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Ground squirrels (Rodentia, Sciuridae) of the late Cenozoic Meade Basin sequence: diversity and paleoecological implications

Published online by Cambridge University Press:  15 August 2017

H. Thomas Goodwin
Affiliation:
Department of Biology, Andrews University, Berrien Springs, MI 49104 〈goodwin@andrews.edu〉
Robert A. Martin
Affiliation:
Department of Biology, Murray State University, Murray, KY 42071 〈rmartin@murraystate.edu〉

Abstract

The Meade Basin, SW Kansas, yields a rich vertebrate fossil record from the late Cenozoic. Here, we review fossil ground squirrels (Sciuridae) from the region as a contribution to the broader Meade Basin Rodent Project. We recognize 14 species in seven genera: two species of giant ground squirrels (Paenemarmota Hibbard and Schultz, 1948) from the early Pliocene, and at least 12 species in six extant genera (Ammospermophilus Merriam, 1892; Otospermophilus Brandt, 1844; Ictidomys Allen, 1877; Poliocitellus Howell, 1938; Urocitellus Obolenskij, 1927; Cynomys Rafinesque, 1817) from the Pliocene–Pleistocene sequence, including the first regional records of Ammospermophilus. Based on dental morphology and the ecology of modern congeners, we interpret faunal change through the sequence as primarily reflecting a shift from a Pliocene assemblage of “southwestern” taxa with granivorous/omnivorous diets (relatively low-crowned, transversely narrow cheek teeth) in warm and at least occasionally dry shrub or shrub-steppe habitats (Ammospermophilus, Otospermophilus, Ictidomys meadensis [Hibbard, 1941a]), to a Pleistocene temperate assemblage of grazing taxa that either exhibited relatively high-crowned, transversely wider cheek teeth (Urocitellus, Cynomys, Ictidomys tridecemlineatus [Mitchill, 1821]) or were otherwise dependent on grassland habitats (Poliocitellus). The early Pleistocene Borchers assemblage was transitional in this regard, heralding a “revolution” observed as well with other clades in the Meade Basin rodent community. This interpretation is broadly congruent with evidence of Pliocene climatic change and the staged development of regional grasslands, with the modern proportion of C3/C4 plants established in the Meade Basin during the early Pleistocene.

Type
Articles
Copyright
Copyright © 2017, The Paleontological Society 

Introduction

This paper represents a contribution of the Meade Basin Rodent Project (MBRP), a long-term research program designed to examine the history of rodent diversity on the Central Great Plains. The Meade Basin, a depositional trough running through part of southwestern Kansas and the panhandle of Oklahoma, covers an area of ~50×150 km and includes episodic exposures from the late Miocene to Late Pleistocene (Figs. 1, 2). The primary goal of the MBRP is to create a species-level database from which a number of analyses can be generated, testing a variety of ecological and evolutionary hypotheses. For example, the database has been used to examine patterns of diversity in cotton rats and pocket gophers (Peláez-Campomanes and Martin, Reference Peláez-Campomanes and Martin2005; Martin et al., Reference Martin, Peláez-Campomanes, Honey, Marcolini and Akersten2011) and diversity dynamics of the entire rodent community through the late Neogene and Quaternary (Martin and Peláez-Campomanes, Reference Martin and Peláez-Campomanes2014).

Figure 1 Location of the Meade Basin (gray ellipse).

Figure 2 Stratigraphic relationships of Meade Basin fossil assemblages. MPTS, magnetic polarity time scale; Ma, millions of years ago; C, Chron; r, reversed; n, normal; Br, Brunhes; Ma, Matuyama; Ga, Gauss; Gi, Gilbert; Jar, Jaramillo; Old, Olduvai; Reun, Reunion; Mam, Mammoth; Coch, Cochiti; Nun, Nunivak; Sud, Sidufjall; Thv, Thvera; Crk, Creek; Tol, Toledo; Huck R, Huckleberry Ridge; Gr., gravel; CC, calcium carbonate layer; (N) and (R), Normal and Reversed polarity; Rap, Raptor; C., Canyon; RZ, rodent zones.

While the taxonomy and diversity of most rodent groups in the Meade Basin are reasonably resolved, the taxonomy of Sciuridae (squirrels and allies) has not been reviewed. Prior studies recognized the early Pliocene giant ground squirrel Paenemarmota and an average of two smaller ground squirrels (previously assigned to Spermophilus Cuvier, Reference Cuvier1825) and one prairie dog (Cynomys) of unknown affinities (Martin et al., Reference Martin, Peláez-Campomanes, Honey, Fox, Zakrzewski, Albright, Lindsay, Opdyke and Goodwin2008; Martin and Peláez-Campomanes, Reference Martin and Peláez-Campomanes2014). Here, we review the Sciuridae within the Meade Basin, representing the culmination of a study by the senior author of both newer material collected through the MBRP and material housed at the University of Michigan and University of Kansas collected previously by C.W. Hibbard and his students. A more comprehensive phylogenetic analysis of extinct and extant ground squirrels would be helpful, but was beyond the scope of this analysis, which is primarily concerned with taxonomy of the Meade Basin species. This review recognizes seven genera and possibly 14 species of sciurids in the Meade Basin record. The increase in number of genera reflects both recognition of additional species and application of a revised taxonomy of Spermophilus to existing material. Helgen et al. (Reference Helgen, Cole, Helgen and Wilson2009) divided the paraphyletic Spermophilus into eight presumably monophyletic genera, and we recognize four of these genera from the Meade Basin fossil sequence.

Morphometric comparisons among fossil ground squirrels from the Meade Basin revealed multiple phenetic clusters of tooth size and relative tooth width. In part, these clusters helped to separate and identify species, but they also revealed a pattern of dental morphological change in Ictidomys during the early Pleistocene that mirrors previously reported size shifts in other Meade Basin rodents, such as the cotton rats and pocket gophers (Peláez-Campomanes and Martin, Reference Peláez-Campomanes and Martin2005; Martin, Reference Martin2016). Consequently, in addition to providing basic taxonomic descriptions of the Meade Basin sciurid remains, we present some graphic comparisons suggesting that the Huckleberry Ridge ash-fall may have played a part in dental structural and size change within Ictidomys.

Materials and methods

Diagnostic dental specimens were digitally photographed in occlusal view (and usually in other views) along with a scale through a Leica MZ8 stereoscope (Leica Microsystems, Inc., Bannockburn, Illinois). Dental photographs were organized in a FileMaker Pro database (http:://www.Filemaker.com), along with associated taxonomic and locality data. Specimens examined for this study are listed in the appendix (provided as Supplemental Data 1).

Digital photographs were output from the FileMaker database, calibrated to the scale, and measured digitally using GraphicConverter (https://www.lemkesoft.de/en/products/graphicconverter/) to obtain the following variables: greatest mesiodistal length of upper and lower cheek teeth; tooth width from the lingual margin of the protocone to buccal margin of the paracone on P3–M3; and tooth width across the trigonid on p4–m3, and likewise across the talonid on p4 (Fig. 3). Relative trigonid width of p4 was calculated as trigonid width/length of p4. Metric data were employed to graphically and statistically explore taxonomic and stratigraphic patterns in dental size and shape. All statistical analyses and graphing were done with SPSS (http://www-01.ibm.com/software/analytics/spss/).

Figure 3 Measured dimensions, and orientation and dental terminology for (1) lower (FHSM VP-18159; left p4 of I. tridecemlineatus from Cudahy) and (2) upper teeth (UMMP 42319C; left M1 or M2 of P. franklinii from Cudahy). Scale bars=1 mm Abbreviations: ac=anterior cingulum, buc=buccal, dis=distal, hpcd=hypoconid, L=length, lin=lingual, mes=mesial, mst=mesostyle, mtc=metacone, mtcd=metaconid, mtcl=metaconule, mtl=metaloph, mtld=metalophid, pc=posterior cingulum, prc=paracone, ptc=protocone, ptcd=protoconid, ptl=protoloph, ptld=protolophid, TlW=width across the talonid, TrW=width across the trigonid, W=width at paracone.

Digital photographs were also used in detailed qualitative comparisons within and across putative taxa, across sites, and with relevant modern taxa using a companion photographic database of modern ground squirrels described elsewhere (Goodwin, Reference Goodwin2009). Genus and species assignments were informed by both quantitative and qualitative comparisons; descriptions in the text employ standard dental terminology (Fig. 3). We followed the taxonomy of Helgen et al. (Reference Helgen, Cole, Helgen and Wilson2009) when assigning fossil species to genera.

The way that paleontologists recognize and describe species in the fossil record strongly affects subsequent diversity analyses. Our perspective since beginning the MBRP was to make the database as biologically realistic as possible. Consequently, we do not accept anagenesis, the phyletic origin of new species. New species are recognized only as the result of cladogenesis, or lineage-splitting. The criteria for recognizing cladogenesis in the Meade Basin were delimited by Martin and Peláez-Campomanes (Reference Martin and Peláez-Campomanes2014), and no intra-basin speciation events have been recognized to this point, though the origin of the diminutive gopher Geomys tyrioni Martin, Reference Martin2016 was likely induced by the Huckleberry Ridge ash-fall on the Central Great Plains (Martin, Reference Martin2016).

During the previous generation of work in the Meade Basin, C.W. Hibbard and his students attempted to fit their fossil localities in Meade, Seward, and Clark counties into a common stratigraphic framework by allocating geographically isolated sites to the same “formations” based on faunal content rather than lithology. For example, the Kingsdown Formation, originally named for late Pleistocene sediments in Clark County, was extended by Hibbard and Taylor (Reference Hibbard and Taylor1960) to the Big Springs Ranch in Meade County to include the Cragin Quarry vertebrate assemblage. Schultz (Reference Schultz1969) continued this approach, applying the name Cragin Quarry to one of four superposed Late Pleistocene faunal levels that he recognized farther south in Meade County on the XI Ranch. Our current perspective is that it is very difficult to correlate the many isolated Late Pleistocene depositional environments, and we pursue a more cautious interpretation. Primarily through the careful field-mapping program directed by the late J. Honey, we have been able to determine the stratigraphic position of most of Hibbard’s fossil assemblages, but we have refrained from using many of Hibbard’s geologic names and marker units (e.g., the Angel gravel) or extending formational names beyond the sediments in which they were initially described (Martin et al., Reference Martin, Honey and Peláez-Campomanes2000). Late Pleistocene sediments on the Big Springs Ranch containing the Cragin Quarry assemblage cannot be securely correlated in time with sediments on the XI Ranch, with the latter apparently representing localized sinkhole and collapse features (Kapp, Reference Kapp1965). Because the name Cragin Quarry in both places has led to considerable confusion regarding faunal composition and could potentially create mistaken conclusions regarding faunal turnover, we here name the Kapp horizon for the Cragin Quarry level of Schultz (Reference Schultz1969) on the XI Ranch, in honor of Ronald O. Kapp’s (Reference Kapp1965) detailed fossil pollen analyses on both the Big Springs and XI ranches.

