Research on plant-water relations examining physiological, structural, and molecular mechanisms of plant responses to their environment

植物与水关系的研究，考察植物对其环境反应的生理、结构和分子机制

• 批准号: RGPIN-2014-04137
• 负责人: Hacke, Uwe
• 金额: $ 2.19万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=652788
• 关键词: Research; plant; water; relations; examining

Water availability plays an important role in maintaining the health and productivity of both managed and natural ecosystems. In the light of global changes in temperature and precipitation patterns, it is becoming increasingly important to better understand physiological and molecular responses of plants to water stress. The impact of changes in temperature and precipitation on Canada's boreal forest is expected to be greater than on temperate and tropical forests. Forests in Canada are likely to be affected not only by direct impacts of drought but also by natural disturbances that are brought on by drought (e.g., fire and insects).**Water availability is often a limiting factor for the productivity of crops and the survival of plantation trees. Drought also reduces tree productivity and survival across many forest ecosystems. Whether a tree lives or dies in response to a drought episode depends in part on maintaining the integrity of its `plumbing system', which is positioned between the dry soil and the even dryer atmosphere. **The xylem (wood) is the principal water-conducting tissue in vascular plants. The hydraulic system of plants depends on a unique but inherently unstable mechanism. As the soil dries, water columns in the xylem may break, causing an air blockage (embolism). As drought increases, more embolism forms in the wood until leaves do not receive enough water to survive. We will study the hydraulic properties of different plant organs (leaves, stems, and roots) to determine which part of the plant is most vulnerable to embolism formation and loss of hydraulic conductivity. **While xylem allows for efficient transport of water and nutrients over long distances (over 100m in redwood trees), aquaporins (membrane-based water channels) facilitate water movement on a cellular scale. Before water enters the xylem in roots, and after it exits the xylem in leaf veins, it flows through living cells, via aquaporins. Water channels are dynamically regulated and are likely to play an important role in a plant's response to changing environments. We will study how aquaporins impact water flow in living cells of roots and leaves, in order to understand their role in drought stress physiology. Findings will be interpreted in a whole-plant context. The proposed research will integrate water relations research at the molecular, organ, organismal scales.

水的可用性在维持管理生态系统和自然生态系统的健康和生产力方面发挥着重要作用。鉴于全球温度和降水模式的变化，更好地了解植物对水分胁迫的生理和分子反应变得越来越重要。气温和降水变化对加拿大北方森林的影响预计将大于对温带和热带森林的影响。加拿大的森林可能不仅受到干旱的直接影响，而且还受到干旱带来的自然干扰（例如火灾和昆虫）的影响。**水的可用性往往是农作物和森林生产力的限制因素。人工林树木的生存。干旱还会降低许多森林生态系统的树木生产力和生存率。一棵树在干旱时期的生存或死亡部分取决于其“管道系统”的完整性，该系统位于干燥的土壤和甚至干燥的大气之间。 **木质部（木材）是维管植物中主要的导水组织。工厂的液压系统依赖于一种独特但本质上不稳定的机制。当土壤干燥时，木质部中的水柱可能会破裂，导致空气堵塞（栓塞）。随着干旱的加剧，木材中会形成更多的栓塞，直到叶子无法吸收足够的水来生存。我们将研究不同植物器官（叶、茎和根）的水力特性，以确定植物的哪个部分最容易形成栓塞和失去水力传导性。 **虽然木质部允许长距离（红杉树超过 100m）有效运输水和养分，但水通道蛋白（基于膜的水通道）促进细胞尺度上的水运动。在水进入根部木质部之前以及离开叶脉中的木质部之后，它通过水通道蛋白流经活细胞。水道是动态调节的，并且可能在植物应对不断变化的环境中发挥重要作用。我们将研究水通道蛋白如何影响根和叶活细胞中的水流，以了解它们在干旱胁迫生理学中的作用。研究结果将在整个工厂的背景下进行解释。拟议的研究将整合分子、器官、有机体尺度的水关系研究。