Peabody Museum
of Natural History
New Haven, Ct. 06520

Postilla Number 176

3 May 1979

A New Aquatic Eosuchian
from the Newark Supergroup
(Late Triassic-Early Jurassic)
of North Carolina and Virginia

Paul Eric Olsen

Received 13 October 1977
Abstract

Tanytrachelos ahynis (n.gen., n. sp.) is a
lepidosaur from the Late Triassic Dan River
Group (Newark Supergroup) of North
Carolina and Virginia. The new reptile has
gracile proportions similar to Tanystropheus
(Middle Triassic) and is referred to the family
Tanystropheidae of the suborder Prolacer-
tiformes. Unlike Tanystropheus, Tanytrach-
elos has relatively short cervical vertebrae
bearing splintlike ribs anteriorly and
plowshare-shaped ribs posteriorly. The
species is much smaller than Tanystropheus
and has long straight ribs fused to the most
distal dorsal vertebrae and proximal caudal
vertebrae. The associated fish and nonmarine
invertebrate fauna and flora suggest that the
age of the Tanytrachelos-bearing horizon is
Middle Keuper (Carnian of the Late Triassic).

Introduction

The Newark Supergroup (Olsen, 1978; Van
Houten, 1977) consists of thick continental
Sequences preserved in discrete basins ex-
posed in the Piedmont province of eastern
North America from Nova Scotia to South
Carolina. Despite the great geographic area
involved and the considerable time repre-

© Copyright 1979 by the Peabody Museum of
Natural History, Yale University. All rights reserved.
No part of this publication, except brief quotations
for scholarly purposes, may be reproduced without
the written permission of the Director, Peabody
Museum of Natural History.

sented by the Newark (at least. Late Triassic
through Early Jurassic, Olsen and Galton,
1977), knowledge of this interval’ has been
very sketchy, primarily because it was thought
to be fossil poor.

This negative concept had to change in
1974, when a locality in the upper member of
the Cow Branch Formation of the Dan River
Group [Newark Supergroup of North Carolina
and Virginia (Thayer, 1970)] was discovered
(Fig. 1). This site has yielded many skeletons

ree
100km,

Fig. 1

Map of southeastern United States showing extent
of Newark Supergroup Rocks. A, Dan River Group;
B, Davie County Basin; C, D, E, Durham, Sanford,
and Wadesboro Basins of Chatham Group; F,
Farmville Basin and minor basins to the south; G,
Scottsville Basin; H, Richmond Basin; /, Taylorsville
Group; J, Culpeper Basin; K, Gettysburg Basin; L,
M, N, O, P, Q, Newark Supergroup rocks inferred to
exist below the Coastal Plain sediments.

2 A New Aquatic Eosuchian

Postilla 176

of small reptiles, reptile footprints, five genera
of fish, abundant insects, other arthropods,
and arich megafossil flora (Olsen, etal., 1978)
constituting a reasonable representation ofa
large Late Triassic lake. In this lake lived
abundanttanystropheid lepidosaurs and their
remains form the basis for this report.

Prior to the discovery of the Cow Branch
reptile, the family Tanystropheidae was defi-
nitely known only from the marine Middle
Triassic Tanystropheus (Peyer, 1931). This
form is characterized by an extremely long
neck and skeleton with a number of lizardlike
features: the resemblance has suggested to
some (Wild, 1973) that Tanystropheus was, in
fact, a true lizard. Recent advances in our
understanding of lizard phylogeny (Gow,
1975; Carroll, 1977) suggest that Tany-
stropheus is closely allied to the lizardlike
family Prolacertidae, and that true lizards
have had a completely independent history.
It now seems that the prolacertilians (includ-
ing Tanystropheus) underwent a radiation of
their own culminating in the Middle Triassic,
prior to their replacement by aquatic true
lizards, plesiosaurs, and archosaurs.

A comparison of the diminutive Cow Branch
tanystropheid, certainly lacustrine, with the
giant (ca. 6 m) Tanystropheus, found in
marine deposits, points up the differing sorts
of trophic strategies presentin closely related
species living in different environments. In
fact, many of the gross morphological differ-
ences between the new reptile and Tany-
stropheus are such that one could be ~“de-
rived” from the other by relatively simple
geometric transformations; hence, a number
of interesting evolutionary interpretations
come to mind (Gould, 1977). These interpre-
tations, as well as the functional anatomy
and ecological relationships of the new reptile
will be dealt with in a separate work. Now,
however, it is appropriate to present a brief
diagnosis and description of this tany-
stropheid to facilitate further work and
reference.

