飞行效率的海拔限制塑造了鸟类翅膀形态的全球梯度

bioRxiv Pub Date : 2024-07-16 DOI:10.1101/2024.07.12.603304
Jingyi Yang, Chenyue Yang, Hung-wei Lin, Alexander C. Lees, Joseph A. Tobias
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摘要

在从昆虫到鸟类的多种动物中,形状修长或表面积较大的翅膀与提高飞行效率和扩散能力有关1-4。翅膀形状的这些属性在种间和种内的差异由一系列因素决定,包括觅食生态学、迁徙和气候季节性5-8,所有这些因素都可能导致翅膀形态的纬度梯度9,10。另一个假说预测,翅膀形状也应遵循海拔梯度,因为空气密度和氧气供应随着海拔的升高而下降11,从而改变了飞行的空气动力学,促使高海拔物种进化出更高效的翅膀,以补偿升力的降低12,13。然而,以前的分析只发现了对 "稀薄空气 "假说的不同支持14-18,而且我们目前缺乏对任何分类群的翅膀设计的海拔梯度的全球综合分析。在本研究中,我们利用系统发生比较模型探讨了海拔高度对 9986 种鸟类翅膀形态的影响,同时考虑了多种气候和生态属性,包括纬度、温度季节性、体重、空中生活方式和迁徙。我们发现,相对翅膀伸长率(手翅指数)和翅膀面积随着海拔的升高而增加,尤其是在高山地区(海拔超过 4 公里)。这些结果证实了鸟类翅膀形态普遍存在海拔梯度,凸显了空气动力制约因素是影响飞行动物全球性状进化模式的关键机制。
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Elevational constraints on flight efficiency shape global gradients in avian wing morphology
Wings with elongated shape or larger surface area are associated with increased flight efficiency and dispersal ability in a wide range of animals from insects to birds 1–4. Inter- and intraspecific variation in these attributes of wing shape is determined by a range of factors – including foraging ecology, migration and climatic seasonality 5–8 – all of which may drive latitudinal gradients in wing morphology 9,10. A separate hypothesis predicts that wing shape should also follow an elevational gradient because air density and oxygen supply decline with altitude 11, altering the aerodynamics of flight, and driving the evolution of more efficient wings in high-elevation species to compensate for reduced lift 12,13. However, previous analyses have found only mixed support for the ‘thin-air’ hypothesis 14–18, and we currently lack a global synthesis of elevational gradients in wing design for any taxonomic group. In this study, we use phylogenetic comparative models to explore elevational effects on wing morphology in 9986 bird species, while accounting for multiple climatic and ecological attributes, including latitude, temperature seasonality, body mass, aerial lifestyle and migration. We found that relative wing elongation (hand-wing index) and wing area increase with elevation, particularly in the upper montane zone (>4 km above sea level). These results confirm a pervasive elevational gradient in avian wing morphology, highlighting the role of aerodynamic constraints as key mechanisms shaping global patterns of trait evolution in flying animals.
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