Complexes between uncouplers of oxidative phosphorylation

Summary We have examined the effects of two weak acid uncouplers of oxidative phosphorylation, 2,4-dinitrophenol and 5,6-dichloro-2-trifluoromethyl-benzimidazole, on the electrical properties of phospholipid bilayer membranes. All the effects they produce are consistent with the charged permeant species being a HA ₂ ^– complex formed between the neutral acid HA and its anion A^– and the current in the aqueous phases being carried by buffered hydrogen ions. When both uncouplers are present simultaneously, all the evidence we have obtained is consistent with the charged permeant species being a HAB^– complex formed between the neutral acid HA of one uncoupler and the anion B^– of the other. It was necessary, however, to take into account interfacial processes and the unstirred layers adjacent to the membrane, the adsorption of anions to the bilayer and the buffer level in the aqueous phases to explain the results in terms of this model. The degree to which these factors will complicate a comparison of results obtained on artificial systems and mitochondria is also discussed.     

The binding of uncouplers of oxidative phosphorylation to rat-liver mitochondria

The binding of different uncouplers of oxidative phosphorylation to rat-liver mitochondria was measured. At pH 7.2 and about 0.7 mg mitochondrial protein/ml the percentage bound of the uncoupler added was 84% for 2,3,4,5,6-pentachlorophenol (PCP), 40% for carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP), 35% for 4,5,6,7-tetrachloro-2-trifluoromethylbenzimidazole (TTFB), 4% for α′,α′-bis (hexafluoroacetonyl)acetone (1799), and less than 4% for 2,4-dinitrophenol. These percentages are constant up to amounts of uncoupler added several times the one needed for maximal uncoupling. The values found for FCCP and TTFB are in contradiction to the proposed stoichiometric interaction of uncouplers with the coupling sites of the mitochondrial membrane.From titration experiments of the rate of O₂ uptake by rat-liver mitochondria in State 4 as a function of the uncoupler concentration in the presence of albumin or of different types of liposomes the conclusion is drawn that the negative surface charge of the mitochondrial phospholipids may be an important parameter in determining the binding of anionic uncouplers to rat-liver mitochondria.     

Surface potential and the interaction of weakly acidic uncouplers of oxidative phosphorylation with liposomes and mitochondria

The pH dependence of the binding of weakly acidic uncouplers of oxidative phosphorylation to rat-liver mitochondria and liposomes is mainly determined by the pK_a of the uncoupler molecule.

The absorption and fluorescence excitation spectra of the anionic form of weakly acidic uncouplers of oxidative phosphorylation are red-shifted upon interaction with liposomal or mitochondrial membranes. The affinity for the liposomes, as deduced from the red shift, is independent of the degree of saturation of the fatty acid chains of different lecithins. The intensity of the spectra at one pH value is strongly dependent upon the surface charge of the liposomes. With positively charged liposomes the results obtained can be almost quantitatively explained with the Gouy-Chapman theory, but with negatively charged ones deviations are observed. At a particular pH, the divalent ion Ca²⁺ strongly influences the intensity of the spectra in the presence of negatively charged liposomes, but has no effect with neutral liposomes.

With mitochondrial membranes an effect of Ca²⁺ similar to that with negatively charged liposomes is observed. Depletion of the phospholipids of the mitochondria and subsequent restoration of the mitochondrial membrane with lecithin, strongly diminishes this effect, but restoration with negatively charged phospholipids does not influence it.

From these observations it is concluded that the anionic form of the uncoupler molecule when bound to mitochondria is located within the partly negatively charged phospholipid moiety of the membrane, with its anionic group pointing to the aqueous solution.     

Surface potential and the interaction of weakly acidic uncouplers of oxidative phosphorylation with liposomes and mitochondria.

The pH dependence of the binding of weakly acidic uncouplers of oxidative phosphorylation to rat-liver mitochondria and liposomes is mainly determined by the pKa of the uncoupler molecule. The absorption and fluorescene excitation spectra of the anionic form of weakly acidic uncouplers of oxidative phosphorylation are red-shifted upon interaction with liposomal or mitochondrial membranes. The affinity for the liposomes, as deduced from the red shift, is independent of the degree of saturation of the fatty acid chains of different lecithins. The intensity of the spectra at one pH value is strongly dependent upon the surface charge of the liposomes. With positively charged liposomes the results obtained can be almost quantitatively explained with the Gouy-Chapman theory, but with negatively charged ones deviations are observed. At a particular pH, the divalent ion Ca-2+ stongly influences the intensity of the spectra in the presence of negatively charged liposomes, but has no effect with neutral liposomes. With mitochondrial membranes an effect of Ca-2+ similar to that with negatively charged liposomes is observed. Depletion of the phospholipids of the mitochondria and subsequent restoration of the mitochrondrial membrane with lecithin, strongly diminishes this effect, but restoration with negatively charged phospholipids does not influence it. From these observations it is concluded that the anionic form of the uncoupler molecule when bound to mitochondria is located within the partly negatively charged phospholiped moiety of the membrane, with its anionic group pointing to the aqueous solution.     

