulf of St.
Lawrence south to South Carolina (Robins and Ray, 1986). It
has been recorded at depths of 1 to 400 m, with a preferred depth
range of between 60 and 200 m (Almeida et al., 1984). The hake
feeds on fishes and invertebrates (Thomson et al., 1978).
Order PERCIFORMES
Family Triglidae
(searobins)
Prionotus cf. P. evolans (Linnaeus, 1766)
Figure 68
Horizon.—Yorktown Formation (units 1-3).
Referred Material.—5 skulls, NCSM 2978, USNM
290627, 459826, 459828, 459862; about 100 partial skulls,
USNM 289396, 289397, 290215, 290216, 290663, 291154,
FIGURE 68.—Prionotus cf. P. evolans: a, USNM 290627, neurocranium, dorsal view of skull roof; b, same spec-
imen, ventral view; c, same specimen, lateral view; d, USNM 291218, dorsal view of hyperostosed skull roof; e,
same specimen, ventral view;/ USNM 459827, ?pathologic, hyperostosed skull roof, dorsal view; g, same spec-
imen, ventral view; h, USNM 290663, dorsal view of hyperostosed skull roof; /', same specimen, ventral view;/
USNM 412167, lateral view of left operculum; k, NCSM 3106, lingual view of partial right dentary. (Scale bars:
a-c,y=0.5 cm; d-i= 1.0 cm; k=0.5 cm.)
NUMBER 90
169
291218, 291262, 459827; 4 preopercula, USNM 459830; 1
operculum, USNM 412167; 2 lacrimals, USNM 291192,
336359; 1 premaxilla, USNM 291156; 1 dentary, NCSM
3106.
REMARKS.—Numerous fossil skulls have been found at the
Lee Creek Mine site that are very similar to the extant northern
searobin, Prionotus carolinus, and the striped searobin, Prion-
otus evolans. They are easily recognized by the elaborate
sculpturing of the external surfaces of the skull, which is char-
acteristic of Prionotus. The posttemporals extend caudally well
beyond the caudal margin of the supraoccipital. The skull roof
is broad and somewhat flat and is slightly concave between the
orbits, which penetrate the margin of the skull roof. The ros-
trum tapers from the orbits to the ethmoid, and its dorsal sur-
face is slightly convex.
At Lee Creek Mine, three different skull types of Prionotus
occur. In the first type (USNM 290627, Figure 68a-c), hyper-
ostotic enlargement of the posttemporals is absent; only three
skulls of this type are complete, and they measure 45.4 mm
(USNM 290627), 35.8 mm (USNM 459862), and 45.6 mm
(USNM 459826) in total length.
In the second type (USNM 291218, Figure 680"^), the post-
temporals are hyperostosed and fuse at the midline of the skull.
None of these skulls are complete; the rostra are missing, and
the largest, USNM 291218, measures 37.6 mm in total length.
One specimen of this type, USNM 459827, may be pathologic
(Figure 68/g).
In the third type (USNM 290663), the hyperostosis is not a
singular, bulbous mass as in the second type but develops in an
elongate mass of a central and two lateral lobes, which are
asymmetrical (Figure 68/?,/). Although in all of these speci-
mens (n=43) the rostral and orbital regions are missing, the
outline of the braincase is identical to that in the other two
types of Prionotus mentioned above. The largest specimen of
this third type, USNM 290663, measures 64.9 mm in total
length.
An isolated fossil operculum, USNM 412167 (Figure 68/'),
was found at Lee Creek Mine, and it exhibits a sculpture and
structure similar to those of the extant species. A partial right
dentary also was recovered (Figure 68A:).
Fossil searobins from the eastern coastal plain of the United
States have been reported from the Pleistocene of Virginia
(Ray et al., 1968), New Jersey (Selden, 1986), Maryland
(Blake, 1953), and Florida (Swift and Wing, 1968). All of these
specimens are partial neurocraniums that were identified as
Prionotus sp., but Blake (1953) and Selden (1986) suggested
their specimens had a closer affinity to P. evolans.
Prionotus carolinus and P. evolans are benthic species that
occur from Nova Scotia to Florida (Robins and Ray, 1986) at
depths of 1 to 80 m (Thomson et al., 1978). Searobins feed on
shrimp, amphipods, squids, and worms (Manooch, 1984).
Family Serranidae
(sea basses)
Epinephelus sp.
Figure 69a,b
Horizon.—Yorktown Formation (units 1,2).
Referred Material.—13 incomplete premaxillae, USNM
256272,285321, 286935, 290572, 290594, 290612, 290634,
291073, 291149, 291162, 291177, 291199, 291248; 5 incom-
plete dentaries, NCSM 4797, USNM 256273, 286907, 286925,
290539.
Remarks.—The generic assignment is based on the great
similarity of the fossil premaxillae to the premaxillae of Epi-
nephelus morio. Because genera of groupers, not to mention
species, are rather difficult to distinguish based on jaw ele-
ments alone, no attempt at specific identification is made.
The premaxilla (Figure 69a) has a labial row of large teeth
that decrease in size posteriorly; the alveolus for the largest
and anteriormost tooth is 4 mm in diameter. Lingual to this
row of large teeth is a triangular area of numerous small alve-
oli supporting a cardiform tooth series. Alveoli in this area in-
crease in size toward the lingual edge. Maximum height of the
premaxilla (excluding teeth) is 20.5 mm, maximum width is
10.9 mm, and the width of the tooth-bearing area is 8.8 mm at
the symphysial end. At the symphysial end, the ascending
process is transversely compressed and is moderately low.
The arrangement of the tooth series and the shape of the as-
cending branch of the premaxilla closely resemble that of Epi-
nephelus morio.
The dentary contains teeth of three different sizes. On the la-
bial side of the symphysial end of the dentary is a tooth patch
(Figure 696) with large, conical teeth (usually two). Lingual to
these teeth on this same tooth patch there are five to six rows of
small teeth (about 1 mm in diameter at their bases), and lingual
to these is a row of intermediate-sized teeth (about 1.5-2 mm
in diameter at their bases); this row extends to the distal end of
the dentary. On the main tooth surface of the dentary and labial
to this row of intermediate-sized teeth there is a row of smaller
teeth followed labially by a row of intermediate-sized teeth,
three rows in all along most of the dentary. Dentary USNM
256273 is 8.9 mm wide and 16.9 mm deep (excluding teeth);
the largest dentary, USNM 290539, which is incomplete, mea-
sures 13.7 mm in width, 56.0 mm in length, and 22.6 mm in
depth (excluding teeth).
Groupers are offshore reef fishes that occur from Massachu-
setts to Brazil (Robins and Ray, 1986) at depths of 24 to 210 m
(Manooch, 1984). They feed on a variety of bony fishes, in-
cluding snappers, scuds, porgies, and searobins, and on a vari-
ety of invertebrates, including shrimp, crabs, squids, and
worms (Manooch, 1984).
170
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 69.—Epinephelus sp.: a. USNM 256272, right premaxilla, ventrolingual view; b, USNM 256273, ante-
rior fragment of left dentary, labial view. Mycteroperca sp., USNM 290658, left dentary: c, lingual view; d,
labial view. Seriola sp., NCSM 1857, partial left dentary: e, labial view;/ occlusal view. (Scale bars= 1.0 cm.)
Mycteroperca sp.
Figure 69c,d
Horizon.—From spoil piles, probably lower Yorktown For-
mation (unit 1).
REFERRED Material.—1 left dentary, USNM 290658.
REMARKS.—A single dentary (Figure 69c,d) with the alveo-
lar ridge complete and with several conical teeth resembles
those of modern Mycteroperca. At the symphysial end there
are two large alveoli for conical teeth, about 6 mm in diameter;
these are followed lingually by a row of very small teeth that
extends distally a short distance, about 20% of the length of the
dentary. This row of small teeth is between two rows of inter-
mediate-sized teeth, with alveoli of 2 to 4 mm in diameter;
these intermediate-sized teeth extend distally to the end of the
dentary. The total length of the dentary is 14.6 cm, and the
depth at the symphysis is 2.9 cm.
NUMBER 90
171
Mycteroperca are offshore reef fishes that occur from Mas-
sachusetts to Brazil (Robins and Ray, 1986) at depths between
10 and 130 m (Manooch, 1984). They feed on shrimp, scuds,
porgies, snappers, grunts, squids, and sardines (Manooch,
1984).
Family Branchiostegidae
(tilefishes)
Two genera of branchiostegids, Caulolatilus and Lopholatit-
us, occur at Lee Creek Mine. This is the first occurance in the
fossil record for Caulolatilus. Lopholatilus was previously re-
corded from the Yorktown Formation as otoliths (Fitch and
Lavenberg, 1983) and from the Calvert Formation of Maryland
(Kimmel and Purdy, 1984).
Based on a specimen from Miocene sediments near Oran,
Algeria, Arambourg (1927) described Latilus mesogeus, but
Dooley (1978) found Arambourg's illustration and description
too vague to ascertain the identity of this species. Except for
this specimen, the specimens from Lee Creek Mine are the only
definite fossil branchiostegids yet known.
Caulolatilus cf. C. cyanops Poey, 1866
Figure 70a, b
Horizon.—Yorktown Formation (unit 1).
Referred Material.—Associated right and left ceratohy-
al, USNM 412151.
REMARKS.—A pair of associated ceratohyals (Figure 10a, b)
compare well with those of the extant blackline tilefish, Cau-
lolatilus cyanops. They are similar in having an anterior projec-
tion for articulation with the posteroventral notch of the hypo-
hyal. The broad, flattened section of the ceratohyal is much
shorter than in Lopholatilus and has only a short groove that
extends from the upper one-third to about one-half of the
length of the ceratohyal; in Lopholatilus this groove extends
the entire length of the ceratohyal.
Robins and Ray (1986) reported that Caulolatilus cyanops
ranges from North Carolina south to the Gulf of Mexico and to
northern South America. This species has been recorded at
depths between 45 and 495 m, with a preferred depth range of
150 to 250 m (Dooley, 1978).
Lopholatilus rayus, new species
Figure 70c-f
Holotype.—Partial skull including associated partial left
dentary (30 mm in length) missing distal end, partial left pre-
maxilla lacking distal end, partial left operculum, epiotic, frag-
ment of center portion of preoperculum, and fragments of max-
illa, hyomandibular, and palatine, NCSM 2900.
Type Locality.—Lee Creek Mine, Aurora, North Carolina.
Horizon.—Yorktown Formation (unit 1).
Paratypes.—1 partial left dentary, 22 mm long, NCSM
1572; 1 partial left dentary, 22 mm long, NCSM 3233; 1 partial
left dentary, 26 mm long, NCSM 3160; 1 partial skull, USNM
437559, including symphysial portions of both dentaries; 1 par-
tial dentary, 37.3 mm long, USNM 336240; 1 vomer, 19.6 mm
wide, USNM 437550.
Etymology.—In recognition of Clayton E. Ray, whose de-
termination has brought about the extensive study of the Lee
Creek Mine fauna.
Diagnosis.—A villiform tooth row extends from the anteri-
or tooth posteriorly along the lingual margin of the coronoid
process of the dentary. In all other branchiostegids, this villi-
form tooth row is absent.
Remarks.—This is one of the most common species of the
nonpelagic fishes found at the Lee Creek Mine site. It also is
one of the few fish species for which numerous partial skele-
tons have been found. Although the otoliths from Lee Creek
Mine have been described as Lopholatilus chamaeleonticeps,
the extant species (Fitch and Lavenberg, 1983), we believe the
difference between the dentaries of the fossil and extant species
is sufficient to warrant the establishment of a new species.
Numerous skeletal elements have been identified as belong-
ing to L. rayus. These include premaxillaries, dentaries, hyo-
mandibulars, vomers, parasphenoids, lateral ethmoids, angu-
lars, ceratohyals, epihyals, vertebra, exoccipitals, and more.
Most of these elements, including the premaxillaries, angulars,
hyomandibulars, ceratohyals, epihyals, vertebra, and exoccipi-
tals, agree very well in structure with L. chamaeleonticeps.
The dentaries (Figure 70c,d) of L. rayus are very similar to
those of L. chamaeleonticeps in having the same basic struc-
ture, including a broad anterior tooth patch and a well-defined
ventral exterior groove. In L. chamaeleonticeps the villiform
teeth are confined to the anterior tooth patch, with the remain-
der of the tooth row being made up of large, canine-like teeth.
The vomer (Figure 10e,f) of L. rayus, although similar to
that of L. chamaeleonticeps, differs in being broader and in
having a flatter ventral base. The lateral processes of the vomer
are prominent, thinning out to a sharp edge, and the anterior
surfaces of the lateral processes are slightly striated and are flat
or very slightly concave rather than noticeably concave as in L.
chamaeleonticeps.
Dooley (1978) reported that Lopholatilus chamaeleonticeps
has a current range from Nova Scotia south to the Gulf of Mex-
ico and to northern South America. This species has been re-
corded at depths of 81 to 540 m, but it occurs generally in a rel-
atively narrow zone along the continental slope and along the
upper reaches of canyons at depths of 120 to 200 m (Dooley,
1978). There are two critical habitat requirements for tilefish, a
suitable temperature, 9° to 14°C, and shelter, which can be pro-
vided by rocks, boulders, or clay in which the tilefish can exca-
vate vertical burrows (Grimes et al., 1986).
Lopholatilus feeds on various crustaceans, snails, worms,
fish, sea urchins, anemones, and sea cucumbers (Manooch,
1984).
172
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Family Pomatomidae
(bluefishes)
Pomatomus saltatrix (Linnaeus, 1766)
Figure 70g-o
HORIZON.—Yorktown Formation (units 1, 2).
Referred Material.—Numerous premaxillae, USNM
286874, 290602, 290610, 290611, 290615, 290682, 291122,
291130; numerous dentaries, USNM 290600, 291063, 291088,
291100,291131,291172; 1 ethmoid, USNM 437564; 2 fron-
tals, USNM 437562,437563; 1 ceratohyal, NCSM 1442; 1 ver-
tebra, USNM 437566; 2 angulars, USNM 437565, 476366; 1
hyomandibular, NCSM 8363; 3 quadrates, NCSM 2908, 6685,
USNM 476365; 1 maxilla, NCSM 3648; 1 vomer, USNM
437564.
Remarks.—Numerous skeletal elements of this fish have
been found at Lee Creek Mine, including several associated
partial skeletons. The premaxillae compare well with those of
modern bluefish, Pomatomus saltatrix, in having a labial row
of laterally compressed caniform teeth and a row of smaller but
otherwise similar teeth along the lingual side of the jaw (Figure
lOg.h). The two rows converge posteriorly until they are side
by side just forward of the postmaxillary process. Anteriorly,
the labial and lingual rows are separated by a toothless ex-
panse. The arrangement of the tooth rows and the shape and
angle of the ascending and articular processes match those of
the modem species.
Other skeletal elements, including the dentary (Figure 70/),
ceratohyal (Figure 70/), quadrate (Figure 10k), angular (Figure
70/), vertebrae (Figure 10m), frontal (Figure 70«), and vomer
(Figure 70o), also agree well with Pomatomus saltatrix. This is
Figure 70.—Caulolatilus cf. C. cyanops, USNM 4I2I5I, left and right ceratohyal: a, medial view; b, lateral
view. Lopholatilus rayus, new species: c, NCSM 2900 (holotype), left dentary, occlusal view; d, same speci-
men, labial view; e, USNM 437550 (paratype), vomer, ventral view;/ same specimen, labial view. Pomato-
mus saltatrix: g, USNM 290615, right premaxilla, ventrolingual view; h, same specimen, occlusal view; i,
USNM 291100, right dentary, labial view;/ NCSM 1442, ceratohyal, lateral view; k, USNM 476365, left
quadrate, lateral view; /, USNM 476366, right angular, labial view; m, USNM 437566, vertebra, lateral view;
n. USNM 437562, right frontal, dorsal view; o, USNM 437564, vomer, dorsal view. (Scale bars: a-d,g-j=\.Q
cm; e,f,k-m=0.5 cm; n=0.7 cm; o= 1.0 cm.)
NUMBER 90
173
the first occurrence of the genus Pomatomus in the fossil
record.
The extant bluefish is a pelagic species distributed world-
wide except in the eastern Pacific Ocean (Robins and Ray,
1986). It feeds on various fishes, shrimps, lobsters, crabs, and
worms (Manooch, 1984).
Family Carangidae
(jacks)
Seriola sp.
Figure 69e/
HORIZON.—Yorktown Formation (units 1, 2).
Referred Material.—1 dentary, NCSM 1857.
REMARKS.—The dentary (Figure 69c,/) is similar to that of
Seriola dumerili in having the same villiform teeth, numerous
foramina on the outer surface, and the same anterior profile, a
noticeable curvature, from dorsal or ventral view.
Seriola dumerili is an offshore reef fish with a world-wide
distribution (Robins and Ray, 1986). It feeds on crabs, squid,
round herring, round scad, filefish, little tunny, and other fishes
(Manooch, 1984).
Family Sparidae
(porgies)
Archosargus cf. A. probatocephalus (Walbaum, 1792)
Figure 7la
Horizon.—Yorktown Formation (unit 1).
REFERRED Material.—Numerous frontals, USNM 287938,
476235-^76243.
Remarks.—Numerous frontals (Figure 71a), which com-
pare well with those of the extant sheepshead porgy, Archosar-
gus probatocephalus, have been found at Lee Creek Mine.
They are very thick and robust, and at their anterior ends, they
have a V-shaped groove for accepting the ethmoid. On the pos-
terior half of the dorsal surface, along the midline, there is an
elevated crest. Based on frontals alone, we hesitate to make a
specific identification.
Archosargus probatocephalus is a benthic species that oc-
curs from Nova Scotia south to Brazil, primarily in bays and
estuaries (Robins and Ray, 1986). It feeds on shellfish and sea
urchins (Manooch, 1984).
Lagodon cf. L. rhomboides (Linnaeus, 1766)
Figure 7 \b,c
Horizon.—Pungo River Formation (units 2-6); Yorktown
Formation (units 1,2).
Referred Material.—Numerous isolated teeth, USNM
291137; 1 partial vomer-ethmoid, NCSM 9589.
Remarks.—The isolated teeth (Figure lib) from Lee Creek
Mine compare well with those of the extant Lagodon rhom-
boides. In cross section, the teeth are round at the base and in-
cisiform at the tip; a small notch divides the tip, and the result-
ing lobes of the tip are rounded or pointed.
The vomer-ethmoid fragment (Figure 71c) from the York-
town Formation also compares well with that of the extant L.
rhomboides; there are no characters in this specimen or in the
isolated teeth that would warrant separating them from the ex-
tant species, but the remains are too fragmentary to determine
that they are the same species.
We must remark on the abundance of these teeth at Lee
Creek Mine. Because these teeth are small and phosphatic, they
are found in the flotation concentrate produced by the mill.
Along the base of the outdoor storage piles, the coarser grains
of concentrate accumulate on the crests of wind ripples, and
Lagodon teeth can be picked in great numbers from this coarse
fraction. Because as many as two million tons of concentrate
may be on the ground at a given time, the numbers of these fos-
sil teeth are astronomical.
There are only two other reported fossil occurrences of La-
godon, one from the St. Marys Formation of Maryland (Berry,
1932) and one from a Pliocene deposit in Florida (Caldwell,
1957).
Lagodon rhomboides is a benthic species that occurs from
Massachusetts to the Yucatan Peninsula (Robins and Ray,
1986) at depths from several centimeters to 67 m; it feeds on
worms, crustaceans, and mollusks (Manooch, 1984).
Pagrus hyneus, new species
Figure 71a"-/
Holotype.—One partial neurocranium from the frontals to
the occipital area, NCSM 2916.
Type Locality.—Lee Creek Mine, Aurora, North Carolina.
Horizon.—Yorktown Formation (unit 1).
Paratypes.—One partial neurocranium including the fron-
tals and the occipital area and a nonswollen supraoccipital
crest, USNM 479858; both frontals with supraoccipital crest,
NCSM 10221.
Etymology.—In recognition of Becky and Frank Hyne,
whose collections at the Lee Creek Mine have increased our
knowledge of the fossil fish faunas of North Carolina.
Diagnosis.—This species differs from all other sparids by
the narrow frontals, which thicken anteriorly; the articulation
surface of the frontal with the ethmoid being, in profile, a deep-
ly grooved "W"; the greatly hyperostosed supraoccipital,
which in dorsal view is as wide as the frontals; and the apex of
the supraoccipital crest being, in lateral view, above the poste-
rior margin of the orbit.
REMARKS.—In the holotype (Figure lld-f), the supraoccip-
ital crest articulates along the midline ridge of the frontals, with
its point of origin at the anterior end of the frontal. From the
midline an oblique frontal ridge continues caudally onto the
pterotic, where the ridge thickens and becomes grooved along
174
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
¦ "•i...'!v;v^

FIGURE 71.—Archosargus cf. A. probatocephalus: a. USNM 476240, left frontal, dorsal view. Lagodon cf. L.
rhomboides: b, USNM 291137, incisiform tooth; c, NCSM 9589, vomer-ethmoid, dorsal view. Pagrus hyneus,
new species: d, NCSM 2916 (holotype), neurocranium, lateral view; e. same specimen, dorsal view;/ same
specimen, ventral view; g, NCSM 10221 (paratype), both frontals with supraoccipital crest, lateral view; h,
same specimen, dorsal view; i, same specimen, ventral view. Pagrus sp.:j. USNM 298296, paired frontals, dor-
sal view; k, same specimen, ventral view. Stenotomus cf. S. chrysops: I, USNM 412154, neurocranium, dorsal
view; m. USNM 336236, right premaxilla, lingual view. (Scale bars: a,b,d-f,j-l=\.0 cm; c,g=0.5 cm;
h,i.m=0.75 cm.)
NUMBER 90
175
its crest. Another ridge extending from the frontal-supraoccipi-
tal suture intersects this ridge on the pterotic. Lateral to the
frontal and anterior to the pterotic, there is a triangular sphenot-
ic. Caudal to the pterotic, on the dorsal surface of the epiotic, is
the epiotic condyle, which articulates with the posttemporal.
Pagrus hyneus has characteristics that are similar to both
Pagrus pagrus, the extant red porgy, and Stenotomus, the ex-
tant Atlantic scup. Like the fossil species, P. pagrus possesses
the same frontal-supraoccipital articulation, the same frontal-
pterotic ridge morphology, and the same shapes of the epiotic
condyle and the sphenotic.
Pagrus hyneus shows greater similarity to the genus Pagrus
than to Stenotomus in the following characters: (1) the supraoc-
cipitals articulate along two-thirds of the length of the frontals
rather than along one-half of their length as in Stenotomus; (2)
the structure of the ridge that runs from the frontal-supraoccipi-
tal articulation to the epiotic; and (3) the shape of the epiotic
condyle. For these reasons we place the fossil species in the ge-
nus Pagrus. We also think that the differences in the shape and
placement of the supraoccipital crest, the thickness of the fron-
tals anteriorly, and the profile of the articular surface of the
frontals with the ethmoid warrant the establishment of a new
species.
Pagrus sp.
Figure 71/*
HORIZON.—Yorktown Formation (unit 1).
Referred Material.—About 100 frontals, USNM 287925,
287927,287929, 289366, 290552, 290652, 298296.
REMARKS.—Numerous frontals (Figure l\j,k), which com-
pare well with the extant red porgy, Pagrus pagrus, occur at
Lee Creek Mine. Like Archosargus, these frontals are thick-
ened by an elevated crest, which is worn down in most speci-
mens, along the midline of the posterior half of their dorsal sur-
faces. Unlike Archosargus and P. hyneus, the anterior margins
of the frontals are not grooved.
Pagrus pagrus is a benthic species that occurs from New
York to Argentina in the deeper parts of the continental shelf
(Robins and Ray, 1986) at depths of 27 to 110 m (Manooch,
1984). The extant species feeds on worms, snails, crabs, and
sea urchins (Manooch, 1984).
Stenotomus cf. S. chrysops (Linnaeus, 1766)
Figure 7 l/,m
Horizon.—Yorktown Formation (units 1, 2?, 3?).
Referred Material.—3 premaxillae, USNM
336236-336238; posterior portion of 1 neurocranium, USNM
412154.
Remarks.—The Lee Creek Mine specimens agree well with
those of Stenotomus chrysops, the extant Atlantic scup. The
fossil neurocranium (Figure l\l,m) differs from Stenotomus
chrysops in having a much broader and more massive anterior
section of the parasphenoid, but it is still not as great as that in
Pagrus.
The premaxillae are similar to S. chrysops in having larger
teeth distally, small villiform teeth toward the symphysial end
and on the labial edge at the symphysial end, one row of large
teeth, and a small descending process at the distal end of the
premaxilla.
Stenotomus chrysops is a benthic species that occurs from
Nova Scotia to South Carolina, inhabiting the near-shore re-
gion of the continental shelf; it feeds on shrimp, worms, clams,
starfish, snails, crabs, and sea urchins and occasionally on
small fishes (Manooch, 1984).
Family Sciaenidae
(drums)
Sciaenops sp.
Figure 72a-d
HORIZON.—Yorktown Formation (units 1, 2).
Referred Material.—14 incomplete premaxillae, USNM
244482, 285336, 285348, 285366, 286857, 290621, 290623,
290653, 291067, 291117, 291144, 291166, 291203, 291668; 6
dentaries, USNM 244470, 284899, 285341, 286902, 291086,
291098; 2 vertebrae, USNM 244481.
Remarks.—This is a large sciaenid that closely resembles
Sciaenops ocellatus. The premaxillae (Figure 12a,b) differ
from those of the latter species in that the alveoli within the
cardiform tooth area, which is lingual to the row of enlarged
teeth, are not uniform in size. The bases of the lingualmost
tooth row enlarge toward the symphysis, which suggests the
presence of teeth that were about one-half the size of those of
the enlarged labial row. Among the other sciaenids, the pres-
ence of a labial row of large teeth distinguishes these premaxil-
lae from those of Micropogon and Leiostomus. Lingual to this
row, the presence of a cardiform tooth area distinguishes this
form from Cynoscion and Otolithus. The closely spaced labial
teeth are more like those of Sciaenops than like the widely
spaced teeth of Menticirrus.
The dentaries (Figure 72c) differ from those of S. ocellatus
mainly in that the tooth-bearing area is convex dorsally rather
than flattened.
Also illustrated (Figure 72^) is an associated pair of anteri-
ormost vertebrae. These vertebrae match those of S. ocellatus
and are about the right size to be associated with the above
mouth parts, but all of the sciaenids have very similar vertebrae
in this region, and they cannot be identified with certainty.
Sciaenops ocellatus (Linnaeus, 1766)
Figure 72e
Horizon.—Yorktown Formation (?unit 3, possibly much
higher).
Referred Material.—Fragmental skeletal parts from one
individual, including pieces of both premaxillae, an opercular,
176
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
articular, quadrate, hyomandibular, atlas, and thoracic verte-
brae lacking neural arches, USNM 475010.
Remarks.—The stratigraphic position of this specimen is
uncertain, but the preservation of the bone is similar to that of
the material from unit 3 of the Yorktown Formation. The bones
of this partial skeleton are so similar to the extant species that
there is no question that the Lee Creek Mine specimen is this
species. Consequently, the specimen may have come from a
considerably higher position in the Lee Creek Mine section.
The extant Sciaenops ocellatus is a benthic species that oc-
curs from Massachusetts to Tuxpan, Mexico, in coastal and es-
tuarine waters (Simmons and Breuer, 1962). It feeds on shrimp,
crabs, sand dollars, and bony fishes, such as menhaden, mullet,
pinfish, pigfish, searobins, lizardfish, spot, croaker, and floun-
der (Manooch, 1984).
Pogonias cf. P. cromis Cope, 1869
Figure 72/g
HORIZON.—Pungo River Formation (units 4, 5); Yorktown
Formation (units 1, 2, 3?).
Referred Material.—6 complete upper pharyngeal
plates, NCSM 3469, USNM 287978, 459832-459835; 1 com-
plete lower pharyngeal plate, USNM 459836; numerous in-
complete pharyngeal plates, USNM 256270, 256271, 290625,
290665, 290676, 291107, 291108, 291112, 291195, 291259,
291683; 2 premaxillae, questionably referred; isolated pharyn-
geal teeth (Pungo River Formation, units 4, 5); 2 worn pharyn-
geal plates (Yorktown Formation, unit 3).
Remarks.—Compared to the extant black drum, Pogonias
cromis, and the Miocene species, P. multidentatus Cope, the
Lee Creek Mine pharyngeals are more similar to those of the
extant species.
Based on a nearly complete, upper right pharyngeal dental
battery from the Calvert Formation of Westmoreland County,
Virginia, Cope (1869) described P. multidentatus as having
TABLE 4.—Comparison of the upper pharyngeal in fossil and extant Pogonias.
(VZ=vertebrate zoology collection.)
Specimen	Pharyngeal length (mm)	Number of teeth	Age
Pogonias cromis			
USNM VZ 26132	24.5	18	recent
USNM VZ 110700	51	33	recent
USNM VZ 110216	63	37	recent
Pogonias multidentatus			
Holotype	45	45	Miocene
Pogonias cf. P. cromis			
NCSM 3469	69	36	Pliocene
USNM 287978	41	24	Pliocene
USNM 459832	78	43	Pliocene
USNM 459833	67	41	Pliocene
USNM 459834	72	41	Pliocene
USNM 459835	68	35	Pliocene
more crushing teeth in the same relative area than does the
modern species, P cromis. The number of teeth in the Lee
Creek Mine specimens, all upper pharyngeals, falls within the
range of the extant species (Table 4).
In contrast to P. cromis, the Lee Creek Mine pharyngeals
(Figure 12f,g), are more elongate. Perhaps correlated with this
elongation, a consistent difference appears in the articulation of
the pharyngeal to the epibranchial. On the dorsal surface of the
upper pharyngeal of P. cromis, a ridge originates near the ante-
rior border, slightly toward the symphysial side of the plate's
midwidth. This ridge extends posteriorly and gives rise to a
knob to which the second epibranchial attaches. This ridge
originates relatively further back on the Lee Creek Mine speci-
mens and is longer and narrower than that of the modem form.
Therefore, we assign these specimens only tentatively to the
extant species.
The extant Pogonias cromis is a benthic species that occurs
from New England to Argentina in coastal and estuarine waters
(Choa, 1978). It feeds on clams, mussels, oysters, crabs,
worms, and some fishes (Manooch, 1984).
Family Labridae
(wrasses)
Tautoga cf. T. onitis (Linnaeus, 1758)
Figure 72h-j
Horizon.—Yorktown Formation (units 1,2).
Referred Material.—4 incomplete premaxillae, USNM
207605, 459843^159845; 7 incomplete and 2 complete lower
pharyngeals, USNM 290501, 297606, 281341,
459838-459841; 2 upper pharyngeals, 281341, 459842.
Remarks.—Several premaxillaries (Figure 12h,i) collected
at the Lee Creek Mine, except for size, compare favorably with
those of the extant tautog, Tautog onitis. The fossil premaxil-
laries are nearly twice the size of those of the extant species
available to us. The extant tautog premaxillaries were from in-
dividuals between 350 and 407 mm TL, which are less than
half the maximum size (915 mm TL) for this species. This size
difference, therefore, does seem not taxonomically significant.
In dorsal or ventral view the lower pharyngeals (Figure 72/)
form an isosceles triangle, with the top pointing anteriorly.
The dorsal surface of the pharyngeal is covered with cylindri-
cal teeth of varying sizes, with the largest toward the midline,
and with blunt, rounded crowns. In the one complete speci-
men with an associated upper left pharyngeal, the lower pha-
ryngeal has an anteroposterior length of 16.7 mm and a width
of 38.8 mm. In a nearly complete specimen, in which the ante-
rior edge is missing, the anteroposterior length is about 21
mm, and it is 52.2 mm wide. These specimens, except for
their sizes, are identical with those available of the extant spe-
cies, Tautoga onitis.
Based on an incomplete premaxilla from the Miocene of Vir-
ginia, Leidy (1873) proposed the new genus and species Pro-
tautoga conidens. He distinguished it from Tautoga onitis by
NUMBER 90
177
FIGURE 72.—Sciaenops sp.: a, USNM 244482, anterior portion of left premaxilla, lingual view; b, same speci-
men, occlusal view showing outer row of large alveoli and inner cardiform area; c, USNM 244470, anterior end
of dentary, labial view; d. USNM 244481, associated atlas and second vertebrae. Sciaenops ocellatus: e, USNM
475010, lateral view of atlas. Pogonias cf. P cromis, upper right pharyngeal plates, occlusal view:/ USNM
256270; g, USNM 256271. Tautoga cf. T. onitis: h, USNM 207605, incomplete right premaxilla, lacking deli-
cate posterior and elongate ascending processes, labial view; i, same specimen, lingual view;/ USNM 459838,
lower pharyngeal, occlusal view. (Scale bars: o-g=1.10 cm; h-j=l.O cm.)
its large size, greater number of teeth, and the wider spacing of
its teeth. As in the extant species, however, these characteris-
tics reflect different stages of growth, and Leidy's species Pro-
tautoga conidens cannot be separated from the extant species,
Tautoga onitis.
The extant tautog is a benthic species that occurs from Nova
Scotia south to South Carolina (Robins and Ray, 1986) at
depths of 1 to 30 m (Bigelow and Schroeder, 1953). It feeds on
mussels, barnacles, crabs, shrimp, and worms (Manooch, 1984).
Family Uranoscopidae
(stargazers)
Astroscopus sp.
FIGURE 73a-c
HORIZON.—Yorktown Formation (unit 1).
Referred Material.—5 opercula, USNM 412156,
412158-412160,459837; 1 preoperculum, USNM 412157.
178
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Remarks.—The Lee Creek Mine opercula (Figure 13a,b)
are very similar to those of Astroscopus guttatus in the shape of
the articular fossa of the opercula, which articulates with the
opercular process of the hyomandibular, in the ridge line ex-
tending from this facet posteriorly to approximately two-thirds
of the mesial surface of the opercula, and in ornamentation.
The preoperculum is a somewhat crescent-shaped bone with
three radially divergent processes along the caudal edge (Fig-
ure 73c). Like the extant species, the exterior surface of the
bone is ornamented with circular depressions. The Lee Creek
Mine specimens are insufficient for attempting a specific iden-
tification.
I

\
FIGURE 7 s—Astroscopus sp.: a, USNM 412156, Yorktown Formation, operculum, medial view; b, same speci-
men, lateral view; c, USNM 412157, preoperculum, lateral view. Sphyraena cf. 5. barracuda: d, USNM 295338,
Yorktown Formation, anterior portion of left dentary, labial view; e, USNM 476367, Yorktown Formation, par-
tial right dentary, lingual view;/ USNM 291168, Pungo River Formation, isolated tooth; g, USNM 291081,
Yorktown Formation, vertebra, lateral view; h, USNM 476368, Yorktown Formation, premaxilla, occlusal view.
(Scale bars=1.0cm.)
NUMBER 90
179
Astroscopus has been previously reported from the Atlantic
Coastal Plain. Ray et al. (1968) identified to this genus an otico-
temporal portion of a neurocranium from the Pleistocene
Kempsville Formation of Virginia, and Fitch and Lavenberg
(1983) also identified otoliths from the Pliocene at Lee Creek
Mine to this genus.
Of the two extant species along the Atlantic coast of the
United States, Astroscopus guttatus is a benthic species that oc-
curs from New York to North Carolina, and A. y-graecum oc-
curs from North Carolina to Mexico (Robins and Ray, 1986).
Family Sphyraenidae
(barracudas)
Sphyraena cf. S. barracuda (Walbaum, 1792)
Figure 7sd-h
HORIZON.—Pungo River Formation (units 2-6); Yorktown
Formation (units 1, 2).
REFERRED MATERIAL.— 9 vertebrae, USNM 291076,
291081; 1 dentary lacking teeth, USNM 291664; 4 partial den-
taries with teeth, USNM 291236, 295338, 437561, 476367; 2
partial premaxillae, USNM 476368; about 40 uncataloged frag-
ments of jaws; about 50 isolated teeth, USNM 291168.
REMARKS.—In both the Pungo River and Yorktown forma-
tions, lanceolate and compressed barracuda teeth (Figure 73/)
are among the more common osteichthyan remains. The teeth
offer no certain characteristics that distinguish them from the
modern form, Sphyraena barracuda. Fossil sphyraenid spe-
cies founded on isolated teeth, such as S. major Leidy or 5.
speciosa Leidy, probably cannot be distinguished from S. bar-
racuda.
The Lee Creek Mine dentaries (Figure 13d,e) are within the
size range of S. barracuda. On their symphysial ends, they bear
a large, lanceolate tooth that is followed by a single row of la-
biolingually compressed to flat, carinate teeth. Some of these
dentaries came from individuals that attained a very great size;
the largest, USNM 295338, which is lacking its posterior half
(Figure 73a"), has a depth at the symphysis of 37.5 mm.
In the symphysial area of the premaxilla (Figure 73/z), two
large lanceolate teeth are followed by teeth similar to those in
the dentary, but they are much smaller than those in the oc-
cluding dentary. Both the dentaries and the premaxillaries are
indistinguishable from those of the extant Sphyraena barra-
cuda.
Vertebrae, which we believe are sphyraenid (Figure 73g),
also were collected at Lee Creek Mine. Although the neural
arch is broken away in the available specimens, the long,
smooth, medially constricted centra with deep sulci dorsal to
the midheight duplicate recent specimens.
Sphyraena barracuda is an offshore reef species that occurs
from Massachusetts to Brazil and also occurs worldwide in
tropical and warm-temperate waters (Robins and Ray, 1986). It
feeds on many species of bony fishes, including jacks, silver-
sides, parrotfish, and filefish (Manooch, 1984).
Family SCOMBRIDAE
(mackerels and tunas)
Sarda aff. S. sarda (Bloch, 1801)
Figure 74
Horizon.—Pungo River Formation (units 4, 5); Yorktown
Formation (units 1-3).
Referred Material.—Numerous mesethmoids, USNM
290654, 291082, 291090, 291146, 291170, 291201; numerous
portions of skulls, USNM 290544, 290595, 475012, 475013,
476225-476231; anterior end of 1 dentary, USNM 476250; nu-
merous hypural elements, USNM 290681, 291092, 291095,
291104, 291140, 291152, 291158, 291160, 291167, 291169,
291197, 291233, 291252, 291677, 476396; numerous uncata-
loged vertebrae.
Remarks.—The incomplete dentary (Figure 74/) from the
Yorktown Formation belongs to the tribe Sardini, which in-
cludes the genera Cybiosarda, Orcynopsis, Gymnosarda, Al-
lothunnus, and Sarda. Sarda sarda is the only member of the
group now occurring in the western Atlantic Ocean, and it is
with this species that the fossil compares favorably.
A characteristic feature of Sardini dentaries, other than the
large teeth, is the acute angle formed between the plane of the
tooth row and the anterior margin of the dentary (see Collette
and Chao, 1975). This angle is about 65° on the fossil, but it is
usually less than 57° on dentaries of recent Sarda. In this as-
pect the fossil dentary resembles Cybiosarda.
In Sarda, Collette and Chao (1975) also noted the presence
of a notch on the upper portion of the anterior margin of the
dentary; in the Lee Creek Mine specimens, this notch is weakly
developed or absent. The extant bonitos Cybiosarda, Orcynop-
sis, and Gymnosarda lack this notch; however, unlike Cybio-
sarda and Gymnosarda, the Lee Creek Mine dentaries possess
a notch in the anterior, ventral margin that is similar to the
notch in the dentaries of Orycnopsis and Sarda.
Despite the noted differences between the fossil dentary and
the dentaries of Sarda, the fossil dentary compares more favor-
ably with those of this genus than with any of the others in the
Sardini. It may prove to be a distinct species, but available fos-
sil material is inadequate to establish its identity.
Mesethmoids (Figure 14a,b) and incomplete skulls (Figure
14c,d) are common fossils in the lower Yorktown Formation.
On the center of the ventral surface of the mesethmoid, the an-
terior end of the vomer (or prevomer) is often present. Like
most other bonitos except Orcynopsis, the anterior edge of the
ethmoid is "concave... with an anteromedian projection and an
anterolateral horn on each side" (Collette and Chao, 1975:539).
These characters are found in the Lee Creek Mine meseth-
moids, which are identical to those of the extant species.
180
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 74.—Sarda aff. 5. sarda: a, USNM 290654, mesethmoid, dorsal view; b, same specimen, ventral view,
with anterior end of prevomer; c. USNM 476225, incomplete skull, dorsal view; d, same specimen, ventral view;
e, USNM 476369, incomplete hypural, lateral view;/ USNM 476250, anterior portion of dentary, labial view.
(Scale bar= 1.0 cm.)
The incomplete skulls are principally left or right portions of
the skull roof from the anterior tips of the frontals to the su-
praoccipital and epiotic. As in Sarda, the sphenotic is larger
than it is in Thunnus atlanticus or T. obesus.
The triangular hypural plate is composed of five fused hy-
pural bones (Potthoff, 1975). According to Collette and Chao
(1975), the dorsalmost hypural bone, hypural 5, does not
completely fuse with the hypural plate in the bonitos or in
higher tunas, Auxis to Thunnus; they did not present charac-
ters for the hypural plates that could be used to separate Sar-
da from other bonitos or from tunas. A vestige of the primi-
tive hypural notch is present only in the bonito genus Gymno-
sarda.
While examining the skeletons of the extant Sarda sarda
and comparing them to the Lee Creek Mine specimens, we no-
ticed that the majority of ethmoid fossils were equal to or
smaller than those from the extant species (550 mm TL size
range). A hypural from a 550 mm TL Sarda sarda had a
cranio-caudal length of 13 mm and a dorsoventral height of 16
mm. The Lee Creek Mine hypurals (Figure 74c), which we
have assigned to Sarda sarda, are very small, 13-14 mm in
cranio-caudal length and 15 mm in dorsoventral width, and
lack a hypural notch; therefore, based on size, these hypurals
are assigned to Sarda.
Sarda sarda is a coastal pelagic species that occurs from the
Gulf of St. Lawrence to Argentina (Robins and Ray, 1986); it
feeds on squid, mackerels, anchovies, menhaden, silversides,
and shrimp (Manooch, 1984).
Auxis sp.
Figure 75
Horizon.—Yorktown Formation (unit 1).
Referred Material.— 1 nearly complete dentary, USNM
291139.
REMARKS.—This dentary (Figure 75) is a flat, thin bone with
a single row of minute teeth. The dorsal surface bearing the
tooth row rises toward the distal end; at the mesial end it is bent
slightly toward the symphysis. The teeth are broken off, but the
preserved tooth bases are circular in cross section, uniform in
size (approximately 0.5 mm in diameter), and evenly spaced
(13 teeth per cm). On the lingual face the intermandibularis
fossa is short and broad. It is bounded above by a shelf-like an-
teroventrally directed ridge.
The dentary is 11.6 mm high and 5.2 mm wide at the sym-
physis. Height at the mesial termination of the notch dividing
the dorsal and ventral rami is 14.8 mm. Width at the same place
is 5 mm.
The combination of a distally rising tooth row, small teeth,
and the peculiar intermandibularis fossa allies this dentary with
Auxis. The fossil dentary differs only in minute detail from a
dentary of Auxis thazard (Collette collection, USNM; uncata-
loged; 315 mm fork length). The fossil dentary is four times
larger than that of the extant specimen; it has a shorter inter-
mandibularis fossa, and at the distal end, the tooth row does not
rise to as great an extent as it does in the extant species.
The genus Auxis is currently represented by two species,
Auxis rochei, the bullet tuna, and A. thazard, the frigate tuna.
NUMBER 90
181
a
FIGURE 75.—Auxis sp., USNM 291139, nearly complete dentary: a, labial view; b, lingual view showing abbre-
viated intermandibular fossa. (Scale bar= 1.0 cm.)
These are pelagic species that occur in the warm waters of the
Indian, Pacific, and Atlantic oceans (Joseph et al., 1980).
Thunnus sp.
Figure 76
HORIZON.—Pungo River Formation (units 3, 4); Yorktown
Formation (unit 1).
Referred Material.—Numerous isolated vertebrae,
USNM 291070, 475232-475234, 494371; 36 hypural bones,
including 1 nearly complete caudal complex, USNM 291069,
291092, 291140, 291152, 291160, 291167, 291169, 291197,
291252, 291677; about 100 incomplete dentaries, USNM
290162, 290163, 290575, 290622, 290672, 291093, 291094,
291119, 291242; about 50 incomplete premaxillae, USNM
290551,475011; 1 articular, USNM 291147; 2 maxilla, USNM
291132, 291202; 5 quadrates, USNM 290648, 291111,
291129,291237,291247; 1 angular, USNM 319669.
Remarks.—In the Yorktown Formation at Lee Creek Mine,
the most abundant teleost remains are those belonging to Thun-
nus. This material agrees well with most of the available skele-
tons of the extant tunas. As Gibbs and Collette (1967) noted,
the amount of variation that occurs in different skeletal ele-
ments of the genus Thunnus often overlaps between different
species; although some skeletal characters for identifying spe-
cies do exist, they are not preserved in the material available to
us. Species determination will have to await the availability of
articulated skeletons.
In the Lee Creek Mine collection, the numbers of tuna-like
scombrid vertebrae (Figure 76a) exceed those of all other te-
leostean taxa combined. Many of these are exceptionally large
and duplicate in size and form those of the extant Thunnus
thynnus. The precaudal vertebrae are slightly wider than tall
and bear deep upper and lower fossa. At the anterior border of
the ridge that separates these fossae, there is a small triangular
depression for ligament attachment.
In that the parhypural is not fused to the complex, the fused
hypural plate does not bear a medial notch, and there is a deep
fossa developed on the hypural just behind the terminal cen-
trum. The hypural complex (Figure 16b) is typical of Thunnus.
The large size of the complex suggests that it belongs to Thun-
nus thynnus rather to some other species in the genus.
The dentaries (Figure 76c) bear a single row of very small
(1.5 mm in basal diameter), evenly spaced (4-6 per cm), coni-
cal teeth. Due to a pronounced rounded crest on the lingual side
situated above the intermandibularis fossa, the bone is unusual-
ly thick for scombrid dentaries. The head for the attachment of
the geniohyoideus muscle is at the head of the fossa below this
ridge and is unusually prominent.
Two incomplete dentaries from the Pungo River Formation,
USNM 290162 and 290163, differ from those of T. thynnus in
that the intermandibularis fossa does not reach up to the sym-
physis and the mesial edge of the bone is only faintly notched
rather than prominently notched (Figure 76o"). The available
fragmental material is not sufficient to establish the specific
identity of the Pungo River Thunnus, but it may be closely re-
lated to T. thynnus.
A small premaxilla (34 mm long; approximately 38 mm re-
stored), USNM 290551 (Figure 76e), from unit 3 of the York-
town Formation, has large, well-spaced teeth with labiolingual-
ly compressed bases and conical, lingually curved tips. Tooth
shape and spacing and the overall shape of the bone are very
similar to a premaxilla of T obesus. The only apparent differ-
ence is the much thinner dorsal process of the fossil premaxilla.
Premaxillae, however, appear to be conservative elements in
Thunnus skeletons so identifications based on them are neces-
sarily tenuous.
