雅罗维亚
酵母
代谢工程
同化(音韵学)
合成生物学
生物化学
商品化学品
酿酒酵母
生物
工业微生物学
甲醇
化学
发酵
计算生物学
酶
有机化学
催化作用
哲学
语言学
作者
Guokun Wang,Mattis Olofsson-Dolk,Frederik G. Hansson,Stefano Donati,Xiaolin Li,Hong Chang,Jian Cheng,Jonathan Dahlin,Irina Borodina
标识
DOI:10.1021/acssynbio.1c00464
摘要
Conferring methylotrophy on industrial microorganisms would enable the production of diverse products from one-carbon feedstocks and contribute to establishing a low-carbon society. Rebuilding methylotrophs, however, requires a thorough metabolic refactoring and is highly challenging. Only recently was synthetic methylotrophy achieved in model microorganisms─Escherichia coli and baker's yeast Saccharomyces cerevisiae. Here, we have engineered industrially important yeast Yarrowia lipolytica to assimilate methanol. Through rationally constructing a chimeric assimilation pathway, rewiring the native metabolism for improved precursor supply, and laboratory evolution, we improved the methanol assimilation from undetectable to a level of 1.1 g/L per 72 h and enabled methanol-supported cellular maintenance. By transcriptomic analysis, we further found that fine-tuning of methanol assimilation and ribulose monophosphate/xylulose monophosphate (RuMP/XuMP) regeneration and strengthening formate dehydrogenation and the serine pathway were beneficial for methanol assimilation. This work paves the way for creating synthetic methylotrophic yeast cell factories for low-carbon economy.
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