Spectroscopic and Kinetic Studies of Perturbed Trinuclear Copper Clusters: The Role of Protons in Reductive Cleavage of the O−O Bond in the Multicopper Oxidase Fet3p

Abstract

The multicopper oxidase Fet3p couples four 1e^- oxidations of substrate to the 4e^- reduction of O₂ to H₂O. Fet3p uses four Cu atoms to accomplish this reaction: the type 1, type 2, and coupled binuclear type 3 sites. The type 2 and type 3 sites together form a trinuclear Cu cluster (TNC) which is the site of O₂ reduction. This study focuses on mutants of two residues, E487 and D94, which lie in the second coordination sphere of the TNC and defines the role that each plays in the structural integrity of the TNC, its reactivity with O₂, and in the directional movement of protons during reductive cleavage of the O−O bond. The E487D, E487A, and D94E mutants have been studied in the holo and type 1 depleted (T1D) forms. Residue E487, located near the T3 center, is found to be responsible for donation of a proton during the reductive cleavage of the O−O bond in the peroxide intermediate and an inverse kinetic solvent isotope effect, which indicates that this proton is already transferred when the O−O bond is cleaved. Residue D94, near the T2 site, plays a key role in the reaction of the reduced TNC with O₂ and drives electron transfer from the T2 Cu to cleave the O−O bond by deprotonating the T2 Cu water ligand. A mechanism is developed where these second sphere residues participate in the proton assisted reductive cleavage of the O−O bond at the TNC.