Inhibitors of the ATP/ADP antiporter suppress stimulation of mitochondrial respiration and H+ permeability by palmitate and anionic detergents

The action of ATP/ADP-antiporter inhibitors upon the uncoupling effect of palmitate, detergents and 'classical' uncouplers has been studied. The uncoupling effect was estimated by stimulation of succinate oxidation and of H+ permeability of rat liver mitochondria in the presence of oligomycin. It is shown that carboxyatractylate (CAtr) and pyridoxal 5-phosphate (PLP) suppress the uncoupling induced by palmitate and the anionic detergents SDS and cholate, but do not affect that induced by the cationic detergents CTAB, by the non-ionic detergent Triton X-100, as well as by the 'classical' uncouplers FCCP and DNP. The results are discussed in terms of a concept assuming that the ATP/ADP-antiporter facilitates the electrophoretic export of hydrophobic anions from mitochondria.     

The ATP/ADP-antiporter is involved in the uncoupling effect of fatty acids on mitochondria

The ATP/ADP-antiporter inhibitors and the substrate ADP suppress the uncoupling effect induced by low (10-20 microM) concentrations of palmitate in mitochondria from skeletal muscle and liver. The inhibitors and ADP are found to (a) inhibit the palmitate-stimulated respiration in the controlled state and (b) increase the membrane potential lowered by palmitate. The degree of efficiency decreases in the order: carboxyatractylate (CAtr) greater than ADP greater than bongkrekic acid, atractylate. GDP is ineffective, Mg.ADP is of much smaller effect, whereas ATP is effective at much higher concentration than is ADP. Inhibitor concentrations, which maximally suppress the palmitate-stimulated respiration, correspond to those needed for arresting the state 3 respiration. The extent of the CAtr-sensitive stimulation of respiration by palmitate has been found to decrease with an increase in palmitate concentration. Stimulation of the controlled respiration by p-trifluoromethoxycarbonylcyanide phenylhydrozone (FCCP) and gramicidin D at any concentrations of these uncouplers is CAtr-insensitive, whereas that caused by a low concentrations of 2,4-dinitrophenol and dodecyl sulfate is inhibited by CAtr. The above effect of palmitate develops immediately after addition of the fatty acid. It is resistant to EGTA as well as to inhibitors of phospholipase (nupercain) and of lipid peroxidation (ionol). Moreover, palmitate accelerates spontaneous release of the respiratory control, developing in rat liver mitochondria under certain conditions. This effect takes several minutes, being sensitive to EGTA, nupercain and ionol. Like the fast uncoupling, this slow effect is inhibited by ADP but CAtr and atractylate are stimulatory rather than inhibitory. In artificial planar phospholipid membrane, palmitate does not increase the membrane conductance, FCCP increases it strongly and dinitrophenol only slightly. In cytochrome oxidase proteoliposomes, FCCP, gramicidin and dinitrophenol (less effectively) lower, whereas palmitate enhances the cytochrome-oxidase-generated membrane potential. In this system, monensin substitutes for palmitate. It is concluded that the ATP/ADP antiporter is somehow involved in the uncoupling effect caused by low concentrations of palmitate and, partially, of dinitrophenol, whereas uncoupling produced by FCCP and gramicidin is due to their action on the phospholipid part of the mitochondrial membrane. A possible mechanism of this effect is discussed.     

Carboxyatractylate inhibits the uncoupling effect of free fatty acids

The ATP/ADP-antiporter inhibitors and ADP decrease the palmitate-induced stimulation of the mitochondrial respiration in the controlled state. The degree of inhibition decreases in the order: carboxyatractylate greater than bongkrekic acid, palmitoyl-CoA, ADP greater than atractylate. GDP is ineffective. The inhibiting concentration of carboxyatractylate coincides with this arresting the state 3 respiration. Carboxyatractylate inhibition decreases when the palmitate concentration increases. Stimulation of controlled respiration by FCCP or gramicidin D at any concentration of these uncouplers is carboxyatractylate-resistant, whereas that by low concentrations of DNP is partially suppressed by carboxyatractylate. These data together with observations that palmitate does not increase H+ conductance in bilayer phospholipid membranes and in cytochrome oxidase-asolectin proteoliposomes indicate that the ATP/ADP-antiporter is somehow involved in the uncoupling by low concentrations of fatty acids (or DNP), whereas that by FCCP and gramicidin D is due to their effect on the phospholipid bilayer. It is suggested that the antiporter facilitates translocation of palmitate anion across the mitochondrial membrane.     

