The genetic architecture of repeated local adaptation to climate in distantly related plants

IF 13.9 1区 生物学 Q1 ECOLOGY Nature ecology & evolution Pub Date : 2024-08-26 DOI:10.1038/s41559-024-02514-5
James R. Whiting, Tom R. Booker, Clément Rougeux, Brandon M. Lind, Pooja Singh, Mengmeng Lu, Kaichi Huang, Michael C. Whitlock, Sally N. Aitken, Rose L. Andrew, Justin O. Borevitz, Jeremy J. Bruhl, Timothy L. Collins, Martin C. Fischer, Kathryn A. Hodgins, Jason A. Holliday, Pär K. Ingvarsson, Jasmine K. Janes, Momena Khandaker, Daniel Koenig, Julia M. Kreiner, Antoine Kremer, Martin Lascoux, Thibault Leroy, Pascal Milesi, Kevin D. Murray, Tanja Pyhäjärvi, Christian Rellstab, Loren H. Rieseberg, Fabrice Roux, John R. Stinchcombe, Ian R. H. Telford, Marco Todesco, Jaakko S. Tyrmi, Baosheng Wang, Detlef Weigel, Yvonne Willi, Stephen I. Wright, Lecong Zhou, Sam Yeaman
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Abstract

Closely related species often use the same genes to adapt to similar environments. However, we know little about why such genes possess increased adaptive potential and whether this is conserved across deeper evolutionary lineages. Adaptation to climate presents a natural laboratory to test these ideas, as even distantly related species must contend with similar stresses. Here, we re-analyse genomic data from thousands of individuals from 25 plant species as diverged as lodgepole pine and Arabidopsis (~300 Myr). We test for genetic repeatability based on within-species associations between allele frequencies in genes and variation in 21 climate variables. Our results demonstrate significant statistical evidence for genetic repeatability across deep time that is not expected under randomness, identifying a suite of 108 gene families (orthogroups) and gene functions that repeatedly drive local adaptation to climate. This set includes many orthogroups with well-known functions in abiotic stress response. Using gene co-expression networks to quantify pleiotropy, we find that orthogroups with stronger evidence for repeatability exhibit greater network centrality and broader expression across tissues (higher pleiotropy), contrary to the ‘cost of complexity’ theory. These gene families may be important in helping wild and crop species cope with future climate change, representing important candidates for future study. Analysis of genomic data from 25 distantly related plant species shows signatures of selection on the same gene families and functions that repeatedly contributed to local adaptation to climate.

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远缘植物反复适应当地气候的遗传结构。
近亲物种经常使用相同的基因来适应相似的环境。然而,我们对这些基因为何具有更强的适应潜力以及这种潜力是否在更深的进化世系中得以保留知之甚少。对气候的适应是检验这些观点的天然实验室,因为即使是远缘物种也必须面对类似的压力。在这里,我们重新分析了来自 25 个植物物种的数千个个体的基因组数据,这些物种与落羽松和拟南芥(约 300 Myr)存在差异。我们根据基因中等位基因频率与 21 个气候变量变异之间的种内关联来检验遗传可重复性。我们的研究结果表明,在随机性条件下,遗传可重复性在整个深部时间内具有显著的统计学意义,并确定了一套 108 个基因家族(正交群)和基因功能,这些基因家族和基因功能反复驱动着当地对气候的适应。这组基因包括许多在非生物应激反应中具有众所周知功能的正交组。利用基因共表达网络来量化多效性,我们发现重复性证据更强的正交组表现出更高的网络中心性和更广泛的跨组织表达(更高的多效性),这与 "复杂性成本 "理论相反。这些基因家族在帮助野生物种和作物物种应对未来气候变化方面可能很重要,是未来研究的重要候选对象。
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来源期刊
Nature ecology & evolution
Nature ecology & evolution Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics
CiteScore
22.20
自引率
2.40%
发文量
282
期刊介绍: Nature Ecology & Evolution is interested in the full spectrum of ecological and evolutionary biology, encompassing approaches at the molecular, organismal, population, community and ecosystem levels, as well as relevant parts of the social sciences. Nature Ecology & Evolution provides a place where all researchers and policymakers interested in all aspects of life's diversity can come together to learn about the most accomplished and significant advances in the field and to discuss topical issues. An online-only monthly journal, our broad scope ensures that the research published reaches the widest possible audience of scientists.
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