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© The Rockefeller University Press,
0021-9525/2000//1489 $5.00
The Journal of Cell Biology, Volume 150, Number 6,
, 2000 1489-1498
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Calcium Regulates the Association between Mitochondria and a Smooth Subdomain of the Endoplasmic Reticulum
Association between the ER and mitochondria has long been observed, and the formation of close contacts between ER and mitochondria is necessary for the ER-mediated sequestration of cytosolic calcium by mitochondria. Autocrine motility factor receptor (AMF-R) is a marker for a smooth subdomain of the ER, shown here by confocal microscopy to be distinct from, yet closely associated with the calnexin- or calreticulin-labeled ER. By EM, smooth ER AMF-R tubules exhibit direct interactions with mitochondria, identifying them as a mitochondria-associated smooth ER subdomain. In digitonin-permeabilized MDCK cells, the addition of rat liver cytosol stimulates the dissociation of smooth ER and mitochondria under conditions of low calcium. Using BAPTA chelators of various affinities and CaEGTA buffers of defined free Ca2+ concentrations and quantitative confocal microscopy, we show that free calcium concentrations <100 nM favor dissociation, whereas those >1 µM favor close association between these two organelles. Therefore, we describe a cellular mechanism that facilitates the close association of this smooth ER subdomain and mitochondria when cytosolic free calcium rises above physiological levels.
Key Words: free calcium • autocrine motility factor receptor • AMF-R tubule • cytosol • semipermeabilized cell assay
© 2000 The Rockefeller University Press
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Introduction |
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Interaction between ER and mitochondria has also been implicated in the sequestration and regulation of free cytosolic calcium (Ca2+; for review see Pozzan et al. 1994). Ca2+ release due to the generation of inositol 1,4,5-triphosphate (IP3) in response to receptor activation results in the formation of high local concentrations of Ca2+ at sites of close contact between ER and mitochondria that results in increases in mitochondrial Ca2+ (Rizzuto et al. 1993, Rizzuto et al. 1998; Simpson et al. 1997). ER-mediated Ca2+ uptake by mitochondria may activate mitochondrial metabolic activity by stimulating Ca2+-dependent mitochondrial dehydrogenases (Denton and McCormack 1990; Rutter et al. 1996; Jouaville et al. 1999), as well as regulate the subcellular pattern of Ca2+ oscillations generated by receptor activation (Rizzuto et al. 1994; Landolfi et al. 1998; Robb-Gaspers et al. 1998; Hajnoczky et al. 1999). Close contacts between ER and mitochondria, particularly under conditions of high local free cytosolic Ca2+, are therefore of functional importance.
We have identified a smooth ER subdomain specifically labeled for autocrine motility factor receptor (AMF-R; Benlimame et al. 1995). By EM, smooth AMF-R–labeled tubules exhibit continuity with the ribosome-studded tubules of the rough ER, and after treatment with ilimaquinone, form a highly fenestrated network of smooth tubules morphologically equivalent to the smooth ER of the hepatocyte (Benlimame et al. 1995; Wang et al. 1997). AMF-R tubules can be distinguished from the ER-Golgi intermediate compartment (ERGIC) by fluorescence microscopy and therefore represent a distinct smooth ER subdomain (Wang et al. 1997). We show here that smooth ER AMF-R tubules are intimately associated with mitochondria. Using a semipermeabilized cell assay, we further show that this association can be disrupted by cytosol in the presence of low cytosolic free Ca2+ levels. Elevated cytosolic free Ca2+ inhibits the ability of cytosol to dissociate the two organelles identifying a mechanism that facilitates the close association between the ER and mitochondria necessary for mitochondrial Ca2+ uptake.
