On the state of calcium ions in isolated rat liver mitochondria. II. Effects of phosphate and pH on Ca2+-induced Ca2+ release

At high K+ concentration, the effect of phosphate on Ca2+ uptake and release was studied in isolated rat liver mitochondria. Phosphate stimulated uptake at moderately high Ca2+ concentration, and inhibited release at high pH. At low pH, phosphate accelerated Ca2+ release. Ca2+ was released after a lag phase. The time of onset and the velocity of Ca2+ release depended on Ca2+ concentration. Ca2+ release was associated with mitochondrial swelling and destruction of the permeability barrier for sucrose and for chloride. Mg2+ inhibited Ca2+ release and the accompanying events. Ruthenium red and EGTA protected mitochondria from the destructive Ca2+ release and induced an immediate, slow release of Ca2+ and phosphate. Destructive Ca2+ release depended on the time of preincubation of respiration-inhibited mitochondria in the presence of Ca2+, prior to respiration-initiated Ca2+ uptake. The presence of phosphate and mitochondrial energization antagonized the destructive effect of calcium ions. Ca2+ release by acetoacetate also depended on pH. At pH 6.8, phosphate-stimulated Ca2+ release by acetoacetate, while it inhibited the acetoacetate effect at pH 7.6. The results suggest that an essential cause for the destruction of mitochondrial integrity is an increase in the intramitochondrial concentration of free calcium ions under the influence of phosphate.     

Modulation of the mitochondrial cyclosporin A-sensitive permeability transition pore by the proton electrochemical gradient. Evidence that the pore can be opened by membrane depolarization.

This paper reports an investigation on the relationship between the proton electrochemical gradient (delta mu H+) and the cyclosporin A-sensitive permeability transition pore (PTP) in rat liver mitochondria. Using the SH group cross-linker phenylarsine oxide as the inducer, we show that both matrix pH and the membrane potential can modulate the process of PTP induction independently of Ca2+. We find that membrane depolarization induces the PTP per se when pHi is above 7.0, while at acidic matrix pH values PTP induction is effectively prevented. Since Ca2+ uptake leads to major modifications of the delta mu H+ (i.e. matrix alkalinization and membrane depolarization), we have explored the possibility that the Ca(2+)-induced changes of the delta mu H+ may contribute to PTP induction by Ca2+. Our data in mitochondria treated with Ca2+ plus N-ethylmaleimide and Ca2+ plus phosphate show that membrane depolarization is a powerful inducer of the PTP. Taken together, our observations indicate that the PTP can be controlled directly by the delta mu H+ both in the absence and presence of Ca2+, and suggest that a collapse of the membrane potential may be the cause rather than the consequence of PTP induction under many experimental conditions. Thus, many inducers may converge on dissipation of the membrane potential component of the delta mu H+ by a variety of mechanisms.     

Changes in membrane potential during calcium ion influx and efflux across the mitochondrial membrane.

1. A depolarisation of the membrane of rat liver mitochondria, as measured with the safranine method, is seen during Ca2+ uptake. The depolarisation is followed by a slow repolarisation, the rate of which can be increased by the addition of EGTA or phosphate. 2. Plots relating the initial rate of calcium ion (Ca2+) uptake and the decrease in membrane potential (delta psi) to the Ca2+ concentration show a half-maximal change at less than 10 micron Ca2+ and a saturation above 20 micron Ca2+. 3. Plots relating the initial rate of Ca2+ uptake to delta psi are linear. 4. Addition of Ca2+ chelators, nitriloacetate or EGTA, to deenergized mitochondria equilibrated with Ca2+ causes a polarisation of the mitochondrial membrane due to a diffusion potential created by electrogenic Ca2+ efflux. 5. If the extent of the response induced by different nitriloacetate concentrations is plotted against the expected membrane potential a linear plot is obtained up to 70 mV with a slope corresponding to two-times the extent of the response induced by valinomycin in the presence of different potassium ion gradients. This suggests that the Ca2+ ion is transferred across the membrane with one net positive charge in present conditions.     

Interactions of calcium with yeast mitochondria.

