The invisible copper of cytochrome c oxidase. pH and ATP dependence of its midpoint potential and its role in the oxygen reaction.

Formation of the CO compound has been studied in intact mitochondria, submitochondrial particles and isolated cytochrome oxidase. The reaction requires the prior reduction of both cytochrome a₃ and one other single-electron acceptor. It is inferred that the second acceptor is the “invisible” copper which is undetectable by both optical and spin resonance spectroscopy. The overall process can be viewed as two single electron steps plus a ligand binding reaction. At high concentrations of CO, when titrations are performed at oxidation-reduction potentials significantly above the midpoints of either cytochrome a₃ or “invisible” copper, appearance of the CO compound follows a strict n = 2 (2-electron) relationship. Its midpoint potential is also dependent on the prevailing concentration of CO and is increased by approx. 30 mV for each tenfold increase in the level of CO. At redox potentials approaching the midpoints of cytochrome a₃ or “invisible” copper, significant deviations from n = 2 behavior are apparent which are readily detectable experimentally using low CO concentrations.A mathematical analysis of this model is presented and the oxidation-reduction properties of the CO compound are utilized to determine the midpoint potential of the “invisible” copper. This value is estimated to be 340 ± 10 mV at pH 7.8, independent of pH and the prevailing $\text{sol}\text{ATP]}\text{ADP]}\text{×}\text{P}{}_1\text{]}$ ratio.By analogy with the observations on CO binding, the primary intermediate in the oxidase reaction with oxygen is concluded to be a bridged a₃²⁺-O₂-Cu¹⁺ complex. The initial reduction of molecular oxygen can then proceed via a thermodynamically favorable two-electron step to form a bridged peroxide intermediate. Subsequent reduction to water may later occur by way of two single-electron steps or one two-electron step.