Abstract
Wave-like propagation of [Ca2+]i increases is a remarkable intercellular communication characteristic in astrocyte networks, intercalating neural circuits and vasculature. Mechanically-induced [Ca2+]i increases and their subsequent propagation to neighboring astrocytes in culture is a classical model of astrocyte calcium wave and is known to be mediated by gap junction and extracellular ATP, but the role of each pathway remains unclear. Pharmacologic analysis of time-dependent distribution of [Ca2+]i revealed three distinct [Ca2+]i increases, the largest being in stimulated cells independent of extracellular Ca2+ and inositol 1,4,5-trisphosphate-induced Ca2+ release. In addition, persistent [Ca2+]i increases were found to propagate rapidly via gap junctions in the proximal region, and transient [Ca2+]i increases were found to propagate slowly via extracellular ATP in the distal region. Simultaneous imaging of astrocyte [Ca2+]i and extracellular ATP, the latter of which was measured by an ATP sniffing cell, revealed that ATP was released within the proximal region by volume-regulated anion channel in a [Ca2+]i independent manner. This detailed analysis of a classical model is the first to address the different contributions of two major pathways of calcium waves, gap junctions and extracellular ATP.
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Introduction
Deeper understanding of the mechanisms underlying the spatio-temporal diversity and complexity of [Ca2+]i increases in astrocytes is crucial for exploring the physiological and pathological functions of this glial cell population. Calcium waves are a remarkable aspect of [Ca2+]i dynamics in astrocytes, and a unique type of intercellular communication in astrocyte networks, intercalating neuronal circuitries and vasculature. Various pharmacologic and physical stimuli have been found to induce [Ca2+]i increases propagating between astrocytes in cell cultures1,2, in brain slices3,4, and in other in vivo preparations5,6. These calcium waves are regarded as transmitting physiologic and pathologic signals within the brain, because they influence the activities of adjacent neurons7,8, microglia9, and endothelial cells10. Furthermore, recent studies have demonstrated the involvement of astrocyte networks and calcium waves in regulating neuronal activities11 and neurological diseases12,13.
Because calcium waves can propagate between astrocytes in the absence of physical contact14, they are likely induced by intracellular and extracellular signals in a synergistic manner. Astrocytes are intracellularly connected via connexin channels15, and their transmission of Ca2+ and IP3 via gap junctions has been demonstrated experimentally and theoretically16,17. Moreover, astrocytes are equipped with ATP release mechanisms and ATP receptors inducing [Ca2+]i increases18, and purinergic signaling has been found to be involved in calcium waves19,20. Furthermore, gap junction and purinergic signaling are regulated in a supplementary manner to maintain calcium waves21. However, the contributions of these components to the dynamics and functions of calcium waves, and the mechanisms involved in initiating [Ca2+]i increases and release ATP in calcium waves are incompletely understood.
Theoretical17 and experimental1,2 studies have shown that calcium waves can be mechanically induced by gently touching cultured astrocytes with tips of glass pipettes. The present analysis of this classical model pharmacologically and by using an ATP sniffing cell revealed distinct [Ca2+]i increases during calcium waves. This study was therefore designed to assess the distinct contributions of gap junction and extracellular ATP and the ATP release mechanism in calcium waves, revealing novel aspects of the diverse and complicated dynamics of astrocyte [Ca2+]i.
Results
Components of [Ca2+]i increases in calcium waves
Figure 1a shows a representative calcium wave induced by mechanical stimulation of cultured astrocytes. The [Ca2+]i increase in the mechanically-stimulated cell (arrow) propagated to adjacent cells, and the area of [Ca2+]i increases reached a maximum at 24 sec. Then, [Ca2+]i in the distal region declined to the baseline by 120 sec, whereas that proximal to the stimulated cell remained elevated for longer than 120 sec. The distribution of [Ca2+]i increases was expressed as a maximum [Ca2+]i projection, in which each pixel represents the maximum Δ340/380 ratio during the calcium wave (Fig. 1b left). As shown in Fig. 1b center, we defined the peak [Ca2+]i increase (red) as [Ca2+]i increase in the stimulated cell, and the persistent (orange) and transient (blue) [Ca2+]i increases as [Ca2+]i increases sustained and declined until 120 sec, respectively. The appropriateness of 120 sec was clarified later. The histogram of maximum [Ca2+]i increases along a line in Fig. 1b right, shows that the peak [Ca2+]i increase was the largest [Ca2+]i increase during the calcium wave, and the persistent [Ca2+]i increases were larger than the transient [Ca2+]i increases (Fig. 1c). The [Ca2+]i increases of individual cells in the region of the peak and persistent [Ca2+]i increases (Cell 1–3) were persistent, whereas those in the region of transient [Ca2+]i increases (Cell 4–6) were transient (Fig. 1d). These findings suggested that the peak, persistent and transient [Ca2+]i increases were distinct components of the same calcium wave.
