OSMOTICALLY LYSED RAT LIVER MITOCONDRIA : Biochemical and Ultrastructural Properties in Relation to Massive Ion Accumulation

Osmotically lysed rat liver mitochondria have been utilized for a study of the biochemical and ultrastructural properties in relation to divalent ion accumulation. Osmotic lysis of mitochondria by suspension and washing in cold, distilled water results in the extraction of about 50% of the mitochondrial protein, the loss of the outer mitochondrial membrane, an increase in respiration, and a marked decrease in the ability to catalyze oxidative phosphorylation. Nevertheless, except for a decrease in the ability to accumulate Sr²⁺ by an ATP-supported process, these lysed mitochondria retain full capacity to accumulate massive amounts of divalent cations by respiration-dependent and ATP-supported mechanisms. The decreased ability of osmotically lysed mitochondria to accumulate Sr²⁺ by an ATP-energized process does not appear to be due to a loss or inactivation of a specific Sr²⁺-activated ATPase. The energy-dependent accumulation processes in lysed mitochondria show an increased sensitivity to inhibition by monovalent cations. Extraction of cytochrome c from osmotically lysed mitochondria results in a complete loss of phosphorylation and the respiration-dependent accumulation of Ca²⁺; a lesser, but significant, decrease in the ATP-supported accumulation of Ca²⁺ also was observed. The addition of cytochrome c fully restores the respiration-dependent accumulation of Ca²⁺ to the level present in unextracted, osmotically lysed mitochondria. The ATP-supported process is not affected by the addition of cytochrome c to extracted mitochondria, indicating that cytochrome c is not involved in ion transport energized by ATP. The osmotically lysed mitochondria are devoid of outer membranes and contain relatively little matrix substance. The accumulation of Ca²⁺ and P_i by lysed mitochondria under massive loading conditions is accompanied by the formation of electron-opaque deposits within the lysed mitochondria associated with the inner membranes. This finding suggests that the inner membrane plays a role in the deposition of divalent ions within intact rat liver mitochondria. The relevance of these observations to those of other investigators is discussed.     

Effects of antibiotic ionophore, A23187, on oxidative phosphorylation and calcium transport of liver mitochondria

A23187, a new antibiotic with ionophore properties, uncoupled oxidative phosphorylation in mitochondria which oxidized either malate plus glutamate or succinate. Ca²⁺, but not Mg²⁺, enhanced the uncoupling effect. Fluorescence of ANS¹ was increased by A23187 suggesting the mitochondrial membranes were de-energized. This de-energization was presumably by activation of the energy-dependent uptake of Ca²⁺. The steady-state measurements of murexide-divalent cation complexes showed that A23187 caused mitochondria to release the accumulated Ca²⁺ to the medium. This reduced the transmembrane Ca²⁺ gradient even though normal active Ca²⁺ uptake could take place. A23187 inhibited activity of ATPase induced by 2,4-dinitrophenol, valinomycin, and Ca²⁺. The addition of Mg²⁺ could prevent this inhibition presumably by maintaining the endogenous Mg²⁺ concentration. The above metabolic events could be explained by the fact that molecules of A23187 function in the mitochondrial inner membrane as mobile carriers for divalent cations.     

Physical properties of biological membranes determined by the fluorescence of the calcium ionophore A23187

Interactions between the divalent cation ionophore, A23187, and the divalent cations Ca²⁺, Mg²⁺, and Mn²⁺ were studied in sarcoplasmic reticulum and mitochondria. Conductance measurements suggest that A23187 facilitates the movement of divalent cations across bilayer membranes via a primarily electroneutral process, although a cationic form of A23187 does carry some current.On the basis of fluorescence excitation spectra, A23187 can form either a 1:1 or 2:1 complex with Ca²⁺ in organic solvents. However, in biological membranes, only the 1:1 complexes with Ca²⁺, Mg²⁺, or Mn²⁺ are detected. A23187 produces fluorescent transients under conditions of Ca²⁺ uptake in sarcoplasmic reticulum, which appear to represent changes in intramembrane Ca²⁺ content. Changes in A23187 fluorescence due to mitochondrial Ca²⁺ accumulation are much smaller by comparison and fluorescence transients are not detected.Studies of A23187 fluorescence polarization and lifetimes in biological membranes allow a determination of the rotational correlation time (ρh) of the ionophore. In mitochondria at 22 °C, ρh is 11 nsec in the presence of Ca²⁺ and Mg²⁺, and less than 2 nsec in the presence of excess EDTA.The present results are consistent with a model of ionophore-mediated cation transport in which free M²⁺ binds with A23187 at the membrane surface to form the complex M(A23187)⁺. Reaction of this complex with another molecule of A23187 at the membrane surfaces results in the formation of electrically neutral M(A23187)₂, which carries the divalent cation through the membrane.These results are discussed in terms of physical properties of biological membranes in regions in which divalent cation transport occurs.     

