Increased permeability of mitochondria during Ca2+ release induced by t-butyl hydroperoxide or oxalacetate. the effect of ruthenium red

Ca2+ release from mitochondria induced by oxalacetate or t-butyl hydroperoxide is accompanied by loss of endogenous Mg2+ and K+, swelling, loss of membrane potential, and other alterations which indicate that Ca2+ release is a result of increased inner membrane permeability. When ruthenium red is added after Ca2+ uptake, but before the releasing agent, the extent of Ca2+ release is diminished as is the extent of Mg2+ and K+ depletion and the extent of swelling. Under these conditions, the membrane potential appears to remain at a high value. When Ca2+ release is induced by oxalacetate or t-butyl hydroperoxide and ruthenium red is added subsequently, an apparent regeneration of membrane potential is observed providing that the associated swelling and Mg2+ loss had not been completed at the time ruthenium red was added. Under these conditions subsequent swelling and Mg2+ loss are inhibited.l Ultrastructural observations show the mitochondria become permeable in response to Ca2+ plus oxalacetate or Ca2+ plus t-butyl hydroperoxide in a heterogeneous manner. Conditions which appear to separate Ca2+ release from a decline in membrane potential or to produce an apparent recovery of membrane potential following partial collapse are shown to prevent a subpopulation of the mitochondria from becoming permeable. It is shown that membrane potential probes will not indicate a decline in potential or the presence of a permeable fraction under these conditions. It is concluded that the presence of Ca2+ accumulation inhibitors does not separate Ca2+ release from the development of increased inner membrane permeability.     

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.     

Respiration-dependent uptake and extrusion of Mg2+ by isolated heart mitochondria

It has been known for some time that isolated heart mitochondria can both take up and extrude Mg2+ by respiration-dependent, uncoupler-sensitive processes. A re-examination of these reactions reveals that the respiration-dependent uptake of Mg2+ can be quite rapid and efficient and is apparently preceded by a passive binding to the inner membrane. The rate of Mg2+ uptake can exceed 30 ng ion/min/mg protein at an efficiency of about 1 ng ion Mg2+ accumulated per ng atom O2 consumed. Passive binding and respiration-dependent accumulation of Mg2+ are strongly inhibited by K+ and other monovalent cations and the uptake reaction is further decreased by the presence of ATP or ADP. Under conditions approaching those faced by mitochondria in situ (state 3 respiration in a KCl medium) the rate of Mg2+ uptake, as estimated from 28Mg2+ distribution, is no more than 0.25 ng ion/min/mg. When heart mitochondria are suspended in a Mg2+-free medium, a slow, respiration-dependent Mg2+ efflux is seen. This reaction is quite insensitive to external K+ and otherwise shows an inhibitor profile markedly different from that of the Mg2+ accumulation reaction. Neither the uptake nor the loss of Mg2+ is inhibited by ruthenium red or diltiazem. These reactions therefore appear unrelated to those involved in the uptake and release of Ca2+. It is concluded that heart mitochondria have separate pathways available for Mg2+ uptake and release.     

Effects of lanthanum on calcium-dependent phenomena in human red cells.

Lanthanum (0.25 mM) does not penetrate into fresh or Mg2+-depleted cells, whereas it does into ATP-depleted or ATP + 2,3-diphosphoglycerate-depleted cells, into cells containing more than 3 mM calcium, or cells stored for more than 4 weeks in acid/citrate/dextrose solution. In fresh cells loaded with calcium, extracellular lanthanum blocks the active Ca2+-efflux completely and inhibits (Ca2+ + Mg2+)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) activity to about 50%. In Mg2+-depleted cells Ca2+-Ca2+ exchange is inhibited by lanthanum. Ca2+-leak is unaffected by lanthanum up to 0.25 mM concentration; higher lanthanum concentrations reduce leak rate. In NaCl medium Ca2+-leak +/ S.D. amounts to 0.28 +/ 0.08 mumol/1 of cells per min, whereas in KC1 medium to 0.15 +/ 0.04 mumol/1 of cells per min at 2.5 mM [Ca2+]e and 0.25 mM [La3+]e pH 7.1. Lanthanum inhibits Ca2+-dependent rapid K+ transport in ATP-depleted and propranolol-treated red cells, i.e. whenever intracellular calcium is below a critical level. The inhibition of the rapid K+ transport can be attributed to protein-lanthanum interactions on the cell surface, since lanthanum is effectively detached from the membrane lipids by propranolol. Lanthanum at 0.2--0.25 mM concentration has no direct effect on the morphology of red cells. The shape regeneration of Ca2+-loaded cells, however, is blocked by lanthanum owing to Ca2+-pump inhibition. Using lanthanum the transition in cell shape can be quantitatively correlated to intracellular Ca2+ concentrations.     

