Protonmotive activity of cytochrome c oxidase: control of oxidoreduction of the heme centers by the protonmotive force in the reconstituted beef heart enzyme

This paper contributes to the characterization of partial steps of electron and proton transfer in mitochondrial cytochrome c oxidase with respect to their membrane arrangement and involvement in energy-linked protonmotive activity. It is shown that delta psi controls electron flow from cytochrome c to heme a is consistent with the view that the latter center is buried in the membrane in a central position. The pressure exerted by delta psi on oxidation of heme alpha 3 by O2 indicates also that this center is buried in the membrane at some distance from the inner side and is consistent with observations showing that protons consumed in the reduction of O2 to H2O derive from the inner space. Electron flow from heme alpha to heme alpha 3 is shown to be specifically controlled by delta pH and in particular by the pH of the inner phase. Analysis of the effect of DCCD treatment of oxidase vesicles reveals that concentrations of this reagent which result in selective modification of subunit III (Prochaska et al., 1981) produce inhibition of redox-linked proton release. Higher concentrations of DCCD which result also in modification of subunits II and IV (Prochaska et al., 1981) cause inhibition of the pH-dependent electron-transfer step from heme alpha to heme alpha 3.     

Reduction of oxygen-pulsed cytochrome c oxidase by cytochrome c and other electron donors

1. Stopped-flow experiments were performed in which solutions containing dithionite were mixed with air-saturated buffer. Cytochrome c oxidase present in the dithionite-containing syringe is fully oxidized within the mixing time and the oxygen-pulsed form of the oxidase is produced. 2. The reduction of this form by dithionite, by dithionite plus cytochrome c and by dithionite plus methyl viologen or benzyl viologen was followed and compared with the corresponding reduction reactions of the "resting" oxidized enzyme. Reduction by dithionite is relatively slow, but the rate of reduction is greatly increased by addition of cytochrome c or the viologens, which are even more effective than cytochrome c on a molar basis. 3. Profound differences between the transient kinetics of the reduction of the two oxidized oxidase derivatives were observed. The results are consistent with a direct reduction of cytochrome a followed by an intramolecular electron transfer to cytochrome a3 (k1obs = 7.5 s-1 for the oxygen-pulsed oxidase). 4. The spectrum of the oxygen-pulsed oxidase formed within 5 ms of the mixing closely resembles that of the "oxygenated" compound, but there were small differences between the two spectra.     

New perspectives on the assembly process of mitochondrial respiratory chain complex cytochrome c oxidase

The assembly of cytochrome c oxidase (COX) is a complicated process and requires a number of assembly factors to put all the necessary subunits in the correct position. Defects in COX assembly lead in particular to serious neuromuscular disorders. We demonstrated that COX-deficient patients can be associated with different assembly patterns. To obtain more insight in the biogenesis of COX in a living cell, we used yeast as a model organism to design a way to pulse label holo-COX with green fluorescent protein (GFP). Using blue native electrophoresis, we showed that the GFP-tagged subunit is incorporated into fully assembled COX and this GFP tagged complex still has enzymatic activity. This allows us to correlate the GFP fluorescence signal detected in vivo by microscopy with the synthesis, turnover and assembly of COX.     

The photoreactivity of the copper-NO complexes in cytochrome c oxidase and in other copper-containing proteins

The complexes of NO with CuB of cytochrome c oxidase in which cytochrome a3 may or may not be ligated to cyanide or fluoride are photodissociable. NO does not appear to react with CuB in complexes of cytochrome c oxidase in which sulphide or mercaptans are ligated to the haem iron of cytochrome a3. A comparison is made between the photoreactivity of the complexes of NO with cytochrome c oxidase and those with ceruloplasmin, ascorbate oxidase, and haemocyanin. It is shown that the photoreactivity of CuB 2+.NO in cytochrome c oxidase is not unique for this enzyme, but may also be observed in the complexes of NO with type-1 copper-containing enzymes. This would suggest that the ligation of CuB in cytochrome c oxidase shows some similarity to type-1 copper in blue oxidases.     