The synthesis of 3-nonaprenyl-4-hydroxybenzoate in rat liver mitochondria: the effect of Ca2 , Mg2+, chelators, and bacitracin on the activity of p-hydroxybenzoate-polyprenyl transferase

The formation of the first intermediate in ubiquinone-9 biosynthesis, 3-nonaprenyl-4-hydroxybenzoate (NPHB), by the enzyme p-hydroxybenzoate:polyprenyl transferase, has been studied in isolated rat liver mitochondria using solanesol pyrophosphate and p-hydroxybenzoate as the substrates. Phosphate buffer (100 mm) is inhibitory but at 20 mm inhibition is not apparent compared to other buffers at the same concentration. With various buffers at low concentration (20 mm) both EDTA and Mg²⁺ stimulate formation of NPHB while Ca²⁺ inhibits. Release of Ca²⁺ inhibition can be achieved by the addition of Mg²⁺, or EDTA, or EGTA, with EGTA being less effective than EDTA. When Mg²⁺, Ca²⁺, and EDTA are present together, a two- to threefold increase in activity of the enzyme is observed. The antibiotic bacitracin inhibits the synthesis of NPHB and the inhibition is increased when divalent cations are present. EGTA is more effective than EDTA in overcoming inhibition due to bacitracin. The possibility that these effects are partially due to alteration of mitochondrial membrane conformation as well as a direct effect on the enzyme is evaluated. The possible role of polyprenylphosphates in mitochondrial membrane function is discussed.     

Proton transport is necessary for divalent metal cations release from deenergized mitochondria

The release of divalent cations (Ca2+ and Sr2+) from rat liver mitochondria after membrane depolarization with protonophore (carbonyl cyanide m-chlorophenyl hydrazone, CCCP), sodium azide and K(+)-ionophore (valinomycin) was studied. It is stated that membrane depolarization itself is not sufficient for cations release from mitochondrial matrix (provided that mitochondrial permeability transition pore is blocked by cyclosporin A). Complete delivering of divalent cations is observed only after protonophore (CCCP) addition to suspension of deenergized mitochondria. The data show that membrane permeabilisation to hydrogen ions (H+) is necessary for complete cation release from the mitochondrial matrix. The enhancement in K(+)-conductivity of mitochondrial membrane (by valinomycin), on the contrary, is not able to provide complete delivering of cations from mitochondria. It is shown that quantity of divalent metal cation released from mitochondria (depolarized and permeabilized for K+ as well) is proportional to the concentration of protonophore (but not K(+)-ionophore) introduced in the incubation medium. The data obtained lead to the conclusion that H(+)-permeabilization of the mitochondrial membrane is necessary for the complete release of Ca2+ and Sr2+ from mitochondria after membrane depolarization. The possible mechanism of divalent metal cations release from deenergized mitochondria is discussed.     

Membranotropic effects of ω-hydroxypalmitic acid and Ca<Superscript>2+</Superscript> on rat liver mitochondria and lecithin liposomes. Aggregation and membrane permeabilization

