INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Mitochondrial Ca²⁺ fluxes are the subject of renewed attention because of their possible involvement on modulation of Ca²⁺ signals and secretion (Montero et al., 2000) and on triggering of apoptosis (Di Lisa and Bernardi, 1998; Green and Reed, 1998; Crompton, 1999). Mitocondrial [Ca²⁺] ([Ca²⁺]_M) is low in resting cells but, during cell activation, mitochondria take up large amounts of Ca²⁺ from local cytosolic [Ca²⁺] ([Ca²⁺]_c) microdomains generated in the vicinity of plasma membrane Ca²⁺ channels (Rizzuto et al., 1993, 1994; Brini et al., 1997; Montero et al., 2000). The increase in [Ca²⁺]_M activates mitochondrial dehydrogenases and respiration (McCormack et al., 1990; Robb-Gaspers et al., 1998; Duchen, 1999), thus matching the rate of ATP production to the increasing energy demands. On the other hand, neurons and chromaffin cell mitochondria accumulate large amounts of Ca²⁺ during cell stimulation (Werth and Thayer, 1994; Herrington et al., 1996; Park et al., 1996; Babcock et al., 1997; White and Reynolds, 1997). This large mitochondrial Ca²⁺ uptake may damp the [Ca²⁺]_c increase thus modulating secretion. In fact, using mitochondrially targeted aequorin, we have shown that chromaffin cell mitochondria can take up Ca²⁺ up to near the millimolar level during stimulation and that this Ca²⁺ uptake regulates catecholamine release (Montero et al., 2000).

Mitochondria take up Ca²⁺ through the Ca²⁺ uniporter, a specific Ca²⁺ pathway driven by the electrical potential difference across the mitochondrial membrane. The mitochondrial membrane potential, 150 to 180 mV, is enough to accumulate Ca²⁺ within the mitochondrial matrix up to 5-6 orders of magnitude above [Ca²⁺]_c. However, the Ca²⁺ uniporter requires a high extramitochondrial [Ca²⁺]_c to be activated (Kroner, 1986; Igbavboa and Pfeiffer, 1988; Gunter and Pfeiffer, 1990; Rizzuto et al., 1993; Xu et al., 1997; Bernardi, 1999; Csordás et al., 1999; Montero et al., 2000), a condition that is fulfilled only for a brief period of time during cell stimulation. Protonophores collapse mitochondrial membrane potential and prevent mitochondrial Ca²⁺ accumulation. Consistently, it has been shown that cell stimulation produces much larger [Ca²⁺]_c increases in cells treated with protonophores (Friel and Tsien, 1994; Werth and Thayer, 1994; Hehl et al., 1996; Herrington et al., 1996; Park et al., 1996; Babcock et al., 1997; Tang and Zucker, 1997; Giovanucci et al., 1999; Pivovarova et al., 1999). Moreover, addition of protonophores immediately after cell stimulation produces in many cells a large increase in [Ca²⁺]_c due to release of the Ca²⁺ accumulated into mitochondria (Werth and Thayer, 1994; Hehl et al., 1996; Herrington et al., 1996; Tang and Zucker, 1997; White and Reynolds, 1997).

The pathway for this protonophore-induced mitochondrial Ca²⁺ release is unclear. Although the Ca²⁺ uniporter shares most of the properties of a channel, flux through this system is not easily reverted after mitochondrial depolarization (Petronilli et al., 1993; Bernardi, 1999). Normally, Ca²⁺ exit from mitochondria occurs via Na⁺/Ca²⁺ exchange and an Na⁺-independent pathway that may include a H⁺/Ca²⁺ exchange. There is evidence that both kinds of transporters are electrogenic, and stoichiometries of 3Na⁺/1Ca²⁺ (Baysal et al., 1994; Jung et al., 1995) and more than 2H⁺/Ca²⁺ have been proposed (Gunter et al., 1991). If this is correct, Ca²⁺ release through the exchangers would be favored by the mitochondrial membrane potential and hence it should be inhibited on mitochondrial membrane depolarization by protonophores. In fact, it has been shown that mitochondrial Na⁺-independent Ca²⁺ exchange pathways are inhibited by mitochondrial depolarization (Bernardi and Azzone, 1982, 1983).

Another relevant mitochondrial transport mechanism, which could be activated by protonophores, is the so-called mitochondrial permeability transition pore (MPT, reviewed in Zoratti and Szabó, 1995; Di Lisa and Bernardi, 1998; Ichas and Mazat, 1998; Crompton, 1999). MPT allows passage of molecules with molecular weights below 1500 Da and is inhibited by cyclosporin A. A series of factors, including high mitochondrial Ca²⁺, mitochondrial depolarization, oxidized state of pyridine nucleotides and of critical dithiols, etc., favor pore opening, whereas the opposite conditions stabilize it in the closed conformation. Opening of MPT triggers a fast release of Ca²⁺ and mitochondrial metabolites, and prolonged opening of this pathway has been associated to the release of apoptotic factors and cell death. MPT may also be involved in the development of the so-called mitochondrial Ca²⁺-induced Ca²⁺ release (mCICR) responses (Ichas et al., 1997), and has been shown to be activated by protonophores after Ca²⁺-loading of mitochondria (Bernardi et al., 1984; Igbavboa and Pfeiffer, 1988; Bernardi, 1992).

