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全球真核生物生命之树的生境转变格局和速率。

Global patterns and rates of habitat transitions across the eukaryotic tree of life.

机构信息

Department of Organismal Biology (Systematic Biology), Uppsala University, Uppsala, Sweden.

CNRS, UMR7144, Team ECOMAP, Station Biologique, Sorbonne Université, Roscoff, France.

出版信息

Nat Ecol Evol. 2022 Oct;6(10):1458-1470. doi: 10.1038/s41559-022-01838-4. Epub 2022 Aug 4.

DOI:10.1038/s41559-022-01838-4
PMID:35927316
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9525238/
Abstract

The successful colonization of new habitats has played a fundamental role during the evolution of life. Salinity is one of the strongest barriers for organisms to cross, which has resulted in the evolution of distinct marine and non-marine (including both freshwater and soil) communities. Although microbes represent by far the vast majority of eukaryote diversity, the role of the salt barrier in shaping the diversity across the eukaryotic tree is poorly known. Traditional views suggest rare and ancient marine/non-marine transitions but this view is being challenged by the discovery of several recently transitioned lineages. Here, we investigate habitat evolution across the tree of eukaryotes using a unique set of taxon-rich phylogenies inferred from a combination of long-read and short-read environmental metabarcoding data spanning the ribosomal DNA operon. Our results show that, overall, marine and non-marine microbial communities are phylogenetically distinct but transitions have occurred in both directions in almost all major eukaryotic lineages, with hundreds of transition events detected. Some groups have experienced relatively high rates of transitions, most notably fungi for which crossing the salt barrier has probably been an important aspect of their successful diversification. At the deepest phylogenetic levels, ancestral habitat reconstruction analyses suggest that eukaryotes may have first evolved in non-marine habitats and that the two largest known eukaryotic assemblages (TSAR and Amorphea) arose in different habitats. Overall, our findings indicate that the salt barrier has played an important role during eukaryote evolution and provide a global perspective on habitat transitions in this domain of life.

摘要

新栖息地的成功殖民在生命进化中起着至关重要的作用。盐度是生物体跨越的最强障碍之一,这导致了独特的海洋和非海洋(包括淡水和土壤)群落的进化。尽管微生物代表了迄今为止绝大多数真核生物的多样性,但盐度障碍在塑造真核生物树多样性方面的作用还知之甚少。传统观点认为存在罕见而古老的海洋/非海洋过渡,但这一观点受到了最近发现的几个过渡谱系的挑战。在这里,我们使用一组独特的富含分类群的系统发育树,这些系统发育树是通过组合长读和短读环境宏条形码数据推断出来的,跨越核糖体 DNA 操纵子,来研究真核生物树中的栖息地进化。我们的研究结果表明,总体而言,海洋和非海洋微生物群落在系统发育上是不同的,但在几乎所有主要的真核生物谱系中,都发生了双向的过渡,检测到了数百个过渡事件。一些群体经历了相对较高的过渡率,最显著的是真菌,它们跨越盐度障碍可能是其成功多样化的一个重要方面。在最深远的系统发育水平上,祖先栖息地重建分析表明,真核生物可能最初是在非海洋栖息地中进化的,而两个最大的已知真核生物组合(TSAR 和 Amorphea)是在不同的栖息地中出现的。总的来说,我们的研究结果表明,盐度障碍在真核生物进化中起着重要作用,并为该生命领域的栖息地过渡提供了全球视角。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3531/9525238/326883d4ec1a/41559_2022_1838_Fig6_ESM.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3531/9525238/fdd0b200231c/41559_2022_1838_Fig7_ESM.jpg
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