"a" . . . A .04..»vu HERPETOFAUNA OF THE ECK RANCH LOCAL FAUNA B UPPER PLIOCENE 0F TEXkS BLANCAN) ( .1 ‘99:! a. “ . . . pup-WW” ,. _. . . wwm. . ._. .mfiflm W _. . am. a . rm 1W 4 Wm. ._ This is to certify that the thesis entitled ”Herpetofauna of the Beck Ranch local fauna (Upper PliocenezBlancan) of Texas.“ presented by Karel Rogers has been accepted towards fulfillment of the requirements for PhD degree in Zoology ' ofemunr / z/M/A / my 2 , I Date 9 January 975 0-7639 v V .4 ll [SENS . “Wt 8mm ms . “‘ warmth BtN'JLHEb‘ l s? WC”ORI.IIGIIG‘_' “1‘7“.“ , h _ :; HERPE The Beck 0f Scurry Counl four salamande] Eight lilards, fauna is made t ‘% nand DEScribed finders (Amphit aspecies of s Gecchelone . L 0 he 1505311 recc ABSTRACT HERPETOFAUNA OF THE BECK RANCH LOCAL FAUNA (UPPER PLIOCENE: BLANCAN) OF TEXAS by Karel Louise Rogers The Beck Ranch local fauna (Upper Pliocene: Blancan) of Scurry County, Texas, yielded a herpetofauna of at least four salamanders, nine anurans, one crocodilian, six turtles, eight lizards, and twenty snakes. About 75 percent of the fauna is made up of extant species. Two extinct genera, AmphitritonenuiOgmophis, and ten extinct species occur in the fauna. Described as new from the fauna are a family of sala- manders (Amphitritontidae), a species of lizard, Gerrhonotus, a species of snake, Ogmoghis, and a species of turtle, Geochelone. Recent species occurring for the first time in the fossil record include Ambystoma opacum and Scelogorus olivaceus. Paleoecological evidence indicates that the climate in Scurry County, Texas, was more equitable than at present, but in a state of deterioration. The fauna consists of two elements, an upland Kansan biotic province element with a tall-grass prairie type of vegetation, and a lowland, moister Austroriparia with an easte Faunal c indicate that that fauna . Karel Louise Rogers Austroriparian biotic province element from eastern Texas with an eastern deciduous forest type of vegetation. Faunal comparisons with Rexroad Locality Number 3 indicate that the Beck Ranch Fauna is contemporaneous with that fauna. HERP in HERPETOFAUNA OF THE BECK RANCH LOCAL FAUNA (UPPER PLIOCENE: BLANCAN) OF TEXAS BY Karel Louise Rogers A DISSERTATION Submitted to Michigan State University in partial fulfillment of the requirements for the degree of DOCTOR OF PHILOSOPHY Department of Zoology 1975 For Richard n I-p - I... u a o.. ' M- -: v'. ACKNOWLEDGMENTS I would like to thank my major professor, J. Alan Holman, and my doctoral committee, Charles E. Cleland, Marvin M. Hensley, and Stephen N. Stephenson, for their help in the preparation of this paper. I would also like to thank Ms. Bonnie Marris, Mr. Merald Clark, Ms. Barbara Gudgeon, and Ms. Chris Kulczycki who prepared the illus- trations. Appreciation is also expressed to Walter W. Dalquest for the loan of the Beck Ranch fossils and to the University of Michigan Museum of Paleontology for the use of the Rexroad Locality Number 3 Fauna. iii TABLE OF CONTENTS Page LIST OF TABLES . . . . . . . . . . . . . . . . . . . . v LIST OF FIGURES . . . . . . . . . . . . . . . . . . . vi INTRODUCTION . . . . . . . . . . . . . . . . . . . . . l SYSTEMATIC PALEONTOLOGY . . . . . . . . . . . . . . . 6 Class Amphibia O O O O O O O O O O O O I O O O O O O 8 Class Reptilia . . . . . . . . . . . . . . . . . . . 30 DISCUSSION . . . . . . . . . . . . . . . . . . . . . . 88 Paleoecology . . . . . . . . . . . . . . . . . . . . 88 Stratigraphic Comparisons . . . . . . . . . . . . . 96 SUWRY O O O O O O O O O O O O O O O O O O O O O O O 1 0 2 LITERATURE CITED . . . . . . . . . . . . . . . . . . . 105 iv LIST OF TABLES Table Page 1. Comparison of body length and dentary length in Texas species of Sceloporus . . . . . . . 55 2. Comparison of species from the Beck Ranch Fauna and from the Rexroad Locality Number 3 Fauna . . . . . . . . . . . . . . . 97 Q/O 0 ‘11! I Did thin Figure 1. 10. 11. 12. 13. 14. 15. 16. LIST OF FIGURES a. Location of the Beck Ranch Site; b. Section of Ogallala sediments at Beck Ranch measured by Dalquest and Donovan (1973). . . . . . . . Ambystoma atlas (MUVP9243) . . . . . . . . . . Ambystoma Opacum vertebra (MUVP9245) . . . . . Amphitriton brevis vertebra, Holotype MUVP9247) o o o o o o o o o o o o o o o o o Amphitriton brevis referred vertebra from Rexroad Locality Number 3 (UMMP31226) . . . . Amphitriton brevis, scapula (MUVP9248) . . . . Bufo woodhousei woodhousei, vomer (MUVP9255) . Chrysemys picta, complete shell (MUVP9266) -. . PSeudemys scripta, shell elements (MUVP9267) . Terrapene ornata, nuchal (MUVP9264) . . . . . . Geochelone beckensis, nuchal Holotype (MUVP9272). Geochelone beckensis, shell elements, Paratype (MUVP9273) . . . . . . . . . . . . . Comparison of characters of Geochelone alleni, Q. beckensis, and g. johnstoni . . . Hypothetical phylogenetic relationships of the turtles of the Geochelone turgida group as proposed by Holman (1972a) with the addition of g. beckensis . . . . . . . . Gerrhonotus insolitus dentary, Holotype (MUVP9278) . . . . . . . . . . . . . . . . . Ogmophis parvus, vertebra Holotype (MUVP9284) . vi Page 12 14 15 17 26 33 37 39 44 45 48 49 52 63 Figure 17. 18. 19. 20. Page Ogmophis parvus vertebra, Paratype (MUVP9285) . . . . . . . . . . . . . . . . . 65 Hypothetical phylogenetic relationships of the Ogmophis compactus evolutionary line . . 67 Heterodon plionasicus, vertebra (MUVP9289) . . 70 Approximate boundaries of the biotic provinces in Texas as proposed by Blair (1950) . . . . 90 vii INTRODUCTION In 1966, Walter W. Dalquest discovered a rich and varied vertebrate fauna on the property of Mr. Jimmie Beck 11 miles east of Snyder, in Scurry County, Texas, which he designated the Beck Ranch local fauna (Dalquest and Donovan, 1973). Between 1967 and 1972, approximately 50 tons of fossil-bearing matrix was collected for washing by Midwest- ern University personnel under the direction of Walter Dalquest. The fossils of the Beck Ranch local fauna include fishes, amphibians, reptiles, birds, and mammals (Dalquest and Donovan, 1973). The present report deals with the herpetofauna of the Beck Ranch local fauna. Three papers on the Beck Ranch mammals (Dalquest, 1971, 1972, Dalquest and Donovan, 1973) and one paper on the birds (Brodkorb, 1971) have been published. In 1971, Dalquest reported on fossils of a small species of skunk, Spilogale rexroadi, which was known previously only from the Rexroad Locality Number 3 Fauna (Dalquest, 1971). Beckiasorex hibbardi, a new genus and species of shrew, was described from Beck Ranch by Dalquest (1972). In the same paper, he reported that four genera of rabbits, Hypolagus, Nekrolagus, Notolagus, and Pratilepus, four genera of myomorph rodents, Perognathus, Prodipodomys, Baiomys, and 1 . .‘fi‘C ~ . _.-. vi- (If ‘ z A Ki: ISO-lI \-\ "a :A. u..‘ .H I {O ‘— 1 ,‘l o.‘ g'o, o“, < II.) 1' a. "K, "Y L Q q ~ 5 |‘ 0‘ “.1. “4 l “u ‘I “ '\ Sigmodon, and two genera of carnivores, Bassariscus and Nasua, are represented in the Beck Ranch local fauna. The most extensive paper available on Beck Ranch is by Dalquest and Donovan (1973) where Equus (Plesippus) simplicidens is listed, and a new species of horse, Nannippus beckensis, is described. The only paper in which the birds of Beck Ranch have been discussed is one on fossil woodpeckers by Brodkorb (1971) in which a new species of woodpecker, Campephilus dalguesti, is described. Dalquest (1972) reported that Brodkorb has also identified a turkey from the fauna. Thus, 14 mammals and two birds are known from the Beck Ranch Fauna. Evidence from the mammals indicates that the age of the fauna is late Pliocene. Spilggale rexroadi has been reported previously only from the upper Pliocene Rexroad Locality Number 3 (Dalquest, 1971). Hypolagus is a Ter- tiary genus that did not survive the Blancan. Notolagus and Pratilepus are upper Pliocene genera unknown from the Pleistocene. Hypolagus extends only to the earliest Pleistocene. Nannippus beckensis is considered an inter- mediate step in the evolution of N. lenticularis, of the middle Pliocene, to N. phlegon, the terminal member of the genus, of the latest Pliocene and earliest Pleistocene (Dalquest and Donovan, 1973). This evidence strongly indi- cates a late Pliocene age of the fauna. The mammal and bird fossils studied so far represent three ecological elements, a grassland habitat, a lowland or tropical habitat, and a NeotrOpical element. Grassland or prairie genera include the rodents, Perognathus, Prodipodomys, Baiomys, and Sigmodon. The lowland element is represented by the carnivores Bassariscus and Nasua and possibly by Nannippus (Dalquest, 1972, Dalquest and Donovan, 1973). The woodpecker, Campephilus dalquesti, is most closely related to the Guatemalan ivory-billed woodpecker, and thus represents a NeotrOpical element in the fauna (Brodkorb, 1971). The geology of the Tertiary deposits in Scurry County, Texas, as described by Dalquest and Donovan (1973), is as follows. The Beck Ranch deposits are 55 miles east of the escarpment of the High Plains, at an elevation of 1700 feet, about 1000 feet below the caprock of the escarpment (Figure bah Dalquest and Donovan feel that the cross-sectional geometry of the area suggests a basin-fill deposit with successively higher beds overlapping the flanks of the valley in which they were deposited. A section of the deposit measured by Dalquest and Donovan in a large, southward-draining canyon, 1750 feet west of Beck Ranch house and 1650 feet south of Highway 0.8. 180, is shown in Figure U3. Regard- ing this section, Dalquest and Donovan (1973, p. 34) say: The lower half (31 feet) of the exposure consists of massive light brown to pinkish sandy and clayey siltstone and very fine sandstone which forms vertical a Lubbock MR T] 80¢" ite &MMEF"“L .__ Bi; 59""! 41mm - San Angelo b III" 0 Mon, any“. any. pld (5'! 1m flat to “In. gn calcareous. m lhlt s y.” M.“ — I.» bun-(snow " can pm (5" mm» a (rah-rm and Mic; with: d luau W, H urn-(snmmmyu «an id 5131/2), In [rel-01mm nacho “Wilt-n! III" I Mum‘s: manning-bu. 11'4" mum-nan had. “'41" Total «pad I.“ not on...“ vertical scale, '10' Figure l. a. Location of the Beck Ranch Site. b. Section of Ogallala sediments at Beck Ranch measured by Dalquest and Donovan (1973). Most vertebrate fossils come from Unit 4. Redrawn from Dalquest and Donovan (1973). . . f" n I A .‘ouvu'v ‘:.a* n‘ ‘vv' U. ““ARO‘ '- \ , ‘vrvat ‘ . . :- ”ice (u... v: A 2;..ed l v. V ~IO. H -u.3 u (A ' .H I ‘~v. .N 1.}! a cliffs. This is overlain by and is in sharp contact with an 11 feet thick section of friable, fine-to— medium grained sandstone with small floating pebbles and pebble lenses containing clear and white quartz and reworked Gryphea shells. Brown clay balls are common. Portions of the overlying section are covered and form slopes and the entire area is capped by a thick layer of coating. The pebbly sand is correla- tive with the Beck Ranch quarry unit which yields ver- tebrate fossils. Evidence from mean grain size indicates that the lower 31 feet of the measured section is a loess, or wind-blown deposit, while the upper half is fluvial in origin. Dalquest and Donovan conclude the valley was partially filled with loess, and this was followed by stream aggrada- tion in which vertebrate fossils were trapped in fine sedi- ments deposited in backwaters associated with a southeasterly flowing stream system. /. '7. LL! (1 . ‘ - L. ) Ih ( -v II I/ I J :11 '44 F tow: :(I 11- (u {u 1 ;J ,- 1)! I I '7 7 I 1 n '. l)! (I) (I) 1) 05:7 1 ); I; SYSTEMATIC PALEONTOLOGY. This section consists of an annotated list of the species of the Beck Ranch Fauna. Osteological characters are discussed, present range and geologic range of each species is given, and habitat preferences are noted. A checklist of the species discussed is given below. Extinct genera are marked with a double asterisk, extinct species with a single one. Class Amphibia Order Urodela Family Ambystomatidae *Ambystoma hibbardi or A. tigrinum Ambystoma gpacum Family Plethodontidae, sp. indet. Family Amphitritontidae, n. fam. **Amphitriton brevis, n. gen. et sp. Order Salientia Family Pelobatidae *Scaphiopus diversus Family Hylidae Acris crepitans Family Bufonidae Bufo cf. valliceps Bufo cognatus *Bufo rexroadensis Bufo woodhousei woodhousei Family Ranidae Rana pipiens Rana palustris Rana areolata Class Reptilia Order Crocodilia Family Alligatoridae Alligator mississipiensis Order Chelonia Family Kinosternidae Kinosternon flavescens I- e. . . I. u. r. .. . e . t . x: ‘3 .5 . .. a a . \ . WV,- ..(.. .C A .4 . a L s: 2‘ . « ~.. . « Vs Ad Q Q ~ . Q 35.. «\h A l.- L. . . - c . - . . . . . . . . t . .. v. S. e 2. n.-. u . w .H "l. G. .«u "l. mu .1). .1H s . a t 5“. .s . t u . .1 .1 ~ ... A: . l 24 L.“ a.» A,» A.» ~ . mm um . . u u v. a.-. u ~ 1 in c. A: .Q a :1 .C L .. LN. : «3 PJ . I s a . . I ., .. D. .\u Ce «\9 . . Pr. 7. . . Fl» A 4,. A v . . p. . "Hi. u.“ .. . Pi. rt. rt. . . ~ . .. . hm... a!» u: Pu T~ Nu. .. v 0. .t 6.. u _. A u .0- . l .uu 6.. A“ 6. .— e up .-u "I -A sch \ .1 . I . . un. -\~ cl. qt. A\J ~\~ .u- on. Family Emydidae Chrysemys picta Pseudemys scripta, ssp. indet. Terrapene ornata Family Testudinidae *Geochelone rexroadensis *Geochelone beckensis, n. sp. Order Squamata Suborder Lacertilia Family Anguidae *Gerrhonotus insolitus, n. sp. Family Iguanidae Phrynosoma cornutum Sceloporus olivaceus *Sceloporus cf. robustus Sce10porus undulatus Family Scincidae Eumeces obsoletus *Eumeces striatulatus Family Teidae Cnemidophorus sexlineatus Suborder Serpentes Family Boidae *Ogm0phis parvus, n. sp. Family Colubridae Subfamily Xenodontidae Heterodon platyrhinos *Heterodon plionasicus Subfamily Natricinae Natrix erythrogaster *Natrix cf. hibbardi Natrix cyclopion or N. rhombifera Thamnophis marcianus Thamnophis sirtalis Subfamily Colubrinae Masticophis cf. flagellum Coluber constrictor Elaphe guttata Elaphe obsoleta Elaphe vulpina Pituophis melanoleucus sayi Rhinocheilus lecontei Lampropeltis getulus Lampropeltis triangulum Family Crotalidae Agkistrodon contortrix Sistrurus catenatus Crotalus atrox (D I H... ‘3 lfin ."o.~d a...” n .3 .3: I“ 'c *3: h . 'b'V: Fossils are from the collections of the Midwestern University (MUVP) and from the Museum of Paleontology, University of Michigan (UMMP). Class Amphibia Order Urodela Suborder Ambystomatoidea Family Ambystomatidae Ambystoma hibbardi Tihen or A. tigrinum (Green) Material: One atlas, MUVP9243; nine atlases, 186 vertebrae, MUVP9242. Remarks: The atlas of ambystomatoid salamanders can be distinguished from other suborders on the basis of the inter- cotylar process of Estes (1969, p. 87). The intercotylar process has a single articular facet in the ambystomatoids, but this facet is double or absent in the salamandroids and absent in all other urodeles. The atlases listed above have been assigned to the Ambystomatoidea, and on the basis of size have been assigned to the Ambystoma hibbardi-tigrinum complex. Single rib bearers occur on one of ten Beck Ranch atlases and at least one Rexroad Locality Number 3 (UMMP41156) atlas (Figure 2). These rib bearers probably are atavistic structures since all recent salamanders examined by me lack these processes. Figure 2. Amgystoma atlas (MUVP9243), ventral view.’ The remaining vertebrae were identified using char- acters discussed by Tihen (1958) and Holman (1969b). Accord- ing to Tihen (1958), the vertebrae of the A. tigrinum group of Ambystoma are shorter and wider than those of the remain— ing groups except for those of the A. mexicanum group. Characters of Holman (1969b) used were the large size and the upswept neural arch of A. tigrinum that extends well beyond the end of the centrum. In other species, the pos- terior part of the neural arch is straighter and does not extend so far posteriorly. I am uncertain if the Beck Ranch vertebrae represent Ambystoma tigrinum or A. hibbardi. According to Tihen (1955, 1958), the vertebrae of A. hibbardi and A. tigrinum L: tvv“ , a ”I; 4:", "av 3". “a head out .. . 