Effect of membrane potential and pH gradient on electron transfer in cytochrome oxidase

Steady-state spectra of cytochrome oxidase in phospholipid vesicles were obtained by using hexaammineruthenium(II) and ascorbate as reductants. Cytochrome a was up to 80% reduced in the steady state in coupled vesicles. Upon addition of nigericin or acetate, which decrease delta pH, resulting in an increase in delta psi, cytochrome a became more oxidized in the steady state with no change in the rate of respiration. On the other hand, uncouplers or valinomycin plus nigericin, which lower both delta psi and delta pH, stimulated respiration 2-8-fold and also lowered the steady-state level of reduction of cytochrome a. These experiments indicate that electron transfer between cytochromes a and a 3 is sensitive primarily to the pH gradient. Studies with the reconstituted and the soluble enzyme at various pH values indicated that the pH on the matrix side of the membrane, rather than delta pH, controlled the steady-state level of reduced cytochrome a. Hexaammineruthenium(II) substituted for cytochrome c in measurements of proton pumping by cytochrome oxidase. Dicyclohexylcarbodiimide, which eliminated proton pumping by cytochrome oxidase, decreased the effect of ionophores on the steady-state level of reduced cytochrome a.     

Control of proteoliposomal cytochrome c oxidase: the overall reaction

The control of cytochrome c oxidase incorporated into proteoliposomes has been investigated as a function of membrane potential (delta psi) and pH gradient (delta pH). The oxidase generates a pH gradient (alkaline inside) and a membrane potential (negative inside) when respiring on external cytochrome c. Low levels of valinomycin collapse delta psi and increase delta pH; the respiration rate decreases. High levels of valinomycin, however, decrease delta pH as valinomycin can also act as a protonophore. Nigericin (in the absence of valinomycin) increases delta psi and collapses delta pH; the respiration rate increases. On a millivolt equivalent basis delta pH is a more effective inhibitor of activity than is delta psi. In the absence of any ionophores the cytochrome oxidase proteoliposomes enter a steady state, in which there are both delta pH and delta psi components of control. Present and previous data suggest that the respiration rate responds in a linear way ("ohmically") to increasing delta pH but in a nonlinear way to delta psi ("non-ohmically"). High levels of both delta psi and delta pH do not completely inhibit turnover (maximal respiratory control values lie between 6 and 10). The controlled steady state involves the electrophoretic entry and electroneutral exit of K+ from the vesicles. A model is presented in which the enzyme responds to both delta pH and delta psi components of the proton-motive force, but is more sensitive to delta pH than to delta psi at an equivalent delta mu H+. The steady state of the proteoliposome system can be represented for any set of permeabilities and enzyme activity levels using the computer simulation programme Stella.     

Independent control of respiration in cytochrome c oxidase vesicles by pH and electrical gradients

The effects of altering the pH and electrical components of the membrane potential on the visible spectra and oxygen consumption rates of cytochrome oxidase vesicles were examined during steady-state respiration using cytochrome c as the substrate. Heme a was found to be 30-55% reduced in the presence of a membrane potential, becoming more reduced when the electrical gradient (delta psi) was abolished by valinomycin and more oxidized when the pH gradient (delta pH) was abolished by nigericin, with little increase (1.2-1.8-fold) in the rates of oxygen consumption in either case. When both gradients were eliminated, heme a reduction was close to initial levels, and activity was stimulated up to 8-fold. The magnitude of the changes in heme a reduction levels upon elimination of a gradient component was shown to be positively correlated with the magnitude of the respiratory control ratio of the vesicle preparation. Kinetic analysis of the dependence of oxidase activity on cytochrome c concentration indicated that changes in the Michaelis constant of the enzyme for its substrate are not a major factor in regulation by either delta pH or delta psi. These results suggest a dual mechanism for respiratory control in cytochrome oxidase vesicles under steady-state conditions, in which the electrical gradient predominantly affects electron transfer from cytochrome c to heme a, possibly by altering the reduction potential of heme a, while the pH gradient affects electron transfer from heme a (CuA) to heme a3 (CuB), possibly by a conformationally mediated change in the reduction potential of heme a3 or in the kinetics of the electron-transfer process.     