Tunas are pelagic species that have a world-wide distribution
in tropical and temperate waters (Robins and Ray, 1986). They
feed on larval crustaceans, squid, paper nautilus, filefish, trig-
gerfish, jacks, mackerel, and many other bony-fish species
(Manooch, 1984).
Acanthocybium solandri (Cuvier in Cuvier
and Valenciennes, 1831)
Figure 77
Sphyraenodus bottii Capellini, 1878:250, pl. 3: figs. 1-6 [middle Miocene,
Italy].
Scomberomorus both (Cappellini).—Caria, 1973:19, pl. 6: figs. 1, 2, pl. 7: figs.
1, 2, pl. 8: figs. 1-3 [Miocene, Sardinia].
HORIZON.—Yorktown Formation (unit 1).
Referred Material.—1 dentary, USNM 319668; 1 in-
complete dentary, USNM 291077; 3 incomplete premaxillae,
USNM 25782; 4 hypurals, USNM 291084; 1 precaudal verte-
bra, USNM 476370.
Remarks.—In the fossil dentaries and premaxillae, each
ridge, sulcus, and foramen as well as the shape and relative size
of these jaw elements, and the replacement pattern of the teeth
182
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 76.—Thunnus sp.: a, USNM 494371, Yorktown Formation, incomplete caudal vertebra, lateral view; b,
USNM 291069, Yorktown Formation, associated hypural complex, lateral view; c, USNM 290575, Yorktown
Formation, partial left dentary, labial view; d. USNM 290163, Pungo River Formation, partial right dentary, lin-
gual view; e, USNM 290551, Yorktown Formation, left premaxilla with teeth, labial view. (Scale bars= 1.0 cm.)
are duplicated in three western Atlantic specimens of Acantho-
cybium solandri. The fossils are from larger individuals than
the largest recent individual available to us (1780 mm TL; 36.8
kg), and they exceed the known size range of the species (max-
imum observed size -83 kg).
In the fossil form, the premaxillae (Figure 77a) have a great-
er transverse diameter compared with jaw depth, particularly at
the dorsal edge below the tooth row. The ratio of the transverse
diameter (width) to depth at the tenth alveoli from the symphy-
sis of the fossil premaxilla averages 0.54, whereas this ratio in
the modern specimens averages 0.44. This difference is minor
compared to the much more marked differences in proportions
and tooth shape encountered when comparing corresponding
bones from two allopatric species of Thunnus, for example.
Furthermore, this is the sort of change one would expect from a
normal allometric growth pattern.
The most nearly complete and largest dentary (Figure lib)
of this species from Lee Creek Mine, USNM 319668, exhibits
the characters identified by Collette and Russo (1984:575,
578-579) as diagnostic of dentaries of Acanthocybium: the
teeth are more tightly packed, the notch on the anteroventral
margin is absent, and a prominent notch is present on the ante-
rior margin of the dentary.
The fossil hypural (Figure 77c) is typical of Acanthocybium
solandri in that the parhypural, which carries the laterally ex-
tending parhypurapophysis, is fused to the complex, and the
posterior border of the plate carries a well-defined medial
notch. The condition in Gymnosarda is similar (Collette and
Chao, 1975) but differs in that hypural five and the parhypural
are incompletely fused to the complex. Scomberomorus, the
most closely related extant genus, also has a similar caudal
construction, but the parhypural is not always completely
fused. The only striking quality of the fossil caudal complex
when compared to A. solandri is its large size. Dorsoventral di-
ameters of the fossils range from 49 to 88 mm, but modern
specimens that have been examined do not exceed 50 mm.
Precaudal Acanthocybium vertebrae (Figure lid) are easily
recognized by the development of three lateral sulci rather than
the usual two.
Capellini (1878) established Sphyraenodus bottii on the basis
of an associated dentary and premaxilla, which also compares
favorably with Acanthocybium solandri.
NUMBER 90
183
FIGURE 77.—Acanthocybium solandri: a, USNM 25782, posterior end of premaxilla, labial view; b, USNM
319668, anterior end of dentary, labial view; c, USNM 291084, hypural, lateral view; d, USNM 476370, verte-
bra, lateral view. (Scale bars: a=2.0 cm; b= 1.0 cm; c= 1.25 cm; rf=0.9 cm.)
Acanthocybium solandri is a pelagic species that occurs
from New Jersey to South America and is distributed world-
wide in tropical and warm-temperate waters (Robins and Ray,
1986). It feeds on a variety of bony fishes, including frigate
mackerel, butterfish, porcupinefish, and round herring (Ma-
nooch, 1984).
Family Xiphiidae
(swordfishes)
Xiphias gladius Linnaeus, 1758
FIGURE 78
Horizon.—Yorktown Formation (unit 1).
Referred Material.—1 rostrum fragment, USNM
476396.
Remarks.—In the course of studying the Lee Creek Mine
marlins, Harry Fierstine (pers. comm., Nov 1993) discovered a
FIGURE 78.—Xiphias gladius, USNM 476396, lateral view of rostral fragment
showing rectangular chambers. (Scale bar=1.0 cm.)
fragment of a swordfish rostrum (USNM 476396). He stated
that the central chambers of the rostrum (Figure 78), which are
rectangular in this specimen, are distinctive characters of Xiph-
ias rostra (Poplin, 1975; Poplin et al, 1976).
According to Manooch (1984:306), the extant swordfish is a
warm-water species; in the summer, it ranges from Newfound-
land to Argentina. It feeds on squid and bony fishes, including
hake, mackerel, and barracuda.
184
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Family ISTIOPHORIDAE
(marlins)
For the genera Makaira, Istiophorus, and Tetrapturus, see
Fierstine (this volume).
Hemirhabdorhynchus sp.
Figure 79
HORIZON.—Pungo River Formation (units 2-5).
Referred Material.—7 broken rostra, USNM 24745,
421907^121909.
REMARKS.—Leidy (1856a: 12) gave the name Cylindracan-
thus ornatus to a fluted fish spine that was said to be from the
Upper Cretaceous beds near Pemberton, Burlington County,
New Jersey, but the type specimen was not illustrated. Later
that year, in the same journal, Leidy (1856b:302) noted that
Agassiz had previously described two species, Coelorhynchus
rectus and C. sinuatus, based on the same type of spine, which
Agassiz (1833-1843:92) said were from the London Clay
(Ypresian) at Sheppey, England. In 1905 Leriche noted that
Coelorhynchus Agassiz is a junior homonym of Coelorhynchus
Giorna, and unaware of Leidy's genus Cylindracanthus, he
erected the genus Glyptorhynchus. Four years later Leriche
(1909:381-383) discovered the priority of Leidy's genus; at the
same time he restricted the name Glyptorhynchus to fluted ros-
tra with flat oral surfaces bearing two parallel bands of crowd-
ed alveoli for very small acicular teeth. He did not, however,
know of these rostra until after he erected Glyptorhynchus; this
last genus, therefore, is a junior synonym of Cylindracanthus,
and it is not available for Leriche's rostra with flat oral surfaces
bearing two bands of tooth alveoli.
Based on Leriche's holotype of G. costatus but excluding
other species of Glyptorhynchus, Casier (1946:155) erected the
genus Hemirhabdorhynchus, which he characterized as having
"a more or less depressed cylindro-conical form, with longitu-
dinal costae, limited to the dorsal half or nearly on this half,
and by the existence of two ventral wide alveolar bands."
These characters also may be applied to the species Casier ex-
cluded. If Leriche's and Casier's separation of these rostra
from Cylindracanthus is correct, then Hemirhabdorhynchus is
the senior name for these rostra.
The familial identity of these specimens is uncertain. On the
basis of the two bands of small acicular teeth, Leriche (1910,
1936a, 1942) placed this genus in the Xiphiidae. As confirming
evidence of this taxonomic assignment, Leriche (1910) men-
tioned a rostrum associated with vertebrae and a hypural from
the Oligocene of Belgium. Concerning the hypural of Leriche's
specimen, as in the Istiophoridae but not the Xiphiidae, the par-
hypural is fused to the ventral hypural plate; unlike the avail-
able hypurals of the extant Xiphiidae and Istiophoridae, the hy-
pural notch is extremely shallow. In other scombroids,
however, both of these characters may vary within a family.
Because the shape of the rostra and tooth bands are characteris-
tic of the Istiophoridae rather than the Xiphiidae, we assign
Hemirhabdorhynchus to the Istiophoridae.
The rostra (Figure 79) are known only as detached elements,
and they are very seldom found complete. They are long,
straight, slender rods of dense bone that taper to a point, which
may be rounded by wear. Except for the flattened tooth-bearing
surface, they are covered completely by fine longitudinal
grooves, which may be obscured by wear. The flattened surfac-
es bear two parallel bands of tooth alveoli, which are similar to
those found on istiophorid rostra (Figure 19b); between these
parallel rows the surface of the spine is smooth to very finely
grooved.
Order Pleuronectiformes
Family BOTHIDAE
(lefteye flounders)
Paralichthys sp.
Figure 80o-c
HORIZON.—Yorktown Formation (units 1, 2).
Referred Material.—2 anterior portions of dentaries with
teeth, USNM 412162, 412163; 1 left maxilla, USNM 412164;
1 partial right articular, USNM 412165.
Remarks.—The maxilla (Figure 80a), which consists of the
articular end, is identical to that of the extant Paralichthys den-
tatus. The dentary (Figure 806) has long, stout, rugose teeth,
which, as in P. dentatus, are almost one-half the height of the
dentary. The lower one-third of the dentary is striated distally
and has a sculptured texture. The partial right angular (Figure
80c) is lacking most of the anterior process, the coronoid pro-
cess, and part of the postarticular process. Because the fossil
FIGURE 79.—Hemirhabdorhynchus sp.: a, USNM 421907, rostral fragment, dorsal view; b, same specimen, ven-
tral view; c, same specimen, cross-sectional view. (Scale bar= 1.0 cm.)
NUMBER 90
185
material consists of isolated bone fragments, species determi-
nation is not possible at this time.
Paralichthys dentatus is a benthic species that occurs from
Maine to northern Florida (Robins and Ray, 1986). It feeds pri-
marily on menhaden, silversides, sand lances, herrings, ancho-
vies, weakfish, squids, shrimp, and crabs (Manooch, 1984).
Order Tetraodontiformes (Plectognathi)
Family Monacanthidae
(filefishes)
AI uterus sp.
Figure SOd-f
HORIZON.—Pungo River Formation (units 4-6); Yorktown
Formation (units 1-3).
Referred Material.—About 200 hyperostosed vertebrae,
USNM 286157, 286158, 286164, 290288, 290302, 290528,
291690, 291693, 291707-291729, 291731-291779,291801,
291803-291805, 291807-291823, 291825-291827, 291831,
291834, 291840-291845, 291847-291849, 291851-291856,
291858-291862,476354.
Remarks.—The most common hyperostosed bones found in
the lower Yorktown Formation are vertebrae, which are identi-
cal in their morphology and hyperostosis to those of the extant
Alutents shoepfi. Like the extant species, they are dorsoventral-
ly compressed, with prominent dorsal and ventral grooves on
the centra (Figure 80o». In articular view, the second precau-
dal vertebra is hexagonal in outline. Two or three precaudal
vertebrae are often found as a fused unit (Figure 80/"). The pre-
caudal vertebrae from Lee Creek Mine have a more pro-
nounced lateral ridge than do those of the extant species, and
FIGURE SO.—Paralichthys sp.: a, USNM 412164, proximal portion of left maxilla, labial view; b, USNM
412162, symphseal portions of left dentary, labial view; c, USNM 412165, partial right articular, labial view.
Aluterus sp.: d, USNM 290302 (left) and 290288 (right), vertebrae, dorsal view; e, same specimens, axial view;
/ USNM 476354, three fused caudal vertebrae, tlorsal view. (Scale bars: a=0.5 cm; 6=1.25 cm; c=1.5 cm;
c/,e= 1.0 cm;/=1.25 cm.)
186
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
the centra in the more cranial vertebrae are more elongate than
those of A. shoepfi.
The average craniocaudal length is 2.1 cm (range =1.74-2.28
cm, m=11); the average dorsoventral height is 1.4 cm
(range=1.15-1.63 cm, n=\ 1), and the average lateral width is
1.8 cm (range= 143-2.24 cm, «=11).
The extant Aluterus shoepfi ranges from Nova Scotia to Bra-
zil and also is found worldwide in temperate and tropical wa-
ters (Robins and Ray, 1986). It prefers coral reefs and rocky
bottoms. This species feeds on a variety of invertebrates, in-
cluding crabs and shrimp (Thomson et al., 1978).
Family Tetraodontidae
(puffers)
Sphoeroides hyperostosus Tyler, Purdy, and Oliver, 1992
Figures 81,82e
HORIZON.—Yorktown Formation (units 1-3).
Referred Material.—Skull and first 4 vertebrae, USNM
437601 (holotype); incomplete cranium, USNM 290643; skull
roof and first 3 vertebrae, NCSM 11179; 8 dentaries, USNM
364354, 364356, 437601; 7 premaxillae, USNM 364349,
364350, 364351; about 3000 opercula, USNM 364328-
FlGURE 81.—Sphoeroides hyperostosus: a, USNM 437601, holotype, dorsal view of skull; b, same specimen,
lateral view of left side; c, USNM 364351, left premaxilla, labial view; d, same specimen, lingual view; e,
USNM 364356, left dentary, labial view;/ same specimen, lingual view; g, USNM 457096, preoperculum, lat-
eral view; h, USNM 364322, sightly hyperostosed suboperculum, lateral view; i, USNM 440874, extremely
hyperostosed suboperculum, lateral view;y, USNM 364329, operculum, lateral view; k, USNM 283794, ventral
postcleithrum, lateral view; /, USNM 437601, second to fourth abdominal vertebrae removed from holotype, lat-
eral view. (Scale bars= 1.0 cm.)
NUMBER 90
187
364339; about 500 preopercula, USNM 364340-364346,
457096; about 500 subopercula, USNM 364321-364327,
440814, 440859, 440864, 440867, 440874, 440885, 440893;
about 500 ventral postsupracleithra, USNM 283794, 283839,
283891, 284070, 364361-364363; about 100 uncataloged ver-
tebrae.
REMARKS.—The remains of this fish are among the most
abundant present in the lower units of the Yorktown Forma-
tion. Tyler et al. (1992) identified these remains as a new spe-
cies of pufferfish, Sphoeroides hyperostosus. The reader is re-
ferred to this paper for a description of the Lee Creek Mine
type material. Prior to Tyler et al., Weiler (1973:469-477)
identified the suboperculum, preoperculum, and ventral postsu-
pracleithra as hyperostosed parts of the fin skeleton of an inde-
terminate fish.
Subsequent to the publication of Tyler et al. (1992), one of us
(V.P.S.) collected a third skull roof of this species, including
the right operculum, cleithrum, dorsal postcleithrum, hyperos-
tosed ventral postcleithrum, and three associated vertebrae
from the Yorktown spoil piles (Figure 82e). From ethmoid to
pterotics, the skull roof is nearly complete. On the left side, the
frontal portion of the flange formed by the frontal and the sphe-
notic is missing; on the right side it is incomplete. Like the ho-
lotype, the lateral ethmoid is broad, with a flat, unornamented
upper surface, and the posterior dorsal surfaces of the frontals
have thick, curved crests that extend posteriorly as short pro-
cesses over the epiotics. The cleithrum and matrix adhering to
the ventral portion of the skull roof obscure the morphological
details of this area.
The closest living relative of Sphoeroides hyperostosus, S.
maculatus, does not posess any hyperostosed bones (see Tyler
et al., 1992).
Sphoeroides maculatus is a benthic species that occurs from
Newfoundland to northern Florida (Robins and Ray, 1986). It
is found in sandy-bottom habitats in waters ranging from 1 to
54 m deep (Manooch, 1984). It feeds primarily on clams, mus-
sels, shrimp, worms, sea urchins, sponges, sea anemones, sea
squirts, and crabs (Manooch, 1984).
Family Diodontidae
(porcupineflshes)
Chilomycterus schoepfi (Walbaum, 1792)
FIGURE %2a-d
HORIZON.—Pungo River Formation (units 4, 5); Yorktown
Formation (units 1-3); James City Formation.
Referred Material.—Partial skull, NCSM 8364; about
2000 mouthplates, USNM 291200, 291219 (Yorktown Forma-
FlGURE 82.—Chilomycterus schoepfi: a, NCSM 8364, skull, dorsal view; b, USNM 291200, occlusal view of
upper jaws showing trituration tooth plates; c, USNM 291219, occlusal view of lower jaws; d. USNM 476374,
dermal spine, dorsal view. Sphoeroides hyperostosus: e, NCSM 11179, dorsal view of skull roof. (Scale bars:
a=2.0 cm; b,c,e=\.0 cm; d=0.5 cm.)
188
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
tion), 476400, 476401 (James City Formation); numerous der-
mal spines, USNM 476374.
Remarks.—Although many jaws (Figure 82b,c) and a partial
skull were available for study, these bones are identical in Di-
odon and Chilomycterus; the skeletons can be separated only on
the basis of dermal spines (Tyler, 1980). The dermal spines of
Diodon are two-rooted and erectile, whereas those of Chilo-
mycterus are three-rooted, short, and triangular. The spines
found at Lee Creek Mine (Figure %2d) clearly resemble those of
Chilomycterus. Because specimens of Diodon have not yet been
found at the mine, we believe the other skeletal elements found
at Lee Creek Mine also should be referred to Chilomycterus.
The partial skull, NCSM 8364 (Figure 82a), includes well-
preserved fused dentaries, ethmoids, and frontals. The fused
premaxillae are badly crushed as is the posterior portion of the
skull. The skull is 65 mm wide and 106 mm long.
The most common remains of this fish at Lee Creek Mine are
incomplete, fused dentaries and fused premaxillae that consist
of the beak and tooth plate area; these are alike in both jaws
and thus are difficult to distinguish from each other. In com-
plete dentaries, on each side of the tooth plate area, there is a
rounded, ventrally directed process that articulates with the an-
gular. Remnants of these processes are often preserved in the
fossils. A portion of the ventral surface of the dentary is often
worn away, exposing a small area of the tooth-forming surface.
On the dorsal surface of the premaxilla, the fragile processes
that articulate with the vomer-ethmoid complex are missing,
exposing a large area of the tooth-forming surface. In occlusal
view, the beaks of the dentaries tend to be rounded; those of the
upper jaw are usually pointed.
Chilomycterus schoepfi is a benthic species that occurs pri-
marily from North Carolina to Brazil. It is common in seagrass
beds in bays and coastal lagoons (Robins and Ray, 1986). Por-
cupinefishes feed primarily on shrimp and crabs (Manooch,
1984).
Family Molidae
(ocean sunfishes)
Mola chelonopsis (Van Beneden, 1883)
Figure %sa,b
Horizon.—Yorktown Formation (unit 1).
Referred Material.—5 premaxillae, USNM 265650,
291211, 457143,476341, 476395.
Remarks.—Weems (1985:431-432) identified the Lee
Creek Mine specimens to this species, and he characterized it
as follows: "Premaxillary beak toothless, and lacking palatal
tooth brace, toothless shelf anterior to location of the former
tooth position much longer than in M. mola, such that the ante-
ro-posterior beak length is greater than the lateral beak width at
the level of the back shelf. Dentary beak comparable to M. mo-
la." Due to the lack of comparative material of the extant spe-
cies and the unavailability of Van Beneden's type specimen,
we cannot confirm or refute Weems's identification.
The Lee Creek premaxillae have attached to them portions of
the edentulous palate (Figure 83a, b). In all five specimens the
articular ends of the premaxillae are missing.
Molas are pelagic fish that have a worldwide distribution in
warm waters. In the Atlantic they range from Newfoundland to
South America. They feed on jellyfishes, Portuguese man-of-
war, ctenophores, and other soft-bodied pelagic invertebrates
and on larval fishes (Robins and Ray, 1986).
Teleost incertae sedis
Emmons's "fish tooth"
Figure 83c-e
Horizon.—Yorktown Formation (unit 3).
Referred Material.—About 12 specimens, mostly bro-
ken, USNM 421518.
Remarks.—Emmons (1858:244, figs. 99, 100) reported on a
small fossil from the marl beds (probably the Yorktown For-
mation) in Edgecombe County, North Carolina, which he con-
sidered to be a "fish tooth," attached by ligaments in the throat.
Emmons's fish tooth is not a tooth but a hyperostosed bone, the
identity of which has eluded paleontologists and ichthyologists
for over 140 years.
At Lee Creek Mine only a few of these enigmatic forms have
been found in the thin unit 3 of the Yorktown Formation. Unit
3 was described by Gibson (1967:646) as "2 feet of blue clayey
fine sand," and the irregular contact and color contrast with the
underlying unit 2 are shown very well in his pl. 1. Small, isolat-
ed patches of unit 3 sediments can readily be spotted on the
weathered spoil piles by their darker color and finer grain tex-
ture. Close inspection of these patches has yielded distinctive
small fossils (otoliths, porcupinefish spines, crab chelae, etc.),
including the examples of Emmons's "tooth."
Emmons's tooth is bilaterally symmetrical, consists of dense,
brittle bone, and has a maximum height of 13 mm. It is bean-
shaped but more attenuated at one end than the other, with a
sulcus down the midline of the convex side, and some speci-
mens split along this plane. On the concave side of the "bean,"
there is a longitudinal, deep groove at the midline. It is also on
the concave side that the attenuated end curls inward, forming a
"beak." In well-preserved specimens, the groove forms the
back wall of a bifurcating tubular process that allowed the pas-
sage of nerves and blood vessels.
Paleoecology
The 104 species of Lee Creek Mine fossil fishes represent
the first fossil record of a marine vertebrate, high-use feeding
area and the largest and most diverse fossil fish fauna known
from the Atlantic Coastal Plain. Of these taxa, 55 are found in
the Pungo River Formation, and 77 are found in the Yorktown
Formation. Because we were unable to bulk-sample the York-
town fauna, it may be even more diverse than available evi-
dence indicates.
NUMBER 90
189
FIGURE 83.—Mola chelonopsls, USNM 265650, fused premaxillae: a, occlusal view; b, lateral view of right
side. Emmons's "fish tooth," USNM 421518, anatomical orientation unknown: c, front view; d, lateral view; e,
rear view. (Scale bars= 1.0 cm.)
These faunas, and their associated sedimentological and in-
vertebrate paleontological data, permit us to interpret the paleo-
ecology of the Pungo River and Yorktown seas.
Temperature
Lee Creek Mine is at the southwestern extremity of the Au-
rora embayment, a deep Tertiary embayment (Figure 84) of the
western Atlantic continental shelf (Popenoe, 1985). During the
Miocene and early Pliocene, the 100 m depth contour was near
the present mouth of the Pamlico River. During Pungo River
and basal Yorktown time (Riggs, 1984; Snyder, 1988), this em-
bayment allowed upwelling, colder waters to intrude over 100
km westward onto the continental shelf, an area covered by
warm-temperate to subtropical surface waters. The Lee Creek
fauna reflects this contrast in temperatures.
Gibson (1967) concluded from his study of benthic foramin-
ifera that the bottom temperatures during Pungo River and low-
er Yorktown deposition were cool-temperate. In addition, Gib-
son's (1987) study of the pectens demonstrated a greater
similarity to those of the Calvert Formation to the north than to
those of similar ages in Florida. In contrast, approximately
two-thirds of the modern representatives of the fossil fish fauna
of both formations now have tropical and/or warm-temperate
distributions, whereas only one-third of the fauna suggests a
cool-temperate influence.
Pungo River Formation.—Taxa that can be broadly
grouped as eurythermic tropical and warm-temperate domi-
nate (70%) the Pungo River fauna. These are species that mi-
grate to avoid temperature extremes (>25°-28°C, <15°C),
coming north during the spring and summer and returning
south during the winter. This fauna has a distinctly warm but
not a tropical character. The following examples support this
warm character and suggest temperatures no colder than 20°C
during the warm season.
Stingrays (Dasyatis, the dominant batoid) and other rays
(Rhinoptera, Mobula) occur in the Carolinian province (North
Florida to Cape Hatteras) only during the summer, when sur-
face temperatures are between 20°C and 27°C (Bigelow and
Schroeder, 1953:11). Except Rhinoptera, which seems to toler-
ate cooler temperatures, they are not usually found north of the
21°C isotherm.
The most common shark taxa at Lee Creek Mine are warm-
water carcharhiniforms: twenty of the species (30%) and 11 of
Middle
Miocene
coastline
FIGURE 84.—Map showing location of Lee Creek Mine in relation to the
Aurora Embayment (after Popenoe, 1985, published with permission of Kluwer
Academic Publishers).
190
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
the genera (22%). This dominance also applies to the relative
abundance of carcharhiniform remains. In samples obtained by
screening substantial quantities of the phosphate ore, teeth of
Carcharhinus macloti are as numerous as those of the other
shark taxa combined. Following Carcharhinus macloti in these
screen residues are (in decreasing order of abundance) Car-
charhinus brachyurus, Galeocerdo, Hemipristis, and Sphyrna
cf. S. media. The abundance of carcharhiniforms compared
with other galeoid sharks parallels modern warm-temperate
and tropical faunas. Also, the diversity of carcharhinid genera
exceeds that now present on the middle Atlantic Seaboard and
is similar to the diversity encountered in tropical seas.
Temperature range during the Pungo River deposition was
probably at least as great as that of the Carolina province today
(15°-25°C). Warm-water taxa such as Sphyraena, Negaprion,
Sphyrna cf. S. media, and Hemipristis suggest maximum tem-
peratures as great as 27°C. None of the Pungo River taxa are
found only in cool waters; therefore, we believe that warm-
temperate to subtropical temperatures persisted year round.
The warmth of the Pungo River sea may account for the lack
of abundance of tuna and other pelagic fishes that are common
in the Yorktown Formation. Horwood and Cushing (1978) ob-
served that the largest stocks of pelagic fish are associated with
thermal boundaries where the waters are high in nutrients. In
his study on the phosphate-phosphorus and zooplankton vol-
umes of the Pacific Ocean, Reid (1962:302) noted two condi-
tions, which may also have affected the productivity of the
Pungo River sea: (1) if the depth of the boundary between the
warm surface water and the denser, cooler upwelling water is
deeper than 75 m, the concentrations of phosphate-phosphorus,
which are utilized by plankton, are low; and (2) "high tempera-
tures are usually accompanied by lower plankton volumes."
Popenoe (1985) noted also that in Pungo River time the Aurora
embayment was isolated from both northward- and southward-
flowing currents; the embayment was an area of quiet deposi-
tion. These conditions may have reduced the productivity of
the Pungo River sea, which would account for the scarcity of
oceanic fish, such as tunas, and sperm whales (see below),
which are common in the Yorktown Formation.
Yorktown Formation.—Unlike the Pungo River fauna,
the Yorktown fauna has a distinctly modem aspect, particularly
among the teleosts, so paleoecologic inferences are more defi-
nite. The dominant taxa are sturgeon (Acipenser), scombrids
(Thunnus, Sarda, Acanthocybium), billfish (Makaira), filefish
(Aluterus), hakes (Merluccius), bluefish (Pomatomus), tilefish
(Lopholatilus), pufferfish (Sphoeroides), porcupinefish (Chilo-
mycterus), and the sharks—Isurus, Hemipristis, and Galeocer-
do. Except Hemipristis, this is a mix of tropical, warm-temper-
ate, and cool-temperate forms with ranges that overlap near
Cape Hatteras today, but their abundance suggests that a ther-
mocline existed in the Lee Creek area of the Yorktown sea.
The cool-temperate components of the assemblage (seven
taxa, 15% of the fauna) include the genera Merluccius and Lop-
holatilus, which are common at Lee Creek Mine, and the rarer
Squalus, although its rarity may be due to collection bias.
These taxa suggest temperatures in the 4°-18°C range
(Grosslein and Azarovitz, 1982) (10°C is the optimum temper-
ature for Squalus acanthias, according to the distributional data
of Edwards et al., 1962). The abundance of Merluccius and Lo-
pholatilus at Lee Creek Mine suggests that cool water was an
important component of the Yorktown sea.
The warm component of the fauna (14 taxa, 30% of the fau-
na) includes the genera Sphyraena, Makaira, Acanthocybium,
Epinephelus, Hemipristis, Isistius, Negaprion, and Pristis. Be-
cause they occur exclusively in tropical areas, the temperature
regime suggested by these fishes is 27°C (the temperature
boundary between warm-temperate and tropical in the western
Atlantic Ocean) or warmer.
Abundant tuna, marlin, sea birds, sea turtles, and cetaceans
suggest that the area was an important feeding ground. Off the
west coast of Central America today, in waters underlain by a
sharp thermocline, a similar abundance of marine vertebrates
occurs: feeding tuna force schools of prey fish to the surface
where cetaceans, sea turtles, and sea birds feed on them (Au
and Perryman, 1985). Au (1991:346) elaborated on the make-
up of these polyspecific associations with tuna schools, noting
that "sharks clearly stood out among the fishes found associat-
ed with tuna." The most common species was Carcharhinus
falciformis; less common sharks were C. longimanus, C. leu-
cas, and Rhincodon typus. The rays observed were mostly "me-
dium- to large-sized manta rays (Mobulidae)" (Au, 1991:346).
Among the bony fishes present, he reported billfishes, includ-
ing Makaira, dolphinfish (Coryphaena), amberjack (Seriola
sp.), wahoo (Acanthocybium solandri), and triggerfish (Balis-
tidae). Cushing (1971), in his study of upwelling and the pro-
duction of fish, mentioned that hake (Merluccius) also are
abundant in upwelling areas. Au (1991) could identify only
three of the sea turtles he observed: Lepidochelys olivacea,
Dermochelys coriacea, and Chelonia mydas. Boobies (Sula
spp.), shearwaters (Puffinus spp.), and frigatebirds Fregata
spp.) were the most common birds in the area, and the porpois-
es included Stenella spp. and Delphinus delphis (Au, 1991).
With the exceptions of Carcharhinus longimanus and Dermo-
chelys coriacea, all of these genera occur in the Yorktown fau-
na. Their abundance at Lee Creek Mine suggests the presence
of nutrient-rich, cold, upwelling waters meeting warm water
from the Gulf Stream to provide an important feeding zone for
both warm- and cold-water fishes and other marine vertebrates.
The abundance of tuna and sperm whale remains in the
Yorktown Formation suggests a divergence of the Gulf Stream
into the Aurora embayment. Cushing (1971:315) noted, "The
coastal upwellings are less important to the tuna than offshore
divergences. ...Although tuna may be caught in the area of
coastal upwelling, it is likely that they pass 100 km or more
offshore." Concerning sperm whale catches, Cushing
(1971:320) stated, "This suggests that the sperm whales do not
in fact aggregate in the coastal upwellings themselves but in
offshore divergences.... Thus the sperm whale must be a truly
NUMBER 90
191
oceanic animal like the tuna and may be excluded to some ex-
tent from the coastal upwelling themselves." At Lee Creek
Mine, 100 km west of the edge of the continental shelf, these
two oceanic vertebrates occur abundantly.
Depth
Three general bathytrophic groups of fishes occur at Lee
Creek Mine (percentage constituted by the Pungo River assem-
blage and the Yorktown assemblage, respectively, follows):
predominantly coastal fishes of the inner shelf (0-100 m)
(33%, 49%), outer-shelf benthic or mesopelagic fishes
(100-1000 m) (12%, 9%), and epipelagic fishes (45%, 21%).
About 9% of the Pungo River assemblage and 11% of the
Yorktown assemblage are benthic groups that may occur over
either the inner or outer shelf; these are excluded in the figures
given above.
In the Pungo River assemblage, the relative rarity of coastal
fishes and the abundance of epipelagic, outer shelf, benthic,
and mesopelagic fishes suggest a deeper depositional environ-
ment than that prevailing during the Yorktown deposition. The
abundance of "blue water" fishes (open-ocean epipelagic spe-
cies, such as Thunnus thynnus and Acanthocybium solandri)
and the rarity of strictly near-shore species suggest deposition
of the Yorktown Formation at the Lee Creek locality occurred
in the deeper part of the inner shelf but not as deep as that of
the Pungo River Formation.
In both formations, the same groups of coastal benthic fishes
limit the maximum depth. Stingrays (Dasyatis), which are
common in both formations, occur mostly in water shallower
than 37 m and are unknown in water deeper than 110 m (Big-
elow and Schroeder, 1953). Lagodon ranges from the shore
down to 74 m. The largest individuals of L. rhomboides occur
in the deepest part of the range (Caldwell, 1957); specimens
from the Pungo River Formation are near the maximum report-
ed size of the extant species.
In the Yorktown assemblage, the only taxa present that pro-
vide some indication of minimum depth are Hexanchus, Isis-
tius, Scyliorhinus, a tilefish (Lopholatilus), and a hake (Merluc-
cius). Both species of Hexanchus are mesopelagic or deep
epipelagic in warm-temperate and tropical areas; they are usu-
ally found at depths of 90 m and greater (Compagno, 1984).
Similarly, the species of Isistius inhabit epipelagic to bathype-
lagic waters (Compagno, 1984:93-96). The genus Scyliorhinus
inhabits the outer shelf and continental slope, but there are ex-
ceptions. The fossil scyliorhinid S.l distans, which occurs in
the Yorktown Formation, cannot now be satisfactorily related
to any extant member of the genus, so any inference as to its
depth tolerance would be suspect.
Merluccius and Lopholatilus are more limited in occurrence.
If the habitats of Merluccius sp. and M. bilinearis are alike,
fairly deep water is indicated. Merluccius bilinearis ranges
from the shoreline to a depth of about 550 m off the New En-
gland coast (Grosslein and Azarovitz, 1982:72). It is not known
from the Carolinian coast, but it has been taken sporadically off
the Virginia coast in waters between 160 and 350 m deep
(Hildebrand and Schroeder, 1928). Winter ranges are some-
what shallower along the middle Atlantic Coast. Edwards et al.
(1962) recorded occurrences of M. bilinearis as shallow as 31
m and in relative abundance between 131 and 316 m off the
mouth of Chesapeake Bay. According to Grosslein and Azaro-
vitz (1982:83), Lopholatilus "ranges in depth from about 75 to
460 m," and in the Middle Atlantic Bight, "it is concentrated in
depths of approximately 110 to 240 m." In view of the latitude
of the deposit and the inferred temperature, it is unlikely that
depths were much shallower than 50 to 60 m.
In the Pungo River Formation, no species were found that
would suggest a minimum depth. Based on foraminiferal as-
semblages, Gibson (1983:63-64) reported that the lower Bel-
haven Member "formed on the middle to outer shelf (approxi-
mately 100- to 200-m water depth)" and the upper Bonnerton
Member "formed on the middle to inner shelf (150 m to less
than 70 m in the uppermost bed)."
Paleoecological Comparisons
Pungo River Fauna.—When we compared this fauna to
other fossil fish faunas in the Atlantic Coastal Plain and Eu-
rope, we discovered some important differences. The taxonom-
ic composition of the two formations is very similar to that of
the Calvert Formation of Maryland and Virginia, with three
significant exceptions: the absence or scarcity of the mako
shark Isurus xiphodon, the absence of tilefish, Lopholatilus,
and the absence of sturgeon, Acipenser, in the Pungo River fau-
na. The absence of the mako shark may be due to the absence
or rarity of pinnipeds in the Pungo River Formation, which
were present in the Calvert sea. Tilefish are burrowers
(Grosslein and Azarovitz, 1982) that inhabit areas with clay
and boulder substrates; the abundance of sand, which is unsuit-
able for tilefish burrows, in the Pungo River Formation may
explain their absence here. We found no clues to explain the
absence of sturgeon.
In the Calvert Formation near Smyrna, Delaware, which was
deposited in shallow coastal or estuarine waters (Purdy, in
prep.), the fish fauna differs from that of the Calvert Formation
of Maryland and Virginia and the Pungo River Formation. Ex-
cept for sea catfish at Smyrna, teleost remains are less com-
mon. Unlike the Pungo River fauna, the teeth of Carcharodon
megalodon, which represent very small individuals, and Isurus
are uncommon. In contrast to the rarity of these species, the
teeth of adult Negaprion, which are rare in the Calvert and
Pungo River faunas, are very common. The shallower depths
of the Delaware portion of the Calvert sea probably account for
these faunal differences.
A slightly older (Aquitanian) fauna from the Belgrade For-
mation (Case, 1980), 47 km (30 mi) south of Lee Creek Mine
at New Bern, is at the northern limit of the Atlantic Coastal
Plain Miocene limestone beds and contains a subtropical fauna.
192
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
It differs from the Pungo River shark fauna in the presence of
Heterodontus and Carcharhinus isodon (identified by Case
(1980) as Aprtonodon acuarias). In the extant shark fauna,
both taxa prefer water temperatures above 20°C (Compagno,
1984; Castro, 1983). The Lee Creek Pungo River sea may have
been slightly cooler than these sharks preferred.
Gillette (1984) noted a similarity between the Miocene fau-
nas of Panama, Ecuador, and the Caribbean region and the
Pungo River Formation, but some important differences exist.
Odontaspids and species of Isurus are absent from the first
three faunas and in them the number of carcharhiniform sharks
(Panama, 8; Caribbean, 4; Ecuador, 7) is much less than the
number present (19) in the Pungo River Formation. Although
the taxa present in these faunas are similar to those in the Pun-
go River Formation, they are cosmopolitan, warm-water taxa,
and their presence sheds little light on the similarity of the en-
vironments for these faunas.
In comparison to the European Miocene, the Pungo River
Formation has a greater abundance of carcharhiniform sharks
(19 species) than either the Belgian Miocene (4 species) (Ler-
iche, 1927; Nolf, 1988) or the Swiss Molasse (8 species) (Ler-
iche, 1926). The Belgian Miocene sea appears to have been
cooler than that of the Swiss Molasse or the Pungo River For-
mation; Hemipristis, a subtropical shark common to the last
two, was absent in the Belgian Miocene sea. Absent from both
the Belgian and Swiss faunas is the subtropical lemon shark,
Negaprion, which suggests that the Pungo River sea was
warmer than those of Belgium or Switzerland.
The differences between these faunas reflect the important
influence of ecological factors on the distribution offish taxa,
particularly sharks, an influence that must be considered in
stratigraphic interpretations even in geographically close areas.
Yorktown Fauna.—Unlike the Yorktown Formation, fish
remains are uncommon in the Raysor Formation of South
Carolina and the Duplin Formation of North and South Caroli-
na, both of which were deposited in shallow, warm water dur-
ing the early Pliocene (Ward et al., 1991). We know of no re-
ports of fish remains from the Raysor Formation. From Duplin
localities (south of the Neuse River), Leriche (1942) reported
the presence of Carcharodon carcharias and Chilomycterus
vetus, and from the Martin Marietta quarry at New Bern, ama-
teur collectors Peter J. Harmatuk and Bob Johnson (pers.
comm., 1991) reported the occurrence of Carcharodon megal-
odon. These shallow, warm-water deposits were evidently not
high-use areas for fishes and other vertebrates.
The European Pliocene fish faunas offer some interesting
contrast to the Yorktown fauna. They have fewer taxa, and they
represent cooler environments. In the Belgian Pliocene fish
fauna (Leriche, 1926), warm-water forms, such as Hemipristis,
Negaprion, and Galeocerdo, are absent, and cold-water taxa,
such as Gadus, Merluccius, Carcharodon carcharias, and Ce-
torhinus, are present. In the Pliocene of Italy (Landini, 1976)
more taxa are present than in Belgium, including warm-water
species, but at least two of the shark taxa, Parotodus benedenii
and Galeocerdo cf. G. cuvier, have smaller teeth than do those
of the Yorktown Formation, and two subtropical taxa, Hemi-
pristis and Negaprion, are rare or absent.
In comparison with other Pliocene faunas of the Atlantic
Coastal Plain and Europe, the Yorktown fauna at Lee Creek
Mine has the greatest abundance and diversity of fossil fish and
other marine vertebrates. This suggests to us that at Lee Creek
in Yorktown time, the physiography of the environment of dep-
osition, the presence at shallow depths of upwelling waters,
and the presence of an eddy of the Gulf Stream were significant
factors contributing to the congregation of many marine verte-
brates in this area.
Taxonomic Discussion
The abundant remains at Lee Creek Mine allowed us to re-
construct composite dentitions and to resolve some important
problems in the taxonomy of fossil sharks, problems that can-
not be resolved with a few isolated teeth. For example, by com-
paring the anterior teeth of Carcharodon and Carcharocles, we
were able to reassign the teeth of the latter genus to the genus
Carcharodon. The absence of ontogenetic heterodonty be-
tween juvenile and adult dentitions allowed us to separate Isu-
rus xiphodon from /. hastalis. This fauna also provided suffi-
cient specimens of Parotodus benedenii for us to reconstruct its
dentition, and based on the mako-like nature of characters of
the roots and the size relationships between the upper and low-
er teeth we assigned this species to the Lamnidae.
Composite dentitions, however, have their pitfalls. Shark
teeth vary greatly within a species, even in the anterior teeth.
Before we knew of the variation in mako teeth, we reconstruct-
ed a composite dentition of the invalid species Isurus retroflex-
us. The Miocene species of Galeocerdo are another example.
Applegate (1978) believed that the teeth of Galeocerdo contor-
tus were the lower teeth of G. aduncus Agassiz. Although his
reconstruction seems very logical, we were able to identify
characters that distinguish upper and lower teeth in the denti-
tions of the extant Galeocerdo. When we applied these charac-
ters to the teeth of fossil species, we were able to separate Ga-
leocerdo contortus from G. aduncus (=G. sp. herein). Our
experience with composite dentitions suggests that an exten-
sive knowledge of tooth characters and variation in related ex-
tant species is a prerequisite to reconstructing fossil shark den-
titions accurately.
Associated fossil dentitions are the most important tools of
shark paleontology. At Lee Creek Mine, two associated denti-
tions of Carcharodon subauriculatus, two of C megalodon,
and one of Parotodus benedenii have been found, and these are
more common than previously thought. The current commer-
cial market for shark teeth, however, and the apathy of many
amateur collectors toward preserving these scientifically im-
portant specimens in museums will make these specimens
harder to obtain for scientific research, and thus retard progress
in understanding the systematics and evolution of fossil sharks.
NUMBER 90
193
The rediscovery of some of Agassiz's fossil-fish type speci-
mens allowed us to evaluate some of his species. Although
Agassiz's syntypes of Isurus desori had not been lost, in over
150 years they were never examined and compared to the den-
titions of extant makos. When we made these comparisons, be-
sides designating a lectotype, we determined that one tooth of
Agassiz's type series was definitely from a mako and that it is a
junior synonym of /. oxyrinchus. In contrast, the unknown
whereabouts of the holotype of Probst's Oxyrhina exigua
(^Alopias exigua) leaves unresolved the generic identity of his
species.
Many of the Lee Creek Mine taxa cannot be separated from
the living forms, for example, the Lee Creek specimens identi-
fied as Notorynchus cepedianus, Isurus oxyrinchus, Carcharhi-
nus brachyurus, Cfalciformis, C leucas, C macloti, C. obscu-
rus, C. perezi, C. plumbeus, Negaprion brevirostris,
Triaenodon obesus, Sphyrna lewini, and S. zygaena, which at-
tests to the relative longevity of many shark species. Further
study of the variability in the teeth of extant species may result
in the synonymy of fossil species, such as Hexanchus gigas,
with the extant species and extant species, such as Echinorhi-
nus cookei and Isurus paucus, with the fossil species.
Conclusions
The Lee Creek fossil fish faunas are important because of
their diversity and their abundance and because of the paleo-
ecological information they yield about the Pungo River and
Yorktown seas. Based on the taxa present and other geological
data, we offer the following conclusions.
First, the fish faunas suggest that the Pungo River sea was
warm temperate to subtropical and that the Yorktown sea was
warm temperate with the presence of upwelling cold water.
Second, in Yorktown time this upwelling water supported a
large vertebrate fauna of fish, sea turtles, sea birds, cetaceans,
and pinnipeds. In Pungo River time, upwelling did not reach
shallow depths and the fauna was not as diverse as in York-
town time.
Third, the Pungo River fish fauna suggests that it was depos-
ited in an epipelagic, outer-shelf, benthic environment, whereas
the Yorktown fish fauna suggests that it was deposited in an in-
ner-shelf environment.
Fourth, in comparing both Lee Creek faunas to those of the
Atlantic Coastal Plain and Europe, the Pungo River fauna has
the largest number of warm-water fishes but lacks the subtropi-
cal forms found in the Belgrade Formation that outcrops 47 km
to the south. In comparison to these other Atlantic Pliocene fish
faunas, the Yorktown fauna has the greatest abundance and di-
versity, and it has more warm-water forms than do the Europe-
an faunas.
Fifth, the Lee Creek sediments yielded new records of occur-
rence for the Atlantic Coastal Plain for four fossil shark taxa:
Rhincodon sp. from the Pungo River Formation, Megascylio-
rhinus miocaenicus from the basal Pungo River Formation,
Isistius sp. from the basal Yorktown Formation, and Mega-
chasma sp. from the Pungo River and the Yorktown forma-
tions.
Sixth, the Yorktown Formation yielded two new species of
bony fishes: Lopholatilus rayus and Pagrus hyneus.
Seventh, the Lee Creek shark taxa suggest that shark species
or tooth morphologies existed for several million years or
more.
Eighth, in the extant sharks, tooth form is highly variable;
understanding this variation and knowing the tooth characters
for each dental position is essential to reconstructing fossil
shark dentitions accurately.
Future Study
As we stated earlier, our study is a beginning. Much work
needs to be done in the study of the extant and fossil species.
Recently, ichthyologists have made significant discoveries
about the effects of segregation by size, water temperature, and
ocean-floor topography upon the distribution of fishes (Munoz-
Chapuli, 1984; Klimley, 1985; Galvan-Magana et al., 1989;
Stevens, 1990; Smale, 1991; Klimley etal., 1992; Simpfendor-
fer and Milward, 1993). Considering this information, the fos-
sil record of Tertiary fishes needs to be reexamined in light of
the ecology of modem fishes.
In extant sharks, age/size differences can exist between two
or more populations of a species (see Galeocerdo), and these
differences may occur in other extant species of sharks and also
in the fossil species. Shark vertebrae can be aged by ring
counts, a technique that can be applied to fossil vertebrae,
which are common at Lee Creek Mine. By applying this tech-
nique to fossil faunas, the age and the mean tooth size of a fos-
sil species could be compared with those from other areas. If,
as seems possible (Applegate, 1967; Kozuch and Fitzgerald,
1989), shark vertebrae can be identified to species, the abun-
dant shark vertebrae at Lee Creek Mine will be most useful for
such a study, and by excavating the basal Yorktown Formation,
some of these may be found associated with dentitions.
A new area of investigation for paleontologists is the effect
of segregation by size on the distribution of fossil sharks and
rays. In the extant species, some sharks and rays segregate by
size and/or sex. Females pup in areas that are safe from preda-
tors, and as the pups increase in size, they migrate toward adult
feeding areas. In many shark species, males and females—fe-
males are usually larger than males—live and feed in different
areas except during mating season. This segregation by size
and by sex raises some questions about the fossil record of
sharks: Do size increases in shark teeth reflect evolutionary or
environmental changes? What types of paleoenvironments are
fossil shark teeth found in, and in comparison to the extant spe-
cies, would these paleoenvironments favor sharks of one size
or sex? Do the fossil teeth contribute to the interpretation of
segregation by size or sex? The answers to these questions re-
quire careful stratigraphic sampling of shark-tooth-bearing
194
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
strata, the analysis of paleoecological data, and the comparison
of the fossil species with, if they exist, extant species of the
same genus.