Material and Methods
The material for this work consists of more
than 100 skeletons in various states of

completeness from a single locality (see
below) in the upper member of the Cow
Branch Formation.

All of the skeletons are preserved as black
or silvery compressions on black or gray lami-
nated dolomitic siltstone; their preparation is
hindered by a thin covering of this siltstone. it
can be cleaned off by several weeks of soak-
ing in dilute acetic acid (ca. 15%) followed
by careful removal of the matrix by the “air-
brasive” method. Two specimens have been
prepared in this manner, three required no
preparation. The majority of the findings pre-
sented in this paper are principally based on
these five specimens.

A Note on the Locality

The owners of the Tanytrachelos locality have
been extremely cooperative but do not want
the position of the site to become common
knowledge; therefore, a code will be used for
the locality data, the key to which is recorded
in the archives of the Yale Peabody Museum
(Olsen, 1978a). The first reptile specimens
were found in displaced boulders that were
later traced to their origin. Both the area of
displaced boulders and the extensive expo-
sures that produced them are termed CB1. A
number after CB1 indicates the exact strati-
graphic position of the fossil or fossiliferous
unit, and a letter after that gives the geo-
graphic location. The locality designation for
the area of displaced boulders is CB1-A (no
stratigraphic position) and those of four col-
lecting sites along a single horizon are CB1-
2-B, CB1-2-C, CB1-2-D, and CB1-2-E (see
Fig. 9). The quarry from which most of the
material was recovered 1s at CB1-2-D. Sev-
eral specimens have also been recovered
from units CB1-3 and CB1-16 from the same
large exposure as CB1-2-B through CB1-2-E.

Systematic Paleontology

Class Reptilia

Subclass Lepidosauria

Order Eosuchia

Suborder Prolacertiformes

Family Tanystropheidae Gervais, 1858

3 A New Aquatic Eosuchian Postilla 176

Peers fcres Perk rte A

\
ss

Fig. 2
The type specimen of Tanytrachelos ahynis (YPM 7496) A, line drawing, scale 2 cm; B, photograph,
Scale in mm,

4 A New Aquatic Eosuchian

Postilla 176

Family Definition: Small (18cm) tovery large
(6 m) lepidosaurs, with an elongate body and
neck. Skull diapsid with incomplete jugal
arch; orbits large and lower jaw slender. 12
cervical, 13 dorsal, 2 sacral, and up to 46
caudal vertebrae, all amphicoelous (in Tany-
stropheus) or procoelous (in Tanytrachelos).
Cervical and anterior dorsal ribs dicephalous,
but capitulum reduced on posterior dorsal
rips. Last two or three dorsal vertebrae with
straight ribs fused to the centra. Interclavicle
quadrangular, clavicles bladelike; coracoids
oval: scapular sublunate. Forelimbs consid-
erably shorter than hind; manus with short
metacarpals anda phalangeal formula of 2, 3,
4, 4, 3. Pelvic girdle of general lepidosaur
nature with a large thyroid fenestra. Hind
limbs long; pes with a large calcaneum and
astragalus; metatarsal V hooked and short;
proximal phalanx of V elongate; pes pha-
langeal formula 2, 3, 4, 5, 4. Gastralia nu-
merous with each element composed of four
pieces forming a“V" in shape. Paired, triangu-
lar heterotopic bones present alongside the
fourth through sixth caudal vertebrae in some
specimens.

As defined here the family Tanystropheidae
includes Tanystropheus, Tanytrachelos
(n.gen.), possibly Cosesaurus (Ellenberger
and de Villalta, 1974) and an undescribed
reptile from India (Cruickshank, 1972).
Distribution: Anisian-Landinian (Middle
Triassic), Central Europe; ?Anisian, eastern
North America; Middle Triassic, Middle East
and India; Late Carnian (Late Triassic), east-
ern North America.

Tanytrachelos, new genus

Type Species: Janytrachelos ahynis, new
and only known species.

Distribution: Late Triassic (Late Carnian) of
south-central Virginia and central North
Carolina.

Diagnosis: Same as for species, see below.
Etymology: Jany (Greek), Jong; trachelos

(Greek), neck. Name suggested by John H.
Ostrom.

Tanytrachelos ahynis, new species

Type: YPM (Yale Peabody Museum).7496, a
nearly complete Type A individual, missing
both pedes and posterior portion of tail. Local-
ity CB1-2-C. Note that “Type A” or “Type B”
refer to the presence of a presumably sexually
dimorphic character (see Fig. 2).

