Control of mitochondrial motility and distribution by the calcium signal: a homeostatic circuit

Mitochondria are dynamic organelles in cells. The control of mitochondrial motility by signaling mechanisms and the significance of rapid changes in motility remains elusive. In cardiac myoblasts, mitochondria were observed close to the microtubular array and displayed both short- and long-range movements along microtubules. By clamping cytoplasmic [Ca2+] ([Ca2+]c) at various levels, mitochondrial motility was found to be regulated by Ca2+ in the physiological range. Maximal movement was obtained at resting [Ca2+]c with complete arrest at 1-2 microM. Movement was fully recovered by returning to resting [Ca2+]c, and inhibition could be repeated with no apparent desensitization. The inositol 1,4,5-trisphosphate- or ryanodine receptor-mediated [Ca2+]c signal also induced a decrease in mitochondrial motility. This decrease followed the spatial and temporal pattern of the [Ca2+]c signal. Diminished mitochondrial motility in the region of the [Ca2+]c rise promotes recruitment of mitochondria to enhance local Ca2+ buffering and energy supply. This mechanism may provide a novel homeostatic circuit in calcium signaling.     

Control of cytosolic free calcium by intracellular organelles in bovine adrenal glomerulosa cells. Effects of sodium and inositol 1,4,5-trisphosphate

The regulation of cytosolic free Ca2+ concentration ([Ca2+]c) by intracellular organelles was studied in permeabilized bovine adrenal glomerulosa cells. Two compartments, with distinct characteristics, were able to pump Ca2+. A first pool, sensitive to ruthenium red and presumably mitochondrial, required respiratory chain substrates to maintain [Ca2+]c around 700 nM. Ca2+ efflux from this compartment was activated by Na+ (ED50 = 5 mM). Inositol 1,4,5-trisphosphate (IP3) had no effect on this pool. A second nonmitochondrial pool required ATP to lower [Ca2+]c to about 200 nM and released Ca2+ transiently upon addition of IP3. When the two systems were allowed to work simultaneously, the nonmitochondrial pool regulated [Ca2+]c and IP3 released Ca2+ in a concentration-dependent manner (EC50 = 0.6 microM). Under these conditions the mitochondria seemed Ca2+ depleted. Upon repeated stimulations with IP3, a marked attenuation of the response was observed. This phenomenon was due to Ca2+ sequestration by a nonmitochondrial IP3-insensitive pool. Neither dantrolene (200 microM) nor 8-(N,N-diethylamino)octyl-3,4,5-trimethoxybenzoate (10 microM) were able to abolish IP3-induced Ca2+ release, though both compounds efficiently inhibited aldosterone production in intact cells stimulated with angiotensin II (10 nM) or K+ (12 mM). These results suggest that in permeabilized adrenal glomerulosa cells: the nonmitochondrial pool is responsible for buffering [Ca2+]c and for releasing Ca2+ in response to IP3; at resting [Ca2+]c levels, the mitochondria appear Ca2+ depleted; when [Ca2+]c rises above their set point, the mitochondria accumulate Ca2+ as a function of [Na+]c; 4) the mitochondria are not involved in the desensitization mechanism of the response to IP3.     

Mitochondrial localization as a determinant of capacitative Ca2+ entry in HeLa cells

Whether different subsets of mitochondria play distinct roles in shaping intracellular Ca2+ signals is presently unresolved. Here, we determine the role of mitochondria located beneath the plasma membrane in controlling (a) Ca2+ release from the endoplasmic reticulum (ER) and (b) capacitative Ca2+ entry. By over-expression of the dynactin subunit dynamitin, and consequent inhibition of the fission factor, dynamin-related protein (Drp-1), mitochondria were relocalised from the plasma membrane towards the nuclear periphery in HeLa cells. The impact of these changes on free calcium concentration in the cytosol ([Ca2+]c), mitochondria ([Ca2+]m) and ER ([Ca2+]ER) was then monitored with specifically-targeted aequorins. Whilst dynamitin over-expression increased the number of close contacts between the ER and mitochondria by >2.5-fold, assessed using organelle-targeted GFP variants, histamine-induced changes in organellar [Ca2+] were unaffected. By contrast, Ca2+ influx elicited significantly smaller increases in [Ca2+]c and [Ca2+]m in dynamitin-expressing than in control cells. These data suggest that the strategic localisation of a subset of mitochondria beneath the plasma membrane is required for normal Ca2+ influx, but that the transfer of Ca2+ ions between the ER and mitochondria is relatively insensitive to gross changes in the spatial relationship between these two organelles.     

