Research Article

Paleobiology of a large mammal community from the late
Pleistocene of Sonora, Mexico

Rachel A. Shorta* , Laura G. Emmertb, Nicholas A. Famosoc,d, Jeff M. Martina,†, Jim I. Meade,f, Sandy L. Swifte

and Arturo Baezg
aDepartment of Ecology and Conservation Biology, Texas A&M University, College Station, Texas 77843 USA; bDon Sundquist Center of Excellence in Paleontology,
East Tennessee State University, Johnson City, Tennessee 37614 USA; cJohn Day Fossil Beds National Monument, U.S. National Park Service, Kimberly, Oregon 97848
USA; dDepartment of Earth Sciences, University of Oregon, Eugene, Oregon 97403 USA; eThe Mammoth Site of Hot Springs, S.D.,1800 Hwy 18 Bypass, Hot Springs,
South Dakota, 57747 USA; fDesert Laboratory on Tumamoc Hill, University of Arizona, Tucson, Arizona 85745 USA and gCollege of Agriculture and Life Sciences,
University of Arizona, Tucson, Arizona 85721 USA

Abstract

A paleontological deposit near San Clemente de Térapa represents one of the very few Rancholabrean North American Land Mammal Age
sites within Sonora, Mexico. During that time, grasslands were common, and the climate included cooler and drier summers and wetter
winters than currently experienced in northern Mexico. Here, we demonstrate restructuring in the mammalian community associated
with environmental change over the past 40,000 years at Térapa. The fossil community has a similar number of carnivores and herbivores
whereas the modern community consists mostly of carnivores. There was also a 97% decrease in mean body size (from 289 kg to 9 kg)
because of the loss of megafauna. We further provide an updated review of ungulates and carnivores, recognizing two distinct morphotypes
of Equus, including E. scotti and a slighter species; as well as Platygonus compressus; Camelops hesternus; Canis dirus; and Lynx rufus; and
the first regional records of Palaeolama mirifica, Procyon lotor, and Smilodon cf. S. fatalis. The Térapa mammals presented here provide a
more comprehensive understanding of the faunal community restructuring that occurred in northern Mexico from the late Pleistocene to
present day, indicating further potential biodiversity loss with continued warming and drying of the region.

Keywords: Community ecology, Mammals, Ungulates, Carnivores, Rancholabrean, Sonora, Conservation paleobiology

(Received 19 April 2020; accepted 4 December 2020)

INTRODUCTION

Conservation paleobiology aims to use knowledge of the past to
make informed predictions about the future of Earth’s threatened
biodiversity (Dietl and Flessa, 2011, Dietl et al., 2015, Barnosky
et al., 2017). These studies provide a baseline of what community
structures looked like in the past, how extant communities might
respond to impending changes, and how we should approach
conservation. For example, in the Greater Everglades Ecosystem,
paleoecological data from pollen and invertebrates have been
used to establish pre-anthropogenic trends and cycles, predict
future changes, and identify restoration targets for anticipatory
resource management efforts (Wingard et al., 2017). Other similar
work has documented the presence of Bison in the Grand Canyon
region (Martin et al., 2017), inspired interagency conservation
and management plans for Bison today (Plumb and McMullen,
2018), and encouraged restoration of threatened plant species in
Hawaii (Burney and Burney, 2007).

Increasingly xeric landscapes, such as those in the southwest
US and northwest Mexico, are challenging for natural resource
management (Sayre et al., 2013). Integration of fossil sites with
climate patterns may reveal potential future areas for faunal refu-
gia and migratory corridors as fauna must shift their geographic
ranges or risk extinction (Blois and Hadly, 2009). Additionally,
studying past faunal change may reveal trends in restructuring
of faunal communities, which may enhance anticipatory natural
resource management decisions and strategies. In particular,
large animals and plants are disproportionately important for
ecosystem function (Enquist et al., 2020), and changes in these
communities can indicate environmental change (Blois and
Hadly, 2009).

Paleobiology of mammal communities has commonly focused
on body size and diet because they can be inferred from fossil
remains. Smith et al. (2018) demonstrated a widespread 95%
decline in mean body mass of North American mammal commu-
nities (e.g., from 100 kg to 5 kg) associated with the loss of the
Pleistocene megafauna. Stegner and Holmes (2013) investigated
mammalian community structure over 16 million years and dem-
onstrated static diversity of dietary functional groups except in
times of major environmental pressures. In the Pleistocene of
Mexico, mammal communities were more taxonomically diverse,
with more large-bodied taxa and a more similar ratio between

*Corresponding Author: Rachel A. Short, Email: rachel.a.short@tamu.edu
†Current address: Center of Excellence for Bison Studies, South Dakota State

University, Rapid City, South Dakota 57703 USA
Cite this article: Short RA, Emmert LG, Famoso NA, Martin JM, Mead JI, Swift SL,

Baez A (2021). Paleobiology of a large mammal community from the late Pleistocene of
Sonora, Mexico. Quaternary Research 102, 247–259. https://doi.org/10.1017/qua.2020.125

© University of Washington. Published by Cambridge University Press, 2021. This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence
(http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.

Quaternary Research (2021), 102, 247–259

doi:10.1017/qua.2020.125

https://doi.org/10.1017/qua.2020.125 Published online by Cambridge University Press

https://orcid.org/0000-0001-6180-3294
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herbivores and carnivores as compared to modern communities
(Ferrusquía-Villafranca et al., 2010).

Overall, our knowledge of the fossil mammals of Mexico is
biased toward taxa of larger sizes and younger geological ages,
possibly because of collection methods (Montellano-Ballesteros
and Jiménez-Hidalgo, 2006; Ferrusquía-Villafranca et al., 2010).
Of 64 Neogene sites in Sonora, Mexico, only three sites have
detailed faunal records: El Golfo, San Clemente de Térapa
(hereon, Térapa), and Rancho la Brisca (White et al., 2010). El
Golfo is the only known Irvingtonian LMA site in northern
Mexico (Lindsay, 1984; Croxen et al., 2007; Sussman et al.,
2016). Rancho La Brisca is from the Rancholabrean LMA but
has a slightly different fauna than is preserved at Térapa and
other sites in the region because its record is biased toward
small and medium fish, amphibians, and reptiles (Van
Devender et al., 1985). Additional small and isolated records in
the region, including La Botana, Llano Prieto, and
Chinobampo, consist of mostly large mammals, such as Bison,
Equus, Mammuthus, Glyptotherium, and Camelops (White
et al., 2010; Cruz-y-Cruz et al., 2018). West of Térapa, La Playa
has fossils of Bison, Platygonus, Mammuthus, Equus, camelids,
and other large mammals, but also has the first record of
Cynomys in Sonora, which suggests more small mammals may
be found at other sites (Mead et al., 2010).

