热稳定性
土曲霉
突变体
化学
胺气处理
立体化学
转氨酶
二硫键
突变
蛋白质工程
生物化学
酶
有机化学
基因
作者
Dong‐Fang Xie,Hui Fang,Jiaqi Mei,Jinyan Gong,Hongpeng Wang,Shen Xiuying,Jun Huang,Lehe Mei
摘要
Abstract To improve the thermostability of ( R )‐selective amine transaminase from Aspergillus terreus (AT‐ATA), we used computer software Disulfide by Design and Modelling of Disulfide Bonds in Proteins to identify mutation sites where the disulfide bonds were most likely to form. We obtained three stabilized mutants (N25C‐A28C, R131C‐D134C, M150C‐M280C) from seven candidates by site‐directed mutagenesis. Compared to the wild type, the best two mutants N25C‐A28C and M150C‐M280C showed improved thermal stability with a 3.1‐ and 3.6‐fold increase in half‐life ( t 1/2 ) at 40 °C and a 4.6 and 5.1 °C increase in T 50 10 . In addition, the combination of mutant R131C‐D134C and M150C‐M280C displayed the largest shift in thermostability with a 4.6‐fold increase in t 1/2 at 40 °C and a 5.5 °C increase in T 50 10 . Molecular dynamics simulation indicated that mutations of N25C‐A28C and M150C‐M280C lowered the overall root mean square deviation for the overall residues at elevated temperature and consequently increased the protein rigidity. The stabilized mutation of R131C‐D134C was in the region of high mobility and on the protein surface, and the disulfide bond constraints the flexibility of loop 121–136.
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