P450 化合物 I 和 II 的还原电位：对 C-H 键活化热力学的深入了解。

Reduction Potentials of P450 Compounds I and II: Insight into the Thermodynamics of C-H Bond Activation.

机构信息

Department of Chemistry and Department of Molecular Biology and Biochemistry , University of California , Irvine , California 92697 , United States.

出版信息

J Am Chem Soc. 2019 Apr 3;141(13):5504-5510. doi: 10.1021/jacs.9b00242. Epub 2019 Mar 20.

DOI:10.1021/jacs.9b00242

PMID:30892878

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7104868/

Abstract

We present a mixed experimental/theoretical determination of the bond strengths and redox potentials that define the ground-state thermodynamics for C-H bond activation in cytochrome P450 catalysis. Using redox titrations with [Ir(IV)Cl], we have determined the compound II/ferric (or Fe(IV)OH/Fe(III)OH) couple and its associated D(O-H) bond strength in CYP158. Knowledge of this potential as well as the compound II/ferric (or Fe(IV)O/Fe(III)OH) reduction potential in horseradish peroxidase and the two-electron compound I/ferric (or Fe(IV)O(Por)/Fe(III)OH(Por)) reduction potential in aromatic peroxidase has allowed us to gauge the accuracy of theoretically determined bond strengths. Using the restricted open shell (ROS) method as proposed by Wright and co-workers, we have obtained O-H bond strengths and associated redox potentials for charge-neutral H-atom reductions of these iron(IV)-hydroxo and -oxo porphyrin species that are within 1 kcal/mol of experimentally determined values, suggesting that the ROS method may provide accurate values for the P450-II O-H bond strength and P450-I reduction potential. The efforts detailed here indicate that the ground-state thermodynamics of C-H bond activation in P450 are best described as follows: E = 1.22 V (at pH 7, vs NHE) with D(O-H) = 95 kcal/mol and E = 0.99 V (at pH 7, vs NHE) with D(O-H) = 90 kcal/mol.

摘要

我们提出了一种混合实验/理论的方法，用于确定细胞色素 P450 催化中 C-H 键活化的基态热力学的键强度和氧化还原电位。通过使用[Ir(IV)Cl]的氧化还原滴定，我们确定了 CYP158 中的复合物 II/铁（或 Fe(IV)OH/Fe(III)OH）偶联及其相关的 D(O-H)键强度。该电位以及辣根过氧化物酶中的复合物 II/铁（或 Fe(IV)O/Fe(III)OH）还原电位和芳香过氧化物酶中的两电子复合物 I/铁（或 Fe(IV)O(Por)/Fe(III)OH(Por))还原电位的知识，使我们能够评估理论确定的键强度的准确性。使用 Wright 及其同事提出的受限开壳（ROS）方法，我们获得了这些铁（IV）-羟和 -氧卟啉物种中性 H-原子还原的 O-H 键强度和相关氧化还原电位，这些值与实验确定的值相差 1 kcal/mol 以内，表明 ROS 方法可能为 P450-II O-H 键强度和 P450-I 还原电位提供准确的值。这里详细描述的努力表明，P450 中 C-H 键活化的基态热力学最好描述为：E = 1.22 V（在 pH 7 下，相对于 NHE），D(O-H) = 95 kcal/mol 和 E = 0.99 V（在 pH 7 下，相对于 NHE），D(O-H) = 90 kcal/mol。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a573/7104868/c5119d7d581d/nihms-1574586-f0002.jpg

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