酶和合成体系中双铜配合物O[键]O裂解的热力学比较。

A comparison of the thermodynamics of O[bond]O cleavage for dicopper complexes in enzymes and synthetic systems.

作者信息

Siegbahn Per E M

机构信息

Department of Physics, Stockholm Centre for Physics, Astronomy and Biotechnology (SCFAB), Stockholm University, 106 91 , Stockholm, Sweden.

出版信息

J Biol Inorg Chem. 2003 May;8(5):577-585. doi: 10.1007/s00775-003-0451-x. Epub 2003 Mar 28.

DOI:10.1007/s00775-003-0451-x

PMID:12764603

Abstract

The preferred state, the peroxide Cu(2)(II,II) or the bis-mu-oxo Cu(2)(III,III) states, for oxygen-bridged copper dimers with nitrogen donors is reinvestigated. Experiments have indicated that for the enzymatic complexes with histidine ligands the peroxide state should be favored, at least for hemocyanin, while for the synthetic complexes with strained ligands the bis-mu-xo state should be intrinsically favored. The present B3LYP study essentially agrees with these results. The quite different results obtained in CASPT2 and some previous B3LYP studies for these systems are investigated and discussed. The conclusion, drawn in an earlier study, that the Cu(2)(III,III) state is an unlikely intermediate in the enzyme mechanisms of tyrosinase and catechol oxidase, still remains.

摘要

对具有氮供体的氧桥连铜二聚体的首选状态，即过氧化物Cu(2)(II,II)或双μ-氧代Cu(2)(III,III)状态，进行了重新研究。实验表明，对于具有组氨酸配体的酶复合物，至少对于血蓝蛋白而言，过氧化物状态应该更受青睐，而对于具有张力配体的合成复合物，双μ-氧代状态本质上应该更受青睐。目前的B3LYP研究基本上与这些结果一致。对这些体系在CASPT2和一些先前的B3LYP研究中获得的截然不同的结果进行了研究和讨论。早期研究得出的结论，即Cu(2)(III,III)状态不太可能是酪氨酸酶和儿茶酚氧化酶的酶机制中的中间体，仍然成立。

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酶和合成体系中双铜配合物O[键]O裂解的热力学比较。

A comparison of the thermodynamics of O[bond]O cleavage for dicopper complexes in enzymes and synthetic systems.

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