Here we use a targeted aequorin to investigate the mechanisms for Ca²⁺ exit from mitochondria of intact chromaffin cells, previously loaded with Ca²⁺ by high-K⁺ depolarizing stimuli. Surprisingly, protonophores did not accelerate but inhibited Ca²⁺ exit from mitochondria, probably by interfering with electrogenic Na⁺/Ca²⁺ exchange. In these cells, with depolarized and Ca²⁺-loaded mitochondria, increasing the extramitochondrial [Ca²⁺]_c triggered a massive mitochondrial Ca²⁺ release. This mCICR was sensitive to ruthenium red, but not to CGP37157 or cyclosporin A, revealing that the mitochondrial Ca²⁺ uniporter can behave, under certain conditions, as a [Ca²⁺]_c-activated Ca²⁺ release channel functionally similar to the ryanodine receptor.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Cell Preparation and Culture

Bovine adrenal medulla chromaffin cells were isolated following standard methods (Livett, 1984) with some modifications (Moro et al., 1990). Cells were suspended in DMEM supplemented with 5% fetal calf serum, 10 µM cytosine arabinoside, 10 µM fluorodeoxyuridine, 50 IU ml¹ penicillin and 50 IU ml¹ streptomycin. Cells were plated in 12-mm glass polilysine-coated coverslips (0.25 × 10⁶ cells/1 ml of DMEM). Cultures were maintained at 37°C in a humidified atmosphere of 5% CO₂, and used within 1-3 d.

Expression of Aequorin with Defective Herpes Virus (HSV) as Vectors

The mitochondrial aequorin was a kind gift of Prof. Tullio Pozzan, Padova, Italy. The EcoRI-fragment containing the cDNA encoding for mitochondrially targeted aequorin (mitAEQ) was isolated from the original vector and inserted into the recipient vector pHSVpuc (Geller et al., 1993) to generate the pHSVmitAEQ. For construction of the mitochondrially targeted mutated (Asp119Ala) aequorin cDNA we replaced in frame the wild-type aequorin in pHSVmitAEQ with the mutated aequorin (Montero et al., 1995), obtaining the pHSVmutmitAEQ. The expression was confirmed after transfection of 2-2 cells by inmunofluorescence with an antibody against the HA1 epitope. These two vectors were packaged into HSV particles by using a deletion mutant packaging system (Lim et al., 1997). In brief, 3 × 10⁵ 2-2 cells were seeded on 60-mm dishes and transfected with 6 µg of pHSVmitAEQ or pHSVmutmitAEQ by using lipofectamine. 24 h later the cells were infected with ~2 × 10⁶ plaque-forming units of 5dl1.2 helper virus, which contains a deletion in the IE2 gene of HSV-1. On the following day virus was harvested and subsequently passaged on fresh 2-2 cells twice to increase both the ratio of vector to helper and the total amount of virus. Titering has been previously described (Alonso et al., 1998). The titers of packaged pHSVmitAEQ and pHSVmutmitAEQ, as determined by immunocytochemistry in PC12 cells, were 1.5 × 10⁵ infectious virus units (ivu)/ml and 2.4 × 10⁵ ivu/ml, respectively. For expression in chromaffin cells, the coverslips containing 0.25 × 10⁶ cells were suspended in 0.5 ml of DMEM and infected with 2 × 10³ ivu 12-24 h before measurements. Immunofluorescence with the anti-HA1 antibody showed a typical mitochondrial pattern in chromaffin cells infected with HSV expressing mitochondrially targeted aequorin (our unpublished results).

[Ca²⁺]_M Measurements

For aequorin reconstitution, the coverslip with the cells expressing mitochondrial mutated aequorin was incubated with 1 µM coelenterazine n in 0.2 ml of standard medium containing 145 mM NaCl, 5 mM KCl, 1 mM MgCl₂, 1 mM CaCl₂, 10 mM glucose, and 10 mM HEPES, pH 7.4. Reconstitution was carried out in the dark at room temperature for 1-2 h. Reconstitution of aequorin with coelenterazine n is much slower than with wild-type coelenterazine (the half-time in vitro is 5 h compared with 22 min for the wild-type; Shimomura et al., 1993). This means that longer times of reconstitution will give an almost linear increase in the total luminescence output. A very important factor is also to keep low the temperature of reconstitution. Increasing the temperature to 37°C during reconstitution decreases considerably the total luminescence of the sample, probably because of increased aequorin consumption. Cells were then placed in the perfusion chamber of a purpose-built luminometer thermostatized at 37°C. Perfusion of up to eight different solutions was controlled by a system of electrovalves. For the experiments with permeabilized cells, standard medium containing 0.5 mM EGTA instead of Ca²⁺ was perfused for 1min. Then, intracellular medium (130 mM KCl, 10 mM NaCl, 1 mM MgCl₂, 1 mM K₃PO₄, 0,2 mM EGTA, 1 mM ATP, 20 µM ADP, 2 mM succinate, 20 mM HEPES, pH 7) containing 20 µM digitonin was perfused during 1 min, followed by intracellular medium without digitonin for 1-2 min before the experiment. Buffer containing 10 µM [Ca²⁺] in EGTA-free intracellular medium was prepared using an HEDTA/Ca²⁺/Mg²⁺ mixture (5 mM HEDTA, 0.84 mM Ca²⁺, 4.71 mM Mg²⁺).

