High membrane potential promotes alkenal-induced mitochondrial uncoupling and influences adenine nucleotide translocase conformation

Mitochondria generate reactive oxygen species, whose downstream lipid peroxidation products, such as 4-hydroxynonenal, induce uncoupling of oxidative phosphorylation by increasing proton leak through mitochondrial inner membrane proteins such as the uncoupling proteins and adenine nucleotide translocase. Using mitochondria from rat liver, which lack uncoupling proteins, in the present study we show that energization (specifically, high membrane potential) is required for 4-hydroxynonenal to activate proton conductance mediated by adenine nucleotide translocase. Prolonging the time at high membrane potential promotes greater uncoupling. 4-Hydroxynonenal-induced uncoupling via adenine nucleotide translocase is prevented but not readily reversed by addition of carboxyatractylate, suggesting a permanent change (such as adduct formation) that renders the translocase leaky to protons. In contrast with the irreversibility of proton conductance, carboxyatractylate added after 4-hydroxynonenal still inhibits nucleotide translocation, implying that the proton conductance and nucleotide translocation pathways are different. We propose a model to relate adenine nucleotide translocase conformation to proton conductance in the presence or absence of 4-hydroxynonenal and/or carboxyatractylate.     

Effects of atractyloside and palmitoyl coenzyme A on calcium transport in cardiac mitochondria.

Palmitoyl CoA (PCoA) and the adenine translocase inhibitor atractyloside (ATR) appear to produce a similar effect in discharging accumulated calcium from cardiac mitochondria. Although mitochondrial respiration is stimulated upon addition of either PCoA or ATR to preparations preloaded with calcium, the effect is not the same as that produced by classical uncouplers. PCoA and ATR also do not interfere with respiration-supported calcium uptake by mitochondria. The presence of exogenous ATP can prevent the calcium discharging effects of PCoA or ATR. Carnitine will prevent the PCoA calcium discharging effect, but has no effect on ATR-induced discharge. It is suggested the PCoA may act at a site on or near the adenine translocase, perhaps through allosteric interaction, to produce an efflux of calcium from mitochondria. The results also suggest that the internal adenine nucleotide pool plays a significant role in mitochondrial calcium retention.     

Unique action of a modified weakly acidic uncoupler without an acidic group, methylated SF 6847, as an inhibitor of oxidative phosphorylation with no uncoupling activity: possible identity of uncoupler binding protein

The potent weakly acidic uncoupler SF 6847 was modified by methylation of its phenolic OH group, and the effect of the resulting derivative, with no acid-dissociable group, on oxidative phosphorylation in rat liver mitochondria was examined. The methylated SF 6847 did not induce uncoupling at up to 40 microM, while SF 6847 uncoupled oxidative phosphorylation completely at about 20 nM, indicating that the acid-dissociable group is essential for uncoupling. The O-methylated SF 6847 at 20 microM did, however, inhibit state 3 respiration of mitochondria, although it did not inhibit electron-flow through the respiratory chain, ATPase activated by weakly acidic uncouplers or Pi-ATP exchange. At the same concentration, it also inhibited ATP synthesis in submitochondrial particles. These features are different from those of known inhibitors of oxidative phosphorylation. Thus, O-methylated SF 6847 is a unique inhibitor of oxidative phosphorylation. The possible identity of the uncoupler binding protein is discussed on the basis of these results.     

