热稳定性
二聚体
饱和突变
化学
热的
单体
氢键
结晶学
材料科学
分子
计算化学
合理设计
二硫键
共价键
热分析
残留物(化学)
分子动力学
分子内力
饱和(图论)
化学物理
热力学
晶体结构
组合化学
分子模型
理论(学习稳定性)
作者
Shaoyan Zheng,Yujie Huang,Haiyi Zhang,Shu Wu,Weiqiu Ding,Chunfang Xie,Dongsheng Yao
标识
DOI:10.1021/acs.jafc.5c05633
摘要
Zearalenone hydrolase, derived from Clonostachys rosea, effectively degrades zearalenone, a major contaminant in animal feed; however, its poor thermal stability significantly hinders industrial applications. We improved the thermal stability of ZHD101 through rational molecular design. First, disulfide bonds were introduced at the interface to construct dimers, with ZHD101 T229C demonstrating stable dimerization. Subsequently, two high-vibration hotspot amino acids were selected by analyzing atomic position fluctuations and dynamic information on the dimer crystal structure. A precise mutant library, containing ZHD101 T229C/N137L, ZHD101 T229C/D170L, and ZHD101 T229C/D170C, was obtained by virtual saturation mutagenesis and conformational free energy calculations. The ZHD101 T229C/D170C variant exhibited remarkable thermal stability enhancement, with thermal half-inactivation temperature ( T 50 ) reaching approximately 54 °C (7 °C higher than wild-type) and half-life ( t 1/2 ) at 50 °C extending to 10.5 min (110% increase). The melting temperature ( T m ) of ZHD101 T229C/D170C increased from 49 ± 1.0 °C (wild-type) to 67.1 ± 0.95 °C, representing an increase of 18.1 °C, making it the highest Δ T m value reported for ZEN hydrolases to date. Overall, a combination mutation strategy of introducing disulfide bonds between monomers and utilizing B-factor analysis was applied, resulting in improved thermal stability of ZHD101 T229C/D170C . The improved strategy and identification method reported herein provides a reference for the thermal stability modification and optimization of other proteins.
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