Xiangyu Xu, Hongyan Liu, Myrthe Praat, Gaston A. Pizzio, Zhang Jiang, Steven Michiel Driever, Ren Wang, Brigitte Van De Cotte, Selwyn L. Y. Villers, Kris Gevaert, Nathalie Leonhardt, Hilde Nelissen, Toshinori Kinoshita, Steffen Vanneste, Pedro L. Rodriguez, Martijn van Zanten, Lam Dai Vu, Ive De Smet
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Coinciding stress conditions may evoke conflicting stomatal responses, but the cellular mechanisms to resolve these conflicts are unknown. Here we demonstrate that the high-temperature-associated kinase TARGET OF TEMPERATURE 3 directly controls the activity of plasma membrane H+-ATPases to induce stomatal opening. OPEN STOMATA 1, which regulates stomatal closure to prevent water loss during drought stress, directly inactivates TARGET OF TEMPERATURE 3 through phosphorylation. Taken together, this signalling axis harmonizes stomatal opening and closing under high temperatures and/or drought. In the context of global climate change, understanding how different stress signals converge on stomatal regulation allows the development of climate-change-ready crops. Stomata regulate gas exchange and help plants cope with abiotic stress. 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引用次数: 0
摘要
植物不断响应不断变化的环境条件,以防止损害并保持最佳性能。为了调节与环境的气体交换和控制非生物压力的释放,植物的叶表皮上有气孔,称为气孔。多种环境信号影响着这些气孔的开启和关闭。高温促进气孔打开(降温),干旱导致气孔关闭(防止水分流失)。一致的应激条件可能会引起相互冲突的气孔反应,但解决这些冲突的细胞机制尚不清楚。在这里,我们证明了高温相关激酶TARGET OF TEMPERATURE 3直接控制质膜H+- atp酶的活性来诱导气孔打开。OPEN STOMATA 1在干旱胁迫下调节气孔关闭以防止水分流失,通过磷酸化直接使TARGET OF TEMPERATURE 3失活。综上所述,这条信号轴在高温和/或干旱条件下协调气孔的开启和关闭。在全球气候变化的背景下,了解不同的胁迫信号如何汇聚到气孔调节中,可以培育出适应气候变化的作物。
Stomatal opening under high temperatures is controlled by the OST1-regulated TOT3–AHA1 module
Plants continuously respond to changing environmental conditions to prevent damage and maintain optimal performance. To regulate gas exchange with the environment and to control abiotic stress relief, plants have pores in their leaf epidermis, called stomata. Multiple environmental signals affect the opening and closing of these stomata. High temperatures promote stomatal opening (to cool down), and drought induces stomatal closing (to prevent water loss). Coinciding stress conditions may evoke conflicting stomatal responses, but the cellular mechanisms to resolve these conflicts are unknown. Here we demonstrate that the high-temperature-associated kinase TARGET OF TEMPERATURE 3 directly controls the activity of plasma membrane H+-ATPases to induce stomatal opening. OPEN STOMATA 1, which regulates stomatal closure to prevent water loss during drought stress, directly inactivates TARGET OF TEMPERATURE 3 through phosphorylation. Taken together, this signalling axis harmonizes stomatal opening and closing under high temperatures and/or drought. In the context of global climate change, understanding how different stress signals converge on stomatal regulation allows the development of climate-change-ready crops. Stomata regulate gas exchange and help plants cope with abiotic stress. The authors identify a signalling pathway that coordinates the balance between stomatal opening and closing under high-temperature and/or drought conditions.
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Nature Plants is an online-only, monthly journal publishing the best research on plants — from their evolution, development, metabolism and environmental interactions to their societal significance.
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