EAGER: SusChEM: Developing Temporal Compartmentalization Tools in Yeast to Enhance the Bioproduction of Phytosterols

EAGER：SusChEM：开发酵母中的时间区室化工具以增强植物甾醇的生物生产

• 批准号: 1748695
• 负责人: Yanran Li
• 金额: $ 10万
• 依托单位: University of California-Riverside
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2017
• 资助国家: 美国
• 起止时间: 2017-10-01 至 2019-03-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1748695&HistoricalAwards=false
• 关键词: EAGER; SusChEM; Developing; Temporal; Compartmentalization

Plant steroids are complex, naturally occurring molecules that have a wide variety of pharmaceutical and agricultural applications; however, they are usually found in quite small amounts in plants, and they are difficult to synthesize chemically. This research project investigates ways to engineer yeasts to produce these molecules. To accomplish this goal, it is necessary to introduce into the yeast the ability to perform the targeted degradation of specific proteins. The researchers on this project are employing advanced biochemical methods in order to realize this alteration in the yeast. This research project include specific activities for high school students and for undergraduate students from a local community college, which will help in developing a highly trained technical workforce for the biotechnology industry. This research project provides a foundation for the development of programmable temporal regulation machinery for complex heterologous plant pathways in yeast. Such machinery employs yeast endogenous temporal compartmentalization strategies and an inducible protein degradation system associated with the endoplasmic reticulum (ER). Introducing complex plant pathways into microbial hosts including yeast has been highly challenging, mainly due to 1) the high burden from the expression of large numbers of plant enzymes; and 2) the lack of efficient coordination among the many heterologous enzymatic steps. A plant biosynthetic platform is required to incorporate and validate the proposed temporal regulation strategy, as is a targeted protein degradation (TPD) approach. The biosynthetic pathway of the plant steroid hormone brassinosteroids (BRs) is being verified and established in yeast, which will enable the downstream establishment of the proposed temporal regulation strategies. In addition, the feasibility of introducing TPD in the proposed temporal regulation strategy is being evaluated.

植物类固醇是复杂的，天然存在的分子，具有广泛的药物和农业应用;然而，它们通常在植物中以相当小的量存在，并且它们难以化学合成。该研究项目研究了工程酵母产生这些分子的方法。为了实现这一目标，有必要在酵母中引入对特定蛋白质进行靶向降解的能力。 该项目的研究人员正在采用先进的生物化学方法来实现酵母的这种改变。该研究项目包括为高中生和当地社区学院的本科生开展的具体活动，这将有助于为生物技术行业培养一支训练有素的技术队伍。该研究项目为酵母中复杂异源植物途径的可编程时间调节机制的开发提供了基础。这种机制采用酵母内源性时间区室化策略和与内质网（ER）相关的诱导蛋白质降解系统。将复杂的植物途径引入包括酵母在内的微生物宿主中具有高度挑战性，主要是由于1）来自大量植物酶表达的高负担;和2）在许多异源酶促步骤之间缺乏有效的协调。需要一个植物生物合成平台来整合和验证所提出的时间调控策略，靶向蛋白质降解（TPD）方法也是如此。植物类固醇激素油菜素类固醇（BR）的生物合成途径正在酵母中验证和建立，这将使下游建立拟议的时间调控策略。此外，引入TPD在拟议的时间监管策略的可行性正在评估。