Manipulating microalgal-to-microbial carbon transfer for sustainable bioenergy and bioproducts

操纵微藻到微生物的碳转移以获得可持续的生物能源和生物产品

• 批准号: 2110800
• 金额: --
• 依托单位: University of Manchester
• 依托单位国家: 英国
• 项目类别: Studentship
• 财政年份: 2018
• 资助国家: 英国
• 起止时间: 2018 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=studentship-2110800
• 关键词: Manipulating; microalgal; microbial; carbon; transfer

Microorganisms have significant potential as sources of chemicals and metabolites to be used for industrial applications such as the production of high-value chemicals, food products or biofuels. Many species of bacteria and yeast are very efficient at producing biofuels via fermentation and are extremely amenable to genetic engineering but are dependent on the supply of organic carbon substrates, thus reducing the sustainability and potential carbon neutrality of chemicals from these organisms. In contrast, photosynthetic organisms such as microalgae can make use of freely available carbon dioxide and sunlight, but currently have limitations as viable industrial biotechnology platform strains. This project aims to combine the properties and potential of microalgae with the proven biotechnological characteristics of certain bacterial and yeast strains to drive towards the carbon neutral production of chemicals and biofuels. We will evaluate the utilisation of sugars derived from microalgae to sustain cultivation and fermentation of strains such Saccharomyces cerevisiae and Clostridium acetobutylicum. One set of experiments will investigate the breakdown of microalgal biomass to release sugars for use for fermentation and will screen for optimal microalgal saccharification and yeast fermentation conditions. A second experimental approach will genetically engineer the model eukaryotic microalga Chlamydomonas reinhardtii to allow sugar efflux. Computational modelling will be used to optimise the cultivation and metabolic conditions of the autotrophic microalga and the heterotrophic yeast or bacterium, using previously developed approaches. The goal will be to develop a combined system that will harness the photosynthetic properties of the microalga to provide carbon to microorganisms to drive industrial chemical production. Furthermore, the microorganism biomass will be evaluated as a 'biorefinery' in order to evaluate by-products for additional applications and so to make full use of the cultivated biomass. The project will provide training in a variety of experimental techniques and disciplines including molecular biology, genetic engineering, and metabolic modelling.

微生物作为化学品和代谢物的来源具有巨大潜力，可用于工业应用，如生产高价值化学品、食品或生物燃料。许多种类的细菌和酵母在通过发酵生产生物燃料方面非常有效，非常容易接受基因工程，但依赖于有机碳底物的供应，从而降低了这些生物化学物质的可持续性和潜在的碳中性。相比之下，微藻等光合作用生物可以利用可自由获得的二氧化碳和阳光，但目前作为可行的工业生物技术平台菌株存在局限性。该项目旨在将微藻的特性和潜力与某些细菌和酵母菌株已证明的生物技术特性相结合，以推动化学品和生物燃料的碳中性生产。我们将评估从微藻中提取的糖用于支持酿酒酵母和乙酰丁酸梭菌等菌株的培养和发酵。一组实验将研究微藻生物量的分解以释放糖用于发酵，并将筛选出最佳的微藻糖化和酵母发酵条件。第二种实验方法将对真核微藻模型莱茵衣藻进行基因改造，使其允许糖外流。使用以前开发的方法，计算模型将被用来优化自养微藻和异养酵母或细菌的培养和代谢条件。其目标将是开发一种组合系统，利用微藻的光合作用特性为微生物提供碳，以推动工业化学生产。此外，微生物生物量将被评估为“生物精炼”，以便评估副产品以供更多的应用，从而充分利用栽培的生物质。该项目将提供各种实验技术和学科的培训，包括分子生物学、基因工程和新陈代谢模型。