Subplasmalemmal mitochondria modulate the activity of plasma membrane Ca2+-ATPases

Mitochondria are dynamic organelles that modulate cellular Ca2+ signals by interacting with Ca2+ transporters on the plasma membrane or the endoplasmic reticulum (ER). To study how mitochondria dynamics affects cell Ca2+ homeostasis, we overexpressed two mitochondrial fission proteins, hFis1 and Drp1, and measured Ca2+ changes within the cytosol and the ER in HeLa cells. Both proteins fragmented mitochondria, decreased their total volume by 25-40%, and reduced the fraction of subplasmalemmal mitochondria by 4-fold. The cytosolic Ca2+ signals elicited by histamine were unaltered in cells lacking subplasmalemmal mitochondria as long as Ca2+ was present in the medium, but the signals were significantly blunted when Ca2+ was removed. Upon Ca2+ withdrawal, the free ER Ca2+ concentration decreased rapidly, and hFis1 cells were unable to respond to repetitive histamine stimulations. The loss of stored Ca2+ was due to an increased activity of plasma membrane Ca2+-ATPase (PMCA) pumps and was associated with an increased influx of Ca2+ and Mn2+ across store-operated Ca2+ channels. The increased Ca2+ influx compensated for the loss of stored Ca2+, and brief Ca2+ additions between successive agonist stimulations fully corrected subsequent histamine responses. We propose that the lack of subplasmalemmal mitochondria disrupts the transfer of Ca2+ from plasma membrane channels to the ER and that the resulting increase in subplasmalemmal [Ca2+] up-regulates the activity of PMCA. The increased Ca2+ extrusion promotes ER depletion and the subsequent activation of store-operated Ca2+ channels. Cells thus adapt to the lack of subplasmalemmal mitochondria by relying on external rather than on internal Ca2+ for signaling.     

Coordinated regulation of free Ca2+ by isolated organelles from a rat insulinoma

Experiments aimed at the partial reconstitution of the intracellular transport systems regulating the cytosolic free Ca2+ homeostasis are reported. Rat insulinoma subcellular fractions enriched in mitochondria, endoplasmic reticulum (microsomes), and secretory granules were studied. The ambient free Ca2+ concentration maintained by the separate or combined organelles was determined with a Ca2+-selective minielectrode. The data demonstrate that ambient [Ca2+] is established by the microsomes, not by the mitochondria or the secretory granules, in the range of resting cytosolic Ca2+ concentrations (0.1-0.2 microM Ca2+). Furthermore, the microsomes are able to deplete largely the mitochondria of their exchangeable calcium. Nonetheless, both mitochondria and microsomes, but not secretory granules, function as a coordinated unit to restore the previous ambient [Ca2+] following its perturbation. Thus, mitochondria play a major role in bringing down rapidly ambient [Ca2+] to the submicromolar range, whereas the endoplasmic reticulum acts as a relay in the transport mechanisms which lower [Ca2+] to the resting level.     

Mitochondria suppress local feedback activation of inositol 1,4, 5-trisphosphate receptors by Ca2+.

