Turtle Shell Kinesis Underscores Constraints and Opportunities in the Evolution of the Vertebrate Musculoskeletal System.

IF 2.2 4区 生物学 Q2 BIOLOGY
Integrative Organismal Biology Pub Date : 2023-09-04 eCollection Date: 2023-01-01 DOI:10.1093/iob/obad033
G A Cordero
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Abstract

Species groups that feature traits with a low number of potentially variable (evolvable) character states are more likely to repeatedly evolve similar phenotypes, that is, convergence. To evaluate this phenomenon, this present paper addresses anatomical alterations in turtles that convergently evolved shell kinesis, for example, the movement of shell bones to better shield the head and extremities. Kinesis constitutes a major departure from the evolutionarily conserved shell of modern turtles, yet it has arisen independently at least 8 times. The hallmark signature of kinesis is the presence of shell bone articulations or "hinges," which arise via similar skeletal remodeling processes in species that do not share a recent common ancestor. Still, the internal biomechanical components that power kinesis may differ in such distantly related species. Complex diarthrodial joints and modified muscle connections expand the functional boundaries of the limb girdles and neck in a lineage-specific manner. Some lineages even exhibit mobility of thoracic and sacral vertebrae to facilitate shell closure. Depending on historical contingency and structural correlation, a myriad of anatomical alterations has yielded similar functional outcomes, that is, many-to-one mapping, during the convergent evolution of shell kinesis. The various iterations of this intricate phenotype illustrate the potential for the vertebrate musculoskeletal system to undergo evolutionary change, even when constraints are imposed by the development and structural complexity of a shelled body plan. Based on observations in turtles and comparisons to other vertebrates, a hypothetical framework that implicates functional interactions in the origination of novel musculoskeletal traits is presented.

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龟壳运动揭示了脊椎动物肌肉骨骼系统进化中的制约因素和机遇。
具有少量潜在可变(可进化)特征状态的物种群体更有可能重复进化相似的表型,即趋同。为了评估这一现象,本文讨论了海龟的解剖学变化,这些变化集中进化出了外壳运动,例如,外壳骨骼的运动以更好地保护头部和四肢。Kinesis与现代海龟进化上保守的外壳有很大不同,但它已经独立出现了至少8次。运动学的标志性特征是壳骨关节或“铰链”的存在,这是通过类似的骨骼重塑过程在没有共同祖先的物种中产生的。尽管如此,在这种亲缘关系较远的物种中,驱动运动学的内部生物力学成分可能有所不同。复杂的二颈关节和改良的肌肉连接以特定谱系的方式扩展了肢带和颈部的功能边界。一些谱系甚至表现出胸椎和骶骨的活动性,以便于闭合外壳。根据历史偶然性和结构相关性,在外壳运动的趋同进化过程中,无数的解剖改变产生了类似的功能结果,即多对一映射。这种复杂表型的各种迭代说明了脊椎动物肌肉骨骼系统发生进化变化的潜力,即使在有壳身体计划的发展和结构复杂性施加限制的情况下也是如此。基于对海龟的观察和与其他脊椎动物的比较,提出了一个假设框架,该框架将功能相互作用与新的肌肉骨骼特征的起源联系起来。
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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来源期刊
CiteScore
3.70
自引率
6.70%
发文量
48
审稿时长
20 weeks
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