The Amazing High-Valent Nonheme Iron-Oxo Landscape

Bulletin of Japan Society of Coordination Chemistry Pub Date : 2016-05-31 DOI:10.4019/BJSCC.67.10

L. Que, Mayank Puri

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引用次数: 8

Abstract

Over the past 25 years, a-ketoglutarate (aKG)-dependent enzymes with mononuclear nonheme iron centers that activate dioxygen have emerged as a versatile family of enzymes involved in a variety of important metabolic transformations as well as in the biosynthesis of antibiotics. These enzymes are capable of C–H bond hydroxylation, halogenation, and stereoinversion, C–C bond desaturation, and heterocyclic ring formation. Their active sites, as represented by taurine:aketoglutarate dioxygenase (TauD), generally consist of a 2-His-1-carboxylate facial triad that serves to bind the iron(II) center. In the nonheme iron halogenase enzymes, the carboxylate is replaced by a chloride or a bromide, which is the atom that is incorporated into the C–H bond. Reaction of the reduced enzymes with O2 leads to the generation of highvalent oxoiron intermediates responsible for the critical C– H cleavage step (Scheme 1). Such species have been trapped by Bollinger and Krebs for several enzymes in this family and demonstrated to have a high-spin S = 2 Fe=O unit that is kinetically competent to cleave the C–H bonds of their respective substrates with large nonclassical H/D kinetic isotope effects.

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惊人的高价非血红素铁氧景观

在过去的25年里，a-酮戊二酸(aKG)依赖的酶，具有激活双氧的单核非血红素铁中心，已经成为一个多用途的酶家族，参与各种重要的代谢转化以及抗生素的生物合成。这些酶具有碳氢键羟基化、卤化和立体转化、碳氢键去饱和和杂环形成的能力。它们的活性位点，以牛磺酸为代表:aketoglutarate dioxygenase (TauD)，通常由2- his1 -羧酸表面三联体组成，用于结合铁(II)中心。在非血红素铁卤素酶中，羧酸盐被氯离子或溴离子取代，氯离子是与C-H键结合的原子。还原酶与O2的反应导致产生高价氧化铁中间体，负责关键的C - H裂解步骤(方案1)。这些物种已经被Bollinger和Krebs捕获，用于该家族的几种酶，并证明具有高自旋S = 2 Fe=O单元，具有裂解各自底物的C - H键的动力学能力，具有较大的非经典H/D动力学同位素效应。

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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Bulletin of Japan Society of Coordination Chemistry

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