Ca2+ release from mitochondria induced by prooxidants

A variety of chemically different prooxidants causes Ca2+ release from mitochondria. The prooxidant-induced Ca2+ release occurs from intact mitochondria via a route which is physiologically relevant and may be regulated by protein ADP-ribosylation. When the released Ca2+ is excessively cycled by mitochondria they are damaged. This leads to uncoupling, a decreased ATP supply, and a decreased ability of mitochondria to retain Ca2+. Excessive Ca2+ cycling by mitochondria will deprive cells of ATP. As a result, Ca2+ ATPases of the endoplasmic (sarcoplasmic) reticulum and the plasma membrane are stopped. The rising cytosolic Ca2+ level cannot be counterbalanced due to damage of mitochondria which, under normoxic conditions, act as safety device against increased cytosolic Ca2+. It is proposed that prooxidants are toxic because they impair the ability of mitochondria to retain Ca2+.     

Ca release from mitochondria induced by prooxidants

A variety of chemically different prooxidants causes Ca²⁺ release from mitochondria. The prooxidant-induced Ca²⁺ release occurs from intact mitochondria via a route which is physiologically relevant and may be regulated by protein ADP-ribosylation. When the released Ca²⁺ is excessively cycled by mitochondria they are damaged. This leads to uncoupling, a decreased ATP supply, and a decreased ability of mitochondria to retain Ca²⁺. Excessive Ca²⁺ cycling by mitochondria will deprive cells of ATP. As a result, Ca²⁺ ATPases of the endoplasmic (sarcoplasmic) reticulum and the plasma membrane are stopped. The rising cytosolic Ca²⁺ level cannot be counterbalanced due to damage of mitochondria which, under normoxic conditions, act as safety device against increased cytosolic Ca²⁺. It is proposed that prooxidants are toxic because they impair the ability of mitochondria to retain Ca²⁺.     

Ca2+ currents and acid secretion in the isolated parietal cell involved in response to gastrin, compound 48/80, and ethylenediamine tetraacetic acid

In intact guinea pig parietal cells, gastrin or compound 48/80 caused an initial increase in cytosolic Ca2+ concentration and subsequent acid secretion, owing to release of intracellulary stored Ca2+ besides the Ca2+ entry from the extracellular space. However, the maximum gastrin-induced Ca2+ entry into the cell was delayed by 60 min, a time which coincided with sustained acid secretion (by gastrin) that was dependent on medium Ca2+. On the other hand, there are two ATP-dependent Ca2+-removal systems detected in either plasmalemma or smooth surfaced membrane besides that of mitochondria. The plasmalemmal Ca2+-removal system was dependent on calmodulin. Smooth surfaced membrane vesicles caused an ATP-dependent Ca2+ uptake that was almost similar to that taken by saponin-permiabilized cell. In this system (permeable cell), myo-inositol 1,4,5-triphosphate (InsP3) caused the release of ATP-accumulated Ca2+ into the cytosol, suggesting an ATP-dependent and InsP3-sensitive Ca2+ pool(s) is in or near the smooth surfaced membranes. The ATP-dependent Ca2+ uptake by vesicles was markedly enhanced by the stimulation of cells with gastrin, compound 48/80, or EDTA. The increase of this Ca2+ uptake in stimulated cells by plasmalemmal vesicles exceeded that by smooth surfaced ones. The increase of the Ca2+ uptake by plasmalemmal vesicles was abolished by the cease of intracellular Ca2+ release without Ca2+ entry. In addition, gastrin or compound 48/80 evoked an early Ca2+ efflux across the plasma membrane owing to a pump that was independent of medium Ca2+ in intact cells. These results suggest that in the first acid secretion by gastrin or others, the Ca2+ released, which may be derived from an ATP-dependent and InsP3-sensitive Ca2+ pool, is mainly pumped out by the plasmalemmal Ca2+-removal system rather than the intracellular Ca2+-removal system; whereas the sustained acid secretion by gastrin required medium Ca2+ and in this phase, Ca2+ efflux across the plasma membrane became lower, suggesting that an ATP-dependent Ca2+ pool may be replenished by Ca2+ entering from the extracellular space.     