The paper examines membranotropic Ca²⁺-dependent effects of ω-hydroxypalmitic acid (HPA), a product of ω-oxidation of fatty acids, on the isolated rat liver mitochondria and artificial membrane systems (liposomes). It was established that in the presence of Ca²⁺, HPA induced aggregation of liver mitochondria, which was accompanied by the release of cytochrome c from the organelles. It was further demonstrated that the addition of Ca²⁺ to HPA-containing liposomes induced their aggregation and/or fusion. Ca²⁺ also caused the release of the fluorescent dye sulforhodamine B from liposomes, indicating their permeabilization. HPA was shown to induce a high-amplitude swelling of Ca²⁺-loaded mitochondria, to decrease their membrane potential, to induce the release of Ca²⁺ from the organelles and to result in the oxidation of the mitochondrial NAD(P)H pool. Those effects of HPA were not blocked by the MPT pore inhibitor CsA, but were suppressed by the mitochondrial calcium uniporter inhibitor ruthenium red. The effects of HPA were also observed when Ca²⁺ was replaced with Sr²⁺ (but not with Ba²⁺ or Mg²⁺). A supposition is made that HPA can induce a Ca²⁺-dependent aggregation of mitochondria, as well as Ca²⁺dependent CsA-insensitive permeabilization of the inner mitochondrial membrane – with the subsequent lysis of the organelles.     

Ursodeoxycholic acid,in contrast to other bile acids,induces Ca<Superscript>2+</Superscript>-dependent cyclosporin A-insensitive permeability transition in liver mitochondria in the presence of potassium chloride

The effects of hydrophobic and hydrophilic bile acids as inducers of Ca²⁺-dependent permeability of the inner membrane were studied on isolated liver mitochondria. It is shown that in the absence of the inorganic phosphate (P_i)–a modulator of the mitochondrial pore–hydrophobic bile acids (lithocholic, deoxycholic, chenodeoxycholic) at concentrations of 20–50 μM, as well as a hydrophilic cholic acid at a concentration of 800 μM, induce swelling of liver mitochondria loaded with Ca²⁺. This effect is completely eliminated by a specific inhibitor of mitochondrial pore cyclosporin A (CsA). The effect of the bile acids as inducers of Ca²⁺-dependent CsA-sensitive mitochondrial pore is not associated with the modulation of the P_i effects. In contrast to other tested bile acids, a hydrophilic ursodeoxycholic acid (UDCA) at a concentration of 400 μM is able to induce Ca²⁺-dependent CsA-sensitive pore opening in liver mitochondria only in the presence of P_i or in the absence of potassium chloride in the incubation medium. In the presence of potassium chloride but in the absence of P_i, UDCA effects associated with the induction of the inner membrane permeability (swelling of mitochondria, drop in Δψ, and Ca²⁺ release from the matrix) are also observed in the presence of CsA. This Ca²⁺-dependent permeability of the inner membrane, in contrast to the “classical” CsA-sensitive pore, is characterized by a lower intensity of the mitochondrial swelling, a total drop in Δψ, and Ca²⁺ release from the matrix and is blocked by P_i. We suggest that the induction of the CsA-insensitive permeability in the inner mitochondrial membrane by UDCA is associated with activation of electrophoretic influx of K⁺ into the matrix and Ca²⁺ release from the matrix in exchange to H+. The effect of P_i as a blocker of such permeability is discussed.     

BAX insertion, oligomerization, and outer membrane permeabilization in brain mitochondria: Role of permeability transition and SH-redox regulation

BAX cooperates with truncated BID (tBID) and Ca²⁺ in permeabilizing the outer mitochondrial membrane (OMM) and releasing mitochondrial apoptogenic proteins. The mechanisms of this cooperation are still unclear. Here we show that in isolated brain mitochondria, recombinant BAX readily self-integrates/oligomerizes in the OMM but produces only a minuscule release of cytochrome c, indicating that BAX insertion/oligomerization in the OMM does not always lead to massive OMM permeabilization. Ca²⁺ in a mitochondrial permeability transition (mPT)-dependent and recombinant tBID in an mPT-independent manner promoted BAX insertion/ oligomerization in the OMM and augmented cytochrome c release. Neither tBID nor Ca²⁺ induced BAX oligomerization in the solution without mitochondria, suggesting that BAX oligomerization required interaction with the organelles and followed rather than preceded BAX insertion in the OMM. Recombinant Bcl-xL failed to prevent BAX insertion/oligomerization in the OMM but strongly attenuated cytochrome c release. On the other hand, a reducing agent, dithiothreitol (DTT), inhibited BAX insertion/oligomerization augmented by tBID or Ca²⁺ and suppressed the BAX-mediated release of cytochrome c and Smac/DIABLO but failed to inhibit Ca²⁺-induced swelling. Altogether, these data suggest that in brain mitochondria, BAX insertion/oligomerization can be dissociated from OMM permeabilization and that tBID and Ca²⁺ stimulate BAX insertion/oligomerization and BAX-mediated OMM permeabilization by different mechanisms involving mPT induction and modulation of the SH-redox state.     

