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Direct Copper(III) Formation from O2 and Copper(I) with Histamine Ligation

Gary, J. Brannon, Citek, Cooper, Brown, Timothy A., Zare, Richard N., Wasinger, Erik C., Stack, T. Daniel P.
Journal of the American Chemical Society 2016 v.138 no.31 pp. 9986-9995
chelation, copper, enzymes, histamine, histidine, hydrogen, ligands, oxidants, oxidation, oxygen, superoxide anion, temperature, thermodynamics
Histamine chelation of copper(I) by a terminal histidine residue in copper hydroxylating enzymes activates dioxygen to form unknown oxidants, generally assumed as copper(II) species. The direct formation of copper(III)-containing products from the oxygenation of histamine-ligated copper(I) complexes is demonstrated here, indicating that copper(III) is a viable oxidation state in such products from both kinetic and thermodynamic perspectives. At low temperatures, both trinuclear Cu(II)₂Cu(III)O₂ and dinuclear Cu(III)₂O₂ predominate, with the distribution dependent on the histamine ligand structure and oxygenation conditions. Kinetics studies suggest the bifurcation point to these two products is an unobserved peroxide-level dimer intermediate. The hydrogen atom reactivity difference between the trinuclear and binuclear complexes at parity of histamine ligand is striking. This behavior is best attributed to the accessibility of the bridging oxide ligands to exogenous substrates rather than a difference in oxidizing abilities of the clusters.