低自旋血红素/Cu 过氧化物配合物的电子结构：反应性的自旋态和自旋拓扑贡献。

Electronic structure of a low-spin heme/Cu peroxide complex: spin-state and spin-topology contributions to reactivity.

机构信息

Department of Chemistry, Stanford University, Stanford, California 94305, United States.

出版信息

Inorg Chem. 2011 Nov 21;50(22):11777-86. doi: 10.1021/ic2018727. Epub 2011 Oct 18.

DOI:10.1021/ic2018727

PMID:22007669

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3226806/

Abstract

This study details the electronic structure of the heme–peroxo–copper adduct {[(F8)Fe(DCHIm)]-O2-[Cu(AN)]}+ (LS(AN)) in which O2(2–) bridges the metals in a μ-1,2 or “end-on” configuration. LS(AN) is generated by addition of coordinating base to the parent complex {[(F8)Fe]-O2-[Cu(AN)]}+ (HS(AN)) in which the O2(2–) bridges the metals in an μ-η2:η2 or “side-on” mode. In addition to the structural change of the O2(2–) bridging geometry, coordination of the base changes the spin state of the heme fragment (from S = 5/2 in HS(AN) to S = 1/2 in LS(AN)) that results in an antiferromagnetically coupled diamagnetic ground state in LS(AN). The strong ligand field of the porphyrin modulates the high-spin to low-spin effect on Fe–peroxo bonding relative to nonheme complexes, which is important in the O–O bond cleavage process. On the basis of DFT calculations, the ground state of LS(AN) is dependent on the Fe–O–O–Cu dihedral angle, wherein acute angles (<~150°) yield an antiferromagnetically coupled electronic structure while more obtuse angles yield a ferromagnetic ground state. LS(AN) is diamagnetic and thus has an antiferromagnetically coupled ground state with a calculated Fe–O–O–Cu dihedral angle of 137°. The nature of the bonding in LS(AN) and the frontier molecular orbitals which lead to this magneto-structural correlation provide insight into possible spin topology contributions to O–O bond cleavage by cytochrome c oxidase.

摘要

本研究详细介绍了 [（F8）Fe（DCHIm）]-O2-[Cu（AN）]+（LS（AN））中血红素-过氧-铜加合物的电子结构，其中 O2(2–) 以 μ-1,2 或“端接”构型桥连金属。LS(AN) 通过向母体配合物 {[(F8)Fe]-O2-[Cu（AN）]+（HS（AN））} 中添加配位碱来生成，其中 O2(2–) 以 μ-η2:η2 或“侧接”模式桥连金属。除了 O2(2–) 桥接几何结构的变化外，配体的配位还改变了血红素片段的自旋态（从 HS(AN) 中的 S = 5/2 变为 LS(AN) 中的 S = 1/2），导致 LS(AN) 中呈现反铁磁耦合的抗磁性基态。卟啉的强配体场调节了相对于非血红素配合物的 Fe–过氧键的高自旋到低自旋效应，这在 O–O 键断裂过程中很重要。基于 DFT 计算，LS(AN) 的基态取决于 Fe–O–O–Cu 二面角，其中锐角（<~150°）产生反铁磁耦合的电子结构，而更钝角则产生铁磁基态。LS(AN) 是抗磁性的，因此具有反铁磁耦合的基态，计算得到的 Fe–O–O–Cu 二面角为 137°。LS(AN) 的成键性质和导致这种磁结构相关性的前沿分子轨道为细胞色素 c 氧化酶中 O–O 键断裂的可能自旋拓扑贡献提供了深入了解。

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