漆酶
定向进化
生物信息学
分子动力学
突变
基质(水族馆)
化学
结合位点
酶动力学
酶
生物化学
活动站点
生物
生物物理学
立体化学
组合化学
突变
突变体
计算化学
基因
生态学
作者
Vânia Brissos,Patrícia T. Borges,Reyes Núñez‐Franco,Maria Fátima Lucas,Carlos Frazão,Emanuele Monza,Laura Masgrau,Tiago N. Cordeiro,Lı́gia O. Martins
出处
期刊:ACS Catalysis
[American Chemical Society]
日期:2022-04-13
卷期号:12 (9): 5022-5035
被引量:29
标识
DOI:10.1021/acscatal.2c00336
摘要
Laccases are in increasing demand as innovative solutions in the biorefinery fields. Here, we combine mutagenesis with structural, kinetic, and in silico analyses to characterize the molecular features that cause the evolution of a hyperthermostable metallo-oxidase from the multicopper oxidase family into a laccase (k cat 273 s-1 for a bulky aromatic substrate). We show that six mutations scattered across the enzyme collectively modulate dynamics to improve the binding and catalysis of a bulky aromatic substrate. The replacement of residues during the early stages of evolution is a stepping stone for altering the shape and size of substrate-binding sites. Binding sites are then fine-tuned through high-order epistasis interactions by inserting distal mutations during later stages of evolution. Allosterically coupled, long-range dynamic networks favor catalytically competent conformational states that are more suitable for recognizing and stabilizing the aromatic substrate. This work provides mechanistic insight into enzymatic and evolutionary molecular mechanisms and spots the importance of iterative experimental and computational analyses to understand local-to-global changes.
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