Water temperature and ocean-floor topography affect the
distribution of extant fishes, but their effects upon the distribu-
tion of fossil fishes have not been studied. In the Yorktown sea,
large sharks (Carcharodon megalodon, Isurus xiphodon,
Hemipristis serra, Galeocerdo cf. G. cuvier) and schooling
fishes (Merluccius, Pomatomus, Thunnus) are more abundant
in the area of the Aurora embayment than they are at other
Yorktown localities in North Carolina and Virginia. The pres-
ence of a submarine canyon or embayment and upwelling af-
fected the distribution of these fishes. We can ask, What effects
may water temperature and ocean floor topography have had
on other fossil fish faunas? At Lee Creek Mine, do the differ-
ences in the abundance and the diversity of taxa between units
1 and 3 reflect changes in water temperature? How great is the
taxonomic difference between these two units?
The fossil beds at Lee Creek Mine offer the potential for an-
swering some of these questions and for increasing our knowl-
edge about the taxa that lived there, their environment, and
their relationships with other fossil organisms that lived with
them. A careful excavation of the fossil beds in units 1 to 3 of
the Yorktown Formation would greatly increase our knowl-
edge of the fauna. It would allow us to observe any faunal
changes that occur in these units that cannot be observed ade-
quately by spoil-pile collecting. It would allow us to gather ad-
ditional information about predator-prey relationships. It would
allow us to obtain large samples of the fauna, including many
articulated skeletons, which are so important to the studies of
taxonomy and functional anatomy. Such an excavation would
allow us to create a more detailed and accurate picture of life in
the Yorktown sea.
Lee Creek Mine is a hint of the fossil beds that may lie bur-
ied deep beneath the sea. In comparison to the limited and
geochronologically incomplete outcrops of Tertiary sedi-
ments, the paleontological record of the outer continental
shelf, where today marine vertebrates are abundant, is poten-
tially much more extensive, and it may provide a more contin-
uous record of the evolution of marine environments and ma-
rine vertebrates. The Yorktown fauna at Lee Creek Mine may
be an indication of the species diversity of marine vertebrate
faunas that existed during the Neogene along the edge of the
continental shelf of eastern North America. Today, Lee Creek
Mine is the only exposure of this part of the fossil record
available to us, a part of the fossil record that we have only
begun to understand.
NOTE ADDED IN PROOF
After our paper was submitted for publication, we received
three publications, one by Bourdon (1999) and two by Arnold
Muller (1992, 1999), on the fossil fishes of the Atlantic Coastal
Plain Tertiary sediments. Bourdon, on the basis of teeth, de-
scribed a new species of manta ray, Manta hynei. Because little
is known about dental variation in recent manta rays, we cannot
assess the validity of this species, but we think the naming of it
is premature.
Miiller's publications are all but unavailable in the United
States, and we were unable to comment on his findings in the
present paper. His 1999 work is the publication of his thesis
(1992), which is based on about 12,000 otoliths and some
1000 elasmobranch teeth collected in the Eocene-Pliocene
sediments of the Atlantic Coastal Plain, including Lee Creek
Mine. None of his new species has priority over the two de-
scribed herein.
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Turtles of the Lee Creek Mine
(Pliocene: North Carolina)
George R. Zug
ABSTRACT
Eleven taxa of turtles have been recovered from the Lee Creek
Mine: a sideneck turtle (Bothremys); six seaturtles (Caretta, IChe-
lonia, Lepidochelys, Procolpochelys, Syllomus, and Psephopho-
rus); two pond turtles (probably Pseudemys and Trachemys); a
softshell turtle (trionychid); and a giant tortoise (Geochelone). The
fossils are largely disassociated skeletal elements and fragments
derived from spoil piles created by drag-line mining of phosphate.
The mining removes and discards the Yorktown Formation
(Pliocene) and processes much of the Pungo River Formation
(middle Miocene), hence the Lee Creek Mine turtles are mainly
from the lower Pliocene. The turtle fauna appears to be a natural
assemblage of extant and extinct taxa. Caretta and Syllomus are
the most abundant fossils; a few specimens of each had some
adherent Yorktown matrix. Geochelone fossils are next in abun-
dance, although an order of magnitude less than Caretta and Syllo-
mus. The other genera are each represented by fewer than 10
fragments or elements. Cranial and carapacial differences indicate
that the Lee Creek Caretta represents a new species, C. patriciae.
The Geochelone also differs from its eastern North American
Pliocene contemporaries by its larger size and unique plastral mor-
phology. The fossils of the other taxa are too few and fragmentary
to identify reliably to species or genus.
Introduction
The middle Miocene to early Pliocene faunas of the central
Atlantic coast and coastal plain of North America included a
variety of marine, freshwater, and terrestrial turtles. Marine
species dominated the turtle fauna, and at least one species
each of the sideneck turtle Bothremys; the three hard-shelled
seaturtles Chelonia, Procolpochelys, and Syllomus; and the
leatherback seaturtle Psephophorus have been reported. Other
Miocene turtles from this region included a terrestrial tortoise,
Geochelone, and a softshell turtle (freshwater trionychid). Ad-
ditional hard-shelled seaturtles (Table 1) have been described
George R. Zug, National Museum of Natural History, Smithsonian In-
stitution, Washington, D.C. 20560-0162.
from the central Atlantic and adjacent regions, but close exam-
ination (Weems, 1974) of these fossils has shown these taxa to
be synonyms of Syllomus aegyptiacus (Lydekker). Representa-
tives of these seven genera of turtle occur in the Miocene ma-
rine deposits of New Jersey, Maryland, and Virginia (Table 3).
These turtles and the extant taxa of southeastern North Ameri-
ca provided the comparative base for the identification and
analysis of the temporally and geographically close fossil tur-
tles of the Lee Creek Mine.
The Lee Creek Mine turtles appear to derive primarily from
the Yorktown Formation and, thus, are a more recent fauna
than the turtles from the Calvert Formation of Virginia and
Maryland. The mining operation, however, penetrates and dis-
cards the top of the Pungo River Formation (temporally equiv-
alent to the Calvert Formation), so there is a possibility that a
few Calvert-aged (middle Miocene) turtles are mixed in with
this predominantly (early to middle Pliocene) Yorktown fauna
(see Gibson, 1983, for age and stratigraphy of mid-Atlantic
coastal deposits). The mining operation scatters the fossils
from the numerous beds of the Yorktown Formation, resulting
in fewer associations of skeletal elements with one another or
with their stratum of origin in the Lee Creek Mine fauna as
compared to the Calvert fauna. This lack of positive association
is unfortunate because the Lee Creek seaturtle fauna is diverse
and straddles a faunal transition between a middle Tertiary and
the Holocene fauna.
My primary objective has been to identify the Lee Creek
Mine turtles and briefly describe their fossil remains. This task
has forced me to make taxonomic decisions on isolated bony
elements, and in some instances the amount of comparative
material has been limited. These necessarily tenuous decisions
must be and can be confirmed only with less fragmented and
better associated fossils from Yorktown deposits.
Acknowledgments.—All fossil specimens described here-
in are in the vertebrate paleontological collection of the Nation-
al Museum of Natural History (NMNH, which houses collec-
tions of the former United States National Museum (USNM)).
Some of the USNM catalog numbers cited herein represent lots
rather than individuals due to the quantity of disassociated ele-
203
204
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Table 1.—Miocene turtles described as new species from the central Atlantic coast of North America.
Taxon	Citation	Type locality	Current name
Suborder Pleurodira			
Family PELOMEDUSIDAE			
Taphrosphys miocenica	Collins and Lynn, 1936:155	Calvert County, Maryland	(=Bothremys miocenica)
Suborder Cryptodira			
Family CHELONIIDAE			
Chelonia grandaeva	Leidy, 1851:329	Salem County, New Jersey	(=Procolpochelys grandaeva)
Chelonia marylandica	Collins and Lynn, 1936:162	Calvert County, Maryland	(=Syllomus aegyptiacus)
Peritresius virginianus	Berry and Lynn, 1936:176	Westmoreland County, Virginia	(=Syllomus aegyptiacus)
Syllomus crispalus	Cope, 1896:139	Pamunky River, Virginia	(=Syllomus aegyptiacus)
Family DERM0CHELY1DAE			
Psephophorus calvertensis	Palmer, 1909:370	Calvert County, Maryland	
Family TESTUDrNiDAE			
Testudo ducateli	Collins and Lynn, 1936:166	Calvert County, Maryland	(^Geochelone ducateli)
Family Trionychidae			
Trionyx cellulosus	Cope, 1868:142	Charles County, Maryland	
ments received from the mine. My use of this collection was
aided by Robert Purdy and Clayton Ray (both NMNH). Glad-
wyn Sullivan (NMNH) prepared and assembled the better-asso-
ciated fragments. Victor E. Krantz (NMNH) photographed all
of the specimens.
A number of individuals assisted in this study: Robert
Weems (U.S. Geological Survey), Eugene Gaffney (American
Museum of Natural History), and Rainer Zangerl (Rockville,
Indiana) broadened my narrow outlook on this fossil assem-
blage, and I hope improved my interpretation of it, and they re-
viewed early drafts of the manuscript; more recent versions
benefitted from the comments of D. Bohaska (NMNH), C.
Crumly (Academic Press), K. Dodd (U.S. Geological Survey),
C. Ernst (George Mason University), R. Estes (deceased),
W.R. Heyer (NMNH), A. Holman (Michigan State University),
and R. Weems. I thank all of the above for their assistance.
Seaturtle Identification
The Lee Creek Mine turtle fossils are predominantly hard-
shelled seaturtle fragments, and many of these cannot be identi-
fied to species or even to genus. Having worked with these fos-
sils intensely in the early 1970s and then only episodically until
the final preparation of this manuscript in 1988, I discovered
that my ability to assign taxonomic names with confidence was
directly proportional to my current immersion in seaturtle oste-
ology. To assist my memory, I developed diagnoses for the
main fossil skeletal elements and include them herein to assist
others in the identification of seaturtle elements and fragments.
These diagnoses also document my criteria for the assignment
of taxonomic names to the Lee Creek Mine fossils. The diag-
noses are not complete; they emphasize the type and nature of
the Lee Creek Mine fossils. For example, I describe only the tip
of the dentary because only that part of the lower jaw has been
recovered, and in Psephophorus, only osteoderms are known.
The diagnoses also tend to state differences as absolutes when
some of the differences are more subtle and subjective.
The major features for distinguishing the various genera of
extant cheloniid seaturtles are summarized in Table 2. A partial
skull of Caretta (USNM 186731; Figures 3, 4) was reassem-
bled from fragments. The two critical features for identifying
this skull as Caretta are the exclusion of the frontal from the
orbit and the absence of vomerine-premaxillary contact on the
secondary palate. The frontal also enters the orbit in Pro-
colpochelys and Syllomus.
Dentaries can be differentiated by the nature of the ridges on
the triturating surface. Syllomus has a complex pseudodont
surface (Figure 7a) with a high, denticulate symphyseal ridge
extending across the entire width of the dentary; a high,
sharp-edged denticulate ridge on the lingual edge; and
cone-shaped denticles along the labial border (Weems, 1980,
fig. 2c). The dentary surface is nearly as complex in Chelonia;
a high symphyseal ridge extends across the entire width of the
dentary; a high, sharp-edged ridge is slightly inset along the
entire lingual border; and the labial border is sharp-edged and
occasionally faintly denticulate. In Eretmochelys a low sym-
physeal ridge occurs on the posterior half of the dentary's trit-
urating surface and enlarges near the labial border to form a
large, pyramidal protuberance; a lingual ridge is often evident,
although weakly developed. The triturating surface in Caretta
and Lepidochelys is a smoothly concave surface curving gently
to a sharp labial edge. The labial and lingual borders are
sharp-edged but low. Some Caretta have a low, sharp-edged
symphyseal ridge across the entire width of the dentary. Juve-
nile Lepidochelys kempii (Garman) have a low pyramidal pro-
tuberance (Figure 7b) at the posterior end of the symphysis
and occasionally have a faint lingual ridge; the protuberance
and lingual ridge are not evident in adult L. olivacea
(Eschscholtz). The dentary of Procolpochelys is unknown.
Of the many carapacial fragments, it is possible to distin-
guish the linked osteoderm (=epithecal ossicle) shell of dermo-
chelyids from the typical testudine shell of cheloniids. The os-
teoderms of Psephophorus are large, thick, irregular polygons
(Figure 7c), in contrast to the small, thin, irregular polygons of
Dermochelys. The osteoderms forming the dorsal ridges of the
NUMBER 90
205
Table 2.—Comparison of cranial characteristics of Holocene cheloniid seaturtles and the Lee Creek Mine sea-
turtle skull. Abbreviations: Cc, Caretta caretta (Linnaeus); Cm, Chelonia mydas (Linnaeus); Ei, Eretmochelys
imbricata (Linnaeus); Lk, Lepidochelys kempii; Lo, Lepidochelys olivacea; LCs, Lee Creek skull; +, structure
present or as described; -, absent or not as described; ±, present or absent.
Cranial characteristics		Cc	Cm	Ei	Lk	Lo	LCs
Frontal in orbit		-	+	+	+	+	_
Strong temporal emargination		+	-	-	+	+	+
Supraoccipital ridge blade-like dorsally		+	-	-	±	-	-
Premaxillary-vomer contact on secondary palate		-	+	+	+	+	-
Trochlear process of pterygoid elongate	and thin	+	-	-	-	-	+?
Articular surface of quadrate broad		+	-	_	_	_	+
Triturating surface of dentary strongly r	dged	-	+	+	-	±	-
carapace in Dermochelys are as large in circumference as those
of Psephophorus but are thinner. The reticulated external sur-
face of the Syllomus carapace is unlike the surface texture of
any other cheloniid, although the surface texture might be con-
fused with that of trionychids. The shell elements are distinctly
thinner (absolutely and relatively) in Syllomus than they are in
any of the other Lee Creek Mine cheloniids.
Neurals are found frequently. In most cheloniids, the neu-
rals are elongate hexagons with the posterior segment two to
three times longer than the anterior segment (i.e., cas-
ket-shaped). Only in Procolpochelys are the neurals regular
hexagons; the neurals also are proportionately thicker in Pro-
colpochelys than they are in any of the other seaturtles except
Psephophorus. The neural series in Caretta and Lepidochelys
appears to be evolutionarily undergoing fragmentation and
size reduction. Regular polygonal neurals lie between elongate
ones in these two taxa. In addition to their unique surface tex-
ture, Syllomus neurals often bear a longitudinal ridge along the
entire length of each neural; the ridge ranges from a faint indi-
cation to a distinctly elevated (-5 mm), sharp-edged keel.
Young Caretta and Lepidochelys (of extant species) also have
keeled neurals; in the small juveniles, the middorsal ridge is
continuous only in the youngest individuals. The ridge has
five spines or knobs extending well above the keel. These
spines are most evident in small (carapace length (CL) <25
cm) Lepidochelys; in larger juveniles (CL >40 cm) only the
second spine may persist, and none remains in adults. In L.
kempii the spines occur at the posterior edge of each vertebral
scute, hence on neurals 1, 4, 7, and 10 (neural number may
differ slightly because of tendency for neural fragmentation in
carettine seaturtles) and on the posterior suprapygal. The re-
duction or loss of spines appears to occur from posterior to an-
terior, with the second spine being the last to disappear, and
the external surface of all neurals flattens with increasing cara-
pace length. This external surface is planar in all size classes
of Chelonia and Eretmochelys.
Costal fragments are unidentifiable for most genera, al-
though the surface texture of the Syllomus carapace is unique
and readily identifies even small fragments. Peripherals also
are difficult to assign to genus, other than those of Syllomus. In
general, the larger ninth, tenth, and eleventh peripherals with
distinct, serrate borders were identified as Caretta peripherals.
The pygals of carettine turtles characteristically show a wide,
deep, medial V-shaped notch posteriorly (this notch is small or
absent in Procolpochelys) and have medially slanted peripher-
al-pygal articular surfaces. The cheloniine pygal has a narrow,
shallow notch posteriorly and nearly parallel peripheral-pygal
articular surfaces. These differences emphasize the extremes,
and pygal morphology in cheloniids forms a continuum.
The most numerous limb bones are humeri, and their mor-
phology appears generically diagnostic in most cases. The Syl-
lomus humerus (Figure lC,E; Weems, 1974, pl. 3: figs. 1-3) is
the most distinctive; however, rather than describe the entire
humerus of each genus sequentially, a comparative description
of each part of the humerus is offered. Humeral morphology
terminology follows that proposed by Zug et al. (1986); the
major difference from previous use is the recognition that the
cheloniid humerus possesses both a radial (lateral) process and
a deltopectoral ridge.
The ulnar (medial) process of seaturtles is elongate and ex-
tends proximally. This process is greatly elongated and pointed
in Syllomus (Figure 1C,E) and extends proximally well beyond
the humeral head (roughly the width of the head beyond); this
elongation produces an attenuated appearance, although the Syl-
lomus humerus is proportionately of the same width as that of
the other genera. In Caretta, Lepidochelys, and Procolpochelys
the ulnar process is rounded and extends only slightly beyond
the head proximally. This process is intermediate in length and
is somewhat acute in Chelonia and Eretmochelys.
The radial (lateral) process is low and lies distal to the level
of the humeral head (Figure 1). In Chelonia, Eretmochelys, and
Syllomus the process forms a narrow ridge extending nearly
two-thirds across the ventral surface of the shaft. This ridge is
broader in Caretta, Lepidochelys, and Procolpochelys and ex-
tends across no more than one-half of the shaft.
The articular (cartilage-supporting) surface of the humeral
head is ellipsoidal in all cheloniids (Figure 1). This surface in
Syllomus is narrower and more elongate than in the other five
genera and is moderately pointed at its pre- and postaxial ends.
This surface is usually continuous with the radial process in
Caretta, Lepidochelys, and Procolpochelys, continuous or sep-
arate in Eretmochelys, usually separate in Chelonia, and al-
ways separate in Syllomus. The head appears to extend farther
off the diaphysis in Chelonia and Syllomus.
206
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Figure I.—Morphology of cheloniid right humeri. A, ventral view of a Holocene Chelonia mydas humerus
(USNM, uncataloged); B,D, ventral and dorsal views, respectively, of a Holocene Caretta caretta humerus
(USNM 235590); c,E, ventral and dorsal views, respectively, of a Syllomus aegyptiacus humerus (USNM
433179). Abbreviations: dc, deltopectoral crest or ridge; ef, ectepicondylar foramen; if, intertubercular fossa; re,
radial epicondyle; rp, radial process; ue, ulnar condyle; ur, ulnar process. (Scale bar= 1 cm.)
NUMBER 90
207
In Syllomus the deltopectoral crest is a cone-like tubercle
projecting strongly beyond the preaxial surface. In the other
genera the crest extends longitudinally along the preaxial sur-
face, and it is continuous (or nearly so) with the lesser trochant-
er in all cheloniids except Syllomus, where it is separated from
the radial process by a deep, U-shaped groove. In Caretta and
Lepidochelys the crest is truncate and moderately projecting,
and it is flattened and slightly projecting in Chelonia and Eret-
mochelys.
The Syllomus humerus differs strikingly from that of the oth-
er genera (Figure 1). Using the deltopectoral crest to divide the
humerus into proximal and distal segments, these segments are
subequal in length in Syllomus, and the proximal segment is
one-third to three-eighths the length of the distal segment in the
other five genera. The condylar surface has distinct trochlear
and capitellar ridges in Syllomus; these articular ridges are low
and rounded or are absent in the other genera.
Ulnae are fairly abundant. The ulna of Syllomus differs from
the ulnae of other cheloniids by its robustness and shape. It is
proportionately shorter; has a deep, concave, proximal articular
surface facing postaxially; a raised, sharp-edged postaxial
crest; and a broad, radial articular surface.
The cheloniid femur is similar in all of the Lee Creek Mine
genera, with subtle differences that allow some differentiation
of the taxa. The head is round (nearly circular in outline) in
Chelonia, Eretmochelys, and Syllomus and is ellipsoidal in
Caretta, Lepidochelys, and Procolpochelys. The greater
(posterior) trochanter is large and angular, forming a broad sur-
face anterior to the head in Chelonia, Eretmochelys, Caretta,
and Lepidochelys. In Syllomus this trochanter is equally large,
but the anterior border is curved and extends proximally be-
yond the head; it also is hook-shaped above the intertrochanter-
ic fossa (Weems, 1980, pl. 1: figs. 7, 8). The greater trochanter
of Procolpochelys is narrow and straight-edged relative to the
diaphysis. The lesser (anterior) trochanter is large and protrud-
ing in Chelonia, Eretmochelys, Caretta, and Lepidochelys. It is
about the same size in Syllomus, but the preaxial border is en-
larged and rugose. It is only moderately protruding in Pro-
colpochelys. The condylar surface bears distinct articular ridg-
es only in Syllomus.
Turtle Fauna
Family PELOMEDUSIDAE
(sideneck turtles)
Bothremys
Figure 2
Collins and Lynn (1936) described the sideneck turtle Taph-
rosphys miocenica from an anterior lobe of a plastron. Later,
Gaffney and Zangerl (1968) reassigned this fossil to Bothre-
mys; however, they were reluctant to confirm its specific iden-
tification owing to the incompleteness of the fossil. They did
emphasize that this piece of plastron represented the only un-
questionable sideneck turtle from the Tertiary of North Ameri-
ca. Later, Gaffney (1975) noted that the type material of T. mi-
ocenica was too incomplete to provide a reliable diagonsis,
hence this species is a nomen dubium.
Several pieces of carapace and plastron match the Bothremys
material. A single hexagonal nuchal (USNM 186773; Figure
2a,b) is 59 mm long at its midline, 47 mm wide anteriorly, and
84 mm wide posteriorly. The nuchal is thin (11 mm at thickest
region) and possesses smooth dorsal and ventral surfaces. The
scute sutures are lightly etched on the surface. A cervical scute
is absent. Sutures of the left and right first marginals, left and
right first pleurals, and first vertebral scutes are present dorsal-
ly on the nuchal. No scute sutures are visible ventrally. The
ventral scute surface occupies the anterior third of the nuchal.
The nuchal's shape and the absence of a cervical scute identify
it as a pelomedusid element.
Four fragments are from the plastron. Three of these (USNM
358462A (Figure 2c), 358747, 358784) are xiphiplastral frag-
ments with pubic or ischial articular scars (fusion of pelvic gir-
dle to plastron is characteristic of pleurodires), and the remain-
ing fragment (USNM 358462B) is unidentifiable to plastron
location. A small fragment of a costal (USNM 425594) has the
texture of the other Lee Creek pleurodiran fragments.
A complete left humerus (USNM 358316; Figure 2d,E) is as-
signed to Bothremys. It is a short, robust humerus with a widely
flaring greater trochanter, a squat, rugose lesser trochanter, and
an ectepicondylar canal on the anterodorsal edge of the diaphy-
sis (canal does not intersect the condylar articular surface). It
shares some of the features of the humerus of Taphrosphys sul-
catus (Leidy) (Gaffney, 1975, fig. 12C,D).
Family Cheloniidae
(hard-shelled seaturtles)
I recognize five species of cheloniid and one species of der-
mochelyid seaturtles in the Lee Creek Mine fauna. Caretta and
Syllomus are represented by hundreds of elements, the other
seaturtles are represented by many fewer elements.
A partial skull and mandibular fragments match the mor-
phology of these elements in Caretta. Numerous carapacial
fragments (particularly posterior peripherals) and humeri pos-
sess the carettine morphology and also are assigned to Caret-
ta. These fossil elements show sufficient differences to indi-
cate that they represent a species distinct from extant Caretta
caretta.
Caretta patriciae, new species
Figures 3-6
Holotype.—USNM 186731, a partial skull lacking basioc-
cipital, basisphenoid, and left quadrate-squamosal complex
through and including left jugal. Collected by J.H. McLellan,
17-20 Jul 1972.
TYPE Locality.—North Carolina, Beaufort County, Lee
Creek Mine (35°23TSI, 76°47'30"W; United States Geological
208
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
B       <
'^
-
Figure 2.—Fossil remains of the sideneck turtle Bothremys from Lee Creek Mine. a,b, dorsal and ventral views,
respectively, of a nuchal (USNM 186773); c, dorsal view of a fragmented xiphiplastron (USNM 358462A),
showing a pelvic girdle attachment scar. D,E, dorsal and ventral views, respectively, of a humerus (USNM
358316). (Scale bar=l cm.)
Survey quadrangle map, 7.5-minute series, Bath, North Caro-
lina, quadrangle), south side of Pamlico River, near Aurora;
from a spoil pile.
Horizon and Age.—Presumably from the Yorktown For-
mation, lower Pliocene.
Etymology.—The specific epithet is a patronym in honor
of my wife, Patricia, for her years of support and love. It is pro-
posed as a noun in the genitive case.
Definition.—A cheloniid seaturtle with frontals excluded
from orbits by prefrontal-postorbital contact, maxillary contact
on secondary palate separating premaxillae from vomer, slight
temporal emargination, and deep pterygoid grooves. Triturat-
ing surface of dentary smoothly concave, with or without a low
symphyseal ridge. Carapace morphology carettine, with
strongly serrate posterior border, pygal widely and deeply
notched posteriorly; neural series in adults bearing large, pro-
jecting spines or knobs on neurals 1, 4, 7, 10, and posterior su-
prapygal; suprapygal spine very large.
Description of Holotype.—Most of the dorsal surface of
the skull is present (Figures 3, 4a). The skull roof has a slight
transverse arch and an equally slight longitudinal arch. Togeth-
er, the parietals are trapezoidal and are 91 mm long, 50 mm
NUMBER 90
209
FIGURE 3.—Cranial skeleton of Caretta patriciae, new species. A,B, dorsal and ventral views, respectively, of a
skull (USNM 186731, holotype). (Scale bar=l cm.)
210
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
B        /*£%=¦.


, '} y
¦JfP
c
FIGURE 4.—Cranial skeleton oi Caretta patriciae. new species. A, lateral view of a skull (USNM 186731, holo-
type); B-D, dorsal, lateral, and ventral views, respectively, of a dentary (USNM 186730). (Scale bars=l cm.)
wide anteriorly, and 98 mm wide posteriorly. The frontals have
a pentagonal outline, are 29 mm long medially, and are exclud-
ed from the orbits by the prefrontals and the postorbitals. The
nasals are truncated anteriorly and are 20 mm long medially
and 42 mm long laterally.
The anterior palatal region of the skull lacks only the right
maxilla and left premaxilla. The triturating surface and adja-
cent secondary palatal surface are flat and smooth. There is a
slight depression in the premaxilla for the tip of the mandible.
Posteriorly, the left side of the skull is represented by the artic-
ular process of the quadrate and the adjacent part of the ptery-
goid. The articular surface is ellipsoidal with no distinct medial
constrictions, and the surface is inclined only slightly anterior-
ly. The pterygoid groove is deep and is bordered laterally and
medially by well-developed ridges.
Additional Specimens.—Numerous fossil elements pos-
sess characteristics of Caretta or carettine seaturtles and are re-
ferred to C patriciae. The morphology of the carapace is based
entirely on these isolated elements (Figures 5, 6), even though
their association with the skull is uncertain. A few elements are
described below.
Parts of a supraoccipital and right opisthotic are present. In
addition to unidentified skull fragments, pieces of a right jugal
and right quadratojugal are recognizable. The skull fragments
NUMBER 90
211
rfi
1S/9<ro
FIGURE 5.—Carapacial elements oi Caretta patriciae, new species. A,B, dorsal and ventral views, respectively,
of a nuchal (USNM 186687); c,D,E, dorsal views of a first neural (USNM 451940), a third or fourth neural
(USNM 186683), and a suprapygal (USNM 358420), respectively, of adults; f,g,h, same specimens, lateral
views. (Scale bar=l cm.)
are derived from two individuals; the pieces represent two right
Jugals and two left pterygoids. Five dentaries are recognizable.
The largest piece of dentary (USNM 186730; Figure 4b-d)
comprises nearly the entire left half, with only the anterior tip
and coronoid extension missing. The triturating surface is
broad and smooth. There are no raised labial or tomial ridges.
The sulcus cartilaginis meckelii is deep, and anteriorly the dor-
sal wall overhangs the ventral one. Two fragments are anterior
dentary tips (USNM 187101, 358792); each possesses a mucro-
nate outline and a smooth, concave triturating surface with a
low symphyseal ridge; anteroposterior widths are 21 and 26
mm, respectively.
Eighteen left and 32 right Caretta humeri have been identi-
fied from entire specimens or proximal ends. They were differ-
entiated from those of other seaturtles by the diagonistic fea-
tures listed earlier. Because I found no feature to differentiate
212
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 6.—Carapacial elements of Caretta patriciae, new species. A,B,D, dorsal views of a right eighth periph-
eral (USNM 186708), a left eleventh peripheral (USNM 186714), and a left twelfth peripheral (USNM 186703),
respectively; c, dorsal view of a pygal (USNM 186688). (Scale bars=l cm.)
unquestionably the humeri of Caretta and Lepidochelys, the
latter taxon may be represented in this collection of humeri;
however, the preponderance of Caretta cranial skeletal ele-
ments suggests a similar preponderance of postcranial ele-
ments. I also identified 15 femora as Caretta. Cheloniid ulnae
(with the exception of the Syllomus ulna) and other appendicu-
lar skeleton elements in the Lee Creek Mine collection cannot
be identified to genus.
Carettine carapace fragments are the most numerous turtle
fossils from Lee Creek Mine. There are hundreds of carapace
pieces. Many of the peripherals and neurals are complete or
nearly so; costals are invariably highly fragmented; nuchals
are rare and incomplete. The similarity of C. patriciae and C.
caretta peripherals suggests that shell shape and size of both
species are similar and that the posterior margin of the cara-
pace in both was distinctly serrate. Pygals are numerous; 54
were identified as Caretta, and all show a strong notch on the
posterior margin. The difference in carapace morphology is
the smooth middorsal surface of C. caretta and the presence
of a middorsal series of spines or knobs in C. patriciae. The
spine-bearing neurals are 1, 4, 7, and 10 based on a compari-
son of neural outlines and vertebral scute-suture positions in
juvenile and adult C. caretta and juvenile Lepidochelys
kempii. The spines are variably developed on the neurals but
clearly persisted in adult C. patriciae and could be quite large
(Figure 5c,D,F,G); the suprapygal (Figure 5E,H) bears propor-
tionately the largest spine, which remains sharply pointed
even in the large adults. The largest nuchal fragment (Figure
5A,B) is the anteromedial part of the bone, which bears the an-
terior lip of the carapace and, ventrally, the bony process for
the attachment of the eighth cervical vertebra. This bony pro-
cess lies less than its longitudinal length from the anterior
edge of the nuchal. This position is common in Caretta,
whereas in the other extant cheloniids the process tends to be
posterior.
1 Chelonia
A single right humerus (USNM 186749, proximal end) ap-
pears to represent this genus. There are numerous other fossils
that might also derive from Chelonia. but distinguishing char-
acteristics are lacking for reliable identifications.
Lepidochelys
Figure 7b
A nearly complete left dentary (USNM 425612; Figure 7b),
broken to the right of the symphysis, resembles closely the
dentaries of juvenile Lepidochelys kempii. The fossil dentary is
17 mm wide at the symphysis, and a large symphyseal pyramid
rises from the posterior edge of the triturating surface. This sur-
face is deeply concave in the symphyseal area, gradually be-
coming more planar toward the articular end. The dentary is
slightly deformed by a constriction extending diagonally from
the middle of the ventral surface upward and posteriad to the
coronoid process.
A small left humerus (USNM 508056) matches closely the
humeral morphology of extant juvenile Lepidochelys.
NUMBER 90
213
I   f
J>
FIGURE 7.—Fossil remains of Lee Creek Mine seaturtles. A,B, dorsal views oi Syllomus aegyptiacus (USNM
427790) and Lepidochelys (USNM 425612) dentaries, respectively; c, dorsal view of three osteoderms (USNM
214649) from the carapace of a Psephophorus; D,E, pygals (USNM 358461, 358457, respectively) oi Syllomus
aegyptiacus. (Scale bar= 1 cm.)
Procolpochelys
A piece of a left hyoplastron (USNM 214648; principally the
medial and posterior portion) possesses a strong xiphiplastral
notch, which is covered ventrally by a bony shelf and projects
from the midline at about a 30° angle. The shape and depth of
this notch matches well plastral fragments of juvenile Pro-
colpochelys from the Calvert fauna. Several neurals match Cal-
vert Procolpochelys neurals in shape and thickness.
Syllomus aegyptiacus
Figure 7a,d,e
Syllomus is represented by numerous fragments. The dis-
tinctive surface texture of its carapace allows even the most
fragmentary carapacial elements to be recognized. Neurals are
numerous; most have distinct longitudinal keels. Eight pygals
(two figured; Figure 7d,e) have been found, and all but the
largest one bear an attenuate tip with a distal bifurcation. Hu-
meri are extremely abundant, with 44 left and 56 right humeri
recognized from either entire elements or proximal halves.
One humerus (USNM 187122) contained a small amount of
matrix, and sedimentological analysis of this matrix indicates
that the humerus was derived from the Yorktown Formation.
Thus, Syllomus survived into the Pliocene and probably was a
contemporary of Caretta patriciae. Only six femora have
been found.
Family Dermochelyidae
(leatherback seaturtles)
Psephophorus
Figure 7c
Three articulated carapacial osteoderms (USNM 214649;
Figure 7c) represent this genus. They are 10 mm thick, and
the largest plate has a maximum length of 39 mm. Each of the
three plates is of a different size and shape. There are eight
other isolated osteoderms, and most of these are derived from
a keeled area of the carapace. The three articulated osteo-
derms are darker and more mineralized than are most Lee
Creek Mine fossils and may derive from the Pungo River For-
mation.
Family Emydidae
(pond turtles)
Chrysemys complex
Figure 8
A few emydid shell fragments represent the Chrysemys com-
plex. Over the past three decades, the contents of this complex
have been variously considered to be members of one genus or
of two or three genera; the number of species has remained es-
sentially static. Herein, I follow the three-genera concept
214
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Figure 8.—Carapacial and plastral elements from tur-
tles of the Chrysemys complex. A, ventral view of a
Pseudemys left hyoplastron (USNM 187104); B,C, dor-
sal views of a Trachemys posterior peripheral (USNM
358314) and pygal (USNM 186774), respectively.
(Scale bar=l cm.)
(Ward, 1984; Seidel and Smith, 1986): Chrysemys, monotypic
with picta; Pseudemys, containing thefloridana and rubriven-
tris species groups; and Trachemys, containing the scripta spe-
cies group.
The Lee Creek Mine emydine fragments appear to derive
from both Pseudemys and Trachemys. An emydine plastron is
represented by a left hyoplastron (USNM 187104; Figure 8a).
This hyoplastron lacks most of the bridge buttress, but the hy-
poplastral and hypoxiphiplastral sutures and the position of the
abdominofemoral sulcus are distinct. The element is 39 mm
long and 33 mm wide, approximately the size of a hyoplastron
of an adult Chrysemys picta; however, its morphology is more
similar to that of a juvenile Pseudemys. A piece of left hyo-
plastron (USNM 358315A) and a smooth-edged ninth or tenth
right peripheral (USNM 358315B) also appear to be derived
from a Pseudemys. Two pygals (USNM 186774 (Figure 8c),
359009) and a tenth or eleventh left peripheral (USNM
358314; Figure 8b) bear deep notches that have the serrated
border of a Trachemys carapace.
Family Testudinidae
(tortoises)
Geochelone
A giant tortoise is represented by a complete shell (USNM
336458; Figure 9) and miscellaneous shell fragments, princi-
pally peripherals. The complete shell has an estimated carapace
length (CL) of 88 cm and an estimated plastron length (PL) of
70 cm. The costals and neurals have collapsed into the body
cavity but retain their alignment. The shell was high-domed,
with a smooth surface and distinct but lightly incised scute bor-
ders. In outline, the shell is slightly obovate, wider posteriorly
than anteriorly; the peripherals possess a slight lateral flare.
The plastron is smaller than the shell opening and bears a well-
developed epiplastral lip, which extends beyond the anterior
margin of the carapace. The plastral surface is very lightly
etched with scute outlines.
Three lineages of tortoises are known from the late Tertiary
of eastern North America: Geochelone (Caudochelys), Geo-
chelone (Hesperotestudo), and Gopherus. The Lee Creek Mine
tortoise is large, has a narrow nuchal scute, parallel-sided cos-
tals, and a plastron smaller than the carapace opening, traits
that ally it to Geochelone. Two species of Geochelone, G.
ducateli (Collins and Lynn) (Calvert Formation, Maryland)
and G. tedwhitei (Williams) (Hawthorne Formation, Florida),
occur in Miocene faunas (Auffenberg, 1974). Both of these
species are moderate-sized tortoises of less than 40 cm PL and
are considered to be members of the subgenus Caudochelys.
Larger tortoises of the subgenus Hesperotestudo have mem-
bers in midcontinental Miocene faunas but do not appear in At-
lantic coast faunas until the Pliocene and then only in the
Southeast. The Lee Creek Mine tortoise fossils do not closely
match either of these two species groups. Although some of
the isolated peripherals fall within the size range of G. ducate-
li, the Lee Creek Mine peripherals are proportionately thinner.
The epiplastral lip of the shell also is more angular and project-
ing than that of G. ducateli. As in many Hesperotestudo, the
fossil's humeropectoral scute border lies on the hyoplastron
immediately posteriorad to the entoplastron; however, the pec-
toroabdominal border is widely separated from the humeropec-
toral border (pectoral/abdominal midline lengths, 0.30%). This
feature distinguishes the Lee Creek Mine tortoise from the
Hesperotestudo lineage, and this separation also is greater than
in Caudochelys.
Of the eastern Pliocene Geochelone, only G. (Caudochelys)
hayi (Sellards) is a large species, encompassing the size of the
Lee Creek Mine tortoise. Both G. (Hesperotestudo) alleni
Auffenberg and G (H) turgida (Cope) have plastron lengths of
less than 25 cm and large plastra filling their shell openings.
The Lee Creek Mine tortoise may be G. hayi; however, without
additional comparative material, such an identification is tenta-
tive. The type of G. hayi (USNM 8815) has a carapace of
equivalent size but has a proportionately larger plastron with
broader epiplastra and a deeper xiphiplastral notch. The type
NUMBER 90
215
Figure 9.—Ventral view of the complete shell (USNM 336458) of the Lee Creek Mine Geochelone. A, shell
resting in a plaster jacket (ruler on right= 15 cm); B, reconstruction of the plastron proportionately matching the
lengths and widths of the fossil elements. (Scale bar=15 cm.)
also has strongly flaring posterior peripherals, which flared
only slightly in the Lee Creek Mine specimen.
Family Trionychidae
(softshell turtles)
Genus undetermined
Three carapacial fragments are referable to trionychid turtles.
All possess the strongly pitted and ridged surface texture of the
trionychid shell. A proximal end of a costal (USNM 186677) is
extremely thick, with the thickness about 25% of the width. A
neural (USNM 508057) is of equal thickness. These elements
are darker and more mineralized than are most other Lee Creek
Mine fossils and perhaps are derived from the Pungo River
Formation.
The extant North American softshell turtles represent a
monophyletic group (Apalone; Meylan, 1987) of three species.
Although the Lee Creek Mine fragments likely represent Apal-
one, shell fragments, indeed entire carapaces or plastrons, are
insufficient for the differentiation of Apalone from its Asian
relatives.
Family incertae sedis
A nearly complete right ilium, USNM 187103, lacking the
distal sacral border, is indeterminate. It is a small (-40 mm
long), stout element with a straight anterior edge and a
fan-shaped posterior edge. It possesses the stoutness of a Che-
lydra ilium and the shape of an Emydoidea one.
A heavily mineralized right parietal (USNM 187100), -45
mm long and unquestionably turtle, cannot be reliably assigned
to genus. Its manner of fossilization suggests that it came from
the Pungo River Formation.
Discussion
The Lee Creek Mine fauna has 11 recognizable turtles: a
sideneck turtle, six seaturtles, two pond turtles, a softshell tur-
tle, and a giant tortoise. This fauna derives principally from the
Yorktown Formation, although the mining operation may have
introduced some elements from the Pungo River Formation.
Both of these formations are marine, yet the fauna has repre-
sentatives of marine, freshwater, and terrestrial turtles. None-
theless, it seems likely that both faunal components derive
216
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
from the waters and land immediately adjacent to the deposi-
tional site. None, in my opinion, requires a long-distance trans-
portation hypothesis.
The turtles occurring in the two Miocene and one Pliocene
marine deposits of the mid-Atlantic coast are summarized in
Table 3. Only three species have been recovered from the New
Jersey Miocene, and the "Chelonia" is almost certainly from an
Eocene deposit. This small number probably reflects a lack of
good collecting localities rather than a depauperate fauna. The
Calvert and the Lee Creek faunas are similar in size and con-
tent, sharing six taxa: Bothremys, Procolpochelys, Syllomus,
Psephophorus, Geochelone, and a trionychid.
The freshwater and terrestrial taxa are all extant taxa, al-
though only the pond turtles occur in the Lee Creek Mine area
today. The fragmentary nature of the fossil pond turtles allows
only a statement of their presence in the fauna, not their specif-
ic identity or ecological significance. Their presence is not un-
usual because both are known from other late Tertiary and
Quaternary faunas. Trachemys is both common and widespread
in Cenozoic faunas east of the Rocky Mountains and has a tem-
poral distribution from the early Miocene (Williams, 1953, pl.
4; Jackson, 1988) to the present in eastern North America. Wil-
liams (1953) also pictured a Pseudemys floridana-\ike turtle
from an early Miocene deposit in Florida. Specific identifica-
tion of the Lee Creek Pseudemys and Trachemys will require
more complete specimens from Lee Creek Mine and a more
comprehensive examination of the fossil history of the Chryse-
mys complex. The Lee Creek Mine specimens extend the geo-
graphic occurrence of these taxa in the Pliocene into the
mid-Atlantic region.
Trionychids occurred at the Lee Creek site. Today, they are
not present in that area or adjacent to the other two mid-Atlan-
tic fossil sites, yet fragmentary fossils of the trionychids dem-
onstrate their Pliocene or Miocene occurrence (Table 3) in the
rivers of the mid-Atlantic coastal plain.
Geochelone also is a common member of late Tertiary and
Quaternary faunas of North America. Four of the previously
known species (G. ducateli, G tedwhitei, G. alleni, G. turgida)
from eastern Miocene-Pliocene faunas are much smaller tor-
toises. Some Lee Creek tortoise fossils match the size of these
species, but they are too fragmentary to discern whether they
represent a second, smaller species in the Lee Creek Mine fau-
na or represent juveniles of the giant tortoise. The complete
shell and many fragments show the Lee Creek Geochelone to
be a giant tortoise, the first from the mid-Atlantic Tertiary. It
may be G. hayi, but comparative material is inadequate for
confirmation.
The pelomedusid Bothremys is considered to be a marine
sideneck turtle. The presence of the xiphiplastra with girdle
scars confirms its presence in the Lee Creek Mine fauna. Its oc-
currence is important because it may extend the temporal range
of this genus from the Calvert Formation through the York-
town Formation. Without precise stratigraphic data, however,
the Lee Creek sideneck turtle must be assigned questionably to
the Pliocene. Whether Miocene or Pliocene, the Lee Creek
Mine occurrence confirms the presence of sidenecks in the
North American Tertiary.
Procolpochelys and Psephophorus are very rare in the Lee
Creek Mine assemblage, perhaps because they are from the
Pungo River Formation; however, Psephophorus was recently
discovered (Dodd and Morgan, 1992) in a Pliocene deposit in
central Florida. They are assumed to be highly pelagic species.
Although this pelagic behavior may account for their relative
rarity, Dermochelys, the modern day counterpart of Psepho-
phorus, seasonally migrates along the Atlantic coast (Shoop,
Table 3.—Occurrence of Miocene and Pliocene turtles in marine deposits of the central Atlantic coastal plains
of North America. Symbols: +, species occurs in fauna; -, species absent from fauna; ?, occurrence doubtful.
Taxon
Miocene fauna of
New Jersey
Calvert fauna of Maryland   Lee Creek Mine fauna of
and Virginia                     North Carolina
Family Pelomedusidae
Bothremys
Family Cheloniidae
Caretta
Chelonia
Lepidochelys
Procolpochelys
Syllomus
Family Dermochelyidae
Psephophorus
Family Emydidae
Chrysemys complex
Family Testudinidae
Geochelone
Family Trionychidae
cf. Apalone
•?i
'Cope (1868) considered two fragments to represent Chelonia; Weems (1974) believed them to be from Syllo-
mus and Procolpochelys, respectively.
NUMBER 90
217
1987), regularly enters the larger estuaries (e.g., Chesapeake
Bay; Musick, 1988), although briefly and in small numbers,
and strands regularly on Atlantic beaches (Prescott, 1988). I
suspect that the rarity of Psephophorus is not because they are
pelagic and their carcasses were lost at sea, but because the Lee
Creek depositional environment was estuarine, equivalent to
today's Albemarle and Pamlico Sounds. Stranding on high en-
ergy ocean-front beaches destroys carcasses and provides little
opportunity for fossilization. This destruction occurs to all sea-
turtles, whether they are near-shore or pelagic species.
Extant Caretta caretta and Lepidochelys kempii use the estu-
aries, bays, and sounds of North America (south of Cape Cod)
as summer feeding grounds for juveniles and often occur in
high densities in these areas. The abundance of Syllomus and
Caretta patriciae suggests that the Lee Creek area was similar-
ly used by these extinct species. This suggestion is further
strengthened by the numerous limb bones of juvenile Caretta
and Syllomus. To extend this suggestion into speculation, I note
that juvenile Caretta caretta, Chelonia mydas, Eretmochelys
imbricata, and Lepidochelys kempii are year-around residents
in some Florida bays and sounds (Ehrhart, 1983). During the
winter, they burrow into the bottom of these bays and possibly
hibernate (Ogren and McVea, 1982). It seems likely that the
Lee Creek Caretta and Syllomus also were year-around resi-
dents of the Pliocene Lee Creek estuary. The abundant fossils
of the latter two seaturtles might be attributed to cold-stunning
(K. Dodd, pers. comm., 1991), a regular event in some estuar-
ies (Meylan, 1986; Witherington and Ehrhart, 1989) that kills
many resident seaturtles.
Without stratigraphic control, suggestions on the origin of
the Lee Creek vertebrate fauna are speculative. The common-
ness of tortoises and juvenile seaturtles and the types of seatur-
tles present argue for a shallower, near-shore deposition. The
teleost fish data is less precise, indicating a "deposition at 60 to
100 m, but could in fact have been much shallower or a great
deal deeper" (Fitch and Lavenberg, 1983:527).
