The mechanism of inhibition by oligomycin of oxidative phosphorylation in mitochondria

1. The concentration of specific oligomycin-binding sites in rat-liver mitochondria is 0.12 nmole/mg protein, whereas at least 10-times more oligomycin can be bound non-specifically.

2. The activity of oligomycin-inhibited processes in intact mitochondria and submitochondrial particles cannot be restored by treatment with egg lecithin or mitochondrial phospholipids.

3. Analysis of the kinetics of inhibition of State-3 respiration by oligomycin reveals that (i) after a certain lag period the inhibition by oligomycin is pseudo-first order with respect to the respiratory-control ratio, defined as the ratio of the respiratory rate at time t to that of the final inhibited site, (ii) the value of the pseudo-first-order rate constant (k₀) is dependent on the oligomycin: protein ratio, phospholipid: protein ratio, pH and temperature, (iii) the effects of various substrates and inhibitors of electron transfer on the kinetics of oligomycin inhibition can be explained by their effects on respiratory control.

4. A detailed model is proposed for the interaction of oligomycin with mitochondria. It is proposed that two conformations of the oligomycin-sensitive site are present, and that oligomycin specifically binds to the conformation that is involved in the induction of respiratory control.     

Pyridoxalphosphate-modified derivatives of cytochrome c. Mono- and disubstituted derivatives: characteristics and effect on electron transport in cytochrome c-depleted mitochondria

Cytochrome c is modified by covalent binding of pyridoxal phosphate (PLP) to lysine residues. One di-substituted [(PLP)2--C] and two mono-substituted derivatives [(PLP)--c and (PLP)'--c] were obtained and precisely purified. The peak at 695 nm and CD-spectra in 190--600 nm region show that all derivatives have native conformation. The differential UV-spectra of the derivatives against native protein show that in (PLP)2--c there is a contact dipole-dipole interaction between PLP chromophores. It is calculated that the N-atoms of the two PLP-substituted lysines must be at a distance less than or equal to 12 A. Analysing our and literature data, one may suppose that Lys-13 and Lys-87 are the most probable candidates for modification with PLP. (PLP)---c and (PLP)'--c behave differently during ion-exchange chromatography and when added to cytochrom c-depleted mitochondria. (PLP)'--c restores electron transfer at higher concentrations than (PLP)'--c. Both they restore fully succinate and ascorbate oxidation but at considerably higher concentrations than the native protein, i. e. modification of any one of the reactive towards PLP lysines descreases but does not exclude the interaction with its reductase and oxidase. The effective equilibrium constants of binding of modified derivatives to cytochrome c-depleted mitochondria are lower than the constant for native protein. Together with decrease in binding activity, Hill coefficients increase. From our results it may be supposed that probably the binding sites of cytochrome c for its reductase and oxidase partially overlap.     

Steady-state redox behavior of cytochrome c, cytochrome a, and CuA of cytochrome c oxidase in intact rat liver mitochondria.

We have examined the steady-state redox behavior of cytochrome c (Fec), Fea, and CuA of cytochrome c oxidase during steady-state turnover in intact rat liver mitochondria under coupled and uncoupled conditions. Ascorbate was used as the reductant and TMPD (N,N,N',N'-tetramethyl-1,4-phenylenediamine) as the redox mediator. After elimination of spectroscopic interference from the oxidized form of TMPD, we found that Fea remains significantly more oxidized than previously thought. During coupled turnover, CuA always appears to be close to redox equilibrium with Fec. By increasing the amount of TMPD, both centers can be driven to fairly high levels of reduction while Fea remains relatively oxidized. The reduction level at Fea is close to a linear function of the enzyme turnover rate, but the levels at Fec and CuA do not keep pace with enzyme turnover. This behavior can be explained in terms of a redox equilibrium among Fec, CuA, and Fea, where Fea is the electron donor to the oxygen reduction site, but only if Fea has an effective Em (redox midpoint potential) of 195 mV. This is too low to be accounted for on the basis of nonturnover measurements and the effects of the membrane potential. However, if there is no equilibrium, the internal CuA----Fea electron-transfer rate constant must be slow in the time average (about 200 s-1). Other factors which might contribute to such a low Em are discussed. In the presence of uncoupler, this situation changes dramatically. Both Fec and CuA are much less reduced; within the resolution of our measurements (about 10%), we were unable to measure any reduction of CuA. Fea and CuA remain too oxidized to be in redox equilibrium with Fec during steady-state turnover. Furthermore, our results indicate that, in the uncoupled system, the (time-averaged) internal electron-transfer rate constants in cytochrome oxidase must be of the order of 2500 s-1 or higher. When turnover is slowed by azide, the relative redox levels at Fea and Fec are much closer to those predicted from nonturnover measurements. In presence of uncouplers, Fea is always more reduced than Fec, but in the absence of uncouplers, the two centers track together. Unlike the uninhibited, coupled system, the redox behavior here is consistent with the known effect of the electrical membrane potential on electron distribution in the enzyme. Interestingly, in these circumstances (azide and uncoupler present), Fea behaves as if it were no longer the kinetically controlling electron donor to the bimetallic center.     

