Aspects of energy-linked calcium accumulation by rat heart mitochondria

Protective role of taurine against oxidative stress (Review)

Taurine is a fundamental mediator of homeostasis that exerts multiple roles to confer protection against oxidant stress. The development of hypertension, muscle/neuro‑​associated disorders, hepatic cirrhosis, cardiac dysfunction and ischemia/reperfusion are examples of some injuries that are linked with oxidative stress. The present review gives a comprehensive description of all the underlying mechanisms of taurine, with the aim to explain its anti‑oxidant actions. Taurine is regarded as a cytoprotective molecule due to its ability to sustain normal electron transport chain, maintain glutathione stores, upregulate anti‑oxidant responses, increase membrane stability, eliminate inflammation and prevent calcium accumulation. In parallel, the synergistic effect of taurine with other potential therapeutic modalities in multiple disorders are highlighted. Apart from the results derived from research findings, the current review bridges the gap between bench and bedside, providing mechanistic insights into the biological activity of taurine that supports its potential therapeutic efficacy in clinic. In the future, further clinical studies are required to support the ameliorative effect of taurine against oxidative stress.

Sarcoplasmic reticulum and calcium signaling in muscle cells: Homeostasis and disease

The sarco/endoplasmic reticulum is an extensive, dynamic and heterogeneous membranous network that fulfills multiple homeostatic functions. Among them, it compartmentalizes, stores and releases calcium within the intracellular space. In the case of muscle cells, calcium released from the sarco/endoplasmic reticulum in the vicinity of the contractile machinery induces cell contraction. Furthermore, sarco/endoplasmic reticulum-derived calcium also regulates gene transcription in the nucleus, energy metabolism in mitochondria and cytosolic signaling pathways. These diverse and overlapping processes require a highly complex fine-tuning that the sarco/endoplasmic reticulum provides by means of its numerous tubules and cisternae, specialized domains and contacts with other organelles. The sarco/endoplasmic reticulum also possesses a rich calcium-handling machinery, functionally coupled to both contraction-inducing stimuli and the contractile apparatus. Such is the importance of the sarco/endoplasmic reticulum for muscle cell physiology, that alterations in its structure, function or its calcium-handling machinery are intimately associated with the development of cardiometabolic diseases. Cardiac hypertrophy, insulin resistance and arterial hypertension are age-related pathologies with a common mechanism at the muscle cell level: the accumulation of damaged proteins at the sarco/endoplasmic reticulum induces a stress response condition termed endoplasmic reticulum stress, which impairs proper organelle function, ultimately leading to pathogenesis.

Mechanical, Biochemical, and Structural Effects of Vitamin D Deficiency on the Chick Heart

The effects of vitamin D depriva tion on the chick heart were investi gated from three aspects: cardiac contractility (±dP/dT), intracellular high-energy phosphorus compounds, and structural differences. Four- week-old vitamin D-deficient chicks were divided into four groups: Group A served as the normal group and re ceived subcutaneous injections of cholecalciferol; Groups B and C were vitamin D-deficient hearts but per fused differently; Group D received daily subcutaneous injections of 5 μg of 1,25(OH) 2D3. When the isolated spontaneously beating hearts (modi fied Langendorff preparation) were perfused with Krebs-Henseleit (KH) solution containing a calcium concen tration of 2.5mM, the myocardial contractility of the vitamin D-defi cient hearts was significantly in creased when compared with group A. After the isolated heart had beaten for one hour, the myocardial contractility in the vitamin D-defi cient hearts was found to decline to significantly lower values. Presacri fice administration of 1,25(OH) 2D3 improved cardiac performance. Vita min D deficiency resulted in an en hanced rate of decline of the intracellular high-energy phosphorus compounds. No differences were found in the microscopic study. These observations suggest that vitamin D has a role in cardiac function.

Mitochondrial calcium transport and the redox nature of the calcium-induced membrane permeability transition

Mitochondria possess a Ca²⁺ transport system composed of separate Ca²⁺ influx and efflux pathways. Intramitochondrial Ca²⁺ concentrations regulate oxidative phosphorylation, required for cell function and survival, and mitochondrial redox balance, that participates in a myriad of signaling and damaging pathways. The interaction between Ca²⁺ accumulation and redox imbalance regulates opening and closing of a highly regulated inner membrane pore, the membrane permeability transition pore (PTP). In this review, we discuss the regulation of the PTP by mitochondrial oxidants, reactive nitrogen species, and the interactions between these species and other PTP inducers. In addition, we discuss the involvement of mitochondrial redox imbalance and PTP in metabolic conditions such as atherogenesis, diabetes, obesity and in mtDNA stability.

Control mechanisms of mitochondrial Ca(2+) uptake - feed-forward modulation of aldosterone secretion

Mitochondrial Ca(2+) signal activates metabolism by boosting pyridine nucleotide reduction and ATP synthesis or, if Ca(2+) sequestration is supraphysiological, may even lead to apoptosis. Although the molecular background of mitochondrial Ca(2+) uptake has recently been elucidated, the regulation of Ca(2+) handling is still not properly clarified. In human adrenocortical H295R cells we found a regulatory mechanism involving p38 MAPK and novel-type PKC isoforms. Upon stimulation with angiotensin II (AII) these kinases are activated typically prior to the release of Ca(2+) and - most probably by reducing the Ca(2+) permeation through the outer mitochondrial membrane - attenuate mitochondrial Ca(2+) uptake in a feed-forward manner. The biologic significance of the kinase-mediated reduction of mitochondrial Ca(2+) signal is also reflected by the attenuation of AII-mediated aldosterone secretion. As another feed-forward mechanism, we found in HEK-293T and H295R cells that Ca(2+) signal evoked either by IP(3) or by voltage-gated influx is accompanied by a concomitant cytosolic Mg(2+) signal. In permeabilized HEK-293T cells Mg(2+) was found to be a potent inhibitor of mitochondrial Ca(2+) uptake in the physiologic [Mg(2+)] and [Ca(2+)] range. Thus, these inhibitory mechanisms may serve not only as protection against mitochondrial Ca(2+) overload and subsequent apoptosis but also have the potential to substantially alter physiological responses.