The concerted action of inositol 1,4,5-trisphosphate (IP3) and Ca2+ on the IP3 receptor Ca2+ release channel (IP3R) is a fundamental step in the generation of cytosolic Ca2+ oscillations and waves, which underlie Ca2+ signaling in many cells. Mitochondria appear in close association with regions of endoplasmic reticulum (ER) enriched in IP3R and are particularly responsive to IP3-induced increases of cytosolic Ca2+ ([Ca2+]c). To determine whether feedback regulation of the IP3R by released Ca2+ is modulated by mitochondrial Ca2+ uptake, the interactions between ER and mitochondrial Ca2+ pools were examined by fluorescence imaging of compartmentalized Ca2+ indicators in permeabilized hepatocytes. IP3 decreased luminal ER Ca2+ ([Ca2+]ER), and this was paralleled by an increase in mitochondrial matrix Ca2+ ([Ca2+]m) and activation of Ca2+-sensitive mitochondrial metabolism. Remarkably, the decrease in [Ca2+]ER evoked by submaximal IP3 was enhanced when mitochondrial Ca2+ uptake was blocked with ruthenium red or uncoupler. Moreover, subcellular regions that were relatively deficient in mitochondria demonstrated greater sensitivity to IP3 than regions of the cell with a high density of mitochondria. These data demonstrate that Ca2+ uptake by the mitochondria suppresses the local positive feedback effects of Ca2+ on the IP3R, giving rise to subcellular heterogeneity in IP3 sensitivity and IP3R excitability. Thus, mitochondria can play an important role in setting the threshold for activation and establishing the subcellular pattern of IP3-dependent [Ca2+]c signaling.     

Prostaglandin F2alpha potentiates the calcium dependent activation of mitochondrial metabolism in luteal cells

Cytoplasmic Ca2+ signals are transferred to the mitochondria and activate the Krebs cycle. We have compared the efficiency of this process for two Ca2+ mobilising agonists, PGF2alpha and ATP (acting at metabotropic P2 receptors) in rat luteal cells. [Ca2+]c, [Ca2+]m and mitochondrial NAD(P)H were monitored by means of microspectrofluorimetry and confocal microscopy. While both agonists caused similar elevations of [Ca2+]c, changes in NAD(P)H were larger in response to PGF2alpha than to ATP. PGF2alpha more effectively increased NAD(P)H level also in mouse luteal cells. PGF2alpha caused a faster rate of rise of NAD(P)H fluorescence than ATP when reoxidation was prevented with rotenone, suggesting a faster rate of NAD(P)+ reduction. The NAD(P)H response to both agonists was dependent on the mobilisation of stored Ca2+. We found no difference in the efficacy of transmission of the [Ca2+]c signal to mitochondria in response to PGF2alpha and ATP. Raising [Ca2+]c with ionomycin increased the NAD(P)H signal, which was further raised by PGF2alpha but not by ATP. These data suggest that PGF2alpha potentiates the Ca2+-induced stimulation of mitochondrial metabolism by a Ca2+-independent mechanism and shows that agonists may modulate mitochondrial function differentially through a novel process beyond the simple transfer of Ca2+ from ER to mitochondria.     

Characterization of hypoxia-induced [Ca2+]i rise in rabbit pulmonary arterial smooth muscle cells

We have investigated the effects of hypoxia on the intracellular Ca2+ concentration ([Ca2+]i) in rabbit pulmonary (PASMCs) and coronary arterial smooth muscle cells with fura-2. Perfusion of a glucose-free and hypoxic (PO2<50 mmHg) external solution increased [Ca2+]i in cultured as well as freshly isolated PASMCs. However it had no effect on [Ca2+]i in freshly isolated coronary arterial myocytes. In the absence of extracellular Ca2+, hypoxic stimulation elicited a transient [Ca2+]i increase in cultured PASMCs which was abolished by the simultaneous application of cyclopiazonic acid and ryanodine, suggesting the involvement of sarcoplasmic reticulum (SR) Ca2+ store. Pretreatment with the mitochondrial protonophore, carbonyl cyanide m-chlorophenyl-hydrazone (CCCP) enhanced the [Ca2+]i rise in response to hypoxia. A short application of caffeine gave a transient [Ca2+]i rise which was prolonged by CCCP. Decay of the caffeine-induced [Ca2+]i transients was significantly slowed by treatment of CCCP or rotenone. After full development of the hypoxia-induced [Ca2+]i rise, nifedipine did not decrease [Ca2+]i. These data suggest that the [Ca2+]i increase in response to hypoxia may be ascribed to both Ca2+ release from the SR and the subsequent activation of nifedipine-insensitive capacitative Ca2+ entry. Mitochondria appear to modulate hypoxia induced Ca2+ release from the SR.     