[3H]Noradrenaline Release from Brain Slices Induced by an Increase in the Intracellular Sodium Concentration: Role of Intracellular Calcium Stores

Rat brain slices, prelabeled with [3H]noradrenaline, were superfused and exposed to K+ depolarization (10-120 mM K+) or to veratrine (1-25 microM). In the absence of extracellular Ca2+ veratrine, in contrast to K+-depolarization, caused a substantial release of [3H]noradrenaline, which was completely blocked by tetrodotoxin (0.3 microM). The Ca2+ antagonist Cd2+ (50 microM), which strongly reduced K+-induced release in the presence of 1.2 mM Ca2+, did not affect release induced by veratrine in the absence of extracellular Ca2+. Ruthenium red (10 microM), known to inhibit Ca2+-entry into mitochondria, enhanced veratrine-induced [3H]noradrenaline release. Compared with K+ depolarization in the presence of 1.2 mM Ca2+, veratrine in the absence of Ca2+ caused a somewhat delayed release of [3H]noradrenaline. Further, in contrast to the fractional release of [3H]noradrenaline induced by continuous K+ depolarization in the presence of 1.2 mM Ca2+, that induced by prolonged veratrine stimulation in the absence of Ca2+ appeared to be more sustained. The data strongly suggest that veratrine-induced [3H]noradrenaline release in the absence of extracellular Ca2+ is brought about by a mobilization of Ca2+ from intracellular stores, e.g., mitochondria, subsequent to a strongly increased intracellular Na+ concentration. This provides a model for establishing the site of action of drugs that alter the stimulus-secretion coupling process in central noradrenergic nerve terminals.     

Inhibition of gastric (H+ + K+)-ATPase by unsaturated long-chain fatty acids

Arachidonic acid and unsaturated C18 fatty acids at concentrations near 10(-5) M markedly inhibited (H+ + K+)-ATPase in hog or rat gastric membranes. Arachidonic acid was a more potent inhibitor than unsaturated C18 fatty acids, but the involvement of the metabolites of arachidonic acid cascade was ruled out. Linolenic acid inhibited the formation of phosphoenzyme and the K+ -dependent p-nitrophenylphosphatase activity of the hog ATPase. Treatment with fatty acid-free bovine serum albumin abolished only the inhibitory effect of the fatty acid on the phosphatase activity without restoring the overall ATPase action. These data suggest the existence of at least two groups of hydrophobic binding sites in the gastric ATPase for unsaturated long-chain fatty acids which affect differentially the catalytic reactions of the ATPase. (H+ + K+)-ATPase in rat gastric membranes was found more susceptible to the fatty acid inhibition and also more unstable than the ATPase in hog gastric membranes. The presence of a millimolar level of lanthanum chloride or ethylene glycol bis(beta-aminoethyl ether)-N,N'-tetraacetic acid stabilized the rat ATPase probably via the inhibition of Ca2+ -dependent phospholipases in the gastric membranes.     

The Ba2+ sensitivity of the Na+-induced Ca2+ efflux in heart mitochondria: the site of inhibitory action

