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多铜氧化酶CueO对氧气的四电子还原作用以及位于三核铜中心附近的Asp112和Glu506的作用。

Four-electron reduction of dioxygen by a multicopper oxidase, CueO, and roles of Asp112 and Glu506 located adjacent to the trinuclear copper center.

作者信息

Kataoka Kunishige, Sugiyama Ryosuke, Hirota Shun, Inoue Megumi, Urata Kanae, Minagawa Yoichi, Seo Daisuke, Sakurai Takeshi

机构信息

Graduate School of Natural Science and Technology, Kanazawa University, Kakuma, Kanazawa 920-1192, Japan.

出版信息

J Biol Chem. 2009 May 22;284(21):14405-13. doi: 10.1074/jbc.M808468200. Epub 2009 Mar 18.

DOI:10.1074/jbc.M808468200
PMID:19297322
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2682889/
Abstract

The mechanism of the four-electron reduction of dioxygen by a multicopper oxidase, CueO, was studied based on reactions of single and double mutants with Cys(500), a type I copper ligand, and the noncoordinating Asp(112) and Glu(506), which form hydrogen bonds with the trinuclear copper center directly and indirectly via a water molecule. The reaction of C500S containing a vacant type I copper center produced intermediate I in an EPR-silent peroxide-bound form. The formation of intermediate I from C500S/D112N was restricted due to a reduction in the affinity of the trinuclear copper center for dioxygen. The state of intermediate I was realized to be the resting form of C500S/E506Q and C500S of the truncated mutant Deltaalpha5-7CueO, in which the 50 amino acids covering the substrate-binding site were removed. Reactions of the recombinant CueO and E506Q afforded intermediate II, a fully oxidized form different from the resting one, with a very broad EPR signal, g < 2, detectable only at cryogenic temperatures and unsaturated with high power microwaves. The lifetime of intermediate II was prolonged by the mutation at Glu(506) involved in the donation of protons. The structure of intermediates I and II and the mechanism of the four-electron reduction of dioxygen driven by Asp(112) and Glu(506) are discussed.

摘要

基于单突变体和双突变体与I型铜配体Cys(500)以及非配位性的Asp(112)和Glu(506)的反应,对多铜氧化酶CueO催化氧气四电子还原的机制进行了研究。Asp(112)和Glu(506)通过水分子直接或间接与三核铜中心形成氢键。含有空I型铜中心的C500S反应生成了EPR沉默的过氧化物结合形式的中间体I。由于三核铜中心对氧气的亲和力降低,C500S/D112N生成中间体I的过程受到限制。中间体I的状态在C500S/E506Q和截短突变体Deltaalpha5-7CueO的C500S中被认为是静止形式,其中覆盖底物结合位点的50个氨基酸被去除。重组CueO和E506Q的反应产生了中间体II,这是一种与静止形式不同的完全氧化形式,具有非常宽的EPR信号,g < 2,仅在低温下可检测到且未被高功率微波饱和。参与质子供体作用的Glu(506)处的突变延长了中间体II的寿命。讨论了中间体I和II的结构以及由Asp(112)和Glu(506)驱动的氧气四电子还原机制。

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