Abstract
We recently showed that inhibition of neuronal activity, glutamate uptake, or reversed-Na+/Ca2+-exchange with TTX, TFB-TBOA, or YM-244769, respectively, increases mitochondrial mobility in astrocytic processes. In the present study, we examined the interrelationships between mitochondrial mobility and Ca2+ signaling in astrocyte processes in organotypic cultures of rat hippocampus. All of the treatments that increase mitochondrial mobility decreased basal Ca2+. As recently reported, we observed spontaneous Ca2+ spikes with half-lives of ∼1 s that spread ∼6 μm and are almost abolished by a TRPA1 channel antagonist. Virtually all of these Ca2+ spikes overlap mitochondria (98%), and 62% of mitochondria are overlapped by these spikes. Although tetrodotoxin, TFB-TBOA, or YM-244769 increased Ca2+ signaling, the specific effects on peak, decay time, and/or frequency were different. To more specifically manipulate mitochondrial mobility, we explored the effects of Miro motor adaptor proteins. We show that Miro1 and Miro2 are both expressed in astrocytes and that exogenous expression of Ca2+-insensitive Miro mutants (KK) nearly doubles the percentage of mobile mitochondria. Expression of Miro1KK had a modest effect on the frequency of these Ca2+ spikes but nearly doubled the decay half-life. The mitochondrial proton ionophore, FCCP, caused a large, prolonged increase in cytosolic Ca2+ followed by an increase in the decay time and the spread of the spontaneous Ca2+ spikes. Photo-ablation of mitochondria in individual astrocyte processes has similar effects on Ca2+. Together, these studies show that Ca2+ regulates mitochondrial mobility, and mitochondria in turn regulate Ca2+ signals in astrocyte processes.
SIGNIFICANCE STATEMENT In neurons, the movement and positioning of mitochondria at sites of elevated activity are important for matching local energy and Ca2+ buffering capacity. Previously, we demonstrated that mitochondria are immobilized in astrocytes in response to neuronal activity and glutamate uptake. Here, we demonstrate a mechanism by which mitochondria are immobilized in astrocytes subsequent to increases in intracellular [Ca2+] and provide evidence that mitochondria contribute to the compartmentalization of spontaneous Ca2+ signals in astrocyte processes. Immobilization of mitochondria at sites of glutamate uptake in astrocyte processes provides a mechanism to coordinate increases in activity with increases in mitochondrial metabolism.
Introduction
In the CNS, mitochondria accumulate at sites of elevated activity or metabolic demand, including presynaptic and postsynaptic compartments, growth cones, nodes of Ranvier, and near clusters of glutamate transporters (GLT-1) in the astrocyte processes that appose synapses (Li et al., 2004; Ohno et al., 2011; Schwarz, 2013; Jackson et al., 2014). Recently, we found that mitochondria are present in the processes of astrocytes and that their mobility is inhibited by neuronal activity, glutamate uptake, and reversed Na+/Ca2+-exchange (Genda et al., 2011; Jackson et al., 2014). Further, we demonstrated that neuronal activity increased the probability that mitochondria approach clusters of the glial glutamate transporter GLT-1 within astrocyte processes that appose VGLUT1 puncta, suggesting that regulation of mitochondrial mobility may represent a mechanism to retain mitochondria near sites of glutamate uptake in astrocytes. Here we sought to uncover molecular mechanisms regulating the immobilization of mitochondria and the consequences of inhibiting their regulated distribution.
In neurons, mitochondria accumulate at sites of elevated activity in part via the actions of the Miro (RhoT) proteins. There are two Miro isoforms (Miro1 and Miro2) that share ∼60% identity (Fransson et al., 2003). These Ca2+-sensitive adaptor proteins link the mitochondria to the motor protein kinesin-1 through Trak1/2 (Milton) proteins (Stowers et al., 2002; Glater et al., 2006; Brickley and Stephenson, 2011). Elevations of [Ca2+]i result in a Miro-mediated disengagement of the mitochondria from the motor apparatus through mechanisms that are incompletely understood (Macaskill et al., 2009; Wang and Schwarz, 2009). Little is known about the mechanisms regulating mitochondrial movement and distribution in astrocyte processes (Stephen et al., 2014; Benjamin Kacerovsky and Murai, 2015).
Although astrocytes are not electrically excitable, they are heavily integrated into the neuronal circuitry in which they reside (for review, see Barres, 2008; Halassa and Haydon, 2010). They possess numerous processes and a large complement of receptors that allow them to sense and respond to extracellular stimuli. The activation of many of these receptors is coupled to increases in intracellular [Ca2+], either through flux across the plasma membrane (ionotropic receptors, reversed Na+/Ca2+ exchange) or via release from intracellular stores (metabotropic receptors, etc.) (for review, see Volterra et al., 2014; Rusakov, 2015). The diversity of these signals (localization, amplitude, kinetics, and frequency) allows a common signal to potentially couple to distinct cellular activities. Indeed, elevations of astrocyte [Ca2+]i have been implicated in diverse physiologic functions, including regulation of local blood flow (Petzold et al., 2008; Schummers et al., 2008; Petzold and Murthy, 2011; Otsu et al., 2015), release of transmitter (Nedergaard, 1994; Parpura et al., 1994; Marchaland et al., 2008; Navarrete et al., 2013), and synaptic plasticity (Di Castro et al., 2011; Min and Nevian, 2012). Understanding how these local Ca2+ signals are generated, compartmentalized, and the consequences of these signals is crucial to understanding the physiologic function of astrocytes.
Mitochondria play complex, interdigitated roles in cellular physiology. In addition to providing the ATP necessary to maintain ionic gradients (via the tricarboxylic acid [TCA] cycle and oxidative phosphorylation), mitochondria can also buffer cytosolic Ca2+ (Rizzuto et al., 2012; for review, see Williams et al., 2013b). The ability of mitochondria to accumulate Ca2+ is dependent upon the large electrochemical potential of the mitochondria (Kirichok et al., 2004). Accumulated Ca2+ is released back into the cytosol via mitochondrial Na+/Ca2+ exchangers (Baron and Thayer, 1997). Ca2+ uptake stimulates TCA cycle flux (Wan et al., 1989) via stimulation of the Ca2+-sensitive dehydrogenases (Denton et al., 1972). Indeed, constitutive IP3 receptor-mediated transfer of Ca2+ from the endoplasmic reticulum to mitochondria is essential for optimal mitochondrial performance (Cárdenas et al., 2010).