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Materials and Methods |
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Monoclonal IgM antibody against AMF-R was used in the form of concentrated hybridoma supernatant (Nabi et al. 1990). Polyclonal antibody to calreticulin was kindly provided by Dr. Luis Rokeach (Department of Biochemistry, Université de Montréal, Quebec, Canada) and to calnexin by Dr. John Bergeron (Department of Cell Biology and Anatomy, McGill University, Montreal, Quebec, Canada). Antibody to mitochondrial heat shock protein 70 (Mt-HSP70; clone JG1) was purchased from Affinity Bioreagents, Inc. Secondary antibodies conjugated to either Texas red or FITC were purchased from Jackson ImmunoResearch Laboratories. DTT was purchased from Sigma-Aldrich, and digitonin was purchased from ICN. The K2H2EGTA and K2CaEGTA solutions (Calibration Buffer Concentrate Kit) used to prepare the CaEGTA buffers. 5,5'-dimethyl BAPTA-AM, BAPTA-AM, 5,5'-difluoro BAPTA-AM, and 5,5'-dibromo BAPTA-AM were purchased from Molecular Probes.
Confocal and Electron Microscopy
Immunofluorescence labeling of 80/20% (vol/vol) methanol/acetone fixed MDCK cells for AMF-R, calnexin, calreticulin, and Mt-HSP70, and postembedding immunoelectron microscopic labeling for AMF-R were performed as previously described (Benlimame et al. 1995; Wang et al. 1997). Confocal images were obtained with a BioRad MRC-600 confocal microscope and EM images with a Phillips 300 electron microscope. The minimal ER-mitochondria distance was quantified by measuring from 14 randomly taken EM images (21,000x), the distance between the point on each ER tubule, smooth or rough, labeled or not for AMF-R, closest to a mitochondrion within the same cell. Rough ER tubules were identified by the presence of a linear array of membrane-associated ribosomes.
Preparation of Rat Liver Cytosol
Rat liver cytosol was prepared from cleaned rat liver cut into small pieces by scissors in buffer A (25 mM Tris, 25 mM KCl, 1 mM DTT, pH 7.4) supplemented with 85 mM sucrose and protease inhibitors at 4°C and homogenized at 4°C in 1 vol of the same buffer. The homogenate was centrifuged at 11,060 g for 20 min and the supernatant recentrifuged at 100,000 g for 90 min at 4°C. The supernatant was collected and assayed for protein concentration. Cytosol was heat-inactivated by boiling for 5 min.
In Vitro Assay for Smooth ER Mitochondria Association
MDCK cells plated at 25,000–50,000 cells/35-mm plate on glass cover slips for 2 d were quickly washed twice with cytoskeleton stabilizing buffer (CSB; 130 mM Hepes, 2 mM MgCl2, 10 mM EGTA, pH 6.9) prewarmed to 20°C and then incubated with 10 µg/ml digitonin in buffer A for 1 min at 20°C. The cells were then washed with CSB and incubated in buffer A, supplemented as indicated in the text, for 1 h at 37°C. The cells were washed twice with CSB containing 0.2% BSA, fixed with methanol/acetone and labeled for AMF-R (Texas red) and Mt-HSP70 (FITC). The gain and black level of the confocal images were adjusted for each slide for both the FITC and rhodamine channels such that the full dynamic range of the instrument was used. For each experiment, confocal images from all slides were obtained in one sitting using equivalent pinhole settings and the extent of overlap of AMF-R tubule labeling with mitochondria was determined using Northern Eclipse software (Empix Imaging). The nonspecific AMF-R labeling of the nuclei was first cut from the image and the total number of cytoplasmic pixels labeled for AMF-R determined. Using a convolution filter, the mitochondrial labeling was enlarged to ensure that shifts between the FITC and Texas red images and cellular variations in the intensity of the mitochondrial image did not influence the measure of the extent of AMF-R tubule overlap with mitochondria. Using the enlarged mitochondrial labeling as a mask, AMF-R labeling that coincided with the enhanced mitochondrial labeling was deleted and quantification of the remaining AMF-R–labeled pixels provided a measure of smooth ER AMF-R tubules that had dissociated from mitochondria. This value was divided by the total AMF-R–labeled cytoplasmic pixels to generate the percent dissociation of AMF-R tubules from mitochondria.
Ca2+ Measurements
To prepare the CaEGTA buffers, 100 mM stock solutions of K2H2EGTA and K2CaEGTA were diluted in buffer A to 25 mM. The resulting buffers were then mixed to generate 8 different 25-mM CaEGTA buffers containing 0, 5, 10, 15, 20, 22.13, 22.92, and 25 mM total Ca2+ (see Table ). Predicted free Ca2+ concentrations were calculated using WEBMAXCv1.10 at the CPatton MaxChelator website.
