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.     

Transport of Ca and Mn by mitochondria from rat liver, heart and brain

The energy-dependent, respiration-supported uptake and the uncoupler- or Na+-induced release of Ca2+ and Mn2+ by mitochondria from rat liver, heart and brain were investigated, using as indicators radioisotopes (45Ca and 54Mn), proton ejection, oxygen consumption, nicotinamide nucleotide oxidation-reduction and, in the case of Ca2+, the metallochromic dye Arsenazo III. Ca2+ uptake in the presence of Pi was rapid in mitochondria from liver and brain, and less rapid in those from heart. Mn2+ uptake was much slower than that of Ca2+ in liver and heart, but only slightly slower in brain. When added together, Ca2+ accelerated the uptake of Mn2+, and Mn2+ retarded the uptake of Ca2+, by mitochondria from all three tissues. When Mn2+ was present during Ca2+ uptake, its own uptake remained accelerated even after Ca2+ uptake was terminated. Mg2+, which was not taken up, inhibited Ca2+ uptake by mitochondria from all three tissues, and, when present during Ca2+ uptake, accelerated the subsequent uptake of Mn2+. The uncoupler CCCP induced a release of both Ca2+ and Mn2+ from all three sources of mitochondria; yet, release of Mn2+ took place only in the absence of Pi. The release followed the same pattern as the uptake, i.e., Ca2+ accelerated the release of Mn2+ and Mn2+ retarded the release of Ca2+. Na+ induced a release of both Ca2+ and Mn2+ from heart and brain but not from liver mitochondria; again, Mn2+ release occurred only in the absence of Pi. The Na+-induced release of Ca2+ was inhibited by Mn2+, but the Na+-induced release of Mn2+ was not accelerated by Ca2+.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of ferric iron complex on isolated rat liver mitochondria. II. Ion movements

It has been found that addition of iron(III)-gluconate complex to rat liver mitochondria disturbed the mitochondrial Ca2+ transport. Indirect evidence when the changes in the membrane potential during the transport of Ca2+ were followed, as well as direct evidence, when the fluxes of Ca2+ were monitored by a Ca2+-selective electrode, indicated that this iron complex induced an efflux of Ca2+ from liver mitochondria. The mechanisms by which iron induced Ca2+ release appeared to be linked to the induction of lipoperoxidation of mitochondrial membrane. The mitochondrial membrane, however, did not become irreversibly damaged under these conditions, as indicated by its complete repolarization. It was also shown that the induction by iron of lipoperoxidation brought about an efflux of K+ from mitochondria.     

Calcium behavior in endotoxin-poisoned mice: especially calcium accumulation in mitochondria

A possible role of intracellular Ca2+ and participation of calmodulin in cellular metabolism in endotoxin-poisoned mice were investigated. The levels of calcium in liver cytosol and liver mitochondria fractions in poisoned mice were markedly higher 18-48 hr after endotoxin injection than in the control mice. On the other hand, the levels of serum calcium in the poisoned mice were about 20% lower at 18 hr than in the controls. The serum calcium levels in mice injected with 50 and 100 micrograms of endotoxin showed no dose-response effect, but a dose-response effect was observed at a dose of 200-400 micrograms. The serum Ca2+ levels in endotoxin-tolerant mice were similar to those in the control mice. The levels in mice injected with glucocorticoid-antagonizing factor mice were about 14% lower at 3 hr than in the controls. The mice fed a vitamin D3- and calcium-free diet showed a higher mortality rate in the early stage (12-18 hr) of endotoxication than that of the mice fed a normal diet. The lipid peroxide levels and Ca2+-ATPase activity in the liver mitochondria fraction in endotoxin-poisoned mice showed a higher level than those of the control mice. There was little or no difference in the levels of serum glucose between the mice injected with calmodulin antagonist (trifluoperazine, TFP) plus endotoxin and those given endotoxin alone. However, the liver glycogen levels in TFP plus endotoxin-treated mice were markedly higher than that in mice given endotoxin alone. Furthermore, calcium antagonist (verapamil) plus endotoxin-treated mice had about a 40% higher survival rate after 72 hr than those given endotoxin alone. The findings suggest that there is a possibility of participation of the Ca2+-calmodulin system in carbohydrate metabolic disorders during endotoxemia and that the changes in intracellular Ca2+ may result in various metabolic disorders.     

Changes in ultrastructure and the occurrence of permeability transition in mitochondria during rat liver regeneration.