The proteoliposomal steady state. Effect of size, capacitance and membrane permeability on cytochrome-oxidase-induced ion gradients.

1. The flux pathways for H+ and K+ movements into and out of proteoliposomes incorporating cytochrome c oxidase have been investigated as a function of the electrical and geometrical properties of the vesicles. 2. The respiration-induced pH gradient (delta pH) and membrane potential (delta psi) are mutually dependent and individually sensitive to the permeability properties of the membrane. A lowering or abolition of delta psi by the addition of valinomycin increased the steady-state level of delta pH. Conversely, removal of delta pH by the addition of nigericin resulted in a higher steady-state delta psi. 3. Vesicles prepared by sonication followed by centrifugation maintained similar pH gradients at steady state to those in vesicles prepared by dialysis, although the time taken to reach steady state was longer. Higher pH gradients can be induced in non-centrifuged sonicated preparations. 4. No significant differences were found in H+ and K+ permeability between proteoliposomes prepared by dialysis or by sonication. The permeability coefficient of the vesicle bilayers for H+ was 6.1 x 10(-4) cm.s-1 and that for K+ was 7.5 x 10(-10) cm.s-1. An initial fast change in internal pH was seen on the addition of external acid or alkali, followed by a slower, ionophore-sensitive, change. The initial fast phase can be increased by the lipid-soluble base dibucaine and the weak acid oleate. In the absence of ionophores, increasing concentrations of oleate increased the rate of H+ translocation to a level similar to that seen in the presence of nigericin. Internal alkalinization could also be induced by oleate upon the addition of potassium sulphate. 5. The initial, pre-steady-state and steady-state delta pH and delta psi changes can be simulated using a model in which the enzyme responds to both delta pH and delta psi components of the protonmotive force. At steady state, the electrogenic entry of K+ is countered by electroneutral exit via a K+/H+ exchange. 6. The permeability coefficient, PH, calculated from H+ flux under steady-state turnover conditions, was approx. 100 times higher than the corresponding 'passive' measurements of PH. Under conditions of oxidase turnover, the vesicles appear to be intrinsically more permeable to protons.     

Kinetic characterization of cytochrome c oxidase from Bacillus subtilis

Bacillus subtilis aa3-type cytochrome c oxidase is capable of oxidizing cytochrome c from different origins. The kinetic properties of the enzyme are influenced by ionic strength. The affinity for Saccharomyces cerevisiae cytochrome c declines with increasing ionic strength whereas the Vmax remains almost constant. An increase of Vmax is observed when the enzyme is incorporated in artificial membranes. Negatively charged phospholipids allow high turnover rates of the aa3-type oxidase. The effect of ionic strength on oxidation of horse heart cytochrome c results in significant changes of both Km and Vmax. These effects can be explained by disturbances of enzyme-substrate interactions and are not related to changes in the aggregation state of the enzyme. The respiration control index of the enzyme reconstituted in artificial membranes appeared to be dependent on phospholipid composition, protein/lipid ratios and also on the external pH. The action of the ionophores nigericin and valinomycin, at various pH values, on the enzyme activity and proton-permeability measurements of the membranes indicate that both components of the proton-motive force, the membrane potential and the pH gradient, can in principle regulate enzyme activity in the reconstituted state.     

Cation transport in cytochrome oxidase reconstituted vesicles.

Cation translocation across the membrane of cytochrome oxidase reconstituted vesicles may be followed with a simple spectrophotometric method. Cytochrome oxidase reconstituted vesicles, supplemented with ascorbate and cytochrome c. induce large spectral changes of the positive dye safranine, reversed by uncouplers and inhibitors of respiration. The dye is probably accumulated in the inner space of the vesicles, where it reaches high concentrations and aggregates. The spectral shifts and the absorbance changes, due to aggregation, are proportional to the amount of the dye taken up and depend on the respiratory control. In the presence of potassium, valinomycin causes an inhibition, whereas nigericin stimulates the dye uptake. The data are discussed in terms of electrical potential dependent fluxes.     

The dioxygen cycle. Spectral, kinetic, and thermodynamic characteristics of ferryl and peroxy intermediates observed by reversal of the cytochrome oxidase reaction.

