The antihypertensive drug carvedilol inhibits the activity of mitochondrial NADH-ubiquinone oxidoreductase

A study is presented on the interaction of carvedilol with mitochondria isolated from several rat organs. It is shown that carvedilol causes a moderate uncoupling effect under non phosphorylating succinate supported respiration of intact mitochondria, as well as a marked inhibition of coupled respiration with NAD-dependent substrates. The inhibitory effect was also found in the bovine heart purified Complex I as well as in experiments with mitochondrial particles, where the individual redox segments of the respiratory chain were analysed. It is also shown that carvedilol, though exhibiting an intrinsic scavenger activity, caused reactive oxygen species to be produced as a consequence of its inhibitory effect on the steady-state respiration. Under these conditions the pro-oxidant activity of carvedilol appears to prevail over its scavenging activity, and a net generation of ROS is promoted.     

Succinimidyl oleate, established inhibitor of CD36/FAT translocase inhibits complex III of mitochondrial respiratory chain

The functional role of CD36 protein detected in mitochondrial fractions in long chain fatty acid (LCFA) oxidation is unclear due to conflicting results obtained in Cd36 knockout mice and experiments using sulfo-N-succinimidyl oleate (SSO) for inhibition of CD36 mediated LCFA transport. We investigated effect of SSO on mitochondrial respiration and found that SSO substantially inhibits not only LCFA oxidation, but also oxidation of flavoprotein- and NADH-dependent substrates and generation of mitochondrial membrane potential. Experiments in rat liver, heart and kidney mitochondria demonstrated a direct effect on mitochondrial respiratory chain with the most pronounced inhibition of the complex III (IC₅₀ 4 μM SSO). The results presented here show that SSO is a potent and irreversible inhibitor of mitochondrial respiratory chain.     

Cytochrome c Effect on Respiration of Heart Mitochondria: Influence of Various Factors

The effect of exogenous cytochrome c on respiration rate of the rat and human heart mitochondria was assessed in situ, using permeabilized fibers. It was (i) much more pronounced in State 2 and 4 than in State 3 with all the respiratory substrates (pyruvate+malate, succinate, palmitoyl-CoA+carnitine and octanoyl-L-carnitine), (ii) different with different substrates, (iii) much higher after ischemia in both metabolic states, particularly in the case of succinate oxidation compared to pyruvate+malate, (iv) the highest in State 4 with succinate as a substrate. Similar results were obtained with the isolated rat and rabbit heart mitochondria. The differences in the degree of stimulation of mitochondrial respiration by cytochrome c and, thus, sensitivity of cytochrome c test in evaluation of the intactness/injury of outer mitochondrial membrane are probably determined by the differences in the cytochrome c role in the control of mitochondrial respiration in the above-described conditions.     

Oxidative phosphorylation in mitochondria isolated from small intestinal epithelium of thiamphenicol-treated rats and control rats

Treatment of rats with thiamphenicol in a dose of 125 mg/kg per day for 60–64 h causes specific inhibition of mitochondrial protein synthesis, leading to a drastic decrease of the cytochrome c oxidase activity in intestinal epithelium. At the same time the mitochondrial ATPase activity becomes resistant to inhibition by oligomycin. Experiments with isolated intestinal mitochondria revealed that respiration in state 3 is diminished by 55% with succinate (5 mM) and by 40% with pyruvate (10 mM) plus L-malate (2 mM) as the substrates, both as compared to intestinal mitochondria isolated from control rats. P : O ratios as well as respiratory control indices are comparable in the two groups of animals. Uncoupled respiration is inhibited by 35% with succinate as the substrate, while the succinate cytochrome c reductase activity remains unaltered. No inhibition of uncoupled respiration with pyruvate plus L-malate as the substrates was observed. The ATP-P_i exchange activity in the mitochondria from the treated animals is diminished by about 75%. It is concluded that in the mitochondria of the treated animals the inhibition of the coupled respiration (state 3) is caused by the limitation of the ATP-generating capacity and that electron transport is rate limiting only with the rapidly oxidized substrates such as succinate, if respiration is uncoupled.     

