克鲁维酵母
乳酸
发酵
化学
食品科学
水解物
生物转化
生物化学
代谢工程
产量(工程)
下游加工
酶
衣康酸
乳酸片球菌
贝氏梭菌
生物技术
拉伤
生物过程
漆酶
生物高聚物
工业微生物学
生物炼制
生物反应器
催化作用
木质纤维素生物量
脱氢酶
转氨酶
商品化学品
丙酸盐
细菌
作者
Yuxin Wang,Yuan Liu,Jia Liu,Xiaomin Li,Guipeng Hu,Cong Gao,Liu Liming
标识
DOI:10.1021/acssuschemeng.5c04344
摘要
Lactic acid (LA) is widely utilized in the food, pharmaceutical, and biopolymer industries. However, microbial LA production often faces challenges due to byproduct accumulation and limited acid tolerance. (i) Herein, an ARS ori-based synthetic plasmid was developed in Kluyveromyces marxianus to facilitate key enzyme screening. Bovine-derived lactate dehydrogenase (BLDH) demonstrated superior catalytic activity under high temperatures and acidic conditions. (ii) Knocking out competitive pathway genes PDC1 (pyruvate decarboxylase) and CYB2 (l-lactate: cytochrome oxidase) via genome insertion of BLDH significantly enhanced LA production and reduced byproduct accumulation. (iii) Transcriptomic analysis identified a novel acid tolerance gene, ESBP6, whose overexpression markedly improved strain survival by 41.2% and LA production by 80.2% under high-LA stress. After optimizing fermentation conditions, the optimal strain, FL3.8, produced 144.8 g/L L-LA with a yield of 0.9 mol/mol and productivity of 2.0 g/L/h. Furthermore, this strain produced 132 g/L L-LA using a synthetic lignocellulosic hydrolysate medium. This study establishes a technical foundation for LA production using K. marxianus under low pH conditions (as low as 2.97) and highlights the biotechnological potential of nonconventional microorganisms.
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