Characterization of the Preprocessed Copper Site Equilibrium in Amine Oxidase and Assignment of the Reactive Copper Site in Topaquinone Biogenesis

Authors

Charles N. Adelson, Esther M. Johnston, Kimberly M. Hilmer, Hope Watts, Somdatta Ghosh Dey, Doreen E. Brown, Joan B. Broderick, Eric M. Shepard, David M. Dooley, Edward I. Solomon

Publication

Journal of the American Chemical Society

Abstract

Copper-dependent amine oxidases produce their redox active cofactor, 2,4,5-trihydroxyphenylalanine quinone (TPQ), via the CuII-catalyzed oxygenation of an active site tyrosine. This study addresses possible mechanisms for this biogenesis process by presenting the geometric and electronic structure characterization of the CuII-bound, prebiogenesis (preprocessed) active site of the enzyme Arthrobacter globiformis amine oxidase (AGAO). CuII-loading into the preprocessed AGAO active site is slow (kobs = 0.13 h–1), and is preceded by CuII binding in a separate kinetically favored site that is distinct from the active site. Preprocessed active site CuII is in a thermal equilibrium between two species, an entropically favored form with tyrosine protonated and unbound from the CuII site, and an enthalpically favored form with tyrosine bound deprotonated to the CuII active site. It is shown that the CuII-tyrosinate bound form is directly active in biogenesis. The electronic structure determined for the reactive form of the preprocessed CuII active site is inconsistent with a biogenesis pathway that proceeds through a CuI-tyrosyl radical intermediate, but consistent with a pathway that overcomes the spin forbidden reaction of 3O2 with the bound singlet substrate via a three-electron concerted charge-transfer mechanism.

Links

• Characterization of the Preprocessed Copper Site Equilibrium in Amine Oxidase and Assignment of the Reactive Copper Site in Topaquinone Biogenesis