Adenine nucleotides, glutamate and respiratory function of heart mitochondria during acute hypoxia

The effect of acute hypoxia on adenine nucleotides, glutamate, aspartate, alanine and respiration of heart mitochondria was studied in rats. The losses of intramitochondrial adenine nucleotides (ATP+ADP+AMP) during hypoxia were related to depression of state 3 respiration supported by glutamate and malate, as well as decrease in uncoupled respiration. Hypoxia had less prominent effect on succinate-dependent state 3 respiration. Non-phosphorylating (state 4) respiratory rates and ADP/O ratios were slightly affected by oxygen deprivation. Glutamate fall in tissue and mitochondria of hypoxic hearts was concomitant with significant increase in tissue alanine and mitochondrial aspartate. The losses of intramitochondrial ATP and respiratory activity with NAD-dependent substrates during hypoxia were related to a decrease in mitochondrial glutamate. The results suggest that hypoxia-induced impairment of complex I of respiratory chain and a loss of glutamate from the matrix may limit energy-producing capacity of heart mitochondria.     

Effects of equisetin on rat liver mitochondria: Evidence for inhibition of substrate anion carriers of the inner membrane

The effect of equisetin, an antibiotic produced byFusarium equiseti, has been studied on mitochondrial functions (respiration, ATPase, ion transport). Equisetin inhibits the DNP-stimulated ATPase activity of rat liver mitochondria and mitoplasts in a concentration-dependent manner; 50% inhibition is caused by about 8 nmol equisetin/mg protein. The antibiotic is without effect either on the ATPase activity of submitochondrial particles or on the purified F₁-ATPase. It inhibits both the ADP- or DNP-activated oxygen uptake by mitochondria in the presence of glutamate + malate or succinate as substrates, but only the ADP-stimulated respiration is inhibited if the electron donors are TMPD + ascorbate. It does not affect the NADH or succinate oxidation of submitochondrial particles. Equisetin inhibits in a concentration-dependent manner the active Ca²⁺-uptake of mitochondria energized both by ATP or succinate without affecting the Ca²⁺-uniporter itself. The antibiotic inhibits the ATP-uptake by mitochondria (50% inhibition at about 8 nmol equisetin/mg protein) and the P_i and dicarboxylate carrier. It does not lower the membrane potential at least up to 200 nmol/mg protein concentration. The data presented in this paper indicate that equisetin specifically inhibits the substrate anion carriers of the mitochondrial inner membrane.Abbreviations EGTA ethyleneglycol bis/-aminoethylether/-N, N-tetraacetic acid - DNP 2, 4-dinitrophenol - TMPD N,N,N,N,tetramethyl-p-phenylenediamine - CCP carbonylcyanide-m-chlorophenyl hydrazone - TPP tetraphenyl-phosphonium - Hepes /4,(2-hydroxyethyl)-1-piperazine-ethanesulfonic acid/     

Substrate-dependent differential regulation of mitochondrial bioenergetics in the heart and kidney cortex and outer medulla

The kinetics and efficiency of mitochondrial oxidative phosphorylation (OxPhos) can depend on the choice of respiratory substrates. Furthermore, potential differences in this substrate dependency among different tissues are not well-understood. Here, we determined the effects of different substrates on the kinetics and efficiency of OxPhos in isolated mitochondria from the heart and kidney cortex and outer medulla (OM) of Sprague-Dawley rats. The substrates were pyruvate+malate, glutamate+malate, palmitoyl-carnitine+malate, alpha-ketoglutarate+malate, and succinate±rotenone at saturating concentrations. The kinetics of OxPhos were interrogated by measuring mitochondrial bioenergetics under different ADP perturbations. Results show that the kinetics and efficiency of OxPhos are highly dependent on the substrates used, and this dependency is distinctly different between heart and kidney. Heart mitochondria showed higher respiratory rates and OxPhos efficiencies for all substrates in comparison to kidney mitochondria. Cortex mitochondria respiratory rates were higher than OM mitochondria, but OM mitochondria OxPhos efficiencies were higher than cortex mitochondria. State 3 respiration was low in heart mitochondria with succinate but increased significantly in the presence of rotenone, unlike kidney mitochondria. Similar differences were observed in mitochondrial membrane potential. Differences in H₂O₂ emission in the presence of succinate±rotenone were observed in heart mitochondria and to a lesser extent in OM mitochondria, but not in cortex mitochondria. Bioenergetics and H₂O₂ emission data with succinate±rotenone indicate that oxaloacetate accumulation and reverse electron transfer may play a more prominent regulatory role in heart mitochondria than kidney mitochondria. These studies provide novel quantitative data demonstrating that the choice of respiratory substrates affects mitochondrial responses in a tissue-specific manner.     

