Bcl-2 prevents mitochondrial permeability transition and cytochrome c release via maintenance of reduced pyridine nucleotides

Digitonin-permeabilized PC12 and GT1-7 neural cells exhibited a cyclosporin A-sensitive decrease in mitochondrial membrane potential, increased volume, and release of the pro-apoptotic factor cytochrome c in the presence of Ca2+ and the mitochondrial permeability transition (MPT) inducers t-butyl hydroperoxide (t-bOOH) or phenylarsine oxide (PhAsO). Although the concentration of PhAsO required to induce the MPT was similar for Bcl-2 negative and Bcl-2 overexpressing transfected cells (Bcl-2(+)), the level of t-bOOH necessary for triggering the MPT was much higher for Bcl-2(+) cells. A higher concentration of t-bOOH was also necessary for promoting the oxidation of mitochondrial pyridine nucleotides in Bcl-2(+) cells. The sensitivity of Bcl-2(- ) cell mitochondria to t-bOOH but not PhAsO could be overcome by the use of conditions that protect the pyridine nucleotides against oxidation. We conclude that the increased ability of Bcl-2(+) cells to maintain mitochondrial pyridine nucleotides in a reduced redox state is a sufficient explanation for their resistance to MPT under conditions of oxidative stress induced by Ca2+ plus t-bOOH.     

Mangiferin, a natural occurring glucosyl xanthone, increases susceptibility of rat liver mitochondria to calcium-induced permeability transition

Mitochondrial permeability transition (MPT) is a Ca(2+)-dependent, cyclosporine A-sensitive, non-selective inner membrane permeabilization induced by a wide range of agents or conditions, which has often been associated with necrotic or apoptotic cell death. When mitochondria isolated from livers of rats treated with the natural occurring glucosyl xanthone mangiferin (40 mg/kg body weight) were exposed in vitro to Ca(2+), they underwent CsA, NEM, and ADP-sensitive high amplitude swelling and associated membrane potential dissipation, release of pre-accumulated Ca(2+), oxidation of thiol groups, and depletion of GSH, without changes in the NAD(P)H redox state. The same treatment reduced the phosphorylation rate of mitochondria and the resting respiration by around 4 and 11%, respectively, as well as generation of reactive oxygen species (ROS) by organelle. The in vitro exposure of untreated mitochondria to mangiferin plus Ca(2+) also resulted in oxidation of thiol groups, in the same way that the compound inhibited the Ca(2+)-induced peroxidation of mitochondrial membrane lipids. The spectrum of mangiferin during its oxidation by the H(2)O(2)/HRP system showed a characteristic absorption peak at 380 nm, which decreased immediately after reaction was started; two isosbestic points at around 336 and 412 nm, with a blue shift in the position of the maxima absorption of mangiferin were observed, suggesting their conversion into one oxidation product. Glutathione abolished this decrease of absorbance, suggesting that the oxidation product of mangiferin forms adducts with GSH. We propose that Ca(2+) increases levels of mitochondria-generated ROS, which reacts with mangiferin producing quinoid derivatives, which in turn react with the most accessible mitochondrial thiol groups, thus triggering MPT. It seems probable that the free radical scavenging activity of mangiferin shifts its anti-oxidant protection to the thiol arylation. An interesting proposition is that accumulation of mangiferin quinoid products would take place in cells exposed to an overproduction of ROS, such as cancer cells, where the occurrence of MPT-mediated apoptosis may be a cellular defence mechanism against excessive ROS formation.     

t-Butylhydroperoxide-induced Ca2+ efflux from liver mitochondria in the presence of physiological concentrations of Mg2+ and ATP

Isolated rat liver mitochondria, energized either by succinate oxidation or by ATP hydrolysis, present a transient increase in the rate of Ca2+ efflux concomitant to NAD(P)H oxidation by hydroperoxides when suspended in a medium containing 3 mM ATP, 4 mM Mg2+ and acetate as permeant anion. This is paralleled by an increase in the steady-state concentration of extramitochondrial Ca2+, a small decrease in delta psi and an increase in the rate of respiration and mitochondrial swelling. With the exception of mitochondrial swelling all other events were found to be reversible. If Ca2+ cycling was prevented by ruthenium red, the changes in delta psi, the rate of respiration and the extent of mitochondrial swelling were significantly diminished. In addition, there was no significant decrease in the content of mitochondrial pyridine nucleotides. Mitochondrial coupling was preserved after a cycle of Ca2+ release and re-uptake under these experimental conditions. It is concluded that hydroperoxide-induced Ca2+ efflux from intact mitochondria is related to the redox state of pyridine nucleotides.     

Inhibition of oxidative phosphorylation by Ca2+ or Sr2+: a competition with Mg2+ for the formation of adenine nucleotide complexes

Intramitochondrial Sr2+, similar to Ca2+, inhibits oxidative phosphorylation in intact rat-liver mitochondria. Both Ca2+ and Sr2+ also inhibit the hydrolytic activity of the ATPase in submitochondrial particles. Half-maximal inhibition of ATPase activity was attained at a concentration of 2.5 mM Ca2+ or 5.0 mM Sr2+ when the concentration of Mg2+ in the medium was 1.0 mM. The inhibition of ATPase activity by both cations was strongly decreased by increasing the Mg2+ concentration in the reaction medium. In addition, kinetical data and the determination of the concentration of MgATP, the substrate of the ATPase, in the presence of different concentrations of Ca2+ or Sr2+ strongly indicate that these cations inhibit ATP hydrolysis by competing with Mg2+ for the formation of MgATP. On the basis of a good agreement between these results with submitochondrial particles and the results of titrations of oxidative phosphorylation with carboxyatractyloside or oligomycin in mitochondria loaded with Sr2+ it can be concluded that intramitochondrial Ca2+ or Sr2+ inhibits oxidative phosphorylation in intact mitochondria by decreasing the availability of adenine nucleotides to both the ADP/ATP carrier and the ATP synthase.     

