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扁桨龙(伪鳄类,海鳄亚目)的综合古生理学

Integrative paleophysiology of the metriorhynchoid Pelagosaurus typus (Pseudosuchia, Thalattosuchia).

作者信息

Cubo Jorge, Sena Mariana V A, Pellarin Romain, Faure-Brac Mathieu G, Aubier Paul, Cheyron Cassandra, Jouve Stéphane, Allain Ronan, Jalil Nour-Eddine

机构信息

Sorbonne Université, Muséum National d'Histoire Naturelle, CNRS, Centre de Recherche en Paléontologie-Paris (CR2P, UMR 7207), Paris, France.

Naturhistorisk Museum, Universitetet i Oslo, Norsk Senter for Paleontologi, Oslo, Norway.

出版信息

Anat Rec (Hoboken). 2025 Feb;308(2):394-411. doi: 10.1002/ar.25548. Epub 2024 Aug 23.

DOI:10.1002/ar.25548
PMID:39180142
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11725722/
Abstract

Paleophysiology is an emergent discipline. Organismic (integrative) approaches seem more appropriate than studies focusing on the variation of specific features because traits are tightly related in actual organisms. Here, we used such an organismic approach (including lifestyle, thermometabolism, and hunting behavior) to understand the paleobiology of the lower Jurassic (Toarcian) thalattosuchian metriorhynchoid Pelagosaurus typus. First, we show that the lifestyle (aquatic, amphibious, terrestrial) has an effect on the femoral compactness profiles in amniotes. The profile of Pelagosaurus indicates that it was amphibious, with a foraging activity in shallow marine environments (as suggested by the presence of salt glands) and thermoregulatory basking behavior in land (as suggested by the presence of osteoderms with highly developed ornamentation). As for the thermometabolism, we show that the mass-independent resting metabolic rate of Pelagosaurus is relatively high compared to the sample of extant ectothermic amniotes, but analysis of vascular canal diameter and inferences of red blood cell size refute the hypothesis suggesting incipient endothermy. Finally, the foraging behavior was inferred using two proxies. Pelagosaurus had a mass-independent maximum metabolic rate and an aerobic scope higher than those measured in the almost motionless Iguana iguana, similar to those measured in the sit-and-wait predator Crocodylus porosus but lower than those quantified in the active hunter Varanus gouldii. These results suggest that Pelagosaurus may have had a hunting behavior involving a slow sustained swimming or a patient waiting in shallow waters, and may have caught preys like gharials, using fast sideways sweeping motions of the head.

摘要

古生理学是一门新兴学科。与专注于特定特征变化的研究相比,生物体(综合)方法似乎更为合适,因为在实际生物体中,性状是紧密相关的。在这里,我们采用了这样一种生物体方法(包括生活方式、体温调节代谢和捕食行为)来理解下侏罗纪(托阿尔阶)海生鳄类中真鼻鳄类的平齿蜥的古生物学。首先,我们表明生活方式(水生、水陆两栖、陆生)对羊膜动物的股骨致密性剖面有影响。平齿蜥的剖面表明它是水陆两栖的,在浅海环境中有觅食活动(盐腺的存在表明了这一点),在陆地上有体温调节的晒太阳行为(高度发达纹饰的骨板的存在表明了这一点)。至于体温调节代谢,我们表明,与现存变温羊膜动物的样本相比,平齿蜥的质量独立静息代谢率相对较高,但对血管管径的分析和对红细胞大小的推断反驳了表明初期恒温的假说。最后,利用两个指标推断了捕食行为。平齿蜥的质量独立最大代谢率和有氧代谢范围高于几乎不动的绿鬣蜥,与坐等捕食者湾鳄的测量值相似,但低于活跃捕食者砂巨蜥的测量值。这些结果表明,平齿蜥可能具有一种捕食行为,包括缓慢持续游泳或在浅水中耐心等待,并且可能像恒河鳄一样,利用头部快速的侧向扫动动作捕捉猎物。

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