The Origin and Evolution of Mammals - Moodle

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Simpson, G.G. 1970. The Argyrolagidae, extinct southern American marsupials. Bull. Mus. Comp. Zool. Harvd. 139: 1–86. Simpson, G.G. 1980. Splendid isolation: the curious history of South American mammals. Yale University Press: New Haven. Slaughter, B.H. 1971. Mid-Cretaceous (Albian) therians of the Butler Farm local fauna, Texas. In D.M. Kermack and K.A. Kermack (eds) Early mammals. Zool. J. Linn. Soc. 50 (Suppl. 1), 31–144. Smith, A.G., Smith, D.G., and Funnell, B.M. 1994. Atlas of Mesozoic and Cenozoic coastlines. Cambridge University Press: Cambridge. Smith, R.M.H. 1987. Helical burrow casts of therapsid origin from the Beaufort group (Permian) of South Africa. Palaeogeogr. Palaeoclimatol. Palaeoecol. 60: 155–170. Smith, R.M.H. 1993. Sedimentology and ichnology of palaeosurfaces in the Beaufort Group (Late Permian), Karoo Sequence, South Africa. Palaios 8: 339–357. Smith, R.M.H. 1995. Changing fluvial environments across the Permian-Triassic boundary in the Karoo Basin, South Africa and possible causes of tetrapod extinctions. Palaeogeogr. Palaeoclimatol. Palaeoecol. 117: 81–104. Smith, R.M.H. and Ward, P.D. 2001. Pattern of vertebrate extinctions across an event bed at the Permian–Triassic boundary in the Karoo basin of South Africa. Geology 29: 1147–1150. Smithson, T.R., Carroll, R.L., Panchen, A.L., and Andrews, S.M. 1994. Westlothiana lizziae from the Visean of East Kirton, West Lothian, Scotland, and the amniote stem. Trans.R. Soc. Edinb. Earth Sci. 84: 417–431. Springer, M.S., Kirsch, J.A., and Case, J.A. 1997a. The chronicle of marsupial evolution. In T.J. Givnish and K.J. Sytsma (eds) Molecular evolution and adaptive radiation. Cambridge University Press: Cambridge, pp. 129–161. Springer, M.S., Cleven, G.C., Madsen, O., Jong, W.W. de, Waddell, V.G., Amrine, H.M., and Stanhope, M.J. 1997b. Endemic African mammals shake the phylogenetic tree. Nature 388: 61–64. Springer, M.S., Westerman, M., Kavanagh, J.R., Burk, A., Woodburne, M.O., Kao, D.J., and Krajewski, C. 1998. The origin of the Australasian marsupial fauna and the phylogenetic affinities of the enigmatic monito del monte and marsupial mole. Proc. R. Soc. Lond. B265: 2381–2386. Springer, M.S., Murphy, W.J., Eizirik, E., and O’Brien, S.J. 2003. Placental mammal diversification and the Cretaceous-Tertiary boundary. Proc. Natl. Acad. Sci. 100: 1056–1061. Stanhope, M., Waddell, V., Madsen, O., de Jong, W., Hedges, S., Cleve, G., Kao, D., and Springer, M. 1998. REFERENCES 319 Molecular evidence for multiple origins of Insectivora and a new order of endemic African insectivore mammals. Proc. Natl. Acad. Sci. USA. 95: 9967–9972. Stehli, F.G. and Webb, S.D. (eds) 1985. The Great American Interchange. Plenum: New York. Stewart, J.R. 1997. Morphology and evolution of the egg of oviparous amniotes. In S.S. Sumida and K.L.M. Martin (eds) Amniote origins: completing the transition to land. Academic Press: London, pp. 291–326. Storch, G. 1981. Eurotamandua joresi, ein Myrmecophagide aus dem Eozän der ‘Grube Messel’ bei Darmstadt (Mammalia: Xenarthra). Senckenbergiana Lethaea 61: 247–289. Storch, G. and Richter, G. 1992a. The ant-eater Eurotamandua: a South American in Europe. In S. Schaal and W. Ziegler (eds) Messel: an insight into the history of life and of the Earth. Oxford