Localities from which rodent assemblages were collected within the Meade Basin system are shown in Fig. 2. Because rodent assemblages were collected from a limited vertical horizon (<1.0 m) at each locality noted in Figure 2, the name of the locality and the assemblage derived from it are here used synonymously. A few Neogene assemblages including sciurid remains listed in Table 1 do not appear in Figure 2, either because rodents were poorly represented or their stratigraphic positions were not precisely determined. None of the late Pleistocene assemblages (from Adams through Robert) in Table 1 is shown in Figure 2, but their temporal placement can be found in Martin and Peláez-Campomanes (Reference Martin and Peláez-Campomanes2014). We follow the International Commission on Stratigraphy 2015 International Chronostratigraphic Chart and consider the base of the Pleistocene at 2.58 Ma. The early Pleistocene ranges from 2.58–0.78 Ma (million years ago), Middle Pleistocene from 0.78–0.13 Ma, and Late Pleistocene from 0.13–0.01 Ma.

Table 1 Sciurid species recovered from selected assemblages in the Meade Basin, Kansas. Assemblage abbreviations listed in approximate stratigraphic sequence from oldest (left) to youngest (right): HB=High Banks; SRC=Saw Rock Canyon; FC=Fox Canyon; RipB=Ripley B; XIT1B=XIT 1B; Rap1C=Raptor 1C; WnsB–D=Wiens B, C, D; Vas=Vasquez; Nwt=Newt; Hor=Hornet; R3A-C=Rexroad 3A-C; Wb=Wheelbarrow; WFP=Wendell Fox Pasture; R2A=Rexroad Loc. 2A; R2=Rexroad Loc. 2; DP=Deer Park A; HD=Hart Draw; Pal=Paloma; Mar=Margaret; Bor=Borchers; SH=Short Haul; ArA=Aries A; ArNE=Aries northeast; RF=Rick Forester; Na72=Nash 72; Cud=Cudahy; Sun=Sunbrite; RR=Robin’s Roost; AD=Adams; BS=Butler Spring; MS=Mt. Scott; Kapp=Kapp Horizon; CQ=Cragin Quarry; Jin=Jinglebob; Jon=Jones; Tay=Taylor; GolB, C=Golliher B-C; Rob=Robert; Mod=Modern. *=exact stratigraphic placement uncertain.

Fossils referred to each of the following species are listed in the appendix (provided as Supplemental Data 1), organized alphabetically by genus and species, stratigraphically by age (early and late Pliocene; early, Middle, and Late Pleistocene), alphabetically by locality within age category, by element (skulls, maxillae, upper cheek teeth, dentaries, lower cheek teeth), then alphanumerically by museum acronym and catalog number.

Repositories and institutional abbreviations

One of us (HTG) inspected sciurid fossils (skulls, jaws, maxillae with teeth; most isolated teeth; N>1,000) from the Meade Basin in the vertebrate fossil collections of the University of Kansas (KUVP) and University of Michigan Museum of Paleontology (UMMP), as well as more recent collections made during the MBRP and curated by the Fort Hayes State Museum (FHSM).

Systematic paleontology

Family Sciuridae Fischer de Waldheim, Reference Fischer de Waldheim1817

Tribe Marmotini Pocock, Reference Pocock1923

Genus Ammospermophilus Merriam, Reference Merriam1892

Ammospermophilus sp.

Figure 4.1

Figure 4 Lower cheek teeth (p4, m1 or m2) of Meade Basin ground squirrels. Scale bar=1 mm. To facilitate comparisons, all are displayed as left specimens (reversed right teeth are indicated). (1–3) Lower m1 or m2 of (1) Ammospermophilus sp. from Wiens B (FHSM VP-18438; R reversed), (2) extant A. interpres from Dona Ana Co., NM (KUVP 131708; m1), and (3) Ictidomys meadensis from Rexroad 3 (UMMP 35057). (4–9) Lower p4s of (4) I. meadensis from Rexroad 3C (FHSM VP-18365; R reversed), (5) I. meadensis from Borchers (KUVP 156258), (6) Poliocitellus franklinii from Cudahy (UMMP 36796; R reversed), (7) Otospermophilus rexroadensis from Rexroad 3B (FHSM VP-18348), (8) Urocitellus? cragini from Borchers (UMMP 50136), and (9) Cynomys? sp. from Sunbrite (KUVP 6704; R reversed).

Remarks

Ammospermophilus today incorporates four or five extant species of antelope squirrels (Hall, Reference Hall1981; Alvarez-Castaneda, Reference Alvarez-Castaneda2007) of the southwestern deserts, with the closest approach to the Meade Basin being populations of Texas antelope squirrels (Ammospermophilus interpres [Merriam, Reference Merriam1890]), ~600 km to the WSW in central New Mexico (Hall, Reference Hall1981). Early Pliocene fossils from XIT 1B and Wiens B are assigned to Ammospermophilus based on small size (all teeth; Table 2) and, for m1 or m2, narrow transverse width and well-developed metalophid (Fig. 4.1) that resemble some individuals of extant Ammospermophilus (Fig. 4.2), but differ sharply from Pliocene Ictidomys meadensis in tooth size and proportions (Fig. 4.3). Ammospermophilus has not previously been recognized in the Meade Basin, and its presence implies at least a brief episode of increased early Pliocene aridity.

Table 2 Measurements of p4 and P4 (in mm) in composite stratigraphic samples used for statistical analysis. L=length, W=width. Cell values represent mean (standard deviation) n. See Table 1 for assemblage abbreviations.

Three specimens from the late Pliocene (Rexroad 2, 2A, Wendell Fox Pasture) may represent additional records of Ammospermophilus. The dp4 from Rexroad 2 differs from fossil and extant Ictidomys, but resembles Ammospermophilus in very small size, transversely narrow trigonid, and closely adjacent protoconid and metaconid. P4s from Rexroad 2A and Wendell Fox Pasture are much smaller than in coeval I. meadensis (Table 2; Fig. 5.2) and have a reduced anterior cingulum, in both features resembling Ammospermophilus, but exhibit a more developed connection between the metaloph and protocone than is typical for the genus. We tentatively assign both specimens to Ammospermophilus.

Figure 5 Stratigraphic variation in (1) lengths of p4 and (2) P4 of fossils from the Meade Basin, excluding Paenemarmota (log10-scale for tooth lengths). Envelopes of size variation in Ictidomys and Otospermophilus given by dotted lines. (3) Stratigraphic variation in relative width of p4 (trigonid width/length). Dashed vertical line represents equivalence of trigonid width and tooth length. Dark horizontal line in all panels represents the Pliocene-Pleistocene boundary. Representative localities indicated in (2); locality abbreviations defined in Table 1.

Genus Otospermophilus Brandt, Reference Brandt1844

Otospermophilus rexroadensis (Hibbard, Reference Hibbard1941c)

Figure 4.7

1941c Citellus rexroadensis Reference HibbardHibbard, p. 348, fig. 7.

1961 Citellus (Otospermophilus) rexroadensis Reference HazardHazard, p. 477, figs. 1, 2.

1980 Spermophilus rexroadensis Reference Kurtén and AndersonKurtén and Anderson, p. 213.

Holotype

KUVP 4608, left dentary with I, p4–m3 from Rexroad Loc. 3, Meade Co., KS (Hibbard, Reference Hibbard1941c, fig. 7).

Remarks

Assignment to Otospermophilus is supported by multiple characters, including moderately large size (Fig. 5.1, 5.2), low relative trigonid width of p4 (Figs. 5.3, 6.1), low tooth crown height, and incomplete metaloph on M1 and M2 (constricted at contact with the base of the protocone). Otospermophilus rexroadensis (Hibbard, Reference Hibbard1941c) from the type locality (Rexroad Loc. 3; Hibbard, Reference Hibbard1941c) and other late Pliocene localities display significantly larger teeth (and presumably body mass) than fossils from Fox Canyon and other early Pliocene localities (Table 2; length of p4: t=2.93, df=20, p<0.01; length of P4: t=6.26, df=20, p<0.001), a difference previously noted by Hazard (Reference Hazard1961) that we attribute to phyletic evolution.

Figure 6 (1) Scatter plot of relative trigonid width of p4 (trigonid width/tooth length) versus p4 length (log10 scale) for all Meade Basin fossils of p4 that can be identified to genus. Genera marked with different symbols; stratigraphic samples distinguished for Ictidomys and Urocitellus. (2) Scatter plot of trigonid width versus tooth length (log10 scale for both) of the m3 for fossils of Poliocitellus franklinii, and Urocitellus cf. U. richardsonii, and for comparative extant species (P. franklinii, U. elegans, and U. richardsonii). One fossil outside the Meade Basin (holotype of P. lorisrusselli; UMMP 61136) is plotted and labelled. Fossils from Borchers and Cudahy are indicated.

Otospermophilus spp.

Remarks

Both Saw Rock Canyon and Fox Canyon include O. rexroadensis and probably a second, larger species of Otospermophilus (UMMP 117762, P4, from Saw Rock Canyon in Fig. 5.2) that we cannot presently identify to species. Otospermophilus was not observed in early Pleistocene or the Middle Pleistocene Cudahy assemblages, but a single p4 from the Adams local fauna (UMMP 34735; Fig. 5.1) is clearly assignable to the genus. We are unable to confidently assign this tooth to species, but it plausibly represents a temporary northeastern range expansion of the extant rock squirrel, Otospermophilus variegatus (Erxleben, Reference Erxleben1777), a species that ranges today from northern Utah to southern Mexico and from far southeastern California to the panhandle of Oklahoma, ~60 km SW of Meade County (Helgen et al., Reference Helgen, Cole, Helgen and Wilson2009).

