The effect of butylated hydroxytoluene, an inhibitor of lipid peroxidation, on the calcium-induced uncoupling of rat liver mitochondria

The accumulation of Ca2+ by rat liver mitochondria in the presence of Pi results in spontaneous activation of respiration, accompanied by progressive loss of the accumulated cation. The lipid peroxidation inhibitor, butylated hydroxytoluene, completely prevents and reverses the loss of accumulated Ca2+ and restores respiration to the state 4 level, but exerts no effect on the rate of Ca2+ accumulation and respiration in the presence of the uncoupler. The strong inhibition by butylated hydroxytoluene of ruthenium red-insensitive Ca2+ efflux has also been observed. No correlation between the BHT-sensitive Ca2+ loss and the formation of malonic dialdehyde in mitochondria has been found. The data obtained suggest that the Ca2+-induced uncoupling of mitochondria is mainly due to the appearance of electrogenic ion fluxes that are controlled by the initial steps of lipid peroxidation.     

An antioxidant prevents and reverses calcium-induced uncoupling of rat liver mitochondria

Accumulation of Ca2+ by rat liver mitochondria in the presence of inorganic phosphate results in spontaneous activation of respiration accompanied by a progressive loss of the accumulated cation. The lipid peroxidation inhibitor, ionol, completely prevents and reverses the Ca2+/phosphate-induced loss of accumulated Ca2+ and restores the respiration to state 4 level without having any effect on the rate of Ca2+ accumulation and respiration in the presence of an uncoupler. No correlation between the ionol-dependent loss of Ca2+ and the formation of malonic dialdehyde in mitochondria was found. The measurements of delta psi across the inner mitochondrial membrane during a progressive loss of Ca2+ suggest that the Ca2+/phosphate-induced "uncoupling" is mainly due to the appearance of electrogenic fluxes (but not Ca2+ cycling) which is under control of some products of initial steps of lipid peroxidation.     

Effects of photodynamic action on energy coupling of Ca2+ uptake in liver mitochondria

In mitochondria isolated from rat liver, incubated in the presence of 6 X 10(-3) mM hematoporphyrin and irradiated with UV light at 365 nm, respiration, oxidative phosphorylation and Ca2+ uptake were measured in order to determine the respective photosensitivity of these functions. Irradiation with increasing doses produces uncoupling of oxidative phosphorylation followed by inhibition of Ca2+ uptake and finally arrest of respiration. Ca2+ uptake stimulated by the addition of ATP was also studied in mitochondria uncoupled by irradiation which were still able to concentrate Ca2+ aerobically. Anaerobic Ca2+ uptake driven by ATP hydrolysis was found to be similar in control and in irradiated mitochondria, suggesting a different photosensitivity for the ATPase as compared to the ATP-synthase activity.     

Effect of ebselen on Ca2+ transport in mitochondria

The seleno-organic compound ebselen mimics the glutathione-dependent, hydroperoxide reducing activity of glutathione peroxidase. The activity of glutathione peroxidase determines the rate of hydroperoxide-induced Ca2+ release from mitochondria. Ebselen stimulates Ca2+ release from mitochondria, accelerates mitochondrial respiration and uncoupling, and induces mitochondrial swelling, indicating a deterioration of mitochondrial function. These manifestations are abolished by cyclosporine A, a potent inhibitor of the mitochondrial permeability transition. However, when ebselen-induced Ca2+ cycling is prevented with ruthenium red, an inhibitor of the Ca2+ uniporter, or by chelation of extramitochondrial Ca2+ by EGTA, no detectable elevation of swelling or uncoupling is observed. The release of Ca2+ from mitochondria is delayed in the absence of rotenone, i.e. when pyridine nucleotides are maintained in the reduced state due to succinate-driven reversed electron flow. We suggest that ebselen induces Ca2+ release from intact mitochondria via an NAD+ hydrolysis-dependent mechanism.     

Glucagon stimulation of mitochondrial respiration.

