UndA 介导脂肪酸脱羧反应时,底物触发过氧合-Fe(III/III) 中间产物的形成。
Substrate-Triggered Formation of a Peroxo-Fe(III/III) Intermediate during Fatty Acid Decarboxylation by UndA.
机构信息
Department of Chemical and Biomolecular Engineering , University of California Berkeley , Berkeley , California 94720 , United States.
出版信息
J Am Chem Soc. 2019 Sep 18;141(37):14510-14514. doi: 10.1021/jacs.9b06093. Epub 2019 Sep 10.
Abstract
The iron-dependent oxidase UndA cleaves one C3-H bond and the C1-C2 bond of dodecanoic acid to produce 1-undecene and CO. A published X-ray crystal structure showed that UndA has a heme-oxygenase-like fold, thus associating it with a structural superfamily that includes known and postulated non-heme diiron proteins, but revealed only a single iron ion in the active site. Mechanisms proposed for initiation of decarboxylation by cleavage of the C3-H bond using a monoiron cofactor to activate O necessarily invoked unusual or potentially unfeasible steps. Here we present spectroscopic, crystallographic, and biochemical evidence that the cofactor of Pf-5 UndA is actually a diiron cluster and show that binding of the substrate triggers rapid addition of O to the Fe(II/II) cofactor to produce a transient peroxo-Fe(III/III) intermediate. The observations of a diiron cofactor and substrate-triggered formation of a peroxo-Fe(III/III) intermediate suggest a small set of possible mechanisms for O, C3-H and C1-C2 activation by UndA; these routes obviate the problematic steps of the earlier hypotheses that invoked a single iron.
摘要
铁依赖型氧化酶 UndA 可裂解十二烷酸的一个 C3-H 键和 C1-C2 键,生成 1-十一烯和 CO。已发表的 X 射线晶体结构显示,UndA 具有血红素加氧酶样折叠,因此与一个结构超家族相关,该超家族包括已知和推测的非血红素双铁蛋白,但在活性位点中仅显示出一个铁离子。使用单铁辅因子裂解 C3-H 键引发脱羧反应的机制提议,必然涉及不寻常或潜在不可行的步骤。在这里,我们提出了光谱学、晶体学和生物化学证据,表明 Pf-5 UndA 的辅因子实际上是一个双铁簇,并表明底物的结合触发 O 迅速添加到 Fe(II/II)辅因子上,产生瞬态过氧-Fe(III/III)中间体。双铁辅因子和底物触发形成过氧-Fe(III/III)中间体的观察结果表明,UndA 对 O、C3-H 和 C1-C2 的激活可能存在一小部分可能的机制;这些途径排除了先前假设中涉及单个铁的有问题的步骤。
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