Hypodigm: YPM 7491, large Type B, missing
neck and skull. Anterior portion of trunk dis-
articulated. Locality CB1-A.

YPM 7702, complete small Type A. Locality
CB1-A.

YPM 7485, Type A, missing tail and most of
skull. Locality CB1-A.

YPM 7484, Type B, with good trunk, neck, and
proximal portion of tail. Locality CB1-2-B,
weathered zone.

YPM 7644, Type B, missing tail, legs, and
skull. Locality CB1-2-B, weathered zone.
YPM 7490, Type B, missing portion of trunk.

Locality CB1-2-C.

YPM 7492, partially disarticulated specimen.
Locality CB1-2-C.

YPM 7498, Type A, missing part of neck. Lo-

cality CB1-2-C.

YPM 7494, large Type A, missing part of neck
and skull. Locality CB1-2-C.

YPM 7486, Type B, missing distal parts of hind
limbs and tail. Locality CB1-2-D.

YPM 7487, Type B, missing anterior portion of
skeleton. Locality CB1-2-D

YPM 7488, excellent neck. Locality CB1-2-D.

YPM 7489, Type A, missing one pes and distal
portion of tail. Locality CB1-2-D.

YPM 7495, Type A, missing anterior portion of
skeleton. Locality CB1-2-D.

YPM 7497, Type B, missing skull and one leg.
Locality CB1-2-D.

YPM 7498, Type B, fragmentary skeleton.
Locality CB1-2-D.

YPM 7499, Type A, fragmentary skeleton.
Locality CB1-2-D.

YPM 7540, pes and distal part of tibia and
fibula. Locality CB1-2-D.

YPM 7541, anterior three-quarters of skeleton
preserving outline of soft tissue. Missing tail
and both feet. Locality CB1-2-D.

YPM 7542, fragmentary skeleton with good
pes. Locality CB1-2-D.

6) A New Aquatic Eosuchian

Postilla 176

Table 1.

Some selected measurements of Tanytrachelos ahynis.

Sex refers to whether it is

a Type A or Type B individual.

(See "Discussion" in text.)

Measurements are

averages of left and right limb bones and several dorsal vertebrae.

ok 7496 7485 T7487 ThOL 7493 7621 7622
"Sex" A A B B A A A
Length (mm )
Dorsal
vertebrae ba0 4.8 v0) Guy Teall 652 Lo
Femur 2120 SShHS THES) 35.2 exer 6) 50.5 ESS
Tibia 20.5 1569 aA ios OR a5 21.4 1.540
Metatarsal
III ion 11.0 oe 18.0 15 iby, 13.4
Humerus elegy) ea ae 29.0 24.6 25.0) ONY.
Ulna LOD pile ae 14.0 10.0 12.0 OWS

YPM 7612, fragment of trunk and pectoral gir-
dle. Locality CB1-2-D.

YPM 7615, Type B, complete skeleton. Local-
ity CB1-2-D.

YPM 7617, parts of several individuals. Local-
ity CB1-2-D.

YPM 7618, Type A, missing pectoral girdle,
forelimbs, neck, skull, and tip of tail.

YPM 7619, Type B, missing head and end of
tail. Locality CB1-2-D.

YPM 7620, articulated humerus, radius, and
ulna. Locality CB1-2-D

YPM 7621, Type A, excellent disarticulated
skeleton, missing tail tip and skull. Locality
CB1-2-D.

YPM 7622, Type A, lacking most of skull, one
foot, and end of tail. Locality CB1-2-D.

YPM 7623, Type B, missing tail tip. Locality
CB1-2-D.

YPM 7626, Type A, missing skull and tail. Lo-

Cality CB1-2-D.

YPM 7628, Type A, missing skull and tail. Lo-

Cality CB1-2-D.

YPM 7629, Type B, complete skeleton. Local-
ily. CBi22-D,

YPM 7680, Type B, complete skeleton. Local-
ity CB1-2-D.

YPM 7632, impression of anterior portion of
skeleton. Locality CB1-2-D.

YPM 7633, Type A, pelvis and legs. Locality
CB1-2-D.

YPM 7649, Type A, missing neck, head, and
tail end. Locality CB1-2-D.

YPM 7482, very good skull and anterior por-
tion of body. Locality CB1-2-E, weathered
zone rubble.

YPM 7501, 7502, poor fragments. Locality
CB1-A.