Acute glucagon treatment of intact rats has been found to cause a stimulation of hepatic mitochondrial respiration as measured by monitoring oxygen uptake polarographically. Rates of State 3 respiration with several NAD-linked substrates and succinate were increased significantly after hormonal treatment and isolation of mitochondria. This stimulation cannot be ascribed to a partial uncoupling effect since State 4 respiration as measured by monitoring oxygen uptake polarographically. Rates of State 3 respiration with either slightly increased or unchanged. Furthermore, rates of uncoupled respiration with these substrates were also stimulated after hormonal treatment. On the other hand, respiratory rates (State 3, 4, and uncoupled) with ascorbate-N,N,N',N'-tetramethyl-p-phenylenediamine as substrate were unaffected by glucagon treatment. The hormonally stimulated rates of respiration produced a corresponding increase in the rate of generation of high energy state as indicated in measurements of Ca2+ uptake by isolated mitochondria. Rates of Ca2+ uptake were monitored by two methods: measurement of initial rates of proton ejection following CaCl2 additions and measurement of disappearance of Ca2+ from the suspension medium using murexide as indicator in a dual wavelength spectrophotometer. A significant stimulation in the initial rate of succinate-dependent Ca2+ uptake was noted after glucagon treatment of animals and isolation of hepatic mitochondria. No effect of the hormonal treatment was seen on the extent of Ca2+ uptake or the stoichiometry of H+ ejected per Ca2+ taken up. That the hormonal effect on Ca2+ transport is at the level of the substrate-induced generation of high energy state is indicated by the observation that no effect of glucagon treatment is seen on ATP-dependent Ca2+ uptake. Glucagon-induced changes in the activities of substrate-metabolizing enzymes are considered unlikely for the following reasons: (a) previously published data showed a lack of a hormonal effect on pyruvate-metabolizing enzymes and (b) data in this study showing no effect of glucagon treatment on the activity of NAD-malate dehydrogenase as measured in mitochondrial lysates. All of these observations are consistent with either an activation of mitochondrial substrate transport and/or a stimulation of mitochondrial electron transport by glucagon treatment. Regardless of the exact mechanism involved, the effect of the hormonal treatment is to produce an increase in ATP synthetic and ion-pumping capability during a period of increased energy demand, i.e. increased gluconeogenesis.     

Why is inorganic phosphate necessary for uncoupling of oxidative phosphorylation by Cd2+ in rat liver mitochondria?

The phosphate (Pi)-dependent uncoupling action of Cd2+ in oxidative phosphorylation in rat liver mitochondria was studied mainly in terms of Pi transport. Cd2+ at 2 microM caused full uncoupling in the presence of 10 mM Pi, but no uncoupling in the absence of Pi. Cd2+ released state 4 respiration after a certain lag-time, and then the respiration increased progressively with time. After its addition, Cd2+ was taken up by mitochondria in a similar period to the lag time before respiratory release. KIH-201, a potent and specific inhibitor of Pi transport via the Pi/H+ symporter, abolished the uncoupling completely. Cd2+ caused dissipation of the electric transmembrane potential (delta psi) and swelling of mitochondria in a Pi-dependent manner. Uncoupling by Cd2+ was found to take place in parallel with the uptake of Pi into mitochondria via the Pi/H+ symporter, suggesting that the uncoupling was due to acceleration of H+ influx through the Pi/H+ symporter activated by Cd2+.     

Metabolic Changes Induced by Cold Stress in Rat Liver Mitochondria

The mechanisms involved in the metabolic changes induced by cold stress in isolated rat liver mitochondria were studied. Respiration, ATP synthesis, and membrane potential as well as the contents of several metabolites were determined in liver mitochondria from cold-exposed rats. At different times of cold exposure, the force-flux relationships showed net variation in flux (enhanced respiration, diminished ATP synthesis) with no associated variation in force (H+ gradient); this suggested that decoupling rather than classical uncoupling was involved in the effects of cold stress. The flux control coefficient of the H+ leak on basal respiration was slightly increased by 380 h of cold exposure. Cold stress also induced a diminution in total membrane fatty acids, Zn2+, Fe3+, ATP, and ADP/O ratios; the content of cytochromes c + c1 and b oscillated. The contents of Ca2+, Na+, Pi, and cytochromes a + a3 were not affected, whereas matrix ADP, AMP, K+, and Mg2+ were markedly increased. Basal and oleic acid-stimulated respiration of mitochondria from cold-stressed rats was inhibited by GDP, carboxyatractyloside, or albumin. These agents did not affect basal respiration in control mitochondria. Western blot analysis showed enhanced expression of a protein of about 35 kDa, presumably the uncoupling protein 2, induced by long-term cold exposure. The overall data suggest that cold stress promoted decoupling of oxidative phosphorylation, and hence, changes in several matrix metabolites, by increasing free fatty acids and the UCP2 content.     