Calcium transport by ehrlich ascites cell mitochondria in vitro and in situ

The rate, maximum extent of accumulation, and passive release of Ca²⁺ by mitochondria within Ehrlich ascites tumor cells treated with digitonin and by isolated tumor mitochondria have been compared. The mitochondrial protein content of Ehrlich cells was determined by cytochrome and cytochrome oxidase analyses. The Ca²⁺ uptake rate in situ is approximately one-half the rate in vitro whereas maximum Ca²⁺ accumulation by mitochondria within the cell is about twice the value for isolated mitochondria. When isolated tumor mitochondria were supplemented with exogenous ATP the maximum uptake (approximately 3.0 μeq Ca²⁺/mg protein) was about the same as in situ. Adenine nucleotides retained in digitonized cells may account for the observed differences. The rate of uncoupler stimulated Ca²⁺ release from mitochondria within the cell (ca. 10 neq Ca²⁺/min · mg mitochondrial protein for Ca²⁺ loads up to 800 neq Ca²⁺/mg protein) agrees exceptionally well with previous estimates for isolated tumor mitochondria. Therefore the capacity for extensive Ca²⁺ accumulation without uncoupling and attenuation of Ca²⁺ efflux are virtually the same in the cell as in vitro.     

Induction of Ca2+-dependent cyclosporin a-insensitive nonspecific permeability of the inner membrane of liver mitochondria and cytochrome c release by α,ω-hexadecanedioic acid in media of varying ionic strength

In liver mitochondria loaded with Ca²⁺ or Sr²⁺, α,ω-hexadecanedioic acid (HDA) can induce nonspecific permeability of the inner membrane (mitochondrial pore) by the mechanism insensitive to cyclosporin A (CsA). In this work we studied the effect of ionic strength of the incubation medium on the kinetics of the processes that accompany Ca²⁺-dependent induction of the mitochondrial pore by fatty acid: organelle swelling, Ca²⁺ release from the matrix, changes in transmembrane potential (Δψ) and rate of oxygen consumption, and the release of cytochrome c from the intermembrane space. Two basic incubation media were used: sucrose medium and isotonic ionic medium containing KCl without sucrose. We found that 200 μM Ca²⁺ and 20 μM HDA in the presence of CsA effectively induce high-amplitude swelling of mitochondria both in the case of sucrose and in the ionic incubation medium. In the presence of CsA, mitochondria can rapidly absorb Ca²⁺ and retain it in the matrix for a while without reducing Δψ. Upon incubation in the ionic medium, mitochondria retain most of the added Ca²⁺ in the matrix for a short time without reducing the Δψ. In both cases the addition of HDA to the mitochondria 2 min after the introduction of Ca²⁺ leads to the rapid release of these ions from the matrix and total drop in Δψ. The mitochondrial swelling induced by Ca²⁺ and HDA in non-ionic medium is accompanied by almost maximal stimulation of respiration. Under the same conditions, but during incubation of mitochondria in the ionic medium, it is necessary to add cytochrome c for significant stimulation of respiration. The mitochondrial swelling induced by Ca²⁺ and HDA leads to the release of cytochrome c in a larger amount in the case of ionic medium than for the sucrose medium. We conclude that high ionic strength of the incubation medium determines the massive release of cytochrome c from mitochondria and liberates it from the respiratory chain, which leads to blockade of electron transport along the respiratory chain and consequently to disruption of the energy functions of the organelles.     

Mitochondrial handling of excess Ca2+ is substrate-dependent with implications for reactive oxygen speciesgeneration