Calcium sequestration in the liver: Review article

Hepatic parenchymal cells maintain intracellular total and cytosolic free Ca2+ levels by: entry of Ca2+ through channels, extrusion of Ca2+ by an outwardly directed Ca2+ pump, and controlled sequestration into intracellular pools. The mechanism of Ca2+ inflow is poorly characterized. The plasma membrane Ca2+ channels seem to share some of the characteristics of Ca2+ channels in excitable cells, but also differ from them. The outwardly directed plasma membrane Ca2(+)-ATPase is a calmodulin independent, P-type enzyme. Ca2+ uptake into the endoplasmic reticulum is due to the activity of a different Ca2(+)-ATPase, which is similar in molecular weight and shares antigenic determinants with the sarcoplasmic reticulum enzyme. In addition, mitochondria and nuclei also take up calcium. The exact mechanism by which Ca2+ is released from intracellular organelles is not well known. Several mechanisms for Ca2+ release from the endoplasmic reticulum were reported, including IP3 and GTP-induced. The most effective identified way of eliciting Ca2+ release from microsomal fraction is by the oxidation of critical -SH groups. This mechanism is likely to be involved in the rise of cytosolic Ca2+ observed in many situations of hepatocellular injury. In addition to being sequestered into subcellular organelles, some of the intracellular Ca2+ is bound to specific Ca2+ binding proteins. Both calmodulin and members of the annexin family were identified in the liver. Stimulation of the liver with gluconeogenic hormones results in increased Ca2+ entry into the cell, the release of Ca2+ from intracellular pools, and an oscillatory increase in free cytosolic Ca2+ levels. Extensive research is still needed for the elucidation of the exact mechanisms by which these events occur.     

Uptake, retention, and efflux of Ca2+ by mitochondrial preparations from skeletal muscle

Functionally intact mitochondria, substantially free of contamination, were isolated from rabbit gastrocnemius muscle after protease digestion and their Ca2+-handling properties examined. When judged by their capacity to retain large Ca2+ loads and the magnitude of basal and Na+-stimulated Ca2+ effluxes, the most suitable isolation method was digestion of finely minced muscle in buffered isoosmotic KCl with low levels (0.4 mg/g) of trypsin or the bacterial protease nagarse, followed by differential centrifugation. Polytron disruption of skeletal muscle in both sucrose- and KCl-based media released mitochondria deficient in cytochrome c. Use of the divalent ion chelator EDTA rather than EGTA in the isolation medium sharply reduced Ca2+-dependent respiratory control and tolerance of the mitochondria to Ca2+ loads, probably by removing Mg2+ essential to membrane integrity. ADP-dependent respiratory control was not altered in mitochondria prepared in an EDTA-containing isolation medium. Purification of mitochondria on a Percoll density gradient did not improve their Ca2+-handling ability despite removal of minor contaminants. Mitochondria prepared by the protease method could accumulate micromole loads of Ca2+/mg while maintaining a low basal Ca2+ efflux. Addition of BSA to the assay medium slightly improved Ca2+ retention but was not essential either during isolation or assay. Ca2+-dependent state 3 respiration was maximal at pH 6.5-7.0 while respiratory control and Ca2+/O were optimal at pH 7.0-7.5. Neither Pi nor oxaloacetate induced Ca2+ release from loaded mitochondria when monitored for 30 min after ruthenium red addition. Na+-stimulated Ca2+ efflux had sigmoidal kinetics with a Hill coefficient of 3. Since skeletal muscle mitochondria can be isolated and assayed in simple media, functional deficiencies of mitochondria from diseased muscle are unlikely to be masked.     

