Characterization of the molecular pathways that direct development and pathogenicity in the vascular wilt fungus Verticillium dahliae

维管束枯萎病真菌大丽黄萎病指导发育和致病性的分子途径的表征

• 批准号: 216879-2012
• 负责人: Dobinson, Katherine
• 金额: $ 1.82万
• 依托单位: University of Western Ontario
• 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=523615
• 关键词: Characterization; molecular; pathways; direct; development

Verticillium dahliae is a filamentous fungus that causes vascular wilt of a broad range of economically important annual and perennial crops. During infection the fungus is confined to the plant's water-conducting (vascular) system, growing dimorphically (in two forms), as hyphal and yeast-like cells. In the late stages of disease V. dahliae escapes from the vascular system into the surrounding tissues where it produces its survival structures. These hardy, pigmented clusters of cells are dispersed into the soil with plant debris, can survive for at least a decade in the soil, and are the primary source of disease inoculum. The molecular pathways involved in development of these structures, and in planta dimorphic growth offer attractive potential targets for disease control. In previous studies in my lab we showed that both a hydrophobic protein (hydrophobin VDH1) and the process of autophagy (the cells' intracellular recycling system) are essential for survival structure development. The other important discovery was that VDH1 is recognized by the plant during the early phase of infection to induce plant defence responses, but that the plant is unable to sustain those defences. Molecular strategies will be used to address two major objectives in of the proposed research. The first will be to better define the survival structure developmental pathway, and to identify steps in the pathway that could potentially be blocked to prevent survival structure formation and/or pathogen colonization of the plant. The second objective will be to determine the roles of as-yet uncharacterized V. dahliae hydrophobins during survival structure development and in plant recognition to induce plant defences. Studies will be initiated to determine what molecular mechanism(s) the pathogen uses to thwart the plant defence responses that are triggered by recognition of the pathogen. The results of the proposed research would provide knowledge for future development of new, and badly needed disease control strategies to manage verticillium wilt. The resulting data are also anticipated to be relevant to studies of other pathogenic fungi for which the plant vascular system is the preferred environmental niche.

黄萎病是一种丝状真菌，可引起多种重要的一年生和多年生作物的维管束枯萎。在感染期间，真菌被限制在植物的导水(维管)系统中，以两种形式(以两种形式)生长，作为菌丝和酵母样细胞。在疾病的晚期，大丽弧菌从血管系统逃逸到周围的组织中，在那里它产生了生存结构。这些耐寒、着色的细胞团与植物残渣一起散布到土壤中，可以在土壤中存活至少十年，是接种疾病的主要来源。参与这些结构发育和植物二态生长的分子途径为疾病控制提供了有吸引力的潜在靶点。在我的实验室之前的研究中，我们表明疏水蛋白(疏水蛋白VDH1)和自噬过程(细胞内的循环系统)对生存结构的发展都是必不可少的。另一个重要的发现是，VDH1在感染的早期阶段被植物识别，以诱导植物防御反应，但植物无法维持这些防御反应。分子战略将被用来解决拟议研究的两个主要目标。第一个将是更好地定义生存结构发育途径，并确定该途径中可能被阻止的步骤，以防止植物生存结构的形成和/或病原菌的定植。第二个目标是确定迄今尚未确定的大丽弧菌疏水蛋白在生存结构发育和植物识别中的作用，以诱导植物防御。将开始研究以确定病原菌使用什么分子机制(S)来挫败由识别病原菌而触发的植物防御反应。拟议的研究结果将为未来开发新的、迫切需要的疾病控制策略来管理黄萎病提供知识。由此得到的数据也有望与其他病原真菌的研究相关，对这些病原真菌来说，植物维管系统是首选的环境生态位。