The time dependent changes of areas of [Ca2+]i increases were further analyzed by averaging 10 calcium waves. The area of [Ca2+]i increases peaked at 40 sec and declined to become constant at 120 sec as shown in Fig. 2a. Thus, it is appropriate to define the persistent [Ca2+]i increase depending on the area of [Ca2+]i increase at 120 sec. The areas of peak, persistent and transient [Ca2+]i increases were 1133 ± 453 μm2, 13069 ± 4574 μm2 and 127633 ± 51000 μm2, respectively (Fig. 2b), equivalent to circles with radii of 19 μm, 65 μm and 201 μm respectively. The averaged maximum [Ca2+]i in the areas of peak and persistent [Ca2+]i increases did not significantly differ, but that in the area of transient [Ca2+]i increases was significantly smaller than that in the area of peak [Ca2+]i increases by 46% as shown in Fig. 2c. These results further confirm the difference between transient and persistent [Ca2+]i increases.
Mechanisms increasing [Ca2+]i in calcium waves
The mechanisms underlying the [Ca2+]i increases during calcium waves were pharmacologically examined by omitting extracellular Ca2+ (Ca2+-free), which inhibits Ca2+ influx; and by treating cells with 1 μM thapsigargin (TG), 10 μM U73122 and 20 μM Xestospongin C (Xest C), which inhibit, calcium storage, inositol1,4,5-trisphosphate (IP3) production and IP3 receptor, respectively. Figure 3a shows representative calcium waves of control (−), Ca2+-free and TG-treated cells. Omitting extracellular Ca2+ was found to eliminate the persistent [Ca2+]i increases without affecting the peak [Ca2+]i increase or propagation of the calcium wave, whereas treating with thapsigargin abolished the calcium wave without affecting the peak [Ca2+]i increase. Figure 3b shows quantitative analyses of the calcium wave components. Amplitudes of the peak [Ca2+]i increases were not significantly affected by any pharmacologic treatment, indicating that the peak [Ca2+]i increases were not mediated by Ca2+influx or IP3-induced Ca2+release (IICR), and that alterations of calcium waves described below did not reflect the difference of initial [Ca2+]i increases before propagations. In contrast, incubation of cells with Ca2+-free medium, TG, TG + Ca2+-free medium, U73122, and Xest C resulted in significant reductions in areas of the persistent [Ca2+]i increases to 32%, 18%, 9%, 40%, and 8%, respectively. The elimination of persistent [Ca2+]i increases was partial in some experiments of Ca2+-free group, presumably due to insufficient reduction of extracellular Ca2+ concentration in the nominally Ca2+-free condition. Although Ca2+-free medium had no effect on areas of the transient [Ca2+]i increases, the latter was significantly reduced by TG, TG + Ca2+-free, U73122 and Xest C to 2%, 2%, 5% and 1%, respectively. These findings indicate that the persistent [Ca2+]i increase is maintained synergistically by Ca2+influx and IICR, whereas the transient [Ca2+]i increases are mediated by IICR alone.
The effects of omitting extracellular Ca2+ on calcium waves were further analyzed. A representative [Ca2+]i increase in an individual cell treated with Ca2+-free medium was transient similar to that in the distal region of control (Fig. 3c). The velocity of calcium wave in the Ca2+-free group (9.1 ± 1.8 μm/sec) were similar to that of the transient [Ca2+]i increases in the control group (9.3 ± 1.6 μm/sec), with both being significantly lower than the velocity of the persistent [Ca2+]i increase in the control group (22.6 ± 2.9 μm/sec) (Fig. 3d). These results indicate that extracellular Ca2+ does not affect the propagations of the transient [Ca2+]i increases.