Here, we examine a role for Ca2+ signaling in regulating the immobilization of mitochondria within the processes of astrocytes. We examine mechanisms that mediate increases in [Ca2+]i and potential roles for Miro proteins in mediating the Ca2+-dependent arrest of mitochondria within these processes. Last, we explore how modulating mitochondrial Ca2+ buffering or positioning influences Ca2+ signaling within the astrocytes.
Materials and Methods
cDNA contructs.
pRK5-myc-Miro1 (Addgene plasmid #47888), pRK5-myc-Miro1 E208K/E328K (Miro1KK; Addgene plasmid #47894), pRK5-myc-Miro2 (Addgene plasmid #47891), and pRK5-myc-Miro2 E208K/E328K (Miro2KK; Addgene plasmid #47900) (Fransson et al., 2003; Fransson et al., 2006) were generated by Pontus Aspenström (Karolinska Institute, Stockholm, Sweden). EGFP-Miro1, EGFP-Miro2, EGFP-Miro1KK (EGFP-Miro1E208K/E328K) and EGFP-Miro2KK (EGFP-Miro2E208K/E328K) are all N-terminal fusions with EGFP and were constructed using PCR amplification from their myc-Miro cognates. pGP-CMV-GCaMP6s was a gift from Douglas Kim (Addgene plasmid #40753) (Chen et al., 2013). pN1 LCK-GCaMP5G was a gift from Baljit Khakh (Addgene plasmid #34924) (Akerboom et al., 2012). LCK-GCaMP6s was generated by transferring the LCK-derived membrane-tethering domain from LCK-GCaMP5G in-frame with GCaMP6s. pDsRed2-mito was purchased from Clontech (catalog #632421). pGFAABC1D:DsRed2mito was generated by replacing the CMV promoter of pDsRed2-mito with the minimal GFAP promoter (GFAABC1D) from pTY-GFAABC1D-gp43mcherry. pTY-GFAABC1D:mCherry has been described previously (Jackson et al., 2014). pEGFP-mito (a gift from Dr. Stanley Thayer-University of Minnesota, Minneapolis) is a fusion of EGFP with the mitochondrial matrix targeting sequence from CoxVIII and has been shown to result in specific targeting of EGFP into mitochondria (Rizzuto et al., 1992; Wang et al., 2003).
Antibodies.
Rabbit anti-Miro1 antibody was purchased from Sigma-Aldrich (Atlas; catalog #PA010687). Rabbit anti-Miro1 (for immunoblot) was purchased from Novus Biologicals. Mouse anti-Miro2 (catalog #75-365, RRID:AB_2315894) was purchased from Neuromab. Highly cross-adsorbed secondary antibodies conjugated to AlexaFluor dyes were purchased from Invitrogen. TTX was purchased from Alomone Labs. FCCP (carbonyl cyanide 4-(trifluoromethoxy)phenylhydrazone)), A967079, (3S)-3-[[3-[[4-(trifluoromethyl)benzoyl]amino]phenyl]methoxy]-l-aspartic acid (TFB-TBOA), N-[(3-aminophenyl) methyl]-6-[4-[(3-fluorophenyl) methoxy] phenoxy]-3-pyridine carboxamide dihydrochloride (YM-244769) were purchased from Tocris Bioscience. All other reagents were purchased from VWR.
Slice culture and transfections.
All procedures involving animals were conducted with the approval of the Institutional Animal Care and Use Committee at the Children's Hospital of Philadelphia. Organotypic hippocampal cultures were prepared as described previously (Benediktsson et al., 2005 Jackson et al., 2014). Briefly, postnatal rat pups (p8-p12) of either sex were decapitated and their brains rapidly removed into ice-cold (4°C) sucrose-aCSF composed of the following (in mm): 280 sucrose, 5 KCl, 2 MgCl2, 1 CaCl2, 20 glucose, and 10 HEPES. Hippocampi were isolated and sliced into 300 μm sections using a McIlwain-type tissue chopper (Brinkman Instruments). Three or four slices were placed onto each 0.4 μm Millicell tissue culture insert (PICMORG50; Millipore) in six-well plates, 1 ml of medium containing the following: 50% Neurobasal medium, 25% horse serum, 25% HBSS, supplemented with 10 mm HEPES, 36 mm glucose, 2 mm glutamine, 1× Gem21-Neuroplex supplement, 10 U/ml penicillin, and 100 μg/ml streptomycin, pH 7.2–7.3, placed underneath each insert. One-third of the media was changed every 2 d. Slices were maintained in a humidified incubator with 5% CO2/95% air at 37°C. Slices were allowed to recover for 2 d before transfection via a Helios Gene-Gun (Bio-Rad) (McAllister, 2004; Benediktsson et al., 2005). Gene gun bullets were generated as follows: cDNAs (10 μg total) were combined with 8–10 mg of 1.0 μm gold particles (Bio-Rad) in a solution containing 0.05 m spermidine, and 1 m CaCl2 in 0.02 mg/ml polyvinylpyrrolidone 20. This suspension was used to coat Teflon tubing (Tefzel; Bio-Rad) that was subsequently cut and loaded into the Gene-Gun. The cDNA-coated gold particles were shot using high-pressure helium (120–140 psi) into cultured slices in inserts sitting on warmed agarose slabs. Although the smaller gold particles improve selectivity for transducing astrocytes (Benediktsson et al., 2005), we also always included at least one construct in which a GFAP promoter is used to control expression (see below). These cells are always astrocytes as defined by expression of glutamine synthetase or GFAP (Jackson et al., 2014).
Astrocyte cultures.
Primary cultures of astrocytes were prepared as previously described (Garlin et al., 1995). Briefly, neonatal (P0-P3) rat pups of either sex were decapitated and their brains placed into ice-cold HEPES-buffered Hanks solution. Cortices were isolated and meninges removed. Cortices were minced into smaller pieces and treated with trypsin for 20 min at 37°C in 5% CO2/95% air. Trypsinization was terminated by washing in HBSS. Tissue was triturated in warm media (10% heat-inactivated FBS, 10% Ham's F-12 medium, and 80% DMEM with 0.24% penicillin/streptomycin) through a series of subsequently smaller pipets. Dissociated tissue was plated into T75 flasks (BD Falcon). Once cells reached confluence (∼7 d), A2B5-positive cells were removed by incubating with anti-A2B5 antibody and rabbit complement for 45 min. Cultures were then replated onto 6 cm dishes (BD Falcon) and harvested 5 d later.
Immunoblotting.
