What is the essential proton-translocating molecular machinery in cytochrome oxidase?

Pulses of O2 added to anaerobic mitochondria in the presence of antimycin, but in the absence of exogenous reductants, led to H+ translocation until the amount of oxidizing equivalents exceeded the number of endogenous reducing equivalents capable of rapid reduction of cytochrome oxidase. This demonstrates that either the heme of cytochrome alpha or that CuA is the redox center, the function of which is coupled to proton translocation in cytochrome oxidase. Chemical labeling of subunit III of cytochrome oxidase by dicyclocarbodiimide (DCCD), or removal of this subunit by treatment of the enzyme at high pH, results in loss of proton translocation by the isolated and membrane-reconstituted enzyme. Possible roles of subunit III in proton translocation are discussed.

The current-voltage relationships of liposomes and mitochondria.

Current-voltage relationships were determined for various membrane systems. We show that phospholipid and mitochondrial membranes exhibit linear relations between H+ flux and pH gradients. These membranes, however, exhibited non-linear relationships when the applied voltage was a membrane potential. The current-voltage relationship approximated to an exponential function. This relationship was found to be linearized when the membranes were treated with an electrogenic proton ionophore. The incorporation of cytochrome c oxidase (EC 1.9.3.1) was found to have no effect on the current-voltage characteristics of the phospholipid membranes. When a membrane potential of more than 140 mV was imposed across vesicular and mitochondrial membranes, they exhibited reversible di-electric breakdown. This phenomenon was correlated with the requirement of a permeant ion for the experimental demonstration of proton translocation by so-called 'proton pumps'.

A quantitative characterisation of H+ translocation by cytochrome c oxidase vesicles.

A quantitative analysis of H+ extrusion by reconstituted cytochrome c oxidase vesicles is presented with particular regard to the decay kinetics of the extruded proton pulse and to the structural heterogeneity of the vesicle preparation. The decay of the extruded H+ pulse under conditions typical of those used for its measurement is much slower than expected from the passive proton permeability of the vesicle membranes. It is shown that this apparent anomaly results from insufficient transmembrane charge equilibration via valinomycin and K+ during oxidase turnover. This situation can be remedied by increasing the valinomycin concentration or by replacing this counterion system with 1 mM tetraphenylphosphonium. Under these latter conditions, the decay kinetics can be described as the sum of two exponential terms. To facilitate interpretation of the proton pump decay kinetics, a structural analysis of the oxidase vesicle preparation is presented. The bulk of the reconstituted vesicles (i.e., those representing approx. 80% of the total oxidase and lipid) are 30-62 nm in diameter. At least 70% of the reconstituted oxidase molecules are contained individually in separate vesicles, indicating that the enzyme monomer is competent in H+ translocation.

Structural and functional alterations induced in the mitochondrial cytochrome b-c1 complex by N,N'-dicyclohexylcarbodiimide.

N,N'-Dicyclohexylcarbodiimide (DCCD) inhibits the activity of ubiquinol-cytochrome c reductase in the isolated and reconstituted mitochondrial cytochrome b-c1 complex. In proteoliposomes containing b-c1 complex DCCD inhibits equally electron flow and proton translocation catalyzed by the enzyme. In both isolated and reconstituted systems the inhibitory effect is accompanied by structural alterations in the polypeptide pattern of the enzyme consistent with cross-linking between subunits V and VII. The kinetics of inhibition of enzymic activity correlates with that of the cross-linking, suggesting that the two phenomena may be coupled. Binding of [14C] DCCD to both isolated and reconstituted enzyme was also observed, though it was not correlated kinetically with the inhibition.

Effects of N, N'-dicyclohexylcarbodiimide on isolated and reconstituted cytochrome b-c1 complex from bovine heart mitochondria.

N,N'-Dicyclohexylcarbodiimide (DCCD) inhibits the activity of ubiquinol-cytochrome c reductase in the isolated and reconstituted mitochondrial cytochrome b-c1 complex. DCCD inhibits equally electron flow and proton translocation (i.e., the H +/- ratio is not affected) catalysed by the enzyme reconstituted into phospholipid vesicles. The inhibitory effects are accompanied by structural alterations in the polypeptide pattern of both isolated and reconstituted enzyme. Cross-linking was observed between subunits V (iron-sulfur protein) and VII, indicating that these polypeptides are in close proximity. A clear correlation was found between the kinetics of inhibition of enzyme activity and the cross-linking, suggesting that the two phenomena may be couples. Binding of [14C]DCCD was also observed, to all subunits with the isolated enzyme and preferentially to cytochrome b with the reconstituted vesicles; in both cases, however, it was not correlated kinetically with the inhibition of the enzymic activity.

An evaluation of the evidence for H+ pumping by reconstituted cytochrome c oxidase in the light of recent criticism.

We review the evidence for H+ translocation by reconstituted cytochrome c oxidase; attention is paid to those aspects which we feel most open to criticism. Possible alternative hypotheses are assessed, with regard to experiments carried out to test them directly and with regard to published data. We conclude that, whilst certain aspects of this system are worthy of further clarification, the reported observations are all consistent with proton translocation by reconstituted cytochrome c oxidase; most of these observations provide a positive indication of such an activity.

Purification and characterization of the cytochrome c oxidase from Rhodopseudomonas sphaeroides.