To calibrate the data obtained in terms of [Ca²⁺]_M, we need to know the total amount of luminescence that can be emitted by the sample (see below). For that, at the end of every experiment it is essential to perfuse lysis solution containing detergent (100 µM digitonin) and excess Ca²⁺ (10 mM) to measure all the remaining aequorin luminescence. To transform luminescence data in [Ca²⁺], a computer program subtracts the background and calculates the fractions L/L_max at every point along the experiment. L is the luminescence value at every point (minus the background) and L_max is the integral of luminescence (minus the background) from that point to the end of the experiment. L/L_max values are then transformed into [Ca²⁺] values by using the following mathematical algorithm:

(1)

The values for the parameters of the algorithm used to calculate [Ca²⁺] in experiments at 37°C with mutated aequorin reconstituted with coelenterazine n have been obtained previously (Montero et al., 1997): K_R = 8.47 · 10⁷, K_TR = 1.656 · 10⁵, n = 1.2038, and  = 0.138. This algorithm and the parameters K_R, K_TR, and n derive from a mathematical model proposed originally to explain from a molecular point of view the Ca²⁺ dependence of aequorin luminescence (Allen et al., 1971), but can be used as a simple mathematical transformation independent of the model. The parameter  is the rate constant for aequorin consumption at saturating [Ca²⁺]. This parameter was not included in the original description of the algorithm (Brini et al., 1995), because the maximum rate constant of native aequorin reconstituted with wild-type coelenterazine is 1.0 s¹. Reconstitution with coelenterazine n reduces considerably the maximum rate constant, and this allows recording high [Ca²⁺] values with slower aequorin consumption. In some experiments, L_max was reduced 50% to take into account that only ~50% of mitochondria undergo large increases in [Ca²⁺]_M after high-K⁺ stimulation (Montero et al., 2000).

Measurements of Single-Cell [Ca²⁺]_c

Single cell measurements of [Ca²⁺]_c were performed in cells loaded with the low-affinity Ca²⁺ dye fura-4F (4 µM; 60 min at 25°C). Other details were as described previously (Nuñez et al., 1995). Cells were epi-illuminated alternatively at 340 and 380 nm and light emitted above 520 nm was recorded by an extended ISIS-M camera (Photonic Science, Robertbridge, East Sussex, United Kingdom) and analyzed using an Applied Imaging Magical image processor (Sunderland, TyneandWear, United Kingdom). Eight frames excited at every wavelength were averaged by hardware, with a time resolution of 1.7 s for each pair of images. [Ca²⁺]_c was estimated from the formula (Grynkiewicz et al., 1985):

(2)

where R is the ratio between the fluorescence emissions measured at 340 and 380 nm excitation; R_max and R_min are the ratios obtained at saturation of the dye with Ca²⁺ and in the absence of Ca²⁺, respectively; K_d is the dissociation constant for the dye (0.77 µM); and  is the ratio of the maximal (in the absence of Ca²⁺) and minimum (at saturation with Ca²⁺) fluorescence emissions measured at 380-nm excitation. The values of R_max, and R_min and  were determined in cells permeabilized to Ca²⁺ with ionomycin and perfused with media containing either no Ca²⁺ (5 mM EGTA) or 10 mM Ca²⁺. These values were similar to the ones obtained with fura-2. All the experiments were performed at 37°C.

Materials

Fura-4F and coelenterazine n were obtained from Molecular Probes, Eugene, OR. Carbonyl cyanide m-chlorophenyl-hydrazone (CCCP) and cyclosporin A were from Sigma (St. Louis, MO). CGP37157 was from Tocris, Bristol, United Kingdom. Ruthenium red was from Calbiochem, La Jolla, CA. Other reagents were from Sigma or Merck (Darmstadt, Germany).

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

We have shown recently that stimulation of chromaffin cells with high-K⁺ medium triggers a fast Ca²⁺ uptake into ~50% of the total mitochondrial pool. Mitochondrial depolarization by treatment with the protonophore CCCP prevented mitochondrial Ca²⁺ accumulation during stimulation with high K⁺ (Montero et al., 2000). We wanted now to investigate the effect of the protonophore on Ca²⁺ exit from mitochondria (Figure 1). In control cells [Ca²⁺]_M increased to ~300 µM during the 10-s stimulation period with high K⁺ and returned to the low resting levels with a half-time of <30 s (Figure 1A, first trace). Adding CCCP just after high-K⁺ stimulation slowed Ca²⁺ exit from mitochondria (Figure 1A, second trace). The inhibitory effect started a few seconds after addition of the protonophore, probably the time required to collapse the mitochondrial membrane potential. Figure 1, B and C, compare the effects of the inhibitor of the mitochondrial Na⁺/Ca²⁺ exchanger CGP37157 and of both CGP37157 and CCCP on Ca²⁺ exit from mitochondria after stimulation with high K⁺. The inhibition by CGP37157 was similar to the one effected by CCCP, except for the fact that inhibition by CGP37157 had no delay (it was preincubated for 2 min). In addition, the effects of both compounds were scarcely additive. As a representative parameter to compare the rate of mitochondrial Ca²⁺ efflux under the different conditions, we have measured the rate of [Ca²⁺]_M decrease between 150 and 100 µM. The average values obtained (mean ± SEM) were 4.0 ± 0.4 µM/s (n = 7) in control cells, 1.1 ± 0.13 µM/s (n = 6) in the presence of CCCP, 1.22 ± 0.11 µM/s (n = 7) in the presence of CGP37157, and 0.95 ± 0.03 µM/s (n = 5) in the presence of both CGP37157 and CCCP. These results suggest that CCCP inhibits Ca²⁺ release by acting on the mitochondrial Na⁺/Ca²⁺ exchanger.

