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EMBO J. 2009 April 22; 28(8): 1043–1054. Published online 2009 March 19. doi: 10.1038/emboj.2009.45. | PMCID: PMC2664656 |
Copyright © 2009, European Molecular Biology Organization Acid sphingomyelinase activity triggers microparticle release from glial cells Fabio Bianco,1,2* Cristiana Perrotta,3* Luisa Novellino,1* Maura Francolini,1 Loredana Riganti,1 Elisabetta Menna,1 Laura Saglietti,1 Edward H Schuchman,4 Roberto Furlan,5 Emilio Clementi,6,7 Michela Matteoli,1,8 and Claudia Verderio1a 1CNR Institute of Neuroscience and Department of Medical Pharmacology, University of Milano, Milano, Italy 2NeuroZone srl, Milano, Italy 3Hospital of Luigi Sacco, Milano, Italy 4Department of Genetics and Genomic Science, Mount Sinai School of Medicine, New York, NY, USA 5Clinical Neuroimmunology Unit, Institute of Experimental Neurology, S Raffaele Scientific Instute, Milano, Italy 6Medea Science Institute, Bosisio Parini, Italy 7Department of Preclinical Science, LITA-Vialba University of Milano, Milano, Italy 8Fondazione Don Gnocchi, Milano, Italy Received November 21, 2008; Accepted January 29, 2009. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits distribution, and reproduction in any medium, provided the original author and source are credited. This license does not permit commercial exploitation or the creation of derivative works without specific permission. We have earlier shown that microglia, the immune cells of the CNS, release microparticles from cell plasma membrane after ATP stimulation. These vesicles contain and release IL-1β, a crucial cytokine in CNS inflammatory events. In this study, we show that microparticles are also released by astrocytes and we get insights into the mechanism of their shedding. We show that, on activation of the ATP receptor P2X7, microparticle shedding is associated with rapid activation of acid sphingomyelinase, which moves to plasma membrane outer leaflet. ATP-induced shedding and IL-1β release are markedly reduced by the inhibition of acid sphingomyelinase, and completely blocked in glial cultures from acid sphingomyelinase knockout mice. We also show that p38 MAPK cascade is relevant for the whole process, as specific kinase inhibitors strongly reduce acid sphingomyelinase activation, microparticle shedding and IL-1β release. Our results represent the first demonstration that activation of acid sphingomyelinase is necessary and sufficient for microparticle release from glial cells and define key molecular effectors of microparticle formation and IL-1β release, thus, opening new strategies for the treatment of neuroinflammatory diseases. Keywords: A-SMase, glia, IL-1β, microparticles, P2X7
Cells communicate and exchange information by different secreting mechanisms. Among these, extracellular vesicles (exosomes and plasma membrane (PM)-derived microparticles, MPs) are gaining increasing attention as efficient vehicles for the release of signalling molecules. Exosomes are secreted as a result of multivesicular bodies (MVB) fusion with the PM, represent a population of vesicles homogenous in size and shape (40–80 nm). PM-derived MPs represent instead a heterogeneous population of vesicles larger than exosomes (100 nm–1 μm), which bud directly from the PM of healthy cells and contain cytoskeleton and ER elements ( Ratajczak et al, 2006). MPs have high levels of phosphatidylserine (PS) exposed to the outer membrane ( MacKenzie et al, 2001), whereas exosomes have lower PS exposed to the outer membrane leaflet, depending on cell type and stimuli, but over express tetraspanin superfamily of proteins, including CD63 ( Heijnen et al, 1999; Théry et al, 2001; Morelli et al, 2004; Simpson et al, 2008). Both exosomes and MPs control fundamental cellular responses, such as intercellular signalling and immune reactions ( Ratajczak et al, 2006; Simpson et al, 2008). Release of exosomes has received only limited attention in the CNS ( Potolicchio et al, 2005; Fauré et al, 2006; Schiera et al, 2007; Taylor et al, 2007), where these organelles might mediate cell-to-cell transfer of proteins, lipid components or mRNAs, as already demonstrated outside the CNS ( Smalheiser, 2007). So far, regarding MP release in the CNS, there is only one study ( Bianco et al, 2005) showing that microglia release MPs on ATP stimulation. Microglial MPs store and release the