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¹ Instituto de Biología y Genética Molecular (IBGM), Universidad de Valladolid and Consejo Superior de Investigaciones Científicas (CSIC), c/Sanz y Forés s/n, 47003 Valladolid, Spain

	Abstract

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Changes in the cytosolic Ca²⁺ concentration ([Ca²⁺]_c) are essential for triggering neurotransmitter release from presynaptic nerve terminals. Calcium-induced Ca²⁺ release (CICR) from the endoplasmic reticulum (ER) may amplify the [Ca²⁺]_c signals and facilitate neurotransmitter release in sympathetic neurons. In adrenal chromaffin cells, functional triads are formed by voltage-operated Ca²⁺ channels (VOCCs), CICR sites and mitochondria. In fact, mitochondria take up most of the Ca²⁺ load entering the cells and are essential for shaping [Ca²⁺]_c signals and exocytosis. Here we have investigated the existence of such functional triads in sympathetic neurons. The mitochondrial Ca²⁺ concentration ([Ca²⁺]_m) in soma and neurites of individual mouse superior cervical ganglion (SCG) neurons was monitored by bioluminescence imaging of targeted aequorins. In soma, Ca²⁺ entry through VOCCs evoked rapid, near millimolar [Ca²⁺]_m increases in a subpopulation of mitochondria containing about 40% of the aequorin. Caffeine evoked a similar [Ca²⁺]_m increase in a mitochondrial pool containing about 30% of the aequorin and overlapping with the VOCC-sensitive pool. These observations suggest the existence of functional triads similar to the ones described in chromaffin cells. In neurites, mitochondria were able to buffer [Ca²⁺]_c increases resulting from activation of VOCCs but not those mediated by caffeine-induced Ca²⁺ release from the ER. The weaker Ca²⁺ buffering by mitochondria in neurites could contribute to facilitate Ca²⁺-induced exocytosis at the presynaptic sites.

(Received 13 December 2006; accepted after revision 18 January 2007; first published online 18 January 2007)
Corresponding author L. Núñez: Instituto de Biología y Genética Molecular (IBGM), Universidad de Valladolid and CSIC, c/ Sanz y Forés s/n, 47003 Valladolid, Spain.  Email: nunezl{at}ibgm.uva.es