View larger version (10K): [in this window] [in a new window]   Figure 1.   Effects of CCCP and CGP37157 on Ca2+ release from mitochondria after high-K+ cell stimulation. Chromaffin cells expressing mitochondrial mutated aequorin reconstituted with coelenterazine n were stimulated by 10-s pulses of medium containing 70 mM K+ (indicated at the bottom). When indicated, cells were perfused with 2 µM CCCP added immediately after the high-K+ pulse (CCCP), with 10 µM CGP37157 (CGP, preincubated for 2 min before high-K+ stimulation), or with both together. For [Ca2+]M calculations, total luminescence was reduced 50%, assuming that [Ca2+]M changes take place in only 50% of the mitochondrial space.

Inhibition of mitochondrial Ca²⁺ exit by CCCP came as a surprise because protonophores have been reported to induce release of mitochondrial Ca²⁺ in several neuronal cells (see the Introduction). This interpretation was based mainly on measurements of cytosolic [Ca²⁺], nominally in the induction of an increase of [Ca²⁺]_c by CCCP added just after mitochondrial Ca²⁺ loading. We then studied the effect of CCCP on the high-K⁺-induced [Ca²⁺]_c transient. The low-Ca²⁺ affinity fluorescent probe fura-4F was used to avoid saturation of the dye at high-Ca²⁺ loads. Figure 2A shows that when CCCP was perfused before stimulation with high K⁺, the [Ca²⁺]_c peak was considerably increased both in amplitude and duration, and this effect was reverted on washing CCCP. This outcome illustrates the action of mitochondria as a damper of the [Ca²⁺]_c peak. In contrast, when CCCP was perfused just after high-K⁺ stimulation, the relaxation of the [Ca²⁺]_c peak was indistinguishable from the control condition and we did not find a secondary [Ca²⁺]_c peak (Figure 2B). This result indicates that, at least under the experimental conditions used in this work, CCCP did not release the Ca²⁺ accumulated in mitochondria during the stimulation period. This is consistent with the results seen with aequorin in Figure 1, where CCCP did not increase the rate of Ca²⁺ exit from mitochondria (as a matter of fact, it decreased it). The mitochondrial Na⁺/Ca²⁺ inhibitor CGP37157 had no significant effect on [Ca²⁺]_c or on the kinetics of the high-K⁺-induced [Ca²⁺]_c peak (our unpublished results).

View larger version (13K): [in this window] [in a new window]   Figure 2.   Effects of CCCP on [Ca2+]c. Cell were loaded with fura-4F and stimulated with 10-s pulses of medium containing 70 mM K+. When indicated, 2 µM CCCP was perfused. Traces correspond to the average of 25 (A) and 58 cells (B) present in the microscope field.

CCCP induced by itself a small increase in [Ca²⁺]_c in resting cells (Figure 2A). This effect was still present in Ca²⁺-free medium, indicating that Ca²⁺ comes, at least partially, from intracellular stores. This kind of effect has been observed previously in different cell types, and it was attributed to Ca²⁺ release from mitochondria (Werth and Thayer, 1994; Babcock et al., 1997; White and Reynolds, 1997). However, [Ca²⁺]_M has been shown to be in the same range as [Ca²⁺]_c (100-200 nM) in resting cells (Rizzuto et al., 1993, 1994; Babcock et al., 1997). In these reports, protonophores produced a decrease in resting [Ca²⁺]_M, but too small (100 nM) to justify the observed [Ca²⁺]_c changes. Here we show that the initial resting [Ca²⁺]_M values reported by the low-Ca²⁺-affinity aequorin were higher (5.8 ± 0.5 µM; mean ± SEM, n = 16), and that CCCP induced a reversible decrease in [Ca²⁺]_M of several micromolar (Figure 3A). In contrast, using the mitochondrially targeted aequorin with high affinity for Ca²⁺ (native aequorin reconstituted with wild-type coelenterazine), the estimated resting [Ca²⁺]_M value was 73 ± 7 nM, (mean ± SEM, n = 20). In this case, perfusion of the cells with CCCP induced a transient increase in [Ca²⁺]_M to 300-400 nM (Figure 3B). The conflicting results obtained with both aequorins suggest that different mitochondria maintain different resting [Ca²⁺]_M, which therefore cannot be considered as homogeneous among mitochondrial subpopulations. CCCP would be able to release Ca²⁺ from a subpopulation of mitochondria that contains micromolar levels of Ca²⁺ under resting conditions. Release of Ca²⁺ from these mitochondria may explain the increase in [Ca²⁺]_c induced by CCCP. The endoplasmic reticulum could also be a possible source for that Ca²⁺, but using aequorin targeted to this organelle we were not able to detect any release of Ca²⁺ induced by CCCP (our unpublished results).

View larger version (19K): [in this window] [in a new window]   Figure 3.   Effects of CCCP on [Ca2+]M. (A) Cells expressing mitochondrially targeted low-Ca2+-affinity mutated aequorin were reconstituted with coelenterazine n, and 2 µM CCCP was added as indicated. (B) Cells expressing mitochondrially targeted wild-type aequorin were reconstituted with native coelenterazine, and 2 µM CCCP was added as indicated.

