Deciphering the Key Loop: Enhancing l-Threonine Transaldolase’s Catalytic Potential

转醛醇酶 催化作用 化学 饱和突变 酶动力学 立体化学 生物催化 生物化学 活动站点 反应机理 突变体 糖酵解 磷酸戊糖途径 基因
作者
Zhiwen Xi,Jingxin Rao,Xinyi Zhang,Zhiyong Liu,Mingyue Zheng,Lihong Li,Wenchi Zhang,Yan Xu,Rongzhen Zhang
出处
期刊:ACS Catalysis [American Chemical Society]
卷期号:14 (14): 10462-10474 被引量:16
标识
DOI:10.1021/acscatal.4c02049
摘要

l-Threonine transaldolase (LTTA) is an attractive biocatalyst because of its potential diastereoselectivity in the synthesis of β-hydroxy-α-amino acids (βHAAs). However, prospective development of LTTA has been hampered by its low activity. Here, a combination of techniques involving structural comparison, computational analysis, Loop deletion, and alanine scanning was used to identify a key Loop region (Loop 1) regulating the catalytic ability of Chitiniphilus shinanonensis LTTA (CsLTTA). Saturation mutagenesis and iterative saturation mutagenesis at the hot spots in Loop 1 were performed, and the best variant containing an F70T/C57Q/Y69T (TQT) triple mutation was screened. The diastereoisomer excess (de) produced by the TQT variant (95.4%syn) was greater than that produced by the wild-type (WT) enzyme (75.2%syn), and the catalytic efficiency (kcat/Km) of the TQT variant was four times higher than that of the wild-type enzyme. Molecular dynamics simulations, metadynamics simulations, and CAVER analysis revealed the critical role of the Loop 1 structure in regulating the hydrogen bond network and thus reshaping the active-site pocket to control the syn-tunnel direction. Further engineering of Loop 1 in ObiH, an LTTA responsible for obafluorin biosynthesis, resulted in the development of the F70T-C57Q-H69T (ObiH-TQT) variant producing a de of 97%syn. Using the ObiH-TQT variant for kilogram-scale synthesis of l-syn-p-methylsulfonylphenylserine, coupled with acetaldehyde elimination, resulted in space–time yields of up to 12.7 g L–1 h–1. The method achieved 98.3% substrate conversion and 99.2%syn de within 6 h, marking the highest reported levels to date. The above findings will contribute to the industrial production of β-hydroxy-α-amino acids, offer insights into the mechanism of Loop regions regulating the catalytic function of LTTAs, and provide ideas for engineering other enzymes.
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