Located in Sonora, Mexico, Térapa (29°41′N, 109°39′W; 605 m
elevation; Fig. 1) provides an excellent case study of faunal
response to environmental and climatic changes in an area
vulnerable to continued alteration because of its geographic loca-
tion in an ecotone between the northern Nearctic climate and
the southern Neotropical climate. Modern (i.e., interglacial)
Sonoran and Chihuahuan deserts are typified by scrubland
ecosystems with warm tropical-subtropical climates, and at pre-
sent, this area is situated on the margin of the Madrean
Archipelago and the Sinaloa-Sonora Hills and Canyons
(Morrone et al., 2017). However, when the fossil-bearing sedi-
ments were deposited in the Térapa basin, western Sonora was
more temperate, with cooler, drier summers and wetter winters
than are seen today (Nunez et al., 2010), and was typified by
pinyon-juniper-oak woodlands (Van Devender, 2007). Stable iso-
tope analyses of carbon and oxygen from ungulate teeth (Nunez
et al., 2010) and ostrocodes (Bright et al., 2016) recovered at
Térapa suggest that, at least in the valley, marsh and grasslands
were likely present at the time of deposition. Previous studies of
Térapa avifauna (Steadman and Mead, 2010; Oswald and
Steadman, 2011), crocodilians (Mead et al., 2006), bats and
shrews (Czaplewski et al., 2014), and ostracodes (Bright et al.,
2016) indicate that the environment was an elevational mosaic
of temperate to tropical-subtropical marsh and savanna/grassland
with a slow-moving freshwater stream flowing from north of
Térapa down to the Río Moctezuma and Río Yaqui to the Gulf
of California.

Discovered in 2000, late Pleistocene (MIS/OIS 3) faunal depos-
its at Térapa include fossils of more than 60 taxa (Mead et al.,
2006). A preliminary faunal list is provided in Mead et al.
(2006), and an updated faunal list is provided in Supplemental
Table S1. Recent publications have described Mammuthus and
Cuvieronius (Mead et al., 2019), Glyptotherium cylindricum and
Pampatherium cf. P. mexicanum (Mead et al., 2007), two shrews
and six bats (Czaplewski et al., 2014), and 39 species of birds
(Steadman and Mead, 2010; Oswald and Steadman, 2011). With
Bison present throughout the stratigraphic profile, Térapa repre-
sents one of the few Rancholabrean North American Land

Mammal Age (LMA) sites studied in detail in Sonora (Bell
et al., 2004; Mead et al., 2006). However, the Holarctic genus
Bison did not arrive in Mexico until much later than in the north-
ern part of the continent. This biochronological delay complicates
assigning LMA ages to Mexican sites, and also illustrates the need
to further explore Mexico for fossil sites that can provide insight
into North American fauna during the Pleistocene.

Fossils found at Térapa were deposited where the Tonibabi
basalt flow dammed and diverted the Río Moctezuma and created
a shallow lake at the northern extent of the Sierra Madre
Occidental (Mead et al., 2006). Río Moctezuma sediments
beneath the basalt dam date to 42.9 ± 3.3 ka using infrared stim-
ulated luminescence, providing a maximum age estimate for the
fossils (Bright et al., 2010). Also using infrared stimulated lumi-
nescence, sediments 1 m above the basalt date to 40.2 ± 3.2 ka
(Bright et al., 2010). Using radiocarbon dating, charcoal near
the top of the 11-m-thick sequence of medium- to fine-grained
sediments dates to 41.7 ± 1.0 cal ka BP (Bright et al., 2010).
Additional dates throughout the sequence using amino-acid race-
mization on ostracodes and radiocarbon analysis on a bivalve
confirm deposition between 40 ka and 43 ka (Bright et al.
2010). Because of Térapa’s geographic location and diverse fossil
record at a time of extensive environmental change, ongoing
research on this fauna will contribute to a better understanding
of the late Pleistocene in northwestern Mexico.

Here, we use the fossil record at Térapa to investigate changes
in large mammal community structure in response to environ-
mental change. To do this, we explore community structure, as
represented by feeding strategy and body size, by describing
Térapa specimens and their traits, and discussing their geographic
distributions in the North American desert region. We hypothe-
size that changes in this site’s large mammal community structure
at the end of the Pleistocene are because of a loss of herbivores
and large-bodied taxa. We expect that the fauna described in
this paper will help to further refine paleoecological interpreta-
tions as well as provide a long-term record of faunal change in
a region that is vulnerable to ongoing climate change.

METHODS

Taxa described here were presented by Mead et al. (2006) as:
Equus, Tapirus, cf. Platygonus, Camelops-sized camelid,
Hemiauchenia-sized camelid, Canis dirus, Lynx rufus, and
Procyon. Mead et al. (2006) also included cf. Odocoileus,
Capromeryx, Stockoceras, and Bison on the preliminary list of
fauna, but these additional artiodactyl specimens have been
excluded from this analysis because they either require additional
detailed revision or are part of another review.

Systematic paleontology

To determine taxonomic assignments, we primarily used compar-
ative reference specimens from the Florida Museum of Natural
History (FLMNH) and the East Tennessee Museum of Natural
History (ETMNH). When possible, linear measurements and the
related citations are provided within the taxonomic descriptions.
Geographic occurrences were determined using The Paleobiology
Database (https://paleobiodb.org) and literature. Records were
downloaded from The Paleobiology Database on 27 July 2017
for: Taxonomy = “Equus, Palaeolama, Camelops, Platygonus,
Canis, Lynx, Procyon, Smilodon,” Time = “Rancholabrean,” and
Location = “North America.”

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Species identifications for equid post-crania were determined
using a quadratic discriminant analysis implemented in the R
statistical computing environment using the package MASS (R
Core Team, 2016). Training data used in the analyses are from
Sertich et al. (2014) and McHorse et al. (2016). For analysis of
the phalanx, training data included Equus occidentalis, E. conver-
sidens, E. lambei, E. scotti, and a northwestern stilt-legged taxon.
For analysis of the metacarpal, training data included Equus com-
plicatus, E. conversidens, E. occidentalis, and E. scotti. R code for
this analysis is given in Supplementary Materials.