Mechanisms of cardiodepression by an Na+-H+ exchange inhibitor methyl-N-isobutyl amiloride (MIA) on the heart: lack of beneficial effects in ischemia-reperfusion injury

Although Na+-H+ exchange (NHE) inhibitors such as methyl-N-isobutyl amiloride (MIA) are known to depress the cardiac function, the mechanisms of their negative inotropic effect are not completely understood. In this study, isolated rat hearts were perfused with MIA to study its action on cardiac performance, whereas isolated subcellular organelles such as sarcolemma, myofibrils, sarcoplasmic reticulum, and mitochondria were treated with MIA to determine its effect on their function. The effect of MIA on intracellular Ca2+ mobilization was examined in fura-2-AM-loaded cardiomyocytes. MIA was observed to depress cardiac function in a concentration-dependent manner in HCO3- -free buffer. On the other hand, MIA had an initial positive inotropic effect followed by a negative inotropic effect in HCO3-containing buffer. MIA increased the basal concentration of intracellular Ca2+ ([Ca2+]i) and augmented the KCl-mediated increase in [Ca2+]i. MIA did not show any direct effect on myofibrils, sarcolemma, and sarcoplasmic reticulum ATPase activities; however, this agent was found to decrease the intracellular pH, which reduced the myofibrils Ca2+-stimulated ATPase activity. MIA also increased Ca2+ uptake by mitochondria without having any direct effect on sarcoplasmic reticulum Ca2+ uptake. In addition, MIA did not protect the hearts subjected to mild Ca2+ paradox as well as ischemia-reperfusion-mediated injury. These results suggest that the increase in [Ca2+]i in cardiomyocytes may be responsible for the initial positive inotropic effect of MIA, but its negative inotropic action may be due to mitochondrial Ca2+ overloading as well as indirect depression of myofibrillar Ca2+ ATPase activity. Thus the accumulation of [H+]i as well as occurrence of intracellular and mitochondrial Ca2+ overload may explain the lack of beneficial effects of MIA in preventing the ischemia-reperfusion-induced myocardial injury.     

The regulatory role of mitochondria in capacitative calcium entry

Capacitative regulation of calcium entry is a major mechanism of Ca2+ influx into electrically non-excitable cells, but it also operates in some excitable ones. It participates in the refilling of intracellular calcium stores and in the generation of Ca2+ signals in excited cells. The mechanism which couples depletion of intracellular calcium stores located in the endoplasmic reticulum with opening of store-operated calcium channels in the plasma membrane is not clearly understood. Mitochondria located in close proximity to Ca2+ channels are exposed to high Ca2+ concentration, and therefore, they are able to accumulate this cation effectively. This decreases local Ca2+ concentration and thereby affects calcium-dependent processes, such as depletion and refilling of the intracellular calcium stores and opening of the store-operated channels. Finally, mitochondria modulate the intensity and the duration of calcium signals induced by extracellular stimuli. Ca2+ uptake by mitochondria requires these organelles to be in the energized state. On the other hand, Ca2+ flux into mitochondria stimulates energy metabolism. To sum up, mitochondria couple cellular metabolism with calcium homeostasis and signaling.     

Permeability transition pore regulates both mitochondrial membrane potential and agonist-evoked Ca2+ signals in oligodendrocyte progenitors

In this study, we investigated the importance of mitochondrial permeability transition pore (PTP) in agonist-evoked cytosolic Ca2+ ([Ca2+]c) signals in oligodendrocyte progenitor cells (OP cells). We measured transmembrane potential across the mitochondrial inner membrane (delta psi m) and [Ca2+]c in the immediate vicinity simultaneously using tetramethylrhodamine ethyl ester (TMRE) and calcium green respectively. Stimulation of OP cells with methacholine evoked robust [Ca2+]c signals in approximately 80% of cells which were either oscillatory or showed a peak followed by a plateau. Elevations in [Ca2+]c induced by supramaximal concentrations of the agonist (> 200 microM) were accompanied by changes in delta psi m in 33-42% of the total mitochondria investigated. The mitochondria that responded either depolarized (26-29%), hyperpolarized (7-13%) or showed no change (58-67%). Thus, of the responsive mitochondria, most (70%) depolarized during agonist-evoked [Ca2+]c signals. Blockade of PTP with cyclosporin A (CSA) reduced the number of mitochondria that depolarized with a corresponding increase in the number that hyperpolarized. In addition, CSA or its analogue methyl valine-4- CSA (MeVal-CSA), reduced the frequency of agonist-evoked global [Ca2+]c oscillations. In resting cells, CSA (63%) and MeVal-CSA (77%) hyperpolarized a majority of the mitochondria suggesting that PTP is constitutively active and may show flickering openings. Such hyperpolarizations were not mimicked by either cyclosporine H or verapamil and were inhibited by Ru360, which blocks the mitochondrial uniporter. This observation suggested that in resting cells, Ca2+ ions might redistribute between cytosol and mitochondrial matrix through the uniporter and the PTP. Taken together, these data suggest that PTP may play an important role in regulating delta psi m and local [Ca2+]c signals during agonist stimulation in OP cells.     

