ROBERT J. EMRY
and

WILLIAM W. KORTH

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY • NUMBER 67

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SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY • NUMBER 67

Rodents of the Bridgerian
(Middle Eocene) Elderberry Canyon
Local Fauna of Eastern Nevada

Robert J. Entry
and William W. Korth

SMITHSONIAN INSTITUTION PRESS
Washington, D.C.

1989

ABSTRACT

Emry, Robert J., and William W. Korth. Rodents of the Bridgerian (Middle Eocene)
Elderberry Canyon Local Fauna of Eastern Nevada. Smithsonian Contributions to Paleobiology,
number 67, 14 pages, 5 figures, 1989.—The Elderberry Canyon Local Fauna, presently
represented by more than 40 vertebrate taxa, including at least 30 mammals, occurs in carbonate
rocks assigned to the Sheep Pass Formation, near Ely, Nevada. Among the mammals, nine
rodent species, representing four families, are recognized. Reithroparamys delicatissimus , and
R. cf. R. huerfanensis are species previously known from the Rocky Mountain region;
Microparamys sambucus and Pauromys exallos are new species assigned to genera commonly
occurring in Eocene faunas elsewhere; Elymys complexus is a new genus and species of minute
rodent thought to be related to Simimys and questionably assigned to the family Zapodidae;
Sciuravus, Mattimys, and Knightomys are represented by material not assignable to species;
and another unidentified ischyromyid completes the roster of rodents presently known in the
assemblage. The fauna as a whole, and the rodents in particular, share the greatest homotaxial
similarity with early Bridgerian (early middle Eocene) faunas elsewhere, allowing a confident
early Bridgerian age assignment for the Elderberry Canyon Local Fauna. The composition of
this rodent assemblage suggests that faunal interchange was relatively unrestricted from
southern California through Nevada to the Rocky Mountain region in Bridgerian time.

OFFICIAL PUBLICATION date is handstamped in a limited number of initial copies and is
recorded in the Institution’s annual report, Smithsonian Year. Series cover DESIGN: The
trilobite Phaecops rana Green.

Library of Congress Cataloging in Publication Data
Emry, Robert J.

Rodents of the Bridgerian (middle Eocene) Elderberry Canyon local fauna of Eastern Nevada.

(Smithsonian contributions to paleobiology ; no. 67)

Bibliography p.

SupL of Docs, no.: SI 1.30:67

1. Rodents, Fossil—Nevada—Elderberry Canyon. 2. Paleontology—Eocene. I. Korth, William W. II. Ti¬
tle. III. Series.

QE701.S56 no. 67 560 s [569'.323] 89-600114 [QE882.R6]

Contents

Page

Introduction.1

Abbreviations.1

Acknowledgments.1

Order Roden TIA Bowdich, 1821.2

Family ISCHYROMYIDAE Alston, 1876.2

Subfamily Reithroparamyinae Wood, 1962 .2

Genus Reithroparamys Matthew, 1920.2

Reithroparamys delicatissimus (Leidy, 1871).2

Reithroparamys cf. R. huerfanensis Wood, 1962 .3

Subfamily Microparamyinae Wood, 1962 .4

Genus Microparamys Wood, 1959a.4

Microparamys sambucus, new species.4

Ischyromyid, species indeterminate.6

Family Sciuravidae Miller and Gidley, 1918.6

Genus Sciuravus Marsh, 1871.6

Sciuravus species.6

Genus Pauromys Troxell, 1923 .7

Pauromys exallos, new species.7

Genus Knightomys Gazin, 1961.8

Knightomys species.8

Family 7ZAPODIDAE Coues, 1875 .8

Genus Elymys, new genus.8

Elymys complexus, new species.9

Family 7EUTYPOMYIDAE Miller and Gidley, 1918.11

Genus Mattimys Korth, 1984 . 11

Mattimys species.11

Conclusions.11

Literature Cited.13

iii

Rodents of the Bridgerian
(Middle Eocene) Elderberry Canyon
Local Fauna of Eastern Nevada

Robert J. Emry
and William W. Korth

Introduction

The Elderberry Canyon Local Fauna (Emry, in press), the
first Eocene mammalian fauna reported from the Great Basin,
occurs in carbonate rocks referred to the Sheep Pass Formation
near Ely, in White Pine County, Nevada. The quarryable
concentration of bone that has produced the fauna was
discovered in 1975 by Dr. Thomas Fouch of the U.S.
Geological Survey, who guided one of us (Emry) to the locality
in the summer of 1976, and assisted in collecting more of the
bone-bearing limestone. The delicate and time consuming job
of extracting the fragile fossil material from the limestone, by
etching in dilute formic acid, has proceeded almost uninter¬
rupted since that time, with additional rock being collected in
1977, 1979, 1980, and 1983. The Elderberry Canyon Local
Fauna, as presently known, includes at least 40 taxa of
vertebrates, more than 30 of which are mammals (Emry, in
press). This report describes in detail the nine species of rodents
presently known from Elderberry Canyon.

The order of authorship of this report is alphabetical, and
does not necessarily indicate the order of greatest contribution,
which we consider to have been nearly equal and complemen¬
tary.

Abbreviations.— Acronym prefixes denoting institutional
collections are: AMNH (American Museum of Natural History,
New York); CM (Carnegie Museum of Natural History,
Pittsburgh); FMNH-PM (Field Museum of Natural History,
Chicago); USNM (National Museum of Natural History,

Robert J. Emry, Department of Paleobiology, National Museum of
Natural History, Smithsonian Institution, Washington, D.C. 20560.
William W. Korth, Department of Geological Sciences, University of
Rochester, Rochester, New York, 14627.

Washington); YPM (Yale Peabody Museum, Yale University);
YPM-PU (original Princeton University number of specimen
now at Yale Peabody Museum).

When used with dental notations, L = left and R = right.
Also in dental notations, an upper case letter indicates upper
or maxillary teeth, and a lower case letter indicates lower or
dentary teeth (for example P4 is the upper fourth premolar, and
ml is the lower first molar).

In dental descriptions and measurements, a-p = anteropos¬
terior and tr = transverse. In lower dentitions, two transverse
measurements may be indicated; tra is across the anterior, or
trigonid, part of the tooth, and trp is across the posterior, or
talonid, part.