Cortical tissue was harvested from adult male Sprague-Daley rats after death by decapitation to avoid effects of anesthetic agents. Tissue was homogenized in RIPA buffer (150 mm NaCl, 1 mm EDTA, 100 mm Tris-HCl, 1% Triton X-100, and 1% sodium deoxycholate, pH 7.4) plus protease and phosphatase inhibitors (1 μg/ml leupeptin, 260 μm PMSF, 1 μg/ml aprotonin, 1 mm iodoacetamide, 10 mm NaF, and 1 mm sodium orthovanadate; 18.5 ml/g wet weight). Homogenates were rotated on a shaker for 1 h at 4°C and then cleared by centrifugation at 13,000 × g for 30 min at 4°C. Protein concentration was analyzed (bicinchorinic acid protein assay kit, Thermo Scientific). For analysis of proteins present in primary cultures of rat astrocytes, cultures were lysed in RIPA (as above). Proteins (including rainbow molecular weight marker; GE Healthcare) were resolved using 8% SDS-polyacrylamide gels, transferred to PVDF membranes (PVDF-FL; Millipore), and blocked for 1 h at 25°C in TBS-T (50 mm Tris, pH 8.0, 150 mm NaCl, 0.2% Tween 20) containing 5% nonfat dry milk (Carnation; Nestle). Membranes were then probed with rabbit anti-Miro1 (1:2000) and mouse anti-Miro2 (1:100). Membranes were washed 3× in TBS-T containing 1% nonfat dry milk. Membranes were probed with fluorescent dye-conjugated secondary antibodies (goat anti-Rb 688 or goat anti-mouse 800; 1:10,000; LI-COR Biosciences). Protein bands were visualized using an Odyssey infrared imager (LI-COR Biosciences).
Immunohistochemistry.
Immunohistochemical analyses of organotypic cultures of rat hippocampus were conducted as previously described (Jackson et al., 2014). Slices were transfected with pTY-GFAABC1D:mCherry and EGFP-mito. Two days after transfection, tissues were fixed by immersion in 4% PFA in PBS (0.1 m). Tissue was processed as free-floating sections for subsequent immunostaining. Sections were extracted for 1 h in a solution of PBS and 1% Triton X-100 at room temperature. Sections were blocked in 5% goat serum for 1 h at room temperature and incubated with primary antibodies against Miro1 (1:100; Sigma-Aldrich) or Miro2 (1:100; Neuromab) for 2 d at 4°C in a solution containing 1% Triton X-100 and 5% goat serum. The sections were rinsed three times for 15 min each in PBS and subsequently incubated overnight with secondary antibody (highly cross-adsorbed goat anti-rabbit or anti-mouse AlexaFluor-633; Invitrogen). Slices were rinsed three times for 15 min each in PBS before mounting on precoated slides (Superfrost Plus, Fisher Scientific) with aqueous mounting medium (Vectashield; Vector Laboratories). Sections were imaged on a laser confocal microscope (Olympus FV1000). To avoid potential bleed through of fluorophores, images were collected in sequential scan mode using the 488, 546, or 633 excitation lines to independently excite EGFP, mCherry, or AlexaFluor633, respectively.
Live slice imaging.
Two days after transfection, slices were excised from the membrane supports and placed face-down in a flow-through chamber (RC21; Warner Instruments). Slices were continuously superfused with oxygenated (95% O2/5% CO2) aCSF composed of the following (in mm): 130 NaCl, 3 KCl, 1.25 NaH2PO4, 26 NaHCO3, 10 glucose, 1 MgCl2, 2 CaCl2, and maintained at 34°C. Slices were imaged on an Olympus Fluoview 1000 Laser Scanning Confocal Microscope equipped with a 40× UPlanApo objective (NA = 1.3). Slices were allowed to equilibrate in the imaging chamber for 10 min before initiating recording. Cells expressing EGFP or mCherry were identified using epifluorescence and were imaged using the 488 and 546 laser lines, respectively. Previously, we showed that the minimal GFAP promoter (GFAABC1D) limits transduction to astrocytes (Jackson et al., 2014). To control for possible variability between different sets of cultures, all experiments included control and experimental slices from the same cultures and were imaged randomly interspersed throughout the same day. Slices were visually inspected to ensure that the slice was intact and that the hippocampus retained its laminar organization. Cells were visually selected based on their complex morphology, and lack of a reactive phenotype (nonhypertrophic). Cells at the surface of the slice or at the slice margins were excluded. For all cells, image stacks (15–25 optical sections; 1 μm z-spacing) were acquired to aid in retrospective identification. A subfield of these astrocytes was identified and imaged at 512 × 512 pixels with an additional 4–5× digital zoom. For imaging mitochondrial movement, image stacks (3–10 optical sections; 1 μm z-spacing) were collected every 6–10 s for 15 min from a field containing 5–20 astrocyte processes and at least 10 mitochondria. For GCaMP imaging, a single optical section was imaged at a frequency of 1 Hz. Care was taken to choose processes or groups of processes that existed in a single optical section. Pharmacological agents were administered via superfusion using a solution changer (VC-6; Warner Instruments).
Image analysis.
All data analyses were performed blinded to transfection or treatment conditions. All data analyses were conducted using the FIJI implementation of the NIH ImageJ program (http://rsb.info.nih.gov/ij/) (Schneider et al., 2012). All images were background corrected. Motion artifacts due to slice drift were corrected using the MultistackReg plugin of FIJI to implement rigid registration, aligning all images in a time-lapse series to the original image. As GCaMP5G and GCaMP6S have low fluorescence at basal [Ca2+]i, image series from the simultaneously acquired mCherry fluorescence were first aligned and this alignment file used to align the GCaMP image series.
To track the mobility of individual mitochondria, image stacks (3–5 image planes; 1 μm spacing) were compressed into a single plane (maximal z-compression). Individual mitochondria were tracked using the MTrackJ plugin to ImageJ (Meijering et al., 2012). A mitochondrion was considered mobile if its displacement exceeded 2 μm during the 15 min imaging epoch. Kymographs (displacement vs time) were constructed from individual astrocyte processes for display purposes and are displayed such that time is on the y-axis. Mitochondria that are not mobile appear as vertical lines, whereas mobile mitochondria appear as diagonal lines across the kymograph.
To analyze GCaMP fluorescence, kymographs were constructed by tracing each process, guided by the mCherrry fluorescence images. Ca2+ signaling events were selected based on a threshold of 3× the SD of the mean, similar to what has been used to isolate Ca2+ sparks from cardiac myocytes (Cheng et al., 1999), and exported as text files for further analysis. Examples of these kymographs are presented in Figure 2B, C and are oriented with time progressing toward the right.