Community structure

To investigate how community structure has changed at Térapa
through time, the fossil community of Perissodactyla, select
Artiodactyla, and Carnivora presented here was compared to
the same three orders from the modern community. Modern
mammal range maps were downloaded from the IUCN (2018).
Range maps were sampled at the geographic point of Térapa to
assemble a faunal list. Taxa were limited to those that are extant
and either native or reintroduced. Antilocapridae, Bovidae, and
Cervidae were excluded from both communities because,
although they are known from Térapa (Mead et al., 2006), they
are not within the scope of the discussion within this manuscript.

Feeding strategies were obtained from Paleobiology Database
(https://paleobiodb.org) on 10 August 2020 by searching for tax-
onomic names. Strategies were grouped into herbivore, herbivo-
rous omnivore, carnivorous omnivore, and carnivore. Body
mass (BM; kg) averages were extracted from the MOM database
(Smith et al., 2003) for each species. Mass estimates include
males and females across distribution ranges and are not precise
values for the southern geographic location of Térapa. However,
they provide a measure to estimate temporal changes in the fauna.

RESULTS

From the mammalian fauna found at Térapa, we provide descrip-
tions for eight species in seven genera, including Equus,
Platygonus, Camelops, Palaeolama, Canis, Procyon, Lynx, and

Smilodon. Six of these genera appeared on the preliminary faunal
list of Mead et al. (2006), and two of these genera (Palaeolama
and Smilodon) are new additions to the known faunal commu-
nity. Specimens from Térapa are housed temporarily at The
Mammoth Site, Hot Springs, South Dakota, USA, and are curated
with numbers prefixed with TERA. Specimens will be perma-
nently housed at the Instituto Nacional de Antropología e
Historia in Sonora, Mexico.

Systematic paleontology

Class Mammalia
Order Perissodactyla

Family Equidae
Genus Equus Linnaeus, 1758
Equus scotti Gidley, 1900

Material: Left distal metacarpal (TERA 313), left partial pha-
lanx 1 (TERA 320), phalanx 2 and sesamoid (TERA 319).

Description: The left metacarpal (TERA 313) is broken trans-
versely across the diaphysis, but the distal end is complete
(Fig. 2A). The left partial first phalanx (TERA 320) is missing
the lateral, distal portion (Fig. 2B). The metacarpal and phalanx
articulate. The second phalanx is complete (TERA 319; Fig. 2C)
and articulates with a sesamoid. The first and second phalanges
do not articulate.

Identification: In quadratic discriminant analyses, the second
phalanx (TERA 319) was identified to species level with 87.5%
confidence, and the distal metacarpal (TERA 313) was identified
with 100% confidence.

Remarks: Equus is widespread across the US and Mexico dur-
ing the Rancholabrean (Ferrusquía-Villafranca et al., 2010, 2017),
including in Sonora (Cruz-y-Cruz et al., 2018). Taxonomy of
Equus introduces complex questions surrounding species identifi-
cations. Equus scotti is a stout-legged horse that has been docu-
mented across the North American desert region during the
Rancholabrean (Harris, 2014), including in the Tule Springs
local fauna (Scott et al., 2017). Recent efforts to revise equid
taxonomy have considered E. scotti to be synonymous with

Figure 1. (For interpretation of the reference to color in this figure legend, the reader is referred to the web version of this article) Geographic location of study area
(Left), inset figured in (Right) with Sonora, Mexico highlighted in yellow; (Right) location of Térapa (black star) within Sonora, Mexico.

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E. mexicanus (see Alberdi et al., 2014) and E. excelsus (see
Priego-Vargas et al., 2017), but by convention we use E. scotti
to be consistent with the data sources used in the analyses.
Previous work identified E. excelsus at Térapa
(Carranza-Castañeda and Roldán-Quintana, 2007), and it is likely
the same as our E. scotti. However, equid taxonomy needs to be
thoroughly and formally evaluated before these issues can be con-
fidently resolved.

Equus cf. E. scotti Gidley, 1900
Material: Right P4 (TERA 284), right M2 (TERA 287), right

M3 (TERA 285), right P4 and M1 (TERA 291), right P3 and
P4 (TERA 168), left P2 (TERA 282, 289), left P4 (TERA 290),
left M2 (TERA 286, 288), left M3 (TERA 283), right p4 (TERA
310), lower left tooth (TERA 308), upper left tooth and lower
right tooth (TERA 266).

Description: Most of the teeth are complete with moderate
wear. These teeth (Fig. 3A–D) are larger and have more complex
enamel patterns than the teeth assigned to Equus sp. (Fig. 3E–H).

Identification: We hypothesize that the teeth are from the same
species as the postcranial elements previously identified as Equus
scotti because of their large size. More specific identification is dif-
ficult with isolated teeth because they lack a majority of diagnostic
characters (Famoso and Davis, 2014).

Equus sp.
Material: Right P3 (TERA 166), right M1 (TERA 263), right

M2 (TERA 157, 169, 296, 300), right M3 (TERA 298), left M2
(TERA 303), left P4 and M1 (TERA 293), left P3-M1 and right
M1 (TERA 297), upper right tooth (TERA 299, 307), upper
tooth (TERA 267), right m2 (TERA 295), right m3 (TERA 262,
305, 306), left m2 with fragment (TERA 312), left m3 (TERA
322), lower left molar (TERA 301, 302), lower right tooth
(TERA 309), lower left tooth (TERA 311), lower tooth fragment
(TERA 264, 265, 304), mandibular symphysis (TERA 294), left
partial distal humerus (TERA 314), left magnum (TERA 318),
right distal tibia (TERA 317), left partial calcaneum (TERA 315,
316), right cuneiform and lunar (TERA 321).

Description: The postcranial elements are slight compared to
extant Equus caballus and the Térapa specimens conferred to
Equus scotti, and these teeth (Fig. 3E–H) are noticeably smaller
and have less complex enamel patterns than those assigned to
E. cf. E. scotti (Fig. 3A–D).

Identification: It is unknown if the post-cranial elements are of
the same species as the dentition. At this time, there are no mor-
phological features to confirm species designations.