The similarity of the Caretta patriciae skull to that of C
caretta indicates a similar diet, dominated by mollusks and
crustaceans (Mortimer, 1982; Plotkin, 1989). The skull of Syl-
lomus is more elongate (Weems, 1980) and generally resem-
bles that of Eretmochelys, so it may have shared a preference
for sponges (Meylan, 1988) as well. One of the more striking
features of Syllomus, however, is its humeral morphology,
which is unlike that of any modern seaturtle. Syllomus un-
doubtedly swam with the aquatic flight locomotor pattern, but
the proportional and shape differences of the humerus suggest
a modification of the typical pattern, perhaps a more rapid or
powerful stroke. Rather than eating sponges, was it capable of
chasing and capturing fish or squid? Another peculiarity of Syl-
lomus is the surface texture of the carapace, suggesting a differ-
ent type of epidermal covering. Scutes were present, but they
may have been softer, less keratinized, perhaps similar to the
scutes of Natator depressa (Garman). The relationships of
these two taxa require closer examination.
The abundance of Caretta fossils in the Lee Creek Yorktown
deposits and their absence from the Calvert Formation indicate
a Pliocene arrival to the mid-Atlantic coast. Caretta has been
reported from faunas as early as the Eocene and questionably
the late Cretaceous (Mlynarski, 1976). These early fossils (Cre-
taceous and Eocene) are suspect, and their identities must be
confirmed.
Zangerl and Turnbull (1955) placed the Miocene Pro-
colpochelys grandaeva Leidy in the cheloniid tribe Carettini.
They considered Procolpochelys to be a pelagic divergent and
not ancestral to the extant carettines, Caretta and Lepidochelys.
The presence of Caretta in the Lee Creek Mine assemblage is
additional evidence against Procolpochelys as an ancestor of
extant carettines. Carapace structure of these two is similar in
two characteristics. Both lack surface sculpturing and possess
costoperipheral fontanelles; however, the extent of fontanelle
development can not be determined from the present Lee Creek
Mine fragments. The fontanelles probably never closed in Pro-
colpochelys. In extant Caretta, closure does occur but appar-
ently only after sexual maturity. The extent of closure, its tim-
ing, and intra- and interpopulational variation remain
undocumented. Some of the peripherals from Lee Creek Caret-
ta are equivalent in size to those of extant, reproductively ac-
tive Caretta, and these peripherals lack costoperipheral sutures.
Further, the shape of the largest (and clearly adult) posterior su-
prapygal indicates the presence of large costoperipheral fon-
tanelles in the posterior aspect of the carapace.
Conclusions
Examination of the turtle fossils from the Lee Creek Mine re-
veals the following: (1) The Pliocene turtle fauna of the
mid-Atlantic coast and coastal plain contained extinct and
modern genera. The marine or estuarine taxa were Bothremys,
Caretta patriciae, IChelonia, Lepidochelys, Procolpochelys,
Syllomus, and Psephophorus. The freshwater taxa were two
pond turtles (probably Pseudemys and Trachemys) and a tri-
onychid, and there was a single terrestrial taxon, Geochelone.
(2) The estuarine/near-shore nature of the Lee Creek Mine de-
posit and the abundance of Caretta and Syllomus indicate that
these two taxa were regular residents of the estuaries and coast
of the Albemarle Embayment. Juveniles and adults are repre-
sented, so the area likely included both feeding grounds and
nesting beaches, just as it does for Caretta caretta today. (3)
The Pliocene Caretta is morphologically distinct from the
modern species and is recognized as a new species, C. patrici-
ae. (4) The Lee Creek Geochelone is the earliest Cenozoic
record of a giant tortoise from the mid-Atlantic coast of North
America. This tortoise also appears to be morphologically dis-
tinct from previously known Miocene-Pliocene Geochelone.
(5) The presence of xiphiplastral fragments with pelvic girdle
articular scars confirms the presence and likely extends the
temporal range of pleurodiran turtles in North America.
218
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
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Auffenberg, Walter
1974.     Checklist of Fossil Land Tortoises (Testudinidae). Bulletin of the
Florida Stale Museum. Biological Sciences, 18(3): 121 -251.
Berry, Charles T., and W. Gardner Lynn
1936.    A New Turtle, Peritresius virginianus, from the Miocene of Vir-
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Collins, R. Lee, and W. Gardner Lynn
1936.    Fossil Turtles from Maryland. Proceedings of the American Philo-
sophical Society, 76(2): 155-173.
Cope, ED.
1868.    An Addition to the Vertebrate Fauna of the Miocene Period, with a
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Dodd, C. Kenneth, Jr., and Gary S. Morgan
1992.    Fossil Sea Turtles from the Early Pliocene Bone Valley Formation,
Central Florida. Journal of Herpetology. 26(1): 1-8.
Ehrhart, Llewellyn M.
1983.    Marine Turtles of the Indian River Lagoon System. Florida Scien-
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Fitch, John E., and Robert J. Lavenberg
1983.    Teleost Fish Otoliths from Lee Creek Mine, Aurora, North Carolina
(Yorktown Formation: Pliocene). In Clayton E. Ray, editor, Geol-
ogy and Paleontology of the Lee Creek Mine, North Carolina, I.
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Gaffney, Eugene S.
1975.     A Revision of the Side-necked Turtle Taphrosphys sulcatus (Leidy)
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Gaffney, Eugene S., and Rainer Zangerl
1968.    A Revision of the Chelonian Genus Bothremys (Pleurodira: Pelome-
dusidae). Fieldiana: Geology. 16(7): 193-239.
Gibson, Thomas G.
1983.    Stratigraphy of Miocene through Lower Pleistocene Strata of the
United States Central Atlantic Coastal Plain. In Clayton E. Ray, edi-
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lina, I. Smithsonian Contributions to Paleobiology, 53:35-80.
Jackson, Dale R.
1988.    A   Re-examination  of Fossil   Turtles  of the  Genus   Trachemys
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Leidy, J.
1851.    Description of Fossils from the Greensand of New Jersey. Proceed-
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Meylan, Anne Barkau
1986.     Riddle of the Ridleys; Frozen and Stranded, Were These Rarest of
Sea Turtles Giving a Clue to Their Secret Migrations? Natural His-
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1988.    Spongivory in Hawksbill Turtles: A Diet of Glass. Science, 239:
393-395.
Meylan, Peter Andre
1987.     The Phylogenetic Relationships of Softshelled Turtles (Family Tri-
onychidae). Bulletin of the American Museum of Natural History.
186(1):1-101.
Mlynarksi, Marian
1976.    Testudines. Handbuch der Paldoherpelologie.  7: vi+130 pages.
Stuttgart: Fischer.
Mortimer, Jeanne A.
1982.    Feeding Ecology of Sea Turtles. In Karen A. Bjorndal, editor, Biol-
ogy and Conservation of Sea Turtles, pages 103-109. Washington,
D.C: Smithsonian Institution Press.
Musick, J.A.
1988.     The Sea Turtles of Virginia with Notes on Identification and Natural
History. Second revised edition, iv+22 pages. Glouster Point: Vir-
ginia Sea Grant College Program, Virginia Institute of Marine Sci-
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Ogren, Larry, and Charles McVea, Jr.
1982.    Apparent Hibernation by Sea Turtles in North American Waters. In
Karen A. Bjorndal, editor, Biology and Conservation of Sea Turtles,
pages 127-132. Washington, D.C: Smithsonian Institution Press.
Palmer, William
1909.    Description of a New Species of Leatherback Turtle from the Mi-
ocene of Maryland. Proceedings of the United States National Mu-
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Plotkin, Pamela
1989.     Feeding Ecology of the Loggerhead Sea Turtle in the Northwestern
Gulf of Mexico. NOAA Technical Memorandum, NMFS-SEFC-
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Prescott, Robert L.
1988.     Leatherbacks in Cape Cod Bay, Massachusetts, 1977-1987. NOAA
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Seidel, Michael E., and Hobart M. Smith
1986.     Chrysemys, Pseudemys, Trachemys (Testudines: Emydidae): Did
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Shoop, C. Robert
1987.     Sea Turtles. In R.H. Bachus and H.H. Bourne, editors, Georges
Bank, pages 357-358. Cambridge, Massachusetts: MIT Press.
Ward, Joseph P.
1984.    Relationships of Chrysemyd Turtles of North America. Special Pub-
lications, The Museum. Texas Tech University, 21:1-50.
Weems, Robert E.
1974.    Middle Miocene Sea Turtles (Syllomus. Procolpochelys, Psepho-
phorus) from the Calvert Formation. Journal of Paleontology,
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1980.    Syllomus aegyptiacus. a Miocene Pseudodont Sea Turtle. Copeia,
1980(4):621-625.
Williams, Ernest E.
1953.    A New Fossil Tortoise from the Thomas Farm Miocene of Florida.
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1989.     Hypothermic Stunning and Mortality of Marine Turtles in the Indian
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Zangerl, Rainer, and William D. Tumbull
1955.    Procolpochelys grandaeva (Leidy), an Early Carettine Sea Turtle.
Fieldiana: Zoology, 37:345-384.
Zug, George R., Addison H. Wynn, and Carol Ruckdeschel
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Incremental Growth Marks in the Skeleton. Smithsonian Contribu-
tions to Zoology, 427: 34 pages.
Thecachampsa antiqua (Leidy, 1852)
(Crocodylidae: Thoracosaurinae)
from Fossil Marine Deposits at
Lee Creek Mine, Aurora, North Carolina, USA
Albert C. Myrick, Jr.
ABSTRACT
Fossil remains of crocodilians at Lee Creek Mine have been few
and fragmentary. Nevertheless, isolated teeth and dermal plates
from the spoil piles are identifiable as Thecachampsa antiqua
(Leidy). This species was established by Leidy on characters of
teeth presumably from the Calvert Formation of Virginia (late
early to early middle Miocene), but the species is now validated by
skulls and numerous elements from the middle Miocene forma-
tions of the Chesapeake Group. The same form is common in the
Florida early Pliocene, where it is represented by several fairly
complete skeletons known as Gavialosuchus americanus (Sell-
ards). It also is known from numerous skulls from early and mid-
dle Miocene formations near Lisbon, Portugal, as Tomistoma
lusitanica (Vianna and Moraes). Teeth and a dermal scute indicat-
ing the same species have been collected from late early Miocene
deposits. The resemblance among teeth, scutes, and skulls from
the Chesapeake Group, Florida, and from Portugal indicates that
these forms are conspecific. The earliest available name, Theca-
champsa antiqua, has priority.
Introduction
A small collection of isolated and fragmentary remains of
fossil crocodilians from Lee Creek Mine has accumulated in
the collections of the National Museum of Natural History
(which includes collections of the former United States Na-
tional Museum (USNM)), Smithsonian Institution, over the
past 25 years. The sample is a result of collecting from mixed
tailings from the Pungo River Formation (late early to early
middle Miocene; Gibson, 1983) and the overlying Yorktown
Albert C. Myrick, Jr., Research Associate, Vertebrate Paleontology
Division, Los Angeles County Museum of Natural History, 900 Expo-
sition Boulevard, Los Angeles, California 90007.
Formation (early Pliocene; Gibson, 1983; Hazel, 1983). It
provides a first opportunity to study the Lee Creek crocodilian
materials in relation to other similar forms of comparable geo-
logic age. The purpose of this paper is to describe the Lee
Creek Mine crocodilian specimens and to comment on the
taxonomic status and paleozoogeographic implications related
to the Lee Creek Mine occurrence and to occurrences of
closely related forms elsewhere.
ACKNOWLEDGMENTS.—The Lee Creek Mine specimens cit-
ed in this report were collected and donated by P.J. Harmatuk,
F. Hyne, and B. Hyne. I thank L.G. Barnes (Los Angeles
County Museum of Natural History) for providing refresher
information on the California specimens. S.D. Webb's (Uni-
versity of Florida) age estimations of the Florida localities
were of great help. C. Repenning (United States Geological
Survey) loaned crocodilian teeth from California. A. Sanders
(The Charleston Museum) and B. Erickson (Science Museum
of Minnesota) gave helpful advice. I am especially grateful to
T. Demere, at the San Diego Museum of Natural History, who
permitted me to study the Museum's holdings of recent verte-
brate paleontology literature.
Materials and Provenience
The fossil crocodilian remains from Lee Creek Mine consist
of approximately 24 isolated teeth, 15 unassociated vertebrae,
two incomplete dermal scutes, three skull fragments, a man-
dibular fragment, a right maxilla fragment, and several bones
and bone fragments from appendicular skeletons (Figures
1-5). These have been assigned USNM catalog numbers.
Field data indicate that none of the specimens were collected
in association or in situ. Adherent matrix indicates at least one
specimen (fragment of right maxilla, USNM 307548) came
from the Pungo River Formation, but, because the spoil piles
219
220
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
consist of disturbed mixtures of sediments from the Pungo
River Formation and the Yorktown Formation, others could
equally well have come from the Yorktown Formation. The
most that can be said at present is that the Lee Creek Mine
crocodilian fossils are of late early Miocene and possibly early
Pliocene age.
Morphological Description
The appendicular elements, vertebrae, and skull fragments in
hand are of little immediate diagnostic use below the family
level. If, however, one may judge from the several robust verte-
brae (USNM 412243, 412254) and the large size of the posteri-
or fragment of a right maxilla (USNM 307548; Figure 2),
which contains complete teeth, some of these animals probably
attained greater sizes than most modern crocodilians.
Most of the crocodilian teeth collected at Lee Creek Mine,
including those in the maxillary (USNM 307548) and mandib-
ular (USNM 437930) fragments, are in a state of excellent
preservation and are of diagnostic importance (Figures 1-3).
They are heavily built simple cones, elliptical to subcircular in
cross section, with bluntly pointed apices. A carina of variable
prominence occurs on anterior and posterior surfaces of the
crowns. It typically extends basally from near the apex to about
one-half the length of the crown, although carinal distance also
is highly variable. The carinae divide the tooth subequally,
such that the greater half of the crown lies toward the labial
side. The longer teeth are slightly recurved, the shorter, stubbi-
er ones are barely so. Labiolingual compression is exhibited es-
pecially in the shorter, presumably more posterior, teeth. The
enamel is thin, variably transparent, and finely rugose, with a
silky fibrous surface texture. Within the enamel can be seen
various light and dark colored bands encircling the crowns hor-
izontally at irregular intervals.
The two specimens of dermal plates or scutes (USNM
244391, 412252) also have diagnostically important charac-
ters (Figure 4). They are rectangular with one corner more or
less rounded and with two edges more strongly beveled than
the others. The external surface of the scute contains very
large, irregularly rounded pits with no discernable pattern. In
addition, the scutes have no keels (i.e., plate-like ridges that
project at right angles from the pitted external surface), which
commonly are found in the dermal scutes of most modern
crocodilians.
Comparison with Other Materials
I confine my remarks to the North American Miocene and
Pliocene and the Portuguese Miocene forms.
In their diagnostic characters, the crocodilian teeth and
scutes are identical to numerous isolated teeth and scutes from
the Miocene formations of the Chesapeake Group of Mary-
land and Virginia. They also closely resemble elements asso-
FlGURE 1.—Teeth of Thecachampa antiqua from Lee Creek Mine, North Caro-
lina (a.c, USNM 412246; b.d. USNM 299794): a.b, apical view; c.d. lingual
view. (Scale bar= 1 cm.)
ciated with one well-preserved skull (USNM 25243; Figure
5b) from the Calvert Formation in northern Virginia (late ear-
ly Miocene) and with at least several skulls from the Bone
Valley Gravel and the Alachua formations (early Pliocene;
S.D. Webb, pers. comm., 1967) of Florida. In addition, they
do not differ in any consistent feature from teeth and dermal
scutes associated with skulls from Miocene deposits near Lis-
bon, Portugal. Finally, the only crocodilian material known
from late Tertiary marine deposits in southwestern California
and in Baja California, one partial scute and more than a doz-
en teeth, compares favorably in detail with the Lee Creek
Mine materials.
In cases where skulls and other skeletal elements have been
closely compared and described (i.e., from the Virginia Cal-
vert Formation, Maryland St. Marys Formation, Florida
Pliocene formations, and Miocene formations near Lisbon,
NUMBER 90
221
FIGURE 2.—Posterior fragment of right maxilla containing teeth of Thecachampsa antiqua from Lee Creek
Mine, North Carolina, USNM 307548: a, dorsal view; b. lateral view; c, medial view. (Scale bar=5 cm.)
222
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 3.—Distal ends of mandibles of Thecachampsa antiqua from Lee Creek Mine, North Carolina, USNM
437930, dorsal view. (Scale bar=5 cm.)
Portugal), I have not been able to identify consistent morpho-
logical differences. They all have long robust snouts that are
gradually tapered from strongly built skulls (Figure 56).
Among other unifying features, they share the same or similar
sutural patterns, bone proportions, tooth counts, and serial
tooth diameter differentiation patterns.
Taxonomy
Although this is not the place for a revision of the European
and North American thoracosaurine crocodiles, the fossil
skulls are distinctly different in generic features from the
modern false gavial, Tomistoma schlegelii Miiller, of south-
east Asia. Several studies (Toula and Kail, 1885; Mook, 1921,
1924; Vianna and Moraes, 1945; Auffenberg, 1954) have
carefully pointed out that the European and North American
"tomistomines" of Miocene-Pliocene age represent a genus
separate from Tomistoma. Modern workers who have accept-
ed evidence for a separate genus have used the name Gavialo-
suchus to designate the more robust Miocene and Pliocene
forms. The name Gavialosuchus dates from Toula and Kail
(1885). Mook (1921) referred the Florida fossils to Gavialo-
suchus, but Antunes (1994) continues to use the more conser-
vative name Tomistoma lusitanica (Vianna and Moraes) for
the Portuguese fossils.
Until a partial skeleton with skull, teeth, and dermal scutes
(USNM 25243; Figure 5) was collected from the Calvert For-
mation in Virginia, in the late 1960s, it was not possible to
show that Gavialosuchus americanus and Tomistoma lusitani-
ca were junior synonyms of Leidy's species, based on the
tooth characteristics, and that Gavialosuchus was a junior
synonym of Cope's genus Thecachampsa, in which taxon
Cope included Leidy's species antiqua in 1869.
From my own study of USNM 25243 and other Chesapeake
Group specimens, however, it now seems apparent that the
four species of Thecachampsa (antiqua, sericodon, sicaria,
and contusor) recognized by Cope on the basis of differences
in tooth shape should be naturally combined under one name
by virtue of the variation in teeth exhibited along the tooth
rows of Thecachampsa antiqua skulls. In addition, consider-
ing that there seem to be no important morphological differ-
ences between skulls of different nominal species, in my opin-
ion there is no useful purpose in maintaining taxonomic
distinctions between specimens from the Chesapeake Group,
Florida, and Lisbon, Portugal (and presumably now from Lee
Creek Mine and possibly from southern and Baja California).
I therefore consider these taxa to be conspecific and propose
the following taxonomic scheme, which follows Steel (1973)
in part.
NUMBER 90
223
crocodylidae
Thoracosaurinae
Thecachampsa Cope, 1867
Thecachampsa antiqua (Leidy, 1852)
Crocodylus antiquus Leidy, 1852
Thecachampsa sericodon Cope, 1867
Thecachampsa contusor Cope, 1867
Thecachampsa antiqua (Leidy).—Cope, 1869
Thecachampsa sicaria Cope, 1869
Tomistoma americana Sellards, 1915
Gavialosuchus americana (Sellards).—Mook, 1921
Gavialosuchus americanus (Sellards).—Auffenberg, 1954
Gavialosuchus americanus (Sellards) var. lusitanica Vianna and
Moraes, 1945
Tomistoma lusitanica (Vianna and Moraes).—Antunes, 1961
Paleozoogeography of Thecachampsa antiqua
The earliest known occurrences of this species in North
America are from the Kirkwood Formation of New Jersey and
the Calvert Formation of Maryland and Virginia (both late ear-
ly to early middle Miocene, Gibson, 1983). This is probably a
little later than the early Burdigalian appearance of the species
in Portugal (Antunes, 1961; Benson, 1998).
A fragment of a right maxilla (USNM 307548) from the Pun-
go River Formation at Lee Creek Mine establishes a new
southern record for eastern North America for Thecachampsa
antiqua in the middle Miocene. Further, if some of the other
specimens are from the Yorktown Formation at Lee Creek
Mine, then these would establish the most northern extension
in the early Pliocene. Thecachampsa antiqua remains have
been collected from the St. Marys Formation (Chesapeake
Group), but none have yet been reported in the Yorktown For-
mation (early Pliocene) in Virginia.
Although the species is well represented in the Bone Valley
Gravel and Alachua formations in Florida (early Pliocene), it is
surprising that there is no record of the species from the Haw-
thorn Formation (middle Miocene, Webb, pers. comm., 1967).
These results may indicate that the T. antiqua populations were
vacating Maryland-Virginia waters by the beginning of York-
town deposition and may not have come to inhabit coastal ar-
eas of Florida in force until late in the Miocene.
The sparse remains that seem to place this or a related spe-
cies on the southwestern coast of North America have been
collected from Barstovian Age (Calvert equivalent?) marine
deposits in California and deposits in Baja California of possi-
ble early Pliocene age (Barnes, pers. comm., 1988). The lack of
crocodilians in otherwise abundantly rich fossiliferous marine
and coastal deposits of late Miocene age is enigmatic. The
problem is still under investigation.
FIGURE 4.—Partial dorsal dermal scute of Thecachampsa antiqua from Lee
Creek Mine, North Carolina, USNM 412252: a, dorsal view; b, ventral view.
(Scale bar=l cm.)
224
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Figure 5.—Partial skeleton of Thecachampsa antiqua from the Calvert Formation of Virginia, USNM 25243: a.
teeth (4) (scale bar=l cm); b, skull, dorsal view (scale bar=l m); c, dorsal dermal scutes (8), dorsal view (scale
bar=3 cm).
NUMBER 90
225
Literature Cited
Antunes, M.T.
1961. Tomistoma lusitanica, crocodilien du Miocene du Portugal. Revista
de Faculdade de Ciencias, Universidade de Lisboa, series 2,
9:5-88, 13 figures, plates 1-12, 3 tables.
1994.    On Western Europe Miocene Gavials (Crocodylia); Their Paleo-
geography, Migrations and Climatic Significance. Comunicacoes
Instituto Geologico e Mineiro, 80:57-69.
Auffenberg, W.
1954.    Additional Specimens oi Gavialosuchus americanus (Sellards) from
a New Locality in Florida. Quarterly Journal of the Florida Acad-
emy of Sciences, 17(4): 185-209, 15 figures, 3 tables.
Benson, R.N.
1998. Radiolarians and Diatoms from the Pollack Farm Site, Delaware:
Marine-Terrestrial Correlation of Miocene Vertebrate Assemblages
of the Middle Atlantic Coastal Plain. In R.N. Benson, editor, Geol-
ogy and Paleontology of the Lower Miocene Pollack Farm Fossil
Site, Delaware. Delaware Geological Survey Publication, 21:5-19.
Cope, E.D.
1867. An Addition to the Vertebrate Fauna of the Miocene Period with a
Synopsis of the Extinct Cetacea of the United States. Proceedings of
the Academy of Natural Sciences of Philadelphia, 1867:136-156.
1869.    Third Contribution to the Fauna of the Miocene Period of the United
States. Proceedings of the Academy of Natural Sciences of Philadel-
phia, 1869:6-12.
Gibson, T.C
1983. Stratigraphy of Miocene through Lower Pleistocene Strata of the
United States Central Atlantic Coastal Plain. In CE. Ray, editor,
Geology and Paleontology of the Lee Creek Mine, North Carolina,
I. Smithsonian Contributions to Paleobiology, 53:35-80, 37 figures,
19 tables.
Hazel, J.E.
1983. Age and Correlation of the Yorktown (Pliocene) and Croatan
(Pliocene and Pleistocene) Formations at the Lee Creek Mine. In
CE. Ray, editor, Geology and Paleontology of the Lee Creek Mine,
North Carolina, I. Smithsonian Contributions to Paleobiology,
53:81-200, 4 figures, 38 plates.
Leidy, J.
1852.    Description of a New Species of Crocodile from the Miocene of
Virginia. Journal of the Academy of Natural Sciences ofPhiladel-
phia, 2(2): 135-138, 1 plate.
Mook, CC.
1921.    Skull Characters and Affinities of the Extinct Florida Gavial Gavia-
losuchus americanus (Sellards). Bulletin of the American Museum
of Natural History, 44:39^16, 5 plates.
1924.    Further Notes on the Skull Characters of Gavialosuchus americanus
(Sellards). American Museum Novitates, 155:1-2, 1 figure.
Sellards, E.H.
1915.    A New Gavial from the Late Tertiary of Florida. American Journal
of Science, 4(11):138-138, 2 figures.
Steel, R.
1973.    Crocodylia. In O. Kuhn, editor, Handbuch der Palaoherpetologie,
16: vii +116 pages. Stuttgart: Gustav Fischer.
Toula, F., and J.A. Kail
1885.    Uebereinen Krokodilschadel aus den Tertiarablagerungen von Egg-
enberg, in Nieder Oesterreich. Denkschriften der Koniglichen Akad-
emie der Wissenschaften, Mathematisch-naturwissenschaftlichen
Klasse (Vienna), 50:299-355, 3 figures, 3 plates.
Vianna, A., and A. Moraes
1945. Sur un crane de crocodile fossile decouvert dans le Miocene de Lis-
bonne. Boletim da la Sociedade Geologica de Portugal, 4(3):
161-170.
A New Pliocene Grebe from the Lee Creek Deposits
Robert W. Storer
ABSTRACT
A new species of Podiceps (Aves: Podicipedidae) is described
from the early Pliocene Lee Creek marine deposits in North Caro-
lina. The holotype is a femur. Referred material includes entire or
partial femora (7), tarsometatarsi (5), coracoid (1), humeri (7), and
ulna(l).
Introduction
Among the thousands of bird bones found in the Neogene
marine deposits at Lee Creek Mine, near Aurora, Beaufort
County, North Carolina, are 22 bones or parts of bones belong-
ing to a small species of grebe. Different bones representing the
same element of the skeleton vary considerably in overall size
and in the positions of the muscle scars on them; however,
comparable differences may be found within series of a single
recent species (e.g., in a series of skeletons of the Horned
Grebe, Podiceps auritus (Linnaeus)), and there is no reason to
believe that they represent more than a single species. Accord-
ing to the characteristics listed by Murray (1967:278) for the
appropriate elements, the Lee Creek Mine grebe is referable to
the recent genus Podiceps. Comparisons with skeletons of liv-
ing grebes in the University of Michigan Museum of Zoology
(UMMZ) confirm this placement. The fossil form is about the
size of P. auritus but differs in several respects that warrant de-
scribing it as a new species.
Acknowledgments.—I am grateful to the curators of the
National Museum of Natural History (which includes collec-
tions of the former United States National Museum (USNM)),
Smithsonian Institution, and the University of Kansas Museum
of Natural History (KUVP) for permission to borrow the fossils
described herein, to L. Delle Cave (Museo Geologia e Paleon-
tologia, Universita di Firenze) for providing a cast of the holo-
type of Podiceps pisanus (Portis), and to the curators of the
University of Michigan Museum of Paleontology (UMMP) for
Robert W. Storer, Museum of Zoology and Department of Biology,
University of Michigan, Ann Arbor, Michigan 48109-1079.
permission to study comparative material. Clayton E. Ray,
Storrs L. Olson, and T.J. Cohn offered valuable comments on
the manuscript; Kama Steelquist and Jennifer Emry prepared
the figure. Tom and Pat Burns, Raymond Douglas, Frank and
Becky Hyne, Peter J. Harmatuk, and Clyde Swindell collected
many of the Lee Creek Mine specimens used in this study.
Podiceps howardae, new species
Figure 1
Holotype.—Complete right femur, vertebrate paleontologi-
cal collections of the National Museum of Natural History,
Smithsonian Institution, USNM 252314.
Paratypes.—Seven other femora (KUVP 21240, USNM
177918, 178151, 206413, 215453, 215649, 460785) probably
represent this species. Their measurements are shown in Table 1.
Type Locality.—Lee Creek Mine, near Aurora, Beaufort
County, North Carolina (35° 18TST, 76°48'W), collected in 1977
by Peter J. Harmatuk.
Horizon and Age.—Yorktown Formation, early Pliocene.
Etymology.—Named in honor of Hildegarde Howard in
recognition of her many important contributions to the study of
fossil birds.
DIAGNOSIS.—Podiceps howardae was a small grebe, ap-
proximately the size of the recent P auritus, and had similar
leg proportions. It differed from the recent species in confor-
mation of the known skeletal elements as noted below. It was
smaller than the fossil species Podiceps oligoceanus
(Shufeldt), P. subparvus (L. Miller and Bowman), P. parvus
(Shufeldt), and P dixi Brodkorb and was larger than P. pisa-
nus, P. discors Murray, and Pliolymbus baryosteus Murray.
Measurements of Holotype.—Overall length 32.5 mm,
width at head 8.6 mm, width at distal end 8.7 mm, least width
of shaft 3.6 mm.
Description of Holotype.—The specimen is similar in
size to femora of Podiceps auritus, but it is considerably nar-
rower across the distal end and has a much narrower external
condyle. The latter is difficult to measure, but the differences
are readily seen when the bones are viewed from the anterior or
distal aspects.
227
228
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE I.—Specimens oi Podiceps howardae: a. holotype femur USNM 252314; b, paratype femur USNM
177918; c, tarsometatarsus KUVP 21239; d, coracoid USNM 177927; e. humerus USNM 243764;/ distal por-
tion of humerus USNM 215034. (Scale bar= 17.5 mm.)
Additional Specimens.—A nearly complete tarsometatar-
sus (KUVP 21239) is approximately the length of that of the
largest available male of Podiceps auritus and, in general, it is
similarly shaped. The foramen between the trochleae for digits
three and four is longer in the fossil, and the trochlea for digit
four is less offset and does not extend distally as far as that of
digit three (in 27 out of 31 P auritus, the trochlea for digit four
is the longer). The proximal half of a tarsometatarsus (USNM
250773) is as wide as that of a large example of P. auritus,
whereas the distal portion of another (USNM 210531) is no-
ticeably more slender, differing to the same degree as tar-
sometatarsi of males and females of recent P auritus. Two oth-
er fragmentary tarsometatarsi, a proximal portion (USNM
193175) and a distal portion (USNM 206326), are more similar
in size to the smaller one. Unfortunately, the trochlea for digit
four has been lost in each of the distal pieces.
The nearly complete tarsometatarsus measures 48.8 mm (if it
were complete, it would measure approximately 50 mm.) As-
suming that this bone and the largest femur (USNM 177918,
paratype) belong to the same sex of the same species, the ratio
of femoral length to tarsometatarsal length would be about
0.72. The comparable ratios of four specimens each off auri-
tus and P grisegena (Boddaert) are 0.73 and 0.76, respectively,
whereas those of Aechmophorus occidentalis (Lawrence) and
Podilymbus podiceps (Linnaeus) are 0.60 and 1.02, respective-
ly. Thus, the new bird presumably had similar hind-limb pro-
portions to those of P. auritus.
The proximal two-thirds of a tarsometatarsus (USNM
250773) has a nearly complete articular portion and resembles
that of a large male P. auritus in size and in width of the proxi-
mal end. This is in contrast with the relatively narrow distal
end of the femur.
A nearly complete coracoid (USNM 177927) resembles co-
racoids of P. auritus in size and form but has a relatively deep-
er sternal facet. The bone is 30.5 mm long, 12.4 mm wide at the
base, 3.0 mm in least width of shaft, and 4.0 mm in maximum
depth of the external facet. In the shape of the head it differs
markedly from that illustrated for the holotype of Pliodytes
lanquisti Brodkorb (1953:954) of the Bone Valley Formation.
A nearly complete humerus (USNM 243764) measures 75.4
mm in length and thus is within the range of measurements of
females of P. auritus.
Five partial humeri, consisting of a proximal portion (USNM
183430) and four distal portions (USNM 193242, 215034,
368557, 430524), also fall within the range of P. auritus. A
fifth distal portion (USNM 407798) is somewhat larger and
heavier (Table 2) than the extreme of P. auritus and probably is
from a large male of P howardae. The shaft of the humerus is
somewhat wider and flatter in the fossil than it is in the living
NUMBER 90
229
form, but not enough to suggest an adaptation for using the
wings under water.
The distal portion of an ulna (KUVP 21292) is slightly
heavier than it is in males of P. auritus and measures 5.8 mm in
maximum width at the distal end, which is near the maximum
for males of P. auritus.
Comparisons.—According to Brodkorb (1963b:227), the
earliest fossil species of Podiceps, and the earliest record of the
Podicipedidae, is P. oligoceanus from the early Miocene of Or-
egon. The holotype femur, as figured by Wetmore (1937:197),
is considerably heavier and somewhat longer than that of P.
howardae. Storrs Olson (in litt., 1986) reported that according
to Jane Gray (in litt.) the provenance, and likewise the age, of
the type of P. oligoceanus are in doubt. He added that "it is a
typical modern grebe and could as well be Pleistocene as early
Miocene."
Podiceps pisanus, from the middle Pliocene of Italy, is
known from the distal portion of a humerus. According to Re-
galia (1902:233-234, pl. 27[I]: figs. 21, 22), P. pisanus was
somewhat larger than P "auritus," and the holotype is charac-
terized by the shape of the scar for the attachment of M. brachi-
alis anticus near the distal end of the bone. A cast of the holo-
type was compared with four humeri of P. howardae (USNM
193242, 215034, 368557, 407798) and with a series of skele-
tons of recent P. auritus in the UMMZ (Table 2). In size it is at
or near the lower limits of females of P. auritus (from this, it
appears that Regalia's comparisons were made with the smaller
species, P. nigricollis Brehm, which for many years was called
"auritus"). In its shorter, wider, more transverse scar for the at-
tachment of M. brachialis anticus, P. pisanus differs from P
auritus (and also from P. howardae) as described by Regalia.
Podiceps subparvus, described by Miller and Bowman
(1958:6-7) from the middle Pliocene of San Diego, California,
was somewhat larger than P. howardae and was wider across
the distal end of the femur.
Podiceps discors, described by Murray (1967:279-282)
from the late Pliocene Rexroad Formation of Kansas, appears
to have been a slightly smaller species than P. howardae. The
type, a well-preserved tarsometatarsus (UMMP 52465), is
smaller and more slender than the tarsometatarsi referred to P.
howardae. The latter specimens also differ from P. discors and
resemble P. auritus and P nigricollis in having the support of
the internal condyle more flared internally.
Murray (1967:281-282) referred several specimens from the
Hagerman local fauna of Idaho to P. discors. One of these, a
femur (UMMP 52423), is within the range of P. howardae and
is proportionally too narrow at the distal end for P. auritus. It
differs from the holotype of P. howardae in having facets for
the insertion of M. obturator internus and M. ischiofemoralis
TABLE 1.—Measurements (in mm) of femora of Podiceps howardae and P. auritus. Data for P. auritus are the
ranges of 12 individuals, six of each sex, in the collection of the UMMZ.
Specimen	Total length	Width at head	Least width of shaft	Width at distal end	Width at distal end/total length
Podiceps howardae Holotype USNM 252314	32.5	8.6	3.6	8.7	0.27
Paratypes USNM 177918	35.8	9.5±	3.5	9.5±	0.27±
USNM 178151	-	9.9	3.8	-	-
USNM 206413	-	10.0	4.0	-	-
USNM 215453	32.5	8.7±	3.6	-	-
USNM 215649	35.0	9.0	3.3	9.0±	0.26±
USNM 460785	32.4	9.9	3.8	9.3	0.29
KUVP 21240 Podiceps auritus	31.3-35.7	8.7-10.3	3.7 3.4-3.9	9.3-10.9	0.27-0.31
TABLE 2.—Measurements (in mm) of the distal portions of humeri oi Podiceps auritus (UMMZ), P. howardae,
and P. pisanus (UMMP). Data for P. auritus are range and mean standard deviation for 10 individuals of each
sex.
Specimen	Width at distal end		Least width of shaft		Height of shaft	
Podiceps auritus	7.2-	-8.1 7.69±0.26	3.3-	-3.95 3.62±0.19	2.75-	-3.5 3.08±0.I6
Podiceps howardae						
USNM 193242		7.5		4.0		3.4
USNM 215034		7.5		3.8		3.15
USNM 368557		7.9		4.1		3.35
USNM 407798		8.3		4.4		3.75
USNM 243764		7.3		4.0		3.25
USNM 430524		8.0		-		-
Podiceps pisanus						
(cast of holotype)		7.2		3.75		2.95
230
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
lying more on the lateral plane of the bone than in P. howard-
ae, P. auritus, or P. nigricollis, and in having a larger, deeper
depression for the insertion of M. obturator externus. Two of
the three coracoids assigned to P. discors by Murray (UMMP
52277', 49590) have considerably shallower external sternal
facets than in P. howardae.
Pliolymbus baryosteus, also described by Murray
(1967:278-279) from late Pliocene deposits in Kansas, was
placed in a new genus on the basis of characters in the sternum,
an element that so far is unknown in Podiceps howardae. The
other skeletal elements of Pliolymbus are much smaller than
the corresponding ones of P. howardae.
The holotype of Podiceps parvus has been discussed and fig-
ured by Wetmore (1937:195-197, 200-201) and reviewed by
Miller and Bowman (1958:4-5). This was a larger species than
P. howardae and has been stated to range from the early mid-
dle Pliocene to the middle Pleistocene.
Podiceps dixi, from middle Pleistocene beds in Florida, is
known from the proximal part of the carpometacarpus, an ele-
ment as yet unknown for P. howardae. Measurements given in
the original description (Brodkorb, 1963a:54) indicate that it
was a larger bird than P auritus, and hence, than P. howardae.
Steadman (1984:49), after reviewing the literature on fossil
grebes, pointed out the "unsatisfactory nature" of this species
and preferred to regard it "as a synonym of P auritus."
Podiceps gadowi, described from Quaternary deposits on
Mauritius (Hachisuka, 1953:124-125), is known from a single
right ulna (205k) in the Cambridge University Museum of Zo-
ology. This was examined by S.L. Olson (pers. comm.) in Au-
gust 1985, who found that it had been annotated by Graham
Cowles of the British Museum (Natural History) (now The
Natural History Museum, London) as being from a whimbrel
(Numenius phaeopus, Scolopacidae). According to Olson, the
specimen measures 81.8 mm in length and is definitely not a
grebe.
The fossil Thiornis sociata Navas from the middle Miocene
of Spain has been recognized as a grebe and was redescribed
by Olson (1995:131-140), who placed it tentatively in the ge-
nus Podiceps, although "in its general morphology, particularly
the pelvis and hind limb, Thiornis sociata is decidedly more
similar to Tachybaptus than to modern species of Podiceps."
Because comparisons with skeletons of recent grebes show that
P howardae clearly belongs in the genus Podiceps, compari-
son with Thiornis was not attempted.
Remarks.—Podiceps howardae was a small grebe; it aver-
aged slightly larger in size than the recent Horned Grebe, Podi-
ceps auritus, but it was similar in proportions. The known
specimens all come from offshore marine deposits; however,
because the floating nests of all living grebes are subject to
damage or loss by wave action and fluctuations in water level,
these birds do not nest near large expanses of open water or in
tidal situations. Assuming that P. howardae had similar nesting
requirements, it probably nested inland on fresh water and win-
tered on salt water. Thus, specimens of this Pliocene species
may well be expected in inland localities. Such a pattern of dis-
tribution is already known for the fossil species Podiceps par-
vus (Miller and Bowman, 1958:5).
In spite of the similarities in size and proportions between P.
howardae and P auritus, whether the former was ancestral to
the latter is unclear. Fjeldsa (1983) has provided convincing
evidence for character displacement in the bill length of grebes,
and character displacement also is evident in the overall size of
the Red-necked Grebe (Podiceps grisegena), which is consid-
erably smaller in Europe, where it is sympatric with the larger
Great Crested Grebe (P. cristatus (Linnaeus)), than it is in
North America, where no larger congener occurs (Palmer,
1962:63-87). Even greater geographic variation in size is
found in the White-tufted Grebe (Rollandia rolland (Quoy and
Gaimard)), in which tarsometatarsal length of study skins var-
ies from 51.7 mm in a male of the race on the Falkland Islands
(Islas Malvinas) to 31.0 mm in a small female from northern
Argentina (Storer, unpublished data). Smaller, but significant,
differences in size in this species occur between lakes Junin
and Titicaca, where R. rolland is found with different assem-
blages of grebes. There is no reason to doubt that geographic
variation occurred in the past as it does today, and this should
be taken into consideration in any analysis of fossils (Storer,
1992:419^22).
It is thus evident that size in grebes is not necessarily an indi-
cation of close relationships. It is therefore to be expected that
as faunas change with the disappearance of some forms and the
appearance of others, shifts in the size of at least some of the
species can be expected. This being the case, other characteris-
tics, especially the conformation of bones, should be more use-
ful in assessing relationships among closely related species of
grebes.
Differences in proportions can arise from more than one
source. In birds using similar types of locomotion, wings must
increase more rapidly than overall size in order for a bird to
maintain the ability to fly. This explains most, if not all, of the
differences in the ratios of humeral length to tarsometatarsal
length mentioned above. Other proportional differences, such
as those in the toes, are more likely to reflect differences in the
way the foot is used and are presumably more significant in
phylogenetic studies.
Compared with other pre-Pleistocene grebes, Podiceps
howardae is represented by a fair number of specimens. Until
other species become known from more adequate material,
little can be shown about the relationships among them and
recent species.
NUMBER 90
231
Literature Cited
Brodkorb, P.
1953.    A Pliocene Grebe from Florida. Annals and Magazine of Natural
History, series 12, 6:953-954.
1963a. A New Pleistocene Grebe from Florida. Quarterly Journal of the
Florida Academy of Sciences, 26( 1): 53-55.
1963b. Catalogue of Fossil Birds. Bulletin of the Florida Slate Museum, Bi-
ological Sciences, 7(4): 179-293.
Fjeldsa, J.
1983.    Ecological  Character  Displacement  and  Character  Release   in
Grebes Podicipedidae. Ibis, 125(4):463-481.
Hachisuka, M.
1953.    The Dodo and Kindred Birds, xvi + 250 pages. London: H.F. and G.
Witherby.
Miller, L., and R.I. Bowman
1958.    Further Bird Remains from the San Diego Pliocene. Contributions
in Science of the Los Angeles County Museum. 20:1-15.
Murray, B.G., Jr.
1967.    Grebes   from  the   Late   Pliocene  of North  America.   Condor,
69(3):277-288.
Olson, S.L.
1995.    Thiornis sociata Navas, a Nearly Complete Miocene Grebe (Aves:
Podicipedidae). Courier Forschungsinsul Senckenberg, 181:
131-140, 4 figures.
Palmer, R.S., editor
1962.    Handbook of North American Birds. Volume 1, x+567 pages. New
Haven and London: Yale University Press.
Regalia, E.
1902.    Serte   Uccelli   Pliocenici.   Palaeontographia   Ilalica,   8(1902):
219-238, plate 27[I].
Steadman, D.W.
1984.    A Middle Pleistocene (Late Irvingtonian) Avifauna from Payne
Creek, Central Florida. Carnegie Museum of Natural History Spe-
cial Publication, 8:47-52.
Storer, R.W.
1992.    Intraspecific Variation and the Identification of Pliocene and Pleis-
tocene Grebes. In K.E. Campbell, Jr., editor, Papers in Avian Pale-
ontology Honoring Pierce Brodkorb. Science Series, Natural
History Museum of Los Angeles County, 36:419-422.
Wetmore, A.
1937. A Record of the Fossil Grebe, Colymbus parvus, from the Pliocene
of California, with Remarks on Other American Fossils of This
Family. Proceedings of the California Academy of Sciences, series
4,23:195-201.
Miocene and Pliocene Birds from the Lee Creek Mine,
North Carolina
Storrs L. Olson and Pamela C. Rasmussen
ABSTRACT
An account is given of a collection of over 10,000 fossils repre-
senting at least 112 species of birds from middle Miocene (Pungo
River Formation) and early Pliocene (Yorktown Formation)
deposits exposed during phosphate mining in the Lee Creek Mine,
near Aurora, Beaufort County, North Carolina.
Relatively few of these species are derived from the Pungo
River Formation, as determined partly by similarity to contempo-
raneous species from the Calvert Formation of Maryland and Vir-
ginia. The tremendous avifauna now known from the Yorktown
Formation consists of nearly 100 species, including three species
of loons, two grebes, five albatrosses, at least 16 shearwaters and
petrels, one pelican, two pseudodontorns (horizon less certain),
three gannets, two cormorants, at least nine auks and puffins
(probably 11 or more), one skua, three jaegers, five gulls, two
terns, and 20 species of ducks, geese, and swans. Incidental land
and shore birds, a few of which likely originated in the Pungo
River Formation, are represented by 29 species, including three
cranes, one rail, two oystercatchers, one plover, four scolopacids,
one flamingo, one ibis, one heron, three storks, one condor, five
accipitrids, one osprey, one chachalaca, one phasianid, one turkey,
one pigeon, and one crow. Three new species are described, one in
each of the genera Gavia, Phoebastria, and Calonectris. In num-
bers of individuals, the avifauna is dominated by a radiation of
auks of the genus Alca. The avifauna of the Yorktown Formation
indicates conditions of much greater marine productivity, with
accompanying greater diversity of marine birds, than existed in the
middle Miocene. Loss of diversity since the early Pliocene
involved extinction of most of the radiation of Alca, two species of
albatrosses, two species of gannets (Moms), a pelican, and possi-
bly a cormorant. Diversity in the western North Atlantic Ocean
also was reduced by the withdrawal of three species of albatrosses,
numerous petrels, and a puffin (Fratercula) to the Pacific Ocean.
Other species, mostly of land and shore birds, appear to have with-
drawn from North America but have persisted in Europe and Asia.
Apart from the relatively few extinctions and several range retrac-
tions, the avifauna in the early Pliocene of North Carolina was
very modem in aspect, and many modern species lineages of birds
may already have been in existence at least five million years ago.
Storrs L. Olson, National Museum of Natural History, Smithsonian In-
stitution, Washington, D.C. 20560-0131. Pamela C. Rasmussen, Mich-
igan State University Museum, East Lansing, Michigan 48824-1045.
Introduction
This paper originated as a survey of an extensive fossil avi-
fauna from Miocene and Pliocene marine deposits obtained in
the late 1960s and early 1970s at what was then called the
Texasgulf Lee Creek Phosphate Mine in North Carolina (now
owned by the Potash Corporation of Saskatchewan). Bird fos-
sils from this site were originally turned over to Alexander
Wetmore for study, and he was to have prepared a paper on
these specimens for inclusion in a projected volume on the ge-
ology and paleontology of the mine. Because of Wetmore's
commitment to his magnum opus on the birds of Panama,
Olson later volunteered to take on the bulk of the work associ-
ated with preparing a manuscript on the Lee Creek Mine birds.
Olson and Wetmore (Figure 1) produced a manuscript entitled
"Preliminary Survey of an Extensive Miocene and Pliocene
Marine Avifauna from Lee Creek, North Carolina," which was
submitted to the volume editor on 28 September 1973 and sub-
sequently was optimistically cited as "in press" (Olson, 1975,
1977; Alvarez and Olson, 1978).