The Use of Fura-2 Fluorescence to Monitor the Movement of Free Calcium Ions into the Matrix of Plant Mitochondria (Pisum sativum and Helianthus tuberosus)

Purified mitochondria isolated from pea (Pisum sativum L. cv Alaska) stems and Jerusalem artichoke (Helianthus tuberosus L. cv OB1) tubers were loaded with the acetoxymethyl ester of the fluorescent Ca2+ indicator fura-2. This made possible the continuous monitoring of free [Ca2+] in the matrix ([Ca2+]m) without affecting the apparent viability of the mitochondria. Pea stem mitochondria contained an initial [Ca2+]m of approximately 60 to 100 nM, whereas [Ca2+]m was severalfold higher (400-600 nM) in mitochondria of Jerusalem artichoke tubers. At low extramitochondrial Ca2+ concentrations ([greater than or equal to]100 nM), there was an energy-dependent membrane potential increase in [Ca2+]m; the final [Ca2+]m was phosphate-dependent in Jerusalem artichoke but was phosphate-independent in pea stem mitochondria. The data presented indicate that (a) there is no absolute requirement for phosphate in Ca2+ uptake; (b) plant mitochondria can accumulate external free Ca2+ by means of an electrophoretic Ca2+ uniporter with an apparent affinity for Ca2+ (Km approximately 150 nM) that is severalfold lower than that measured by conventional methods (isotopes and Ca2+-sensitive electrodes); and (c) [Ca2+]m is within the regulatory range of mammalian intramitochondrial dehydrogenases.     

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.     

Integrating cytosolic calcium signals into mitochondrial metabolic responses.

Stimulation of hepatocytes with vasopressin evokes increases in cytosolic free Ca2+ ([Ca2+]c) that are relayed into the mitochondria, where the resulting mitochondrial Ca2+ ([Ca2+]m) increase regulates intramitochondrial Ca2+-sensitive targets. To understand how mitochondria integrate the [Ca2+]c signals into a final metabolic response, we stimulated hepatocytes with high vasopressin doses that generate a sustained increase in [Ca2+]c. This elicited a synchronous, single spike of [Ca2+]m and consequent NAD(P)H formation, which could be related to changes in the activity state of pyruvate dehydrogenase (PDH) measured in parallel. The vasopressin-induced [Ca2+]m spike evoked a transient increase in NAD(P)H that persisted longer than the [Ca2+]m increase. In contrast, PDH activity increased biphasically, with an initial rapid phase accompanying the rise in [Ca2+]m, followed by a sustained secondary activation phase associated with a decline in cellular ATP. The decline of NAD(P)H in the face of elevated PDH activity occurred as a result of respiratory chain activation, which was also manifest in a calcium-dependent increase in the membrane potential and pH gradient components of the proton motive force (PMF). This is the first direct demonstration that Ca2+-mobilizing hormones increase the PMF in intact cells. Thus, Ca2+ plays an important role in signal transduction from cytosol to mitochondria, with a single [Ca2+]m spike evoking a complex series of changes to activate mitochondrial oxidative metabolism.     

Quasi-synaptic calcium signal transmission between endoplasmic reticulum and mitochondria.

