550.5
FI

n.s.
no. 33

F1ELD1ANA

Geology

NEW SERIES, NO. 33

The Mammalian Faunas of the Washakie Formation,
Eocene Age, of Southern Wyoming.
Part III. The Perissodactyls

Steven M. McCarroll
John J. Flynn
William D. Turnbull

CO

CT)

CL.
LU
CO

March 29, 1996
Publication 1474

PUBLISHED BY FIELD MUSEUM OF NATURAL HISTORY

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Croat, T B. 1978. Flora of Barro Colorado Island. Stanford University Press, Stanford, Calif., 943 pp.

Grubb, P. J., J. R. Lloyd, and T D. Pennington. 1963. A comparison of montane and lowland rain forest in Ecuador.

I. The forest structure, physiognomy, and floristics. Journal of Ecology, 51: 567-601.
Langdon, E. J. M. 1979. Yage among the Siona: Cultural patterns in visions, pp. 63-80. In Browman, D. L.,and R. A.

Schwarz, eds., Spirits, Shamans, and Stars. Mouton Publishers, The Hague, Netherlands.
Murra, J. 1946. The historic tribes of Ecuador, pp. 785-821. In Steward, J. H., ed., Handbook of South American

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ILLINOIS LIBP
\T URBANA-CHAMrv
GEOLOGY

FIELDIANA

Geology

NEW SERIES, NO. 33

The Mammalian Faunas of the Washakie Formation,
Eocene Age, of Southern Wyoming.
Part III. The Perissodactyls

Steven M. McCarroll
John J. Flynn
William D. Turnbull

Department of Geology
Field Museum of Natural History
Roosevelt Road at Lake Shore Drive
Chicago, Illinois 60605-2496

Accepted July 6, 1995
Published March 29, 1996
Publication 1474

PUBLISHED BY FIELD MUSEUM OF NATURAL HISTORY

© 1 996 Field Museum of Natural History

ISSN 0096-2651

PRINTED IN THE UNITED STATES OF AMERICA

GEOLOGY LIBRARY

Table of Contents

Abstract 1

Introduction 1

Abbreviations and Institutions 5

Systematic Paleontology 5

Orohippus sp 5

Epihippus gracilis 6

Telmatherium sp 8

Mesatirhinus sp 8

Metarhinus sp 11

Dolichorhinus sp 13

Brontotherioidea indeterminate 15

Isectolophus latidens 15

Eomoropus amarorum 15

Helaletes nanus 18

Dilophodon minusculus 20

Hyrachyus modestus 22

Hyrachyus eximius 25

Triplopus cubitalis 26

Trip/opus implicates 26

cf. Forstercooperia minuta 28

Hyracodontidae indeterminate 28

Amynodon advenus 28

BlOSTRATIGRAPHY 30

Conclusions 34

Acknowledgments 34

Literature Cited 35

Appenddc 1 : Field Museum Localities Cited

in Text 38

Appendix 2: Metarhinus sp. Specimens from
the Monospecific Titanothere Quarry
Reported by Turnbull and Martill
(1988) 38

List of Illustrations

1 . Regional location map 2

2. Washakie Formation location map 2

3. General stratigraphic correlation of the
Washakie, Bridger, and Uinta forma-
tions 3

4. pm 55790, Orohippus sp. pm 55311,
Epihippus gracilis 7

5. pm 27939, Mesatirhinus sp 9

6. pm 36045, Mesatirhinus sp 10

7. pm 3935 and pm 35932, Metarhinus sp. . . 12

8. pm 3870, Dolichorhinus sp 14

9. pm 55925, Isectolophus latidens. pm
1670 and pm 2082, Eomoropus amaro-
rum 16

10. pm 55951, Helaletes nanus, pm 55709,
Dilophodon minusculus 19

11. pm 55710 and pm 37284, Hyrachyus
modestus. pm 26128, Hyrachyus

eximius 24

12. pm 28365, Triplopus cubitalis. cm

18464, Triplopus implicatus 27

13. pm 1088, Amynodon advenus 29

List of Tables

1 . Comparative dental measurements

of selected middle Eocene perissodactyl
taxa 20

2. Length-width measurements of all lower
cheektooth specimens reported here 21

3. Length-width measurements of all upper
cheektooth specimens reported here 23

4. Currently recognized chronologic distri-
butions of selected North American mid-
dle and late Eocene perissodactyl taxa ... 3 1

5 . Stratigraphic distribution within the Wash-
akie Formation of perissodactyl taxa re-
ported here 32

The Mammalian Faunas of the Washakie Formation,
Eocene Age, of Southern Wyoming. Part III.
The Perissodactyls

Steven M. McCarroll John J. Flynn William D. Turnbull

Abstract

Eighteen perissodactyl taxa have been identified in the Field Museum collections from the
Washakie Formation, Washakie Basin, Wyoming: Orohippus sp., Epihippus gracilis, Telma-
therium sp., Mesatirhinus sp., Metarhinus sp., Dolichorhinus sp., Brontotherioidea indeter-
minate, Isectolophus latidens, Eomoropus amarorum, Helaletes nanus, Dilophodon minusculus,
Hyrachyus modestus, Hyrachyus eximius, Triplopus cubitalis, Triplopus implicates, cf. For-
stercooperia minuta, Hyracodontidae indeterminate, and Amynodon advenus. At present, the
Washakie Formation is divided into two members: the lower Kinney Rim Member and the
upper Adobe Town Member. The Adobe Town Member is informally divided into lower,
middle, and upper units, with the Bridgerian-Uintan North American Land Mammal "Age"
boundary currently placed between the lower and middle units.

The Kinney Rim Member contains Mesatirhinus sp., Helaletes nanus, Hyrachyus modestus,
and Hyrachyus eximius. Helaletes nanus and Hyrachyus modestus occur throughout the Bridg-
erian, and their usefulness in defining finer temporal divisions is thus limited. Hyrachyus eximius
elsewhere is limited in age to the late Bridgerian. Its occurrence near the base of the Kinney
Rim Member indicates the lack of early Bridgerian age sediments in the Washakie Formation.
Telmalherium sp., Mesatirhinus sp., Isectolophus latidens, Hyrachyus modestus, and Hyrachyus
eximius are present in the lower unit of the Adobe Town Member, also considered to be late
Bridgerian in age. Metarhinus sp., Dolichorhinus sp., Eomoropus amarorum, Dilophodon min-
usculus, Triplopus cubitalis, Triplopus implicatus, cf. Forstercooperia minuta, and Amynodon
advenus occur only in the middle unit of the Adobe Town Member. All these taxa have early
Uintan first occurrences except Dilophodon minusculus and Hyrachyus eximius, which have
late Bridgerian first occurrences, and Amynodon advenus, which has an earliest Uintan first
occurrence. Additionally, Dilophodon minusculus and Hyrachyus eximius are known from
earliest Uintan deposits elsewhere. This apparent overlap of late Bridgerian taxa with early
Uintan taxa in the middle unit of the Adobe Town Member indicates that the Shoshonian
Subage of the Uintan North American Land Mammal "Age" may be present within the middle
unit of the Adobe Town Member in addition to the lower unit, as previously suggested by
Flynn (1986). The presence of the Uintan taxon Epihippus gracilis from the upper unit of the
Adobe Town Member indicates only an undifferentiated Uintan age. Among perissodactyls,
the future discovery of Colodon or Epitriplopus (both late Uintan first appearance taxa) from
the upper unit of the Adobe Town Member would indicate the presence of the early-late Uintan
boundary within the Washakie Formation.

Introduction sin of northwestern Colorado (Roehler, 1 973). This

paper deals only with the Washakie Formation

The Washakie Formation consists of fluvial rocks within the Washakie Basin as defined by the Rock

of Eocene age cropping out in the Washakie Basin Springs uplift to the west, the Cherokee Ridge to

of southwestern Wyoming and the Sand Wash Ba- the south, the Sierra Madre uplift to the east, and

FIELDIANA: GEOLOGY, N.S., NO. 33, MARCH 29, 1996, PP. 1-38 1

t

IDAHO

ROCK SPRINGS UPLIFT

WAMSUTTER ARCH

I

WASHAKIE BASIN j

SIERRA MAMS MTS

WYOMING I

COLORADO

CHEROKEE RIDGE
AND WASH BASIN

Fig. 1 . General location map showing geographic re-
lationship of the Washakie, Green River (containing the
Bridger Basin), and Uinta basins (from Roehler, 1973).

the Wamsutter arch to the north (Fig. 1). Corre-
lation of the Washakie Formation between the Sand
Wash Basin and the Washakie Basin, however, is
discussed briefly. Within the Washakie Basin (Fig.
2) the Washakie Formation crops out in an area
of about 680 square miles in the geographic center
of the basin (Roehler, 1973).

Granger (1909) divided the Washakie Forma-
tion into two lithostratigraphic units, the lower

Washakie A and the upper Washakie B. Washakie
A corresponded faunally with faunas from the
Bridger C-D, and Washakie B corresponded fau-
nally with faunas from the Uinta A-B. As later
defined by Roehler (1973), the Washakie For-
mation is divided into two members, the lower
Kinney Rim Member (-900 ft/270 m thick) and
the upper Adobe Town Member (~ 2,300 ft/700
m thick). In addition, the Adobe Town Member
is divided into three informal units: lower, middle,
and upper (Fig. 3). Granger's Washakie A is equiv-
alent to Roehler's lower unit of the Adobe Town
Member, and Granger's Washakie B is equivalent
to Roehler's middle unit of the Adobe Town
Member. The Kinney Rim Member of Roehler's
section was considered to be the uppermost part
of the Green River Formation by Granger ( 1 909).
Granger did not recognize rocks stratigraphically
higher than those capping Haystack Mountain, but
subsequent work by Roehler (1973) and Turnbull
(1972) showed a sequence of beds near the geo-
graphic center of the basin to be stratigraphically
higher than the top of Haystack Mountain; the
uppermost of these rocks are the upper unit of the
Adobe Town Member.

N

Twg

/K HAYSTACK MT

^r -^"Ht^

SAND '' HVP^i
BUTTE « jZr J

^Cs«

1 8

s

z

pine v / Ty^y jk

BUTTE ( 1 S*^ ^S

\ 1 / f

/{ \f

/*^dobe}*-i

ir *

1

ill X

\ TOWN \ 1

i-4

#\

K

C*S Twg

VJW

Twka ?

Twg \\V^_

%CZ""

Twkk

WYOMING

-^^ Tpe

COLORADO

1 1

I

0 5 MILKS

I

Fig. 2. Detailed map of study area showing outcrop extent of the Washakie Formation members and informal
units. Major physiographic features are also shown. Abbreviations as follows: Twg = Wasatch and Green River
formations; Twkk = Washakie Formation, Kinney Rim Member; Twka = Washakie Formation, Adobe Town
Member; Tpe = post-Eocene rocks (from Roehler, 1973).

FIELDIANA: GEOLOGY

3&

s

=3

i

fl

CO

Bridger
Formation

Twin Buttes
Member

Black Forks
Member

Vfeshakie

Formation

Granger, 1909

UashakieB

Washakie A

Washakie

Formation

Roehler, 1973

upper

middle

lower

Kinney Rim
Member

Washakie
Formation
This Paper

upper

middle

lower

Kinney Rim Mem

Uinta
Formation

Myton
Member

^Jfagonhound
Member

Fig. 3. Generalized correlation of the Washakie, Bridger, and Uinta formations to the North American Land
Mammal Ages. The upper Bridger Formation is shown to include earliest Uintan time, based on the biostratigraphic
results of Evanoff et al. (1994) and the stratigraphic correlations of Roehler (1992).

Roehler (1973) speculated that some lower por-
tion of the Kinney Rim Member was early Bridg-
erian in age and that the upper unit of the Adobe
Town Member was possibly late Uintan in age.
These age assignments were tentative, based on
lithostratigraphic changes, and have not been borne
out by subsequent faunal evidence. Recently,
McCarroll et al. (1993, 1996) have shown that no
definitive faunal evidence supports an early Bridg-
erian age for the Kinney Rim Member, and it
should be considered late Bridgerian in age (al-
though to date, no specimens have come from the
lowest 30 m of this member). In addition, no de-
finitive faunal evidence supports a late Uintan age
for the upper unit of the Adobe Town Member,
and it should be considered early Uintan in age.

Fossil vertebrates were first collected from the
Washakie Formation in the 1870s (for complete
histories see Roehler, 1973, and Turnbull, 1978).
Fossil mammals are found throughout the for-
mation but are rare in the Kinney Rim Member
and very rare in the upper unit of the Adobe Town
Member. No comprehensive faunal revisions of
the Washakie Formation faunas have been pro-
duced, as has been the case for other western North

American faunas (for example, the lower Eocene
Wasatch and Wind River faunal revisions of Mat-
thew & Granger, 1915). Even so, selected Wash-
akie Formation taxa have been included in various
taxonomic descriptions and revisions, or taphon-
omic reports (Osborn, 1929, titanotheres; Whee-
ler, 1961, uintatheres; Radinsky, 1967a, Hyraco-
dontidae; Turnbull & Martill, 1988, Mesatirhinus
[= Metarhinus of this paper]; Turnbull, 1 99 1 , Pro-
toptychus).