Years went by and the single volume that was originally en-
visioned was expanded to two, then three, and ultimately four
volumes. The first of these appeared a decade after the original
manuscript on birds had been submitted (Ray, 1983) and was
followed by a second volume four years later (Ray, 1987).
Meanwhile, the quantity of avian fossils from Lee Creek Mine
increased. At the same time, Wetmore's health declined, and he
was no longer able to participate in the several attempts Olson
made to keep the Lee Creek manuscript up to date. By the time
Wetmore died on 7 December 1978, the manuscript bore little
resemblance to the first draft to which he had contributed.
Some of the ideas first developed by Olson in the early drafts
appeared subsequently in an overall summary of the fossil
record of birds (Olson, 1985d).
Because so many new fossils were acquired after Olson's
last lone revision of the manuscript, Jonathan Becker was en-
listed to identify new specimens and worked to produce an up-
dated version of the manuscript. This, too, eventually became
almost completely obsolete, both apart from, and because of,
233
234
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
FIGURE 1.—Olson (left) and Alexander Wetmore (right) in the early 1970s, examining the available fossil bird
bones from Lee Creek Mine. Since then, the number of specimens has increased by probably more than an order
of magnitude.
acquisition of new material. By this time Becker had changed
careers. Olson and Rasmussen began collaboration on a revi-
sion of the Lee Creek Mine avifaunas in 1991, greatly expand-
ing the material included and gaining entirely new insights into
systematics, biogeography, and evolution. The present manu-
script thus bears little resemblance to its predecessors. We must
therefore acknowledge with gratitude the contributions of our
previous collaborators, Wetmore and Becker, to the early stag-
es of study of this massive avifauna, while relieving them of
any responsibility for our conclusions.
To our knowledge, the Lee Creek Mine collection constitutes
what is probably the largest Tertiary marine avifauna now
known, with at least 112 species of birds, most being pelagic
forms, represented by over 10,000 specimens, not all of which,
however, have been included in the present study. The fossils
from Lee Creek Mine are from two distinct faunas, one of mid-
dle Miocene age (-14 Ma) derived from the Pungo River For-
mation, and a much larger early Pliocene (3.7-4.8 Ma) avifau-
na derived from the Yorktown Formation. Because of the
nature of the mining operations, it is often uncertain which ho-
rizon produced a given fossil, and this mixing contributes to
the complexity of analyzing certain groups.
The Pungo River Formation is in part equivalent to the Cal-
vert Formation of the Chesapeake Group of Maryland and Vir-
ginia. The avifauna of the Calvert Formation is now reasonably
well known from fossils, many still undescribed, found in pre-
cise stratigraphic contexts. Thus, the horizon of certain Lee
Creek Mine fossils may be inferred from their identity with
NUMBER 90
235
species known from the Calvert deposits. We also have a few
additional undescribed specimens of fossil birds from the
Choptank, St. Marys, and Eastover formations in Maryland and
Virginia that we propose to study by systematic groups in con-
junction with fossils from the Calvert Formation before at-
tempting to synthesize the East Coast marine avifaunas that
preceded those of the Pliocene.
For this reason, we have not dwelt at length on the avifauna
of the Pungo River Formation in the present report, the species
of which will be treated in more detail later in conjunction
with those of the Calvert Formation. Instead, we emphasize
herein the much more extensive and diverse avifauna of the
Yorktown Formation, fossils of which are extremely rare in
surface exposures. This very important marine avifauna would
be all but unknown were it not for mining operations.
The present study is preliminary, and no one is more aware
of its shortcomings than the authors. We have intended this
mainly as a faunal survey, but of necessity we must deal with
many issues of systematics as well. Needless to say, a great
deal of revisionary work is still urgently needed, particularly
among such difficult groups as the shearwaters (Procellari-
idae). By making these avifaunas better known, we hope to
stimulate taxonomists to undertake revisions of various taxa,
and we invite them to include the Lee Creek Mine material,
especially that from the Yorktown Formation, in their studies.
ACKNOWLEDGMENTS.—We thank the officials of Texas-
gulf, Inc., and their successors, for their continuing consider-
ation in permitting paleontological investigations at the Lee
Creek Mine. Field parties from the Smithsonian Institution
were funded by the Smithsonian through the Remington and
Marguerite Kellogg Fund and the Walcott Fund.
We owe our greatest debt to the many collectors whose
sharp eyes spied thousands of small bird bones on the mine
spoil piles and whose generosity in donating the specimens to
the Smithsonian has permitted this study. In this connection
the massive contributions of Peter J. Harmatuk and Frank and
Becky Hyne must be singled out. The following additional
collectors also donated specimens: Calvin Allison, David R.
Amos, Elizabeth and Wallace L. Ashby, Donnie Bailey, Aura
L. and J. Wayne Baker, Peter Ballmann, William C. Bean, N.
Bikan, David and Paula Bohaska, Captain and Mrs. Michael
Boroff, John Boyd, Eldon Branch, Pat and Tom Burns, Kerry
Button, Ken Carpenter, John H. Carson, Richard Carter,
Gerard R. Case, Ralph Chamness, Richard Chandler, Mike
Cohen, Phillip Cox, Larry Decina, Daryl Domning, Raymond
C Douglass, Duke University Marine Lab (through Dan
Rittschof), Ralph Eshelman, John Everette, Alan Feduccia,
James Firebaugh, Mark Florence, George C. Fonger, Frank
Garcia, Steve Gotte, Michael D. Gottfried, Fred Grady,
Richard W. Grier, Jr., Robert W. Grier, Todd Grimsley, Leslie
Hale, Christopher J. Harmatuk, Eugene F. Hartstein, Barbara
Harvey, Bill Heim, Anne Henderson, Wayne Henschel, Linda
Heritage, Carolynne and Scott Hertenstein, Pam Hester, Mr.
and Mrs. L. Hodges, Candace Holiday, Sid Hostetter, Jane
Hubbard, Fran Hueber, Aileen and Stanley Hyne, Kelly Irwin,
Ronald M.A. Ison, Jeremy Jacobs, Helen James, Walter Johns,
Linda Johnson, Ralph Johnson, James Kaltenbach, William G.
Keel, John Keshishian, Anne Leightner Kienlen, Jim Knight,
Trish Kohler, Arnold Lewis, Lloyd Logan, Andreas Luettge,
Royal H. Mapes, Earl Mason, Vance McCollum, Peter A. Mc-
Crery, Rita McDaniel, Tom Mclntyre, Gregory S. McKee,
Jack H. McLellan, Robert Metzger, Robert L. Meyer, Jon
Moore, Wayne Morgan, A.C. Myrick, Jr., John and Myrna
Nay, Randy Nunnery, Gene C. Oliver, John A. Onderdonk, Jr.,
Tom Parks, Franklin Pearce, Michael A. Pehachek, James and
Susan Pendergraft, Diane Pitassy, John L. Pittman, Pamela
Platt, George Potter, George W. Powell, Jr., Robert W. Purdy,
Clayton E. Ray, Charles A. Repenning, William J. Rieger,
Norman L. Riker, Albert J. Robb III, Betty L. Roberts, Rocky
Mount Children's Museum, Annette Salensky, Mr. and Mrs.
Vincent P. Schneider, Randy Scott, William Shelton, David
Oscar Siegert, Edward S. Slagle, Wilton Smith, Albert and
Cheryl Snelson, Scott W. Snyder, Gladwyn Sullivan, Clyde
Swindell, Calvin E. Taylor, Bill and Juanda Taylor, Reginald
Titmas, Jerry D. Tracy, John Waldrop, David Wells, James
Westgate, Alexander Wetmore, Frank C, Jr., and Martha
Whitmore, Gaye Williams, Druid Wilson, E.A. Womble,
Roger Wood, Wendell P. Woodring, W.W. Zack, and George
Zug.
David J. Bohaska, Mark Florence, Robert W. Purdy, and
Clayton E. Ray, of the Department of Paleobiology, National
Museum of Natural History (NMNH), Smithsonian Institu-
tion, have assisted repeatedly in many aspects of this study.
We are indebted to Frank B. Gill and Earl A. Shapiro (Acade-
my of Natural Sciences of Philadelphia), William N. Orr
(Condon Museum of Fossils, University of Oregon), Michael
Gottfried (then of the Calvert Marine Museum), and Larry D.
Martin (University of Kansas, Lawrence (KU)) for making
fossil material available for study. Janet Hinshaw lent recent
comparative material from the University of Michigan Muse-
um of Zoology, Ann Arbor (UMMZ). S. David Webb, Bruce
J. MacFadden, Gary S. Morgan, and Pierce Brodkorb made
material from the Bone Valley Formation, now in the Florida
Museum of Natural History (UF), available for study. Tom
Demere kindly lent specimens, including holotypes, from the
San Diego Natural History Museum (SDSNH). Over the years
we have benefited from study of both fossil and modern mate-
rial from the Natural History Museum of Los Angeles County
(LACM), and we thank Kenneth E. Campbell for lending fos-
sils from Rancho La Brea for comparison in this study. We
also had access to specimens from the Big Sandy Formation,
Arizona, lent from the Frick Collection at the American Muse-
um of Natural History (F:AM), New York. We are particularly
grateful to Thomas G. Gibson (United States Geological Sur-
vey) for analyzing matrix samples from some of the bird fos-
sils. Raphael Alvarez (formerly UMMZ) provided initial iden-
tifications of some of the duck fossils that were available in
the 1970s. Kenneth I. Warheit (Washington Department of
236
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Fish and Wildlife, Seattle) and Helen F James (NMNH) aided
in a variety of ways. Camm C. Swift (formerly of the Natural
History Museum of Los Angeles County) identified fish prey
of an auk. Douglas Siegel-Causey and Jiri Mlfkovsky translat-
ed portions of articles in Russian. David W. Steadman provid-
ed measurements of some albatross fossils at UF.
The many photographs are the patient work of our dedicated
associate of many years, Victor E. Krantz, of the Smithson-
ian's Office of Photographic Services. Brian K. Schmidt
(NMNH) assisted with revisions of some of the plates. Pierce
Brodkorb, Robert W. Storer, Miklos D.F. Udvardy, John Far-
rand, Jr., and Albert C. Myrick commented long ago on por-
tions of an early draft of this paper. We are especially grateful
to Steve Emslie (University of North Carolina, Wilmington)
and Cecile Mourer-Chauvire (Universite Claude Bernard, Ly-
on) for supplying numerous references and for their comments
on the manuscript. Craig Ludwig (NMNH) checked the accura-
cy of catalog numbers of modern comparative material in the
manuscript with the specimen database in the Division of
Birds, National Museum of Natural History, Smithsonian Insti-
tution. Finally, with dedication and tireless attention to detail,
Mark Florence (NMNH) checked each of the catalog numbers
of fossils in the manuscript against the specimens themselves,
correcting a number of errors.
Synopsis of the Geology of the Lee Creek Mine
The Lee Creek fossil locality is an open-pit mining operation
for obtaining commercial quantities of phosphate from the
middle Miocene marine sediments of the Pungo River Forma-
tion. The mine is located on the south bank of the Pamlico Riv-
er, north of the town of Aurora, Beaufort County, in central
eastern North Carolina (35°23'22"N, 76°47'06"W). Mining
was started at what was then the debouchment of Lee Creek
into the Pamlico River (McLellan, 1983), the lower reaches of
the lesser stream having since been obliterated by the mine to
which it gave its name (see Ward and Blackwelder, 1987, figs.
1,2).
This sacrifice of a bit of coastal topography has been more
than compensated by the tremendous increase in knowledge of
geology and paleontology that was made possible by the min-
ing operations at Lee Creek. There are no naturally occurring
outcrops of the Pungo River Formation anywhere, so the only
fossil birds known from it have come from Lee Creek Mine.
Practically the same may be said of the overlying Yorktown
Formation, surface outcrops of which are very limited and
which have yielded at most a handful of bird bones. This is in
marked contrast with the thousands upon thousands of bird fos-
sils of Yorktown age from Lee Creek Mine, an assemblage that
constitutes the most extensive marine paleoavifauna in the
world in terms of both species and numbers of specimens.
Without these fossils we would scarcely have an inkling of the
dramatic turnover that took place in the pelagic avifaunas of
the North Atlantic Ocean between the moderately well-known
avifauna of the Calvert Formation, some 14 million years ago,
and the present.
Mainly for the benefit of those who do not have access to the
other volumes in this series, we have included herein a very
brief synopsis of the geology of Lee Creek Mine, which, unless
otherwise indicated, has been extracted from the lucid and in-
formative papers of Gibson (1983a, 1983b).
Neogene sediments at Lee Creek Mine accumulated in a neg-
ative feature, the Albemarle embayment, flanked by two
east-west trending positive geological structures, the Norfolk
arch, running across southern Virginia, and the New Bern arch,
running across central eastern North Carolina, just south of
Pamlico Sound. Although the sediment column at the mine is
capped unconformably by late Pliocene and Pleistocene sedi-
ments (see also Ward and Blackwelder, 1987), we are unaware
of any fossil birds from these strata. If these deposits ever were
exposed on the surface of spoil piles at the mine, they likely
would not attract much attention from the amateur collectors
responsible for collecting the majority of the fossil birds at the
mine, who search mainly in sediments in which large sharks'
teeth are likely to be found.
Thus, attention is focused herein on the other strata exposed
at the mine—those of the Pungo River Formation and the over-
lying Yorktown Formation. The Pungo River Formation was
laid down during an extensive marine transgression responsible
for the mainly contemporaneous Calvert Formation to the
north, around Chesapeake Bay, and the Kirkwood Formation in
New Jersey (Figure 2). Commercially profitable phosphate de-
posits occur in the Pungo River Formation, so the mine, of
course, does not extend below this level, although it is known
from well cores that the formation rests unconformably on Pa-
leogene sediments, as does the Calvert Formation. The Pungo
River Formation is more than 122 m thick at its maximum, but
at Aurora, near Lee Creek Mine, it is about 28 m thick. Sedi-
ments at the mine are characterized by the absence of terrige-
nous elastics and include diatomaceous clay, carbonates, and
phosphatic sands. The lower part of the Pungo River Formation
(Belhaven Member) formed on the middle to outer shelf in wa-
ter depths of 100 to 200 m, whereas the upper part (Bonnerton
Member) formed on the inner to middle shelf in water depths
of 150 m to less than 70 m. The top of the formation is an ero-
sional surface.
In the middle to late Miocene, three lesser marine transgres-
sions resulted in the Choptank, St. Marys, and Eastover forma-
tions, but these all lie to the north and are not represented at
Lee Creek Mine. The next great transgression gave rise to the
Yorktown Formation and its lateral equivalents (the Cohansey
Sand and the Duplin Formation), extending from New Jersey to
South Carolina (Figure 3). The depth and composition of the
sediments varies greatly geographically due to environmental
differences. At Lee Creek, the 15 m thick Yorktown Formation
rests unconformably on the Pungo River Formation. Its basal
unit consists of muddy, gravelly phosphatic sand containing re-
worked phosphate nodules from the underlying Pungo River.
NUMBER 90
237
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FIGURE 2.—Isopachous map of middle Miocene strata showing the extent of
the Calvert/Pungo River embayment (shaded). l=Kirkwood Formation,
2=Calvert Formation, 3=Pungo River Formation; contours in feet. Based on
Gibson (1983a:39, fig. 3).
160 Kilometers
FIGURE 3.—Isopachous map of early Pliocene strata showing the extent of the
embayment (shaded) of the Yorktown Formation and equivalent deposits.
l=Cohansey Sand, 2=Yorktown Formation, 3=Duplin Formation; contours in
feet. Based on Gibson (1983a:70, fig. 32).
This is succeeded by several fossiliferous units of muddy sand
and sandy mud (see section in Snyder et al., 1983, fig. 2). The
top of the formation is an erosional unconformity.
There are lithic and faunal changes within the Yorktown For-
mation, as well as scour surfaces, although it is not known
whether these formed below water or subaerially. The York-
town Formation in the Albemarle embayment, which contains
Lee Creek Mine, contains older strata deposited in deeper wa-
ter than was in the Salisbury embayment to the north. The basal
unit at Lee Creek Mine is thought to have formed under 80 to
100 m of water. The majority of vertebrate fossils from the
mine are considered to have been derived from this basal part
of the Yorktown Formation. This accords very well with the
highly pelagic nature of almost the entire avifauna and the
great scarcity of shore and land birds in the collections, indicat-
ing deposition on the high seas in relatively deep water.
Foraminifera could be obtained only from the upper 3.7 m of
the Pungo River Formation. These correlated with foraminifer-
al zones N8 and N9, indicating a late early and early middle
Miocene age, equivalent to the European Langhian stage, the
middle of which is about 14 Ma, the same age as the upper part
of the Calvert Formation. Foraminifera from the basal part of
the Yorktown Formation indicate an age of N19/20, which is
early Pliocene, falling within the European Zanclian stage. The
Yorktown Formation at Lee Creek Mine is considered to range
in age from 3.7 to 4.8 Ma (Hazel, 1983:97). The majority of
bird fossils from Lee Creek Mine come from the basal part of
the Yorktown Formation, hence their age would be closer to
4.8 Ma.
Paleoenvironment
Marine conditions at Lee Creek during the period of deposi-
tion of the Pungo River and Yorktown formations have been
ably summarized by Purdy et al. (this volume), and the avifau-
na strongly supports their reconstructions. Fossils were depos-
ited well offshore in water of about 100 m depth at the south-
western end of the Aurora Embayment, a deep depression that
allowed cold waters to upwell 100 km west of the margin of the
continental shelf (Popenoe, 1985). Bottom temperatures in
both time periods were cool temperate (Gibson, 1967).
The ichthyofauna of the Pungo River Formation indicates a
warm but not tropical environment with few pelagic elements,
suggesting an absence of cold upwelling. Fishes of the York-
town Formation, on the other hand, are a mixture of tropical,
warm-temperate, and cool-temperate taxa, with abundant tuna
and other pelagic fishes, indicating a sharp temperature gradi-
ent in the region with nutrient-rich cold upwelling. In the vicin-
ity of Lee Creek Mine, this created what Purdy et al. (p. 188,
this volume) call, rather understatedly, a "marine vertebrate,
high-use feeding area," in which tuna drove prey fish to the
surface where they were fed upon by abundant cetaceans, sea-
birds, and sea turtles in company with an extremely abundant
and diverse shark fauna.
238
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
This must have been one of the most spectacular feeding as-
semblages of marine vertebrates the world has ever known. To
put it in perspective, the total number of species of birds known
from Lee Creek Mine is greater than the total number of spe-
cies of fishes collected there. The figure is perhaps somewhat
inflated for bird species by the relatively high proportion of
very rare incidental shore and land birds, but nevertheless it is
an extremely diverse avifauna that in terms of numbers of indi-
viduals is overwhelmingly dominated by pelagic, piscivorous
species, particularly auks, along with abundant shearwaters, al-
batrosses, gannets, and loons.
Taphonomy
Although we have not attempted a taphonomic analysis, we
discuss herein some impressions that may help to explain why
there were so many fossils of birds in the area of Yorktown-age
deposits that have been excavated at Lee Creek Mine. When
the size of the mine is taken into consideration, however, the
concentration of bird bones seems less impressive than that
conveyed by the numbers of museum drawers filled with fos-
sils. As of January 1998, the area excavated at Lee Creek Mine
was 2408 hectares (5949 acres), or 24.1 km2 (9.3 mi2). Using a
conservative figure of 10,000 avian fossils collected so far
from the mine, this averages out to only 0.7 bird specimens per
hectare.
Very few fossil birds have been found in the Yorktown For-
mation as associated partial skeletons. These have been found
in nodules that apparently come from higher levels in the stra-
tum, as opposed to the basal part of the formation, from which
most of the bird bones are believed to have been derived. In the
basal part of the Yorktown Formation, we suspect that much of
the accumulation of bird bone ultimately came from regurgita
of predators.
The Yorktown seas off present-day North Carolina must
have supported one of the greatest levels of marine productivi-
ty in the history of the earth. As a consequence, these waters
seethed with a diversity of sharks, seals, and carnivorous ceta-
ceans that has no parallel on the planet today. One may envi-
sion vast schools offish, among which a multitude of auks,
loons, and diving shearwaters swam in pursuit of their prey.
These invaders of a piscine world, despite being well adapted
to their environment, would have been highly susceptible to
predation by larger carnivores. A large shark wreaking havoc
on a school of hake would doubtless much prefer a large, fat
auk, with a beakful offish, to any smaller prey. Not only diving
birds but any others that may occasionally venture below the
surface, such as albatrosses and gulls, also would have been
susceptible. Sharks, particularly tiger sharks (Galeocerdo),
which were abundant at Lee Creek, will at times even take
birds from the surface (e.g., Moseley, 1892:49; Gudger, 1949;
Dodrill and Gilmore, 1978).
Most bird fossils from Lee Creek Mine are found singly and
are typically broken. For example, at one point in our study
we had examined over 2700 alcid humeri, of which only 83
specimens (3%) were complete or nearly so. The most abun-
dant bird fossils at Lee Creek Mine are the humeri, coracoids,
and ulnae of the larger auks, particularly Alca antiqua
(Marsh). These are among the densest and heaviest bones of
any of the birds in the fauna and thus would have been the
least subject to complete digestion. Furthermore, many appear
etched as well as being broken. Obvious tooth marks of either
predators or smaller scavengers are preserved on some (Fig-
ure 4). Sharks cannot pass solid objects such as these through
their spiral intestines, so "indigestible bodies must come out
where they went in—through the mouth" (Gudger, 1949:46).
Thus, much of the accumulation of bird bones at Lee Creek
Mine may be the result of shark regurgita, which would intro-
duce considerable bias into the fossil record, not only in the
relative abundance of species represented, but in the propor-
tion of different elements of the body as well, with bones of
the wing and pectoral girdle predominating over hindlimb ele-
ments, and the latter over cranial elements.
Figure 4.—Parallel scratches on a tarsometatarsus of an albatross (Phoebast-
ria anglica, USNM 430533), presumably made by the teeth of a predator or
scavenger. (Magnification x-4.3.)
NUMBER 90
239
The Species Question
In dealing with an avifauna such as that of the Yorktown
Formation, we have been forced to deal with difficult ques-
tions, both practical and philosophical, regarding the limits of
species, particularly through time, that are inescapable in a
work of this nature. As might be expected, our own views
evolved during the course of our investigations, and so some
discussion of the approach used herein is warranted.
During the third quarter of the twentieth century, avian pale-
ontology in North America developed under the influence of
Pierce Brodkorb, who presumed that most species of birds did
not cross epoch boundaries (Brodkorb, 1960). On the face of
it, there is little reason why this should be so, and it is counter-
intuitive to presume that speciation occurred simultaneously in
all lineages at the transition from the Pliocene to the Pleis-
tocene, for example. Such may have been the wish of alpha-
level systematists for whom the description of new species
was an end in itself, but this is not helpful in documenting and
comprehending evolution. There are also workers, whose re-
search is more faunally oriented, who subscribe to nomencla-
tural recognition of any morphological variation that is tempo-
rally removed from modern taxa, advocating that "in the case
of a smallest constant morphological difference a new system-
atical name is reasonable" (Janossy, 1987:190).
Another matter that compounds the difficulties of referring
to species in a fauna such as that at Lee Creek Mine is the
cladistic viewpoint that ancestors cannot or should not be
identified in the fossil record (e.g., Englemann and Wiley,
1977; Eldredge and Cracraft, 1980; Norell, 1996), although
this has been vigorously contested by others (e.g., Wagner,
1995, 1996; Foote, 1996). The proposition that, within a rela-
tively small and circumscribed basin such as the North Atlan-
tic, none of the multitude of species that existed four to five
million years ago in Yorktown times was ancestral to any ex-
tant species is hardly tenable. The main problem arises when a
given lineage may have split into two species. How, then, does
one recognize (and deal nomenclaturally with) the common
ancestor of the two? The Pliocene loons at Lee Creek Mine
may reflect just such a problem, with Gavia concinna Wet-
more possibly being ancestral to the living Pacific Loon, G.
pacifica (Lawrence), and the Arctic Loon, G. arctica (Lin-
neaus), and with a new large species (described below) con-
ceivably being ancestral to the modern Common Loon, G. im-
mer (Briinnich), and the Yellow-billed Loon, G. adamsii
(Gray).
This is rather a different matter from saying that the harle-
quin duck (Histrionicus) at Lee Creek Mine, although differ-
ing somewhat from the single living species, is still probably
on a direct line with that species and need not be named as a
distinct taxon. Compounding the difficulties of communica-
tion are the semantic problems that arise from the fact that the
same terminology—species—is applied to two completely dif-
ferent phenomena. As Haffer (1995) has discussed at length,
extant species, regardless of which concept one employs to de-
fine them, are geographical entities that occupy areas with
more or less defined borders that may or may not overlap with
congeneric species. In contrast, temporal "species" are arbi-
trary, morphologically defined units of a continuous lineage
through time. Haffer rightly concluded that Linnean species
nomenclature should not be used for temporal entities, but no
consensus on a useful alternative terminology has yet
emerged.
Mammalian paleontologists have had much longer to con-
tend with such issues, whereas the fossil record in birds has
only recently become sufficiently extensive, particularly
among seabirds, to provide investigators with any meaningful
possibility of detecting changes within a lineage. Differentiat-
ing between extant lineages and those that are extinct, with no
modern descendants, should be one of the most important ac-
tivities of paleontologists dealing with late Cenozoic faunas.
We can hardly have any sensible discussion of faunal changes
and "turnover" without having at least some grasp of whether
the "disappearance" of individual units is due to extinction or
to the evolution of new morphologies.
In the present analysis, when the material from the York-
town Formation is reasonably extensive and we can still find
little or no differences from existing species, we have simply
referred the fossils directly to living taxa, as, for example,
among some of the albatrosses.
We attempted to identify extinct versus extant lineages, but
there are various sources of potential error in this undertaking.
Not the least of these is that different groups of birds have
changed morphologically (but not necessarily speciated) at
very different rates. Shearwaters and albatrosses (Procellarii-
formes), for example, have evolved very slowly. Some procel-
lariiform lineages appear to date back at least to the late Oli-
gocene with little change in morphology. Puffinus conradi
Marsh from the Calvert Formation was very similar to the liv-
ing Greater Shearwater, P. gravis (O'Reilly), so it would be
very difficult to separate the Yorktown-age representative of
this lineage from earlier and later manifestations.
On the other hand, loons (Gaviidae) evolved very rapidly in
the Neogene. Since the middle Miocene, they have increased
greatly not only in size but also in degree of specialization of
both the leg and wing elements for underwater propulsion. Be-
cause there are three species of loons in the Yorktown Forma-
tion, it is tempting to suggest that these are the Pliocene repre-
sentatives of the three major extant lineages, which may well
be the case. Two of the three modern lineages of loons now
consist of pairs of sibling species, of unknown times of diver-
gence. Two of the early Pliocene forms therefore may repre-
sent the common ancestors of the sibling-species pairs rather
than direct ancestors of any of the sibling species. Through the
collection of more fossils from different time intervals and
geographic areas, we can hope to resolve this problem satis-
factorily.
Sometimes the problem is too many fossils. We can easily
recognize a flightless early Pliocene relative of the modern
240
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Great Auk, Pinguinus impennis (Linnaeus), lineage in the
Yorktown deposits. In addition to the rare but unmistakable
Pinguinus bones, however, the fauna contains a vast array of
fragmentary and usually unassociated fossils of closely related
species of the genus Alca that constitutes a continuum varying
so much in size that we calculate it to have encompassed four
species at minimum. Nevertheless, there is only one modern
descendent of this assemblage, the Razorbill (Alca torda Lin-
naeus). Although the ancestor of Alca torda clearly is repre-
sented among all these broken bones, assigning individual
fragmentary limb bones to this lineage is not always possible.
The other side of the coin, too few fossils, is the situation
most frequently encountered. Many late Neogene species of
birds have been founded on material too inadequate even to
distinguish extant from truly extinct lineages.
We have designated lineages that are apparently ancestral to
modern species with the prefix "aff." (Latin affinis, related to,
neighboring), even if minor differences in structure can be dis-
cerned (for example, in Histrionicus). We have listed as syn-
onyms previously named fossil taxa that evidently are continu-
ous with modern lineages. We have used the designation "cf."
(Latin confer, compare) to denote only a general morphological
similarity, not necessarily a close relationship.
Even the ambiguous designation "aff." may be too precise
when confronted with taxa such as the dabbling ducks of the
genus Anas. Among modern species of this genus it is very dif-
ficult or impossible to identify fragmentary material to species
because many species do not differ postcranially other than in
size, and among species there may be considerable variation
and overlap. In such such osteologically difficult groups, we
used the designation "magn." (from Latin, magnitudino) to in-
dicate the approximate size range of the fossils in comparison
with modern species, without implying possible relationship.
The waterfowl, i.e., ducks and geese (Anatidae), provide par-
ticularly illustrative examples of some of the problems we have
attempted to address. The most abundantly represented duck at
Lee Creek Mine turns out, unexpectedly, to be a harlequin
duck, Histrionicus, the material of which is sufficient to show
that the Yorktown bird was very similar to the extant species,
although the wing was slightly less specialized. By previous
standards, this would have been a nameable species, yet only
the quality and abundance of the material would allow it to be
distinguished from the modern species, and then only in some
of the elements. Although it is interesting to find that the wing
has changed slightly in this lineage in the past few million
years, does this mean the Pliocene bird is a new species? When
we found that this apparently new species was bracketed by
names given to extremely scanty, generically misidentified fos-
sils that were both older and younger than the Yorktown For-
mation, it reinforced our opinion that the use of Linnean no-
menclature for such fossils that appear to belong to existing
lineages is untenable. If we have been overly enthusiastic in
our species attributions, we hope nevertheless to have fostered
a healthy new trend in viewing late Cenozoic avifaunas.
Methods
In a few instances, bird fossils were found on spoil piles of
known stratigraphic position. In most cases, however, speci-
mens were brought in as mixed lots gleaned from the spoil
piles with no stratigraphic information. Some differences in
preservation are apparent; bones from the Pungo River Forma-
tion are usually better preserved, black in color, less water-
worn, and have a more polished appearance than do those from
the Yorktown Formation, but such criteria cannot always be re-
lied on. The stratigraphic position of a particular fossil can of-
ten be determined by examination of the adherent matrix and
its contained microfauna. Thomas G. Gibson examined the mi-
crofossils in matrix samples from 43 fossil bird bones selected
at random from the early collections from Lee Creek Mine. His
determinations indicate that all of these probably came from
the basal part of the Yorktown Formation.
The great quantity of fossil material, in particular that repre-
senting the Alcidae, and the unresolved systematics of some
taxa make it impractical to list all specimens thus far identified.
We have, however, listed by catalog number referred material
for all but the most common species; for the latter we list spec-
imens that are unusually complete or diagnostic or that belong
to uncommonly represented skeletal elements. Unless designat-
ed by some other museum acronym (see "Acknowledgments"),
all listed material is in the Vertebrate Paleontology collections
of the National Museum of Natural History (NMNH, which in-
cludes collections of the former United States National Muse-
um (USNM)), Smithsonian Institution.
To attempt to determine whether specimens from Lee Creek
Mine were from the Pungo River Formation or the Yorktown
Formation, we made comparisons with fossil birds from the
Calvert Formation in Maryland and from the Upper Bone Val-
ley Formation in Florida. Most of the Maryland specimens also
are housed in the Vertebrate Paleontology collections of the
National Museum of Natural History; most of those from Bone
Valley are housed in the Florida Museum of Natural History
(UF), which now includes the collection of Pierce Brodkorb
(UF PB). Modern comparative material was mostly from the
collections of the Division of Birds, Department of Vertebrate
Zoology, National Museum of Natural History, Smithsonian
Institution, and also have the USNM acronym, although these
collections have a separate numbering system.
Measurements of bones were taken according to the illustra-
tions in von den Driesch (1976), unless otherwise stated, and
are given in millimeters. Osteological nomenclature is modi-
fied from Howard (1929). Literature citations are given for au-
thorities of scientific names of fossil taxa only. Authorities for
extant North American taxa are generally those cited in the
seventh edition of the A.O.U. Check-list (American Ornitholo-
gists' Union, 1998); those for taxa extralimital to that work are
from Sibley and Monroe (1990).
Elements are listed in the following order: skull, vertebrae
(except synsacral vertebrae), sternum, furcula, coracoid, scapu-
la, humerus, ulna, radius, carpometacarpus, alar phalanges in
NUMBER 90
241
numerical order, pelvis, femur, tibiotarsus, tarsometatarsus,
and pedal phalanges in numerical order. Right elements are
listed before left elements, and complete elements are listed be-
fore partial elements, with proximal portions listed before dis-
tal portions (scapular portions before sternal portions in the
case of coracoids).
Systematic Paleontology
Pelagic Birds
The species account are divided into two sections. The sec-
ond section deals with shore and land birds that are incidental
to the fauna, usually being known by a single bone or fragment
or by at most a few specimens. The present section deals with
the pelagic avifauna, which for the most part consists of species
that lived and fed in the vicinity of deposition. Some of the spe-
cies of waterfowl and gulls would probably not have met this
criterion, although most are more commonly represented than
the incidental shore and land birds. On the other hand, most of
the species represented at Lee Creek Mine in these families
would certainly have been members of the pelagic avifauna,
and we did not consider it practical to split the accounts of
these families along speculative ecological lines.
Order Gaviiformes
(loons)
Family Gaviidae
(loons)
Genus Colymboides Milne-Edwards, 1867
Colymboides? sp.
Material.—Distal end of right humerus, USNM 302286.
Left carpometacarpus missing distal end, minor metacarpal,
and proximal parts of carpal trochlea, KU 21251.
Horizon.—Pungo River Formation inferred from known
temporal distribution of genus.
Measurements (mm).—Humerus:    Distal width, 8.8.
Carpometacarpus:    Length of alular metacarpal, 9.0.
Remarks.—These specimens appear to be referable to Co-
lymboides rather than to Gavia based on the following charac-
ters. In the humerus, the attachment of the anterior articular lig-
ament extends proximally only to the level of the ectepicondyle,
and the surface is nearly plane, rather than sloping medially; in
distal view it is much flatter, and the condyles are much less
bulbous; the olecranal fossa does not extend proximo-intemally
between the internal condyle and the entepicondylar process;
and the ridge on the internal border of the impression of the bra-
chialis anticus is more diagonally oriented with respect to the
shaft. In the carpometacarpus, the alular metacarpal is very
short; the shaft is relatively unflattened; the proximal symphysis
between major and minor metacarpals is very short; and the lig-
amental attachment of the pisiform process is not flattened or
produced anteriorly.
These specimens are from a species smaller than any of the
other loons from Lee Creek Mine or the Chesapeake Group.
Their size suggests that they pertain to an undescribed species,
the humerus being smaller than that of Colymboides anglicus
Lydekker but larger than that of C minutus Milne-Edwards. If
correctly referred to genus, they would provide the first record
of the genus Colymboides outside of Europe. The latest occur-
rence of Colymboides in Europe is in the early Miocene of the
Cheb Basin of the Czech Republic, where the tiny species C.
minutus, otherwise known only from the early Miocene of
France, has been found (Svec, 1980, 1982; Mlikovsky, 1996).
This species is known only from freshwater deposits, so it is
quite possible that the genus Colymboides may have persisted
somewhat later in marine environments (see discussion of Ga-
via egeriana, below).
Genus Gavia Forster
Gavia egeriana Svec, 1982
Material.—Right coracoid, USNM 430523. Proximal two-
thirds of right ulna, USNM 241423.
Horizon.—Pungo River Formation inferred from similarity
to fossils from Calvert Formation.
Measurements (mm).—Coracoid: Length with sternal
facet flat on calipers, -35; width and depth of shaft at midpoint,
4.3x3.8.
Ulna:    Proximal width and depth, 7.3 x 8.3.
Remarks.—Gavia egeriana is a very small species of loon
described from two distal ends of humeri from early Miocene
deposits at Dolnice, in the Cheb Basin in the Czech Republic
(Svec, 1982). The micromammal zone of these deposits is MN
4b (Mlikovsky, 1996); thus, these deposits are probably slight-
ly older than the Calvert or Pungo River formations, and fossils
of this species form the earliest occurrence of the genus Gavia.
Several specimens of Gavia have been recovered from the
Calvert Formation in Maryland, Virginia, and Delaware (Ras-
mussen, 1998) and appear to be referable to two species, differ-
ing in size. We were able to compare the holotype of Gavia
egeriana directly with these specimens, and we assign the larg-
er of the two Calvert loons to that species. The smaller Calvert
loon is undescribed and is not known from Lee Creek Mine.
The coracoid from Lee Creek Mine listed above is black and
phosphatized. It compares well with a coracoid from the Cal-
vert Formation that is associated with a sternum, scapula, and
furcula (USNM 23717) that we refer to G. egeriana based on
size. Likewise, the ulna from Lee Creek Mine is close to one
from the Calvert Formation that is associated with a radius and
the proximal end of a humerus of G. egeriana (USNM
237204). We therefore assume that the specimens from Lee
Creek Mine are from the Pungo River Formation, which is fur-
ther supported by the preservation of the coracoid. The Calvert
material will be described in detail elsewhere.
242
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Gavia howardae Brodkorb, 1953c
PLATE ia,c,d,fhJ,l,m,o,q
MATERIAL.—Right coracoids, USNM 244209, 321271;
complete left coracoids, USNM 192845, 366413; right cora-
coid lacking part of both ends, USNM 446482; left coracoid
lacking part of both ends, USNM 430515; scapular end of right
coracoid, USNM 257461; medial portion of left coracoid,
USNM 302363. Anterior end of right scapula, USNM 430472.
Left humerus, USNM 206448; proximal end of left humerus,
USNM 446473; distal ends of right humeri, USNM 206347,
242363, 257480, 430508, 430510-430512, 446474,446475;
distal ends of left humeri, USNM 215850, 257465, 366664,
446478. Proximal end of right ulna, USNM 215436; proximal
ends of left ulnae, USNM 252348, 446471; distal ends of right
ulnae, USNM 215473, 215629, 430500; distal ends of left ul-
nae, USNM 193204,430494. Distal end of right radius, USNM
177820. Right carpometacarpus missing alular and minor
metacarpals, USNM 460766; proximal portions of left car-
pometacarpi, USNM 177783, 366702, 460767; distal end of
left carpometacarpus, USNM 192449. Right femora, USNM
215426, 367161, 446480; right femur lacking distal end,
USNM 248590; distal end of left femur, USNM 250681. Distal
end of right tibiotarsus, USNM 192676. Left tarsometatarsus
lacking most of both ends, USNM 430520; proximal end of
right tarsometatarsus, USNM 446481; proximal ends of left
tarsometatarsi, USNM 193274, 430522; distal ends of right tar-
sometatarsi, USNM 183423, 183431, 366565, 460768; distal
ends of left tarsometatarsi, USNM 177879, 193059.
Horizon.—Yorktown Formation.
Additional Material Examined.—San Diego Forma-
tion, California: Right humerus, SDSNH 42762; right hu-
merus lacking most of proximal end, SDSNH 42776; left hu-
merus, SDSNH 42763; fragmented left humerus, SDSNH
42781. Distal half of right ulna, SDSNH 35252. Left radius,
SDSNH 42778. Left carpometacarpus, SDSNH 42774; proxi-
mal end of right carpometacarpus, SDSNH 42768. Right femo-
ra, SDSNH 42764, 42775; left femur, SDSNH 42779. Right ti-
biotarsus, SDSNH 42765; left tibiotarsus, SDSNH 42772;
distal end of left tibiotarsus, SDSNH 42773. Proximal half of
right tarsometatarsus, SDSNH 35251.
Measurements.—See Table 1.
Remarks.—Gavia howardae was first described from the
late Pliocene (Blancan) San Diego Formation of California
(Brodkorb, 1953c). Chandler (1990a) referred a subsequent
specimen from the same deposits to this species, and numerous
additional specimens, which we examined (see list above),
have since been found there. As in the Red-throated Loon, G.
stellata (Pontoppidan), the bones of G. howardae are slim rela-
tive to those of the Arctic Loon, G. arctica, or the Pacific Loon,
G. pacifica, and many of them are shorter than those of G. stel-
lata (Table 1). Characters given for G howardae by Chandler
(1990a) were used to identify the Lee Creek Mine specimens,
and other elements were referred to this species mainly on their
small size and gracile proportions. The small size of G.
howardae suggests a relationship to G. stellata, the smallest
modern loon, and this also is supported by small fossil cora-
coids from Lee Creek Mine. These agree with G. stellata in
having only an incisura on the medial edge of the coracoid,
whereas in most individuals of all other modern and fossil
loons (in which the coracoid is known), there is a distinct,
closed procoracoid foramen.
Gavia moldavica Kessler (1984) was described from por-
tions of all the major wing elements from the early late Mi-
ocene (Middle Sarmatian) of Kishinev (Chisinau), Moldavia.
The measurement given for the distal end of one of the paratyp-
ical humeri is 12.0 mm, which is within the range of G.
howardae (Table 1). The length of a paratypical radius of G.
moldavica was 87.6 mm, compared with 86.5 mm for a radius
of G howardae (SDSNH 42778). There is, however, a consid-
erable period of time between the probable age of G moldavica
(MN ?9 (=planktonic foraminifera zone N15) according to
Mlikovsky, 1996), the Yorktown Formation at Lee Creek Mine
(N19), and the even younger San Diego Formation (N21). Giv-
en that loons appear to have been increasing rapidly in size dur-
ing the last half of the Neogene, it is possible that G. moldavica
could have been ancestral to the larger Pliocene species G con-
cinna.
Gavia schultzi Mlikovsky (1998), from the middle Miocene
(upper Badenian) of Austria, is somewhat younger than the
Calvert/Pungo River formations and apparently falls within the
lower size range of G. howardae, being considerably larger
than any middle Miocene loon yet known from North America.
Gavia brodkorbi Howard (1978) is known from a complete
ulna from the early late Miocene (Clarendonian; N14-16) at
Laguna Niguel, California. This is shorter and more robust than
in G. howardae. The holotype of Gavia paradoxa Umanskaja
(1981) is the proximal portion of an ulna from the late Miocene
(MN 11-13 = ~N 16-17) of the Ukraine. The published dimen-
sions of G paradoxa suggest that it is very similar in size to G.
brodkorbi, from which it appears to differ in its long attach-
ment for the anterior articular ligament.
The relationship of these late Miocene loons to the tiny spe-
cies of the middle Miocene and the larger ones of the Pliocene
can only be determined with more and better material and di-
rect comparisons with the types.
Gavia howardae is very similar to the modern Red-throated
Loon, Gavia stellata, and is probably on a direct line with that
species. Although there is overlap in size (Table 1), the fossil
form on average is smaller, and some individuals were smaller
than any of the individuals in the modern sample. The main
qualitative difference noted was that the pectoral crest of the
humerus in G. howardae is not as long and low as it is in the
modern form.
NUMBER 90
243
Gavia concinna Wetmore, 1940
PLATE 2a,c,d,fg,i,k-n,p,r-t,v,x,y
Gavia concinna Wetmore, 1940:25.
Gaviapalaeodytes Wetmore, 1943a:64.
Gavia sp., Howard, 1982:3.
Material.—Because of the abundance of material of this
species from Lee Creek Mine, only the best-preserved speci-
mens and rarer elements are listed.
Right coracoid, USNM 430477; left coracoids, USNM
366592, 430476; scapular ends of left coracoids, USNM
192029, 192033, 192772. Anterior end of left scapula, USNM
192083. Proximal end of left humerus, USNM 430501; distal
ends of right humeri, USNM 367020, 430470, 446489,
460771; distal ends of left humeri, USNM 181037, 252360,
366642, 366894, 430460, 430503. Proximal ends of right ul-
nae, USNM 430457, 430458, 446470, 446485, 446491,
460770; proximal ends of left ulnae, USNM 430453, 446472;
distal ends of right ulnae, USNM 252340, 252377; distal ends
of left ulnae, USNM 430443, 430456, 446488, 460769. Proxi-
mal end of left radius, USNM 446484. Right carpometacarpus
missing minor metacarpal, USNM 430451; proximal ends of
right carpometacarpi, USNM 215873, 446483; proximal ends
of left carpometacarpi, USNM 367132, 430441. Proximal half
of fused synsacral vertebrae, USNM 460774. Right femora
lacking part of distal ends, USNM 183477, 430518, 446479;
left femora lacking part of distal ends, USNM 366000,460783.
Proximal end of left tibiotarsus, USNM 430519; distal ends of
right tibiotarsi, USNM 241388, 446490; distal ends of left ti-
biotarsi, USNM 215646, 430481, 430482. Right tarsometatar-
si, USNM 366714, 430485, 430486; left tarsometatarsus,
USNM 193359; proximal end of left tarsometatarsus, USNM
430446; distal ends of right tarsometatarsi, USNM 430490,
460773; distal end of left tarsometatarsus, USNM 460772.
Pedal phalanx, USNM 192543.
Horizon.—Yorktown Formation.
Additional Material Examined.—San Diego Forma-
tion, California: Left humeri, SDSNH 42761, 42763; distal
half of left humerus, SDSNH 42767. Right carpometacarpus
missing minor metacarpal, SDSNH 42769. Right major alar
digit phalanx 2, SDSNH 42771. Left femur, SDSNH 42777.
Right tarsometatarsi, SDSNH 22916, 42766; left tarsometatar-
si, SDSNH 42770,42780.
Bone Valley Formation, Florida: Right coracoids, UF PB
132, USNM 256375. Proximal half of right humerus, UF PB
306; distal thirds of right humeri, UF PB 88, 524, USNM
256376; distal halves of left humeri, UF PB 297, USNM
256395. Distal third of right ulna, UF PB 89. Right femora, UF
PB 133, USNM 256378; left femur, UF PB 298. Proximal half
of right tarsometatarsus, USNM 256374.
Horizon Uncertain: Distal end of left radius, USNM
460775, from Renny Creek, New Bern, Craven County, North
Carolina. Yorktown or equivalent deposits are exposed there,
but the specimen might be Pleistocene and is included herein
for purposes of illustration (Plate 2/).
Measurements.—See Table 1.
REMARKS.—Gavia concinna Wetmore (1940) was described
from the proximal end of an ulna from the Etchegoin Forma-
tion of Monterey County, California, which is late Hemphillian
in age (Becker, 1987) and thus is approximately contemporane-
ous with the Yorktown and Bone Valley formations. This spe-
cies was said to be intermediate in size between the modern
species G. stellata and the Common Loon, G. immer. It was not
stated how the fossil species could be discriminated from mod-
ern G. arctica or G. pacifica, however, which are in this inter-
mediate size range. Wetmore (1943a) then described Gavia
palaeodytes from an imperfect coracoid from the Bone Valley
Formation of Florida. He considered the coracoid to be smaller
than that of any then-known species of loon, living or fossil;
however, it is stout and has a heavily rimmed procoracoid fora-
men, unlike G. stellata or the Lee Creek material referred to G.
howardae. Brodkorb (1953c) referred additional material from
California to G. concinna, which he regarded as being most
similar to G. pacifica, although approaching G. immer in size.
He also referred material from Bone Valley to G. concinna,
which he considered to be a larger species than G. palaeodytes,
which in turn was said to be the size of G. stellata. Delle Cave
et al. (1984) described the skull of a loon from the Pliocene of
Italy and identified it as Gavia cf. concinna.