Genus Ictidomys Allen, Reference Allen1877

Ictidomys meadensis (Hibbard, Reference Hibbard1941a)

Figures 4.3–4.5, 7.1

Figure 7 Upper M3 fossils, all displayed as right (indicated if reversed). Scale bar=1 mm. (1) I. meadensis from Borchers (FHSM VP-18122; L reversed). Abrupt deflection of posterior cingulum(arrow) distal to short ridge coursing buccodistally from protocone (dotted line) noted in text. (2) I. tridecemlineatus from Short Haul (FHSM VP-18902; L reversed). (3) P. franklinii from Sunbrite (UMMP 39596). (4) Urocitellus cf. U. richardsonii from Adams (UMMP 34705; L reversed). (5) Cynomys hibbardi from Rick Forrester (FHSM VP-14104).

1941a Citellus meadensis Reference HibbardHibbard, p. 203, Plate 1, figs. 2, 7.

1941c Citellus howelli Reference HibbardHibbard, p. 347, fig. 6.

1980 Spermophilus howelli Reference Kurtén and AndersonKurtén and Anderson, p. 212.

1980 Spermophilus meadensis Reference Kurtén and AndersonKurtén and Anderson, p. 214.

Holotype

KUVP 6169, right dentary with p4–m2 from Borchers, Meade Co., KS (Hibbard, Reference Hibbard1941a, pl. 1, fig. 2). Paratype KUVP 6119, left maxillary fragment with P4–M2 (Hibbard, Reference Hibbard1941a, pl. 1, fig. 7).

Remarks

Hibbard described two small-sized ground squirrels from the Meade Basin sequence in the same year: Citellus meadensis Hibbard, Reference Hibbard1941a from the early Pleistocene Borchers locality and Citellus howelli Hibbard, Reference Hibbard1941c from the late Pliocene Rexroad Locality 3 (Hibbard, Reference Hibbard1941a, Reference Hibbard1941c). We assign both to the genus Ictidomys (Citellus is no longer regarded as a valid name).

Hibbard distinguished Ictidomys meadensis from the Pliocene Ictidomys howelli by its lesser molar tooth width, better developed trigonid pit, and more pronounced metalophid that reaches to the base of the metaconid on lower molars (Hibbard, Reference Hibbard1941b). However, we observed that the trigonid pit was variably developed in both species, and average width of m1 or m2 did not differ significantly between late Pliocene I. howelli (2.3 mm, sd=0.14, N=21) and I. meadensis (2.4 mm, sd=0.14, N=24; t=−1.61, p=0.998).

The Borchers and Margaret specimens of small ground squirrels (early Pleistocene) differ significantly from the combined Pliocene Ictidomys sample in frequencies of two attributes. First, ~60% of measured M3s from Borchers (10 of 17) display a ridge coursing buccodistally from the protocone (dashed line in Fig. 7.1) that does not merge with the margin of the posterior cingulum, with the contact between this ridge and the posterior cingulum typically marked by a distinct notch or groove (arrow in Fig. 7.1). This feature was not observed on Pliocene M3s (0 of 22; χ2=17.40, df=1, p<0.001). Second, only 30% of Borchers and Margaret M1s or M2s (7/23) display a mesostyle, compared to 60% of Pliocene M1s and M2s (14/23; χ2=4.29, df=1, p<0.05). We did not observe other consistent morphological differences that separated the Pliocene and early Pleistocene Borchers samples.

Graphic plots of tooth size and relative trigonid width of p4 across early Pliocene, late Pliocene, and early Pleistocene Borchers samples of Ictidomys suggest overall stasis in these attributes through this interval (Fig. 5; key faunas in each stratigraphic sample are indicated in Fig. 5.2). Statistical comparisons across stratigraphic samples (one-way ANOVAs) confirm stasis in length of P4 (F=1.61, df=2, 39, p>0.05) and relative width of p4 (F=2.06, df=2, 35, p>0.05), but reject stasis in length of p4 (F=4.28, df=2, 39, p<0.05), with significant difference being a size reduction between the early Pliocene and Borchers samples (Tukey’s HSD, p<0.05). There are no differences in these variables between the late Pliocene sample (which includes the type locality of S. howelli, Rexroad Loc. 3) and Borchers (the type locality of S. meadensis). We conclude that it is most parsimonious to infer a single, long-lived, small-sized ground squirrel species in the Meade Basin during the Pliocene and early Pleistocene (as represented at Borchers). Thus, we interpret changes in character frequency and subtle quantitative change in length of p4 as phyletic change within this lineage.

We assign the Meade Basin squirrel material described in this section to the genus Ictidomys, but this assignment is complicated by conservative and similar dental morphology of Ictidomys and Xerospermophilus (Merriam, Reference Merriam1892), both of which occur in the Meade Basin today (the thirteen-lined ground squirrel, Ictidomys tridecemlineatus, and spotted ground squirrel, Xerospermophilus spilosoma [Bennett, Reference Bennett1833]; Helgen et al., Reference Helgen, Cole, Helgen and Wilson2009). Cheek teeth of Xerospermophilus tend to be relatively narrow (Goodwin, Reference Goodwin2009), and the hypoconid of p4 tends to be more rounded and less elongate buccally than in I. tridecemlineatus, but there is overlap in both features. In addition, the M1s–M2s of extant Xerospermophilus usually lack a mesostyle (present in one of 50 teeth observed in extant species of Xerospermophilus), a feature more commonly observed in extant species of Ictidomys (15 of 46 teeth observed). Unfortunately, fossils assigned to I. meadensis typically display narrow cheek teeth and a more rounded hypoconid on p4 (Fig. 4.4, 4.5) as in Xerospermophilus, but also may exhibit a mesostyle on M1–M2 (7 of 23), as in Ictidomys. Better material may clarify assignment of the fossils, but for now we assign the material to Ictidomys.

Ictidomys tridecemlineatus (Mitchill, Reference Mitchill1821)

Figures 3.1, 7.2

1821 Sciurus tridecem-lineatus Reference MitchillMitchill, p. 248 [For listing of synonyms in the literature of modern Ictidomys tridecemlineatus, see Streubel and Fitzgerald, Reference Streubel and Fitzgerald1978b, p. 1].

Holotype

Not designated. Type locality fixed as “Central Minnesota” by Allen (Reference Allen1895, p. 338).

Remarks

During the early Pleistocene, an abrupt and significant reduction in tooth size between Borchers I. meadensis and slightly younger fossils of Ictidomys from the Borchers Badlands (length of p4: t=−6.90, df=30, p<0.001; length of P4: t=−9.89, df=30, p<0.001; Fig. 5.1, 5.2) was accompanied by increase in relative trigonid width of p4 (t=2.88, df=28, p<0.01; Fig. 5.3) and decrease in frequency of the mesostyle on M1–M2 (from 30% [7 of 23] to 8% [2 of 26]). These simultaneous changes in tooth size, relative width, and mesostyle frequency indicate the appearance of a new species in the Meade Basin, which we identify as Ictidomys tridecemlineatus based on size and dental proportions, although extant I. tridecemlineatus more frequently exhibits a mesostyle on M1–M2 (~33%). Early Pleistocene I. tridecemlineatus usually displays a relatively elongate M3, and never displays the discontinuity between the ridge extending posterodistally from the protocone and the posterior cingulum described previously for I. meadensis from Borchers (compare Fig. 7.2 with Fig. 7.1).

We interpret the combination of abrupt change in size, shape, and qualitative characters as indicating immigration rather than in situ phyletic evolution. The abrupt size reduction in local Ictidomys immediately post-Borchers mirrors the appearance of the dwarf pocket gopher Geomys tyrioni at Short Haul (Martin, Reference Martin2016), and may reflect dramatic restructuring of regional communities after the massive Huckleberry Ridge ash-fall (Martin and Peláez-Campomanes, Reference Martin and Peláez-Campomanes2014).

Pleistocene I. tridecemlineatus from the Meade Basin varies temporally in size (Fig. 5.1, 5.2), significantly so for length of p4 (F=13.72, df=2, 17, p<0.001), but not length of P4 (F=2.02, df=2, 21). There was no significant stratigraphic variation in relative p4 trigonid width (Fig. 5.3; F=0.31, df=2, 14). In length of p4, both early and Late Pleistocene were significantly smaller than Middle Pleistocene fossils from Cudahy and Sunbrite (Tukey HSD, p<0.001).

Genus Poliocitellus Howell, Reference Howell1938

Poliocitellus franklinii (Sabine, Reference Sabine1822)

Figures 3.2, 4.6, 7.3

1822 Arctomys franklinii Reference SabineSabine, p. 587 [For listing of synonyms in the literature of modern Poliocitellus franklinii, see Ostroff and Finck, Reference Ostroff and Finck2003, p. 1].

1976 Spermophilus lorisrusselli, Reference HibbardHibbard, p. 282, fig. 2.

Holotype

Not specified; type locality restricted to Carlton House, Saskatchewan, Canada by Preble (Reference Preble1908, p. 165).

Remarks

Poliocitellus franklinii (Sabine, Reference Sabine1822) is an extant occupant of tall-grass prairies of the northern and central Great Plains that does not occur in the Meade Basin today, with closest populations ~200 km to the NNE (Ostroff and Finck, Reference Ostroff and Finck2003). It is the sole extant member of its genus. Hibbard (Reference Hibbard1976) described Poliocitellus lorisrusselli (Hibbard, Reference Hibbard1976) from the Cudahy-equivalent Wilson Valley local assemblage of NE Kansas, which he characterized as smaller than but otherwise similar in dental morphology to extant P. franklinii.

Multiple fossils from the Meade Basin can be assigned to Poliocitellus. These fossils differ from I. tridecemlineatus in larger size (Fig. 5.1, 5.2) and the presence of a pronounced protolophid on p4 (Fig. 4.6, compare with Fig. 3.1). They differ from coeval Urocitellus cf. U. richardsonii (Sabine, Reference Sabine1822) in much less relative trigonid width on p4 (Fig. 5.3), and relatively less-elongate M3 (Fig. 7.3) and m3 (Fig. 8.1) that lack the defined metaloph and talonid basin trench, respectively, of Urocitellus (Figs. 7.4, 8.2).