The mitochondrial electron transport chain is the major source of reactive oxygen species (ROS) during cardiac ischemia. Several mechanisms modulate ROS production; one is mitochondrial Ca²⁺ uptake. Here we sought to elucidate the effects of extramitochondrial Ca²⁺ (e[Ca²⁺]) on ROS production (measured as H₂O₂ release) from complexes I and III. Mitochondria isolated from guinea pig hearts were preincubated with increasing concentrations of CaCl₂ and then energized with the complex I substrate Na⁺ pyruvate or the complex II substrate Na⁺ succinate. Mitochondrial H₂O₂ release rates were assessed after giving either rotenone or antimycin A to inhibit complex I or III, respectively. After pyruvate, mitochondria maintained a fully polarized membrane potential (ΔΨ; assessed using rhodamine 123) and were able to generate NADH (assessed using autofluorescence) even with excess e[Ca²⁺] (assessed using CaGreen-5N), whereas they remained partially depolarized and did not generate NADH after succinate. This partial ΔΨ depolarization with succinate was accompanied by a large release in H₂O₂ (assessed using Amplex red/horseradish peroxidase) with later addition of antimycin A. In the presence of excess e[Ca²⁺], adding cyclosporin A to inhibit mitochondrial permeability transition pore opening restored ΔΨ and significantly decreased antimycin A-induced H₂O₂ release. Succinate accumulates during ischemia to become the major substrate utilized by cardiac mitochondria. The inability of mitochondria to maintain a fully polarized ΔΨ under excess e[Ca²⁺] when succinate, but not pyruvate, is the substrate may indicate a permeabilization of the mitochondrial membrane, which enhances H₂O₂ emission from complex III during ischemia.     

Adenine nucleotide transport in hepatoma mitochondria. Characterization of factors influencing the kinetics of ADP and ATP uptake

Initial velocity measurements of [³H]ADP and [³H]ATP uptake have been made with mitochondria isolated from Morris hepatomas of differing growth rates, and factors known to influence the rates of nucleotide exchange have been examined in an effort to determine whether the elevated rates of aerobic glycolysis in these tumors can be attributed to altered carrier activity. These studies included the determination of the apparent kinetic constants for nucleotide uptake as a function of the mitochondrial energy state and the dependence of transport rates on temperature. Also included in these studies were measurements of the mitochondrial levels of endogenous inhibitors, divalent cations and internal adenine nucleotides. Results obtained showed that with mitochondria isolated from the various tumor lines, the apparent kinetic constants for nucleotide uptake are different from those of control rat or regenerating liver mitochondria; the apparent V_max values for both ADP and ATP uptake are significantly lower. Furthermore, under conditions of a high-energy state, the K_m and V_max values for ATP uptake are greater than the K_m and V_max value for ADP uptake but that under uncoupled conditions, the opposite is observed. Comparison of the levels of mitochondrial Ca²⁺, Mg²⁺, long-chain acyl-CoA ester and adenine nucleotide from the various mitochondria showed that important differences exist between liver and hepatoma mitochondria in the levels of Ca²⁺, long-chain acyl-CoA ester and AMP. Mitochondrial Ca²⁺ levels are elevated 3–5-fold in all tumor lines, and for Morris 7777 hepatoma (a rapidly growing tumor) by a remarkable 70-fold; whereas the levels of acyl-CoA ester and AMP are significantly lower in the more rapidly growing tumors. Arrhenius plots for nucleotide uptake in mitochondria from liver and hepatoma are characterized as being biphasic, having similar activation energies above and below the break point temperature (28–38 and 6–16 kcal/mol, respectively). However, the transition temperature for mitochondria from the various hepatomas is uniformly 4–5°C lower than mitochondria from control liver. The latter difference may reflect a variation in membrane composition, most probably lipid components. It is concluded that the presence of elevated levels of Ca²⁺ and lower levels of AMP in hepatoma mitochondria and difference of membrane compositions may play an important role in limiting adenine nucleotide transport activity in vivo and that the impaired carrier activity may contribute to higher rates of aerobic glycolysis observed in these tumors.     

The Ca2+-induced membrane transition in mitochondria. III. Transitional Ca2+ release.