1 'I:I D L .u-uob l - :9“ ”POP I::.“MVU . .5223, h;.~ {-iais 1: Scar] 1% low 11"“: um” Ere :P'Fr:l 'TV‘«. I I. Q '5: Mil 1 '1". 33?; fr< ': ‘1 ‘ 6., HP ’- i‘.‘(‘..1 , 's- ‘ “n, / 1'1; 10 are identical although the species can be distinguished on the degree of ossification of certain cartilage bones in the head. Since the Beck Ranch Fauna yielded no identi- fiable urodele cranial elements, the fossils cannot be assigned to species. Larval individuals are represented in the fossil popu- ' lation, but no evidence for the presence of neotenic indi— viduals could be found using the criteria of Tihen (1942, 1958). The largest fossil vertebrae are within the size range of recent Ambystoma tigrinum. Ambystoma tigrinum is a widespread species which occurs in Scurry County, Texas, today and is known as a fossil from the lower Pliocene to the Recent. Ambystoma hibbardi is an extinct species known only from the upper Pliocene of Kansas. Breeding adults of Ambystoma tigrinum are found in temporary ponds and pools. Non-breeding adults are found hidden under material near water or in the burrows of mammals away from water (Holman, 1971). The habitat of A. hibbardi is unknown but is presumed to be similar to that of A. tigrinum. Ambystoma Opacum (Gravenhorst) Material: Nine vertebrae, MUVP9245 Remarks: According to Tihen (1958), the postzyga- pOphyses extend as far, usually farther, posteriorly than the neural arch, at least in the posterior part of the trunk, v I ’II n.- p..- In A. 0‘ 11 in the A. maculatum group and in the subgenus Linguaelgpsus. My observations indicate that this is also the case in the Ambystoma opacum group. The neural spine extends poste- riorly beyond the postzygapophyses in all other species of Ambystoma. The A. opacum group can be distinguished from the A. maculatum group and the subgenus Linguaelapsus by by the height of the postzygapophyseal area. In the A. opacum group, the neural arch is more upswept resulting in a much higher and more triangular postzygapophyseal area. There are only two members of the Ambystoma opacum group, A. Opacum and A. talpoideum, and both are restricted to the Austroriparian biotic province of the eastern part of Texas (Blair, 1950). A. opacum ranges about fifty miles closer to Scurry County than A. taipoideum, and reaches a larger size than A. talpoideum (Conant, 1958). In addition, the vertebrae of A. opacum tend to have the postzyga- pophyses extending farther beyond the neural spine than does A. talpoideum. Therefore, on the basis of size, geographic range, and neural spine length, the fossil vertebrae have been referred to A. opacum. See Figure 3. The fossil vertebrae are slightly larger than is found today in A. opacum. A. opacum ranges from 87 - 112 mm with a record of 125 mm (Conant, 1958). The size of the fossil vertebrae indicates that the individuals were 175 — 200 mm. The western limit of the geographic range of Ambystoma opacum is approximately 330 miles to the east of Beck Ranch. s! F ‘3‘ r. .vvlfi- " :35, :A 5! .V‘I. I!.“ .. r I . \ 12 It has not been reported previously as a fossil. A. Opacum occurs in a variety of habitats, ranging from moist sandy areas to dry hillsides. It breeds in the autumn and the eggs, which are guarded by the female, are deposited in low depressions which are subsequently filled by rains (Conant, 1958). Figure 3. Ambystoma Opacum vertebra (MUVP9245), dorsal view. Amphitritontidae n. fam. Amphitriton n. gen., type of fam. Diagnosis: Amphitritontidae is a family of salamanders represented by a single fossil genus, Amphitriton, that is at present known only from the upper Pliocene of Texas and Kansas.- The only elements known are vertebrae and a scapula. The vertebrae of Amphitritontidae are distinct from those of - .I-fi l '- --..u. rd; 4 13 all other North American fossil and Recent salamanders in the following combination of characters: (1) amphicoelus vertebrae (opisthocoelus in Batrachosauridae, Salamandridae, Desmognathinae of the Plethodontidae, and Prodesmodon of the Prosirenidae); (2) presence of a well-developed keel on the anterior vertebrae (absent in Cryptobranchidae, Sala- mandridae, Ambystomatidae, Plethodontidae, and Prosiren in the Prosirenidae): (3) absence of a keeled neural spine (present in Sirenidae, Scapherpetonidae, Amphiumidae, Desmognathinae, and Prodesmodon in the Prosirenidae); (4) presence of bicipital rib processes (unicipital in Sirenidae, Cryptobranchidae, Necturidae, Amphiumidae, some Plethodontidae and Salamandridae, and in Prodesmodon in the Prosirenidae). Amphitriton brevis n. sp. Holotype: One almost complete anterior vertebra, slightly broken at the end of the neural spine, MUVP9247. Figure 4. Paratypes: Eleven vertebrae, one scapula, MUVP9248. Figure 6. Horizon and type-locality: Beck Ranch local fauna, Blanco Formation, Blancan age, Upper Pliocene, of Scurry County, Texas. Found on the Property of Mr. Jimmie Beck, 10 mi. E. Snyder, SW corner of NE quarter of NE quarter, Sec. 62, HTC Survey, Scurry County, Texas. l4 Figure 4. Amphitriton brevis vertebra, Holotype (MUVP9247); a. dorsal, b. ventral, c. lateral, d. anterior view. w: 1 ...- ~ HF": 50"." l \ (I, 15 Referred Material: Ten vertebrae, UMMP31226, UMMP31727, UMMP38757, UMMP41156 formerly identified as "Ambystoma hibbardi” and "Salamander.” Material from_Rexroad Locality Number 3. See Figure 5. Figure 5. Amphitriton brevis referred vertebra from Rexroad Locality Number 3 (UMMP31226); a. dorsal View, b. ventral view. Etymology: Latin, Amphitrite, the goddess of the sea, and brevis, short, referring to the shortness of the verte- brae. Distribution: Known only from the upper Pliocene of Scurry County, Texas, and Meade County, Kansas. v‘u- ' n . 1‘... ha-.. I ~ on»- o n u a t. (I? 1" \- - q u I. e " ~ -1 l6 Diagnosis: Differs as the genus. Description 9; Holotype: In dorsal view, the pre- zygapophyses are directed anteriorly. There is very little constriction anterior to the rib-bearers giving the verte- bra a square appearance (greatest length 4.9 mm, greatest width 4.8 mm). The rib-bearers (which arise near the anterior end of the vertebra and are directed posteriorly) have two well-developed articular surfaces connected by a thin web of bone. The dorsal rib-bearer arises slightly below the dorsal surface of the neural arch. In ventral view, the centrum is short and broad, has a well-developed keel, is moderately constricted in the middle, and is amphicoelus. Lateral to the ventral keel are posterior basapophyses. In anterior View, the neural canal has an U-shaped bulge produced upward between the prezygapOphyses. The holotype lacks a septum in the notochordal canal. Posteriorly, the neural arch is upswept resulting in a high triangular postzygapophyseal area. The postzyga- pophyseal facets do not extend beyond the end of the centrum. The cotyle is nearly round in outline. Description 9; referred scapula: Figure 6. The extent of ossification of the scapula is similar to that found in Ambystoma. The dorsal scapular portion arises more anteriorly and the ossified area around the glenoid fossa is more oval than that found in the ambystomatids. In addition, the .I n - 17 suprocoracoid foramen is directly posterior to the lgenoid fossa rather than lateral to it. Figure 6. Amphitriton brevis, scapula (MUVP9248), lateral. Remarks: The presence of a well-developed ventral keel and accessory basapophyses indicates that Amphitriton brevis may have been an aquatic species (Estes, 1969). These struc— tures usually occur in conjunction with a keeled neural spine and elongate vertebrae; thus it may be that the aquatic hab- its of A. brevis were secondarily derived. If Amphitriton is aquatic, then it would seem that the ambystomatoid Amphitritontidae is the ecological equivalent of the salaman- droid Amphiumidae. The vertebrae of Amphiuma are very sim- ilar to plethodontid vertebrae except that aquatic features are stressed; that is, a ventral keel, keeled neural spine, and accessory basapOphyses are present. Similarly, the vertebrae of Amphitriton are very similar to ambystomatid vertebrae except that a ventral keel, accessory basapophyses, and un upward bulge of the neural arch are present. I :1) . -o‘n.~ ‘tvvd-V 3 Dz“: vial" . n, . T u. . b I . A a "'1 ‘IY9~ ' u. _.‘ . . . fl \ u l8 Suborder Salamandroidea Family Plethodontidae Subfamily Plethodontinae, sp. indet. Material: Anterior half of two vertebrae, MUVP9246. Remarks: All of the Salamandridae and some of the Plethodontidae have Opisthocoelus vertebrae, although the condition has a different structural basis in each family (Soler, 1950). The anterior half of the notochordal canal can either be solid bone (as in the Desmognathinae) or it can be hollow for almost its entire length but covered anteriorly with an ossified (as in the Salamandridae) or cartilaginous cap (as in some older Plethodontinae). It appears from my observations, that the base of the car- tilaginous cap in some species of the Plethodontinae becomes partially ossified with age resulting in a thin, concave, bony cover on the anterior end of the centrum. The fossil vertebrae have this condition so were referred to the Plethodontinae. The vertebrae are too incomplete for spe- cific identification. Six (or possibly seven) species of the Plethodontinae occur today in Texas (Blair, 1950, Conant, 1958). Eurycea longicauda, Manculus quadridigitatus, Plethodon glutinosus, and possibly a relict pOpulation of Plethodon cinereus, are restricted in Texas to the eastern Austroriparian biotic province. Typhlomolge rathbuni, Eurycea troglodytes, and 19 Eurycea neotenes (including the three subspecies S. B- neotenes, S. A. pteroPhila, S. A. latitans) are cave and underground stream-dwellers endemic to the Balconian biotic province of central Texas. Order Salentia Family Pelobatidae Genus ScaphiOpus Subgenus Spea Scaphiopus diversus Taylor Material: Four ethmoids, nine sacrococcyges, two scapulae, five humeri, six radioulnae, 20 ilia, one fused astragulus and calcaneum, MUVP9260. Remarks: According to Estes (1970), the anterior pro- cess of the ethmoid becomes extremely large and flared anteriorly in the subgenus Spea. The fossil Scaphiopus elements have been referred to Spea since all of the ethmoids have an enlarged anterior process. Pliocene and Pleistocene species that are considered to belong to the subgenus Spea are Scaphiopus alexanderi, S. pliobatrachus, S. studeri, S. diversus, S. hammondi, S. bombifrons, and S. intermontanus (Estes, 1970). The fossil bones are similar to Recent S. bombifrons and dis- tinct from Recent S. hammondi and S. intermontanus in having a proboscis-like process on the anterior end of the ethmoid, and in having a round sacral cotyle (Tihen, 1960, Taylor, .tl‘l ‘1HLJ , I iiull ‘ I :5“ - ...\-l \- --:c Hob-r, I | o.‘.‘,‘ ,1 . “,3 .S'I "I‘bb I 5' ' I: h. '4' MC \ v: I’M VE . ‘fi ‘ ~. .. C‘v‘ s: \ ~ . v. 4‘s, h “4.11 \ “A . 9‘ ”u“ ‘Av’ . 1‘ Q. .. ,‘ — . VI ‘ a \1 VI \ ‘A t '\ N ‘uycv s. 1‘ ..' \ 1 y. .- ‘ N ‘ . .- ‘ V: . . 3 ‘~ 20 1941). S. bombifrons differs from the fossil elements in having a separate rather than fused astragulus and calcaneum, and a weak or absent deltoid crest on the humerus and a post-axial crest on the radioulna. Among the fossil spe— cies, S. alexanderi is distinguished by its characteristic fusion of the sacral and first precaudal vertebrae. S. pliobatrachus has an oval rather than round sacral cotyle, and S. studeri can be distinguished from the fossil ele- ments by its straight rather than deflected anterior proboscis-like process of the ethmoid. Tihen (1960) con- siders S. diversus, which was described by Taylor (1941) on the basis of a single sacrococcyx, closely related to and possibly directly ancestral to S. bombifrons. The major distinction between the two species is the more variable sacrococcyx with a more frequent involvement of two well- defined vertebrae in that element in the late Pliocene S. diversus. The Beck Ranch fossils have been assigned to S. diversus rather than to S. bombifrons because they fall within the range of sacrococcygeal variability of S. diversus, and because they differ from S. bombifrons on the basis of astragulus and calcaneum fusion and degree of develOpment of the deltoid and post-axial crests. Scaphiopus diversus is known as a fossil from the upper Pliocene of Kansas. Since S. diversus is so closely related to S. bombifrons, the habitat of the former is presumed to be similar to that of the latter. S. bombifrons occurs in .‘i.‘ 'I'.. .g': ‘v‘- ‘ a- I... ‘9‘. q. A t '_ 1,.“ 4., u... o.. .- o‘.~ u g o'q ‘.“ 21 the Great Plains and is a species of the open grasslands, avoiding river bottoms and wooded areas (Conant, 1958). Family Hylidae Genus Acris Acris crepitans Baird Material: Eleven ilia, MUVP9259. Remarks: Characters of Holman (1959) were used to identify the ilia of Acris. The ventral acetabular expan- sion is rounded in Acris and in Pseudacris nigrita, but more acute in Hyla and the remaining Pseudacris. Acris differs from Pseudacris in that the dorsal prominence is more elevated from the shaft in Pseudacris. On this basis, the fossil ilia have been assigned to Acris. There are only two living species of Acris, Acris crepitans and A. gryllus. According to Chantell (1968), the dorsal surface of the supra-acetabular expansion is more strongly concave in A. gryllus than in A. crepitans, and a distinct ilial groove medial to the dorsal protuber- ance is present in A. gryllus but absent in A. crepitans. The fossils have been assigned to A. crepitans on the basis of these characters and on the basis that A. crepitans occurs in the area of the fossil site today. Acris crepitans is known as a fossil from the middle Pliocene to the Recent. It is found in or near permanent bodies of shallow water that provide cover in the form of 22 vegetation, either emergent or along the shore, and which are exposed to the sun during the greater part of the day (Conant, 1958). Family Bufonidae Genus Bufo Bufo cf. valliceps Wiegmann Material: Six ilia, MUVP9257. Remarks: These ilia are distinguished from all fossil and Recent species of Bufo except Bufo suspectus, S. debilis, S. punctatus, S. terrestris, and S. vallicgps in having a low ilial prominence with a broadly rounded peak. It is very unlikely that the fossils represent S. terrestris since the latter's present distribution is far to the east of the fossil site, and since S. terrestris is a larger species than represented by the fossils. The posterior slope of the prominence is steeper than the anterior in S. suspectus but S. debilis, S. punctatus, and S. valliceps are similar to the fossils in having the anterior and posterior slopes subequal or the anterior slightly steeper. The dorsal acetabular expansion tends to be lower in S. punctatus and S. debilis than in S. vallicgps and the fossils. Since the dorsal acetabular expansions of the fossil ilia are more similar to those of S. valliceps, the fossil ilia are here referred to S. valliceps. :t a.. Mug-h i‘ibl 33:88! Q .o 3... 