The interactions of Ca2+ with mitochondria from Saccharomyces cerevisiae were explored. Mitochondria were loaded with the metallochromic dye Fluo-3 to measure the concentration of free calcium in the matrix. Addition of EGTA or Ca2+ led to fluctuations in mitochondrial free calcium between 120 and 400 nM. Ca2+ variations were slower at 4 degrees C than at 25 degrees C or in the presence of phosphate instead of acetate. The net uptake of 45Ca2+ was higher with phosphate than with acetate. The optimum pH for Ca2+ uptake was 6.8. Ruthenium red did not affect the uptake of Ca2+. Addition of antimycin-A or uncouplers led to a small and transient release of Ca2+. Addition of EGTA or the monovalent cations Na+ or K+ resulted in higher release of Ca2+. Site I but not site II dependent O2 consumption was partially inhibited by EGTA. The effect of Ca2+ on NADH oxidation is similar to results reported with enzymes from mammalian sources which use NADH, such as the pyruvate, isocitrate and oxoglutarate dehydrogenases.     

Kinetics of Ca2+ and Sr2+ uptake by yeast. Effects of pH, cations and phosphate.

The uptake of Ca2+ and Sr2+ by the yeast Saccharomyces cerevisiae is energy dependent, and shows a deviation from simple Michaelis-Menten kinetics. A model is discussed that takes into account the effect of the surface potential and the membrane potential on uptake kinetics. The rate of Ca2+ and Sr2+ uptake is influenced by the cell pH and by the medium pH. The inhibition of uptake at low concentration of Ca2+ and Sr2+ at low pH may be explained by a decrease of the surface potential. The inhibition of Ca2+ and Sr2+ uptake by monovalent cations is independent of the divalent cation concentration. The inhibition shows saturation kinetics, and the concentration of monovalent cation at which half-maximal inhibition is observed, is equal to the affinity constant of this ion for the monovalent cation transport system. The inhibition of divalent cation uptake by monovalent cations appears to be related to depolarization of the cell membrane. Phosphate exerts a dual effect on uptake of divalent cations: and initial inhibition and a secondary stimulation. The inhibition shows saturation kinetics, and the inhibition constant is equal to the affinity constant of phosphate for its transport mechanism. The secondary stimulation can only partly be explained by a decrease of the cell pH, suggesting interaction of intracellular phosphate, or a phosphorylated compound, with the translocation mechanism.     

Membrane potential of mitochondria in intact lymphocytes during early mitogenic stimulation.

The mitochondrial membrane potential (delta psi m) in intact lymphocytes was calculated by measuring the distribution of radiolabelled methyltriphenylphosphonium cation. The value obtained was 120 mV. The pH gradient across the mitochondrial membrane in situ (delta pH m) was estimated to be 73 mV (1.2 pH units). Thus the electrochemical gradient of protons was about 190 mV. Addition of the mitogen concanavalin A did not alter delta psi m, showing that, if movement of Ca2+ across the inner membrane of lymphocyte mitochondria occurs when concanavalin A is added, it is accompanied by charge-compensating ion movements.     

Regulation of the mitochondrial matrix volume in vivo and in vitro. The role of calcium.

The ability of alpha-adrenergic agonists and vasopressin to increase the mitochondrial volume in hepatocytes is dependent on the presence of extracellular Ca2+. Addition of Ca2+ to hormone-treated cells incubated in the absence of Ca2+ initiates mitochondrial swelling. In the presence of extracellular Ca2+, A23187 (7.5 microM) induces mitochondrial swelling and stimulates gluconeogenesis from L-lactate. Isolated liver mitochondria incubated in KCl medium in the presence of 2.5 mM-phosphate undergo energy-dependent swelling, which is associated with electrogenic K+ uptake and reaches an equilibrium when the volume has increased to about 1.3-1.5 microliter/mg of protein. This K+-dependent swelling is stimulated by the presence of 0.3-1.0 microM-Ca2+, leading to an increase in matrix volume at equilibrium that is dependent on [Ca2+]. Ca2+-activated K+-dependent swelling requires phosphate and shows a strong preference for K+ over Na+, Li+ or choline. It is not associated with either uncoupling of mitochondria or any non-specific permeability changes and cannot be produced by Ba2+, Mn2+ or Sr2+. Ca2+-activated K+-dependent swelling is not prevented by any known inhibitors of plasma-membrane ion-transport systems, nor by inhibitors of mitochondrial phospholipase A2. Swelling is inhibited by 65% and 35% by 1 mM-ATP and 100 microM-quinine respectively. The effect of Ca2+ is blocked by Ruthenium Red (5 micrograms/ml) at low [Ca2+]. Spermine (0.25 mM) enhanced the swelling seen on addition of Ca2+, correlating with its ability to increase Ca2+ uptake into the mitochondria as measured by using Arsenazo-III. Mitochondria derived from rats treated with glucagon showed less swelling than did control mitochondria. In the presence of Ruthenium Red and higher [Ca2+], the mitochondria from hormone-treated animals showed greater swelling than did control mitochondria. These data imply that an increase in intramitochondrial [Ca2+] can increase the electrogenic flux of K+ into mitochondria by an unknown mechanism and thereby cause swelling. It is proposed that this is the mechanism by which alpha-agonists and vasopressin cause an increase in mitochondrial volume in situ.     