Neurotransmitter release

Axon terminals release more than one physiologically active substance. Synaptic messengers may be stored in two different types of vesicles. Small electron-lucent vesicles mainly store classical low molecular weight transmitter substances and the larger electron-dense granules store and release proteins and peptides. Release of the two types of substances underlies different physiological control. Release of messenger molecules from axon terminals is triggered by influx of Ca2+ through voltage sensitive Ca2+ channels and a rise in cytosolic Ca2+ concentrations. Neither the immediate Ca2+ target(s) nor the molecular species involved in synaptic vesicle docking, fusion and retrieval are known. It is, however, likely that steps involved in the molecular cascade of transmitter release include liberation of vesicles from their association with the cytonet and phosphorylation by protein kinase C of proteins which have the ability to alter between membrane bound and cytoplasmic forms and thus facilitate or initiate the molecular interaction between synaptic vesicles and the plasma membrane.     

The origin, quantitation, and kinetics of intracellular calcium mobilization by vasopressin and phenylephrine in hepatocytes

The addition of phenylephrine or vasopressin to isolated hepatocytes resulted in an efflux of calcium. The intracellular source of this calcium was determined by measuring the calcium released upon the sequential additions of an uncoupling agent and the Ca2+ ionophore A23187 to control and hormone-treated cells. The release promoted by these agents was used as an estimate of the calcium content of the mitochondria and endoplasmic reticulum, respectively. The validity and limitations of this method are critically evaluated. The source of the calcium mobilized by the hormones was found to depend on the intracellular calcium distribution. When the amount of total cell-releasable Ca2+ was low (less than 0.9 nmol/mg cell dry weight), the endoplasmic reticulum represented the major cellular calcium pool and was also the predominant pool mobilized by the hormone. As the cell calcium content was increased, the endoplasmic reticulum attained its maximum capacity and the mitochondria sequestered increasing amounts of calcium. Under these conditions, the hormones mobilized calcium from the mitochondria with minimal effects on the endoplasmic reticulum calcium pool. These results suggest that more than one hormone-induced Ca2+-releasing agent may be formed. Both the total amount and the rate of calcium released from the cell under the influence of hormones was independent of the cell calcium content. The appearance of hormone-releasable Ca2+ in the extracellular medium showed a lag period of 5 to 10 s, during which a rapid increase of phosphorylase activity was observed. In contrast, the mobilization of a comparable amount of calcium by carbonyl cyanide p-trifluoromethoxyphenylhydrazone showed no significant lag, but the activation of phosphorylase was slower. A kinetic analysis of the hormone-releasable Ca2+ indicated a rapid onset with a peak increase of cytosolic free Ca2+ between 5 and 10 s prior to release of Ca2+ from the cell. The results suggest that an early action of the hormone is the inhibition of the plasma membrane Ca2+ efflux pump.     

Perturbation in liver mitochondrial Ca2+ homeostasis in experimental iron overload: a possible factor in cell injury

The functional state of isolated mitochondria and specifically the integrity of the inner membrane, were investigated in the liver of rats made siderotic by dietary supplementation with carbonyl iron. The concentration of iron in the hepatic tissue increased progressively up to nearly 40 days and reached a steady-state level. When the iron content reached a threshold value (higher than 90 nmol/mg protein) the occurrence of in vivo lipid peroxidation in the mitochondrial membrane was detected. This process did not result in gross alterations in the mitochondrial membrane, as indicated by electron microscopy, phosphorylative capability and membrane potential measurements. On the contrary, the induction of lipoperoxidative reaction appeared to be associated with the activation of Ca2+ release from mitochondria. This was shown to occur as a consequence of rather subtle modifications in the inner membrane structure via a specific efflux route, which appeared to be linked to the oxidation level of mitochondrial pyridine nucleotides. The induction of this Ca2+ release from iron-treated mitochondria resulted in enhancement of Ca2+ cycling, a process which dissipates energy to reaccumulate into mitochondria the released Ca2+. The perturbation in mitochondrial Ca2+ homeostasis reported here may be a factor in the onset of cell damage in this experimental model of hepatic iron overload.     