University Press: Oxford, pp. 209–216. Storch, G. and Richter, G. 1992b. Pangolins: almost unchanged for 50 million years. In S. Schaal and W. Ziegler (eds) Messel: an insight into the history of life and of the Earth. Oxford University Press: Oxford. Stuart, A.J. 1999. Late Pleistocene megafaunal extinctions: a European perspective. In R.D.E. MacPhee (ed) Extinctions in near time: causes, contexts, and consequences. Kluwer Academic: New York, pp. 257–269. Stucky, R.K. 1998. Eocene bunodont and selenodont Artiodactyla (‘dichobunids’). In C.M. Janis, K.M. Scott, and L.L. Jacobs (eds) Evolution of Tertiary mammals of North America, Vol. 1: Terrestrial carnivores, ungulates, and ungulate-like mammals. Cambridge University Press: Cambridge, pp. 358–374. Sues, H.-D. 1983. Advanced mammal-like reptiles from the early Jurassic of Arizona. Ph.D. thesis, Harvard University. Sues, H.-D. 1985. The relationships of the Tritylodontidae (Synapsida). Zool. J. Linn. Soc. 85: 205–217. Sues, H.-D. 1986a. Locomotion and body form in early therapsids (Dinocephalia, Gorgonopsia, and Therocephalia). In N. Hotton III, P.D. MacLean, J.J. Roth, and E.C. Roth (eds) The ecology and biology of mammal-like reptiles. Smithsonian Institution Press: Washington, pp. 61–70. Sues, H.-D. 1986b. Relationships and biostratigraphic significance of the Tritylodontidae (Synapsida) from the Kayenta Formation of northeastern Arizona. In K. Padian (ed) The beginning of the age of dinosaurs: faunal change across the Triassic–Jurassic boundary. Cambridge University Press: Cambridge, pp. 279–284. Sues, H.-D. 2001. On Microconodon, a Late Triassic cynodont from the Newark Supergroup of eastern North America. Bull. Mus. Comp. Zool. Harvd. 156: 37–48.
320 REFERENCES Sues, H.-D. and Boy, J.A. 1988. A procynosuchid cynodont from central Europe. Nature 331: 523–524. Sues, H.D. and Munk, W. 1996. A remarkable assemblage of terrestrial tetrapods from the Zechstein (Upper Permian, Tatarian) near Korbach (northwestern Hesse). Palaeontol. Zeitsch 70: 213–223. Sues, H.-D, Olsen, P.E., and Carter, J.G. 1999. A Late Triassic traversodont cynodont from the Newark Supergroup of North Carolina. J. Vert. Paleontol. 19: 351–354. Sumida, S.S. 1997. Locomotor features of taxa spanning the origin of amniotes. In S.S. Sumida and K.L.M. Martin (eds) Amniote origins: completing the transition to land. Academic Press: London, pp. 353–398. Sun, A. 1991. A review of Chinese therocephalian reptiles. Vert. PalAs. 29: 85–94. Sweet, A.R., Braman, D., and Lerbekmo, J.F. 1993. Northern mid-continental Maastrichtian and Paleocene extinction events. Geol. Assoc. Can. Progr. Abt. p. 103. Swisher, C.C. III and Prothero, D.R. 1990. Single-Crystal 40 39 Ar/ Ar dating of the Eocene–Oligocene transition in North America. Science 249: 760–762. Szalay, F.S. 1969. Origin and evolution of function of the mesonychid condylarth feeding mechanism. Evolution 23: 703–720. Szalay, F.S. 1982. A new appraisal of marsupial phylogeny and classification. In M. Archer (ed) Carnivorous marsupials. Royal Zoological Society of New South Wales: Sydney, pp. 621–640. Szalay, F.S. 1994. Evolutionary history of the marsupials and an analysis of osteological characters. Cambridge University Press: Cambridge. Szalay, F.S. and Delson, E. 1979. Evolutionary history of the primates. Academic Press: New York. Szalay, F.S. and Lucas, S.G. 