Collection efforts by the Field Museum in the
Washakie Formation were begun in the late 1 940s
by Rainer Zangerl. Zangerl's main interest was the
collection of the varied reptilian fauna. One of
Zangerl's field assistants was William D. Turnbull,
who is now Curator Emeritus at fmnh. Over the
past four decades (although not every year) Turn-
bull has made an extensive collection of the mam-
malian fauna (Turnbull, 1972). This report con-
centrates on specimens in the fmnh collections
(and a few from cm) and is not an inclusive report
of all Washakie Formation perissodactyl speci-
mens in other collections (see Turnbull, 1978, for
a discussion of Washakie Formation collections
in other institutions). In addition, many of the

McCARROLL ET AL: THE PERISSODACTYLS

more complete titanothere specimens are still not
identifiable to genus, as they do not preserve di-
agnostic characters. These and unidentifiable post-
cranial specimens are not included in this study.
Such exclusions explain the small number of spec-
imens in this study, although fossils are much rarer
in the Washakie Formation than in the Bridger
Formation. For our purposes, the most important
of the older fmnh collections are:

1) A small but very important fauna from the
Kinney Rim Member. Roehler (1973) recog-
nized the Kinney Rim Member as distinct from
the underlying Green River Formation, and
more characteristic of, and assignable to, the
Washakie Formation. Prior to Turnbull's col-
lecting, no fossils were known from the section
of rocks now placed within the Kinney Rim
Member.

2) The rim below the Adobe Town Rim. Within
this set of beds, Flynn (1986) postulated the
presence of the Shoshonian Subage (earliest
Uintan) of the Uintan North American Land
Mammal "Age" (NALMA) within the Wash-
akie Formation. ("Age" is in quotation marks
because the NALMAs are not based on cor-
responding time stratigraphic stages.)

3) Haystack Mountain. Many of the classic Uin-
tan age collections from the Washakie For-
mation were made from Haystack Mountain
(Mammoth Buttes of Cope). Cope (1884) dis-
tinguished Haystack Mountain as the eastern
tip of the Mammoth Buttes; subsequent usage
refers to this entire linear feature (see Fig. 2)
as Haystack Mountain (Turnbull, 1 978, p. 581).
In addition to these three major efforts, Turn-
bull has collected throughout the basin and from
within the entire stratigraphic section.

More recent Field Museum collecting efforts be-
gan in the summer of 1990, under the direction
of John J. Flynn and William D. Turnbull, and
continue to the present. As with the earlier efforts,
reconnaissance collecting has encompassed the en-
tire stratigraphic section and much of the areal
extent of the Washakie Formation. Concentrated
collection efforts have been made in the southern
and southeastern portions of the basin (areas un-
dercollected historically, Turnbull, 1972). Of par-
ticular interest is a series of red beds (the middle
red beds of Roehler, 1973) that have produced a
fauna rich in smaller taxa (insectivores, primates,
rodents, creodonts) but few perissodactyls to date.
Stratigraphically, these red beds are approximately

equivalent to the less fossiliferous beds of the rim
below the Adobe Town Rim, which is exposed in
the northwestern portion of the basin, and the Wil-
low Creek Rim, which is exposed in the north-
eastern part of the basin. Also of note is a small
mammalian fauna from the upper unit of the Ado-
be Town Member that at present indicates an early
Uintan age for the upper unit. This fauna will be
reported elsewhere (McCarroll, 1995, in prep.).

The Washakie Formation is important because
of its well-preserved fossil fauna and the presence
of the Bridgerian-Uintan NALMA boundary
within the formation. When fossils were first dis-
covered in western North America, the larger and
most productive basins were heavily collected and
many of the NALMAs were a direct result of this
early work. As we understand more about the
NALMAs, it becomes imperative that we also try
to tie them together so that the transitions and
boundaries between them can be documented, de-
fined, and dated. A recent example of this kind of
work is Flynn's (1986) assessment of the Bridg-
erian-Uintan transition in western North Amer-
ica. Flynn (1986) used biostratigraphy, magnetic
polarity stratigraphy, and radioisotopic dating to
correlate the Bridgerian-Uintan transition be-
tween the Washakie Formation, the Aycross and
Tepee Trail formations of northwestern Wyo-
ming, and the marine and continental La Jolla and
Poway groups of southern California. Flynn (1986)
named the Shoshonian (earliest Uintan) a subage
of the Uintan NALMA. The Shoshonian was de-
fined (see Flynn, 1986, p. 380) by the first ap-
pearance of Amynodon and characterized by the
co-occurrence of what previously had been re-
garded as typically late Bridgerian or early Uintan
taxa. These taxa tended to be (but were not exclu-
sively) smaller-bodied Bridgerian taxa (i.e., Hyop-
sodus, primates, rodents) and larger-bodied Uin-
tan taxa (i.e., perissodactyls).

The Uintan NALMA has gone through many
changes since its inception (summarized in Krish-
talka et al., 1987). Herein, we recognize three
biochronologic divisions of the Uintan NALMA:
1) the earliest Uintan or Shoshonian, 2) the early
Uintan, and 3) the late Uintan. At present, there
is no known fauna from the Uinta A lithostrati-
graphic unit of the Uinta Basin, and the age of
Uinta A strata relative to the Shoshonian and oth-
er Uintan temporal subdivisions is not well un-
derstood. A portion (or all) of the Uinta A strata
may be time equivalent to the earliest Uintan. The
Bridgerian NALMA, by contrast, has had a fairly

FIELDIANA: GEOLOGY

straightforward history (Krishtalka et al., 1987).
The Bridgerian is divided into three biochrono-
logic divisions: 1) earliest Bridgerian or Gardner-
buttean, 2) early Bridgerian, and 3) late Bridgerian.
Historically, the Washakie Formation has been
temporally correlated with varying portions of the
Bridger and Uinta formations (see Fig. 3).

In this paper and a previously published abstract
(McCarroll, 1994) we concentrate on the peris-
sodactyls for the following reasons, all of which
relate to the biostratigraphic and biochronologic
usefulness of the perissodactyls:

1 ) The stratigraphic distribution of perissodactyls
is fairly even throughout the formation. Pri-
mates are much more common finds (abun-
dance) in any particular field season, but their
distribution within the formation is limited to
one or two productive layers within the lower
unit of the Adobe Town Member.

2) The taxonomic diversity of perissodactyls is
relatively high. To date, we have recovered 1 8
perissodactyl taxa from the Washakie Forma-
tion. To use primates as an example once again,
we find only four genera and four species of
primates known to date.

3) Taxonomic revisions of the perissodactyls have
been fairly numerous, resulting in elucidation
of the combination of primitive and derived
characters by which these taxa can be recog-
nized. Unfortunately, in this respect some
specimens reported here can only tentatively
be assigned to a taxon, as they do not preserve
some of the defining characters. In addition,
revisions are needed for some perissodactyl
groups (see Schoch, 1989). The present paper
is not a systematic revision. Even so, we discuss
problems involving perissodactyl systematics,
specifically morphological characters used to
define taxa.

Abbreviations and Institutions

L indicates length; W, width. Bed numbers are
those of Roehler (1973) (or Granger, 1909, as
noted). Many specimens are not given specific bed
numbers because of the difficulty of determining
exactly which bed a specimen was collected from;
most of the beds numbered by Roehler (1973) are
not laterally continuous. Molarization terminol-
ogy is that of Radinsky (1967a). Cusp terminology

is that of Hooker (1989, Fig. 1). Detailed locality
information for locality abbreviations cited in the
text is given in Appendix 1 (except those listed in
Turnbull, 1978). All specimen measurements are
in millimeters (mm), amnh = American Museum
of Natural History, cm = Carnegie Museum of
Natural History, fmnh or fm = Field Museum of
Natural History, jjf = John J. Flynn, NALMA =
North American Land Mammal Age, pm or p =
fmnh fossil mammal collection, ucmp = Univer-
sity of California Museum of Paleontology, Berke-
ley, uw = The Geological Museum, The Univer-
sity of Wyoming, wdt or klwdt = William D.
Turnbull or Kubet Luchterhand, ypm = Yale Pea-
body Museum, ypm-pu = Princeton University
(now housed at the Peabody Museum of Natural
History, Yale University).

Systematic Paleontology

Order Perissodactyla Owen, 1848
Infraorder Hippomorpha Wood, 1927
Superfamily Equoidea Grey, 1821
Family Equidae Grey, 1821

Orohippus sp. Marsh, 1872
(Fig. 4A)

Referred Specimens— pm 55790, isolated left
M1, from Loc. jjf 7-26-92-1, Twka,; pm 39944,
paired lower jaws with partial right and left M3
from Loc. fm-6-83-klwdt, Twka,.

Description— pm 55790 (Fig. 4A) is an almost
complete left M1 lacking only the parastyle. It ap-
pears to be an M1 rather than an M2 because of
its square outline and a hypocone that is slightly
more prominent than the protocone. If pm 55790
were a P4, one would expect a more prominent
protocone and a smaller hypocone. A small me-
sostyle is present. Small but distinct paraconule
and metaconule are present, which may appear
larger in less worn specimens of the same size and
taxon.

Discussion — Granger (1908) differentiated
Orohippus from Hyracotherium (= Eohippus) by
the progressive molarization of the premolars in
Orohippus. He recognized 1 0 species of Orohippus.
More recently, Kitts (1957) revised the genus and
recognized only five species.

Compared to the measurements reported by
Kitts (1957) for Orohippus, pm 55790 (see Table
3) is outside the size ranges of the much larger O.

McCARROLL ET AL: THE PERISSODACTYLS

major and O. agilis; it is within the size range of
O. pumilus. It is slightly smaller than measure-
ments reported for O. progressus and O. sylvaticus,
although only one M1 measurement was reported
for O. progressus by Kitts (1957). pm 55790 may
represent a small individual of O. sylvaticus, as it
is morphologically indistinguishable from ypm
1 1322, a specimen of O. sylvaticus preserving P2-
M1 figured by Kitts (1957, Fig. 8A,B). As stated
previously, pm 55790 is also within the size range
of O. pumilus, a taxon previously known only from
Bridger B beds of the Bridger Formation (Kitts,
1957).

pm 55790 is from the rim below the Adobe Town
Rim that is thought, based on other taxa (Granger,
1 909), to be late Bridgerian in age. At present, the
limited Washakie material assignable to Orohip-
pus prevents a definitive species-level identifica-
tion. At present, taxa restricted to the Bridger B
beds of the Bridger Formation are unknown from
the Washakie Formation. If future specimens in-
dicate the undisputed presence of O. pumilus from
the rim below the Adobe Town Rim, either the
temporal range of O. pumilus should be revised
to include the late Bridgerian or, less likely, given
current knowledge of the temporal distribution of
taxa, the age of a portion of the lower unit of the
Adobe Town Member may be older (early Bridg-
erian) than presently recognized (late Bridgerian).

Epihippus gracilis (Marsh, 1871)
(Fig. 4B,C)

Referred Specimen— pm 55311, left dentary
with dP,-M2 with the unerupted M3 exposed in
the lingual surface of the dentary, from Loc. jjf
7-21-90-1, Twka3.

Description— pm 55311 (Fig. 4B,C) possesses
a diastema between the canine alveolus and the
root of dP, . Two foramina are present on the labial
surface of the dentary. The larger anterior mental
foramen is under the diastema and the smaller
posterior mental foramen is directly under dP2.

pm 5531 1 is missing dP,, which appears to be
single-rooted. dP2 possesses a metaconid-meta-
stylid complex; this area is too worn to determine
with certainty if the metaconid and metastylid were
distinct, but a small posterior extension of enamel
from this area leads us to think that they were.
The protoconid is small and the paracristid and
protocristid are not well developed. The cristid
obliqua is complete, intersecting the posterolabial

base of the metaconid-metastylid complex. The
hypoconid is well developed with a hypolophid
connecting it to a very small entoconid. A small
postcristid branch extends posteriorly from the
small entoconid. The postcristid branch appears
to be notched, separated from the main body of
the tooth by a wear facet. Distinct cingula are not
present.

dP3 and dP4 are more molarized than dP2, with
better developed protocristid and paracristid; the
paracristid descends anterolingually from the pro-
toconid and bends sharply lingually near the mid-
line of the tooth. This pattern is repeated in the
remaining, more posterior teeth. The entoconid
on dP3 and dP4 is better developed than that of
the dP2, appearing as a distinct cusp. The proto-
cristid branch is also more distinct and located
more medially but is still slightly linguad of the
tooth midline. The metaconid and metastylid are
distinct cusps; the metaconid on dP3 is at the mid-
line of the tooth but more linguad on dP4 than on
dP3. Small anterior, posterior, and lingual cingula
are present on dP3 and they are slightly larger on
dP4.

M, and M2 are distinctly more squared than the
deciduous premolars, which are narrower anteri-
orly, giving them a trapezoidal outline. As on DP^,
the area between the postcristid branch and the
posterior edge of the entoconid forms a small an-
teroposteriorly oriented groove, slightly lingual to
the midline of the tooth. Well-developed cingula
are present on both M, and M2, although they are
slightly reduced labially on M2.

Discussion— Granger (1908) recognized only
two species of Epihippus: E. gracilis and E. parvus.
He distinguished E. parvus from E. gracilis by its
smaller size, greater development of the parastyle,
and its compressed mesostyle. Granger (1908) did
not recognize E. uintensis (= Orohippus uintensis)
and considered it synonymous with E. gracilis.