Chandler (1990a) dismissed all published records of the oc-
currence of Gavia concinna in the San Diego Formation as
misidentifications. At least seven specimens collected there in
1989 and 1990 (listed above), however, are best referred to this
species, being far too large to be G. howardae; none is so large
as definitely to pertain to the new species of Gavia described
herein (see below).
A worn tarsometatarsus from the San Mateo Formation (ear-
ly Hemphillian), in San Diego County, California, was referred
to by Howard (1982) only as "Gavia sp.," but its size and age
are compatible with G. concinna as defined herein, to which
we tentatively refer the specimen.
The material from Bone Valley, including part of that re-
ferred by Brodkorb (1953c) to G. concinna, appears to be a
composite, as it contains at least two specimens (proximal end
of humerus UF PB 593; distal end of humerus UF PB 90) that
are too large for that species and that we refer to the new spe-
cies of Gavia described below. We regard all of Brodkorb's
(1953c) material of G. palaeodytes as belonging to G. concin-
na. Although there is considerable size variation shown in this
series, with some specimens being quite small, none of the ma-
terial we have yet seen from Bone Valley can convincingly be
referred to G. howardae. Therefore, we regard the great major-
ity of specimens of loons from Bone Valley, including the ho-
lotype of G palaeodytes Wetmore (1943a), to be referable to
G. concinna Wetmore (1940).
Emslie (1998) referred to G. concinna the distal end of a tar-
sometatarsus from the earliest Pleistocene of Florida, where it
was contemporaneous with G. pacifica. Otherwise, G. concin-
na would presumably be part of the lineage that includes G.
arctica and G. pacifica, which have often in the past been con-
244
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
sidered conspecific. The fossils differ very little from the mod-
ern forms. A much more detailed analysis would be required to
determine whether the split between G. arctica and G. pacifica
took place before or after the early Pliocene, if indeed such a
determination can be made osteologically.
Gavia fortis, new species
FIGURES 5, 6; PLATES 3a.c,e,g-i,k,l,n, 4a-c,e,fh.j.l,n,p,q,s.u,v,x,z
Holotype.—Associated partial skeleton consisting of a por-
tion of shaft of right humerus, distal end of left humerus, prox-
imal ends of right and left radii and ulnae, proximal end of
right carpometacarpus, synsacrum, fragment of left innominate
with most of the acetabulum, distal end of right tibiotarsus,
complete right tarsometatarsus, pedal phalanx, and various
small fragments of bone, USNM 252432.
Type Locality.—Texasgulf Inc. Lee Creek Mine, south
side of Pamlico River, near Aurora, Beaufort County, North
Carolina (35°23'22"N, 76°47'06"W).
Horizon and Age.—As determined from foraminifera and
sedimentary characters of matrix, the holotype is from the low-
er to middle part of the Yorktown Formation, lower Pliocene.
Paratype USNM 179222 is from the basal Yorktown, and
paratype USNM 178148 is from the lower to middle part of the
Yorktown Formation. Other paratypes are assumed to be of the
same age.
Distribution.—Known from the type locality and from the
Bone Valley Formation in central Florida.
Measurements of Holotype (mm).—Humerus. Distal
width, 17.5.
Ulna:    Proximal width, 13.0; proximal diagonal, 13.1.
Radius:    Proximal width, 7.4
Carpometacarpus:    Proximal depth, 16.0.
Tibiotarsus:    Distal width, 13.9; distal diagonal, 13.1.
Tarsometatarsus:    Length, 77.5; proximal width, 14.1; dis-
tal width, 11.0.
TOPOTYPICAL PARATYPES.—Associated Specimen: Partial
skeleton consisting of vertebral fragments, proximal end of left
radius and ulna, left femur, proximal and distal ends of left ti-
biotarsus, left tarsometatarsus, and pedal phalanx, USNM
302392.
Individual Elements: Cervical vertebra, USNM 460782.
Left coracoid, USNM 215562; scapular ends of right cora-
coids, USNM 215463, 215502; scapular ends of left coracoids,
USNM 206368, 206432, 210452. Anterior end of right scapula,
USNM 206587. Left humerus lacking most of proximal end,
USNM 206625; proximal ends of right humeri, USNM
244212, 460778, 460779; proximal ends of left humeri, USNM
215840, 366588; distal ends of right humeri, USNM 178149,
192848, 192981, 193009, 252370, 252372,460780; distal ends
of left humeri, USNM 177742, 192450, 192771, 193230,
242173, 252353. Right ulna, USNM 250778; proximal end of
right ulna, USNM 367044; proximal ends of left ulnae, USNM
206450, 215753; distal end of right ulna, USNM 366414; distal
ends of left ulnae, USNM 178148,460777. Left radius, USNM
192060/192065 (two pieces fitting together); proximal end of
right radius, USNM 460795; distal end of right radius, USNM
215749; distal end of left radius, USNM 430444. Right car-
pometacarpus lacking proximal end, USNM 460776; proximal
end of right carpometacarpus, USNM 430442; proximal ends
of left carpometacarpi, USNM 244210, 430440. Right femora,
USNM 183459, 206348, 275779, 367062,482593; left femora,
USNM 177912, 179222, 250713, 257491, 275842, 460781;
right femur lacking proximal end, USNM 308212; left femur
lacking distal end, USNM 366681. Proximal end of right tibio-
tarsus, USNM 256254; distal ends of right tibiotarsi, USNM
178057, 430483; distal end of left tibiotarsus, USNM 206593.
Right tarsometatarsus, USNM 206629; proximal ends of right
tarsometatarsi, USNM 183492, 206533, 308193; proximal
ends of left tarsometatarsi, USNM 215570, 242340, 308204,
366559, 446492, 482592; distal ends of right tarsometatarsi,
USNM 206302, 257501, 430449, 430450; distal ends of left
tarsometatarsi, USNM 192880, 215772, 250753, 430447,
430448, 446493. Pedal phalanx, USNM 236812.
Additional Paratypes.—Bone Valley Formation,
Florida: Proximal third of right humerus, UF PB 593; distal
third of left humerus, UF PB 90.
Measurements of Paratypes.—See Table 1.
Etymology.—Latin fortis, strong, powerful; from the ro-
bustness of the bones in comparison to the Common Loon,
Gavia immer.
Diagnosis.—Larger than any living or fossil species of
Gavia except G. immer and the Yellow-billed Loon, G. adam-
sii. Smaller than all but the smallest individuals of G. immer,
but all skeletal elements markedly more robust. Differs from
G. immer in having the sacrum in lateral view more curved
ventrally.
Remarks.—This common species at Lee Creek Mine is
larger than any of the known fossil forms of Gavia but is simi-
lar in overall size to the modern G. immer-G. adamsii super-
species. Gavia fortis is similar to G. immer and differs from G.
concinna and G. arctica in that the ectepicondylar prominence
of the humerus is more laterally produced, and the attachment
for the anterior articular ligament is longer; the distal end of the
ulna is much expanded, especially the palmar edge of the shaft
immediately proximal to the articular surface, the base of the
internal cotyla is rounded and heavy, the internal-palmar edge
of the shaft is less ridge-like, and the internal cotyla and inter-
nal condyle are more produced palmarly; the distal end of the
radius is more expanded; there is a larger spur on the posterior
edges of the external and internal condyles of the tibiotarsus,
the distal intercondylar sulcus is wider, and the entire distal end
is more expanded; and the distal foramen of the tarsometatar-
sus is proportionately larger in posterior view, and the inter-
trochlear notch between trochleae III and IV is narrower.
Regalia (1902) described a large species of loon, Gavia por-
tisi, based on a broken tenth or eleventh cervical vertebra from
the Pliocene of Italy (middle Pliocene at Orciano Pisano near
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246
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Val di Fine). From the illustrations it appears that the specimen
was correctly identified as a loon. Although Brodkorb (1953c)
stated that this came from a species the size of modern G. im-
mer, the measurements seem to indicate a smaller species
(Delle Cave et al., 1984), but the holotype can no longer be
found (Delle Cave et al., 1984; Delle Cave, 1996). Although
Colymbus portisi Regalia is the earliest name applied to any
Pliocene loon and almost certainly pertains to one of the
younger epithets we have used in this paper, the application of
the name can seemingly no longer be determined. Thus, we re-
gard Colymbus portisi Regalia as a nomen dubium and we have
not used it. There appear to be no records of Gavia immer earli-
er than the late Pleistocene (Emslie, 1998).
Differences in proportions between the modern and fossil
loons were confirmed by a bootstrapped principal components
(PC) analysis of 12 variables (listed in Table 2) for Gavia im-
mer (n= 13), G. pacifica (n= 10), and G. fortis (n=2 associated
partial skeletons) using a covariance matrix of logi0-trans-
formed data (Figure 5). By far the greatest amount of variation
(89%) was explained by PC-I, on which all variables loaded
highly and positively, as is typical for a general-size axis (Ta-
ble 2). All T statistics (resampled eigenvectors divided by
their standard errors) for PC-I were greater than T value
(|T|)=5, which can be considered the level above which T sta-
tistics are significant (Marcus, 1990), although tarsometatar-
sus-shaft width had a much smaller |T| than did any other vari-
able (Table 2). Gavia fortis is similar on factor I, and thus in
overall size, to small G. immer and large G. pacifica. The only
length measure available for both of the associated skeletons
of G. fortis, however, was tarsometatarsus length, which was
shorter than that of G. immer; elements from other specimens
of G. fortis are shorter than similarly stout elements of G im-
mer (Table 1). On PC-II, tarsometatarsus-shaft width was by
far the most important variable (Figure 6), with a |T| >2 (Table
2), contrasted with the less important ulna-shaft width. On PC-
III, which remained the third axis after 500 bootstrap itera-
tions, tibiotarsus distal depth and tarsometatarsus length (Fig-
ure 6) were the most important variables, based on their T val-
ues (Table 2). On factors II and III, G. immer and G. pacifica
overlap widely (Figure 5), whereas G. fortis differs from both
extant species in having a combination of a relatively short,
heavy tarsometatarsus (scores low on PC-III and high on PC-
II), and a relatively thin ulnar shaft immediately distal to the
external condyle (scores high on PC-II). In proportions, the
u
q-
0.75-
0.50-
0.25-
0.00-
-0.25-
-0.50-
-0.75-
64
C
0

heavy ulna
heavy tarsometatarsus
i       i      i      i       i--------1--------r
-0.75      -0.50      -0.25       0.00       0.25       0.50       0.75
PC-II
Figure 5.—Scatter plot of individual factor scores from principal components analysis of loons Gavia immer (I),
G. pacifica (P), and associated specimens of G fortis, new species (F).
NUMBER 90
247
two associated specimens available of G. fortis differ more
from these two recent species than they differ from one anoth-
er. In fact, the principal components analysis underrepresents
the distinctness of G. fortis because of the scarcity of usable
length measures for this species.
PC-II
1.0
Tarsometatarsus
_ _    shaft width
PC-I
-l.ol-
a
PC-I
-11.0
_ J Ulna shaft width
1
-1.0
PC-II
PC-III
1.0
Tarsometatarsus
length
I Tibiotarsus
1 distal depth
PC-II
-1.0|-
+—T
I Ulna shaft width
PC-II
-11.0
Tarsometatarsus
distal breadth
Tarsometatarsus
shaft width
-1.0
PC-III
Figure 6.—Component loadings for principal components analyses of loons
Gavia immer, G. pacifica, and G. fortis, new species: a, factors I and II; b, fac-
tors II and III.
TABLE 2.—Summary of results (T statistics, eigenvalues, and percent of vari-
ance explained) for factors I—III of a bootstrapped principal components analy-
sis of 12 skeletal variables for loons Gavia immer, G pacifica, and G. fortis,
new species.
Variable	T statistics		
	PC-I	PC-II	PC-III
Ulna proximal width	19.76	-1.34	-0.15
Ulna shaft width (immediately distal to base of external condyle)	10.41	-1.60	-0.51
Ulna proximal diagonal	21.87	-0.79	-0.19
Tibiotarsus distal width	19.68	0.71	0.95
Tibiotarsus distal depth	19.37	0.06	1.76
Tibiotarsus condyle height	14.28	-0.33	-0.36
Radius proximal width	24.90	0.16	0.52
Tarsometatarsus length	14.90	0.03	1.46
Tarsometatarsus proximal width	21.84	0.41	0.89
Tarsometatarsus distal width	13.80	0.25	-0.67
Tarsometatarsus distal depth	20.74	0.85	-0.27
Tarsometatarsus shaft width	7.82	2.04	-0.58
Eigenvalues	0.0296	0.0009	0.0007
Percent of variance explained	89.26	2.9	2.2
Discussion of Gaviidae
Although modern loons breed in the boreal zone and are en-
tirely confined to the Northern Hemisphere, even in winter, the
fossil record shows that the family once occurred, and perhaps
even originated, in the Southern Hemisphere. Once thought to
belong to the Mesozoic toothed divers of the order Hesperomi-
thiformes, Neogaeornis wetzeli Lambrecht (1929), from the
Late Cretaceous of Chile, has been shown to belong to the
Gaviidae (Olson, 1992). Another Late Cretaceous fossil, from
Seymour Island, Antarctica, also is referable to the Gaviidae
(Chatterjee, 1989) and possibly to Neogaeornis.
The published fossil record of loons resumes with Colym-
boides anglicus Lydekker (1891a), from the late Eocene of En-
gland (Lydekker, 1891a; Harrison and Walker, 1976). The ge-
nus Colymboides comprises two species that differ
considerably from Gavia in many aspects of their osteology
(Storer, 1956; Cheneval, 1984), and they are believed to repre-
sent a separate lineage (Storer, 1956). The type of the genus is
C. minutus Milne-Edwards (1867), a tiny species described
from the rich early Miocene (Aquitanian) deposits at St.-
Gerand-le-Puy, France. Colymboides minutus also has been
identified from the early Miocene of the Dolnice basin in the
Czech Republic, where it occurs together with a small species
of Gavia (Svec, 1980, 1982), and from the early Miocene
Faluns de Saucats in France (Cheneval, 1984). The two speci-
mens from Lee Creek Mine referred to Colymboides sp. and
presumed to be from the Pungo River Formation thus probably
represent the latest occurrence of the genus.
The genus Gavia, as represented by G. egeriana Svec
(1982), was first known from the early Miocene of the Czech
Republic. This was a very small species, which we also have
identified from the Calvert and Pungo River formations. The
Calvert material differs considerably, in characters that are
248
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
doubtless primitive, from modern species of Gavia. Contempo-
raneous with G. egeriana in the Calvert Formation is a second,
somewhat smaller, undescribed species. Both of these middle
Miocene species are much smaller than any known later spe-
cies of Gavia.
Loons intermediate in age between the early middle Miocene
and the early Pliocene are known from several localities in Eu-
rope and are briefly discussed above. Abundant material of Ga-
via from the early Pliocene Yorktown Formation clearly en-
compasses at least three species, which differ in size. These are
all much larger than any loons of the Calvert Formation or de-
posits of equivalent or earlier age, and they may represent the
three modern lineages, consisting of G. stellata, G. arctica/
pacifica, and G. immer/adamsii.
The three extant species-groups of loons are essentially Hol-
arctic in distribution, breeding on fresh water at much higher
latitudes than North Carolina but wintering almost entirely at
sea. All forms except G. stellata have such high wing loadings
that their flight would presumably be impaired by any loss of
remiges during molt. Because of the necessity of leaving their
breeding grounds before the waters freeze, adults do not molt
until they reach their wintering grounds at sea, where they molt
the remiges simultaneously and undergo a flightless period
(Woolfenden, 1967).
Gavia fortis, certainly, and G. concinna, probably, were al-
ready sufficiently large by the early Pliocene as to have neces-
sitated this pattern of molt of the flight feathers, and it seems
reasonable to assume that all loons from the Yorktown Forma-
tion at Lee Creek Mine were individuals on their wintering
grounds. Thus, the basic pattern of loons wintering at sea had
evidently already evolved by the early Pliocene.
If the three species identified at Lee Creek Mine are really
the predecessors of the three modern species groups, then
there have been some interesting changes in the wintering dis-
tributions of the lineages. Gavia stellata is "a common mi-
grant and regular winter resident" off North Carolina (Lee,
1995:119), although it is much scarcer farther south in Geor-
gia and Florida. Gavia immer is the common wintering loon
in eastern North America today, being abundant in Florida,
yet what we have identified as G. fortis is very rare in the
Bone Valley deposits. Gavia concinna is by far the most com-
mon loon in the Bone Valley deposits and is at least as abun-
dantly represented at Lee Creek Mine as is either of the other
two species. If this represents the G. arctica/pacifica lineage,
then its status has changed dramatically since the Pliocene be-
cause G. pacifica is only a casual visitor to the western North
Atlantic, where it does not regularly winter. For North Caroli-
na there are only a few sight reports and one specimen found
just north of the North Carolina/Virginia border (Lee,
1995:119).
Order PODICIPEDIFORMES
(grebes)
Family Podicipedidae
(grebes)
Genus Podiceps Latham
Pliodytes Brodkorb, 1953d:953.
Podiceps aff. auritus (Linnaeus)
PLATE 5a-g
"Fulica sp. (Pisana Nob.)" Portis, 1888:195.
"Fulica sp. (pisana Portis)" Portis, 1891:13.
Podicepespisanus (Portis).—Regalia, 1902:233.
Podiceps pisanus (Portis).—Lambrecht, 1933:262.
Pliodytes lanquisti Brodkorb, 1953d:953.
Podiceps howardae Storer, p. 227, this volume.
Material.—Right coracoid, USNM 177927. Right humer-
us, USNM 243764; proximal three-fourths of right humerus,
USNM 183430; distal ends of right humeri, USNM 193242,
215034, 407798; distal ends of left humeri, USNM 368557,
430524. Right femora, USNM 215453, 215649, 252314,
460785; left femur, USNM 177918; proximal ends of left fem-
ora, USNM 178151, 206413. Proximal ends of right tarsometa-
tarsi, USNM 193175, 250773; distal end of right tarsometatar-
sus, USNM 206326, distal end of left tarsometatarsus, USNM
210531.
Horizon.—Yorktown Formation inferred from identity with
specimens in Bone Valley Formation and similarity to modern
species.
Additional Material Examined.—Bone Valley Forma-
tion, Florida: Proximal half of right humerus, USNM
447059.
Measurements.—See Storer (p. 227, this volume).
Remarks.—Grebes are uncommon among the Lee Creek
Mine fossils, almost all of the few specimens appearing to be
from a single species that was very similar in size and other
characters to the modern Horned Grebe, Podiceps auritus,
which is the common species of grebe wintering at sea in North
Carolina today.
We compared the appropriate specimens from Lee Creek
Mine with a cast of the holotype of Podiceps pisanus (Portis,
1888, original in the Museo di Geologia e Paleontologia
dell'Universita di Firenze, Italy), which was described from the
distal end of a humerus from the Pliocene of Italy, and we
could detect no meaningful differences. The species originally
was described by Portis (1888) as a coot (Fulica, Rallidae) and
at that point was almost a nomen nudum. It was well described
and figured by Portis, still as a coot, in a subsequent publica-
tion (Portis, 1891). Brodkorb (1963:227) cited the latter as the
original description, with the date 1889, but the Zoological
Record (1892, volume 28:21) lists the publication for 1891.
The supposed extinct genus and species Pliodytes lanquisti
Brodkorb (1953d), based on a coracoid from the Bone Valley
NUMBER 90
249
Formation in Florida, is in this size range. The length of a cora-
coid from Lee Creek Mine (USNM 177927) is exactly the
same as that given for the holotype of Pliodytes lanquisti and
falls within the range of Podiceps auritus, from which it shows
no significant differences. The proximal end of a humerus from
Bone Valley (USNM 447059), which presumably is from the
same species of grebe as represented by the holotype of
Pliodytes lanquisti, is indistinguishable from comparable ele-
ments from Lee Creek Mine, and these in turn are identical to
Podiceps auritus. Storer (this volume), although recognizing
the affinities of the Lee Creek grebe with P. auritus, according
to long-accepted practice has emphasized slight differences
and has named it as a new species, Podiceps howardae. In ac-
cordance with the philosophy outlined in our introduction, we
emphasize its similarities to P. auritus.
Podiceps sociatus (Navas, 1922), a fossil species of grebe
also the size of P. auritus, is known from as far back as the
middle Miocene of Spain, although it was more primitive in
some respects than the modern species (Olson, 1995).
The Horned Grebe is circumpolar in distribution and is one
of the commoner grebes in the Northern Hemisphere, especial-
ly in marine environments, so it would not be surprising if its
antecedents occurred in the same situations in the Pliocene.
Podicipedidae, genus and species indeterminate
Material.—Left tarsometatarsus lacking distal end and
with proximal end badly damaged, USNM 501509.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Estimated length, 36.8.
Remarks.—This poorly preserved specimen comes from a
grebe considerably smaller than Podiceps aff. auritus (above).
The tarsometatarsus is relatively shorter and more robust than
it is in the Eared Grebe, Podiceps nigricollis Brehm, and per-
haps comes from a grebe with less specialized tarsal morpholo-
gy, such as the species of Tachybaptus Reichenbach (see
Olson, 1995).
Order PROCELLARHFORMES
(tubenoses)
Two of the four families of this order, Diomedeidae and Pro-
cellariidae, are abundantly represented at Lee Creek Mine. The
diving-petrels (Pelecanoididae) are known only from the
Southern Hemisphere and would not be expected, whereas the
absence of storm-petrels (Oceanitidae=Hydrobatidae auct.) is
almost certainly an artifact of collection and taphonomy. Al-
though storm-petrels are common in the same area today and
would doubtless have been so in the Pliocene, they are the
smallest members of the order and feed entirely from the sur-
face of the water; thus, they would be less likely to fall prey to
submarine predators. This is probably the main factor contrib-
uting to their absence at Lee Creek Mine, although the small
size of their bones also would make them less likely to be spot-
ted by collectors. The only Tertiary locality where fossils of
storm-petrels have been found in numbers is a coastal site in
South Africa thought to be in the immediate vicinity of insular
breeding colonies (Olson, 1985b), whereas in nearby pelagic
deposits storm-petrels were all but absent (Olson, 1985c).
Family DIOMEDEIDAE
(albatrosses)
Albatrosses now occur largely in the southern oceans, with
only three modern species found in the North Pacific and none
found in the North Atlantic, except as very rare vagrants. Thus,
it is of considerable interest that over 500 specimens represent-
ing five species of albatross have been recovered from Lee
Creek Mine. The only albatross known from the Calvert For-
mation is a rare, very small species, even smaller than the
smallest one known from Lee Creek Mine. Because of this and
the similarity of the Lee Creek birds to modern species, and as
indicated by microfossil analysis of the matrix associated with
some of the fossils, all of the Lee Creek albatross material is re-
garded as being from the Yorktown Formation.
In attempting to identify the Lee Creek fossils and in making
comparisons with modern taxa, we found that all the North Pa-
cific albatrosses (Short-tailed Albatross, Phoebastria albatrus
(Pallas); Black-footed Albatross, P. nigripes (Audubon); Lay-
san Albatross, P. immutabilis (Rothschild)) differ from all the
smaller Southern Hemisphere albatrosses (mollymawks,
Thalassarche Reichenbach; sooty albatrosses, Phoebastria Re-
ichenbach) in having the tarsometatarsus proportionately long-
er and more slender (Plate 8). In this respect the North Pacific
albatrosses were more similar to the "great" albatross group,
which consists of the Wandering Albatross, Diomedea exulans
Linnaeus; Amsterdam Albatross, D. amsterdamensis Roux et
al.; and Royal Albatross, D. epomophora Lesson, than to the
mollymawks or the sooty albatrosses.
These osteological observations have been corroborated by
DNA sequences in which four major groups of albatrosses
were recognized (Nunn et al., 1996): the North Pacific species
just mentioned (plus the Waved Albatross, D. leptorhyncha
Coues (=D. irrorata Salvin auct.)), which take the name Phoe-
bastria; the great albatrosses, genus Diomedea Linnaeus,
which forms the sister group of Phoebastria; the mollymawks,
genus Thalassarche; and the sister-group of the latter genus,
Phoebastria. We have followed this classification herein.
Genus Phoebastria Reichenbach
Phoebastria anglica (Lydekker, 1891a), new combination
Plates da, 7e,g,i,l
Diomedea anglica Lydekker, 1891 a: 189.
IDiomedea californica L. Miller, 1962:471.
Diomedea sp. A, Chandler, 1990a: 100.
Material.—Fragment of ramus of furcula, USNM 206434.
Proximal ends of right scapulae, USNM 192688, 430529,
250
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
464253. Proximal end of right humerus, USNM 242324; distal
end of right humerus, USNM 366454; distal end of left humer-
us, USNM 183511. Proximal end of left ulna, USNM 430602;
distal ends of right ulnae, USNM 193160, 252321; distal end of
left ulna, USNM 430528. Associated(?) distal ends of left ulna
and radius, USNM 215748, 215751. Proximal ends of right
carpometacarpi, USNM 193170, 321242, 366628; proximal
end of left carpometacarpus, USNM 430590; distal ends of
right carpometacarpi, USNM 302354, 366922, 464254. Major
alar digit phalanx 1, USNM 430526. Left femur, USNM
210458; proximal end of right femur, USNM 368546; distal
ends of right femora, USNM 181085, 308201, 366689,
366906, 430530; distal ends of left femora, USNM 464255,
464256. Distal ends of right tibiotarsi, USNM 206486, 206638,
241429, 248495, 464257; distal ends of left tibiotarsi, USNM
181045, 248533, 321230, 430531, 430532, 464258. Right tar-
sometatarsi, USNM 250732, 430538; left tarsometatarsi,
USNM 250777, 430533; proximal ends of left tarsometatarsi
USNM 250739, 366627, 368543, 430622, 464259, 464260;
shafts of right tarsometatarsi, USNM 192809, 215478, 241431;
shaft of left tarsometatarsus, USNM 256257; distal ends of
right tarsometatarsi, USNM 193142, 257457, 366716, 430539,
464261-464263; distal ends of left tarsometatarsi, USNM
215884, 250743, 250758, 252303, 256250, 275850, 321236,
430534, 430535, 430537, 430619, 464264, 464265. Pedal pha-
langes, USNM 192469, 257482, 366380, 464266-464274.
Horizon.—Yorktown Formation (USNM 181085 from bas-
al Yorktown as determined from foraminifera in matrix).
Additional Material Examined.—Red Crag Formation,
England: Right tarsometatarsus, USNM 215038 (cast of ho-
lotype).
Coralline Crag Formation, England: Proximal two-thirds
of right ulna, USNM 215040 (cast of paratype).
Bone Valley Formation, Florida: Distal end of left ulna,
UF 123829. Right carpometacarpus, UF 65765. Distal end of
right tibiotarsus (cast), USNM 16751. Left tarsometatarsus, UF
53942; distal end of left tarsometatarsus, UF 57309.
San Diego Formation, California:    Right tarsometatarsus,
SDSNH 27872.
Measurements.—See Table 3.
REMARKS.—Diomedea anglica was originally described by
Lydekker (1891a) from an associated tarsometatarsus and pha-
lanx 1, supposedly of pedal digit IV, from the late Pliocene Red
Crag at Foxhall, Suffolk, England. The phalanx, however, is
actually that of digit II, the phalanx for digit IV in albatrosses
being proportionately much longer and more slender. The
proximal end of an ulna from the underlying Coralline Crag in
the same vicinity (Lydekker, 189lb:395) was soon after con-
sidered to belong to the same species. Both these records are
now considered to be late Pliocene (MN 16-17) in age (Mlik-
ovsky, 1996:766). Later, Wetmore (1943a) referred the distal
end of a tibiotarsus from Bone Valley, Florida, to D. anglica.
Lydekker (1891a) characterized the tarsometatarsus of Di-
omedea anglica as being somewhat smaller and proportionate-
ly more slender than that of D. exulans. Harrison and Walker
(1978) concluded that D. anglica was a valid species that
seemed most similar to D. albatrus but was larger. An albatross
the size of D. anglica is one of the two most common albatross
species at Lee Creek Mine. We examined additional material
from the Bone Valley Formation in Florida that falls in the
same size class, as well as a specimen from the San Diego For-
mation in California first reported by Chandler (1990a: 100) as
an unidentified species of Diomedea. We refer all of this mate-
rial to Lydekker's species Diomedea anglica, but under the ge-
nus Phoebastria, as explained below.
The species known as Diomedea californica L. Miller, 1962,
may be the Miocene representative of this same lineage. It was
originally described from the distal end of a tarsometatarsus
from the middle Miocene of Sharktooth Hill (Miller, 1962),
with the distal end of a humerus and another tarsometatarsus
from the same locality being referred later (Howard, 1966,
1978). A tibiotarsus from the late Miocene at Laguna Niguel,
Orange County, also was referred, with a query, to D. californi-
ca (Howard, 1978). The distal width of the holotypical tar-
sometatarsus was 20.6 mm, and that of the referred specimen
was about 21.5 mm (as extrapolated from the percentages giv-
en by Howard, 1978), which is within or very near the range
for the series of tarsometatarsi from Lee Creek Mine assigned
to Phoebastria anglica (18.7-21.2 mm, «=21). The humerus
referred to D. californica had a distal width of 27.5 mm, which
compares very well with three assigned to P anglica from Lee
Creek Mine (27.3, 28.5, 30.2 mm).
There are few living albatrosses the size of Phoebastria an-
glica, which was larger than all known species except the great
albatrosses. The largest living species are the Wandering and
Royal albatrosses (Diomedea exulans and D. epomophora).
Based on specimens available to us, these have larger and
much more robust tarsometatarsi than does P. anglica (Table
3). Our series of both modern species, however, was quite inad-
equate because there are several recognized subspecies in this
complex, some of which differ in size, so there may be more
overlap than was apparent in our comparisons.
Another enigmatic member of the great albatross group is the
Amsterdam Albatross, Diomedea amsterdamensis (Plates 6b,
Ifh.m), known from a small remnant population on Amster-
dam Island in the southern Indian Ocean. This was named as
recently as 1983 (Roux et al., 1983), and although photographs
of living specimens were published with the original "descrip-
tion," the so-called "holotype" was evidently a composite as-
sortment of subfossil bones, perhaps belonging to several dif-
ferent individuals. It was not stated what elements of the
skeleton were included in the "holotype," nor were any mea-
surements or comparisons made of these bones, the character-
ization of the species thus being utterly inadequate. The taxon
is sometimes considered to be a subspecies of D. exulans (e.g.,
Warham, 1990:424).
We were able to examine a small composite assortment of
bones of Diomedea amsterdamensis (USNM 560597), which
NUMBER 90
251
shows this species to be smaller than any of the available spec-
imens of D. exulans, although it is about the size of the fossils
we have referred to Phoebastria anglica (Table 3). Although P.
anglica possibly falls within the lower size ranges of the great
albatrosses of the restricted genus Diomedea, there is no other
indication of now-exclusively Southern Hemisphere albatross-
es in the Northern Hemisphere. Thus, it appears much more
likely that anglica is a very large member of the Northern
Hemisphere albatrosses of the genus Phoebastria, to which we
refer it. As such, it may be regarded as an extinct lineage with
no living descendents.
Phoebastria aff. albatrus (Pallas)
Plates 6f,k, 7a,j, Sa
Diomedea howardae Chandler, 1990a:96.
Material.—Portion of ramus of furcula, USNM 430609.
Fragment of shaft of right coracoid, USNM 206548. Anterior
end of right scapula, USNM 193298. Proximal end of left hu-
merus, USNM 460858; distal ends of right humeri, USNM
242347, 256249, 430607; distal end of left humerus, USNM
430606. Proximal ends of left ulnae, USNM 179230, 181039;
distal ends of right ulnae, USNM 430598, 430599, 430601;
distal ends of left ulnae, USNM 206623, 430603, 430605.
Proximal ends of left radii, USNM 181068, 250825; distal ends
of right radii, USNM 193149, 241368; distal ends of left radii,
USNM 215563, 244300, 464290. Left carpometacarpus lack-
ing minor metacarpal, USNM 430588; proximal ends of right
carpometacarpi, USNM 192023, 206499, 256211, 275854,
430593; proximal end of left carpometacarpus, USNM 430589;
distal end of right carpometacarpus, USNM 193319; distal end
of left carpometacarpus, USNM 430591. Major alar digit pha-
lanx 1, USNM 193378. Left femur, USNM 192945; distal ends
of left femora, USNM 177921, 366925, 430610. Proximal end
of right tibiotarsus, USNM 308215; distal ends of right tibio-
tarsi, USNM 241361, 308249; distal ends of left tibiotarsi,
USNM 275849, 430614, 430616. Right tarsometatarsi, USNM
193223, 275847, 430629; left tarsometatarsi, USNM 181095,
430618; proximal end of right tarsometatarsus, USNM 368545;
proximal end of left tarsometatarsus, USNM 178191; distal end
of right tarsometatarsus, USNM 464245; distal ends of left tar-
sometatarsi, USNM 192858, 192876,430626. Pedal phalanges,
USNM 464275^164280.
Horizon.—Yorktown Formation.
Additional Material Examined.—Bone Valley Forma-
tion, Florida: Distal end of right ulna, UF 53915. Left tar-
sometatarsus, UF 94549.
San Diego Formation, California: Distal half of left car-
pometacarpus, SDSNH 25244. Right major alar digit phalanx
1, SDSNH 25243. Right tarsometatarsus, SDSNH 25245 (holo-
type of Diomedea howardae).
Measurements.—See Table 3.
Remarks.—The Short-tailed Albatross, Phoebastria al-
batrus (Plates 6l-o, lb), was probably the common inshore al-
Table 3.—Length (mm) of the tarsometatarsus in large living and fossil alba-
trosses Diomedea and Phoebastria. (n=number of specimens.)
Species	n	Range	Mean
D. epomophora D. exulans subsp. D. amsterdamensis	2 5 2	125.0-128.1 113.2-125.8 106.9-111.6	126.5 121.3 109.2
P. anglica (holotype) P. anglica, Lee Creek Mine	1 4	110.3—117+	110.9 113.5
P. anglica, Bone Valley P. anglica, San Diego Formation P. albatrus	I 1 25	89.5-104.0	118.5 112.8 98.4
P. aff. albatrus, Lee Creek Mine P. aff. albatrus, Bone Valley P. albatrus, San Diego formation (holotype of D. howardae)	5 1 1	97.7-103+	100.9 105.2 101.7
batross in the North Pacific in pre-human times. Hunting and
fishing cultures around the northern Pacific rim took a heavy
toll on the species, at least on the wintering grounds. In the
nineteenth and twentieth centuries the combination of Japanese
feather hunters and volcanic eruptions nearly exterminated the
species from its remaining breeding grounds in the Volcano Is-
lands, south of Japan, and the population of this species is still
perilously low but has been increasing.
The commonest albatross at Lee Creek Mine is similar to P.
albatrus in size, being larger than any of the Northern Hemi-
sphere species except P. anglica. We have identified speci-
mens from Bone Valley, Florida, as belonging to the same spe-
cies. Further evidence of the presence of this lineage in the
North Atlantic comes from a mid-Pleistocene deposit on Ber-
muda, where there was clearly a breeding colony of P. al-
batrus, as numerous bones were found of non-volant juveniles,
and in some cases even of embryos (Olson, unpublished data).
A rapid and very high sea-level stand about 450,000 years ago
(Hearty et al., 1999) probably caused the extinction of this spe-
cies on Bermuda and in the entire North Atlantic.
The Lee Creek Mine material shows some differences from
P. albatrus, such as in the shape and orientation of the internal
tuberosity of the humerus and the less proximally oriented head
of the femur. These may be only temporal differences in the
same species lineage.
The species described as Diomedea howardae from a tar-
sometatarsus from the late Pliocene San Diego Formation in
California (Chandler, 1990a) is the size of Phoebastria al-
batrus (Table 3), but it was not compared with that species in
the original description. It was diagnosed on supposed differ-
ences in the shape of the distal foramen that do not hold up in a
series of modern P. albatrus. We consider Diomedea howard-
ae Chandler, 1990a, to be synonymous with Phoebastria al-
batrus (Pallas, 1769).
That albatrosses of this size have occurred in the Pacific well
before the early Pliocene is shown by a tarsometatarsus from
the middle Miocene Astoria Formation in Oregon (USNM
424081, Plate 6g) that has a decidedly modem aspect.
252
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Phoebastria aff. nigripes (Audubon)
Plate %d
Material.—Distal ends of right humeri, USNM 430608,
464243; distal end of left humerus, USNM 366898. Distal ends
of right tibiotarsi, USNM 183457, 248572, 275798; distal ends
of left tibiotarsi, USNM 177900, 192950,430613, 430615.
HORIZON.—Yorktown Formation.
Measurements.—See Tables 4, 5.
Remarks.—The Black-footed Albatross, Phoebastria ni-
gripes (Plates lk, 86,/), and the Laysan Albatross, P. immuta-
bilis (Plates 6d, 8c,g), are medium-sized species confined today
to the North Pacific, where their main breeding grounds are in
the northwestern Hawaiian Islands. Despite their considerable
differences in plumage, the two species hybridize with some
regularity.
Although P. nigripes is definitely the larger species, there is
overlap in the measurements of some of the elements (e.g., see
Table 4) so that many of the fossils in this general size range
from Lee Creek Mine probably cannot be identified except as
belonging to one or the other of these two species. We have not
undertaken a comprehensive analysis of this material but have
attempted only sufficient comparisons to establish that both
species are indeed present in the fauna.
Among eight distal ends of humeri in this size class recov-
ered at Lee Creek Mine (Table 4) are three that are larger than
the largest available specimen of P. immutabilis and hence are
assigned to P. aff. nigripes. Three others are in the area of
overlap between the two species and could belong to either.
The situation with distal ends of tibiotarsi was more com-
plex. In our comparative series, there was essentially no over-
lap in this measurement between the two species, P. nigripes
being larger (Table 5). All of the fossil specimens that had
originally been assigned to this size class, however, fell within
the range of P immutabilis. We then found that some of the
specimens that had been assigned to the P. albatrus size class
were too small for that species. The smallest of six modern
specimens of P. albatrus, a juvenile, had the distal width of the
tibiotarsus 16.9 mm, which is barely larger than the largest P.
nigripes, but the shaft in this specimen is markedly more ro-
bust. Based on measurements of distal width and visual com-
parison of the robustness of the shaft, we assign the tibiotarsi
listed above to P. aff. nigripes.
Although more material than we have identified doubtless
belongs to this species, P. aff. nigripes is apparently less com-
mon in the Lee Creek Mine deposits than is P. aff. immutabi-
lis. We also examined the distal end of a left ulna from the
Bone Valley Formation in Florida (UF 95654) that belongs in
the P. nigripes/P. immutabilis size range and which appears to
be the first record of an albatross other than P. anglica in those
deposits.
Phoebastria aff. immutabilis (Rothschild)
Plates 6c. 7c
Material.—Distal end of right humerus, USNM 367115;
distal end of left humerus, USNM 430677. Right carpometac-
arpus lacking minor metacarpal, USNM 460841. Distal ends of
right tibiotarsi, USNM 193387, 302293, 321274, 366669,
430686-430688, 460864, 460865; distal ends of left tibiotarsi,
USNM 183440, 430680, 430681, 430683, 430684, 460847,
464247, 464248. Right tarsometatarsus, USNM 464250; left
tarsometatarsus, USNM 430689.
Horizon.—Yorktown Formation.
Measurements (mm).—Carpometacarpus: Length, 96.9
(within range of Phoebastria immutabilis and smaller than any
of four females of P. nigripes (100.0-103.6); see also Tables
4, 5).
REMARKS.—As discussed under the preceding species, sev-
eral distal ends of tibiotarsi and two distal ends of humeri from
Lee Creek Mine are too small to belong to Phoebastria ni-
gripes and fall within the range of variation of P. immutabilis.
In addition, there are two complete tarsometatarsi with lengths
of 87.5 and 87.8 mm, values well within the range of females
of P. immutabilis (Table 6), from which they are inseparable.
Phoebastria aff. nigripes or P. aff. immutabilis
The following specimens from Lee Creek belong to one or
the other of these two species but have not been further identi-
fied.
Proximal, shaft, and distal fragments of left humerus, USNM
193231; distal ends of right humeri, USNM 193250, 430679;
distal ends of left humeri, USNM 430678. Proximal ends of
right ulnae, USNM 366663, 366717; proximal ends of left ul-
nae, USNM 210448, 242315, 430656, 430657; distal ends of
right ulnae, USNM 181057, 192487, 206350, 215743, 366417,
366648, 430658-430663, 430666, 460840, 460859; distal ends
of left ulnae, USNM 181075, 193388, 206475, 366803,
366939, 367000, 368466, 368542, 430664, 430665,
430667^130669, 430671, 430672. Proximal end of left radius,
USNM 366435; distal ends of left radii, USNM 464288,
464289. Proximal portions of right carpometacarpi, USNM
430654, 460854; proximal halves of left carpometacarpi,
USNM 430647^130649, 460855, 460856; distal ends of right
carpometacarpi, USNM 206566, 275799, 368554, 430592,
460857; distal ends of left carpometacarpi, USNM 178090,
256237, 430655. First phalanges of major alar digit USNM
206557, 460846, 460862, 460863, 464282, 464283. Right fe-
mur, USNM 460860; proximal ends of right femora, USNM
321302, 430674; proximal end of left femur, USNM 215479;
distal ends of right femora, USNM 308223, 430675, 430676,
460861; distal ends of left femora, USNM 321312, 430673.
Proximal end of right tibiotarsus, USNM 430685. Proximal
and distal ends of right tarsometatarsus, USNM 464251; proxi-
mal and distal ends of left tarsometatarsus, USNM 430691;
proximal ends of right tarsometatarsi, USNM 275816, 366346,
NUMBER 90
253
430694,430695, 430707; proximal ends of left tarsometatarsi,
USNM 192654, 241372, 252306, 366347, 430690, 464252;
distal ends of right tarsometatarsi, USNM 181110, 192705,
275823, 302317, 430696, 430697, 460851, 460852, 464249;
distal ends of left tarsometatarsi, USNM 248542, 257500,
302292, 430693. Pedal phalanges, USNM 177819, 248577,
321229,464284^164287.
Phoebastria rexsularum, new species
Plates 6h, i, 8e
HOLOTYPE.—Right tarsometatarsus, USNM 302313.
Type Locality.—Texasgulf Inc. Lee Creek Mine, south
side of Pamlico River, near Aurora, Beaufort County, North
Carolina (35°23'22"N, 76°47'06"W).
Horizon.—Yorktown Formation, lower Pliocene.
Distribution.—Known so far only from the type locality
and from the Rappahannock River in Middlesex County, Vir-
ginia.
Measurements of Holotype (mm).—Length, 73.9; proxi-
mal width, 13.7; width and depth of shaft at midpoint, 5.5 x
6.0; distal width, 13.8; depth of middle trochlea, 8.4; width
through outer and middle trochleae, 9.7.
TOPOTYPICAL Paratypes.—Distal end of left humerus,
USNM 302414. Distal ends of right tibiotarsi, USNM 250848,
275795, 308185; distal ends of left tibiotarsi, USNM 178050,
430682,430701, 430702,464291. Right tarsometatarsi, USNM
430704, 430705; proximal ends of right tarsometatarsi, USNM
242334, 366607, 430708, 460848, 460849; proximal end of left
tarsometatarsus, USNM 460850; distal ends of right tarsometa-
tarsi, USNM 366611,460838; distal ends of left tarsometatarsi,
USNM 430703, 460853. Pedal phalanx, USNM 464281.
The following specimens are tentatively referred to this spe-
cies, most being very fragmentary or undiagnostic, although
they appear to be too small for Phoebastria aff. immutabilis.
Shaft of right coracoid, USNM 430700. Three fragments of
proximal end of left humerus, USNM 430699. Distal end of
right ulna, USNM 430670; distal end of left ulna, USNM
460839. Proximal ends of right carpometacarpi, USNM
178066,430653; proximal ends of left carpometacarpi, USNM
460842, 460843; distal ends of right carpometacarpi, USNM
250702, 460844, 460845; distal end of left carpometacarpus,
USNM 257494.
Additional Paratype.—Left tarsometatarsus lacking
proximal end, USNM 256620, south side of Rappahannock
River, 3 mi (5 km) upstream from Stingray Point, near
Deltaville, Middlesex County, Virginia; collected by Eldon
Branch, received in 1979.
The specimen was found as a "float" and is presumed to be
from the Yorktown Formation, which crops out there.
Measurements of Paratypes (mm).—Tarsometatarsus
(USNM 256620):    Distal width, 14.1.
For measurements of other paratypes see Table 6.
Etymology.—"King of the gannets," from Latin rex, king,
and the genitive plural of Sula, now used as the generic name
Table 4.—Comparison of distal width (mm) of humerus of modern and fossil
medium-sized albatrosses, Phoebastria. Measurements are in list form for fos-
sil species. («=number of specimens.)
Species
P. immutabilis females
P. immutabilis males
P. aff. immutabilis, Lee Creek Mine
P. aff. immutabilis/nigripes, Lee Creek Mine
P. aff. nigripes, Lee Creek Mine
P. nigripes females
P. nigripes males
Range
Mean
9	20.9-22.2	21.5
9	21.9-23.5	22.9
2	21.6,21.8	-
3	22.6, 22.9, 23.0	-
3	23.7,23.8,24.0	-
4	22.6-24.0	23.4
5	23.1-24.3	23.8
Table 5.—Comparison of distal width (mm) of tibiotarsus of modern and fos-
sil medium-sized albatrosses, Phoebastria. (n=number of specimens.)
Species	n	Range	Mean
P. immutabilis females	6	12.1-13.2	12.6
P. immutabilis males	8	14.4-15.0	14.7
P. aff. immutabilis, Lee Creek Mine	17	13.0-14.8	14.0
P. aff. nigripes, Lee Creek Mine	5	14.9+-I6.5	15.8
P. nigripes females	4	14.9-15.4	15.2
P. nigripes males	5	15.1-16.7	15.6
Table 6.—Measurements (mm) of hindlimb elements of Phoebastria rexsu-
larum, new species, compared with females (the smaller sex) of modern P. im-
mutabilis.
Element	P. rexsularum, n		sp.	P. immutabilis,		females
	n	Range	Mean	n	Range	Mean
Tibiotarsus						
Distal width	6	12.1-13.2	12.6	9	13.3-14.1	13.9
Tarsometatarsus						
Length	3	73.8-82+	78.5	9	83.7-88.5	86.1
Proximal width	9	12.5-14.2	13.5	9	14.8-15.8	15.4
Distal width	6	12.9-14.2	13.6	9	14.4-15.8	15.0
of boobies but derived from the Scandinavian name applied to
the Northern Gannet, Morus bassanus. The name comes from
the extraordinary example of a single female of the Southern
Hemisphere Black-browed Albatross, Thalassarche mel-
anophris (Temminck), that appeared in a gannetry on Myggen-
aes Holm in the Faeroe Islands in 1860 and returned each sum-
mer for 34 years until shot in 1894 (Andersen, 1894, 1895;
Murphy, 1936:511). During this time it was known among the
Faeroese who visited the gannetry as "Sulekongen," or "Gan-
net King," as the gannets would make way for the albatross
when it moved about the colony.