The mechanism by which oxygen and cytochrome c increase the rate of electron transfer from cytochrome a to cytochrome a3 of cytochrome c oxidase

When cytochrome c oxidase is isolated from mitochondria, the purified enzyme requires both cytochrome c and O2 to achieve its maximum rate of internal electron transfer from cytochrome a to cytochrome a3. When reductants other than cytochrome c are used, the rate of internal electron transfer is very slow. In this paper we offer an explanation for the slow reduction of cytochrome a3 when reductants other than cytochrome c are used and for the apparent allosteric effects of cytochrome c and O2. Our model is based on the conventional understanding of cytochrome oxidase mechanism (i.e. electron transfer from cytochrome a/CuA to cytochrome a3/CuB), but assumes a relatively rapid two-electron transfer between cytochrome a/CuA and cytochrome a3/CuB and a thermodynamic equilibrium in the "resting" enzyme (the enzyme as isolated) which favors reduced cytochrome a and oxidized cytochrome a3. Using the kinetic constants that are known for this reaction, we find that the activating effects of O2 and cytochrome c on the rate of electron transfer from cytochrome a to cytochrome a3 conform to the predictions of the model and so provide no evidence of any allosteric effects or control of cytochrome c oxidase by O2 or cytochrome c.     

Oxidation of cytochrome c by cytochrome c oxidase: spectroscopic binding studies and steady-state kinetics support a conformational transition mechanism

The long-known biphasic response of cytochrome c oxidase to the concentration of cytochrome c has been explained, alternatively, by the presence of a catalytic and a regulatory site on the oxidase, by negative cooperativity between adjacent active sites in dimeric oxidase, or by a transition of the enzyme molecule between different conformational states. The three mechanistic hypotheses allow testable predictions about the relationship between substrate binding and steady-state kinetics catalyzed by the monomeric and dimeric (or oligomeric) enzyme. We have tested these predictions on monomeric, dimeric, and oligomeric beef heart oxidase and on monomeric oxidase from Paracoccus denitrificans. The aggregation state of the oxidase was evaluated from the sedimentation equilibrium in the ultracentrifuge and by gel chromatography. The binding of cytochrome c to cytochrome c oxidase was measured by spectrophotometric titration of cytochrome c oxidase with cytochrome c. The procedure makes use of a small perturbation in the Soret band of the absorption spectrum of the cytochrome c-cytochrome c oxidase complex. The steady-state oxidation of cytochrome c was followed spectroscopically by an automated assay procedure, and the kinetic parameters were deduced by numerical analysis of several hundred initial rate assays in the substrate concentration range 0.15-30 microM. The following results were obtained: (1) The kinetics of cytochrome c oxidation are always biphasic at low ionic strength, independent of the aggregation state of the enzyme. (2) The kinetics become apparently monophasic at ionic strengths above 100 mM or at slightly acidic pH values.(ABSTRACT TRUNCATED AT 250 WORDS)     

A mechanism of respiratory control: studies with proteoliposomes containing cytochrome oxidase and bacteriorhodopsin

Both beef heart cytochrome oxidase and bacteriorhodopsin of Halobacterium halobium were reconstituted into liposomes by the sonication-cholate dialysis method. The proteoliposomes showed the respiratory control ratio of 4.2, and steady-state illumination of the vesicles lead to the 2.7-fold stimulation of the oxidase activity in the absence of uncouplers. The light-stimulated state 4 respiration increased with light intensity, but light had no effect on the oxidase activity that had been relieved by addition of uncouplers. Proteoliposomes with the photosensitive oxidase activity were also obtained when cytochrome oxidase vesicles were fused with bacteriorhodopsin vesicles in the presence of calcium chloride, and the extent of photoactivation was maximally 1.4-fold. The light-induced respiratory release was observed even in the presence of valinomycin or nigericin, indicating that the oxidase activity was sensitive to both the membrane potential and the pH gradient. We propose as a mechanism of the respiratory control that the process of proton transport to the reaction center for water formation is the rate limiting step for the cytochrome oxidase activity.     

Inhibition of the cytochrome c/cytochrome c oxidase system by cytochrome c derivatives and related fragments

The oxidation of ferrocytochrome c mediated by cytochrome c oxidase was investigated in the presence of ferricytochrome c, trifluoroacetyl-cytochrome c, the heme fragments Hse65-[1-65] and Hse80-[1-80] and their respective porphyrin derivatives, as well as carboxymethylated apoprotein and related fragments, polycations, salts and neutral additives. The inhibition of the redox reaction by salts and neutral molecules, even if in theoretical agreement with their effect on electrostatic interactions, may alternatively be interpreted in terms of hydrophobicity. The latter can account for the inhibitory properties of trifluoroacetylated ferricytochrome c, similar to those of ferricytochrome c. On the assumption that the inhibitory properties of some of the investigated derivatives monitor their binding affinities to the cytochrome c oxidase at the cytochrome c binding sites, the experimental results do not confirm a primarily electrostatic character for the cytochrome c/cytochrome c oxidase association process. Strong indication was found that the cytochrome c C-terminal sequence is critically involved in the complex formation. Conformational studies by circular dichroism measurements and IR spectroscopy in solution and in solid state respectively, show that some of the derivatives examined may possibly acqkuire in the binding process to the oxidase, as secondary structure similar to that present in the native cytochrome c.     