Remarks: Previous work on different specimens also identified
E. conversidens at Térapa (Carranza-Castañeda and Roldán-
Quintana, 2007), and, because of the smaller size, it is possible
that our Equus sp. refers to the same taxon. Occurrence of both
E. scotti and a smaller-sized horse is common at Rancholabrean
sites, and the smaller horse is often identified as E. conversidens
(Harris, 2014). Again, most isolated teeth can only be identified
to genus because of the lack of diagnostic characters (Famoso
and Davis, 2014).

Mead et al. (2006) listed Tapirus sp. among the taxa found at
Térapa based on a mandibular symphysis (TERA 294; Fig. 4A).
However, this specimen is now identified as Equus sp. Depth of
the mandible suggests hypsodont teeth as in Equus. The narrow
intermandibular space extends anterior to the second premolar
as in Equus. In Tapirus, this space is closed at the anterior end
of the second premolar. The mandibular foramen is located

well anterior to the tooth row as in Equus. In Tapirus, the man-
dibular foramen is inferior to the anterior second premolar.

Order Artiodactyla
Family Tayassuidae

Platygonus LeConte, 1848
Platygonus compressus LeConte, 1848

Material: Molar fragments (TERA 167), deciduous upper pre-
molar (TERA 280), right upper canine (TERA 281).

Description: The molar fragments (TERA 167) are hypsodont
and zygodont (Fig. 5A). The deciduous tooth (TERA 280) is com-
plete and more bunodont than the molar fragments (Fig. 5B). The
canine is complete (TERA 281) and has an anterior occlusal sur-
face (Fig. 5C).

Identification: This specimen was initially identified as cf.
Platygonus by Mead et al. (2006). Comparisons with fossil material
at FLMNH suggest that these teeth are Platygonus because the
cusps are more zygolophodont, as in Platygonus, rather than buno-
dont as in Mylohyus. Because Platygonus is monotypic in the mid-
dle and late Rancholabrean (Kurtén and Anderson, 1980; Wright,
1998), these specimens are assigned to P. compressus.

Remarks: Platygonus compressus is known from the
Rancholabrean of Arizona (Murray et al., 2005), New Mexico,
and eastern Texas, as well as the Central Plateau and
Trans-Mexican Volcanic Belt (Ferrusquía-Villafranca et al.,
2010, 2017). In Sonora, Platygonus sp. is known from La Playa
and Bajimari (White et al., 2010) and P. cf. P. vetus is known
from El Golfo (Croxen et al., 2007). Térapa provides the first
record of P. compressus in Sonora, but it is not unexpected.

Figure 2. (color online) Equus scotti specimens. (A) left distal metacarpal (TERA 313);
(B) left partial phalanx (TERA 320); (C) second phalanx (TERA 319). (A) and (B) artic-
ulate. Scale bar = 5 cm.

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Family Camelidae
Camelops Leidy, 1854

Camelops hesternus (Leidy, 1873)
Material: Left mandibular fragment with roots of m1-2 (TERA

278); left partial distal phalanx (TERA 279).
Description: The partial distal phalanx (TERA 279) has splayed

ventral trochlea (Fig. 6A). This specimen is not a metapodial
because of the lack of a condylar keel (Zazula et al., 2016). The

mandibular fragment (TERA 278) has the roots of large seleno-
dont molars (Fig. 6B). At its base, the m2 measures 43.28 mm.

Identification: These specimens were initially identified as
“Camelops-sized” by Mead et al. (2006). The m2 measurement is
within the range of Camelops provided by Honey et al. (1998)
and Baskin and Thomas (2016). The mandible is also substantially
larger than comparative material of Palaeolama and Hemiauchenia.
The phalanx was also compared to phalanges of Palaeolama and
Hemiauchenia, but it is considerably larger than specimens within
both genera. Camelops is the only other Rancholabrean camelid,
and it was large enough to have mandibles and phalanges of the
size found at Térapa (Baskin and Thomas, 2016). The most recent
review of Camelops described two species: C. hesternus in the
Rancholabrean and C. minidokae in the Irvingtonian (Baskin and
Thomas, 2016). Because Camelops is considered monotypic in
the Rancholabrean and the specimens are consistent with the mor-
phology, these specimens are assigned to C. hesternus.

Figure 3. (color online) Equus spp. teeth. (A, B) Equus cf. E. scotti, upper left molar (TERA 286); (C, D) Equus cf. E. scotti, lower left molar (TERA 308); (E, F) Equus sp.,
upper left molar (TERA 303); (G, H), Equus sp., lower right molar (TERA 295). (A, C, E, G) in occlusal view; (B, D, F, H) in lingual view. Scale bar = 5 cm.

Figure 4. (color online) Equus spp. mandible fragments. (A) Equus sp. (TERA 294); pre-
viously identified as Tapirus by Mead et al. (2006); (B) Equus caballus (ETMNH-Z
15462); reference specimen. Scale bar = 5 cm.

Figure 5. (color online) Platygonus compressus specimens. (A) Three molar fragments
(TERA 167); (B) deciduous upper tooth in occlusal view (TERA 280); (C) right upper
canine in labial view (TERA 281). Scale bar = 5 cm.

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Remarks: Camelops hesternus is widespread across the US and
northern Mexico (Ferrusquía-Villafranca et al., 2010, 2017),
including in Sonora (Cruz-y-Cruz et al., 2018). In the southern
US, C. hesternus is known from Rancho La Brea (Jones and
DeSantis, 2017), Diamond Valley Lake (Springer et al., 2009),
Tule Springs (Scott et al., 2017), and throughout Arizona
(Mead et al., 2005) and New Mexico (Harris, 2014).

Palaeolama Gervais, 1867
Palaeolama mirifica (Simpson, 1929)

Material: Left mandible fragment with partial p4-m3 (TERA 156).
Description: The mandibular fragment (TERA 156) has a partial

p4 and m1–3 with brachydont, selenodont dentition (Fig. 6C, D).
The p4 has a vertical groove just posterior to the break. The m2 mea-
sures 19.18mm at the base and 21.25mm at the occlusal surface.

Identification: This specimen was initially identified as
“Hemiauchenia-sized” by Mead et al. (2006). The groove on the
p4 is indicative of the ‘complex infolding’ seen in Palaeolama
(Fig. 6C; Kurtén and Anderson, 1980; Honey et al., 1998,
p. 454). Both m2 measurements are within the range of
Palaeolama provided by Honey et al. (1998). Because
Palaeolama is monotypic in the Rancholabrean of North
America (Honey et al., 1998) and the specimens fit the morphol-
ogy, these specimens are assigned to P. mirifica.