Protonophores collapse the electrical potential difference that drives Ca²⁺ accumulation into the mitochondria. This abolishes mitochondrial Ca²⁺ uptake (Rizzuto et al., 1994; Montero et al., 2000). However, stimulation of Ca²⁺ release requires, in addition, the opening of a pathway for Ca²⁺ exit. The possible implication of MPT was examined first. Figure 4 compares the [Ca²⁺]_M peaks induced by stimulation with high K⁺ in the control condition and in the presence of cyclosporin A, an inhibitor of MPT. Except for the small differences in the lower part of the traces, cyclosporin A had little effect on the rate of Ca²⁺ efflux from mitochondria, suggesting no participation of MPT. On the other hand, inhibition of mitochondrial Ca²⁺ exit by CCCP (Figure 1) is inconsistent with MPT opening. Therefore, under the conditions used in our experiments, neither the large mitochondrial Ca²⁺ accumulation observed nor the mitochondrial depolarization induced by CCCP was enough to induce MPT opening.

View larger version (19K): [in this window] [in a new window]   Figure 4.   Effect of cyclosporin A on the [Ca2+]M transient induced by high-K+ stimulation. Either control cells or cells preincubated for 5 min with 10 µM cyclosporin A were stimulated with a 10-s pulse of medium containing 70 mM K+. The figure shows the mean of 11 experiments of each type (bars indicate the SEM of each point). Other details as in Figure 1. For [Ca2+]M calculations, total luminescence was reduced 50%.

Another possible pathway for Ca²⁺ exit from mitochondria would be the reversal of the Ca²⁺ uniporter. After treatment with the protonophore, the mitochondrial membrane potential collapses and the electrochemical gradient for Ca²⁺ becomes directed outwards. However, the uniporter might be inactive because of lack of cytosolic Ca²⁺. High local [Ca²⁺]_c is required to activate mitochondrial Ca²⁺ uptake through the uniporter and half-maximum rates of transport are only reached at [Ca²⁺]_c of 15-50 µM (Xu et al., 1997; Csordás et al., 1999; Montero et al., 2000). Then the failure of CCCP to induce mitochondrial Ca²⁺ release through the uniporter may be due to inactivation of this system following the rapid decrease of local [Ca²⁺]_c after high-K⁺ stimulation. If that was the case, increasing [Ca²⁺]_c at that time should, paradoxically, promote mitochondrial Ca²⁺ release. This rationale was tested by performing a second stimulation with high K⁺ in the presence of CCCP at the time [Ca²⁺]_M was returning toward the resting level. The first trace in Figure 5 shows the slow decline of [Ca²⁺]_M obtained in the presence of CCCP (compare to Figure 1). In the second trace a new stimulation with high K⁺ was applied during the decline of [Ca²⁺]_M, ~90 s after the first stimulus. This maneuver induced a very fast release of mitochondrial Ca²⁺. Of course, in the absence of CCCP, repetitive cell stimulation even at short periods (every 15-30 s) always induced repetitive increases in [Ca²⁺]_M (our unpublished results; Montero et al., 2000). The third trace in Figure 5 shows that caffeine was also able to accelerate the release of mitochondrial Ca²⁺ in the presence of CCCP. We have shown before that caffeine induces a large local increase of [Ca²⁺]_c by releasing Ca²⁺ from the endoplasmic reticulum (Alonso et al., 1999; Montero et al., 2000). Thus, the increase of [Ca²⁺]_c, either due to Ca²⁺ entry through the plasma membrane or to release from the endoplasmic reticulum, was able to induce fast release of Ca²⁺ from depolarized mitochondria. The rate constants for efflux increased similarly on stimulation with either high K⁺ or caffeine from 0.7-0.9 to 3-5 µM/s. The same effects of CCCP on mitochondrial Ca²⁺ release were obtained in the presence of 2 µM oligomycin, to prevent reversal of the ATP synthase, or 10 µM cyclosporin A (preincubated for 2 min before high-K⁺ stimulation) to inhibit MPT. In addition, the effects of CCCP on Ca²⁺ exit from mitochondria were tested also at 22°C because, in many previous studies, release of Ca²⁺ from mitochondria by CCCP was studied at room temperature (Friel and Tsien, 1994; Herrington et al., 1996; Park et al., 1996; Babcock et al., 1997; Tang and Zucker, 1997; White and Reynolds, 1997). The results were similar to those shown in Figure 5. CCCP strongly inhibited mitochondrial Ca²⁺ exit at 22°C, and a second stimulation with high K⁺ produced a massive Ca²⁺ release.

View larger version (9K): [in this window] [in a new window]   Figure 5.   Cell stimulation induces Ca2+ release from depolarized Ca2+-loaded mitochondria. Cells were stimulated with a 10-s pulse of medium containing 70 mM K+ (indicated at the bottom), and 2 µM CCCP was perfused immediately afterward (A). Addition of a later 10-s high-K+ pulse (B) or a 30-s pulse with 50 mM caffeine (C) triggered Ca2+ release from mitochondria. Other details as in Figure 1. For [Ca2+]M calculations, total luminescence was reduced 50%.