Undesirable feature of safranine as a probe for mitochondrial membrane potential

This communication describes experiments showing that safranine, at the concentrations usually employed as a probe of mitochondrial membrane potential, causes significant undesirable side effects on Ca2+ transport by liver mitochondria. The major observations are: (i) safranine potentiates the spontaneous Ca2+ release from liver mitochondria induced by phosphate or acetoacetate. This is paralelled by potentiation of the release of state-4 respiration and of the rate of mitochondrial swelling, indicating a generalized effect of the dye on the mitochondrial membrane; (ii) the efflux of mitochondrial Ca2+ stimulated by hydroperoxide is irreversible in the presence of safranine even if membrane stabilizers such as Mg2+ and ATP are present. It is concluded that the use of safranine to monitor the changes in membrane potential during Ca2+ transport by mitochondria should be avoided or special care be taken.     

Inhibition of ruthenium red-induced Ca2+ efflux from liver mitochondria by the antibiotic X-537A

It has been reported (Becker, G.L., Fiskum, G. and Lehninger, A.L. (1980) J. Biol. Chem. 255, 9009-9012) that respiring rat liver mitochondria suspended in KC1 medium containing ATP, Mg2+ and phosphate, maintain a steady state extramitochondrial free Ca2+ concentration of about 0.5 microM. The results reported here show that the addition of the antibiotic X-537A, at concentrations far below those required for ionophorous activity, caused a perturbation in this steady state, lowering the extramitochondrial free Ca2+ concentration by about 0.20 microM. This shift in steady state was clarified by a study of X-537A inhibition of the Ca2+ efflux induced by ruthenium red; a half-maximum effect was observed at approximately 25 nM X-537A. No effect on Ca2+ transport through the influx uniporter was observed. The possibility of a generalized stabilizing action of the antibiotic on the mitochondrial membrane seems to be ruled out by its effectiveness at very low concentrations.     

Calcium inhibition of the ATP in equilibrium with [32P]Pi exchange and of net ATP synthesis catalyzed by bovine submitochondrial particles

A previous communication (Fagian, M. M., Pereira da Silva, L. and Vercesi, A. E. (1986) Biochim. Biophys. Acta 852, 262-268) indicated that intramitochondrial calcium inhibits oxidative phosphorylation by decreasing the availability of adenine nucleotides to both the ADP/ATP translocase and the F0F1-ATP synthase complex. In this work we analyzed the interactions of calcium-nucleotide and magnesium-nucleotide complexes with the ATP synthase during catalysis of ATP in equilibrium with [32P]Pi exchange and net synthesis of ATP by submitochondrial particles. Concerning the ATP in equilibrium with [32P]Pi exchange reaction, calcium was ineffective as divalent cation when assayed alone. Furthermore, the addition of calcium increased the magnesium concentration required for half-maximal activation of the exchange, without changing Vmax. With respect to net ATP synthesis, the inhibition by calcium was shown to be due to formation of the CaADP- complex, which competes with MgADP- for the active site of the F0F1-ATP synthase. Moreover, ATP hydrolysis was competitively inhibited by CaATP2-, showing that calcium is able to interact with the enzyme in both forward and backward reactions in the same manner. That high calcium concentrations are required for significant inhibition of ATP synthesis indicates that this inhibition is relevant under conditions in which cytosolic calcium concentrations rise to pathological levels. Therefore, this mechanism may be responsible, in part, for the decrease in cellular ATP content that has been observed to occur when calcium accumulates in the cytosol.     

Anion uniport in plant mitochondria is mediated by a Mg(2+)-insensitive inner membrane anion channel.

It has long been established that the inner membrane of plant mitochondria is permeable to Cl-. Evidence has also accumulated which suggests that a number of other anions such as Pi and dicarboxylates can also be transported electrophoretically. In this paper, we present evidence that anion uniport in plant mitochondria is mediated via a pH-regulated channel related to the so-called inner membrane anion channel (IMAC) of animal mitochondria. Like IMAC, the channel in potato mitochondria transports a wide variety of anions including NO3-, Cl-, ferrocyanide, 1,2,3-benzene-tricarboxylate, malonate, Pi, alpha-ketoglutarate, malate, adipate, and glucuronate. In the presence of nigericin, anion uniport is sensitive to the medium pH (pIC50 = 7.60, Hill coefficient = 2). In the absence of nigericin, transport rates are much lower and much less sensitive to pH, suggesting that matrix H+ inhibit anion uniport. This conclusion is supported by measurements of H+ flux which reveal that "activation" of anion transport at high pH by nigericin and at low pH by respiration is associated with an efflux of matrix H+. Other inhibitors of IMAC which are found to block anion uniport in potato mitochondria include propranolol (IC50 = 14 microM, Hill coefficient = 1.28), tributyltin (IC50 = 4 nmol/mg, Hill coefficient = 2.0), and the nucleotide analogs Erythrosin B and Cibacron Blue 3GA. The channel in plant mitochondria differs from IMAC in that it is not inhibited by matrix Mg2+, mercurials, or N,N'-dicyclohexylcarbodiimide. The lack of inhibition by Mg2+ suggests that the physiological regulation of the plant channel may differ from IMAC and that the plant IMAC may have functions such as a role in the malate/oxaloacetate shuttle in addition to its proposed role in volume homeostasis.