Statistics and data analysis.
All data are representative of at least three independent sets of experiments (separate sets of slices prepared on separate days). Analysis was conducted blinded to treatment. Time constants (tau) were calculated using ClampFit9 (Molecular Devices). The decay phase of the Ca2+ transient was consistent with a first-order exponential decay process (R2 > 0.7). The results of fits where R2 was <0.7 were discarded. Ca2+ traces were produced using Microcal Origin (OriginLab). Normality of data distribution was assessed using the D'Agostino and Pearson omnibus normality test. Normally distributed data were assessed using Student's t test or ANOVA with Bonferroni's multiple comparisons, as appropriate. Non-normally distributed data were assessed via Mann–Whitney test or Friedman's test with multiple comparisons as appropriate and are expressed as median with interquartile range (IQR). Statistical significance between cumulative probability distributions was assessed using the Kolmogorov–Smirnov test. Statistical significance of linear regressions was assessed using Pearson's coefficient of variance. All statistical analyses were conducted using Graphpad Prism software.
Results
We recently showed that inhibition of neuronal activity (TTX), glutamate uptake (TFB-TBOA), or reversed Na+/Ca2+-exchange (KB-7943 or YM-244769) increases the percentage of mobile mitochondria in astrocyte processes. Inhibition of neuronal activity with TTX decreases the probability that mitochondria appose glutamate transporters in astrocytes without changing the proximity of glutamate transporters (GLT-1) to synapses (VGLUT1) (Jackson et al., 2014). Ugbode et al. (2014) also recently showed that neurons/neuronal activity increase colocalization of mitochondria with GLT1 in astrocyte-neuron cocultures. In neurons and other systems (Saotome et al., 2008; Macaskill et al., 2009), the arrest of mitochondria at domains of elevated activity proceeds, in part, through elevations of intracellular calcium ([Ca2+]i). Based on these sets of observations, we decided to explore a role for Ca2+ signaling in regulating the arrest of mitochondria in astrocyte processes.
Treatments that increase mitochondrial mobility decrease basal [Ca2+]i
We used organotypic hippocampal cultures derived from P8-P12 rats to examine Ca2+ signaling in the processes of individual astrocytes. In contrast to primary cultures of astrocytes, astrocytes in organotypic culture maintain their fine architecture and express a complement of proteins more representative of that found in vivo (Benediktsson et al., 2005; Genda et al., 2011; Jackson et al., 2014). We predicted that treatments that increase mitochondrial mobility would decrease basal [Ca2+]i. To examine changes in basal [Ca2+]i, astrocytes were transduced with the genetic Ca2+ indicator, GCaMP6S. This indicator was chosen because of its relatively higher affinity (lower Kd) for Ca2+ (144 nm) (Chen et al., 2013), which is closer to astrocytic basal [Ca2+]i (50–250 nm) (Fatatis and Russell, 1992; Reyes et al., 2012), and therefore is more sensitive to changes in this range. As others have done, we fused GCaMP6s to the membrane-tethering domain of the lymphocyte-specific protein tyrosine kinase (LCK) to allow movement of the indicator out into the small processes of the astrocyte (Benediktsson et al., 2005; Shigetomi et al., 2010b). Astrocytes were cotransfected with a membrane-targeted mCherry driven by a minimal GFAP promoter to visualize the astrocyte processes and to aid in image registration. Individual nonreactive astrocytes were identified, and subfields containing 7–15 processes were imaged for 15 min. Blockade of neuronal activity with TTX (Fig. 1A), glutamate uptake with TFB-TBOA (Fig. 1B), or reversed Na+/Ca2+-exchange with YM-244769 (Fig. 1C) all decreased basal [Ca2+]i. These effects were relatively rapid, occurring within ∼60 s (Fig. 1A–C). The decrease in [Ca2+] observed with TFB-TBOA only partially recovered following washout, consistent with the high affinity and slow washout observed when this inhibitor was first described (Shimamoto et al., 2004). Increasing neuronal activity with 4-aminopyridine (4-AP; 100 μm) increased basal [Ca2+] (Fig. 1D). The simplest explanation of these and our recently published data (Jackson et al., 2014) is that neuronal activity followed by astrocytic glutamate uptake and subsequent reversed operation of the Na+/Ca2+-exchanger results in increased Ca2+ in astrocytic processes. A similar effect of glutamate uptake on intracellular [Ca2+] has been observed in astrocyte cultures (Reyes et al., 2012; Magi et al., 2013). Because of variability in the latency to peak and duration of the [Ca2+] increase observed with 4-AP (Fig. 1D), we were not able to test whether this increase was reversed by application of TFB-TBOA or YM-244769.
Properties of spontaneous Ca2+ signals in astrocyte processes
Astrocytes exhibit increases in [Ca2+] both spontaneously and in response to evoked stimuli (synaptic activation, glutamate, etc) (Cornell-Bell et al., 1990; Fatatis and Russell, 1992; Nett et al., 2002). These events have been characterized in the soma and primary processes of astrocytes in cultures, in acute and cultured brain slices, and in vivo (Bernardinelli et al., 2011; Pérez-Alvarez et al., 2013). Newer methodologies using targeted genetic Ca2+ sensors (GCaMPs) have revealed more localized Ca2+ signals within the smaller secondary and tertiary astrocyte processes (Shigetomi et al., 2010b, 2012, 2013a). These local events have not been characterized in organotypic cultures. Therefore, we first examined the properties of spontaneous [Ca2+]i spikes using the genetic Ca2+ indicator LCK-GCaMP5G. This indicator was chosen both for its lower affinity (Kd = 440 nm) and its relatively faster Koff (2.52 s−1) relative to GCaMP6s (Kd = 144 nm; Koff = 1.12 s−1) (Chen et al., 2013). Individual processes were traced using mCherry fluorescence (Fig. 2A, magenta and green lines), and kymographs were constructed to identify Ca2+ signals within individual processes (Fig. 2B,C). As observed in other systems (Shigetomi et al., 2010a, 2012), astrocytes exhibit small (Fig. 2D; median peak ΔF/F0 = 1.2, IQR: 0.8, 2.0), brief (Fig. 2F; median tau = 1.3 s, IQR: 0.7, 2.0), or a t1/2 of ∼0.8 s increases in [Ca2+] that are spatially discrete (Fig. 2E; median distance propagated = 5.7 μm, IQR: 3.8, 11.3; n = 15 cells, 111 processes, 742 events). These [Ca2+]i transients appear in 36% of processes and are not coordinated between processes (Fig. 2B,C; n = 251 processes, 23 cells). In the 36% of processes that exhibited Ca2+ transients, oscillations appeared with a mean frequency of 0.18 ± 0.03 spikes/min/process (mean ± SEM of 90 processes), indicating a high degree of variability even between processes. As has been previously observed in other systems (Shigetomi et al., 2010b), application of the TRPA1 antagonist (A967079; 3 μm) decreased both the frequency (to 12 ± 4% of control, p < 0.0001) and amplitude (to 45 ± 7% of control; p < 0.0001, n = 16 processes; 3 cells) of these transients (Fig. 2G). As this is a concentration that would be expected to inhibit 90% of TRPA1 channel activity (IC50 = 289 nm) (Chen et al., 2011), this suggests the presence of other processes coupled to increases in [Ca2+]i and is consistent with observations of Ca2+ signaling in both acute slice and primary cultures of astrocytes (Shigetomi et al., 2010b; Haustein et al., 2014; for review, see Rusakov et al., 2014).