The results shown in Figure 5 strongly suggest that mitochondrial Ca²⁺ release induced by cell stimulation in the presence of CCCP is due to reversal of the mitochondrial Ca²⁺ uniporter, which may require relatively high [Ca²⁺]_c to open. To obtain further evidence on this point, we studied the effect of CCCP in permeabilized cells, where extramitocondrial [Ca²⁺] can be tightly controlled. Cells were permeabilized by a 1-min treatment with 20 µM digitonin (Montero et al., 2000). Cells were then perfused with Ca²⁺-free intracellular medium, and a mitochondrial [Ca²⁺]_M transient was triggered by brief (3-s) perfusion with a 10 µM Ca²⁺ buffer (Figure 6A). The rates of Ca²⁺ efflux from mitochondria were very similar to the ones measured in intact cells (compare to Figure 1). Figure 6B shows that the effect of CCCP in the permeabilized cells was nearly the same as in the intact cells. After a short lag, Ca²⁺ exit was strongly inhibited. Figure 6,C and D, show the effects of CGP37157 and both CGP37157 and CCCP on Ca²⁺ exit. As observed in the intact cells, the effects of these inhibitors were scarcely additive. The rate of Ca²⁺ release between 150 and 100 µM [Ca²⁺]_M (mean ± SEM) was 4.4 ± 0.3 µM/s (n = 10) in control cells, 1.42 ± 0.16 µM/s (n = 6) in the presence of CCCP, 1.56 ± 0.03 µM/s in the presence of CGP37157 (n = 3), and 1.4 ± 0.3 µM/s (n = 3) in the presence of both CGP37157 and CCCP.

View larger version (18K): [in this window] [in a new window]   Figure 6.   Effects of CCCP and CGP37157 on Ca2+ release from mitochondria in permeabilized cells. Cells expressing mutated aequorin reconstituted with coelenterazine n were permeabilized on line as described in MATERIALS AND METHODS. Then, transient Ca2+ uptake was induced by a 3-s perfusion of intracellular medium containing a 10 µM [Ca2+] buffer (arrows). When indicated, cells were perfused with 2 µM CCCP immediately after the Ca2+ pulse (CCCP), with 10 µM CGP37157 (CGP) or with both together.

The question was now whether we could induce Ca²⁺ release from depolarized Ca²⁺-loaded mitochondria by increasing extramitochondrial [Ca²⁺], as in the experiments with intact cells (Figure 5). Figure 7 shows that this was the case. In Figure 7A short (3-s) pulses with a 10 µM Ca²⁺ buffer induced a fast Ca²⁺ release from Ca²⁺-loaded mitochondria. Once CCCP was washed away, mitochondria recovered the ability to accumulate Ca²⁺ and to release it slowly. The [Ca²⁺]_c-induced mCICR was not prevented by the Na⁺/Ca²⁺ blocker CGP37157 (Figure 7B) but it was fully prevented by ruthenium red (Figure 7C), an inhibitor of the mitochondrial Ca²⁺ uniporter. This confirms that mCICR takes place though reversal of the mitochondrial Ca²⁺ uniporter.

View larger version (24K): [in this window] [in a new window]   Figure 7.   Ca2+-induced Ca2+ release from depolarized Ca2+-loaded mitochondria. Cells expressing mutated aequorin reconstituted with coelenterazine n were permeabilized on line as described in MATERIALS AND METHODS. The arrows indicate 3-s pulses with intracellular medium containing a 10 µM [Ca2+] buffer. When indicated, either 2 µM CCCP, 10 µM CGP37157 (CGP), or 4 µM ruthenium red (RR) was perfused.

An important point was to show that the observed mCICR develops after mitochondrial depolarization induced by CCCP but is independent of other effects of CCCP such as matrix acidification. We have tested the effects of other ionophores such as valinomycin and nigericin. Figure 8A shows the effect of nigericin. This ionophore carries out an electroneutral H⁺/K⁺ exchange that should acidify the mitochondrial matrix similarly to CCCP but without the associated depolarization. Consistently, it produced little effects on the kinetics of Ca²⁺ release. Figure 8B shows the effect of valinomycin. This ionophore carries out an electrogenic K⁺ transport, and should depolarize mitochondria and increase the matrix pH. In spite of its opposite effect on matrix pH, valinomycin produced the same effects as CCCP: Ca²⁺ exit from mitochondria was slowed and mCICR could be induced by a second Ca²⁺ pulse. Finally, Figure 8C shows the effects of a combination of valinomycin and nigericin. This combination should be equivalent to CCCP, and produced in fact the same effects.

View larger version (13K): [in this window] [in a new window]   Figure 8.   Effects of nigericin and valinomycin on Ca2+ release from mitochondria in permeabilized cells. Cells expressing mutated aequorin reconstituted with coelenterazine n were permeabilized on line as described in MATERIALS AND METHODS. The arrows indicate 3-s pulses with intracellular medium containing a 10 µM [Ca2+] buffer. When indicated, either 0.5 µM nigericin, 0.5 µM valinomycin, or both were perfused. In B and C, the ionophores were perfused just after the Ca2+ pulse.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In this article we have studied the dynamics of [Ca²⁺]_M after high mitochondrial Ca²⁺ loads and the effects of collapsing the mitochondrial membrane potential on the rate of Ca²⁺ exit from mitochondria. We have reported recently that Ca²⁺ entry through voltage-gated Ca²⁺ channels of plasma membrane induces, in chromaffin cells, a fast Ca²⁺ uptake to near millimolar levels into a population of mitochondria, probably with subplasmalemmal location (Montero et al., 2000). Then, Ca²⁺ exits from mitochondria within 1-2 min, mainly through the mitochondrial Na⁺/Ca²⁺ exchanger. The large increase in [Ca²⁺]_M was apparently not enough to activate the MPT, which should have produced an abrupt drop in [Ca²⁺]_M. In fact, a series of such millimolar mitochondrial transients could be elicited with no sign of activation of MPT (Montero et al., 2000). In addition, we show here that cyclosporin A, an inhibitor of MPT, had almost no effect on this mitochondrial Ca²⁺ release (Figure 4), suggesting that MPT did not open under our experimental conditions. However, some contribution of MPT to Ca²⁺ release cannot be completely excluded, because the degree of inhibition of MPT by cyclosporin A may be variable or transient depending on a series of factors (Bernardi, 1999).