Calcium compartmentation in isolated renal tubules in suspension

Substantial increases of total cell Ca2+ have been observed in suspensions of isolated rabbit proximal tubules subjected to hypoxic injury or treated with exogenous ATP followed by apparent recovery with reoxygenation of the hypoxic tubules or continued incubation of ATP-treated tubules. Ca2+ compartmentation studies using digitonin and metabolic inhibitors were done to clarify the basis for these changes. Digitonin, 40-90 micrograms/mg tubule protein, rapidly permeabilized the tubule cells and did not impair mitochondrial Ca2+ sequestration. Most of the increases of tubule cell Ca2+ produced by hypoxia and ATP were accounted for by pools which could be rapidly removed by exposure of tubules to EGTA and the uncoupler carbonyl cyanide m-chlorophenyl hydrazone without concomitant use of digitonin, suggesting that the changes of Ca2+ predominantly reflect sequestration by mitochondria in severely damaged cells or mitochondria already released to the medium from them. The time course of uptake followed by spontaneous release of mitochondrial Ca2+ from tubule cells deliberately permeabilized with digitonin, then incubated for prolonged periods, indicated that the decreases of tubule cell Ca2+ during reoxygenation of hypoxic suspensions and prolonged incubation of ATP-treated tubules were likely to be attributable to loss of Ca2+ from free mitochondria and those in damaged cells rather than to extrusion by intact cells.     

The toxicity of acetaminophen and N-acetyl-p-benzoquinone imine in isolated hepatocytes is associated with thiol depletion and increased cytosolic Ca2+

The effects of acetaminophen and its major toxic metabolite, N-acetyl-p-benzoquinone imine (NAPQI), have been investigated in hepatocytes isolated from 3-methylcholanthrene-pretreated and -untreated rats, respectively. The two compounds produced qualitatively similar changes although the quinone imine was toxic with shorter incubations periods and at lower doses. Both agents caused an elevation of cytosolic Ca2+, assessed by phosphorylase a activity, which was accompanied by the concomitant appearance of plasma membrane blebs. A loss of mitochondrial Ca2+ was also observed. This disruption of Ca2+ homeostasis always preceded cell death. Studies with NAPQI showed that low doses were able to cause complete Ca2+ release from isolated liver mitochondria which was accompanied by pyridine nucleotide oxidation and preceded membrane damage. NAPQI also produced a rapid, dose-dependent depletion of both cytosolic and mitochondrial reduced glutathione as well as a loss of protein-bound SH groups. This loss of protein thiols may have been responsible for the observed inhibition of the high-affinity Ca2+-ATPase activity of the plasma membrane fraction isolated from NAPQI-treated cells. In addition, NAPQI inhibited microsomal Ca2+ uptake which would further contribute to the elevation in cytosolic Ca2+. Our results suggest that acetaminophen and N-acetyl-p-benzoquinone imine exert their cytotoxic effects via a disruption of Ca2+ homeostasis secondary to the depletion of soluble and protein-bound thiols. This mechanism may prove to be of general applicability to a variety of hepatotoxins.     

Sustained Ca2+ transfer across mitochondria is Essential for mitochondrial Ca2+ buffering,sore-operated Ca2+ entry,and Ca2+ store refilling

Mitochondria have been found to sequester and release Ca2+ during cell stimulation with inositol 1,4,5-triphosphate-generating agonists, thereby generating subplasmalemmal microdomains of low Ca2+ that sustain activity of capacitative Ca2+ entry (CCE). Procedures that prevent mitochondrial Ca2+ uptake inhibit local Ca2+ buffering and CCE, but it is not clear whether Ca2+ has to transit through or remains trapped in the mitochondria. Thus, we analyzed the contribution of mitochondrial Ca2+ efflux on the ability of mitochondria to buffer subplasmalemmal Ca2+, to maintain CCE, and to facilitate endoplasmic reticulum (ER) refilling in endothelial cells. Upon the addition of histamine, the initial mitochondrial Ca2+ transient, monitored with ratio-metric-pericam-mitochondria, was largely independent of extracellular Ca2+. However, subsequent removal of extracellular Ca2+ produced a reversible decrease in [Ca2+]mito, indicating that Ca2+ was continuously taken up and released by mitochondria, although [Ca2+]mito had returned to basal levels. Accordingly, inhibition of the mitochondrial Na+/Ca2+ exchanger with CGP 37157 increased [Ca2+]mito and abolished the ability of mitochondria to buffer subplasmalemmal Ca2+, resulting in an increased activity of BKCa channels and a decrease in CCE. Hence, CGP 37157 also reversibly inhibited ER refilling during cell stimulation. These effects of CGP 37157 were mimicked if mitochondrial Ca2+ uptake was prevented with oligomycin/antimycin A. Thus, during cell stimulation a continuous Ca2+ flux through mitochondria underlies the ability of mitochondria to generate subplasmalemmal microdomains of low Ca2+, to facilitate CCE, and to relay Ca2+ from the plasma membrane to the ER.     