Effect of ruthenium red on the induction by Ca2+ ions of the beta- and gamma states of comuton regulation of mitochondrial respiration and oxidative phosphorylation

Preincubation of liver mitochondria (Mch) with Ca2+ ions at inorganic phosphate concentration less than I mM in the presence of liver cell soluble phase (CSP) induced rotenone-independent tissue-specific uncoupling of oxidative phosphorylation (beta state of comuton regulation) and rotenone-stimulated tissue-specific uncoupling (gamma state of comuton regulation). The reduction in K+ ion concentration in the incubation medium entirely inhibited the induction of beta state. Tissue-specific stimulation of the rat liver Mch respiration in substrate-containing medium was increased after rotenone addition. Ruthenium red was added to the medium before and after the end of Mch preincubation with Ca2+ in the presence of CSP. The results suggest that limited Ca2+ transport in Mch is necessary for the induction of beta and gamma states of comuton regulation. Ca2+ ejected from Mch also participates in the induction of beta state of comuton regulation. Comuton receptor on the mitochondrial membrane surface is devoid of glyco- and mucoprotein components bound by ruthenium red.     

Mechanism of low intensity ultrasound effect on mitochondria

Ultrasound of 0,2 Wt/cm2 intensity affects the ionic transport across the mitochondrial membrane in vitro. In the presence of 1 mM EGTA in the incubation medium ultrasound slows down K+ exit into the external medium after the addition of an uncoupling agent (2,4-dinitrophenol). With the addition of 100 divided by 400 mM Ca2+ to the starting medium ultrasound makes the amount of Ca2+ absorbed by mitochondrial decrease and the rate of Ca2+/H+ electroneutral exchange increase. Without Ca2+ ultrasound does not influence the rate of coupled and 2,4-dinitrophenol uncoupled respiration and oxidative phosphorylation, i.e. does not produce strong functional changes.     

Features of the Uncoupling Effect of Fatty Acids in Liver Mitochondria of Mammals with Different Body Weight

In the presence of oligomycin, EGTA, and magnesium ions, the protonophore uncoupling activity of palmitate (V(Pal)) is determined as the ratio of the acceleration of respiration with palmitate to its concentration. Under these conditions, V(Pal) in liver mitochondria of one-month-old rats with the body weight of 50 g is 1.46-fold higher than in liver mitochondria of adult rats with the body weight of 250 g, whereas the uncoupling activity of FCCP does not depend on the age of the animals. The difference in V(Pal) is mainly due to its component insensitive to carboxyatractylate and glutamate (V(Ins)). This value is 2.9-fold higher in mitochondria of one-month-old rats than in those of adult rats. The protonophore activity of palmitate is similar in liver mitochondria of four-day-old and adult rats. In liver mitochondria of adult mammals (mouse, rat, guinea pig, rabbit), V(Pal) decreases with increase in the body weight of the animals. In double logarithmic coordinates, the dependence of the V(Pal) value on the body weight is linear with slope angle tangent of -0.18. The V(Pal) value is mainly contributed by its component V(Ins). In the presence of calcium ions, palmitate induces the nonspecific permeability of the inner membrane of liver mitochondria (pore opening). This Ca2+-dependent uncoupling effect of palmitate is less pronounced in mitochondria of one-month-old rats than in those of adult rats. In mitochondria of adult animals (mice, rats, and guinea pigs), the Ca2+-dependent uncoupling activity of palmitate is virtually the same. It is concluded that the protonophore uncoupling effect of palmitate in liver mitochondria of mammals, unlike its Ca2+-dependent effect, is associated with thermogenesis at rest and also with production of additional heat on cooling of the animals.     

