Is vertebral shape variability in caecilians (Amphibia: Gymnophiona) constrained by forces experienced during burrowing?

Aurélien Lowie, B. De Kegel, M. Wilkinson, J. Measey, J. C. O’Reilly, N. Kley, P. Gaucher, J. Brecko, T. Kleinteich, D. Adriaens, A. Herrel
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Abstract

Caecilians are predominantly burrowing, elongate, limbless amphibians that remain relatively poorly studied. Although it has been suggested that the sturdy and compact skulls of caecilians are an adaptation to their head-first burrowing habits, no clear relationship between skull shape and burrowing performance appears to exist. However, the external forces encountered during burrowing are transmitted by the skull to the vertebral column, and as such, may impact vertebral shape. Additionally, the muscles that generate the burrowing forces attach onto the vertebral column and consequently may impact vertebral shape that way as well. Here, we explore the relationships between vertebral shape and maximal in vivo push forces in 13 species of caecilian amphibians. Our results show that the shape of the two most anterior vertebrae, as well as the shape of the vertebrae at 90% of the total body length, are not correlated with peak push forces. Conversely, the shape of the third vertebrae, and the vertebrae at 20% and 60% of the total body length, do show a relationship to push forces measured in vivo. Whether these relationships are indirect (external forces constraining shape variation) or direct (muscles forces constraining shape variation) remains unclear and will require quantitative studies of the axial musculature. Importantly, our data suggest that mid-body vertebrae may potentially be used as proxies to infer burrowing capacity in fossil representatives.
无尾螈(两栖类:裸鱼纲)的椎体形状变异性是否受到挖洞过程中所经历的力的限制?
无足动物主要是穴居、细长、无肢的两栖动物,对它们的研究相对较少。尽管有人认为,无尾猿结实紧凑的头骨是对其头朝前挖洞习惯的一种适应,但头骨形状和挖洞表现之间似乎没有明确的关系。然而,在挖洞过程中遇到的外力通过颅骨传递到脊柱,因此可能影响椎体形状。此外,产生挖洞力的肌肉附着在脊柱上,因此也可能以这种方式影响椎体的形状。在这里,我们探讨了13种蛭形两栖动物的脊椎形状和体内最大推力之间的关系。我们的研究结果表明,两个最前面的椎骨的形状,以及占体长90%的椎骨的形状,与最大推力无关。相反,第三节椎骨的形状,以及占全身长度20%和60%的椎骨,确实与体内测量的推力有关。这些关系是间接的(外力约束形状变化)还是直接的(肌肉力约束形状变化)尚不清楚,需要对轴向肌肉组织进行定量研究。重要的是,我们的数据表明,中体椎骨可能潜在地用作推断化石代表的挖洞能力的代理。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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