From these analyses, it also became apparent that these Ca2+ spikes frequently occur in the same spatially restricted location within a process (Fig. 2B,C). We hypothesized that mitochondria might accumulate at these sites. To test this, we transfected astrocytes with plasmids encoding LCK-GCaMP5G and the mitochondrially targeted DsRed2 driven by the minimal GFAP promoter (pGFAABC1D:DsRed2-mito). As was observed in analyses presented in Figure 2, time-lapse microscopy reveals domains of repeated Ca2+ signaling (Fig. 3B) that overlap with mitochondria (Fig. 3A,C). Indeed, 98.3 ± 3% of Ca2+ transients overlapped at least 1 mitochondria, whereas 62 ± 6% of mitochondria encountered a Ca2+ transient during a 10 min imaging window (n = 9 cells; 32 processes). To further examine the relationship of mitochondria to these Ca2+ spikes, we measured the length of each process and the sum of the lengths of mitochondria in each process. These data were expressed as the percentage of the process occupied by mitochondria (% Mito occupancy). We found that the frequency (Fig. 3D) and the lateral spread of individual transients (Fig. 3E) is inversely proportional to the percentage of the process occupied by mitochondria. Given the known relationship of mitochondrial recruitment to sites of high Ca2+, it seems likely that mitochondria are being recruited to locations with high TRPA1 channel activity, but one cannot rule out the possibility that TRPA1 channels are selectively trafficked to processes with more mitochondria.
Effect of agents that increase mitochondrial mobility on spontaneous Ca2+ signals in astrocyte processes
Mitochondria accumulate at sites of elevated Ca2+ in neurons and other cells (Li et al., 2004; Macaskill et al., 2009; Wang and Schwarz, 2009). The proper positioning of mitochondria at these domains controls Ca2+ signaling (Csordás et al., 1999; Wang et al., 2003; for review, see Rizzuto et al., 2012). Although TTX, TFB-TBOA, and YM-244769 decrease basal [Ca2+]i, they also increase the percentage of mitochondria that are mobile (Jackson et al., 2014). We hypothesized that the increased movement of mitochondria by these agents might increase Ca2+ signaling in astrocytic processes. Astrocytes were transfected with LCK-GCaMP5G and membrane-targeted mCherry. Images were collected for 10 min before superfusion of pharmacological agents (vehicle/aCSF, TTX, TFB-TBOA, YM-244769) to measure baseline Ca2+ signaling and then for an additional 15 min. The properties of the Ca2+ signals measured in the final 10 min of drug treatment were compared with baseline. As was previously observed (Dwight Bergles, personal communication), the frequency of these Ca2+ spikes increases with time even in slices continuously perfused with aCSF (vehicle) from 0.28 ± 0.05 to 0.49 ± 0.07 spikes/min/process (n = 97 processes; p < 0.0001, paired Student's t test). Superfusion with aCSF was not accompanied by a change in the peak amplitude, rate of decay (tau), or spread of the Ca2+ signal (11 cells; 83 processes, 743 events; data not shown). TTX (1 μm; Fig. 4A) prolonged the half-life (tau, p < 0.001, Kolmorogov–Smirnov test) but did not alter amplitude or the spatial spread of these signals. Although there was an increase in the frequency of oscillations, it was not significantly different from that observed with vehicle (p = 0.4, n = 74, Kruskal–Wallis test with Dunn's multiple comparisons test). TFB-TBOA (3 μm) increased the amplitude (ΔF/F0) of the Ca2+ transients (from 1.0 ± 0.1 to 1.5 ± 0.1, p < 0.0001, Kolmorogov–Smirnov test) without affecting half-life or spatial spread. TFB-TBOA increased the frequency of these Ca2+ spikes twofold relative to that observed in vehicle-treated slices (p < 0.0001, p = 34 processes, Kruskal–Wallis test with Dunn's multiple comparisons test). Inhibition of reversed Na+/Ca2+-exchange with YM-244769 (1 μm) had a nearly significant effect on amplitude (from 1.1 ± 0.1 to 1.6 ± 0.1, p = 0.07), but did not alter tau, or spatial spread. The effect of YM-244769 on frequency was not different from that observed with vehicle (p = 0.6, n = 49 processes, Kruskal–Wallis test with Dunn's multiple comparison's test). Together, these data are consistent with the notion that increasing mitochondrial mobility with pharmacologic inhibitors increases Ca2+ signaling, but these agents do not only change mitochondrial mobility. For example, inhibition of glutamate transporters can increase ambient glutamate (Isaacson and Nicoll, 1993; Jabaudon et al., 1999) with consequent activation of glutamate receptors (Huang et al., 2004; Haustein et al., 2014). The increased frequency and amplitude of Ca2+ transients in the presence of TFB-TBOA are consistent with this (Fig. 4B). Interestingly, previous experiments failed to show an effect of either activating or inhibiting mGluR5 on the percentage of mobile mitochondria (Jackson et al., 2014). Prolonged exposure to elevated glutamate, however, may result in desensitization of neuronal glutamate receptors (Trussell et al., 1988). Therefore, it is important to use other strategies that directly affect mitochondrial positioning or function.
Miro 1 and Miro2 colocalize with and regulate mobility of astrocytic mitochondria
In our previous study, we showed that disruption of microtubule assembly with vinblastine or disruption of actin assembly with cytochalasin D reduced mitochondrial mobility in astrocytic processes, implying a role for motor proteins in their movement (Jackson et al., 2014). Miro1 and Miro2 localize to mitochondria and mediate both the movement of mitochondria and their Ca2+-sensitive immobilization by a mechanism that is still controversial but somehow involves disengagement of mitochondria from the cytoskeleton (Fransson et al., 2003, 2006; Saotome et al., 2008; Macaskill et al., 2009; Wang and Schwarz, 2009).
