饱和突变
热稳定性
定向进化
蛋白质工程
突变
活动站点
化学
突变体
生物化学
基质(水族馆)
糖
定点突变
底物特异性
酶
立体化学
组合化学
生物
基因
生态学
作者
Runxi Wang,Lu Qiao,Mufei Liu,Yanpeng Ran,Jun Wang,Wupeng Yan,Yan Feng,Li Cui
出处
期刊:Engineering
[Elsevier BV]
日期:2024-08-12
卷期号:42: 185-195
被引量:1
标识
DOI:10.1016/j.eng.2024.04.026
摘要
Sugar aminotransferases (SATs) catalyze the installation of chiral amines onto specific keto sugars, producing bioactive amino sugars. Their activity has been utilized in artificial reactions, such as using the SAT WecE to transform valienone into the valuable α-glucosidase inhibitor valienamine. However, the low thermostability and limited activity on non-natural substrates have hindered their applications. Simultaneously improving stability and enzyme activity is particularly challenging owing to the acknowledged inherent trade-off between stability and activity. A customized combinatorial active-site saturation test-iterative saturation mutagenesis (CAST-ISM) strategy was used to simultaneously enhance the stability and activity of WecE toward valienone. Fourteen hotspots related to improving the stability-activity trade-off were identified based on evolutionary conservation and the average mutation folding energy assessment of 57 residues in the active site of WecE. Positive mutagenesis and combinatorial mutations of these specific residues were accomplished via site-directed saturation mutagenesis (SSM) and iterative evolution cycles. Compared with those of the wild-type (WT) WecE, the quadruple mutant M4 (Y321F/K209F/V318R/ F319V) displayed a 641.49-fold increase in half-life at 40 °C and a 31.37-fold increase in activity toward the non-natural substrate valienone. The triple mutant M3 (Y321F/K209F/V318R) demonstrated an 83.04-fold increase in half-life at 40 °C and a 37.77-fold increase in activity toward valienone. The underlying mechanism was dependent on the strengthened interface interactions and shortened transamination reaction catalytic distance, compared with those of the WT, which improved the stability and activity of the obtained mutants. Thus, we accomplished a general target-oriented strategy for obtaining stable and highly active SATs for artificial amino-sugar biosynthesis applications.
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