YPM 7614, 7625, 7631, 7611, 7634, 7635,
7637, 7638, 7639, 7640, 7641, 7642, 7643,
7645, 7647, 7648, 7650, 7651, 7652, 7653,
7654, fragments. Locality CB1-2-D.

YPM 7483, fragment. Locality CB1-2-E,
weathered zone rubble.

YPM 8172, fragmentary skeleton. Locality
CBi-3,

YPM 8178, good partial skeleton missing dis-
tal part of tail. Locality CB1-3.

YPM 8075, fragment. Locality CB1-16.

Horizon: Upper member of the Cow Branch
Formation, Dan River Group, Newark Super-
group. Most specimens from laminite (Divi-
sion 2) of cycle number CB1-2, at localities
CB1-2-B through CB1-2-E, or from rubble
(locality CB1-A) presumably from cycle
number CB1-3. Several specimens have
been removed from in situ in CB1-3. Position

6 A New Aquatic Eosuchian

Postilla 176

of the units is about 540 m above the base of
the upper member of the Cow Branch Forma-
tion. One possible specimen is from cycle
number 16(CB1-16, about 415m above base
of the upper member of the Cow Branch
Formation).

Etymology: a (Greek), with hynis (Greek),
plow, in reference to the plowsnare-shaped
cervical ribs

Diagnosis: Small, gracile tanystropheid
skull as for family, with large orbits. Teeth
closely spaced, sharply pointed, with the-
codont or subthecodont emplacement. Neck
nearly as long as trunk. Vertebrae procoelous
with 12 cervicals, 13 dorsals, 2 sacrals, and at
least 25 caudals. Cervical vertebrae 3-6 with
closely parallel splintlike ribs, the posterior
extension of which is about two vertebrae in
length. Cervical vertebrae 7-12 with shorter,
plowshare-shaped ribs that become larger on
posterior vertebrae. Anterior dorsal ribs di-
cephalous, posterior dorsal ribs single-
headed. Last two or three dorsal vertebrae
bear long but slender, slightly anteriorly di-
rected transverse processes, but seemingly
no ribs. Anterior caudal vertebrae with long
transverse processes that shorten and disap-
pear by the sixth or seventh caudal. Total
length of tail about twice that of trunk. Pectoral

and pelvic girdle as for family. Forelimbs rela-

tively short: humerus 0.84 length of femur,
ulna 0.46 length of humerus. Hind limbs
long: femur 5.2 length of single dorsal ver-
tebra, tibia 0.68 length of femur. Pes very
large with third metatarsal 0.79 length of
tibia with structure as for family (proportions
based on Table 1). Differs from Tany-
stropheus principally in having procoelous
vertebrae, shorter cervical vertebrae, plow-
shaped posterior cervical ribs, relatively
longer hind limb and pes, and amuch smaller
maximum size.

Discussion

The fossil record of lepidosaurs is replete with
cases of apparent iterative evolution of
characters and trends in characters; for

example, Carroll (1977) and Robinson (1975)
have shown that a hooked fifth metatarsal,
once thought to be of considerable phylo-
genetic importance (Goodrich, 1916), was
probably independently derived four times
in different phyletic groups. Likewise, Robin-
son (1973) and Gow (1975) have demon-
strated that the incomplete jugal arch, so
characteristic of lizards, evolved (in slightly
different ways) ina minimum of two additional,
nonlizard lineages. Clearly, differentiating
the phylogenetic significance of the charac-
ters visible in Tanytrachelos is beyond the
scope of this preliminary description; it would
require the examination of the rest of the rep-
tiles. Due to the nature of the material, fur-
thermore, the characters visible on Tany-
trachelos are gross morphologic ones, de-
tails of bone articular surfaces, braincase
morphology, and even skull-bone shape are
obscured in the presently prepared material.
Therefore, for this work, a cladistic approach
(in the sense of Schaeffer, Hecht, and El-
dredge, 1972) will be used in which the
characters relevant to the relationships of
Tanytrachelos are listed at each level of com-
parison in the classificatory hierarchy. The
distribution of these characters in the relevant
sister groups are documented by Goodrich
(1916), Robinson (1973, 1975), Gow (1975),
and Carroll (1977).