Effect of cytosolic Mg2+ on mitochondrial Ca2+ signaling

Cytosolic Ca2+ signals are followed by mitochondrial Ca2+ uptake, which, in turn, modifies several biological processes. Mg2+ is known to inhibit Ca2+ uptake by isolated mitochondria, but its significance in intact cells has not been elucidated. In HEK293T cells, activation of purinergic receptors with extracellular ATP caused cytosolic Ca2+ signals associated with parallel changes in cytosolic [Mg2+]. Neither signals were affected by omitting bivalent cations from the extracellular medium. The effect of store-operated Ca2+ influx on cytosolic Mg2+ concentration ([Mg2+]c) was negligible. Uncaged Ca2+ displaced Mg2+ from cytosolic binding sites, but for an equivalent Ca2+ signal, the change in [Mg2+] was significantly smaller than that measured after adding extracellular ATP. Inositol 1,4,5-trisphosphate mobilized Ca2+ and Mg2+ from internal stores in permeabilized cells. The increase of [Mg2+] in the range that occurred in ATP-stimulated cells inhibited mitochondrial Ca2+ uptake in permeabilized cells without affecting mitochondrial Ca2+ efflux. Therefore, the Mg2+ signal generated by Ca2+ mobilizing agonists may attenuate mitochondrial Ca2+ uptake.

Calcineurin regulates myocardial function during acute endotoxemia

RATIONALE

Cyclosporin A (CsA) is known to preserve cardiac contractile function during endotoxemia, but the mechanism is unclear. Increased nitric oxide (NO) production and altered mitochondrial function are implicated as mechanisms contributing to sepsis-induced cardiac dysfunction, and CsA has the capacity to reduce NO production and inhibit mitochondrial dysfunction relating to the mitochondrial permeability transition (MPT).

OBJECTIVES

We hypothesized that CsA would protect against endotoxin-mediated cardiac contractile dysfunction by attenuating NO production and preserving mitochondrial function.

METHODS

Left ventricular function was measured continuously over 4 h in cats assigned as follows: control animals (n = 7); LPS alone (3 mg/kg, n = 8); and CsA (6 mg/kg, n = 7), a calcineurin inhibitor that blocks the MPT, or tacrolimus (FK506, 0.1 mg/kg, n = 7), a calcineurin inhibitor lacking MPT activity, followed in 30 min by LPS. Myocardial tissue was then analyzed for NO synthase-2 expression, tissue nitration, protein carbonylation, and mitochondrial morphology and function.

MEASUREMENTS AND MAIN RESULTS

LPS treatment resulted in impaired left ventricular contractility, altered mitochondrial morphology and function, and increased protein nitration. As hypothesized, CsA pretreatment normalized cardiac performance and mitochondrial respiration and reduced myocardial protein nitration. Unexpectedly, FK506 pretreatment had similar effects, normalizing both cardiac and mitochondrial parameters. However, CsA and FK506 pretreatments markedly increased protein carbonylation in the myocardium despite elevated manganese superoxide dismutase activity during endotoxemia.

CONCLUSIONS

Our data indicate that calcineurin is a critical regulator of mitochondrial respiration, tissue nitration, protein carbonylation, and contractile function in the heart during acute endotoxemia.

Calcium-induced contraction of sarcomeres changes the regulation of mitochondrial respiration in permeabilized cardiac cells

The relationships between cardiac cell structure and the regulation of mitochondrial respiration were studied by applying fluorescent confocal microscopy and analysing the kinetics of mitochondrial ADP-stimulated respiration, during calcium-induced contraction in permeabilized cardiomyocytes and myocardial fibers, and in their 'ghost' preparations (after selective myosin extraction). Up to 3 microm free calcium, in the presence of ATP, induced strong contraction of permeabilized cardiomyocytes with intact sarcomeres, accompanied by alterations in mitochondrial arrangement and a significant decrease in the apparent K(m) for exogenous ADP and ATP in the kinetics of mitochondrial respiration. The V(max) of respiration showed a moderate (50%) increase, with an optimum at 0.4 microm free calcium and a decrease at higher calcium concentrations. At high free-calcium concentrations, the direct flux of ADP from ATPases to mitochondria was diminished compared to that at low calcium levels. All of these effects were unrelated either to mitochondrial calcium overload or to mitochondrial permeability transition and were not observed in 'ghost' preparations after the selective extraction of myosin. Our results suggest that the structural changes transmitted from contractile apparatus to mitochondria modify localized restrictions of the diffusion of adenine nucleotides and thus may actively participate in the regulation of mitochondrial function, in addition to the metabolic signalling via the creatine kinase system.