Zn~(2+)对PTP开放和细胞色素c释放的浓度依赖性双向调节

研究Zn2+对Ca2+介导线粒体通透过渡孔道(PTP)开放和线粒体细胞色素c释放的影响,及其与线粒体膜电位(ΔΨm)和Ca2+介导的线粒体Ca2+释放(mCICR)之间的关系.提取大鼠肝线粒体,通过紫外分光光度仪检测不同浓度Zn2+作用下Ca2+介导的PTP开放状态;采用荧光分光光度仪测定不同浓度Zn2+作用下线粒体膜电位的变化;采用双波长双光束紫外分光光度仪检测不同浓度Zn2+作用下测试体系内Ca2+浓度的变化,以反映线粒体Ca2+的转运情况(即mCICR);通过免疫印迹法检测不同浓度Zn2+作用下Ca2+介导的线粒体细胞色素c的释放.高浓度Zn2+完全抑制Ca2+介导的PTP开放和细胞色素c释放.一定浓度的Zn2+部分抑制Ca2+介导的PTP开放和细胞色素c释放.适当浓度Zn2+自身介导PTP开放和细胞色素c释放.低浓度Zn2+加速Ca2+介导PTP开放和Ca2+释放;高浓度和一定浓度Zn2+分别完全或部分破坏ΔΨm;高浓度Zn2+完全抑制mCICR.当抑制mCICR时,Ca2+和Zn2+对PTP开放和细胞色素c释放的作用完全抑制.结果表明,Zn2+以浓度依赖方式双向调节PTP开放和细胞色素c释放.Zn2+的作用可能与Zn2+破坏ΔΨm和影响mCICR相关.     

NADP-linked dismutation and concentrations of citrate, cytosolic free Ca2+ and phosphoenolpyruvate in islet B-cells stimulated with glucose

B-cells stimulated with glucose showed enhanced activities of NADP-isocitrate dehydrogenase, aconitase, ATP-citrate lyase and phosphoenolpyruvate carboxy-kinase, elevated cytosolic [NADPH]/[NADP+] ratio, and increased concentrations of glucose 6-phosphate, 6-phosphogluconate, citrate, phosphoenolpyruvate and cytosolic free Ca2+. Phosphoenolpyruvate induced release of Ca2+ accumulated in isolated mitochondria. Glucose is suggested to stimulate a cytosolic NADP-linked dismutation and synthesis of citrate, associated with increased cytosolic free Ca2+ concentration. Subsequent breakdown of cytosolic citrate may yield Pi (possibly related to the "phosphate flush") and phosphoenolpyruvate which potentiates the release of Ca2+ accumulated in the B-cell mitochondria.     

Mechanisms involved in the cellular calcium homeostasis in vascular smooth muscle: calcium pumps