MacFadden (1980), in a study of the perisso-
dactyls of the Tepee Trail Formation of north-
western Wyoming, recognized both E. gracilis and
E. uintensis, differentiating the two solely on the
basis of size. MacFadden (1980) found no mor-
phologic or size differences between E. parvus and
E. gracilis and considered E. parvus to be syn-
onymous with E. gracilis. Length-width plots for
Epihippus P4's (see MacFadden, 1 980, Fig. 3) show
two discrete size populations, the larger E. uin-
tensis and the smaller E. gracilis. The more im-
portant measure for distinguishing the species is
tooth width, as the P4 lengths for the two species
overlap.

FIELDIANA: GEOLOGY

^Br

Fig. 4. A, Orohippus sp., pm 55790, isolated left M1, in occlusal view (fmnh neg. 858 1 3). B-C, Epihippus gracilis,
pm 5531 1, left dentary with dP,-M2. B, Lateral view (fmnh neg. 85824.27). C, Occlusal view (fmnh neg. 85825.6).

McCARROLL ET AL: THE PERISSODACTYLS

pm 5531 1 is confidently assigned to Epihippus
based on the degree of loph development of the
molars, which is typical for Epihippus. pm 5531 1
is too small to be E. uintensis, and is assigned to
E. gracilis solely on the basis of size (see Table 2).

pm 5531 1 is from the upper unit of the Adobe
Town Member, a unit that produces few mammal
fossils. Epihippus gracilis is currently known from
throughout the entire Uintan elsewhere, and its
occurrence here indicates a Uintan age assignment
for the upper unit.

Infraorder Titanotheriomorpha

Hooker, 1989
Superfamily Brontotherioidea

Marsh, 1873

Our discussion of the Washakie Formation ti-
tanotheres will be limited to the generic level. A
good generic-level revision of the group has re-
cently been published (Mader, 1989). That revi-
sion included generic diagnoses based on numer-
ous primitive and derived characters, allowing us
to confidently identify the specimens in this study.
We consider only taxa represented by complete or
partial skulls for this titanothere section, because
many of the taxa are indistinguishable on the basis
of dentition and because Mader's (1989) revision
showed most of the diagnostic derived, generic
characters to be cranial. The species-level taxon-
omy of titanotheres is still in need of extensive
and thorough revision, and we therefore will not
attempt species-level identifications. All dental
measurements of titanothere specimens are given
in the respective taxic descriptions rather than in
a separate table; following Mader (1989), only P2-
M3 measurements are presented.

Telmatherium sp. Marsh, 1872

Referred Specimen— pm 56049, almost com-
plete skull (partially prepared), from Loc. jjf 8-11-
93-1, Twka,.

Description— pm 56049 is a large titanothere
with a P2-M3 length greater than 160 mm. The
unprepared nature of the specimen prevents an
accurate P2-M3 measurement at this time. The
sagittal crest is well developed.

Discussion— pm 56049 is assigned to Telma-
therium based on its size and well-developed high,

narrow sagittal crest, pm 56049 is within the size
range of Dolichorhinus. Dolichorhinus, however,
possesses a low, broad sagittal crest (Mader, 1 989).

Mesatirhinus sp. Osborn, 1908

(Figs. 5A,B, 6A,B)

Referred Specimens— pm 27939, complete skull
with upper dentition, from Loc. fm-1 1-70-wdt,
Twkk, bed 527; pm 27938, partial juvenile skull
preserving P1, dP2"*, M'-2, and indication of the
crypt of M3, from Loc. fm-1 1-70-wdt, Twkk, bed
527; pm 36045, almost complete skull and skele-
ton, from Loc. fm-2-72-wdt, Twka^

Description— pm 27939 (Fig. 5A,B) is a me-
dium-sized titanothere with a P2-M3 length of
137.0 mm. pm 27939 has a very small diastema
between the canine and the P1 alveolus. Both P''s
are missing, and P2-P4 are unmolarized. The orbit
is only moderately developed, and a broad sub-
orbital protuberance is present. The zygomatic arch
is moderately large and curved.

The skull of pm 36045 (Fig. 6A,B) is almost
complete, missing only portions of the anterior
dentition, portions of the molars, and a small por-
tion of the sagittal crest and the left frontal-nasal
boundary. P2-M3 length is 135.2 mm. pm 36045
possesses fairly robust nasals, which are slightly
flared distally. The nasal incision, which is crushed,
appears to extend back to the posterior border of
the M1. The orbital area is also crushed, but ap-
pears not to have been enlarged. The suborbital
protuberance is long and well developed. The right
canine is present and has moved out of the alve-
olus by approximately xh inch. This makes the
canine appear enlarged when actually it is fairly
small. Very small upper diastemas are present be-
tween the canine and the I3 and P1.

Mader (1989) was unable to corroborate the as-
sertion by Osborn (1929) that Mesatirhinus pos-
sessed incipient horns, pm 36045 possesses what
appears to be an "incipient" horn on the right side
of the skull near the frontal-nasal boundary. This
area is not preserved on the left side of the skull.
The "incipient" horn of pm 36045 might be an
artifact of crushing. Osborn often ignored defor-
mation due to crushing, and his observation of
incipient horns in specimens assigned to Mesati-
rhinus may have been a result of postdepositional
deformation of certain specimens. Comparisons
with other skulls, however, indicate that the in-
cipient horns of pm 30645 are real and not an
artifact of crushing.

FIELDIANA: GEOLOGY

Fig. 5. Mesatirhinus sp., pm 27939, complete skull. A, Dorsal view (fmnh neg. 85824.7). Arrow indicates large
suborbital protuberance characteristic of Mesatirhinus. B, Lateral view (fmnh neg. 85824.16).

McCARROLL ET AL: THE PERISSODACTYLS

Fig. 6. Mesatirhinus sp., pm 36045, almost complete skull. A, Dorsal view (fmnh neg. 8581 1). Arrow 1 indicates
posteriormost extension of the lateral nasal incision; arrow 2 indicates anteriormost extension of the orbit. Note that
the lateral nasal incision does not reach back to the orbit, characteristic of Mesatirhinus. B, Lateral view (fmnh neg.
85812).

10

FIELDIANA: GEOLOGY

Discussion— According to Mader (1989), Mes-
atirhinus is distinguished from Metarhinus by the
morphology of the nasal and orbital regions. In
Mesatirhinns the lateral nasal incision does not
extend as far back as the orbital region, in contrast
to the condition in Metarhinus. Mesatirhinus pos-
sesses a prominent suborbital protuberance, and
the orbit is not prominent. In contrast, Metarhinus
possesses a small suborbital protuberance and the
orbit is prominent. Even though pm 36045 is dor-
soventrally crushed, the orbits are clearly not pro-
nounced. In addition, the lateral nasal incision
does not extend as far posterior as the rim of the
orbit.

pm 27939 is moderately crushed, affecting direct
comparison with Mader's ( 1 989) generic diagnosis
of Mesatirhinus. Characters used by Mader (1 989)
that are also present in pm 27939 include small
canines, very small upper diastema, unmolarized
premolars, well-developed suborbital protuber-
ance, and no hypocone on M3. The nature of the
nasals is difficult to determine because of crushing.
It appears, however, that after correcting for crush-
ing the nasals would have been flared distally.

pm 27938 and pm 27939 are from the Kinney
Rim Member, and pm 36045 is from the lower
unit of the Adobe Town Member. Mesatirhinus
is currently known from the Bridgerian elsewhere
(Mader, 1989).

Metarhinus sp. Osborn, 1908
(Fig. 7A,B,C)

Referred Specimens— pm 3935, anterior half of
skull with right and left P'-M3, from Loc. fm-3-
57-wdt, Twka2; pm 56023, left half of skull with
C-M3, from Loc. fm-6-58-wdt, Twka2. pm num-
bers for the skull (n = 1 5), lower jaw (n = 27),
isolated teeth (n = 85), and postcranial specimens
(n = 106) from a monospecific titanothere (Me-
tarhinus) assemblage are given in Appendix 2. This
assemblage has been described by Turnbull and
Martill (as Mesatirhinus) (1988); all specimens
from this quarry are from Loc. fm-12-70-wdt,
Twka2, bed 643 or low in bed 644. Because it is
from a single catastrophic event, this assemblage
provides an important record of variation within
a single titanothere taxon, comparable to single
locality samplings of modern animals. This is in
contrast to the typical time-averaged accumula-
tion samples of most titanothere taxa. Additional
study of the paleobiology of this assemblage is
planned for a future date. One specimen (pm 35932)
from the quarry is figured here (Fig. 7C) to further

document the generic assignment of the quarry
sample.

Description— pm 3935 (Fig. 7A,B) is a medi-
um-sized titanothere with a P2-M3 length of 144.0
mm. pm 3935 possesses a prominent orbit and a
deep nasal incision that reaches back to the front
of the orbital region. There is a small but obvious
suborbital protuberance. The nasal region is slight-
ly crushed and it is difficult to discern whether the
nasals are constricted at the base. Although the
nasals appear to be slightly constricted at the base,
it is possible that if the skull were uncrushed the
constriction would appear greater; alternatively,
the apparent constriction now present may be a
result of crushing, in which case the uncrushed
skull would have no constriction.

pm 35932 (Fig. 7C) is a poorly preserved, crushed
skull from the Metarhinus quarry. It possesses a
large bony orbit, small suborbital protuberance,
and a nasal incision that reaches back to the orbit.
The P2-M3 length is 157.0 mm.

Discussion— Overall, the nasals of pm 3935 are
most similar to the spoon-shaped nasals of Me-
tarhinus rather than the unconstricted, distally
flared nasals of Mesatirhinus or the shorter, ta-
pered nasals of Rhadinorhinus. The tips of the
nasals do seem to taper slightly, giving them a
distinct spoon shape; this tapering is not the same
as in Rhadinorhinus, in which the nasals taper
from their base to their tips. Of titanotheres pos-
sessing a suborbital protuberance, Metarhinus is
the only one in which it is small; Mesatirhinus,
Rhadinorhinus, and Dolichorhinus all possess a
large suborbital protuberance. The lateral nasal
incision in pm 3935 and pm 35932 extends back
to the orbital region, as described for Metarhinus
(Mader, 1989). The posterior extension of the na-
sal incision may in part be attributed to crushing
of surrounding bones, although we think it is clear
that the nasal incision reached the orbital region
in this specimen. The crushing in pm 3935 is most
extensive on the right side. This crushing may have
displaced the lateral nasal incision further poste-
riorly than it actually was, on the less crushed left
side; however, the lateral nasal incision still reach-
es the anteriormost portion of the prominent orbit.

Generic assignment of the titanothere quarry
sample of Turnbull and Martill (1988) is changed
from Mesatirhinus to Metarhinus. These speci-
mens were assigned to Mesatirhinus prior to Mad-
er's (1989) revision. The small suborbital protu-
berance, large bony orbit, and deep nasal incision
all indicate Metarhinus rather than Mesatirhinus.

pm 3935, pm 56023, and the quarry sample are

McCARROLL ET AL: THE PERISSODACTYLS

11

Fig. 7. Metarhinus sp., pm 3935, anterior half of skull. A, Dorsal view (fmnh neg. 85805). B, Lateral view (fmnh
neg. 85806). Arrow 1 indicates posteriormost extension of the lateral nasal incision; arrow 2 indicates anteriormost
extension of the orbit. Note that the lateral nasal incision does reach back to the orbit and the orbit is well defined
by a raised bony rim, both characteristic of Metarhinus. (Figure continued on page 13.)

12

FIELDIANA: GEOLOGY

Fig. 7 (continued). C, pm 35932, lateral view (fmnh neg. 85982).

from the middle unit of the Adobe Town Member.
Metarhinus is currently known from the Uintan
elsewhere (Mader, 1989), including the Shoshon-
ian (earliest Uintan) Subage (Flynn, 1986). pm
56023 is from near the base of the middle unit of
the Adobe Town Member and, based on the dis-
tribution of other taxa, probably represents an ear-
liest Uintan (Shoshonian Subage) occurrence of
Metarhinus rather than an early Uintan occur-
rence. The same may be true of pm 3935, although
it is from slightly higher in the section. The quarry
sample (Appendix 2) is stratigraphically higher, in
strata inferred to be early Uintan in age (based on
other taxa).

Dolichorhinus sp. Hatcher, 1895

(Fig. 8A,B)

Referred Specimens— pm 3870, complete skull,
from Loc. fm-2-57-wdt, Twka2; pm 3873, com-
plete skull, from Loc. fm-6-57-wdt, Twka2.

Description— pm 3870 (Fig. 8A,B) is a com-
plete skull missing only the right and left I1-2. pm
3870 is a large titanothere with a P2-M3 length of
179.1 mm. pm 3870 possesses six upper incisors
and large pointed canines. A small diastema is
present between I3 and the canine, and a larger
diastema exists between the canine and P1. P' has
a single cusp, whereas P2-3 possess two labial and
a single lingual cusp. M1-3 lack metaconules and
protoconules, and M3 possesses a small hypocone.
The nasals broaden very slightly from their base

and are slightly spoon-shaped. Two small horns
are present dorsally and slightly anterior of the
orbit. A large suborbital protuberance is present,
subdivided into a smaller anterior flange and a
larger posterior flange. The distinction between the
two flanges, and their difference in size, are not as
great in pm 3870 as we observed in other speci-
mens of Dolichorhinus from the Uinta Formation
(p 12175, p 12182). A broad shelf, rather than a
sharp sagittal crest, defines the top of the cranium.
pm 3870 is only slightly crushed, the most exten-
sive crushing being on the posterior dorsal portion
of the skull.

