Apoplastic alterations as a common mechanism to freezing avoidance and growth cessation/dormancy induction through temperature-mediated pectin gelation

质外体改变是通过温度介导的果胶凝胶化避免冷冻和生长停止/休眠诱导的常见机制

• 批准号: 97642-2012
• 负责人: Tanino, Karen
• 金额: $ 1.82万
• 依托单位: University of Saskatchewan
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2013
• 资助国家: 加拿大
• 起止时间: 2013-01-01 至 2014-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=521885
• 关键词: Apoplastic; alterations; common; mechanism; freezing

Lack of plant synchrony with the environment is the primary cause of abiotic stress injury resulting in significant economic loss. Plants are stationary organisms and must adapt to their environment in order to survive. Temperature has been a key driver to adaptation throughout plant evolutionary history. However, the mechanism of these thermal adaptations is still not understood. The apoplastic space represents a key region regulating both ice propagation and cell growth. Apoplastic regions are permeability barriers to avoid ice propagation directly into the plant cell through arabinoxylan polymers or Anti-Freeze Proteins. The cell wall fraction is a biphasic structure consisting of cellulose microfibrils held together by a gel-like matrix. This gel-like matrix constitutes up to two-thirds of the cell wall's dry weight (47% of primary cell walls of Populus), and is composed of cross-linking extensin glycoproteins and non-cellulosic polysaccharides including pectins (polygalacturonic acids (PGAs), and rhamnogalacturonan (RG) I and II) and hemicelluloses. Pectins are the major regulatory molecule dictating the porosity of cell walls. The gelation, rigidity and subsequent permeability of the apoplast is dictated by the pectin matrix through Pectin Methyl Esterase (PME) which removes pectin methyl groups, allowing Ca2+ binding to the carboxylate ions and creating calcium cross-linkages. This rigidity and pectic gel formation also influences key cell expansion parameters of water flow and turgor pressure through changes in water permeability. PME's and pectin gelation are dynamic and temperature-sensitive but most of the evidence comes from the food processing literature. Remarkably, there are only a limited number of such studies in plants. This project will address the following overarching hypothesis through 1 Ph.D. student, 1 M.Sc. student and 4 undergraduate summer students: Apoplastic alterations through pectin gelation result in: a) freezing avoidance by reduced ice propagation into the intracellular space, and b) temperature-dependent dormancy induction through reduction of water flow.

植物与环境的不同步是造成非生物胁迫伤害的主要原因，造成了巨大的经济损失。植物是静止的生物，必须适应环境才能生存。 在植物进化史上，温度一直是适应的关键驱动力。 然而，这些热适应的机制仍然不清楚。质外体空间代表了调节冰繁殖和细胞生长的关键区域。 质外体区域是渗透性屏障，以避免冰通过阿拉伯木聚糖聚合物或防冻蛋白直接传播到植物细胞中。细胞壁部分是由通过凝胶状基质保持在一起的纤维素微纤丝组成的双相结构。 这种凝胶状基质占细胞壁干重的三分之二（占杨树初生细胞壁的47%），由交联伸展素糖蛋白和非纤维素多糖组成，包括果胶（聚半乳糖醛酸（PGA）和鼠李糖半乳糖醛酸聚糖（RG）I和II）和半纤维素。 果胶是决定细胞壁孔隙率的主要调节分子。 质外体的凝胶化、刚性和随后的渗透性由果胶基质通过果胶甲基酯酶（PME）决定，所述果胶甲基酯酶（PME）去除果胶甲基，允许Ca2+结合至羧酸根离子并产生钙交联。 这种刚性和果胶凝胶的形成也通过水渗透性的变化影响水流和膨压的关键细胞膨胀参数。 PME和果胶凝胶化是动态的和温度敏感的，但大多数证据来自食品加工文献。 值得注意的是，在植物中进行的此类研究数量有限。 该项目将通过1博士解决以下总体假设。学生、1名硕士生和4名暑期本科生：通过果胶凝胶化的质外体改变导致：a）通过减少冰传播到细胞内空间来避免冻结，和B）通过减少水流来诱导温度依赖性休眠。