Regulation of the mitochondrial Na+/Ca2+ antiport by matrix pH

The effect of matrix pH (pHi) on the activity of the mitochondrial Na+/Ca2+ antiport has been studied using the fluorescence of SNARF-1 to monitor pHi and Na(+)-dependent efflux of accumulated Ca2+ to follow antiport activity. Heart mitochondria respiring in a KCl medium maintain a large delta pH (interior alkaline) and show optimal Na+/Ca2+ antiport only when the pH of the medium (pH0) is acid. Addition of nigericin to these mitochondria decreases delta pH and increases the membrane potential (delta psi). Nigericin strongly activates Na+/Ca2+ antiport at values of pH0 near 7.4 but inhibits antiport activity at acid pH0. When pHi is evaluated in these protocols, a sharp optimum in Na+/Ca2+ antiport activity is seen near pHi 7.6 in the presence or absence of nigericin. Activity falls off rapidly at more alkaline values of pHi. The effects of nigericin on Na+/Ca2+ antiport are duplicated by 20 mM acetate and by 3 mM phosphate. In each case the optimum rate of Na+/Ca2+ antiport is obtained at pHi 7.5 to 7.6 and changes in antiport activity do not correlate with changes in components of the driving force of the reaction (i.e., delta psi, delta pH, or the steady-state Na+ gradient). It is concluded that the Na+/Ca2+ antiport of heart mitochondria is very sensitive to matrix [H+] and that changes in pHi may contribute to the regulation of matrix Ca2+ levels.     

Mitochondrial nitric oxide synthase regulates mitochondrial matrix pH.

Nitric oxide (nitrogen monoxide, NO) exerts a wide profile of its biological activities via regulation of respiration and respiration-dependent functions. The presence of nitric oxide synthase (NOS) in mitochondria (mtNOS) was recently reported by us (Ghafourifar and Richter, FEBS Lett. 418, 291-296, 1997) and others (Giulivi et al., J. Biol. Chem. 273, 11038-11043, 1998). Here we report that NO, provided by an NO donor as well as by mtNOS stimulation, regulates mitochondrial matrix pH, transmembrane potential and Ca2+ buffering capacity. Exogenously-added NO causes a dose-dependent matrix acidification. Also mtNOS stimulation, induced by loading mitochondria with Ca2+, causes mitochondrial matrix acidification and a drop in mitochondrial transmembrane potential. Inhibition of mtNOS's basal activity causes mitochondrial matrix alkalinization and provides a resistance to the sudden drop of mitochondrial transmembrane potential induced by mitochondrial Ca2+ uptake. We conclude that mtNOS plays a critical role in regulating mitochondrial delta(pH).     

Dynamic regulation of the mitochondrial proton gradient during cytosolic calcium elevations