Mitochondrial depolarization induces Ca²⁺ release from Ca²⁺-loaded mitochondria under several conditions (Bernardi et al., 1984; Igbavboa et al., 1988; Bernardi, 1992). In resting cells, measurements of [Ca²⁺]_M by using either high-affinity aequorin (Rizzuto et al., 1993, 1994) or the fluorescent Ca²⁺ indicator rhod-2 (Babcock et al., 1997) have provided very low values, close to the resting [Ca²⁺]_c. In both cases, however, protonophores still produced a small but significant reduction in [Ca²⁺]_M. We obtain here conflicting results on this matter by using either the high- or the low-Ca²⁺-affinity aequorin. In the first case we estimate resting [Ca²⁺]_M levels of 70 nM, which increase transiently to 300-400 nM on addition of CCCP. In contrast, with the low-Ca²⁺-affinity aequorin we estimate resting [Ca²⁺]_M values around 5 µM, which decrease on addition of CCCP. Low-Ca²⁺-affinity aequorin has little sensitivity at these [Ca²⁺], and the level of luminescence produced is very low compared with the peaks induced by cell stimulation. However, because of the large dynamic range of aequorin, the luminescence observed at resting [Ca²⁺]_M is still severalfold the background. In addition, CCCP produced a clear and reversible decrease in the resting [Ca²⁺]_M, demonstrating the presence of mitochondria with micromolar resting [Ca²⁺] that can release their Ca²⁺ upon CCCP addition. The discrepancies among the results obtained with both types of aequorin may be due to the presence of heterogeneity in the resting [Ca²⁺]_M levels. Although some mitochondria keep a low resting [Ca²⁺]_M around 100 nM, others may have values in the micromolar range or perhaps oscillating [Ca²⁺]_M values due to spontaneous opening of nearby Ca²⁺ channels. When using high-Ca²⁺-affinity aequorin, the photoprotein present in these last ones would be consumed during the reconstitution period before measurements, so that they are never observed. The remaining aequorin would be present in low-Ca²⁺ mitochondria, which may take up transiently small amounts of Ca²⁺ from the cytosol after CCCP addition (up to 300-400 nM, undetectable for low-Ca²⁺-affinity aequorin).

Addition of protonophores after cell stimulation induces, in several cell types, a large increase in [Ca²⁺]_c, due to release of Ca²⁺ from mitochondria (Werth and Thayer, 1994; Hehl et al., 1996; Herrington et al., 1996; Tang and Zucker, 1997; White and Reynolds, 1997). At variance with these observations, we find that CCCP inhibited Ca²⁺ exit from Ca²⁺-loaded mitochondria both in intact and in permeabilized chromaffin cells. Because both the Na⁺/Ca²⁺ and Ca²⁺/H⁺ antiporters are electrogenic (see the Introduction), inhibition of Ca²⁺ exit through these systems by depolarization should be expected and is consistent with the results obtained here. On the contrary, opening of MPT would favor Ca²⁺ release because, once mitochondria are depolarized, the Ca²⁺ electrochemical gradient is directed outwards. Depolarization of Ca²⁺-loaded mitochondria is known to favor opening of MPT (Igbavboa and Pfeiffer, 1988; Bernardi, 1992; Di Lisa and Bernardi, 1998). However, we could not evidence such behavior in intact or permeabilized chromaffin cells under our experimental conditions, in spite of the large accumulation of Ca²⁺ into mitochondria. This may be due to the presence of other factors promoting MPT closure, such as nucleotides or reduced pyridine nucleotides (Di Lisa and Bernardi, 1998; Bernardi, 1999; Crompton, 1999).

Another possible pathway for Ca²⁺ exit from depolarized mitochondria would be reversal of the mitochondrial uniporter. However, Ca²⁺ release through this system has been difficult to observe (Petronilli et al., 1993; Bernardi, 1999), this leading to the suggestion that flux through the uniporter may be scarcely reversible. However, a high [Ca²⁺]_c is necessary to activate Ca²⁺ entry through this system (Rizzuto et al., 1993; Xu et al., 1997; Csordás et al., 1999; Montero et al., 2000) and probably a threshold concentration of Ca²⁺ is also required at the extramitochondrial side to allow Ca²⁺ exit (Kroner, 1986; Gunter and Pfeiffer, 1990, Igbavboa and Pfeiffer, 1988). Should this condition apply, then an increase of [Ca²⁺]_c would, paradoxically, release Ca²⁺ from depolarized Ca²⁺-loaded mitochondria. Cell stimulation with high K⁺ generates high local [Ca²⁺]_c microdomains that trigger mitochondrial Ca²⁺ uptake (Montero et al., 2000), but they dissipate rapidly after closure of the Ca²⁺ channels. Measurements with fura-4F show that [Ca²⁺]_c decreases to <1 µM within ~10 s of stimulation (Figure 2). Thus, when CCCP is added after stimulation, local [Ca²⁺]_c microdomains may return below the threshold for opening of the uniporter before mitochondrial depolarization is achieved. This rationale predicts that increasing [Ca²⁺]_c at this time would trigger mitochondrial Ca²⁺ release through the uniporter. This prediction was confirmed by further stimulating the Ca²⁺-loaded cells with either high K⁺ or caffeine (Figure 4). The massive Ca²⁺ release induced by these maneuvers was insensitive to cyclosporin A. In addition, Ca²⁺ release from depolarized Ca²⁺-loaded mitochondria could be induced in permeabilized cells by brief perfusion with 10 µM Ca²⁺, and this Ca²⁺ release was blocked by ruthenium red. These results demonstrate that the Ca²⁺ uniporter is readily reversible after mitochondrial depolarization in the presence of micromolar extramitochondrial Ca²⁺ and can mediate mCICR.

