ADP and Mg2+ requirement for Ca2+ accumulation by hog heart mitochondria. Correlation with energy coupling

Kinetic evidence for a heart mitochondrial pore activated by Ca2+, inorganic phosphate and oxidative stress. A potential mechanism for mitochondrial dysfunction during cellular Ca2+ overload

Evidence that the Ca2+-induced permeabilization of mitochondria is attributable to a reversible Ca2+-activated pore [Al Nasser & Crompton (1986) Biochem. J. 239, 19-29] has been further investigated. Permeabilization is induced in a wholly synergistic manner by either Ca2+ plus phosphate or Ca2+ plus tert-butyl hydroperoxide. When permeabilization is complete, extramitochondrial [14C]sucrose equilibrates with the matrix space with a half-time of about 800 ms; [14C]mannitol equilibrates at least threefold faster. Permeabilization is essentially fully reversed on Ca2+ chelation with EGTA, when the half time for [14C]sucrose equilibration is increased 600-1400-fold (to 550-1150 s). A pulsed-flow [14C]solute-entrapment technique has been developed to measure the kinetics of EGTA-induced resealing. The technique incorporates a suitable choice of [14C]solute and an appropriate model for data analysis, and is competent to measure permeation state changes occurring in 100 ms. The data obtained are consistent with exponential resealing of mitochondria in which pores of any single mitochondria close with a high degree of synchrony. The rate of resealing is increased about eight-fold by ADP (half-time approximately 1 s; Km approximately 30 microM). CoA, Mg2+, AMP and also ATP, when account is taken of ADP arising by hydrolysis, are essentially ineffective. It is concluded that heart mitochondria do contain a pore whose permeation state is controlled over an approximate 1000-fold range by Ca2+ and other factors including phosphate, oxidative stress and ADP. The possible involvement of the pore in reoxygenation-induced injury in heart is discussed.

The entrapment of the Ca2+ indicator arsenazo III in the matrix space of rat liver mitochondria by permeabilization and resealing. Na+-dependent and -independent effluxes of Ca2+ in arsenazo III-loaded mitochondria

The permeabilization-resealing technique [Al-Nasser & Crompton, Biochem. J. (1986) 239, 19-29] has been applied to the entrapment of arsenazo III in the matrix compartment of rat liver mitochondria. The addition of 10 mM-arsenazo III to mitochondria permeabilized with Ca2+ partially restores the inner-membrane potential (delta psi) and leads to the recovery of 3.9 nmol of arsenazo III/mg of protein in the matrix when the mitochondria are washed three times. The recovery of entrapped arsenazo III is increased 2-fold by 4 mM-Mg2+, which also promotes repolarization. ATP with or without Mg2+ decreased arsenazo III recovery. Under all conditions, less arsenazo III than [14C]sucrose is entrapped, in particular in the presence of ATP. The amount of arsenazo III entrapped is proportional to the concentration of arsenazo III used as resealant, and is equally distributed between heavy and light mitochondria. Arsenazo III-loaded permeabilized and resealed (PR) mitochondria develop delta psi values of 141 +/- 3 mV. PR mitochondria retain arsenazo III and [14C]sucrose for more than 2 h at 0 degrees C. At 25 degrees C, and in the presence of Ruthenium Red, PR mitochondria lose arsenazo III and [14C]sucrose at equal rates, but Ca2+ efflux is more rapid; this indicates that Ca2+ is released by an Na+-independent carrier in addition to permeabilization. The Na+/Ca2+ carrier of PR mitochondria is partially (60%) inhibited by extramitochondrial free Ca2+ stabilized with Ca2+ buffers; maximal inhibition is attained with 2 microM free Ca2+. A similar inhibition occurs in normal mitochondria with 3.5 nmol of matrix Ca2+/mg of protein, but the inhibition is decreased by increased matrix Ca2+. The data suggest the presence of Ca2+ regulatory sites on the Na+/Ca2+ carrier that change the affinity for matrix free Ca2+.

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.

Mitochondrial calcium transport and calcium-activated phospholipase in porcine malignant hyperthermia