DIAGNOSIS.—This species is referable to Phoebastria by the
slender configuration of the tarsometatarsus; it is without ex-
panded articular surfaces seen in Thalassarche, but it is smaller
than any other member of the genus and is probably smaller
than any existing species of albatross.
Remarks.—In sorting the albatross material from Lee Creek
Mine, it became evident that some of the specimens at the
small end of the observed size variation were too small to be
encompassed by the range of variation seen in the size class in-
cluding P. nigripes and P. immutabilis. Although in life there
may have been overlap in size between this smallest species
254
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
and P. aff. immutabilis, we have assigned fossil leg elements to
the new species only when they are smaller than observed in a
series of females of modern P. immutabilis. The holotype of P.
rexsularum is from a particularly small individual, being a full
centimeter shorter than the shortest available tarsometatarsus
of P. immutabilis.
The distal width of the humerus assigned to P. rexsularum is
20.7 mm, which is smaller than that in any available specimen
of P. immutabilis or P. nigripes (Table 4). The pedal phalanx
referred to P. rexsularum is the diagnostic long, slender proxi-
mal phalanx of the fourth toe, which measures 43.9 mm in
length. The same element in a small female of P. immutabilis
was 51.8 mm long, again illustrating how small some individu-
als of P. rexsularum must have been.
Howard (1966) described a new species of rather small alba-
tross, Diomedea milleri, from the middle Miocene deposits of
Sharktooth Hill, California. The holotype is the most proximal
portion of a left ulna and was compared only with a single
modern specimen of D. (=Phoebastria) nigripes. The proximal
end of a tarsometatarsus from the same locality was referred to
D. milleri in the same publication. Howard and Barnes (1987)
later tentatively referred another proximal end of an ulna with
associated fragments of radii from middle Miocene deposits at
Oso Creek, Orange County, California, to D. milleri. The prox-
imal widths of the holotype and of the Oso Creek specimen
were 14.4 and 15.8 mm, respectively, whereas in a small fe-
male of Phoebastria immutabilis (USNM 488178) the same
measurement is 12.7 mm. No measurements were given for the
referred tarsometatarsus, but if the illustration (Howard, 1966,
fig. le) is at natural size, as stated, the proximal width would
be about 18 mm, which is considerably larger than it is in any
female of P. immutabilis measured (Table 6). The material of
D. milleri is probably inadequate for characterization of a new
species of albatross, but the available evidence suggests that it
was not smaller than P. immutabilis. Therefore there is no rea-
son to identify it with P. rexsularum.
Chandler (1990a: 100) mentioned the distal end of a tibiotar-
sus from the San Diego Formation as belonging to a small alba-
tross ("Diomedea sp. B") that he said was "86 percent that of
D. nigripes in distal width." Because no measurements were
given for either species, there is no way to assess the actual size
of the specimen from his publication.
Phoebastria rexsularum represents the least-common size
class of albatross at Lee Creek Mine. Curiously, this smallest
of the Northern Hemisphere albatrosses, and D. anglica, the
largest, were the ones that became extinct, whereas the three
species of intermediate size have persisted elsewhere up to the
present.
Family Procellariidae
(shearwaters and petrels)
By far the majority of fossils of this family from Lee Creek
Mine are referable to the genus Puffinus Brisson and the close-
ly related genus Calonectris Mathews and Iredale. The identifi-
cation of these fossils was extremely difficult for reasons given
below. To begin with, many fossil species of Puffinus have
been described and named from deposits of various ages on
both sides of the Atlantic and from the eastern Pacific. A prop-
er treatment of the Lee Creek fossils would have to take these
fossil taxa into account, necessitating a great deal of revision-
ary work.
Another problem with the Lee Creek Mine material in partic-
ular is that species lineages in the Procellariidae appear to have
changed very slowly, if at all, through time. Species of Puffinus
in the Calvert Formation, for example, may be extremely simi-
lar to living species. Thus, when precise stratigraphic informa-
tion is absent it is impossible to determine whether a given
form of Puffinus from Lee Creek Mine is middle Miocene or
early Pliocene in age.
Shearwaters of the genera Puffinus and Calonectris were
treated in an admirable monograph by Kuroda (1954), who ex-
amined osteology in addition to external characters. He was
careful to attempt to distinguish between primitive and special-
ized characters well before the advent of cladistics.
In summary, the species of shearwaters are marked by a pro-
gression from a primitive, aerially adapted condition (Calonec-
tris) to increasing use of both the wings and feet for underwater
propulsion—what Kuroda referred to as "aquatic" adapta-
tions—in which the humerus becomes flattened, the forewing
shortened, the pelvis laterally compressed and lengthened, the
femur stouter and more curved, the cnemial crest of the tibio-
tarsus lengthened, and the tarsometatarsus more laterally com-
pressed—all of these being typical diving adaptations also
found in other groups of birds. The groups consisting of the
Wedge-tailed Shearwater (Puffinus pacificus (Gmelin)) and
Buller's Shearwater (P. bulleri Salvin, subgenus Thyellodroma
Stejneger), and the Pink-footed Shearwater (P. creatopus
Coues) and Flesh-footed Shearwater (P. carneipes Gould, sub-
genus Hemipuffinus Iredale), are only slightly more specialized
along these lines than is Calonectris and are hardly separable
from one another except on size. The Greater Shearwater,
Puffinus gravis (O'Reilly) (subgenus Ardenna Reichenbach),
occupies an intermediate position between those species and
the most specialized members of the family, which are of the
subgenus Puffinus. Among the last, the Short-tailed Shearwa-
ter, P. tenuirostris (Temminck), appears to be the least derived.
Despite the distinct osteological differences between Ca-
lonectris and the different subgroups of Puffinus, the nature of
the fossils from Lee Creek Mine still renders them difficult to
identify. There is practically no associated material. Bones of
the wing are much more frequently represented than are ele-
ments of the hindlimb, and these are almost always broken.
Whereas complete humeri of Puffinus would be relatively easy
to assign to one subgroup or another, the differences become
greatly blurred when hundreds of fragmentary distal ends with
varying degrees of wear are compared. Therefore, we have not
attempted to identify many of the specimens of Procellariidae
NUMBER 90
255
to species. Instead we have selected only a few specimens of
some of the more diagnostic elements in order to attempt to as-
sess the minimum number of species that are present in the fau-
nas. Further refinements will have to await much patient revi-
sionary analysis. The great majority of the procellariid fauna at
Lee Creek Mine is apparently made up of the five medium-
large species Calonectris aff. diomedea, C. aff. borealis, Puffi-
nus aff. gravis, Puffinus (Ardenna) sp., and P. aff. pacificoides.
Below, we identify 16 species of Procellariidae from the Lee
Creek deposits. This is undoubtedly a minimum and others will
almost certainly be distinguished among the specimens already
at hand.
Genus Pterodromoides Segui et al. (in press)
Pterodromoides minoricensis Segui et al. (in press)
Plate 9o
Material.—Distal end of left humerus lacking ectepi-
condylar spur, USNM 464315.
HORIZON.—Yorktown Formation (see below).
Measurements (mm).—Distal width, 8.9; distal depth
through ulnar condyle, 5.8; width and depth of shaft 20 mm
above distal extremity, 4.4 x 3.1.
REMARKS.—This bone seemingly cannot be assigned to any
living genus in the family. There is practically no expansion of
shaft above the entepicondyle, even to the rather limited extent
seen in Pterodroma Bonaparte and quite unlike Puffinus, and
the brachial depression is large and deep. The specimen ap-
pears to be closest to that of the so-called "fulmarine" petrels,
exemplified by Fulmarus Stephens, but it is smaller than any of
those birds. It is of a rather unusual size class for the family,
being intermediate in size between the largest of the smaller
species of Pterodroma and the smallest of the larger species of
that genus.
We had originally listed this specimen only as "Procellari-
idae, genus and species indeterminate," the preceding para-
graph having been written before we thought to compare the
specimen with Pterodromoides minoricensis Segui et al. (in
press). This is a new genus and species described from Mio/
Pliocene deposits on Menorca in the Balearic Islands of the
Mediterranean, which was shown to have similarities to the
Fulmarinae. Olson examined and compared some of the type
material and agreed that it could not be referred to any known
genus of Procellariidae. The distal width of the humerus of P.
minoricensis was given as 9.2, 9.3, and 9.6 mm, and the slight-
ly smaller size of the Lee Creek fossil (8.9 mm) would proba-
bly fall within the range of a larger sample. The fact that, as re-
marked above, this is an unusual size class within the
Procellariidae makes the assignment of the Lee Creek fossil all
the more likely.
The deposits on Menorca from which P. minoricensis was
obtained could not be dated directly but were reasoned from
faunal evidence to be Mio/Pliocene, but younger than Langhian
(middle Miocene), and they were inferred to be late Miocene.
The shared presence of this species in Menorca and North
Carolina suggests that the Lee Creek Mine specimen came
from the Yorktown Formation. The temporal range of such a
seabird could surely encompass both the late Miocene and the
early Pliocene.
This trans-Atlantic correlation suggests that the wintering
grounds of P. minoricensis included the western North Atlan-
tic. That it is so rare at Lee Creek Mine may be due to tapho-
nomic processes discussed above relating to its having been a
surface feeder.
Genus Procellaria Linnaeus
This genus, including Adamastor Bonaparte, is now used for
the four largest species of the family, apart from the albatross-
sized giant petrels Macronectes Richmond. One of the species
of petrels at Lee Creek Mine is of this size class, but it appears
to be more closely related to Calonectris and is listed under
that genus. The living species of Procellaria are practically
confined to southern oceans, only two of them being found in
the South Atlantic. For our comparisons we had only a single
skeleton of each of the species except the White-chinned Pe-
trel, P. aequinoctialis, of which we had 13.
Procellaria cf. aequinoctialis Linnaeus
Plate 9y
Material.—Distal end of right tibiotarsus, USNM 464312.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Distal width, 9.7; depth through
inner condyle, 9.7; width of shaft 30 mm above distal extremi-
ty, 5.7.
Remarks.—This bone is from a very large procellariid the
size of males of Procellaria aequinoctialis, there apparently
being no other species of the family that falls in this size range
or any other procellariid fossils from Lee Creek Mine of such
great size. At present, the breeding stations of P aequinoctialis
in the Atlantic are at Inaccessible Island in the Tristan da Cun-
ha group, the Falklands, South Georgia, and possibly Gough Is-
land. The normal modern range at sea does not extend north
much beyond 15°S, so the Lee Creek bird may have been only
a vagrant.
Procellaria cf. parkinsoni Gray
Plate 9q.r
Material.—Proximal half of right humerus lacking most of
pectoral crest and internal tuberosity, USNM 430845; distal
third of right humerus, USNM 430726.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Greatest depth through head, 5.8;
width and depth of shaft below pectoral crest, 7.6 x 6.1; distal
width, 14.4; depth through radial condyle, 8.2 mm.
256
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
REMARKS.—The proximal portion of the humerus appears to
be nearly identical with that of Parkinson's Petrel, Procellaria
parkinsoni, not only in size and details of attachments, but also
in the shape of the shaft, which is noticeably flattened on the
anconal surface. The distal portion is an equally good match.
The smallest species in its genus, P. parkinsoni breeds only in
New Zealand but crosses the Pacific to winter off western
America as far north as the latitude of Guatemala. Evidently it
or a related form occurred in the Atlantic in the early Pliocene,
possibly having been a vagrant entering through the Panamani-
an seaway.
Genus Pterodroma Bonaparte
Gadfly petrels of the genus Pterodroma are all but absent in
the fossil record except at their nesting islands. Their rarity in
marine deposits may be due to their feeding entirely from the
surface, thus making them much less susceptible to predation
by aquatic carnivores.
Measurements (mm).—Width and depth of shaft at ap-
proximate midpoint, 3.7 x 3.0, 3.9 x 3.2.
Remarks.—The relatively terete shafts of these fragmentary
specimens remove them from association with species of Puffi-
nus. They indicate a species larger than Bulwer's Petrel, Bulw-
eria bulwerii (Jardine and Selby), and about the size of the
smallest of the forms of Pterodroma or of Jouanin's Petrel,
Bulweria fallax Jouanin. The only species in this size range re-
ported from the Atlantic Ocean is B. bifax Olson (1975),
known only from Quaternary deposits on St. Helena Island
(Olson, 1975), although the Indian Ocean species B. fallax has
been recorded as a vagrant in Italy (Olson, 1985a).
Genus Pachyptila Illiger
The prions of the genus Pachyptila are small, filter-feeding
petrels that are now entirely confined to the southern oceans.
Thus, the following record was quite unexpected.
Pterodroma magn. lessonii (Garnot)
Plate 9/7"
Material.—Left tarsometatarsus lacking only the inner tro-
chlea, USNM 430854.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Length, 45.0; proximal width, 7.9;
width through outer and middle trochleae, 6.0; width and depth
of shaft at midpoint, 3.9 x 3.7.
Remarks.—The lack of either lateral compression or asym-
metry of the shaft distinguishes this bone from any of the spe-
cies of Puffinus. It is too small for any of the species of Procel-
laria or Fulmarus, and it is compatible with the morphology in
Pterodroma, within which, however, it is very large, being the
size of the White-headed Petrel, P. lessonii. We did not have
appropriate comparative skeletal material for this species, but
the fossil matched very well in size with the tarsus as visible in
skin specimens. Pterodroma lessonii is very much a southern
species today, being found circumpolarly from Antarctica to
about 33°S latitude. Gadfly petrels the size of those resident in
the western North Atlantic, the Black-capped Petrel (P. hasita-
ta (Kuhl)) and the Cahow (P. cahow Nichols and Mowbray),
have not been found at Lee Creek Mine.
Genus Bulweria Bonaparte
Bulweria? sp.
Material.—Most of shaft of left humerus with distalmost
portion of pectoral crest, USNM 464298; proximal two-thirds
of shaft of left humerus with portions of pectoral and bicipital
crests, USNM 501505.
HORIZON.—Uncertain, either Pungo River Formation or
Yorktown Formation.
Pachyptila sp.
Plate 9a,c,e
Material.—Distal end of right humerus, USNM 464313.
Distal end of left tarsometatarsus, USNM 496162.
Horizon.—Uncertain, probably Yorktown Formation.
MEASUREMENTS (mm).—Humerus: Distal width, 7.6; dis-
tal depth through ulnar condyle, 6.0.
Tarsometatarsus: Distal width, 4.7; depth of middle tro-
chlea, 2.7; width and depth of shaft 10 mm above distal ex-
tremity, 2.3 x 1.8.
REMARKS.—These specimens are indistinguishable from
medium-sized modern species of Pachyptila, the systematics of
which is complex. The only previously known fossils of the ge-
nus are those reported from deposits contemporaneous with the
Yorktown Formation in South Africa, where fossils in the size
range of modern species occurred with those of a much larger
extinct species, P. salax Olson (1985b).
Genus Calonectris Mathews and Iredale
Calonectris krantzi, new species
Plate 9m. u
Holotype.—Distal end of left humerus, USNM 430724.
Type Locality.—Texasgulf Inc. Lee Creek Mine, south
side of Pamlico River, near Aurora, Beaufort County, North
Carolina (35°23'22"N, 76°47'06"W).
Horizon and Age.—Yorktown Formation, early Pliocene,
inferred from preservation and lack of any known species of
Procellariidae of such large size in deposits of middle Miocene
age.
Distribution.—Known so far only from the type locality.
NUMBER 90
257
Measurements of Holotype (mm).—Distal width, 15.8;
depth through radial condyle, 9.5; shaft width and depth at
proximal margin of brachial depression, 9.9 x 5.5.
PARATYPES.—Right coracoid lacking part of head and exter-
nal distal angle, USNM 250805. Proximal end of left humerus,
USNM 464308; distal third of right humerus lacking ectepi-
condylar spur, USNM 430728; distal fourth of left humerus
lacking ectepicondylar spur, USNM 464307. Distal two-thirds
of right carpometacarpus, USNM 430718.
Measurements of Paratypes (mm).—Coracoid: Head
to tip of internal distal angle, 37.4.
Humerus: Proximal width, 21.2; distance from head to dis-
tal extent of pectoralis scar, 28.6; distal width, 15.9, 15.0.
Etymology.—To Smithsonian photographer Victor E.
Krantz, who, for nearly 30 years, has photographed thousands
of fossil bird bones to illustrate dozens of publications, includ-
ing this one, in recognition of his long service to avian paleon-
tology.
DIAGNOSIS.—Referable to Calonectris by the following
combination of characters: ectepicondylar spur relatively short
and somewhat triangular (unlike the more elongate process in
Procellaria); attachment of anterior articular ligament relative-
ly short and wide (longer and narrow in Procellaria); brachial
depression large and deep, extending proximally well past
proximal margin of ectepicondylar spur, and shaft showing no
signs of flattening or expansion of entepicondylar area (in the
last two respects differing from Puffinus). Larger than any
known species of Calonectris, falling within the size range of
smaller species of Procellaria.
Remarks.—The coracoid and carpometacarpus are referred
to this species almost entirely on size and could belong with
one of the other large species, although the coracoid differs in
shape from that of Procellaria.
The largest form of Calonectris is Cory's Shearwater, C. bo-
realis Cory, in which the distal width of the humerus ranges
from 13.0 to 14.6 mm («=12, all unsexed, average 13.9 mm).
These figures do not adequately convey the more massive na-
ture of the bones of the new species.
Calonectris aff. borealis (Cory)
Plate 9t
Material.—Distal two-thirds of right humerus lacking
most of ectepicondylar spur, USNM 501506.
Horizon.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Distal width, 14.2.
Remarks.—This specimen is clearly within the size range
of Cory's Shearwater, Calonectris borealis, which is the larg-
est of the living taxa of the genus. The Atlantic forms of Ca-
lonectris, all often considered to be subspecies of the Mediter-
ranean Shearwater, C. diomedea (Scopoli), differ considerably
in size. The material from Lee Creek Mine suggests that at
least two of these lineages have been separate for some 5 Ma,
for which reason subspecific rank seems inappropriate. The
Cape Verde Shearwater, C. edwardsi (Oustalet), of the Cape
Verde Islands, is the smallest form and is supposed to winter in
the vicinity of its natal islands, although this appears to be little
more than an assumption. The largest species, C. borealis,
nests on islands in the North Atlantic (Azores, Canaries, Ma-
deira, Desertas, Porto Santo, Salvages, and the Berlengas off
Portugal). Calonectris diomedea is of intermediate size and
nests on islands of the Mediterranean. The nonbreeding ranges
of C. diomedea and C. borealis have been confounded because
both taxa have usually been considered together. Both, howev-
er, certainly occur in the North Atlantic Ocean off North Caro-
lina today and evidently did so in the past as well (see follow-
ing species). We depart from any of the modern lists we have
cited in recognizing these taxa at the specific level.
Calonectris aff. diomedea (Scopoli)
Plate 9j
Material.—Distal ends of right humeri, USNM 215433,
366013; distal end of left humerus, USNM 430745. Left femur
lacking internal distal condyle, USNM 430950.
Horizon.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Humerus: Distal width, 12.5,
12.0, 12.7.
Femur:    Length, 38.1; proximal width, 8.7.
REMARKS.—These specimens agree in size and general mor-
phology with Calonectris diomedea, the Mediterreanean mem-
ber of the genus. These birds leave the Mediterranean in win-
ter, and large numbers occur in the western North Atlantic
Ocean off North Carolina (Lee, 1995:126). This also is the
most abundant bird in a beach deposit on Bermuda dating to
about 450,000 BP (Olson, unpublished data), which, with the
Lee Creek Mine specimens, suggests that this pattern of winter
distribution has been established for a very long time.
Genus Puffinus Brisson
Puffinus all. pucificoides Olson, 1975
Plate 9v,ee
Material.—Associated Specimen: Partial skeleton con-
sisting of right and left coracoids, right humerus lacking head,
proximal two-thirds of shaft of left humerus, and left car-
pometacarpus lacking minor metacarpal, USNM 464335.
Individual Elements: Left humerus lacking portions of pec-
toral crest, USNM 193130; right humeri lacking most of proxi-
mal end, USNM 430751,430840. Left femora, USNM 242227,
501507; left femur lacking proximal end, USNM 501508.
Right tarsometatarsus, USNM 430852; left tarsometatarsus,
USNM 464297.
Horizon.—Yorktown Formation.
MEASUREMENTS (mm).—Coracoid: Length with sternal
facet flat on calipers, 25.8.
258
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Humerus: Length, 99.4; length from distal extent of pecto-
ral crest to ectepicondyle, 76.9, 74.5, 77.2, 77.7; distal width,
11.9,11.8,11.7,12.4.
Femur: Length, 35.2, 37.8; proximal width, 8.2, 8.7; distal
width, 8.1,8.4, 7.9.
Tarsometatarsus: Length, 47.6, 47.3; proximal width, 7.6,
8.0; distal width, 7.7, 6.9.
Remarks.—These specimens indicate a shearwater refer-
able to the subgenus Thyellodroma, the existing members of
which are Puffinus pacificus, of wide distribution in the Indian
and Pacific oceans, and P. bulleri of New Zealand, wintering to
the eastern Pacific. That this group formerly extended outside
the Indo-Pacific was established by Olson (1975), who de-
scribed a new species, P pacificoides, from Pleistocene depos-
its on St. Helena Island in the South Atlantic Ocean. Most of
the Lee Creek Mine fossils are from a species more robust than
either P pacificus or P bulleri but quite similar to P. pacifi-
coides. One femur (USNM 242227) is slightly smaller and de-
cidedly more gracile than the other Lee Creek femora or those
of P. pacificoides and closely resembles that of P. bulleri, pos-
sibly indicating a third species in the Thyellodroma group (see
following species). Regardless, this group of shearwaters had a
long history in the Atlantic, from which it vanished at some
time in the Pleistocene.
Puffinus (Thyellodroma) sp.
Plate 9gg
Material.—Distal end of right humerus, USNM 464303;
distal end of left humerus, USNM 464301. Complete left tar-
sometatarsus, USNM 250810.
Horizon.—Uncertain, but Pungo River Formation inferred
from similarity to fossils of an unnamed species from Calvert
Formation and differences from any modern species lineage.
MEASUREMENTS (mm).—Humerus:    Distal width, 9.7, 9.0.
Tarsometatarsus: Length, 42.1; proximal width, 6.0+; dis-
tal width, 6.3.
Remarks.—The humerus and tarsometatarsus in this spe-
cies have a morphology consistent with that in the Thyellodro-
ma group of shearwaters but come from a species much smaller
than any modem taxon.
Puffinus (Ardenna) sp.
Plate 9bb,cc
Material.—Distal end of right humerus, USNM 179269;
distal ends of left humeri, USNM 177786, 179249, 242329,
366613. Left tarsometatarsus lacking inner and outer trochleae,
USNM 366625; proximal ends of left tarsometatarsi, USNM
177806, 366977; distal ends of left tarsometatarsi, USNM
181072,215620.
HORIZON.—Uncertain, either Pungo River Formation or
Yorktown Formation.
Measurements (mm).—Humerus: Distal width, 14.3,
14.6, 15.2, 14.3, 14.0.
Tarsometatarsus: Length, 65.1; proximal width, 9.5+, 9.7,
9.2; distal width, 8.3.
Remarks.—This shearwater is a fairly common species in
the Lee Creek Mine fauna. The humerus and tarsometatarsus
are similar in morphology to those of Puffinus gravis (subge-
nus Ardenna Reichenbach) but are larger.
Puffinus aff. gravis (O'Reilly)
Plate 9p
Material.—Distal ends of right humeri, USNM 177890,
178187; distal end of left humerus, USNM 430709.
Horizon.—Uncertain, either Pungo River Formation or
Yorktown Formation.
Measurements (mm).—Distal width, 13.7, 12.8, 12.4.
Remarks.—The modern Greater Shearwater breeds at
Tristan da Cunha and Gough islands and breeds in limited
numbers in the Falklands, spending the boreal summer in the
North Atlantic, a pattern of distribution that the fossils suggest
may have been in effect for millions of years. Puffinus conradi
Marsh (1870), from the Calvert Formation, is quite similar to
the modem P. gravis and would be expected in the Pungo Riv-
er Formation, as would the Pliocene representative of this sub-
genus.
Puffinus aff. tenuirostris (Temminck)
Plate 9k,z
Material.—Distal portions of right humeri, USNM
430760, 430761; distal two-thirds of left humerus, USNM
464333. Complete left ulna, USNM 366014.
HORIZON.—Uncertain, probably Yorktown Formation.
MEASUREMENTS (mm).—Humerus: Distal width, 10.8+,
11.9, 11.7.
Ulna:    Length, 88.0.
Remarks.—These remains indicate a shearwater with a very
compressed shaft of the humerus. This species is smaller than
the Sooty Shearwater, Puffinus griseus (Gmelin), but is larger
than the Christmas Island Shearwater, P. nativitatis Streets, or
any of the Manx Shearwater, P. puffinus (Briinnich), assem-
blage. No existing shearwater with these qualities is found in
the Atlantic today, the only other one being P. tenuirostris,
which breeds on islands around Australia and ranges widely
over most of the Pacific. The well-preserved left humerus listed
above (Plate 9k) is virtually identical to that of P. tenuirostris
except for the shorter scar for the anterior articular ligament.
The ulna is at the low end of the size range for P. tenuirostris
or perhaps is smaller, but it has no closer match among other
modern species of Puffinus. The species described as P. holei
(Walker et al., 1990; emended to P. holeae by Micheaux et al.,
1991:806, note 11), from the Pleistocene of the Canary Islands,
may bear scrutiny in connection with this material.
NUMBER 90
259
Puffinus cf. puffinus (Briinnich) sensu lato
Plate 9/
Material.—Right humerus lacking head, internal tuberosi-
ty, and ectepicondylar spur, USNM 430765.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Length from distal extent of pecto-
ralis scar to entepicondyle, 64.5; distal width, 10.8.
REMARKS.—Among the Lee Creek Mine collections are sev-
eral specimens of humeri with compressed shafts that fall in the
general size range of the various taxa often grouped as subspe-
cies of the Manx Shearwater, Puffinus puffinus. The best pre-
served of these, listed above, has the size and proportions of the
Levantine Shearwater, P. mauretanicus Lowe, a Mediterranean
breeder that winters in the eastern North Atlantic. Nominate P.
puffinus breeds on both sides of the North Atlantic and is high-
ly migratory. The fossil taxa P. nestori (Alcover, 1989) and P.
olsoni (McMinn et al., 1990), from the late Pliocene of Eivissa
(Ibiza) and the Holocene of the Canary Islands, respectively,
also belong in this group of small shearwaters.
Puffinus magn. Iherminieri Lesson
Plate 9g, h h, a
Material.—Proximal end of right humerus, USNM
464332. Proximal end of left tarsometatarsus, USNM 464311;
distal end of right tarsometatarsus, USNM 178074.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Humerus:    Proximal width, 11.3.
Tarsometatarsus:    Distal width, 5.8.
REMARKS.—Remains of Puffinus in this smallest size class
of the genus (which also includes the Little Shearwater, P. assi-
milis Gould) are extremely rare at Lee Creek Mine, despite the
fact that Audubon's Shearwater, P. Iherminieri, now occurs
abundantly off North Carolina. The distal end of a tarsometa-
tarsus listed above is only tentatively included because, al-
though it is of an appropriate size, it is not referable with cer-
tainty to Puffinus.
Order Pelecaniformes
(pelicans, cormorants, and allies)
Family Pelecanidae
(pelicans)
Genus Pelecanus Linnaeus
Pelecanus schreiberi Olson (1999)
Plate\0a-d
Material.—Distal end of right femur, USNM 192077 (ho-
lotype); distal end of left femur, USNM 263567 (paratype).
Pedal phalanx 1 of digit III, USNM 446506 (paratype); pedal
phalanx 2 of digit III, USNM 421948 (paratype).
Horizon.—Basal Yorktown Formation from matrix analysis
of paratypical femur (Olson, 1999); also tentatively identified
from early Pliocene Bone Valley Formation in Florida.
Additional Material Examined (paratypes).—Bone Val-
ley Formation, Florida: Right quadrate lacking orbital pro-
cess, UF 125031. Axis vertebra lacking dorsal spine, UF 65677.
Measurements.—See Olson (1999).
Remarks.—This large species exceeds in size either of the
living North American pelicans (American White Pelican,
Pelecanus erythrorhynchos Gmelin; Brown Pelican, P. occi-
dentalis Linnaeus) and would have equalled the two largest
modern pelicans in size (Dalmatian Pelican, P. crispus Bruch;
Great White Pelican, P. onocrotalus Linnaeus). The fossil fem-
ora differ from all modem pelicans in having the rotular groove
markedly deeper and narrower, the internal condyle more ele-
vated anteriorly, and the intercondylar fossa narrower and
deeper. The pedal phalanges are much more robust than are the
comparable elements of modern pelicans.
The shaft of the femur of the holotype is filled with dense
medullary bone. This serves as a calcium reserve in females,
forming 10 to 14 days prior to egg-laying and being quickly re-
sorbed afterwards (see references cited in Ballmann, 1979, and
Mourer-Chauvire et al., 1999). Thus, this species must have
been breeding in the vicinity of deposition.
Family Pelagornithidae
(pseudodontorns, false-toothed birds)
These gigantic, soaring, pseudotoothed birds are rather well
represented in the Lee Creek Mine collections, but, as is usual
in this group, only by scraps because the extremely thin walls
of the bones are easily broken. Olson (1985d) reviewed some
aspects of the systematics of these birds, concluding that all
those known are referable to a single family, Pelagornithidae,
which has several synonyms. The first species to be named was
Pelagornis miocaenus Lartet (1857), from the Miocene of
France. So far, all of the considerable material of these birds
found in late Oligocene and Neogene deposits around the North
Atlantic appear to be referable to a single genus—Pelagornis—
although this includes a variety of species. Evidence from other
localities suggests that as many as three species of pseudodon-
torns may have coexisted. We have not attempted to describe
the Lee Creek Mine material in detail, pending planned revi-
sionary studies of the group by K.I. Warheit and Olson.
Adding to the problems of identifying the Lee Creek pseudo-
dontorns is the fact that we do not yet know from which hori-
zon any of the material comes. The preservation of much of the
material resembles that of Yorktown-age specimens. The most
frequently represented species of pseudodontorn in the Calvert
Formation, including the Pollack Farm site in Delaware (Ras-
mussen, 1998), is smaller than either of the two species known
so far from Lee Creek Mine, which also is indirectly suggestive
of their derivation from the Yorktown Formation. This line of
reasoning has its limitations, however, because there was an
260
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
extremely large pseudodontom in the late Oligocene of South
Carolina (Warheit and Olson, unpublished data) and presum-
ably there would have been large species in the middle Mi-
ocene as well.
Although mainly fragmentary, the material from Lee Creek
Mine is important, as certain elements represented are other-
wise unknown, or nearly so, for the entire family. At least two
species can be distinguished, mainly on the very different sizes
of comparable elements: in this case, the heads of humeri, frag-
ments of coracoid, and distal ends of femora.
Genus Pelagornis Lartet, 1857
Pelagornis sp. 1
Plate 1 \p.q,t,u
Material.—Fragment of left coracoid with glenoid and
scapular facets, USNM 464329. Heads of right humeri, USNM
215442, 308155. Proximal ends of left femora, USNM 321289,
446499; distal end of right femur, USNM 242202; distal ends
of left femora, USNM 205473, 242327, 446498. Inner and
middle trochleae of left tarsometatarsus, USNM 446500.
HORIZON.—The stratigraphy is uncertain; preservation and
abundance suggest that most specimens are probably from the
Yorktown Formation, but the Pungo River Formation cannot
be ruled out because pseudodontorns were already diverse in
the late Oligocene and early Miocene in the North Atlantic.
Measurements (mm).—Femur: Proximal width, 29, 30;
distal width, 29.6, 30.9, 32.7, 30.6.
Tarsometatarsus: Width and depth of middle trochlea,
11.7x 17.1.
REMARKS.—The very long but light humeri of these birds
did not preserve well at Lee Creek Mine, and they are repre-
sented only by the heavy, rounded heads. These and the scap-
ulae articulate well with the single fragment of coracoid and
associate these elements with the smaller species present in
the deposits. There are two size classes of femora, the larger
species (see below) being represented only by a very worn
distal end. All of the remaining femoral fragments are referred
to the smaller species, along with the fragment of tarsometa-
tarsus. The shafts of all of the femora are filled with medul-
lary bone, as are those of a specimen from the Calvert Forma-
tion, so either all of these were from laying females or the
presence of medullary bone in these birds has some other sig-
nificance.
Pelagornis sp. 2
PLATE ll/.M
Material.—Fragment of sternal articulation of right cora-
coid, USNM 425109; fragment of left coracoid with glenoid
and scapular facets, USNM 446501. Heads of right humeri,
USNM 425111,446497; head of left humerus, USNM 464331.
Distal end of left femur, USNM 252307.
Horizon.—The stratigraphy is uncertain; preservation and
abundance suggest that most specimens are probably from the
Yorktown Formation, but the Pungo River Formation cannot
be ruled out because pseudodontorns were already diverse in
the early Miocene and late Oligocene in the North Atlantic.
Measurements (mm).—Femur:   Distal width, >33.
Remarks.—The coracoidal fragment is much larger than
that referred to the preceding species, and the humeral heads
articulate well with it, except for USNM 446497, which ap-
pears almost intermediate in size. The sternal portion of the co-
racoid is so large and massive as to suggest its placement here
rather than with the smaller species.
Pelagornis sp. 1 or Pelagornis sp. 2
Plate Wa-d.fih.j
Material.—The following material cannot at this point be
identified certainly with one or the other of the above species
and is referred only to the genus Pelagornis.
Rostral "tooth" (pseudotooth), USNM 464325; fragment of
mandible with "tooth," USNM 182106; distal end of right
mandible, USNM 425108; associated distal ends of right and
left mandibles, USNM 446494; right quadrate, USNM 446495
(height 45.6 mm); right pterygoid, USNM 425110 (length 40.1
mm, greatest anterior width 17.2 mm). Cervical vertebrae: ax-
es, USNM 275777, 446502, 464326; vertebral centra, USNM
250715, 425102, 425103; basal cervical vertebra, USNM
425101. Anterior portion of carina of sternum, USNM 464328
(depth of furcular facet 44.0 mm). Proximal end of left radius,
USNM 183512 (greatest diameter 22.4 mm). Left radiale,
USNM 446496 (greatest diameter 27.0 mm). Distal end of
right tibiotarsus lacking external condyle, USNM 446507; dis-
tal end of left tibiotarsus lacking internal and part of external
condyle, USNM 448913. Pedal phalanx, USNM 183506.
Also of questionable placement are the following scapulae:
anterior end of right scapula lacking much of acromion, USNM
464330 (greatest width 35+ mm), anterior end of left scapula
lacking much of acromion, USNM 425104 (greatest width 38.7
mm), and anterior portion of shaft of left scapula with part of
glenoid facet, USNM 425105. These are all of roughly the
same size, which is approximately the size of the largest Oli-
gocene pseudodontom known from South Carolina (K.I. War-
heit, pers. comm., 1998). This suggests that they should be re-
ferred to the larger species at Lee Creek Mine, but the two
scapulae that preserve the coracoidal heads do not articulate
well with the largest coracoidal fragment having a scapular fac-
et (USNM 446501, Pelagornis sp. 2), yet they fit nearly per-
fectly with the smaller one (USNM 464329, Pelagornis sp. 1).
Family Sulidae
(boobies and gannets)
The phylogeny and paleontology of the Sulidae have been
studied extensively by K.I. Warheit, who included fossils from
NUMBER 90
261
Lee Creek Mine in his investigations. Some discussion of fos-
sils may be found in his dissertation and elsewhere (Warheit,
1990, 1992), but most of his paleontological studies remain to
be published. Pending his revisionary study of this material,
we have set forth herein only a skeletal outline (with measure-
ments omitted) concerning the sulid faunas from Lee Creek
Mine based partly on Warheit's unpublished data and partly
on our own observations. Specimens listed follow Warheit's
identifications.
Genus Morus Vieillot
The modern Sulidae consists of the tropical boobies (Sula
Brisson and Papasula Olson and Warheit) and the temperate
gannets (Morus). The three living species of gannets, often
considered to form a superspecies, occur in the North Atlantic,
in southern Africa, and in New Zealand and along the southern
coast of Australia. Fossil taxa also are known from the North
Pacific. Although neontologists have frequently included
Morus in the genus Sula, the two are quite distinct osteologi-
cally, with Morus being the more derived genus (Warheit,
1990). The distinguishing characters of Morus are evident at
least as far back as the late early Miocene, which is argument
enough for recognizing the genus.
All fossil Sulidae from Lee Creek Mine and the Calvert For-
mation are referable to the genus Morus, which was much more
diverse in the North Atlantic in the past, with at least three con-
temporaneous species occurring sympatrically in both the mid-
dle Miocene and the early Pliocene.
Gannets are the most abundant fossil birds in the Calvert
Formation. For some time it has been known that at least three
species are represented in the fauna, and that despite their hav-
ing been originally referred to Sula, all are more closely relat-
ed to gannets (Olson, 1984). Thus, the three named taxa are
herein referred to Morus. All are smaller than any modem spe-
cies of Morus, and one, M. avitus (Wetmore), is smaller than
any living member of the family. These same three species
also occur at Lee Creek Mine, where they are known or as-
sumed to come from the Pungo River Formation. All are gen-
erally less pneumatic than the larger Pliocene species.
Of the three species of gannets from the early Pliocene, the
smallest, which is about the size of or slightly smaller than the
living Northern Gannet, Morus bassanus Linnaeus, is referred
to the species Morus peninsularis Brodkorb (1955), previously
known from the Bone Valley Formation in Florida. The other
two are new, as yet undescribed species, both larger than living
gannets. It is not known whether the three Pliocene species are
larger descendents of the three Miocene lineages or which of
the Pliocene species, if any, gave rise to modern gannets. The
Pliocene species all have pneumaticity well developed, in con-
trast to those from the Miocene.
Morus avitus (Wetmore), new combination
Sula (subgenus Microsula) avita Wetmore, 1938:22.
Material.—Left coracoid, USNM 177798; left coracoid
lacking sternal end, USNM 501510. Distal half of right humer-
us, USNM 178033. Proximal end of right ulna, USNM 501511.
Distal end of radius, USNM 210530. Left carpometacarpus
missing minor metacarpal, USNM 215722; proximal ends of
right carpometacarpi, USNM 183481, 215638; distal end of
right carpometacarpus, USNM 178186. Left femur, USNM
215761. Left tarsometatarsi, USNM 181029, 426057; distal
end of left tarsometatarsus, USNM 426063.
HORIZON.—Pungo River Formation inferred from similarity
to fossils from Calvert Formation.
Remarks.—A small amount of material exists that is insep-
arable from the type of Sula (Microsula) avita, from the Cal-
vert Formation of Maryland. Several elements (ulna, coracoid)
were collected by J.H. McLellan from spoil derived from units
4 and 5 of the Pungo River Formation. This was a tiny gannet,
much smaller than the smallest living member of the family.
Morus atlanticus (Shufeldt, 1915), new combination
Sula atlantica Shufeldt, 1915:62.
Material.—Distal end of left humerus, USNM 411963.
Proximal end of right ulna, USNM 426031; proximal ends of
left ulnae, USNM 302327, 368551, 412039; distal ends of right
ulnae, USNM 192574, 206512, 275806, 367103; distal ends of
left ulnae, USNM 177943, 215686, 241374. Left carpometac-
arpus missing minor metacarpal, USNM 193364; proximal end
of left carpometacarpus, USNM 257493; distal ends of left car-
pometacarpi, USNM 210439, 412056. Left femur, USNM
252310. Distal end of right tibiotarsus, USNM 368562; distal
end of left tibiotarsus, USNM 426068.
HORIZON.—Pungo River Formation inferred from similarity
to fossils from Calvert Formation.
Remarks.—The holotype of this species came from the
Kirkwood Formation in New Jersey, which is temporally
equivalent to the Calvert Formation, whence specimens insepa-
rable from the holotype have been collected. This species was
intermediate in size between M. avitus and M. loxostylus
(Cope), but there is probably some overlap in size with the lat-
ter (K.I. Warheit in litt., 1997).
Morus loxostylus (Cope, 1870)
Sula loxoslyla Cope, 1870:236.
Morus loxostyla [sic].—Brodkorb, 1963:259.
Material.—Right coracoid lacking sternal end, USNM
241426; right coracoid lacking most of both ends, USNM
367004. Distal ends of right humeri, USNM 366796, 411973;
distal ends of left humeri, USNM 181116, 215456. Proximal
end of right ulna, USNM 177935; proximal end of left ulna,
USNM 366936; distal end of right ulna, USNM 236836; distal
262
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
end of left ulna, USNM 367088. Proximal ends of radii,
USNM 412008, 426089; distal ends of radii, USNM 178055,
192075. Right tarsometatarsus, USNM 215476; left tarsometa-
tarsus, USNM 412010; distal end of right tarsometatarsus,
USNM 366715; distal ends of left tarsometatarsi, USNM
193002,412089,412094.
Horizon.—Pungo River Formation inferred from similarity
to fossils from Calvert Formation.
Remarks.—This fairly common form is about the size of
the modern Blue-footed Booby, Sula nebouxii Milne-Ed-
wards. The fossil material compares well with material from
the Calvert Formation of Maryland assigned by Wetmore
(1926) to Morus loxostylus, the holotype of which has been
lost. Study of the original illustration and description (K.I.
Warheit, pers. comm., 1997) indicates that it is reasonable to
assign the largest Calvert gannet to this species, as has been
done for material from the Calvert Formation of Delaware
(Rasmussen, 1998).
Morus peninsular is Brodkorb, 1955
PLATES \2h.l, \Sa,e,g,i,m,n
Material.—Right coracoids, USNM 412054, 426052; left
coracoids, USNM 367093, 412016, 412021, 426053, 501512,
501514; right coracoid lacking part of sternal end, USNM
308220, left coracoid lacking much of both ends, USNM
412042; sternal end of left coracoid, USNM 426054. Proximal
portions of left humeri, USNM 464323, 501514; distal end of
right humerus, USNM 215691; distal ends of left humeri,
USNM 215716, 411971, 411981. Proximal two-thirds of right
ulna, USNM 412017; proximal end of left ulna, USNM
412023; distal half of right ulna, USNM 412006. Left car-
pometacarpi missing minor metacarpals, USNM 412066,
426023; proximal end of left carpometacarpus, USNM 366806.
Left femora, USNM 177910, 412048. Right tarsometatarsus,
USNM 426061; left tarsometatarsus lacking much of proximal
end, USNM 275838; distal ends of left tarsometatarsi, USNM
179261,248510.
HORIZON.—Yorktown Formation (USNM 179261 probably
from the middle Yorktown as determined from foraminifera
and sedimentary characteristics of matrix).
Remarks.—The most abundant sulid at Lee Creek Mine is a
large gannet that appears to be identical to material from the
Bone Valley Formation described by Brodkorb (1955) as
Morus peninsularis, which was characterized as being some-
what smaller than the modern Northern Gannet, M. bassanus,
similar in size to or slightly smaller than either the Australian
Gannet, M. serrator (Gray) or the Cape Gannet, M. capensis
(Lichtenstein), but slightly larger than the Masked Booby, Sula
dactylatra Lesson.
Morus, undescribed species 1
Plates \2a-g,i,n, [3b,k,o
MATERIAL.—Associated Specimen: Partial skeleton con-
sisting of mandible (lacking symphysis), 3 cervical vertebrae,
proximal portions of right and left humeri, distal ends of left
ulna and radius, left ulnare, and proximal end of left car-
pometacarpus, USNM 181052.
Individual Elements: Left coracoid, USNM 464322; right
coracoid lacking much of sternal end, USNM 193086,412053.
Proximal half of right humerus, USNM 368548; distal ends of
left humeri, USNM 411966,411982,426011. Proximal ends of
right ulnae, USNM 321227, 412077, 426030; proximal ends of
left ulnae, USNM 366880, 412087, 426029; distal end of right
ulna, USNM 366883; distal end of left ulna, 412078. Proximal
end of radius, USNM 193019; distal ends of radii, USNM
411983, 412083. Proximal ends of right carpometacarpi,
USNM 412065, 412067; proximal ends of left carpometacarpi,
USNM 308197, 321241. Distal two-thirds of right tibiotarsus,
USNM 426069. Left tarsometatarsus, USNM 366904.
Horizon.—Yorktown Formation.
Remarks.—This is a large gannet, being intermediate in
size between Morus peninsularis and the following extremely
large species; it is larger than M. bassanus by roughly the same
amount as the latter is larger than M. capensis.
Morus, undescribed species 2
Plates \2j.m. 13c
Material.—Scapular ends of left coracoids, USNM
183499, 321253; sternal ends of left coracoids, USNM 366666,
412047. Proximal end of left humerus, USNM 426009; distal
end of right humerus, USNM 242374; distal ends of left hu-
meri, USNM 411951, 411987 Proximal end of left ulna,
USNM 215558; distal end of left ulna, USNM 183508. Distal
end of radius, USNM 177881. Right carpometacarpus missing
minor metacarpal and most of distal end, USNM 206346; prox-
imal end of right carpometacarpus, USNM 412062; distal end
of right carpometacarpus, USNM 256212.
Horizon.—Yorktown Formation.
Remarks.—This is a huge species, at least half again larger
than the largest living gannets (Morus).
Family Phalacrocoracidae
(cormorants)
Genus Phalacrocorax Brisson
Because cormorants have never been found in the Calvert
Formation, we assume that it is unlikely that any of the cormo-
rant fossils from Lee Creek Mine come from the Pungo River
Formation. Furthermore, the morphology of the Lee Creek cor-
morants does not differ greatly from that of modem species,
which would not be expected of taxa as old as middle Miocene.
NUMBER 90
263
Phalacrocorax wetmorei Brodkorb, 1955
Figure 7; Plate \4a,b,d,e,g,h,j,n,o,q,s,t
MATERIAL.—Associated Specimen:    Distal end of left ulna,
carpometacarpus, and radiale, USNM 179307.
Individual Elements: Mandibular articulation, USNM
215700. Anterior fragment of sternum, USNM 446468. Right
coracoids, USNM 242346, 446444-446450; scapular ends of
right coracoids, USNM 192013, 192922, 192944, 206303,
206482, 206586, 248565, 302344, 366352, 366411, 446451,
446452; scapular ends of left coracoids, USNM 177761,
192868, 193279, 193306, 215467, 215752, 215842, 241407,
308186, 446454^446464; sternal ends of right coracoids,
USNM 256244, 446453; sternal ends of left coracoids, USNM
178179,250762. Anterior end of right scapula, USNM 242361.
