Substitution of Lysine-362 in a Putative Proton-Conducting Channel in the Cytochrome c Oxidase from Rhodobacter sphaeroides Blocks Turnover with O2 but Not with H2O2

Abstract

The recently reported X-ray structures of cytochrome oxidase reveal structures that are likely proton-conducting channels. One of these channels, leading from the negative aqueous surface to the heme a₃/Cu_B bimetallic center, contains a lysine as a central element. Previous work has shown that this lysine (K362 in the oxidase from Rhodobacter sphaeroides) is essential for cytochrome c oxidase activity. The data presented demonstrate that the K362M mutant is impeded in the reduction of the heme a₃/Cu_B bimetallic center, probably by interfering with the intramolecular movement of protons. The reduction of the heme−copper center is required prior to the reaction with dioxygen to form the so-called peroxy intermediate (compound P). This block can be by-passed to some extent by the addition of H₂O₂, which can react with the enzyme without prereduction of the heme−copper center and can then be reduced to water using electrons from cytochrome c. Hence, the K362M mutant, though lacking oxidase activity, exhibits cytochrome c peroxidase activity. Rapid mixing techniques have been used to determine the kinetics of this peroxidase activity at concentrations of H₂O₂ up to 0.5 M. The K_m for peroxide is about 50 mM and the V_max is 50 electrons s^-1, which is considerably slower than the turnover that can be obtained for the oxidase activity of the wild-type enzyme (1200 s^-1). The turnover of the mutant oxidase with H₂O₂ appears to be limited by the rate of reaction of the enzyme with peroxide to form compound P, rather than the rate of reduction of compound P to water by cytochrome c. The data require a reexamination of the proposed roles of the putative proton-conducting channels.