Transcriptomic dynamics of ABA response in Brassica napus guard cells.

Florent Villiers, Yasir Suhail, Jade Lee, Felix Hauser, Jaeung Hwang, Joel S Bader, John K McKay, Scott C Peck, Julian I Schroeder, June M Kwak
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Abstract

Drought has a significant, negative impact on crop production; and these effects are poised to increase with climate change. Plants acclimate to drought and water stress through diverse physiological responses, primarily mediated by the hormone abscisic acid (ABA). Because plants lose the majority of their water through stomatal pores on aerial surfaces of plants, stomatal closure is one of the rapid responses mediated by ABA to reduce transpirational water loss. The dynamic changes in the transcriptome of stomatal guard cells in response to ABA have been investigated in the model plant Arabidopsis thaliana. However, guard cell transcriptomes have not been analyzed in agronomically valuable crops such as a major oilseed crop, rapeseed. In this study, we investigated the dynamics of ABA-regulated transcriptomes in stomatal guard cells of Brassica napus and conducted comparison analysis with the transcriptomes of A. thaliana. We discovered changes in gene expression indicating alterations in a host of physiological processes, including stomatal movement, metabolic reprogramming, and light responses. Our results suggest the existence of both immediate and delayed responses to ABA in Brassica guard cells. Furthermore, the transcription factors and regulatory networks mediating these responses are compared to those identified in Arabidopsis. Our results imply the continuing evolution of ABA responses in Brassica since its divergence from a common ancestor, involving both protein-coding and non-coding nucleotide sequences. Together, our results will provide a basis for developing strategies for molecular manipulation of drought tolerance in crop plants.

甘蓝型油菜护卫细胞中 ABA 响应的转录组动态。
干旱对作物生产有重大的负面影响;随着气候变化,这些影响还会加剧。植物通过各种生理反应来适应干旱和水分胁迫,这些反应主要由脱落酸(ABA)激素介导。由于植物的大部分水分是通过植物气生表面的气孔流失的,因此气孔关闭是 ABA 介导的快速反应之一,以减少蒸腾失水。在模式植物拟南芥(Arabidopsis thaliana)中研究了气孔保卫细胞转录组响应 ABA 的动态变化。然而,尚未对具有农艺价值的作物(如主要油料作物油菜籽)的保卫细胞转录组进行分析。在这项研究中,我们研究了甘蓝型油菜气孔保卫细胞中 ABA 调控转录组的动态,并与拟南芥的转录组进行了比较分析。我们发现基因表达的变化表明一系列生理过程发生了改变,包括气孔运动、代谢重编程和光反应。我们的研究结果表明,芸苔属防护细胞对 ABA 的反应既有即时反应,也有延迟反应。此外,我们还将介导这些反应的转录因子和调控网络与拟南芥中发现的转录因子和调控网络进行了比较。我们的研究结果表明,自芸薹属植物从共同祖先分化而来以来,其 ABA 反应在不断进化,其中涉及蛋白编码和非编码核苷酸序列。我们的研究结果将为制定作物耐旱性分子调控策略奠定基础。
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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