Inhibition by Ca2+ of the hydrolysis and the synthesis of ATP in Ehrlich ascites tumour mitochondria: relation to the Crabtree effect

Phosphorylation of ADP and hydrolysis of ATP by isolated mitochondria from Ehrlich ascites tumour cells is greatly reduced when the mitochondria have been preloaded with Ca2+ (50 nmol/mg protein or more). Translocation of ADP is diminished in Ca(2+)-loaded mitochondria. However, ATPase in toluene-permeabilized mitochondria and in inside-out submitochondrial particles is also strongly inhibited by micromolar concentrations of Ca2+, indicating that, independently of adenine nucleotide transport, F1Fo-ATPase is also affected. ATP hydrolysis by submitochondrial particles depleted of the inhibitory subunit of F1Fo-ATPase (the Pullman-Monroy protein inhibitor) is insensitive to Ca2+; however, this sensitivity is restored when the particles are supplemented with the inhibitory subunit isolated from beef heart mitochondria. In view of the previous observations that glucose elicits in Ehrlich ascites tumour cells an increase of cytoplasmic free Ca2+ (Teplova, V.V., Bogucka, K., Czyz, A., Evtodienko, Yu.V., Duszyński, J. and Wojtczak, L. (1993) Biochem. Biophys. Res. Commun. 196, 1148-1154) and that this calcium is then taken up by mitochondria, resulting in a strong inhibition of coupled respiration (Evtodienko, Yu.V., Teplova, V.V., Duszyński, J., Bogucka, K. and Wojtczak, L. (1994) Cell Calcium 15, 439-446), the present results are discussed in terms of the mechanism of the Crabtree effect in tumour cells.

Influence of the anesthetic 2,6-diisopropylphenol (propofol) on isolated rat heart mitochondria

The influence of the anesthetic 2,6-diisopropylphenol on isolated rat heart mitochondria has been investigated at a range of concentrations encompassing high and low clinical values. Low clinical concentrations of the anesthetic appeared unable to affect both oxidative phosphorylation and calcium homeostasis. 2,6-diisopropylphenol at high clinical levels decreased both the transmembrane electrical potential and the synthesis of ATP, while leaving mitochondrial calcium homeostasis unaffected. The results obtained suggest that isolated heart mitochondria are substantially insensitive to low clinical concentrations of 2,6-diisopropylphenol, thus largely excluding the possibility that mitochondrial alterations might be involved in the cardiac depression induced by this anesthetic.

Effect of magnesium administered during postischemic reperfusion on myocardial oxidative metabolism in isolated rat hearts

To determine the effect of magnesium on myocardial function and oxidative metabolism after reperfusion, isolated rat hearts perfused retrogradely with erythrocyte-enriched medium (0.4 mM palmitate bound to 0.4 mM albumin, 11 mM glucose) were subjected to 60 minutes of no-flow ischemia followed by 60 minutes of reperfusion. Untreated postischemic hearts exhibited after 15 minutes of reperfusion recovery of myocardial oxygen consumption to 65% of the preischemic value despite persistent depression of left ventricular isovolumic pressure development to 21%. Magnesium (15 mM) administered during the initial 30 minutes of reperfusion reduced myocardial oxygen consumption of reperfuse myocardium by 35%. Oxidation of [1-14C]palmitate was slightly more reduced (-55%) than oxidation of [U-14C]glucose (-42%). Magnesium did not influence ultimate recovery of contractile function and cumulative myocardial release of creatine kinase. Thus, 15 mM magnesium administered during reperfusion elicited a reduction of oxidative metabolism. However, magnesium did not modify myocardial injury.

The role of cytoplasmic [Ca2+] in glucose-induced inhibition of respiration and oxidative phosphorylation in Ehrlich ascites tumour cells: a novel mechanism of the Crabtree effect

The effect of Ca2+ on energy-coupling parameters of Ehrlich ascites carcinoma was studied in digitonin-permeabilized cells. In nominally Ca-free medium the permeabilized cells respond to the addition of ADP by increased oxygen uptake with externally added respiratory substrates (succinate or pyruvate), decrease of the mitochondrial membrane potential (delta psi) and alkalinization of the medium. This typical behaviour is drastically changed if Ca2+ is added. The subsequent addition of ADP induces neither State 3 respiration, nor decrease of delta psi, nor alkalinization of the medium, indicating a complete block of ATP synthesis. These effects are produced by both a single pulse of 100 microM Ca2+ and a preincubation for 2 min with 0.4-1.0 microM Ca2+. Preincubation of the cells with glucose or deoxyglucose prior to permeabilization makes them sensitive to Ca2+ concentrations as low as 0.3 microM. In view of the previous finding that glucose and deoxyglucose produce an increase of cytoplasmic [Ca2+] in Ehrlich ascites cells [Teplova VV. Bogucka K. Czyz A. Evtodienko YuV. Duszyński J. Wojtczak L. (1993) Biochem. Biophys. Res. Commun., 196, 1148-1154; Czyz A. Teplova VV. Sabala P. Czarny M. Evtodienko YuV. Wojtczak L. (1993) Acta Biochim. Polon., 40, 539-544], the present results suggest that cytoplasmic Ca2+ plays a crucial role in the Crabtree effect.

Effects of diltiazem on the calcium accumulation and ATP synthesis simultaneously sustained by isolated rat heart mitochondria

1. The effects of diltiazem have been investigated in isolated rat heart mitochondria exposed to conditions possibly attained in ischemia-damaged cells. 2. The results obtained indicate that diltiazem, at the concentrations expected within cells following pharmacological treatment, does not significantly affect the mitochondrial calcium content. 3. Diltiazem did not appear to modify ATP synthesis, and hence the capacity of mitochondria to sustain the ATP-requiring processes needed for the recovery of cardiac cells.

