基于氧化还原平衡原理的用于NADPH依赖性反应的高通量体内筛选平台的开发
Development of a High-Throughput, In Vivo Selection Platform for NADPH-Dependent Reactions Based on Redox Balance Principles.
作者信息
Zhang Linyue, King Edward, Luo Ray, Li Han
出版信息
ACS Synth Biol. 2018 Jul 20;7(7):1715-1721. doi: 10.1021/acssynbio.8b00179. Epub 2018 Jun 29.
Abstract
Bacteria undergoing anaerobic fermentation must maintain redox balance. In vivo metabolic evolution schemes based on this principle have been limited to targeting NADH-dependent reactions. Here, we developed a facile, specific, and high-throughput growth-based selection platform for NADPH-consuming reactions in vivo, based on an engineered NADPH-producing glycolytic pathway in Escherichia coli. We used the selection system in the directed evolution of a NADH-dependent d-lactate dehydrogenase from Lactobacillus delbrueckii toward utilization of NADPH. Through one round of selection, we obtained multiple enzyme variants with superior NADPH-dependent activities and protein expression levels; these mutants may serve as important tools in biomanufacturing d-lactate as a renewable polymer building block. Importantly, sequence analysis and computational protein modeling revealed that diverging evolutionary paths during the selection resulted in two distinct cofactor binding modes, which suggests that the high throughput of our selection system allowed deep searching of protein sequence space to discover diverse candidates en masse.
摘要
进行厌氧发酵的细菌必须维持氧化还原平衡。基于这一原理的体内代谢进化方案一直局限于针对依赖NADH的反应。在此,我们基于大肠杆菌中工程化的产生NADPH的糖酵解途径,开发了一种简便、特异且高通量的基于生长的体内筛选平台,用于筛选消耗NADPH的反应。我们将该筛选系统用于从德氏乳杆菌中依赖NADH的d - 乳酸脱氢酶的定向进化,使其能够利用NADPH。通过一轮筛选,我们获得了多个具有优异NADPH依赖活性和蛋白质表达水平的酶变体;这些突变体可作为生物制造d - 乳酸(一种可再生聚合物构建单元)的重要工具。重要的是,序列分析和计算蛋白质建模表明,筛选过程中的不同进化路径导致了两种不同的辅因子结合模式,这表明我们筛选系统的高通量允许深入搜索蛋白质序列空间,从而大规模发现多样的候选物。
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Synth Syst Biotechnol. 2017 Oct 6;2(3):208-218. doi: 10.1016/j.synbio.2017.09.002. eCollection 2017 Sep.
2
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Metab Eng. 2017 Jan;39:181-191. doi: 10.1016/j.ymben.2016.11.012. Epub 2016 Dec 6.
3
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