The catalytic mechanism of O2 reduction by cytochrome oxidase was studied in isolated mitochondria and mitoplasts by partial reversal of the reaction. At a high redox potential (Eh) of cytochrome c, high pH, and a high electrochemical proton gradient (delta mu H+) across the inner mitochondrial membrane, the initial ferriccupric state (O) of the oxidized enzyme's bimetallic oxygen reaction center is converted to ferryl (F) and peroxy (P) intermediates, the optical spectroscopic properties of which are reported in detail. This is associated with reversed electron transfer from the bimetallic center to ferricytochrome c. The kinetics of reduction of ferricytochrome c by the reversed electron transfer process are compared with the kinetics of formation of F and P. The results are consistent with transfer of one electron from the ferric-cupric bimetallic center (O) to cytochrome c, yielding the F intermediate, followed by transfer of one electron from the latter to cytochrome c, yielding the P state. In the absence of an effective redox buffer, poising cytochrome c highly oxidized, these primary events are immediately followed by reoxidation of cytochrome c, which is ascribed to forward electron transfer to enzyme molecules still in the O state. This forward reaction also results in accumulation of the P intermediate. Kinetic stimulations of the data predict equilibrium constants for the reversed electron transfer steps, and Em,7 values of approximately 1.1 and 1.2 V may be calculated for the F/O and P/F redox couples, respectively, at delta mu H+ and delta psi equal to zero. Taken together with previously measured Em,7 values, these data indicate that it is the two-electron reduction of bound dioxygen to bound peroxide that is responsible for the irreversibility of the catalytic dioxygen cycle of cell respiration.     

Protonmotive functions of cytochrome c oxidase in reconstituted vesicles. Influence of turnover rate on 'proton translocation'.

1. Oxidation of ferrocytochrome c by cytochrome c oxidase incorporated into proteoliposomes induces a transient acidification of the external medium. This change is dependent on the presence of valinomycin and can be abolished by carbonyl cyanide p-trifluoromethoxyphenylhydrazone or by nigericin. The H+/e- ratio for the initial acidification varies with the internal buffering capacity of the vesicles, and under suitable conditions approaches + 1, the pulse slowly decaying to give a net alkalinity change with H+/e- value approaching -1. 2. Inhibition of cytochrome c oxidase turnover by ferricytochrome c or by azide addition results in ferrocytochrome c-dependent H+ pulses with decreasing H+/e- ratios. The rate of the initial H+ production remains higher than the rate of equilibration of the pH gradient, indicating an intrinsic dependence of the H+/e- ratio on enzyme turnover. The final net alkalinity changes are relatively unaffected by turnover inhibition.     

New control of mitochondrial membrane potential and ROS formation--a hypothesis

A new control of mitochondrial membrane potential delta(psi)m and formation of reactive oxygen species (ROS) is presented, based on allosteric ATP-inhibition of cytochrome c oxidase at high intramitochondrial ATP/ADP ratios. Since the rate of ATP synthesis by the ATP synthase is already maximal at low membrane potentials (100-120 mV), the ATP/ADP ratio will also be maximal at this delta(psi)m (at constant rate of ATP consumption). Therefore the control of respiration by the ATP/ADP-ratio keeps delta(psi)m low. In contrast, the known 'respiratory control' leads to an inhibition of respiration only at high delta(psi)m values (150-200 mV) which cause ROS formation. ATP-inhibition of cytochrome c oxidase is switched on and off by reversible phosphorylation (via cAMP and calcium, respectively). We propose that 'stress hormones' which increase intracellular [Ca2+] also increase delta(psi)m and ROS formation, which promote degenerative diseases and accelerate aging.     