Mechanisms of calcium wave propagation
The mechanisms underlying calcium wave propagation were pharmacologically examined by treating cells with the gap junction blockers, 100 μM carbenoxolone (CBX), 100 μM 18β-glycyrrhetinic acid (18GA) and 1 mM octanol; a blocker of gap junction hemichannels containing connexin 43 (Cx43), which is a major connexin subtype in cultured astrocytes22, 300 μM gap-1923; a pannexin hemichannel blocker, 1 mM Probenecid; an ATP receptor antagonist, 100 μM suramin; and an ATP degrading enzyme, 15 unit/ml apyrase. Figure 4a shows representative calcium waves of control, CBX- and suramin-treated cells. These results indicate that CBX abolishes calcium waves without affecting the peak [Ca2+]i increases, whereas suramin eliminates the transient [Ca2+]i increases without affecting the peak or the persistent [Ca2+]i increases. Figure 4b shows quantitative analyses of the calcium wave components. The peak [Ca2+]i increases were not significantly affected by any pharmacologic treatments, indicating that they do not involve either gap junction or purinergic signaling. In contrast, CBX, 18GA and octanol significantly reduced areas of the persistent [Ca2+]i increases, to 10%, 8% and 7%, respectively, and reduced areas of the transient [Ca2+]i increases to 1%, 1% or 0.8%, respectively, indicating that gap junctions are essential for calcium waves. Gap-19 and probenecid did not affect either the persistent or transient [Ca2+]i increases, indicating that connexin and pannexin hemichannels are not involved in calcium waves. Suramin and apyrase had no effect on areas of the persistent [Ca2+]i increases, but significantly reduced areas of the transient [Ca2+]i increases to 20% or 18%, respectively, suggesting that purinergic signaling is involved in the generation and/or propagation of transient [Ca2+]i.
The effects of purinergic inhibitors on the persistent [Ca2+]i increases were further analyzed. Individual astrocytes showed persistent [Ca2+]i increases, regardless of the presence of purinergic inhibitors (Fig. 4c). The extent of [Ca2+]i increases, expressed as peak amplitude (peak) or area under the curve (AUC), was not affected by these purinergic inhibitors (Fig. 4d), indicating that purinergic signaling is not involved in the persistent [Ca2+]i increases.
The inhibition of astrocyte gap junction hemichannels by gap-19 was confirmed by measuring ATP release, using luciferase assays, following treatment in Ca2+ and Mg2+ free (CMF) medium, which is commonly used to induce the release of macromolecules from gap junction hemichannels24. As expected, CMF enhanced extracellular ATP, but this increase was significantly reduced to 4% and 10% by CBX and gap-19, respectively (Fig. 4e), indicating that gap-19 potently inhibits astrocyte gap junction hemichannels. These findings confirmed that calcium waves do not involve ATP release via gap junction hemichannels.
ATP release mechanisms in calcium waves
ATP release during the propagation of astrocyte calcium waves was investigated using an ATP sniffing cell, HEK293 cells expressing a fluorescent Ca2+ indicator protein, GCaMP225. P2Y1 and P2Y4, but not P2Y2, P2Y6 or P2X receptors are expressed in HEK293 cells and mediate ATP-induced [Ca2+]i increases26. Meanwhile, cultured astrocytes express a variety of P2X and P2Y receptors, but their ATP-induced [Ca2+]i increases are largely mediated by P2Y receptors, except P2×7 receptor-mediated calcium influx in response to high concentrations of ATP27. Thus, it is assumed that HEK293 + GCaMP2 cells adjacent to astrocytes show [Ca2+]i increases in response to extracellular ATP mediating astrocyte calcium waves. HEK293 + GCaMP2 cells were placed on top of Fura2-loaded astrocytes for simultaneous imaging of [Ca2+]i in both cell types (Fig. 5a). HEK293 + GCaMP2 cells were seeded sparsely enough to avoid transmissions of [Ca2+]i increases by their own gap junctions. Mechanical stimulation of astrocytes induced [Ca2+]i increases in HEK293 + GCaMP2 cells, in areas equivalent to those of astrocyte calcium waves (Fig. 5b). To interpret these findings, the characteristics of [Ca2+]i increases in HEK293 + GCaMP2 cells were analyzed. Transient [Ca2+]i increases, which are characteristic of astrocyte [Ca2+]i increases in the distal region, were induced in HEK293 + GCaMP2 cells by astrocyte calcium waves and ATP, as well as in astrocytes by ATP (Fig. 5c), indicating that the temporal dynamics of GCaMP2-expressing HEK293 cells is comparable to that of Fura2-loaded astrocytes. The EC50 values of HEK293 + GCaMP2 cells and astrocytes to ATP were 5.9 μM and 8.5 μM, respectively (Fig. 5d). Addition of 100 μM suramin significantly reduced the [Ca2+]i increases in both cell types induced by ≤10 μM ATP. Thus, HEK293 + GCaMP2 cells and astrocytes respond to ATP in the same concentration range, and these responses are similarly sensitive to suramin, suggesting that HEK293 + GCaMP2 cells detect extracellular ATP with the same sensitivity as astrocytes.