Oxidative stress as regulatory factor for fatty-acid-induced uncoupling involving liver mitochondrial ADP/ATP and aspartate/glutamate antiporters of old rats

Palmitate-induced uncoupling, which involves ADP/ATP and aspartate/glutamate antiporters, has been studied in liver mitochondria of old rats (22-26 months) under conditions of lipid peroxidation and inhibition of oxidative stress by antioxidants--thiourea, Trolox, and ionol. It has been shown that in liver mitochondria of old rats in the absence of antioxidants and under conditions of overproduction of conjugated dienes, the protonophoric uncoupling activity of palmitate is not suppressed by either carboxyatractylate or aspartate used separately. However, the combination of carboxyatractylate and aspartate decreased uncoupling activity of palmitate by 81%. In this case, palmitate-induced uncoupling is limited by a stage insensitive to both carboxyatractylate and aspartate. In the presence of antioxidants, the palmitate-induced protonophoric uncoupling activity is suppressed by either carboxyatractylate or aspartate used separately. Under these conditions, palmitate-induced uncoupling is limited by a stage sensitive to carboxyatractylate (ADP/ATP antiporter) or aspartate (aspartate/glutamate antiporter). In the absence of antioxidants, the uncoupling activity of palmitate is not suppressed by ADP either in the absence or in the presence of aspartate. However, in the presence of thiourea, Trolox, or ionol ADP decreased the uncoupling activity of palmitate by 38%. It is concluded that in liver mitochondria of old rats the development of oxidative stress in the presence of physiological substrates of ADP/ATP and aspartate/glutamate antiporters (ADP and aspartate) results in an increase of the protonophoric uncoupling activity of palmitate.     

Acetoacetate as regulator of palmitic acid-induced uncoupling involving liver mitochondrial ADP/ATP antiporter and aspartate/glutamate antiporter

The effect of acetoacetate on palmitate-induced uncoupling with the involvement of ADP/ATP antiporter and aspartate/glutamate antiporter has been studied in liver mitochondria. The incubation of mitochondria with acetoacetate during succinate oxidation in the presence of rotenone, oligomycin, and EGTA suppresses the accumulation of conjugated dienes. This is considered as a display of antioxidant effect of acetoacetate. Under these conditions, acetoacetate does not influence the respiration of mitochondria in the absence or presence of palmitate but eliminates the ability of carboxyatractylate or aspartate separately to suppress the uncoupling effect of this fatty acid. The action of acetoacetate is eliminated by β-hydroxybutyrate or thiourea, but not by the antioxidant Trolox. In the absence of acetoacetate, the palmitate-induced uncoupling is limited by a stage sensitive to carboxyatractylate (ADP/ATP antiporter) or aspartate (aspartate/glutamate antiporter); in its presence, it is limited by a stage insensitive to the effect of these agents. In the presence of Trolox, ADP suppresses the uncoupling action of palmitate to the same degree as carboxyatractylate. Under these conditions, acetoacetate eliminates the recoupling effects of ADP and aspartate, including their joint action. This effect of acetoacetate is eliminated by β-hydroxybutyrate or thiourea. It is supposed that the stimulating effect of acetoacetate is caused both by increase in the rate of transfer of fatty acid anion from the inner monolayer of the membrane to the outer one, which involves the ADP/ATP antiporter and aspartate/glutamate antiporter, and by elimination of the ability of ADP to inhibit this transport. Under conditions of excessive production of reactive oxygen species in mitochondria at a high membrane potential and in the presence of small amounts of fatty acids, such effect of acetoacetate can be considered as one of the mechanisms of antioxidant protection.     

Carboxyatractylate-sensitive uncoupling in liver mitochondria from ground squirrels during hibernation and arousal

Energy coupling parameters of liver mitochondria from hibernating and arousing ground squirrels have been studied. In the oligomycin-treated mitochondria, carboxyatractylate, an inhibitor of the ATP/ADP-antiporter, is shown to decrease the respiration rate, to increase the membrane potential and to lower the rate of the membrane-potential discharge after the addition of cyanide to liver mitochondria from hibernating and arousing animals. BSA effectively substitutes for carboxyactactylate so that carboxyactactylate, added after BSA, has no effect. In mitochondria from hibernating animals, the maximal respiration rate in the presence of DNP and the rate of the membrane potential discharge in its absence are much lower than in those from arousing animals. It has been concluded that upon arousal of the animals from hibernation, the uncoupling of oxidative phosphorylation, mediated by free fatty acids and ATP/ADP-antiporter, parallels the respiratory chain activation.     