The efflux of Ca²⁺ from mitochondria respiring at steady state, and much of uncoupler-induced Ca²⁺ efflux, is shown to be a consequence of the Ca²⁺-induced membrane transition (the Ca²⁺-induced transition is the Ca²⁺-dependent sudden increase in the nonspecific permeability of the mitochondrial inner membrane which occurs spontaneously when mitochondria are incubated under a variety of conditions (D. R. Hunter, R. A. Haworth, and J. H. Southard, 1976, J. Biol. Chem.251, 5069–5077)). Ca²⁺ release from mitochondria respiring at steady state is shown to be transitional by four criteria: (1) Ca²⁺ release is inhibited by Mg²⁺, ADP, and bovine serum albumin (BSA), all inhibitors of the transition; (2) release is selective for Ca²⁺ over Sr²⁺, a selectivity also found for the transition; (3) the time course of Ca²⁺ release is identical to the time course of the change in the mitochondrial population from the aggregated to the orthodox configuration; and (4) from kinetics, Ca²⁺ release from individual mitochondria is shown to occur suddenly, following a lag period during which no release occurs. Ca²⁺ release induced by uncoupler is shown to be mostly by a transitional mechanism, as judged by four criteria: (1) release of Ca²⁺ is ruthenium red-insensitive and is an order of magnitude faster than Sr²⁺ release which is ruthenium red-sensitive; (2) release of Ca²⁺ is strongly inhibited by keeping the mitochondrial NAD⁺ reduced; (3) the kinetics of Ca²⁺ release indicates a transitional release mechanism; and (4) uncoupler addition triggers the aggregated to orthodox configurational transition which, at higher levels of Ca²⁺ uptake, occurs in the whole mitochondrial population at a rate equal to the rate of Ca²⁺ release. Na²⁺-induced Ca²⁺ release was not accompanied by a configurational change; we therefore conclude that it is not mediated by the Ca²⁺-induced transition.     

Lithocholic acid induces two different calcium-dependent inner membrane permeability systems in liver mitochondria

The effect of the most hydrophobic bile acid–lithocholic–as an inducer of two different Ca²⁺-dependent inner membrane permeability systems was studied on isolated rat liver mitochondria. It is shown that the addition of lithocholic acid at a concentration of 20 μM to the Ca²⁺-loaded mitochondria leads to swelling of the organelles, rapid release of Ca²⁺ from the matrix and almost complete collapse of Δψ. Mitochondrial pore blocker cyclosporin A (CsA) eliminates mitochondrial swelling but has no effect on the process of Ca²⁺ release and Δψ collapse. In the absence of Ca²⁺ lithocholic acid causes only a transient decrease of Δψ with subsequent complete recovery. Ruthenium red, inhibitor of mitochondrial Ca²⁺ uniporter, which blocks Ca²⁺ influx into the matrix, prevents mitochondrial swelling induced by lithocholic acid. At the same time, ruthenium red, which is added before lithocholic acid to the Ca²⁺-preloaded mitochondria, does not affect the swelling of the organelles but reduces the CsA-insensitive drop in Δψ. It is concluded that lithocholic acid is able to induce two Ca²⁺-dependent energy dissipation systems in the inner membrane of liver mitochondria: CsA-sensitive mitochondrial pore and CsA-insensitive permeability, which exhibits sensitivity to ruthenium red. It is found that the effect of this bile acid as an inductor of CsA-sensitive mitochondrial pore is not associated with the modulation of Pi effects. It is assumed that CsA-insensitive action of lithocholic acid is associated with the induction of Ca²⁺ efflux from the matrix in exchange for protons. In this case, the energy-dependent Ca²⁺ transport in the opposite direction with the participation of mitochondrial calcium uniporter sensitive to ruthenium red leads to the formation of calcium cycle and thereby to energy dissipation.     

Differentiation of two states of F1-ATPase by nucleotide analogs

The hydroperoxide-induced net release of Ca²⁺ from rat liver mitochondria is stimulated by the Ca²⁺ uptake inhibitor ruthenium red. At moderate Ca²⁺ loads the release takes place with preservation of a high mitochondrial membrane potential. During and after Ca²⁺ release mitochondria remain intact. The hydroperoxide-induced release of Ca²⁺ might therefore be a physiological relevance.     

Metabolism of calcium and effect of divalent cations on respiratory activity of yeast mitochondria

The adsorption of Ca²⁺ to the mitochondria ofSaccharomyces cerevisiae was investigated and it was found that, in contrast with animal mitochondria, Ca²⁺ is not accumulated through an energydependent process but is more probably adsorbed to mitochondrial membranes. The adsorption magnitude depends both on the amount of added calcium and on the ionic composition of the medium. It was found by study of the effect of divalent cations on the respiratory activity of yeast mitochondria that (a) Ca²⁺ and Mg²⁺ inhibit their oxidation competitively with succinate or citrate, the oxidation of NADH not being affected; (b) stimulation of oxidation of NADH and inhibition of oxidation of citrate and succinate may be observed with Ca²⁺ in the mitochondria ofTorulopsis utilis and with Co²⁺ in the mitochondria ofSaccharomyces cerevisiae; (c) Zn²⁺ inhibits the oxidation of NADH and of citrate; (d) the rate of oxidation of NADH in the presence of Cd²⁺ is several-fold greater than State 3 activity—on the other hand, oxidation of suceinate and citrate is inhibited by cadmium. In comparison with animal mitochondria, the fate of Ca²⁺ as well as the effects of other divalent cations on the respiratory activity of yeast mitochondria are different.     

