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甲基(烷基)辅酶 M 还原酶:含镍 F-430 的酶,参与厌氧甲烷形成以及甲烷或短链烷烃的厌氧氧化。

Methyl (Alkyl)-Coenzyme M Reductases: Nickel F-430-Containing Enzymes Involved in Anaerobic Methane Formation and in Anaerobic Oxidation of Methane or of Short Chain Alkanes.

机构信息

Max Planck Institute for Terrestrial Microbiology , Karl-von-Frisch-Strasse 10 , Marburg 35043 , Germany.

出版信息

Biochemistry. 2019 Dec 31;58(52):5198-5220. doi: 10.1021/acs.biochem.9b00164. Epub 2019 Apr 5.

DOI:10.1021/acs.biochem.9b00164
PMID:30951290
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6941323/
Abstract

Methyl-coenzyme M reductase (MCR) catalyzes the methane-forming step in methanogenic archaea. The active enzyme harbors the nickel(I) hydrocorphin coenzyme F-430 as a prosthetic group and catalyzes the reversible reduction of methyl-coenzyme M (CH-S-CoM) with coenzyme B (HS-CoM) to methane and CoM-S-S-CoB. MCR is also involved in anaerobic methane oxidation in reverse of methanogenesis and most probably in the anaerobic oxidation of ethane, propane, and butane. The challenging question is how the unreactive CH-S thioether bond in methyl-coenzyme M and the even more unreactive C-H bond in methane and the other hydrocarbons are anaerobically cleaved. A key to the answer is the negative redox potential (') of the Ni(II)F-430/Ni(I)F-430 couple below -600 mV and the radical nature of Ni(I)F-430. However, the negative one-electron redox potential is also the Achilles heel of MCR; it makes the nickel enzyme one of the most O-sensitive enzymes known to date. Even under physiological conditions, the Ni(I) in MCR is oxidized to the Ni(II) or Ni(III) states, e.g., when in the cells the redox potential (') of the CoM-S-S-CoB/HS-CoM and HS-CoB couple (' = -140 mV) gets too high. Methanogens therefore harbor an enzyme system for the reactivation of inactivated MCR in an ATP-dependent reduction reaction. Purification of active MCR in the Ni(I) oxidation state is very challenging and has been achieved in only a few laboratories. This perspective reviews the function, structure, and properties of MCR, what is known and not known about the catalytic mechanism, how the inactive enzyme is reactivated, and what remains to be discovered.

摘要

甲基辅酶 M 还原酶(MCR)催化产甲烷古菌中的甲烷形成步骤。活性酶含有镍(I)氢化腐啉辅酶 F-430 作为辅基,并催化辅酶 B(HS-CoM)与甲基辅酶 M(CH-S-CoM)的可逆还原为甲烷和 CoM-S-S-CoB。MCR 还参与甲烷生成的逆反应中的厌氧甲烷氧化,并且很可能参与乙烷、丙烷和丁烷的厌氧氧化。具有挑战性的问题是如何在厌氧条件下裂解甲基辅酶 M 中不反应的 CH-S 硫醚键以及甲烷和其他烃类中更不反应的 C-H 键。答案的关键是 Ni(II)F-430/Ni(I)F-430 偶联的负氧化还原电位(')低于-600 mV 以及 Ni(I)F-430 的自由基性质。然而,负单电子氧化还原电位也是 MCR 的致命弱点;它使镍酶成为迄今为止已知的对 O 最敏感的酶之一。即使在生理条件下,MCR 中的 Ni(I)也会被氧化为 Ni(II)或 Ni(III)状态,例如,当细胞中的 CoM-S-S-CoB/HS-CoM 和 HS-CoB 偶联的氧化还原电位(')变得过高时。因此,产甲烷菌拥有一种酶系统,用于在依赖 ATP 的还原反应中使失活的 MCR 重新活化。以 Ni(I)氧化态纯化活性 MCR 非常具有挑战性,并且仅在少数几个实验室中实现。本文综述了 MCR 的功能、结构和性质,催化机制的已知和未知内容,失活酶的重新活化方式以及仍有待发现的内容。

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