Comparative study on uncoupling effects of laurate and lauryl sulfate on rat liver and skeletal muscle mitochondria

Uncoupling effects of laurate and lauryl sulfate have been studied in the isolated rat liver and skeletal muscle mitochondria. In the oligomycin-treated liver mitochondria, 0.02 mM laurate or 0.16 mM lauryl sulfate caused a two-fold stimulation of respiration, accompanied by a membrane potential decrease. Carboxyatractylate (CAtr) and glutamate (or aspartate) strongly decrease the effect of laurate and lauryl sulfate on respiratory rate and membrane potential (the recoupling effect). With both uncouplers, this effect is maximal for CAtr and glutamate (aspartate) at pH 7.8 and 7.0, respectively. Tetraphenyl phosphonium cations, which decrease negative membrane charges, cause an alkaline shift of these pH dependences. Small amounts of lauryl sulfate, which increase the membrane negative charge, induce the opposite shift when laurate is used as an uncoupler. ADP, but not GDP, partially recouple with both laurate and lauryl sulfate. We conclude that lauryl sulfate-induced uncoupling in rat liver, like the uncoupling induced by laurate, is mediated by the ATP/ ADP and glutamate/aspartate antiporters. In skeletal muscle mitochondria uncoupled by laurate, 200 microM GDP causes partial recoupling which can be enhanced by a subsequent additions of CAtr, glutamate and serum albumin. CAtr added before GDP promotes a larger recoupling than when added after GDP and prevents the subsequent effect of GDP. ADP is effective as recoupler at lower concentrations that GDP, whereas CDP is without influence. Lauryl sulfate uncoupling of skeletal muscle mitochondria is GDP-resistant but is sensitive to ADP, CAtr, glutamate and serum albumin. Our data suggest that in skeletal muscle mitochondria a GDP-sensitive mechanism is involved in uncoupling induced by laurate. This mechanism is absent in liver mitochondria. Possible mechanisms of laurate and lauryl sulfate-induced uncoupling are discussed.     

Participation of ATP/ADP antiporter in oleate- and oleate hydroperoxide-induced uncoupling suppressed by GDP and carboxyatractylate

In experiments on isolated kidney and liver mitochondria, it is shown that oleate hydroperoxide induces a much smaller increase in the controlled respiration rate and DeltaPsi decrease than the same concentrations of oleate. Palmitate appears to be less efficient than oleate but more efficient than oleate hydroperoxide. In all cases, GDP and CAtr cause some recoupling, CAtr being more effective. Addition of 0.2 mM GDP before CAtr does not prevent further DeltaPsi increase by subsequent CAtr addition. On the other hand, GDP added after CAtr is without any effect. GDP partially prevents the DeltaPsi lowering by ADP at the State 4--State 3 transition if small amounts of CAtr are present. The data are consistent with the suggestion of F. Goglia and V.P. Skulachev (FASEB J. 17, 1585-1591, 2003) that fatty acid anions are translocated by mitochondrial anion carriers much better than their hydroperoxides. As to GDP recoupling, it cannot be regarded as a specific probe for uncoupling by UCPs since it can be mediated by the ATP/ADP antiporter.     

Uncoupling effect of lauryl sulfate on mitochondria can be mediated by release of bound endogenous fatty acids

The mechanism of uncoupling by lauryl sulfate (LS) has been studied. The very fact that uncoupling by low concentration of LS (a strong acid) resembles very much that by fatty acids (weak acids) was used as an argument against the fatty acid cycling scheme of uncoupling where protonated fatty acids operate as a protonophore. We have found that rat liver and heart muscle mitochondria can be uncoupled by low (70 microM) LS concentration in a fashion completely arrested by the ATP/ADP antiporter inhibitor carboxyatractylate (CAtr). On the other hand, uncoupling by two-fold higher LS concentration is not sensitive to CAtr. Addition of oleate desensitizes mitochondria to low LS so that addition of bovine serum albumin becomes necessary to recouple mitochondria. The data are accounted for assuming that low LS releases endogenous fatty acids from some mitochondrial depots, and these fatty acids are responsible for uncoupling. As to high LS, it causes a nonspecific (CAtr-insensitive) damage to the mitochondrial membrane.     