Pharmacologic analysis of [Ca2+]i increases by HEK293 + GCaMP2 cells during astrocyte calcium waves showed that these GCaMP2 responses were significantly reduced by suramin and apyrase, to 5% and 7%, respectively, confirming that they reflect astrocyte ATP releases (Fig. 5e and g). CBX, which abrogated calcium waves, reduced the GCaMP2 response to 7%, suggesting that interactions between astrocytes via gap junctions is essential for ATP release, and that extracellular ATP released during calcium waves is not likely due to mechanically-stimulated astrocytes alone. Ca2+-free medium, which abrogated the persistent [Ca2+]i increases without affecting the peak and transient [Ca2+]i increases, had no effect on GCaMP2 responses even in the proximal region, confirming that the propagation of the transient [Ca2+]i increases was mediated by extracellular ATP and suggesting that the persistent [Ca2+]i increases in the proximal region, which is larger than the transient [Ca2+]i increases are not essential for ATP release. The finding, that ATP release is independent of [Ca2+]i increase, was further strengthened by results showing that 100 μM glutamate induced robust [Ca2+]i increases in astrocytes, but failed to induce GCaMP2 responses (Fig. 5f and g). These results indicate that [Ca2+]i increases do not trigger astrocyte ATP release.
Extracellular ATP diffusion during calcium waves
To monitor extracellular ATP diffusion during calcium waves, the GCaMP2 responses of astrocyte-free areas, generated by scratching astrocyte monolayers with a needle, were examined. Figure 6a is a representative fluorescence image of Fura2-loaded astrocytes after scratching and seeding HEK293 + GCaMP2 cells. Mechanical stimulation induced an astrocyte calcium wave and GCaMP2 responses in both astrocytes and astrocyte-free areas (Fig. 6b). HEK293 + GCaMP2 cells with [Ca2+]i increases 25–50% of the highest [Ca2+]i increase adjacent to stimulated astrocytes were subjected to further analysis for determining the influence of astrocytes on extracellular ATP diffusion. HEK293 + GCaMP2 cells with [Ca2+]i increases >50% were excluded because these cells were mostly present in astrocyte-containing proximal regions. HEK293 + GCaMP2 cells with [Ca2+]i increases <25% were also excluded, because of their sparse distribution. When peak amplitudes (Fig. 6C) and AUCs (Fig. 6d) of [Ca2+]i increases in individual HEK293 + GCaMP2 cells showing 25–50% increases in [Ca2+]i were plotted against the distance from the stimulated astrocyte, these HEK293 + GCaMP2 cells were found to be located approximately 100–300 μm from stimulated astrocytes, indicating that these cells were in the distal region. Their magnitude of [Ca2+]i increase did not correlate with distance (R2 values were not significant) both in the presence and absence of astrocytes. The mean distances between stimulated astrocytes and HEK293 + GCaMP2 cells showing 25–50% increases in [Ca2+]i and the amplitudes and AUC of their [Ca2+]i increases were not affected by the presence of astrocytes (Fig. 6e and f). These results indicate that the GCaMP2 responses do not decline in the distal region, and are not affected by the presence of astrocytes. These findings therefore suggest that the transient [Ca2+]i increases in the distal region is attributed to the diffusion of ATP released in the proximal region. Since HEK293 + GCaMP2 cell responses did not decline depending on the distance, the concentration of flowing extracellular ATP was likely constant, presumably due to continuous release, rather than diffusion of transiently-released ATP with dilution.
ATP release Mechanisms in calcium waves
ATP release mechanisms underlying calcium waves were explored pharmacologically. To assess the involvement of lysosome exocytosis, which was suggested to be the ATP release mechanism during electrically-induced calcium waves in cultured astrocytes28, astrocytes were treated with a cathepsin C substrate, 200 μM glycyl-L-phenylalanine 2-naphthylamide (GPN), or a cell permeable triadin, 10 μM vacuolin-1, which reduce lysosomes. In addition, cells were treated with 2 μM bafilomycin, an inhibitor of vesicular ATPase that depletes vesicles for exocytosis. None of these inhibitors had any effect on the components of calcium waves, indicating that neither lysosome nor conventional exocytosis was involved in ATP release during calcium waves (Fig. 7). The involvement of volume regulated anion channels (VRACs) was also assessed by incubation with the VRAC blockers, 20 μM 4-[(2-Butyl-6,7-dichloro-2-cyclopentyl-2,3-dihydro-1-oxo-1H-inden-5-yl)oxy]butanoic acid (DCPIB) and 200 μM diisothiocyano-2,2′-stilbenedisulfonic acid (DIDS). Neither of these reagents affected the peak or persistent [Ca2+]i increases, whereas both significantly reduced the transient [Ca2+]i increases to 4% and 14%, respectively (Fig. 8a), suggesting that VRAC blockers eliminate ATP release. The effects of these VRAC blockers on astrocyte ATP releases were examined using HEK293 + GCaMP2 cells and luciferase assays. Both DCPIB and DIDS significantly reduced the GCaMP2 responses, to 6% and 2%, respectively (Fig. 8b). In the luciferase assays, astrocyte ATP release was induced mechanically by dropping glass beads, which was reported to induce astrocyte calcium waves similar to the method of induction by glass pipettes19. Because ATP releases during calcium waves measured by HEK293 + GCaMP2 assays were eliminated by CBX, the effects of gap junction, gap junction hemichannel, and VRAC blockers were tested. DCBPI, DIDS and CBX significantly reduced beads-induced ATP release to 16%, 18% and 15%, respectively, whereas gap-19 had no effect (Fig. 8c). DCPIB was reported to inhibit Cx43 hemichannel29, however the effects of DCPIB on calcium waves and beads-induced ATP release are not mediated by Cx43 hemichannel, because both were not affected by the Cx43 hemichannel selective inhibitor, gap-19. These results indicate that VRAC blockers eliminate propagations of the transient [Ca2+]i increases by blocking mechanically-induced ATP release and that gap junctions are involved in mechanically-induced ATP release.
