Function of Basic Helix-Loop-Helix Transcription Factors in Specifying Stomatal Cell Fate

基本螺旋-环-螺旋转录因子在指定气孔细胞命运中的功能

• 批准号: 0855659
• 负责人: Keiko Torii
• 金额: $ 42万
• 依托单位: University of Washington
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-03-01 至 2012-09-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0855659&HistoricalAwards=false
• 关键词: Function; Basic; Helix; Loop; Transcription

The productivity of land plants relies on the proper development and function of stomata, which are microscopic valves on the plant surface. Stomata regulate the movement of gases between plants and the atmosphere. Molecules of carbon dioxide (a greenhouse gas) enter the plant through the stomata and are converted into carbohydrates by photosynthesis. Oxygen, a byproduct of photosynthesis, is then released from plants to the atmosphere through the stomata. In addition, water loss through open stomata, a process known as transpiration, promotes water movement from the roots and supports plant growth, while closure of stomata prevents plants from wilting. During plant development, stomata are formed through a series of differentiation events, where activation of "master regulatory" transcription factors with a basic helix-loop-helix (bHLH) motif play a pivotal role. Three bHLH proteins, SPEECHLESS, MUTE, and FAMA, act as a switch for three consecutive steps of stomatal cell differentiation, and two other bHLH proteins, SCREAM (SCRM)/ICE1 and SCRM2, act as their partners through the formation of heterodimers. The activity of the SCREAM factors determines the fate of the plant epidermis: the complete absence of SCREAMs eliminates stomatal cell lineages, while gain-of-function of SCRM/ICE1 results in plants that are covered with stomata. This research project will uncover the function and regulation of SCRM/ICE1 and its paralog in specifying stomatal cell fate, and investigate how SCRM/ICE1 influence stomatal-specific bHLH proteins. Biochemical mechanisms that inhibit their action will be investigated, and novel factors that regulate their activity and function will be isolated using a sensitive genetic screen. SCRM/ICE1 has a dual role in freezing tolerance and stomatal differentiation, and the mechanism of the dual function will be explored. The broader impacts of this project include the training of young female scientists (a starting postdoctoral fellow and a graduate student) and an undergraduate student, who will have excellent opportunities to obtain broad training in plant developmental biology, molecular genetics, biochemistry, and cell imaging. Additional undergraduate researchers will also be trained through independent research for credit. They will be mentored directly by the PI to formulate scientific hypotheses, interpret their results, and present their findings within the laboratory as well as in a public setting. A part of this project will be incorporated into the Introductory Biology classroom (with an enrollment of greater than 200 students) and into practical laboratory experiences for college sophomores and juniors. Outreach lectures will be initiated to emphasize the connections between plant stomata and human life, and to encourage young female scientists to advance in their career paths.

植物的生产力依赖于气孔的正常发育和功能，气孔是植物表面的微小阀门。气孔调节植物和大气之间气体的流动。二氧化碳分子（一种温室气体）通过气孔进入植物，并通过光合作用转化为碳水化合物。氧气是光合作用的副产品，然后通过气孔从植物释放到大气中。此外，通过打开气孔的蒸腾作用使水分流失，促进水分从根部流出，支持植物生长，而关闭气孔则防止植物枯萎。在植物发育过程中，气孔是通过一系列分化事件形成的，其中具有基本螺旋-环-螺旋（bHLH）基序的“主调控”转录因子的激活起着关键作用。三个bHLH蛋白无言、静音和FAMA作为气孔细胞分化连续三个步骤的开关，另外两个bHLH蛋白SCREAM (SCRM)/ICE1和SCRM2通过形成异源二聚体作为它们的伙伴。尖叫因子的活性决定了植物表皮的命运：尖叫的完全缺失消除了气孔细胞系，而SCRM/ICE1的功能获得导致植物被气孔覆盖。本项目将揭示SCRM/ICE1在气孔细胞命运调控中的功能和调控，并探讨SCRM/ICE1对气孔特异性bHLH蛋白的影响。抑制其作用的生化机制将被研究，调节其活性和功能的新因素将通过敏感的遗传筛选被分离出来。SCRM/ICE1在抗冻性和气孔分化中具有双重作用，本文将对其双重作用机制进行探讨。该项目的更广泛影响包括培养年轻的女科学家（一名博士后和一名研究生）和一名本科生，她们将有很好的机会获得植物发育生物学、分子遗传学、生物化学和细胞成像方面的广泛培训。其他本科生研究人员也将通过独立研究获得学分。他们将直接接受PI的指导，制定科学假设，解释他们的结果，并在实验室和公共环境中展示他们的发现。这个项目的一部分将被纳入生物学导论课堂（招生人数超过200人），并成为大学二年级和三年级学生的实际实验室经验。为强调植物气孔与人类生命之间的联系，鼓励年轻女性科学家在职业道路上取得进步，将开展外展讲座。