Redox-linked proton translocation in the b-c1 complex from beef-heart mitochondria reconstituted into phospholipid vesicles. General characteristics and control of electron flow by delta micro H+

A study is presented of the characteristics of redox-linked proton translocation in the b-c1 complex isolated from beef-heart mitochondria and reconstituted into phospholipid vesicles. Measurements of the H+/e- stoichiometry, with three different methods, show that four protons are released from the vesicles per 2e- flowing from quinols to cytochrome c, two of these protons formally deriving from scalar oxidation of quinols by cytochrome c. This H+/e- stoicheiometry is independent of the initial redox state of the b-c1 complex (fully reduced or oxidized) and the rate of electron flow through the complex. It does not change in the pH range 6.0 - 7.2, but declines to 1.5 going with pH from 7.2 - 8.3. This decrease is accompanied by enhancement of the rate of electron flow in the coupled state. Collapse of delta psi effected by valinomycin addition to turning-over b-c1 vesicles resulted in substantial oxidation of cytochrome b-566 and comparable reduction of cytochrome c1, with little oxidation of cytochrome b-562. Nigericin alone had no effect on the steady-state redox levels of b and c cytochromes. Its addition in the presence of valinomycin caused oxidation of b cytochromes but no change in the redox state of cytochrome c1. Valinomycin alone caused a marked enhancement of the rate of electron flow through the complex. Nigericin alone was ineffective, but caused further stimulation of electron flow when added in the presence of valinomycin. The data presented are discussed in terms of two mechanisms: the Q cycle and a model based on combination of protonmotive catalysis by special bound quinone and proton conduction along pathways in the apoproteins.     

Variations in the oxidation-reduction behavior of liganded species of Pseudomonas cytochrome oxidase

In an effort to determine the steady-state redox properties of Pseudomonas aeruginosa cytochrome cd1, changes in absorption spectra after the addition of excess reductant (ascorbate, ferrous ethylenediaminetetraacetic acid) were monitored for degassed unliganded enzyme and samples in the presence of CO and CN- at pH 6.0, 8.0, or 10.0. Plots of [c2+]/[c3+] vs. [d2+]/[d3+] indicate that a "pseudoequilibrium" was reached for all samples at pH 8.0. Calculated values of delta Ed-c, the difference in reduction potential between the heme c and heme d moieties, at pH 8.0 were -25 +/- 5 (unliganded), -10 +/- 5 (enzyme-CO), and -25 +/- 5 mV (enzyme-CN). Relative rates of heme c and heme d reduction were found to be dependent upon type of ligand, reductant, and pH. Evidence for a cooperative heme c-heme d interaction is discussed.     

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.     

Paradoxical effects of methylmercury on the kinetics of cytochrome c oxidase

A stoichiometric amount of methylmercuric chloride substantially inhibits cytochrome c oxidase function under steady-state turnover conditions, where the enzyme is using its substrates, cytochrome c and oxygen, rapidly and continuously. Under these conditions, a reduction in activity of approximately 40% is observed. This is in accord with the results of Mann and Auer [Mann, A.J., & Auer, H.E. (1980) J. Biol. Chem. 255, 454-458], who used mercuric chloride and ethylmercuric chloride. Paradoxically, we found that addition of methylmercuric chloride can increase the activity of cytochrome c oxidase during its initial substrate utilization. This rate enhancement, measured under conditions where the enzyme cycles only a few times, is maximal for the resting state of the enzyme. "Pulsed" cytochrome c oxidase (i.e., enzyme that has been recently reduced and reoxidized) is considerably activated with respect to the resting enzyme, showing faster turnover rates (Antonini, 1977; Brunori et al., 1979). No significant rate enhancement upon treatment with methylmercuric chloride is seen in initial substrate utilization if the enzyme is pulsed immediately before the assay. The apparently contradictory effects of methylmercuric chloride on the resting and pulsed states of the oxidase under low turnover conditions may be reconciled by a model in which mercurial binding greatly stabilizes the enzyme in a state resembling that of the pulsed enzyme. A decrease in conformational flexibility may be the basis of the mercurial-induced diminution in activity of the enzyme during steady-state turnover conditions.     

Routes of electron transfer in beef heart cytochrome c oxidase: is there a unique pathway used by all reductants?