Finally, ATP release by CMF, beads, ionomycin and glutamate were compared quantitatively. The amount of ATP released by beads was 43% that by CMF, whereas neither 100 μM ionomycin nor 1 mM glutamate induced detectable ATP release (Fig. 8d). These results indicate that mechanically-induced ATP release via VRAC is comparable to the ATP released by gap junction hemichannels, whereas [Ca2+]i does not induce release of ATP.
Discussion
The present study demonstrates that mechanically-induced astrocyte calcium waves consist of three components; (i) [Ca2+]i increases in mechanically stimulated cells, which are independent of Ca2+ influx and IICR, (ii) fast propagation of persistent [Ca2+]i increases in the proximal region, which are mediated by gap junctions and (iii) slow propagation of transient [Ca2+]i increases in the distal region, which are mediated by extracellular ATP. These calcium waves also involve ATP release via VRAC activated by non-Ca2+ signal propagation via gap junctions in the proximal region.
The findings in the present study are in good agreement with those of previous studies. For example, the velocities of the calcium waves (22.6 ± 2.9 μm/sec in the proximal region and 9.3 ± 1.6 μm/sec in the distal region) were equivalent to those previously reported, 20 μm/sec.1 and 13.9 μm/sec.30; and the radii of the distal region (201 μm) were similar to those of previous reports, 204 μm30 and 180 μm2. Furthermore, the decline in calcium wave amplitudes and velocities during propagation2 and the discontinuous distribution of [Ca2+]i 16 were shown in previous studies on astrocyte calcium waves. However, to our knowledge, this is the first study demonstrating distinct components of astrocyte calcium waves, and showing different contributions of gap junction and extracellular ATP to calcium wave propagation by characterizing these components.
We also found that the peak [Ca2+]i increases were not affected by any pharmacologic inhibitors of [Ca2+]i increase or propagation. The distinction we observed between the pharmacologic characteristics of peak [Ca2+]i and adjacent propagating [Ca2+]i increases were consistent with those of previous studies, which showed that a PLC and a SERCA inhibitor eliminated propagating [Ca2+]i increases in the calcium waves of airway epithelial cells31 and smooth muscle cells32, respectively, without affecting the [Ca2+]i increases in mechanically-stimulated cells. The lack of effect of the absence of extracellular Ca2+ on peak [Ca2+]i increases excludes the possibility that touching with glass pipette tips induced the initial [Ca2+]i increases by Ca2+ influx via mechanosensitive channels expressed in astrocytes33, or via physically-damaged plasma membranes. Since both omitting extracellular Ca2+ and inhibiting IICR did not affect increases in peak [Ca2+]i, mechanical stimulation may induce Ca2+ release from thapsigargin-insensitive calcium stores, which are not involved in IICR34,35.
The persistent [Ca2+]i increases, which were sustained in the proximal region for several minutes, were larger and propagated faster than the transient [Ca2+]i increases. Since these [Ca2+]i increases were eliminated by IICR inhibitors and by omitting extracellular Ca2+, they may be shaped synergistically by IICR and Ca2+ influx. The induction of IP3 by mechanical stimulation has been demonstrated pharmacologically in many cell types including astrocytes31,36. Theoretical studies have suggested that IP3 mobilization through gap junctions is the main pathway of astrocyte calcium waves, and that the regenerative production of IP3 by Ca2+ dependent PLC subtypes drives the propagation17,37. Regenerative IP3 production likely underlies the persistent [Ca2+]i increases and the gap junction-mediated propagation of calcium waves. It may also be essential for ATP release in the proximal region, whereas the IP3 production for the transient [Ca2+]i increases, which was mediated by P2Y receptors, was not amplified by Ca2+-dependent PLC or capable of inducing ATP release.