Acknowledgments. —The one contribution prerequisite
to any study of the fauna that might have been undertaken was
the discovery of the Elderberry Canyon bone bed by Dr.
Thomas D. Fouch of the U.S. Geological Survey. We gratefully
acknowledge Dr. Fouch for this as well as for guiding the
senior author to the locality and helping to collect additional
limestone for preparation. We thank Dan Chaney, John Flynn,
Frederick Grady, Arnold Lewis, and Michael Pechacek for
ably assisting, at one time or another, in the increasingly
difficult task of collecting additional rock in the field. The
formic acid preparation process has been administered for
more than a decade now, first by Frederick Grady and then by
Dan Chaney, both of the Vertebrate Paleontology Preparation
Laboratory at the NMNH. The figures were rendered by
Jennifer Emry. For their helpful critical reviews of the
manuscript we thank Dr. John E. Storer of the Saskatchewan
Museum of Natural History and Dr. Robert W. Wilson of the
Museum of Natural History at the University of Kansas.

1

2

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Order Rodentia Bowdich, 1821
Family Ischyromyidae Alston, 1876
Subfamily Reithroparamyinae Wood, 1962
Genus Reithroparamys Matthew, 1920

Type Species. — Paramys delicatissimus Leidy, 1871.

Range. —Wasatchian to Uintan (early to middle Eocene)
of North America.

Referred Species. — R. sciuroides (Scott and Osborn,
1887); R. debequensis Wood, 1962; R. huerfanensis Wood,
1962; R. ctenodactylops Korth, 1984.

Discussion. —In the latest review of the genus Reithropara¬
mys, Wood (1962) recognized seven valid species. Korth
(1984) named a new species, R. ctenodactylops, from the
Wasatchian of Wyoming, and transferred two Wasatchian
species, R. atwateri and R. pattersoni, to a new genus
Acritoparamys.

One of the Bridgerian species named by Wood (1962), R.
matthewi, is based on two specimens. The type specimen
(YPM 13399-1) consists of both mandibular rami of one
individual. The molars of the holotype are less lophate than the
lower cheek teeth of its contemporary R. delicatissimus, and
also lack the partial hypolophid that is characteristic of all other
species of Reithroparamys. The single referred specimen of R.
matthewi (YPM 14631; listed as YPM 13398-1 by Wood,
1962:138) is considerably more lophate than the holotype and
does have a distinct partial hypolophid. Wood (1962)
concluded that R. matthewi is more advanced that R.
delicatissimus, basing his reasoning on features of the referred
specimen. However, the single referred specimen of R.
matthewi does not differ in size (see Wood, 1962, tables 46,
48) or in morphology from many referred specimens of R.
delicatissimus, and should be referred to that species. This
leaves R. matthewi represented only by the holotype, which,
for the morphologic reasons mentioned above, cannot be
referred to Reithroparamys. The lower cheek teeth of the
holotype of R. matthewi do have features seen in Acritopara¬
mys, and appear to be indistinguishable from lower cheek teeth
of A. wyomingensis (= Microparamys wyomingensis Wood,
1959; = Paramys wyomingensis West, 1969, 1973). Thus,
based on the type specimen, Reithroparamys matthewi Wood,
1962, is considered a junior synonym of Acritoparamys
wyomingensis (Wood, 1959a).

Wood (1962) referred Plesiarctomys sciuroides Scott and
Osborn, (1887) from the Uinta Formation of Utah, to
Leptotomus Matthew (1910). This species is clearly referable
to Reithroparamys and distinct from Leptotomus because of
(1) smaller size; (2) rostrum of the skull short and tapered
anteriorly; (3) posterior edge of nasal bones even with posterior
edge of premaxillaries; (4) auditory bullae large, ossified, and
attached to the skull; (5) posterior margin of anterior root of
the zygoma even with the posterior half of P4; (6) upper incisor
with a shallow central groove; (7) tibia slender and elongated;

(8) P4 not showing anteroposteriorly compressed triangular
shape, as in Leptotomus ; and (9) partial hypolophid present
on lower molars. On the posterior part of the skull of R.
sciuroides (YPM-PU 11555) a fragment of cranium has a low
non-central temporal crest (i.e., not a single sagittal crest). This
crest, and the configuration of the parasagittal crests on the
anterior portion of the skull of R. sciuroides, are similar to
those on the skull of R. delicatissimus (AMNH 12561; see
Wood, 1962, fig. 41). The rostrum of YPM-PU 11555 appears
broader than that of AMNH 12561, but this is merely due to
dorsoventral crushing of the R. sciuroides skull.

These characters of the skull, and also of the tibia, that are
shared by these two species, R. sciuroides and R. delicatis¬
simus, are not seen in other ischyromyid genera. Both P4’s of
the type of R. sciuroides are very heavily worn and have some
minor breakage along their lingual margins, eliminating any
possibility of determining whether or or not these teeth ever
possessed a hypocone. Wood (1962) stated that there is no trace
of a hypocone on P4 of R. sciuroides (YPM-PU 11555), which
would make it unlike any other known reithroparamyhine
(Korth, 1984:26). However, Scott and Osborn (1887, pi. XI,
fig. lc) originally figured the type specimen of R. sciuroides
with a hypocone on P4. Because the first illustration of the
specimen shows a P4 hypocone that could have been removed
by subsequent breakage, and because all other features of the
skeleton and dentition of the type specimen of R. sciuroides
are similar to those of other Reithroparamys, the species is
transferred to that genus.

Reithroparamys gidleyi (Peterson, 1919) is know from a
single specimen, CM 3461, which is a partial jaw with ml-m2.
These teeth are almost identical in size to those of R. sciuroides
(see Wood, 1962, tables 33, 34, 48). The heavily worn
condition of these teeth in the type of R. sciuroides precludes
comparing most of their crown morphologies to those of R.
gidleyi. However, in the few features that can be compared
(presence of partial hypolophid, size of trigonid, occlusal
outline) the two species appear to be identical. This, combined
with the fact that the holotypes of both R. gidleyi and R.
sciuroides are from the same horizon of the Uinta Formation,
make it reasonable to assume that the two specimens represent
but one species.