Fatty acids as uncouplers of oxidative phosphorylation

This review summarizes data on the uncoupling effect of fatty acids on oxidative phosphorylation in mitochondria of various animal and plant tissues.     

Tissue-specific uncouplers of oxidative phosphorylation in mitochondria from rat heart, kidney, thymus and lung]

The influence of nonmicrosomal cytoplasm fraction from the rat kidney, heart, thymus and lungs on the oxidative phosphorylation of mitochondria (M) of the same tissues and from the ones of the liver and brain was studied. The existence of the tissue-specific uncouplers of the M oxidative phosphorylation was shown in the cross experiments; they were similar to that in the rat liver revealed earlier. A possibility of these regulators participation in the initiation of the M enzymatic degradation process through the activation of phospholipase A when calcium ions leave the M is discussed. The activation under these conditions of the DNA-ase 1, associated with the M membrane, is suggested.     

A correlation between respiration and synthesis of ATP in mitochondria at different degree of uncoupling of oxidative phosphorylation

It is known that mitochondrial respiration in state 3 is due to three simultaneous and independent processes: synthesis of ATP (1), endogenous passive proton leakage (2), and proton leakage by protonophoric uncoupler (3). The total rate of processes (2) and (3) is equal to the product of respiration rate in state 4 and coefficient KR, which is defined as the ratio of the deltamuH+ value in state 3 to that in state 4. It is shown that it is possible to calculate both the rates of processes (1), (2) and (3) separately and the protonophoric activity of uncoupler using the coefficient KR and other coefficients, which are determined as the ratio of deltamuH+ values in state 3 or in state 4 to its maximal value. Simple methods of determination of these coefficients were developed, which are based on the study of the dependence of respiration rate in states 3 and 4 on the concentration of protonophoric uncoupler. It was found that the uncoupling action of palmitate, a natural uncoupler of oxidative phosphorylation, unlike classic uncoupler-protonophores DNP and FCCP, depends not only on its protonophoric activity but also on the inhibition of the process (1).     

The cristal membrane of mitochondria is the principal site of oxidative phosphorylation

The inner membrane system of mitochondria us known to consist of two contiguous but distinct membranes: the inner boundary membrane, which apposes the outer membrane, and the cristal membrane, which forms tubules or lamellae in the interior. Using immunolabeling and transmission electron microscopy of bovine heart tissue, we have calculated that around 94% of both Complex III of the respiratory chain and the ATP synthase are located in the cristal membrane, and only around 6% of either is in the inner boundary membrane. When accounting for the topographical ratio of cristal membrane versus inner boundary membrane, we find that both complexes exist at a 2.2-2.6-fold higher concentration in the cristal membrane. The residual protein in the inner boundary membrane may be newly assembled complexes destined for cristal membranes. Our results argue for restricted diffusion of complexes through the cristal junctions and indicate that the mitochondrial cristae comprise a regulated submitochondrial compartment specialized for ATP production.     

Escherichia coli mutants resistant to uncouplers of oxidative phosphorylation

Two mutant strains of Escherichia coli K 12 Doc-S resistant to the uncoupling agents 4,5,6,7-tetrachloro-2-trifluoromethyl benzimidazole and carbonyl cyanide m-chlorophenylhydrazone were isolated. These strains, designated TUV and CUV, were capable of (a) growth, (b) the transport of succinate and L-proline and (c) electron-transport-linked oxidative synthesis of ATP in the presence of titres of uncoupler which inhibited these processes in strain Doc-S. The inhibition of transport of L-proline by a fixed titre of uncoupler was sharply pH dependent in strain Doc-S: uptake was unaffected at pH 7.6 but completely inhibited at pH 5.6. This pH dependence was not shown by the resistant strains. We believe that uncouplers were equally accessible to their site(s) of action in the energy-conserving membrane of the sensitive and resistant strains. We conclude that uncoupler resistance in these strains of E. coli has arisen as a consequence of mutations which directly affect a specific site of uncoupler action within the cytoplasmic membrane, rather than as a consequence of a decrease in the permeability of cells to uncoupler.