Remarks: Palaeolama mirifica is found at Rancholabrean sites
in Florida, California, and Texas (Kurtén and Anderson, 1980),

South Carolina (Sanders, 2002), Costa Rica (Pérez, 2011), and
in the Mexican state of Puebla (Bravo-Cuevas and
Jiménez-Hidalgo, 2015). However, it has not been documented
in Arizona (Mead et al., 2005). Palaeolama sp. is documented
at Irvingtonian sites at El Golfo in northwestern Sonora
(Croxen et al., 2007) and Rio Tomayate in El Salvador
(Cisneros, 2005), and from the Rancholabrean of Guatemala
(Dávila et al., 2019). Térapa is the first Rancholabrean occurrence
of P. mirifica in northwestern Mexico.

Order Carnivora
Family Canidae

Canis Linnaeus, 1758
Canis dirus Leidy, 1858

Material: Left mandible with c1–m2 (TERA 154), left maxilla
and jugal with P3–M1, left mandible with partial c1–partial m2,
right mandible with p4–m2, four incisors, two upper canines,
two lower canines, one M1, one m3, and two unidentified frag-
ments (TERA 450), distal left humerus (TERA 155).

Description: The left mandible with c1–m2 (TERA 154) and
the distal humerus (TERA 155) were previously described in
detail (Hodnett et al., 2009); the remaining specimens (TERA
450) are described here. All teeth in the maxilla and both mandi-
bles are in an advanced stage of wear. The left maxilla is articu-
lated with the left jugal, and the P3 is broken between the
anterior and posterior roots (Fig. 7A, B). The left mandible is
missing the coronoid process and angular process, but the con-
dyle is complete (Fig. 7C). There is no evidence of an alveolus
for a p1 on the mandible. The anterior mental foramen is inferior
to the anterior p2, and the posterior mental foramen is inferior to
the posterior p3. The right mandible is broken between the p4
and m1 and along the inferior masseter fossa (Fig. 7D). Only
the anterior root of the m2 is present and the alveolus for a single-
rooted m3 is broken. Cranial and dental measurements suggest a
larger than average C. dirus (Fig. 8, Supplemental Table S2;
Tedford et al., 2009).

Identification: Mead et al. (2006) initially identified Canis dirus
at Térapa, and Hodnett et al. (2009) agreed for TERA 154 and
TERA 155. Measurements on the left mandible indicate that this
specimen is too large to be a different Rancholabrean-age canid,
such as C. latrans or C. lupus (Fig. 8). Canis armbrusteri was
also a large canid in the late Irvingtonian (Kurtén and Anderson,
1980; Harris, 2014) and is thought to have given rise to C. dirus
(Tedford et al., 2009). The Térapa teeth are too worn to examine
the cusp patterns, but the upper molars have reduced labial cingula
as in C. dirus rather than C. armbrusteri (Tedford et al., 2009).

Remarks: Canis dirus is considered “one of the most common
mammalian species in the Rancholabrean” and is found across the
US and Mexico (Kurtén and Anderson, 1980, p. 171; Mead et al.,
2005; Harris, 2014; Ferrusquía-Villafranca et al., 2017;
Ruiz-Ramoni and Montellano-Ballesteros, 2019). In the southern
US, C. dirus is common in the local faunas at Rancho La Brea
(McHorse et al., 2012), Diamond Valley Lake (Springer et al.,
2009), and Tule Springs (Scott et al., 2017). However, Térapa is
the first occurrence of C. dirus in Sonora (Hodnett et al., 2009;
Ruiz-Ramoni and Montellano-Ballesteros, 2019). There are at
least three individuals of C. dirus found at Térapa based on
lower left canines. The maxilla and mandibles of TERA 450 are
likely from the same individual because of the similar degree of
wear on the teeth. The extensive wear on the teeth and the
large size suggests one older individual.

Figure 6. (color online) Camelidae specimens. (A) Camelops hesternus, partial left dis-
tal phalanx in anterior view (TERA 279); (B) C. hesternus, left mandibular fragment,
including roots of first and second molars, in occlusal view (TERA 278); (C)
Palaeolama mirifica, right dentary fragment with a partial fourth premolar and
three molars in occlusal view and labial view (D) (TERA 156). Black arrow indicates
the infolding on the p4 that is characteristic of Palaeolama. Scale bar = 5 cm.

252 R.A. Short et al.

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Family Procyonidae
Procyon Storr, 1780

Procyon lotor (Linnaeus, 1758)
Material: Left calcaneum (TERA 453).
Description: The calcaneum (TERA 453) is complete (Fig. 9A).

There is no tubercle present on the trochlear process, which has a
minimal groove, and the calcaneum does not have an accessory
surface between the anterior articular surface and the cuboid
facet. The latter feature has a point on its dorsal edge. The greatest
length of the calcaneum is 28.03 mm and the transverse breadth
of the sustentaculum is 14.49 mm.

Identification: The calcaneum was previously identified as
Procyon sp. (Mead et al., 2006). Following descriptions provided
by Stains (1973; lack of a knob on the trochlear process), the cal-
caneum is now referred to P. lotor. Within Procyon, the calca-
neum is assigned to P. lotor instead of P. cancrivorous because

of the minimal trochlear groove, the cuboid facet, and the lack
of an accessory surface between the anterior articular surface
and the cuboid facet (Stains, 1973). In addition, the length and
breadth measurements are within the range of P. lotor provided
by Stains (1973). Additional Pleistocene species of Procyon have
been synonymized with P. lotor because the morphology was
within the range of intraspecific variation (Kurtén and
Anderson, 1980). Kurtén and Anderson (1980) recognized only
one other fossil species, P. rexroadensis, which was limited to
the Blancan LMA. Emmert and Short (2018) recommended syn-
onymizing P. rexroadensis with P. lotor because of a lack of dis-
tinct morphological characters.

