Transposable elements are entangled in rapid adaptation to climate change

bioRxiv - Plant Biology Pub Date : 2024-09-02 DOI:10.1101/2024.09.02.610836

Evgenii V Potapenko, David Schwartz, Tali Mandel, Nimrod Ashkenazy, Dana Fuerst, Guy Atzmon, Abraham B Korol, Michael B Kantar, Avi Bar-Massada, Sariel Hubner

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Abstract

Biodiversity conservation is urged at biodiversity hotspots that are under constant threat from anthropogenic development, yet a careful examination of the adaptive potential is a prerequisite for action. The Levant is considered a biodiversity hotspot and the distribution edge for many species, including important crop wild relatives. This region is under accelerated desertification and constantly disturbed by human activities, thus urging intervenient action. We collected and sequenced 300 wild barley plants along an eco-geographic gradient following a unique ecological-genetic sampling design. This scheme enabled to overcome the tight correlation between environmental and geographic distances. Phenotypic data was collected from 3600 progeny plants over three years and enabled to identify adaptive haplotype blocks comprised of phenological regulating genes tightly linked to drought and heat responsive genes. These haplotype blocks were highly enriched for transposable elements insertions, likely regulating genetic variation around adaptive genes, especially in stressed populations. Ecological and evolutionary models using over 2600 observations were combined to predict maladaptive risk, indicating that populations will be funneled into higher water availability refugia habitats while increasing isolation. Our findings highlight the main factors affecting rapid local adaptation and provide important recommendations for biodiversity management and conservation.

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可转座元件与快速适应气候变化息息相关

生物多样性热点地区一直受到人类发展的威胁，因此需要保护生物多样性，但采取行动的先决条件是仔细研究其适应潜力。黎凡特被视为生物多样性热点地区和许多物种的分布区，包括重要的作物野生近缘种。该地区正在加速荒漠化，并不断受到人类活动的干扰，因此需要采取干预行动。我们采用独特的生态遗传采样设计，沿着生态地理梯度采集了 300 株野生大麦植物并进行了测序。这一方案克服了环境和地理距离之间的紧密相关性。在三年时间里，我们从 3600 株后代植株中收集了表型数据，从而确定了由与干旱和高温响应基因紧密相关的表型调节基因组成的适应性单倍型区块。这些单倍型区块高度富集了转座元件插入，可能调节了适应性基因周围的遗传变异，尤其是在受压种群中。生态学和进化模型结合使用了2600多个观测数据，预测了适应不良的风险，表明种群将被引向水供应量较高的避难栖息地，同时增加隔离。我们的研究结果强调了影响当地快速适应的主要因素，并为生物多样性管理和保护提供了重要建议。

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 - Plant Biology

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