	Introduction

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Calcium signals govern important processes in neurons, including neurotransmitter release, membrane excitability, neurite outgrowth and neurodegeneration (Clapham, 1995; Ghosh & Greenberg, 1995). The cytosolic Ca²⁺ concentration ([Ca²⁺]_c) increases upon activation of plasma membrane Ca²⁺ channels or Ca²⁺ release from intracellular stores (Berridge, 1998). In addition, Ca²⁺ signals can be amplified by release of Ca²⁺ from the endoplasmic reticulum (ER) through Ca²⁺-induced Ca²⁺ released (CICR; Thayer et al. 1988; Hernández-Cruz et al. 1990; Friel & Tsien, 1992), mediated by ryanodine receptors (RyRs). Cytoplasmic organelles also participate in Ca²⁺ signalling (Alvarez et al. 1999). It is becoming increasingly clear that, besides its central role in cell energetics (Robb-Gaspers et al. 1998), mitochondria modulate cytosolic Ca²⁺ homeostasis (Herrington et al. 1996). Mitochondria can take up Ca²⁺ through the mitochondrial Ca²⁺ uniporter (Gunter & Pfeiffer, 1990; Kirichok et al. 2004), a high-capacity, low-affinity Ca²⁺ transport that activates exponentially with the increase of [Ca²⁺] in the surrounding cytosol (Gunter & Pfeiffer, 1990; Rizzuto et al. 1993; Montero et al. 2000). It has been reported that mitochondria can take up Ca²⁺ with relatively modest increases of [Ca²⁺] in the bulk cytosol (Herrington et al. 1996; Villalobos et al. 2002). In particular, mitochondria seem able to buffer physiological Ca²⁺ loads in neurons, and activation is paralleled by the increase of mitochondrial calcium concentration ([Ca²⁺]_m; Werth & Thayer, 1994; Babcock et al. 1997). This probably results from the generation of subcellular high-Ca²⁺ domains at sites of Ca²⁺ entry or Ca²⁺ release (Rizzuto et al. 1993; Xu et al. 1997; Duchen, 1999; Montero et al. 2000), and mitochondrial uptake is much faster at these high-Ca²⁺ microdomains. Thus, Ca²⁺ uptake by mitochondria is favoured in mitochondria located strategically near Ca²⁺ hot spots, such as the mouth of Ca²⁺ channels or ryanodine and/or inositol 1,4,5-trisphosphate (IP₃) receptors. We have reported that, in chromaffin cells, a subpopulation of mitochondria is strategically and functionally coupled to both Ca²⁺ entry through voltage-operated Ca²⁺ channels (VOCCs) and Ca²⁺ release from intracellular stores, whereas the remaining mitochondria are located far away from these Ca²⁺ hot spots (Montero et al. 2000). The former mitochondrial subpopulation takes up larger Ca²⁺ loads, approaching millimolar levels, during cell stimulation (Montero et al. 2000; Villalobos et al. 2001). In fact, quantitative analysis of Ca²⁺ redistribution among different cytoplasmic compartments in chromaffin cells has demonstrated that most of the Ca²⁺ entering through VOCCs or released from ER by CICR is, in the short term, removed from the cytosol by mitochondria rather than by the other Ca²⁺ extruding systems (Villalobos et al. 2002). Consistently, prevention of mitochondrial Ca²⁺ uptake enhanced both the [Ca²⁺]_c rise and exocytosis (Montero et al. 2000). Therefore, strategically located mitochondria modulate the [Ca²⁺]_c signals and make possible the coexistence of high subplasmalemmal Ca²⁺ levels favouring exocytosis with a much lower [Ca²⁺]_c at the cell core. This is attained by avoiding spread of the entering Ca²⁺ load towards the cell core. In addition, intramitochondrial Ca²⁺ stimulates cellular respiration and tunes ATP synthesis to the increased requirements during the active state. The functional units or triads formed by VOCCs, RyRs and mitochondria seem essential for correct organization of the secretory process in adrenal chromaffin cells (Montero et al. 2000). Whether such functional units are present in neurons has not been investigated, perhaps owing to the difficulty of monitoring aequorin bioluminescence in single neurons. Here we combine the superb selectivity of targeted aequorin, the high expression induced by a viral vector (Alonso et al. 1998) and the high sensitivity provided by a photon-counting camera (Frawley et al. 1994; Rutter et al. 1996; Villalobos et al. 2002) to resolve changes of [Ca²⁺]_m at the single-cell level and even at the subcellular level (cell body and neurites).

	Methods

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Primary culture of sympathetic neurons from adult mouse superior cervical ganglion

The cell culture method was a modification of a previously described protocol (Martínez et al. 2002). Adult (8–12 weeks old) male Balb/c mice were fed ad libitum and maintained under a standard 12 h light–12 h dark photoregime. Experiments were conducted following the Guidelines of the Animal Care Committee and the Commission d'Ethique d'Experimentation Animale of the University of Lovain School of Medicine. Groups of four or five animals were killed by cervical dislocation and their superior cervical ganglia (SCG) rapidly removed under sterile conditions and transferred to a Petri dish containing ice-cold, Ca²⁺- and Mg²⁺-free Hank's balanced salt solution (HBSS). Ganglia were incubated for 10 min in HBSS containing collagenase (1.6 mg ml^–1) at 37°C, washed and incubated again in HBSS containing trypsin (1 mg ml^–1) for 15 min at 37°C. After gentle mechanical disruption with a siliconized, fire-polished Pasteur pipette, the cells were suspended in Dulbecco's modified Eagle's medium (DMEM) containing 10% fetal bovine serum (FBS), washed twice and suspended in culture medium (DMEM supplemented with 10% FBS and 50 ng ml^–1 of nerve growth factor, NGF). Aliquots of the cell suspension (25 µl) were plated on poly L-lysine-coated 12 mm diameter glass coverslips. On average, we obtained the same number of cell-containing coverslips as ganglia dispersed. Cells were allowed to attach for 1 h and then an additional 300 µl of culture medium was added to each well and culture was continued for 2 days before the experiments.