Remarks: Pleistocene-age Procyon has been found across North
America and into northern South America (Kurtén and
Anderson, 1980), but the fossil record is sparse (Harris, 2014).
In Mexico, Procyon sp. is found at the Irvingtonian-age El
Golfo (Croxen et al., 2007), and Procyon lotor is known from
the Rancholabrean in California and New Mexico (Harris,

Figure 7. (color online) Canis dirus specimens (TERA 450). (A) Left maxilla and jugal with P3–M1 in lateral view; (B) left maxilla and jugal with P3–M1 in occlusal
view; (C) left mandible with partial c1–partial m2 in buccal view; (D) right mandible with p4–m2 in buccal view. Scale bar = 5 cm.

Figure 8. Log-ratios of measurements from Térapa Canis dirus (TERA 450) left maxilla
and left mandible compared to Canis dirus from the Rancholabrean (RLB) and
Irvingtonian (IRV), C. armbrusteri, C. lupus, and C. latrans. Measurements are relative
to Eucyon davisi. Methods and reference data from Tedford et al. (2009), and data are
available in Supplemental Table S2. Abbreviations: Left maxilla measurements: LP4 =
length of P4; WP4 = width of P4; LM1 = length of M1; WM1 = width of M1. Left mandi-
ble measurements: Lp3 = length of p3; Lp4 = length of p4; Wp4 = width of p4; Lm1 =
length of m1; Wm1tr = width of m1 trigonid; Wm1tl = width of m1 talonid.

Figure 9. (color online) Carnivora specimens. (A) Procyon lotor, left calcaneum in
anterior view (TERA 453); (B) Lynx rufus, distal left radius in anterior view (TERA
451). Scale bar = 1 cm.

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2014) as well as the Chihuahua-Coahuila Plateaus and Ranges, the
Sierra Madre Oriental, the Trans-Mexican Volcanic Belt and the
Yucatan Platform (Ferrusquía-Villafranca et al., 2010), so it is
expected in the northwest of Mexico, although it is not reported
from the Rancholabrean of Arizona (Mead et al., 2005).

Family Felidae
Lynx Kerr, 1792

Lynx rufus (Schreber, 1777)
Material: Distal left radius (TERA 451).
Description: The radius (TERA 451) is broken transversely

across the diaphysis, which is compressed anteroposteriorly
(Fig. 9B). The styloid process, dorsal tubercle, and lateral tuberos-
ity are angular and pronounced. The greatest breadth of the distal
end (Bd; von den Driesch, 1976) measures 19.41 mm.

Identification: This radius was initially reported as Lynx rufus
by Mead et al. (2006), and the identification is confirmed here.
The distinct features are as in Felidae rather than Canidae, and
the anteroposterior compression excludes Felis (Kelson, 1946).
As in L. rufus, there is a distinct horizontal ridge superior to
the distal articulation on the posterior surface, and a lack of
mediolateral constriction between the diaphysis and epiphysis.
Lynx rufus is known from the Rancholabrean of Mexico
(Ferrusquía-Villafranca et al., 2010) and Arizona (Mead et al.,
2005), whereas Lynx canadensis has not been found south of
Utah (Lavoie et al., 2019).

Remarks: Lynx rufus is frequently found at North American
Pleistocene sites (Kurtén and Anderson, 1980), including at
Rancho La Brea (McHorse et al., 2012), Diamond Valley Lake
(Springer et al., 2009), and Tule Springs (Scott et al., 2017). L.
rufus is known across northern and central Mexico during the
Rancholabrean (Ferrusquía-Villafranca et al., 2010, 2017). In
Mexico, L. rufus is also known from the Irvingtonian of Cedazo
in central Mexico (Mooser and Dalquest, 1975), and the latest
Pleistocene or early Holocene of Jimenez Cave in Chihuahua
(Messing, 1986).

Smilodon Lund, 1842
Smilodon cf. S. fatalis (Leidy, 1868)

Material: Fragment of right dP3 including ectoparastyle and
parastyle (TERA 452).

Description: The tooth fragment (TERA 452) is mediolaterally
compressed and has a distinct parastyle and ectoparastyle
(Fig. 10B). The tooth fragment is lacking a distinct protocone
and preserves no evidence of any lingual flaring that would indi-
cate a protocone had been present. There is a minimal anterior
cingulum on the tooth. Diagnostic measurements are not possible
because of the fragmented nature of the specimen.

Identification: This specimen was initially identified as Canis
latrans by Mead et al. (2006). However, the mediolateral compres-
sion and parastyle suggest this tooth is from Felidae and not
Canidae. The size suggests a large cat, possibly Panthera, Puma,
or Smilodon. The lack of a protocone excludes Panthera and
Puma (Cherin et al., 2013; Babiarz et al., 2018), and the ectopar-
astyle and cingulum are as in Smilodon (Christiansen, 2013).
Therefore, we confer the tooth fragment to Smilodon. Because
Smilodon fatalis is common during the Rancholabrean, S. popula-
tor has not been found in North America, and S. gracilis is from
the early Irvingtonian, we confer the specimen to S. fatalis.

Remarks: Smilodon is known throughout much of North
America from the Irvingtonian and Rancholabrean LMAs
(Kurtén and Anderson, 1980; Babiarz et al., 2018), but this is

the first record from the northwest of Mexico. In Mexico, S. fatalis
has been found at Pleistocene sites across the Central Plateau, the
Trans-Mexico Volcanic Belt, and the Sierra Madre Oriental
(Ferrusquía-Villafranca et al., 2010, 2017). In the United States,
S. fatalis is known from the Rancholabrean of eastern New
Mexico and southern California (Kurtén and Anderson, 1980;
Morgan and Lucas, 2001; Harris, 2014), including at Rancho La
Brea (McHorse et al., 2012), Diamond Valley Lake (Springer
et al., 2009), and Tule Springs (Scott et al., 2017). The presence
in northwestern Mexico is novel but not wholly unexpected,
although it has not been reported from the Rancholabrean of
Arizona (Mead et al., 2005).

Community structure

The late Pleistocene and modern mammalian communities vary
in their composition. The fossil community has two equids, two
camelids, one tayassuid, one canid, two felids, and one procyonid,
whereas in the present day, the Térapa region has one tayassuid,
two canids, three felids, four mephitids, two mustelids, and three
procyonids. The fossil community presented here consists of four
herbivores from two orders of ungulates (Fig. 11). The four carni-
vorans are equally divided into carnivores and carnivorous omni-
vores. Yet, the modern community is largely dominated by 11
carnivorous omnivores, with three carnivores, one herbivorous
omnivore, and no herbivores (Fig. 11). Lynx rufus (carnivore)
and Procyon lotor (carnivorous omnivore) are the only taxa to
occur in both fossil and modern communities.