The Na+-induced Ca2+ release from rat heart mitochondria was measured in the presence of Ruthenium red. Ba2+ effectively inhibited the Na+-induced Ca2+ release. At 10 mM Na+ 50% inhibition was reached by 1.51 +/- 0.48 (S.D., n = 8) microM Ba2+ in the presence of 0.1 mg/ml albumin and by 0.87 +/- 0.25 (S.D., n = 3) microM Ba2+ without albumin. In order to inhibit, it was not required that Ba2+ ions enter the matrix. 140Ba2+ was not accumulated in the mitochondrial matrix space; further, in contrast to liver mitochondria, Ba2+ inhibition was immediate. The Na+-induced Ca2+ release was inhibited by Ba2+ non-competitively, with respect of the extramitochondrial Na+. The double inhibitor titration of the Na+-Ca2+ exchanger with Ba2+ in the presence and absence of extramitochondrial Ca2+ revealed that the exchanger possesses a common binding site for extramitochondrial Ca2+ and Ba2+, presumably the regulatory binding site of the Na+-Ca2+ exchanger, which was described by Hayat and Crompton (Biochem. J. 202 (1982) 509-518). All these observations indicate that Ba2+ acts at the cytoplasmic surface of the inner mitochondrial membrane. The inhibitory properties of Ba2+ on the Na+-dependent Ca2+ release in heart mitochondria are basically different from those found on Na+-independent Ca2+ release in liver mitochondria (Lukács, G.L. and Fonyó, A. (1985) Biochim. Biophys. Acta 809, 160-166).     

Studies on the efflux of metalloporphyrin from rat liver mitochondria. Effect of K+ and other cations.

The mechanism by which metalloporphyrins synthesized within the mitochondria escape to the incubation medium was studied in isolated rat liver mitochondria. In a low-ionic-strength sucrose medium, the efflux of metalloporphyrins is markedly decreased when K+ (greater than 10 mM) is added. The effect of K+ is not dependent on the energy state of the mitochondria and it can in part be abolished by adding globin, but not albumin. K+ also decreases the uptake of porphyrins by the mitochondria and thereby the rate of synthesis of metalloporphyrins. Qualitatively similar results are found with Na+, Li+, Mg2+ and Ca2+. Quantitatively, however, the efficiency of cations to inhibit the release of metalloporphyrins decreases in the order: Mg2+ greater than Ca2+ greater than K+ greater than Li+ greater than Na+. Co-protoporhyrin behaves essentially as Co-deuteroporphyrin. The results provide further evidence that the efflux of metalloporphyrins from the mitochondria depends on haem-binding ligands of the suspending medium and also on the ionic strength of the incubation medium.     

Regulation of Ca2+ efflux from kidney and liver mitochondria by unsaturated fatty acids and Na+ ions.

The effects of fatty acids and monovalent cations on the Ca2+ efflux from isolated liver and kidney mitochondria were investigated by means of electrode techniques. It was shown that unsaturated fatty acids and saturated fatty acids of medium chain length (C12 and C14) induced a Ca2+ efflux from mitochondria which was not inhibited by ruthenium red, but was specifically inhibited by Na+ and Li+. The Ca2+-releasing activity of unsaturated fatty acids did not correlate with their uncoupling activity. In kidney mitochondria a spontaneous, temperature-dependent Ca2+ efflux was observed which was inhibited either by albumin or by Na+. It is suggested that the net Ca2+ accumulation by mitochondria depends on the operation of independent pump and leak pathways. The pump is driven by the membrane potential and can be inhibited by ruthenium red, the leak depends on the presence of unsaturated fatty acids and is inhibited by Na+ and Li+. It is suggested that the unsaturated fatty acids produced by mitochondrial phospholipase A2 can be essential in the regulation of the Ca2+ retention in and the Ca2+ release from the mitochondria.     

Mitochondrial bioenergetics during the initiation of mercuric chloride-induced renal injury. I. Direct effects of in vitro mercuric chloride on renal mitochondrial function

Increasing data suggest that mitochondrial dysfunction may be an important early component of nephrotoxin-induced changes in renal cell function and viability. This study was designed to obtain more detailed information about the effects on several basic bioenergetic parameters of the direct interaction of Hg2+ with renal cortical mitochondria in vitro as a necessary prelude to studies of mitochondrial functional changes after treatment with mercuric chloride in vivo. Beginning at a threshold level of 2 nmol of Hg2+/mg of mitochondrial protein, Hg2+ induced marked stimulation of State 4 respiration, mild inhibition of State 3 respiration, and 2,4-dinitrophenol uncoupled respiration, a striking increase in atractyloside-insensitive ADP uptake and stimulation of both basal- and Mg2+-activated oligomycin-sensitive mitochondrial ATPase activity. These effects of Hg2+ could be prevented and reversed by the sulfhydryl reagent dithioerythritol and by albumin but were not affected by Mg2+. Detailed studies on the addition of HgCl2 to the preparation at different stages of the mitochondrial isolation procedure demonstrated that the presence of other proteins decreased mitochondrial Hg2+ binding, that the Hg2+ was not readily washed off the mitochondria by nonprotein-containing solutions, and that prolonged exposure of mitochondria to Hg2+ during the isolation procedure did not markedly alter its functional effects or their reversibility as assessed on the final mitochondrial preparation. These data provide an important basis for critically assessing the changes in function of mitochondria isolated after in vivo treatment with mercuric chloride.     