Pseudomonas fluorescens CHA0 can kill subterranean termite Odontotermes obesus by inhibiting cytochrome c oxidase of the termite respiratory chain

In the rhizosphere and their interaction with plants rhizobia encounter many different plant compounds, including phytohormones like auxins. Moreover, some rhizobial strains are capable of producing the auxin, indole-3-acetic acid (IAA). However, the role of IAA for the bacterial partner in the legume– Rhizobium symbiosis is not known. To identify the effect of IAA on rhizobial gene expression, a transposon (mTn 5gusA - oriV ) mutant library of Rhizobium etli , enriched for mutants that show differential gene expression under microaerobiosis and/or addition of nodule extracts as compared with control conditions, was screened for altered gene expression upon IAA addition. Four genes were found to be regulated by IAA. These genes appear to be involved in plant signal processing, motility or attachment to plant roots, clearly demonstrating a distinct role for IAA in legume– Rhizobium interactions.     

Stimulation of the respiratory chain of rat liver mitochondria between cytochrome c1 and cytochrome c by glucagon treatment of rats

Mitochondria from glucagon-treated rats oxidize succinate, but not ascorbate plus tetramethylphenylenediamine, faster in the uncoupled state than do control mitochondria. The rate of O(2) uptake in the presence of both substrates is equal to the sum of the rates of the O(2) uptake in the presence of either substrate alone. It is concluded that the mitochondrial respiratory chain is limited at some point between cytochromes b and c and that this step is regulated by glucagon. Measurement of the cytochrome spectra under uncoupled conditions in the presence of succinate and rotenone demonstrates a crossover between cytochromes c and c(1) when control mitochondria are compared with those from glucagon-treated rats, cytochrome c being more oxidized and cytochrome c(1) more reduced in control mitochondria. Under conditions where pyruvate metabolism is studied the control mitochondria are generally more oxidized than those from glucagon-treated rats, the redox state of cytochrome b-566 correlating with the rate of pyruvate metabolism in sucrose medium. However, when the redox state of the mitochondria is taken into account, a crossover between cytochromes c and c(1) is again apparent. The spectra of the b cytochromes are complex, but cytochrome b-562 appears to become more reduced relative to cytochrome b-566 in mitochondria from glucagon-treated rats than in control mitochondria. This can be explained by the existence of a more alkaline matrix in glucagon-treated rats, the redox potential for cytochrome b being pH-sensitive. It is concluded that glucagon stimulates electron flow between cytochromes c(1) and c. The physiological significance of these findings is discussed.     

Electronic and vibrational spectroscopy of the cytochrome c:cytochrome c oxidase complexes from bovine and Paracoccus denitrificans.

The 1:1 complex between horse heart cytochrome c and bovine cytochrome c oxidase, and between yeast cytochrome c and Paracoccus denitrificans cytochrome c oxidase have been studied by a combination of second derivative absorption, circular dichroism (CD), and resonance Raman spectroscopy. The second derivative absorption and CD spectra reveal changes in the electronic transitions of cytochrome a upon complex formation. These results could reflect changes in ground state heme structure or changes in the protein environment surrounding the chromophore that affect either the ground or excited electronic states. The resonance Raman spectrum, on the other hand, reflects the heme structure in the ground electronic state only and shows no significant difference between cytochrome a vibrations in the complex or free enzyme. The only major difference between the Raman spectra of the free enzyme and complex is a broadening of the cytochrome a3 formyl band of the complex that is relieved upon complex dissociation at high ionic strength. These data suggest that the differences observed in the second derivative and CD spectra are the result of changes in the protein environment around cytochrome a that affect the electronic excited state. By analogy to other protein-chromophore systems, we suggest that the energy of the Soret pi* state of cytochrome a may be affected by (1) changes in the local dielectric, possibly brought about by movement of a charged amino acid side chain in proximity to the heme group, or (2) pi-pi interactions between the heme and aromatic amino acid residues.     

The mechanism of energy conservation and transduction by mitochondrial cytochrome c oxidase.