Energization-dependent endogenous activation of proton conductance in skeletal muscle mitochondria

Leak of protons into the mitochondrial matrix during substrate oxidation partially uncouples electron transport from phosphorylation of ADP, but the functions and source of basal and inducible proton leak in vivo remain controversial. In the present study we describe an endogenous activation of proton conductance in mitochondria isolated from rat and mouse skeletal muscle following addition of respiratory substrate. This endogenous activation increased with time, required a high membrane potential and was diminished by high concentrations of serum albumin. Inhibition of this endogenous activation by GDP [classically considered specific for UCPs (uncoupling proteins)], carboxyatractylate and bongkrekate (considered specific for the adenine nucleotide translocase) was examined in skeletal muscle mitochondria from wild-type and Ucp3-knockout mice. Proton conductance through endogenously activated UCP3 was calculated as the difference in leak between mitochondria from wild-type and Ucp3-knockout mice, and was found to be inhibited by carboxyatractylate and bongkrekate, but not GDP. Proton conductance in mitochondria from Ucp3-knockout mice was strongly inhibited by carboxyatractylate, bongkrekate and partially by GDP. We conclude the following: (i) at high protonmotive force, an endogenously generated activator stimulates proton conductance catalysed partly by UCP3 and partly by the adenine nucleotide translocase; (ii) GDP is not a specific inhibitor of UCP3, but also inhibits proton translocation by the adenine nucleotide translocase; and (iii) the inhibition of UCP3 by carboxyatractylate and bongkrekate is likely to be indirect, acting through the adenine nucleotide translocase.     

In vitro alteration of the size of the liver mitochondrial adenine nucleotide pool: Correlation with respiratory functions

Mitochondrial respiration was studied as a function of the total adenine nucleotide content of rat liver mitochondria. The adenine nucleotide content was varied by treating isolated mitochondria with pyrophosphate or by incubating pyrophosphate-treated mitochondria with ATP. Mitochondria with at least 4 nmol adenine nucleotides/mg protein maintained at least 80% of the State 3 activity of control mitochondria, which had approximately 10 nmol/mg protein. However, State 3 decreased rapidly once the adenine nucleotide content fell below 4 nmol/mg protein. Between 2 and 4 nmol adenine nucleotides/mg, State 3 was not limited by the maximal capacity of electron flow as measured by the uncoupled respiration. However, at very low adenine nucleotide levels (<2 nmol/mg), the uncoupled rates of respiration were markedly depressed. State 4 was not affected by changes in the mitochondrial adenine nucleotide content. Adenine translocase activity varied in almost direct correlation with changes in the adenine nucleotide content. Therefore, adenine translocase activity was more sensitive than State 3 to changes in total adenine nucleotides over the range of 4 to 10 nmol/mg protein. The results suggest that (i) State 3 is dependent on the level of intramitochondrial adenine nucleotides, particularly in the range below 4 nmol/mg protein, (ii) adenine translocase activity is not rate-limiting for oxidative phosphorylation in mitochondria with the normal complement of adenine nucleotides, however, at low adenine nucleotide levels, depressed State 3 rates may be explained in part by the low rate of ADP translocation, and (iii) a mechanism of net ATP uptake exists in mitochondria with low internal adenine nucleotides.     

Uncoupling activities of chalcones and dihydrochalcones on isolated mitochondria from potato tubers and mung bean hypocotyls

The uncoupling properties of 23 chalcones and dihydrochalcones were studied. Twelve compounds completely uncouple oxidative phosphorylation in mung bean hypocotyl and potato tuber mitochondria, four are weak uncouplers and seven are without effect. Usually, mung bean mitochondria are more sensitive to uncoupling agents than potato mitochondria. The uncoupling activity of chalcones and dihydrochalcones appears to be connected with the presence of hydrogen or hydroxyl groups in the 2′-position and hydrogen, hydroxyl or nitrate groups in the 4′-position. The α-β-unsaturated carbonyl system is not essential for activity. For the compounds which are not very lipophilic, substituents on the B-ring are without effect on the uncoupling properties. Phloretin appears to be an active uncoupler; its 6′-glucoside is without effect.     

The effect of calcium on the translocation of adenine nucleotides in rat liver mitochondria.