Figure 8 Lower right m3 fossils of (1) P. franklinii (UMMP 117771) and (2) Urocitellus cf. U. richardsonii (UMMP 117732), both from Cudahy, and (3.1, 3.2) of C. hibbardi from Nash (FHSM VP-18209). (3.2) represents an oblique, occlusodistal view of the trigonid. Attributes noted in text are labelled; lam=lingual arm of metapholophid; ctp=closure of trigonid pit. Scale bar=1 mm.

Middle Pleistocene m3s from Cudahy plot with the holotype of P. lorisrusselli and are smaller than extant P. franklinii (Fig. 6.2), but some later p4s were larger (Fig. 5.1). In addition, Eshelman and Hibbard (Reference Eshelman and Hibbard1981) tentatively identified P. franklinii in the early Pleistocene Nash 72 assemblage, explicitly noting that the teeth were larger than in P. lorisrusselli. We provisionally accept their interpretation based on published measurements, but do so with question because we were not able to inspect the specimens.

We conclude that the Meade Basin supported a single, size-variable lineage of Poliocitellus from the Middle (and perhaps early) to Late Pleistocene, with P. lorisrusselli representing an episode of reduced size. We assign all specimens to P. franklinii, which has priority.

Genus Urocitellus Obolenskij, Reference Obolenskij1927

Urocitellus? cragini (Hibbard, Reference Hibbard1941a)

Figure 4.8

1941a Citellus cragini Reference HibbardHibbard, p. 204, pl. 1, fig. 13.

1980 Spermophilus cragini Reference Kurtén and AndersonKurtén and Anderson, p. 214.

1994 Spermophilus? cragini Reference Goodwin and HayesGoodwin and Hayes, p. 283, fig. 3.

Holotype

KUVP 6168, right maxilla with M1–M3 from Borchers, Meade Co., KS (Hibbard, Reference Hibbard1941a, pl. 1, fig. 13).

Remarks

Urocitellus? cragini (Hibbard, Reference Hibbard1941a) represents a large ground squirrel initially described solely on the holotype (Hibbard, Reference Hibbard1941a) and subsequently described more fully and formally assigned to the derived subgenus Spermophilus (genus Urocitellus after Helgen et al., Reference Helgen, Cole, Helgen and Wilson2009) based on a larger sample (Goodwin and Hayes, Reference Goodwin and Hayes1994). It has only been reported from the type locality. The questioned assignment to Urocitellus? follows Goodwin and Hayes (Reference Goodwin and Hayes1994), because U.? cragini could represent a small, dentally underived prairie dog (see below). It represents the first occurrence of a ground squirrel with proportionally wide p4 in the Meade Basin record (Fig. 5.3), a morphology shared by Urocitellus and Cynomys (Goodwin, Reference Goodwin2009).

Urocitellus? cragini differs from all extant species of Urocitellus in the presence of a complete protolophid on most p4s (Fig. 4.8), a feature characteristic of Cynomys; but it differs from all Cynomys in the absence of a well-developed lophulid on the talonid of m1–m2, presence of an incomplete metalophid on m3, more circular P3, and less-elongate M3 and m3, all features of Urocitellus (Goodwin and Hayes, Reference Goodwin and Hayes1994). Urocitellus? cragini was a large squirrel (Table 2, Fig. 4.8) that was much larger than middle Pleistocene and later species assigned to the genus (Table 2, Figs. 5.1, 5.2, 6.1). Its dentition resembles that of the extant Arctic ground squirrel, Urocitellus parryii (Richardson, Reference Richardson1825) in p4 and P4 length, but exhibits much wider teeth (Goodwin and Hayes, Reference Goodwin and Hayes1994, fig. 1).

Urocitellus cf. U. richardsonii (Sabine, Reference Sabine1822)

Figures 7.4, 8.2

1822 Arctomys richardsonii Reference SabineSabine, p. 589 [For listing of synonyms in the literature of modern Urocitellus richardsonii, see Michener and Koeppl, Reference Michener and Koeppl1985, p. 1].

1967 Citellus kimballensis Reference KentKent, p. 18, figs. 1–3.

Holotype

Holotype not designated. Type locality Carlton House, Saskatchewan, Canada.

Remarks

Fossils assigned to Urocitellus cf. U. richardsonii are smaller than fossils of U.? cragini and exhibit much greater trigonid width of p4 than in Otospermophilus, Ictidomys, and Poliocitellus (Fig. 6.1). The M3 usually displays a prominent metaloph (Fig 7.4), and m3 characteristically exhibits a distinct talonid basin trench adjacent to the ectolophid (Fig 8.2), in both cases resembling Cynomys (Figs. 7.5, 8.3.1). Morphometrically, many fossil m3s fall within the envelope of variation defined by the extant sister species U. richardsonii and Urocitellus elegans (Kennicott, Reference Kennicott1863), although Cudahy teeth are distinctly smaller than teeth from earlier and later assemblages (Fig. 6.2).

There is considerable dental morphological overlap between extant U. richardsonii and U. elegans (Goodwin, Reference Goodwin2002). Urocitellus elegans inhabits open habitats in the central Rocky Mountains and northern Basin and Range (Zegers, Reference Zegers1984), and was present at high elevations in central Colorado (Porcupine Cave) during the Middle Pleistocene (Goodwin, Reference Goodwin2002). In contrast, U. richardsonii is an occupant of the northern Great Plains with closest extant populations ~775 km to the NNE in SE South Dakota (Michener and Koeppl, Reference Michener and Koeppl1985). We tentatively refer the Meade Basin fossil Urocitellus to Urocitellus cf. U. richardsonii on geographic grounds because a number of other northern Great Plains rodent species dispersed southward into the Meade Basin, rather than directly eastward from the Rocky Mountains, at various points during the Pleistocene.

Urocitellus sp.

Remarks

Goodwin and Hayes (Reference Goodwin and Hayes1994) tentatively recognized an additional species of Urocitellus from Borchers, which they labeled “morph A.” Assignment to Urocitellus is supported by the large P3 relative to P4 (Goodwin and Hayes, Reference Goodwin and Hayes1994, figs. 4A, 4B). Fossils assigned to “morph A” are smaller than U.? cragini and larger than Urocitellus cf. U. richardsonii, and they differ from both of these species in the presence of a swollen metaconule on M3 that is constricted at its contact with the protocone (Goodwin and Hayes, Reference Goodwin and Hayes1994, fig. 4C). In addition to fossils from Borchers, a somewhat corroded M3 from Margaret (FHSM VP-18908) probably represents “morph A,” bearing remnants of a swollen metaconule and resembling “morph A” in size.

Genus Cynomys Rafinesque, Reference Rafinesque1817

Cynomys hibbardi Eshelman, Reference Eshelman1975

Figures 7.5, 8.3.1, 8.3.2

1975 Cynomys hibbardi Reference EshelmanEshelman, p. 27, figs. 4A, 4B.

1995b Cynomys sappaensis Reference GoodwinGoodwin, p. 16, figs. 2E, 3B, 4B, 4E, 4F.

Holotype

UMMP 61648, left lower jaw with m1–m3 from locality UM-K9-72 “in the silty clay lithosome, approximately 2.2 m below the contact with the sand lithosome, Belleville Formation, SE¼, SE¼, SW¼, Sec. 34, T.1S, R.5W, Republic County, Kansas” (Eshelman, Reference Eshelman1975, p. 27).

Remarks

Eshelman and Hibbard (Reference Eshelman and Hibbard1981) tentatively referred two lower molars from Nash 72 to Cynomys meadensis Hibbard, Reference Hibbard1956, a species described from the Deer Park locality (Hibbard, Reference Hibbard1956), but recognized by Goodwin (Reference Goodwin1995b) as intrusive Cynomys ludovicianus (Ord, Reference Ord1815). The Nash 72 prairie dog fossils were subsequently assigned to Cynomys hibbardi Eshelman, Reference Eshelman1975 (Goodwin, Reference Goodwin1995b), a species described from the late Pliocene White Rock local fauna of northern Kansas (Eshelman, Reference Eshelman1975). A few sciurid teeth from Rick Forester represent the same taxon; a P3 with corroded enamel and fragmentary p4 from Short Haul may likewise represent a small Cynomys.

Three isolated M3s provide the first documentation of M3 morphology for C. hibbardi (Fig. 7.5). A prominent metaloph is present, and the tooth is strongly elongate posteriorly. One specimen (FHSM VP-14104) displays a short distally directed lophule connecting the lingual end of the metaloph with the posterior cingulum (Fig. 7.5).

Goodwin (Reference Goodwin1995b) also described Cynomys sappaensis Goodwin, 1995 from the early Pleistocene Sappa assemblage of Nebraska, which he distinguished from C. hibbardi by greater hypsodonty (described qualitatively, but not measured) and greater development of metalophids on lower molars. Both hypsodonty and metalophid development are temporally gradational in Cynomys, with greatest development in Late Pleistocene and Recent species (Goodwin, Reference Goodwin1995b). However, we now consider C. sappaensis as a younger segment of the C. hibbardi lineage. These two species are similar in size (Goodwin, Reference Goodwin1995b, table 4), display a deeply notched metalophid on m1 and m2, and exhibit a similar m3 trigonid morphology. The trigonid pit is closed by a mesially directed lophid about one-half of the way between the protoconid and metaconid (Fig. 8.3.1), and the pit is separated from the lingual arm of the metalophid (Fig. 8.3.2). The latter feature is well developed on m3 fossils from Nash 72 and Rick Forester, but is absent from later prairie dog m3s.

Cynomys hibbardi resembles U. cragini in size (Fig. 5.1), but differs from it in multiple features, including configuration of the trigonid on m3 and development of the metaloph on M3, described above.

Cynomys ludovicianus (Ord, Reference Ord1815)

1815 Arctomys ludoviciana Reference OrdOrd, p. 292 [For listing of synonyms in the literature of modern C. ludovicianus, see Hall Reference Hall1981, p. 411, 412].

1956 Cynomys meadensis Reference HibbardHibbard, p. 172.

1995b Cynomys spenceri Reference GoodwinGoodwin, p. 18, fig. 9.