Given that the Miro proteins mediate the arrest and accumulation of mitochondria at sites of high activity in neurons, we asked whether either of the Miro isoforms were present within astrocytes and whether they regulate mitochondrial mobility in astrocytes. mRNA for both Miro1 and Miro2 is present in astrocytes. Indeed, expression arrays and RNAseq data suggest that both Miro1 and Miro2 are as abundant or slightly enriched in astrocytes relative to neurons (Cahoy et al., 2008; Zhang et al., 2014). To assess the presence and distribution of Miro protein in astrocytes, we used both organotypic cultures of rat hippocampus and primary cultures of cortical astrocytes. Astrocytes in slice culture were transfected with a membrane-targeted mCherry driven by a minimal GFAP promoter (GFAABC1D; Fig. 5A,E) and an EGFP targeted to the mitochondrial matrix (EGFP-mito; Fig. 5C,G). Slices were subsequently fixed and immunostained with antibodies targeted against Miro1 (Fig. 5B) or Miro2 (Fig. 5F). Punctate Miro1 and Miro2 immunofluorescence colocalizes with EGFP-mito fluorescence within astrocyte processes, with several puncta evident per mitochondrion (Fig. 5D,H). This punctate pattern of expression has been described previously in yeast with the Miro homolog Gem1 (Kornmann et al., 2011). We also tested for expression of Miro1 and Miro2 in primary cultures of rat astrocytes and rat cortical tissue. Immunoblots revealed the presence of bands at the appropriate (∼70 kDa) size (Fig. 5I and Fig. 5J, respectively). However, we note the presence of additional bands at ∼100 kDa (particularly prominent with Miro2; Fig. 5J). Ubiquitinated Miro appears as an ∼100 kDa protein via immunoblot (Birsa et al., 2014), suggesting ubiquitination of Miro (particularly Miro2) protein in primary cultures of astrocytes.
We transfected astrocytes with plasmids encoding EGFP-mito, EGFP-Miro1, EGFP-Miro2, or Ca2+-insensitive mutants of Miro1 or Miro2 (termed MiroKK) in which the Ca2+-coordinating EF-hand motifs are mutated (E208K/E328K) (Fransson et al., 2006). Astrocytes were cotransfected with membrane-targeted mCherry driven by a minimal GFAP promoter (GFAABC1D) to aid in the identification of astrocytes. Discrete, EGFP-expressing mitochondria were readily identifiable within the astrocyte processes (Fig. 6A–E). Mitochondrial movement was followed over a 15 min period using confocal microscopy in fields containing at least 3–5 astrocyte processes and at least 10 mitochondria. The percentage of mobile mitochondria (defined as >2 μm movement in 15 min), the total distance mobile mitochondria move in 15 min, the maximum instantaneous velocity, and average mitochondrial length were examined. As we have previously observed, the majority of mitochondria were stationary (20.9 ± 3.2% mobile) under control conditions (EGFP-mito transfected). Consistent with the pattern of endogenous Miro expression presented in Figure 5, EGFP-Miro1 or EGFP-Miro2 expression colocalized with DsRed2-mito expression in the astrocyte processes (data not shown) and appeared as discrete vermiform structures consistent with a mitochondrial localization. Exogenous expression of EGFP-Miro1 had no significant effect on the percentage of mobile mitochondria on any of the parameters measured (Fig. 6F–I). In contrast, exogenous expression of EGFP-Miro2 doubled the percentage of mobile mitochondria (Fig. 6D,F), suggesting that endogenous Miro protein expression might limit mitochondrial mobility. Expression of Ca2+-insensitive mutants of either Miro1 (Fig. 6C,F; EGFP-Miro1KK) or Miro2 (Fig. 6E,F; EGFP-Miro2KK) approximately doubled the percentage of mobile mitochondria relative to control. EGFP-Miro1KK and EGFP-Miro2KK had small but significant effects on some of the other measures, but the biological relevance of these effects would be difficult to determine given the small effect sizes (Fig. 6F–I). The effects on mitochondrial length are consistent with previous publications (Frederick et al., 2004; Fransson et al., 2006; Glater et al., 2006; Saotome et al., 2008).
Given that the exogenous expression of EGFP-Miro1KK increases the percentage of mobile mitochondria within astrocytic processes, this provides a tool to more specifically disrupt mitochondrial positioning within astrocytes. We hypothesized that the Ca2+-dependent and Miro-dependent positioning of mitochondria might influence the properties of the Ca2+ spikes observed in astrocytic processes. Astrocytes in slice culture were transfected with LCK-GCaMP5G, membrane-targeted mCherry, and either Miro1KK-myc or myc vector (control). We monitored Ca2+ signaling events within subfields containing multiple processes from these astrocytes for a period of 15 min. Expression of Miro1KK increased the frequency of the Ca2+ spikes by ∼25% and nearly doubled the time constant (Fig. 7A,D). There was no effect on amplitude (Fig. 7B) or spatial spread (Fig. 7C). These results suggest that the Ca2+-sensitive positioning of mitochondria (via Miro proteins) at domains of elevated Ca2+ is important for controlling the rate of recovery of the Ca2+ transients and the frequency of Ca2+ signals in the astrocyte processes.
Depolarization of mitochondria alters the kinetics of [Ca2+]i transients within the astrocyte
Mitochondria accumulate Ca2+ using the proton electrochemical gradient established during electron transport (Vasington and Murphy, 1962; Rizzuto et al., 1992; Kirichok et al., 2004). Therefore, we examined the effect of collapsing this gradient using the proton ionophore, FCCP (Reyes and Parpura, 2008). Application of FCCP caused a rapid (within seconds) increase in [Ca2+]i that was long-lasting (minutes) (Fig. 8A,B). After this broad increase in [Ca2+] dissipated, spontaneous events reemerge. These Ca2+ spikes propagate nearly twofold further than observed in control (Fig. 8D; p < 0.0001, Kolmorogov–Smirnov test), their half-lives are prolonged (Fig. 8E; p = 0.0004, Kolmorogov–Smirnov test) and peak amplitude decreased (Fig. 8C; p < 0.0001, Kolmorogov–Smirnov test). The rapid release of Ca2+ following FCCP treatment (Fig. 8A,B) suggests that astrocytic mitochondria accumulate Ca2+. The effects on the properties of the Ca2+ spikes are consistent with the hypothesis that mitochondrial Ca2+ uptake contributes to the spatial restriction of Ca2+ signals within the astrocyte processes.
