Cytochrome c oxidase. Time dependence of optical and EPR spectral changes related to the ‘oxygen-pulsed’ form

Abstract

Time-dependent changes in the optical spectrum (450–920 nm) of cytochrome c oxidase, following oxidation with oxygen of the stoichiometrically reduced form, have been investigated and where possible, attempts have been made to correlate our observations with variations in the EPR spectrum over a parallel time course at 2°C. In this regard, particular emphasis has been placed on establishing absorption features related to the presence of EPR resonances at g 5, 1.78 and 1.69, which have been tentatively assigned to a spin-coupled state involving cytochrome a 3 and ‘EPR-undetectable Cu’ (Beinert, H., Shaw, R.W., Dunham, R.W. and Sands, R.H. (1982) in Oxidases and Related Redox Systems (King, T.E., Mason, H.S. and Morrison, M., eds.), Pergamon Press, Oxford, in the press). For optical studies we have used a versatile rapid-scanning spectrophotometer to obtain well resolved spectra down to 2 ms reaction time. Concomitant with the appearance (within 10 ms) of EPR signals at g 5, 1.78 and 1.69 is the presence of an enhanced absorption ( Δε = 0.25 mM (heme a) −1·cm −1) at 660 nm, with a trough (relative to following spectra) at 580 nm. In our hands, this feature disappears in a first-order process with a half-life of 46 s at pH 7.2 and 2°C. The effect of this spectral transformation is to decrease considerably the acuteness of the 655 nm absorption band, previously suggested as representing a state of the enzyme in which ferric cytochrome a 3 is coupled to oxidised EPR-undetectable Cu (Beinert, H., Hansen, R.E. and Hartzell, C.R. (1976) Biochim. Biophys. Acta 423, 339–355). This observation can be correlated satisfactorily with a small field shift of the high-field resonances at g 1.78 and 1.69 and a broadening at g 1.78. Support for this and further correlative assignments arises from parallel experiments using cytochrome c oxidase purified via an alternative procedure, which displays different kinetic behavior. Further transformations of the oxidized enzyme are evident through an approx. 10% decrease in absorbance at 600 nm together with small changes centered at 640 and 665 nm (which serve to restore the sharpness of the 655 nm band). The kinetics, as analyzed by the Guggenheim procedure using the absorbance at 597 nm, indicate approx. 50% first-order linearity (half-life 40 min) with additional species contributing at longer times, while over a parallel time course (0–3 h) the EPR resonances at g 5, 1.78 and 1.69 virtually disappear. These novel signals can also be seen at a lower intensity in samples of cytochrome c oxidase anaerobically reoxidized by porphyrexide and frozen after a 6 min incubation period at 4°C. This observation, along with the establishment of similar optical changes over the time course of 1 min to 3 h, suggests that aerobic and anaerobic reoxidation produce common forms of the enzyme. Comparison of the g 1.78 and 1.69 resonances between samples rapidly aerobically reoxidized in the presence of H 2 16O and H 2 17O yielded no evidence for the presence of any labile oxygen ligand (including OH −, H 2O) in the coordination sphere of the species involved.