Holotype

Holotype not designated. Type locality not specified.

Remarks

Two fossils from Butler Springs are assigned to C. ludovicianus (an extant black-tailed prairie dog [subgenus Cynomys]), based on conformation of the p4 (relatively narrow trigonid width) and m3 (mesially deflected hypoconid, absence of a bridge interrupting the talonid trench; Goodwin, Reference Goodwin1995b). Cynomys ludovicianus is present in the Meade Basin today.

The Butler Springs black-tailed prairie dog was previously identified as Cynomys spenceri Goodwin, Reference Goodwin1995b, Reference Goodwina species erected for the early segment (late Middle and early Late Pleistocene) of the C. ludovicianus lineage, diagnosed only by smaller average size (Goodwin, Reference Goodwin1995b). Here, we consider C. spenceri part of the C. ludovicianus lineage.

Cynomys niobrarius Hay, Reference Hay1921

1921 Cynomys niobrarius Reference HayHay, p. 615, pl. 122, fig. 7.

1960 Cynomys spispiza Reference GreenGreen, p. 545, figs. 1, 5.

1989 Cynomys churcherii Reference Burns and McGillivrayBurns and McGillivray, p. 2637.

Holotype

AMNH 2715, partial skull. Type locality given only as “Niobrara River, near Grayson, Nebraska” and formation as “Sheridan beds of the Pleistocene” (Hay, Reference Hay1921, p. 615).

Remarks

Cynomys niobrarius Hay, Reference Hay1921 is a white-tailed prairie dog (subgenus Leucocrossuromys Hollister, Reference Hollister1916) that occupied the northern and central Great Plains during the late Middle and Late Pleistocene, co-occurring with C. ludovicianus at multiple sites on the central Plains (Goodwin, Reference Goodwin1995a). It is known from the Kapp horizon of the XI Ranch sequence in the Meade Basin (Table 1). Cynomys niobrarius can be distinguished from C. ludovicianus by greater relative trigonid width of p4, and m3 with less mesially deflected hypoconid and a well-developed bridge connecting the talonid platform and ectolophid and interrupting the talonid trench (Goodwin, Reference Goodwin1995b).

Cynomys sp.

Remarks

Two well-preserved fossils (lower jaws with most teeth) from Robin’s Roost, Beaver Co., OK (approximately time-equivalent with Cudahy) document the presence of a large prairie dog in the Meade Basin south of the Cimarron River. The m3s are similar to those of C. niobrarius based on presence of a bridge between the ectolophid and talonid on m3, but the p4s also display a relatively narrower trigonid than expected for white-tailed prairie dogs. The specimens are currently under study and are referred here to Cynomys sp.

A single large, somewhat worn M1 or M2 from the Cudahy time-equivalent Sunbrite assemblage (KUVP 6703) clearly represents a large Cynomys, but lacks diagnostic features to allow species assignment. An upper molar was likewise attributed to Cynomys from the Robert local fauna (Schultz, Reference Schultz1969). We were unable to examine this specimen, but generic identification is probably correct given that Cynomys molars are much larger than those of any other ground squirrel known from the Late Pleistocene of the Meade Basin, and thus unlikely to be misidentified. We identify both specimens as Cynomys sp.

Cynomys? new sp.

Figure 4.9

Remarks

A single p4 from Sunbrite (KUVP 6704) documents a second prairie dog or prairie dog-like Urocitellus (Fig. 4.9) from that assemblage. This p4 displays great relative width (identified in Fig. 5.3) and a well-developed protolophid that lacks a distinct notch at its attachment with the protoconid (Fig. 4.9), in both respects resembling Cynomys more than Urocitellus. However, it is much smaller than all other known Cynomys (Table 2), plotting between Urocitellus cf. U. richardsonii and U.? cragini in length of p4 (identified in Fig. 5.1). KUVP 6704 represents an undescribed species, but more complete material will be needed to support a description. Generic assignment was queried because it could represent either a small Cynomys or highly derived Urocitellus.

Genus Paenemarmota Hibbard and Schultz, Reference Hibbard and Schultz1948

Paenemarmota barbouri Hibbard and Schultz, Reference Hibbard and Schultz1948

1948 Paenemarmota barbouri Reference Hibbard and SchultzHibbard and Schultz, p. 19, pls. 1–3.

Holotype

KUVP 6994, left lower jaw with I, p4-m3. KUVP Locality 22, Rexroad Formation, sec. 34, T.34S., R.30W (Hibbard and Schultz, Reference Hibbard and Schultz1948).

Remarks

Paenemarmota includes giant ground squirrels from the late Miocene and Pliocene (Fig. 6.1; Goodwin, Reference Goodwin2008). Paenemarmota barbouri Hibbard and Schultz, Reference Hibbard and Schultz1948 had an estimated body mass of ~16 kg, extrapolated from length of p4 (Goodwin and Bullock, Reference Goodwin and Bullock2012), and was present at Fox Canyon within the Meade Basin sequence (Table 1).

Paenemarmota sawrockensis (Hibbard, Reference Hibbard1964)

1964 Marmota sawrockensis Reference HibbardHibbard, p. 118, fig. 1.

1988 Paenemarmota sawrockensis Reference VoorhiesVoorhies, p. 168, figs. 3, 4.

Remarks

Paenemarmota sawrockensis (Hibbard, Reference Hibbard1964) differed from P. barbouri in smaller size (Table 2, estimated body mass ~10 kg; Goodwin and Bullock, Reference Goodwin and Bullock2012), less molariform p4, and more elevated point of attachment of the metalophid on the metaconid (Voorhies, Reference Voorhies1988). It was present at Sawrock Canyon within the Meade Basin.

Recognition of P. sawrockensis and P. barbouri as different lineages rather than temporal variants of a single lineage is supported by the relationship between P. barbouri and Paenemarmota mexicana (Wilson, Reference Wilson1949). The latter species was present in late Miocene and early Pliocene localities of northern Mexico (summarized in Goodwin, Reference Goodwin2008), and shared with P. barbouri a molariform p4 and minimally developed metalophid on lower molars. These species were either closely related or conspecific (Repenning, Reference Repenning1962). If this relationship is correct, the P. barbouriP. mexicana lineage must be distinct from P. sawrockensis because populations of the former lineage were present in the fossil record both prior and subsequent to deposition of the Saw Rock Canyon assemblage with P. sawrockensis.

Discussion

Temporal patterns and environmental reconstruction

The Meade Basin sciurid record is more diverse than previously understood, with at least seven genera and 14 species present in the composite early Pliocene to Late Pleistocene sequence (Table 1). The record is discontinuous (Fig. 2), with fossil assemblages clustering at a few discrete time intervals (Fig. 5), but broad faunal patterns can be inferred.

Extinct giant ground squirrels (Paenemarmota) were restricted to the early Pliocene in the Meade Basin, although P. barbouri remained on the southern High Plains into the late Pliocene (Dalquest, Reference Dalquest1975). In contrast, I. meadensis and O. rexroadensis persisted through the Pliocene, with the former ranging into the earliest Pleistocene at Borchers (Fig. 5). A second, larger species of Otospermophilus was likely also present in the early Pliocene (Fig. 5). Antelope ground squirrel fossils (Ammospermophilus) were relatively uncommon, present at two early Pliocene localities, and possibly present in the late Pliocene (Fig. 5.2, Table 1).

The early Pleistocene Borchers assemblage displays a diverse sciurid assemblage with transitional character. Ictidomys meadensis persisted from the Pliocene. The larger-bodied Otospermophilus was notably absent, but a similar-sized, dentally derived species probably representing the Holarctic genus Urocitellus (U.? cragini) was abundant. Two additional species of Urocitellus were likely present, including the lineage leading to the extant U. richardsonii (Table 1). Prairie dogs (Cynomys) were absent.

The transition between Borchers and slightly younger early Pleistocene faunas in the Meade Basin (e.g., Short Haul, Aries, Rick Forester, and Nash 72) was abrupt, both taxonomically (Table 1) and temporally (Fig. 5). None of the ground squirrels present at Borchers was recorded at higher localities in the same outcrops, although Urocitellus cf. U. richardsonii returned later in the Pleistocene. Ictidomys tridecemlineatus first appeared in the Meade Basin along with an extinct prairie dog, C. hibbardi. Cynomys hibbardi was present by the late Pliocene in northern Kansas (Goodwin, Reference Goodwin1995b), but apparently did not expand its range southward until the early Pleistocene, essentially coincident with the Microtus Schrank, Reference Schrank1798 immigration event in the Meade Basin (Martin et al., Reference Martin, Peláez-Campomanes, Honey, Fox, Zakrzewski, Albright, Lindsay, Opdyke and Goodwin2008).

The composite Middle Pleistocene record from Cudahy and Sunbrite yields a diverse sciurid assemblage distinct from that of the early Pleistocene. Ictidomys tridecemlineatus persisted, but was larger in size than early Pleistocene populations, and both Urocitellus cf. U. richardsonii and Franklin’s ground squirrel, P. franklinii, were present (Table 1; Fig. 5) well south of their current ranges. Prairie dogs were absent from the rich Cudahy fauna, but two prairie dog species were present at the coeval Sunbrite locality: a large form probably representing an extant lineage, but known only from a single heavily worn upper molar, and a diminutive form representing a new species (Fig. 4.9). The roughly time-equivalent Robin’s Roost assemblage from northwestern Oklahoma likewise yielded a large prairie dog. Absence of prairie dogs from Cudahy is puzzling; Cudahy is <25 km from Sunbrite and fossils collected from both localities were excavated from the same limited 20 cm horizon beneath the primary ash-fall of the Lava Creek B Tuff (0.627±0.015 Ma; Mark et al., Reference Mark, Renne, Dymock, Smith, Simon, Morgan, Staff, Ellis and Pearce2017). Both assemblages share the same species of Microtus and other rodents (Martin and Peláez-Campomanes, Reference Martin and Peláez-Campomanes2014), suggesting similar paleoecology. We speculate that the absence of prairie dogs from Cudahy may be an artifact of localized taphonomic sampling, which by chance did not encompass a prairie dog town.