Mitochondria extrude protons across their inner membrane to generate the mitochondrial membrane potential (ΔΨ(m)) and pH gradient (ΔpH(m)) that both power ATP synthesis. Mitochondrial uptake and efflux of many ions and metabolites are driven exclusively by ΔpH(m), whose in situ regulation is poorly characterized. Here, we report the first dynamic measurements of ΔpH(m) in living cells, using a mitochondrially targeted, pH-sensitive YFP (SypHer) combined with a cytosolic pH indicator (5-(and 6)-carboxy-SNARF-1). The resting matrix pH (～7.6) and ΔpH(m) (～0.45) of HeLa cells at 37 °C were lower than previously reported. Unexpectedly, mitochondrial pH and ΔpH(m) decreased during cytosolic Ca(2+) elevations. The drop in matrix pH was due to cytosolic acid generated by plasma membrane Ca(2+)-ATPases and transmitted to mitochondria by P(i)/H(+) symport and K(+)/H(+) exchange, whereas the decrease in ΔpH(m) reflected the low H(+)-buffering power of mitochondria (～5 mm, pH 7.8) compared with the cytosol (～20 mm, pH 7.4). Upon agonist washout and restoration of cytosolic Ca(2+) and pH, mitochondria alkalinized and ΔpH(m) increased. In permeabilized cells, a decrease in bath pH from 7.4 to 7.2 rapidly decreased mitochondrial pH, whereas the addition of 10 μm Ca(2+) caused a delayed and smaller alkalinization. These findings indicate that the mitochondrial matrix pH and ΔpH(m) are regulated by opposing Ca(2+)-dependent processes of stimulated mitochondrial respiration and cytosolic acidification.     

Evaluation of the H+/site ratio of mitochondrial electron transport from rate measurements.

The mitochondrial H+/site ratio (i.e. the number of protons ejected per pair of electrons traversing each of the energy-conserving sites of the respiratory chain) has been evaluated employing a new experimental approach. In this method the rates of oxygen uptake and H+ ejection were measured simultaneously during the initial period of respiration evoked by addition of succinate to aerobic, rotenone-inhibited, de-energized mitochondria. Either K+, in the presence of valinomycin, or Ca2+, was used as mobile cation to dissipate the membrane potential and allow quantitative H+ ejection into the medium. The H+/site ratio observed with this method in the absence of precautions to inhibit the uptake of phosphate was close to 2.0, in agreement with values obtained using the oxygen pulse technique (Mitchell, P. and Moyle, J. (1967) Biochem. J. 105, 1147-1162). However, when phosphate movements were eliminated either by inhibition of the phosphate-hydroxide antiporter with N-ethylamaleimide or by depleting the mitochondria of their endogenous phosphate content, H+/site ratios close to 4.0 were consistently observed. This ratio was independent of the concentration of succinate, of mitochondrial protein, of pH between 6 and 8, and of ionic composition of the medium, provided that sufficient K+ (plus valinomycin) or Ca2+ were present. Specific inhibitors of the hydrolysis of endogenous ATP or transport of other ions (adenine nucleotides, tricarboxylates, HCO3-, etc.) were shown not to affect the observed H+/site ratio. Furthermore, the replacement of succinate by alpha-glycerol phosphate, a substrate which is oxidized on the outer surface of the inner membrane and thus does not need to enter the matrix, gave the same H+/site ratios as did succinate. It is concluded that the H+/site ratio of mitochondrial electron transport, when phosphate movements are eliminated, may be close to 4.0.     

Alterations in mitochondrial Ca2+ flux by the antibiotic X-537A (lasalocid-A).

A previous communication (Pereira da Silva, L., Bernardes, C.F. and Vercesi, A.E. (1984) Biochem. Biophys. Res. Commun. 124, 80-86) presented evidence that lasalocid-A, at concentrations far below those required to act as a Ca2+ ionophore, significantly inhibits Ca2+ efflux from liver mitochondria. In the present work we have studied the mechanism of this inhibition in liver and heart mitochondria. It was observed that lasalocid-A (25-250 nM), like nigericin, promotes the electroneutral exchange of K+ for H+ across the inner mitochondrial membrane and as a consequence can cause significant alterations in delta pH and delta psi. An indirect effect of these changes that might lead to inhibition of mitochondrial Ca2+ release was ruled out by experiments showing that the three observed patterns of lasalocid-A effect depend on the size of the mitochondrial Ca2+ load. At low Ca2+ loads (5-70 nmol Ca2+/mg protein), under experimental conditions in which Ca2+ release is supposed to be mediated by a Ca2+/2H+ antiporter, the kinetic data indicate that lasalocid-A inhibits the efflux of the cation by a competitive mechanism. The Ca2+/2Na+ antiporter, the dominant pathway for Ca2+ efflux from heart mitochondria, is not affected by lasalocid-A. At intermediate Ca2+ loads (70-110 nmol Ca2+/mg protein), lasalocid-A slightly stimulates Ca2+ release. This effect appears to be due to an increase in membrane permeability caused by the displacement of a pool of membrane bound Mg2+ possibly involved in the maintenance of membrane structure. Finally, at high Ca2+ loads (110-140 nmol Ca2+/mg protein) lasalocid-A enhances Ca2+ retention by liver mitochondria even in the presence of Ca2(+)-releasing agents such as phosphate and oxidants of the mitochondrial pyridine nucleotides. The maintenance of a high membrane potential under these conditions may indicate that lasalocid-A is a potent inhibitor of the Ca2(+)-induced membrane permeabilization. Nigericin, whose chemical structure resembles that of lasalocid-A, caused similar results.     