Involvement of phosphate carrier as a part of complex with ADP/ATP and aspartate/glutamate antiporters in palmitic acid-induced uncoupling in liver mitochondria

In liver mitochondria, the phosphate carrier is involved in protonophoric uncoupling effect of fatty acids together with ADP/ATP and aspartate/glutamate antiporters (Samartsev et al. 2003. Biochemistry (Moscow). 68, 618–629). Liver mitochondria depleted of endogenous oxidation substrates (exhausted mitochondria) have been used in the present work. In these mitochondria, like in the intact liver mitochondria, the specific inhibitor of ADP/ATP antiporter (carboxyatractylate) and the substrate of aspartate/glutamate antiporter (aspartate) suppress the uncoupling activity of palmitic acid. It is shown that in exhausted mitochondria the substrate of phosphate carrier (inorganic phosphate) and its nonspecific inhibitor mersalyl partially suppress palmitic acid-induced uncoupling due to decrease in the component of uncoupling activity sensitive to carboxyatractylate and aspartate. In the presence of inorganic phosphate or mersalyl, carboxyatractylate and aspartate added separately subsequent to palmitic acid do not suppress its uncoupling activity. They are effective only when added jointly. In the presence of thiourea or pyruvate, such effects of inorganic phosphate and mersalyl are not observed. It is supposed that in the presence of inorganic phosphate or mersalyl and under the condition of oxidation of critical SH-groups in mitochondria, the phosphate carrier, ADP/ATP antiporter, and aspartate/glutamate antiporter are involved in uncoupling function together with the general fatty acid pool as an uncoupling complex. The role of phosphate carrier in this complex may consist in facilitation of lateral transfer of the fatty acid molecules from one antiporter to another.     

Uncoupling of oxidative phosphorylation by fatty acids and detergents suppressed by ATP/ADP antiporter inhibitors

The effects of ATP/ADP-antiporter inhibitors on the uncoupling of oxidative phosphorylation by palmitic acid, detergents and protonophore FCCP in liver mitochondria were studied. The uncoupling activity of these compounds was estimated by their stimulating effect on succinate oxidation and H+ conductivity of the inner mitochondrial membrane in the presence of oligomycin. Carboxyatractylate and pyridoxal 5-phosphate suppressed the uncoupling effects of palmitic acid and anionic detergents but had no effect on the uncoupling action of the nonionic detergent Triton X-100, the cationic detergent CTAB and FCCP. The data obtained are discussed in terms of the putative role of the ATP/ADP-antiporter in the electrophoretic transport of hydrophobic anions from the mitochondria.     

Dihydrolipoic acid activates oligomycin-sensitive thiol groups and increases ATP synthesis in mitochondria.

Investigations with dihydrolipoic acid in rat heart mitochondria and mitoplasts reveal an activation of ATP-synthase up to 45%, whereas ATPase activities decrease by 36%. In parallel with an increase in ATP synthesis oligomycin-sensitive mitochondrial -SH groups are activated at 2-4 nmol dihydrolipoic acid/mg protein. ATPase activation by the uncouplers carbonylcyanide-p-trifluoromethoxyphenylhydrazone and oleate is diminished by dihydrolipoic acid, and ATP synthesis depressed by oleate is partially restored. No such efficiency of dihydrolipoic acid is seen with palmitate-induced ATPase activation or decrease of ATP synthesis. This indicates different interference of oleate and palmitate with mitochondria. In addition to its known coenzymatic properties dihydrolipoic acid may act as a substitute for coenzyme A, thereby diminishing the uncoupling efficiency of oleate. Furthermore, dihydrolipoic acid is a very potent antioxidant, shifting the -SH-S-S- equilibrium in mitochondria to the reduced state and improving the energetic state of cells.     

Participation of the ATP/ADP antiporter and fatty acids in oxidative phosphorylation uncoupling in squirrel liver mitochondria during winter hibernation and awakening]

The parameters of energy coupling of mitochondria isolated from the livers of hibernating and awakening gophers were studied. The ATP/ADP-antiporter inhibitor carboxyatractylate slowed down the respiration rate, increased delta psi and decreased the ionic conductivity of the inner mitochondrial membrane as measured by the rate of the delta psi decline after addition of cyanide (in the presence of oligomycin and EGTA). A similar effect was produced by BSA, carboxyatractylate being fairly ineffective in the presence of BSA. In hibernating gophers the maximal rate of the uncoupled respiration and the ionic conductivity of the inner mitochondrial membrane were markedly decreased as compared with awakening gophers. The data obtained suggest that in awakening animals fatty acids induce the uncoupling of oxidative phosphorylation by the ATP/ADP-antiporter, this process being simultaneous with the activation of the respiratory chain.     