Relationships between Ca2+ release, Ca2+ cycling, and Ca2+-mediated permeability changes in mitochondria

Ruthenium red and/or EGTA prevent cyclic uptake and release of Ca2+ in mitochondria. These compounds inhibit but do not prevent the swelling of liver mitochondria induced by Ca2+ plus t-butyl hydroperoxide or Ca2+ plus N-ethylmaleimide. Ruthenium red and/or EGTA have complex effects on the release rate of Ca2+ and other cations induced by t-butyl hydroperoxide or N-ethylmaleimide. To determine the relationship between permeability changes and Ca2+ release in the absence of Ca2+ cycling, a novel method of data collection and analysis is developed which allows the relative time courses of Ca2+ release and Mg2+ release or swelling to be accurately and quantitatively compared. This method eliminates errors in time course comparisons which arise from the aging of mitochondrial preparations and allows data from different preparations to be directly contrasted. Using the method, it is shown that permeability changes caused by Ca2+-releasing agents are not secondary effects arising from Ca2+ cycling between uptake and release carriers. In the absence of Ca2+-cycling inhibitors, Ca2+ release induced by t-butyl hydroperoxide or N-ethylmaleimide is, in part, carrier-mediated. In the presence of EGTA and ruthenium red, Ca2+ release induced by either agent is mediated solely by the permeability pathway. No differences are apparent in the solute selectivity of the inner membrane permeability defect induced by Ca2+ plus t-butyl hydroperoxide or Ca2+ plus N-ethylmaleimide. A novel type of Ca2+ release from energized liver mitochondria is reported. This release is induced by EGTA, occurs in the absence of other releasing agents or nonspecific permeability changes, and is rapid (greater than or equal to 50 nmol/min/mg protein).     

The effect of extracellular Ca and Mg on mitochondrial ultrastructure in isolated intact neurons

The ultrastructural transformations of mitochondria in isolated crayfish neurons were studied after incubation of the cells in saline media containing different Ca2+ and Mg2+ concentrations. Incubation in a 5-fold higher Ca concentration resulted in the swelling of mitochondria that was prevented by the addition of the calcium channel blocker, verapamil. Exposure of the cells to Mg2+-depleted medium induced swelling of all the mitochondria, followed by substantial shrinkage of most of them. The absence of Ca as well as the presence of verapamil in Mg2+-free medium led to the inhibition of mitochondrial swelling and to a strong contraction of the mitochondria after 1 h incubation. The omission of Ca2+ from the saline medium or the addition of Ca2+-ionophore A23187 in the presence of Ca2+ resulted in strong mitochondrial shrinkage. These structural alterations of mitochondria are interpreted as an osmotic response of the inner mitochondrial membranes to changes in their potassium transport, induced by a disturbance in the cellular and mitochondrial Ca2+-Mg2+ homeostasis.     

Rapid filtration studies of Ca2+-induced Ca2+ release from skeletal sarcoplasmic reticulum. Role of monovalent ions

