Structural and Functional Study of Protein Post-Translational Modifications involved in Plant Stress Signaling

植物应激信号转导中蛋白质翻译后修饰的结构和功能研究

• 批准号: RGPIN-2019-06807
• 负责人: Cappadocia, Laurent
• 金额: $ 2.19万
• 依托单位: Université du Québec à Montréal
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=748659
• 关键词: Structural; Functional; Study; Protein; Post

Abiotic stresses, such as drought, flood, salinity or extreme temperatures, can severely reduce the yield of major agricultural crops, and these losses are increasing as the effects of climate change become more pronounced. Plants respond to abiotic stresses at the molecular level by triggering signaling pathways that lead to changes in the expression of numerous genes to allow plants to acclimate to their new environment. Ubiquitination and SUMOylation, two post-translational modifications where Ubiquitin or SUMO (Small Ubiquitin-like Modifier) proteins are covalently attached to target proteins, are increasingly recognized as playing a prominent role in the modulation of these pathways. However, how they operate at the molecular level remains quite elusive. The overarching goal of my research program is to structurally and functionally characterize the molecular determinants of Ubiquitination and SUMOylation events involved in plant response to abiotic stresses so that better stress-resilient plant mutants can be rationally designed or selected. Towards this goal, the three following specific objectives will be addressed: 1. Identify the molecular determinants of specific and validated SUMOylation events involved in plant abiotic stress response. 2. Determine how plants balance growth and stress responses at the molecular level by characterizing specific post-translational modification events in the signaling pathway of gibberellins, a family of plant growth regulators that are also involved in plant stress response. 3. Understand the contribution of selected individual and collective E3-substrate interactions to plant abiotic stress response through functional analyses in the model organism Arabidopsis thaliana. In doing so, our research program will generate a framework for understanding interactions involved in plant stress response at the molecular level, with a special interest for post-translational modifications, as these can rapidly remodel entire response pathways. This should facilitate the design or selection of plants with increased tolerance to abiotic stress. Mutants of the gibberellin and SUMOylation pathways are already attractive targets for crop improvement. Our gained structural information will further allow genetic engineering of agronomically useful plants in a very targeted and tunable manner. Also, the identification of the molecular determinants and their validated role in stress response, will help predict the effects of natural variations in genomic populations. Such variants could then be isolated through marker-assisted breeding strategies and would constitute an alternative to the commercial development of transgenic plants. Our research program should thus provide important benefits to Canadian agriculture in a context where pressure on global agriculture steadily increases with increasing world population, shrinking agricultural area, and significant climate change.

干旱、洪水、盐碱化或极端温度等非生物胁迫会严重降低主要农作物的产量，而且随着气候变化的影响变得更加明显，这些损失正在增加。植物在分子水平上通过触发信号通路来应对非生物胁迫，这些信号通路导致许多基因的表达发生变化，从而使植物适应新的环境。泛素化（Ubiquitination）和SUMOylation是泛素或SUMO （Small Ubiquitin-like Modifier）蛋白共价附着在靶蛋白上的两种翻译后修饰，越来越被认为在这些途径的调节中起着重要作用。然而，它们是如何在分子水平上起作用的仍然难以捉摸。我的研究项目的总体目标是在结构和功能上表征植物对非生物胁迫反应中泛素化和SUMOylation事件的分子决定因素，以便合理设计或选择更好的抗逆性植物突变体。为实现这一目标，将处理以下三个具体目标：确定参与植物非生物胁迫反应的特定和验证的SUMOylation事件的分子决定因素。2. 通过描述赤霉素信号通路中特定的翻译后修饰事件，确定植物如何在分子水平上平衡生长和胁迫反应。赤霉素是植物生长调节剂家族，也参与植物的胁迫反应。3. 通过对模式生物拟南芥的功能分析，了解特定个体和集体e3 -底物相互作用对植物非生物胁迫反应的贡献。在此过程中，我们的研究计划将在分子水平上产生一个框架，用于理解植物胁迫反应中涉及的相互作用，对翻译后修饰特别感兴趣，因为这些修饰可以快速重塑整个反应途径。这将有助于设计或选择对非生物胁迫具有更高耐受性的植物。赤霉素和SUMOylation途径的突变体已经成为作物改良的有吸引力的目标。我们获得的结构信息将进一步允许以非常有针对性和可调的方式进行农用植物的基因工程。此外，分子决定因素的鉴定及其在应激反应中的作用将有助于预测基因组群体中自然变异的影响。这样的变异可以通过标记辅助育种策略进行分离，并将构成转基因植物商业开发的另一种选择。随着世界人口的增加、农业面积的缩小和气候的显著变化，全球农业面临的压力稳步增加，因此，我们的研究项目应该为加拿大农业提供重要的好处。