Transmission of cytosolic [Ca2+] ([Ca2+]c) oscillations into the mitochondrial matrix is thought to be supported by local calcium control between IP3 receptor Ca2+ channels (IP3R) and mitochondria, but study of the coupling mechanisms has been difficult. We established a permeabilized cell model in which the Ca2+ coupling between endoplasmic reticulum (ER) and mitochondria is retained, and mitochondrial [Ca2+] ([Ca2+]m) can be monitored by fluorescence imaging. We demonstrate that maximal activation of mitochondrial Ca2+ uptake is evoked by IP3-induced perimitochondrial [Ca2+] elevations, which appear to reach values >20-fold higher than the global increases of [Ca2+]c. Incremental doses of IP3 elicited [Ca2+]m elevations that followed the quantal pattern of Ca2+ mobilization, even at the level of individual mitochondria. In contrast, gradual increases of IP3 evoked relatively small [Ca2+]m responses despite eliciting similar [Ca2+]c increases. We conclude that each mitochondrial Ca2+ uptake site faces multiple IP3R, a concurrent activation of which is required for optimal activation of mitochondrial Ca2+ uptake. This architecture explains why calcium oscillations evoked by synchronized periodic activation of IP3R are particularly effective in establishing dynamic control over mitochondrial metabolism. Furthermore, our data reveal fundamental functional similarities between ER-mitochondrial Ca2+ coupling and synaptic transmission.     

Ca2+ signaling, mitochondria and cell death

In the complex interplay that allows different signals to be decoded into activation of cell death, calcium (Ca2+) plays a significant role. In all eukaryotic cells, the cytosolic concentration of Ca2+ ions ([Ca2+]c) is tightly controlled by interactions among transporters, pumps, channels and binding proteins. Finely tuned changes in [Ca2+]c modulate a variety of intracellular functions ranging from muscular contraction to secretion, and disruption of Ca2+ handling leads to cell death. In this context, Ca2+ signals have been shown to affect important checkpoints of the cell death process, such as mitochondria, thus tuning the sensitivity of cells to various challenges. In this contribution, we will review (i) the evidence supporting the involvement of Ca2+ in the three major process of cell death: apoptosis, necrosis and autophagy (ii) the complex signaling interplay that allows cell death signals to be decoded into mitochondria as messages controlling cell fate.     

Cytosolic and mitochondrial [Ca2+] in whole hearts using indo-1 acetoxymethyl ester: effects of high extracellular Ca2+.

Assessment of free cytosolic [Ca2+] ([Ca2+]c) using the acetoxymethyl ester (AM) form of indo-1 may be compromised by loading of indo-1 into noncytosolic compartments, primarily mitochondria. To determine the fraction of noncytosolic fluorescence in whole hearts loaded with indo-1 AM, Mn2+ was used to quench cytosolic fluorescence. Residual (i.e., noncytosolic) fluorescence was subtracted from the total fluorescence before calculating [Ca2+]c. Noncytosolic fluorescence was used to estimate mitochondrial [Ca2+]. In hearts paced at 5 Hz (N = 17), noncytosolic fluorescence was 0.61 +/- 0.06 and 0.56 +/- 0.07 of total fluorescence at lambda 385 and lambda 456, respectively. After taking into account noncytosolic fluorescence, systolic and diastolic [Ca2+]c was 673 +/- 72 and 132 +/- 9 nM, respectively, noncytosolic [Ca2+] was 183 +/- 36 nM and increased to 272 +/- 12 when extracellular Ca2+ was increased from 2 to 6 mM. This increase in noncytosolic [Ca2+] was inhibited by ruthenium red, a blocker of Ca2+ uptake by mitochondria. We conclude that cytosolic and mitochondrial [Ca2+] can be determined in whole hearts loaded with indo-1 AM by using Mn2+ to quench cytosolic fluorescence.     

Role of calcium ions in the control of embryogenesis of Xenopus. Changes in the subcellular distribution of calcium in early cleavage embryos after treatment with the ionophore A23187.