Omitting extracellular Ca2+ eliminated the persistent [Ca2+]i increases, indicating that the difference between the persistent and transient [Ca2+]i increases was due to Ca2+ influx. Our attempts to pharmacologically identify calcium channels responsible for Ca2+ influx have been unsuccessful. Purinergic inhibitors did not influence persistent [Ca2+]i increases, whereas HEK293 + GCaMP2 cells detected extracellular ATP in the proximal region. These findings suggested that ATP occupies ATP receptors, but that ATP-induced IICR is occluded by the large persistent [Ca2+]i increases in the proximal region. Omitting extracellular Ca2+ likely eliminated these large persistent [Ca2+]i increases, allowing detection of ATP-induced IICR in the proximal region.
Because the transient [Ca2+]i increases are abrogated by purinergic inhibitors and are insensitive to extracellular Ca2+, these increases have been attributed to ATP-induced IICR. The finding, that extracellular ATP in the distal region, as measured by HEK293 + GCaMP2 during calcium waves, was preserved even when astrocytes were removed by scratching, suggested that ATP is released within the proximal region and passively diffuses into the distal region as a continuous flow. These findings contradict a previous hypothesis, that ATP is released by a Ca2+-dependent regenerative process during propagation14. The lack of a regenerative process likely accounts for the lower velocity in the distal region. That is, [Ca2+]i increases in the proximal region propagate rapidly and effectively by direct intracellular communications via gap junctions and regenerative IP3 production. In contrast, [Ca2+]i increases in the distal region propagate slowly and passively by diffusion of ATP.
HEK293 + GCaMP2 cells, which are equivalent in sensitivity and pharmacologic properties to astrocytes in detecting extracellular ATP, were used in the present study to measure ATP release during calcium waves. Our findings, that purinergic inhibitors abolished GCaMP2 responses without affecting astrocyte [Ca2+]i increases in the proximal region, suggested that extracellular ATP transmits [Ca2+]i increases between astrocytes and HEK293 + GCaMP2. Moreover, the ability of CBX to abolish GCaMP2 responses suggests the involvement of gap junctions in ATP release. These findings, together with results showing that exogenous expression of connexin potentiated ATP release via anion channels38, indicate that VRAC is activated by a signal mediated by gap junctions. This signal is not likely to be [Ca2+]i, because (i) Ca2+-free medium reduced proximal [Ca2+]i increases without affecting ATP release measured by GCaMP2 responses; (ii) glutamate induced robust [Ca2+]i increases in astrocytes but not in adjacent HEK293 + GCaMP2 cells, and (iii) glutamate and ionomycin did not induce ATP releases detectable by luciferase assays. The Ca2+ independent ATP release during astrocyte calcium waves is consistent with previous imaging of extracellular ATP by luciferase36. In addition, Bergman glia were shown to release glutamate via DIDS-sensitive anion channels following optogenetic stimulation39, suggesting the possibility that depolarization and/or associated movement of ions trigger DIDS-sensitive release of anionic molecules.
Because ATP in astrocytes is involved in various intercellular communications, these cells are equipped with multiple ATP release mechanisms, including exocytosis, gap junction hemichannels, P2 × 7 receptor and VRAC40. In the present study, luciferase assays showed substantial ATP release via gap junction hemichannels and VRAC, but not via exocytosis. GPN inhibition of lysosome exocytosis was reported to suppress ATP release during electrically-induced astrocyte calcium waves, which were potentiated by metabolic inhibition41. The lack of exocytosis in the present study may reflect differences in stimulation methods or culture conditions that affect metabolism, or the slow and ineffective progression of astrocyte exocytosis, as shown by total internal reflection fluorescence imaging42.
The protein, leucine-rich repeat containing 8 family member A (LRRC8A) was identified as a DCPIB-sensitive VRAC43,44. The involvement of LRRC8A in ATP release during astrocyte calcium wave propagation was examined using siRNA, however no significant influence of knocking-down LRRC8A was found (data not shown), suggesting the involvement of other unidentified VRAC genes. LRRC8A was found to be essential for glutamate release by astrocytes in response to ATP treatment or hypo-osmotic conditions45. However, most DCPIB-sensitive anion conduction in astrocytes has been associated with the release of glutamate, not ATP, although some glutamate release is triggered by ATP45,46. Mechanically-induced ATP release is thought to be due to other VRAC subtypes designated as maxi-anion channels47, which are also activated by mechanical stimulation including swelling by hypo-osmotic conditions. The gene encoding maxi-anion channels has not yet been identified. These channels are thought to possess a large pore, suitable for the permeation of ATP, which has a larger effective radius than glutamate48. Thus, the VRAC genes involved in astrocyte calcium wave are yet to be determined.
