化学
产量(工程)
水解
催化作用
糖苷水解酶
蛋白质工程
突变体
基质(水族馆)
底物特异性
乳糖酶
催化效率
酶
组合化学
半乳糖
碳水化合物结合模块
糖苷
糖苷键
水解酶
生物化学
功能(生物学)
立体化学
下游加工
作者
Lingtong Liao,Laichuang Han,Yanfang Sun,Xuexian Du,Yuqi Wu,Jiaoyan Luo,Jianghua Li,Guocheng Du,Guoqiang Zhang
标识
DOI:10.1021/acs.jafc.5c12262
摘要
Lactases are important glycoside hydrolases that have widespread applications in the food and pharmaceutical industries. However, the application of lactase is limited by its poor stability and transglycosylation activity. In this study, a Kluyveromyces lactis-derived lactase was engineered to improve its hydrolytic activity and transglycosylation. L764T and M2–3(L764T/V842G) had increased catalytic performance (kcat/KM) compared to Kl-β-Gal (2.9 and 4.8-fold increases, respectively) by multistrategy engineering including sequence alignment, flexible regions modification, and model prediction. The M2–3 mutant achieved a galactooligosaccharide (GOS) yield of 47.9%, which is higher than that of the wild type (35.2%). Molecular dynamics (MD) simulations suggested that the improvement of catalytic ability can be attributed to optimized substrate binding affinity and increased rigidity of specific domains. This enhancement is further supported by reinforced intersubunit interfacial interactions and enhanced compactness of the tetrameric structure. These modifications function synergistically, rendering the mutant enzymes highly promising as efficient biocatalysts for industrial applications.
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