Radical Trapping Study of the Relaxation of bis-Fe(IV) MauG.

Reactive oxygen species (Apex, N.C.) Pub Date : 2018-01-01 DOI:10.20455/ROS.2018.801

I. Davis, T. Koto, Aimin Liu

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引用次数: 2

Abstract

The di-heme enzyme, MauG, utilizes a high-valent, charge-resonance stabilized bis-Fe(IV) state to perform protein radical-based catalytic chemistry. Though the bis-Fe(IV) species is able to oxidize remote tryptophan residues on its substrate protein, it does not rapidly oxidize its own residues in the absence of substrate. The slow return of bis-Fe(IV) MauG to its resting di-ferric state occurs via up to two intermediates, one of which has been previously proposed by Ma et al. (Biochem J 2016; 473:1769) to be a methionine-based radical in a recent study. In this work, we pursue intermediates involved in the return of high-valent MauG to its resting state in the absence of the substrate by EPR spectroscopy and radical trapping. The bis-Fe(IV) MauG is shown by EPR, HPLC, UV-Vis, and high-resolution mass spectrometry to oxidize the trapping agent, 5,5-dimethyl-1-pyrroline N-oxide (DMPO) to a radical species directly. Nitrosobenzene was also employed as a trapping agent and was shown to form an adduct with high-valent MauG species. The effects of DMPO and nitrosobenzene on the kinetics of the return to di-ferric MauG were both investigated. This work eliminates the possibility that a MauG-based methionine radical species accumulates during the self-reduction of bis-Fe(IV) MauG.

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铋- fe (IV) mag弛豫的自由基俘获研究。

二血红素酶，MauG，利用高价，电荷共振稳定的双铁(IV)状态来执行基于蛋白质自由基的催化化学。虽然双铁(IV)能够氧化底物蛋白上的远端色氨酸残基，但在没有底物的情况下，它不能迅速氧化自己的残基。铋-铁(IV) mag缓慢恢复到静息二铁态是通过两种中间体发生的，其中一种中间体之前已由Ma等人提出(Biochem J 2016;473:1769)是一种基于蛋氨酸的自由基。在这项工作中，我们通过EPR光谱和自由基捕获研究了在没有底物的情况下，参与高价MauG返回其静息状态的中间体。EPR、HPLC、UV-Vis和高分辨率质谱分析表明，双铁(IV) mag可以直接氧化捕集剂5,5-二甲基-1-吡啶n -氧化物(DMPO)。亚硝基苯也被用作诱捕剂，并被证明与高价mag物质形成加合物。研究了DMPO和亚硝基苯对二铁钼还原动力学的影响。这项工作消除了基于mag的蛋氨酸自由基在双铁(IV) mag的自还原过程中积累的可能性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Reactive oxygen species (Apex, N.C.)

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