The effect of Ca²⁺ on the adenine nucleotide translocase activity of intact rat liver mitochondria has been studied. The results indicate that in mitochondria which have been allowed to accumulate Ca²⁺, the activity of the translocase is strongly diminished; half-maximal inhibition is attained when approximately 40 nmol of Ca²⁺ are accumulated/mg of mitochondrial protein. Inhibition of electron transport or uncoupling prevents the Ca²⁺-induced inhibition of translocase activity; inhibition of Ca²⁺ uptake by ruthenium red also prevents the inhibition of the exchange. These experiments indicate that internal, but not external Ca²⁺ is responsible for the inhibition of adenine nucleotide translocase activity. Inhibition of the exchange activity by Ca²⁺ occurs even in conditions in which external adenine nucleotide concentrations are rate-limiting.     

Energy conservation and uncoupling in mitochondria

Energy conservation and uncoupling in mitochondria are examined in the light of three important new findings: (a) Studies with the photoaffinity-labeling uncoupler 2-azido-4-nitrophenol have shown that mitochondria contain a specific uncoupler binding site (apparently a polypeptide of M_r = 30,000 ± 10%). (b) This site fractionates into an enzyme complex (complex V), which is capable of oligomycin- and uncoupler-sensitive ATP-Pi exchange. It is absent from electron transfer complexes I, III, and IV, which represent segments of the respiratory chain containing coupling sites 1, 2, and 3, respectively. (c) Trinitrophenol is a membrane-impermeable uncoupler (uncouples submitochondrial particles, but not mitochondria) and a poor protonophore. There is an excellent correlation between the uncoupling potencies and the affinities of uncouplers for the mitochondrial uncoupler-binding site. There is no correlation between uncoupling potency and protonophoric activity of uncouplers when a membrane-permeable uncoupler is compared with a membrane-impermeable one.     

Possible role of adenine nucleotide transport in regulating the respiration of rat liver mitochondria]

Studies with liver mitochondria from rats which starved for 48 hours showed the rate of ADP-stimulated respiration to be 20% lower than in the presence of an uncoupler. This effect was eliminated by preincubation of mitochondria with carnitine. Mitochondria from fed rats were characterized by a considerable decrease of states 3 and 4 respiration. In this case carnitine produced no effect. Preincubation of mitochondria from the liver of fed rats with alpha-ketoglutarate resulted in a substantial increase of the states 3 and 4 respiratory rates. There proved to exist at least two types of regulation of adenine nucleotide transport through the inner mitochondrial membrane depending on the metabolic state of the organism, i.e. by inhibition of adenine-nucleotide translocase by cytoplasmic acyl-CoAs and by control of intramitochondrial adenine nucleotide pool.     

Changes in interfacial potentials induced by carbonylcyanide phenylhydrazone uncouplers: possible role in inhibition of mitochondrial oxygen consumption and other transport processes

The charged and uncharged forms of carbonylcyanide phenylhydrazone uncouplers bind to phosphatidylcholine monolayers in a dose-dependent fashion, inducing changes in the interfacial potential of these model membranes. The interfacial potential change produced by the charged uncoupler is composed of a double-layer potential and an internal electrostatic potential (boundary and/or dipole). Changes in double-layer potential induced by the uncouplers in mitochondrial membranes can explain both the inhibition of oxygen consumption (QO2) caused by the uncouplers and the competition shown by succinate when mitochondria are respiring in the presence of rotenone. From these results and from dose-response curves of QO2 versus uncoupler concentrations, we conclude that 1 microM is an upper limit for free uncoupler concentration in the medium to avoid unwanted side effects during cell physiology studies that require total mitochondrial uncoupling.     