It could be argued that the effects of CCCP on mitochondrial Ca²⁺ release could be due to acidification of the mitochondrial matrix rather than to depolarization. Aequorin is scarcely sensitive to pH, and acidification should, in any case, decrease the luminescence (Moisescu and Ashley, 1977) and thus the apparent [Ca²⁺]_M levels. Instead, we observe that CCCP slows down the [Ca²⁺]_M decrease after cell stimulation. To exclude other possible effects of matrix acidification, we used nigericin and valinomycin. Nigericin, which decreases matrix pH and does not depolarize the mitochondrial membrane (it may actually hyperpolarize it), had no effect on Ca²⁺ release. In contrast, valinomycin, which depolarizes mitochondria but does not acidify the mitochondrial matrix (in fact, it should probably increase matrix pH), produced effects similar to CCCP. Finally, the combination of valinomycin + nigericin also reproduced the effects of CCCP on Ca²⁺ release. This demonstrates that the effect of CCCP on Ca²⁺ exit from mitochondria is due to mitochondrial depolarization.

It is not clear whether this mCICR may occur under physiological conditions. A mCICR has been described previously (Ichas et al., 1997), but mediated by opening of the MPT after mitochondrial Ca²⁺ overload. For the mCICR described here, mediated by the Ca²⁺ uniporter, mitochondrial depolarization after the Ca²⁺ loading would be required. Both, Ca²⁺ uptake through the uniporter and Ca²⁺ release through the exchangers tend to depolarize mitochondria. It would then be conceivable that mitochondrial depolarization after a large Ca²⁺ uptake, particularly if respiration is somewhat compromised, could render mitochondria sensitive to mCICR through the Ca²⁺ uniporter. Opening of other mitochondrial membrane channels, such as uncoupling proteins or K_ATP channels, could also contribute or trigger mitochondrial depolarization. In addition, opening of any of these channels would be essential to allow net Ca²⁺ exit from mitochondria through the uniporter by providing charge compensation. At this stage, further increase in local [Ca²⁺]_c would trigger opening of the uniporter and Ca²⁺ release from mitochondria. mCICR through the Ca²⁺ uniporter could be advantageous over MPT for clearing of mitochondrial Ca²⁺ overload. Because the uniporter is a pathway specific for Ca²⁺, loss of metabolites would not happen in this case, and quick recovery of the ability to produce ATP would be easier.

Our results point out the subtlety of the Ca²⁺-handling mechanisms of mitochondria and how slight differences can lead to very different outcomes. Mitochondria take up large amounts of Ca²⁺ though the uniporter when a high-[Ca²⁺]_c microdomain is generated close enough after cell stimulation (Montero et al., 2000). Exit of Ca²⁺ from the loaded mitochondria can then follow several alternative pathways, with very different consequences for the cell. If the mitochondrial membrane potential remains high, Ca²⁺ exits mitochondria through the Ca²⁺/Na⁺ and the Ca²⁺/H⁺ exchangers, as it happens in most of the experiments shown here. If the mitochondrial membrane potential collapses, Ca²⁺ can exit mitochondria by reversal of the uniporter, provided that mitochondrial H⁺ or K⁺ pathways allow charge compensation and local [Ca²⁺]_c is high enough at that time (mCICR). Finally, if added circumstances favoring opening of MPT exist, Ca²⁺ can exit mitochondria through this pathway, but now accompanied by other low-molecular weight mitochondrial constituents. Transition from one alternative to the other may depend on subtle differences in kinetics of the [Ca²⁺]_c changes, oxygen supply, metabolic state, oxidative stress, etc.

The discrepancies of our results with previous reports showing CCCP-induced Ca²⁺-release from mitochondria may be explained on the basis of the above-mentioned complexity. It seems clear that the pathway responsible for the CCCP-induced Ca²⁺ release observed in previous studies should not be the Ca²⁺ uniporter acting in reverse mode, because the local [Ca²⁺]_c returns rapidly to resting values once stimulation has ceased, leading to inactivation of this system. A more probable alternative is the MPT, given that MPT open-closed transitions are highly regulated by multiple effectors (Di Lisa and Bernardi, 1998; Bernardi, 1999; Crompton, 1999), including [Ca²⁺]_M and mitochondrial membrane potential, so that opening may critically depend on the particular experimental conditions. Our data suggest that, in intact cells and under our conditions, mitochondrial Ca²⁺ accumulation and depolarization are not enough to promote opening of MPT. Use of uncouplers to study mitochondrial Ca²⁺ homeostasis should therefore take into account that, even though uncouplers certainly abolish mitochondrial Ca²⁺ uptake, they do not necessarily induce Ca²⁺ release from mitochondria.