Late in the Pleistocene, I. tridecemlineatus persisted, but returned to the same smaller size as during the early Pleistocene, Urocitellus cf. U. richardsonii remained abundant, and P. franklinii was present at least intermittently (Table 1). Both black-tailed (C. ludovicianus) and white-tailed (C. niobrarius) prairie dogs were present, but were not found in the same assemblages (Table 1). A single fossil from the Adams locality demonstrated at least a temporary Late Pleistocene presence of Otospermophilus in the Meade Basin, perhaps representing the extant rock squirrel (O. variegatus) that today occurs <100 km to the SW.

Two of five Late Pleistocene ground squirrels (Urocitellus cf. U. richardsonii and P. franklinii) disappeared from the Meade Basin near the end of the Pleistocene, but persisted farther north on the Great Plains, and a third (C. niobrarius) became globally extinct at this time. The modern Meade Basin ground squirrel community was assembled from the remaining two Pleistocene species (I. tridecemlineatus and C. ludovicianus), along with the spotted ground squirrel (Xerospermophilus spilosoma), with the latter reaching the eastern margin of its modern range in southwestern KS (Streubel and Fitzgerald, Reference Streubel and Fitzgerald1978a). While the dentition of X. spilosoma cannot reliably be distinguished from that of I. tridecemlineatus, the consistency of size and characters in Pliocene and Pleistocene Ictidomys from the Meade Basin and the current predominantly western and southwestern distribution of X. spilosoma suggest that the spotted ground squirrel, like the hispid cotton rat (Sigmodon hispidus Say and Ord, Reference Say and Ord1825) and fox squirrel (Sciurus niger Linnaeus, Reference Linnaeus1758), may be a Holocene immigrant to the basin.

Overall, the record of ground squirrels is congruent with two early Pliocene to Pleistocene trends in paleoenvironments inferred from stable isotopic and faunal evidence in the Meade Basin. First, carbon isotopic investigation of paleosol soil carbonates demonstrates a step-wise increase in regional abundance of C4 vegetation (mostly grasses) leading to emplacement of essentially modern-type grassland ecosystems in at least some habitats during the early Pleistocene (Fox et al., Reference Fox, Honey, Martin and Peláez-Campomanes2012b). Pliocene squirrels of the Meade Basin were likely granivorous to omnivorous (they lacked dental specializations of small grazers, such as high-crowned, transversely wide cheek teeth; Goodwin, Reference Goodwin2009), and, based on modern analogs, at least Otospermophilus and Ammospermophilus probably occupied shrub to shrub-steppe environments (Oaks et al., Reference Oaks, Young, Kirkland, Gordon and Schmidt1987; Best et al., Reference Best, Lewis, Caesar and Titus1990a, Reference Best, Titus, Caesar and Lewis1990b; Belk and Smith, Reference Belk and Smith1991). In contrast, species with high-crowned, transversely wider cheek teeth known to occupy grassland ecosystems abruptly appeared in the early Pleistocene (Fig. 5.3), at or just above Borchers, and were dominant in later Pleistocene assemblages (Ictidomys tridecemlineatus, Urocitellus, and Cynomys). A similar pattern is evident in arvicolid rodents—Microtus, with ever-growing cheek teeth, first appears in the Borchers Badlands at Short Haul, dated to ca. 2.0 Ma (Martin et al., Reference Martin, Peláez-Campomanes, Honey, Fox, Zakrzewski, Albright, Lindsay, Opdyke and Goodwin2008).

Second, oxygen isotopic analysis of paleosol carbonates suggests an association between the stepwise increase in C4 abundance and a combination of cooling temperatures, increased winter precipitation, and/or increased soil moisture, with particularly significant change across the Pliocene–Pleistocene transition (Fox et al., Reference Fox, Honey, Martin and Pelaez-Campomanes2012a)—a change reflected in the replacement of a more southern-adapted rodent community with one more adapted to temperate conditions (Martin et al., Reference Martin, Peláez-Campomanes, Honey, Fox, Zakrzewski, Albright, Lindsay, Opdyke and Goodwin2008). Based on the distribution and ecology of modern representatives, the same pattern holds for sciurids; Pliocene species with modern congeners either permit (I. meadensis) or support (O. rexroadensis and Ammospermophilus sp.) warmer and/or more-arid paleoenvironments, whereas Pleistocene faunas incorporate species of cooler, more-temperate aspect (Urocitellus spp., Cynomys spp., I. tridecemlineatus, and P. franklinii).

The presence of Ammospermophilus at two early Pliocene localities slightly younger than Fox Canyon (XIT 1B, Wiens B) may indicate an episode of significant aridity in the early Pliocene. All extant species of Ammospermophilus occupy desert habitats (Best et al., Reference Best, Lewis, Caesar and Titus1990a, Reference Best, Titus, Caesar and Lewis1990b; Belk and Smith, Reference Belk and Smith1991), thus it seems probable that fossil Ammospermophilus were likewise arid-adapted. This interpretation is consistent with the absence of cotton rats from the Meade Basin during the early Pliocene (Peláez-Campomanes and Martin, Reference Peláez-Campomanes and Martin2005), although cotton rats were present at the later Pliocene Rexroad Locs. 2 and 2A, from which Ammospermophilus was also tentatively identified. Today, Sigmodon arizonae Mearns, Reference Mearns1890 can be found in limited mesic habitat along small streams coursing through Arizona deserts, so the association of Ammospermophilus with Sigmodon minor Gidley, Reference Gidley1922 during the middle Pliocene could still be consistent with an arid period.

Ictidomys and the Huckleberry Ridge Tuff

There is growing evidence that eruptions from the Yellowstone Caldera, resulting in huge accumulations of volcanic ash hundreds of km from the source, contributed to disruption of community structure and influenced cladogenesis in the Meade Basin rodents (Martin and Peláez-Campomanes, Reference Martin and Peláez-Campomanes2014; Martin, Reference Martin2016). The rapid dwarfing in Ictidomys from Borchers to slightly higher assemblages, such as Short Haul, Aries A, and Nash 72, may provide another example. As noted above, because there is a dental shape as well as size change, we interpret the post-Borchers early Pleistocene Ictidomys samples to represent immigration of the extant I. tridecemlineatus, perhaps originating from populations of I. meadensis outside of the Meade Basin as a result of natural selection during the post-ashfall environment. This hypothesis is congruent with similar dwarfing in pocket gopher populations of Geomys tyrioni, likely originating from the Borchers Geomys floralindae Martin et al., Reference Martin, Peláez-Campomanes, Honey, Marcolini and Akersten2011. Geomys tyrioni was also recovered from the Short Haul, Aries A, and Nash 72 assemblages, and was replaced by modern-sized Geomys bursarius (Shaw, Reference Shaw1800) at Rick Forester. It is conceivable that I. tridecemlineatus originated in the Meade Basin, but given the widespread distribution of the Huckleberry Ridge Tuff and the likely wide geographic distribution of I. meadensis, the probability that we have recorded the I. tridecemlineatus speciation event is very unlikely and, in any case, impossible to distinguish from immigration. The important point is that widespread, devastating ash-falls may have contributed significantly to today’s North American rodent diversity.

In conclusion, taxonomic revision of the Meade Basin sciurids results in the recognition of seven genera and at least 14 species, with changing Pliocene–Pleistocene associations consistent with environmental reconstructions made previously on the basis of other rodent clades and geochemical environmental proxies. The rapid size shift in Ictidomys and appearance of the modern I. tridecemlineatus provides further circumstantial evidence for the influence of volcanic eruptions and subsequent ash-falls on rodent community structure and cladogenesis.

Acknowledgments

Research in the Meade Basin of southwestern Kansas was supported by the National Geographic Society (5963-97, 6547-99) and the National Science Foundation (EAR 0207582, EAR 1338262). The Office of Research and Creative Scholarship at Andrews University funded museum travel for HTG. G. Gunnell and A. Rountrey (UMMP), D. Miao (KU), and R. Zakrzewski (FHSM) provided access to and assistance with relevant collections.

Accessibility of supplemental data

Data available from the Dryad Digital Repository: http://dx.doi.org/10.5061/dryad.7h398

