Synergic action of calcium ions and diamide on mitochondrial swelling

Characteristics of Ca2+ transport by Trypanosoma cruzi mitochondria in situ

The use of digitonin to permeabilize Trypanosoma cruzi plasma membrane has allowed the study of Ca2+ transport and oxidative phosphorylation in mitochondria in situ (R. Docampo and A. E. Vercesi (1989) J. Biol. Chem. 264, 108-111). The present results show that these mitochondria are able to build up and retain a membrane potential as indicated by a tetraphenylphosphonium-sensitive electrode. Ca2+ uptake caused membrane depolarization compatible with the existence of an electrogenically mediated Ca2+ transport mechanism in these mitochondria. Addition of Ca2+ or ethylene glycol bis (beta-aminoethyl ether) N-N'-tetraacetic acid to these preparations under steady-state conditions was followed by Ca2+ uptake or release, respectively, tending to restore the original Ca2+ "set point" at about 0.9 microM. In addition, large amounts of Ca2+ were retained by T. cruzi mitochondria even after addition of thiols and NAD(P)H oxidants such as t-butyl hydroperoxide, diamide, and the 1,2-naphthoquinone beta-lapachone. However, when ascorbate plus N,N,N',N'-tetramethyl-p-phenylenediamine in the presence of antimycin A was used as subtrate, beta-lapachone caused pyridine nucleotide oxidation, and Ca2+ accumulation by these mitochondria was considerably lower than in control preparations, this effect being dose-dependent.

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.

Restoration of membrane potential in mitochondria deenergized with carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP)

The membrane potential (delta psi) of rat liver mitochondria dropped upon addition of carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) but was gradually and fully restored to the original value by the subsequent addition of dithioerythritol. Concomitantly, Ca2+ released from mitochondria was reaccumulated and the oxidative phosphorylation process completely recoupled. Neither of these effects has been observed with dinitro-o-cresol or 2,4-dinitrophenol, uncouplers which, unlike FCCP, do not react with thiols. Delta psi abolished by FCCP was also restored, though incompletely, by albumin; a prompt and complete restoration was however achieved upon subsequent addition of dithioerythritol. Dithioerythritol also completely and rapidly restored the delta psi decreased by addition of diazene dicarboxylic acid bisdimethylamide (diamide).

The effect of superoxide generation on the ability of mitochondria to take up and retain Ca2+

When heart or liver mitochondria are exposed to superoxide radicals generated from xanthine + xanthine oxidase their ability to take up and to retain Ca2+ is impaired. The rate of oxidation of pyruvate + malate as substrates is diminished and the appearance of thiol groups when the mitochondria are supplied with these substrates is abolished. These inhibitory effects are offset if respiration is supported by succinate in presence of rotenone provided that a substrate (beta-hydroxybutyrate) is provided to maintain the reduction of NADH. The data agree with the thesis that a generation of thiol groups is essential to maintain membrane integrity and that the generation depends on provision of reduced NAD(P)H.

Diamide, temperature and spontaneous transmitter release at the neuromuscular junction: stimulation of exocytosis by a direct effect on membrane fusion?

The thiol-oxidizing agent diamide markedly increases m.e.p.p. frequency at the frog neuromuscular junction, even at low [Ca2+]0 and also when the mitochondria are uncoupled with DNP. The effect is reversed by dithioerythritol and is very temperature-sensitive, with a marked transition at 16 degrees C; m.e.p.p. frequency is raised 2- to 5-fold at 13-15 degrees C and 55- to 60-fold at 17-20 degrees C. Diamide increases the frequency of large amplitude m.e.p.p.s, the effect being explicable as the fusion of two or more vesicles. It is concluded that (a) diamide does not act at the Ca2+ channels of the plasma membrane, nor at the mitochondria. It affects the release system directly via an alteration of membrane protein --SH groups; (b) the eventual decline in m.e.p.p. frequency after DNP treatment is because of the exhaustion of mitochondrial Ca2+ rather than a depletion of quanta; (c) the major effect of temperature is on the release mechanism, perhaps via a phase-change in the phospholipoproteins of the plasmalemma or vesicles, rather than an elevation of [Ca2+]i; (d) either diamide or temperatures above 16 degrees C make Ca2+ more effective in promoting vesicle-plasmalemma fusion.

Correlated effluxes of adenine nucleotides, Mg2+ and Ca2+ induced in rat-liver mitochondria by external Ca2+ and phosphate

The presence of inorganic phosphate and Ca2+ in the external medium induces a closely parallel efflux of both endogenous adenine nucleotides and Mg2+ from rat liver mitochondria. These effluxes are (a) pH-dependent and inhibited by uncouplers, respiration inhibitors and external Mg2+; (b) completely prevented by bongkrekate, but stimulated by atractylate. ATP, ADP or AMP each inhibit the release of Mg2+ promoted by Ca2+ and phosphate; however, in the presence of oligomycin and P1,P5-di(adenosine-5')-pentaphosphate (an inhibitor of adenylate kinase) only ADP is effective. Also the release of accumulated Ca2+ observed when approximately 50% Mg2+ is discharged is retarded by bongkrekate and added Mg2+ whereas it is accelerated by atractylate. All adenine nucleotides have a significant effect in retarding the efflux of accumulated Ca2+ but, in the presence of oligomycin and P1,P5-di(adenosine-5')-pentaphosphate, only ADP is active. From these results we conclude that effluxes of Mg2+, Ca2+ and adenine nucleotide from rat liver mitochondria induced by external phosphate are interconnected and regulated by external ADP and Mg2+ levels.