Treatment of stage 5 Xenopus embryos with the ionophore A23187 for only 10 min, in the absence of extracellular Mg2+ and Ca2+, causes cortical contractions and a high incidence of abnormal embryos during subsequent development. Cation analysis shows that divalent ions are not lost from the embryos, but that Ca2+ is redistributed within the subcellular fractions. Ca2+ is probably released from yolk platelets and/or pigment granules by the action of A23187, [Ca2+] rises in the cytosol, and the mitochondria attempt to take up this free Ca2+. The mitochondria concomitantly undergo characteristic ultrastructural transformations, changing towards energized-twisted and energized-zigzag conformations. A23187 allows these changes to be demonstrated in situ. Extracellular divalent cations (10(-4) M) interfere with this intracellular action of A23187. Intracellular accumulation of Na+ (by treatment with ouabain) or Li+ also causes abnormal development, probably by promoting a release of Ca2+ from the mitochondria. It is suggested (a) that all these treatments cause a rise in [Ca2+]i which interferes with normal, integrated cell division, so causing, in turn, abnormal embryogenesis, (b) that levels of [Ca2+]i are of importance in regulating cleavage, (c) that the mitochondria could well have a function in regulating [Ca2+]i during embryogenesis in Xenopus, and (d) that vegetalizing agents may well act by promoting a rise in [Ca2+]i in specific cells in the amphibian embryo.     

Inositol 1,4,5-trisphosphate and intracellular Ca2+ homeostasis in clonal pituitary cells (GH3). Translocation of Ca2+ into mitochondria from a functionally discrete portion of the nonmitochondrial store

Ca2+-specific minielectrodes were used to monitor changes in the ambient free Ca2+ concentration [( Ca2+]a) maintained by the intracellular organelles of permeabilized GH3 cells. Mitochondria maintained a [Ca2+]a steady state of around 500 nM and displayed a very high capacity for Ca2+ uptake. A nonmitochondrial pool, tentatively identified as the endoplasmic reticulum (ER), displayed higher affinity for Ca2+ by maintaining a steady state of approximately 170 nM. The capacity of this pool was around 10 nmol/mg cell protein. Inositol 1,4,5-trisphosphate (InsP3) released Ca2+ specifically from the ER, with an EC50 of approximately 2 microM, and gave maximal release of around 4 nmol Ca2+/mg of cell protein. Repeated InsR3 additions under conditions allowing for functional mitochondrial transport resulted in successively attenuated peaks, leading eventually to the depletion of the InsP3 sensitive portion of the ER. However, Ca2+ could still be released from the total ER pool with the ATPase inhibitor, vanadate. This InsP3-insensitive store did not reaccumulate InsP3 releasable Ca2+ nor could it directly refill the sensitive pool. However, the attenuation of the InsP3 responses could be overcome by repleting the sensitive pool with exogenous Ca2+ or by inhibiting Ca2+ uptake into the mitochondria. The results suggest: 1) the ER is the major intracellular organelle buffering Ca2+ in nonstimulated GH3 cells; 2) InsP3 releases Ca2+ from only a portion of the ER; 3) the InsP3-sensitive and -insensitive ER pools are functionally distinct; 4) InsP3 addition results in a transfer of Ca2+ from the ER to the mitochondria.     

Calcium induced release of mitochondrial cytochrome c by different mechanisms selective for brain versus liver.

Increased mitochondrial Ca2+ accumulation is a trigger for the release of cytochrome c from the mitochondrial intermembrane space into the cytosol where it can activate caspases and lead to apoptosis. This study tested the hypothesis that Ca2+-induced release of cytochrome c in vitro can occur by membrane permeability transition (MPT)-dependent and independent mechanisms, depending on the tissue from which mitochondria are isolated. Mitochondria were isolated from rat liver and brain and suspended at 37 degrees C in a K+-based medium containing oxidizable substrates, ATP, and Mg2+. Measurements of changes in mitochondrial volume (via light scattering and electron microscopy), membrane potential and the medium free [Ca2+] indicated that the addition of 0.3 - 3.2 micromol Ca2+ mg-1 protein induced the MPT in liver but not brain mitochondria. Under these conditions, a Ca2+ dose-dependent release of cytochrome c was observed with both types of mitochondria; however, the MPT inhibitor cyclosporin A was only capable of inhibiting this release from liver mitochondria. Therefore, the MPT is responsible for cytochrome c release from liver mitochondria, whereas an MPT-independent mechanism is responsible for release from brain mitochondria.