The regulation of cytosolic Ca2+ homeostasis is essential for cells, and particularly for vascular smooth muscle cells. In this regulation, there is a participation of different factors and mechanisms situated at different levels in the cell, among them Ca2+ pumps play an important role. Thus, Ca2+ pump, to extrude Ca2+; Na+/Ca2+ exchanger; and different Ca2+ channels for Ca2+ entry are placed in the plasma membrane. In addition, the inner and outer surfaces of the plasmalemma possess the ability to bind Ca2+ that can be released by different agonists. The sarcoplasmic reticulum has an active role in this Ca2+ regulation; its membrane has a Ca2+ pump that facilitates luminal Ca2+ accumulation, thus reducing the cytosolic free Ca2+ concentration. This pump can be inhibited by different agents. Physiologically, its activity is regulated by the protein phospholamban; thus, when it is in its unphosphorylated state such a Ca2+ pump is inhibited. The sarcoplasmic reticulum membrane also possesses receptors for 1,4,5-inositol trisphosphate and ryanodine, which upon activation facilitates Ca2+ release from this store. The sarcoplasmic reticulum and the plasmalemma form the superficial buffer barrier that is considered as an effective barrier for Ca2+ influx. The cytosol possesses different proteins and several inorganic compounds with a Ca2+ buffering capacity. The hypothesis of capacitative Ca2+ entry into smooth muscle across the plasma membrane after intracellular store depletion and its mechanisms of inhibition and activation is also commented.     

Alterations in intracellular calcium compartmentation following inhibition of calcium efflux from isolated hepatocytes

Addition of ATP to the incubation medium of freshly isolated rat hepatocytes causes a marked inhibition of the efflux of Ca2+ from the cells, and its accumulation in intracellular compartments. After an initial rise in cytosolic free Ca2+ concentration, as indicated by the activation of phosphorylase, Ca2+ is preferentially sequestered in the mitochondria, without any apparent contribution by the endoplasmic reticulum. Impairment of mitochondrial Ca2+ homeostasis by pyridine nucleotide oxidation associated with tert-butyl hydroperoxide metabolism, prevents the ATP-dependent cellular Ca2+ accumulation and causes a release of Ca2+ from the hepatocytes into the medium. Conversely, maintenance of the mitochondrial pyridine nucleotides in a more reduced state, e. g. in presence of 3-hydroxybutyrate in the medium, prevents this hydroperoxide-induced release of intracellular Ca2+. Under conditions of impaired mitochondrial Ca2+ sequestration, there appears to be a redistribution of a minor fraction of the intracellular Ca2+ from the mitochondria to the endoplasmic reticulum. Our results provide additional evidence for the critical involvement of the plasma membrane Ca2+-extruding system in the physiological regulation of the cytosolic free Ca2+ concentration in hepatocytes, and suggest that the mitochondria play a more important role than the endoplasmic reticulum in the regulation of the cytosolic free Ca2+ level when the plasma membrane Ca2+ pump is inhibited.     

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.     

Mechanism of alloxan-induced calcium release from rat liver mitochondria

The objective of the present work was to investigate the mechanism of alloxan-induced Ca2+ release from rat liver mitochondria. Transport of Ca2+, oxidation and hydrolysis of mitochondrial pyridine nucleotides, changes in the mitochondrial membrane potential, and oxygen consumption by mitochondria were investigated. Alloxan does not inhibit the uptake of Ca2+ but stimulates the release of Ca2+ from liver mitochondria, which is accompanied by oxidation and hydrolysis of pyridine nucleotides. Oxidation of mitochondrial pyridine nucleotides by alloxan is not mediated by glutathione peroxidase and glutathione reductase and may occur largely nonenzymatically. Measurements of the mitochondrial membrane potential in combination with inhibitors of Ca2+ reuptake indicate that Ca2+ release takes place from intact liver mitochondria via a distinct pathway. Limited redox cycling of alloxan by mitochondria is indicated by measurements of the membrane potential and O2 consumption in the presence of cyanide. It is concluded that alloxan can cause Ca2+ release from intact rat liver mitochondria. Redox cycling of alloxan is not significantly involved in the Ca2+ release mechanism. Oxidation and hydrolysis of pyridine nucleotides, possibly in conjunction with oxidation of critical sulfhydryl groups, seem to be key events in the alloxan-induced Ca2+ release. Disturbance of cellular Ca2+ homeostasis may partly explain alloxan toxicity.     

Calcium ion activation of the anion-conducting channel in the rat liver mitochondrial inner membrane.