A second complete skull (pm 3873) is almost
identical to pm 3870. pm 3873 shows a greater
distinction, as well as a greater difference in size,
between the anterior and posterior suborbital pro-
tuberances, pm 3873 is much less crushed than pm
3870 and the rounded nature of the cranial vertex
is more obvious. There are two "pits" posterolin-
gual to the horns above the orbit; these are not
discernible on pm 3870.

Discussion— Dolichorhinus has the most de-
rived features of any Eocene titanothere discussed
by Mader (1989). pm 3873 and pm 3870 may be
confidently assigned to Dolichorhinus based on the
presence in both specimens of all the unique de-
rived characters that Mader (1989) assigned as
diagnostic of the genus. These derived features are
"hyperdolichocephalic skull; large suborbital pro-
tuberance with a small anterior flange and a larger
posterior flange; small angular horn at frontonasal

McCARROLL ET AL: THE PERISSODACTYLS

13

Fig. 8. Dolichorhinus sp., pm 3870, complete skull. A, Dorsal view (fmnh neg. 85810). Arrow indicates low,
broad sagittal crest typical of Dolichorhinus. Compare this to the sharply defined sagittal crest of Mesatirhinus in
Figure 5A. B, Lateral view (fmnh neg. 85809).

14

FIELDIANA: GEOLOGY

boundary over orbit; rounded cranial vertex with
no sagittal crest" (Mader, 1989, p. 468).

Both pm 3873 and pm 3870 are from high within
the middle unit of the Adobe Town Member. Doli-
chorhinns is currently known from the Uintan
elsewhere (Mader, 1989). Its occurrence here in-
dicates an undifferentiated Uintan age assignment
for the middle unit of the Adobe Town Member.

Brontotherioidea indeterminate

Referred Specimen— pm 1 676, partial skull and
associated bone fragments, from Loc. fm-6-56-
wdt, Twka2.

Description— pm 1676 is approximately the
same size as pm 36045 (Mesatirhinus), but is miss-
ing the orbital and nasal regions; the suborbital
protuberance is as well developed as in pm 36045,
although there is a more obvious division into
smaller anterior and larger posterior flanges, sim-
ilar to those in some specimens of Dolichorhinus.
Preserved portions of the maxillary indicate that
the lateral nasal incision was deep, possibly reach-
ing back to the orbits.

Discussion— pm 1676 cannot be confidently as-
signed to a taxon because the uniquely diagnostic
parts of the nasal and orbital regions are not pre-
served, pm 1 676 could be assigned to Mesatirhinus
or Rhadinorhinus based on its size and the prom-
inent suborbital protuberance. The specimen,
however, is from the middle unit of the Adobe
Town Member, which is thought to be earliest to
early Uintan in age. If pm 1676 is Mesatirhinus,
it would be the first Uintan occurrence of the taxon
(see Mader, 1989). Alternatively, pm 1676 could
be assigned to Rhadinorhinus, which is known from
the Uintan of the Uinta Formation. The specimen
also possesses a deep nasal incision, also a char-
acter of Rhadinorhinus (Mader, 1989). IfPM 1676
is Rhadinorhinus, it would represent the first re-
port of the genus from outside of the Uinta For-
mation of the Uinta Basin.

Infraorder Moropomorpha

Schoch, 1984
Family Isectolophidae Peterson, 1919

Isectolophus latidens
(Osborn, Scott, & Speir, 1878)

(Fig. 9A)

Referred Specimen— pm 55952, associated
RM1"3, LM2-3, partial R&LM3, from Loc. jjf 8- 1 3-
93-1, Twka,.

Description— M' of pm 55952 (Fig. 9 A) is nar-
rower posteriorly than anteriorly, the paracone is
the most prominent cusp, and the parastyle is
rounded and well developed. M2 is also narrower
posteriorly and the parastyle is larger and more
prominent than in M1. In M3 the metaloph is ex-
tended lingually compared to that of M1 and M2,
giving M3 a more trapezoidal outline. The para-
style is flattened and less prominent than on M1-2.
Prominent anterior, posterior, and lingual cingula
are present on all upper molars.

Both M3's are incomplete, lacking the anterior
portion of the tooth. The hypolophid is well de-
veloped, with the cristid obliqua intersecting the
protocristid slightly lingual to the protoconid. A
large, well-developed hypoconulid is present, with
a large notch in the posterolabial corner.

Discussion— Isectolophus differs from Homo-
galax in the lack of protoconules and metaconules
on M1-3 (rarely present in Homogalax), the lack
of a metastylid on M,_3, and in being larger in size
(Radinsky, 1963). At present, two species of Is-
ectolophus are recognized, /. latidens and /. an-
nectens. They are differentiated by the larger size
and the consistent presence of two lingual cusps
on P3 in /. annectens. Without the preservation of
P3 we can use only size to distinguish between /.
latidens and /. annectens. On the basis of size (see
Tables 2 and 3) we assign pm 55952 to /. latidens,
as all measurements fall within the range reported
for that species and outside the range of/, annec-
tens (Radinsky, 1963).

pm 55952 is from the lower unit of the Adobe
Town Member. The occurrence of /. latidens (pm
55952), a late Bridgerian taxon elsewhere, from
the lower unit of the Adobe Town Member in-
dicates a late Bridgerian age assignment for this
unit.

Superfamily Chalicotherioidea

Gill, 1872
Family Chalicotheriidae

Gill, 1872

Eomoropus a ma ro rum (Cope, 1881)
(Fig. 9B-H)

Referred Specimens— pm 1670, left dentary
fragment with P4-M3, from Loc. fm-3-56-wdt,
Twka2; pm 2082, associated postcrania, including
proximal end of femur, distal ends of tibia and
fibula, astragalus, calcaneum, navicular, cuboid,
lateral cuneiform, internal cuneiform, three com-

McCARROLL ET AL: THE PERISSODACTYLS

15

Fig. 9. See legend on opposite page.

16

FIELDIANA: GEOLOGY

Fig. 9. A, Isectolophus latidens, pm 55925, right M1-3 found in association, in occlusal view (fmnh neg. 85808).
B-H, Eomoropus amarorum. B, pm 1670, left dentary fragment with P4-M,, in occlusal view (fmnh neg. 85814).
C-D, pm 2082, anterior (fmnh neg. 85978) and posterior (fmnh neg. 85977) views of right tibia and fibula; note the
well-developed fibula compared to the figured type specimen (see Osborne, 1913, Fig. 7). E-G, pm 2082, internal
(fmnh neg. 85981), anterior (fmnh neg. 85980), and external (fmnh neg. 85979) views of right tarsus. H, pm 2082,
three sesamoids (fmnh neg. 85976).

plete metatarsals (II, III, IV), two podials, and
three sesamoids, from Loc. fm-1-56-wdt, Twka2.
Description -The P4 of pm 1670 (Fig. 9B) has
a prominent metaconid and a small but distinct
metastylid; the entoconid is very small. M, is worn
and heavily damaged, but a well-developed en-
toconid is indicated by an upturn in the partial
crown surface near the posterior lingual corner of
the tooth. M2_3 are almost complete, with well-

developed metastylids and very prominent ento-
conids compared to M,. Small cingula are present
along the anterior edge of M2_3. M,_2 possess small
hypoconulids; the posterior end of M3 is broken,
but the presence of a well-developed hypoconulid
is indicated by the surface features that are pre-
served.

pm 2082 (Fig. 9C-H) comprises an almost com-
plete distal right hind limb. There is a proximal

McCARROLL ET AL: THE PERISSODACTYLS

17

half of a badly crushed femur. Its head is attached
by a short neck and has a well-developed foveal
pit. Most of the greater trochanter is present; its
anterior portion reaches a height equal to that of
the head, while the posterior, broken portion ex-
ceeds the height of the head. As in the type (amnh
5096, using Osborn's 1913 figures and descrip-
tions), there is a marked fossa on the posterior
surface. Second and third trochanters are similarly
developed as in the type, although the latter is
incomplete and may have extended a bit farther
down the shaft than it does on the type (amnh
5096). Length of the preserved proximal half is
260.0 mm, the distance from the head to the tip
of the third trochanter is 150.0-160.0 mm, and
the distance from the head to the middle of the
second trochanter is 100.0-1 10.0 mm.

The tibia and fibula of pm 2082 (Fig. 9C,D) also
correspond well with the type, except for one sig-
nificant difference: the fibula of pm 2082 has a
robust shaft and the type does not. Osborn (1913,
p. 271) stated that "A distinctive feature is the
marked reduction of the fibula; the lower portion
of the shaft is so slender as to indicate that the
central portion may have been incomplete. In Mo-
ropus the fibula has a complete shaft." We suspect
that Osborn may have misinterpreted a weathered
or incomplete shaft, in which case pm 2082 may
give a better idea of the condition of the fibula of
Eomoropus than does the type.

The tarsus of pm 2082 is almost complete (Fig.
9E-G). The three metatarsals, astragalus, and cal-
caneum have the same features and proportions
as in the type. The same is true for the navicular,
except that the facet for articulation with the cal-
caneum indicates a weaker articulation than Os-
born noted for the type. Furthermore, in pm 2082
the cuboid articulates with the dorsal internal sur-
face of the astragalus, and it is only on the surface
that the two could be even slightly separated by
the navicular. The posterior extension of the cu-
boid is a somewhat more massive and pronounced
process than Osborn figured (1913, Fig. 4— B2).
The ectocuneiform (= external, or tarsal III) is
broader than deep, and not as quadrate on its an-
terior face as is that of the type. The mesocunei-
form (= middle, or tarsal II) is small and abbre-
viated, as Osborn described it in the type. Osborn
(1913, Fig. 4— B3) showed a bone he took to be
the entocuneiform (= internal, or tarsal I), but that
to us resembles a sesamoid, pm 2082 has three
sesamoid bones (Fig. 9H), but unfortunately they
were prepared free without their positions relative
to the rest of the foot being noted, pm 2082 has
no obvious facets which would indicate the pres-
ence of an entocuneiform.

The three metatarsals (II, III, IV) are complete
bones. On the distal end each shows exactly the
same sort of division into a keeled sesamoidal
posterior face and a smoothly convex anterior
phalangeal face, which Osborn describes for the
metacarpals of the type. The best preserved of the
two podial bones may belong to the fourth toe, as
it makes a fair articulation with metatarsal IV.

Discussion— The most recent revision of Eo-
cene chalicotheres is that of Lucas and Schoch
(1989). They recognized Eomoropus amarorum
and Grangeria anarisus from the western United
States, and E. quadridentatus and G. canina from
the People's Republic of China. Radinsky (1964)
recognized the same taxa, as well as a third Chinese
species, G.l major, which Lucas and Schoch (1989)
synonymized with G. canina.

Both Radinsky (1964) and Lucas and Schoch
(1989) referred pm 1670 to E. amarorum, but did
not discuss the specimen in detail. Its size (see
Table 2) indicates that it should be assigned to a
species of the smaller genus Eomoropus rather than
of the larger genus Grangeria. According to Lucas
and Schoch (1989), E. amarorum differs from E.
quadridentatus in the more molariform premolars
of E. quadridentatus, and in differences between
P2"* and P2 of the two species. P2 is not preserved
in pm 1 670, so direct comparisons cannot be made.
P4 is preserved, but we have found no comparative
discussions of P4 morphology between E. ama-
rorum and E. quadridentatus. We have not been
able to examine specimens of E. quadridentatus
for comparison. Barring evidence to the contrary,
we follow Radinsky (1964) and Lucas and Schoch
(1989) and assign pm 1670 to E. amarorum. pm
2082 agrees well enough with Osborn's (1913) de-
scription of the type that we also assign it to E.
amarorum.

Both pm 1 670 and pm 2082 are from the middle
unit of the Adobe Town Member. Eomoropus
amarorum is currently known from the early Uin-
tan elsewhere (Lucas and Schoch, 1989); its oc-
currence here indicates an early Uintan age as-
signment for some part of the middle unit of the
Adobe Town Member.

Superfamily Tapiroidea

Burnett, 1830
Family Helaletidae Osborn, 1892, in

Osborn and Wortman, 1892

Helaletes nanus (Marsh, 1871)
(Fig. 10 A)

referred specimen— pm 55951 isolated right M3,
from Loc. fm-3-74-wdt, Twkk.

18

FIELDIANA: GEOLOGY

A

!

5 cm

B

Fig. 10. A, Helaletes nanus, pm 55951, isolated right M3> in occlusal view (fmnh neg. 85815). B, Dilophodon
minusculus, pm 55709, right M'-3 found in association, in occlusal view (fmnh neg. 85825.7).

Description— pm 55951 (Fig. 10A) is almost
complete, lacking only broken metaconid and en-
toconid tips. The roots lack only the proximal tips,
and the posterior half of the tooth root shows a
bony reinforcement under the hypoconulid char-
acteristic of an M3.

pm 55951 is distinctly bilophodont. The pro-
toconid is very slightly anterior to the metaconid,
whereas the hypoconid is distinctly more anterior
than the entoconid. Both the paralophid and the
protocristid are small, with the paralophid more
pronounced and descending anteriorly from the
protoconid, then turning sharply lingually. The

protolophid is distinctly notched, while the hy-
polophid is only slightly notched. No lingual or
labial cingula are present. A small anterior cin-
gulum is present, starting lingually where the par-
alophid descends to the base of the metaconid,
and running labial I \ around the base of the pro-
tocone. A hypoconulid is present. It is medially
situated, but closer to the entoconid than to the
hypoconid. Small ridges connect the hypoconulid
to the entoconid and the hypoconid. The ridge
extending to the hypoconid is the longer of the
two.
Discussion— Helaletes is a small- to medium -

McCARROLL ET AL: THE PERISSODACTYLS

19

Table 1 . Comparative dental measurements (in mm) of selected middle Eocene perissodactyl taxa.