Myocardial energetics during ventricular fibrillation investigated by magnetization transfer nuclear magnetic resonance spectroscopy

Ventricular fibrillation (VF) is known to produce alterations in myocardial energetics, but the mechanism of these changes remains unclear. To investigate energy metabolism during VF, phosphorus nuclear magnetic resonance spectroscopy and magnetization transfer were applied to isolated perfused ferret hearts. VF was induced either by perfusion with digitalis (strophanthidin, 30 microM) or by high-frequency electrical stimulation. We measured the flux in two critical reactions: from inorganic phosphate (Pi) to ATP (ATP synthesis rate) and from phosphocreatine (PCr) to ATP (energy transfer capacity). During digitalis-induced VF, energy-related phosphates showed changes similar to those during hypoxia: myocardial [Pi] increased and [PCr] decreased. Concomitantly, the ATP synthesis rate increased to levels about threefold higher than control, whereas oxygen consumption increased by only 16%. The ATP synthesis rate exhibited a strong negative correlation with left ventricular pressure during VF (r = -0.95, n = 5, p < 0.02), whereas oxygen consumption did not (r = 0.19, p > 0.05). On the other hand, energy transfer capacity catalyzed by creatine kinase was significantly smaller during VF than in the control condition but still higher than the simultaneous ATP synthesis rate. In contrast to the marked energetic deterioration during VF induced by digitalis, electrically induced VF led to only a small increase in [Pi] and a small decrease in [PCr], and there were no significant changes in the ATP synthesis rate, energy transfer capacity, or O2 consumption. These results indicate that the rundown in energy metabolism during VF induced by digitalis was mainly attributable to a limitation of energy production through oxidative phosphorylation as well as to a marked increase in energy consumption. In contrast, myocardial energy generation remained unimpaired during VF induced by electrical stimulation. Intracellular calcium overload is more severe during VF induced by digitalis than during electrically induced VF (Circ Res 1991;68:1378-1389); severe calcium overload would be expected to compromise the capacity for energy generation by mitochondria. Thus, we propose that known differences in cellular calcium loading underlie the discrepant energetic patterns of the two types of VF.

Dehydrogenase activation by Ca2+ in cells and tissues

The activation of intramitochondrial dehydrogenases by Ca2+ provides a link between the intensity of work performance by a tissue and the activity of pyruvate dehydrogenase and the tricarboxylate cycle, and hence the rate of ATP production by the mitochondria. Several aspects of this model of the control of oxidative phosphorylation are examined in this article, with particular emphasis on mitochondrial functioning in situ in cardiac myocytes and in the intact heart. Recent use of the fluorescent Ca2+ chelating agents indo-1 and fura-2 has allowed a more quantitative description of the dependence of dehydrogenase activity upon concentration of free intramitochondrial Ca2+, in experiments with isolated mitochondria. Further, a novel technique developed by Miyata et al. has allowed description of free intramitochondrial Ca2+ within a single cardiac myocyte, and the conclusion that this parameter changes in response to electrical excitation of the cell over a range which would be expected to give substantial modulation of dehydrogenase activity.

Sensitivity to oxidants of mitochondrial and sarcoplasmic reticular calcium uptake in saponin-treated cardiac myocytes

Calcium transport functions of mitochondria and sarcoplasmic reticulum (SR) were studied without prior extraction using isolated rat heart myocytes permeabilized with saponin. Calcium uptake by SR was rapid and its affinity was high in comparison to calcium uptake by mitochondria, which had a higher capacity. The sensitivity of uptake to two oxidants, H2O2 and HOCl (hypochlorous acid), depended on the cytosolic calcium concentration; when this was similar to the concentration in diastole (180 nM), HOCl inhibited calcium uptake by mitochondria and SR, whereas when the calcium concentration was 750 nM, mitochondrial calcium uptake showed relatively high resistance, although SR uptake was still markedly inhibited by HOCl. Calcium uptake of both mitochondria and SR was less sensitive to the action of H2O2 than to HOCl, and the H2O2 effect was less dependent on the cytosolic calcium concentration. Therefore, HOCl, when produced by activated leukocytes and supplied to the heart cells, may seriously impair the excitation-contraction coupling function of SR, whereas H2O2, possibly generated directly by mitochondria or generated from superoxide anions, may be tolerated relatively well by heart SR and mitochondria.

Overall tolerance and safety of quinapril in clinical trials

A comprehensive analysis of the reporting of adverse events, withdrawals due to adverse events, and serious adverse events has been conducted on 2,010 patients treated with quinapril hydrochloride. An analysis of all events (from both double-blind and open label studies combined) showed no increase in the incidence of events reported in congestive heart failure (CHF) patients compared to hypertensive patients. When the data for all studies were combined, an age analysis showed no increase in the total reporting of adverse events in the 379 elderly patients studied. The incidence of events was lower in those patients who did not take concomitant diuretic therapy. A comparison of the double-blind phases showed quinapril to have a lower incidence of adverse events than captopril, enalapril, or chlorthalidone. An analysis of the onset of events, or withdrawals, did not show an increase with time on quinapril therapy, and no dose-relationship. A review of serious adverse events did not reveal an unexpected occurrence or a high incidence of serious events considered to be related to quinapril therapy. The proportion of patients who experienced "first-dose" hypotension, or symptomatic hypotension was similar to captopril or enalapril. Quinapril, a nonsulfhydryl ACE inhibitor, has been extensively studied and is equally well tolerated in the young and elderly for the treatment of hypertension and CHF.