References

Allen, J.A., 1877, Sciuridae, in Coues, E., and Allen, J.A., eds., Monographs of North American Rodentia: Washington, D.C., United States Geological Survey of the Territories, Government Printing Office, p. 631940.Google Scholar
Allen, J.A., 1895, Descriptions of new American mammals: Bulletin of the American Museum of Natural History, v. 7, p. 327536.Google Scholar
Alvarez-Castaneda, S.T., 2007, Systematics of the Antelope ground squirrel (Ammospermophilus) from islands adjacent to the Baja California peninsula: Journal of Mammalogy, v. 88, p. 11601169.Google Scholar
Belk, M., and Smith, H.D., 1991, Ammospermophilus leucurus: Mammalian Species, v. 368, p. 18.Google Scholar
Bennett, E.T., 1833, Characters of new species of Mammalia from California: Proceedings of the Royal Society of London, v. 1833, p. 3940.Google Scholar
Best, T.L., Lewis, C.L., Caesar, K., and Titus, A.S., 1990a, Ammospermophilus interpres : Mammalian Species, v. 365, p. 16.Google Scholar
Best, T.L., Titus, A.S., Caesar, K., and Lewis, C.L., 1990b, Ammospermophilus harrisii : Mammalian Species, v. 366, p. 17.Google Scholar
Brandt, J.F., 1844 [1843], Observations sur les différentes espèces de sousliks de Russie, suivies de remarques sur l’arrangement et la distribution géographique du genre Spermophilus, ansé que sur la classification de la familie des ecureuils (Sciurina) en général: Bulletin Scientifique l’Académie Impériale des Sciences de Saint-Pétersburg, v. 1844, p. 357382.Google Scholar
Burns, J.A., and McGillivray, W.B., 1989, A new prairie dog, Cynomys churcherii, from the late Pleistocene of southern Alberta: Canadian Journal of Zoology, v. 67, p. 26332639.Google Scholar
Cuvier, F., 1825, Des Dents des Mammiferes: Strasbourg, F. G. Levrault, 256 p.Google Scholar
Dalquest, W.W., 1975, Vertebrate fossils from the Blanco Local Fauna of Texas: Occasional Papers The Museum Texas Tech University, v. 30, p. 152.Google Scholar
Erxleben, J., 1777, Systema regni animalis per classes, ordines, genera, species, varietates cum synonymia et historia animalium. Classis 1: Mammalia, Lipsiae, Impensis Weygandianis, 636 p.Google Scholar
Eshelman, R.E., 1975, Geology and paleontology of the early Pleistocene (late Blancan) White Rock fauna from north-central Kansas, Studies on Cenozoic Paleontology and Stratigraphy. Claude W. Hibbard Memorial Volume 4: University of Michigan Papers on Paleontology 13, p. 160.Google Scholar
Eshelman, R.E., and Hibbard, C.W., 1981, Nash local fauna (Pleistocene: Aftonian) of Meade County, Kansas: Contributions from the Museum of Paleontology University of Michigan, v. 25, p. 317326.Google Scholar
Fischer de Waldheim, G., 1817, Adversaria zoologica fasciculus primus: Mémoires de la Sociéte Impériale des Naturalistes de Moscou, v. 5, p. 357428.Google Scholar
Fox, D.L., Honey, J.G., Martin, R.A., and Pelaez-Campomanes, P., 2012a, Pedogenic carbonate stable isotope record of environmental change during the Neogene in the southern Great Plains, southwest Kansas, USA: Oxygen isotopes and paleoclimate during the evolution of C4-dominated grasslands Geological Society of America Bulletin, v. 124, p. 431443.Google Scholar
Fox, D.L., Honey, J.G., Martin, R.A., and Peláez-Campomanes, P., 2012b, Pedogenic carbonate stable isotope record of environmental change during the Neogene in the southern Great Plains, southwest Kansas, USA: Carbon isotopes and the evolution of C4-dominated grasslands Geological Society of America Bulletin, v. 124, p. 444462.Google Scholar
Gidley, J.W., 1922, Preliminary report on fossil vertebrates of the San Pedro Valley, Arizona, with descriptions of new species of Rodentia and Lagomorpha: United States Geological Survey Professional Paper, v. 131E, p. 119131.Google Scholar
Goodwin, H.T., 1995a, Pliocene–Pleistocene biogeographic history of prairie dogs, genus Cynomys (Sciuridae): Journal of Mammalogy, v. 76, p. 100122.Google Scholar
Goodwin, H.T., 1995b, Systematic revision of fossil prairie dogs with descriptions of two new species: University of Kansas Museum of Natural History Miscellaneous Publications, v. 86, p. 138.Google Scholar
Goodwin, H.T., 2002, Spermophilus elegans (Rodentia, Sciuridae) from the middle Pleistocene of Colorado and the origin of the Spermophilus richardsonii group: Journal of Vertebrate Paleontology, v. 22, p. 182185.Google Scholar
Goodwin, H.T., 2008, Sciuridae, in Janis, C.M., Gunnell, G.F., and Uhen, M.D., eds., Evolution of Tertiary mammals in North America, v. 2: Cambridge, UK, Cambridge University Press, p. 14041502.Google Scholar
Goodwin, H.T., 2009, Odontometric patterns in the radiation of extant ground-dwelling squirrels within Marmotini (Sciuridae: Xerini): Journal of Mammalogy, v. 90, p. 10091019.Google Scholar
Goodwin, H.T., and Bullock, K.M., 2012, Estimates of body mass for fossil giant ground squirrels, genus Paenemarmota : Journal of Mammalogy, v. 93, p. 11691177.CrossRefGoogle Scholar
Goodwin, H.T., and Hayes, F.E., 1994, Morphologically derived ground squirrels from the Borchers Local Fauna, Meade County, Kansas, with a redescription of ?Spermophilus cragini : Journal of Vertebrate Paleontology, v. 14, p. 278291.Google Scholar
Green, M., 1960, A Tertiary Cynomys from South Dakota: Journal of Paleontology, v. 34, p. 545547.Google Scholar
Hall, E.R., 1981, Mammals of North America: New York, John Wiley and Sons, 1181 p.Google Scholar
Hay, O.P., 1921, Descriptions of species of Pleistocene Vertebrata, types or specimens of most of which are preserved in the United States National Museum: Proceedings of the United States National Museum, v. 59, p. 599642.Google Scholar
Hazard, E.B., 1961, The subgeneric status and distribution in time of Citellus rexroadensis : Journal of Mammalogy, v. 42, p. 477483.Google Scholar
Helgen, K.M., Cole, F.R., Helgen, L.E., and Wilson, D.E., 2009, Generic revision in the Holarctic ground squirrel genus Spermophilus : Journal of Mammalogy, v. 90, p. 270305.Google Scholar
Hibbard, C.W., 1941a, The Borchers fauna, a new Pleistocene interglacial fauna from Meade County, Kansas: Geological Survey of Kansas Bulletin, v. 38, p. 197220.Google Scholar
Hibbard, C.W., 1941b, Mammals of the Rexroad fauna from the upper Pliocene of southwestern Kansas: Transactions of the Kansas Academy of Sciences, v. 44, p. 265313.Google Scholar
Hibbard, C.W., 1941c, New mammals from the Rexroad fauna, upper Pliocene of Kansas: The American Midland Naturalist, v. 26, p. 337368.Google Scholar
Hibbard, C.W., 1956, Vertebrate fossils from the Meade Formation of southwestern Kansas: Papers of the Michigan Academy of Science, Arts, and Letters, v. 41, p. 145203.Google Scholar
Hibbard, C.W., 1964, A contribution to the Saw Rock Canyon Local Fauna of Kansas: Papers of the Michigan Academy of Science, Arts, and Letters, v. 49, p. 115127.Google Scholar
Hibbard, C.W., 1976, The localities of the Cudahy fauna, with a new ground squirrel (Rodentia, Sciuridae) from the fauna of Kansas (late Kansan), in Churcher, C.S., ed., Athlon: essays in palaeontology in honour of Loris Shano Russell: Toronto, Royal Ontario Museum, p. 278286.Google Scholar
Hibbard, C.W., and Schultz, C.B., 1948, A new sciurid of Blancan age from Kansas and Nebraska: Bulletin of the University of Nebraska State Museum, v. 3, p. 1929.Google Scholar
Hibbard, C.W., and Taylor, D.W., 1960, Two late Pleistocene faunas from southwestern Kansas: Contributions from the Museum of Paleontology University of Michigan, v. 16, p. 1223.Google Scholar
Hollister, N., 1916, A systematic account of the prairie-dogs: North American Fauna, p. 137.Google Scholar
Howell, A.H., 1938, Revision of the North American ground squirrels with a classification of North American Sciuridae: North American Fauna, v. 56, p. 1256.Google Scholar
Kapp, R.O., 1965, Illinoian and Sangamon vegetation in southwestern Kansas and adjacent Oklahoma: Contributions from the Museum of Paleontology University of Michigan, v. 19, p. 167255.Google Scholar
Kennicott, R., 1863, Descriptions of four new species of Spermophilus, in the collections of the Smithsonian Institution: Proceedings of the Philadelphia Academy of Natural Sciences, v. 15, p. 157158.Google Scholar
Kent, D.C., 1967, Citellus kimballensis, a new late Pliocene ground squirrel: Bulletin of the University of Nebraska State Museum, v. 6, p. 1726.Google Scholar
Kurtén, B., and Anderson, E., 1980, Pleistocene Mammals of North America: New York, Columbia University Press, 442 p.Google Scholar
Linnaeus, C., 1758, Systema naturae per regna tria naturae, secundum classes, ordines, genera, species, cum characteribus & differentiis. Editio decima, reformata Tom. I: Holmiae, Laurentii Salvii, 824 p.Google Scholar
Mark, D.F., Renne, P.R., Dymock, R.C., Smith, V.C., Simon, J.I., Morgan, L.E., Staff, R.A., Ellis, B.S., and Pearce, N.J.G., 2017, High-precision 40Ar/39Ar dating of Pleistocene tuffs and temporal anchoring of the Matuyama-Brunhes boundary: Quaternary Geochronology, v. 39, p. 123.Google Scholar
Martin, R.A., 2016, Geomys tyrioni, a new species of early Pleistocene dwarf pocket gopher from the Meade Basin of Southwestern Kansas: Journal of Mammalogy, v. 97, 949959.Google Scholar
Martin, R.A., and Peláez-Campomanes, P., 2014, Diversity dynamics of the Late Cenozoic rodent community from south-western Kansas: the influence of historical processes on community structure: Journal of Quaternary Science, v. 29, p. 221231.Google Scholar
Martin, R.A., Honey, J.G., and Peláez-Campomanes, P., 2000, The Meade Basin rodent project: a progress report: Paludicola, v. 3, p. 132.Google Scholar
Martin, R.A., Peláez-Campomanes, P., Honey, J.G., Fox, D.L., Zakrzewski, R.J., Albright, L.B., Lindsay, E.H., Opdyke, N.D., and Goodwin, H.T., 2008, Rodent community change at the Pliocene–Pleistocene transition in southwestern Kansas and identification of the Microtus immigration event on the Central Great Plains: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 267, p. 196207.Google Scholar
Martin, R.A., Peláez-Campomanes, P., Honey, J.G., Marcolini, F., and Akersten, W.A., 2011, Five million years of pocket gopher history in the Meade Basin of southwestern Kansas and northwestern Oklahoma: Journal of Vertebrate Paleontology, v. 31, p. 866884.Google Scholar
Mearns, E.A., 1890, Description of supposed new species and subspecies of mammals, from Arizona: Bulletin of the American Museum of Natural History, v. 2, p. 277307.Google Scholar
Merriam, C.H., 1890, Descriptions of five new ground squirrels of the genus Tamias: North American Fauna, v. 4, p. 1722.Google Scholar
Merriam, C.H., 1892, The geographic distribution of life in North America with special reference to the Mammalia: Proceedings of the Biological Society of Washington, v. 7, p. 164.Google Scholar
Michener, G.R., and Koeppl, J.W., 1985, Spermophilus richardsonii : Mammalian Species, v. 243, p. 18.Google Scholar
Mitchill, S.L., 1821, Description of two mammiferous animals of North America: New York Medical Repository (N.S.), v. 6, p. 248250.Google Scholar
Oaks, E.C., Young, P.J., Kirkland, J., Gordon, L., and Schmidt, D.F., 1987, Spermophilus variegatus : Mammalian Species, v. 272, p. 18.Google Scholar
Obolenskij, S., 1927, A preliminary review of the Palaearctic sousliks (Citellus and Spermophilopsis): Comptes Rendus de l’Academie des Sciences de l’URSS, A, v. 12, 188193.Google Scholar
Ord, G., 1815, Zoology of North America, in Guthrie, W., Ferguson, J., Knox, J., and Ord, G. A New Geographical, Historical, and Commercial Grammar; and Present State of the Several Kingdoms of the World: Philadelphia, Johnson & Warner, v. 2, p. 290361.Google Scholar
Ostroff, A.C., and Finck, E.J., 2003, Spermophilus franklinii : Mammalian Species, v. 724, p. 15.Google Scholar
Peláez-Campomanes, P., and Martin, R.A., 2005, The Pliocene and Pleistocene history of cotton rats in the Meade basin of southwestern Kansas: Journal of Mammalogy, v. 86, p. 475494.Google Scholar
Pocock, R.I., 1923, The classification of the Sciuridae: Proceedings of the Zoological Society of London, v. 1923, p. 209246.Google Scholar
Preble, E.A., 1908, A biological investigation of the Athabaska-Mackenzie region: North American Fauna, v. 27, p. 1574.Google Scholar
Rafinesque, C., 1817, Description of seven new genera of North American quadrupeds: American Monthly Magazine and Critical Review, v. 2, p. 4446.Google Scholar
Repenning, C.A., 1962, The giant ground squirrel Paenemarmota : Journal of Paleontology, v. 36, p. 540556.Google Scholar
Richardson, J., 1825, Account of the quadrupeds and birds, Appendix to Captain Parry’s journal of a second voyage for the discovery of a north-west passage from the Atlantic to the Pacific, performed in His Majesty’s ships Fury and Hecla in the years 1821-22-23: London, John Murray, p. 285379.Google Scholar
Sabine, J., 1822, Account of the marmots of North America hitherto known, with notices and descriptions of three new species: Transactions of the Linnean Society of London, v. 13, p. 579591.Google Scholar
Say, T., and Ord, G., 1825, Description of a new species of Mammalia, whereon a genus is proposed to be founded: Journal of the Academy of Natural Sciences of Philadelphia, v. 4, p. 352356.Google Scholar
Schrank, F., 1798, Fauna Boica: Nürnberg, Stein, v. 1, 720 p.Google Scholar
Schultz, G.E., 1969, Geology and paleontology of a late Pleistocene basin in southwest Kansas: Geological Society of America Special Papers, v. 105, p. 178.Google Scholar
Shaw, G., 1800, Descriptions of the Mus Bursarius and Tubularia Magnifica; from Drawings communicated by Major-General Thomas Davies, FRS & LS.: Transactions of the Linnean Society of London, v. 5, p. 227229.Google Scholar
Streubel, D.P., and Fitzgerald, J.P., 1978a, Spermophilus spilosoma: Mammalian Species, v. 101, p. 14.Google Scholar
Streubel, D.P., and Fitzgerald, J.P., 1978b, Spermophilus tridecemlineatus : Mammalian Species, v. 103, p. 15.Google Scholar
Voorhies, M.R., 1988, The giant marmot Paenemarmota sawrockensis (new combination) in Hemphillian deposits of northeastern Nebraska: Transactions of the Nebraska Academy of Sciences, v. 16, p. 165172.Google Scholar
Wilson, R.W., 1949, Rodents of the Rincon fauna, western Chihuahua, Mexico: Carnegie Institution of Washington Publications, v. 584, p. 165176.Google Scholar
Zegers, D.A., 1984, Spermophilus elegans : Mammalian Species, v. 214, p. 17.Google Scholar
Figure 0