136336 otl knswn A: ‘CFA -l ‘1- v 23 All of the fossil ilia represent individuals which probably were less than 75 mm long. According to Blair et a1. (1968), Bufo valliceps grows to 125 mm. Bufo valliceps ranges north to approximately 50 miles south of the fossil site and has been-previously reported as a fossil from the late Pleistocene of the Yucatan Penin— sula (Tihen, 1962a). Bufo valliceps occurs in a variety of habitats including coastal prairies and barrier beaches bordering the Gulf of Mexico (Conant, 1958). Bufo cognatus Say Material: One vomer, ll sacral vertebrae, 15 ilia, MUVP9256. Remarks: According to Holman (1971), the ilial prom- inence of Bufo cognatus and S. speciosus is higher than that of other extant species of Bufo in or near Texas. Only two fossil species, S. repentinus and S. rexroadensis, are known to have an ilial prominence as high or higher than S. speciosus and S. cognatus (Tihen, 1962a). The Beck Ranch fossils do not have the anterior slope of the ilial promi- nence as steep as does S. repentinus, and the ilial promi- nence of S. rexroadensis is higher than that found in the Beck Ranch fossil ilia. Holman (1964a, 1969b) was not able to separate S. speciosus and S. cognatus on ilial char- acters alone, but he (1971) considers the species separable 24 on characters of the sacral vertebrae. In dorsal view, the condyles end only slightly posterior to the posterior border of the neural arch in S. cognatus, whereas in S. speciosus the condyles project well posterior to the posterior border of the neural arch. On this basis, the fossils have been assigned to S. cognatus. The vomer is useful in separating species of SASS. It has considerable ontogenetic variation, but interspecific variation is also great, possibly due to the close associa- tion of this element with feeding. In Bufo cognatus, the vomer is shorter and broader posteriorly than in any other species of SASS studied. A fossil vomer from the Beck Ranch Fauna has a shape comparable to S. cognatus and is there- fore assigned to that species. Bufo cognatus occurs today in Scurry County, Texas, and is known as a fossil from the Middle Pliocene to the Recent. Today, this species is most common in the tall and mixed grass prairies, and less common in the short grass areas where it tends to be restricted to the vicinity of streams (Holman, 1971). Bufo rexroadensis Tihen Material: Two ilia, MUVP9258. Remarks: The ilial prominence of Bufo rexroadensis is higher than in any other extant or fossil species of Bufo except for S. repentinus. The peak of the prominence is 25 set decidedly anterior to the midpoint of the base in S. repentinus and at the midpoint or only slightly anterior in S. rexroadensis (Tihen, 1962a). The fossil ilia have a very high ilial prominence with the peak of the prominence at the midpoint of the base and have, therefore, been identified as S. rexroadensis. S. rexroadensis is known as a fossil from the upper Pliocene of Kansas. Its habitat is unknown. Bufo woodhousei woodhousei Girard Material: One premaxilla, two frontoparietals, one vomer, three sacral vertebrae, 31 ilia, MUVP9255. Remarks: The cranial crests of the fragmentary fossil frontoparietals are heavier and have a larger occipital groove, which is roofed over anteriorly, than that of Recent Bufo woodhousei woodhousei, although they are simi- lar in all other respects to that species. The vomer of Bufo g. woodhousei is longer and narrower in the central portion that in any other species of Bufo except for B. _w_. fowleri (see Figure 7). The vomer of S. g. woodhousei can be distinguished from S. g. fowleri in that the cup-like depression on the posterior end of the bone is round in the former and more flattened in the latter. On this basis, one fossil vomer has been assigned to S. g. woodhousei. ‘q‘: Q‘- ‘v. ”If .... . . IL) (I) 26 Figure 7. §E£2 woodhousei woodhousei, vomer (MUVP9255), lateral view. The fossil ilia were identified using characters of Holman (1971) and Tihen (1962b). The ilial prominences of these fossils are higher than in SASS americanus, S. debilis, S. punctatus, S. valliceps, S. marinus, and S. woodhousei fowleri but lower than in S. cognatus and S. speciosus. They are comparable in all respects to modern S. g. woodhousei. Very few intermediate-sized individuals are represented in the population. Twenty-seven out of the 31 §E§2 woodhousei woodhousei ilia are of small immature individ- uals which probably did not exceed 75 mm in total length. Fruir ilia are of much larger individuals which were as large as the maximum size known for S. E- woodhousei today. This 27 discontinuity in the sizes of the ilia may be due to having only young and breeding adults fossilized. Bufo woodhousei woodhousei occurs in Scurry County, Texas, today and is known as a fossil from the Pleistocene (Aftonian) to the Recent. At present, this subspecies is most abundant in tall grass and mixed grass prairies, where they inhabit a large variety of situations (Holman, 1971). Family Ranidae Genus Rana Rana pipiens Schreber Material: Twenty scapulas, 30 ilia, MUVP9253. Remarks: Species of the genus Rana occurring in Texas today are Rana pipiens, S. areolata, S. palustris, S. cates- beiana, S. grylio, and S. clamitans. According to Holman (1965a), these species are separable into two groups based on ilial characters. The posteriodorsal border of the ilial crest slopes gently into the dorsal acetabular expan- sion in S. pipiens, S. areolata, and S. palustris, but it lepes precipitously into the dorsal acetabular expansion in S. catesbeiana, S. grylio, and S. clamitans. The fossil ilia are similar to S. pipiens, S. areolata, and S. plaus- E£i§ in this character. The ilia of S. pipiens can be sep- arated from those of S. areolata since the ilial prominence is narrower, more rounded, and less extensive in S. pipiens (Holman, 1971). According to Lynch (1965), the ilia of 28 S. pipiens can be separated from S. palustris on the fol- lowing characters: the ilial blade is thinner and more delicate in S. palustris, the posterior portion of the ilial blade is more angular in S. palustris than in S. pipiens, and the ilial prominence is less pronounced in S. palustris. Since the fossil ilia are similar to S. pipiens in the above characters, they have been referred to that species. Rana pipiens occurs today in Scurry County, Texas, and is known as a fossil from the lower Miocene to the Recent. At present, S. pipiens is an abundant species occurring in any aquatic situation during the breeding season, but during much of the year individuals may be found in damp places far from water (Holman, 1971). Rana areolata Baird and Girard Material: Ten scapulas, 29 ilia, MUVP9251. Remarks: These ilia are similar to S. pipiens, S. areolata, and S. palustris in having the posteriodorsal border of the ilial crest slope gently into the dorsal acetabular expansion. They have been separated from S. pipiens on the basis of characters discussed previously under S. pipiens. S. areolata and S. palustris are sep- arable on the appearance of the ilial prominence. In S. palustris, the ilial prominence is much lower and smoother \ 29 than in S. areolata. The fossil ilia are referred to S. areolata on that basis. Rana areolata occurs in the southern portion of the Austroriparian biotic province in Texas, approximately 330 miles to the southeast of Beck Ranch. This species has been identified recently as a fossil from the late Pleisto- cene of Florida (Reddick 1B) by V. Wilson (Pers. comm.). S. areolata is a nocturnal species, normally spending the daylight hours underground in crawfish burrows, mammal tunnels, or in holes beneath stumps (Conant, 1958). Rana palustris Le Conte Material: Nine scapulas, 37 ilia, MUVP9252. Remarks: These ilia were identified using characters previously discussed under Rana pipiens and S. areolata. Rana palustris has the lowest and most gently rounded ilial prominences of the North American species of Rana. Rana palustris occurs in the Austroriparian biotic province of Texas, approximately 330 miles to the south- east of Beck Ranch, and is known as a fossil from the late Pleistocene of Virginia (Gelbach, 1964). This species inhabits cool water (Sphagnum bogs, rocky ravines, and meadow streams) but also occupies a wide variety of other habitats. It often wanders out into grassy fields or weed- covered areas in the summer (Conant, 1958). 30 Class Reptilia Order Crocodilia Family Alligatoridae Alligator cf. mississipiensis (Daudin) Material: Thirteen small and three large teeth, MUVP9262. Remarks: These teeth have a thick enamel layer arui finely striated surface. Some have a sharp ante- rjxxr and posterior keel indicating they may be Alligator rnississipiensis teeth (Holman, 1966). Alligator mississipiensis ranges to within 100 miles exist of Scurry County, Texas. It is known as a fossil from true lower Pliocene to the Recent. Alligator mississipiensis lgives in swamps, lakes, bayous, and marshes (Conant, 1958). Order Chelonia Family Kinosternidae Kinosternon flavescens (Agassiz) Material: Five cervical vertebrae, four caudal verte_ brine, two humeri, one femur, one nuchal, 44 marginals, one enoiplastra, 12 hyoplastra, ll hypoplastra, three Xiphi- plastra, MUVP9265 . Remarks: The fossil Kinosternon elements were assigned tC>ZKinosternon flavescens on the basis of scute suture lines afmi shape of plastral elements. Characters used were the 31 more ridge-like ventro-lateral margin of the hyoplastron in S. flavescens than in S. subrubrum, and the wide marginal scute impressions on the hyo- and hypoplastra of S. flavescens (narrow in S. subrubrum) . Only one Kinosternon nuchal bone was found in the fauna. It has a narrow first central scute similar to that of Recent S. subrubrum rather than the wide first central scute of S. flavescens. Since there are no plastral elements of S. subrubrum, and since S. subrubrum and S. flavescens are only narrowly sympatric today, all of the Kinosternon elements are assigned to S. flavescens. Measurements of hyOplastral length and hyo- and hypoplastral thickness of the Beck Ranch S. flavescens elements with corresponding measurements of Fichter (1969) have yielded the following results . Fichter ' s hyoplastral length data indicate that no significant size change has occurred between the fossil and Recent forms. The Beck Ranch S. flavescens are comparable in size with those reported by Fichter (§%15.06 mm). The hyo- and hypoplastral thickness data of Fichter show an increase in shell thick- ness from early Blancan to a maximum in the Aftonian and a subsequent decrease in thickness to the Recent. The Beck Ranch hyo— and hypOplastra are comparable in thickness to the slightly later preglacial Cottrell Locality (x%2.89 mm). Thus, the Beck Ranch S. flavescens do not support Fichter's shell thickness trends. 32 Kinosternon flavescens occurs in Scurry County, Texas, today and is known as a fossil from the Late Pliocene to the Recent. It is a common turtle throughout much of its range, occurring in a variety of bodies of water, but pre- fers those with muddy bottoms. It occasionally appears on a land during rains, while migrating, or when foraging ‘ (Conant, 1958). Family Emydidae Genus Chrysemyg Chrysemys picta ssp. indet. Material: One almost complete shell (Figure 8), eight marginals, one pygial, one entoplastron, five xiphi- plastra, MUVP9266. Remarks: I choose to recognize the genus Pseudemyg as in Holman (1972a) rather than to combine Chrysemys with Pseudemys as in McDowell (1964). The elements assigned to Chrysemys picta were identi- fied using characters described by Weaver and Rose (1967a). The long underlap of the nuchal scute distinguishes the fossils from Pseudemys concinna and S. floridana, and the lack of rugosity on the carapace distinguishes them from most subspecies of Pseudemys scripta. Another character used to separate the fossils from the genus Pseudemys was 33 . o. 'n Na .8"- I 0 I .. .5: . I .0 ”cl... dk‘c.‘ ... (i)... n . . a. .55.”... 'éu,loo‘gl ' oA’nI-o’o Us- 0-. .o... 3:17. st”: .11 J! a... o I actual Size. ventral view; Chrysemys picta, complete shell (MUVP9266) b. a. dorsal view, Figure 8. 34 the longer nuchal bone in Chrysemys. Plastral characters used were the long gular scute overlap (short in Pseudemys concinna and S. floridana) and the presence of a longer epiplastron and narrower entoplastron than are present in Pseudemys scripta. The fossil shell was identified by the above char- acters, and on the basis that it is indistinguishable from Recent shells of Chrysemys picta. But the shell is about 50 percent thicker than in Recent S. 21232 from Kansas. The entoplastron is approximately 3.2 mm thick in Recent S. 21222 and 4.7 mm in the Beck Ranch S. 212E2- Fossil species placed in the Chrysemys group are S. limnodytes from the Clarendonian of Oklahoma and S. timida of the Illinoian of Nebraska. The Beck Ranch S. picta fossils are distinct from these species on the basis of the smooth carapace (rugose in S. limnodytes) and shape of the carapace (widest anteriorly in S. timida and widest posteriorly in S. picta). Galbraith (1948) indi- cates that S. limnodytes is somewhat intermediate between Recent Chrysemys picta and Recent Pseudemys scripta, but he does not consider S. limnodytes ancestral to Pseudemys. If S. picta evolved from a S. limnodytes-like ancestor, that evolution was completed by Blancan times since the Beck Ranch fossils are not intermediate between S. limnontes and Recent Chgysemys, but rather are true S. picta. 35 Chrysemys picta does not occur today in Scurry County, Texas, but pOpulations of S. p. belli (Gray) occur 190 miles to the west and 270 miles to the north of the fossil site. A relict pOpulation of S. E- dorsalis (Agassiz) occurs 360 miles east of Beck Ranch. Chrysemys picta dorsalis is known as a fossil from the Early Pleistocene to the Recent. Chrysemys picta lives in ponds, marshes, backwaters of streams, and prairie sloughs, where the water is shallow with a soft muddy bottom and profuse aquatic vegetation (Conant, 1958). Genus Pseudemyg Pseudemys scripta ssp. indet. (Schoepff) Material: Four nuchals, 23 marginals, five epiplastra, two entOplastra, two hyoplastra, MUVP9267. See Figure 9. Remarks: The fossil elements listed above were placed in the Pseudemys scripta group on the basis of characters of Weaver and Rose (1967a, 1967b), Weaver and Robertson (1967), and Preston (1966). There is a long nuchal scute underlap and gular scute overlap (short in Pseudemys concinna and S. floridana), rugosity is present on at least some scutal areas of the nuchal bone (smooth in Chrysemys picta), and the marginals are doubly toothed (single in Pseudemys concinna and S. floridana, and absent in Chrysemys picta). Fossil species assigned to the genus Pseudemys are the middle Pliocene Pseudemys williamsi and S. carri, the middle to upper Pliocene S. inflata, and the Pleistocene (Irvington) 36 S. platymarginata. The Pseudemys scripta elements are dis- tinct from S. williamsi since S. williamsi has the short nuchal scute underlap and gular scute overlap character- istic of S. concinna and S. floridana. The epiplastral lip is smooth with a moderate gular scute overlap in S. n carri and serrate with a long gular scute overlap in the S. scripta fossils. S. inflata is distinguished from S. -3 scripta by its extremely deep and wide nuchal notch and I excessive rugosity. The remaining species, S. platymarginata, differs from S. scripta in having a deeper and wider nuchal notch angle and smooth marginal scute areas of the nuchal bone. Fossil species now considered to be subspecies of the Pseudemys scripta complex include S. S. bisornata (Preston, 1966) and S. S. petrolei (Holman, 1969a), which are known as Pleistocene fossils from Florida west to Texas (Preston, 1966). Pseudemygyg. bisornata is considered to be similar to S. S. elegans, and S. S. petrolei has features which are identical to S. §~ scripta (Preston, 1966). Preston (1966) describes a cline of bony shell characters present in the S. scripta group. The subspecies S. S. scriRta in the southeastern 0.8. has the anterior edge of the epiplastron rounded, the carapace and nuchal bone moderately keeled middorsally, the nuchal lamina long and narrow with deep sulci, and the first central lamina narrow relative to the maximum width of the nuchal bone. As the range of S. S. 37 elegans in Texas and S. S. ornata in Central America is approached, the anterior edge of the epiplastron becomes acute and serrate (except in S. §- scripta), the middorsal keel becomes less pronounced or absent, the nuchal lamina becomes shorter and wider with less distinct sulci, and the first central lamina increases in width in comparison to the width of the nuchal bone. The Beck Ranch