Mechanism of uncoupling by uncouples of oxidative phosphorylation

Classical uncouplers duplicate exactly the uncoupling actions of the valinomycin-nigericin ionophoric combination in presence of K⁺ — a combination that mediates cyclical transport of K⁺ driven by electron transfer or pyrophosphorolysis of ATP in mitochondria. Evidence has been presented that uncouplers have the properties essential for mediating coupled cyclical transport of cations and that uncoupling of oxidative phosphorylation can be rationalized in terms of one coupled process being displaced and replaced by another. The critical demonstrations were first that uncoupling is a cation-dependent process and that only those cations that can undergo complexation with uncouplers are effective in restoring mitochondrial uncoupler action in a cation-deficient medium. The second demonstration was that uncouplers are ionophores, not only of the nigericin type but also of the valinomycin type (electrogenic). This combination in one molecule of electrogenic as well as non-electrogenic ionophoric activity for cations endows uncouplers with the capability for duplicating the uncoupling action of the valinomycin-nigericin combination and for mediating coupled cyclical transport of cations.     

A short-chain alkyl derivative of Rhodamine 19 acts as a mild uncoupler of mitochondria and a neuroprotector

Limited uncoupling of oxidative phosphorylation is known to be beneficial in various laboratory models of diseases. The search for cationic uncouplers is promising as their protonophorous effect is self-limiting because these uncouplers lower membrane potential which is the driving force for their accumulation in mitochondria. In this work, the penetrating cation Rhodamine 19 butyl ester (C₄R1) was found to decrease membrane potential and to stimulate respiration of mitochondria, appearing to be a stronger uncoupler than its more hydrophobic analog Rhodamine 19 dodecyl ester (C₁₂R1). Surprisingly, C₁₂R1 increased H⁺ conductance of artificial bilayer lipid membranes or induced mitochondria swelling in potassium acetate with valinomycin at concentrations lower than C₄R1. This paradox might be explained by involvement of mitochondrial proteins in the uncoupling action of C₄R1. In experiments with HeLa cells, C₄R1 rapidly and selectively accumulated in mitochondria and stimulated oligomycin-sensitive respiration as a mild uncoupler. C₄R1 was effective in preventing oxidative stress induced by brain ischemia and reperfusion in rats: it suppressed stroke-induced brain swelling and prevented the decline in neurological status more effectively than C₁₂R1. Thus, C₄R1 seems to be a promising example of a mild uncoupler efficient in treatment of brain pathologies related to oxidative stress.     

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.     

Relationship between the systems of activation of fatty acids and ademine nucleotide translocase in the mitochondria]

Experiments were conducted on freshly isolated rat liver mitochondria and mitochondria subjected to ageing by two different methods. It was shown that the work of the mitochondrial system of fatty acid activation could lead to inhibition of the adenine nucleotide transport through the internal mitochondrial membrane. Inhibition of adenine nucleotide translocase was eliminated by preincubation of mitochondria with carnitine. The presence in the mitochondrial preparations of fatty acids in the concentration adequate for induction of inhibition of addition of CoA and ATP served as a preculiarity of adenine nucleotide translocase inhibition of the ageing mitochondria. The data obtained permitted to make a supposition on the participation of acyl-CoA formed by the mitochondrial acyl-CoA-synthetase in the regulation of adenine nucleotide transport into the mitochondria.     

Uncoupler-inhibitor titrations of ATP-driven reverse electron transfer in bovine submitochondrial particles provide evidence for direct interaction between ATPase and NADH:Q oxidoreductase

