Fibular reduction and the evolution of theropod locomotion

IF 50.5 1区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Nature Pub Date : 2024-11-20 DOI:10.1038/s41586-024-08251-w

Armita R. Manafzadeh, Stephen M. Gatesy, John A. Nyakatura, Bhart-Anjan S. Bhullar

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Abstract

Since Hampé’s classic developmental experiments in the mid-twentieth century^1,2, the reduced avian fibula has sparked sustained curiosity^3,4,5,6. The fibula transformed throughout dinosaur evolution from a columnar structure into its splint-like avian form, a change long thought to be of little biomechanical consequence^3,6. Here we integrated comparative three-dimensional kinematic analyses with transitional morphologies from the fossil record to refute this assumption and show that the reduced fibula serves a crucial function in enabling extreme knee long-axis rotation (LAR). Extreme LAR is fundamental to avian locomotion and is regularly exploited by living birds to execute complex terrestrial manoeuvres⁷. We infer that the evolution of this capacity was preceded by restriction of the knee to hinge-like motion in early theropod dinosaurs, driven by the origin of a mid-shank articulation⁸ that precluded ancestral patterns of tibiofibular motion. Freeing of the fibula from the ankle joint later enabled mobilization of this initially static articulation and, in doing so, established a novel pattern of tibiofibular kinematics essential to the extreme levels of LAR retained by modern birds. Fibular reduction thus ushered in a transition to LAR-dominated three-dimensional limb control, profoundly altering the course of theropod locomotor evolution.

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腓骨缩小与兽脚类运动的进化

自从汉佩在二十世纪中期进行了经典的发育实验1,2以来，鸟类腓骨的缩小一直引发着人们的好奇3,4,5,6。在恐龙的进化过程中，腓骨从柱状结构转变为鸟类的劈状结构，长期以来人们一直认为这种变化对生物力学影响不大3,6。在这里，我们将三维运动学比较分析与化石记录中的过渡形态相结合，驳斥了这一假设，并证明了退化的腓骨在实现膝关节长轴极限旋转（LAR）方面起着至关重要的作用。极度膝长轴旋转是鸟类运动的基本要素，活体鸟类经常利用它来执行复杂的陆地动作7。我们推断，在这种能力进化之前，早期的兽脚类恐龙的膝关节运动受限于铰链状运动，这是由胫骨中部关节8 的起源所驱动的，它排除了胫腓骨运动的祖先模式。后来，将腓骨从踝关节中解放出来，使这一最初静止的关节得以活动，从而建立了一种新的胫腓骨运动学模式，这种模式对于现代鸟类保持极高的LAR水平至关重要。因此，腓骨缩减开启了向以 LAR 为主导的三维肢体控制的过渡，深刻地改变了兽脚类运动进化的进程。

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

Nature 综合性期刊-综合性期刊

CiteScore

90.00

自引率

1.20%

发文量

3652

审稿时长

3 months

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