Calcium oscillations in digitalis-induced ventricular fibrillation: pathogenetic role and metabolic consequences in isolated ferret hearts

The pathophysiology of the ventricular fibrillation that complicates digitalis intoxication was investigated. In this and other calcium-overload states, oscillations of the intracellular free calcium concentration ([Ca2+]i) have been implicated as the cause of ventricular tachyarrhythmias. We addressed two questions: 1) Are [Ca2+]i oscillations obligatory in the pathogenesis of ventricular fibrillation during digitalis toxicity? 2) What are the metabolic consequences of [Ca2+]i oscillations? Ferret hearts (n = 20) were Langendorff-perfused at constant flow with oxygenated HEPES-buffered Tyrode's solution at 37 degrees C. Isovolumic left ventricular pressure was measured along with the extracellular electrogram or with simultaneous phosphorus nuclear magnetic resonance spectra. When strophanthidin (20 microM) was added during pacing at 3 Hz, the positive inotropic effect soon gave way to a decrease in developed force. The decrease in force was accompanied by an increase in inorganic phosphate concentration, a decrease in phosphocreatine concentration, and a slight acidosis. The rhythm changed to ventricular fibrillation after 12-25 minutes. This change was initially accompanied by further metabolic deterioration, but all metabolites reached steady state within 12-18 minutes of the onset of ventricular fibrillation. Fast Fourier transformation revealed the existence of periodic oscillations at 7-10 Hz in both the extracellular electrogram and the ventricular pressure during ventricular fibrillation. Ryanodine, an inhibitor of [Ca2+]i oscillations, abolished the pressure oscillations but not the voltage oscillations. Exposure to ryanodine significantly decreased the inorganic phosphate concentration and increased the phosphocreatine concentration (p less than 0.05) despite continuing exposure to strophanthidin. The results indicate that oscillations of [Ca2+]i are not required to sustain ventricular fibrillation, but when present, such oscillations contribute importantly to metabolic deterioration.

Calcium transport and catabolism of adenosine triphosphate in the protozoan parasite Giardia lamblia

1. Calcium uptake by washed trophozoites of Giardia lamblia was dependent on inorganic orthophosphate and stimulated by glucose. Uptake was both rapid and substantial: 224 +/- 73 nmoles Ca2+/mg protein/min. 2. Known inhibitors of Ca2+ uptake in mammalian cells also impeded Ca2+ influx into G. lamblia. 3. The inhibitor studies indicated that Ca2+ transport in G. lamblia was an active process. Energy for such a process could be provided by the action of ATPases. 4. Two types of ATPases were found in the parasite; one, a membrane-associated enzyme activated by Ca2+; the other, a soluble, cytosolic enzyme activated by Mg2+. 5. These enzymes differed not only in their intracellular distribution and divalent cation requirements, but also in their sensitivity to calmodulin antagonists. The particulate enzyme was sensitive to these inhibitors whereas the soluble ATPase was not. 6. Our data indicate that Ca2+ transport in G. lamblia is mediated by a membrane-bound, calmodulin-regulated, Ca2+-ATPase.

Inhibition of oxidative phosphorylation by Ca2+ or Sr2+: a competition with Mg2+ for the formation of adenine nucleotide complexes

Intramitochondrial Sr2+, similar to Ca2+, inhibits oxidative phosphorylation in intact rat-liver mitochondria. Both Ca2+ and Sr2+ also inhibit the hydrolytic activity of the ATPase in submitochondrial particles. Half-maximal inhibition of ATPase activity was attained at a concentration of 2.5 mM Ca2+ or 5.0 mM Sr2+ when the concentration of Mg2+ in the medium was 1.0 mM. The inhibition of ATPase activity by both cations was strongly decreased by increasing the Mg2+ concentration in the reaction medium. In addition, kinetical data and the determination of the concentration of MgATP, the substrate of the ATPase, in the presence of different concentrations of Ca2+ or Sr2+ strongly indicate that these cations inhibit ATP hydrolysis by competing with Mg2+ for the formation of MgATP. On the basis of a good agreement between these results with submitochondrial particles and the results of titrations of oxidative phosphorylation with carboxyatractyloside or oligomycin in mitochondria loaded with Sr2+ it can be concluded that intramitochondrial Ca2+ or Sr2+ inhibits oxidative phosphorylation in intact mitochondria by decreasing the availability of adenine nucleotides to both the ADP/ATP carrier and the ATP synthase.

Regulation of the mitochondrial ATP synthase/ATPase complex

The mitochondrial ATP synthase/ATPase (F0F1 ATPase) is perhaps the most complex enzyme known. In animal systems it consists of a minimum of 11 different polypeptide chains, 10 (or more) of which appear to be essential for function, and 1 called the "ATPase inhibitor peptide" which is involved in regulation. Recent studies from a variety of laboratories indicate that the ATP synthase/ATPase complex is regulated by several interrelated factors including the thermodynamic poise of the proton gradient across the inner mitochondrial membrane; the ATPase inhibitor peptide; ADP (and/or ADP and Pi); divalent cations; and perhaps the redox state of SH groups on the F1 molecule. The central focus of this review is the ATPase inhibitor peptide. A model involving four distinct conformational states of F1 seems essential to account for the inhibitor's mode of action. The model depicts the ATPase inhibitor protein as acting at the asymmetric center of the F1 moiety. In addition, it accounts for the "unidirectional" role of the inhibitor peptide as a "down regulator" of ATP hydrolysis and for its binding/debinding dependence on the proton motive force and other regulatory factors. Finally, it is suggested that during any physiological process, where there is an energy demand followed by a resting phase, the F1 molecule may follow a "cyclic" path involving the four distinct conformational states of the enzyme.