Mitochondrial bioenergetic impairment has been found in the organelles isolated from rat liver during the prereplicative phase of liver regeneration. To gain insight into the mechanism underlying this impairment, we investigated mitochondrial ultrastructure and membrane permeability properties in the course of liver regeneration after partial hepatectomy, with special interest to the role played by Ca2+ in this process. The results show that during the first day after partial hepatectomy, significant changes in the ultrastructure of mitochondria in situ occur. Mitochondrial swelling and release from mitochondria of both glutamate dehydrogenase and aspartate aminotransferase isoenzymes with an increase in the mitochondrial Ca2+ content were also observed. Cyclosporin-A proved to be able to prevent the changes in mitochondrial membrane permeability properties. At 24 h after partial hepatectomy, despite alteration in mitochondrial membrane permeability properties, no release of cytochrome c was found. The ultrastructure of mitochondria, the membrane permeability properties and the Ca2+ content returned to normal values during the replicative phase of liver regeneration. These results suggest that, during the prereplicative phase of liver regeneration, the changes in mitochondrial ultrastructure observed in liver specimens were correlated with Ca2+-induced permeability transition in mitochondria.     

Effect of calcium ion on lipid peroxide formation in endotoxemic mice

The present study was conducted to determine the possible role of intracellular Ca2+ in lipid peroxide formation in endotoxin-poisoned mice. Leakages of LDH isozyme and acid phosphatase in serum of mice fed a Ca2+-deficient diet were remarkably increased after administration of 200 micrograms of endotoxin compared to that in endotoxin-nontreated Ca2+-deficient mice. Superoxide anion generation in liver of Ca2+-deficient mice and in mice fed a normal diet greatly increased after endotoxin administration. On the contrary, after endotoxin injection there was scarcely any difference in SOD activity of liver of Ca2+-deficient mice as compared to that in endotoxin-nontreated Ca2+-deficient mice. In spite of an increase of superoxide anion generation there was little or no effect of endotoxin administration on lipid peroxide formation in mice given a Ca2+-deficient diet. In the mice treated with a Ca2+-deficient diet, free radical scavenger levels (alpha-tocopherol and nonprotein sulfhydryl) in liver tissue after endotoxin injection were markedly decreased compared to those in Ca2+-deficient diet alone. Mice fed a normal diet exhibited a significant decrease of lipid peroxide level in liver by injection of endotoxin together with verapamil (10 mg/kg, s.c.). When mice fed a normal diet were injected with endotoxin, the state 3 respiratory activity showed a 49% decrease, and respiratory control ratio (RCR) of endotoxemic mice liver mitochondria was 38% lower than normal liver mitochondria. No difference could be observed in levels of state 3 and RCR between the mice given verapamil plus endotoxin and the normal mice. These findings suggest the possibility that Ca2+ may participate in the free radical formation in the liver during endotoxemia and also that Ca2+ may play an important role in the damage of liver mitochondrial function in endotoxemic mice.     

The role of hydroperoxides as calcium release agents in rat brain mitochondria

Hydroperoxides have previously been shown to induce Ca2+ release from intact rat liver mitochondria via a specific release pathway. Here it is reported that, in rat brain mitochondria, a hydroperoxide-induced Ca2+ release is also operative but is of minor importance. Hydroperoxide stimulates Ca2+ release in the presence of ruthenium red about twofold at a Ca2+ load of 40 nmol/mg mitochondrial protein. After addition of hydroperoxide, Ca2+ release from brain mitochondria can still be evoked by Na+. In the presence of succinate and rotenone, hydroperoxide induces only a very limited oxidation of pyridine nucleotides, most probably due to the low level of glutathione peroxidase (EC 1.11.1.9) and glutathione reductase (EC 1.6.4.2) found in brain mitochondria. Similar to liver mitochondria, a NADase (EC 3.2.2.5) activity is found in brain mitochondria. Its localization and sensitivity toward ADP and ATP, however, is different from that of the liver mitochondrial enzyme.     