Submicromolar Ca2+ regulates phosphorylating respiration by normal rat liver and AS-30D hepatoma mitochondria by different mechanisms

The stimulation of 2-oxoglutarate and NAD(+)-isocitrate dehydrogenase by Ca2+ in mitochondria from normal tissues has been proposed to mediate partially the activation of oxidative energy metabolism elicited by physiological elevations in cytosolic Ca2+. This mode of regulation may also occur in tumor cells in which several aspects of mitochondrial metabolism are known to be altered. This study provides a comparison of the stimulation by submicromolar concentrations of Ca2+ on the rates of ATP-generating (state 3) respiration under physiologically realistic conditions by mitochondria isolated from normal rat liver and from highly malignant rat AS-30D ascites hepatoma cells. The K0.5 for activation of glutamate-dependent state 3 respiration by Ca2+ in the presence of ATP at 37 degrees C was determined to be 0.70 +/- 0.05 (S.E.) microM for hepatoma mitochondria and 0.90 +/- 0.03 microM for rat liver mitochondria. This activation was also reflected by a Ca2(+)-induced shift in the oxidation-reduction state of hepatoma mitochondrial pyridine nucleotides to a more reduced level and Ca2+ stimulation of 14CO2 production from [1-14C]glutamate. Whereas the Ca2+ sensitivity of state 3 respiration by hepatoma mitochondria can be explained by the activation of 2-oxoglutarate and possibly NAD(+)-isocitrate dehydrogenases, the Ca2+ sensitivity of liver mitochondrial respiration appears to be predominantly mediated by activation of electron flow through ubiquinone and Complex III of the electron transport chain, as indicated by the specificity of the effects of Ca2+ on respiration with different oxidizable substrates. Although rat liver and hepatoma mitochondria employ different modes of Ca2(+)-activated ATP generation, these results support the hypothesis that changes in cytosolic Ca2+ play a significant role in the potentiation of energy production in tumor, as well as normal tissue.     

Involvement of Ca2+ release and activation of phospholipase A2 in mitochondrial dysfunction during anoxia

During anoxic incubation, depletion of mitochondrial ATP was followed by release of Ca2+ with concomitant increase in the rate of state 4 respiration due to disruption of the diffusion barrier against protons. The external addition of ATP and its non-metabolizable analog, beta,gamma-methylene adenosine 5'-triphosphate, prevented both the release of Ca2+ and increase in the rate of state 4 respiration. Addition of EGTA, which did not prevent release of the ion, resulted in little increase in the respiration rate. Addition of an inhibitor of mitochondrial phospholipase A2, such as quinacrine, dibucaine, or chlorpromazine, also prevented increase in the respiration rate without affecting Ca2+ release from mitochondria during anoxic incubation. Non-esterified polyunsaturated fatty acids were also found to be liberated from anoxic mitochondria. External addition of the ATP-analog, EGTA, and inhibitors of phospholipase A2 suppressed the liberation of non-esterified polyunsaturated fatty acids. Melittin and Ca2+, which activate phospholipase A2, increased the rate of state 4 respiration and the liberation of fatty acids. These findings support the hypothesis proposed previously that the following sequence changes occurs in mitochondria during anoxia; depletion of ATP, liberation of free calcium from mitochondria, and disruption of the diffusion barrier against H+ of the inner membrane. The results also indicate another event; activation of phospholipase A2 by release Ca2+ which results in H+ leakiness of the inner membrane.     

The activation of non-phosphorylating electron transport by adenine nucleotides in Jerusalem-artichoke (Helianthus tuberosus) mitochondria.

In isolated plant mitochondria the oxidation of both succinate and exogenous NADH responded in the expected manner to the addition of ADP or uncoupling agents, and the uncoupled rate of respiration was often in excess of the rate obtained in the presence of ADP. However, the oxidation of NAD+-linked substrates responded in a much more complex manner to the addition of ADP or uncoupling agents such as carbonyl cyanide p-trifluoromethoxyphenylhydrazone to mitochondria oxidizing pyruvate plus malate failed to result in a reliable stimulation; this uncoupled rate could be stimulated by adding AMP or ADP in the presence of oligomycin or bongkrekic acid. Spectrophometric measurements showed that the addition of AMP or ADP resulted in the simultaneous oxidation of endogenous nicotinamide nucleotide and the reduction of cytochrome b. ADP was only effective in bringing about these changes in redox state in the presence of Mg2+ whereas AMP did not require Mg2+. It was concluded that AMP activated the flow of electrons from endogenous nicotinamide nucleotide to cytochrome b, possible at the level of the internal NADH dehydrogenase.     