Influence of severe hypoglycemia on brain extracellular calcium and potassium activities, energy, and phospholipid metabolism

In the cerebral cortices of rats, during insulin-induced hypoglycemia, changes in the concentrations of labile phosphate compounds [ATP, ADP, AMP, and phosphocreatine (PCr)] and glycolytic metabolites (lactate, pyruvate, and glucose) as well as phospholipids and free fatty acids (FFAs) were studied in relation to extracellular potassium and calcium activities. Changes in extracellular calcium and potassium activities occurred at approximately the onset of isoelectricity . The extracellular calcium activity dropped from 1.17 +/- 0.14 mM to 0.18 +/- 0.28 mM and the potassium activity rose from 3.4 +/- 0.94 mM to 48 +/- 12 mM (means +/- SD). Minutes prior to this ionic change the levels of ATP, PCr, and phospholipids were unchanged while the levels of FFAs remained unchanged or slightly elevated. Following the first ionic change the steady-state levels of ATP decreased by 40%, from 2.42 to 1.56 mumol/g. PCr levels decreased by 75%, from 4.58 to 1.26 mumol/g. Simultaneously, the levels of FFAs increased from 338 to 642 nmol/g, arachidonic acid displaying the largest relative increase, 33 to 130 nmol/g. The first ionic change was followed by a short period of normalization of ionic concentrations followed by a sustained ionic change. This was accompanied by a small additional decrease in ATP (to 1.26 mumol/g). The FFA levels increased to 704 nmol/g. There was a highly significant negative correlation between the levels of FFAs and the energy charge of the tissue. The formation of FFAs was accompanied by a decrease in the phospholipid pool. The largest relative decrease was observed in the inositol phosphoglycerides, followed by serine and ethanolamine phosphoglycerides.(ABSTRACT TRUNCATED AT 250 WORDS)

Alterations in liver mitochondrial function as a result of fasting and exhaustive exercise

The effect of exercise upon liver mitochondria structure and function was examined in fasted and fed rats, following a single run to exhaustion on a motor-driven treadmill. Exercise alone and exercise coupled with fasting both produced a significant decrease in the amount of hexokinase bound to the mitochondria, as well as reduction in the ADP/O ratio and acceptor control index measured in the presence of succinate. The mitochondria of the exercised animals, when exposed to freeze-fracture analysis while in state 3, displayed fewer deflections in the fracture plane between the inner and outer membrane than those isolated from control animals. This suggests that fewer contacts existed between the two membranes. Measurements based upon the binding of 8-anilinonaphthalene 1-sulphonate indicated that there was an increase in the net negative charge on the surface of the mitochondrial membranes of the exercised animals. All of these effects could be mimicked by incubation of mitochondria from control animals with free fatty acids. This fact, coupled with the observation that washing of the mitochondria with a solution comprising 5% (w/v) albumin could reverse all of the consequences of exercise, suggests that these alterations in mitochondrial structure and function may be the result of the increase in plasma free fatty acids that accompanies long-term exercise. Furthermore, the observation that the exercise-induced changes are dynamic and readily reversible indicates that the mitochondria were not necessarily damaged, but rather that the coupling of oxidative phosphorylation may be subject to physiological regulation.

Maintenance of aerobic metabolism during global ischemia with perfluorocarbon cardioplegia improves myocardial preservation

We used phosphorus-31 nuclear magnetic resonance to test the ability of a perfluorocarbon blood substitute that has been shown in previous studies to improve oxygen delivery to hypothermic myocardium to maintain aerobic high-energy phosphate metabolism during total global ischemia. Twenty-three isolated perfused rabbit hearts were subjected to 180 min of hypothermic (23 degrees C) global ischemia followed by 45 min of normothermic reperfusion. Hearts received multiple doses of a cardioplegic solution that contained either oxygenated perfluorocarbon (Fluosol O2), nonoxygenated perfluorocarbon (Fluosol N2), or standard crystalloid hyperkalemic cardioplegic solution (STD-KCl) at 30 min intervals. Recovery of isovolumic left ventricular developed pressure (LVDP) was used to assess preservation of contractile function. Recovery of LVDP was 84 +/- 19% of preischemic control values with Fluosol O2, 68 +/- 16% with Fluosol N2, and 67 +/- 17% with STD-KCl (p = .058 vs Fluosol N2 and p = .056 vs STD-KCl). During 3 hr of ischemia intracellular pH (pHi) fell to 6.68 +/- 0.20 with STD-KCl and to 6.71 +/- 0.14 with Fluosol N2 but remained above 7.00 throughout the ischemic period with Fluosol O2 (p less than .0001 vs Fluosol N2 or STD-KCl). Myocardial ATP content was better preserved at 107 +/- 14% of control values with Fluosol O2 compared to 60 +/- 18% of control with Fluosol N2 and 75 +/- 21% of control with STD-KCl (p less than .001 vs Fluosol N2, p = .002 vs STD-KCl). Phosphocreatine (PCr) was also better preserved with Fluosol O2.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibition of oxidative phosphorylation by a Ca2+-induced diminution of the adenine nucleotide translocator

The mechanism through which internal Ca2+ inhibits oxidative phosphorylation of rat heart mitochondria has been explored. In parallel to a Ca2+-induced diminution of the activity of the adenine nucleotide translocator, an efflux of internal adenine nucleotides is observed. The efflux of adenine nucleotides depends on the amount of Ca2+ accumulated by the mitochondria and on the time that Ca2+ remains in the mitochondria; this efflux is atractyloside insensitive. These results suggest that internal Ca2+, by inducing a lowering of the internal concentration of adenine nucleotides, diminishes the rate of exchange of adenine nucleotides via the translocase, and in consequence of oxidative phosphorylation. Under conditions in which the Ca2+-induced release of adenine nucleotides takes place, no gross changes of the permeability properties of the membrane are observed. As revealed by studies with arsenate, respiratory activity and the function of the ATPase in the direction of ATP synthesis are not affected by internal Ca2+.

