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Collaborative Research: EDGE FGT: Establishing functional genomics in anaerobic fungi for applications in agriculture, sustainability, and carbon cycling

合作研究：EDGE FGT：建立厌氧真菌的功能基因组学，用于农业、可持续发展和碳循环

基本信息

批准号：
2128271
负责人：
Michelle O'Malley
金额：
$ 48万
依托单位：
University of California-Santa Barbara
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2021
资助国家：
美国
起止时间：
2021-08-15 至 2025-07-31
项目状态：
未结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=2128271&HistoricalAwards=false
关键词：
Collaborative Research EDGE FGT Establishing

项目摘要

Anaerobic fungi are powerful microorganisms native to the digestive tracts of ruminants and hindgut fermenters, including important livestock such as cattle, sheep, and goats. Within their hosts, these fungi provide essential nutrients and compounds that drive animal growth and behavior. Specifically, they promote the digestion of fiber-rich feedstocks, secrete metabolites that sustain the growth of other microbes critical for digestion, produce compounds that enhance host health, and control the production of methane. This project develops and optimizes methods to engineer anaerobic fungi allowing scientists to study and control these molecular processes for diverse applications. Undergraduate and graduate students, postdoctoral fellows, K-12 students, and the public will be integrated into the studies through coursework, laboratory research, YouTube videos and local outreach to communities in Southern California and the Mid Atlantic. Training materials will also be developed to broadly disseminate project findings to the scientific community, accelerating research into these unusual microbes. This project has far reaching impacts on plant biomass breakdown, economical biofuels, renewable chemical production, climate change, animal nutrition and health, and drug discovery.This project develops foundational genetic tools to study anaerobic gut fungi. To date, only a handful of reports exist for the transient transformation of these species. However, the advent of CRISPR-Cas technology and the recent acquisition of complete genomes for these species enable new strategies for permanent genetic modification. Focusing on representative isolates from several genera within the Neocallimastigomycota phylum, this project optimizes methods to deliver genetic materials to fungal zoospores, the juvenile life stage of this phylum, which will be quantified through selection and fluorescence-activated cell sorting. Next, the project develops two strategies l to introduce or knock down/out genes. In the first strategy, CRISPR-based tools will be deployed and optimized to engineer novel cellular phenotypes. In the complementary second approach, the project leverages LTR retrotransposons distributed throughout anaerobic fungal genomes as platforms to enhance DNA integration frequency and identify fungal promoters. Research findings will be distilled into training materials that will be disseminated through international and interdisciplinary research communities such as the Rumen Microbial Genomics (RMG) Network and the Anaerobic Fungi Network (AFN) to catalyze scientific advancement in a number of allied fields. Similarly, the public will be engaged through partnerships with organizations such as the Santa Barbara Zoo. This research will result in the first experimental tools to test gene function in the anaerobic fungi, enabling insight into their lifestyle and providing a path to microbial engineering and hypothesis testing.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

厌氧真菌是反刍动物消化道和后肠发酵罐中的强大微生物，包括重要的牲畜，如牛，绵羊和山羊。在宿主体内，这些真菌提供了驱动动物生长和行为的必需营养素和化合物。具体来说，它们促进富含纤维的原料的消化，分泌维持对消化至关重要的其他微生物生长的代谢物，产生增强宿主健康的化合物，并控制甲烷的产生。该项目开发和优化了工程厌氧真菌的方法，使科学家能够研究和控制这些分子过程以用于不同的应用。本科生和研究生，博士后研究员，K-12学生和公众将通过课程，实验室研究，YouTube视频和当地推广到南加州和大西洋中部社区的研究。还将开发培训材料，向科学界广泛传播项目发现，加速对这些不寻常微生物的研究。该项目对植物生物质分解、经济的生物燃料、可再生化学品生产、气候变化、动物营养和健康以及药物发现产生了深远的影响。该项目开发了研究厌氧肠道真菌的基础遗传工具。到目前为止，只有少数报告存在这些物种的瞬时转化。然而，CRISPR-Cas技术的出现和最近获得的这些物种的完整基因组使永久性遗传修饰的新策略成为可能。专注于代表性的菌株从几个属内的Neocallimastigomycota门，该项目优化的方法，提供遗传物质的真菌游动孢子，该门的少年生命阶段，这将是量化的选择和荧光激活细胞分选。接下来，该项目开发了两种策略l来引入或敲除基因。在第一种策略中，将部署和优化基于CRISPR的工具，以设计新的细胞表型。在补充的第二种方法中，该项目利用分布在厌氧真菌基因组中的LTR反转录转座子作为平台来提高DNA整合频率并识别真菌启动子。研究结果将被提炼成培训材料，通过国际和跨学科研究团体，如瘤胃微生物基因组学（RMG）网络和厌氧真菌网络（AFN）传播，以促进一些相关领域的科学进步。同样，公众将通过与圣巴巴拉动物园等组织的伙伴关系参与进来。这项研究将产生第一个测试厌氧真菌基因功能的实验工具，使人们能够深入了解它们的生活方式，并为微生物工程和假设检验提供一条道路。该奖项反映了NSF的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。