The present study found that a single mechanical stimulation of an individual astrocyte induced ATP release via VRAC from adjacent astrocyte networks connected by gap junctions. This process may represent the initiation and/or propagation of pathological processes following brain injuries. Microglia co-cultured with astrocytes respond to adjacent astrocyte calcium waves by increasing [Ca2+]i 49 or releasing IL1β50. In vivo microglia adjacent to focal insults to brain parenchyma undergo structural changes in response to ATP released by astrocytes via a mechanism involving gap junctions51. This pathological activation of microglia is likely due to astrocyte release of ATP during calcium waves. Furthermore, blockers of P2Y receptors, including suramin52,53, gap junctions54 and VRAC55 are neuroprotective after brain injury, strengthening the pathological implications of astrocyte ATP release. DCPIB has been reported to attenuate inflammatory responses after brain injury56. Further investigations based on the results of this study may identify the mechanically-induced signaling molecules, which propagate via gap junctions, and subsequent cascades for activating VRAC after mechanical stimulation, providing new insights into mechanisms of brain injury and possibly identifying therapeutic targets.
This detailed analysis of a classical model has revealed novel aspects of astrocyte physiology, especially the different contributions of two major pathways of calcium waves, gap junctions and extracellular ATP. The physiological and pathological implications of [Ca2+]i dynamics and purinergic signaling of astrocytes remain incompletely understood. Addressing the mechanisms of action and functions of astrocyte [Ca2+]i, including calcium waves, calcium oscillation, and spontaneous [Ca2+]i increases using cell culture models, remains important in basic and clinical research.
Methods
Cell culture
All animal experiments were approved by the Institutional Animal Care and Use Committee of Kobe University (Permission number: 25–20) and performed according to the Kobe University Animal Experimentation Regulations. Rats of either sex aged 0–2 postnatal days were sacrificed, and their cerebral cortices were removed and chopped into small pieces in Hank’s Balanced Salt Solution (Thermo Fisher Scientific, Franklin, MA). Cell preparations were incubated with 0.25% trypsin (Worthington Biochem, Freehold, NJ), with occasional agitation, at 37 °C for 20 min. DNase (Sigma-Aldrich, St. Louis, MO) was added to a final concentration of 0.1% and the cell preparations were incubated at room temperature for 5 min. The samples were transferred to Dulbecco’s Modified Eagle’s Medium containing 10% fetal bovine serum (FBS, Nichirei Biosciences, Tokyo, Japan) and antibiotics (50 μg/ml penicillin and 50 μg/ml streptomycin) and dispersed by pipetting. The resulting cells were seeded at 2.5 × 104 cells/cm2 in 75 cm2 flasks and cultured in the presence of 5% CO2 at 37 °C for 1–2 weeks. The mixed brain cell cultures were shaken to remove less-adherent cells and treated with trypsin. The resulting astrocyte preparations were seeded at 2.5 × 104 cells/cm2 on 12 mm coverslips, which were incubated overnight with 1 μg/ml poly-D-lysine (Sigma) for imaging analysis; or in wells of 96 well plates for luciferase assays. Astrocytes were subjected to experiments 1–3 weeks after seeding.
HEK293 cells (ATCC, Manassas, VA) were maintained in DMEM/F12 containing 10% FBS and antibiotics, and subcultured by treating with 10 mM EDTA/PBS. Cells were transfected with pN1-G-CaMP2 (RIKEN, Saitama, Japan) using Geneporter (Genlantis, San Diego, CA) and screened with 2 mg/ml G418 (Roche, Indianapolis, IN) and by fluorescence imaging to obtain stable transfectants expressing GCaMP2.
Calcium imaging
Astrocytes were washed three times with Basal Salt Saline (BSS; 129 mM NaCl, 4 mM KCl, 1 mM MgCl2, 2 mM CaCl2, 10 mM D-glucose, 10 mM Hepes pH 7.4) and incubated with 7.5 μM Fura2-AM (Dojin, Kumamoto Japan) at 30 °C for one hour. After three additional washes with BSS, the cells were maintained in BSS containing 100 μM sulfinpyrazone (Sigma), which inhibits Fura2 sequestration and secretion57, at room temperature until imaging experiments. HEK293 + GCaMP2 cell suspensions were added to Fura2-loaded astrocytes in BSS, and cocultured for more than two hours at room temperature. Fluorescence images were obtained using an inverted microscope, IX70 (Olympus, Tokyo, Japan) equipped with a filter exchanger (MAC5000; Ludl Electronic Products, Hawthorne, NY) and a cooled-CCD camera, Orca-R2 (Hamamatsu Photonics, Hamamatsu, Japan). The objective lens was UApo/340 20×/0.70w (Olympus). A 0.5x camera adaptor U-TV0.5XC (Olympus) was inserted before the camera. For Fura2-based calcium imaging, a set of F340 (Ex/DM/Em = 340/500/535) and F380 (Ex/DM/Em = 380/500/535) images were obtained every three seconds. For simultaneous calcium imaging of Fura2-loaded astrocytes and HEK293 + GCaMP2 cells, a set of F380 and F480 (Ex/DM/Em = 480/500/535) images were obtained every three seconds. Astrocytes were mechanically stimulated by touching them with 1–10 MΩ tips of a glass pipette (G150F-3, Warner Instruments, Hamden, CT), fabricated using P-87 (Sutter Instrument, Novato, CA). To maintain a constant stimulation force, contact by the tip was measured by input impedance using an amplifier (CEZ-2400; Nihon Kohden, Hyodo, Japan), and its approach was stopped immediately upon any increase in input impedance. The tip remained in contact during calcium wave propagation, because the waves were unaffected regardless of tip withdrawal.