Measurements of cytosolic [Ca²⁺] by fluorescence microscopy

The cells were loaded with fura-2 by incubation with fura-2 AM (4 µM) for about 1 h at room temperature in a standard medium of the following composition (mM): NaCl, 145; KCl, 5; MgCl₂, 1; CaCl₂, 1; glucose, 10; and sodium-Hepes, 10; pH 7.4 (adjusted with NaCH). Cells were then washed with the same medium, placed in a thermostatically controlled (37°C) chamber on the stage of an inverted microscope (Nikon Diaphot) and perfused with standard medium, prewarmed at 37°C. Cells were epi-illuminated alternately at 340 and 380 nm, and light emitted above 520 nm was recorded using a Magical Image processor (Applied Imaging, Newcastle, UK). Pixel-by-pixel ratios of consecutive frames were captured, and [Ca²⁺]_c values were estimated from these ratios by comparison with fura-2 standards. Other details were as reported previously (Núñez & García-Sancho, 1996; Villalobos et al. 2002).

Expression of aequorins

Mitochondria-targeted wild-type aequorin (mitAEQ) and low-Ca²⁺-affinity, mutated aequorin (mitmutAEQ) were delivered using defective herpes simplex virus type 1 (HSV-1) amplicons prepared, packed and titrated as previously described (Alonso et al. 1998; Montero et al. 2000). The range of Ca²⁺ sensitivies for these aequorins has been published elsewhere (Montero et al. 2000). The native aequorin can discriminate different Ca²⁺ concentrations within the 0.1–10 µM range, whereas the low-Ca²⁺-affinity, mutated aequorin can distinguish different Ca²⁺ concentrations from the tens of micromolar to the low millimolar range when used in combination with celenterazine n. Cells were infected with 1 x 10³ to 3 x 10³ infectious virus particles per coverslip of the HSV-1 containing the corresponding aequorin gene and cultured for 18 h before measurements. Infection efficiency ranged between 50 and 85% (mean ± S.E.M., 67 ± 3%; 120 cells from 18 experiments). The correct targeting of aequorins to mitochondria has been reported elsewhere (Montero et al. 2000) and was confirmed here (results not shown).

Imaging of aequorin bioluminescence

Cells expressing the apoaequorins were incubated for 1–2 h at room temperature with 1 µM coelenterazine. Coelenterazine n was used in some experiments for reconstitution of the low-Ca²⁺-affinity mutmitAEQ. Cells were placed into a perfusion chamber thermostatically regulated to 37°C under a Zeiss Axiovert 100 TV microscope and perfused at 5–10 ml min^–1 with the test solutions, based on the standard perfusing solution described above, prewarmed at 37°C. At the end of each experiment, cells were permeabilized with 0.1 mM digitonin in 10 mM CaCl₂ to release all the residual aequorin counts. Bioluminescence images were taken with a Hamamatsu VIM photon counting camera handled with an Argus-20 image processor and integrated for 10 s periods. Photons per cell in each image were quantified using the Hamamatsu Aquacosmos software. Total counts per cell ranged between 2 x 10³ and 2 x 10⁵ and noise was (mean ± S.D.) 1 ± 1 counts s^–1 per typical cell area (2000 pixels). Data were first quantified as rates of photoluminescence emission divided by the total counts remaining at each time and divided by the integration period (L/L_total in s^–1). Emission values of less than 4 counts s^–1 were not used for calculations. Calibrations in terms of [Ca²⁺]_m were performed using the constant's values published previously (Alvarez & Montero, 2001). A bright field image was also taken at the beginning of each experiment. Further details have been reported previously (Villalobos et al. 2001, 2005).