Calcium uptake in mitochondria from different skeletal muscle types

The kinetics of calcium (Ca2+) uptake have been studied in mitochondria isolated from the different types of skeletal muscle. These studies demonstrate that the Ca2+ uptake properties of skeletal mitochondria are similar to those from liver and cardiac mitochondria. The Ca2+ carriers apparently have a high affinity for Ca2+ (Michaelis constants in the microM range). The relationship between Ca2+ uptake and initial Ca2+ concentration (10(-5) to 10(-7) M) is sigmoid in all mitochondria from the different skeletal muscle types suggesting that the uptake process is cooperative. Hill plots reveal coefficients of approximately 2 for mitochondria from fast-twitch muscle and 3.5 for slow-twitch muscle, adding further evidence to the concept that the uptake process is cooperative. An analysis of the potential role of mitochondria in the sequestration of Ca2+ during muscular contraction demonstrated that mitochondria from slow-twitch muscle of both rats and rabbits can potentially account for 100% of the relaxation rate at a low frequency of stimulation (5 Hz). In fast-twitch muscle, the mitochondria appear unable to play a significant role in muscle relaxation, particularly at stimulation frequencies that are considered in the normal physiological range. In summary, it appears that Ca2+ uptake by mitochondria from slow-twitch skeletal muscle has kinetic characteristics which make it important as a potential regulator of Ca2+ within the muscle cell under normal physiological conditions.     

Membrane-bound Ca2+ in the mitochondria of Ehrlich ascitic tumor cells

Ca2+ transport in mitochondria of Ehrlich ascite tumour cells and in liver mitochondria has been compared. It has been shown that in tumour cell mitochondria unlike liver ones even small amounts of Ca2+ caused marked increase in membrane-bound Ca2+ level. Therefore, a decrease in the electro-neutral Ca2+ efflux, stabilization of mitochondria membranes and inhibition of phosphorylated respiration were observed. It has been proposed that high content of membrane-bound Ca2+ is predetermined by a higher affinity of membrane phospholipids to Ca2+.     

Rapid efflux of Ca2+ from heart mitochondria in the presence of inorganic pyrophosphate

Inorganic pyrophosphate (PPi) in the intracellular concentration range causes rapid efflux of Ca2+ from rat heart mitochondria oxidizing pyruvate + malate in a low Na+ medium. Half-maximal rates of Ca2+ efflux were given by 20 microM PPi. During and after PPi-stimulated Ca2+ efflux the mitochondria retain their structural integrity and complete respiratory control. Carboxyatractyloside inhibits PPi-stimulated Ca2+ efflux, indicating PPi must enter the matrix in order to promote Ca2+ efflux. Heart mitochondria have a much higher affinity for PPi uptake and PPi-induced Ca2+ efflux than liver mitochondria.     

The role of inorganic phosphate in the release of Ca2+ from rat-liver mitochondria

The effect of inorganic phosphate on Ca2+ retention has been investigated using phosphate-depleted liver mitchondria. Phosphate induces the release of Ca2+ through an efflux route insensitive to ruthenium red. This effect is not due to functional or structural damage, since mitochondria maintain their membrane potential during phosphate-induced Ca2+ efflux. Direct enzymatic measurement of mitochondria pyridine nucleotides has established that changes in their redox state (i.e. increased oxidation) do not play a role in the phosphate-effect. The phosphate-induced Ca2+ efflux requires transport of phosphate out of mitochondria. However, the fluxes of Ca2+ and phosphate do not coincide: the release of phosphate preceeds that of Ca2+.     

Nutritional effects on mitochondrial bioenergetics. Alterations in calcium uptake by rat liver mitochondria

The uptake of Ca2+ by energized liver mitochondria was compared in normal fed as well as in protein-energy malnourished rats. In the presence of phosphate, mitochondria obtained from both groups were able to accumulate Ca2+ from the suspending medium and eject H+ during oxidation of common substrates which activate different segments of the respiratory chain. The rate of Ca2+ uptake was significantly lower in mitochondria from protein-energy malnourished rats. The rates of oxygen consumption and H+ ejection were decreased by 20-30% during oxidation of substrates at the three coupling sites. Similarly, mitochondria from protein-energy malnourished rats exhibit a 34% decrease in the maximal rate of Ca2+ uptake and a 25% lower capacity for Ca2+ load. The stoichiometric relationship of Ca2+/2e- remained unaffected. In steady state, with succinate as a substrate in the presence of rotenone and N-ethylmaleimide, mitochondria from normal fed and protein-energy malnourished rats showed a similar rate of Ca2+ uptake. Furthermore in both groups the stoichiometry of the H+/O ratio was close to 8.0 (H+/site ratio close to 4.0), and of Ca2+/site was close to 2.0. The diminished rate of Ca2+ uptake observed in mitochondria from protein-energy malnourished rats could be explained on the basis of a depressed rate of electron transport in the respiratory chain rather than by an effect at the level of the Ca2+ or H+ transport mechanism per se.     