Pseudemys scripta fossils are similar to S. S. elegans (and S. §- bisornata). The ratio of the width of the nuchal bone to the anterior width of the first central lamina is 1.63 in the Beck Ranch S. scripta and ranges from 1.58 to 1.75 in the nuchals similar to S. g. elegans reported by Preston (1966). In addition, the Beck Ranch S. scripta has serrate epiplastral lips as in S. scripta elegans (Figure 9). Figure 9. Pseudemys scripta, shell elements (MUVP9267); a. nuchal. b. epiplastron; actual size. 38 Evidence from the fossil distribution of the sub- species of Pseudemys scripta indicates that the distribu- tions of these turtles have not been static (Preston, 1966). Preston (1966) hypothesizes that during warm and/or dry periods turtles similar to S. S. scripta shifted north— ward and turtles similar to S. S. elegans moved eastward into Florida; and conversely, during cool and/or moist periods S. S. elegans-like turtles moved southward into Mexico and S. S. scripta-like turtles moved westward into Texas. Thus, the presence of S. S. elegans-like turtles at Beck Ranch indicates a warm and/or dry period for the area. Pseudemys scripta elegans occurs today in Scurry County, Texas. Pseudemys scripta is known as a fossil from the Lower Pliocene to the Recent (Preston, 1966). It is a primarily herbivorous species which inhabits rivers, sloughs, lakes, and ponds which have aquatic vegetation (Preston, 1966). Terrapene ornata Agassiz Material: One nuchal (Figure 10), one entoplastron, MUVP9264. Remarks: The entoplastron of Terrapene ornata can be separated from that of the Terrapene carolina group by the gular scute which extends much farther posteriorly on the entoplastron of S. ornata than on S. carolina. In addition, the entoplastron of S. ornata tends to be oval in outline, 39 and that of S. carolina tends to be more round and extended laterally at the epiplastral-hyoplastral suture. The fossil is comparable in shape and plastral thickness to Recent S. ornata from Kansas. Terrapene ornata is found in Scurry County, Texas, today and is known as a fossil from the early Pliocene to the Recent. It is a species of the plains and prairies, often found in sandy areas. This species is able to toler- ate arid conditions, and will often burrow to escape heat (Conant, 1958). Figure 10. Terrapene ornata, nuchal (MUVP9264);(actual.size. Family Testudinidae Genus Geochelone Subgenus Caudochelyg Geochelone rexroadensis Oelrich Material: One femur, one ilium, dermal ossicles, right carapace bridge area, three adjacent peripherals (apparently numbers 8, 9, 10), one right half of plastron with medial and epiplastral areas broken away, one epiplastron, one 40 incomplete xiphiplastron, 28 fragments of carapace and plastron, MUVP9271. Remarks: The fossil elements listed above have been assigned to the subgenus Caudochelys since they represent a giant, smooth-shelled form which lacks a supracaudal buckler (Auffenberg, 1963b). The species of the subgenus Hesperotestudo are smaller, more rugose, and have supra- caudal bucklers. According to Auffenberg (1963b), seven species of Geochelone are placed in the subgenus Caudochelys. These are Geochelone ligonia, S. arenivaga, S. tedwhitei, S. hayi S. rexroadensis, S. laticaudata, and S. crassiscutata. Of these, the Beck Ranch fossil elements are most similar to S. rexroadensis. The plastral sulci which can be traced follow the pattern seen in the type of S. rexroadensis. The peripherals are very high as in S. rexroadensis and rela- tively low in all other species of Caudochelys. Oelrich (1952) considers Geochelone orthopygia, which is a member of the subgenus Hesperotestudo, to be the closest relative of S. rexroadensis. The distinguishing characters (pectoral scute short along the midline in S. orthopygia and longer in S. rexroadensis, and a shorter wider plastron in S. orthopygia than in S. rexroadensis) are difficult to determine in the Beck Ranch fossils since the anterior and medial portion of the plastron is broken away. But the pec— toral scute is narrow laterally and then appears to begin to 41 widen medially as seen in the holotype of S. rexroadensis. Those plastral measurements which can be made are more similar to S. rexroadensis than tqu. orthopygia. Also, the Beck Ranch fossils are thick-shelled like S. rexroadensis rather than thin-shelled like S. orthopygia. Therefore, the Beck Ranch fossils have been referred to S. rexroadensis. The Beck Ranch Geochelone rexroadensis is slightly larger than S. rexroadensis from the Rexroad fauna. Com- parative measurements indicate a size difference of 10 to 12 percent. The thickness of the carapace is comparable to that seen in the holotype of Geochelone rexroadensis. The peripherals are approximately 57 mm thick at their thickest point in the holotype and are 53.5 mm thick in the Beck Ranch S. rexroadensis. The costals average 22 mm thick in the holotype and 20 mm thick in the Beck Ranch fossils. Thus, the Beck Ranch S. rexroadensis is 6 to 9 percent thinner-shelled than the Rexroad S. rexroadensis. The slightly thinner shell of the Beck Ranch S. rexroadensis may be due to sexual dimorphism or to the presumably warmer conditions at the more southern Beck Ranch site. The plastron is only very slightly concave, so it is felt that this specimen was a female. Both the holotype and paratype are considered to be males (Oelrich, 1952). 42 The single epiplastron and five of the carapace and plastron fragments represent a smaller individual of the same species. Width measurements of the posterior end of the epiplastron indicate that this second individual was about 37 percent smaller than the other (60 mm and 95 mm, resp.). Geochelone rexroadensis is known as a fossil only from the late Pliocene (Blancan) of Kansas. Its habitat, as i! discussed by Hibbard (1960), was a tropical or subtrOpical area with enough vegetation for food and shelter from excessive heat, or from cool nights. Therefore, Scurry County, Texas, was an area with very few, if any, frosts during the late Pliocene. Subgenus Hesperotestudo Geochelone beckensis n. sp. Holotype: One nuchal bone, MUVP9272. Figure 11. Paratypes: One nuchal, nine first costals, 18 other costals, five peripherals, two pygials, three epiplastra, one entOplastron, three hyo- and hypoplastral fragments, two xiphiplastra, two caudal bucklers, MUVP9273. Figure 12. Horizon and type-localigy: Beck Ranch local fauna, Blanco Formation, Blancan age, upper Pliocene, of Scurry County, Texas. Found on the property of Mr. Jimmie Beck, 10 miles E. Snyder, SW corner of NE quarter of NE quarter, Sec. 62, HTC Survey, Scurry County, Texas. 43 Etygplogy: This species is named after the Beck Ranch site. Diagnosis: A small species of thick-shelled late Pliocene tortoise belonging to the subgenus Hesperotestudo in the genus Geochelone. It is a member of the western branch of the alleni line as described by Holman (1972a), and ancestral to Geochelone johnstoni, the first member of that line. It is distinguished from G. johnstoni by its shallower, wider xiphiplastral notch, convergent rather than parallel sides of the nuchal bone, and lack of fusion of the first suprapygial and pygial. Description Q: the Holotype: The type nuchal is sculptured on all scutal areas excluding the nuchal which is longer than wide. The first pleural scute does not encroach on the nuchal bone and the first vertebral scute is large and v-shaped anteriorly. Maximum width of the nuchal is 100 mm, maximum length is 58 mm, greatest thick- ness of the first marginal is 20 mm, and the posterior medial thickness is 8.5 mm. I estimate that the carapace length of this individual was about 300 mm. a s“ 4... 44 Figure 11. Geochelone beckensis, nuchal Holotype (MUVP 9272); a. dorsal view, b. Ventral view. Description Q: the paratypes: The carapace elements are all deeply sculptured with grooves and ridges. The available costals are fragmentary, but it appears that the sculpturing is more pronounced distally than medially. The peripherals are excessively rugose and of moderate length. A costal, which appears to be from an individual approximately the same size as the type, has a thickness of 9.5 mm. The pygial (Figure 12a) is subtriangular and separate from the second suprapygial. The plastral elements are sculptured, but with much finer grooves and ridges than the carapace. The epiplas- tral beak, which has a weak ventral keel, is moderately well developed with slightly divergent apices. See Figures 12b,c. The entoplastron is oval in shape and has gular scute impressions anteriorly but no pectoral scute impressions posteriorly. Hyo- and hypoplastral elements 45 Figure 12. Geochelone beckensis, shell elements, Paratype (MUVP9273); a. pygial, dorsal view, b. epiplastron, ventral view, c. epiplastron, dorsal view, d. xiphiplastron, ventral view, e. xiphiplastron, dorsal View, f. supracaudal buckler, dorsal view. 46 are represented only as fragments, but they appear to have been greatly thickened laterally. The xiphiplastron (Figures 12d,e) has a short and very wide notch posteriorly and a high lateral border. The supracaudal buckler is subtriangular and composed of 14 ossicles arranged in four rows. See Figure 12f. The hinge area consists of four anterior to posteriorly flat- tened ossicles. On each end of the next row are high recurved ossicles bordering lower cone-like ossicles. The remaining ossicles are low and cone-like. Comparisons: Geochelone beckensis differs from the S. turgida line of Hesperotestudo (including S. turgida, S. riggsi, and S. oelrichi) in being less rugose and in having a smaller epiplastral beak. Geochelone alleni, S. equicomes, and S. wilsoni lack plastral sculpturing and a ventral keel on the epiplastral beak both of which are pres- ent in S. beckensis. Geochelone beckensis can be distin- guished from S. johnstoni by its lack of a dorsal epiplastral keel, lack of fusion of the first suprapygial and pygial, and by its wider, shallower xiphiplastral notch. Geochelone incisa has a wider epiplastral beak and shorter anal scute than S. beckensis. Phylogenetic relationships: According to Holman (1972a), the alleni line of Hesperotestudo consists of an eastern branch (including Geochelone incisa from the late Pleistocene of Florida) and a western branch (including 47 S. johnstoni from the early Pleistocene of Texas, S. Egg;- gggg§_from the middle Pleistocene of Kansas, and S. wilsoni from the late Pleistocene of south Texas). The basal form of both branches is S. alleni from the middle Pliocene of Florida. I Geochelone beckensis appears to be a late Pliocene member of the western branch of the alleni line. It is intermediate between S. alleni and S. johnstoni, but more closely related to the latter. Figure 13 contains a compari- son of characters of the three species. The hypothetical phylogenetic relationships of the tortoises of the S. turgida group as proposed by Holman (1972a) with the addition of S. beckensis can be seen in Figure 14. Several trends seem to be apparent in the western branch of the alleni line. These are: (1) increase and subsequent decrease in shell sculpturing, (2) deve10pment of dorsal and ventral keels on the epiplastral beak, (3) decrease in epiplastral beak height, (4) increase in length of anal scute. Remarks: At least four different size classes are represented in the fossil material. Although none of the material could be reassembled, no more variation occurs in any element than is found in Recent specimens of different ages and sizes. 48 S. alleni S. beckensis S. johnstoni carapace sculpturing moderate deep deep pygial fused to. ? no yes second suprapygial plastral sculpturing absent present present epiplastral keel dorsal absent absent present ventral absent present present epiplastral beak length lip/height lip 1'0 1'3 1'3 wider longer longer entoplastral shape than long than wide than wide anal scute short long longer Figure 13. Comparison of characters of Geochelone alleni, S. beckensis, and S. johnstoni. 49 LATE PLEIS‘I: mun-I mm IEO. PLEIST. Munro-£8 EA. FIJI". onpml NINTH)” LA‘I’E Puoc. INT» ucmm HID. PLIOC. to In ALILII ? \,/ Figure 14. Hypothetical phylogenetic relationships of the turtles of the Geochelone turgida group as proposed by Holman (1969a) with the addition of S. beckensis. from Holman (1969a). Redrawn 50 Order Squamata Suborder Lacertilia Family Anguidae Genus Gerrhonotus Subgenus Gerrhonotus Gerrhonotus insolitus n. sp. Holotype: One right dentary, MUVP9278. Figure 15. Horizon and type-locality: Beck Ranch local fauna, Blanco Formation, Blancan age, upper Pliocene, of Scurry County, Texas. Found on the property of Mr. Jimmie Beck, 10 miles E. Snyder, SW corner of NE quarter of NE quarter, Sec. 62, HTC Survey, Scurry County, Texas. Etymology: Latin, insolitus, meaning strange referring to the odd dentition of this new species. Diagnosis: A medium-sized species of Gerrhonotus sim- ilar to members of that subgenus in dentary bone form, but differing from them in having all but the back four or five teeth anterio-posteriorly compressed, lacking enameloid crowns with striations, and nearly straight and chisel- shaped. No other species of Gerrhonotus has teeth which are so sharply chisel-shaped and lacking both striations and enamel. Description: The dentary is complete except for a length of approximately 1 mm anteriorly where the symphysial area is broken away. The remaining portion is 13.5 mm 51 long and has nine teeth in place. Two additional teeth are broken off, and there are spaces for five more, making a total of 16 teeth in the tooth row. It does not appear that more than one tOOth, if any, is missing anteriorly. The coronoid reaches as far anteriorly as the pos- terior border of the last tooth. The splenial scar extends from the coronoid area around ventrally flattening out in the middle portion of the bone, and then extends on forward to the anterior ventro-lateral margin. The dorsal portion of the anterior inferior alveolar foramen is evident below the sixth tooth from the back. The angular-surangular notch lies under the fifth tooth from the back. The teeth are pleurodont, widely spaced, and extend about one fourth their height above the external margin of the jaw. The teeth of most of the tooth row are extremely anterio—posteriorly compressed, with a very slight recurva- ture at the top. The posterior teeth are not so strongly compressed and are straight rather than recurved. In dorsal aspect, all but the back four teeth are very acute on the occlusal surface. All teeth lack striations and enameloid crowns . 52 Figure 15. Gerrhonotus insolitus dentary, Holotype (MUVP9278): a. lingual view, b. dorsolateral view. Remarks: The relationship of Gerrhonotus insolitus to extant and fossil species of Gerrhonotus is unclear. According to Meszoely (1970), the teeth in most species of Gerrhonotus are recurved and somewhat pointed in the ante— rior part of the jaw, but become erect with chisel-shaped, laterally compressed crowns posteriad. This pattern is very different from that seen in S. insolitus which has the anterior and middle teeth erect, anterio—posteriorly com- pressed, and chisel-shaped, and the most posterior four or five teeth lower, wider, and less acute. The presence of a fossil Gerrhonotus dentary with teeth similar to Recent S. leiocephalus in the Mic-Pliocene Valentine Formation of Nebraska (Meszoely, 1970) and the presence of S. mungerorum from the lower Pliocene of Kansas (Holman, in press) with teeth similar to Recent Gerrhonotus in having striations and enamel indicates that the evolution of the genus Gerrhonotus was well under way, if not completed, by late 53 Pliocene times. Therefore, since all members of that genus have dental characteristics in common which are not shared by S. insolitus, it is felt that that species is not ances- tral to a Recent species but rather represents a local aberrant sidebranch of a member of the genus Gerrhonotus, probably S. leiocgphalus, since that species occurs near the fossil site today. The secondary loss of enameloid tips and striations on the teeth and the development of such strongly anterio-posteriorly compressed teeth, and the reduction in tooth number, was probably in response to specialized food habits of the species. Family Iguanidae Phrynosoma cornutum Harlan Material: Sixteen dentaries, 12 maxilla, three fron- tals, one parietal, MUVP9279. Remarks: According to Etheridge (1960), Phrynosoma cornutum is the only species of Phrynosoma in which the lateral face of the dentary drops steeply from the lateral alveolar border to meet the flat ventral face of the ele- ment in an acute angle. All other species of Phrynosoma are more rounded laterally or have ornamentation along the ventrolateral margin of the dentary. The fossil elements have been referred to S. cornutum since they are similar to that species in all major details. 