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[Ca2+]SOL was calculated using the following equation (Grynkiewicz et al. 1985): [Ca2+]SOL = Kd x (R – RMIN)(RMAX – R) x Sf2/Sb2; with Kd equal to 224 nM, R the ratio of the fluorescence measured at 350 and 380 nm, respectively, and Sf2/Sb2, the ratio of fluorescence at 380 nm in low and high Ca2+, respectively. The maximum fluorescence ratio (RMAX) was determined using a 10 mM CaCl2 solution to oversaturate the Fura-2, whereas RMIN was obtained with a Ca2+ free solution containing 10 mM EGTA. Measurements of [Ca2+]SOL were performed at a pH of 7.35 at room temperature (21–23°C).
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Results |
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90%. In the absence of cytosol, Ca2+ alone did not affect the extent of association between smooth ER and mitochondria, demonstrating that Ca2+ specifically regulates the cytosolic dissociation activity. To determine the role of free Ca2+ in the regulation of the cytosol-dependent dissociation of smooth ER and mitochondria, we used BAPTA Ca2+ chelators with varying Kds for Ca2+ (Fig. 6 C). 5-5'-dimethyl BAPTA (Kd = 40 nM) reversed by 70%, and BAPTA (Kd = 160 nM) by 30% the ability of 0.5 mM Ca2+ to inhibit cytosol-dependent smooth ER-mitochondria dissociation. 5-5'-difluoro BAPTA (Kd = 635 nM) and 5-5'-dibromo BAPTA (Kd = 1.6 µM) reversed only minimally smooth ER–mitochondria dissociation. The ability of BAPTAs of various Kd's to differentially influence smooth ER mitochondria association demonstrates that free Ca2+ levels regulate ER–mitochondria association. The fact that these effects are observed in the presence of 100 µM BAPTA indicates that free Ca2+ in the presence of cytosol and cells must be below 100 µM, in spite of the fact that 0.5 mM Ca2+ was added to the reaction. Indeed, no effect was observed using 50 µM of the various BAPTAs, indicating that protein Ca2+ chelators in the cells and in the cytosol reduce free Ca2+ to between 50–100 µM.
To further define the free Ca2+ concentrations that regulate cytosol-mediated dissociation of smooth ER and mitochondria, we added cytosol in the presence of CaEGTA buffers of defined free Ca2+ concentrations. Free [Ca2+]SOL was predicted using the WEBMAXCv1.10 program and measured using Fura-2 (Table ). Compared with the high degree of dissociation observed in the presence of free [Ca2+]SOL of less than 50 nM (CaEGTA buffers 2 and 3), free [Ca2+]SOL of 100–400 nM (CaEGTA buffers 4 and 5) were associated with partial inhibition and free [Ca2+]SOL concentrations >1 µM (CaEGTA buffers 6–8) associated with a significant inhibition of cytosol-mediated dissociation of smooth ER and mitochondria. Graphic representation of the data presented in Table (CaEGTA buffers 2–7) reveals a logarithmic relationship between free [Ca2+]SOL measured with Fura-2 and cytosol dissociation activity (Fig. 6 D). In particular, free [Ca2+]SOL below 100 nM are associated with extensive dissociation of the two organelles, whereas increasing the free [Ca2+]SOL above 100 nM results in the progressive inhibition of cytosol-mediated dissociation.