The interaction of Ca2+ with mitochondria isolated from longissismus dorsi, a predominantly white skeletal muscle, of normal and malignant hyperthermia pigs was investigated using tightly-coupled preparations. Arrhenius plots of mitochondrial Ca2+ -stimulated respiration for succinate oxidation of malignant hyperthermia pigs showed a transition temperature (Tt) of 26.31 +/- 0.80 degrees C (n = 5), which was decreased by spermine to 15.41 +/- 0.69 degrees C (n = 3), a value very similar to that for normal pigs. No difference in either the Tt or in the activation energy (Ea) was observed between the two types of pigs when ADP was used instead of Ca2+. Mitochondria of malignant hyperthermia pigs were uncoupled at 40 degrees C by exogenous Ca2+ at 1221 +/- 301 (n = 9) nmol Ca2+ per mg proteinn during succinate oxidation and the uncoupled mitochondria showed large amplitude swelling. Both the Ca2+ -induced uncoupling and swelling were prevented by bovine serum albumin and by the phospholipase inhibitors, spermine and tetracaine. In contrast, mitochondria of normal pigs were still tightly coupled even after a total addition of 2313 +/- 287 (n = 5) nmol Ca2+ per mg protein and retained the original condensed configuration in the presence or absence of spermine and tetracaine. Mitochondria of malignant hyperthermia pigs contained significantly (P less than 0.001) higher quantities of endogenous Ca2+ and showed a significantly (P less than 0.001) faster FCCP-induced endogenous Ca2+ efflux rate than normal when monitored spectroscopically with murexide. No significant difference was observed in either the rate of exogenous Ca2+ uptake or in the extent of Ca2+ accumulated in the aerobic steady state during succinate oxidation between the two types of pigs. The rate of mitochondrial Ca2+ efflux of malignant hyperthermia pigs during anaerobiosis was about twice that of normal. Experimental evidence suggests that mitochondria from musculi longissimus dorsi of malignant hyperthermia pigs contained a Ca2+ -stimulated phospholipase A2 (EC 3.1.1.4, phosphatide 2-acylhydrolase), and that this enzyme if present in mitochondria of normal pigs is either latent or in very low concentration. The significance of the Ca2+ -stimulated phospholipase A2 and its association with the enhanced rate of glycolysis in porcine malignant hyperthermia syndrome and in the post-mortem formation of the pale, soft and exudative conditions observed in white skeletal muscles of malignant hyperthermia pigs is discussed.

Steady state regulation of extramitochondrial Ca2+ by rat liver mitochondria: effects of Mg2+ and ATP

An electrode-based system capable of monitoring ionized Ca2+ concentrations ([Ca2+]) < 1 microM was used to examine the regulation of extramitochondrial [Ca2+] by rat liver mitochondria. At the point of steady state balance between Ca2+ uptake and release, [Ca2+] ranged between 0.5 and 1.0 microM in a KCl/Hepes/succinate medium. When 1 mM Mg2+ was included in this basal medium, the range of steady state [Ca2+] values was 1-2 microM. Further additions (3 mM MgATP and 2 mM Pi) lowered extramitochondrial [Ca2+] to 0.4-0.8 microM. Thus under experimental conditions simulating the control of cytosolic [Ca2+], liver mitochondria buffered extramitochondrial [Ca2+] at constant values within the range of [Ca2+] estimated for liver cytosol; and cytosolic levels of Mg2+ and ATP significantly affected those steady state [Ca2+] values in directions consistent with previously reported effects of those modulators on mitochondrial Ca2+ uptake and release.

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.

Studies on the energy-linked Ca2+ accumulation in pig heart mitochondria - role of Mg2'ons

Comparative intracellular distribution of Ca2+, Mg2+ and adenine nucleotides has been studied in pig heart by differential centrifugation or fractional extraction and has shown that Mg2+ and ATP are associated mainly with soluble fractions whereas Ca2+ and ADP are more tightly bound to subcellular structures. Ca2+ accumulation and Ca2+ stimulated respiration were studied in pig heart mitochondria under different energetic conditions in the absence or presence of phosphate. Ca2+ concentrations of about 1200 nmoles/mg protein inhibit Ca2+ accumulation, site I substrate oxidation and induce an efflux of mitochondrial Mg2+. These deleterious effects of Ca2+ on respiration occur even in the absence of phosphate or oxidizable substrate; they are completely prevented by ruthenium red only, and partially prevented by the addition of M2+ to the medium. The kinetics of Ca2+ uptake become of the sigmoidal type when Mg2+ is present. This cation strongly inhibits the rate of Ca2+ uptake in the presence of added phosphate and decreases the affinity of Ca2+ for its transport system. In the absence of phosphate, Mg2+ has no effect on Ca2+ uptake. The possible physiological implications of these findings are discussed

The effect of lead on the calcium-handling capacity of rat heart mitochondria

1. Very low concentrations of Pb2+ decrease the capacity of rat heart mitochondria, oxidizing pyruvate plus malate, to remove Ca2+ from the medium. 2. The primary effect is on the rate of Ca2+ sequestration; this is reflected in the overall extent of Ca2+ removal. 3. Pb2+ has at least two separate actions. Below about 0.5 nmol/mg of protein, it acts solely by competing with Ca2+ (Ki = 0.4 muM); above this concentration it also inhibits the production or use of respiratory energy, so that at 1 nmol of Pb2+/mg of protein, Ca2+ removal is almost completely abolished. 4. Pb2+ inhibits coupled and uncoupled respiratory O2 use by mitochondria oxidizing pyruvate plus malate, but at higher concentrations than those that affect Ca2+ removal; similar concentrations of Pb2+ inhibit pyruvate uptake, but not malate uptake, by the mitochondria. 5. Mg2+ only decreases Ca2+ removal by competition, and is a far-less effective competitor than Pb2+ (Ki = 0.15 mM). It is possible that the primary cause of the second effect of Pb2+ is displacement of membrane Mg2+. 6. The consequences of these results are discussed in terms of the possible involvement of heart mitochondria in excitation-contraction coupling, and the Pb2+ levels that might occur in heart tissue in vivo.