54 In four out of the 16 dentaries of Phrynosoma cornutum, Meckel's groove is Open as in the Recent species. In the other 12, however, the upper and lower borders of Meckel's groove are in contact anterior to the distal extremity of the splenial. This situation is apparently normal for late Pliocene S. cornutum as evidenced by both Open and closed Meckelian grooves in the Rexroad Locality Number 3 S. cornutum dentaries. Phrynosoma cornutum occurs in Scurry County, Texas, today and is known as a fossil from the Pliocene and Pleisto- cene of North America. S. cornutum is typically a lizard of dry, flat, open terrain with sparse plant cover. It is also found in areas of mesquite or prickly pear, on sandy, rocky, or loamy soil (Conant, 1958). Genus Sceloporus Sceloporus olivaceus Smith Material: Twenty-six dentaries, 15 maxilla, five frontals, MUVP9280. Remarks: ScelOporus olivaceus can be distinguished from all other species of ScelOporus in Texas by size. S. cyanogenys and S. poinsetti are larger, and S. grammicus, S. variabilis, and S. undulatus are smaller than S. olivaceus. See Table l. The dentaries of the members of the genera Holbrookia and Urosaurus are similar to those of 55 Sceloporus, but all Texas species of those genera are much smaller than S. olivaceus. Table 1. Comparison of body length and dentary length in Texas species of Sceloporus. 7 Max. Body Lengtha X Dentary Length N S. cyanogenys 141 19.8 1 S. ggammicus 75b 8.9 3 g S. olivaceus 100 13.0 6 S. poinsetti 125 17.5 2 S. undulatus 84 8.5 6 S. variabilis 53 8.6 6 aBlair, W. F. 1968. Vertebrates of the United States. bEstimated from Conant, 1958. The fossil dentaries are indistinguishable from Recent Sceloporus olivaceus in tooth form, tooth count, and in most details of bone shape. The Meckelian groove is closed in Recent S. olivaceus, but in six out of 26 of the late Pliocene S. olivaceus dentaries the Meckelian groove is open. This situation parallels that seen in Recent and late Pliocene Phrynosoma cornutum (Etheridge, 1960). ScelOporus olivaceus occurs today in Scurry County, Texas, and has not been reported previously as a fossil. This species is usually seen in trees but can also be found 4 _ z. 56 in patches of prickly pear, or in other places that offer shelter in the form of cracks or cavities (Conant, 1958). Sceloporus undulatus Latreille Material: Eight dentaries, seven maxilla, MUVP9282. Remarks: Sceloporus grammicus, S. undulatus, and S. variabilis can be separated from S. olivaceus, S. poin— setti, and S. cyanogenys by the smaller size of the former three species. Sceloporus grammicus is smaller in size and has a deeper depression on the lateral face of the dentary for the insertion of the adductor mandicularis muscle than does S. undulatus. According to Holman (1968b), all of the teeth in the posterior half of the dentary are very dis- tinctly tricuspid in S. undulatus. The fossil elements are indistinguishable from Recent S. undulatus. Sceloporus undulatus is a widespread species which occurs in Scurry County, Texas, today. It is known as a fossil from the Pleistocene (Illinoian) of Texas and Kansas. This species is often seen on rotting logs or stumps and will often climb a nearby tree when frightened. Sceloporus undulatus frequently occurs in open pine woods (Conant, 1958). 57 Sce10porus cf. robustus Twenty Material: Five dentaries, three maxilla, MUVP9281. Remarks: The fossil elements tentatively assigned to Scelgporus robustus are comparable in size, but very slightly larger, than Recent S. undulatus. They are dis- tinguished from all other Texas species of Sceloporus except for S. grammicus in possessing a deeper excavation on the posterio-lateral surface of the dentary for the insertion of the adductor mandibularis muscle. S. grammicus is distinctly smaller than S. robustus and the fossil ele- ments. The fossil dentaries are similar to S. robustus in bone shape and in having relatively heavy and transversely compressed teeth, but differ from S. robustus in lacking trilobate posterior teeth. This difference may be only due to wear, but until more fossils are recovered, it is felt that the fossils should tentatively be referred to S. robustus. The presence of three species of Sceloporus in the Beck Ranch Fauna raises the question of possible ecological rela- tionships of the three forms. Three species of Sceloporus occur together today in central Texas, Sceloporus poinsetti, S. olivaceus, and S. undulatus. Sceloporus poinsetti is primarily a boulder or rock species, and is most frequently found in limestone bluffs (Smith, 1946). Scelgporus olivaceus is primarily arboreal, spending most of its time in mesquite, oak, pecan, or elm trees (Smith, 1946). 58 Scelgporus undulatus is a species of sandy flats with sparse vegetation (Holman, 1968b). Presuming that S. olivaceus and S. undulatus have not changed ecologic- ally since early Blancan times, this situation leads to 1‘s“. 5 the speculation that S. robustus may have been the ecologi- '.l|r cal equivalent of S. poinsetti. If that is the case, then S. robustus was a species which preferred rocky areas. Sceloporus robustus is known as a fossil species from a the Upper Pliocene of Kansas. Family Scincidae Genus Eumeces Eumeces obsoletus Baird and Girard Material: Two dentaries, three maxilla, MUVP9276. Remarks: These fossils differ from all extant species of Eumeces in Texas except Eumeces obsoletus and S. laticeps on the basis of their larger size. According to Holman (1972a), the maxillary teeth of S. obsoletus are higher crowned and taper less abruptly to a point than in S. laticeps. In this respect, the fossils are similar to S. obsoletus. The fossils have been compared with specimens of Eumeces striatulatus from the Rexroad Locality Number 3 and Fox Canyon. In addition to being smaller than S. striatulatus, the fossil dentaries have 10 teeth in a space of 4 mm as does S. obsoletus rather than six or seven as does 59 S. striatulatus. The fossil elements have, therefore, been referred to S. obsoletus. Eumeces obsoletus occurs in Scurry County, Texas, today and is known as a fossil from the Pleistocene (Sangamon). This species is found chiefly in rough country, including limestone outcrOps and grassy or partially wooded hillsides, but also on Open plains, Often in sandy areas, and where numerous mammal burrows offer shelter (Conant, 1958). Emueces striatulatus Taylor Material: Eleven dentaries, nine maxilla, one parietal, MUVP9277. Remarks: The fossil elements are distinctly larger than all extant species of Eumeces in Texas. The general character of the teeth is most similar to Eumeces obsoletus among Recent forms, but the teeth are wider and longer in S. obsoletus than in S. striatulatus. There are six or seven teeth in a space of 4 mm in S. striatulatus and in the Beck Ranch fossils whereas there are nine or 10 in a similar space in S. obsoletus (Taylor, 1941). The fossils have been referred to S. striatulatus since they are simi- lar to that species in these characters. The occurrence of Eumeces obsoletus and S. striatu- lus together in the same deposit makes it seem very unlikely that S. striatulatus is ancestral to S. obsoletus even though 60 the two species are obviously closely related. It seems more reasonable to postulate that both descended from a common ancestor earlier in the Pliocene or Miocene. Eumeces obsoletus, which reaches a maximum size of 125 mm, occurs today in central Texas with S. laticeps, which grows to 130 mm (Smith, 1946). A similar size rela- tionship exists between S. obsoletus and S. striatulatus in the Beck Ranch Fauna. Eumeces laticeps occurs in trees much more frequently than does S. obsoletus, which is found most frequently on grassy hillsides underneath loose, flat, limestone rocks (Smith, 1946). Possibly, correlated with the size relationship of the two species of the Beck Ranch Eumeces is also an ecological relationship such as that found today between S. obsoletus and S. laticeps.v If this is true, then S. striatulatus occurred primarily in wooded areas and spent much of its time in trees. Eumeces straitulatus is known as a fossil from the late Pliocene of Kansas. Family Teidae Genus Cnemidgphorus Cnemidophorus sexlineatus (Linnaeus) Material: Eleven dentaries, six maxilla, MUVP9275. Remarks: Two Recent species of Cnemidophorus, Cnemi- dOphorus sexlineatus and S. sacki gularis, occur in Texas. According to Taylor (1941), S. sacki gularis has the 61 posterior four or five teeth generally trilobed with the posterior lobe being nearly as distinct as the anterior, whereas trilobed teeth are normally absent in S. sexlineatus. The fossil dentaries are similar to S. sexlineatus in this character. Taylor (1941) also considers S. bilobatus dis- r} tinct from S. sexlineatus in having more slender and some- what more tapering, laterally compressed teeth with their bases closer together and upper parts widely separated. M Etheridge (1958) distinguishes the two species further by the number of mental foramen in the dentary. Cnemidophorus bilobatus has nine to 10, and S. sexlineatus has five to seven. On this basis, the fossils have been referred to S. sexlineatus. Cnemidgphorus sexlineatus does not occur in Scurry County, Texas, today but does occur approximately 30 miles west, 50 miles north, and 50 miles east of Beck Ranch. It is known as a fossil from the upper Pliocene to the Recent. This species prefers relatively dry areas where there is sandy or other loose soil and where there is short grass or other kinds of low vegetation (Holman, 1971). 62 Family Boidae Subfamily Erycinae Ongphis parvus n. sp. Holotype: One mid-dorsal vertebra with the accessory processes, neural spine, and posterior right corner of the neural arch broken off. MUVP9284. Figure 16. Horizon and type-locality: Beck Ranch local fauna, Blanco Formation, Blancan age, upper Pliocene, of Scurry County, Texas. Found on the property of Mr. Jimmie Beck, 10 miles E. Snyder, SW corner of NE quarter of NE quarter, Sec. 62, HTC Survey, Scurry County, Texas. Paratype: One nearly complete vertebra of an immature specimen, MUVP9285. Figure 17. Etymology: Latin, parvus, meaning small, referring to the small size of the species. Diggnosis: An Ogmophis that appears to be most closely related to a new Ogmophis species (Holman, MS) from the WaKeeyen local fauna (lower Pliocene, Clarendonian) of Trego County, Kansas, in its wide, distinct haemal keel, upward tilted prezygapophyses, laterally directed accessory processes, thicker posterior part of the neural spine than anterior part, division of the paradiapophyses into parapophyseal and diapophyseal segments, and parapophyses visible in dorsal view. Ogmophis parvus differs from the new Ogmthis species and S. compactus in being smaller and in having a wide oblanceolate haemal keel rather than an oblong one. 63 ior views. c. anter Ongphis parvus, vertebra Holotype (MUVP9284); ventral, b. 1 . . .. .x...w.... . ... . _. .:. .gmw... Far. . .41.. 33:31.6... . . , . ..... K. on a. Figure 16. lateral: a. 64 Description 9S Holotype: In dorsal view, the right postzygapophyseal area, the neural spine, and both acces- sory processes are broken off. The prezygapOphyses are nearly round. The posterior part of the neural arch is deflected posteriorly and laterally. The paradiapophyses are visible just posterior to the prezygapophyses. In lateral view, the base of the accessory process is visible and appears to have been well developed and directed slightly anteriorly. The paradiapophyseal surface is divided into two surfaces, the dorsal portion of which lies sl'ightlymore posteriad than the ventral portion. The subcentral ridges, which are fairly well developed, start at the paradiapophyses and continue forward one-half of the way to the condyle. A large fossa is present slightly below the interzygapophyseal ridges. The condyle is oblique to the long axis of the centrum. In ventral view, the centrum is triangular in shape and moderately short. The haemal keel is flat, wide, oblanceo- late, and distinctly raised from the floor of the centrum. The ventral edge Of the cotyle is thickened and flattened. A small portion of the ventral part of the condyle is broken off. The postzygapophyses are oval, and the ventral edge of the zygantrum can be seen. In anterior view, the condyle is oval, and the zygan- trum is well developed. The dorsal edge of the neural arch 65 is quite thick. The neural canal is round and approxi- mately the same size as the condyle. In posterior view, the prezygapophyses are slightly deflected upward. The cotyle is oval with a flattened bot- tom. The area lateral to the cotyle contains one very small foramina on the right side and a large, eroded one of the left side. The zygantrum is wider than the neural canal, indicating that the zygosphene was at least as wide as the neural canal. Description 9S Paratype: The paratype is similar to the holotype except that the neural canal is large as is found in immature individuals. The neural spine is com- plete except that the anterodorsal corner is broken off. The neural spine is low and moderately thick with the pos- terior part thicker than the anterior. The cavities lat- eral to the cotyle lack foramina. Figure 17. Ogmophis parvus vertebra, Paratype (MUVP9285), lateral view. 66 Remarks: Characters of Holman (MS) were used to place these vertebrae in the family Boidae. These char- acters include the following. The vertebrae are higher than long, the subcentral ridges are arched, the postzygapophyseal part of the neural arch is upswept, and the neural spine is thick. Holman also considers the lack of foramina in the cavities on either side of the cotyle one of the char- acters diagnostic of boids. This appears to be true, but the presence of foramina in those cavities does not neces- sarily indicate that the vertebra is not a boid. In one specimen of Charina bottae, approximately one-fourth of the vertebrae had at least one foramen on each side of the cotyle. The absence or presence of the foramina does not appear to be correlated with any particular area of the vertebral column. Therefore, Ogmophis parvus is considered to be a boid even though the foramina are present in the type vertebra. The fossil vertebrae were placed in the genus Ogmophis on the basis of having a long neural spine which is thick and apparently unnotched anteriorly, of having a broad, distinct haemal keel, and of having moderately well-develOped accessory processes. Ogmophis parvus seems to be a late Pliocene represen- tative of the evolutionary line of S. compactus from the Oligocene of the Saskatchewan to the new Ogmophis species from the lower Pliocene of Kansas. See Figure 18. Trends 67 which seem to be evident in the group are a decrease in size, thinning and lengthening of the neural spine, move- ment of the accessory processes from an anterior direction to a lateral direction, thinning of the haemal keel anteri- orly, and increasing distinctness of the