Five species of Reithroparamys are recognized here, R.
ctenodactylops and R. debequensis from the Wasatchian, R.
huerfanensis and R. delicatissimus from the Bridgerian, and R.
sciuroides from the Uintan.

Reithroparamys delicatissimus (Leidy, 1871)

Table 1

Referred Specimens— USNM336407, 336408,417489-
417492, all isolated lower molars; and USNM 336406, RP4.

Discussion. — Reithroparamys delicatissimus is the largest
rodent presently represented in the Elderberry Canyon Local
Fauna. Considering the volume of limestone already processed

NUMBER 67

3

Table 1 .— Measurements (in millimeters) of teeth of Reithroparamys
delicatissimus from Elderberry Canyon Quarry.

USNM#

p4 ml or m2 m3

a-p tra trp a-p tra trp a-p tra trp

336407

3.11 2.08 2.06

336408

3.22 2.98 3.15

417489

3.31 2.69 2.86

417491

3.18 2.63 3.04

417490

4.05 2.95 2.87

417492

3.58 2.81 2.68

P4

a-p tr

336406

2.42 2.98

from the site, it seems likely that if larger rodents occur there
they would have been found. This suggests that the absence
of larger ischyromyids is due to taphonomic, or possibly local
environmental, controls. The isolated teeth referred here to R.
delicatissimus do not differ detectably from the topotypic
material described by Wood (1962).

Reithroparamys cf. R. huerfanensis Wood, 1962

Figure 1; Table 2

Referred Specimen.— USNM 336409-336414, 417493,
417494, all isolated upper cheek teeth; USNM 336415, a partial
maxilla with LDP3-M1; and USNM 417495, partial maxilla
with LM1-M2.

Description. —DP3 small, single rooted; single main cusp
at anterolingual corner of tooth with low continuous shelf on
all sides. DP4 triangular in occlusal outline, expanded
anteriorly in parastylar area; anterior cingulum running from
buccal slope of protocone to buccal margin of tooth, bowing
anteriorly at parastyle; hypocone distinct, smaller and lingual
to protocone; metaconule single, larger than protoconule; small
cuspule buccal to protoconule; mesostyle anteroposteriorly

elongate; posterior cingulum extending from hypocone to
buccal margin of tooth. P4 not represented in the Elderberry
Canyon sample.

Ml similar morphologically to those of R. delicatissimus
(see Wood, 1962); protoloph and metaloph less lophate than
in R. delicatissimus; protoconule a distinct cusp slightly
anterior to paracone; a small cusp present along a small loph
running anterobucally from the protocone, sometimes repre¬
sented by a distinct crest running between protoloph and
anterior cingulum; metaconule doubled; conules large and of
subequal size, slightly smaller than metacone; mesostyle
relatively large; all other morphology appears to be as in R.
delicatissimus.

M2 longer buccally than Ml; protoconule less distinct and
more lingually positioned than in Ml; otherwise similar in all
features to Ml.

M3 lacking hypocone and metacone; metaconule doubled,
conules small; cuspule anterobuccal to protocone distinct; tooth
expanded posterobuccally.

Discussion. —No upper molars have previously been
described for Reithroparamys huerfanensis. The specimens
listed above are referred to this species because they are of the
right size (Table 2), and because of their general similarity to
the upper cheek teeth of R. delicatissimus. These teeth are
smaller than those of R. delicatissimus and differ morphologi¬
cally in their more cuspate lophs, and the presence of an
accessory cuspule or lophule anterior and buccal to the
protocone. This lophule is a distinct feature of most primitive
aplodontids (see Rensberger, 1975). Reithroparamys huer¬
fanensis also shares several other features with early aplodon¬
tids: (1) the masseteric fossa placed more anteriorly on the
mandible; (2) a distinct (though not complete) hypolophid on
the lower molars; (3) doubled metaconule on the upper molars,
a feature seen in Prosciurus vetustus, the earliest known species
of Prosciurus, from the Chadronian of Montana.

Currently, the earliest aplodontid recognized is Spurimus

Figure 1.—Upper dentition of Reithroparamys cf. R. huerfanensis from Elderberry Canyon Quarry: A, USNM
336415, LdP3-Ml; B, USNM 336412, LM1 or M2; C, USNM 336410, LM3. (All in occlusal aspect, all
approximately x 16, bar = 1 mm.)

4

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Table 2.—Measurements (in millimeters) of teeth of Reithroparamys cf. R. huerfanensis from Elderberry
Canyon, Quarry.

USNM#

dP3

dP4

Ml

M2

M3

a-p

tr

a-p

tr

a-p

tr

a-p

tr

a-p tr

336415

0.46

0.81

2.04

2.21

2.35

2.90

336411

2.19

2.38

336414

2.19

2.37

417494

2.31

2.73

2.25

2.73

417495

2.24

2.97

2.29

2.86

336409*

2.45

2.74

336412’

2.28

2.60

336413*

2.23

2.43

336410

2.64 2.54

’Ml or M2

Black, (1971) from the Uintan of Wyoming, which is not a
likely ancestor for Prosciurus Matthew (1903) but which may
be ancestral to Pelycomys Galbreath (1953), which ranges from
Chadronian to Whitneyan (Korth, 1986).

The similarities of the dentition of R. huerfanensis to that
of the type species of the genus, R. delicatissimus, are close
enough to include R. huerfanensis in this genus. However, the
similarities seen between R. huerfanensis and primitive
Prosciurus suggests that the origin of Aplodontidae might be
found within the Reithroparamyinae.

If these upper teeth are correctly assigned to R. huerfanensis,
then the presence of this taxon in the Elderberry Canyon Local
Fauna is perhaps the best indicator, among the known rodents,
of earliest Bridgerian time (= Gardnerbuttean sensu Stucky,
1984).

Subfamily Microparamyinae Wood, 1962
Genus Microparamys Wood, 1959a

Microparamys sambucus, new species

Figure 2; Table 3

Type Specimen.— USNM 336417, left ramus of mandible
with il and ml-m2.

Locality and Horizon.— Elderberry Canyon Quarry, near
Ely in White Pine County, Nevada, from rocks referred to the
Sheep Pass Formation.

Age.—E arly Bridgerian (early Middle Eocene).

Referred Specimens.— USNM 336392-336403, 336419,
336428, 404716, 417479-417488, 417498, 417499; all
isolated cheek teeth.