Cytochrome c oxidase oxidizes several hydrogen donors, including TMPD (N,N,N',N'-tetramethyl-p-phenyl-enediamine) and DMPT (2-amino-6,7-dimethyl-5,6,7,8-tetrahydropterine), in the absence of the physiological substrate cytochrome c. Maximal enzyme turnovers with TMPD and DMPT alone are rather less than with cytochrome c, but much greater than previously reported if extrapolated to high reductant levels and (or) to 100% reduction of cytochrome a in the steady state. The presence of cytochrome c is, therefore, not necessary for substantial intramolecular electron transfer to occur in the oxidase. A direct bimolecular reduction of cytochrome a by TMPD is sufficient to account for the turnover of the enzyme. CuA may not be an essential component of the TMPD oxidase pathway. DMPT oxidation seems to occur more rapidly than the DMPT--cytochrome a reduction rate and may therefore imply mediation of CuA. Both "resting" and "pulsed" oxidases contain rapid-turnover and slow-turnover species, as determined by aerobic steady-state reduction of cytochrome a by TMPD. Only the "rapid" fraction (approximately 70% of the total with resting and approximately 85% of the total with pulsed) is involved in turnover. We conclude that electron transfer to the a3CuB binuclear centre can occur either from cytochrome a or CuA, depending upon the redox state of the binuclear centre. Under steady-state conditions, cytochrome a and CuA may not always be in rapid equilibrium. Rapid enzyme turnover by either natural or artificial substrates may require reduction of both and two pathways of electron transfer to the a3CuB centre.     

Formation of pH and potential gradients by the reconstituted Azotobacter vinelandii cytochrome bd respiratory protection oxidase.

To directly characterize the bioenergetic properties of the cytochrome bd terminating branch of the Azotobacter vinelandii electron transport chain, the purified cytochrome bd oxidase was reconstituted into a phospholipid environment consisting of phosphatidylethanolamine and phosphatidylglycerol (3:1). The average diameter of the proteoliposomes after extrusion through a polycarbonate membrane was 94 +/- 4 nm. Initiation of respiration upon the addition of 20 microM ubiquinone-1 to proteoliposomes loaded with the pH-sensitive dye pyranine resulted in an immediate alkalization of the vesicle lumen by an average pH change of 0.11 unit. This pH gradient was readily collapsed upon the addition of nigericin, carbonyl cyanide p-(tri-fluoromethoxy) phenyl-hydrazone, gramicidin, Triton X-100, or 2-heptyl-4-hydroxyquinoline N-oxide (HQNO). Proteoliposomal respiration initiated in the presence of the potentiometric membrane dye rhodamine 123 caused the generation of a transmembrane potential; the potential was collapsed upon the addition of either valinomycin or HQNO. The formation of both pH and potential gradients during turnover demonstrates that the A. vinelandii cytochrome bd oxidase is coupled to energy conservation in vivo.     

The control of electron flux through cytochrome oxidase.

1. The electron flux through cytochrome oxidase is a linear function of the net thermodynamic force across the complex over a limited range of conditions. 2. Over a wide range of conditions the electron flux is a complicated function of the percentage reduction of the cytochrome c pool and of delta psi (at low values of delta pH). 3. We have estimated the elasticities of electron flux through cytochrome oxidase to delta Eh of the redox reaction catalysed by cytochrome oxidase (or to cyt c2+/cyt c3+) and to delta psi. The elasticities varied depending on the values of delta psi and of the percentage reduction of the cytochrome c pool. 4. At intermediate rates (which may correspond to those in vivo) the electron flux through cytochrome oxidase is controlled to about the same extent by delta psi and by delta Eh.     

Respiratory control in cytochrome oxidase

Vesicles of cytochrome oxidase, generated by dilution of the oxidase with a 15-fold excess of lipid by the Hinkle-Racker method, showed a respiratory control index of greater than 5 in presence of the combination of valinomycin and nigericin. Uncouplers were found to be ineffective in releasing respiratory control in the absence of valinomycin. Valinomycin titration in the presence of excess nigericin gave approximately a one to one stoichiometry with cytochrome oxidase. We propose that coupling of electron transfer to valinomycin K⁺ transport in cytochrome oxidase vesicles is a molecular event; the insensitivity of respiratory control to uncouplers is a consequence of the absence of the systems other than cytochrome oxidase which are required for the action of uncouplers.     

