自鸟类起源以来,肌红蛋白对内热和飞行的独特适应性。

IF 3.5 1区 生物学 Q1 ZOOLOGY
Shengjing Song, Heye Chen, Yu Zhang, Xiaojia Zhu, David M Irwin, Kai He, Yang Liu
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引用次数: 0

摘要

肌红蛋白(Mb)介导肌肉组织中的氧气扩散和储存,因此对动物的能量利用和活动非常重要。鸟类的体温通常较高,大多数物种还具有动力飞行的能力。这两者都需要高水平的有氧代谢。在内热哺乳动物中,蝙蝠也独立进化出了飞行能力。尽管对深潜羊膜脊椎动物中肌红蛋白的功能进化进行了深入研究,但自鸟类和蝙蝠起源以来肌红蛋白的功能进化尚不清楚。在这里,我们利用来自超过200种现存羊膜动物的Mb编码序列,重建了祖先序列,以估计羊膜动物进化过程中肌红蛋白的功能特性。在鸟类的起源过程中,肌红蛋白的净表面电荷发生了巨大变化,这可能是在所有鸟类的血统中发生的正向选择氨基酸置换所导致的。然而,在蝙蝠中,净表面电荷没有发生变化,相反,Mb 基因显示出强烈的纯化选择。鸟类肌红蛋白表面净电荷的增加意味着鸟类适应了与飞行有关的内热和较高的体温,这可能是通过减少有害蛋白质的聚集实现的。与表面净电荷的发现不同,现生鸟类的肌红蛋白与其他羊膜动物相比稳定性较低,这可能加快了肌肉中氧气的利用率。在蝙蝠和其他哺乳动物中,Mb的较高稳定性可能是适应内温的另一种途径,这表明鸟类和蝙蝠的肌红蛋白在进化上存在差异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Unique myoglobin adaptation to endothermy and flight since the origin of birds.

Myoglobin (Mb) mediates oxygen diffusion and storage in muscle tissue and thus is important for the energy utilization and activity of animals. Birds generally have a high body temperature, and most species also possess the capability of powered flight. Both of these require high levels of aerobic metabolism. Within endothermic mammals, bats also independently evolved flight. Although the functional evolution of myoglobins in deep-diving amniote vertebrates has been well-studied, the functional evolution of myoglobin since the origins of both birds and bats is unclear. Here, with Mb-coding sequences from >200 extant amniote species, we reconstructed ancestral sequences to estimate the functional properties of myoglobin through amniote evolution. A dramatic change in net surface charge on myoglobin occurred during the origin of Aves, which might have been driven by positively selected amino acid substitutions that occurred on the lineage leading to all birds. However, in bats, no change in net surface charge occurred and instead, the Mb genes show evidence of strong purifying selection. The increased net surface charge on bird myoglobins implies an adaptation to flight-related endothermic and higher body temperatures, possibly by reducing harmful protein aggregations. Different from the findings of net surface charge, myoglobins of extant birds show lower stability compared with other amniotes, which probably accelerates the rate of oxygen utilization in muscles. In bats and other mammals, higher stability of Mb may be an alternative pathway for adaptation to endothermy, indicating divergent evolution of myoglobin in birds and bats.

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来源期刊
CiteScore
6.40
自引率
12.10%
发文量
81
审稿时长
>12 weeks
期刊介绍: The official journal of the International Society of Zoological Sciences focuses on zoology as an integrative discipline encompassing all aspects of animal life. It presents a broader perspective of many levels of zoological inquiry, both spatial and temporal, and encourages cooperation between zoology and other disciplines including, but not limited to, physics, computer science, social science, ethics, teaching, paleontology, molecular biology, physiology, behavior, ecology and the built environment. It also looks at the animal-human interaction through exploring animal-plant interactions, microbe/pathogen effects and global changes on the environment and human society. Integrative topics of greatest interest to INZ include: (1) Animals & climate change (2) Animals & pollution (3) Animals & infectious diseases (4) Animals & biological invasions (5) Animal-plant interactions (6) Zoogeography & paleontology (7) Neurons, genes & behavior (8) Molecular ecology & evolution (9) Physiological adaptations
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