Effect of ethanol on the palmitate-induced uncoupling of oxidative phosphorylation in liver mitochondria

The effect of ethanol on the uncoupling activity of palmitate and recoupling activities of carboxyatractylate and glutamate was studied in liver mitochondria at various Mg²⁺ concentrations and medium pH values (7.0, 7.4, and 7.8). Ethanol taken at concentration of 0.25 M had no effect on the uncoupling activity of palmitic acid in the presence of 2 mM MgCl₂ and decreased the recoupling effects of carboxyatractylate and glutamate added to mitochondria either just before or after the fatty acid. However, ethanol did not modify the overall recoupling effect of carboxyatractylate and glutamate taken in combination. The effect of ethanol decreased as medium pH was decreased to 7.0. Elevated concentration of Mg²⁺ (up to 8 mM) inhibits the uncoupling effect of palmitate. Ethanol eliminates substantially the recoupling effect of Mg²⁺ under these conditions, but does not influence the recoupling effects of carboxyatractylate and glutamate. It is inferred that ADP/ATP and aspartate/glutamate antiporters are involved in uncoupling function as single uncoupling complex with the common fatty acid pool. Fatty acid molecules gain the ability to migrate under the action of ethanol: from ADP/ATP antiporter to aspartate/glutamate antiporter on addition of carboxyatractylate and in opposite direction on addition of glutamate. Possible mechanisms of fatty acid translocation from one transporter to another are discussed.     

Mitochondrial porin regulates the sensitivity of anion carriers to inhibitors

In mitoplasts, respiratory stimulation by ADP, palmitate, DNP and CCCP and sensitivity of respiration to carboxyatractylate are considerably less pronounced than in mitochondria. Addition of porin-containing preparations (purified outer membranes or solubilized mitochondrial porin) to mitoplasts results in partial restoration of the oxygen consumption and sensitivity to carboxyatractylate (CAT). The uncoupling effect of FCCP in mitoplasts is CAT-resistant and does not depend on added porin. It is suggested that mitochondrial porin may be a natural activator of ADP/ATP antiporter and succinate carrier in mitochondria.     

Use of an adenosine triphosphate analog, adenylyl imidodiphosphate, to evaluate adenosine triphosphate-dependent reactions in mitochondria.

Adenylyl imidodiphosphate (AMP-PNP), an analog of adenosine triphosphate (ATP), was found to be an effective inhibitor of adenine nucleotide translocation in rat liver mitochondria. Inhibition by AMP-PNP was shown to be competitive with ATP. Therefore, studies designed to evaluate the interaction of ATP with mitochondrial adenosine triphosphatase (ATPase) in the presence of AMP-PNP were carried out on submitochondrial particles which lack a membrane barrier between the enzyme and the test medium. The effect of AMP-PNP on the ATP-driven reversed electron transfer reaction in sonically prepared submitochondrial particles was further examined by using oligomycin to induce coupling. The ATPase of oligomycin treated particles did not show significantly different sensitivity to AMP-PNP. Submitochondrial particles which were sensitive to AMP-PNP were less efficient in driving energy-coupled reactions. Results from these studies indicate that uncoupling in mitochondria is not only due to a leaky membrane but may also result from an altered membrane-ATPase association.     

Role of the ADP/ATP-antiporter in fatty acid-induced uncoupling of Ca2+-loaded rat liver mitochondria

We show that Ca2+ loading of mitochondria substantially augments the myristate-induced decrease in the transmembrane electric potential difference (deltapsi). Such a Ca2+ action is without effect on the respiration rate and is not accompanied by the high-amplitude swelling when low concentrations of Ca2+ and myristate are used. The myristate-induced deltapsi decrease is prevented and reversed by cyclosporin A (CsA); the decrease is prevented and transiently reversed by nigericin. To explain these effects, we suggest that myristate induces opening of the mitochondrial permeability transition pore at a low-conductance state. Addition of carboxyatractylate (CAtr) after myristate induces the CsA-sensitive uncoupling, but when added after myristate and CsA, CAtr produces a decrease in deltapsi, if the interval between myristate and CsA addition is sufficiently long. The CAtr effect is completely reversed by EGTA and transiently reversed by nigericin. This suggests that the ADP/ATP-antiporter participates in the CsA-sensitive uncoupling when present as a pore complex constituent. ADP/ATP-antiporter that does not take part in the pore complex formation is involved in the CsA-insensitive uncoupling.     