Ca(2+)-induced high amplitude swelling and cytochrome c release from wheat (Triticum aestivum L.) mitochondria under anoxic stress

Under stress conditions, mitochondria sense metabolic changes, e.g. in pH, cytoplasmic Ca(2+), energy status, and reactive oxygen species (ROS), and respond by induction of the permeability transition pore (PTP) and by releasing cytochrome c, thus initiating the programmed cell death (PCD) cascade in animal cells. In plant cells, the presence of all the components of the cascade has not yet been shown. In wheat (Triticum aestivum L.) root mitochondria, the onset of anoxia caused rapid dissipation of the inner membrane potential, initial shrinkage of the mitochondrial matrix and the release of previously accumulated Ca(2+). Ca(2+) uptake by mitochondria was dependent on the presence of inorganic phosphate. Treatment of mitochondria with high micromolar and millimolar Ca(2+) (but not Mg(2+)) concentrations induced high amplitude swelling, indicative of PTP opening. Alterations in mitochondrial volume were confirmed by transmission electron microscopy. Mitochondrial swelling was not sensitive to cyclosporin A (CsA)-an inhibitor of mammalian PTP. The release of cytochrome c was monitored under lack of oxygen. Anoxia alone failed to induce cytochrome c release from mitochondria. Oxygen deprivation and Ca(2+) ions together caused cytochrome c release in a CsA-insensitive manner. This process correlated positively with Ca(2+) concentration and required Ca(2+) localization in the mitochondrial matrix. Functional characteristics of wheat root mitochondria, such as membrane potential, Ca(2+) transport, swelling, and cytochrome c release under lack of oxygen are discussed in relation to PCD.     

Regulation of Ca2+ efflux in rat liver mitochondria. Role of membrane potential

The paper analyzes the relationship between membrane potential (delta psi), steady state pCao (-log [Ca2+] in the outer aqueous phase) and rate of ruthenium-red-induced Ca2+ efflux in liver mitochondria. Energized liver mitochondria maintain a pCao of about 6.0 in the presence of 1.5 mM Mg2+ and 0.5 mM Pi. A slight depression of delta psi results in net Ca2+ uptake leading to an increased steady state pCao. On the other hand, a more marked depression of delta psi results in net Ca2+ efflux, leading to a decreased steady-state pCao. These results reflect a biphasic relationship between delta psi and pCao, in that pCao increases with the increase of delta psi up to a value of about 130 mV, whereas a further increase of delta psi above 130 mV results in a decrease of pCao. The phenomenon of Ca2+ uptake following a depression of delta psi is independent of the tool used to affect delta psi whether by inward K+ current via valinomycin, or by inward H+ current through protonophores or through F1-ATP synthase, or by restriction of e- flow. The pathway for Ca2+ efflux is considerably activated by stretching of the inner membrane in hypotonic media. This activation is accompanied by a decreased pCao at steady state and by an increased rate of ruthenium-red-induced Ca2+ efflux. By restricting the rate of e- flow in hypotonically treated mitochondria, a marked dependence of the rate of ruthenium-red-induced Ca2+ efflux on the value of delta psi is observed, in that the rate of Ca2+ efflux increases with the value of delta psi. The pCao is linearly related to the rate of Ca2+ efflux. Activation of oxidative phosphorylation via addition of hexokinase + glucose to ATP-supplemented mitochondria, is followed by a phase of Ca2+ uptake, which is reversed by atractyloside. These findings support the view that Ca2+ efflux in steady state mitochondria occurs through an independent, delta psi-controlled pathway and that changes of delta psi during oxidative phosphorylation can effectively modulate mitochondrial Ca2+ distribution by inhibiting or activating the delta psi-controlled Ca2+ efflux pathway.     