parapOphyseal and diapophyseal facets of the paradiapOphyses. ll. aloe. o. qua: I. PLIOC. L. moo. wanna moms macs»: 0. mm: OLIGOCENE sec-news Figure 18. Hypothetical phylogenetic relationships of the Ongphis compactus evolutionary line. 68 Family Colubridae Subfamily Xenodontinae Heterodon platyrhinos Latreille Material: Fifty—nine vertebrae, MUVP9288. Remarks: Only two extant species of Heterodon, Heterodon nasicus and S. platyrhinos, occur today in Texas. The vertebrae of S. platyrhinos are longer and narrower than those of S. nasicus and the zygosphene of S. platyrhinos tends to be convex when viewed from the rear. Holman (1963) also considers the anterior borders of the prezygapOphyseal faces flatter in S. platyrhinos than in S. nasicus. Auffenberg (1963a) described Heterodon brevis frOm the middle Pliocene of Florida, a species he considers ances- tral to S. platyrhinos. The main difference between the two species is the shorter neural spine base in S. brevis (centrum length/neural spine base=2.07 in S. brevis and =1.32 to 1.82 in S. pSatyrhinos). Similar measurements in the Beck Ranch S. platyrhinos vertebrae yielded a range of 1.43 to 2.08. The prezygapophyses of the Beck Ranch S. plagyrhinos are directed slightly more anteriorly, and the accessory processes are more blunt than in Recent S. platyrhinos . This may indicate either that the validity of S. brevis is Open to question since both short and long neural spine bases occur together in a single population; or that 69 the Beck Ranch S. platyrhinos was evolutionarily inter- mediate between the two species. Heterodon platyrhinos occurs today in Scurry County, Texas, and is known as a fossil from the late Pliocene and Pleistocene. This species prefers dry areas where ample sunlight reaches the ground. These snakes can be found in dry woods, sandy river shores, or in sand dunes, but they tend to avoid moist or heavily wooded areas (Holman, 1971). Heterodon plionasicus Peters Material: Fifty-two vertebrae, MUVP9289. Figure 19. Remarks: The vertebrae of Heterodon nasicus and S. plionasicus are shorter and broader than those of S. platyrhinos. S. plionasicus is a larger species than S. nasicus and the anterior dorsal edge of the zygosphene is flat in S. plionasicus but slightly upturned at the sides in S. nasicus (Brattstrom, 1967). The Beck Ranch S. pSionasicus vertebrae range in size up to a maximum of 9 mm long, much larger than that seen in Recent S. nasicus, but the anterior dorsal edge of the zygosphene is slightly upturned in some, but not all, of the specimens. This vari- ability further supports Brattstrom's (1967) contention that the transition from S. plionasicus to S. nasicus occurred in the uppermost Pliocene to earliest Pleistocene. Heterodon plionasicus is known as a fossil species from the late Pliocene of Kansas. Its habitat is unknown -Ell‘.\ n‘.‘ S 70 but is presumed to be similar to its descendent species, S. nasicus, which prefers relatively dry and sandy prairie areas (Conant, 1958). Figure 19. Heterodon plionasicus, vertebra (MUVP9289); a. dorsal, b. ventral views. Subfamily Natricinae Genus Natrix Natrix erythrogaster (Forster) Material: Nineteen vertebrae, MUVP9292. Remarks: These vertebrae are assignable to Natrix rather than to Thamnophis because of their larger size and higher neural spines (Holman, 1971). There are four large extant species of Natrix which range into Texas, Natrix §i22§92. S. eryghrogaster, S. rhombifera, and S. cyc10pion. )ne ?lf he the am 385 l9( 1 In 181 th: Te. of f0 71 One fossil species, S. hibbardi, is known from the upper Pliocene. According to Holman (1962, 1968a, 1970, 1971), these species can be separated by neural spine height. The neural spine of S. sipedon and S. hibbardi is longer than high, that of S. erythrogaster is as long as high, and that of S. rhombifera and S. cyclopion is higher than long. On the basis of the above criteria and on the basis of range, the fossil vertebrae have been assigned to S. erythrogaster. Natrix erythrogaster and S. fasciata from the south- eastern U.S. are similar in neural spine height (Holman, 1968a), but my observations indicate that the two species can be separated by the posterior edge of the neural spine. In S. erythrogaster, the posterior edge of the neural spine tends to be more angular than in S. fasciata, although there is some overlap in this character. The fossil verte- brae from Beck Ranch agree with S. erythrogaster in this character. Natrix erythrogaster (Forster) occurs in Scurry County, Texas, today and is known as a fossil from the Pleistocene of Texas (Holman, 1969a). This species is likely to be found wherever permanent or semipermanent water occurs. In the western part of its range, it follows rivers into what is otherwise arid country (Conant, 1958). 72 Natrix cf. hibbardi Holman Material: Thirty-five vertebrae, MUVP9293. Remarks: The fossil vertebrae were placed in the genus Natrix on the basis of characters discussed previously I: under Natrix erythrogaster. S. sipedon and S. hibbardi differ from all large Texas species of Natrix in having neural spines longer than high. Natrix hibbardi and S. sipedon are distinguished on characters of the mandible g and only very subtle vertebral differences (Holman, 1968a). Since the snake mandibular elements from the Beck Ranch Fauna are too fragmentary for specific identification, the two species cannot be separated with any degree of certainty. However, since S. hibbardi is temporally equivalent to the Beck Ranch fossils and since the Beck Ranch fossils and S. hibbardi have longer and more robust accessory processes than S. sipedon, the fossils have been tentatively referred to S. hibbardi. Natrix hibbardi is known only from the upper Pliocene of Idaho (Holman, 1968a). Since S. hibbardi is apparently ancestral to S. sipedon, their habitats are presumed to be somewhat similar. S. sipedon prefers the quiet waters of swamps, marshes, bogs, streams, ponds, and lakes, but swift- flowing streams are also inhabited (Conant, 1958). 73 Natrix gyclopion (Dumeril, Bibron, and Dumeril) or S. rhombifera (Hallowell) Material: Eight vertebrae, MUVP9291. Remarks: The vertebrae were assigned to the genus Natrix on the basis Of characters described previously under Natrix erythrogaster. The neural spines of S. cyclopion and S. rhombifera are higher than long. All other large species of Natrix in Texas have the neural spines as long as high or longer than high. I am unable to distinguish between the two species osteologically although S. rhombifera occurs approximately 280 miles closer to Scurry County than does S. cyclopion. Natrix rhombifera rhombifera (Hallowell) occurs within 50 miles and S. cyclopion cyglOpion (Dumeril, Bibron, and Dumeril) ranges to 330 miles east of Scurry County, Texas. S. cyclopion has been reported as a fossil from the middle or late Pleistocene (Haile I) (Auffenberg, 1963), but to my knowledge, S. rhombifera has not been found as a fossil. S. cyclopion prefers quiet bodies of water whereas S. rhombifera is a more ubiquitous species which follows rivers into arid country toward the western part of its range (Conant, 1958). 74 Natrix sp. indet. Material: One hundred seventy-nine vertebrae, MUVP9290. Remarks: I have been unable to identify these verte- brae beyond the generic level. Many represent the previously described species of Natrix. Genus ThamnOphis Thamnophis marcianus (Baird and Girard) Material: Nine vertebrae, MUVP9295. Remarks: Vertebrae of ThamnOphis were separated from those of Natrix on the basis of having lower neural spines and being smaller than those of Natrix (Holman, 1971). Five species of Thamnophis Occur in Texas, Thamnophis gyrtopsis, S. marcianus, S. radix, S. sauritus, and S. sirtalis. According to Holman (1962), the neural spines of S. sirtalis and S. sauritus are higher than those of S. marcianus and S. radix. He also says (1972b) that S. sirtalis and S. sauritus have the anterior and posterior borders of the neural spine gently curved or straight whereas S. marcianus and S. radix have these borders deeply concave. S. cyrtgpsis is a smaller species than repre- sented by the fossil vertebrae and has the neural spine lower than in the other four species. I am unable to sep- arate S. marcianus from S. radix on the basis of osteologi- cal characters, but the southern limit of the range of 75 S. radix is 230 miles to the north of Beck Ranch whereas T. marcianus occurs in Scurry County, Texas. The fossil vertebrae are, therefore, referred to S. marcianus on the basis of range. Thamnophis marcianus (Baird and Girard) occurs in Scurry County, Texas, today and has previously been tenta- tively identified as a fossil from the Pleistocene (Kansan) of Texas (Holman, 1969a). This snake lives in arid country but seldom strays far from streambeds, springs, or other places where water is present (Conant, 1958). Thamngphis sirtalis (Linnaeus) Material: Six vertebrae, MUVP9296. Remarks: These vertebrae were separated from Natrix and species of Thamnophis except for Thamngphis sauritus and S. sirtalis on the basis of characters of Holman (1962) described previously under S. marcianus. One character of Holman (1962) separates most S. sirtalis from most S. sauritus. In S. sirtalis, the accessory processes are at right angles to the centrum whereas in S. suaritus they are directed more anteriad. The fossil vertebrae are similar to S. sirtalis in this character and have, therefore, been referred to that species. The western limit of the range of Thamnophis sirtalis annectens (Linnaeus) is approximately 100 miles to the east 76 of Beck Ranch. This species is known as a fossil from two Pleistocene (Kansan, Wisconsin) localities in Texas (Holman, 1969a). In the western part Of its range, this species occurs wherever water is found, and it follows watercourses, even intermittent ones, far into arid country (Conant, 1958). Thamnophis sp. Material: Twelve vertebrae, MUVP9294. Remarks: These vertebrae were separated from those of Natrix on the basis of characters of Holman (1962). I am unable to assign them to species but they seem to represent one or both of the Thamnophis species previously discussed. Subfamily Colubrinae Genus Elaphe Elaphe guttata ssp. indet. Linnaeus Material: Twelve vertebrae, MUVP9298. Remarks: The vertebrae of Elaphe are very simi- lar to those of Arizona, Pituophis, and Lampropeltis (Holman, 1959). They differ from Pituophis in having a lower neural spine, and from Arizona in having the acces- sory processes much blunter and less delicate (Holman, 1970). From Lampropeltis, they differ in having a much 77 less depressed neural arch (Auffenberg, 1963a) and straighter subcentral ridges brom below (Brattstrom, 1955). The neural spine of Elaphe guttata and the fossil vertebrae is higher than that of S. nebraskensis, S. pliocenica, S. vulpina, and S. kansensis but lower than that of S. obsoleta. The fossil vertebrae are indis- tinguishable from Recent S. guttata, but I am unable to determine which subspecies they belong to. Expahe guttata emoryi (Baird and Girard) occurs today in Scurry County, Texas. Elaphe guttata is known as a fossil from the Pleistocene. Today the species prefers canyons, rocky draws, or hillsides rather than open plains or prairies. It is secretive and essentially nocturnal during warm weather, hiding beneath stones or in rock crevices during the day (Conant, 1958). Elaphe obsoleta Say Material: Five vertebrae, MUVP9299. Remarks: The fossil vertebrae assigned to Elaphe obsoleta were separated from the similar genera Pituophis, Arizona, and LamprOpeltis on the basis of characters dis- cussed previously under Elaphe guttata. The fossil ver- tebrae are similar to S. obsoleta in having higher neural spines than in S. nebraskensis, S. pliocenica, S. guttata, and S. vulpina. The haemal keel of S. kansensis is more 78 flattened, and the neural spine is lower than that found in S. obsoleta and the fossil vertebrae. Eighty-nine vertebrae are considered to belong to either Elgphe gpttata or S. obsoleta, but have the neural spines broken off so I am unable to assign them to species since the vertebrae of the two species are very similar except for neural spine height. The western limit of the range of Elaphe obsoleta lindheimeri (Baird and Girard) is 60 miles to the east of Beck Ranch. Elaphe obsoleta is known as a fossil from the Pliocene and Pleistocene. This snake lives in a variety of habitats, ranging from bayou and swampy coun- try in eastern Texas to woods, stream valleys, and rocky canyons in the western part of its range (Conant, 1958). Elaphe vulpina Baird and Girard Material: Fifty-six vertebrae, MUVP9301. Remarks: Elaphe vulpina is distinguished from similar genera and other species of Elaphe except for S. kansensis, S. nebraskensis, and S. pliocenica, by characters discussed previously under S. guttata and S. obsoleta. Elaphe kansensis, S. nebraskensis, S. pliocenica, S. vulpina, and the fossil vertebrae are similar in having low neural spines. The fossil vertebrae and S. vulpina differ from S. kansensis in lacking the flattened haemal 79 keel (sharper in S. vulgina), and in being smaller than S. kansensis. flflmaprezygapophyses and accessory pro- cesses of S. nebraskensis are directed much more laterally than in S. vulpina (Holman, 1964b). Elaphe pliocenica dif— ‘ fers from S. vulpina in having a much thicker neural spine r} and a stronger, thicker haemal keel than the latter species (Holman, 1968a). The fossil vertebrae are similar to S. vulEina in all of the above characters. 9 The southern limit of the present range of Elaphe vulpina vulpina (Baird and Girard) is approximately 500 miles north of Scurry County, Texas. This species has been reported previously from the upper Pliocene of Idaho, the late Pleistocene of Arkansas, and the late Pleisto- cene of Missouri (Holman, MS). These fossil occurrences indicate that the fossil range of this species was much more southern than its present range. Elaphe vulpina occurs in prairies, stream valleys, woods, and dune country in the western part of its range (Conant, 1958). Pituophis melanoleucus say; (Schlegel) Material: Seventy-nine vertebrae, MUVP9305. Remarks: The vertebrae of Pituophis are most simi- lar to those of the genus Elaphe. According to Auffenberg (1963a), Pitquhis has a concave zygosphene from above (rarely so in ElaEhe), more developed epizygapophyseal spines (weak in Elaphe), and a higher neural spine than 80 in Elaphe. The neural spines of the vertebrae of Pitquhis melanoleucus sayi are lower than those of the southeastern species, S. S. mugitus (Holman, 1972b). The fossil vertebrae have, therefore, been referred to 3- E- £211- Pituophis melanoleucus sayi (Schlegel) occurs in Scurry County, Texas, today and is known as a fossil from the upper Pliocene and Pleistocene. This snake is a resident of the plains and prairies, often lurking in clumps of vegetation and mammal burrows (Conant, 1958). Rhinocheilus lecontei Baird and Girard Material: Eleven vertebrae, MUVP9304. Remarks: The vertebrae of Rhinocheilus are quite characteristic (Holman, 1969b). They can be separated from all other North American snake genera by the combi- nation of characters listed by Hill (1971). I cannot distinguish these vertebrae from Recent Rhinocheilus lecontei. Rhinocheilus lecontei Baird and Girard occurs in Scurry County, Texas, and has been reported twice pre- viously as a fossil from the Pleistocene of Texas (Holman, 1969a). This species is a resident of deserts and dry prairies. It is mainly nocturnal, spending daylight hours hidden among rocks or debris or in mammal burrows (Conant, 1958). 