Effect of thyroidectomy and hyperthyroidism on Ca2+/2H+-antiporter activity in rat liver mitochondria

The manifestation of Ca2+/2H+ antiporter activity in rat liver mitochondria was shown to be inhibited in thyroidectomy and stimulated in hyperthyroidosis. Experiments with measuring the kinetics of the swelling of deenergized mitochondria in isoosmotic solutions Ca (NO3)2, pH 8.1 demonstrated inhibition of the swelling of liver mitochondria during thyroidectomy and stimulation because of administering thyroid hormones in vivo. During thyroidectomy, the phosphate-induced swelling of rat liver mitochondria was powerfully inhibited. Meanwhile administration of thyroxine to rats stimulated the swelling of mitochondria.     

Some characteristics of Ca2+ transport in plant mitochondria

Coupled mitochondria isolated from the white leaves of cabbage (Brassica Oleracea, var. capitata) were inactive in respiration-coupled Ca2+ accumulation, in contrast to mitochondria isolated from etiolated corn (Zea mays) which showed the ability to take up Ca2+ from the medium, although with a much lower activity than liver mitochondria. The addition of corn mitochondria to aerobic medium containing succinate as respiratory substrate and a free Ca2+ concentration of 40 microM resulted in Ca2+ uptake with a decrease in free Ca2+ concentration until a steady state of about 2.0 microM was reached and maintained constant for several minutes. Perturbation of this steady state by the addition of Ca2+ or EGTA was followed by Ca2+ uptake or release, respectively, until the steady state was attained at the original extramitochondrial free Ca2+ concentration. These results indicate that corn but not cabbage mitochondria, as with some animal mitochondria, have the ability to buffer external Ca2+ and may be involved in the maintenance of Ca2+ homeostasis in the cell.     

The role of mitochondrial calcium transport during inflammation and the effect of anti-inflammatory drugs

The effects of inflammation induced by the inoculation of rats with Freund's adjuvant on calcium transport by isolated rat liver mitochondria and on mitochondrial in vivo protein synthesis were investigated. Mitochondria isolated from the liver of inflamed rats exhibited (i) a reduction in 45Ca2+ uptake and, (ii) a reduction in protein synthesis. Addition of ATP to the calcium uptake medium stimulate the uptake in inflamed rat liver mitochondria. After inflammation was controlled by treatment with a mixture of Clerodendron inerme flavonoidal glycosides and indomethacin, rat liver mitochondria showed (i) an increase in 45Ca2+ uptake and, (ii) an increase in mitochondrial in vivo protein synthesis. The mechanism of mitochondrial calcium transport and the mitochondrial protein metabolism during inflammation and after treatment with anti-inflammatory drugs were discussed.     

Ca2+-induced accumulation of pyrophosphate in mitochondria during acetate metabolism.

The mechanism of pyrophosphate (PPi) accumulation in rat liver during acetate metabolism was investigated. Perfusion of the liver with acetate in the presence of noradrenaline and glucagon induced marked accumulation of PPi (2 mumol/g of liver, 200 times that of control). In contrast, perfusion with glutamine, which generates PPi only in the cytosol, caused little accumulation of PPi, even in the presence of the two hormones. The site of PPi accumulation was shown to be the mitochondria by the finding that isolated mitochondria from the liver perfused with acetate and the hormones contained 50 nmol of PPi/mg of protein. The addition of an uncoupler to mitochondria with accumulated PPi caused gradual decrease in their PPi content, with concomitant release of a stoichiometric amount of Ca2+. Similar accumulation of PPi was observed when isolated mitochondria were incubated with acetate and Ca2+. These results show that an increase in cytosolic Ca2+ caused by the co-administration of the two hormones induced uptake of the ion into mitochondria, and that PPi accumulated in mitochondria only when it was generated in the organelles with an elevated concentration of Ca2+. High mitochondrial concentrations of Ca2+ are considered to inhibit inorganic pyrophosphatase through the formation of a stable complex, CaPPi-. Mitochondria with accumulated PPi had normal respiratory activities, and their adenine nucleotide concentrations were increased 2-fold rather than being decreased, the increases also being considered to be caused by their high concentration of Ca2+.     

Pathways for Ca2+ efflux in heart and liver mitochondria.

