发酵
代谢网络
大肠杆菌
生物化学
代谢工程
无氧运动
代谢途径
化学
产量(工程)
焊剂(冶金)
合成生物学
生物反应器
缺氧水域
细菌
氨
生物
嗜热菌
新陈代谢
代谢通量分析
无氧呼吸
氨基酸
工业发酵
定向进化
拉伤
混合酸发酵
微生物代谢
电子传输链
作者
Siqi Yang,Fenghui Qian,Tao Wu,Bingbing Sun,Huiqi He,Meng Qiao,冯东 Feng Dong,Peng Gao,Zhao Chen,Ying Zhang,Junjie Yang,Yu Jiang,Sheng Yang
标识
DOI:10.1038/s41467-026-73619-7
摘要
Abstract L-valine is an essential amino acid for animal nutrition. Ideally, it can be produced from D-glucose through homotypic L-valine fermentation in a growth-coupled manner. To date, no known microorganism, native or engineered, can grow on D-glucose and ammonia anaerobically with L-valine as the sole product. Here, we direct the metabolic flux through a reinforced L-valine synthetic pathway by blocking mixed-acid fermentation and L-alanine synthesis reactions to create an NADH driving force in Escherichia coli . We further evolve the engineered strain to debottleneck growth constraints by anaerobic growth rescue. The resulting evolved hyper-valine producer converts D-glucose in a 320 m 3 reactor to 83.6 g/L L-valine within 60 h, reaching a yield of 0.55 g/g glucose (85% of the theoretical maximum). Through reverse engineering, we identify that more than a 10-fold improvement in anaerobic growth and L-valine production rate arises from the amplified L-valine synthetic pathway, the additional electron sinks and reprogramming of global regulation. Together, we changed the way of L-valine production into homotypic L-valine fermentation and demonstrate how E. coli variants adapted their metabolic activities and transcriptional regulation to boost fitness in an anoxic condition, with L-valine synthesis serving as the primary NADH-consuming pathway.
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