Modulation of Intracellular Calcium Waves and Triggered Activities by Mitochondrial Ca Flux in Mouse Cardiomyocytes

Recent studies have suggested that mitochondria may play important roles in the Ca²⁺ homeostasis of cardiac myocytes. However, it is still unclear if mitochondrial Ca²⁺ flux can regulate the generation of Ca²⁺ waves (CaWs) and triggered activities in cardiac myocytes. In the present study, intracellular/cytosolic Ca²⁺ (Ca_i ²⁺) was imaged in Fluo-4-AM loaded mouse ventricular myocytes. Spontaneous sarcoplasmic reticulum (SR) Ca²⁺ release and CaWs were induced in the presence of high (4 mM) external Ca²⁺ (Ca_o ²⁺). The protonophore carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP) reversibly raised basal Ca_i ²⁺ levels even after depletion of SR Ca²⁺ in the absence of Ca_o ²⁺ , suggesting Ca²⁺ release from mitochondria. FCCP at 0.01 - 0.1 µM partially depolarized the mitochondrial membrane potential (Δψ _m) and increased the frequency and amplitude of CaWs in a dose-dependent manner. Simultaneous recording of cell membrane potentials showed the augmentation of delayed afterdepolarization amplitudes and frequencies, and induction of triggered action potentials. The effect of FCCP on CaWs was mimicked by antimycin A (an electron transport chain inhibitor disrupting Δψ _m) or Ru360 (a mitochondrial Ca²⁺ uniporter inhibitor), but not by oligomycin (an ATP synthase inhibitor) or iodoacetic acid (a glycolytic inhibitor), excluding the contribution of intracellular ATP levels. The effects of FCCP on CaWs were counteracted by the mitochondrial permeability transition pore blocker cyclosporine A, or the mitochondrial Ca²⁺ uniporter activator kaempferol. Our results suggest that mitochondrial Ca²⁺ release and uptake exquisitely control the local Ca²⁺ level in the micro-domain near SR ryanodine receptors and play an important role in regulation of intracellular CaWs and arrhythmogenesis.     

ADP requirement for prevention by a cytosolic factor of Mg2+ and Ca2+ release from rat liver mitochondria

One hundred micromolar Ca²⁺ added to rat liver mitochondria induces a transient uptake of Ca²⁺ plus a rapid efflux of the mitochondrial Mg²⁺. Addition of a cytosolic molecule, cytosolic metabolic factor, to mitochondria prevents the efflux of the two divalent cations. ADP is required for this cytosolic metabolic factor action. This requirement for ADP is specific as it is shown by experiments with traps for nucleotides and inhibitors of the translocase. The implication of cytosolic metabolic factor in the mitochondrial regulation process is discussed.     

Mitochondrial calcium function and dysfunction in the central nervous system

The ability of isolated brain mitochondria to accumulate, store and release calcium has been extensively characterized. Extrapolation to the intact neuron led to predictions that the in situ mitochondria would reversibly accumulate Ca²⁺ when the concentration of the cation in the vicinity of the mitochondria rose above the ‘set-point’ at which uptake and efflux were in balance, storing Ca²⁺ as a complex with phosphate, and slowly releasing the cation when plasma membrane ion pumps lowered the cytoplasmic free Ca²⁺. Excessive accumulation of the cation was predicted to lead to activation of the permeability transition, with catastrophic consequences for the neuron. Each of these predictions has been confirmed with intact neurons, and there is convincing evidence for the permeability transition in cellular Ca²⁺ overload associated with glutamate excitotoxicity and stroke, while the neurodegenerative disease in which possible defects in mitochondrial Ca²⁺ handling have been most intensively investigated is Huntington's Disease. In this brief review evidence that mitochondrial Ca²⁺ transport is relevant to neuronal survival in these conditions will be discussed.