1993. Cranioskeletal morphology of archontans, and diagnoses of Chiroptera, Volitantia, and Archonta. In R.D.E. MacPhee (ed) Primates and their relatives in phylogenetic perspective. Plenum: New York, pp. 187–226. Szalay, F.S. and McKenna, M.C. 1971. Beginning of the age of mammals in Asia: the Late Paleocene Gashato fauna, Mongolia. Bull. Am. Mus. Nat. Hist. 144: 269–318. Szalay, F.S. and Sargis, E.J. 2001. Model-based analysis of postcranial osteology of marsupials from the Palaeocene of Itaboraí (Brazil) and the phylogenetics and biogeography of Metatheria. Geodiversitas 23: 139–302. Szalay, F.S. and Trofimov, B.A. 1996. The Mongolian Late Cretaceous Asiatherium, and the early phylogeny and paleobiogeography of Metatheria. J. Vert. Paleontol. 16: 474–509. Tabuce, R., Coiffait, B., Coiffait, P.E., Mahboubi, M., and Jaeger, J.J. 2001. A new geneus of Macroscelidea (Mammalia) from the Eocene of Algeria: a possible origin for elephant shrews. J. Vert. Paleontol. 21: 535–546. Takei, M., Anaya, F., Shigehara, N., and Setoguchi, T. 2000. New fossil material of the earliest New World monkey, Branisella boliviana, and the problem of platyrrhine origins. Am. J. Phys. Anthropol. 111: 263–282. Tassy, P. 1996. Who is who among the Proboscidea? In J. Shoshani and P. Tassy (eds) The Proboscidea: evolution and palaeoecology of elephants and their relatives. Oxford University Press: Oxford, pp. 39–48. Tassy, P. and Shoshani, J. 1988. The Tethytheria: elephants and their relatives. In M.J. Benton (ed) The phylogeny and classification of the tetrapods, Vol. 2: Mammals. Oxford University Press: Oxford, pp. 283–316. Tatarinov, L.P. 1968. Morphology and systematics of the North Dvina cynodonts (Reptilia, Therapsida: Upper Permian). Postilla 126: 1–15. Tatarinov, L.P. 1974. Theriodonts of the USSR. Tr. Paleontol. Inst. Akad. Nauk SSSR (Moscow) 143: 1–240. Tatarinov, L.P. and Matchenko, E.N. 1999. A find of an aberrant tritylodont (Reptilia, Cynodontia) in the Lower Cretaceous of the Kemerovo region. Palaeontol. J. 33: 422–428. Taveré, S., Marshall, C.R., Will, C.O., Soligo, C., and Martin, R.D. 2002. Using the fossil record to estimate the age of the last common ancestor of extant primates. Nature 416: 726–729. Tchudinov, P.K. 1960. Upper Permian therapsids of the Ezhovo locality. Paleontol. J. 2: 85–98. Tchudinov, P.K. 1983. Early therapsids. Tr.Paleontol. Inst. Akad. Nauk SSSR (Moscow). 202: 1–230. Tedford, R.H. and Woodburne, M.O. 1987. The Iliariidae, a new family of vombatiform marsupials from Miocene strata of South Australia and an evaluation of the homology of molar cusps in the Diprotodontia. In M. Archer (ed) Possums and opossums: studies in evolution. Surrey Beatty and Sons: Chipping Norton, Australia, pp. 401–418. Teeling, E.C., Scally, M., Kao, D.J., Romagnoli, M.L., Springer, M.S., and Stanhope, M.J. 2000. Molecular evidence regarding the origin of echolocation and flight in bats. Nature 403: 188–192. Teeling, E.C., Madsen, O., Van Den Bussche, R.A., Jong, W. de, Stanhope, M.J. and Springer, M.S. 2002. Microbat paraphyly and the convergent evolution of a key innovation in the Old World rhinolophoid microbats. Proc. Natl. Acad. Sci. USA. 99: 1431–1436. Temple-Smith, P. 1987. Sperm structure and marsupial phylogeny. In M. Archer (ed) Possums and opossums: studies in evolution. Surrey Beatty and Sons: Chipping Norton, Australia, pp. 171–193.