Role of calcium in the inotropic effects of caffeine in cardiac Purkinje fibers

The inotropic effects of caffeine (1-3 mM) were studied in the presence and absence of strophanthidin in canine Purkinje fibers perfused in vitro. Caffeine (1 mM) induced a similar initial increase in contractile force in different calcium solutions (+22, +23 and +24% in 0.54, 2.7 and 8.1 mM calcium, respectively) and when propranolol (3.4 X 10(-6) M) was present. Also, caffeine increased contractile force in high potassium (16.2 mM) at a time when the slow action potentials were unaltered. After the increase, 1 mM caffeine decreased force by about 50%, and the decrease was larger when caffeine (3 mM) or [Ca]0 (8.1 mM) was higher. In the presence of caffeine, strophanthidin (3 X 10(-7)-1 X 10(-6) M) increased force (+302%) if caffeine (0.3 mM) and Ca concentrations (0.54 mM) were low. If either caffeine or calcium was increased, strophanthidin had no effect or decreased force. Strophanthidin alone increased force and then decreased it; caffeine increased force in the first stage and decreased it during the second stage. The positive inotropic effect (+224%) of low sodium (78.4 mM versus 149.4 mM in Tyrode solution) was also abolished by caffeine (-24%). In ventricular muscle fibers, caffeine increased force more (+59%) and reduced force less in the presence of strophanthidin. The results indicate that caffeine increases force initially by releasing calcium from intracellular stores. The caffeine-induced decline in force is modulated by calcium in that it is exaggerated by agents or procedures which increase cellular calcium (strophanthidin, high calcium, low sodium solutions) and is reversed in a low calcium solution.

The transport of cations in mitochondria

The present paper has reviewed several factors related to ion transport and examined the properties of cation transport in mitochondria. The analysis suggests that: (1) The concept that a metabolically dependent electrical potential across the mitochondrial membrane plays a role in determining ion fluxes and steady-state concentrations is not justified and the data indicate that such exchanges are generally electroneutral. (2) Generally, the influx and efflux of an ion proceed by the same mechanism with at least one exception. (3) There are indications that some of the steps in transport are common to several cations. (4) The idea that carrier or ionophoric molecules are involved in cation transport has been examined in some detail together with the possible involvement of some known mitochondrial components. In particular, a model has been introduced in which local charge imbalances produced by H+ fluxes serve as the driving force of transport. The molecules of the complex are arranged in series in a tripartite arrangement including a filter or gate, a nonselective channel and an H+-transferring portion linked to either electron transport or the ATPase. Parts of this model have been introduced by other investigators. Models in which different portions of channels have differing functions have been proposed previously for other transport systems.

The effect of glucagon on the kinetics of hepatic mitochondrial calcium uptake

Previous work by this and other laboratories has shown that glucagon administration stimulates calcium uptake by subsequently isolated hepatic mitochondria. This stimulation of hepatic mitochondrial Ca2+ uptake by in vivo administration of glucagon was further characterized in the present report. Maximal stimulation of mitochondrial Ca2+ accumulation was achieved between 6-10 min after the intravenous injection of glucagon into intact rats. Under control conditions, Ca2+ uptake was inhibited by the presence of Mg2+ in the incubation medium. Glucagon treatment, however, appeared to obliterate the observed inhibition by Mg2+ of mitochondrial Ca2+ uptake. Kinetic experiments revealed the usual sigmoidicity associated with initial velocity curves for mitochondrial calcium uptake. Glucagon treatment did not alter this sigmoidal relationship. Glucagon treatment significantly increased the V max for Ca2+ uptake from 292 +/- 22 to 377 +/- 34 nmoles Ca2+/min per mg protein (n = 8) but did not affect the K 0.5, (6.5-8.6 microM). Since the major kinetic change in mitochondrial Ca2+ uptake evoked by glucagon is an increase in V max, the enhancement mechanism is likely to be an increase either in the number of active transport sites available to Ca2+ or in the rate of Ca2+ carrier movement across the mitochondrial membranes.

Active transport of Ca2+ in bacteria: bioenergetics and function

The bioenergetics of Ca2+ transport in bacteria are discussed with special emphasis on the interrelationship between transport and other cellular functions such as substrate oxidation by the respiratory chain and oxidative phosphorylation. The unusual polarity of Ca2+ movement provides an exceptional tool to compare active transport and other ATP requiring or generating processes since this ion is actively taken up by everted vesicles in which the coupling-factor ATPase is exposed to the external medium. As inferred from studies with everted vesicles, the active extrusion of Ca2+ by whole cells can be accomplished by substrate driven respiration, hydrolysis of ATP or as in the case of Streptococcus faecalis by a nonhydrolytic unknown process which involves ATP directly. Substrate oxidation and the hydrolysis of ATP result in the generation of a pH gradient which can energize the Ca2+ uptake directly (Ca2+/H+ antiport) or via a secondary Na+ gradient (Ca2+/Na+ antiport). In contrast to exponentially growing cells sporulating Bacilli accumulate Ca2+ during the synthesis of dipicolinic acid. Studies involving Ca2+ transport provided evidence in support of the hypothesis that the Mg2+ ATPase from Escherichia coli not only provides the driving force for various cellular functions but exerts a regulatory role by controlling the permeability of the membrane to protons. The different specificity requirements of various naphthoquinone analogs in the restoration of transport or oxidative phosphorylation, after the natural menaquinone has been destroyed by irradiation, has indicated that a protonmotive force is sufficient to drive active transport. However, in addition to the driving force (protonmotive force) necessary to establish oxidative phosphorylation, a specific spatial orientation of the respiratory components, such as the naphthoquinones, is essential for the utilization of the proton gradient or membrane potential or both. Finally, evidence suggesting that intracellular Ca2+ levels might play a fundamental role in bacterial homeostasis is discussed, in particular the role of Ca2+ in the process of chemotaxis and in conferring bacteria heat stability. A vitamin K-dependent carboxylation reaction has been found in Escherichia coli which is similar to that reported in mammalian systems which results in gamma carboxylation of glutamate residues. Although all of the proteins containing gamma-carboxyglutamate described so far are involved in Ca2+ metabolism, the role of these proteins in Escherichia coli is unknown and remains to be elucidated.