Temperature dependence of rat liver mitochondrial respiration with uncoupling of oxidative phosphorylation by fatty acids. Influence of inorganic phosphate

The respiration rate of liver mitochondria in the course of succinate oxidation depends on temperature in the presence of palmitate more strongly than in its absence (in state 4). In the Arrhenius plot, the temperature dependence of the palmitate-induced stimulation of respiration has a bend at 22°C which is characterized by transition of the activation energy from 120 to 60 kJ/mol. However, a similar dependence of respiration in state 4 is linear over the whole temperature range and corresponds to the activation energy of 17 kJ/mol. Phosphate partially inhibits the uncoupling effect of palmitate. This effect of phosphate is increased on decrease in temperature. In the presence of phosphate the temperature dependence in the Arrhenius plot also has a bend at 22°C, and the activation energy increases from 128 to 208 kJ/mol in the range from 13 to 22°C and from 56 to 67 kJ/mol in the range from 22 to 37°C. Mersalyl (10 nmol/mg protein), an inhibitor of the phosphate carrier, similarly to phosphate, suppresses the uncoupling effect of laurate, and the effects of mersalyl and phosphate are not additive. The recoupling effects of phosphate and mersalyl seem to show involvement of the phosphate carrier in the uncoupling effect of fatty acids in liver mitochondria. Possible mechanisms of involvement of the phosphate carrier in the uncoupling effect of fatty acids are discussed.     

Adenine nucleotide and phosphate transport systems of mitochondria. Relative location of sulfhydryl groups based on the use of the novel fluorescent probe eosin-5-maleimide

Eosin-5-maleimide is impermeable to the inner mitochondrial membrane, exhibiting essentially no reactivity with matrix glutathione or with beta-hydroxybutyrate dehydrogenase located on the matrix surface of the inner membrane. In intact mitochondria, eosin-5-maleimide is unreactive with the ADP/ATP antiporter even under conditions which promote maximal labeling by N-[3H]ethylmaleimide (i.e., ADP present). However, eosin-5-maleimide readily labels the ADP/ATP antiporter in "inverted" inner membrane vesicles even in the presence of N-ethylmaleimide. Labeling is prevented if the vesicles are prepared from mitochondria pretreated with carboxyatractyloside. In contrast to the ADP/ATP antiporter, essential sulfhydryl groups of the Pi/H+ symporter are accessible to eosin-5-maleimide in intact mitochondria with optimal inhibition of phosphate transport being observed at 25 degrees C. Eosin-5-maleimide also prevents labeling of the Pi/H+ symporter by N-[3H]ethylmaleimide. These results show that essential sulfhydryl groups of the ADP/ATP antiporter and the Pi/H+ symporter have differing reactivities and locations in functionally intact mitochondria. With respect to eosin-5-maleimide, sulfhydryl groups of the ADP/ATP carrier occur in two distinct classes, both of which are inaccessible in intact mitochondria. Only one class, depending on conditions, can be exposed in submitochondrial particles. In contrast, sulfhydryl group(s) of the Pi/H+ symporter behave as a single reactive class which is readily accessible in mitochondria at 25 degrees C.     

Proton translocation in membranes of submitochondrial particles]

Effect of an electrophilous inhibitor, chlorophenacyl, on energy-dependent functions of submitochondrial particles is studied. Chlorophenacyl at concentrations up to 1 mM is found practically not to affect the generation of membrane potential under NADH and succinate oxidation and ATP hydrolysis and to be a strong inhibitor of oxidative phosphorylation and reverse electron transport. The mechanism of the inhibition of energy-dependent functions of submitochondrial particles with chlorophenacyl is different from that of electron transport inhibitor, energy transport inhibitors and classical uncoupling agents--protonophors. The data obtained are suggested to be due to the existence of two ways of proton translocation in submitochondrial particle membrane, phosphorylating and non-phosphorylating, the effect of chlorophenacyl being directed on phosphorylating way only.