Page 2 and 3:
The Origin and Evolution of Mammals
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The Origin and Evolution of Mammals
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Preface This book arose from twin a
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For Mal /gosia with love and thanks
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Contents 1 Introduction The definit
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CHAPTER 1 Introduction There are ab
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transversely occluding molar teeth
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the Mesozoic mammals, is to do with
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a hierarchy of committees under the
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it means that a 200 Ma igneous rock
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een a more fundamental impact than
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Table 2.3 Classification of marsupi
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(a) (b) (c) humerus radius aquatic
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(a) Westlothiana Limnoscelis PO Wes
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the ankle bones to form an astragal
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(b) (c) (a) Casea rutena Casea broi
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(Fig. 3.2(f)), is actually an ophia
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the first one is enlarged, often to
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Even at their initial appearance in
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(a) Nikkasaurus (b) (d) Reiszia (e)
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Nikkasauridae The family Nikkasauri
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has figured large in discussions of
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(c) Figure 3.9 (continued). Syodon
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a mixture of progressively more spe
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animal with interdigitating, but no
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(e) (a) Anomocephalus Ulemica (b) S
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mandibulae musculature. This, as in
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To date the postcranial skeleton of
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ecognised four subgroups, based mai
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the presence of a deep, longitudina
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collected from the Lystrosaurus Ass
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(a) (d) (c) (b) Leontocephalus V PA
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(a) (c) Lycosuchus Oliveria (d) EVO
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separate families. Lycosuchidae (Fi
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consist of a large labial cusp and
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Procynosuchus (d) Procynosuchus (a)
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They constitute the monophyletic gr
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Although there is no mammal-like co
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Cynognathidae Cynognathus (Fig. 3.2
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(e) (f) Figure 3.22 (continued). Ma
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(c) (d) (a) (b) Kayentatherium EVOL
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Pachygenelus (e) (a) (c) Therioherp
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palatal, and orbitosphenoid bones,
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Wible and Hopson 1993). The interor
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published a cladogram based on rece
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310-320 Ma. By this time, the great
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are forms such as Casea itself, var
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lakes and swamps in the low-lying l
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urrowing and subsisting on a diet o
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Eothyris Haptodus sphenacodontine B
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z (a) (c) a.pt.m. M B PO P P SQ P M
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(b) a.pt.m. temp.m. a.pt.m. temp.m.
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the dentary bone above the level of
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the therocephalian grade was not on
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A balance was also achieved in the
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Locomotion Ancestral amniote grade
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screw-shaped: the front part faces
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For the recovery phase, the relativ
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SC PRC p.i.f.i tr.min (c) dp.cr ect
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the therocephalian pelvis and hindl
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spc s.sp s.sp SC PRC (d) delt T AST
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no significant novelties to what ha
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(a) (c) (e) (g) D D ex. au.m C tym
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(a) (c) (d) PMX (f) V n.turb mx.tur
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ol.b (a) (b) cer.hem gorgonopsian t
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(a) (b) (i) (ii) (iii) (iv) (v) a g
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cold stress, the part that usually
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conducted the experiment of wrappin
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mammals themselves that the enlarge
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elevation of maximum aerobic activi
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a mammal. The difficulty with all s
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collection, ingestion, and assimila
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were edaphosaurid and caseid pelyco
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CHAPTER 5 The Mesozoic mammals The
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(a) (d) AL condylar foramina are se
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evidence to relate the haramiyidans
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postcranial skeleton, and Graybeal
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side of the head can be in action a
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the lower molars is relatively high