Confocal microscopy

To identify endoplasmic reticulum and mitochondria in living sympathetic neurons, we first transiently expressed a fused green fluorescent protein (GFP) targeted to the ER. Endoplasmic reticulum–GFP contain in-frame fusion of enhanced green fluorescent protein (EGFP) and a Lys-Asp-Glu-Leu (KDEL) ER retention sequence in the herpes simplex virus plasmid (pHSV) amplicon vector. Expression was achieved by infecting cells with a defective HSV-1 containing the ER–GFP–aequorin gene and cultured for 18 h before measurements. Then, cells were loaded with Mitotracker Red^® (200 nM) for 30 min at 37°C and washed with standard incubation medium. Confocal images were obtained using a Bio-Rad laser scanning system (Radiance 2100) coupled to a Nikon eclipse TE2100U inverted microscope with x63 oil immersion objective (N.A. = 1.4). Green fluorescent protein was excited by the 488 nm laser line and emission was collected through a 500–560 nm bandpass filter. Mitotracker Red^® was excited at 543 nm, and emitted light was collected through a 590 nm long-pass filter.

	Results

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In a first series of experiments, we studied the effects of both Ca²⁺ entry from the extracellular medium and Ca²⁺ release from the intracellular stores on [Ca²⁺]_m. Calcium entry was induced by stimulation with high-K⁺ solution, which depolarizes the plasma membrane and opens VOCCs. Calcium release from the ER was induced by stimulation of the ryanodine receptors with caffeine (Thayer et al. 1988; Hernández-Cruz et al. 1995). In all cases, we measured the changes of the [Ca²⁺]_c using fura-2 (Villalobos et al. 2002) and the changes of [Ca²⁺]_m with different aequorins (Montero et al. 2000). Both measurements were performed in the soma of the sympathetic neurons.

Figure 1 summarizes the effects of repetitive stimulation with high K⁺. Use of fura-2 produced reproducible increases of [Ca²⁺]_c, whose size varied between 800 and 2000 nM from cell to cell (Fig. 1A). In contrast, bioluminescence imaging of mitochondria-targeted aequorin (Montero et al. 2000; Villalobos et al. 2001) produced very different effects for the first stimulation and for subsequent ones (Fig. 1B). Since aequorin is burned out during the high-[Ca²⁺] periods (Shimomura et al. 1993; Alvarez & Montero, 2001; Villalobos et al. 2001), aequorin consumption provides a realistic record of what has happened each time, not biased by any calculation. The first stimulus consumed 44 ± 3% of the total photonic emissions (mean ± S.E.M. of 35 cells in 17 experiments). Aequorin consumption could be prevented by collapsing the mitochondrial membrane potential with the protonophore carbonyl cyanide p-(trifluoromethoxy) phenylhydrazone (FCCP) (data not shown), confirming that it results from mitochondrial Ca²⁺ uptake. The second and subsequent K⁺ pulses released only 3 ± 1% of the total photons (Fig. 1B). The remaining photonic emissions could be released easily by permeabilizing the plasma membrane with digitonin and perfusing these permeabilized cells with solutions containing high levels of Ca²⁺ (> 20 µM; Fig. 1B and results not shown). The bottom part of Fig. 1B shows the calibrated [Ca²⁺]_m values. Apparently, the first stimulus produced a large [Ca²⁺]_m increase, whereas subsequent ones had a much smaller effect.

View larger version (28K): [in this window] [in a new window]   Figure 1.  Effects of repeated stimulation of sympathetic neurons by depolarization with high K+ on cytosolic and mitochondrial [Ca2+] Cells were repeatedly stimulated by perfusion with high K+ solution (150 mM; 10 s pulses every 2 min). A, sympathetic neurons loaded with fura-2. [Ca2+]c traces from two representative neurons (large and small response) are shown. Sixty-four consecutive fura-2 fluorescence images taken at either 340 or 380 nm excitation were captured, averaged and ratioed by hardware every 5 s. The image size was 256 x 256 pixels and the spatial resolution was 1 µm per pixel. Results are representative of 15 similar experiments. B, sympathetic neurons infected with mitAEQ and subjected to photon counting imaging. The upper traces show AEQ consumption in two representative neurons (large and small response), and open circles show the average value of 7 neurons present in the same microscopic field. The lower traces show calibrated signals (two single cells) from the same experiment. Data are representative of 17 similar experiments. C, sympathetic neurons were infected with mitmutAEQ and reconstituted with coelenterazine n (the low-Ca2+-affinity system; see Methods). Data were corrected for the pool size (44% of the total AEQ counts). The traces corresponding to two extreme individual cells (large and small response) and the average of 5 cells present in the same microscope field (open circles) are shown. Only photonic emissions from the neuron cell body were counted for quantification of [Ca2+]m. Data are representative of 7 similar experiments.