We have developed a rapid filtration technique for the measurement of Ca2+ release from isolated sarcoplasmic reticulum vesicles. Using this technique, we have studied the Ca2+-induced Ca2+ release of sarcoplasmic reticulum vesicles from rabbit skeletal muscle passively loaded with 5 mM Ca2+. The effect of known effectors (adenine nucleotides and caffeine) and inhibitors (Mg2+ and ruthenium red) of this release were investigated. In a medium composed of 100 mM KCl buffered at pH 6.8 with 20 mM K/3-(N-morpholino)propanesulfonic acid the Ca2+ release rate was maximal (500 nmol of Ca2+ released.(mg of protein)-1.s-1) at 1 micron external Ca2+ and 5 mM ATP. We also observed a rapid Ca2+ release induced by micromolar Ag+ in the presence of ATP (at 1 nM Ca2+). The Ag+-induced Ca2+ release was totally inhibited by 5 micron ruthenium red. We have also investigated the effect of monovalent ions on the Ca2+ release elicited by Ca2+ or Ag+. We show that the Ca2+ release rate: 1) was dependent upon the presence of K+ or Na+ in the release medium and 2) was influenced by a K+ gradient created across the sarcoplasmic reticulum membrane. These results directly support the idea of the involvement of an influx of K+ (through K+ channels) during the Ca2+ release and allow to reconsider a possible influence of the membrane potential of the sarcoplasmic reticulum on the Ca2+ release.     

Uncoupler-stimulated release of Ca2+ from Ehrlich ascites tumor cell mitochondria

Ruthenium red-insensitive, uncoupler-stimulated release of Ca2+ from Ehrlich ascites tumor cell mitochondria is much slower than from rat liver mitochondria under comparable conditions. In the presence of Pi and at moderate or high Ca2+ loads, ruthenium red-insensitive Ca2+ efflux elicited with uncoupler is approximately 20 times more rapid for rat liver than Ehrlich cell mitochondria. This is attributed to resistance of tumor mitochondria to damage by Ca2+ due to a high level of endogenous Mg2+ that also attenuates Ca2+ efflux. Calcium release from rat liver and tumor mitochondria is inhibited by exogenous Mg2+. This applies to ruthenium red-insensitive spontaneous Ca2+ efflux associated with Ca2+ uptake and uncoupling, and (b) ruthenium red-insensitive Ca2+ release stimulated by uncoupling agent. The endogenous Mg2+ level of Ehrlich tumor mitochondria is approximately three times that of rat liver mitochondria. Endogenous Ca2+ is also much greater (six fold) in Ehrlich tumor mitochondria compared to rat liver. Despite the quantitative difference in endogenous Mg2+, the properties of internal Mg2+ are much the same for rat liver and Ehrlich cell mitochondria. Ehrlich ascites tumor mitochondria exhibit slow, metabolically dependent Mg2+ release and rapid limited release of Mg2+ during Ca2+ uptake. Both have been observed with rat liver and other types of mitochondria. The proportions of apparently "bound" and "free" Mg2+ (inferred from release by the ionophore, A23187) do not differ significantly between tumor and liver mitochondria. Thus, the endogenous Mg2+ of tumor mitochondria has no unusual features but is simply elevated substantially. Ruthenium red-insensitive Ca2+ efflux, when expressed as a function of the intramitochondrial Ca2+/Mg2+ ratio, is quite similar for tumor and rat liver. It is proposed, therefore, that endogenous Mg2+ is a major regulatory factor responsible for differences in the sensitivity to damage by Ca2+ and Ca2+ release by Ehrlich ascites tumor mitochondria compared to mitochondria from normal tissues.     

Na+-dependent regulation of extramitochondrial Ca2+ by rat-liver mitochondria

The presence and significance of Na+-induced Ca2+ release from rat liver mitochondria was investigated by the arsenazo technique. Under the experimental conditions used, the mitochondria, as expected, avidly extracted Ca2+ from the medium. However, when the uptake pathway was blocked with ruthenium red, only a small rate of 'basal' release of Ca2+ was seen (0.3 nmol Ca2+ X min-1 X mg-1), in marked contrast to earlier reports on a rapid loss of sequestered Ca2+ from rat liver mitochondria. The addition of Na+ in 'cytosolic' levels (20 mM) led to an increase in the release rate by about 1 nmol Ca2+ X min-1 X mg-1. This effect was specific for Na+. The significance of this Na+-induced Ca2+ release, in relation to the Ca2+ uptake mechanism, was investigated (in the absence of uptake inhibitors) by following the change in the extramitochondrial Ca2+ steady-state level (set point) induced by Na+. A five-fold increase in this level, from less than 0.2 microM to more than 1 microM, was induced by less than 20 mM Na+. The presence of K+ increased the sensitivity of the Ca2+ homeostat to Na+. The effect of Na+ on the extramitochondrial level was equally well observed in an K+/organic-anion buffer as in a sucrose buffer. Liver mitochondria incubated under these circumstances actively counteracted a Ca2+ or EGTA challenge by taking up or releasing Ca2+, so that the initial level, as well as the Na+-controlled level, was regained. It was concluded that liver mitochondria should be considered Na+-sensitive, that the capacity of the Na+-induced efflux pathway was of sufficient magnitude to enable it to influence the extramitochondrial Ca2+ level biochemically and probably also physiologically, and that the mitochondria have the potential to act as active, Na+-dependent regulators of extramitochondrial ('cytosolic') Ca2+. It is suggested that changes of cytosolic Na+ could be a mediator between certain hormonal signals (notably alpha 1-adrenergic) and changes in this extramitochondrial ('cytosolic') Ca2+ steady state level.     