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Discussion |
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The existence of ER subdomains that interact with mitochondria and which function to sequester cytosolic Ca2+ (Simpson et al. 1997; Rizzuto et al. 1998), together with the demonstrated role of cytosolic Ca2+ in regulating AMF-R tubule–mitochondria association, suggest a role for this smooth ER subdomain in the regulation of cytosolic Ca2+ levels. The diversity of Ca2+ concentrations and expression of Ca2+ binding proteins in different subdomains of the ER is well-established (Takei et al. 1992; Button and Eidsath 1996; Rooney and Meldolesi 1996; Golovina and Blaustein 1997; Montero et al. 1997; Pezzati et al. 1997). Not unlike the smooth ER AMF-R tubule, a smooth membrane-bound organelle of 50–250 nm apposed to the ER and mitochondria, called the calciosome, has been described to be enriched in a nonmuscle calsequestrin-like protein and to represent the major IP3-sensitive Ca2+ storage organelle (Volpe et al. 1988). Both AMF-R and the IP3 receptor are associated with cell surface caveolae (Fujimoto et al. 1992; Benlimame et al. 1998), and the caveolar-like clathrin-independent internalization pathway to smooth ER defined by AMF-R (Benlimame et al. 1998; Le et al. 2000) may serve to regulate the delivery of Ca2+ regulatory proteins to this mitochondria-associated smooth ER subdomain.
In semipermeabilized MDCK cells in the absence of cytosol or energy and independent of Ca2+, smooth ER AMF-R tubules and mitochondria maintain their close association, suggesting that interorganellar adhesion mechanisms are associated with the organelles. The ability of cytosol to dissociate the two organelles demonstrates the existence of a cytosolic mechanism that regulates ER–mitochondria association. The transfer of phosphatidyl serine between mitochondria and MAMs is prevented by proteolysis of mitochondrial surface proteins, but not of MAMs, suggesting that a mitochondrial surface protein is involved in the association between mitochondria and ER (Shiao et al. 1998). Whereas the relationship of smooth ER AMF-R tubules to MAMs remains unclear, cytosol may disrupt smooth ER AMF-R tubule–mitochondria association due to the presence of a Ca2+-regulated cytosolic protein that inhibits the adhesive function of such a mitochondrial surface protein.
Our results using BAPTAs of various affinities and CaEGTA buffers of varying free [Ca2+]SOL indicate that free Ca2+ regulates the ability of cytosol to stimulate dissociation of AMF-R tubules from mitochondria. While we hesitate to attribute precise free Ca2+ levels to our data, both the BAPTA and CaEGTA experiments are consistent with the ability of low free [Ca2+]SOL (<100 nM) to favor dissociation and of high free [Ca2+]SOL (>1 µM) to favor association of smooth ER tubules and mitochondria (Fig. 6; Table ). Therefore, these data argue that at physiological cytosolic Ca2+ levels, cytosol stimulates smooth ER-mitochondria dissociation. Whereas addition of cytosol increases the amount of smooth ER AMF-R tubules that do not colocalize with mitochondria, the two organelles still exhibit extensive association (Fig. 5 F) such that even in the presence of cytosol the two organelles still interact. Dissociation of AMF-R tubules from mitochondria induced by cytosol therefore reflects a partial disruption of direct contacts between the two organelles. The increased overlap of the two fluorescent signals observed in the presence of increasing Ca2+ may be indicative of the increased formation of close contacts between the two organelles.
Ca2+ transients of 1.6–1.9 µM have been identified at high density patches of the ER enriched in the IP3 receptor and calreticulin (Simpson et al. 1997), and the mitochondrial surface has been shown to be exposed to 3.4 µM Ca2+ after IP3 stimulation (Rizzuto et al. 1998). Our data showing increased ER–mitochondria association at millimolar cytosolic Ca2+ indicates that the elevated Ca2+ levels present at these ER–mitochondria close contacts can actively regulate ER–mitochondria association. Ca2+-dependent smooth ER–mitochondria association could therefore contribute to the establishment of segregated cytoplasmic domains between the two organelles in which the local elevated Ca2+ concentrations necessary for mitochondrial uptake can be established. A cellular mechanism that senses elevated cytosolic Ca2+ levels and then facilitates the establishment of ER–mitochondria contacts is therefore proposed to be implicated in the efficient sequestration of cytosolic Ca2+ to mitochondrial stores.
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Acknowledgments |
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This study was supported by grants from the Medical Research Council of Canada.
Submitted: 24 May 2000
Revised: 5 July 2000
Accepted: 27 July 2000
Abbreviations used in this paper: AMF-R, autocrine motility factor receptor; IP3, inositol 1,4,5-triphosphate; MAM, mitochondria-associated membrane; Mt-HSP70: mitochondrial heat shock protein 70.
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