NREL Partnership: Engineering enzymes for improved ethylene production in C.necator

NREL 合作伙伴关系：工程酶可提高 C.necator 的乙烯产量

• 批准号: 1647906
• 金额: --
• 依托单位: University of Nottingham
• 依托单位国家: 英国
• 项目类别: Studentship
• 财政年份: 2015
• 资助国家: 英国
• 起止时间: 2015 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=studentship-1647906
• 关键词: NREL; Partnership; Engineering; enzymes; improved

Ethylene is a small hydrocarbon gas, widely used in the chemical industry. Its annual worldwide production currently exceeds 150 million tonnes, surpassing any other organic compound. Ethylene is currently produced from steam cracking of ethane which produces vast quantities of CO2, contributing to global warming. Ethylene is the monomer for the most common plastic, polyethylene, and annual global production is approximately 80 million tons. Therefore, unlocking a sustainable or carbon neutral alternative to ethylene production is imperative. There are currently three pathways for ethylene synthesis this project will focus on the alternative ethylene synthesis pathway, found in Pseudomonas syringae and Penicillium digitatum, which utilises a-ketoglutarate (AKG) and arginine in a reaction catalysed by the ethylene-forming enzyme (EFE). This project aims to utilise an augmented directed evolution approach, incorporating systems biology, omics data mining and computational biology; to evolve the EFE enzyme improving both solubility and enzyme activity, thus allowing for the substantial productivity improvements required in manufacturing green ethylene. Directed evolution requires a high throughput screen, this project will address this by developing an ethylene biosensor. The transcriptome of the host strain will be evaluated in the presence and absence of ethylene. Transcriptional activation in response to ethylene will be accessed via RNA Seq and used as a proportional expression response to ethylene concentration. Selected candidates will then be used to regulate expression of an essential gene, thus establishing a growth screen in response to ethylene concentration, capable of screening libraries of up to 108-12 variants. In addition, expression of GFP transcribed by the ethylene sensitive promoter candidates will be assessed as a reporter to enable FACS-based screen of up to 108 enzyme variants. We will also access known ethylene biosensors utilising the EnvZ/OmpR two component system in E.coli. Finally the project will aim to elucidate a definitive protein structure for EFE, which is currently lacking. By combining the respective strengths of Nottingham University SBRC and the NREL, there is a real opportunity to make significant progress towards new bacterial-based routes to chemicals and fuels from biomass.

乙烯是一种小烃类气体，广泛应用于化学工业。目前，其全球年产量超过1.5亿吨，超过任何其他有机化合物。乙烯目前是由乙烷的蒸汽裂解产生的，其产生大量的CO2，导致全球变暖。乙烯是最常见的塑料聚乙烯的单体，全球年产量约为8000万吨。因此，开发一种可持续或碳中和的乙烯生产替代品势在必行。目前有三种乙烯合成途径，该项目将重点关注在假单胞菌和指状青霉中发现的替代乙烯合成途径，该途径在乙烯形成酶（EFE）催化的反应中利用α-酮戊二酸（AKG）和精氨酸。该项目旨在利用增强的定向进化方法，结合系统生物学，组学数据挖掘和计算生物学;进化EFE酶，提高溶解度和酶活性，从而实现生产绿色乙烯所需的大幅生产力提高。定向进化需要高通量筛选，本项目将通过开发乙烯生物传感器来解决这一问题。将在存在和不存在乙烯的情况下评价宿主菌株的转录组。响应于乙烯的转录激活将通过RNA Seq获得，并用作与乙烯浓度成比例的表达响应。然后将选择的候选物用于调节必需基因的表达，从而建立响应于乙烯浓度的生长筛选，能够筛选多达108-12个变体的文库。此外，由乙烯敏感启动子候选物转录的GFP的表达将作为报告基因进行评估，以实现多达108种酶变体的基于FACS的筛选。我们还将在大肠杆菌中利用EnvZ/OmpR双组分系统访问已知的乙烯生物传感器。最后，该项目将致力于阐明EFE的明确蛋白质结构，这是目前缺乏的。通过结合诺丁汉大学SBRC和NREL各自的优势，有一个真实的机会，使新的细菌为基础的路线，从生物质化学品和燃料的重大进展。