Ca2+-Mg2+-ATPase activity in brain coated microvesicles purified on immunosorbents

Coated microvesicle fractions isolated from ox forebrain cortex by the ultracentrifugation procedure of Pearse (1) and by the modified, less time consuming method of Keen et al (2) had comparable Ca2+ +Mg2+ dependent ATPase activities (about 9 mumol/h per mg protein). The Na+ +K+ +Mg2+ dependent ATPase activity was 3.2 mumol/h per mg (+/- 1.0, S.D., n = 3) when microvesicles were prepared according to (1) and 1.5 mumol/h per mg (+/- 1.0, S.D., n = 3) when prepared according to (2). Oligomycin, ruthenium red, and trifluoperazine, inhibitors of Ca2+ transport in mitochondria and erythrocyte membranes had no effect on Ca2+ +Mg2+ dependent ATPase from any of the preparations. As demonstrated both by ATPase assays and electron microscopy, coated microvesicles could be bound to immunosorbents prepared with poly-specific antibodies against a coated microvesicle fraction obtained by the method of Pearse (1). The binding could be inhibited by dissolved coat protein using partially purified clathrin. The fraction of coated vesicles eluted from the immunosorbent was purified relative to the starting material as judged by electron microscopy. The Ca2+ +Mg2+ ATPase activity and calmodulin content was copurified with the coated microvesicles and the specific activity of Na+ +K+ +Mg2+ ATPase was decreased. Na+ +K+ +Mg2+ dependent ATPase activity in the coated microvesicle fraction could be ascribed to membranes with the appearance of microsomes. These membranes were also bound to the immunosorbents, but the binding was not influenced by clathrin. The capacity of the immunosorbents for these membranes was less than for the coated microvesicles, resulting in a decrease of Na+ +K+ +Mg2+ dependent ATPase activity in the eluted coated microvesicle fraction. It was concluded that Ca2+ +Mg2+ ATPase activity is not a contamination from plasma membrane vesicles or mitochondrial membranes but seems to be an integral part of the coated vesicle membrane.     

Kinetics of Mg2+ flux into rat liver mitochondria.

Unidirectional fluxes of Mg2+ across the limiting membranes of rat liver mitochondria have been measured in the presence of the respiratory substrate succinate by means of the radioisotope 28Mg. Rates of both influx and efflux of Mg2+ are decreased when respiration is inhibited. A linear dependence of the reciprocal of the Mg2+ influx rate on the reciprocal of the Mg2+ concentration is observed. The apparent Km for Mg2+ averages about 0.7 mM. N-Ethyl-maleimide, an inhibitor of transmembrane phosphate-hydroxyl exchanges, enhances the observed pH dependence of Mg2+, influx. In the presence of MalNEt, the apparent Vmax of Mg2+ influx is greater at pH 8 than at pH 7, and there is a linear dependence of the Mg2+ influx rate on the external OH- concentration. The K+ analogue Tl+ inhibits Mg2+ influx, while La3+, an inhibitor of mitochondrial Ca2+ transport, has no effect on Mg2+ influx. Mg2+ competitively inhibits the flux of K+ into rat liver mitochondria. The mechanism(s) mediating mitochondrial Mg2+ and K+ fluxes appear to be similar in their energy dependence, pH dependence, sensitivity to Tl+, and insensitivity to La3+.     

