Understanding the molecular mechanisms that regulate arbuscular mycorrhizal symbiosis
了解调节丛枝菌根共生的分子机制
基本信息
- 批准号:RGPIN-2018-04007
- 负责人:
- 金额:$ 2.48万
- 依托单位:
- 依托单位国家:加拿大
- 项目类别:Discovery Grants Program - Individual
- 财政年份:2019
- 资助国家:加拿大
- 起止时间:2019-01-01 至 2020-12-31
- 项目状态:已结题
- 来源:
- 关键词:
项目摘要
Although sessile, plants are constantly interacting with their environment, including the living microorganisms (viruses, bacteria, fungi) that comprise their microbiome. Plant-microbe interactions represent one of the strongest determinants of plant health, with the potential to either positively or negatively influence agricultural productivity. Just as it is important to study disease-causing pathogens as a means of protecting crops from infection, so it is important to understand how beneficial microorganisms increase productivity as a means of enhancing these partnerships.*** Arbuscular mycorrhizal (AM) symbiosis is an ancient, beneficial interaction that occurs between approximately 80% of land plants on Earth, and a group of soil-dwelling fungi called Glomeromycota. The symbiosis is based on an exchange of carbon from the plant to the fungus, and in return, soil mineral nutrients from the fungus to its host. AM fungi naturally participate in beneficial symbioses with all globally important food crops, dramatically ameliorating the uptake of phosphorous and other nutrients from the soil. Plants that participate in AM symbiosis also show increased resistance against many stresses (including drought, salinity, and disease), further emphasizing the importance of this association.*** My long-term research objective is to understand the mechanisms by which AM fungi colonize plants. The first objective of this program seeks to identify novel proteins that are synthesized by the fungus during symbiosis and that act in the plant to promote root colonization by the fungus. The second objective focuses on characterizing the function of fungal proteins that are targeted to the nucleus of host plants during symbiosis to assess whether these fungal proteins alter host gene expression.*** Although it is well documented that AM fungi colonize a wide range of plants, how these fungi do so is largely unknown. My research program seeks to address these limitations. Achieving this goal is important because it may translate into ways by which we can further enhance protection of crops against disease-causing microbes, which may infect plants using similar mechanisms. Also, an understanding of how AM fungi actively promote symbiosis may identify avenues from which we can more effectively harness the potential of this ancient partnership. *** There is an ever increasing realization of the importance of agricultural research, particularly in an era where climate change and food security are issues that will strongly shape global development in the coming decades. Closely linked to food security, our current exploitation of soil mineral nutrients such as phosphorous is highly unsustainable. My research has a long-term goal of improving agriculture in a sustainable, environmentally-friendly way, aiding farmers in developing, and developed countries such as Canada, and supporting global society as a whole. **
虽然植物是固着的,但它们不断地与环境相互作用,包括构成其微生物组的活微生物(病毒,细菌,真菌)。植物-微生物相互作用是植物健康的最强决定因素之一,可能对农业生产力产生积极或消极影响。正如研究致病病原体作为保护作物免受感染的一种手段很重要一样,了解有益微生物如何提高生产力作为加强这些伙伴关系的一种手段也很重要。丛枝菌根(AM)共生是一种古老的,有益的相互作用,发生在地球上大约80%的陆地植物和一组称为球囊菌的土壤真菌之间。这种共生关系是基于从植物到真菌的碳交换,作为回报,土壤矿物质营养从真菌到其宿主。AM真菌自然地参与与所有全球重要粮食作物的有益共生,显著改善从土壤中吸收磷和其他营养物质。参与AM共生的植物也表现出对许多胁迫(包括干旱,盐度和疾病)的抗性增强,进一步强调了这种关联的重要性。我的长期研究目标是了解AM真菌在植物中定植的机制。该计划的第一个目标是寻找新的蛋白质,这些蛋白质在共生过程中由真菌合成,并在植物中起作用以促进真菌的根定殖。第二个目标集中于表征在共生过程中靶向宿主植物细胞核的真菌蛋白的功能,以评估这些真菌蛋白是否改变宿主基因表达。虽然有充分的文献证明AM真菌在广泛的植物中定殖,但这些真菌是如何定殖的在很大程度上是未知的。我的研究计划旨在解决这些限制。实现这一目标很重要,因为它可以转化为我们进一步加强保护作物免受致病微生物侵害的方法,这些微生物可能会使用类似的机制感染植物。此外,了解AM真菌如何积极促进共生可能会发现我们可以更有效地利用这种古老伙伴关系的潜力的途径。* 人们越来越认识到农业研究的重要性,特别是在气候变化和粮食安全问题将在未来几十年内强烈影响全球发展的时代。与粮食安全密切相关的是,我们目前对磷等土壤矿物质养分的开发是高度不可持续的。我的研究有一个长期目标,即以可持续,环境友好的方式改善农业,帮助发展中国家和加拿大等发达国家的农民,并支持整个全球社会。**
项目成果
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