Computational thermostability engineering of a nitrile hydratase using synergetic energy and correlated configuration for redesigning enzymes (SECURE) strategy†

IF 4.4 3区 化学 Q2 CHEMISTRY, PHYSICAL Catalysis Science & Technology Pub Date : 2023-09-14 DOI:10.1039/D3CY01102J
Jinling Xu, Haisheng Zhou, Jiaqi Xu, Ziyuan Wang, Zhonglang Yu, Zhe Wang, Hongyu Zhang, Haoran Yu, Jianping Wu and Lirong Yang
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Abstract

Nitrile hydratase (NHase), an excellent biocatalyst, has been widely used for the production of amides, but the exothermic hydration reaction leads to its rapid inactivation, hindering its industrial applications, which requires the thermostability of NHase to be enhanced. In this study, employing NHase from Bordetella petrii DSM 12804 (NHAB) as the object, a computational strategy using synergetic energy and correlated configuration for redesigning enzymes (SECURE) was proposed to prune the reasonable mutant library and assemble effective single mutations, thus maximizing the thermostability of NHAB. Among the mutants, the best variant, A6M/B4M, combined six mutations in its α-subunit (S30T, A71D, A74D, A78R, S81T, and A133P) and four mutations in its β-subunit (L25F, G27Y, N59P, and A173N), showing an increase in Tm by 13.2 °C, an 866.0-fold prolonged half-life at 50 °C, and an 11.2% increase in activity. Then, the catalytic efficiency dramatically increased to 249.5 g L−1 acrylamide in 5 batches compared with that of 166.5 g L−1 by the wild type in 3 batches. Finally, the synergistic effect on the mutant represented by an overall change in structure and newly formed intermolecular interactions through dynamic simulations accounted for the enhanced thermostability. Thus, SECURE was demonstrated to be practical for the redesign of multimeric NHase, which also provided guidance for computational thermostability engineering of other industrial biocatalysts.

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腈水合酶的计算热稳定性工程,使用协同能量和相关配置重新设计酶(SECURE)策略†
腈水合酶(NHase)是一种优秀的生物催化剂,已被广泛用于酰胺的生产,但放热水合反应导致其快速失活,阻碍了其工业应用,这需要提高NHase的热稳定性。在本研究中,以来自Bordetella petrii DSM 12804(NHAB)的NHase为对象,提出了一种利用协同能量和相关配置重新设计酶的计算策略(SECURE),以修剪合理的突变体库并组装有效的单突变,从而最大限度地提高NHAB的热稳定性。在突变体中,最好的变体A6M/B4M结合了α亚基的6个突变(S30T、A71D、A74D、A78R、S81T和A133P)和β亚基的4个突变(L25F、G27Y、N59P和A173N),显示Tm增加13.2°C,在50°C下半衰期延长866.0倍,活性增加11.2%。然后,与野生型的166.5 g L−1相比,5个批次的催化效率显著提高到249.5 g L–1丙烯酰胺。最后,通过动态模拟,以结构的整体变化和新形成的分子间相互作用为代表的对突变体的协同效应解释了热稳定性的增强。因此,SECURE被证明可用于多聚NHase的重新设计,这也为其他工业生物催化剂的计算热稳定性工程提供了指导。
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来源期刊
Catalysis Science & Technology
Catalysis Science & Technology CHEMISTRY, PHYSICAL-
CiteScore
8.70
自引率
6.00%
发文量
587
审稿时长
1.5 months
期刊介绍: A multidisciplinary journal focusing on cutting edge research across all fundamental science and technological aspects of catalysis. Editor-in-chief: Bert Weckhuysen Impact factor: 5.0 Time to first decision (peer reviewed only): 31 days
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