Relation between glutamate and adenine nucleotide levels of heart mitochondria during hypoxia

The effect of acute respiratory hypoxia in rats on mitochondrial respiration, adenine nucleotides and some amino acids of the heart was studied. The decrease in the total (ATP + ADP + AMP) and exchangeable (ATP + ADP) adenine nucleotide pool of the mitochondria was accompanied by a pronounced loss of state 3 respiration with glutamate plus malate and a slight decrease with succinate plus rothenone. The uncoupled respiration of mitochondria with glutamate and malate was decreased in the same degree as in the absence of 2,4-dinitrophenol. State 4 respiration with substrates of both types was unaffected by hypoxia. These data point to a hypoxia-induced impairment of complex I of the respiratory chain. The decrease of tissue and mitochondrial glutamate was accompanied by the elevation of alanine content in the heart and an increase in intramitochondrial aspartate. The ADP-stimulated respiration of mitochondria was correlated with mitochondrial glutamate and ATP as well as with exchangeable adenine nucleotide pools during hypoxia. The experimental results suggest that mitochondrial dysfunction induced by hypoxia may also be attributed to the low level of mitochondrial glutamate.     

Inhibition of lipid peroxidation by a novel compound (CV-2619) in brain mitochondria and mode of action of the inhibition

Lipid peroxidation in rat brain mitochondria was induced by NADH in the presence of ADP and FeCl3. CV-2619 inhibited the lipid peroxidation in a concentration-dependent manner; the concentration giving 50% inhibition (IC50) was 84 microM. In addition, the inhibitory effect of CV-2619 was strongly enhanced by adding substrates of mitochondrial respiration; when succinate, glutamate, or succinate plus glutamate was added, the IC50 of CV-2619 was changed to 1.1, 10, or 0.5 microM, respectively. Metabolites of CV-2619 also inhibited the lipid peroxidation. The inhibitory effect of CV-2619 on mitochondrial lipid peroxidation disappeared when TTFA, an inhibitor of complex II in mitochondrial respiratory chain, was added. The results indicate that in mitochondria CV-2619 is changed to its reduced form which inhibits lipid peroxidation.     

Effect of thyroidectomy and subsequent treatment with triiodothyronine on kidney mitochondrial oxidative phosphorylation in the rat

The effect of thyroidectomy (Tx) and subsequent treatment with triiodothy-ronine (T₃) on rat kidney mitochondrial oxidative phosphorylation was examined. Thyroidectomy resulted in lowering of state 3 respiration rates and cytochrome contents. Thyroidectomized animals administered with T₃ (20 Μg/100 g body wt) resulted in the nonsynchronous stimulation of state 3 respiration rates in kidney mitochondria with glutamate, Β-hydroxybutyrate, succinate and ascorbate+TMPD as substrates. Cytoch-rome contents were also elevated differentially. Increase in the state 4 respiration rates was transient and reversible. However, primary dehydrogenases were not generally altered in the Tx and T₃-treated Tx animals. The results thus indicate that the T₃treatment to-Tx animals brings about differential and nonsynchronous increase in the respiratory parameters and respiratory chain components of kidney mitochondria.     

Creatine kinase of heart mitochondria. Control of oxidative phosphorylation by the extramitochondrial concentrations of creatine and phosphocreatine

