introduction amniotes appear in paleozoic era (pennsylvanian of carboniferous) sauropsida—gave...
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IntroductionAmniotes appear in Paleozoic era (Pennsylvanian
of Carboniferous)
Sauropsida—gave rise to turtles, lizards, snakes, dinosaurs, and birds
Synapsida—gave rise to mammals
FIGURE 01: Phylogeny of Tetrapods
Adapted from Gauthier, J, A.G. Kluge and T. Rowe., Cladistics, 4 (1988):105–209; adapted from Benton, M.J. Vertebrate Palaeontology, Second edition. Chapman and Hall, 1997; and adapted from Carroll, R.L. Vertebrate Palaeontology and Evolution. W. H. Freem
Figure 18-1
Synapsida
• Dominated terrestrial faunas during Permian and early Triassic
• Many synapsid groups went extinct during Permian extinction event
• Therapsida survived– Gave rise to cynodonts– Later, other therapsids dwindle
• Mammals arose from cynodont ancestor in late Triassic
Synapsid Characters
• Single temporal fenestra on skull• Jaw muscles move to outer braincase
FIGURE 02: Diagrammatic views of skulls of amniotes showing some of the arrangements of temporal openings
Synapsid phylogeny
Phylogeny adapted from Wible, J.R., et al., American Museum Novitates 3149 (1995) 1–19; adapted from Rowe, T., J. of Vertebrate Palaeontology, 8 (1998): 241–264; adapted from Rowe, T. Mammal Phylogeny: Mesozoic Differentiation, Multituberculates, Monotre
FIGURE 03: Phylogeny and representative skulls of
synapsids
Synapsid Characters
• Maxilla contacts quadratojugal bone• Caniniform maxillary teeth• Narrow neural arches on trunk vertebrae
Synapsids
• Permian synapsids include a paraphyletic group called Pelycosaurs
Modified from Romer, A.S. Vertebrate Paleontology. University of Chicago Press, 1966.
FIGURE 05: Reconstructed skeletons of primitive and derived
synapsids, showing changes in the postcranial skeleton.
Adapted from Jenkins, F.A. Jr. Primate Locomotion. Academic Press, 1974.
Adapted from Jenkins, F.A. Jr., Evolution 24 (1970): 230-252
Adapted from Jenkins, FA Jr., Journal of Zoology 165 (1971): 303–315;
Therapsids
• Appear in middle Permian
• Diverse assembalage
• Include early cynodonts
Figure 18-5
Therapsid Characters
• Enlarged temporal opening
• Sagittal crest and zygomatic arches
• Upper canines enlarged
• More upright limb posture
• Deep acetabulum
Figure 18-7
Therapsid Characters
• Feet shortened
• External auditory meatus within squamosal
• Jaw joint in line with occiput
• Anterior coronoid bone absent
Cynodont therapsids
• Masseteric fossa on dentary bone
• Two occipital condyles
• Zygomatic arches flare laterally
• Angular bone reduced
• Teeth absent from pterygoid bone
Cynodont therapsids
• Incisors spatulate
• Accessory cusps on postcanine teeth
• Partial secondary palate
• Ribs reduced on lumbar vertebrae
• Calcaneal heel present on foot
Early Mammals
FIGURE 10: Reconstruction of Eozostrodon, a Triassic mammal of the family Morganucodontidae
Adapted from Crompton, A.W. & F.A. Jenkins, Jr., Biological Reviews 43 (1968): 427.
Stem Mammals• Dentary-squamosal jaw articulation
• Tabular bone absent in skull
• Medial wall of orbit enclosed
• Double-rooted cheek teeth
• Cheek teeth include premolars and molars
FIGURE 09: Stages in the development of the lower jaw and
ear region in a young opossum Monodelphis (Didelphidae)
Adapted from Ghiselin, M. T., and Pinna, G. New Perspectives on the History of Life. California Academy of Sciences, 1994.
FIGURE 08: Selected major stages in the evolution of the mammalian jaw joint and ear region
Adapted from Ghiselin, M. T., and Pinna, G. New Perspectives on the History of Life. California Academy of Sciences, 1994.
Stem Mammals
• Precise occlusion of cheek teeth• Diphyodont dentition• Mandibular symphysis reduced• Derived features of soft tissues
– Mammary glands with teats– Viviparity– Separate anal and urogenetal openings– Digastricus muscle lowers jaw
Theria
• Tribosphenic molars
• Supraspinous fossa on scapula
• Cochlea spiraled
Important Transformations
• Evolution of a new squamosal-dentary jaw joint
• Articular, quadrate, and angular bones of lower jaw detach and become part of ear apparatus (malleus, incus, and tympanic ring, respectively)
Other Transformations
Evolution of:• More complex cusps on molars• Secondary palate
– Facilitated suckling
• Parasagittal movement of limbs (more mammalian limb posture)
• Endothermy
Early Mammals
• Small bodied (e.g. 20–30 grams)
• Premolars and molars in cheek teeth
• Large brain size
• Probably insectivorous diet
• Probably nocturnal and arboreal
• Lactation and suckling likely
Figure 15-1
Mesozoic Multituberculates
• Herbivorous or omnivorous• Appear in late Jurassic
– Fossil record spans 100 million years
• Similar in appearance to rodents– 2 or 3 incisors above and 2 on bottom– Diastema– Massive, blade-like lower premolars
Multituberculates
Modified from Romer, A.S. Vertebrate Paleontology. University of Chicago Press, 1966.
FIGURE 16: Ptilodus (order Multituberculata) skull
Multituberculates
• Some retained cervical ribs• Unusual chewing mechanics
Multituberculates began to decline in late Paleocene—probably due to competition with condylarths, early primates, and rodents
Cretaceous Mammals
• Metatherians and eutherians evolved from a clade of Mesozoic mammals
• Angular process on dentary• Tribosphenic molars • Lower molars have talonid in some forms
Cretaceous Mammals
FIGURE 17: Molar of Aegialodon, an early
Cretaceous tribosphenidan (family Aegialodontidae)
Parts c and d modified from Romer, A.S. Vertebrate Paleontology. University of Chicago Press, 1966.
Figure 20-7
Cretaceous Mammals
• Much biotic interchange between continents in Jurassic—sets the stage
• Flowering plants become dominant flora• Insects radiate with flowering plants in
Cretaceous• Dinosaur fauna begins to decline• Mammal faunas begin to radiate
Figure 20-2
Figure 19-1
Figure 19-3
Figure 20-17
Figure 20-18
Figure 20-19
Figure 19-4