Rapid GIT transit time in volant vertebrates, with implications for convergence in microbiome composition

bioRxiv - Ecology Pub Date : 2024-08-09 DOI:10.1101/2024.08.09.607319

Emily Cornelius Ruhs, Katherine McFerrin, Devin N Jones, Natalia Cortes-Delgado, Ny Anjara Fifi Ravelomanantsoa, Carl J Yeoman, Raina K Plowright, Cara E Brook

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Abstract

Flying birds and bats have simplified gastrointestinal tracts (GITs) and low intestinal mass to facilitate flight. Previous work showed reduced GIT transit times in birds relative to other vertebrates, but GIT transit has never been collectively quantified for bats. Unique among mammals, bat GIT microbiomes are dominated by Pseudomonadota bacteria (previously Proteobacteria), which also dominate the microbiomes of flying birds; we hypothesized this convergence to result from rapid GIT transit times for both volant taxa. We conducted a meta-analysis of vertebrate GIT transit times which showed that bats and flying birds have significantly faster transit times relative to nonvolant vertebrates. Additionally, within the bat order (Chiroptera), we demonstrated decreasing transit times associated with increasing body mass, a pattern contrasting other vertebrates (including volant birds) and possibly influencing GIT microbiome composition. This inverted mass-transit association is likely driven by diet as fruit- and nectar-consuming Pteropodids are the largest of all bats.

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伏卧脊椎动物快速的胃肠道转运时间对微生物群组成趋同的影响

飞行鸟类和蝙蝠具有简化的胃肠道（GIT）和较低的肠道质量，以便于飞行。以前的研究表明，相对于其他脊椎动物，鸟类的胃肠道转运时间较短，但蝙蝠的胃肠道转运时间从未被集体量化过。在哺乳动物中，蝙蝠的胃肠道微生物组以假单胞菌属细菌（以前为变形杆菌属）为主，这在飞禽的微生物组中也占主导地位；我们假设这种趋同性是由于这两种挥发性类群的快速胃肠道转运时间造成的。我们对脊椎动物胃肠道的转运时间进行了荟萃分析，结果表明蝙蝠和飞禽的转运时间明显快于非挥发性脊椎动物。此外，在蝙蝠目（Chiroptera）中，我们发现随着体重的增加，转运时间也随之减少，这种模式与其他脊椎动物（包括挥发性鸟类）形成鲜明对比，并可能影响胃肠道微生物组的组成。这种倒置的体重-转运关联可能是由饮食驱动的，因为食用水果和花蜜的翼手目蝙蝠是所有蝙蝠中体型最大的。

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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bioRxiv - Ecology

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