Diagnosis.— Lower molars with anterior cingulum termi¬
nating buccally in small cuspule, and separated from metaco-
nid; posterior arm of protoconid complete to metaconid;
entoconid separate from posterolophid with a partial hypolo-
phid extending into talonid basin; mesoconid small and
circular; metastylids minute to absent; metaconule on upper
molars very small to absent and metaloph incomplete or weakly
connected to protocone.

Etymology.— From the Latin sambucus (elder), the genus

of elderberry.

Description.— Mandible slender; masseteric fossa termi¬
nating anteriorly below anterior end of m2; mental foramen
high and just anterior to p4. Lower incisor laterally compressed
with flattened anterior face. All other features of mandible
obscured due to crushing of USNM 336417 (the only
mandibular specimen).

Dp4 is the smallest cheek tooth; metaconid larger than
protoconid; minute cuspule anterior and slightly lingual to
protoconid; trigonid buccolingually compressed; entoconid
small, isolated with short hypolophid running posterobuccally,
ending anterior to posterolophid; posterolophid separated from
entoconid by groove; mesoconid small, circular; no ectolophid
present.

The occlusal outline of ml and m2 is rectangular, ml
slightly smaller than m2; anterior cingulum short, separated
from metaconid by shallow groove and ending buccally in a
distinct cuspule; posterior arm of the protoconid extends entire
width of trigonid to base of metaconid, closing trigonid
posteriorly; mesoconid small and circular; entoconid separated
from posterolophid with short hypolophid curving anterobuc-
cally, often fusing with posterolophid at center; ectolophid
weakly developed or absent.

The posterior part of m3 is narrower than the anterior part,
and the posterolophid is bowed posteriorly, but this tooth is
otherwise similar to the more anterior molars.

USNM 404716 is a fragment of+ maxilla with P3 and
alveolus for P4. P3 is small, single rooted, with a conical
crown; on the portion of the maxilla anterior to P3 a small
bony knob is preserved, similar to that described in earlier
species of Microparamys (Korth, 1984:39).

DP4 is similar to that of M. minutus (Dawson, 1968:339);
triangular in occlusal outline; protoloph incomplete; proto-
conule minute, sometimes doubled; anterior cingulum running
entire width of tooth from protocone; metaconule elongate
swelling along metaloph; metaloph curving anteriorly, con¬
nected to protocone by small, thin loph; posterior cingulum
running entire width of tooth; hypocone slightly smaller than
protocone, positioned posterior and lingual to protocone.

P4 has a small hypocone; protoconule reduced; metaconule

NUMBER 67

5

FIGURE 2.—Dentition of Microparamys sambucus, new species, from Elderberry Canyon Quarry: A, USNM
417488, RP4; B, USNM 336392, RM1 or M2; C, USNM 417482, LM1 or M2; D, USNM 417486, Rdp4; E,
USNM 336417 (type), Lml-m2; F, USNM 417484, Lm3. (All in occlusal aspect, all approximately x 17, bar =
1 mm.)

doubled but minute; metaloph not continuous with protocone;
mesostyle anteroposteriorly elongate; anterior and posterior
cingula extending entire width of tooth.

Ml and M2 are indistinguishable from one another as
separate teeth; protoconule absent, protoloph continuous from
paracone to protocone; metaconule absent, reduced to part of
loph, or multiple minute cuspules; metaloph connected to
protocone by weak loph, separated from protocone on one
specimen.

M3 is similar to the anterior molars in the morphology of
the anterior cingulum and protoloph, but the metaloph,
metacone, and hypocone are absent; tooth expanded anterobuc-
cally; posterior cingulum forms rim around posterior half of
tooth.

Measurements in millimeters of the holotype are: ml, a-p =
1.43, tra = 1.22, tip = 1.46; m2, a-p = 1.53, tra = 1.41, trp =
1.60. Statistics of measurements of the entire sample of
Microparayms sambucus are given in Table 3.

DISCUSSION.— Microparamys sambucus differs from the
Bridgerian M. minutus and is similar to the later species M.
dubius and Microparamys sp. D (Wood, 1962) in: (1) anterior
cingulum of lower molars with buccal cuspule; (2) posterior
arm of protoconid complete; (3) hypolophid present; (4)
metastylid reduced. The lower molars of Microparamys
sambucus differs from those of the Uintan M. dubius (Dawson,
1966, 1974) in having a metastylid (though quite reduced),
having only a partial hypolophid that does not extend the entire

width of the talonid, and having a valley separating the anterior
cingulum from the metaconid. Microparamys sp. D (Wood,
1962) from the Uintan of California differs from M. sambucus

TABLE 3. —Statistics of measurements of teeth, including those of holotype,
of Microparamys sambucus from Elderberry Canyon Quarry. (Abbreviations:
N = number of specimens; M = mean; OR = observed range of measurements;
S = standard deviation; CV = coefficient of variation; measurements in
millimeters.)

6

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

FIGURE 3.—Lower molars of indeterminate ischyromyid, Mattimys sp., and Knighlomys sp. from Elderberry
Canyon Quarry: A, Ischyromyidae, species indeterminate, USNM 417496, Lml or m2; B, Mattimys sp., USNM
336416, Lml; C, Knightomys sp., USNM 336419, Lm2. (All in occlusal aspect, all approximately x 20, bar =
1 mm.)

by the same features as does M. dubius as well as by the
presence of a crescentic mesoconid not seen in M. sambucus.
The weak connection of the metaloph to the protocone on the
upper cheek teeth of M. sambucus is not known in any other
species of Microparamys.

It seems likely that M. sambucus is ancestral to M. dubius
and Microparamys sp. D, based on their shared derived
similarities, which are absent in the other Bridgerian species
M. minutus. Microparamys sambucus, M. dubius, and Mi¬
croparamys sp. D may represent a distinct lineage of
Microparamys separate from all other known North American
species.

Ischyromyid, species indeterminate

Figure 3a

Referred Specimen.— USNM 417496, Lml or m2.