Oxidation of ferrocytochrome c by molecular oxygen catalysed by cytochrome c oxidase (cytochrome aa3) is coupled to translocation of H+ ions across the mitochondrial membrane. The proton pump is an intrinsic property of the cytochrome c oxidase complex as revealed by studies with phospholipid vesicles inlayed with the purified enzyme. As the conformation of cytochrome aa3 is specifically sensitive to the electrochemical proton gradient across the mitochondrial membrane, it is likely that redox energy is primarily conserved as a conformational "strain" in the cytochrome aa3 complex, followed by relaxation linked to proton translocation. Similar principles of energy conservation and transduction may apply on other respiratory chain complexes and on mitochondrial ATP synthase.     

Oxidation and reduction of exogenous cytochrome c by the activity of the respiratory chain.

Oxidation of exogenous NADH by isolated rat liver mitochondria is generally accepted to be mediated by endogenous cytochrome c which shuttles electrons from the outer to the inner mitochondrial membrane. More recently it has been suggested that, in the presence of added cytochrome c, NADH oxidation is carried out exclusively by the cytochrome oxidase of broken or damaged mitochondria. Here we show that electrons can be transferred in and out of intact mitochondria. It is proposed that at the contact sites between the inner and the outer membrane, a "bi-trans-membrane" electron transport chain is present. The pathway, consisting of Complex III, NADH-b5 reductase, exogenous cytochrome c and cytochrome oxidase, can channel electrons from the external face of the outer membrane to the matrix face of the inner membrane and viceversa. The activity of the pathway is strictly dependent on both the activity of the respiratory chain and mitochondrion integrity.     

Rate enhancement of the internal electron transfer in cytochrome c oxidase by the formation of a peroxide complex; its implication on the reaction mechanism of cytochrome c oxidase

The oxidation of reduced cytochrome c oxidase by hydrogen peroxide was investigated with stopped-flow methods. It was reported by us previously (A.C.F. Gorren, H. Dekker and R. Wever (1986) Biochim. Biophys. Acta 852, 81-92) that at low H2O2 concentrations cytochrome a is oxidised simultaneously with cytochrome a3, but that at higher H2O2 concentrations the oxidation of cytochrome a is slower than that of cytochrome a3. We now report that for high peroxide concentrations (10-45 mM) the oxidation rate of cytochrome a increased linearly with the concentration of H2O2 (k = 700 M-1.S-1). Upon extrapolation to zero H2O2 concentration an intercept with a value of 16 s-1 (at 20 degrees C and pH 7.4) was found. A reaction sequence is described to explain these results; according to this model the rate constant (16 S-1) at zero H2O2 concentration represents the true value of the rate of electron transfer from cytochrome a to cytochrome a3 when the a3-CuB site is oxidised and unligated. However, when a complex of hydrogen peroxide with oxidised cytochrome a3 is formed, this rate is strongly enhanced. The slope (700 M-1.S-1) would then represent the rate of cytochrome a3(3+)-H2O2 complex formation. From experiments in which the pH was varied, we conclude that the reaction of H2O2 with cytochrome a3(2+) is independent of pH, whereas the electron-transfer rate from cytochrome a to cytochrome a3 gradually decreases with increasing pH. From the temperature dependence we could calculate values of 23 kJ.mol-1 and 45 kJ.mol-1 for the activation energies of the oxidations by H2O2 of cytochrome a3(2+) and cytochrome a2+, respectively. The similarity of the values that were obtained for cytochrome a oxidation both with H2O2 and with O2 as the electron acceptor suggests that the reactions share the same mechanism. In 2H2O the reactions studied decreased in rate. For the reaction of 2H2O2 with reduced cytochrome a3 in 2H2O, a small effect was found (15% decrease in rate constant). However, the internal electron-transfer rate from cytochrome a to cytochrome a3 decreased by 50%, Our results suggest that the internal electron transfer is associated with proton translocation.     

Proton translocation by cytochrome c oxidase in different phases of the catalytic cycle

Since mitochondrial cytochrome c oxidase was found to be a redox-linked proton pump, most enzymes of the haem-copper oxidase family have been shown to share this function. Here, the most recent knowledge of how the individual reactions of the enzyme's catalytic cycle are coupled to proton translocation is reviewed. Two protons each are pumped during the oxidative and reductive halves of the cycle, respectively. An apparent controversy that concerns proton translocation during the reductive half is resolved. If the oxidised enzyme is allowed to relax in the absence of reductant, the binuclear haem-copper centre attains a state that lies outside the main catalytic cycle. Reduction of this form of the enzyme is not linked to proton translocation, but is necessary for a return to the main cycle. This phenomenon might be related to the previously described "pulsed" vs. "resting" and "fast" vs."slow" forms of haem-copper oxidases.