81 Genus Lampropeltis Lampropeltis getulus ssp. indet. Linnaeus Material: Thirty—four vertebrae, MUVP9302. Remarks: The vertebrae of Pituophis, Elaphe, and Lampropgltis are very similar but have been separated on the basis of characters of Holman (1965b). Pituophis is distinct from the other two genera in having a higher neural spine with an indented anterior edge. The genera ElaEhe and Lampropeltis can usually be separated by the more depressed neural arch of Lampropeltis. LamprOpeltis getulus can be distinguished from S. triangulum, S. zonata,_ and S. pyromelana since the latter species all have lower neural spines and tend to be smaller in size than S. getulus (Holman, 1965b). Lampropeltis calligaster and S. intermedius both have the tOp of the zygosphene sloping down- wards when viewed anteriorly, whereas the top of the zygo— sphene is flat in S. getulus (Brattstrom, 1955). Lamjgroieltis similis differs from S. getulus in having the top of the zygosphene gently curved rather than straight as in S. getulus (Holman, 1964b). The subspecific status of the fossils could not be determined. Lampropeltis getulus §plendida (Baird and Girard) occurs in Scurry County, Texas, today and is known as a fossil from the Pleistocene. This species is most often found near streams in the arid southwest and tends to be 82 chiefly nocturnal in order to avoid high temperatures and dessication (Conant, 1958). Lampgopeltis triangulum ssp. indet. (Linnaeus) Material: Sixteen vertebrae, MUVP9303. Remarks: These vertebrae were placed in the genus Lampropeltis on the basis of characters discussed pre- viously under LamprOpeltis getulus. Vertebrae of S. triangulum, S. zonata, and S. pyromelana have lower neural spines and are smaller in size than those of S. getulus (Holman, 1965b). On the basis of geographic range, the fossils have been assigned to S. triangulum. Insufficient comparative material is available to assign the vertebrae to a subspecies of S. triangulum. Lampropeltis triangulum does not occur in Scurry County, Texas, today, but S. S. gentilis (Baird and Girard) ranges south to 140 miles north of Beck Ranch. The range of S. S. amaura (Cope) extends west to 210 miles east of Beck Ranch and S. S. annulata (Kennicott) extends north to 100 miles south of the fossil locality. This species is known as a fossil from the Pleistocene. It occupies a wide variety of habitats, including Open prairies, wooded stream valleys, and rocky canyons Conant, 1958). 83 Coluber constrictor Linnaeus Material: Forty-five vertebrae, MUVP9307. Remarks: The vertebrae of the genera Coluber and MastiCOphis are very similar but can be separated with characters of Hill (1966) and Brattstrom (1955). Accord- ing to Hill (1966), the haemal keels of the middle pre- caudal vertebrae are straighter in lateral view in MastiCOphis than in Coluber constrictor. Brattstrom (1955) considers the genera separable on haemal keel characters also. The haemal keel is narrow, thin, and ends anteriorly at the edge of the centrum cup in S. constrictor and is thick, flattened, and ends prior to the cup in Masticophis. My observations indicate that the first character is useful in separating the two gen- era. There is a continuous range of variation in the second character, indicating that it is not diagnostic. The Beck Ranch vertebrae assigned to Coluber constrictor were identified using Hill's criterion and are indistinguishable from Recent specimens. Coluber constrictor foxi (Baird and Girard) occurs in Scurry County, Texas, today. This species is known as a fossil from the Pleistocene to the Recent. Coluber constrictor in Texas occurs in fields and grasslands, brushy areas, and open woods, and will often take refuge in clumps of vegetation, mammal burrows, or in stone or rock piles (Conant, 1958). 84 Masticophis cf. flagellum Shaw Material: Thirty-five vertebrae, MUVP9306. Remarks: Vertebrae of MastiCOphis were separated from those of Coluber on characters discussed previously under Coluber constrictor. The vertebrae have been ten- tatively referred to MastiCOphis flagellum since that species occurs in Scurry County today. The northern limit of the only other species of MastiCOphis in Texas, S. taeniatus, is 90 miles south of the fossil locality. I am unable to separate the two species on the basis of osteological characters. MastiCOphis flagellum testaceus (Say) occurs in Scurry County, Texas, today. Masticophis flagellum is known as a fossil from the Pleistocene (Illinoian). This species occurs in grasslands, mesquite savannas, arid brushlands, and numerous other Open habitats (Conant, 1958). Family Crotalidae Genus Agkistrodon Agkistrodon contortrix Linnaeus Material: Eight vertebrae, MUVP9309. Remarks: According to Holman (1963, 1965b), verte- brae of the genus Agkistrodon can be distinguished from those of Crotalus in having a distinct pit on either side 85 of the centrum which contains one moderately large fossa (in Crotalus, the pits are usually absent and one or more fossae occur on either side of the cotyle). Agkistrodon and Crotalus are distinct from Sistrurus in lacking the tiny spine just anterior to the neural spine which is present in Sistrurus and in having prezygapOphyses which are level rather than tilted upward as in Sistrurus. Two species of Agkistrodon occur in Texas, Agkistrodon contortrix and A. piscivorus. Agkistrodon piscivorus is a larger species with a relatively larger condyle than A. contortrix and the fossil vertebrae, so the fossils have been referred to A. contortrix. I cannot distin- guish the fossil A. contortrix from Recent specimens. Agkistrodon contortrix laticinctus (Gloyd and Conant) occurs in Scurry County, Texas, today. This species is known as a fossil from the Pliocene (Claren- donian) (Holman, 1964a), and from the Pleistocene (Wis- consin) (Holman, 1969a). This is mainly a snake of the lowlands, of low ground near swamps, and cypress-bordered streams (Conant, 1958). 86 Genus Crotalus Crotalus atrox Baird and Girard Material: Fourteen vertebrae, MUVP9310. Remarks: The vertebrae of Crotalus were separated from Agkistrodon and Sistrurus by characters discussed previously under Agkistrodon contortrix. Five species of Crotalus occur in Texas, Crotalus atrox, S. horridus, S. lepidus, S. molusus, and S. viridis. Crotalus lepidus and S. molusus are smaller species than is represented by the fossil vertebrae. The zygosphene of S. atrox and the fossil vertebrae is relatively wider and longer than that of S. horridus and S. viridis, so the vertebrae have been referred to S. atrox. Crotalus atrox Baird and Girard occurs in Scurry County, Texas, today and is known as a fossil from the Pleistocene (Illinoian) of Texas (Holman, 1969a). This is a species of the arid southwest, occurring in the low- lands, desert flats, rocky cliffs, and canyons (Conant, 1958). Genus Sistrurus Sistrurus catenatus (Rafinesque) Material: Six vertebrae, MUVP9311. Remarks: These vertebrae were separated from those of Crotalus and Agkistrodon on the basis of characters discussed under Agkistrodon contortrix. Two species of 87 Sistrurus, Sistrurus catenatus and S. miliarius, occur in Texas. The neural spine of S. catenatus is straight anteriorly and extends up to the edge of the zygosphene whereas in S. miliarius the neural spine is concave anteriorly and does not usually reach the edge of the zygosphene. The fossil vertebrae are similar to S. catenatus in these characters and have, therefore, been referred to that species. Both Sistrurus catenatus tergeminus (Say) and S. S. edwardsi (Baird and Girard) occur in Scurry County, Texas, today. This species has been reported only once previously as a fossil. That record is from the Pleisto- cene (Yarmouth) of Kansas (Holman, 1972b). This is a snake of the plains and prairies which takes advantage of swampy areas where they exist (Conant, 1958). DISCUSSION Faunal, topographic, and geological evidence indicates that the Beck Ranch Fauna represents a wooded stream valley with adjacent higher grassland areas such as those seen in the Texan biotic province today. The climate appears to have been more equitable than at present but in a state of deterioration. Comparisons with the Rexroad Locality Number 3 Fauna show a high degree of similarity in faunal composition and age. Differences seem to be primarily due to differences in faunal size and to the more southern location of the Beck Ranch Fauna. Paleoecology: The Beck Ranch herpetofauna appears to be a mixture of species from the Austroriparian and Kansan biotic provinces of Texas (as redefined by Blair, 1950) since every extant species in the fauna except for Elaphe vulpina occurs in one or the other or both of these biotic provinces. Scurry County, Texas, lies in the Kansan biotic province, but the western limit of the Austroriparian is 300 miles to the east of Scurry County. Today, the Austroriparian and Kansan are separated by the Texan biotic province which is a broad ecotonal area between the forests of the Austroriparian and the grasslands 88 89 of the Kansan (Figure 20). Today, tall-grass prairies of the Texan biotic province are barriers to the westward distribution of forest-inhabiting Austroriparian species. Interdigitation of faunas occurs in areas where Austro- riparian species extend westward along wooded stream valleys while western, grassland species occupy the adjacent uplands (Blair, 1950). Thus, the mixture of elements in the Beck Ranch herpetofauna is considered to be due to the presence of a wooded stream valley near a higher grassland area. Extant Austroriparian species in the fauna include Alligator mississipiensis, Elaphe obsoleta, Ambystoma Opacum, the plethodontids, Rana areolata, Rana palustris, and Bufo valliceps. Of these, AmSystoma opacum, the plethodontids, and Rana palustris are characteristic species of the eastern deciduous forest biociation (Kendeigh, 1961) which is found in the northern part of the Austroriparian in Texas. Therefore, it is felt that the late Pliocene wooded stream valley supported a pine- oak forest corridor which extended at least as far west as Scurry County, Texas. The major dominants of the pine- oak forest listed by Tharp (1939) include loblolly pine, yellow pine, red oak, postoak, and blackjack oak. The climate of the pine-oak forest region is considered to be moist, subhumid (Blair, 1950). 9O /' /- / E l/ z 6 I i 55 I ; 5 l I | 5.7 ~ nus“ \ . ‘\ \ I by \_ ./ \ f\ l,‘ l g \l \ \\~ /// ‘\\~__,/ ‘) : a; ‘( \\ BALCONIAN I ' I g z I ‘ ( 3 ‘\ l a x‘ .- {u MILII'AN cumunwnu ' I I l \1 Figure 20. Approximate boundaries of the biotic provinces in Texas as proposed by Blair (1950). Redrawn from Blair (1950). 91 Extant grassland species:h1the fauna which extend into the Texan from the Kansan biotic province include Kinosternon flavescens, Terrapene ornata, Phgynosoma cornutum, ScelOporus olivaceus, Eumeces obsoletus, Thamnophis marcianus, Elaphe guttata, Pituophis melanoleucus sayi, Rhinocheilus lecontei, Crotalus atrox, Sistrurus catenatus, and Bufo cognatus. Today, grassland areas of the Texan biotic province are characteristically tall-grass prairie. Major dominants, as listed by Tharp (1926), are Aggopyron smithii, Andropogon saccharoides, Andropogon scoparius, Stipa leucotricha, and Triodia pilosa. Extant species in the Beck Ranch Fauna which are too widespread to be used as ecological indicators include Ambystoma tigrinum, Acris crepitans, Bufo woOdhousei woodhousei (edge only of the Austroriparian), Rana pipiens, Chrysemys picta, Pseudemys scripta (elegans), Sceloporus undulatus, Cnemidophorus sexlineatus, Heterodon platyrhinos, Coluber constrictor, MastiCOphis flggellum, Natrix erythrogaster, Natrix rhombifera (S. cyclOpion is asso- ciated with the Austroriparian), ThamnOphis sirtalis, Lampropeltis getulus, Lampropeltis triangulum, and Agkistrodon contortrix. The fossil range of Elaphe vulpina has been shown to be much greater than its present range. Today, this species occurs in prairies, stream valleys, and woods in the western part of its range so 92 is considered to have been associated with both biotic provincesixithe late Pliocene. The ecological requirements of the fossil species in the Beck Ranch Fauna are uncertain but can be partially deduced from the preferences of the closely living rela- tive of the extinct species and from the occurrence of the species in other deposits. Ambystoma hibbardi, Amphitriton brevis, ScaphiOpus diversus, Bufo rexroadensis, Geochelone rexroadensis, Sceloporus robustus, Eumeces striatulatus, and Heterodon plionasicus occur in both the Rexroad Fauna and in the Beck Ranch Fauna. Hibbard (1941) considers the Rexroad Fauna to represent an upland grass community and a major stream valley with areas of meadows, marshes, and trees. He also considers the climate to have been more equitable and humid than at present in Meade County, Kansas. These Rexroad habitats are similar to those available in the Texan biotic province so it is likely that the above species occur in one or more of the above-listed habitats. The closest living relative (and probable descen- dent species) of chphigpus diversus is Scaphiopus bombifrons (Tihen, 1960). Scaphiopus bombifrons occurs on the Great Plains and is a species of the open grass- lands, avoiding river bottoms and wooded areas (Conant, 1958), so it is likely that S. diversus was associated with the grassland element of the Beck Ranch Fauna. 93 Heterodon plionasicus is ancestral to S. nasicus (Brattstrom, 1967), so the habitat of S. plionasicus is presumed to be similar to S. nasicus which prefers rela- tively dry and sandy prairie areas. A species which does not occur in the Rexroad Fauna but which is closely related to a living species is Natrix hibbardi. Natrix hibbardi is closely related to S. sipedon (Holman, 1968a), which prefers the quiet waters of swamps, marshes, bogs, streams, ponds, and lakes, but swift-flowing streams are also inhabited (Conant, 1958). Thus, the affinities of Natrix hibbardi are presumed to be with the Austroriparian. The probable habitat preferences of the extinct species known only from the Beck Ranch Fauna are obscure. These species include Geochelone beckensis, Gerrhonotus insolitus, and Ogmophis parvus. Geochelone beckensis is ancestral to a Pleistocene line which became extinct so no habitat preferences can be deduced. Ongphis parvus is descended from the early Pliocene new Ogmthis species from the WaKeeney Fauna which has.unknown ecological requirements although Holman (MS) concludes that the climate and vegetation of the WaKeeney, Kansas, area must have been different than today, with warmer winters with few if any frosts, and a vegetation similar to that found in southeastern Texas along the coastal regions today. Gerrhonotus insolitus is considered to be a local variant 94 of Gerrhonotus leiocephalus. Differences in dentition indicate that the two species had different diets. Gerrhonotus leiocephalus prefers rocky hillsides among bushes (Smith, 1946, p. 464). Whether or not S. insolitus had similar habitat preferences is unknown. In summary, 10 species (21%) of the Beck Ranch Fauna are considered to belong to the Austroriparian biotic province, 12 species (25%) are considered to belong to the Kansan biotic province, 17 species (35%) occur in both provinces, and the habitats of seven species (14%) are unknown but are apparently similar to habitats found in the Texan biotic province today. Evidence of Hibbard (1960) indicates that the climate at Beck Ranch in the late Pliocene was more equit- able than it is today. Large land tortoises Such as Geochelone rexroadensis, which is present in the Beck Ranch Fauna, could not have survived freezing temperatures, but they may have existed in an area with very few light frosts at night, and daytime temperatures warming to 60 degrees Fahrenheit or more. Hibbard also cites the presence of Alligator as indicating a warm temperature, the presence of permanent water, and some vegetation; although he does note that alligators are more tolerant of cold temperature than are large herbivorous land tortoises. In order for Austroriparian species to range so much farther west, available moisture in the stream valley 95 would have