Effects of isocoumarins isolated from Paepalanthus bromelioides on mitochondria: uncoupling, and induction/inhibition of mitochondrial permeability transition

Isolated mitochondria may undergo uncoupling, and in presence of Ca(2+) at different conditions, a mitochondrial permeability transition (MPT) linked to protein thiol oxidation, and demonstrated by CsA-sensitive mitochondrial swelling; these processes may cause cell death either by necrosis or by apoptosis. Isocoumarins isolated from the Brazilian plant Paepalanthus bromelioides (Eriocaulaceae) paepalantine (9,10-dihydroxy-5,7-dimethoxy-1H-naptho(2,3c)pyran-1-one), 8,8'-paepalantine dimer, and vioxanthin were assayed at 1-50 microM on isolated rat liver mitochondria, for respiration, MPT, protein thiol oxidation, and interaction with the mitochondrial membrane using 1,6-diphenyl-1,3,5-hexatriene (DPH). The isocoumarins did not significantly affect state 3 respiration of succinate-energized mitochondria; they did however, stimulate 4 respiration, indicating mitochondrial uncoupling. Induction of MPT and protein thiol oxidation were assessed in succinate-energized mitochondria exposed to 10 microM Ca(2+); inhibition of these processes was assessed in non-energized organelles in the presence of 300 microM t-butyl hydroperoxide plus 500 microM Ca(2+). Only paepalantine was an effective MPT/protein thiol oxidation inducer, also releasing cytochrome c from mitochondria; the protein thiol oxidation, unlike mitochondrial swelling, was neither inhibited by CsA nor dependent on the presence of Ca(2+). Vioxanthin was an effective inhibitor of MPT/protein thiol oxidation. All isocoumarins inserted deeply into the mitochondrial membrane, but only paepalantine dimer and vioxantin decreased the membrane's fluidity. A direct reaction with mitochondrial membrane protein thiols, involving an oxidation of these groups, is proposed to account for MPT induction by paepalantine, while a restriction of oxidation of these same thiol groups imposed by the decrease of membrane fluidity, is proposed to account for MPT inhibition by vioxanthin.     

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.     

Role of the ADP/ATP-antiporter in fatty acid-induced uncoupling of Ca2+-loaded rat liver mitochondria

We show that Ca2+ loading of mitochondria substantially augments the myristate-induced decrease in the transmembrane electric potential difference (deltapsi). Such a Ca2+ action is without effect on the respiration rate and is not accompanied by the high-amplitude swelling when low concentrations of Ca2+ and myristate are used. The myristate-induced deltapsi decrease is prevented and reversed by cyclosporin A (CsA); the decrease is prevented and transiently reversed by nigericin. To explain these effects, we suggest that myristate induces opening of the mitochondrial permeability transition pore at a low-conductance state. Addition of carboxyatractylate (CAtr) after myristate induces the CsA-sensitive uncoupling, but when added after myristate and CsA, CAtr produces a decrease in deltapsi, if the interval between myristate and CsA addition is sufficiently long. The CAtr effect is completely reversed by EGTA and transiently reversed by nigericin. This suggests that the ADP/ATP-antiporter participates in the CsA-sensitive uncoupling when present as a pore complex constituent. ADP/ATP-antiporter that does not take part in the pore complex formation is involved in the CsA-insensitive uncoupling.     

Brain mitochondria are primed by moderate Ca2+ rise upon hypoxia/reoxygenation for functional breakdown and morphological disintegration

In animal models, brain ischemia causes changes in respiratory capacity, mitochondrial morphology, and cytochrome c release from mitochondria as well as a rise in cytosolic Ca2+ concentration. However, the causal relationship of the cellular processes leading to mitochondrial deterioration in brain has not yet been clarified. Here, by applying various techniques, we used isolated rat brain mitochondria to investigate how hypoxia/reoxygenation and nonphysiological Ca2+ concentrations in the low micromolar range affect active (state 3) respiration, membrane permeability, swelling, and morphology of mitochondria. Either transient hypoxia or a micromolar rise in extramitochondrial Ca2+ concentration, given as a single insult alone, slightly decreased active respiration. However, the combination of both insults caused devastating effects. These implied almost complete loss of active respiration, release of both NADH and cytochrome c, and rupture of mitochondria, as shown by electron microscopy. Mitochondrial respiration deteriorated even in the presence of cyclosporin A, documenting that membrane permeabilization occurred independent of mitochondrial permeability transition pore. Ca2+ has to enter the mitochondrial matrix in order to mediate this mitochondrial injury, because blockade of the mitochondrial Ca2+-transport system by ruthenium red in combination with CGP37157 completely prevented damage. Furthermore, protection of respiration from Ca2+-mediated damage by the adenine nucleotide ADP, but not by AMP, during hypoxia/reoxygenation is consistent with the delayed susceptibility of brain mitochondria to prolonged hypoxia, which is observed in vivo.     