The effect of diamide on amino acid transport by rat renal cortex slices

Diamide directly added to renal cortical slices inhibits the uptake of amino acids. Steady-state kinetic analysis indicates an inhibition of alpha-amino acid influx without effect on efflux. The effect could be reversed by addition of pyruvate to the incubation medium. Although there was a good correlation of the transport effect of diamide with its ability to decrease cellular reduced glutathione concentration, there did not appear to be a necessary connection between them. This was shown by the fact that renal cortical slices stored at 4 degrees C have no alteration in amino acid uptake despite the fact that GSH concentration is as low as that seen with diamide. Diamide was shown to have a direct effect on the uptake of glycine by isolated renal brush border membrane vesicles.

The reduction of diamide by rat liver mitochondria and the role of glutathione

Diamide is reduced by mitochondria utilizing endogenous substrates with Vmax. 20nmol/min per mg of protein and Km 75micrometer. The reaction is inhibited by: (a) thiol-blocking reagents (N-ethylmaleimide, p-hydroxymercuribenzoate, mersalyl and 2,6-dichlorophenol-indophenol);(b) respiratory inhibitors (arsenicals, malonate and antimycin, but not cyanide or oligomycin; inhibition by antimycin is reversed by ATP); (c) uncouplers (carbonyl cyanide p-trifluoromethoxyphenylhydrazone, 2,4-dinitrophenol and valinomycin with K+; inhibition by the first of these uncouplers is not reversed by cyanide); (d) reagents affecting energy conservation (Ca2+, increasing pH, phosphate; phosphate inhibition is augmented by catalytic ADP or ATP and augmentation is abolished by respiratory inhibitors). Concentrations of mitochondrial glutathione are high when diamide reduction is uninhibited, but low after adding one of the above inhibitors such that the reduction rate is roughly proportional to the glutathione concentration. Endogenous ATP concentrations are lower in the presence of diamide than without, but the difference is abolished by respiratory inhibitors. With oligomycin added, however, ATP concentrations are higher in the presence of diamide and this positive increment is decreased by antimycin, N-ethylmaleimide and malonate. In the presence of diamide and an uncoupler, the mitochondrial glutathione content does not fall if various reducible substrates are present, although the inhibition of diamide reduction is not relieved. Some of these substrates prevent the fall in reduced glutathione concentration found with diamide and phosphate. They also relieve the inhibition of diamide reduction and the relief is sensitive to butylmalonate. The inhibition of diamide reduction by N-ethylmaleimide, mersalyl or p-hydroxymercuribenzoate is not relieved by reducible substrates, but the latter mitigate the fall in the concentration of glutathione. Inhibitors of carriers of tricarboxylic acid-cycle intermediates also inhibit reduction of diamide. The reduced glutathione concentration remains high when they are added singly, but falls when two of them are combined. It is proposed that diamide may enter the matrix as a protonated adduct formed with the thiol groups of mitochondrial carriers and then be reduced in the matrix by glutathione, which is regenerated via NADH, energy-dependent transhydrogenase and NADP+-specific glutathione reductase. Some of the high-energy equivalents required for the transhydrogeneration may be generated by the substrate phosphorylation step of the tricarboxylic acid cycle.

Electric hysteresis and mitochondrial incorporation of RNAs from different sources

The paper reports the characteristics of four different RNAs from yeast, Torula and calf thymus of molecular weight ranging between 15,000 and 30,000. The gel-filtration behaviour with aqueous and partially qqueous solvents is studied together with the response of the four RNAs to static electric fields of strength ranging between 20 and 35 kV/cm. The relationship between molecular weight and extent of electric hysteresis is linear for all RNAs, while tRNA slightly deviates from such a relationship. The ability of the RNAs to permeate biological mebranes or bind membrane components such as lecithins is studied with rat liver mitochondria and a two-phase system with egg lecithin dissolved in the organic phase and RNA in the aqueous one. There is no apparent relationship between molecular weight of the RNAs and their ability to interact with biological membranes.

Efflux of magnesium and potassium ions from liver mitochondria induced by inorganic phosphate and by diamide

Addition to rat liver mitochondria of 2 mM inorganic phosphate or 0.15 mM diamide, a thiol-oxidizing agent, induced an efflux of endogenous Mg2+ linear with time and dependent on coupled respiration. No net Ca2+ release occurred under these conditions, while a concomitant release of K+ was observed. Mg2+ efflux mediated either by Pi or low concentration of diamide was completely prevented by EGTA, Ruthenium red, and NEM. These reagents also inhibited the increased rate of state 4 respiration induced both by Pi and diamide. At higher concentrations (0.4 mM), diamide induced an efflux of Mg2+ which was associated also with a release of endogenous Ca2+. Under these conditions EGTA completely prevented Mg2+ and K+ effluxes, while they were only partially inhibited by Ruthenium red and NEM. It is assumed that Mg2+ efflux, occurring at low diamide concentrations or in the presence of phosphate, is dependent on a cyclic in-and-out movement of Ca2+ across the inner mitochondrial membrane, in which the passive efflux is compensated by a continuous energy linked reuptake. This explains the dependence of Mg2+ efflux on coupled respiration, as well as the increased rate of state 4 respiration. The dependence of Mg2+ efflux on phosphate transport is explained by the phosphate requirement for Ca2+ movement.