1. Two processes of Ruthenium Red-insensitive Ca2+ efflux exist in liver and in heart mitochondria: one Na+-independent, and another Na+-dependent. The processes attain maximal rates of 1.4 and 3.0 nmol of Ca2+.min-1.mg-1 for the Na+-dependent and 1.2 and 2.0 nmol of Ca2+.min-1.mg-1 for the Na+-independent, in liver and heart mitochondria, respectively. 2. The Na+-dependent pathway is inhibited, both in heart and in liver mitochondria, by the Ca2+ antagonist diltiazem with a Ki of 4 microM. The Na+-independent pathway is inhibited by diltiazem with a Ki of 250 microM in liver mitochondria, while it behaves as almost insensitive to diltiazem in heart mitochondria. 3. Stretching of the mitochondrial inner membrane in hypo-osmotic media results in activation of the Na+-independent pathway both in liver and in heart mitochondria. 4. Both in heart and liver mitochondria the Na+-independent pathway is insensitive to variations of medium pH around physiological values, while the Na+-dependent pathway is markedly stimulated parallel with acidification of the medium. The pH-activated, Na+-dependent pathway maintains the diltiazem sensitivity. 5. In heart mitochondria, the Na+-dependent pathway is non-competitively inhibited by Mg2+ with a Ki of 0.27 mM, while the Na+-independent pathway is less affected; similarly, in liver mitochondria Mg2+ inhibits the Na+-dependent pathway more than it does the Na+-independent pathway. In the presence of physiological concentrations of Na+, Ca2+ and Mg2+, the Na+-independent and the Na+-dependent pathways operate at rates, respectively, of 0.5 and 1.0 nmol of Ca2+.min-1.mg-1 in heart mitochondria and 0.9 and 0.2 nmol of Ca2+.min-1.mg-1 in liver mitochondria. It is concluded that both heart and liver mitochondria possess two independent pathways for Ca2+ efflux operating at comparable rates.     

Undesirable feature of safranine as a probe for mitochondrial membrane potential

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

Tissue-specific modulation of the mitochondrial calcium uniporter by magnesium ions

This paper analyzes the kinetics of the Ca2+ uniporter of mitochondria from rat heart, kidney and liver operating in a range of Ca2+ concentrations near the steady-state value (1-4 microM). Heart mitochondria exhibit the lowest activity, and physiological Mg2+ concentrations inhibit the mitochondrial Ca2+ uniporter by approx. 50% in heart and kidney, and by 20% in liver. At physiological Ca2+ and Mg2+ concentrations the external free Ca2+ maintained by respiring mitochondria in vitro is higher in heart and kidney with respect to liver mitochondria. This behaviour could represent an adaptation of different mitochondria to their specific intracellular environment.     

Characterization of the effects of Ca2+ on the intramitochondrial Ca2+-sensitive enzymes from rat liver and within intact rat liver mitochondria.

The regulatory properties of the Ca2+-sensitive intramitochondrial enzymes (pyruvate dehydrogenase phosphate phosphatase, NAD+-isocitrate dehydrogenase and 2-oxoglutarate dehydrogenase) in extracts of rat liver mitochondria appeared to be essentially similar to those described previously for other mammalian tissues. In particular, the enzymes were activated severalfold by Ca2+, with half-maximal effects at about 1 microM-Ca2+ (K0.5 value). In intact rat liver mitochondria incubated in a KCl-based medium containing 2-oxoglutarate and malate, the amount of active, non-phosphorylated, pyruvate dehydrogenase could be increased severalfold by increasing extramitochondrial [Ca2+], provided that some degree of inhibition of pyruvate dehydrogenase kinase (e.g. by pyruvate) was achieved. The rates of 14CO2 production from 2-oxo-[1-14C]glutarate at non-saturating, but not at saturating, concentrations of 2-oxoglutarate by the liver mitochondria (incubated without ADP) were similarly enhanced by increasing extramitochondrial [Ca2+]. The rates and extents of NAD(P)H formation in the liver mitochondria induced by non-saturating concentrations of 2-oxoglutarate, glutamate, threo-DS-isocitrate or citrate were also increased in a similar manner by Ca2+ under several different incubation conditions, including an apparent 'State 3.5' respiration condition. Ca2+ had no effect on NAD(P)H formation induced by beta-hydroxybutyrate or malate. In intact, fully coupled, rat liver mitochondria incubated with 10 mM-NaCl and 1 mM-MgCl2, the apparent K0.5 values for extramitochondrial Ca2+ were about 0.5 microM, and the effective concentrations were within the expected physiological range, 0.05-5 microM. In the absence of Na+, Mg2+ or both, the K0.5 values were about 400, 200 and 100 nM respectively. These effects of increasing extramitochondrial [Ca2+] were all inhibited by Ruthenium Red. When extramitochondrial [Ca2+] was increased above the effective ranges for the enzymes, a time-dependent deterioration of mitochondrial function and ATP content was observed. The implications of these results on the role of the Ca2+-transport system of the liver mitochondrial inner membrane are discussed.