Taxon

LM"3

LM..3

LP'-M3

Source

Isectolophus annectens

46.8

Radinsky, 1963

Isectolophus latidens

—

40.4

—

Radinsky, 1963

Helaletes nanus

31.6

—

—

Radinsky, 1963

Helaletes intermedins

44.4

—

—

Radinsky, 1963

Dilophodon minusculus

—

28.0

—

Radinsky, 1963

Dilophodon leonatus

—

25.1

—

Radinsky, 1963

Hyrachyus modestus

45-50

—

—

Radinsky, 1967b

Hyrachyus eximius

64

—

—

Radinsky, 1967b

Triplopus cubitalis

—

35

—

Radinsky, 1967a

Triplopus implicatus

—

46

—

Radinsky, 1967a

Amynodon advenus

93-131

90-117

—

Wall, 1982

Forstercooperia grandis

84-97

84-97

—

Lucas etal., 1981

Forstercooperia minuta

71-79

71-75

—

Lucas etal., 1981

Fouchia elyensis

19.2

18.6

—

Emry, 1989

Palaeosyops

—

—

129-165

Mader, 1989

Telmatherium

—

—

160-190

Mader, 1989

Mesatirhinus

—

—

128-145

Mader, 1989

Metarhinus

—

—

138-145

Mader, 1989

Rhadinorhinus

—

—

143-148

Mader, 1989

Dolichorhinus

—

-

164-193

Mader, 1989

sized helaletid. According to Radinsky ( 1 963), He-
laletes is characterized by the following combi-
nation of characters: canines small; P1 simple; P2^*
submolariform with the metaloph less prominent
than the protoloph and a tendency for the hypo-
cone to separate off from the protocone; metacone
of M1-2 slightly convex to flat and slightly short-
ened; M3 metaloph relatively short; P, absent; tri-
gonids of P2_4 low but with long paracristids; small
entoconid present on P^; M3 retains a hypocon-
ulid; greatly enlarged nasal incision.

At present, two species of Helaletes are recog-
nized: H. nanus and H. intermedins. They are dis-
tinguished from each other most readily on the
basis of size (see Table 1). In addition, the P3 me-
taloph of H. nanus extends toward an incipient
hypocone, in contrast to H. intermedius, where the
metaloph extends toward the protocone, bypass-
ing the hypocone (Radinsky, 1963).

pm 55951 is referred to H. nanus on the basis
of size (see Table 2) and the presence of an M3
hypoconulid. pm 55951 is small for H. nanus com-
pared to measurements reported by Radinsky
(1963), and is smaller than any measurements re-
ported for H. intermedius. pm 55951 is closer in
size to reported measurements (Radinsky, 1963)
of Dilophodon minusculus than to either species
of Helaletes; however, D. minusculus lacks an M3
hypoconulid.

pm 5595 1 comes from the Kinney Rim Member,
the lowest unit of the formation. Helaletes nanus
is currently known from the Bridgerian elsewhere,
and its occurrence here indicates an undifferen-

tiated Bridgerian age assignment for the Kinney
Rim Member.

Dilophodon minusculus Scott, 1883

(Fig. 10B)

Referred Specimens— pm 55709, associated
right M1-3, from Loc. jjf 7-25-92-1, Twka2; pm
5571 1, isolated left M3, from Loc. fm-6-56-wdt,
Twka2.

DESCRiPTiON-The M1 of pm 55709 (Fig. 10B)
has a posterolabially directed metastyle and a me-
tacone that is very slightly convex labially. The
parastyle is very distinct, with a notch between it
and the paracone. Anterior and posterior cingula
are present, as is a cingulum labial to the meta-
cone. In pm 55709, the M2 differs from the M1 in
having a broader notch between the parastyle and
paracone (this may be due to differences in wear
stage), a metacone that is very slightly concave
labially, and a slightly larger parastyle. The M3 of
pm 55709 has a very small metacone that is also
more lingually deflected than in M1-2. In addition,
the labial surface of the metacone is flat and has
no associated cingulum. The posterior cingulum
of M3 is smaller than in M1 or M2.

pm 5571 1 is very similar to pm 55709 but has
a more robust parastyle and metastyle. pm 5571 1
is longer than pm 55709 (Table 3).

Discussion— Dilophodon is a very small hela-
letid. According to Radinsky (1963), Dilophodon
is recognized by the following combination of

20

FIELDIANA: GEOLOGY

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McCARROLL ET AL: THE PERISSODACTYLS

21

characters: premolar molarization retarded com-
pared to the Helaletes-Colodon line; M1-2 meta-
cone lingually displaced, slightly convex labially,
and with a small labial cingulum; short lower post-
canine diastema; P, absent; M3 hypoconulid not
present.

At present, two species of Dilophodon are rec-
ognized, D. minusculus (late Bridgerian) and D.
leotanus (late Uintan). They are distinguished (Ra-
dinsky, 1963) from each other based on the fol-
lowing: size (see Table 1); P2 with two labial cusps
in D. leotanus, only one in D. minusculus; P3-^
relatively nonmolariform in D. minusculus, sub-
molariform in D. leotanus; symphysis begins an-
terior to P2 in D. minusculus, whereas it is pos-
terior to P2 in D. leotanus; P2^» long and narrow
in D. minusculus compared to short and narrow
in D. leotanus.

Both specimens reported here compare well with
D. minusculus measurements reported by Radin-
sky (1963). D. leotanus, a late Uintan form, is
smaller than D. minusculus, but the size difference
is not great (see Table 1). Even so, pm 55709 and
pm 5571 1 are closer to D. minusculus than to D.
leotanus (see Table 3). In addition, the concavity
of M1-2 metacones of pm 55709 are closer to D.
minusculus, as D. leotanus has more convex M1-2
metacones.

Radinsky (1963) recognized no early Uintan
species of Dilophodon and did not preclude the
evolution of the late Uintan D. leotanus directly
from the late Bridgerian D. minusculus.

Black (1979) reported D. leotanus from the late
Eocene Badwater Creek Fauna of central Wyo-
ming. The sizes of the upper and lower molars of
those specimens are closer to D. minusculus,
whereas the anterior teeth are closer in size to D.
leotanus. The possibility thus exists that D. leo-
tanus molars overlap in size with those of D. min-
usculus, and if specimens are found without the
anterior dentitions preserved, the two taxa may
be confused.

Schiebout (1977) reports Dilophodon sp. indet.
from the La Jolla and Poway groups of San Diego
County, California. Schiebout considers these
specimens intermediate between D. minusculus and
D. leotanus. "Early Uintan" (now considered ear-
liest Uintan [Flynn, 1986]) D. minusculus is re-
ported from the Tepee Trail Formation of north-
western Wyoming by MacFadden (1980).

Both specimens reported here were collected low
within the middle unit of the Adobe Town Mem-
ber, both from approximately bed 630. Dilopho-
don minusculus is currently known from the late

Bridgerian to earliest Uintan elsewhere, and D.
leotanus is known from the late Uintan elsewhere
(Radinsky, 1963). Assuming that D. leotanus is
derived from D. minusculus, this leaves us with
no species of Dilophodon from the early Uintan.
Flynn (1986) lists Dilophodon, presumably D.
minusculus, based on MacFadden (1980), as a
characteristic earliest Uintan taxon but gives no
species-level data or discussion. This is an im-
portant distinction here because both pm 55709
and pm 557 1 1 are from low within the middle unit
of the Adobe Town Member, previously thought
to be early Uintan. The co-occurrence of D. min-
usculus with characteristic early Uintan taxa would
indicate an earliest Uintan, rather than late Bridg-
erian or early Uintan, age for some lower portion
of the middle unit of the Adobe Town Member.

Superfamily Rhinocerotoidea
Gill, 1872

Hyrachyus modestus (Leidy, 1870)

(Fig. 11A,B)

Referred Specimens— pm 37284, RM2 in max-
illary fragment, from Loc. fm- 1 1 -70-wdt, Twkk,
bed 527; pm 55358, LP2"4 in maxillary fragment
with possibly associated postcranial fragments,
from Loc. jjf 7-24-90-1, Twka,; pm 55710, RP3-
M3 in dentary fragment, from Loc. jjf 7-24-90-1,
Twka^ pm 55712, RM2 with associated dentary
fragment, from Loc. fm-1-58-wdt, Twka,; pm
55959, left dentary fragment with P4 and partial
M2, from Loc. jjf 7-28-92-2, Twka,.

Description— pm 55710 (Fig. 1 1A) preserves a
portion of the symphysis showing a diastema be-
tween the canine and P,. The symphysis extends
beneath the anterior half of P2. The posterior men-
tal foramen is located beneath the anterior half of
M3. pm 55710 is the most complete H. modestus
dentary in the fmnh collections, possessing the
right P3-M3. The alveoli of the anterior premolars
indicate that P, was single-rooted and P2 was prob-
ably small, unmolarized, and double-rooted. P3
has a well-developed protocristid and a small,
sharply curved paracristid; the hypolophid and en-
toconid are small and poorly developed; the hy-
poconid is distinct but lower than the metaconid
and protoconid. P4 is larger and more molarized
than P3; the hypolophid and entoconid are more
developed but still lower than the metaconid and
protoconid.

22

FIELDIANA: GEOLOGY

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McCARROLL ET AL: THE PERISSODACTYLS

23

Fig. 11. A, Hyrachyus modestus, pm 55710, right dentary fragment with P3-M3, in occlusal view (fmnh neg.
85816). B, Hyrachyus modestus, pm 37284, right maxillary fragment with M2, in occlusal view (fmnh neg. 85817).
C, Hyrachyus eximius, pm 26128, isolated left M3, in occlusal view (fmnh neg. 85777.1 1).

M,_3 are very similar, becoming progressively
larger in size from M, to M3. The molar proto-
cristids and hypolophids are almost equal in size,
compared to those of the premolars, in which the
protocristids and hypolophids differ in size. The
hypolophid on M3 runs slightly more diagonally
across the tooth rather than more transversely as
in M[_2. M3 lacks a hypoconulid.

pm 55358 is a left maxillary fragment preserving
P2 and the lingual half of P3-^. All three premolars
are nonmolariform with no indication of a second
lingual cusp. P2 has two indistinct labial cusps.

pm 37284 (Fig. 1 IB) is a right maxillary frag-
ment preserving a complete M2. It possesses a

slightly concave labial metacone, with a small la-
bial cingulum. The metacone is deflected lingually
to the midline of the tooth. The paracone is the
most prominent cusp of the tooth. The parastyle
is large and distinct from the paracone. The pro-
toloph is long and possesses a small paraconule,
which is slightly labial to the midline of the tooth.
The metaloph is much shorter than the protoloph
and possesses a very small metaconule positioned
along the midline of the tooth. A distinct ridge
runs from the paracone toward the center of the
tooth.

Discussion— A combination of characters is
used to recognize Hyrachyus. These include: re-

24

FIELDIANA: GEOLOGY

tention of P,; nonmolariform to submolariform
premolars; no M3 hypoconulid; and size (Radin-
sky, 1967b). At present, two species of North
American Hyrachyus are recognized, H. modestus
and H. eximius. Both species are reported here
from the Washakie Formation. They are distin-
guished from each other on the basis of size (see
Table 1) (Radinsky, 1967b). Schoch (1989, p. 310)
considered Radinsky's revision of Hyrachyus to
one genus and two species to be too "lumped,"
but gave no species-level revisions. Until further
taxonomic revision, we follow Radinsky (1967b).

pm 55710, a right dentary with P3-M3 and al-
veoli of P,_2, cannot be assigned to Helaletes nan-
us, as its M3 lacks a hypoconulid. Length-width
measurements of the specimens reported here (see
Tables 2 and 3) compare well with those given by
Radinsky ( 1 967b) for H. modestus from the Bridg-
er Formation. Radinsky (1967b) doubted all pre-
vious reports of Hyrachyus from the Washakie
Formation, giving either incorrect locality data or
misidentification of Triplopus specimens as the
reason(s). He stated that Triplopus specimens are
easily confused with Hyrachyus, especially when
M3 is not preserved.

This presents a problem, however, as no spec-
imens of//, modestus reported here preserve M3.
Hyrachyus modestus is the smallest species of Hy-
rachyus, and it overlaps in size with Triplopus im-
plicatus, also known from the Washakie Forma-
tion. A second species of Triplopus from the
Washakie Formation, T cubitalis, is much smaller
than H. modestus (see Table 1) (Radinsky, 1967a).
pm 55710 has an M,_3 length of 47.2 mm, only
slightly larger than T. implicatus reported by Ra-
dinsky (1967a) (see Table 1). Unfortunately, no
discrete morphological characters are known to
distinguish Hyrachyus and Triplopus lower den-
titions. This makes the identification of lower den-
titions of these two taxa tentative, leaving both //.
modestus and T. implicatus from the Washakie
Formation of little biostratigraphic utility. We ten-
tatively assign these specimens to Hyrachyus mo-
destus rather than Triplopus implicatus because of
the late Bridgerian age of the Washakie Formation
strata in which they occur, including the Kinney
Rim Member (pm 37284) and from the lower unit
of the Adobe Town Member (pm 55701, 55358,
55712). Hyrachyus modestus has a late Bridgerian
last occurrence elsewhere (Krishtalka et al., 1987,
and references therein), whereas Triplopus impli-
catus has an early Uintan first occurrence else-
where (Table 4).