Effect of enzyme deficiencies on oxidative phosphorylation: from isolated mitochondria to intact tissues. Theoretical studies

The present article briefly summarizes the theoretical studies made by the authors and co-workers on the effect of inborn enzyme deficiencies on oxidative phosphorylation in intact tissues and on the genesis of mitochondrial diseases. The dynamic computer model of oxidative phosphorylation developed previously allowed to extrapolate experimental data (especially: threshold curves describing the dependence of oxygen consumption and ATP turnover on activities/concentrations of particular oxidative phosphorylation enzymes) obtained for isolated muscle mitochondria in state 3 at saturating oxygen concentrations to more physiological conditions prevailing in intact tissues. In particular, theoretical studies demonstrated that the threshold value of the relative activity/concentration of a given mitochondrial complex, below which a significant decrease in the respiration rate takes place, increases with an increase in energy demand. This fact was proposed as a possible explanation of the tissue specificity of mitochondrial diseases. Additionally, a decreased oxygen concentration was shown to increase the threshold value (and flux control coefficient) for cytochrome oxidase. We subsequently developed a model called binary mitochondria heteroplasmy, in which there are only two subpopulations of mitochondria: one wild-type and one containing only defected molecules of a given enzyme. In this model we show that a defect has a pronounced effect on oxidative phosphorylation, significantly increasing the threshold value. It was also proposed that a parallel activation in the ATP supply-demand system during an increased energy demand significantly lessens the effect of enzyme deficiencies on oxidative phosphorylation (decreases the threshold value). Finally, the necessity of substrate activation may lead to an instability in the system and to appearance of a second threshold, below which respiration suddenly drops to zero, which is equivalent to the energetic death of a cell.     

Sidedness of inhibition of energy transduction in oxidative phosphorylation in rat liver mitochondria by ethidium bromide.

Ethidium bromide, a new type of inhibitor of energy transduction in oxidative phosphorylation, inhibited ATP synthesis in intact mitochondria but not in submitochondrial particles, the latter being inside-out relative to the membranes of intact mitochondria. Ethidium bromide incorporated inside the submitochondrial particles inhibited ATP synthesis in the particles. The decrease of the membrane potential by valinomycin (plus KCl) inhibited only slightly the energy-dependent binding of ethidium bromide to the mitochondria. The present results show clearly that ethidium bromide inhibited energy transduction in oxidative phosphorylation by acting on the outer side (C-side) of the inner mitochondrial membrane, perhaps by neutralizing negative charges created on the surface of the C-side, and that it had no inhibitory activity on the inner side (M-side) of the membrane. Th present results show also that the energy-dependent binding of ethidium is not due to electrophoretic transport down the membrane potential; ethidium may bind to negative charges on the surface of the C-side. The present study suggest that an anisotropic distribution of electric charge in the inner mitochondrial membrane is an intermediary high energy state of oxidatvie phosphorylation.     