Description.— Small tooth (a-p = 1.95 mm; tra. = 1.96
mm; trp = 1.82 mm); approximately square in occlusal outline;
anterior cingulum short, continuous from metaconid to
protoconid; metaconid anterior to protoconid; posterior arm
of protoconid extending half the width of the tooth; enamel of
talonid basin rugose; ectolophid connecting protoconid to
hypoconid; mesoconid minor swelling on ectolophid; metastylid
absent; hypolophid continuous from entoconid to hypoconid;
posterior cingulum running entire width of tooth from
hypoconid.

DISCUSSION.— USNM 417496 is similar to Microparamys
in size and occlusal outline, but differs from it in the presence
of rugose enamel in the talonid basin, anterior cingulum
continuous with the protoconid and posterolophid continuous
with the entoconid. The only genera that are of similar size to
USNM 417496 and that have rugose enamel are Mattimys and
Lophiparamys. However, both these genera have buccally free

anterior cingula as in Microparamys. All of the features that
separate USNM 417496 from Microparamys are features of
paramyines. The complete hypolophid of USNM 417496 is
virtually unknown in paramyines and reithroparamyines.
Among all the ischyromyids except Ischyromys itself, only a
few species of Leptotomus have lower molars with complete
hypolophids (Black, 1971; Nelson, 1974).

Family Sciuravidae Miller and Gidley, 1918
Genus Sciuravus Marsh, 1871
Sciuravus species
Table 4

Referred Specimens.— USNM 336389-336391, all iso¬
lated upper molars.

Discussion.— Measurements of these teeth from Elderberry
Canyon show that they fall within the size range of either
Sciuravus nitidus or S. eucristadens (Wilson, 1938a: 133;
Dawson, 1968, table 4; Table 4, this paper). However, these
species can be distinguished from one another only by
characters of the lower dentition (Dawson, 1968), so no specific
identification can be made at present on the material available
from Elderberry Canyon.

Table 4. —Measurements (in millimeters) of teeth of Sciuravus species from
Elderberry Canyon Quarry.

USNM#

dP4

Ml or m2

a-p

tr

a-p tr

336404

1.82

2.10

336408

1.84

2.03

336389

2.60 2.82

NUMBER 67

7

FIGURE 4.—Dentition of Pauromys exallos, new species, from Elderberry Canyon Quarry: A, USNM 336423,
LM1 or M2; B, USNM 336429, LM3; C, USNM 336401, Rp4; D, USNM 336425 (type), Rm 1; E, USNM 336427,
Lm2; F, USNM 336426, Rm2; G, USNM 336420, Lm3. (All in occlusal aspect, all approximately x 18, bar =
1 mm.)

Genus Pauromys Troxell, 1923

Pauromys exallos, new species

Figure 4; Table 5

Type Specimen.— USNM 336425, Right ml.

Horizon and Locality. —Elderberry Canyon Quarry, near
Ely, in White Pine County, Nevada, from rocks referred to the
Sheep Pass Formation.

Age.— Early Bridgerian (early middle Eocene).

Referred Specimens. —USNM 336418, 336420-336424,
336426, 336427, 336429, 336430, and 417474; all isolated
cheek teeth.

Diagnosis. —Largest species of the genus; p4 nearly equal
to ml in length; mesoconid buccolingually elongate on lower
cheek teeth; hypolophid on lower molars complete or
represented by two lophids originating from entoconid and
hypoconid, respectively.

Etymology.— From the Greek, exallos (very different).

Description. —Only specimen of p4 (USNM 336401)
heavily worn; trigonid buccolingually compressed, metaconid
largest cusp; mesoconid buccolingually elongate; entoconid
separated from posterolophid with short hypolophid; no
distinct hypoconulid present; length of p4 nearly equals that
of ml.

The ml is narrower anteriorly than posteriorly; anterior
cingulum ending buccally in small cuspule, separate from
protoconid; posterior arm of protoconid extends entire width
of tooth to base of metaconid; no ectolophid present;
mesoconid elongate, running slightly posterolingually; hypolo¬
phid complete from entoconid to hypoconid, or arises from
both entoconid and hypoconid and disappears at its center,
lingual half fusing with posterolophid; entoconid separated
from posterolophid.

Except for being broader anteriorly and slightly larger, m2
is similar to ml; m3 with trigonid as in m2; hypolophid greatly
reduced or absent; posterolophid convex posteriorly, lengthen¬
ing the anteroposterior dimension of the tooth.

Ml or M2 nearly square in outline; hypocone subequal to
protocone in size; conules absent, submerged in continuous
lophs; anterior cingulum running nearly the entire width of
tooth parallel to and separated from protoloph; posterobuccally
directed loph from protocone and anteriorly directed loph from
center of metaloph fuse at center of tooth; small anterobuccally
directed loph arises from junction of previously mentioned
lophs.

M3 protoloph as in anterior molar; anterior cingulum
extends entire width of tooth; posterior lophule from protocone
absent on USNM 336429, present on USNM 417474;
hypocone small, buccal and posterior to protocone; low, broad

8

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

Table 5. —Measurements (in millimeters) of teeth of Pauromys exallos from Elderberry Canyon.

USNM #

336401

336425*

336430

336418

336424

336426

336427

336420

336421

336422

336429

1.36

£i

tra

0.96

M1 or M2

trp

1.32

_ml_

a-p tra tip

_ m2

a-p tra

_m3_

trp a-p tra trp

1.34 1.04 1.20
1.29 0.93 1.13

1.40

1.19

1.20

1.45

1.20

1.25

1.37

1.15

1.17

1.65

1.48

1.59

1.46

1.18

0.95

1.42

1.08

0.93

1.34

1.14

1.09

1.43

1.35

1.18

a-p tr
336423 1.33 1.49

404695
417474

1.23

1.20

a-p tr

0.99

1.24

*Holotype

lophule running from hypocone to center of tooth on USNM
336429, absent on USNM 417474; metacone absent; posterior
cingulum extends from hypocone to buccal margin of tooth;
tooth not expanded posteriorly.

DISCUSSION.— Pauromys exallos is approximately 50%
larger than any species of Pauromys previously described
(Dawson, 1968, table 6; Wood, 1959b, table 1; Korth, 1984,
table 14; this paper, Table 5) and does not show any reduction
of p4 with respect to the molars, as is the case in other species
of Pauromys. In all other features, P. exallos is nearly identical
to the other, smaller species. The only morphological
difference, other than size, is that the hypolophid is either
complete, or arises from both the hypoconid and entoconid of
the lower molars of P. exallos.