Tanytrachelos can be distinguished from
Tanystropheus, its presumed nearest relative,
by the following uniquely derived characters
(with respect to its suborder): procoelous ver-
tebrae, very large plowshare-shaped ribs on
the posterior cervical vertebrae (Figs. 2, 4, 5)
and long straight ribs fused to the last three
posterior dorsal vertebrae and anterior caudal
vertebrae (Figs. 2, 3, 4, 5). There are three
obvious characters that are shared by Tany-
trachelos and Tanystropheus (and possibly
Cosesaurus) and no other reptiles known to
this author: a short metatarsal with an elon-
gate (metapodiallike) proximal phalanx on
digit V (Figs. 3, 4); crescent-shaped
heterotopic bones lateral to the proximal
caudal vertebrae [in Type A individuals (Figs.
2, 3, 4)]; and a vertebral count of 12 cervicals
and 13 dorsals. These are apparently shared,
derived characters which unite Tanystroph-

ih A New Aquatic Eosuchian

Postilla 176

Fig. 3

Tanytrachelos ahynis. A, posterior portion of YPM
7621, Type A; unprepared portions in black—scale
4 om: B, skull of YPM 7402; note shape of jugal—
scale 0.5 cm; C, Pes of YPM 7540; note short,
hooked metatarsal V and elongate proximal
phalanx of V—scale 1 cm. Abbreviations: cv,

eus and Tanytrachelos as sister genera in the
family Tanystropheidae Gervais, 1895. The
families Prolacertidae (Macrocnemus and
Prolacerta) and Tanystropheidae have the
same general arrangement of skull bones
(Fig. 3), ahooked metatarsal V (Figs. 2 and 4),
and an incomplete jugal arch. These shared,
derived characters (with respect to other
eosuchians) illustrate that these two families
are probable sister groups to be included in
the suborder Prolacertiformes (Gow, 1975). |
feel, however, that the characters that estab-
lish the family Tanystropheidae do not justify
the formation of the separate and redundant
suborder Tanysitrachelia (Peyer, 1931). Ac-
cording to Gow (1975) the Prolacertiformes
are related to the basal stock of the archo-
Saurs and presumably would, therefore,
belong in the order Eosuchia, as defined by
Carroll (1977).

As noted by Carroll (1977) procoelous ver-
tebrae evolved in parallel at least twice in the
true lizards. The procoelous condition is also
Present in Tanytrachelos and this character

caudal vertebra; dv, dorsal vertebra; f, femur,
fi, fibula; hp, heterotopic bones of the Type A
? hemipenes; il, ilium; is, ischium, j, jugal,N, bones
of the left manus; mt V, metatarsal of digit V, Pp,
pubis; sv, sacral vertebrae; t, tibia; /, digit |, V, digit
V.

could be cited as evidence of relationship
between Tanytrachelos and the lizards. | feel,
however, that the three derived characters
(the unique pes, vertebral count, and hetero-
topic bones) that Tanytrachelos shares with
Tanystropheus effectively demonstrate that
this procoelous condition is a convergent de-
velopment within the Tanystropheidae. It

is yet another example of the complexity

of iterative character states in diapsids and
their derivatives.

The association of Tanytrachelos with
numerous fossil fishes, a lacustrine insect as-
semblage, abundant branchiopods, and phyl-
locarids (Olsen, et al., 1978) suggests It was
aquatic as Wild (1973) believes was the case
for Tanystropheus. The general proportions
and limb morphology of Tanytrachelos are
consistent with this interpretation.

Some of the specimens of Tanytrachelos
preserve traces of soft tissue and body outline
as a thin, silvery film. YPM 7541 shows this
best (Fig. 5) and illustrates that the skin of the
limbs is smooth, whereas that of the belly (and

8 A New Aquatic Eosuchian Postilla 176

Fig. 4

Tanytrachelos ahynis. A, YPM 7622; Type A; scale 2
cm.; B, YPM 7491; Type B; scale 4 cm. Both speci-
mens unprepared.

Fig. 5
Tanytrachelos ahynis, YPM 7541: Shaded area rep-
resents preserved traces of soft tissue. Scale 2 cm:

9 A New Aquatic Eosuchian

Postilla 176

or back) is granular in texture. No direct evi-
dence of webbing of the pes has been found
although it seems likely that the feet were
webbed in life.

About half of the specimens inall size class-
es of Tanytrachelos have a pair of anteriorly
Curved, triangular heterotopic bones lateral to
Caudal vertebrae 4 through 6 (Figs. 2, 3, 4).
Similar structures occur in Tanystropheus,
and Wild (1975) believes they might be the
analogue of the mammalian baculum for the
reptilian hemipenes. But since these struc-
tures are not found in other reptiles, it may be
they served another function, such as support
for an egg (embryo?) pouch in the female.
Because of this uncertainty, for the purposes
of this paper the individuals with these struc-
tures will be termed Type A and those without
them Type B (see ‘“Hypodigm’"’).

