酿酒酵母
代谢工程
模块化设计
合成生物学
计算生物学
计算机科学
异源的
生物技术
生化工程
发酵
生物化学
蛋白质工程
辅因子
代谢途径
生物
次生代谢
生物合成
酵母
迭代和增量开发
代谢通量分析
生产(经济)
基因组工程
组合化学
工业生物技术
酵母菌
作者
Philip Tinggaard Thomsen,Peter Gockel,Christina Vasileiou,Ingrid Mohr,Marc Cernuda Pastor,Irina Borodina
标识
DOI:10.1016/j.ymben.2025.09.006
摘要
Efficiently rewiring microbial metabolism for molecule production lies at the core of industrial metabolic engineering. Combinatorial libraries are useful for directing metabolism towards molecule production; however, their construction is labor-intensive, and their use in iterative strain engineering campaigns is often restricted by site-specific genomic integration. Here we present an automation-friendly framework for generating reusable and modular integration-based combinatorial libraries that can be used repeatedly to build high-performing strains. We apply this approach to engineer the production of betacyanins, a commonly used red food colorant extracted from beetroots, in Saccharomyces cerevisiae. Iterative implementation of combinatorial libraries targeting the betacyanin biosynthesis pathway (design space: ∼25,000), precursors (design space: ∼43,000), and cofactors (design space: ∼26,000) consistently improved pigment production by 1.2-5.7-fold per cycle over seven rounds of engineering. Sequencing of high-performing library isolates from each round revealed unique insights into betacyanin and yeast metabolism, e.g. we found strong evidence implicating the S. cerevisiae cytochrome b5 in heterologous red beet pigment production. Altogether, this study demonstrates a framework for combinatorial library engineering well-suited for accelerating the development of high-performing cell factories for industrial fermentation processes.
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