In size, P. exallos approaches the unnamed species of
sciuravid described by Dawson (1968:348) from the early
Bridgerian Powder Wash locality of Utah, but differs from
that species by possessing elongate mesoconids and posteriorly
closed trigonids on the lower molars, and in having upper
molars more nearly square (width and length nearly equal) in
occlusal outline and with an accessory lophule at the center of
the upper molar arising from the junction of the lophs from
protocone and hypocone. Except that it is much larger, P.
exallos also resembles Namatomys in some features, and in
these respects tends to bridge the sciuravid-eomyid gap.

Genus Knightomys Gazin, 1961
Knightomys species

Figure 3c

Referred Specimen.— USNM 336419, Lm2, incomplete.
Description.— Small tooth (a-p = 1.89 mm; tra = 1.78
mm; trp = 1.68 mm); anterior cingulum continuous from

metaconid to protoconid; posterior arm of protoconid ending
lingually at base of metaconid, closing trigonid basin;
mesoconid large, transversely elongate, and isolated, connect¬
ing to lingual extension; entoconid isolated, not connecting to
posterolophid; very short hypolophid extending into talonid
basin from entoconid; hypoconid and posterolophid damaged;
no hypoconulid observable.

DISCUSSION.— USNM 336419 is referable to Knightomys
based on the morphology of the entoconid (separated from
posterolophid with rudimentary hypolophid) and mesoconid
(isolated with lingual extension). In size, USNM 336419 is
within the range of K. depressus (see Korth, 1984, table 10)
but is morphologically closer to K. huerfanensis in having
more bulbous cusps and a short, distinct hypolophid. USNM
336419 differs from both K. depressus and K. huerfanensis in
having the anterior cingulum continuous with the protoconid,
a feature seen in K. minor and K. senior.

Both K. depressus and K. huerfanensis have been reported
from the earliest Bridgerian (= Gardnerbuttean, Korth, 1984).
The presence of Knightomys in the Elderberry Canyon
assemblage does not extend the known geologic range of the
genus, nor does it suggest an earlier age for the fauna than is
indicated by its other elements.

Family 7ZAPODIDAE Coues, 1875
Genus Elymys, new genus

Type Species. —Elymys complexus, new species.

Range.— Early Bridgerian (early middle Eocene) of Ne¬
vada.

Diagnosis.— Minute rodent; dental formula 1/1,0/0,1/03/3;
cheek teeth lophate and brachydont; P4 small, peg-like tooth;
molars longer than wide; hypocones large and conules absent

NUMBER 67

9

on M2-M3, minute on Ml; mesolophs and mesolophids
lacking; complete endolophs and ectolophids on molars.

Etymology.— For Ely, Nevada, town near Elderberry
Canyon Quarry where all specimens were recovered; and Greek
mys, mouse. The gender is masculine.

DISCUSSION. —The dental formula of Elymys is identical to
that of zapodid rodents. The reduction of P4 to a small single
rooted peg is also similar to all dipodoid rodents. The occlusal
morphology of the cheek teeth of Elymys is similar to those
of both Simimys Wilson (1935) from the Uintan of California
and Plesiosminthus Viret (1926), the earliest sicistine rodent,
which ranges from the late Eocene of Asia to the Miocene of
North America and Europe. Elymys differs from both these
genera by lacking mesolophs and mesolophids on the cheek
teeth and a distinct anteroconid on m 1. It is similar to Simimys
in the occlusal outline of Ml and the bifurcation of the
protoloph of the same tooth, but differs from Simimys in its
dental formula. Plesiosminthus not only shares the same dental
formula with Elymys, but both genera also have complete
ectolophids and endolophs on the molars.

Simimys has been considered both a cricetid and zapodid
since its original description. Emry (1981:13) reviewed the
taxonomic history of Simimys and concluded that it was best
referred to “Muroidea, Family incertae sedis .” Almost
concurrently. Wood (1980) erected a new family Simimyidae
to accommodate this problematical genus. Elymys is assigned
to the Zapodidae because of its dental formula, but also because
of the general dental similarities between it and Plesiosminthus.
The most likely phylogenetic position for Elymys may be as
ancestral to both Simimys and later zapodids. A lineage leading
toward Simimys could be derived from Elymys by the
development of mesolophs and mesolophids and loss of
ectolophids on the cheek teeth, and the loss of P4. Another
lineage leading to the zapodids could be derived from Elymys
by the “squaring” of Ml and development of mesolophs and
mesolophids on the cheek teeth. The loss of P4 in Simimys
may wairant allocation of this genus to a separate family; if
so the family should be closely allied with Zapodidae, possibly
under Dipodoidea, and most likely being derived from an
Elymys- like ancestor.

Elymys complexus, new species
Figure 5; Table 5

Type Specimen.— USNM 404720, right maxilla with
P4-M3.

Horizon AND Locality.— Elderberry Canyon Quarry, near
Ely, in White Pine County, Nevada, from rocks referred to the
Sheep Pass Formation.

Age.—E arly Bridgerian (early middle Eocene).

Referred Specimens. —USNM 404691-404704,404706-
404715, 404717-404719, 417469-417473, 417475-417476,
417478, 417497; all isolated cheek teeth.

Diagnosis.— Only known species of the genus.

Etymology. —From the Greek complexus (complex).

Description. —Cheek teeth lophate amd very brachydont;
dental formula 1/1, 0/0, 1/0, 3/3; P4 small single rooted peg,
circular in occlusal outline; all molars rectangular in occlusal
outline, longer (anteroposteriorly) than wide.

Ml with four major cusps (paracone, metacone, protocone,
hypocone) subequal in size; rectangular in shape with slight
anterior expansion at anterobuccal corner; buccal cusps
transversely elongated, lingual cusps obliquely compressed;
anterior cingulum separated from and parallel to protoloph,
extending from buccal margin to buccal slope of protocone,
free lingually; protoloph curving anterobuccally from proto¬
cone and lingually from paracone, uniting at protoconule;
small lophule arising anterobuccally from protoconule, ending
short of the anterior cingulum; distinct endoloph connecting
protocone and hypocone; hypocone slightly more lingual than
protocone; metaloph continuous from metacone to hypocone
with an anterior bend similar to that of protoloph but with no
accessory lophule; posterior cingulum running entire width of
tooth arising from hypocone, separated from metacone at
buccal end; small mesostyle present.

