Sustainable production of natural products and biochemicals from microalgae

利用微藻可持续生产天然产物和生化产品

• 批准号: RGPIN-2019-04233
• 负责人: Ward, Valerie
• 金额: $ 2.04万
• 依托单位: University of Waterloo
• 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: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=682831
• 关键词: Sustainable; production; natural; products; biochemicals

Over the last decade, the production of chemicals and fuels from renewable resources has increased substantially due to environmental concerns and strong consumer demand for sustainable and renewable products. The bio-based industry has matured and non-traditional organisms for biochemical production are being increasingly adopted. One promising source of renewable chemicals are microalgae. By engineering the metabolic processes of photosynthetic organisms we can use biological systems to create chemicals from CO2 and sunlight and reduce the environmental impact of chemical production. The ultimate goal of this work is to develop a species of green microalgae into a platform for the production of bio-based chemicals from sunlight and CO2. Microalgae are more efficient at fixing CO2 than land plants and have the potential to produce chemical precursors for bioplastics, biofuels, and other high value industrial chemicals, however, the commercialization of these technologies is currently impeded by two challenges: the lack of genetic modification tools and the high cost of the downstream recovery processes.***Recent breakthroughs in the genetic modification of several microalgae species has poised this field for major advancements in the coming years. This research program will begin with the development of genetic engineering tools for the microalgae Chlorella vulgaris. These tools will be used to develop strains of C. vulgaris that overproduce astaxanthin, a strong anti-oxidant used in the aquaculture industry and eaten as a food supplement. This will be later extended to use C. vulgaris as a production platform for other isoprenoids of interest like natural pesticides and chemotherapy agents. ***To address the challenges of creating a low-cost separation process for microalgae biomass, Dr. Ward's group will develop ionic liquid (IL) catalysts capable of the direct conversion of microalgae lipids into biodiesel, and which facilitate the disruption and separation of microalgae carbohydrates and proteins. ILs are often called green solvents because many are not volatile and do not produce air pollution as a result of their use. We will develop ILs that can direct convert lipids produced by microalgae into biodiesel, as well as recovery the large amount of starch they accumulate. With the increasing need for non-edible starch to supply the growing biofuels and thermoplastics industries, starch produced from microalgae grown photosynthetically is likely to play an increasingly important role to these industries. This genetic, metabolic, and bioprocess engineering research program will train HQP in the interdisciplinary skill set needed to be successful in the growing Canadian bioeconomy and help establish Canada as a world leader in bio-based chemical production. *****

在过去十年中，由于环境问题和消费者对可持续和可再生产品的强烈需求，可再生资源的化学品和燃料生产大幅增加。生物基工业已经成熟，越来越多地采用非传统生物进行生化生产。微藻是可再生化学品的一个有前途的来源。通过设计光合生物的代谢过程，我们可以使用生物系统从二氧化碳和阳光中产生化学物质，并减少化学生产对环境的影响。这项工作的最终目标是开发一种绿色微藻，使其成为利用阳光和二氧化碳生产生物基化学品的平台。微藻在固定二氧化碳方面比陆地植物更有效，并且有潜力生产生物塑料，生物燃料和其他高价值工业化学品的化学前体，然而，这些技术的商业化目前受到两个挑战的阻碍：缺乏基因改造工具和下游回收过程的高成本。最近在几种微藻物种的遗传修饰方面取得的突破为该领域在未来几年的重大进展做好了准备。这项研究计划将开始与微藻普通小球藻的基因工程工具的发展。这些工具将用于开发C.一种能过量生产虾青素的普通小麦，一种用于水产养殖业的强抗氧化剂，可作为食品补充剂食用。这将在以后扩展到使用C。vulgaris作为其他感兴趣的类异戊二烯如天然杀虫剂和化疗剂的生产平台。* 为了解决创建微藻生物质低成本分离过程的挑战，Ward博士的团队将开发能够将微藻脂质直接转化为生物柴油的离子液体（IL）催化剂，并促进微藻碳水化合物和蛋白质的破坏和分离。离子液体通常被称为绿色溶剂，因为许多离子液体不挥发，并且使用时不会产生空气污染。我们将开发可以直接将微藻产生的脂质转化为生物柴油的离子液体，以及回收它们积累的大量淀粉。随着对非食用淀粉的需求不断增加以供应不断增长的生物燃料和热塑性塑料工业，由光合生长的微藻生产的淀粉可能对这些工业起越来越重要的作用。这个遗传，代谢和生物过程工程研究计划将培养HQP在不断增长的加拿大生物经济中取得成功所需的跨学科技能，并帮助加拿大成为生物化学生产的世界领导者。 *****