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morganucodontan teeth. However, des
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adjacent lower molars. A small exte
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(a) (b) (d) P4 P4 Plagiaulax P4 Pau
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American Morrison Formation genus C
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a self-sharpening property. As the
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near parasagittal gait (Fig. 5.11(e
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pass through the birth canal. Relat
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(a) 1 (b) (d) me (c) me.d 3 styl st
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(a) (c) Henkelotherium Crusafontia
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pubis is excluded from the acetabul
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Cretaceous, (Aptian or Albian) of M
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eautifully preserved placentals fro
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subsequent specimens revealed that
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Minimal divergence of tribosphenida
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(c) (a) M 1 M 1 M 2 Steropodon M 2
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(b) (a) (c) pa.d pr.d me.d Ambondro
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crown-group therians) is accepted b
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form of the tooth, must reflect sub
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of feasibility that a taxon of endo
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mammals, by creating environmental
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the 11 species of marsupial, of whi
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(d) (a) pa A Dasyuromorphia B C pr
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earing two huge claws on digits thr
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that contains the independent ances
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(b) (d) (a) Glasbius Alphadon (c) D
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elieved to be Late Cretaceous in ag
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(Fig. 6.5(c)). The dentition exhibi
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(d) Figure 6.6 (continued). Thylaco
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(a) (c) Caroloameghina and Procarol
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(a) (e) (d) Proargyrolagus Groeberi
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(a) (b) Djarthia Thylacotinga (c) (
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LIVING AND FOSSIL MARSUPIALS 211 M
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Extinct Notoryctemorphia At present
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(f) (g) Wakaleo Diprotodon optatum
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fossil mammals, which might help cl
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30 40 50 60 Figure 6.13 Southern Go
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the Diprotodontia also included gen
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1. Placentalia 2. Edentata 3. Epith
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effectively absent. However, increa
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Asioryctes (a) (b) (d) Cimolestes p
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and Prokennalestes, although it doe
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(a) Leptictidium Palaeoryctidans we
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(a) Purgatorius (c) are part of the
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(a) (d) (e) (g) Protoungulatum Meso
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(a) (f) (e) Hyopsodus Phenacodus (d
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Titanoides (pantodont) (a) (c) (b)
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(a) (b) (d) Trogosus (tillodont) Es
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Mioclaenus Paulacoutoia (didolodont
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their presence. The five orders may
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Xenungulata. Only two Late Palaeoce
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(a) (b) (d) (c) Oxyaena Patriofelis
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continuously growing, and form a gr
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navicular facet, 19 or more thoraci
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(a) (c) Phosphatherium Numidotheriu
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coexist with other characters that
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The salient feature of Widanelfasia
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1 (a) 1. Perissodactyla 2. Titanoth
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(a) (b) BUNODONTIA or SUIFORMES SUI
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time, which suggests that it was on
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condition. This particular combinat
Page 280 and 281: etween Primates, Dermoptera (colugo
Page 282 and 283: have postcranial adaptations for ar
Page 284 and 285: undoubtedly related at a supraordin
Page 286 and 287: indisputably to occur prior to the
Page 288 and 289: The Late Cretaceous mammal record i
Page 290 and 291: interordinal divergences in the Lat
Page 292 and 293: diversity on Earth (Janis 1993). Fu
Page 294 and 295: effect of the surrounding sea. Trop
Page 296 and 297: was high. It lasted from 5 to 3 Ma
Page 298 and 299: and thus remain in their preferred
Page 300 and 301: agreement about exactly when within
Page 302 and 303: References Abdala, F. Redescription
Page 304 and 305: Ax, P. 1987. The phylogenetic syste
Page 306 and 307: Bramble, D. M. 1978. Origin of the
Page 308 and 309: Colbert, E.H. 1948. The mammal-like
Page 310 and 311: Duvall, D. 1986. A new question of
Page 312 and 313: Gow, C.E. 1980. The dentitions of t
Page 314 and 315: Ivakhnenko, M.F. 1990. The late Pal
Page 316 and 317: Kemp, T.S. 1988a. A note on the Mes
Page 318 and 319: cladogenesis in dasyurid marsupials
Page 320 and 321: (eds) Evolution of Tertiary mammals
Page 322 and 323: McKenna, M.C. and Bell, S.K. 1997.
Page 324 and 325: (ed) The phylogeny and classificati
Page 326 and 327: Ray, S. 2000.Endothiodont dicynodon
Page 328 and 329: Rubidge, B.S., Kitching, J.W., and
Page 332 and 333: Thewissen, J.G.M. 1990. Evolution o
Page 334 and 335: Novacek, M.J., and McKenna, M.C. (e
Page 336 and 337: Index Note: Page numbers in italics
Page 338 and 339: Equoidea 262 Equus 262 Erethizon 28
Page 340 and 341: Overkill hypothesis 289, 290 Oxyaen
Page 342: Tulerpeton 14, 18 Tylopoda 264 Ukha
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