t-Butylhydroperoxide-induced Ca2+ efflux from liver mitochondria in the presence of physiological concentrations of Mg2+ and ATP

Isolated rat liver mitochondria, energized either by succinate oxidation or by ATP hydrolysis, present a transient increase in the rate of Ca2+ efflux concomitant to NAD(P)H oxidation by hydroperoxides when suspended in a medium containing 3 mM ATP, 4 mM Mg2+ and acetate as permeant anion. This is paralleled by an increase in the steady-state concentration of extramitochondrial Ca2+, a small decrease in delta psi and an increase in the rate of respiration and mitochondrial swelling. With the exception of mitochondrial swelling all other events were found to be reversible. If Ca2+ cycling was prevented by ruthenium red, the changes in delta psi, the rate of respiration and the extent of mitochondrial swelling were significantly diminished. In addition, there was no significant decrease in the content of mitochondrial pyridine nucleotides. Mitochondrial coupling was preserved after a cycle of Ca2+ release and re-uptake under these experimental conditions. It is concluded that hydroperoxide-induced Ca2+ efflux from intact mitochondria is related to the redox state of pyridine nucleotides.     

Assessment of uncoupling activity of uncoupling protein 3 using a yeast heterologous expression system.

Uncoupling protein 3L, uncoupling protein 1 and the mitochondrial oxoglutarate carrier were expressed in Saccharomyces cerevisae. Effects on different parameters related to the energy expenditure were studied. Both uncoupling protein 3L and uncoupling protein 1 reduced the growth rate by 49% and 32% and increased the whole yeast O2 consumption by 31% and 19%, respectively. In isolated mitochondria, uncoupling protein 1 increased the state 4 respiration by 1.8-fold, while uncoupling protein 3L increased the state 4 respiration by 1.2-fold. Interestingly, mutant uncoupling protein 1 carrying the H145Q and H147N mutations, previously shown to markedly decrease the H+ transport activity of uncoupling protein 1 when assessed using a proteoliposome system (Bienengraeber et al. (1998) Biochem. 37, 3-8), uncoupled the mitochondrial respiration to almost the same degree as wild-type uncoupling protein 1. Thus, absence of this histidine pair in uncoupling protein 2 and uncoupling protein 3 does not by itself rule out the possibility that these carriers have an uncoupling function. The oxoglutarate carrier had no effect on any of the studied parameters. In summary, a discordance exists between the magnitude of effects of uncoupling protein 3L and uncoupling protein 1 in whole yeast versus isolated mitochondria, with uncoupling protein 3L having greater effects in whole yeast and a smaller effect on the state 4 respiration in isolated mitochondria. These findings suggest that uncoupling protein 3L, like uncoupling protein 1, has an uncoupling activity. However, the mechanism of action and/or regulation of the activity of uncoupling protein 3L is likely to be different.     

Mitochondrial [Ca(2+)] oscillations driven by local high [Ca(2+)] domains generated by spontaneous electric activity

Mitochondria take up calcium during cell activation thus shaping Ca(2+) signaling and exocytosis. In turn, Ca(2+) uptake by mitochondria increases respiration and ATP synthesis. Targeted aequorins are excellent Ca(2+) probes for subcellular analysis, but single-cell imaging has proven difficult. Here we combine virus-based expression of targeted aequorins with photon-counting imaging to resolve dynamics of the cytosolic, mitochondrial, and nuclear Ca(2+) signals at the single-cell level in anterior pituitary cells. These cells exhibit spontaneous electric activity and cytosolic Ca(2+) oscillations that are responsible for basal secretion of pituitary hormones and are modulated by hypophysiotrophic factors. Aequorin reported spontaneous [Ca(2+)] oscillations in all the three compartments, bulk cytosol, nucleus, and mitochondria. Interestingly, a fraction of mitochondria underwent much larger [Ca(2+)] oscillations, which were driven by local high [Ca(2+)] domains generated by the spontaneous electric activity. These oscillations were large enough to stimulate respiration, providing the basis for local tune-up of mitochondrial function by the Ca(2+) signal.