Hyrachyus eximius Leidy, 1871

(Fig. 1 1Q

Referred Specimens— pm 26128, isolated left
M3, from Loc. fm-1 1-70-wdt, Twkk, bed 527; pm
55867, weathered fragments of what was probably
a complete skeleton, including partial left and right
M3, from Loc. jjf 7-28-92-1, Twka,.

Description— pm 26128 (Fig. 11C) has a dis-
tinct protoloph and metaloph. The protocone and
hypocone are only slightly deflected posteriorly
with reference to the paracone and metacone. A
well-developed metastyle runs perpendicular to the
metaloph. The paracone is large and distinct from
the rest of the ectoloph. The parastyle is large, with
a deep notch separating it from the paracone. The
tooth is moderately worn, with a distinct groove
separating the paracone and the protocone on the
occlusal surface. No labial or lingual cingula are
present. Small anterior and posterior cingula are
present.

pm 55867 is very similar to pm 26 1 28. The meta-
style is slightly larger and the anterior and poste-
rior cingula are slightly larger. In addition, a small
cingulum is present lingually between the proto-
cone and hypocone. All these differences may be
attributed to differences in wear stages between
the two specimens, with pm 55867 being much
less worn than pm 26128. The parastyle and par-
acone are broken on pm 55867, thereby limiting
comparison with pm 26128.

Discussion— pm 26128 is a left M3 and is con-
fidently assigned to H. eximius, firmly establishing
the presence of the genus Hyrachyus in the Wash-
akie Formation, contrary to the conclusions of Ra-
dinsky (1967b). This specimen (see Table 3) falls
within the observed size range reported for the
species by Radinsky (1967b). In addition, posses-
sion of a metacone perpendicular to the metaloph
and a large robust parastyle with a deep groove
separating it from the paracone distinguish it from
Triplopus.

pm 26128 is from bed 527, near the base of the
Kinney Rim Member. At present, the temporal
range of H. eximius elsewhere consists of a late
Bridgerian first occurrence and an earliest Uintan
last occurrence. The presence of H. eximius near
the base of the Kinney Rim Member indicates that
the lower part of the Washakie Formation is late
Bridgerian or younger, and the early-late Bridg-
erian boundary is below bed 527 and probably lies
within the underlying Green River Formation (see
biostratigraphic section for further discussion).

McCARROLL ET AL: THE PERISSODACTYLS

25

Family Hyracodontidae Cope, 1879

Triplopus cubitalis (Cope, 1880)

(Fig. 12A)

Referred Specimens— pm 28365, right dentary
fragment with P3-M3, from Loc. fm- 1 2-70-wdt,
Twka2; pm 55708, a fragmentary left dentary with
P3-M3, from Loc. jjf 7-25-92-2, Twka2, bed 630.

Description— pm 28365 (Fig. 12A) is moder-
ately bilophodont, with well-developed paralo-
phids and metalophids. Both the P3 and P4 have
small hypolophids, making the metalophids the
most prominent feature of the posterior half of
these teeth. On P4, however, there is a small pos-
terolingual swelling, indicating an incipient ento-
conid. This swelling is separated from the small
hypolophid by a small groove. Such a swelling
could be considered a small cingulum rather than
an incipient entoconid; it should be noted, how-
ever, that no cingula are present in this position
on any other tooth except for a very small pos-
terolingual cingulum on M3. Small anterolingual
cingula are present on P3 and P4. For all the teeth
the protolophid is higher than the hypolophid; this
is true even for M,, the most heavily worn tooth.
In addition to the complete teeth, the alveoli are
preserved for P, and P2. P2 is double-rooted and
the posterior mental foramen lies directly beneath
it. The P, alveolus is incomplete on its anterior
border, and it may be single- or double-rooted.
Radinsky (1967a, Fig. 1) shows P[ to be single-
rooted in T. cubitalis.

pm 55708 is very similar to pm 28365, differing
only in being slightly larger (see Table 2).

Discussion— Triplopus is a small hyracondon-
tid recognized (Radinsky, 1967a) by the following
combination of characters: dentition unreduced;
incisors equal in size and spatulate; premolars
nonmolariform to submolariform; M3 with small
metacone; and a tridactyl manus.

Two species of Triplopus are currently recog-
nized from the Washakie Formation, T cubitalis
and T. implicatus (Radinsky, 1967a). They are
distinguished from each other on the basis of size
(see Table 1) and are assigned to Triplopus rather
than Hyrachyus because of their Uintan age in the
Washakie Formation and known ranges else-
where, pm 55708 is assigned to T. cubitalis rather
than T. implicatus because of its smaller size (see
Table 2).

pm 55708 is from ~bed 630, near the base of
the middle unit of the Adobe Town Member. Ra-
dinsky (1967a) stated that "All specimens of Tri-

plopus cubitalis come from the Washakie For-
mation of the Washakie Basin, Wyoming, . . . . "
Thus, their presence in fmnh collections is not
surprising, and adds nothing to their biochrono-
logic utility. Furthermore, we have been unable to
locate subsequent reports of T. cubitalis from else-
where in the western interior.

Triplopus implicatus (Cope, 1873)
(Fig. 12B)

Referred Specimens— pm 3228, isolated right
M3, from Loc. fm-8-57-wdt, Twka2; cm 18464,
partial skull with LP4-M3 and RP3-M3 and as-
sociated dentaries, from Loc. "west rim of Adobe
Town about 4 miles south of Haystack Mt."

Description— pm 3228 is only moderately bi-
lophodont, with a well-developed paralophid and
metalophid. The paralophid is the larger of the
two lophids, and runs anteriorly from the proto-
conid and then lingually along the anterior margin
of the tooth. The smaller metalophid runs ante-
riorly from the hypoconid to the posterior base of
the protoconid. The protolophid is slightly higher
than the hypolophid. A small cingulum is present
on the posterolingual corner of the tooth. In ad-
dition, a very small, faint cingular ridge runs along
almost the entire base of the tooth, being absent
only on the anterior margin.

In some features pm 3228 could be mistaken for
an M2. The angle between the posterior and an-
terior halves of the root is not as great as that seen
in the M3 of other specimens of Triplopus (pm
55708, for example), but is closer to that seen in
the M2. Even so, the angle is still fairly high and
the thickness of the posterior half of the root is
more similar to that of an M3 than to either an
M2 or M,.

The M3 of cm 1 8464 (Fig. 1 2B) has a very small
metastyle and M1-3 have small, reduced (com-
pared to Hyrachyus) parastyles. Both P3"* are sub-
molariform.

Discussion— Measurements of pm 3228 (see
Table 2) are well within the range of those reported
for the larger T. implicatus and outside of those
reported for the smaller T. cubitalis (Radinsky,
1967a).

pm 3228 is from the middle unit of the Adobe
Town Member. As with T. cubitalis, T. implicatus
is known only from the Washakie Formation and
is thus of limited biochronologic utility. We sus-
pect, as did Radinsky (1967a, p. 14), that larger
sample sizes will result in the synonymy of Tri-

26

FIELDIANA: GEOLOGY

Fig. 12. A, Triplopus cubitalis, pm 28365, right dentary fragment with P3-M3, in occlusal view (fmnh neg.
85777.19). B, Triplopus implicatus, cm 18464, right maxillary fragment with P3-M3, in occlusal view (fmnh neg.
85824.26).

McCARROLL ET AL: THE PERISSODACTYLS

27

plopus species from the Uinta and Washakie for-
mations.

cm 1 8464 was listed by Radinsky ( 1 967a, p. 13)
as a specimen of T. implicatus. He did not, how-
ever, list it as a specimen preserving the upper
molars (see Radinsky, 1967a, p. 12). cm 18464
does preserve the upper right and left molars. In
overall morphology, cm 1 8464 is assignable to Tri-
plopus and its size (see Table 3) is within the range
reported for T. implicatus.

cf. Forstercooperia minuta
Lucas, Schoch, & Manning, 1981

Referred Specimen— pm 1682, an isolated left
M3, from Loc. fm-5-56-wdt, Twka2.

Description— pm 1682 is not complete, as it
lacks a parastyle, the labial base of the paracone,
and the anterior portion of the hypocone. The ec-
toloph and metaloph are not readily distinguished,
giving the tooth a generally triangular shape. The
metacone intercepts the metaloph lingually just
past the midline of the tooth; the metastyle is al-
most perpendicular to the metaloph. The proto-
loph is slightly crescent-shaped.

Discussion— Forstercooperia is a medium- to
large-sized hyracodontid recognized (Radinsky,
1967a) by the following combination of charac-
ters: size (see Table 1); dentition unreduced com-
pared to that of Hyrachyus; incisors approxi-
mately equal in size and pointed; canines medium-
sized and stubby; premolars nonmolariform to
submolariform; M3 metacone small to absent.
Wood (1938) first coined the name Forstercoop-
eria for the preoccupied genus Cooperia. Radinsky
(1967a) recognized five species of Forstercooperia,
four from Asia and one, F.1 grandis (= Hyrachyus
grandis Wood, 1934), from the Uinta and Wash-
akie formations. Most recently, Lucas et al. (1 98 1)
recognized only three species of Forstercooperia:
F. totadentata (middle to late Eocene of Asia), F.
grandis (middle to late Eocene of Asia, late Eocene
of North America), and F. minuta (middle to late
Eocene of Asia, late Eocene of North America).

pm 1682 is almost identical morphologically to
the M3 of ucmp 69722, a complete skull of F.
grandis figured by Radinsky (1967a, Fig. 1 1). Its
size, however (see Table 3), is closer to measure-
ments reported for the smaller F. minuta and well
outside the range of reported measurements for
the larger F. grandis (Lucas et al., 198 1). The pau-
city of specimens and the fragmentary nature of
pm 1682 preclude a more confident identification.

If accurate, this is the first report of F. minuta
from the Washakie Formation.

pm 1682 is from the middle unit of the Adobe
Town Member. North American F. minuta is cur-
rently known from the Galisteo Formation of
north-central New Mexico, which is of Duches-
nean age (Lucas et al., 1981; Lucas & Sobus, 1 989),
and the Tepee Trail Formation of northwestern
Wyoming, which is of Bridgerian to early Uintan
age (Eaton, 1985). These age occurrences are con-
sistent with an earliest-early Uintan age assign-
ment for the middle unit of the Adobe Town
Member, as indicated by other taxa.

Hyracodontidae indeterminate

Referred Specimen— pm 3937, right maxillary
fragment with fragmentary F*-M2, associated at-
las, from Loc. fm-8-57-wdt, Twka2.

Description— pm 3937 possesses three highly
fractured teeth that are interpreted here as F'-M2.
P4 appears to have a large, well-separated proto-
cone and hypocone, but lacks a well-developed
metastyle. M1 possesses a high paracone and only
a small vestige of a parastyle. The metastyle is
missing, but remnants of enamel present on the
ectoloph and metaloph indicate that a postero-
labially deflected metastyle was present. M2 is very
poorly preserved and adds no further information.

Discussion— pm 3937 is assigned to the Hyra-
codontidae based on overall molar morphology
and size. Although it is broken and fragmentary,
this specimen appears to have been larger (see Ta-
ble 3) than Forstercooperia grandis and is close to
measurements reported for F. totadentata from
China (Lucas et al., 1981). Because of the frag-
mentary nature of the specimen, we do not attempt
a more specific identification.

Family Amynodontidae
Scott and Osborn, 1883

Amynodon advenus Marsh, 1877
(Fig. 13)

Referred Specimens— pm 1088, paired right and
left maxillary dentitions with RP2-M2 and LP2-
M2, from Loc. given only as "Top of Haystack
Mt"; pm 3874, dentary with LC-M2 and RP3-M2,
from FM-8-57-WDT, Twka2; pm 1514, right dentary
fragment with M3 and partial M2, associated cal-
caneum and postcranial fragments, from Loc. fm-

28

FIELDIANA: GEOLOGY

Fig. 13. Amynodon advenus, pm 1088, right and left maxillary dentitions (in matrix) showing RP2-M2 and LP2-
M2, in occlusal view (fmnh neg. 85777.5).

10-56-wdt, Twka2; cm 9382, associated LP3-M2
and tooth fragments, from Loc. given only as
"Haystack Mt."; pm 51597, left dentary fragment
with partial M,_3, and associated incisors, from
Loc. fm-6-73-wdt, Twka2.

Description— In pm 1088 (Fig. 1 3) both second
premolars and both second molars are damaged;
the third molars are both missing. The fourth pre-
molars are large and submolariform, and the third
and fourth premolars have a continuous, heavy
lingual cingulum. In pm 3874, the left and right P2
alveoli show them to be double-rooted, and the
P, is absent. In addition, a distinct labial groove
separates the trigonids and talonids on P4-M2. This
is also true for pm 1514. However, pm 1 5 1 4 is more
worn than pm 3874, making the lingual groove
separating the trigonid and talonid less obvious.
cm 9382 is indistinguishable from pm 1088.