Data analysis
Shading of fluorescence images was corrected by dividing the value of each pixel by the corresponding value in a control image. For Fura2-based calcium imaging, the Δ340/380 ration was calculated as \(\frac{{\rm{F}}340-{\rm{BG}}1}{{\rm{BG}}340-{\rm{BG}}1}/\frac{{\rm{F}}380-{\rm{BG}}2}{{\rm{BG}}380-{\rm{BG}}2}\), where BG1 and BG2 were the fluorescence images obtained in the absence of excitation using filter sets for F340 and F380, respectively, and BG340 and BG380 (control image) were the F340 and F380 images of 10 μM Fura2 potassium salt solution, respectively. For simultaneous imaging of GCaMP2 and Fura2, \({\rm{F}}^{\prime} 480=\frac{{\rm{F}}480-{\rm{BG}}}{{\rm{BG}}480-{\rm{BG}}}\), where BG was the fluorescence image obtained in the absence of excitation using a filter set for F480, BG480 was the F480 image of 10 μM fluorescein, and \({\rm{F}}^{\prime} 380\,=\,\frac{{\rm{F}}380-{\rm{BG}}}{{\rm{BG}}380}\) was used to calculate \(\Delta 480=\frac{F\text{'}480}{{\rm{Fo}}480}\) where Fo480 was the average of five F′480 images before stimulation and \(\Delta (1/380)=1/\frac{F\text{'}380}{{\rm{Fo}}380}\), where Fo380 was the average of five F′380 images before stimulation
Luciferase assay
Astrocytes were equilibrated with BSS at 30 °C for longer than 15 min, pretreated with inhibitors for 10 min, and stimulated by incubation with 100 μl BSS containing inhibitor and stimulus for 10 min. A 50 μl aliquot of the extracellular solution used for stimulation was mixed with 50 μl assay reagent (ATP Bioluminocount Assay Kit CLS II, Sigma-Aldrich) and luciferase activity was measured using a luminometer (GLOMAX 20/20; Promega, Fitchburg, WI).
Materials
18β-Glycyrrhetinic acid, apyrase, ATP, thapsigargin, and U73122 were obtained from Sigma-Aldrich. DCPIB was obtained from Tocris (Bristol, UK); DIDS was from Tokyo Chemical Industry Co. Ltd (Tokyo, Japan); and GPN, vacuolin-1 and Xestospongin C were from Santa Cruz Biotechnology (Dallas, TX). Gap-19 was synthesized (HPLC grade) by MBL (Kyoto, Japan). All other chemicals were from Nacalai (Kyoto, Japan).
Statistical analysis
The values are expressed as mean values ± SD. Differences among the values were analyzed using statistical methods mentioned in Figure Legends and differences with probability (p) values < 0.05 were considered significant.
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Acknowledgements
This work was supported by a Grant-in-Aid for Scientific Research on the Innovative area ‘Cellular and Molecular Basis for Neurovascular Wiring’ (#23122513, Japan), a Grant-in-Aid for Scientific Research (B) (#23300133, Japan), the Smoking Research Foundation (Japan) and the Takeda Science Foundation (Japan). We thank Dr. Junichi Nakai for providing pN1-G-CaMP2. We thank Dr. Mamiko Ozaki (Kobe Univ) for scientific discussion.
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Y.F., S.M. and M.M. designed the study and carried out data acquisition and analysis. Y.F. and M.M. wrote the paper. All authors reviewed the manuscript. M.M. and S.M. wrote the manuscript and Y.F. prepared the figures. All authors reviewed the manuscript.
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Fujii, Y., Maekawa, S. & Morita, M. Astrocyte calcium waves propagate proximally by gap junction and distally by extracellular diffusion of ATP released from volume-regulated anion channels. Sci Rep 7, 13115 (2017). https://doi.org/10.1038/s41598-017-13243-0
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DOI: https://doi.org/10.1038/s41598-017-13243-0
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