An artificial coculture fermentation system for industrial propanol production.

Rémi Hocq, Michael Sauer
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引用次数: 2

Abstract

Converting plant biomass into biofuels and biochemicals via microbial fermentation has received considerable attention in the quest for finding renewable energies and materials. Most approaches have so far relied on cultivating a single microbial strain, tailored for a specific purpose. However, this contrasts to how nature works, where microbial communities rather than single species perform all tasks. In artificial coculture systems, metabolic synergies are rationally designed by carefully selecting and simultaneously growing different microbes, taking advantage of the broader metabolic space offered by the use of multiple organisms. 1-propanol and 2-propanol, as biofuels and precursors for propylene, are interesting target molecules to valorize plant biomass. Some solventogenic Clostridia can naturally produce 2-propanol in the so-called Isopropanol-Butanol-Ethanol (IBE) fermentation, by coupling 2-propanol synthesis to acetate and butyrate reduction into ethanol and 1-butanol. In this work, we hypothesized propanoate would be converted into 1-propanol by the IBE metabolism, while driving at the same time 2-propanol synthesis. We first verified this hypothesis and chose two propionic acid bacteria (PAB) strains as propanoate producers. While consecutive PAB and IBE fermentations only resulted in low propanol titers, coculturing Propionibacterium freudenreichii and Clostridium beijerinckii at various inoculation ratios yielded much higher solvent concentrations, with as much as 21 g/l of solvents (58% increase compared to C. beijerinckii monoculture) and 12 g/l of propanol (98% increase). Taken together, our results underline how artificial cocultures can be used to foster metabolic synergies, increasing fermentative performances and orienting the carbon flow towards a desired product.

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用于工业丙醇生产的人工共培养发酵系统。
在寻找可再生能源和材料的过程中,通过微生物发酵将植物生物质转化为生物燃料和生化物质受到了相当大的关注。到目前为止,大多数方法都依赖于培养单一的微生物菌株,为特定目的量身定制。然而,这与自然界的运作方式形成对比,在自然界中,微生物群落而不是单一物种执行所有任务。在人工共培养系统中,通过精心选择并同时培养不同的微生物,合理设计代谢协同效应,利用多种微生物的使用所提供的更广阔的代谢空间。1-丙醇和2-丙醇作为生物燃料和丙烯的前体,是植物生物量增值的有趣靶分子。一些溶剂型梭菌可以在所谓的异丙醇-丁醇-乙醇(IBE)发酵中自然产生2-丙醇,通过偶联2-丙醇合成乙酸和丁酸还原成乙醇和1-丁醇。在这项工作中,我们假设丙酸将通过IBE代谢转化为1-丙醇,同时推动2-丙醇的合成。我们首先验证了这一假设,并选择了两株丙酸菌(PAB)作为丙酸生产菌。虽然PAB和IBE连续发酵只导致丙醇滴度较低,但以不同接种比例共培养弗氏丙酸杆菌和贝氏梭菌产生的溶剂浓度要高得多,高达21 g/l溶剂(比单培养贝氏梭菌增加58%)和12 g/l丙醇(增加98%)。综上所述,我们的研究结果强调了人工共培养如何用于促进代谢协同作用,提高发酵性能并将碳流导向所需产品。
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CiteScore
3.30
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0.00%
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审稿时长
15 weeks
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