Effects of triorganotin-mediated anion-hydroxide exchange upon reconstituted cytochrome c oxidase proteoliposomes

Proteoliposomes containing cytochrome c oxidase and an internally trapped fluorescent pH probe (pyranine) were used to monitor respiration-dependent internal alkalinization and membrane potential formation. A maximum steady-state pH gradient of about 0.4 pH unit (vesicle interior alkaline) was obtained during active respiration in presence of reducing substrates and cytochrome c. This pH gradient was abolished by the triorganotin compounds tripropyl-, tributyl-, and triphenyl-tin chloride. At the same time, the membrane potential, measured by carbocyanine dye uptake, was slightly increased in value. Valinomycin, which abolishes the membrane potential, restores the value of delta pH at low trialkyltin concentrations. The organotin compounds acted as electroneutral ionophores which exchanged intravesicular OH- ions with external SCN-, I-, and CI- ions, but not NO3- or SO4(2-) ions. Abolition of delta pH is accompanied by an increase in respiration rate, but full respiratory stimulation only occurs when both delta psi and delta pH are abolished by addition of both triorganotin and valinomycin. The triorganotin-valinomycin combination leads to active KCl accumulation by the respiring proteoliposome, and it is necessary to postulate an electrically neutral KCl efflux process to explain the continued steady respiration of the proteoliposomes in the presence of this ionophore combination.     

The effect of energization on the apparent Michaelis–Menten constant for oxyge in nmitochondrial respiration

Lineweaver-Burk plots of 1/v against 1/[O(2)] for rat liver mitochondrial respiration with succinate or ascorbate+NNN'N'-tetramethyl-p-phenylenediamine as substrates are non-linear. In state 3u (uncoupled by trifluoromethoxycarbonyl cyanide phenylhydrazone) such plots tend to be concave upward, whereas in state 4 (energized) the plots were concave downward. The apparent K(m) for oxygen is larger in state 4 than in state 3u, despite the higher turnover in the latter system. It is postulated that at least one reversible reaction occurs between cytochrome c and cytochrome c oxidase, whose rate is increased on energization (reversed electron transfer); a model including such a reaction is proposed which accounts semiquantitatively for the observations.     

Control of electron transfer in the cytochrome system of mitochondria by pH, transmembrane pH gradient and electrical potential. The cytochromes b-c segment.

1. A study is presented of the effects of pH, transmembrane pH gradient and electrical potential on oxidoreductions of b and c cytochromes in ox heart mitochondria and 'inside-out' submitochondrial particles. 2. Kinetic analysis shows that, in mitochondria at neutral pH, there is a restraint on the aerobic oxidation of cytochrome b566 with respect to cytochrome b562. Valinomycin plus K+ accelerates cytochrome b566 oxidation and retards net oxidation of cytochrome b562. At alkaline pH the rate of cytochrome b566 oxidation approaches that of cytochrome b562 and the effects of valinomycin on b cytochromes are impaired. 3. At slightly acidic pH, oxygenation of antimycin-supplemented mitochondria causes rapid reduction of cytochrome b566 and small delayed reduction of cytochrome b562. Valinomycin or a pH increase in the medium promote reduction of cytochrome b562 and decrease net reduction of cytochrome b566. 4. Addition of valinomycin to mitochondria and submitochondrial particles in the respiring steady state causes, at pH values around neutrality, preferential oxidation of cytochrome b566 with respect to cytochrome b562. The differential effect of valinomycin on oxidation of cytochromes b566 and b562 is enhanced by substitution of 1H2O of the medium with 2H2O and tends to disappear as the pH of the medium is raised to alkaline values. 5. Nigericin addition in the aerobic steady state causes, both in mitochondria and submitochondrial particles, preferential oxidation of cytochrome b562 with respect to cytochrome b566. This is accompanied by c cytochrome oxidation in mitochondria but c cytochrome reduction in submitochondrial particles. 6. In mitochondria as well as in submitochondrial particles, the aerobic transmembrane potential (delta psi) does not change by raising the pH of the external medium from neutrality to alkalinity. The transmembrane pH gradient (delta pH) on the other hand, decrease slightly. 7. The results presented provide evidence that the delta psi component of the aerobic delta microH+ (the sum of the proton chemical and electrical activities) exerts a pH-dependent constraint on forward electron flow from cytochrome b566 to cytochrome b562. This effect is explained as a consequence of anisotropic location of cytochromes b566 and b562 in the membrane and the pH-dependence of the redox function of these cytochromes. Transmembrane delta pH, on the other hand, exerts control on electron flow from cytochrome b562 to c cytochromes.