Given the problems inherent in either generalized inhibition of mitochondrial electron transfer (FCCP) or adaptive changes in mitochondrial positioning following transfection (MiroKK), we used a third paradigm to examine the role of mitochondrial positioning in controlling Ca2+ in astrocytic processes; photoablation of individual mitochondria. Astrocytes were transfected with the Ca2+-indictor LCK-GCamp5G (Fig. 9B) and the photosensitizing construct KillerRed targeted to the mitochondrial matrix (KillerRed-mito; Fig. 9A). This construct has been used previously to locally eliminate mitochondria and is thought to act via ROS production (Williams et al., 2013a; Wong and Holzbaur, 2014). Exposure to 405 nm light (2 s; white arrow) results in a rapid ablation of the mitochondria and frequently (8 of 9 cells) an increase in local [Ca2+]i. In 5 of 9 cells, this was followed by an increased frequency of calcium spikes at or adjacent to the ablation site (Fig. 9B). These Ca2+ transients are ∼1.5-fold larger (Fig. 9C; p = 0.037; Mann–Whitney test), spread nearly threefold farther (Fig. 9D; p < 0.0001; Mann–Whitney test), and are slower to decay (Fig. 9E; p = 0.045; Mann–Whitney test) than are Ca2+ transients before photoablation. These results suggest that individual mitochondria within the astrocyte processes accumulate Ca2+ and that the positioning of mitochondria is important for constraining Ca2+ signals within astrocyte processes.
Although each of these approaches has its limitations, in combination, these results show that the astrocytic mitochondria are actively buffering Ca2+ and that the accurate positioning of mitochondria at sites of elevated Ca2+ activity is important in constraining these [Ca2+]i increases within the astrocyte processes.
Discussion
Previously, we showed that mitochondria are present in the processes of astrocytes, that they are mobile, and that their mobility is increased following inhibition of neuronal activity, astrocytic glutamate uptake, or reversed Na+/Ca2+-exchange (Jackson et al., 2014). Indeed, neuronal activity regulates the accumulation of mitochondria near glutamate transporter clusters that appose synapses in organotypic slices (Jackson et al., 2014) and in culture (Ugbode et al., 2014). Here we sought to address the molecular mechanisms regulating the arrest of mitochondria at these sites. We showed that inhibiting neuronal activity, glutamate uptake, or Na+/Ca2+-exchange all decrease basal [Ca2+]i and modulate spontaneous Ca2+ signaling within the astrocyte processes. We demonstrated that the Ca2+-sensitive adaptor proteins Miro1 and Miro2 are expressed in astrocytes and regulate mitochondrial mobility within astrocyte processes. We showed that mitochondrial depolarization (FCCP) decreases the rate of Ca2+ clearance from the cytosol and increases the spread of Ca2+ signals. Last, we demonstrated that the ability of mitochondria to influence Ca2+ dynamics is dependent upon active positioning of the mitochondria in a Miro- and Ca2+-dependent fashion.
Functionally and morphologically, astrocytes are intimately integrated into the neuronal circuitry. In the mouse cortex, a single astrocyte contacts thousands of synapses (Bushong et al., 2002) and ensheaths multiple cell bodies (Halassa et al., 2007). Astrocytes express many neurotransmitter receptors and transporters that allow them to sense and respond to neuronal (or other) stimuli (Zhang et al., 2014; for review, see Rusakov, 2015). Astrocytes respond to many/most of these factors through increase in [Ca2+]i, suggesting an essential role for changes in [Ca2+]i in the astrocytic response (for review, see Rusakov, 2015). Indeed, many of these Ca2+ signals have been linked to changes in synaptic plasticity and local blood flow, although controversies regarding the source of the Ca2+ signals and the physiologic relevance of these signals have arisen (Araque et al., 2014; Rusakov et al., 2014; Benjamin Kacerovsky and Murai, 2015; Srinivasan et al., 2015; for review, see Attwell et al., 2010).
Until recently, much of the local signaling that occurs within individual processes was not apparent (Shigetomi et al., 2010b). Our results are consistent with previous observations using membrane-tethered indicators that describe highly localized Ca2+ signals within the processes of the astrocyte (Shigetomi et al., 2012, 2013b) that are sensitive to inhibition with a TRPA1 antagonist (Fig. 2G). These Ca2+ transients appear to be uncoordinated temporally between processes but reappear frequently within the same locations, suggesting an underlying spatial organization regulating the genesis of these Ca2+ signals. Understanding how these local signals are generated, how they are compartmentalized, and under what circumstances this compartmentalization is changed will be important to understanding how this common signal controls both local and global signaling within the astrocyte.
Others (Grosche et al., 1999; Perea and Araque, 2005; Shigetomi et al., 2010b; Di Castro et al., 2011; Panatier et al., 2011; Reeves et al., 2011; Srinivasan et al., 2015) have observed [Ca2+] signals that are spatially discrete, rarely propagating beyond several microns. While recent research has concentrated on determining how these spatially isolated Ca2+ signals are generated, an equally compelling question is as follows: what are the mechanisms that restrict the spatial spread of these signals? Mitochondria have been shown to inhibit the propagation of Ca2+ waves in primary cultures of rat cortical astrocytes (Boitier et al., 1999). Here we demonstrate that mitochondria colocalize with Ca2+ signals in astrocyte processes and that uncoupling mitochondria increases the spatial spread of spontaneous, localized Ca2+ signals. This effect may be direct, via reduced mitochondrial Ca2+ uptake, or indirect by depletion of local ATP to fuel the sarcoplamic/endplasmic reticulum or plasma membrane Ca2+-ATPases (SERCA or PMCA, respectively) pumps. Nevertheless, it implies that mitochondria play an important role in the functional compartmentalization of Ca2+ signals in astrocytes. It will be interesting to examine how other clearance mechanisms (PMCAs, SERCAs, forward mode Na+/Ca2+ exchanger [NCX]), endogenous buffers, and astrocyte geometry contribute to the spatial and temporal compartmentalization of these calcium signals.