M2 similar in morphology to Ml but lacking anterobuccal
expansion; protoloph bowed anteriorly, but continuous from
paracone to protocone with no protoconule or accessory
lophule; anterior cingulum connected to protoloph by short
anteriorly directed lophule arising just buccal to protocone;
hypocone more crescentic than on Ml and aligned with
protocone; all other features as in Ml.

M3 smaller than anterior molars; anterior cingulum and
protoloph as in M2; hypocone greatly reduced or absent;
metacone reduced and obliquely compressed; posterior cin¬
gulum continuous with metacone.

The anterior part of m 1 is narrower than the posterior part;
metaconid and protoconid are subequal in size; anterior
cingulum short, arising from protoconid, curving anteriorly,
ending at base of metacone; posterior arm of protoconid
continuous to metaconid, slightly curving posteriorly; ectolo-
phid connecting hypoconid to protoconid , aligned directly
anteroposteriorly; minute mesoconid variably present on
ectolophid; posterolophid curving posteriorly from hypoconid
and running entire width of tooth; hypolophid extends buccally
from entoconid across talonid, complete to entoconid on some
specimens.

Like ml, m2 is rectangular in outline, but its trigonid is
wider than in ml; on m2 the anterior cingulum extends the
entire width of tooth, connected by small lophule arising from
protoconid; small cuspule (?anteroconid) present at junction
of anterior cingulum and lophule; posterior arm of protoconid
(metalophulid II) continuous from protoconid to metaconid,
bowed posteriorly; ectolophid as in ml; hypolophid complete
and bowed posteriorly as in metalophid; all other morphology
as in ml. No specimens of m3 have been recognized.

Discussion. —The zygomasseteric structure of Elymys is
not preserved in any of the known specimens. It is likely that

Figure 5.—Dentition of Elymys complexus, new species, from Elderberry Canyon Quarry: A-C, USNM 404720
(type), right maxilla with P4-M3, in A, buccal; B, occlusal; and C, lingual views. D, USNM 404702, Lml,
occlusal view; E, USNM 404703, Lm2, occlusal view; F, USNM 417497, LM1, occlusal view. (All approximately
x 35, bar = 1 mm.)

NUMBER 67

11

Table 6. —Statistics of measurements of teeth of Elymys complexus from
Elderberry Canyon Quarry. (Abbreviations as in Table 3; measurements in
millimeters.)

N

M

OR

S

CV

TYPE

P4

a-p

1

0.24

0.24

tr

1

0.26

0.26

Ml

a-p

10

0.95

0.78-1.03

.07

7.3

0.78

tr

9

0.90

0.70-1.01

.08

9.4

0.70

M2

a-p

9

0.91

0.75-1.00

.08

8.6

0.80

tr

10

0.86

0.72-0.94

.08

8.9

0.72

M3

a-p

5

0.80

0.72-0.83

.04

5.0

0.72

tr

5

0.81

0.70-0.88

.06

7.4

0.70

ml

a-p

5

0.97

0.86-1.12

.12

12.5

tra

6

0.64

0.55-0.74

.06

9.9

trp

5

0.77

0.69-0.86

.07

8.6

m2

a-p

6

1.02

0.98-1.06

.03

2.7

tra

5

0.83

0.80-0.89

.04

4.8

trp

6

0.85

0.80-0.89

.03

3.9

Elymys

had

either

the

primitive condition

for

rodents.

protrogomorphic, or was derived toward dipodoid hystricomor-
phy, as is known to be the case in its presumed nearest relatives,
Simimys and the zapodids (see Emry, 1981).

Dawson (1966) described an isolated upper molar from the
Uintan of Utah, which she compared at length with Simimys.
This specimen, CM 9951, and the species that it represents, is
also derivable from E. complexus. and may be on the lineage
toward true zapodids. If this specimen is an Ml, which is
suggested by the anterobuccal extension of its protoconule, it
has a reduced parastylar area as in Plesiosminthus, and has a
well-developed mesoloph. However, in CM 9951 the endoloph
is not complete and the anterior cingulum is distinct from the
protoloph, conditions not seen in later zapodids.

Family ?Eutypomyidae Miller and Gidley, 1918
Genus Mattimys Korth, 1984

Mattimys species
Figure 3b

Referred Specimen.— USNM 336416, left ml.

Description.— Anterior cingulum separated from protoco-
nid and ending buccally in small cuspule; metaconid and
protoconid subequal in size; posterior arm of protoconid
continuous to apex of metaconid; mesoconid small, circular;
ectolophid continuous from protoconid to hypoconid; hypolo-
phid originating from entoconid, ending in center of talonid;
small metastylid present on posterior slope of metaconid;
rugosities of enamel in center of talonid as in M. kalicola
(Korth, 1984, fig. 32); small, distinct hypoconulid at center of
posterolophid.

Discussion. —USNM 336416 closely resembles ml of
Mattimys kalicola in nearly all occlusal features. It differs from
M. kalicola in having a complete ectolophid and metastylid,

and in being slightly longer anteroposteriorly (a-p = 1.65 mm;
tra = 1.35 mm; trp = 1.25 mm). USNM 336416 differs from
the Uintan Janimus (Dawson, 1966; Storer, 1984) in having
less pronounced irregularities of the enamel in the talonid
basin. It is quite possible that USNM 336416 represents the
same species as FMNH PM 15193, from the Bridget Basin
(West, 1973), previously referred to either Janimus or Mattimys
(Korth, 1984:62).

Conclusions

Nine species of rodents, representing four families, are
presently recognized in the Elderberry Canyon Local Fauna.
Reithroparamys delicatissimus is previously known only from
Bridgerian faunas. The undetermined species of Sciuravus is
larger than the only known Wasatchian species, S. wilsoni, and
is similar in size to the Bridgerian species S. eucristadens and
S. nitidus. Pauromys is known in both Bridgerian and latest
Wasatchian faunas, as is Mattimys. The only rodent in the
Elderberry Canyon assemblage that is otherwise known only
from a very restricted horizon is Reithroparamys huerfanensis,
which has heretofore been known only from the earliest
Bridgerian of Colorado. Unfortunately, all of the specimens
from Elderberry Canyon assigned to this species are upper
cheek teeth, and all other teeth from early Bridgerian horizons
are lower dentitions, so allocation of the Elderberry Canyon
material is not certain. A precise biostratigraphic age cannot
be determined solely on the basis of the rodents currently
known, but what they do suggest, coupled with the greatest
homotaxial similarities of the whole known fauna (Emry, in
press), gives a fairly secure early Bridgerian date to the
Elderberry Canyon assemblage.