The faunal turnover of the taxa in this study corresponds with a
97% decrease in mean body mass (BM; kg) from 289 kg to 9 kg.
Odocoileus virginianus is the largest ungulate at Térapa today
(BM= 55 kg), but, in the past, the larger Equus scotti (BM= 555
kg), Camelops hesternus (BM = 1100 kg), Palaeolama mirifica
(BM= 80 kg), and Platygonus compressus (BM= 110 kg) also
occurred at the site. Similarly, with the loss of Smilodon cf. S. fatalis
(BM= 400 kg), the largest carnivoran today is Puma concolor
(BM= 52 kg). Canis dirus (BM = 50 kg) was nearly the same mass
as P. concolor. Procyon lotor (BM= 5.5 kg) is the smallest taxon
in the fossil community presented here, but the modern commu-
nity has eight species of Carnivora that are smaller than P. lotor.

Figure 10. (color online) Smilodon carnassials. (A) S. fatalis adult upper right fourth
premolar (UF/TRO 11) with parastyle and ectoparastyle shaded more opaquely; ref-
erence specimen; (B) S. cf. S. fatalis fragment of deciduous upper right third premolar
in labial view with parastyle and ectoparastyle labeled (TERA 452). Scale bar = 1 cm.

254 R.A. Short et al.

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DISCUSSION

Térapa provides the first Rancholabrean occurrences of
Palaeolama, Procyon, and Smilodon in northwest Mexico and
the first records of Platygonus compressus and Canis dirus in
Sonora. Equus, Camelops, and Canis are well-represented at
sites across the North American desert region and, although
Platygonus and Lynx are sparsely represented in northern
Mexico, they have extensive records in the southwestern US, mak-
ing them expected at Térapa during the Rancholabrean.

Térapa lies along the Pleistocene Sonora–Central America
Pacific lowlands corridor and the Rocky Mountains–Sierra
Madre Occidental corridor (Ceballos et al., 2010). The former
allowed dispersal of tropical taxa north and the latter permitted
the movement of temperate taxa south (Ceballos et al., 2010).
Additional ‘holding pen’ areas would have been inhabited by
taxa until more preferred environments allowed further migration
(Ceballos et al., 2010; Woodburne, 2010). With the presence of
water and diverse vegetation, Térapa likely acted as an area of fau-
nal exchange. For instance, Palaeolama originated in South
America (Webb, 1974), and researchers postulate that P. mirifica
used tropical corridors along the Sonora–Central America Pacific
lowlands and the Tamaulipas–Central America Gulf lowlands to
move north across Mexico (Bravo-Cuevas and Jiménez-Hidalgo,
2015).

The fauna at Térapa documents a shift in feeding strategy from
a community of primarily herbivores during the late Pleistocene
to one of primarily carnivorous omnivores at present. Ranges of
carnivoran species and the richness of carnivoran communities
have been shown to be affected by climatically driven habitat
changes during the transitions of the glacial and interglacial stages
of the Pleistocene (Arias-Alzate et al., 2017, 2020). In this region
of mosaic complexity and shifting ecosystems, these dynamic
environmental changes may have driven faunal community
change in this area, including the transition to a carnivoran-
dominated community.

Previous studies have documented large declines in commu-
nity average body mass at the transition between the late
Pleistocene and Holocene (Stegner and Holmes, 2013; Smith
et al., 2018). The mammalian fauna presented here indicates a
similar change, with a 97% decline of community average body
mass from 289 kg to 9 kg. The considerable change is due to
the loss of megaherbivores and the reduction in body mass of
the felids present. Average body mass decline has been linked to

rises in global temperature (Gardner et al., 2011; Martin et al.,
2018; Martin and Barboza, 2020) as well as shortages in food
availability (Huston and Wolverton, 2011; McNamara et al.,
2016; Westover and Smith, 2020). Although Térapa provides a
broad scope of temporal change at a single locality (with several
sub-localities therein), it nevertheless captures broad environmen-
tal change as recorded by the reorganization of the terrestrial
fauna.

If antilocaprids, bovids, and cervids had been included in the
study of community structure, the fossil community would add
four artiodactyl species (Capromeryx sp., Stockoceros sp., cf.
Odocoileus, and Bison sp.; Mead et al., 2006) while the modern
community would only add one species (Odocoileus virginianus).
The inclusion of these taxa would only exacerbate the differences
between the faunal communities during the two time periods.
While it is likely additional species lived at Térapa and have not
been recovered, it would require finding 59 additional species of
Carnivora at Térapa to match the proportional community struc-
ture of carnivores and herbivores that is present currently. The
dramatic shift from herbivores to carnivores at Térapa follows a
similar pattern documented across Mexico (Arroyo-Cabrales
et al., 2010; Ferrusquía-Villafranca et al., 2010).

The large mammalian fauna at Térapa aligns with previous
faunal environmental analyses that described an elevational
mosaic of a temperate to tropical/subtropical marsh, an adjacent
semiarid savanna-grassland, a slow-moving freshwater stream,
and a riparian forest area along the water (Mead et al., 2006;
Nunez et al., 2010; Bright et al. 2016). The presence of both
browsing and grazing herbivores implies a diverse assemblage of
trees, forbs, and grasses at Térapa in the past. Currently, there
are no grazing ungulates present at Térapa, and the region lacks
expansive grasslands.

Additionally, the presence of Lynx rufus suggests a more
restrictive paleoenvironmental interpretation and may be indica-
tive of a mosaic-edge habitat associated with the nearby mountain
foothills (∼16 km). Extant L. rufus occupy strictly temperate hab-
itats of savanna/grassland/chaparral but also occupy relatively
large home ranges (3–96 km2 for males and 1–38 km2 for females;
Lariviere and Walton, 1997). The diet of L. rufus includes rodents,
small ungulates, large ground birds, and reptiles (Lariviere and
Walton, 1997), which are all present in the fossil assemblage at
Térapa (Mead et al., 2006).

