Simone Castellana, Paolo Maria Triozzi, Matteo Dell'Acqua, Elena Loreti, Pierdomenico Perata
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Here, using an environmental genome-wide association study (eGWAS) of 934 non-redundant georeferenced Arabidopsis ecotypes, we have identified functional variants of the gene MED25 BINDING RING-H2 PROTEIN 1 (MBR1). This gene encodes a ubiquitin-protein ligase that regulates MEDIATOR25 (MED25), part of a multiprotein complex that interacts with transcription factors that act as key drivers of the hypoxic response in Arabidopsis, namely the RELATED TO AP2 proteins RAP2.2 and RAP2.12. Through experimental validation, we show that natural variants of MBR1 have different effects on the stability of MED25 and, in turn, on hypoxia tolerance. This study also highlights the pivotal role of the MBR1/MED25 module in establishing a comprehensive hypoxic response. Our findings show that molecular candidates for plant environmental adaptation can be effectively mined from large datasets. 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引用次数: 0
摘要
在气候危机导致天气条件迅速变化且难以预测的时代,了解植物的本地适应机制对于保护物种至关重要。随着极端降水事件的频率和强度增加,土壤水分饱和导致的洪水事件也在增加。由此引发的缺氧胁迫是造成作物损害和减产的主要原因之一。如今,通过将基因组学与遥感数据相结合,可以探究在不同降雨机制下进化的自然植物种群,并寻找对缺氧的分子适应性。在这里,通过对 934 个非冗余地理参照拟南芥生态型进行环境全基因组关联研究(eGWAS),我们确定了基因 MED25 BINDING RING-H2 PROTEIN 1(MBR1)的功能变异。这是一种泛素蛋白连接酶,能调节 MEDIATOR25(MED25),MED25 是多蛋白复合物的一部分,能与拟南芥缺氧反应的关键转录因子(即 RELATED TO AP2 蛋白、RAP2.2 和 RAP2.12)相互作用。通过实验验证,我们发现 MBR1 的天然变体对 MED25 的稳定性有不同的影响,进而影响缺氧耐受性。这项研究还强调了 MBR1/MED25 模块在建立全面缺氧反应中的关键作用。我们的研究结果表明,可以从大型数据集中有效地挖掘出植物环境适应的候选分子。因此,这支持了将正向遗传学和反向遗传学结合起来并对结果进行强有力的分子生理学验证的必要性。
Environmental genome-wide association studies across precipitation regimes reveal that the E3 ubiquitin ligase MBR1 regulates plant adaptation to rainy environments.
In an era characterized by rapidly changing and less-predictable weather conditions fueled by the climate crisis, understanding the mechanisms underlying local adaptation in plants is of paramount importance for the conservation of species. As the frequency and intensity of extreme precipitation events increase, so are the flooding events resulting from soil water saturation. The subsequent onset of hypoxic stress is one of the leading causes of crop damage and yield loss. By combining genomics and remote sensing data, it is now possible to probe natural plant populations that have evolved in different rainfall regimes and look for molecular adaptation to hypoxia. Here, using an environmental genome-wide association study (eGWAS) of 934 non-redundant georeferenced Arabidopsis ecotypes, we have identified functional variants of the gene MED25 BINDING RING-H2 PROTEIN 1 (MBR1). This gene encodes a ubiquitin-protein ligase that regulates MEDIATOR25 (MED25), part of a multiprotein complex that interacts with transcription factors that act as key drivers of the hypoxic response in Arabidopsis, namely the RELATED TO AP2 proteins RAP2.2 and RAP2.12. Through experimental validation, we show that natural variants of MBR1 have different effects on the stability of MED25 and, in turn, on hypoxia tolerance. This study also highlights the pivotal role of the MBR1/MED25 module in establishing a comprehensive hypoxic response. Our findings show that molecular candidates for plant environmental adaptation can be effectively mined from large datasets. This thus supports the need for integration of forward and reverse genetics with robust molecular physiology validation of outcomes.
期刊介绍:
Plant Communications is an open access publishing platform that supports the global plant science community. It publishes original research, review articles, technical advances, and research resources in various areas of plant sciences. The scope of topics includes evolution, ecology, physiology, biochemistry, development, reproduction, metabolism, molecular and cellular biology, genetics, genomics, environmental interactions, biotechnology, breeding of higher and lower plants, and their interactions with other organisms. The goal of Plant Communications is to provide a high-quality platform for the dissemination of plant science research.