The largest rodent presently known from Elderberry Canyon
is Reithroparamys delicatissimus, which is an intermediate
sized ischyromyid. No specimens have so far been recognized
as Paramys, perhaps the most common rodent in Wasatchian
and Bridgerian faunas elsewhere, nor have the larger, but rarer,
manitshine rodents been seen at Elderberry Canyon. Consider¬
ing the volume of limestone that has been processed to recover
the material presently known, and the size of the collection,
which includes a variety of small insectivores, condylarths,
carnivores, etc., it seems likely that the larger rodents would
have been found by now if they were present in the fauna. If
the absence of Paramys and other larger rodents is real, then
it suggests that the Elderberry Canyon assemblage may
represent either a special environmental situation, or may be
just the result of selective sorting by taphonomic factors. Since
Microparamys and Paramys commonly (nearly always) occur
together in other Wasatchian and Bridgerian faunas, it seems
unlikely that the Microparamys that occurs at Elderberry
Canyon would have required special environmental conditions
not suitable for Paramys. Certain taphonomic factors, such as
concentration by a predator that did not prey on animals larger
than Reithroparamys, might account for the absence of larger

12

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

rodents even though they may have been a part of the
paleocommunity.

Another rodent that seems to be missing from the Elderberry
Canyon assemblage is the small rodent My sops. Several species
of My sops are recognized from the Bridger Formation (Wilson,
1938b), which has yielded rodents of similar size, as well as
those that are much larger. The various species of My sops are
smaller than Microparamys sambucus and larger than Elymys
complexus. Therefore, if size were the controlling factor in the
species preserved in the Elderberry Canyon fauna, then Mysops
would be expected there too. This leaves the possiblity that
Mysops was excluded from the paleocommunity by competi¬
tion with the minute Elymys.

The Elderberry Canyon Local Fauna is certainly geologi¬
cally older than the numerous mammalian local faunas from
southern California, summarized by Golz and Lillegraven
(1977) and Lillegraven (1979), which appear to be latest
Bridgerian at the oldest, and more probably early Uintan and
younger. There is significant homotaxial similarity, however,

between the early Uintan faunas of California and those of the
same age in the Rocky Mountain region, after which time
endemism becomes progressively greater through the end of
the Eocene. Lillegraven (1979) postulated that in Bridgerian
time faunal interchange was relatively unrestricted between the
Rocky Mountain region and southern California, through a
corridor of tropical to subtropical lowlands that included
southern Nevada. The Elderberry Canyon assemblage occurs
along what would have been the northern margin of this
corridor. This fauna as a whole, and the rodents in particular,
surely demonstrate that interchange was relatively unrestricted
at least between Nevada and the Rocky Mountain region in
early Bridgerian time. And though the similarities in rodents
seem to be greatest with the Rocky Mountain region, the
presence of Elymys, which seems to be closely related to
Simimys, one of the more common rodents in the southern
California Eocene (see, for example, Lillegraven and Wilson,
1975), suggests freedom of interchange between Nevada and
California as well.

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Peterson, Olof A.

1919. Report upon the Material Discovered in the Upper Eocene of the
Uinta Basin by Earl Douglass in the Years 1908-1909 and by O.A.
Peterson in 1912. Annals of the Carnegie Museum, 12(2-4):
40-168.

Rensberger, John M.

1975. Haplomys and Its Bearing on the Origin of Aplodontid Rodents.
Journal of Mammalogy, 56:1-14.

Scott, William B., and Henry F. Osborn

1887. Preliminary Report on the Vertebrate Fossils of the Uinta Formation,
Collected by the Princeton Expedition of 1886. Proceedings of the
American Philosophical Society, 24:255-264.

Storer, John E.

1984. Mammals of the Swift Current Creek Local Fauna (Eocene: Uintan,
Saskatchewan). Saskatchewan Museum of Natural History, Natural
History Contributions, 7:1-158.

Stucky, Richard K.

1984. The Wasatchian-Bridgerian Land Mammal Age Boundary (Early
to Middle Eocene) in Western North America. Annals of the
Carnegie Museum, 53:347-382.

Troxell, Edward L.

1923. Pauromys perditus, a Small Rodent. American Journal of Science,
5:155-156.

Viret, Jean

1926. Nouvelles observations relatives a la faune de Ronseurs de
Saint-Gerard-le Puy. Comptes-rendu Hebdomadaires des Seances
de I'Academie des Sciences, Paris, 183:71-72.

West, Robert M.

1969. Paramys wyomingensis, a Small Rodent from the Middle Eocene
of Wyoming. Journal of Paleontology, 43:175-178.

1973. Geology and Mammalian Paleontology of the New Fork-Big Sandy
Area, Sublette County, Wyoming. Fieldiana: Geology, 29:1-193.

Wilson, Robert W.

1935. Cricetine-like Rodents from the Sespe Eocene of California.
Proceedings of the National Academy of Sciences, 21:26-32.

1938a. Review of Some Rodent Genera from the Bridger Eocene. American
Journal of Science, 35:123-137.

13

14

SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY

1938b. Review of Some Rodent Genera from the Bridger Eocene, Part II.
American Journal of Science, 35:207-222.

Wood, Albert E.

1959a. Rodentia. In P.O. McGrew, editor, The Geology and Paleontology
of the Elk Mountain and Tebemacle Butte Area, Wyoming. Bulletin
of the American Museum of Natural History, 117:157-169.

1959b. A New Sciuravid Rodent of the Genus Pauromys from the Eocene
of Wyoming. American Museum Novitates, 1978:1-6.

1962. The Early Tertiary Rodents of the Family Paramyidae. Transactions
of the American Philosophical Society, 52:1-261.

1980. The Oligocene Rodents of North America. Transactions of the
American Philosophical Society, 70:1-68.

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