Proximal end of right humerus, USNM 501515; proximal ends
of left humeri, USNM 446409, 446410, 446469; distal ends of
right humeri, USNM 177745, 215818, 366340, 366446,
446407, 446408; distal ends of left humeri, USNM
446411^446413. Proximal ends of right ulnae, USNM 215745,
252320, 256265, 302380, 446397-446399; proximal ends of
left ulnae, USNM 177846, 181088, 250701, 367019; distal
ends of right ulnae, USNM 177859, 192491, 206436, 210482,
236825, 250776, 250821, 252428, 321250, 446400-446404;
distal ends of left ulnae, USNM 177856, 177863, 178099,
192982, 206613, 215636, 215672, 241428, 242352, 308194,
366919, 446405, 446406. Proximal end of radius, USNM
446467. Right carpometacarpus, USNM 446391; left car-
pometacarpus, USNM 446394; proximal ends of right car-
pometacarpi, USNM 306343, 366445, 367139, 446392; proxi-
mal ends of left carpometacarpi, USNM 192942, 206472,
215650, 242336, 242370, 446395, 446396; distal ends of right
carpometacarpi, USNM 178204, 446393; distal end of left car-
pometacarpus, USNM 206534. Alar phalanges, USNM
193068, 206542. Synsacral fragments, USNM 210440,
308191, 446465. Right femora, USNM 242205, 302304,
446414,446415; left femora, USNM 179250, 367159,446419,
446420; proximal ends of right femora, USNM 366692,
446416; proximal ends of left femora, USNM 179291, 446421,
446422; distal ends of right femora, USNM 215542, 248562,
368478, 446417, 446418; distal ends of left femora, USNM
177938, 192935, 248571, 250748, 366950, 446423, 446424.
Right tibiotarsus, USNM 446425; distal ends of right tibiotarsi,
USNM 177882, 181115, 446426, 446427; distal end of left ti-
biotarsus, USNM 446428. Right tarsometatarsi, USNM
193098, 275785, 366903, 446429; left tarsometatarsi, USNM
210425, 215429, 446435^146437; proximal ends of right tar-
sometatarsi, USNM 193129, 215815, 252302, 257499,
367030, 368556, 446430^146432; proximal ends of left tar-
sometatarsi, USNM 242364, 446438-446443; distal ends of
right tarsometatarsi, USNM 181065, 446433, 446434; distal
ends of left tarsometatarsi, USNM 178184, 179229, 179262,
206354,215765, 248504. Pedal phalanges, USNM 192458.
Horizon.—Yorktown Formation.
Additional Material Examined.—Bone Valley,
Florida: Right coracoid, UF 95488. Right femur, UF
101946. Distal end of right tibiotarsus, UF 65772. Right tar-
sometatarsus, UF 94550.
Measurements.—See Table 7. The common species of
cormorant at Lee Creek Mine overlaps broadly in size with
Phalacrocorax wetmorei Brodkorb (1955) from the upper
Bone Valley Formation but tends to average smaller. When
skeletal measurements of the two modem subspecies of Dou-
ble-crested Cormorant (P. auritus auritus Lesson, P. a. florida-
nus Audubon) from the Atlantic coast of North America are
plotted with those of the fossil cormorants from Lee Creek
Mine and Bone Valley, all populations show broad overlap in
most measurements. Two measurements of the humerus (width
of the proximal end and depth of the head), however, separate
the fossil populations from the modem ones (Figure 7).
Remarks.—Phalacrocorax wetmorei was described by
Brodkorb (1955) from the Bone Valley Formation as a new
species of cormorant similar in size to P. auritus. Comparisons
of humeri and tarsometatarsi of cormorants of this size class
from Lee Creek Mine with those of Bone Valley revealed no
osteological differences.
Detailed comparisons were made between the Pliocene fos-
sils and the European Shag, P. aristotelis Linnaeus, a species
of somewhat similar size that occurs along the coasts of the
eastern Atlantic and Mediterranean. Both fossil populations,
however, are decidedly more similar to P. auritus than to P. ar-
istotelis in most qualitative characters, as well as in size. Most
Lee Creek and Bone Valley specimens of P wetmorei differ
from P. auritus in having the posterior rim of the medial
condyle of the tarsometatarsus forming an angle with the shaft,
rather than being confluent with it; the accessory distal fora-
men of the tarsometatarsus positioned nearer the primary distal
foramen; the bicipital crest of the humerus less laterally ex-
panded (in some P. wetmorei); and the ventral tubercle of the
humerus less laterally produced. In these four characters the
fossils seem more like P. aristotelis, whereas in all other re-
spects they are more similar to P auritus. Although it seems
likely that P. wetmorei is only a temporal manifestation of P.
auritus, which latter may date back at least to the earliest Pleis-
tocene of Florida (Emslie, 1998), we have used the former
name for the Lee Creek Mine fossils pending future revisionary
work.
Phalacrocorax, large species
PLATE \4c,fii,k-m,p,r,u,v
Material.—Nearly complete right coracoid, USNM
177880; scapular end of right coracoid, USNM 242335. Distal
end of right humerus, USNM 215774. Proximal end of right ra-
dius, USNM 179256. Right femur, USNM 177791. Proximal
ends of left tibiotarsi, USNM 177901,215597; distal end of left
tibiotarsus, USNM 177787. Distal end of left tarsometatarsus,
USNM 430872.
264
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Additional Material Examined.—Bone Valley,
Florida:   Right tibiotarsus, UF 67935.
HORIZON.—Yorktown Formation.
Measurements.—See Table 7.
Remarks.—These bones are from one or more species of
cormorant considerably larger than the preceding. The only
large cormorant in the North Atlantic today is the Great Cor-
morant, Phalacrocorax carbo Linnaeus. Compared with a
large male of that species from the Netherlands (USNM
555669), the fossil femur is larger, but the shaft is slightly less
robust and curved. One of the tibiotarsi proximal ends is not
quite as large as that of P. carbo, but the fibular crest is longer,
extending farther proximally. The other is poorly preserved and
is considerably smaller. The distal ends of the tibiotarsi and tar-
sometatarsi are larger and have much heavier shafts than they
do in the modern species. The fossil pectoral elements are all
either slightly or much smaller than in P carbo.
The fossil cormorants of North America are much in need of
revision, and many of the described taxa, which have been
summarized by Emslie (1995b), are known from inadequate
material. On the other hand, Emslie (1995b) described a new
species, Phalacrocorax filyawi, from abundant material from a
late Pliocene death assemblage in central Florida. This was re-
lated to the large Pacific cormorants (Brandt's Cormorant, P.
penicillatus (Brandt); the extinct Pallas's Cormorant, P. perspi-
cillatus Pallas; and the Flightless Cormorant, P. harrisi Roths-
child) and represents a lineage that must have invaded the At-
lantic prior to the closing of the Panamanian seaway. It would
have existed in a region of cold upwelling that was disrupted
after the emergence of the Panamanian isthmus, causing the ex-
tinction of the cormorant.
Another large cormorant, Phalacrocorax idahensis (Marsh,
1870), has been reported from late Pliocene and Pleistocene de-
posits in Idaho and Florida, although there is some doubt that
all the material ascribed to it belongs to the same species
(Emslie, 1995b, 1998). Emslie (pers. comm., 1997) made com-
parisons of the large cormorant bones from Lee Creek Mine,
noting that the femur compared well with P. idahensis, the co-
racoids with P. filyawi, and the remaining bones with neither of
those species. Given the amount of intraspecific variation in
some modern cormorants, however, it is highly unlikely that
the large cormorant material from Lee Creek Mine would be
referable to more than two species.
s
s
13
E
•a
o
h
a
3
U
B
3
m
25
24
23
22
21
20-
19
Bone Valley
P. wetmorei
Lee Creek P. cf. wetmorei
I
~
6.0    6.5    7.0   7.5     8.0    8.5    9.0     9.5   10.0 10.5   11.0 11.5   12.0  12.5
Humerus head depth (mm)
Figure 7.—Bivariate scatter plot of depth versus width of humerus head for cormorants: Lee Creek Mine Phala-
crocorax wetmorei. Bone Valley P. wetmorei, and two Atlantic coast subspecies of Double-crested Cormorant
(P. auritus auritus and P. a. floridanus).
NUMBER 90
265
TABLE 7.—Measurements (mm) for recent and fossil cormorants (Phalacrocorax): P. wetmorei and P. large spe-
cies from the Lee Creek Mine (LC); P. wetmorei from the upper Bone Valley Formation (BV), and modem spec-
imens of P. auritus auritus (7 males, 7 females). Measurements are in list form when number of specimens (n)<3
for fossil species. (s=standard deviation.)
Element		P. wetmore	(LC)		P. large sp. (LC)		P. wetmorei (BV)			Pa.	auritus (n= 14)	
	n	Range	Mean	s		n	Range	Mean	s	Range	Mean	s
Coracoid												
Length	-	61.3,63.5	-	-	-	4	59.3-67.9	64.4	2.6	-	64.3	2.8
Glenoid facet												
Length	-	11.3,11.7	-	-	13.0	4	12.0-12.6	12.4	0.3	11.5-13.3	12.4	0.5
Carpometacarpus												
Length	3	67.8-73.5	69.9	3.1	-	-	-	69.6	-	63.8-73.3	69.0	2.5
Proximal depth	10	13.4-15.3	13.9	0.7	-	24	13.1-14.2	13.7	0.4	12.7-14.1	13.3	0.4
Distal depth	5	4.4-4.8	4.7	0.2	-	8	4.4-5.4	4.9	0.3	4.6-5.4	5.0	0.2
Distal width	5	7.1-7.5	7.3	0.2	-	9	7.2-7.8	7.4	0.2	7.1-7.7	7.4	0.2
Humerus												
Proximal width	-	22.0	-	-	-	16	21.5-24.8	23.2	0.9	21.0-24.6	22.9	1.0
Head depth	-	6.3, 6.7	-	-	-	16	6.3-7.3	7.0	0.3	10.5-12.3	11.1	0.5
Shaft depth	-	6.0	-	-	-	18	5.4-7.0	6.2	0.3	6.0-7.7	6.8	0.4
Distal width	7	13.2-15.0	14.2	0.7	-	35	14.9-16.8	15.6	0.4	15.4-16.9	15.9	0.5
Distal depth	8	9.8-11.0	10.4	0.4	-	34	9.4-11.1	10.3	0.4	10.0-11.9	10.9	0.6
Ulna												
Proximal width	6	10.8-12.4	11.4	0.7	-	26	10.6-12.8	11.5	0.4	11.4-12.7	11.9	0.4
Proximal depth	6	10.0-11.2	10.7	0.5	-	26	10.5-12.3	11.6	0.4	11.5-13.5	12.5	0.6
Femur												
Length	4	50.0-56.6	53.9	3.2	62.0	9	53.3-59.2	55.5	1.6	49.5-58.7	54.9	2.4
Head depth	7	5.9-7.0	6.6	0.4	8.0	16	6.3-7.2	6.8	0.3	6.4-7.6	7.0	0.3
Proximal width	6	14.2-17.5	15.3	1.4	17.9	19	14.5-16.7	15.4	0.6	15.4-17.4	16.3	0.6
Shaft width	12	5.7-7.0	6.2	0.3	7.9	17	5.9-7.0	6.5	0.3	5.6-7.1	6.5	0.4
Distal width	10	13.2-16.4	15.0	1.1	-	17	14.4-16.0	15.1	0.5	14.9-16.6	15.7	0.6
Tibiotarsus												
Shaft width	_	6.0	-	-	-	5	6.6-7.2	7.0	0.3	6.6-7.4	6.9	0.2
Shaft depth	-	4.8	-	-	-	5	5.0-5.2	5.1	0.1	4.8-6.5	5.4	0.5
Tarsometatarsus												
Length	5	59.8-66.8	63.3	2.9	-	5	60.3-69.2	64.6	3.7	55.2-65.0	62.0	2.4
Proximal width	10	11.5-13.4	12.6	0.6	-	22	12.1-14.1	13.0	0.5	12.0-13.6	12.8	0.4
Order Charadriiformes
(shorebirds, gulls, and auks)
Family Stercorarhdae
(skuas and jaegers)
The skuas and jaegers constitute a small group of predaceous
relatives of gulls, the humerus of which appears to be primitive
(Olson, 1985d) within the suborder Lari (as is also that of the
noddies (Anous) and skimmers (Rynchops)). The jaegers, Ster-
corarius, comprise three species that breed entirely in the Arc-
tic, and the skuas, Catharacta, consist of a complex of taxa that
breed at high latitudes in the Southern Hemisphere, with the
exception of the Great Skua, C. skua Briinnich, which breeds
on islands in the eastern North Atlantic, having recently ex-
panded into the Barents Sea (Cohen et al., 1997:188). We have
retained the two genera mainly to promote comprehension as
we can find no osteological differences between the two
groups, Catharacta merely being an enlarged version of Ster-
corarius as far as the skeleton is concerned. Various authors,
with the perspectives offered by both morphology and behav-
ior, have previously suggested merging these two genera (see
references cited in Braun and Brumfield, 1998:998).
Recent molecular and other evidence has made the tradition-
al view of relationships within this family the object of consid-
erable contention (Cohen et al, 1997; Braun and Brumfield,
1998). The most unexpected result was the apparent closer re-
lationship of the Pomarine Jaeger (Stercorarius pomarinus
(Temminck)) to Catharacta in general, and to the Great Skua
(C. skua) in particular (Cohen et al., 1997). This, combined
with the proposed very recent origin of C. skua in the North At-
lantic (Andersson, 1973), led Cohen et al. (1997) to suggest
three different possible hypotheses of origin of S. pomarinus,
including hybridization between Catharacta and one of the
other species of Stercorarius.
We do not intend to dwell on the specifics of these recent
studies but wish instead to elucidate what bearing the fossil
record may have on the issues. At Lee Creek Mine there are
scarce fossils assignable to all three size classes of modern
jaegers, including S. pomarinus. Although there are some
slight differences from modem species in some of the bones,
the similarities are greater, and all of the fossils are assumed
to have come from the Yorktown Formation. There also are a
266
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
few bones, including a diagnostic distal end of a tarsometatar-
sus, that clearly belong to a much larger species the size of
Catharacta.
The last is not necessarily an indication of a breeding popu-
lation of skuas in the North Atlantic at that time. Given the
propensity of the modem Southern Hemisphere forms of Ca-
tharacta to wander across the equator and the presence at Lee
Creek Mine of other Southern Hemisphere vagrants, especial-
ly among the Procellariidae, it is just as likely that bones of
Catharacta at Lee Creek Mine represent strays from the south,
particularly as skuas and jaegers commonly follow flocking
shearwaters.
Nevertheless, the fossil record indicates that the diversity of
Stercorariidae in the North Atlantic was just as great nearly
five million years ago as it is today. The size range of Sterco-
rarius that existed then appears to encompass three species,
and we assume that these are the same three lineages represent-
ed by the modem species. Although it is still quite possible that
the North Atlantic Great Skua (Catharacta skua sensu stricto)
may be of much more recent origin, the fossil record suggests
that a much greater period of time may need to be allowed for
the point of origination of S. pomarinus.
Genus Catharacta Briinnich
Catharacta sp.
Plate \5a,c,d
Material.—Distal end of left ulna, USNM 366602. Proxi-
mal end and shaft of left carpometacarpus, USNM 430889.
Left tarsometatarsus lacking most of both ends, USNM
430892; distal end of left tarsometatarsus, USNM 183482.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements.—See Table 8.
Remarks.—The above elements are from a large stercorari-
id the size of the Great Skua, Catharacta s. skua Briinnich, or
the South Polar Skua, C maccormicki (Saunders).
The distal portion of the tarsometatarsus from Lee Creek
Mine differs from that of Catharacta skua and C. maccormicki
in having a smaller, rounder distal foramen, especially notable
in posterior view. The metatarsal facet is more deeply excavat-
ed in the fossil and extends farther distally. In posterior view,
the external edge of trochlea III extends farther proximally in
the fossil. In anterior view, there is no distinct furrow proximal
to the internal intertrochlear notch. The carpometacarpus is as
large and heavy as that in large female specimens of C. mac-
cormicki, and the preserved portion is similar to modern spe-
cies examined. The ulna is from a very large skua, larger than
C. maccormicki, with an especially heavy shaft, but the speci-
men is poorly preserved.
These cold-water birds occur mainly in the Southern Hemi-
sphere, with the isolated Great Skua being the only form to
breed in the Northern Hemisphere. Its breeding is restricted to
the subarctic of the eastern North Atlantic, but it winters regu-
larly in the western North Atlantic, virtually never being found
close to land. The South Polar Skua (C. maccormicki) occurs
rarely but regularly in the western North Atlantic in the warmer
months only.
The material from Lee Creek Mine provides the first fossil
record of Catharacta from the North Atlantic, but its scarcity
makes it equivocal as to whether this constitutes evidence for
birds of this group having established breeding colonies north
of the equator by that time. As discussed above, the possibility
of the fossils having originated in vagrants from the south is
perhaps just as likely.
Genus Stercorarius Brisson
Stercorarius aff'. pomarinus (Temminck)
Plate \5f,h.j.k,m,o
Material.—Left coracoid lacking sterno-coracoidal pro-
cess, USNM 430891. Partial distal end of right humerus,
USNM 192818; distal end of left humerus, USNM 366015.
Distal third of left ulna, USNM 430890.
Horizon.—Uncertain, probably Yorktown Formation.
Measurements.—See Table 8.
Remarks.—The shaft of the coracoid is longer than it is in
the Pomarine Jaeger, Stercorarius pomarinus. In other respects
the fossil material agrees with the modern species. Emslie
(1995b:324) reported a coracoid of "Stercorarius sp." from the
late Pliocene of Florida that was considered likely to be an un-
described species larger than S. pomarinus but smaller than any
species of Catharacta. He also noted differences between that
specimen and USNM 430891.
Stercorarius aff. parasiticus (Linnaeus)
Plate \5q,r,t,u,z
Material.—Distal ends of right humeri, USNM 178064,
460819. Proximal end of right carpometacarpus, USNM
193269.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements.—See Table 8.
Remarks.—The distal end of the humerus has the shaft
much more flattened in medial view and has a deeper pit in
the brachial depression than in 15 Parasitic Jaegers (Sterco-
rarius parasiticus) examined. Larine ulnae (USNM 237149,
237176) that resemble Stercorarius and are the size of S. par-
asiticus (Plate 15w,jc) also have been recovered in the Calvert
Formation.
Stercorarius aff. longicaudus Vieillot
Plate \5bb,cc,eeff,hh
Material.—Distal ends of left humeri, USNM 430893,
448914. Proximal three-fourths of left carpometacarpus,
USNM 460818.
NUMBER 90
267
TABLE 8.—Measurements (mm) for recent and fossil skuas (Catharacta) and jaegers (Stercorarius) from Lee
Creek Mine. Measurements are in list form when number of specimens («) <5 and for fossil samples. (r=standard
deviation.)
Element	C. skua («=4)	C. sp.	C. maccormicki («=17)	S. pomarinus («=7)	S. aff. pomarinus	5. parasiticus («=16)	5. aff. parasili cus (n=2) Range	S. longicaudus (n=9)	S aff
			Range   Mean   s	Range    Mean   s		Range   Mean   s		Range    Mean    s	longicaudus
Coracoid									
Median length	51.0,53.4, 56.5, 57.2	-	47.7-53.5 51.2   1.7	38.7^43.0 40.8   1.5	44.7	32.8-36.5 34.4    1.2	-	28.8-32.3   30.2   1.0	-
Humerus									
Distal width	18.2, 19.3, 19.7,20.5	—	17.0-19.7 18.2   0.6	13.6-15.3  14.5  0.6	15.3	12.4-13.6 13.0   0.4	12.4, 13.0	10.4-11.8   11.0   0.4	11.4
Ulna									
Distal diagonal	11.6,12.9, 12.9, 14.0	-	11.3-13.3 12.4  0.6	9.3-10.6  10.0  0.5	10.7	8.4-9.2     8.9   0.3	-	7.1-8.2       7.8   0.3	-
Carpometacarpus									
Proximal width	15.6, 16.8, 16.9, 17.3	16.0	14.5-16.8 15.6  0.6	12.1-13.6  13.0  0.6	-	11.1-12.2  11.5   0.3	11.7	9.5-10.9    10.1   0.4	-
Tarsometatarsus									
Distal width	12.3, 12.9, 12.9, 14.9	11.2+	11.3-13.0  12.2   0.5	8.2-9.0      8.7   0.3	-	6.7-7.8      7.2   0.3	-	6.1-6.8       6.5   0.2	-
HORIZON.—Uncertain, probably Yorktown Formation.
MEASUREMENTS.—See Table 8.
REMARKS.—These humeri are indistinguishable from the
modem Long-tailed Jaeger, Stercorarius longicaudus, a regular
migrant in the western Atlantic.
Family Laridae
(gulls and terns)
Genus Larus Linnaeus
Larus aff. argentatus Pontoppidan
PLATE \6a,c,d,f,h
Material.—Portion of right mandibular ramus, USNM
430931. Proximal end of left humerus, USNM 366923; distal
half of left humerus, USNM 366896. Proximal ends of right ul-
nae, USNM 430896, 430897, 430903; distal end of right ulna,
USNM 430905. Proximal end of right carpometacarpus,
USNM 430895.
MEASUREMENTS (mm).—Humerus: Proximal width, 20.3;
distal width, 16.1.
Ulna:   Proximal width, 12.7,13.7, 14.9+; distal width, 10.5.
Carpometacarpus:    Proximal width, 15.0, 15.7.
HORIZON.—Yorktown Formation.
Remarks.—The above material represents a gull the size of
the modern Herring Gull, Larus argentatus. Emslie
(1995b:324) referred the two humeral fragments listed above to
his new species Larus perpetuus, from the late Pliocene of
Florida. The holotype of that species is a complete humerus
with a length of 107.0 mm and a distal width of 14.2 mm,
whereas the material from Lee Creek Mine indicates a larger
species, within the lower size range of Larus argentatus, and
from which we can detect no significant differences.
Larus aff. delawarensis Ord
PLATE \7a,c,e,h,j,m,p,q
Larus elmorei Brodkorb, I953b:94.
Material.—Associated left coracoid lacking sternal end
and fragment of shaft of left humerus, USNM 215592. Scapu-
lar halves of right coracoids, USNM 430914, 460820; shaft of
right coracoid, USNM 430915. Right humerus lacking most of
both ends, USNM 181025; proximal portions of right humeri
lacking much of proximal ends, USNM 430911, 460821; par-
tial proximal end of left humerus, USNM 460822; distal ends
of right humeri, USNM 192869, 242326, 250678, 321294,
366791, 367136, 430912, 430913, 460826, 460827; distal ends
of left humeri, USNM 206408, 242184, 275819, 366791,
430907^130910,460823^160825. Proximal third of right ulna,
USNM 430918; proximal ends of left ulnae, USNM 430900,
430917; distal ends of right ulnae, USNM 308228, 430904,
430906, 460830, 460831; distal ends of left ulnae, USNM
366295, 366651, 430901, 430902, 460832. Right carpometac-
arpus lacking minor metacarpal, USNM 460833; proximal half
of right carpometacarpus, USNM 256349. Distal end of right
tibiotarsus, USNM 464293; distal end of left tibiotarsus,
USNM 430848. Distal end of right tarsometatarsus lacking tro-
chleae II and IV, USNM 178070; distal end of left tarsometa-
tarsus, USNM 236892.
Horizon.—Yorktown Formation.
Additional Material Examined.— Cobham Wharf
James River, Surrey County, Virginia: Distal third of left hu-
merus, USNM 237211. Lower Yorktown Formation, 25 ft (7.6
m) above beach. Collected by Warren Blow, received 1965.
Bone Valley Formation, Florida: Distal ends of right hu-
meri, USNM 447048, 447049. Proximal half of left ulna, UF
61951. Proximal half of left carpometacarpus, USNM 447047.
268
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Measurements (mm).—Humerus: Distal width,
mean=13.6, standard deviation (s)=0.63, range= 12.9-14.8,
n=9.
Ulna: Proximal width, 10.5, 11.2, 11.9; distal width,
mean=9.1,i=0.48,range=8.4-9.7, «=8.
Carpometacarpus: Length, 57.4; proximal width, 12.0;
distal diagonal, 7.4.
Tibiotarsus:    Distal width, 7.5, 8.2.
Remarks.—These elements are from a gull of the same size
and general morphology as Larus elmorei Brodkorb (1953b)
from Bone Valley (Plate llfg.k.o), thus approximating the
modem Ring-billed Gull, L. delawarensis.
Larus aff. atricilla Linnaeus
Plate 16/,/.«
Material.—Shaft of left coracoid, USNM 192102. Distal
ends of right humeri, USNM 430921, 430922, 464292,
464299; distal ends of left humeri, USNM 215622, 367112,
430920. Distal two-thirds of right ulna, USNM 366451. Right
carpometacarpus missing minor metacarpal, USNM 460828.
Horizon.—Yorktown Formation.
MEASUREMENTS (mm).—Humerus: Distal width, 10.4,
11.0, 11.0, 11.3, 11.5, 11.6, 11.7.
Ulna:    Distal width, 7.8.
Carpometacarpus:    Length, 54.1; proximal width, 11.0.
Remarks.—These specimens, indistinguishable from the
Laughing Gull, Larus atricilla, indicate a species larger than
the Franklin's Gull, L. pipixcan Wagler; Black-headed Gull, L.
ridibundus Linnaeus; or Sabine's Gull, L. (Xema) sabini Sab-
ine, and smaller than L. delawarensis or the Royal Tern, Ster-
na maxima Boddaert. The carpometacarpus is similar in size
to that of 5. maxima but differs from it in having the alular
metacarpal with the extensor attachment more rugose and less
slanted.
Larus aff. minutus Pallas
Plate ]6v,w,y,z,bb
Material.—Left humerus lacking most of proximal end,
USNM 430916; partial distal end of right humerus, USNM
430924; distal ends of left humeri, USNM 430923, 464337.
Right ulna, USNM 460817; distal end of left ulna, USNM
464338.
HORIZON.—Yorktown Formation.
Measurements (mm).—Humerus: Distal width, 7.7, 8.2,
8.6.
Ulna: Length, 61.8+; proximal width, 6.9; distal diagonal,
5.4.
Remarks.—The virtually complete ulna is almost indistin-
guishable from that of the Little Gull, Larus minutus. The fos-
sil has the distal end less rotated internally than it is in modem
L. minutus. The Lee Creek ulna and those of modem L. minut-
us differ from North American species of Sterna of similar
size as follows: in the former, the prominence for the anterior
articular ligament juts farther internally; the distal edge of the
external cotyla is smoothly continuous with the shaft, not
squared; the shaft is not swollen just proximal to the distal end
so that the carpal tuberosity is more distinct from the shaft; the
anconal edge of the external tuberosity is less flared; and there
is no distinct pit proximal to the internal condyle, but instead a
ridge extends from this area to the carpal tuberosity. The fossil
ulna and that of L. minutus differ from the Black Noddy,
Anous minutus Boie, in having a straighter shaft from internal
view; having the external cotyla more flared externally; and
lacking a strongly shelf-like internal edge of the proximal ra-
dial depression.
The Little Gull is essentially an Old World species, although
it has recently begun nesting in North America. As a result of
this recent colonization, the species now regularly occurs dur-
ing the nonbreeding season in North Carolina, where the first
record was in 1971 (Lee, 1995:147), and elsewhere in eastern
North America.
Larus magn. ridibundus Linnaeus
Plate 16/?
MATERIAL.—Proximal half of left humerus lacking internal
tuberosity, USNM 210461.
HORIZON.—Yorktown Formation.
MEASUREMENTS.—No standard measurements possible.
Remarks.—The lack of extension to the median crest distal-
ward along the shaft shows this specimen to be a gull rather
than a tern. It differs from the slightly smaller Larus sabini in
having a less rounded bicipital crest. This specimen is similar
in size to both L. ridibundus and L. pipixcan; we cannot distin-
guish between these species on the basis of the proximal end of
the humerus. The ulna and radius of a gull of about this size
was reported from the late Miocene Big Sandy Formation of
Arizona (Bickart, 1990).
Larus sp.
Plate 16r,/
Material.—Scapular half of right coracoid, USNM
430834.
Horizon.—Pungo River Formation. Collected from Pungo
River spoil pile (fide R. Purdy, Smithsonian Institution).
Measurements (mm).—Length from head to distal rim of
scapular facet, 11.0; depth through head, 8.9; length and width
of glenoid facet, 7.6 x 4.7.
Remarks.—This specimen lacks the pneumaticity under the
furcular facet found in other gulls and thus resembles the Ivory
Gull, Larus (Pagophila) eburnea Phipps. Perhaps this is a
primitive feature, retained among living gulls only in L. ebur-
nea, that may have been characteristic of most or all gulls in
the early middle Miocene.
NUMBER 90
269
Genus Sterna Linnaeus
Sterna aff. maxima Boddaert
Plate\6dd
MATERIAL.—Proximal end of right carpometacarpus,
USNM 215643; proximal end of left carpometacarpus, USNM
430898.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Proximal width, 10.8, 11.9.
REMARKS.—These specimens differ from Larus atricilla and
are similar to the Royal Tern, Sterna maxima, in having the ex-
tensor attachment of the alular metacarpal strongly slanted and
in lacking the pronounced rugosity of L. atricilla. The Royal
Tem is a common species in coastal environments in eastern
North America and breeds in North Carolina today.
Sterna aff. nilotica Gmelin
Plate \6ff
Material.—Right carpometacarpus lacking minor metacar-
pal, USNM 495588.
HORIZON.—Uncertain, probably Yorktown Formation.
Measurements (mm).—Length, 37.8.
Remarks.—This specimen is recognizable as a tem by the
longer and more slender alular metacarpal and by having the
carpal trochlea more squared in outline than it is in Larus. It is
too small for the Sandwich Tem, Sterna sandvicensis Latham,
or for any of the tem species larger than that, and it is too large
for any North Atlantic species except the Gull-billed Tern,
Sterna nilotica, with which it agrees very closely. The fossil is
slightly smaller than the comparative modem material avail-
able to us, but this series of three modem skeletons is insuffi-
cient to determine the amount of size variation in S. nilotica.
The Gull-billed Tem is a nearly cosmopolitan species that oc-
curs during the breeding season along most of the eastern coast
of North America, including North Carolina.
Family Alcidae
(auks and puffins)
Auks are by far the most abundantly represented birds at Lee
Creek Mine both in numbers of specimens and in individuals.
Thousands of fossil bones, representing no fewer than 11 spe-
cies, have been collected. Three skeletal elements are the most
commonly found: the humerus, ulna, and coracoid. We have
examined thousands of specimens just of these elements. By
contrast, elements of the pelvic limb are scarce, and portions of
the skull and mandible are decidedly rare. Greatly compound-
ing the difficulties of sorting and identifying the alcid material
is its fragmentary nature and the fact that most of the taxa
present are the product of a radiation from a single basic stock,
so that there are very few qualitative differences between spe-
cies in the wing elements.
A further complication is the apparently great intraspecific
variation in size. We know from the modern Common Murre,
Uria aalge (Pontoppidan), and Thick-billed Murre, U. lomvia
(Linnaeus), that morphological differences between sibling
species may be very subtle (Spring, 1971), and if such pairs of
sibling species occur in the fossil record, as seems probable,
they would be very difficult to distinguish. At the same time,
they would increase the amount of variation observed within a
size class.
Intraspecific size variation in modem alcids may be correlat-
ed with latitude or with oceanic environment, with larger indi-
viduals occurring in colder regions, as in the Atlantic Puffin,
Fratercula arctica (Linnaeus), and the Great Auk, Pinguinus
impennis (Moen, 1991; Bumess and Montevecchi, 1992). If the
Lee Creek Mine sample consists in part of wintering birds from
different parts of a species' range, this would increase the vari-
ability within species and contribute further to the difficulty of
separating one species from another.
In spite of the difficulties, it has been possible to identify a
minimum of 11 species of auks from Lee Creek Mine, nine of
which are thought to be from the Yorktown Formation and
presumably would have been contemporaneous. Our estimate
of four species in the great radiation of Alca is almost certain-
ly too low, and if there were sibling species of the same gen-
eral size and if more taxa are included at the high and low
ends of the size variation, as we suspect, then the number of
species of Alca might well double. The fossil record of alcids
at Lee Creek Mine is so extensive that the absence of certain
taxa, such as Uria Brisson and Cepphus Pallas, must be con-
sidered as reflecting reality rather than being a product of
sampling bias.
The compatibility analysis of the family by Strauch (1985)
and the phylogenetic analysis by Chandler (1990b) were con-
sulted, but many of the conclusions in the latter unpublished
work seem untenable, and we have not considered them fur-
ther. Both the American Ornithologists' Union (1998) and
Strauch (1985) divide the Alcidae into tribes while omitting
any division at the subfamilial level. Because there are no crite-
ria for determining whether characters are of subfamilial or
tribal value, the next level for grouping genera below the fami-
ly level is the subfamily, so we list the subdivisions of the Al-
cidae at that level.
Subfamily ALCINAE
(auks)
This subfamily has usually been considered an Atlantic radi-
ation and includes the Dovekie (Alle), the murres (Uria), and
the auks (Alca, Pinguinus, and fossil relatives). Rather unex-
pectedly, however, the genus Uria, at least in its modem as-
pect, appears to have originated in the Pacific, as it is entirely
absent at Lee Creek Mine and in all other Atlantic deposits that
have yielded alcids older than Pleistocene. The only fossil that
is truly referable to Uria that has been discovered so far in the
270
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
Atlantic is the type of U. affinis (Marsh, 1870), which is only
about 12,000 years old (see Ray and Spiess, 1981), whereas
two species of Uria have been named from the late Miocene of
California (Howard, 1981, 1982). Thus, despite its similarities
in plumage to Alca, the genus Uria appears to have had a long,
separate history in the Pacific and is probably only distantly re-
lated to Alca.
The genus Miocepphus Wetmore, 1940, known from the
Chesapeake Group in Maryland and Virginia, as well as from
Lee Creek Mine, has nothing to do with the genus Cepphus
(see Howard, 1978; Olson, 1985d:184), but it is closely related
to and possibly ancestral to the Alca radiation.
Genus Miocepphus Wetmore, 1940
Miocepphus mcclungi Wetmore, 1940
Material.—Right coracoids, USNM 460810, 495602. Left
humeri, USNM 495597, 495599; proximal ends of right hu-
meri, USNM 177884, 192467; proximal ends of left humeri,
USNM 192775, 495598; distal ends of right humeri, USNM
210424, 210526; distal ends of left humeri, USNM 178052,
250674.
HORIZON.—Pungo River Formation inferred from similarity
to fossils from Calvert Formation.
MEASUREMENTS.—Omitted pending revision of genus.
Remarks.—Wetmore (1940) described a new genus and
species of alcid, Miocepphus mcclungi, from a right humerus
collected in the Calvert Formation of Maryland. Another hu-
merus from the same locality was later referred to this species
(Wetmore, 1943b), and we now have on hand several addi-
tional specimens of various elements from the Calvert Forma-
tion in both Maryland and Virginia. The specimens listed
above from Lee Creek Mine are the size of Miocepphus and
compare very favorably with the specimens of M. mcclungi
from the Calvert Formation, although the stratigraphic posi-
tion of the Lee Creek specimens was not otherwise deter-
mined.
Miocepphus, undescribed species
Material.—Left humerus, USNM 302324; right humeri
missing heads, USNM 430948, 495584, 495600; proximal end
of right humerus, USNM 192879; proximal ends of left hu-
meri, USNM 178015, 192691, 192698; distal ends of right hu-
meri, USNM 215499, 242316; distal end of left humerus,
USNM 242178. Distal end of radius, USNM 366359.
HORIZON.—Pungo River Formation inferred from similarity
to fossils from Calvert Formation.
Measurements.—Omitted pending revision of genus.
REMARKS.—We have recognized a second species of Mio-
cepphus in the Calvert Formation, although it is as yet unde-
scribed. This was somewhat larger than M. mcclungi, as are the
above specimens from Lee Creek Mine.
Both species of Miocepphus were rather small alcids, about
the size of small individuals of the Black Guillemot, Cepphus
grylle (Linnaeus). Miocepphus mcclungi was likened by Wet-
more (1940) both to Cepphus and to Brachyramphus. The
broad, flattened humeral shaft in Miocepphus, however, is
quite unlike the distinctively terete, and probably primitive,
shaft of Cepphus. The less-expanded distal end, more distinct
pectoralis scar, and higher, more pointed ectepicondylar pro-
cess of Miocepphus are other points that set it apart from Cep-
phus. Miocepphus is actually very similar to the Atlantic Alca
group of auks, although it is smaller, and it may well have been
ancestral to some of the Pliocene forms of that assemblage. In
any case, it now appears to be quite unrelated to Cepphus, the
pre-Pleistocene history of the latter probably having taken
place entirely in the Pacific.
Genus Alca Linnaeus
Figures 8,9
Australca Brodkorb, 1955:25.
The great masses of alcid material from Lee Creek Mine
come mainly from several species belonging to the same genus
as the modern Razorbill, Alca torda Linnaeus, which is con-
fined to the North Atlantic. The humeri of Alca are most easily
distinguished from those of Uria by having the internal and ex-
ternal tricipital grooves of equal width, whereas in Uria the in-
ternal groove is noticeably wider. Also, the ectepicondylar
prominence extends higher on the shaft and projects farther in a
distinct point, whereas in Uria this prominence is lower and
more rounded. The premaxilla is definitely known for only one
of the extinct fossil species, but this is high and laterally com-
pressed, as in Alca, and is unlike the terete, pointed bill of Uria.
To attempt to determine how many species might be encom-
passed by the range of size variation shown in bones identified
as Alca, a principal components (PC) analysis was done using
the following four measurements of the distal ends of 566 fos-
sil humeri from Lee Creek Mine: greatest distal width (with
calipers parallel to axis of shaft); width through the condyles;
mediolateral width of shaft just proximal to ectepicondyle; and
shaft thickness (palmar-anconal) at the same point. This sam-
ple included all specimens then available in which all four
measurements were unaffected by wear or breakage. A correla-
tion matrix was used, and axes were unrotated. PC-I scores
were plotted as a polygon in a density graph, where proportion
per standard unit is the number of cases in each interval divided
by the standard deviation (s).
Factor I was a general-size axis and was the only factor with
eigenvalues above 1.0; this factor explained 93% of the varia-
tion. Because the eigenvalues for factors II and III were far be-
low 1.0, these axes were not interpreted, and instead, PC-I was
taken as a measure of size and was plotted as a density polygon
(Figure 8). This density graph of PC-I shows at least a trimodal
pattern, with each peak (at PC-I=—3.0, -1.5, 0, 2.5) possibly
representing the mode of a different species of Alca.
NUMBER 90
271
0.7-
P
¦d
0.6-
0.5-
0.4-
i
0.2-
0.1-
FIGURE 8.—Density polygon of factor I scores from a principal components
analysis of four measures of the distal end of the humerus of auks, Alca spp.,
from Lee Creek Mine. Factor I is a general-size axis explaining 93% of the
variation.
To determine the minimum number of species of Alca that
must have been present at Lee Creek, we estimated the maxi-
mum expected variance (s2) within species of Strauch's (1985)
tribe Alcini, following the rationale developed by Warheit
(1992). However, rather than using a parsimony procedure to
determine an ancestor's expected variance where the variance
of the two recent sister taxa differed (Warheit, 1992), to avoid
oversplitting we simply used the maximum variance of species
within the clade.
The Dovekie (A lie alle (Linnaeus)) was omitted from this
analysis because its relationships with the subfamily Alcinae
are equivocal. Greatest width of the distal end of the humerus
was measured for 56 Common Murres, Uria aalge; 18 Thick-
billed Murres, U. lomvia; 27 Razorbills, Alca torda; and 203
Great Auks, Pinguinus impennis. Sexes were pooled for each
species because size dimorphism between the sexes of extant
alcids is minimal (Storer, 1952; Livezey, 1988), and the sexes
could not be determined for the specimens of Pinguinus.
For distal width of the humerus, variances of taxa thus deter-
mined in the subfamily Alcinae were s2=Q.33 (Uria aalge),
i2=0.38 (U. lomvia), s2 = 0.5\ (Pinguinus impennis), and
s2=0.51 (Alca torda). The maximum variance expected for any
fossil species within that clade (assuming no evolution in that
trait between ancestors and descendents; Warheit, 1992) is
therefore 0.51, that shown by Pinguinus impennis and Alca tor-
da; Alca torda also is the only living representative of the en-
tire radiation of Alca.
To determine how best to assign individual specimens to
each of four species, a K-means cluster analysis of the four
measurements of the distal end of the humerus used in the pre-
viously mentioned principal components analysis was done,
using K=4 clusters. In addition, K=3 and K=5 analyses were
done to determine if these would provide better clustering. All
analyses resulted in highly significant F-ratios. With K>3,
cluster 3 includes a group with the variance of s2=0.96 for the
distal width of the humerus, which is considerably larger than
that for any extant species in the Alcinae, and the within-
groups sum-of-squares (ss) is large (245.18). With K=5, on the
other hand, cluster 5 has a very small variance (s2-0.\ 1), and
clusters 1, 2, and 5 have largely coincident ranges and similar
means, the range of one of the clusters falling entirely within
that of another. With K=4, however, the standard deviations of
the distal widths of the humeri for clusters 1 through 4 were
0.32, 0.20, 0.21, and 0.45, respectively, thus better fitting the
predicted level of variation for any given species in this clade.
In addition, there was less overlap between ranges of each
group than if five clusters were used, and the within-groups
sum-of-squares is not much larger than for K=5
(s.sK=4=162.19; ss^=5= 112.6). Also, four species each with a
variance of 0.51 would account for most of the total variance
shown by the distribution of distal humerus width. Therefore,
based on the four measurements of the distal end of the humer-
us, fossils of Alca from Lee Creek Mine are statistically best
considered as belonging to four species.
Species intervals as defined by the cluster analysis with K=4
are shown on a histogram of distal humerus width of 621 fossil
specimens of Alca (Figure 9). For the entire distribution the
mean=13.5, range=9.0-17.2, s=l.46, and the distribution is
strongly skewed to the left (skewness=-0.58) but is not kurtot-
ic (kurtosis=0.07). The skewness simply reflects the smaller
number of specimens of the smallest species of Alca at Lee
Creek Mine.
Alca aff. torda Linnaeus
Figure 1 Oc.d
MATERIAL.—Associated Specimens: Left humerus and ul-
na, USNM 321314; proximal two-thirds of scapula, anterior
end of left coracoid, left humerus lacking most of both ends,
and alar digit, USNM 252414.
Individual Elements: Anterior portion of sterna, USNM
215778, 495678. Right coracoids, USNM 177758, 179258,
181070, 306263, 367014, 495625, 495626; left coracoids,
USNM 308158, 321264, 495596, 495628, 495629. Right hu-
meri, USNM 257519, 446653, 446657, 446658, 446686,
446691, 495589, 495668; right humeri lacking part of proxi-
mal ends, USNM 495591, 495592; proximal half of left hu-
merus, USNM 193252; distal ends of right humeri, USNM
193259, 250772; distal half of left humerus, USNM 178032.
Right ulnae, USNM 193184, 215809, 448898, 448904,
448908, 448909; left ulnae, USNM 368515, 446644; left ulna
lacking part of proximal end, USNM 495594; proximal half of
left ulna, USNM 495595. Right carpometacarpi, USNM
178072, 368532; left carpometacarpus, USNM 193292; right
carpometacarpus missing minor metacarpal and part of distal
end, USNM 495593; proximal ends of right carpometacarpi,
USNM 183421, 215586, 215836; proximal ends of left car-
pometacarpi, USNM 192731, 367107. Right femur, USNM
272
SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY
460797; left femur 430949; proximal half of left femur,
USNM 460798; distal end of right femur, USNM 460805; dis-
tal end of left femur, USNM 459393. Proximal ends of left ti-
biotarsi, USNM 179243, 495641; distal ends of right tibiotar-
si, USNM 366660, 366712; distal ends of left tibiotarsi,
USNM 215862, 495638-495640. Left tarsometatarsus,
USNM 495633.
HORIZON.—Yorktown Formation.
Measurements.—See Figure 9.
Remarks.—The smallest size-class of Alca at Lee Creek
Mine is similar to and probably contains the ancestral form of
the modem Razorbill, Alca torda. Some of the fossil specimens
grouped here seem too small and gracile to be included in the
same species, and further analysis may make it possible to dis-
cern a smallest species that could be described as new. This
will need to be carefully distinguished from the much earlier
species of Miocepphus that are mixed in among the Yorktown
alcids, so we have postponed the attempt until undertaking a
revision of the Miocene auks.
Alca ausonia (Portis, 1891), new combination
Uria ausonia Portis, 11
tration].
Figure \0e; Plate 18a,/
: 195 [nomen nudum]; 1891:15 [description and illus-
MATERIAL.—Because of the abundance of this species at
Lee Creek Mine, only the most important and best preserved
elements are listed.
Associated Specimen: Left coracoid and distal end of left
humerus, USNM 495623.
Individual Elements: Partial cranium, USNM 430925.
Right mandibular articulation, USNM 206627; left mandibular
articulations, USNM 177804, 460790. Anterior portion of ster-
na, USNM 178152, 496140^96146. Symphyseal portion of
furcula, USNM 193317. Right coracoids, USNM 177759,
181077, 192718, 192841, 193075, 210498, 215779, 250666,
252300, 308159, 366741; left coracoids, USNM 177751,
179242, 192452, 193145, 206464, 215512, 215852, 242332,
248515, 248575, 366363, 367007, 367155. Proximal ends of
scapulae, USNM 192608, 193353, 215480, 495674, 495675.
Right humeri, USNM 181038, 215443, 366571, 366584,
446661, 446670; left humeri, USNM 179220, 183425, 275870,
368479, 368480, 446685, 446698, 495670-495672. Right ul-
nae, USNM 192706, 192983, 193411, 206353, 210459,
306258, 446545-446547, 446553, 446556, 446568, 446578,
446599, 448902, 448903; left ulnae, USNM 178173, 183432,
183433, 183490, 215723, 215905, 242223, 242300, 252331,
302357, 302364,366567,446622,496160; pathological left ul-
na, USNM 446647. Right carpometacarpi, USNM 178109,
178182, 183463, 192866, 215673, 215855, 250720, 306313;
left carpometacarpi, USNM 177784, 178053, 181102, 192679,
192948, 193399, 236873, 241379, 446536. Synsacra, USNM
275868, 496122-496128. Right femora, USNM 275789,
446702,446703; left femora, USNM 446721-446723, 460799.
Proximal ends of right tibiotarsi, USNM 366561, 495645,
495646; proximal ends of left tibiotarsi, USNM 206394,
206461, 495642^195644; distal ends of right tibiotarsi, USNM
178137, 206569, 366401, 368477; distal ends of left tibiotarsi,
USNM 177902, 206440, 210496, 241396, 252311, 256251.
Right tarsometatarsi, USNM 183468, 321272, 446728,
446729, 446731, 495635; left tarsometatarsi, USNM 177812,
179232, 183491; incompletely ossified right tarsometatarsus,
USNM 206329; incompletely ossified left tarsometatarsus,
USNM 206393.
HORIZON.—Yorktown Formation (USNM 178137, 179220,
and 183425 from basal Yorktown Formation as determined
from foraminifera in matrix).
Measurements.—See Figure 9.
Remarks.—This species was hitherto known only from the
holotype, the distal two-thirds of a left humerus from the
Pliocene at Orciano Pisano, about 25 km SSE of Pisa in the
province of Pisa, Italy. Although Portis's 1888 publication is
usually cited as the original description (e.g., Lambrecht, 1933;
Brodkorb, 1967), the species is stated only to accord well in
size and characters with Uria rhingvia (sic) Briinnich (= U. aal-
ge), which does not diagnose it in any way. Th