Defining how extramitochondrial high-energy phosphate acceptors influence the rates of heart oxidative phosphorylation is essential for understanding the control of myocardial respiration. When the production of phosphocreatine is coupled to electron transport via mitochondrial creatine kinase, the net reaction can be expressed by the balanced equation: creatine + Pi----phosphocreatine + H2O. This suggests that rates of oxygen consumption could be regulated by changes in [creatine], [Pi], or [phosphocreatine], alone or in combination. The effects of altering these metabolites upon mitochondrial rates of respiration were examined in vitro. Rat heart mitochondria were incubated in succinate-containing oxygraph medium (pH 7.2, 37 degrees C) supplemented with five combinations of creatine (1.0-20 mM), phosphocreatine (0-25 mM), and Pi (0.25-5.0 mM). In all cases, the mitochondrial creatine kinase reaction was initiated by additions of 0.5 mM ATP. To emphasize the duality of control, the results are presented as three-dimensional stereoscopic projections. Under physiological conditions, with 5.0 mM creatine, increases in Pi or decreases in phosphocreatine had little influence upon mitochondrial respiration. When phosphocreatine was held constant (15 mM), changes in [creatine] modestly stimulated respiratory rates, whereas Pi again showed little effect. With 1.0 mM Pi, respiration clearly became dependent upon changes in [creatine] and [phosphocreatine]. Initially, respiratory rates increased as a function of [creatine]. However, at [phosphocreatine] values below 10 mM, product "deinhibition" was observed, and respiratory rates rapidly increased to 80% State 3. With 2.0 mM Pi or higher, respiration could be regulated from State 4 to 100% State 3. Overall, the data show how increasing [creatine] and decreasing [phosphocreatine] influence the rates of oxidative phosphorylation when mediated by mitochondrial creatine kinase. Thus, these changes may become secondary cytoplasmic signals regulating heart oxygen consumption.     

Increased uncoupling proteins and decreased efficiency in palmitate-perfused hyperthyroid rat heart

The physiological role of mitochondrial uncoupling proteins (UCPs) in heart and skeletal muscle is unknown, as is whether mitochondrial uncoupling of oxidative phosphorylation by fatty acids occurs in vivo. In this study, we found that UCP2 and UCP3 protein content, determined using Western blotting, was increased by 32 and 48%, respectively, in hyperthyroid rat heart mitochondria. Oligomycin-insensitive respiration rate, a measure of mitochondrial uncoupling, was increased in all mitochondria in the presence of palmitate: 36% in controls and 71 and 100% with 0.8 and 0.9 mM palmitate, respectively, in hyperthyroid rat heart mitochondria. In the isolated working heart, 0.4 mM palmitate significantly lowered cardiac output by 36% and cardiac efficiency by 38% in the hyperthyroid rat heart. Thus increased mitochondrial UCPs in the hyperthyroid rat heart were associated with increased uncoupling and decreased myocardial efficiency in the presence of palmitate. In conclusion, a physiological effect of UCPs on fatty acid oxidation has been found in heart at the mitochondrial and whole organ level.     

The inhibition of succinate, beta-oxybutyrate and glutamate transport in the liver mitochondria of hibernating susliks

Studies have been made on the permeability of the inner membrane of the liver mitochondria from hibernating and active ground squirrels for succinate, glutamate, hydroxybutyrate and inorganic phosphate. The permeability was calculated from the rate of mitochondrial swelling in 100 mM ammonium salts of the substrates and phosphate. It was shown that the rate of mitochondrial swelling in hibernating animals is 2--3 times lower than in active ones, being essentially identical in a solution of ammonium phosphate. It was concluded that the permeability of the inner mitochondrial membrane for the substrates decreases in hibernating animals, remaining unaffected for phosphate. Calcium-induced activation of membrane phospholipase A2 facilitates the transport of oxidative substrates into the mitochondria of hibernating ground squirrels, significant increase in the mitochondrial respiration being simultaneously observed. The data obtained suggest that inhibition of transport of oxidative substrates is one of the main factors which account for a low respiration rate in the mitochondria of hibernating animals.     

Quantitation of the effect of L-carnitine on the levels of acid-soluble short-chain acyl-CoA and CoASH in rat heart and liver mitochondria

The steady state levels of mitochondrial acyl-CoAs produced during the oxidation of pyruvate, alpha-ketoisovalerate, alpha-ketoisocaproate, and octanoate during state 3 and state 4 respiration by rat heart and liver mitochondria were determined. Addition of carnitine lowered the amounts of individual short-chain acyl-CoAs and increased CoASH in a manner that was both tissue- and substrate-dependent. The largest effects were on acetyl-CoA derived from pyruvate in heart mitochondria using either state 3 or state 4 oxidative conditions. Carnitine greatly reduced the amounts of propionyl-CoA derived from alpha-ketoisovalerate, while smaller effects were obtained on the branched-chain acyl-CoA levels, consistent with the latter acyl moieties being poorer substrates for carnitine acetyltransferase and also poorer substrates for the carnitine/acylcarnitine translocase. The levels of acetyl-CoA in heart and liver mitochondria oxidizing octanoate during state 3 respiration were lower than those obtained with pyruvate. The rate of acetylcarnitine efflux from heart mitochondria during state 3 (with pyruvate or octanoate as substrate, in the presence or absence of malate with 0.2 mM carnitine) shows a linear response to the acetyl-CoA/CoASH ratio generated in the absence of carnitine. This relationship is different for liver mitochondria. These data demonstrate that carnitine can modulate the aliphatic short-chain acyl-CoA/CoA ratio in heart and liver mitochondria and indicate that the degree of modulation varies with the aliphatic acyl moiety.     