Discussion— Amynodon is recognized (Wall,
1982) by the following combination of characters:
large double-rooted P2; a distinct labial groove
separating trigonid and talonid on molars; length

of upper and lower premolar series is approxi-
mately half that of molar series (see Table 1); P4
large and submolariform; and M3 metastyle less
labially deflected than in more derived amyno-
donts. At present, only two North American spe-
cies of Amynodon are recognized, A. advenus and
the much smaller A. reedi (Wilson & Schiebout,
1981; Wall, 1982).

The loss of P,, a large double-rooted P2, and
size (see Table 2) allow the lower dentitions to be
confidently assigned XoA. advenus. Unfortunately,
pm 1088 lacks the diagnostic metastyle condition
on M3; even so, it possesses a large submolariform
P4 and is of appropriate size (see Table 3) for as-
signment to A. advenus.

All Amynodon specimens reported here are from
the middle unit of the Adobe Town Member.
Amynodon is currently known from the earliest
Uintan (Shoshonian Subage) through the Duches-
nean elsewhere (Krishtalka et al., 1987), although
we are unsure if Amynodon has a Duchesnean last
occurrence. Amynodon is currently used as the de-

McCARROLL ET AL: THE PERISSODACTYLS

29

fining taxon for the base of the Uintan NALMA
(Flynn, 1986). The lowest stratigraphic occurrence
of Amynodon within the Washakie Formation is
pm 3874 from the northwest flank of Haystack
Mountain. This is stratigraphically higher than
Granger's (1909) bed 1 1, which was his Bridger-
ian-Uintan boundary. We discuss the position of
the Bridgerian-Uintan boundary in the biostrati-
graphic section of this paper.

Biostratigraphy
Overview

Granger ( 1 909) was the first to divide the Wash-
akie Formation (see Fig. 3). Granger called the
lower half of the formation "Washakie A" (~260
ft/79 m, beds 1-10) and considered it to corre-
spond faunally to the "Bridger C-D" based on the
presence of Uintatherium, Manteoceras, Mesati-
rhinus, Notharctus, Hyrachyus, and Sinopa. He
called the upper half of the formation "Washakie
B" (-380 ft/1 16 m, beds 12-22) and considered
it to correspond faunally to the "Uinta A-B" based
on the presence of Eobasileus, Achaenodon, Amy-
nodon, Dolichorhinus, and Metarhinus. Granger
considered the base of the Washakie Formation
to be the "lower brown sandstone," a sequence of
sandstones, varying in thickness, that weather to
a reddish brown and form a distinct rim around
much of the basin. Granger considered the summit
of Haystack Mountain to be the top of the Wash-
akie Formation. Haystack Mountain (as discussed
by Turnbull, 1978) is a high topographic feature
in the north-northeast portion of the basin, which
Granger assumed included the stratigraphically
highest beds in the formation.

Roehler (1973) formally divided the Washakie
Formation into two members, the lower Kinney
Rim Member (~900 ft/270 m, beds 5 1 5-568) and
the upper Adobe Town Member (« 2,300 ft/700
m, beds 569-708). He also informally divided the
Adobe Town Member into lower, middle, and up-
per units (see Fig. 2). As noted earlier, the Wash-
akie Formation as defined by Roehler (1973) is
more inclusive than Granger's (1909) concept of
the Washakie Formation. Roehler's (1973) Kin-
ney Rim Member and the upper unit of the Adobe
Town Member were not recognized by Granger
( 1 909). Granger ( 1 909) assigned the rocks that now
comprise the Kinney Rim Member to the under-
lying Green River Formation. Roehler (1973)

found that rocks stratigraphically below the "lower
brown sandstone" (the base of Granger's Wash-
akie Formation) were lithologically more similar
to those of the overlying Washakie Formation than
to the underlying Green River Formation. These
rocks are bound below by the "persistent white
ridge marker bed" (bed 515) and above by the
unconformable persistent "lower brown sand-
stone" (bed 569), and thus constitute a mappable
unit, named the Kinney Rim Member of the
Washakie Formation. Granger (1909) did not rec-
ognize any rocks stratigraphically higher than those
topping Haystack Mountain. Roehler (1973) and
Turnbull (1972, 1978) independently recognized
that rocks in the geographic center of the basin
were stratigraphically higher than those of Hay-
stack Mountain; this stratigraphically higher part
of the section now constitutes the upper unit of
the Adobe Town Member. The units of the Adobe
Town Member were not formally divided by
Roehler (1973) because they cannot be differen-
tiated on the basis of persistent mappable beds.

Based on the mammalian fauna and lithologic
changes, both Roehler (1973) and Turnbull (1978)
placed the early-late Bridgerian boundary within
the Kinney Rim Member (Roehler at ~bed 540;
Turnbull at ~540 — 559), the Bridgerian-Uintan
boundary between the lower and middle units of
the Adobe Town Member (bed 620; Granger's bed
1 1), and the early-late Uintan boundary between
the middle and upper units of the Adobe Town
Member (~bed 675). Of these boundaries, only
one, the Bridgerian-Uintan boundary, was rec-
ognized by Granger (1909). Granger placed this
boundary in the same place Roehler (1973) and
Turnbull ( 1 972) later did, between his beds 1 0 and
1 1 (bed 620 of Roehler, 1973), based on biostrati-
graphic distributions of Bridgerian and Uintan taxa.
Roehler's (1973) placement of the early-late
Bridgerian boundary and the early-late Uintan
boundary was tentative and based on lithologic
changes, not the biostratigraphic occurrence of di-
agnostic taxa. Two taxa, Hyrachyus near H. mo-
destus and Sciuravus cf. nitidus, were used as ten-
tative evidence for the placement of the early-late
Bridgerian boundary in the Kinney Rim Member
(Turnbull, 1972; Roehler, 1973). These taxa and
their use as early Bridgerian indicators are dis-
cussed in more detail later.

The stratigraphic distributions within the Wash-
akie Formation of the perissodactyl taxa reported
here are shown in Table 5. When compared to the
presently known temporal distributions of these
taxa elsewhere (shown in Table 4), the following

30

FIELDIANA: GEOLOGY

Table 4. Currently recognized chronologic distributions of selected North American middle and late Eocene
perissodactyl taxa.

Taxon

Bridgerian

I in i. in

EB

LB

EU

LU

Duches-
nean

ED

Isectolophus annectens*
Isectolophus latidens
Eomoropus amarorum
Helaletes nanus
Helaletes intermedius*\
Dilophodon minusculus
Dilophodon leotanus*
Colodon*

Forstercooperia grandisf
Forstercooperia minuta
Triplopus cubitalis
Triplopus implicates
Triplopus obliquidens*
Triplopus rhinocerinus*
Amynodon advenus
Amynodon reedi*
Hyrachyus modestus
Hyrachyus eximius
Epitriplopus uintensis*
Orohippus
Epihippus gracilis
Epihippus uintensis
Palaeosyops
Telmatherium
Mesatirhinus
Metarhinus
Dolichorhinus

X'
X1
X1

X8.I0

X8

X

X9

Xs

X9?

X7

X7

X10

X8

X7

X7

X3
X*

X3

Xic
Xic

X3?

X10

G, Gardnerbuttean; EB, early Bridgerian; LB, late Bridgerian; S, Shoshonian; EU, early Uintan; LU, late Uintan;
ED, early Duchesnean.

I, Radinsky 1963; 2, Lucas et al. 1981; 3, Radinsky 1967a; 4, Wall 1982; 5, Radinsky 1967b; 6, Flynn 1983; 7,
Krishtalkaet al. 1987; 8, Flynn 1986; 9, Mader 1989; 10, MacFadden 1980; 11, Lucas and Schoch 1989; 12, Robinson
1966.

* Taxa not found in the Washakie Formation.

t Taxa previously reported from the Washakie Formation but not present in fmnh collections.

general conclusions can be made: 1) The Kinney
Rim Member and the lower unit of the Adobe
Town Member contain only taxa restricted to the
late Bridgerian or that range broadly throughout
the Bridgerian, indicating a late Bridgerian age for
those units; 2) the middle unit of the Adobe Town
Member contains taxa restricted to the earliest-
early Uintan or that range broadly (e.g., Bridger-
ian-early Uintan or early-late Uintan), indicating
an earliest-early Uintan age for all or most of the
unit; and 3) the only perissodactyl from the upper
unit of the Adobe Town Member is Epihippus
gracilis, known to range from early to late Uintan.
Below we discuss each member and unit within
the formation and the biochronologic significance
of each taxon known from it.

Kinney Rim Member

Turabull (1 972) reported finding Hyrachyus near
H. modestus and Sciuravus cf. nitidus from the
Kinney Rim Member. He used these taxa as in-
dicators of an early Bridgerian age for the lower
part of the Kinney Rim Member (Roehler, 1973;
Turnbull, 1978). Both H. modestus and S. nitidus
range throughout the Bridgerian (Krishtalka et al.,
1987) and their presence does not necessarily in-
dicate an early Bridgerian age. In addition, the
specimen reported as Hyrachyus near H. modestus
by Turnbull ( 1 972) is pm 26 1 28 and is here thought
to be H. eximius, not H. modestus (see systematic
section).

The Kinney Rim Member preserves Mesati-

McCARROLL ET AL: THE PERISSODACTYLS

31

Table 5. Stratigraphic distribution within the Washakie Formation of perissodactyl taxa reported here.

Taxon

Kinney Rim
Member

Adobe Town Member

Twka,

Twka2

Twka,

Orohippus sp.

X

Epihippus gracilis

Telmatherium sp.

X

Mesatirhinus sp.

X

Metarhinus sp.

X

Dolichorhinus sp.

X

Isectolophus latidens

X

Eomoropus amarorum

X

Helaletes nanus

X

Dilophodon minusculus

X

Hyrachyus modestus

X

X

Hyrachyus eximius

X

X

Triplopus cubitalis

X

Triplopus implicatus

X

cf. Forstercooperia minuta

X

Amynodon advenus

X

rhinus sp., Helaletes nanus, Hyrachyus modestus,
and Hyrachyus eximius. Helaletes nanus ranges
throughout the Bridgerian and H. modestus occurs
throughout the Bridgerian. Mesatirhinus is cur-
rently restricted to the late Bridgerian (Mader,
1989). Hyrachyus eximius is currently known to
have its first occurrence in the late Bridgerian (Ra-
dinsky, 1967b; Gazin, 1976; although Gazin re-
ported a specimen of//, eximius from just below
the Sage Creek White Layer in the Bridger Basin,
this layer is the dividing line between the early and
late Bridgerian in the Bridger Basin). The presence
of H. eximius (pm 26128) near the base of the
Kinney Rim Member (bed 527) indicates that ear-
ly Bridgerian -aged rocks are probably not present
within the Washakie Formation, and the early-
late Bridgerian boundary in the Washakie Basin
lies within the underlying Green River Formation.
At present, the first occurrence of//, eximius is
confidently placed at the early-late Bridgerian
boundary. The last occurrence of//, eximius, how-
ever, is uncertain. Flynn (1983) assigned an almost
complete skull and right dentary from the Wash-
akie B (amnh 107978, a cast of uw 1937) to H.
eximius. Hyrachyus eximius has not been recog-
nized previously as occurring in the early Uintan.
Upon examination of uw 1937 (fmnh 39232, also
a cast of uw 1937), we agree that it is probably
Hyrachyus, and not the taxon most similar to it,
Triplopus; it is within the size range previously
reported for H. eximius (Radinsky, 1 967b). A range
extension of Hyrachyus, represented by H. exi-
mius, into the early Uintan would not affect the

above reasons for not recognizing early Bridgeri-
an-aged rocks within the Washakie Formation.

Adobe Town Member— Lower Unit

The lower unit of the Adobe Town Member
historically has been considered late Bridgerian in
age (Granger, 1909; Roehler, 1973; Turnbull,
1978). This has been based on the occurrence of
characteristic late Bridgerian taxa within the unit
(e.g., Uintatherium, Mesatirhinus, Notharctus,
Hyrachyus, Sinopa). More recently, in a study
combining biostratigraphy, magnetic polarity stra-
tigraphy, and radioisotopic dating, Flynn (1986)
proposed an earliest Uintan (Shoshonian Subage)
age for some upper portion of the lower unit of
the Adobe Town Member. Flynn (1986) based his
proposal on the finding that the Bridgerian-Uintan
boundary, and earliest Uintan (Shoshonian) fau-
nas, occurred within magnetochron C20R in Eo-
cene sediments of the East Fork Basin area of
northwest Wyoming and the San Diego area of
California. Within the Washakie Formation, a re-
versed polarity interval, correlated by Flynn (1986)
to Chron C20R, is approximately equivalent to
the lower unit of the Adobe Town Member; there-
fore, the Bridgerian-Uintan boundary should lie
within the lower unit. Flynn (1986, pp. 379-380)
defined the Bridgerian-Uintan boundary by the
first occurrence of Amynodon, and characterized
earliest Uintan faunas by the co-occurrence of
small-bodied taxa previously known only from the
late Bridgerian or older intervals with large-bodied

32

FIELDIANA: GEOLOGY

taxa previously known only from the early Uintan
or younger intervals. The larger-bodied early Uin-
tan taxa were predominantly, but not exclusively,
perissodactyls.

