PEROMYSCUS 的骨骼结构分析：穴居行为的影响。

IF 1.8 4区医学 Q2 ANATOMY & MORPHOLOGY

Anatomical Record-Advances in Integrative Anatomy and Evolutionary Biology Pub Date : 2024-06-08 DOI:10.1002/ar.25508

Lindsey A. Young, Emma Munro, Priya Somanchi, Abigail Bemis, Stephanie M. Smith, Sandra J. Shefelbine

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引用次数: 0

摘要

我们比较了两种鹿鼠（Peromyscus）穴居行为对附骨结构的影响。P.polionotus在它们的领地中创造复杂的洞穴，而P.eremicus则是一种不掘洞的筑巢鼠。我们研究了博物馆标本中野生捕获的这两种小鼠的骨骼，以及实验室饲养的没有机会钻洞的 P. polionotus。我们使用微型计算机断层扫描对骨骼进行了扫描，并对皮质和小梁骨骼的结构特性进行了量化。与实验室饲养的小鼠相比，野生小鼠尺骨和胫骨皮质骨的面积矩较大，这表明小鼠在发育过程中适应了弯曲阻力。与勃氏野鼠相比，野生勃氏野鼠胫骨的归一化第二面积矩和横截面积较大。胫骨骨小梁分析表明，野生脊灰龙的骨小梁厚度和间距均低于勃氏脊灰龙；股骨分析表明，野生脊灰龙的厚度低于勃氏脊灰龙，间距低于实验室饲养的脊灰龙，这表明脊灰龙适应了挖掘产生的高负荷。研究结果为今后探索啮齿类动物机械适应的本体和进化基础奠定了基础。

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Analysis of bone structure in PEROMYSCUS: Effects of burrowing behavior

We compare the effects of burrowing behavior on appendicular bone structure in two Peromyscus (deer mouse) species. P. polionotus creates complex burrows in their territories, while P. eremicus is a non-burrowing nesting mouse. We examined museum specimens' bones of wild-caught mice of the two species and lab-reared P. polionotus not given the opportunity to burrow. Bones were scanned using micro-computed tomography, and cortical and trabecular bone structural properties were quantified. Wild P. polionotus mice had a larger moment of area in the ulnar and tibial cortical bone compared with their lab-reared counterparts, suggesting developmental adaptation to bending resistance. Wild P. polionotus had a larger normalized second moment of area and cross-sectional area in the tibia compared with P. eremicus. Tibial trabecular analysis showed lower trabecular thickness and spacing in wild P. polionotus than in P. eremicus and femoral analysis showed wild P. polionotus had lower thickness than P. eremicus and lower spacing than lab-reared P. polionotus, suggesting adaptation to high loads from digging. Results lay the groundwork for future exploration of the ontogenetic and evolutionary basis of mechanoadaptation in Peromyscus.