In order to test the validity of this interpretation, we studied the effects of the same sequential stimuli in cells expressing mitmutAEQ reconstituted with coelenterazine n. This low-Ca²⁺-affinity aequorin (Montero et al. 2000) would not be burned out completely during the first stimulus, and should then report the real and reproducible [Ca²⁺]_m responses to repetitive stimuli. Confirmation of this prediction is shown in Fig. 1C. This panel shows the calibrated [Ca²⁺]_m recordings of two representative individual cells (the ones with the strongest and the smallest response) and the average value of five cells present in the same microscopic field. Note that the responses were similar during the first and second stimuli, reaching [Ca²⁺]_m values that ranged between 100 and 300 µM. Note also that at such high Ca²⁺ concentrations the wild-type aequorin would be fully burned within a few seconds, since the half-consumption time is below 1 s at these saturating Ca²⁺ concentrations (Shimomura et al. 1993; Alvarez & Montero, 2001). The [Ca²⁺]_m peaks reached in the core mitochondrial pool, as shown by the wild-type aequorin during the second and the third high-K⁺ stimuli, were much smaller (about 1 µM; Fig. 1B) and therefore should not be sensed by the low-Ca²⁺-affinity mutmitAEQ.

Experiments to assess the gross properties of the mitochondrial Ca²⁺ uniporter in these neurons were performed in digitonin-permeabilized cells perfused with intracellular-like solutions containing different Ca²⁺ concentrations (Montero et al. 2000). Representative results are shown in Fig. 2. The low-Ca²⁺-affinity aequorin (mitmutAEQ) almost failed to detect noticeable mitochondrial uptake at Ca²⁺ concentrations below 2 µM, but emitted quickly and uniformly more than 90% of the photonic emissions at 5 µM [Ca²⁺], and this was prevented by FCCP (not shown). Thus, although mitochondrial Ca²⁺ uptake at cytosolic Ca²⁺ concentrations below 2 µM might occur, it would not be detected with the low-Ca²⁺-affinity aequorin with a sensitivity limit for [Ca²⁺] in the low micromolar range. As we have discussed elsewhere, the steepness of the Ca²⁺ dependence of the mitochondrial Ca²⁺ uniporter, together with the second-order dependence of the light emission on [Ca²⁺], stresses the abruptness of the transition from non-perceptible to massive mitochondrial uptake (Alonso et al. 2006). When high-Ca²⁺-affinity aequorin is used, some Ca²⁺ uptake is measured also at 1 µM [Ca²⁺]_c and even below (Villalobos et al. 2002). In any case, these results indicate that the properties of the mitochondrial Ca²⁺ uniporter in sympathetic neurons are similar to those reported in other tissues (Gunter & Pfeiffer, 1990; Villalobos et al. 2002) and that high-Ca²⁺ microdomains stimulate mitochondrial uptake (Villalobos et al. 2002). Even more important, the fact that all the aequorin is consumed uniformly and homogeneously in the permeabilized cells indicates that the two mitochondrial pools, the subplasmalemmal and the core-located one, are both equally able to take up Ca²⁺ and that the differences seen in the intact cells do not result from their Ca²⁺ transport properties but from their spatial location.

View larger version (15K): [in this window] [in a new window]   Figure 2.  Ca2+ dependence of mitochondrial Ca2+ uptake in permeabilized sympathetic neurons Sympathetic neurons infected with mitmutAEQ and reconstituted with coelenterazine n were permeabilized by treatment with 20 µM digitonin over 1 min at 37°C in Ca2+-free (containing 0.2 mM EGTA) intracellular-like medium (composition, in mM: NaCl, 5; KCl, 130; MgCl2, 2; KH2PO4, 2; Mg-ATP, 0.2; and potassium-Hepes, 20; pH 7.0 adjusted with KOH). Then the cells were perfused with ‘intracellular-like’ medium containing different [Ca2+] values, as shown in the figure. The different [Ca2+] values were obtained using buffers containing 1 mM EGTA or 1 mM N-(hydroxyethyl) ethylenediamine triacetic acid (HEDTA) and adjusting Ca2+ and Mg2+ as required (Patton et al. 2004). Values represent the mean ± S.E.M. of 5 different cells present in the same microscopic field. Results are representative of 5 similar experiments.