Figure 1 Location of the Meade Basin (gray ellipse).

Figure 1

Figure 2 Stratigraphic relationships of Meade Basin fossil assemblages. MPTS, magnetic polarity time scale; Ma, millions of years ago; C, Chron; r, reversed; n, normal; Br, Brunhes; Ma, Matuyama; Ga, Gauss; Gi, Gilbert; Jar, Jaramillo; Old, Olduvai; Reun, Reunion; Mam, Mammoth; Coch, Cochiti; Nun, Nunivak; Sud, Sidufjall; Thv, Thvera; Crk, Creek; Tol, Toledo; Huck R, Huckleberry Ridge; Gr., gravel; CC, calcium carbonate layer; (N) and (R), Normal and Reversed polarity; Rap, Raptor; C., Canyon; RZ, rodent zones.

Figure 2

Figure 3 Measured dimensions, and orientation and dental terminology for (1) lower (FHSM VP-18159; left p4 of I. tridecemlineatus from Cudahy) and (2) upper teeth (UMMP 42319C; left M1 or M2 of P. franklinii from Cudahy). Scale bars=1 mm Abbreviations: ac=anterior cingulum, buc=buccal, dis=distal, hpcd=hypoconid, L=length, lin=lingual, mes=mesial, mst=mesostyle, mtc=metacone, mtcd=metaconid, mtcl=metaconule, mtl=metaloph, mtld=metalophid, pc=posterior cingulum, prc=paracone, ptc=protocone, ptcd=protoconid, ptl=protoloph, ptld=protolophid, TlW=width across the talonid, TrW=width across the trigonid, W=width at paracone.

Figure 3

Table 1 Sciurid species recovered from selected assemblages in the Meade Basin, Kansas. Assemblage abbreviations listed in approximate stratigraphic sequence from oldest (left) to youngest (right): HB=High Banks; SRC=Saw Rock Canyon; FC=Fox Canyon; RipB=Ripley B; XIT1B=XIT 1B; Rap1C=Raptor 1C; WnsB–D=Wiens B, C, D; Vas=Vasquez; Nwt=Newt; Hor=Hornet; R3A-C=Rexroad 3A-C; Wb=Wheelbarrow; WFP=Wendell Fox Pasture; R2A=Rexroad Loc. 2A; R2=Rexroad Loc. 2; DP=Deer Park A; HD=Hart Draw; Pal=Paloma; Mar=Margaret; Bor=Borchers; SH=Short Haul; ArA=Aries A; ArNE=Aries northeast; RF=Rick Forester; Na72=Nash 72; Cud=Cudahy; Sun=Sunbrite; RR=Robin’s Roost; AD=Adams; BS=Butler Spring; MS=Mt. Scott; Kapp=Kapp Horizon; CQ=Cragin Quarry; Jin=Jinglebob; Jon=Jones; Tay=Taylor; GolB, C=Golliher B-C; Rob=Robert; Mod=Modern. *=exact stratigraphic placement uncertain.

Figure 4

Figure 4 Lower cheek teeth (p4, m1 or m2) of Meade Basin ground squirrels. Scale bar=1 mm. To facilitate comparisons, all are displayed as left specimens (reversed right teeth are indicated). (1–3) Lower m1 or m2 of (1) Ammospermophilus sp. from Wiens B (FHSM VP-18438; R reversed), (2) extant A. interpres from Dona Ana Co., NM (KUVP 131708; m1), and (3) Ictidomys meadensis from Rexroad 3 (UMMP 35057). (4–9) Lower p4s of (4) I. meadensis from Rexroad 3C (FHSM VP-18365; R reversed), (5) I. meadensis from Borchers (KUVP 156258), (6) Poliocitellus franklinii from Cudahy (UMMP 36796; R reversed), (7) Otospermophilus rexroadensis from Rexroad 3B (FHSM VP-18348), (8) Urocitellus? cragini from Borchers (UMMP 50136), and (9) Cynomys? sp. from Sunbrite (KUVP 6704; R reversed).

Figure 5

Table 2 Measurements of p4 and P4 (in mm) in composite stratigraphic samples used for statistical analysis. L=length, W=width. Cell values represent mean (standard deviation) n. See Table 1 for assemblage abbreviations.

Figure 6

Figure 5 Stratigraphic variation in (1) lengths of p4 and (2) P4 of fossils from the Meade Basin, excluding Paenemarmota (log10-scale for tooth lengths). Envelopes of size variation in Ictidomys and Otospermophilus given by dotted lines. (3) Stratigraphic variation in relative width of p4 (trigonid width/length). Dashed vertical line represents equivalence of trigonid width and tooth length. Dark horizontal line in all panels represents the Pliocene-Pleistocene boundary. Representative localities indicated in (2); locality abbreviations defined in Table 1.

Figure 7

Figure 6 (1) Scatter plot of relative trigonid width of p4 (trigonid width/tooth length) versus p4 length (log10 scale) for all Meade Basin fossils of p4 that can be identified to genus. Genera marked with different symbols; stratigraphic samples distinguished for Ictidomys and Urocitellus. (2) Scatter plot of trigonid width versus tooth length (log10 scale for both) of the m3 for fossils of Poliocitellus franklinii, and Urocitellus cf. U. richardsonii, and for comparative extant species (P. franklinii, U. elegans, and U. richardsonii). One fossil outside the Meade Basin (holotype of P. lorisrusselli; UMMP 61136) is plotted and labelled. Fossils from Borchers and Cudahy are indicated.

Figure 8

Figure 7 Upper M3 fossils, all displayed as right (indicated if reversed). Scale bar=1 mm. (1) I. meadensis from Borchers (FHSM VP-18122; L reversed). Abrupt deflection of posterior cingulum(arrow) distal to short ridge coursing buccodistally from protocone (dotted line) noted in text. (2) I. tridecemlineatus from Short Haul (FHSM VP-18902; L reversed). (3) P. franklinii from Sunbrite (UMMP 39596). (4) Urocitellus cf. U. richardsonii from Adams (UMMP 34705; L reversed). (5) Cynomys hibbardi from Rick Forrester (FHSM VP-14104).

Figure 9

Figure 8 Lower right m3 fossils of (1) P. franklinii (UMMP 117771) and (2) Urocitellus cf. U. richardsonii (UMMP 117732), both from Cudahy, and (3.1, 3.2) of C. hibbardi from Nash (FHSM VP-18209). (3.2) represents an oblique, occlusodistal view of the trigonid. Attributes noted in text are labelled; lam=lingual arm of metapholophid; ctp=closure of trigonid pit. Scale bar=1 mm.