Ca(2+) transport in mitochondrial and microsomal fractions from higher plants

Mitochondria from etiolated corn possess a much greater Ca(2+) uptake capacity per mg protein than microsomes from the same source. Differences in energy requirements, sensitivity to specific inhibitors, and sedimentation properties enabled us to study both Ca(2+) uptake mechanisms without mutual contamination. The microsomal Ca(2+) uptake does not vary much among different plants as compared to the mitochondrial Ca(2+) uptake; this is also true for different organs of the same plant. Mitochondrial Ca(2+) uptake is more dependent on the age of the seedlings than microsomal uptake, because of changes in active Ca(2+) uptake activity rather than of changes in efflux. Intactness and the oxidative and phosphorylative properties of the mitochondria remained unchanged during this time period. Na(+) and Mg(2+) do not induce Ca(2+) release from mitochondria.

Control of activity states of heart mitochondrial ATPase. Role of the proton-motive force and Ca2+

The ATPase complex of submitochondrial particles exhibits activity transitions that are controlled by the natural ATPase inhibitor (Gómez-Puyou, A., Tuena de Gómez-Puyou, M. and Ernster, L. (1979) Biochim. Biophys. Acta 547, 252-257). The ATPase of intact heart mitochondria also shows reversible activity transitions; the activation reaction is induced by the establishment of electrochemical gradients, whilst the inactivation reaction is driven by collapse of the gradient. In addition it has been observed that the influx of Ca2+ into the mitochondria induces a rapid inactivation of the ATPase; this could be due to the transient collapse of the membrane potential in addition to a favorable effect of Ca2+-ATP on the association of the ATPase inhibitor peptide to F1-ATPase. This action of Ca2+ may explain why mitochondria utilize respiratory energy for the transport of Ca2+ in preference to phosphorylation. It is concluded that the mitochondrial ATPase inhibitor protein may exert a fundamental regulatory function in the utilization of electrochemical gradients.

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.

Calcium uptake by two preparations of mitochondria from heart

Ca/+ transport and respiratory characteristics of two preparations of cardiac mitochondria (Palmer, J.W., Tandler, B. and Hoppel, C.L. (1977) J. Biol. Chem. 252, 8731-8739) isolated using polytron homogenization (subsarcolemmal mitochondria) and limited Nagarse exposure (intermyofibrillar mitochondria) are described. The Nagarse procedure yields mitochondria with 50% higher rates of oxidative phosphorylation than the polytron-prepared mitochondria in both rat and dog. Rat hear intermyofibrillar mitochondria contain 50% more cytochrome aa3 than the polytron preparation, whereas in the dog, cytochrome aa3 content is not significantly different. Cytochrome oxidase activities and cytochrome c, c1 and b contents were comparable in both populations of rat and dog heart mitochondria. The V of succinate-supported Ca2+ accumulation for Nagarse-prepared mitochondria from rat heart was 1.8-fold higher than the polytron-prepared mitochondria. In dog heart, the Nagarse preparation showed a 3.0-fold higher V for Ca2+ uptake compared to the polytron preparation. A lower apparent affinity for Ca2+ was demonstrated in the intermyofibrillar mitochondria for both species (Km is 2-2.5-fold higher). The Hill coefficient was 1 both mitochondrial types. Subsarcolemmal mitochondria from both species were treated with Nagarse to determine the role of this treatment on the observed differences. Nagarse did not alter any kinetic parameter of Ca2+ uptake. The properties of these mitochondria with reference to their presumed intracellular location may pertain to the role of mitochondria as an intracellular Ca2+ buffering mechanism in contractile tissue.

The effect of metal ions on mitochondrial pyridine dinucleotide transhydrogenase

Bovine heart submitochondrial particle transhydrogenase is inhibited by cations in a concentration and pH-dependent manner, and non-energy-linked transhydrogenation is inhibited to a greater extent by metals than the energy-linked reaction. The inhibition of the enzyme by Mg2+ is competitive with the NADP substrate and non-competitive with the NAD substrate. Mg2+ stimulates inactivation of the enzyme by 5,5'-dithiobis(2-nitrobenzoic acid), and protects against thermal and proteolytic inactivation. This suggests that Mg2+ binding in the NADP site alters transhydrogenase to a more thermostable conformation, which is less susceptible to attack by trypsin and more reactive with 5,5'-dithiobis(2-nitrobenzoic acid). Other cation inhibitors mimic Mg2+ in these properties. The order of effectiveness of the inhibitors tested is La3+ greater than Mn2+ greater than Ca2+ congruent to Mg2+ greater than Sr2+ greater than Na+ congruent to K+. This order is described by the Irving-Williams order for the stability of metal-ligand complexes, suggesting that carboxylates or amines may comprise the inhibitory cation binding site.