At present, the following perissodactyl taxa have
been recovered from the lower unit of the Adobe
Town Member: Orohippus sp., Telmatherium sp.,
Mesatirhinus sp., Isectolophus latidens, Hyrachyus
modestus, and Hyrachyus eximius. The defining
Shoshonian (earliest Uintan) taxon, Amynodon, is
not present. Each of these other taxa is well known
from late Bridgerian deposits of western North
America. Although some (Hyrachyus) may have
earliest Uintan last occurrences, this is insufficient
evidence for demonstrating an earliest Uintan
(Shoshonian) age for the lower unit of the Adobe
Town Member. This unit does contain character-
istic "Bridgerian" taxa (Hemiacodon gracilis, Mi-
crosyops annectens, Notharctus robustior, Hyop-
sodus paulus) noted as occurring in the earliest
Uintan by Flynn (1986); their presence alone,
however, is also insufficient evidence for dem-
onstrating an earliest Uintan age for the unit. At
present, the known taxa from the lower unit of the
Adobe Town Member indicate a late Bridgerian
age, although a Shoshonian (earliest Uintan) age
is still possible for part of the unit.

The absence of a definitive earliest Uintan fauna
from the lower unit of the Adobe Town Member
may be a taphonomic artifact. Many of the "Uin-
tan" taxa used to define or characterize the earliest
Uintan are larger in size (Amynodon, Metarhinus,
Achaenodori). Unfortunately, the most fossilifer-
ous beds known from the lower unit of the Adobe
Town Member ("middle red beds" of Roehler,
1973) typically produce only smaller- bodied taxa
(rodents, primates, insectivores). Preliminary
analysis of the fossil material collected to date in-
dicates that these beds represent paleosols— ho-
rizons where there is a bias (although not exclu-
sive) toward the preservation of smaller skeletal
elements, especially isolated teeth and jaws (Bown
& Kraus, 1981; Bown & Beard, 1990). Thus, a
preservational (and potential collection) bias
against larger-bodied Uintan taxa may exist. In-
creasing our future collection efforts in more en-
vironmentally diverse beds in the lower unit of
the Adobe Town Member may yield a greater di-
versity of larger-bodied taxa from the lower unit
of the Adobe Town Member.

Adobe Town Member— Middle Unit

The middle unit of the Adobe Town Member
historically has been considered early Uintan in

age (Granger, 1909; Roehler, 1973; Turnbull,
1978). This has been based on the occurrence of
characteristic early Uintan taxa (Eobasileus,
Achaenodon, Amynodon, Dolichorhinus, Meta-
rhinus) within the unit.

Perissodactyl taxonomic diversity and abun-
dance are highest for the Washakie Formation in
the middle unit of the Adobe Town Member. The
taxa present are Dolichorhinus sp., Metarhinus sp.,
Eomoropus amarorum, Dilophodon minusculus,
Triplopus cubitalis, Triplopus implicatus, cf. For-
stercooperia minuta, and Amynodon advenus. Di-
lophodon minusculus has been thought to be re-
stricted to the late Bridgerian (Radinsky, 1963).
The remaining taxa listed above have earliest-ear-
ly Uintan first occurrences (Flynn, 1986, Krish-
talka et al., 1987). Thus, the middle unit of the
Adobe Town Member is the only unit within the
Washakie Formation where Bridgerian and Uin-
tan taxa are documented to overlap in occurrence.
This indicates an earliest Uintan age (Shoshonian
Subage) for some lower portion of the middle unit
of the Adobe Town Member.

Alternatively, the occurrence of Dilophodon
minusculus in the middle unit of the Adobe Town
Member could be interpreted as a range extension
for that taxon to include the early Uintan. The
occurrence of other nonperissodactyl taxa (Hyop-
sodus and Notharctus robustior) known to occur
in the Bridgerian (but also in the earliest Uintan)
also indicates a "Bridgerian" component to the
fauna of the middle unit.

Adobe Town Member— Upper Unit

The upper unit of the Adobe Town Member was
not included in Granger's Washakie Formation.
This portion of the section was independently rec-
ognized by Roehler (1973) and Turnbull (1972,
1978) as being stratigraphically above the sedi-
ments capping Haystack Mountain (= top of
Granger's [ 1 909] section). Thus, the upper unit is
younger than the beds capping Haystack Moun-
tain, but by how much is still in question. Roehler
(1973) speculatively assigned a late Uintan age to
the upper unit based on lithologic changes he in-
terpreted as a change in "sedimentary regime."
Roehler (1973) reported no fossil mammal spec-
imens from the upper unit. Turnbull (1978) also
reported an inadequate fossil mammal record from
the upper unit and simply reiterated Roehler's
speculation of a late Uintan age.

Epihippus gracilis is the only perissodactyl
known from the upper unit of the Adobe Town
Member. The paucity of specimens makes place-

McCARROLL ET AL: THE PERISSODACTYLS

33

ment of the early-late Uintan boundary within the
Adobe Town Member difficult. In addition, the
known temporal span of E. gracilis is the entire
Uintan, which prevents further biochronologic
subdivision based on its presence within the unit.
Additional recent collections of nonperissodactyl
taxa from the upper unit indicate the absence of
late Uintan taxa from the upper unit (McCarroll
et al., 1993, in press), this fauna will be reported
elsewhere (McCarroll, 1995, in prep.).

The currently recognized temporal distributions
for selected middle and late Eocene perissodactyl
species are shown in Table 4. Several taxa of late
Bridgerian or early Uintan age have not been rec-
ognized yet from the Washakie Formation, even
though the temporal span of the formation indi-
cates they could have occurred here. Palaeosyops
has been reported from the Washakie Formation
(Osborn, 1929), but we have no specimens of Pa-
laeosyops in the fmnh collections. Helaletes in-
termedins (= Desmatotherium guyotii) may in fact
be known from the Washakie Formation, if the
type of D. guyotii (ymp-pu 10166) is actually from
the Washakie Basin rather than the Bridger Basin
(see Radinsky, 1963, pp. 48-50). Radinsky (1963)
commented on the rarity of H. intermedins in gen-
eral. We have yet to find any specimens that we
confidently assign to H. intermedins, presumably
because of its rarity. Amynodon reedi, originally
described from the Poway Conglomerate of San
Diego, California (Stock, 1939), is now reported
from early Uintan sediments of White River, Utah,
and the Uinta Basin, Utah (Wall, 1982). It has not
been documented in the Washakie Formation.
Triplopus obliquidens and Triplopus rhinocerinus
are both known from the Uinta Formation, but so
far as we can tell they are absent in the Washakie
Formation. This may be due in part to taxonomy;
T. obliquidens of the Uinta Basin may be synon-
ymous with T. implicatus of the Washakie Basin
(see Radinsky, 1967a, p. 14).

Dilophodon leotanus, presently restricted to the
late Uintan, is not identified here from the Wash-
akie Formation, but is known from several late
Uintan faunas from Utah, Wyoming, and Mon-
tana (Radinsky, 1963). Its absence is assumed to
be due to the lack of late Uintan age sediments in
the Washakie Formation. The lack of late Uintan
age sediments may also explain the lack of Colo-
don (late Uintan- Whitneyan) from the Washakie
Formation.

Ecological, paleogeographic, and climatic expla-
nations could all be used to explain the absence
of these taxa from the Washakie Formation. In

addition, the Washakie Formation has long had
the reputation for being relatively unfossiliferous,
thus small sample size may also be a factor. Their
presence in other geographically proximate basins
and temporally equivalent formations, and the
steadily growing collections from the Washakie
Basin, would indicate to us that some causal mech-
anism might have prevented their entry into the
Washakie Basin. Unfortunately, too little is known
about the detailed paleogeographic and climatic
conditions at the time to confidently speculate.
Furthermore, the ecologic preference and inter-
actions of the taxa involved are still uncertain, and
the need for taxonomic revisions of some groups
hinders direct basin-to-basin comparisons.

Conclusions

The following biochronologic conclusions can
be drawn from the perissodactyls of the Washakie
Formation and their biostratigraphic distribu-
tions.

1 ) Early Bridgerian taxa are not currently known
from the Washakie Formation. The occurrence
of Hyrachyus eximius, a late Bridgerian first
occurrence taxon, from near the base of the
Kinney Rim Member places the early-late
Bridgerian boundary within the underlying
Green River Formation.

2) The Kinney Rim Member and the lower unit
of the Adobe Town Member both appear to be
best assigned a late Bridgerian age.

3) Earliest Uintan (Shoshonian Subage) faunas
may be known from the lower portion of the
middle unit of the Adobe Town Member. The
middle unit of the Adobe Town Member is the
only unit in which larger-bodied taxa that occur
in the early Uintan co-occur with smaller-bod-
ied taxa that occur in the late Bridgerian, as is
typical of the Shoshonian elsewhere. The upper
portion of the middle unit of the Adobe Town
Member is early Uintan in age.

4) Late Uintan taxa are currently unknown from
the Washakie Formation. To date, no late Uin-
tan first occurrence taxa are known from the
upper unit of the Adobe Town Member.

Acknowledgments

For help in prospecting and collecting in the field
we thank the field crews listed in Turnbull (1978,

34

FIELDIANA: GEOLOGY

1991) and Turnbull and Martill (1988) and more
recent collectors: James Balodimas, Tamara Biggs,
Steve Borysewicz, Paul Brinkman, Greg Buckley,
Doreen Covey, Annette Golden, Geoff Grove,
Robin Habegger, Jeff Hoke, Doug Jewell, Robert
Masek, Hedy Turnbull, Susan VandenBosch,
Robin Whatley, and Mary Wisz. For typing and
proofreading above and beyond the call of duty
we thank Elaine Zeiger (fmnh Department of
Geology). For photographic illustrations we thank
the fmnh Department of Photography: James Bal-
odimas, Nina Cummings, Linda Dorman, John
Weinstein, and Diane Alexander White. We thank
Andrew H. Leman (fmnh Department of Geology)
for computer production of the line drawings. The
senior author thanks Janet Voight (fmnh Depart-
ment of Zoology) for encouragement (and the oc-
casional drink) during the course of manuscript
preparation. We thank Mary Dawson (cm) for the
loan of specimens in her care. We thank the Wy-
oming state office of the Bureau of Land Manage-
ment, especially Ranel Capron and Laurie Bryant,
for help relating to our collecting permits. We thank
Richard Stucky, Bryn Mader, and an anonymous
reviewer for reviewing the manuscript.

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McCARROLL ET AL: THE PERISSODACTYLS

37

Appendix 1: Field Museum Localities Cited in Text

The following localities are cited in the text. Localities cited in the text but not listed here can be
found in Turnbull (1978).

Twka, jjf 7-24-90-1 Sl/z, SWA, NE'A, Sec. 19, T16N, R97W

Twka, jjf 7-26-92-1 SWA, Sec. 30, T16N, R97W

Twka, jjf 7-28-92-1 E'/2, Sec. 13, T13N, R96W & WVi, Sec. 18, T13N, R95W

Twka, jjf 7-28-92-2 SE'A, NW'A & NE'/4, SWA, Sec. 7, T13N, R95W

Twka, jjf 8-1 1-93-1 S'/2, NEVa & N'/2, SE1/., Sec. 36, T16N, R98W

Twka, jjf 8-13-93-1 N'/2, NW'/4, Sec. 6, T13N, R95W & S'/2, S'/2, Sec. 31, T14N, R95W

Twka2 jjf 7-25-92-1 N'/2, NW'/4, Sec. 2, T16N, R97W & SE1/., SE1/., Sec. 35, T17N, R97W

Twka2 jjf 7-25-92-2 NE1/., SE1/., Sec. 36 & W'/2, NW1/., SW1/., Sec. 31, T17N, R97W

Twka3 jjf 7-21-90-1 SW'/4, NE'/4, NE1/., Sec. 23, T14N, R98W

Appendix 2: Metarhinus sp. Specimens from the Monospecific
Titanothere Quarry Reported by Turnbull and Martill (1988)

Specimens assigned here to Metarhinus from the monospecific titanothere quarry initially described
by Turnbull and Martill (1988): These specimens were assigned to Mesatirhinus by Turnbull and Martill
(1988), prior to Mader's (1985) revision of the Brontotheriidae. Using Mader's (1989) character sets,
we amend the generic assignment to Metarhinus.

Skull and maxillary specimens: pm 28012, 28345, 28348, 30384-5, 30388, 30431-2, 35931-2, 36000,

36053-4, 36072, and 1 uncatalogued skull.
Dentaries: pm 28001-4, 28006-10, 28014, 28342-4, 28359A-D, 30422, 30434-5, 35928A-B, 35931,

35933, 35970, 35996, and 54422.
Isolated teeth: pm 28015, 28023, 28024-31, 28039, 28347, 28350-3, 28358, 28360, 28363^, 30393-

4, 30396-400, 30413, 30417, 35938-40, 35943-51, 35953-9, 35964-8, 35971-3, 35975, 35979-81,

35998, 36004-5, 36007, 36012-4, 36016, and 36055-71.
Postcranial specimens: pm 28005, 28008-9, 28013, 28037-8, 28346, 28348-9, 28354-65, 30383-7,

30389-92, 30395, 30401-16, 30418-21, 30423-30, 30433, 35924, 35928-30, 35935, 35941-2, 35952,

35960-3, 35974, 35976, 35978, 35982-6, 35989-91, 35993-5, 35997, 35999, 36001-3, 36006-11,

36015, 36023, and 36046-52.

The 27 jaw specimens (MNI = 25) listed in Turnbull and Martill (1988, Table II) allowed for age
estimates ranging from about 3 months to well over 1 5 years, with both sexes represented. One dentary
not included in Turnbull and Martill (1988, Table II) has since turned up, which accounts for the change
in numbers.

38 FIELDIANA: GEOLOGY

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