Calcium transport in membrane vesicles of Streptococcus cremoris

Rightside-out membrane vesicles of Streptococcus cremoris were fused with proteoliposomes containing the light-driven proton pump bacteriorhodopsin by a low-pH fusion procedure reported earlier [Driessen, A.J.M., Hellingwerf, K.J. & Konings, W.N. (1985) Biochim. Biophys. Acta 808, 1-12]. In these fused membranes a proton motive force, interior positive and acid, can be generated in the light and this proton motive force can drive the uptake of Ca2+. Collapsing delta psi with a concomitant increase in delta pH stimulates Ca2+ uptake while dissipation of the delta pH results in a reduced rate of Ca2+ uptake. Also an artificially generated delta pH, interior acid, can drive Ca2+ uptake in S. cremoris membrane vesicles. Ca2+ uptake depends strongly on the presence of external phosphate while Ca2+-efflux-induced proton flux is independent of the presence of external phosphate. Ca2+ accumulation is abolished by the divalent cation ionophore A23187. Calcium extrusion from intact cells is accelerated by lactose. Collapse of the proton motive force by the uncoupler carbonylcyanide p-trifluoromethoxyphenylhydrazone or inhibition of the membrane-bound ATPase by N,N'-dicyclohexylcarbodiimide strongly inhibits Ca2+ release. Further studies on Ca2+ efflux at different external pH values in the presence of either valinomycin or nigericin suggested that Ca2+ exit from intact cells is an electrogenic process. It is concluded that Ca2+ efflux in S. cremoris is mediated by a secondary transport system catalyzing exchange of calcium ions and protons.     

Effect of methyl mercury on phosphorylation, transport, and oxidation in mammalian mitochondria.

the toxic effects of CH3HgCL on mitochondria of mammalian organs including human and rat liver were examined. [203Hg]CH3HGCl was bound mainly to mitochondrial proteins. The binding was not effected by the energy state of mitochondria. The state 3 respiration, oxidative phosphorylation and 32Pi-ATP exchange reaction were inhibited by 10 to 50 nmol of CH3HgCl per mg of mitochondrial protein, while NADH-and succinate-dehydrogenase and ATPase were more resistant to it The difference spectrum of the treated mitochondria indicated that the point of inhibition was located after flavin and before cytochrome b. Mitochondrial swelling was induced by CH3HgCl, in accordance with previous morphological observations in vivo. The swelling, stimulation of ATPase and energy-dependent H+ extrusion cauded by CH3HgCl were equally dependent on K+. Under these conditions, uptake of K+ by mitochondria was increased and the membrane potential was dissipated. Unlike the case with other organomercuric compounds, transport of phosphate was not inhibited by CH3HgCl. When tested on liposomes, CH3HgCl itself was not lipid-soluble, as some organomercuric compounds are, and was not an uncoupler or a K+-carrier. It was concluded that protein bound CH3HgS-induced K+ uptake into mitochondria and the resulting loss of membrane potential was the major cause of uncoupling, though at higher concentrations, the electron transport system was also inhibited.     

Effect of Ca2+, peroxides, SH reagents, phosphate and aging on the permeability of mitochondrial membranes

