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.2024 Jul;245(1):181-196.
doi: 10.1111/joa.14034. Epub 2024 Mar 2.

Size and shape heterodonty in the early Permian synapsid Mesenosaurus efremovi

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Size and shape heterodonty in the early Permian synapsid Mesenosaurus efremovi

Tea Maho et al. J Anat.2024 Jul.

Abstract

Paleozoic synapsids represent the first chapter in the evolution of this large clade that includes mammals. These fascinating terrestrial vertebrates were the first amniotes to successfully adapt to a wide range of feeding strategies, reflected by their varied dental morphologies. Evolution of the marginal dentition on the mammalian side of amniotes is characterized by strong, size and shape heterodonty, with the late Permian therapsids showing heterodonty with the presence of incisiform, caniniform, and multicuspid molariform dentition. Rarity of available specimens has previously prevented detailed studies of dental anatomy and evolution in the initial chapter of synapsid evolution, when synapsids were able to evolve dentition for insectivory, herbivory, and carnivory. Numerous teeth, jaw elements, and skulls of the hypercarnivorous varanopid Mesenosaurus efremovi have been recently discovered in the cave systems near Richards Spur, Oklahoma, permitting the first detailed investigation of the dental anatomy of a Paleozoic tetrapod using multiple approaches, including morphometric and histological analyses. As a distant stem mammal, Mesenosaurus is the first member of this large and successful clade to exhibit a type of dental heterodonty that combines size and morphological (shape) variation of the tooth crowns. Here we present the first evidence of functional differentiation in the dentition of this early synapsid, with three distinct dental regions having diverse morphologies and functions. The quality and quantity of preserved materials has allowed us to identify the orientation and curvature of the carinae (cutting edges), and the variation and distribution of the ziphodonty (serrations) along the carinae. The shape-related heterodonty seen in this taxon may have contributed to this taxon's ability to be a successful mid-sized predator in the taxonomically diverse community of early Permian carnivores, but may have also extended the ecological resilience of this clade of mid-sized predators across major faunal and environmental transitions.

Keywords: Permian; amniote; computed tomography; dentition; heterodonty; histology; ziphodonty.

© 2024 The Authors. Journal of Anatomy published by John Wiley & Sons Ltd on behalf of Anatomical Society.

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Figures

FIGURE 1
FIGURE 1
Premaxillary dentition ofMesenosaurus efremovi. (a) Skull drawing ofM. efremovi highlighting premaxilla. (b) Photograph of OMNH 73500 premaxilla in right lateral view. Photographs of ROMVP 85458 in (c) labial view. (d) Closeup of labial view showing distal carinae. (e) Lingual view. (f) Closeup of lingual view showing mesial carinae. (g) Ventral (occlusal) view. (h) Closeup ventral view showing alveoli. Skull drawing was outlined and modified from Maho et al. (2022).
FIGURE 2
FIGURE 2
Maxillary dentition ofMesenosaurus efremovi. (a) Skull drawing ofM. efremovi highlighting maxilla. (b) Photograph of OMNH 73208 maxilla in right lateral view. (c) Photograph of ROMVP 85440 maxilla in left lateral view showing pre‐caniniform, caniniform, and post‐caniniform regions. (d) Photograph of ROMVP 85457 in labial view. (e) Closeup view showing serrated mesial and distal carinae of caniniform dentition. (f) Lingual view. (g) Closeup view showing serrated mesial and distal carinae of post‐caniniform dentition. Skull drawing was outlined and modified from Maho et al. (2022).
FIGURE 3
FIGURE 3
Dentary dentition ofMesenosaurus efremovi. (a) Skull drawing ofM. efremovi highlighting dentary. (b) Photograph of OMNH 73208 left dentary in lateral (labial) view showing mesial and distal regions. ROMVP 85492, tooth position 1 in (c) labial view and (d) lingual view. Tooth position 3 in (e) labial view and (f) lingual view. ROMVP 85499, tooth position 13 in (g) labial view and (h) lingual view. Tooth position 17 in (i) labial view and (j) lingual view. ROMVP 85498, tooth position 26 in (k) labial view and (l) lingual view. Scale = 250 μm. Skull drawing was outlined and modified from Maho et al. (2022).
FIGURE 4
FIGURE 4
Crown size (in mm) variability profiles with respect to tooth position for premaxillary, maxillary, and dentary dentition ofMesenosaurus efremovi. (a) Mean crown height (CH),n = 41. (b) Mean apical length (AL),n = 41.
FIGURE 5
FIGURE 5
Crown base size (in mm) variability profiles with respect to tooth position for premaxillary, maxillary, and dentary dentition ofMesenosaurus efremovi. (a) Mean crown base length (CBL),n = 41. (b) Mean crown base width (CBW),n = 41. Green represents the premaxilla, blue represents the maxilla, and red represents the dentary.
FIGURE 6
FIGURE 6
Crown shape variability profiles with respect to tooth position for premaxillary, maxillary, and dentary dentition ofMesenosaurus efremovi. (a) mean crown height ratio (CHR),n = 41. (b) mean crown base ratio (CBR),n = 41. Green represents the premaxilla, blue represents the maxilla, and red represents the dentary.
FIGURE 7
FIGURE 7
Microanatomy ofMesenosaurus efremovi. ROMVP 85453, dentary tooth showing (a) Photograph in labial view showing planes of TR cross‐section and longitudinal LL sections. (b) Whole view of tooth longitudinal LL section. (c) Closeup view of attachment tissues in longitudinal LL section. (d) Whole view of dentary TR cross‐section. ROMVP 85449, maxillary ziphodont teeth showing (e) photograph in labial view. Longitudinal AP section of (f) distal carina and (g) mesial carina. ab alveolar bone; ac, acellular cementum; cc, cellular cementum; d, dentine; en, enamel; gzd, globular zone of dentine; jb, jawbone; pc, pulp cavity; rl; reversal line. Figure concept after LeBlanc et al. (2016).
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References

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