计算研究氮酶的化学机制。

Computational Investigations of the Chemical Mechanism of the Enzyme Nitrogenase.

机构信息

School of Chemistry, UNSW Sydney, Sydney, 2052, Australia.

出版信息

Chembiochem. 2020 Jun 15;21(12):1671-1709. doi: 10.1002/cbic.201900636. Epub 2020 Jan 21.

DOI:10.1002/cbic.201900636

Abstract

The chemical mechanism of nitrogenase, catalysing N +8 e+8 H →2 NH +H , occurs at a large multi-metal cluster (FeMo-co) with composition CFe MoS (homocitrate). More than 20 steps are required. Experimental elucidation of this mechanism is elusive, for various reasons, and computational approaches have a valuable role. This review critically surveys recent density functional calculations of the coordination chemistry and relevant reactions of FeMo-co within the protein surrounds. Topics covered include the accuracies and validation of the density functionals, the treatment of electronic structure, and the chemical models used. The components of mechanism are described, including the input of N , proton supply, the egress of NH , and the roles of surrounding protein. This leads to descriptions and evaluations of the overall mechanistic cycles proposed on the basis of density functional calculations. Finally, I discuss some current issues, and consider the outlook for further work.

摘要

固氮酶的化学反应机制，催化 N +8 e+8 H →2 NH +H ，发生在一个由多种金属组成的大型多金属簇（FeMo-co）上，其组成是 CFe MoS（柠檬酸）。这个过程需要经过 20 多步。由于各种原因，实验性地阐明这个机制是困难的，而计算方法可以起到重要作用。本文批判性地综述了最近关于在蛋白质环境中 FeMo-co 的配位化学和相关反应的密度泛函计算。涵盖的主题包括密度泛函的准确性和验证、电子结构的处理以及所使用的化学模型。描述了机制的组成部分，包括 N 的输入、质子供应、NH 的排出以及周围蛋白质的作用。这导致了基于密度泛函计算提出的整体机制循环的描述和评估。最后，我讨论了一些当前的问题，并考虑了进一步工作的前景。

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计算研究氮酶的化学机制。

Computational Investigations of the Chemical Mechanism of the Enzyme Nitrogenase.

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