The mechanism by which a number of agents such as hydroperoxides, inorganic phosphate, azodicarboxylic acid bis(dimethylamide) (diamide), 2-methyl-1,4-naphthoquinone (menadione) and aging, induce Ca2+ release from rat liver mitochondria has been analyzed by following Ca2+ fluxes in parallel with K+ fluxes, matrix swelling and triphenylmethylphosphonium fluxes (as an index of transmembrane potential). Addition of hydroperoxides causes a cycle of Ca2+ efflux and reuptake and an almost parallel cycle of delta psi depression. The hydroperoxide-induced delta psi depression is biphasic. The first phase is rapid and insensitive to ATP and is presumably due to activation of the transhydrogenase reaction during the metabolization of the hydroperoxides. The second phase is slow and markedly inhibited by ATP and presumably linked to the activation of a Ca2+-dependent reaction. The slow phase of delta psi depression is paralleled by matrix K+ release and mitochondrial swelling. Nupercaine and ATP reduce or abolish also K+ release and swelling. Inorganic phosphate, diamide, menadione or aging also cause a process of Ca2+ efflux which is paralleled by a slow delta psi depression, K+ release and swelling. All these processes are reduced or abolished by Nupercaine and ATP. The slow delta psi depression following addition of hydroperoxide and diamide is largely reversible at low Ca2+ concentration but tends to become irreversible at high Ca2+ concentration. The delta psi depression increases with the increase of hydroperoxide, diamide and menadione concentration, but is irreversible only in the latter case. Addition of ruthenium red before the hydroperoxides reduces the extent of the slow but not of the rapid phase of delta psi depression. Addition of ruthenium red after the hydroperoxides results in a slow increase of delta psi. Such an effect differs from the rapid increase of delta psi due to ruthenium-red-induced inhibition of Ca2+ cycling in A23187-supplemented mitochondria. Metabolization of hydroperoxides and diamide is accompanied by a cycle of reversible pyridine nucleotide oxidation. Above certain hydroperoxide and diamide concentrations the pyridine nucleotide oxidation becomes irreversible. Addition of menadione results always in an irreversible nucleotide oxidation. The kinetic correlation between Ca2+ efflux and delta psi decline suggests that hydroperoxides, diamide, menadione, inorganic phosphate and aging cause, in the presence of Ca2+, an increase of the permeability for protons of the inner mitochondrial membrane. This is followed by Ca2+ efflux through a pathway which is not the H+/Ca2+ exchange.     

Intramitochondrial K+ as activator of carboxyatractyloside-induced Ca2+ release.

The role of intramitochondrial K+ content on the increase in membrane permeability to Ca2+, as induced by carboxyatractyloside was studied. In mitochondria containing a high K+ concentration (83 nmol/mg), carboxyatractyloside induced a fast and extensive mitochondrial Ca2+ release, membrane de-energization, and swelling. Conversely, in K(+)-depleted mitochondria (11 nmol/mg), carboxyatractyloside was ineffective. The addition of 40 mM K+ to K(+)-depleted mitochondria restored the capability of atractyloside to induce an increase in membrane permeability to Ca2+ release. The determination of matrix free Ca2+ concentration showed that, at an external free-Ca2+ concentration of 0.8 microM, control mitochondria contained 3.9 microM of free Ca2+ whereas K(+)-depleted mitochondria contained 0.9 microM free Ca2+. It is proposed that intramitochondrial K+ affects the matrix free Ca2+ concentration required to induce a state of high membrane permeability.     

Bioenergetic consequences of opening the ATP-sensitive K(+) channel of heart mitochondria

There is an emerging consensus that pharmacological opening of the mitochondrial ATP-sensitive K(+) (K(ATP)) channel protects the heart against ischemia-reperfusion damage; however, there are widely divergent views on the effects of openers on isolated heart mitochondria. We have examined the effects of diazoxide and pinacidil on the bioenergetic properties of rat heart mitochondria. As expected of hydrophobic compounds, these drugs have toxic, as well as pharmacological, effects on mitochondria. Both drugs inhibit respiration and increase membrane proton permeability as a function of concentration, causing a decrease in mitochondrial membrane potential and a consequent decrease in Ca(2+) uptake, but these effects are not caused by opening mitochondrial K(ATP) channels. In pharmacological doses (<50 microM), both drugs open mitochondrial K(ATP) channels, and resulting changes in membrane potential and respiration are minimal. The increased K(+) influx associated with mitochondrial K(ATP) channel opening is approximately 30 nmol. min(-1). mg(-1), a very low rate that will depolarize by only 1-2 mV. However, this increase in K(+) influx causes a significant increase in matrix volume. The volume increase is sufficient to reverse matrix contraction caused by oxidative phosphorylation and can be observed even when respiration is inhibited and the membrane potential is supported by ATP hydrolysis, conditions expected during ischemia. Thus opening mitochondrial K(ATP) channels has little direct effect on respiration, membrane potential, or Ca(2+) uptake but has important effects on matrix and intermembrane space volumes.