Inhibition of mitochondrial respiration by phosphoenolpyruvate

The cytosolic factors that influence mitochondrial oxidative phosphorylation rates are relatively unknown. In this report, we examine the effects of phosphoenolpyruvate (PEP), a glycolytic intermediate, on mitochondrial function. It is reported here that in rat heart mitochondria, PEP delays the onset of state 3 respiration in mitochondria supplied with either NADH-linked substrates or succinate. However, the maximal rate of state 3 respiration is only inhibited when oxidative phosphorylation is supported by NADH-linked substrates. The capacity of PEP to delay and/or inhibit state 3 respiration is dependent upon the presence or absence of ATP. Inhibition of state 3 is exacerbated in uncoupled mitochondria, with a 40% decrease in respiration seen with 0.1mM PEP. In contrast, ATP added exogenously or produced by oxidative phosphorylation completely prevents PEP-mediated inhibition. Mechanistically, the results support the conclusion that the main effects of PEP are to impede ADP uptake and inhibit NADH oxidation. By altering the NADH/NAD(+) status of mitochondria, it is demonstrated that PEP enhances succinate dehydrogenase activity and increase free radical production. The results of this study indicate PEP may be an important modulator of mitochondrial function under conditions of decreased ATP.     

Glucose,Lactate and Glutamine but not Glutamate Support Depolarization-Induced Increased Respiration in Isolated Nerve Terminals

Synaptosomes prepared from various aged and gene modified experimental animals constitute a valuable model system to study pre-synaptic mechanisms. Synaptosomes were isolated from whole brain and the XFe96 extracellular flux analyzer (Seahorse Bioscience) was used to study mitochondrial respiration and glycolytic rate in presence of different substrates. Mitochondrial function was tested by sequentially exposure of the synaptosomes to the ATP synthase inhibitor, oligomycin, the uncoupler FCCP (carbonyl cyanide-4-(trifluoromethoxy) phenylhydrazone) and the electron transport chain inhibitors rotenone and antimycin A. The synaptosomes exhibited intense respiratory activity using glucose as substrate. The FCCP-dependent respiration was significantly higher with 10 mM glucose compared to 1 mM glucose. Synaptosomes also readily used pyruvate as substrate, which elevated basal respiration, activity-dependent respiration induced by veratridine and the respiratory response to uncoupling compared to that obtained with glucose as substrate. Also lactate was used as substrate by synaptosomes but in contrast to pyruvate, mitochondrial lactate mediated respiration was comparable to respiration using glucose as substrate. Synaptosomal respiration using glutamate and glutamine as substrates was significantly higher compared to basal respiration, whereas oligomycin-dependent and FCCP-induced respiration was lower compared to the responses obtained in the presence of glucose as substrate. We provide evidence that synaptosomes are able to use besides glucose and pyruvate also the substrates lactate, glutamate and glutamine to support their basal respiration. Veratridine was found to increase respiration supported by glucose, pyruvate, lactate and glutamine and FCCP was found to increase respiration supported by glucose, pyruvate and lactate. This was not the case when glutamate was the only energy substrate.     

Influence of mitochondrial creatine kinase on the mitochondrial/extramitochondrial distribution of high energy phosphates in muscle tissue: evidence for a leak in the creatine shuttle