Regulation of the oxidative phosphorylation rate in the intact cell

The mechanisms that underlie the balance between the consumption and oxidative generation of ATP in the intact cell are not well-defined. Cytosolic inorganic phosphate (Pi) and ADP levels, the cytosolic ATP/ADP ratio, and the cytosolic phosphorylation potential (PP) have all been proposed as major regulatory variables, the latter as a component of a "near-equilibrium" thermodynamic regulatory scheme. Therefore, the potential regulatory roles of these variables in the intact cell were evaluated with 31P NMR and Langendorff perfused rat hearts; in this preparation, the tissue oxygen consumption rate (MVO2) can be varied over a wide range. When the exogenous carbon source was varied, none of the proposed regulatory parameters, i.e., the ATP/ADP ratio, PP, or cytosolic ADP level, were found to be uniquely related to MVO2. Rather, ADP levels at a given MVO2 decreased progressively for the exogenous carbon sources in the following order: glucose, glucose + insulin, palmitate + glucose, lactate, pyruvate + glucose, and octanoate + glucose. In the octanoate and pyruvate groups, MVO2(-1) was linearly dependent upon [ADP]-1 with apparent Km values being in the range previously observed in isolated mitochondria. A similar trend was observed in the MVO2-[Pi] relationship. The present findings suggest that exogenous carbon sources which effectuate deregulation of intramitochondrial NADH generation lower cytosolic ADP and Pi to levels which are limiting to the rate of oxidative phosphorylation. For other carbon sources, the processes controlling the rate of NADH generation also participate in determining the rate of oxidative ATP synthesis. However, this control must be exerted kinetically rather than through a near-equilibrium thermodynamic mechanism as indicated by the present data and prior kinetic studies of the ATP synthetic process in both isolated mitochondria and intact myocardium [La Noue, K. F., et al. (1986) Biochemistry 25, 7667-7675; Kingsley-Hickman, P., et al. (1987) Biochemistry 26, 7501-7510].     

Binding of cytochrome c to cytochrome c-oxidase in intact mitochondria. A study with radioactive photoaffinity-labeled cytochrome c

[³H]-p-Azidophenacylbromide-(methyl-4-mercaptobutyrimidate)-cytochrome $\text{c}$ from $\text{Saccharomyces cerevisiae}$ was prepared and its properties determined. The radioactive photoaffinity-labeled cytochrome $\text{c}$ was linked by irradiation into a covalent complex with cytochrome $\text{c}$ oxidase. Analysis of the complex on SDS-polyacrylamide gels showed that cytochrome $\text{c}$ bound to one of the smaller subunits of cytochrome $\text{c}$ oxidase with an apparent molecular weight of 15,000.     

Effect of pH on the redox state of cytochrome a in anaerobic, ATP-treated intact mitochondria.

Addition of ATP to anaerobic, glutamate-reduced coupled mitochondria from rat liver or heart caused oxidation of cytochrome a having a peak at 608 nm. Subsequent increase in pH from 7.0 to 8.4 reversed the effect of ATP and subsequent decrease in pH from 8.4 to 7.0 induced reoxidation. This reversible effect of pH on the redox state of cytochrome a may reflect an electrochemical event in the energy-conserving mechanism of the terminal coupling site.     

On the mechanism of action of alkylguanidines on oxidative phosphorylation in mitochondria.

The effect of octylguanidine and oligomycin on the oxygen uptake of rat liver mitochondria and on the ATPase activity of "sonic" submitochondrial particles has been studied. 1. Octylguanidine inhibits state 3 respiration with glutamate-malate and succinate as substrates, but much lower concentrations are required to inhibit oxygen uptake with the former substrates. State 4 respiration is unaffected by octylguanidine. 2. The titration-curve for the octylguanidine inhibition of glutamate-malate oxidation is hyperbolic and apparently biphasic, half-maximal inhibition is obtained at 30 muM octylguanidine. The octylguanidine-curve for inhibition of succinate oxidation is sigmoid with half-maximal inhibition at about 250 muM. 3. Octylguanidine and oligomycin show additive inhibitory action on state 3 respiration with both glutamate plus malage and succinate as respiratory substrates. 4. Concentrations of oligomycin or octylguanidine, which added separately are ineffective on state 3 respiration, become inhibitory when the two inhibitors are added together. 5. Octylguanidine inhibits the ATPase activity of sonic submitochondrial particles with a hyperbolic titration-curve analogous to that obtained for oligomycin inhibition. The inhibitory actions of octylguanidine and oligomycin on the ATPase activity are additive. 6. It is concluded that octylguanidine acts directly on the ATPase complex and that its binding at the action site is mutually exclusive with the binding of oligomycin. A kinetic explanation is given for the reported higher sensitivity of site I phosphorylation to octylguanidine.