In addition to these highly localized events, we describe mechanisms regulating basal [Ca2+]i within the processes of the astrocyte. In particular, we describe a significant contribution of reversed-Na+/Ca2+ exchange to regulating basal [Ca2+]i. The NCX is a bidirectional exchanger that couples the inward movement of three Na+ ions to the outward movement of one Ca2+ ion (Blaustein and Lederer, 1999). All three NCX isoforms are enriched at perisynaptic distal astrocyte processes (Minelli et al., 2007). The reversal potential of the NCX in astrocytes is close to the resting membrane potential (Kirischuk et al., 1997; Reyes et al., 2012), such that NCX can rapidly operate in the so-called reverse mode (Na+ out/Ca2+ in) in response to small Na+ loads, such as occur with glutamate transport (Langer and Rose, 2009). We observed a decrease in basal [Ca2+]i following treatment with TFB-TBOA (Fig. 1B) that is phenocopied by direct inhibition of NCX with YM-244769 (Fig. 1C), suggesting a persistent activation of NCX subsequent to neuronal activity and glutamate uptake. This is consistent with results in primary cultures of astrocytes (Reyes et al., 2012; Magi et al., 2013; Rojas et al., 2013). Other mechanisms (TRPA1) regulating basal [Ca2+]i have been implicated in controlling the surface expression of the GABA transporter GAT (Shigetomi et al., 2012) and the release of d-serine (Shigetomi et al., 2013a). Activation of the reversed mode of the NCX might couple glutamate uptake to downstream signaling via Ca2+.
In neurons, mitochondria are distributed to match energetic supply and Ca2+ buffering to the demand imposed by neuronal signaling. In other systems, a key mediator of mitochondrial movement and positioning is the Miro proteins (Saotome et al., 2008). These Ca2+-sensitive outer-membrane mitochondrial proteins link mitochondria to motor proteins (kinesins) through TRAK adaptor proteins. Increases in [Ca2+]i lead to immobilization of mitochondria in a Miro protein-dependent manner (Fig. 10) (for review, see Sheng and Cai, 2012; Schwarz, 2013). Here, we demonstrate that the Miro proteins (Miro1 and Miro2) are expressed in astrocytes. In astrocytes, the percentage of mitochondria that are mobile is low (Fig. 6F). Exogenous expression increases mitochondrial movement, suggesting that Miro expression might limit baseline mobility of astrocytic mitochondria. Increased mitochondrial movement with expression of Ca2+-insensitive Miro mutants suggests that mitochondrial mobility is controlled by intracellular Ca2+ concentration ([Ca2+]i) and that mitochondrial movement is inhibited at relatively low levels of Ca2+, as would be expected in astrocytes in unstimulated slices. Interestingly, Ugbode et al. (2014) showed that the expression of the Miro-binding partner TRAK increases when astrocytes are cocultured with neurons. These results suggest that, as in neurons, Miro proteins regulate the distribution of mitochondria in astrocytes at domains of elevated activity or [Ca2+]i.
Mitochondria play complex roles in cells. They represent a potential mechanism to locally supply energy via the TCA cycle and oxidative phosphorylation, integrate numerous cues related to cell survival, and regulate local Ca2+ signaling (Jacobson and Duchen, 2004). Many of these roles are interconnected.
Mitochondria import Ca2+ via a Ca2+-sensitive uniporter (MCU). This process is driven by the large negative membrane potential (∼−180 mV) established across the inner mitochondrial membrane (Kirichok et al., 2004). This process occurs in lieu of proton reentry via the ATP synthase (Rizzuto et al., 2012). Accumulated Ca2+ is released into the cytosol via a mitochondrial Na+/Ca2+-exchanger (Baron and Thayer, 1997; Nicholls and Budd, 2000). These processes allow mitochondria to blunt the amplitude, modulate the duration, and spatially restrict the propagation of Ca2+ signals. Several lines of evidence from our current study suggest a role for mitochondria in regulating Ca2+ signaling within the astrocyte processes. First, application of the proton ionophore FCCP (Fig. 8) or photoablation of individual mitochondria (Fig. 9) resulted in large increases in [Ca2+]i, suggesting that mitochondria in the processes accumulate Ca2+. Second, mitochondrial uncoupling increased the time constant and spatial spread of spontaneous Ca2+ transients within the astrocyte processes (Fig. 8D,E), consistent with the loss of a Ca2+ buffer. Last, inhibiting the Ca2+-dependent arrest of mitochondria (MiroKK; Fig. 7) increased the frequency of Ca2+ events and increased the time constant of decay of these transients, suggesting that the Ca2+-dependent positioning of mitochondria is important for their ability to efficiently buffer Ca2+ signals.
In addition to shaping Ca2+ signals, mitochondrial Ca2+ uptake alters the activity of mitochondria. Mitochondrial Ca2+ uptake increases the production of ATP by activating the Ca2+-sensitive dehydrogenases of the mitochondrial matrix (pyruvate dehydrogenase, isocitrate dehydrogenase, and oxoglutarate dehydrogenase) (Denton et al., 1972; Cárdenas et al., 2010), and the adenine nucleotide translocator (Moreno-Sánchez, 1985). Additionally, Ca2+ regulates the glutamate/aspartate carrier proteins (citrin and aralar) (Satrústegui et al., 2007). The net result of these activities is an increase in H+ transport, respiration, and ATP production. Ca2+-dependent mitochondrial positioning and subsequent mitochondrial Ca2+ uptake might allow mitochondria to sense domains of elevated activity and enable mitochondria to tune ATP production to the local energy requirements of the astrocyte.
Here we describe a mechanism by which astrocytes may transport and retain mitochondria at domains of elevated activity (e.g., perisynaptic regions enriched in glutamate transporters) via increases in [Ca2+]. Miro protein-mediated arrest of mitochondria and subsequent Ca2+ uptake by the mitochondria serve to compartmentalize spontaneous Ca2+ signals within the astrocyte processes and provide local energetic support.
Footnotes
This work was supported by National Institute of Neurological Disorders and Stroke Grant RO1 NS077773 to M.B.R., Institutional Intellectual Developmental Disabilities Research Center U54 HD086984 Cellular Neuroscience Core, and Biostatistics and Bioinformatics Core. We thank Dr. Mary Putt for statistical advice; Drs. Douglas Coulter and Hajime Takano for advice with imaging and data analysis; members of the M.B.R. and Coulter laboratories for their advice and suggestions during the conduct of this research; and John O'Donnell for helpful suggestions.
The authors declare no competing financial interests.
- Correspondence should be addressed to Dr. Michael B. Robinson, Department of Pediatrics, 502N, Abramson Research Building, 3615 Civic Center Boulevard, Philadelphia, PA 19104-3779. Robinson{at}mail.med.upenn.edu