View larger version (25K): [in this window] [in a new window]   Figure 3.  Effects of repeated stimulation with caffeine on [Ca2+]c and [Ca2+]m Sympathetic neurons were repeatedly stimulated with caffeine (Cf; 50 mM for 10 s every 4 min). A, effects on [Ca2+]c measured with fura-2. Data are representative of 16 similar experiments. B, effects on [Ca2+]m measured with mitAEQ (high-Ca2+-affinity system). Data are representative of 12 similar experiments. C, effect on [Ca2+]m measured with mutmitAEQ and coelenterazine n (low-Ca2+-affinity system). Data are representative of 6 similar experiments. Other details as in Fig. 1.

View larger version (23K): [in this window] [in a new window]   Figure 4.  Overlap between the mitochondrial pools sensing Ca2+ entry through the plasma membrane and Ca2+ release from ER Sympathetic neurons expressing the high-Ca2+-affinity mitAEQ were repeatedly stimulated first with high K+ and then with caffeine (Cf; A) or first with caffeine and then with high K+ (B), as shown. The upper traces show aequorin consumption and lower traces show the calibrated signal. Values obtained in two extreme cells (large and small responses) and the average of all the cells present in the same microscope fields (circles) are shown. Data are representative of 7 (A) and 12 independent experiments (B).

View larger version (48K): [in this window] [in a new window]   Figure 5.  Differential effects of stimulation with high K+ and caffeine in the cell body and the neurites A, effects on [Ca2+]c measured with fura-2 as described in Methods. Sixty-four 256 x 256 pixel images at alternate excitation wavelengths (340 and 380 nm) were averaged and ratioed by hardware every 5 s. Spatial resolution was of 1 µm per pixel. Results are representative of 4 similar experiments. B, effects on [Ca2+]m measured with mitAEQ (high-Ca2+-affinity system). The first high-K+ stimulation released 37 ± 4% of the total photonic emissions in neurites; the second and subsequent stimuli released 3 ± 1% (mean ± S.E.M. of 20 cells from 15 experiments). The first caffeine stimulus induced a very small aequorin consumption in neurites (5 ± 1% of total photonic emissions; mean ± S.E.M. of 22 cells from 16 experiments); the subsequent stimulation with high K+ consumed 21 ± 2% of aequorin. Regions of interest for measurements were defined selectively either in soma or neurites. Other details are as in Figs 1 and 2. C, analysis of relative content of mitochondria and ER in soma and neurites of sympathetic neurons. A sample of confocal slicing of a neuron expressing ER-GFP (green) and loaded with Mitotracker Red® (red) and the merged image are shown. The right-hand panel compares the contents of soma and neurites for 12 neurons (mean ± S.E.M.). The values are expressed as mitochondria/ER ratio and were normalized to 100% for the soma content in each case (*P < 0.001). Bars in images represent 10 µM.

Finally, we attempted to quantify the relative contents of mitochondria and ER in both soma and neurites. To this end, sympathetic neurons were infected with a defective HSV-1 virus containing ER-targeted GFP. After 18 h of culture, these cells were loaded with Mitotracker Red^® to selectively stain mitochondria and analysed by double-channel laser scanning confocal fluorescence microscopy (Fig. 5C). The amount of mitochondria relative to ER in both soma and neurites was quantified by dividing the Mitotracker Red^® fluorescence signal coming from mitochondria by the green GFP fluorescence coming from the ER. The first two images in Fig. 5C show the labelling of mitochondria and ER, respectively, in two serial 1 µm optical sections (data representative of 18 cells). Mitochondria and ER were present in both the soma and the neurites. These results are in agreement with the ability to release aequorin photonic emissions from mitochondria-targeted aequorin both in the soma and in the neurites. The presence of ER at both locations, soma and neurites, is consistent with the ability of caffeine to increase [Ca²⁺]_c at both locations (Fig. 5A). The relative abundance of mitochondria and ER in soma and neurites was, however, not uniform. Mitochondria seemed to be more abundant in neurites, as shown by the more extensive red labelling at this location (see merged image in Fig. 5C). The average of red/green fluorescence ratio in soma and neurites in 10 independent experiments is summarized in the bar graph in Fig. 5C. The values have been normalized for each neuron with regard to the value in the soma. On average, the mitochondria/ER ratio in the neurites was almost twice as large as in the soma (P < 0.001).