The influence of mitochondrial creatine kinase on subcellular high energy systems has been investigated using isolated rat heart mitochondria, mitoplasts and intact heart and skeletal muscle tissue.In isolated mitochondria, the creatine kinase is functionally coupled to oxidative phosphorylation at active respiratory chain, so that it catalyses the formation of creatine phosphate against its thermodynamic equilibrium. Therefore the mass action ratio is shifted from the equilibrium ratio to lower values. At inhibited respiration, it is close to the equilibrium value, irrespective of the mechanism of the inhibition. The same results were obtained for mitoplasts under conditions where the mitochondrial creatine kinase is still associated with the inner membrane.In intact tissue increasing amounts of creatine phosphate are found in the mitochondrial compartment when respiration and/or muscle work are increased. It is suggested that at high rates of oxidative phosphorylation creatine phosphate is accumulated in the intermembrane space due to the high activity of mitochondrial creatine kinase and the restricted permeability of reactants into the extramitochondrial space. A certain amount of this creatine phosphate leaks into the mitochondrial matrix.This leak is confirmed in isolated rat heart mitochondria where creatine phosphate is taken up when it is generated by the mitochondrial creatine kinase reaction. At inhibited creatine kinase, external creatine phosphate is not taken up. Likewise, mitoplasts only take up creatine phosphate when creatine kinase is still associated with the inner membrane. Both findings indicate that uptake is dependent on the functional active creatine kinase coupled to oxidative phosphorylation.Creatine phosphate uptake into mitochondria is inhibited with carboxyatractyloside. This suggests a possible role of the mitochondrial adenine nucleotide translocase in creatine phosphate uptake.Taken together, our findings are in agreement with the proposal that creatine kinase operates in the intermembrane space as a functional unit with the adenine nucleotide translocase in the inner membrane for optimal transfer of energy from the electron transport chain to extramitochondrial ATP-consuming reactions.     

Decreased mitochondrial creatine kinase activity in dystrophic chicken breast muscle alters creatine-linked respiratory coupling

Dystrophic chicken breast muscle mitochondria contain significantly less mitochondrial creatine kinase than normal breast muscle mitochondria. Breast muscle mitochondria from normal 16- to 40-day-old chickens contain approximately 80 units of mitochondrial creatine kinase per unit of succinate:INT (p-iodonitrotetrazolium violet) reductase, a mitochondrial marker, while dystrophic chicken breast muscle mitochondria contain 36-44 units. Normal chicken heart muscle mitochondria contain about 10% of the mitochondrial creatine kinase per unit of succinate:INT reductase as normal breast muscle mitochondria. The levels in heart muscle mitochondria from dystrophic chickens are not affected significantly. Evidence is presented which shows that the reduced level of mitochondrial creatine kinase in dystrophic breast muscle mitochondria is responsible for an altered creatine linked respiration. First, both normal and dystrophic breast muscle mitochondria respire with the same state 3 and state 4 respiration. Second, the post-ADP state 4 rate of respiration of normal breast muscle mitochondria in the presence of 20 mM creatine continues at the state 3 rate. However, the state 4 rate of dystrophic breast muscle mitochondria and mitochondria from other muscle types with a low level of mitochondrial creatine kinase, such as heart muscle and 5-day-old chicken breast muscle, is slower than the state 3 rate. Third, dystrophic breast mitochondria synthesize ATP at the same rate as normal breast muscle mitochondria but rates of creatine phosphate synthesis in 20-50 mM Pi are reduced significantly. Finally, increasing concentrations of Pi displace mitochondrial creatine kinase from mitoplasts of normal and dystrophic breast muscle mitochondria with the same apparent KD, indicating that the outer surface of the inner mitochondrial membrane and the mitochondrial creatine kinase from dystrophic muscle are not altered.     

Contribution of ATP synthase to stimulation of respiration by Ca2+ in heart mitochondria

A variety of experimental conditions were applied with the aim to estimate the correlation between the contribution of ATP synthase to the respiratory flux control and the calcium-induced activation of succinate oxidation in heart mitochondria isolated from rat, rabbit and guinea pig. The sensitivity of respiration in heart mitochondria to the decrease in temperature from 37 degrees C to 28 degrees C decreases in the order rabbit > guinea pig > rat. Ca2+ effect on succinate oxidation rate in state 3 respiration was species- and temperature-dependent and ranged from 0 (rat, 37 degrees C) to +44% (rabbit, 28 degrees C). For mitochondria from all experimental animals, the increase of Ca2+ in physiological range of concentration did not change state 2 respiration rate, and the stimulatory effect of Ca2+ on state 3 respiration was more pronounced at 28 degrees C than at 37 degrees C. The respiratory subsystem was sensitive to Ca2+ ions only in rabbit heart mitochondria. A high positive correlation between Ca2+ ability to stimulate succinate oxidation in state 3 and the control exerted by ATP synthase over the respiratory flux provides argument confirming stimulation of ATP synthase by Ca2+ ions.