The Lockatong Formation of the Newark
Basin (Fig. 6) is lithologically similar to and

cote
9
(7p) SUBORDER PROLACERTIFORMES
o)
=
tr
ae FAMILY TANYSTROPHEIDAE
TANYTRACHELOS
= ,
\
QD \
io) Awe 34
< 3
iva
=
FAMILY PROLACERTIDAE
WwW
a
MACROCNEMUS
Q Me TANYSTROPHE
= Tx —
(
one
9) We
H
iep)
cs
c
i
p
—
iva
<
Ww
Kal ee
Fig. 6

Diagram of the hypothetical cladistic relationships
within the Prolacertiformes, including Tanytrach-
Glos (n.gen.), showing the earliest known occur-
rences (dots at ends of lines).

approximately contemporaneous with the
Cow Branch Formation (Olsen, et al., 1978).
The Lockatong has produced an exception-
ally diverse variety of small reptiles, and these
were examined to determine their relation-
ship, if any, to Tanytrachelos. Icarosaurus,
from the lower Lockatong of North Bergen,
New Jersey, is a kuehneosaurid lizard with
marked adaptations for flight and is so differ-
ent from Tanytrachelos that no further con-
sideration need be given it. Rhabdopelix
(Cope, 1870) is a composite of several indi-
viduals (if not several taxa) of small reptiles,
some of which may be related to /carosaurus
(Colbert, 1966). Gwynnedosaurus (Bock,
1945) is from the same locality as Rhab-
dopelix. A redescription of Gwynnedosaurus
will be given elsewhere; however, it should be
noted that some of the bones of Rhabdopelix
figured by Cope (1870) are nearly identical to
portions of Gwynnedosaurus. The latter has a
partially emarginate scapulocoracoid and
could be atrue lizard. These two genera, then,
are not closely allied to Tanytrachelos. Colbert
(1966) mentions several undescribed small
reptiles from the same locality as /Carosaurus.
One of these, AMNH 1721, has amphicoe-
lous dorsal vertebrae (Colbert, 1966), and
ofthe 13 vertebrae visible, at least 9 have very
long transverse processes (or fused ribs) and
unique-appearing gastralia; so it is not rele-
vant. Another, AMNH 7206, consists of a small
disarticulated skeleton in association with a
large amount of scattered Diplurus newarki
(coelacanth) material. The bones present are
of a generalized lepidosaurian nature, and no
diagnostic elements are obvious; it cannot be
completely ruled out that this reptile might be
Tanytrachelos. Finally, AMNH 7282 is asmall,
very fragmentary reptile with only proximal
caudal vertebrae and some elongate hemal
arches preserved. The caudal vertebrae bear
high, anteriorly directed neural spines and
very short transverse processes. This, too,
cannot be Tanytrachelos. Thus, despite the
presence of at least five taxa of small reptiles
in the Lockatong, positive evidence for the
presence of Tanytrachelos is lacking. In
marked contrast, the fish faunas of the
Lockatong and Cow Branch Formations

are nearly identical (Olsen, et al., 1978).

10 A New Aquatic Eosuchian

Postilla 176

A possible Tanytrachelos relative is Cose-
saurus (Ellenberger and de Villalta, (1974)
from the upper Muschelkalk of Spain. It has
very gracile proportions, a pointed snout, and
large orbits. Ellenberger and de Villalta be-
lieve Cosesaurus to be a ‘proto-bird.” From
what can be seen of the pes, vertebral count,
and pectoral girdle in the published photo-
graphs, it is more likely to be a primitive
member of the Tanystropheidae as defined
here. It differs from Tanytrachelos in the less
specialized nature of the cervical ribs, shorter
transverse processes on the anterior caudal
vertebrae, and a somewhat proportionally
longer tibia and fibula. The pes (again from
the photographs) seems to have the short
metatarsal V and the elongate proximal
phalanx typical of tanystropheids.