to have been 20 to 40 percent higher than that available in the grassland areas (Blair, 1950). This increased moisture would-have acted to decrease fluctuations in daily temperatures (Hibbard, 1960). Topographic and geological evidence supports the hypothesis that the Beck Ranch Fauna represents a stream valley with adjacent higher grassland areas. Dalquest and Donovan (1973) consider the fossil-bearing deposit to have been formed in backwaters associated with a stream system that flowed southeasterly across the area in late Pliocene times. They also state that the eleva- tion of these fossil-bearing sediments is only 1700 feet, approximately 1000 feet below the caprock of the escarp— ment of the High Plains. Dalquest and Donovan (1973) feel that the unusual features of the Beck Ranch local fauna probably reflect influences of lowland habitat to the east of the High Plains. Therefore, the hypothesis of a low, moist river valley bordered by high, grassland areas is consistent with the topography of the area and seems to represent the true condition of the Beck Ranch area in late Pliocene times. There is some evidence in the Beck Ranch Fauna, however, of slight climatic deterioration. Increased thickness of the shells of land turtles was probably in response to slightly cooler nights or higher summer tem- peratures (Hibbard, 1960). It may also be that the 96 development Of more robust bone structure in populations of species such as Sceloporus robustus and Eumeces striatulatus was in response to this climatic deteriora- tion. Presumably, the increased thickness of the bone acted as an insulator to retard cooling and overheating in the poikilothermic animals. The following is a summary of the paleoecological evidence from the herpetofauna. The area around Beck Ranch in the late Pliocene had warmer winters with few frosts and a more equitable climate than at present. The area consisted of an upland region with a tall-grass prairie vegetation associated with a Kansan biotic prov- ince fauna and a lowland region up to 20 percent more humid than the upland area with a pine-oak forest type of vegetation and topography associated with an Austrori- parian biotic province fauna. Stratigraphic comparisons: The Beck Ranch local fauna is close to the age of the Rexroad Locality Number 3. Sixteen species and 19 genera of the Beck Ranch species are present in the Rexroad Fauna (Table 2). Extant species which occur in both faunas are Phrynosoma cornutum, Heterodon plagyrhinos, Coluber constrictor, Elaphe obsoleta, Pitugphis melanoleucus sgyi, Lampgopeltis getulus, Agkistrodon contortrix, and Sistrurus catenatus. Addi- tional species which may be present in both faunas are Bufo cognatus, Rana pipiens, and Rana areolata. Bufo 97 Table 2. Comparison of species from the Beck Ranch Fauna and from the Rexroad Locality Number 3 Fauna. . Beck Ranch Rexroad Locality SpeCies Fauna Number 3 Class Amphibia Plethodontidae species * - Ambystomatidae Ambystoma tigrinum } * - Ambystoma hibbardi * Ambystoma opacum * - Amphitritontidae Agphitriton brevis * * Pelobatidae Scaphiopus diversus * * Hylidae Acris crepitans * * (cf.) Bufonidae Bufo cognatus * ? (Tihen,l962a) Bufo rexroadensis * * Bufo §p§ciosus - * Bufo sugpectus - * Bufo valliceps * (cf.) - Bufo woodhousei woodhousei * - Ranidae Rana areolata * * Rana palustris * ' - Rana pipiens * * Class Reptilia Alligatoridae Alligator mississipiensis * — Kinosternidae Kinosternon flavescens * - Emydidae Pseudemyg scripta * - Terrapene ornata * - Chrysemys picta * — Testudinidae Geochelone beckensis * - Geochelone rexroadensis * * Geochelone turgida - * Anguidae Gerrhonotus insolitus * - Iguanidae Phrynosoma cornutum * * Sceloporus olivaceus * - Sceloporus robustus * (cf.) * t .. Sceloporus undulatus 98 Table 2. Continued. Species Beck Ranch Fauna Rexroad Locality Number 3 Teidae Cnemidophorus bilobatus Cnemidophorus sexlineatus Scincidae Eumeces obsoletus Eumeces striatulatus Boidae ngophis pgrvus Colubridae Heterodon platyrhinos Heterodon plionasicus Coluber constrictor Masticophis flagellum Natrix sp. Natrix erythrogaster Natrix hibbardi Natrix sipedon Natrix gyclopion Natrix rhombifera Thamnophis sp. Thamnophis sirtalis Thamngphis marcianus Elaphe guttata Elaphe obsoleta Elaphe vulpina Pituophis melanoleucus sayS_ Rhinocheilus lecontei Lampgopeltis getulus Lampropeltis triaggulum Crotalidae Agkistrodon contortrix Crotalus atrox Crotalus viridis Sistrurus catenatus l'fl-I'I’I’fifl- up! :1- *tfl'fl'fififl-I'I'I- *1- (cf.) lttt In *l’O‘Oll Note: * indicates species present, - species absent. 99 cognatus was found in the Beck Ranch Fauna but its presence in the Rexroad has not been proven. Some ilia suggest this species may be present (Tihen, 1962a). I consider eight species of SASS described from the Rexroad by Taylor (1942) on the basis of sacral vertebrae to be invalid. My examination of the Rexroad Locality Number 3 ilia indicates that Rana pipiens and Rana areolata are present and indistinguishable from ilia of Rana pipiens and Rana areolata found in the Beck Ranch Fauna. Brattstrom (1967) notes the similarity of Rexroad Natrix basisphenoids to Natrix sipedon and Natrix cyclopion. Natrix hibbardi, which is apparently ancestral to S. sipedon, is tentatively considered present in the Beck Ranch Fauna although it is very difficult to separate from S. sipedon on the basis of vertebrae. Another group of Beck Ranch vertebrae are considered to represent either Natrix cycloPion or S. rhombifera. The Rexroad ThamnOpSis elements have not been assigned to species but the genus Thamnophis is undoubtedly present in both deposits. Extinct species found in both the Rexroad and Beck Ranch Faunas are Amphitriton brevis, Scaphi0pus diversus, Bufo rexroadensis, Eumeces striatulatus, and Heterodon plionasicus. Ambystoma elements from the Rexroad Fauna are all considered to represent Ambystoma hibbardi. Ambystoma hibbardi or Ambystoma tigrinum is present in the Beck Ranch Fauna. 100 The Beck Ranch Fauna and the Rexroad Locality Number 3 Fauna represent very similar ecological situa- tions. Hibbard (1941) has given evidence of the presence of a major stream valley with areas of marshes, meadows, and rocky hillsides, and higher grassland areas to account for the habitats of the faunal elements. Similarly, the Beck Ranch Fauna apparently represents a wooded stream valley adjacent to higher prairie areas much like that seen in the Texan biotic province today. The presence of more urodeles and pond turtles in the Beck Ranch Fauna may indicate slightly moister conditions in Scurry County, Texas, than in Meade County, Kansas, in the late Pliocene. Differences between the faunas seem to represent differences in geographic location and faunal size. Meade County, Kansas, is approximately 280 miles north of Scurry County, Texas. This would account for the absence of southern species such as Alligator mississipiensis, Sceloporus olivaceus, and Rhinocheilus lecontei from the Rexroad Fauna. In addition, the Beck Ranch Fauna is a larger, more complete fauna than is the Rexroad Locality Number 3 Fauna (Table 2). Osteological comparisons with the Rexroad Fauna are included under the systematic descriptions of the species involved. The strong similarity in faunal composition of the Beck Ranch Fauna and of the Rexroad Locality Number 3 101 Fauna indicates that Beck Ranch is at least as old as the Rexroad Fauna. The presence of Heterodon plionasicus and Geochelone beckensis is strong evidence of a late Pliocene rather than early Pleistocene age for the fauna. By early Pleistocene times, Heterodon plionasicus had evolved into the extant species, Heterodon nasicus (Brattstrom, 1967) so the presence of Heterodon plionasicus indicates a Pliocene age for the deposit. Geochelone beckensis is considered to be ancestral to Geochelone johnstoni which is known from the early Pleistocene (pre-Nebraskan glaciation) of Randal County, Texas (Auffenberg, 1962), and late Kansan of Knox County, Texas (Holman, 1969a). According to Dalquest and Donovan (1973), the Beck Ranch local fauna belongs to the Blancan land mammal age but its exact position in the known Blancan sequence is uncertain. Hibbard (1970) feels that the Beck Ranch Fauna is older than the Blanco local fauna of Crosby County, Texas, and closely resembles the Rex- road Locality Number 3 Fauna. Therefore, the Beck Ranch Fauna is considered to be late Pliocene in age and to belong to the early Blancan land mammal age. SUMMARY The Beck Ranch local fauna is a basin-fill deposit. The lower levels are loess and the upper levels are fluvial in origin. The vertebrate fossils were deposited in fine-grained sediments associated with the backwaters of a stream which flowed southeasterly through Scurry County, Texas, in the late Pliocene. A total of 48 species were identified in the fauna: four salamanders, nine anurans, one crocodilian, six turtles, eight lizards, and twenty snakes. Approximately 75 percent of these species are modern forms. Twelve species are fossil, three of which are ancestral to mod- ern forms (Scaphiopus diversus, Heterodon plionasicus, and Natrix hibbardi), two are considered to be robust upper Pliocene forms (Sceloporus robustus and Eumeces striatulatus), and seven are members of extinct evolu- tionary lines (Ambygtoma hibbardi, Amphitriton brevis, Bufo rexroadensis, Geochelone rexroadensis, Geochelone beckensis, ngophis parvus, and Gerrhonotus insolitus). A new family of salamanders, Amphitritontidae, is erected for the genus Amphitriton, an aquatic form closely related to the Ambystomatidae. A new species of Geochelone, Geochelone beckensis, which is apparently ancestral to the 102 103 early Pleistocene S. johnstoni of Texas, is described. A member of the genus Oggophis, Ogmophis pgrvus, is des- cribed and is considered most closely related to the new OgSophis species from the lower Pliocene of Kansas. Gerrhonotus insolitus is also described herein as a new species most closely related to S. leiocephalus but is not considered ancestral to that species. Species which have not been reported previously as fossils include Ambystoma gpacum and Sceloporus olivaceus. Evidence from the fauna indicates that the climate of Scurry County, Texas, in the late Pliocene was more equitable than at present but in a state of deteriora- tion as evidenced by thick land turtle shells and robust species of lizards. The Austroriparian elements in the fauna indicate that the lowland area in Scurry County was up to 20 percent moister than the upland area and the grassland elements in the fauna suggest that the High Plains near the area were most similar to the tall-grass prairie areas of the Texan biotic province. The Beck Ranch Fauna was compared with the Rexroad Locality Number 3 fauna from Kansas. The faunas are considered contemporaneous since 11 extant and five extinct species of reptiles and amphibians are found in both faunas. POpulations of species from the Rexroad are very similar osteologically to those from Beck Ranch. The 104 Pliocene species Heterodon plionasicus and Geochelone beckensis provide additional evidence of a Pliocene age of the fauna. LITERATURE C ITED LITERATURE CITED Auffenberg, W. 1961. A new genus of fossil salamander from North America. Amer. Mid. Nat. 66(2):456-465. . 1962. A new species of Geochelone from the Pleistocene of Texas. Copeia 1962(3):627-636. . 1963a. 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Geographical distribution and osteo- logical variation in fossil and recent specimens of two species of Kinosternon (Testudines). Journ. Herpet. 3(3-4):ll3-ll9. Galbraith, E. C. 1948. A new extinct emydid turtle from the lower Pliocene of Oklahoma. Univ. Kansas Publ., Mus. of Nat. Hist. 1(16):265-280. Gelbach, F. R. 1964. Amphibians and reptiles from the Pliocene and Pleistocene of North America: A chrono- logical summary and selected bibliography. Texas Journ. Sci. 17:56-70. Hibbard, C. W. 1941. Paleoecology and correlation of the Rexroad Fauna from the upper Pliocene of\southwestern Kansas, as indicated by the mammals. Univ. Kansas Sci. Bull. 27(6):79-104. . 1960. An interpretation of Pliocene and Pleisto- cene climates in North America. Ann. Rept. Mich. Acad. Sci. Arts & Letters. 1960:5-30. . 1970. Pleistocene mammalian local faunas from the Great Plains and Central lowlands. Univ. Kansas Dept. Geol., Spec. Pub. 3:395-433. Hill, W. H. 1966. 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Sci. 29(4):267-275. . 1968a. Upper Pliocene Snakes from Idaho. Copeia 1968(1):152-158. . 1968b. A Pleistocene herpetofauna from Kendall County, Texas. Quart. Jour. Fla. Acad. Sci. 31(3): 165-172. . 1969a. The Pleistocene amphibians and reptiles of Texas. Publ. Mus. Mich. St. Univ. 4(5):163-192. . 1969b. Herpetofauna of the Pleistocene Slaton Local Fauna of Texas. The Southwestern Naturalist 14(2):203-212. . 1970. A Pleistocene herpetofauna from Eddy County, New Mexico. Texas Jour. Sci. 22(1):29-39. . 1971. Herpetofauna of the Sandahl Local Fauna (Pleistocene: Illinoian) of Kansas. Contr. Mus. Paleont. Univ. of Mich. 23(22):349-355. 108 . 1972a. Amphibians and Reptiles. In Early Pleisto- cene preglacial and glacial rocks and faunas of North- Central Nebraska. Bull. Am. Mus. Nat. Hist. 148(1): 55-71. . 1972b. Herpetofauna of the Kanopolis Local Fauna (Pleistocene:Yarmouth) of Kansas. Mich. Academician 5(1):87-98. Kendeigh, S. C. 1961. Animal Ecology. Prentice-Hall, Inc. Lynch, J. D. 1965. The Pleistocene amphibians of Pit II, Arrendondo, Florida. C0peia l965(1):72-77. McDowell, S. B. 1964. Partition of the genus Clemmys and related problems in the aquatic testudininae. Proc. 2001. Soc. London 143:239-279. Meszoely, C. A. M. 1966. North American fossil cryptobranchid salamanders. Am. Mid. Nat. 75(2):295-515. . 1970. North American fossil anguid lizards. Bull. Mus. Comp. Zool. 139(2):87-l49. Oelrich, T. M. 1952. A new Testudo from the upper Pliocene of Kansas with additional notes on associated Rexroad Mammals. Trans. Kansas Acad. Sci. 55(3):300-311. Preston, R. E. 1966. The turtles of the Gilliland Faunule from the Pleistocene of Knox County, Texas. Pap. Mich. Acad. Sci., Arts & Letters. 51:221-239. Smith, H. M. 1946. Handbook of lizards. Ithaca: Comstock Pub. Assoc., Cornell Univ. Press. 557 pp. Soler, E. I. 1950. On the status of the family Desmognathidae. Univ. Kansas Sci. Bull. 33(12):459-480. Taylor, E. H. 1941. Extinct lizards from upper Pliocene deposits of Kansas. State Geol. Survey of Kansas, Bull. 38, 1941. Reports of studies part 5:165-176. 109 . 1942. Extinct toads and frogs from the upper Pliocene deposits of Meade County, Kansas. Univ. Kansas Sci. Bull. 28(10):l99—235. Tharp, B. C. 1926. Structure of Texas vegetation east of the 98th meridian. Univ. Tex. Bull. 2606:1-100. . 1939. The vegetation of Texas. Tex. Acad. Sci. Publ. Nat. Hist., Non-tech. Ser. 1:1-xvi:1-74. Tihen, J. A. 1942. A colony of fossil neotenic Ambystoma tigrinum. Univ. Kansas Sci. Bull. 28(9):189-198. . 1955. A new Pliocene species of Ambystoma, with remarks on other fossil Ambystomids. Contr. Mus. Paleont., Univ. Mich. 12(11):229-244. . 1958. Comments on the osteology and phylogeny of ambystomatic salamanders. Bull. Fla. State Mus. 3:1-49. . 1960. On Neoscaphiopus and other Pliocene pelobatid frogs. Copeia 1960(2):89-94. . 1962a. Osteological observations on new world Bufo. Amer. Mid. Nat. 67(1):157-183. . 1962b. A review of new world fossil bufonids. Amer. Mid. Nat. 68(1):1-50. Weaver, W. G., and J. S. Robertson. 1967. Systematics, fossil history, and evolution of the genus Chrysemys. Tulane Stud. in Zool. 14(2):63-73. Weaver, W. G., and F. L. Rose. 1967a. Two new species of Chrysemys (= Pseudemys) from the Florida Pliocene. Tulane Stud. in Geol. 5(1):41—48. . 1967b. A re-evaluation of the fossil turtles of the Chrysemys scripta group. Tulane Stud. in Geol. 5(2):53-65. fin»...- .‘g"~v‘-w..-_.—-> IHIINHHHIIII IllHillWIIHIIIIIHIIHIHIIHIHtlll 4