Electron transfer process in cytochrome oxidase after pulse radiolysis

The reduction of bovine heart cytochrome oxidase by the 1-methylnicotinamide (MNA) radical was investigated by the use of pulse radiolysis. With the decay of the MNA radical, the absorption at 445 and 605 nm, a characteristic to ferrous heme a of the oxidase, increased. The kinetic difference spectrum obtained was similar to that of the fully reduced minus the fully oxidized form of the oxidase, and was not different from that obtained in the reaction of the MNA radical with the mixed valence CO complex of the oxidase, where heme a3 is the CO-bound reduced form with heme a oxidized. This suggests that the absorption changes at 445 and 605 nm arise from the reduction of heme a, not heme a3. In order to elucidate the contribution of "visible" copper in this reaction, the absorption of the oxidase in the near-infrared region was measured. A decrease of the 830 nm band due to the reduction of visible copper was detected with a half-life of 5 microseconds. This absorption change obeyed pseudo-first order kinetics and its rate constant increased with the concentration of the oxidase. This suggests that the absorption change at 830 nm is followed by a bimolecular reaction of the MNA radical with visible copper of the oxidase. After the first phase of the reduction, the return of the 830 nm band corresponding to oxidation of the copper was observed with a half-life of 100 microseconds. Concomitantly, the absorption at 605 and 445 nm due to the reduction of heme a increased. The rates of oxidation of the copper were identical to those of the reduction of heme a and independent of the oxidase concentration. This suggests that the MNA radical reacts with visible copper of the oxidase with a second order rate constant of 1.5 X 10(9) m-1 s-1 and subsequently the electron flows to heme a by intramolecular electron migration with a first order rate constant of 1.8 X 10(4) s-1. An activation energy of the intramolecular electron transfer was calculated to be 2.8 kcal/mol in the range 4-33 degrees C.