Distribution of the Tanystropheidae

As defined above, the family Tanystropheidae
comprises at least Tanystropheus and Tany-
trachelos. Tanystropheus is known from the
upper Buntsandstein (Middle Triassic,
Anisian) of Germany (Ortlam, 1967), the
Muschelkalk of Central Europe, the Grenz-
bitumenzone (Anisian-Ladinian) of Southern
Europe, and the Middle Triassic of Israel. Re-
cently, Donald Baird (personal communica-
tion) identified Tanystropheus sp. (Princeton
University Number 22000) in a small assem-
blage of reptiles and amphibians from the
lower Wolfville Formation (Fundy Group of
Newark Supergroup) of Lower Economy,
Nova Scotia, Canada. Other elements of the
fauna suggest an Early to Middle Triassic age
for this locality. In contrast, Tanytrachelos is,
of course, known only from the one Late Trias-
sic locality in the southeastern United States
described here. Cosesaurus—a possible
tanystropheid—comes from the Spanish Mid-
dle Triassic. One more tanystropheid may be
the specimen mentioned by Cruickshank
(1972) from the Yerrapalli Formation (Mid-
dle Triassic—Kutty, 1969). If this is a tany-
stropheid, it represents the only Gondwana
example of the family. Thus, the distribution of
the Tanystropheidae may be cosmopolitan

and members lived from early Middle Triassic
through early Late Triassic.

Geology of the Tanytrachelos Locality

The Early Mesozoic Newark Supegroup
(Olsen, 1978) consists of thick sections of
nonmarine red, gray, and black sedimentary
rocks and associated volcanics preserved in
a number of elongate tectonic basins which
are aligned with the regional trend of the Ap-
palachian Mountains. Thirteen major basins
containing Newark Supergroup rocks are ex-
posed in the Piedmont Province of eastern
North America; others are known to exist be-
neath Atlantic Coastal Plain sediments and on
the Continental Shelf (Olsen, in press; Jansa
and Wade, 1975). The Dan River Group (Fig. 7)
of the Newark Supergroup is exposed in cen-
tral North Carolina and Virginia in the contig-
uous Danville and Dan River Basins. Thayer
(1970) has divided the Dan River Group into
three interdigitating formations: the Cow
Branch Formation, consisting of several large
lenses of black and gray siltstone and
sandstone; the Pine Hall Formation, composed
of pink and buff sandstone, red, buff, and gray
siltstone, and buff conglomerate; and the
Stoneville Formation, made up of red and gray
siltstone, sandstone, and conglomerate. Near
Eden, North Carolina, 560 m of Pine Hall For-
mation rests on the Pre-Newark metamorphic
rocks, and is overlain by 600 m of the lower
member of the Cow Branch Formation. This is
succeeded by a 740 m tongue of Pine Hall
Formation which is overlain by 710 m of the
upper member of the Cow Branch Formation.
Finally, 1130 m of Stoneville Formation overlie
this.

To the north of Eden, the upper member
of the Cow Branch Formation thickens
considerably and consists of repetitive,
coarsening-upwards cycles (Thayer, Kir-
stein, and Ingram, 1970) similar to those in
the Lockatong Formation of the Novacaes-
area Group (Newark Supergroup of the
Newark Basin). The modal cycle (one which
best represents the observed section—Duff,
Hallam, and Walton, 1967) is composed of
three divisions (Fig. 8): 1) a basal platy, dark

11 A New Aquatic Eosuchian

Postilla 176

gray, often calcareous siltstone; 2) a middle
finely laminated calcareous siltstone (lami-
nite); and 3) an upper massive siltstone and
sandstone. The source of most of the material
of Tanytrachelos is Division 2 of a single cycle
about 540 m above the base of the upper
member of the Cow Branch Formation (CB1-
2). This is exposed for about 135 m along
strike as part of a single continuous section in
which 17 other cycles are exposed (Figs. 7, 8,
9). Two partial Tanytrachelos specimens have
been found in unit CB1-3 near locality
CB1-2-E (Fig. 9), and it seems likely that
most of the material from rubble in CB1-A is
from this unit. In addition, a small fragment

“| Stoneville Fm.

Cow Branch Fm.
(upper mb.) é
Stoneville Fm, -
Pine Hall Fm.
Cow Branch Fm.
(lower mb.)

“1 Pine Hall Fm.

