Citramalic acid is a central intermediate in a combined biocatalytic and chemocatalytic route to produce bio-based methylmethacrylate, the monomer used to manufacture Perspex and other high performance materials. We developed an engineered E. coli strain and a fed-batch bioprocess to produce citramalate at concentrations in excess of 80 g l-1 in only 65 h. This exceptional efficiency was achieved by designing the production strain and the fermentation system to operate synergistically. Thus, a single gene encoding a mesophilic variant of citramalate synthase from Methanococcus jannaschii, CimA3.7, was expressed in E. coli to convert acetyl-CoA and pyruvate to citramalate, and the ldhA and pflB genes were deleted. By using a bioprocess with a continuous, growth-limiting feed of glucose, these simple interventions diverted substrate flux directly from central metabolism towards formation of citramalate, without problematic accumulation of acetate. Furthermore, the nutritional requirements of the production strain could be satisfied through the use of a mineral salts medium supplemented only with glucose (172 g l-1 in total) and 1.4 g l-1 yeast extract. Using this system, citramalate accumulated to 82±1.5 g l-1, with a productivity of 1.85 g l-1 h-1 and a conversion efficiency of 0.48 gcitramalate g-1 glucose. The new bioprocess forms a practical first step for integrated bio- and chemocatalytic production of methylmethacrylate.
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机译:柠檬酸是生物催化和化学催化结合生产生物基甲基丙烯酸甲酯(用于制造有机玻璃和其他高性能材料的单体)的核心中间体。我们开发了一种工程化的大肠杆菌菌株和分批补料生物工艺,仅在65小时内即可生产浓度超过80 g l-1的柠康酸盐。通过将生产菌株和发酵系统设计为协同运行,可以实现这种非凡的效率。因此,在大肠杆菌中表达了编码来自詹氏甲烷球菌的柠檬酸合酶的嗜温变体的单一基因CimA3.7,以将乙酰辅酶A和丙酮酸转化为柠檬酸,并删除了ldhA和pflB基因。通过使用具有连续的,限制生长的葡萄糖进料的生物过程,这些简单的干预措施将底物通量直接从中心代谢转移至柠檬酸的形成,而不会产生乙酸盐的积聚。此外,通过使用仅添加葡萄糖(总共172 g l-1)和1.4 g l-1酵母提取物的无机盐培养基,可以满足生产菌株的营养需求。使用该系统,枸al酸盐累积至82±1.5 g l-1,生产率为1.85 g l-1 h-1,转化效率为0.48 gcitramalate g-1葡萄糖。新的生物工艺形成了集成的生物催化和化学催化生产甲基丙烯酸甲酯的实用的第一步。
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