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二叠纪晚期爬行动物的颅骨骨学与神经解剖学及其对早期爬行动物进化的意义。

Cranial osteology and neuroanatomy of the late Permian reptile and implications for early reptile evolution.

作者信息

Jenkins Xavier A, Benson Roger B J, Ford David P, Browning Claire, Fernandez Vincent, Griffiths Elizabeth, Choiniere Jonah, Peecook Brandon R

机构信息

Department of Biological Sciences, Idaho State University, Pocatello, Idaho, USA.

Idaho Museum of Natural History, Pocatello, Idaho, USA.

出版信息

R Soc Open Sci. 2025 Jan 8;12(1):241298. doi: 10.1098/rsos.241298. eCollection 2025 Jan.

DOI:10.1098/rsos.241298
PMID:39780968
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11707879/
Abstract

Millerettidae are a group of superficially lizard-like Permian stem reptiles originally hypothesized as relevant to the ancestry of the reptile crown group, and particularly to lepidosaurs and archosaurs. Since the advent of cladistics, millerettids have typically been considered to be more distant relatives of crown reptiles as the earliest-diverging parareptiles and therefore outside of 'Eureptilia'. Despite this cladistic consensus, some conspicuous features of millerettid anatomy invite reconsideration of their relationships. We provide a detailed description of the late Permian millerettid using synchrotron X-ray phase-contrast micro-computed tomography focusing on the cranial anatomy of three individuals known from a burrow aggregation. Our data reveal a suite of neuroanatomical features shares with neodiapsids that are absent both in other 'parareptiles' and in early diverging groups of 'eureptiles'. Traits shared between Milleropsis and neodiapsids include: the presence of a tympanic emargination on the quadrate, quadratojugal and squamosal, the loss of epipterygoid contribution to the basicranial articulation suggesting a more kinetic palatoquadrate, the absence of a sphenethmoid and the pathway of the abducens nerve through the braincase. Our findings suggest that the early reptile neurocranium, a region poorly sampled in phylogenetic analyses due to relative visual inaccessibility and poor preservation, has the potential to inform the phylogenetic relationships of early reptiles.

摘要

米勒古蜥科是一类外表类似蜥蜴的二叠纪干群爬行动物,最初被假设与爬行类冠群的祖先有关,特别是与鳞龙类和主龙类有关。自从分支系统学出现以来,米勒古蜥类通常被认为是冠群爬行动物更为疏远的亲属,是最早分化的副爬行动物,因此在“真爬行动物”之外。尽管有这种分支系统学上的共识,但米勒古蜥类解剖学的一些显著特征促使人们重新考虑它们之间的关系。我们使用同步辐射X射线相衬显微计算机断层扫描技术,对晚二叠世的米勒古蜥类进行了详细描述,重点关注了从一个洞穴聚集群中得知的三个个体的颅骨解剖结构。我们的数据揭示了一系列神经解剖学特征,这些特征是米勒古蜥类与新双弓类共有的,而在其他“副爬行动物”和“真爬行动物”的早期分化类群中都不存在。米勒古蜥属与新双弓类共有的特征包括:方骨、方轭骨和鳞骨上有鼓膜凹陷;上翼骨对基本颅关节的贡献消失,表明腭方骨更加灵活;没有蝶筛骨;外展神经通过脑壳的路径。我们的研究结果表明,早期爬行动物的脑颅,这个在系统发育分析中由于相对难以观察和保存不佳而采样不足的区域,有可能为早期爬行动物的系统发育关系提供信息。

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Cranial anatomy of Emeroleter levis and the phylogeny of Nycteroleteridae.
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PLoS One. 2024 Apr 29;19(4):e0298216. doi: 10.1371/journal.pone.0298216. eCollection 2024.
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Cranial anatomy of Libognathus sheddi Small, 1997 (Parareptilia, Procolophonidae) from the Upper Triassic Dockum Group of West Texas, USA.1997年斯莫尔命名的谢迪利博颚龙(副爬行动物,前棱蜥科)的颅骨解剖,来自美国得克萨斯州西部上三叠统多库姆组
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