100

}cBi6

Fig. 7

A, Idealized section through the Dan River Group
Near Eden, North Carolina; approximate position of
the Tanytrachelos locality at a. B, Modal cycle for
the upper Member of the Cow Branch Formation. C,
Divisions of the modal cycle. D, Stratigraphic sec-
tion at the Tanytrachelos locality showing position of
reptile-bearing horizons (CB1-2, CB1-3, CB1-16).
Division 2 of each cycle shown in black: cycles
Numbered from top down, contrary to normal prac-
tice, because of the uncertain number of cycles
Near the base of the section.

which could be Tanytrachelos (YPM 8075)
has been found in cycle CB1-16. Unfortu-
nately, the specimen is too fragmentary for
positive identification. It is clear, however,
that the distribution of specimens of Tany-
trachelos through several cycles shows that
its density is not an isolated fluke of preser-
vation but, rather, is characteristic of the

facies.
=

cycle
division

unit

meters

4

Fig. 8

Stratigraphic section at CB1-2-D. a, Black and dark
gray micaceous siltstone and calcareous fine
siltstone, showing some graded bedding and
common conifer fragments. 6, Black, microlami-
nated, calcareous siltstone containing Tanytrach-
elos material along with well-preserved insects
and crustaceans, numerous fossil fish and plants,
and also a graded coarse siltstone bed near top of
unit. C, Black siltstone, intensely slickensided and
disturbed. d, Black pyritic, well-bedded siltstone
with common slickensided bedding planes. e, Mi-
crolaminated siltstone with numerous crumpled
casts of a salt and with conifer stems. f, Gray, well-
bedded siltstone with scour marks on bedding
planes and large plant stems in growth position.

V2 A New Aquatic Eosuchian

Postilla 176

CBI2£

A x CBt2-D

CB1-2-B

Transgressions and regressions of a large
lake in a slowly subsiding depositional basin
could have resulted in the Cow Branchcycles
(Olsen, et al., 1978). In particular, the Tany-
trachelos layers (Division 2 of cycles CB1-

2, CB1-3, and CB1-16) were probably de-
posited in the anoxic waters beneath the
chemocline of a perennially stratified lake dur-
ing its maximum transgression. Existing
faunal and floral data (Olsen, et al., 1978 and
Olsen, MS, 1978b) suggest that the upper
member of the Cow Branch Formation corre-
lates with the Lockatong Formation of the
Newark Basin (lower part of Zone 1

of Olsen and Galton, 1977) and that these
correlate with the German middle Middle
Keuper (Late Carnian).

Acknowledgments

The scientific community is indebted to the
owners of the Tanytrachelos locality for per-
mission to collect specimens and carry out
excavations on their property. Indeed,
throughout the field work, they assisted in
numerous ways, and it is largely due to
their generosity that Tanytrachelos has been
discovered

| thank Drs. Donald Baird, W. Bruce Cornet,
Jr., Jean-Claude Gall, John H. Ostrom, John
Rodgers, Hans-Dieter Sues, Keith S. Thom-
son, and Karl M. Waage for many hours of
discussion about the fauna, flora, and geol-
ogy of CB1. Dr. Edwin H. Colbert kindly pro-
vided photographs of two of the undescribed
North Bergen reptiles (Lockatong Formation).
Dr. Eugene S. Gaffney gave access to the
third, and Dr. Earl Shapiro of the Academy
of Natural Sciences of Philadelphia
loaned Gwynnedosaurus. The manuscript
was read by Dr. Baird, Amy J. Litt,
Dr. Ostrom, and Kevin Padian.

Fig. 9

The Tanytrachelos locality showing the positions of
localities CB1-2-B through CB1-2-E and the posi-
tions of the reptile-bearing portions of cycles CB1-2
(A) and CB1-3 (B). Distance from CB1-2-B to
CB1-2-E is about 135 m. Note the flaggy nature of
the beds. View is to the west

Is A New Aquatic Eosuchian Postilla 176

Stan P. Rachootin, and Dr. Thomson. Intro- Note Added While In Press
duction to the owners was through Dr. PaulH. a aditional examination of AMNH 7206
Knappenberger, Jr. of the Virginia Museum of
Science. Special thanks must go to Robert F
Salvia and Robert Brombaugh who worked
with me during the field work, often under
extremely difficult conditions

Work was made possible by a grant from
the National Science Foundation to Dr. Thom-
son (BMS 74-07759) and grants from the
Peabody Museum.

demonstrates the presence of the type of
procoelous vertebrae and cervical ribs char-
acteristic of Tanytrachelos. |In addition, ex-
tremely well-preserved specimens of Tany-
trachelos have been discovered in the lower
Lockatong Formation of the Newark Basin at
Weehawken, New Jersey. This points up the
similarity between the the Cow Branch and
Lockatong faunas and their sedimentary
cycles (Olsen et al. 1978).

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Unpublished References

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The Author
Paul Eric Olsen. Department of Biology,

Yale University, New Haven, Connecticut
06520.