Stimulation of the rat liver mitochondrial inner-membrane anion-conducting channel by aeration is dependent on the concentration of Ca2+ ions in the assay medium. Ca2+ activates anion conduction in both aerated and non-energised mitochondria but acts over a wider concentration range and produces a greater increase in anion-conductivity in aerated mitochondria. EGTA reverses Ca2+ stimulation but takes several seconds to act, indicating slow release of Ca2+ from the activation site possibly on the matrix side of the inner mitochondrial membrane. It is suggested that this channel may respond to hormone-induced changes in cytosolic Ca2+ concentration.     

Localization of intracellular calcium release in cells injured by venom from the ectoparasitoid Nasonia vitripennis (Walker) (Hymenoptera: Pteromalidae) and dependence of calcium mobilization on G-protein activation

Venom from the ectoparasitic wasp Nasonia vitripennis induces cellular injury that appears to involve the release of intracellular calcium stores via the activation of phospholipase C, and culminates in oncotic death. A linkage between release of intracellular Ca2+ and oncosis has not been clearly established and was the focus of this study. When BTI-TN-5B1-4 cells were treated with suramin, an uncoupler of G-proteins, venom-induced swelling and oncotic death were inhibited in a dose-dependent manner for at least 24 h. Suramin also blocked increases in free cytosolic [Ca2+], arguing that venom induces calcium mobilization through G-protein signaling pathways. Endoplasmic reticulum (ER) was predicted to be the source of intracellular calcium release, but labeling with the fluorescent probe ER-tracker revealed no indication of organelle swelling or loss of membrane integrity as would be expected if the Ca(2+)-ATPase pump was disabled by crude venom. Incubation of cell monolayers with calmodulin or nitrendipine, modulators of ER calcium release channels, neither attenuated nor augmented the effects of wasp venom. These results suggest that wasp venom stimulates calcium release from ER compartments distinct from RyRs, L-type Ca2+ channels, and the Ca(2+)-ATPase pump, or calcium is released from some other intracellular store. A reduction of mitochondrial membrane potential delta psi(m) appeared to precede a rise in cytosolic free Ca2+ as evidenced by fluorescent microscopy using the calcium-sensitive probe fluo-4 AM. This argues that the initial insult to the cell resulting from venom elicits a rapid loss of (delta psi(m)), followed by unregulated calcium efflux from mitochondria into the cytosol. Mobilization of calcium in this fashion could stimulate cAMP formation, and subsequently promote calcium release from NAADP-sensitive stores.     

Mitochondrial modulation of calcium signaling at the initiation of development

Fertilization triggers cytosolic Ca(2+) oscillations that activate mammalian eggs and initiate development. Extensive evidence demonstrates that Ca(2+) is released from endoplasmic reticulum stores; however, less is known about how the increased Ca(2+) is restored to its resting level, forming the Ca(2+) oscillations. We investigated whether mitochondria also play a role in activation-associated Ca(2+) signaling. Mitochondrial dysfunction induced by the mitochondrial uncoupler FCCP or antimycin A disrupted cytosolic Ca(2+) oscillations, resulting in sustained increase in cytosolic Ca(2+), followed by apoptotic cell death. This suggests that functional mitochondria may participate in sequestering the released Ca(2+), contributing to cytosolic Ca(2+) oscillations and preventing cell death. By centrifugation, mouse eggs were stratified and separated into fractions containing both endoplasmic reticulum and mitochondria and fractions containing endoplasmic reticulum with no mitochondria. The former showed Ca(2+) oscillations by activation, whereas the latter exhibited sustained elevation in cytosolic Ca(2+) but no Ca(2+) oscillations, suggesting that mitochondria take up released cytosolic Ca(2+). Further, using Rhod-2 for detection of mitochondrial Ca(2+), we found that mitochondria exhibited Ca(2+) oscillations, the frequency of which was not different from that of cytosolic Ca(2+) oscillations, indicating that mitochondria are involved in Ca(2+) signaling during egg activation. Therefore, we propose that mitochondria play a crucial role in Ca(2+) signaling that mediates egg activation and development, and apoptotic cell death.