Some actions of purified toxins from Bungarus fasciatus venom on isolated pig-heart mitochondria

I. In the presence of succinate as an oxidation substrate, neurotoxins alpha, beta and gamma induce the following. Firstly, an increasing stimulation of oxygen uptake, which in potentiated by 25 muM Ca2+, Mg2+ 1.3 mM completely inhibits the effect of toxin alpha but not of toxins beta and gamma. Secondly, a depletion of the Mg2+, Ca2+ and K+ content of the water-soluble and membrane-bound mitochondrial compartments, following complex kinetics, which suggest a multistep interaction mechanism of the toxins with the mitochondria. 25 muM Ca2+ also potentiates the effect of the toxins on these ionic flows. Thirdly, no decrease of turbidity with toxin alpha, and a limited decrease with toxins beta and gamma. 2. In the absence of respiration, the neurotoxins induce a cationic depletion, the kinetics of which are different than with succinate, suggesting an instantaneous maximal effect on the inner membrane. Toxins beta and gamma (but not alpha) induce, under these conditions, a turbidity decrease of large amplitude, which is proportional to the amount of toxin added and tends to reach a maximum. With gamma toxin this turbidity decrease is faster than the rate of water uptake (which never exceeds 18%) indicating that it is due rather to structural modifications than to swelling. The same is observed with beta toxin, provided the mitochondrial protein concentration to be lower than 0.7 mg/ml. For higher concentrations, a continuous decrease of turbidity with a considerable uptake of water probably reflects the onset of phospholipasic activities. 3. It is postulated that structural modifications of the mitochondrial membranes are initiated which lead to the loss of their selective impermeability. The simultaneous loss of respiratory control with succinate may be due to the direct (though Ca2+-potentiated) displacement of the fraction of the membrane-bound Mg2+ ions which controls its energy-transducing properties. 4. In addition, correlations between the effects of the toxins on mitochondria and their neurotoxicity in vivo are discussed.

Special features of Pi transport in pig heart and rat liver mitochondria as revealed by 6,6'-dithiodinicotinic acid (CPDS)

CPDS (6,6'-dithiodinicotinic acid), a non permeant thiol agent which affects several mitochondrial functions in a way different to that of mersalyl [18-19] revealed striking differences between the phosphate translocating systems of pig heart and rat liver mitochondria. Pi entry was measured either by swelling in 0.12 M ammonium phosphate or by rapid centrifugation in 32Pi medium. Pi efflux was measured after preloading of mitochondria with 32Pi, by exchange against Pi or malate; the "ATP-FCCP" system has been tested previously [19]. In pig heart mitochondria, Pi entry seems to proceed exclusively via the Pi/OH- carrier; CPDS completely inhibits this transport and the energy-linked functions. In contrast n-butyl-malonate does not affect the Pi-entry and the energy-linked functions. The Pi efflux is not affected either by CPDS or mersalyl, which do not produce a swelling in the "ATP-uncoupler system". In rat liver mitochondria, CPDS inhibits only the Pi/OH- carrier; both CPDS and n-butylmalonate are necessary to inhibit completely Pi entry. CPDS as well as mersalyl provokes a swelling in the presence of the "APT-uncoupler system". The results suggest two distinct functions of phosphate transport in both types of mitochondria.

The rapid labeling of adenosine triphosphate by 32P-labeled inorganic phosphate and the exchange of phosphate oxygens as related to conformational coupling in oxidative phosphorylation

Evidence is presented that extends and amplifies the concept that in oxidative phosphorylation energy input serves to bring about release of ATP formed at a catalytic site by reversal of hydrolysis. The evidence with beef heart submitochondrial particles includes additional demonstration of uncoupler insensitive Pi leads to HOH exhchange, demonstration that this exchange is sensitive to the specific phosphorylation inhibitor, oligomycin, and demonstration that the small burst of uncoupler-insensitive ATP, rapidly labeled after addition of a tracer of 32Pi, behaves in a manner consistent with its participation as a membrane-bound intermediate in the Pi leads to HOH exchange. In addition, data are presented showing that addition of hexokinase plus glucose to submitochondrial particles in presence of ADP and Pi considerably lowers the Pi leads to HOH exchange but that further addition of cyanide or 2,4-dinitrophenol or both has little additional effect. Such data are compatible with no energy requirement for formation of bound ATP. However, with a large excess of hexokinase, the rate of the Pi leads to HOH exchange is further depressed. This could reflect some use of energy to promote formation of ATP at the catalytic site or to maintain the integrity of the phosphorylation system. Relationships of these findings to related information in the field are discussed.