During the glacial period when the fossils at Térapa were
deposited, cooler global temperatures produced a more con-
stricted Intertropical Convergence Zone (ITCZ) and increased
precipitation in northwestern Mexico (Metcalfe, 2006). As tem-
peratures warmed into the modern interglacial period, the ITCZ
expanded poleward, and shifted the mid-latitude jet stream and
associated precipitation poleward (Metcalfe, 2006). The poleward
shift of the ITCZ and mid-latitude jet stream also shifted the
biodiversity-rich savanna habitats northwards into the southwest-
ern US and as a consequence, left behind the present-day scrub-
land habitats of northern Mexico (Metcalfe, 2006). As
temperatures increased by ∼6°C and precipitation decreased,
Sonora became more arid, and species were forced to shift their
ranges, often northward (Metcalfe, 2006).

With impending climate change and anticipated warming of
an additional 4°C globally by the end of the 21st century, paleo-
ecological studies of past faunas can have great implications for
wildlife conservation because of the associated biodiversity shifts
(Walther et al., 2002; Foley et al., 2005; Lipton et al., 2018). The
Sonoran Desert is expected to continue expanding further

Figure 11. (color online) Feeding strategies of large-bodied mammals at Térapa in
the fossil community (n = 9 species) and the modern community (n = 15 species).

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northwards in Arizona and New Mexico as climate projections
suggest an increasingly arid climate (Magaña et al., 2012). With
shifting environments, species may have to alter their geographic
ranges, but only 41% of natural areas (i.e., areas with low effects of
human modification) in the US are suitably connected to allow
for species movement (McGuire et al., 2016). Conservation efforts
on the margins of species ranges, especially those in or adjacent to
the desert southwest of North America, may also help facilitate
the preservation of unique genetic adaptations to harsh climatic
pressures (Plumb and McMullen, 2018). Sustaining habitats and
their connectivity for conservation may be difficult to facilitate,
but we aim to provide a broad scope of anticipated biodiversity
change in the presence of continued warming.

CONCLUSIONS

Relatively few fossil sites are well known from the Rancholabrean
LMA of northern Mexico (Ceballos et al., 2010; White et al.,
2010), and Térapa provides an extensive faunal record in an area
that was once a marsh savanna but is now xeric desert chaparral.
At this site, we describe mammalian community restructuring
due to the loss of the large-bodied, herbivorous ungulates in
response to environmental change. Whereas the fossil community
was nearly evenly split between carnivorans and herbivorous ungu-
lates, the present community is dominated by carnivorans (Fig. 11).
There is also an associated 97% decrease in mean body mass
through time because of the loss of the largest taxa. We postulate
that this change is largely due to rising temperature and shifting
precipitation regimes and the resulting climatically driven changes
in vegetation, such as the loss of grasslands. As the climate contin-
ues to warm and the deserts shift north, today’s fauna in the south-
western US and northwestern Mexico will be similarly affected.

Long term records of faunal change, such as that at Térapa,
provide valuable information for guiding modern conserva-
tion practices. The presence of eight taxa of Perissodactyla,
Artiodactyla, and Carnivora in a community that existed approx-
imately 40–43 ka (MIS/OIS 3) provides a critical spatial and tem-
poral record, including the first Rancholabrean occurrences of
Palaeolama, Procyon, and Smilodon in northwest Mexico, and
the first records of Platygonus compressus and Canis dirus in
the state of Sonora. It is probable that more sites exist in this
region and can contribute to a more complete understanding of
the area but have yet to be found, fully analyzed, and reported
upon. Future fossil recovery will provide much needed details
about the fauna in and around Térapa and in Sonora, and will
also enable further study of regional habitat and biodiversity shifts
in the southwestern US.

Supplementary material. The supplementary material for this article can
be found at https://doi.org/10.1017/qua.2020.125

Acknowledgments. We are grateful to B. Compton (ETSU Museum of
Natural History) and R. Hulbert (FloridaMuseum of Natural History) for access
to reference specimens. We thankM. Lawing and P. Barboza for providing feed-
back on an earlier draft of this manuscript, S. Holte and E. Doughty for helping
with species identifications, and J. Pigati, associate editor, for constructive edi-
torial contributions during the review process. Field assistance was received
from numerous colleagues and students, more than can be listed here over
the 10 years, but continued help was received from M. Hollenshead, M.C.
Carpenter, J.M. Meyers, C. McCracken, J. Bright, C.J. Czaplewski, G.S.
Morgan, M. Imhof (Madsen), and F. Croxen. We appreciate the discussions
about the Pleistocene of Sonora with J. Arroyo-Cabrales and R.S.
White. F. Tapia Grijalva and E. Villalpando of Instituto Nacional de

Antropología e Historia, INAH Sonora assisted with obtaining excavation and
transportation permits. H. Ruiz Durazo, E.M. Aruna Moore, and family pro-
vided immeasurable logistical help throughout the many years of this ongoing
project. E. Scott and B. McHorse provided equidmetacarpal andmetatarsal data
for quadratic discriminate analyses. Support for RAS came from a Merit
Fellowship and a Tom Slick Graduate Research Fellowship from Texas A&M
College of Agriculture and Life Sciences, and a Dishman-Lucas Graduate
Assistantship from Texas A&M legacy Department of Ecosystem Science and
Management (now the Department of Ecology and Conservation Biology).

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	Paleobiology of a large mammal community from the late Pleistocene of Sonora, Mexico
	INTRODUCTION
	METHODS
	Systematic paleontology
	Community structure

	RESULTS
	Systematic paleontology
	

	
Class MammaliaOrder PerissodactylaFamily EquidaeGenus Equus Linnaeus, 1758Equus scotti Gidley, 1900



	Class MammaliaOrder PerissodactylaFamily EquidaeGenus Equus Linnaeus, 1758Equus scotti Gidley, 1900
	Order ArtiodactylaFamily TayassuidaePlatygonus LeConte, 1848Platygonus compressus LeConte, 1848
	Family CamelidaeCamelops Leidy, 1854Camelops hesternus (Leidy, 1873)
	Palaeolama Gervais, 1867Palaeolama mirifica (Simpson, 1929)
	Order CarnivoraFamily CanidaeCanis Linnaeus, 1758Canis dirus Leidy, 1858
	Family ProcyonidaeProcyon Storr, 1780Procyon lotor (Linnaeus, 1758)
	Family FelidaeLynx Kerr, 1792Lynx rufus (Schreber, 1777)
	Smilodon Lund, 1842Smilodon cf. S. fatalis (Leidy, 1868)
	Community structure

	DISCUSSION
	CONCLUSIONS
	Acknowledgments
	REFERENCES