生物催化
热稳定性
木糖
化学
生物量(生态学)
基质(水族馆)
产量(工程)
定向进化
木质纤维素生物量
蛋白质工程
位阻效应
生化工程
酶
底物特异性
异构酶
催化作用
异构化
有机化学
生物化学
木糖异构酶
制浆造纸工业
过程(计算)
饱和突变
生物技术
偏爱
活动站点
生物转化
作者
Shiqiang Yue,Guangyao Tang,Zepin Guo,F. J. Lu,Kangming Tian,Yixun Jiang,Xin Gao,Hui-Min Qin
标识
DOI:10.1021/acs.jafc.5c17228
摘要
Xylose isomerase is a promising biocatalyst for lignocellulose valorization, but natural enzymes are limited by a preference for either d-xylose or d-glucose. Here, we integrated ancestral sequence reconstruction with deep learning methods to identify ASR285, an enzyme active toward both d-glucose and d-xylose. To enhance its potential for practical applications, we designed a flexible lid by truncating the α3-helix and reducing steric hindrance through the W140F mutation. Guided by computational analysis, the ASR285-M2 mutant (ASR285-Δhelix9/W140F/S147A/W189Y) was engineered, resulting in a 7.85-fold increase in the catalytic activity toward d-glucose while preserving the native d-xylose isomerization capacity. It also exhibited an approximately 2-fold longer half-life, indicating improved thermostability. In real lignocellulosic hydrolysates, ASR285-M2 achieved a 9-fold higher d-fructose yield than ASR285, enabling simultaneous production of d-fructose and d-xylulose. This semirational strategy successfully optimized both substrate preference and stability, providing a practical biocatalyst for biomass valorization.
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