From the chemiosmotic hypothesis it follows that no change is expected in potency of an uncoupler to inhibit an energy-driven reaction in an energy-transducing membrane if the energy-requiring part of the reaction, the so-called secondary proton pump, is partially inhibited by a specific, tightly bound inhibitor. An increase in potency upon inhibition of the primary pump may be expected, due to a lower rate of the total proton flow that can be used by the secondary pump and dissipated by the uncoupler. Contrary to this prediction several uncouplers (S13, SF6847, 2,4-dinitrophenol, valinomycin + nigericin) show an increase in uncoupling efficiency in ATP-driven reverse electron transfer (reversal) upon inhibition of the secondary pump in this reaction, the NADH:Q oxidoreductase, by rotenone. The increase in uncoupling efficiency is proportional to the decrease in the rate of reversal, that is to the decrease in concentration of active secondary pump. Similarly, upon inhibition of the primary pump, the ATPase, with oligomycin, an increase in uncoupling efficiency was found, also proportional to the decrease in the rate of reversal. When the pore-forming uncoupler gramicidin was used, no change in uncoupling potency was found upon inhibition of NADH:Q oxidoreductase. Inhibition of the ATPase, however, resulted in a proportionally lower uncoupling titre for gramicidin, just as was found for S13 in the presence of oligomycin. A difference was also found in the relative concentrations of S13 and gramicidin required to stimulate ATP hydrolysis or to inhibit reversal. The amount of S13 needed to stimulate ATP hydrolysis was clearly higher than the amount needed to inhibit reversal. On the contrary, the titre of gramicidin for both actions was about the same. To explain these results we propose that gramicidin uncouples via dissipation of the bulk delta mu H+, whereas the carrier-type uncouplers preferentially interfere with the direct energy transduction between the ATPase and redox enzymes. This is in accordance with the recently developed collision hypothesis.     

Stimulation of mitochondrial proton conductance by hydroxynonenal requires a high membrane potential

Mild uncoupling of oxidative phosphorylation, caused by a leak of protons back into the matrix, limits mitochondrial production of ROS (reactive oxygen species). This proton leak can be induced by the lipid peroxidation products of ROS, such as HNE (4-hydroxynonenal). HNE activates uncoupling proteins (UCP1, UCP2 and UCP3) and ANT (adenine nucleotide translocase), thereby providing a negative feedback loop. The mechanism of activation and the conditions necessary to induce uncoupling by HNE are unclear. We have found that activation of proton leak by HNE in rat and mouse skeletal muscle mitochondria is dependent on incubation with respiratory substrate. In the presence of HNE, mitochondria energized with succinate became progressively more leaky to protons over time compared with mitochondria in the absence of either HNE or succinate. Energized mitochondria must attain a high membrane potential to allow HNE to activate uncoupling: a drop of 10-20 mV from the resting value is sufficient to blunt induction of proton leak by HNE. Uncoupling occurs through UCP3 (11%), ANT (64%) and other pathways (25%). Our findings have shown that exogenous HNE only activates uncoupling at high membrane potential. These results suggest that both endogenous HNE production and high membrane potential are required before mild uncoupling will be triggered to attenuate mitochondrial ROS production.     

Crystal violet as an uncoupler of oxidative phosphorylation in rat liver mitochondria

Crystal violet exhibited characteristics of an uncoupler of oxidative phosphorylation, i.e. it released respiratory control, hindered ATP synthesis, enhanced ATPase activity, and produced swelling of isolated rat liver mitochondria. Maximal stimulation of respiration, ATPase activity, and swelling was observed at a concentration of 40 microM. The inhibition of State 3 respiration by oligomycin was released by crystal violet. High concentrations of crystal violet inhibited mitochondrial respiration. The uncoupling effect of crystal violet required inorganic phosphate and was abolished by N-ethylmaleimide. The adenine nucleotides ADP and ATP protected mitochondria from uncoupling by the dye. The dye taken up by mitochondria was released into the incubation medium on induction of uncoupling. In the absence of phosphate, the dye did not cause uncoupling, but its retention was much greater than in the presence of phosphate. Crystal violet is suggested to induce uncoupling by acting on the membrane, rather than by its electrophoretic transfer into the mitochondria.     

N-terminally glutamate-substituted analogue of gramicidin a as protonophore and selective mitochondrial uncoupler