	Discussion

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Single-cell photon counting imaging of targeted aequorins reveals that mitochondria take up large amounts of Ca²⁺ during stimulation of mouse sympathetic neurons. Since mitochondrial aequorin is consumed when [Ca²⁺]_m increases, the history of the different mitochondrial pools that contribute to Ca²⁺ accumulation during repetitive stimulation could be traced (Montero et al. 2000; Villalobos et al. 2002). As in chromaffin cells (Montero et al. 2000), most of the Ca²⁺ uptake takes place in a subpopulation of mitochondria, probably the ones closest to the sites of Ca²⁺ entry or Ca²⁺ release. The applicable dimensions have been estimated between 0.2 and 2 µm in adrenal chromaffin cells (Villalobos et al. 2002). These mitochondria would sense Ca²⁺ microdomains in which high enough concentrations are achieved to activate the low-affinity mitochondrial Ca²⁺ uniporter for fast transport inside the mitochondrial matrix. The progression of the Ca²⁺ wave towards the cell core is effectively shielded by this mitochondrial pool in such a way that the other mitochondrial pool senses and takes up much smaller amounts of Ca²⁺ (Figs 1 and 3). These results agree with previous studies using X-ray microanalysis, in which stimulated and rapidly frozen frog sympathetic neurons contained two different subpopulations of mitochondria with different Ca²⁺ levels (Pivovarova et al. 1999). This black and white view is somewhat artificial. A continuum of mitochondria with different Ca²⁺ uptakes must exist, but the transition between both ends of the population must be extremely steep because the rate of mitochondrial Ca²⁺ uptake depends exponentially on [Ca²⁺]_c (Gunter & Pfeiffer, 1990; Rizzuto et al. 1993; Montero et al. 2000). This real bimodality is further exaggerated by aequorin, whose luminescence emission also depends exponentially on [Ca²⁺] (Alonso et al. 2006). Thus, the low-affinity aequorin system senses almost exclusively the high-Ca²⁺ mitochondrial pool, whereas the high-affinity aequorin system is quickly burned in this pool and, after a while, only detects the low-Ca²⁺ mitochondrial pool. In this way, by buffering the Ca²⁺ load, mitochondria can shape the cytosolic Ca²⁺ signal and exocytosis (Herrington et al. 1996; Montero et al. 2000; Friel, 2000; Villalobos et al. 2002; David & Barrett, 2003). Previous observations showing that mitochondrial depolarization, a manoeuvre that limits mitochondrial Ca²⁺ uptake, results in increased [Ca²⁺]_c spikes induced by electric stimulation in sympathetic neurons (Peng, 1998; Friel, 2000) are consistent with this view. The mitochondrial pool sensing Ca²⁺ entry through VOCCs overlapped with the one that accumulated Ca²⁺ after Ca²⁺ release through RyRs. These results suggest that, as in chromaffin cells (Montero et al. 2000), plasma membrane channels, ER release sites and mitochondria group spatially in triads or functional units that activate jointly, regardless of whether the Ca²⁺ originates extra- or intracellularly. Consistent with this view, local Ca²⁺ release events evoked by low caffeine concentrations have recently been reported to take place near the plasma membrane in the soma of superior cervical ganglion neurons (Yao et al. 2006).