Cyclosporin A-insensitive permeability transition in brain mitochondria: inhibition by 2-aminoethoxydiphenyl borate

The mitochondrial permeability transition pore (PTP) may operate as a physiological Ca2+ release mechanism and also contribute to mitochondrial deenergization and release of proapoptotic proteins after pathological stress, e.g. ischemia/reperfusion. Brain mitochondria exhibit unique PTP characteristics, including relative resistance to inhibition by cyclosporin A. In this study, we report that 2-aminoethoxydiphenyl borate blocks Ca2+-induced Ca2+ release in isolated, non-synaptosomal rat brain mitochondria in the presence of physiological concentrations of ATP and Mg2+. Ca2+ release was not mediated by the mitochondrial Na+/Ca2+ exchanger or by reversal of the uniporter responsible for energy-dependent Ca2+ uptake. Loss of mitochondrial Ca2+ was accompanied by release of cytochrome c and pyridine nucleotides, indicating an increase in permeability of both the inner and outer mitochondrial membranes. Under these conditions, Ca2+-induced opening of the PTP was not blocked by cyclosporin A, antioxidants, or inhibitors of phospholipase A2 or nitric-oxide synthase but was abolished by pretreatment with bongkrekic acid. These findings indicate that in the presence of adenine nucleotides and Mg2+,Ca2+-induced PTP in non-synaptosomal brain mitochondria exhibits a unique pattern of sensitivity to inhibitors and is particularly responsive to 2-aminoethoxydiphenyl borate.     

Inhibition of red cell Ca2+-ATPase by vanadate

1. The Mg2+- plus Ca2+-dependent ATPase (Ca2+-ATPase) in human red cell membranes is susceptible to inhibition by low concentrations of vanadate. 2. Several natural activators of Ca2+-ATPase (Mg2+, K+, Na+ and calmodulin) modify inhibition by increasing the apparent affinity of the enzyme for vanadate. 3. Among the ligands tests, K+, in combination with Mg2+, had the most pronounced effect on inhibition by vanadate. 4. Under conditions optimal for inhibition of Ca2+-ATPase, the K 1/2 for vanadate was 1.5 microM and inhibition was nearly complete at saturating vanadate concentrations. 5. There are similarities between the kinetics of inhibition of red cell Ca2+-ATPase and (Na+ + K+)-ATPase prepared from a variety of sources; however, (Na+ + K+)-ATPase is approx. 3 times more sensitive to inhibition by vanadate.     

Effects of sulfhydryl reagents and other inhibitors on Ca2+ transport and inositol trisphosphate-induced Ca2+ release from human platelet membranes

The effects of modifiers of Ca2+ uptake and release in sarcoplasmic reticulum were studied in human platelet membranes. AgNO3,p-chloromercuribenzoate (pClHgBzO), N-ethylmaleimide (MalNEt), quercetin, vanadate, A23187, and caffeine all had the same effects on Ca2+ uptake in platelet membranes as had been observed for sarcoplasmic reticulum. These results strengthen our earlier conclusion that the Ca2+-pump proteins from internal human platelet membranes and muscle sarcoplasmic reticulum are very similar in functional properties. The sulfhydryl reagents Ag+ and pClHgBzO elicited rapid release of Ca2+ from platelet membranes in the presence of ATP, whereas MalNEt induced slow release. Quercetin also caused slow release of Ca2+ from platelet membranes in the presence of ATP. The effects of all three sulfhydryl reagents could be reversed by dithiothreitol, and Ag+-induced release was also reversed by ruthenium red. These effects are similar to those observed in sarcoplasmic reticulum, but in contrast caffeine did not induce Ca2+ release. In the absence of ATP, passively loaded platelet membranes did not release Ca2+ when exposed to sulfhydryl reagents. However, AgCl and pClHgBzO inhibited inositol trisphosphate (InsP3)-induced Ca2+ release from platelet membranes and this effect was reversed by dithiothreitol. Ruthenium red also inhibited InsP3-induced release, but ATP was found not to be required for InsP3-mediated release. LiCl enhanced Ca2+ release from platelet membranes. These results demonstrate that the InsP3-gated Ca2+ release channel is a separate entity from the Ca2+-pump and that essential protein sulfhydryls are involved in the release process.