When grown aerobically in the dark, Rhodopseudomonas sphaeroides develops a respiratory chain similar to that in mitochondria and the photosynthetic apparatus is suppressed. The aa3-type cytochrome c oxidase from Rps. sphaeroides has been purified in Triton X-100 by affinity chromatography with Sepharose 4B coupled to yeast cytochrome c. The oxidase contains 14 nmol heme a/mg protein and is composed of three polypeptide subunits with relative molecular masses of 45000, 37000 and 35000. The enzyme is highly active in the presence of detergents, with a maximal velocity of 300 s-1/mol oxidase using either yeast or horse-heart cytochrome c. The Rps. sphaeroides oxidase is cross-reactive with antibodies directed against the oxidases from Paracoccus denitrificans and Saccharomyces cerevisiae. A particularly close relationship is indicated in the case of P. denitrificans. The Rps. sphaeroides oxidase has been incorporated into phospholipid vesicles. The resulting oxidase in these vesicles demonstrates high enzymatic activity and a respiratory control ratio of 5. Using these vesicles, no evidence for proton extrusion accompanying cytochrome c oxidation was observed. The data suggest that the Rps. sphaeroides oxidase does not function as a proton pump.

Studies on the transmembrane orientation of cytochrome c oxidase in phospholipid vesicles.

We report investigations into the direction of orientation of cytochrome c oxidase in reconstituted vesicles and the factors determining this. Measurement of the enzyme orientation employed two independent techniques: monitoring of the level of haem reduction by membrane-permeant and membrane-impermeant reagents and a kinetic analysis of the reduction of a spin label covalently bound to the oxidase surface. The method of preparation of the oxidase vesicles had a pronounced effect on the enzyme orientation and the two measurement techniques agreed in indicating that the proportion of mitochondrially oriented enzyme was approximately 85% and 50% for vesicles prepared by cholate dialysis and sonication respectively. Our results show that the membrane orientation of the oxidase is determined by interactions between the phospholipid bilayer and the portion of the enzyme embedded therein, as opposed to gross physical constraints. In particular, we demonstrate that the orientation of the oxidase is affected by the fluidity and surface charge of the membrane.

Studies on the molecular basis of H+ translocation by cytochrome c oxidase.

We report here studies which characterize further the interaction of N,N'-dicyclohexylcarbodiimide with cytochrome c oxidase leading to inhibition of H+ translocation by the enzyme. Further evidence is presented to show that the inhibition results from a real interaction of DCCD with the enzyme and cannot be accounted for by uncoupling and, contrary to recent criticisms, this interaction occurs specifically with subunit III of the enzyme even at relatively high inhibitor-to-enzyme stoichiometries. Use of a spin-label analogue of DCCD has enabled us to demonstrate that the carbodiimide-binding site is highly apolar and may not lie on the pathway of electron transfer.

Structural studies on the cytochrome c oxidase proton pump using a spin-label probe.

We report studies in which we have used N-(2,2,6,6-tetramethylpiperidyl-l-oxyl)-N' -cyclohexylcarbodiimide, a spinlabel analogue of N,N' -dicyclohexylcarbodiimide, to investigate the structural aspects of the cytochrome c oxidase proton pump. We establish that the spin label binds to the reconstituted enzyme at the same site as does N,N' -dicyclohexylcarbodiimide, i.e., within subunit III. ESR studies of the bound spin label indicate that its binding site is situated in an apolar region of the enzyme, though close to its surface. The binding of the spin label to the free oxidase is different form that with the reconstituted enzyme, leading to spin-spin exchange between the bound probe molecules. From this and the fact that N,N' -dicyclohexylcarbodiimide binds to subunits III and IV in the free oxidase, we conclude that these two subunits are at the most 20 A apart.

Dicyclohexylcarbodiimide binds specifically and covalently to cytochrome c oxidase while inhibiting its H+-translocating activity.

We have investigated the covalent binding of dicyclohexylcarbodiimide (DCCD) to cytochrome c oxidase in relation to its inhibition of ferrocytochrome c-induced H+ translocation by the enzyme reconstituted in lipid vesicles. DCCD bound to the reconstituted oxidase in a time- and concentration-dependent manner which appeared to correlate with its inhibition of H+ translocation. In both reconstituted vesicles and intact beef heart mitochondria, the DCCD-binding site was located in subunit III of the oxidase. The apolar nature of DCCD and relatively minor effects of the hydrophilic carbodiimide, 1-ethyl-(3-dimethylaminopropyl)-carbodiimide, on H+ translocation by the oxidase indicate that the site of action of DCCD is hydrophobic. DCCD also bound to isolated cytochrome c oxidase, though in this case subunits III and IV were labeled. The maximal overall stoichiometries of DCCD molecules bound per cytochrome c oxidase molecule were 1 and 1.6 for the reconstituted and isolated enzymes, respectively. These findings point to subunit III of cytochrome c oxidase having an important role in H+ translocation by the enzyme and indicate that DCCD may prove a useful tool in elucidating the mechanism of H+ pumping.

Molecular aspects of cytochrome c oxidase: structure and dynamics.

In the last few years much attention has been dedicated to the elucidation of some of the molecular aspects of cytochrome c oxidase. It has been shown conclusively that the enzyme from several sources (yeast, Neurospora, heart, liver) contains seven different subunits, which are asymmetrically inserted in the membrane. All of these are in contact with the lipid bilayer (except subunits V and VI) and to a greater or lesser extent with the water phase as well (except for subunit I). Subunit II of the enzyme appears to be involved in the formation of the binding site of cytochrome c. The location of the redox groups of the enzyme is still a matter of controversy. Their distance from the cytochrome c heme group is approximately 35 A such that electron tunneling appears to be the only possible mechanism for transporting electrons across such a distance. A proton pump appears to be associated with electron transport and approximately one proton is extruded per electron equivalent reducing oxygen via the enzyme. N,N', dicyclohexylcarbodiimide a well-established inhibitor of H+-translocating ATPases inhibits the proton pump and labels specifically subunit III of the enzyme.