It has been proposed that, in addition to Ca²⁺ fluxes through Ca²⁺ channels at the plasma membrane or the ER, other modulatory processes may contribute to generate Ca²⁺ signals with specific spatial location (Johenning et al. 2002). In dorsal root ganglion (DRG) neurons, mitochondria seem to buffer Ca²⁺ entering through plasmalemmal channels more efficiently than Ca²⁺ released from the ER (Svichar et al. 1997). We have investigated here whether redistribution of Ca²⁺ among different subcellular compartments is similar in the soma and neurites inside single sympathetic neurons. Our bioluminescence imaging approach enables photonic emissions from mitochondria in soma and neurites to be dissected. As in the soma, the behaviour in neurites was not homogeneous with regard to VOCCs, and we identified two different populations of mitochondria. One pool accumulated large amounts of Ca²⁺, whereas the other took up much smaller amounts. In contrast, the mitochondria in neurites differed from those in the soma in that they were not able to sense Ca²⁺ release induced by caffeine, as revealed by the high-Ca²⁺-affinity aequorin (Fig. 5B). This did not result from a lack of RyRs in neurites, since caffeine was able to increase [Ca²⁺]_c at this location (Fig. 5A), and previous reports have also demonstrated the presence of functional RyRs in the presynaptic terminals of sympathetic neurons (Peng, 1996). In contrast, ER-directed GFP was also expressed in neurites (Fig. 5C). Thus, even though mitochondria are more abundant in neurites than in the soma (Fig. 5C), mitochondria in neurites are more loosely coupled to ER and do not efficiently buffer the Ca²⁺ released through RyRs. This may explain why the [Ca²⁺]_c signal induced by caffeine is larger in the neurites than in the soma (Fig. 5A). Interestingly, other authors have also reported that Ca²⁺ signals may be larger in neurites than in the soma in a variety of cell models (Svichar et al. 1997; Koizumi et al. 1999; Johenning et al. 2002; Yao et al. 2006). For example, interference of mitochondrial Ca²⁺ uptake with carbonyl cyanide m-chlorophenylhyrazone (CCCP) modulated [Ca²⁺]_c transients induced by Ca²⁺ entry through VOCC channels, but not those resulting from caffeine-induced release of Ca²⁺ from ER in DRG neurons (Svichar et al. 1997). In addition, the somatic Ca²⁺ response to carbachol in differentiated PC12 cells displayed a much shallower slope and smaller amplitude than the response obtained in the neurites (Johenning et al. 2002). These differences were not attributable to differences in the Ca²⁺ contents of the ER in the neurites and soma, and the authors suggested that additional, unrecognized modulatory processes are necessary to generate spatially specific calcium signals. Global Ca²⁺ signals in neurons are made of elementary signals, which have been studied in great detail in both differentiated PC12 cells (Koizumi et al. 1999) and superior cervical ganglion neurons (Yao et al. 2006). In fact, the so-called elementary events (Ca²⁺ sparks and glows) were reported to be larger and more frequent in the neurites than in the soma of these neurons (Yao et al. 2006). The larger responses of these neurites could be at least partly explained by the smaller Ca²⁺-buffering capacity of the mitochondria in the neurites. Our data are consistent with previous suggestions (Svichar et al. 1997) attributing the smaller buffering capacity to peculiar localization of mitochondria, far away from the ER release sites, rather than to functional differences in Ca²⁺ handling by the mitochondrial uniporter. Calcium-induced Ca²⁺ release is believed to play an important role in the action potential-evoked release of neurotransmitter in postganglionic sympathetic nerve terminals (Smith & Cunnane, 1996) and presynaptic neuromuscular terminals (Narita et al. 2000). We can speculate that the lack of mitochondria close enough to ER could result in local higher [Ca²⁺]_c increases at the synaptic sites. Thus, strategic location of mitochondria may shape cytosolic Ca²⁺ signals differentially in soma and neurites.

	References

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	Acknowledgements

 
This work was supported by grants from Junta de Castilla y León (VA071/02; VA022A05), Ministerio de Educación y Ciencia (MEC; BFU2004-02764), Fondo de Investigaciones Sanitarias FIS 04/1510 and Ministerio de Sanidad, Instituto de Salud Carlos III, Red de Terapia Celular. L.N. is fellow of the Ramón y Cajal Program (MEC and FEDER-FSE). L.S. is the recipient of a predoctoral fellowship from MEC. Pablo Chamero held a predoctoral fellowship from the Basque Government.

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