Limited uncoupling of oxidative phosphorylation could be beneficial for cells by preventing excessive generation of reactive oxygen species. Typical uncouplers are weak organic acids capable of permeating across membranes with a narrow gap between efficacy and toxicity. Aimed at designing a nontoxic uncoupler, the protonatable amino acid residue Glu was substituted for Val at the N-terminus of the pentadecapeptide gramicidin A (gA). The modified peptide [Glu1]gA exhibited high uncoupling activity in isolated mitochondria, in particular, abolishing membrane potential at the inner mitochondrial membrane with the same or even larger efficacy as gA. With mitochondria in cell culture, the depolarizing activity of [Glu1]gA was observed at concentrations by an order of magnitude lower than those of gA. On the contrary, [Glu1]gA was much less potent in forming proton channels in planar lipid bilayers than gA. Remarkably, at uncoupling concentrations, [Glu1]gA did not alter cell morphology and was nontoxic in MTT test, in contrast to gA showing high toxicity. The difference in the behavior of [Glu1]gA and gA in natural and artificial membranes could be ascribed to increased capability of [Glu1]gA to permeate through membranes and/or redistribute between different membranes. Based on the protective role of mild uncoupling, [Glu1]gA and some other proton-conducting gA analogues may be considered as prototypes of prospective therapeutic agents.     

Large enhancement of skeletal muscle cell glucose uptake and suppression of hepatocyte glucose-6-phosphatase activity by weak uncouplers of oxidative phosphorylation

Background

Perturbation of energy homeostasis in skeletal muscle and liver resulting from a transient inhibition of mitochondrial energy transduction can produce effects of relevance for the control of hyperglycemia through activation of the AMP-activated protein kinase, as exemplified by the antidiabetic drug metformin. The present study focuses on uncoupling of oxidative phosphorylation rather than its inhibition as a trigger for such effects.

Methods

The reference weak uncoupler 2,4-dinitrophenol, fourteen naturally-occurring phenolic compounds identified as uncouplers in isolated rat liver mitochondria, and fourteen related compounds with little or no uncoupling activity were tested for enhancement of glucose uptake in differentiated C2C12 skeletal muscle cells following 18 h of treatment at 25-100 μM. A subset of compounds were tested for suppression of glucose-6-phosphatase (G6Pase) activity in H4IIE hepatocytes following 16 h at 12.5-25 μM. Metformin (400 μM) was used as a standard in both assays.

Results

Dinitrophenol and nine of eleven compounds that induced 50% or more uncoupling at 100 μM in isolated mitochondria enhanced basal glucose uptake by 53 to 269%; the effect of the 4′-hydroxychalcone butein was more than 6-fold that of metformin; negative control compounds increased uptake by no more than 25%. Dinitrophenol and four 4′-hydroxychalconoids also suppressed hepatocyte G6Pase as well as, or more effectively than metformin, whereas the unsubstituted parent compound chalcone, devoid of uncoupling activity, had no effect.

Conclusions

Activities key to glycemic control can be induced by a wide range of weak uncouplers, including compounds free of difficult-to-metabolize groups typically associated with uncouplers.

General significance

Uncoupling represents a valid and possibly more efficient alternative to inhibition for triggering cytoprotective effects of therapeutic relevance to insulin resistance in both muscle and liver. Identification of actives of natural origin and the insights into their structure-activity relationship reported herein may lead to alternatives to metformin.     

On the extent of localization of the energized membrane state in chromatophores from Rhodopseudomonas capsulata N22.

1. The principle of the double-inhibitor titration method for assessing competing models of electron transport phosphorylation is expounded. 2. This principle is applied to photophosphorylation by chromatophores from Rhodopseudomonas capsulata N22. 3. It is found that, in contrast to the predictions of the chemiosmotic coupling model, free energy transfer is confined to individual electron transport chain and ATP synthase complexes. 4. This conclusion is not weakened by arguments concerning, the degree of uncoupling in the native chromatophore preparation or the relative number of electron transport chain and ATP synthase complexes present. 5. Photophosphorylation is completely inhibited by the uncoupler SF 6847 at a concentration corresponding to 0.31 molecules per electron transport chain. 6. The apparent paradox is solved by the proposal, consistent with the available evidence on the mode of action of uncouplers, that uncoupler binding causes a co-operative conformation transition in the chromatophore membrane, which leads to uncoupling and which is not present in the absence of uncoupler.