inflammatory cytokine IL-1β ( Bianco et al, 2005), a leaderless protein that is not liberated through the default Golgi secreting pathway. Pro-IL-1β is present in MPs 10 min after microglia exposure to ATP, and it is then released into the medium ( Bianco et al, 2005). Besides MPs ( MacKenzie et al, 2001; Bianco et al, 2005), different pathways of secretion mediate IL-1β release in distinct cell types. Among these, release of exosomes ( Qu et al, 2007), exocytose of secretory lysosomes ( Andrei et al, 1999), and direct efflux through PM transporters ( Marty et al, 2005). In microglia, MP shedding is rapidly induced by the activation of the ionotropic ATP receptor P2X 7 (P2X 7R). Activation of the receptor can occur at the site of lesion by ATP leaking from degenerating cells ( Ferrari et al, 1997) or, distantly from the lesion, through propagation of ATP-mediated Ca 2+ wave among astrocytes, a process that has a function in pathological signalling events ( Nedergaard et al, 2003). The P2X 7R is a ligand-gated ATP receptor, which, besides acting as a channel and pore, is known to be coupled to several downstream effectors and protein kinases ( Duan and Neary, 2006). P2X 7R-mediated MP shedding is preceded by exposure of PS at the cell surface, loss of PM asymmetry and formation of membrane protrusions, described in the literature as blebs. Intracellular signalling events required for MP release involve multiple pathways initiated by agonist occupancy of the P2X 7R, including activation of ROCK and p38 MAP kinase (p38 MAPK) ( Morelli et al, 2003; Verhoef et al, 2003), similarly to apoptotic blebbing ( Coleman et al, 2001). However, P2X 7R-induced morphological changes leading to MP release are reversible and not linked to apoptotic cell death ( MacKenzie et al, 2001; Verhoef et al, 2003). How signalling by P2X 7R leads to membrane blebbing is not known. In particular, nothing is known about P2X 7R-induced alterations of the biophysical properties of the PM, which together with actin-cytoskeleton reorganisation are a prerequisite for membrane blebbing and vesiculation at the surface of healthy cells. Blebbing and vesiculation in response to apoptotic stimuli, during the final stages of cell death, depend on breakdown of sphingomyelin (SM), a phospholipid abundant in the outer leaflet of the PM. SM has a high affinity for cholesterol and both lipids are major determinants of membrane fluidity and structural integrity of the PM ( Simons and Ikonen, 1997). SM hydrolysis, catalysed by the enzyme family of sphingomyelinases (SMases), results in increased efflux of cholesterol and increased membrane fluidity ( Slotte et al, 1989; Neufeld et al, 1996), thus inducing membrane destabilisation and facilitating membrane blebbing and MP shedding ( Van Blitterswijk et al, 1982; Chang et al, 1993; Tepper et al, 2000). Therefore, we investigated the role of SMases in P2X 7R-triggered blebbing and found that receptor stimulation leads to the activation of a specific SMase, acid SMase (A-SMase) with rapid SM hydrolysis and MP formation. We also showed the obligatory role of A-SMase in the short term, non-apoptotic process of MP production and showed that A-SMase acts as a P2X 7R effector, downstream of p38 phosphorylation, thus, defining the role of p38 activation in membrane blebbing. P2X7-dependent MP shedding from astrocytes We have earlier shown that stimulation of P2X 7R by ATP or the selective agonist Benzoyl-ATP (BzATP) induces MP shedding from microglia cell surface ( Bianco et al, 2005). In this study, we show that MP shedding occurs also in astrocytes. To study the dynamics of MP formation, we briefly labelled the lipid bilayers of primary cortical astrocytes or glial cell lines with the fluorescent styryl dye FM1–43 or with the fluorophore-conjugated phosphocholine compound NBD C 6-HPC and observed the cells by time-lapse fluorescence video microscopy. By this approach, we observed not only the formation () but also the shedding from the PM of variably sized vesicles on 100 μM BzATP exposure (; Supplementary Movie). To quantify the shedding process, supernatant of glial cells exposed to BzATP for 20 min were pelleted at 10 000 g, to separate MPs as pellet ( Heijnen et al, 1999). Fluorescence of pelleted MPs was then quantified by spectrophotometric analysis ( Supplementary Figure 1; see also ). Several perturbants were tested for their effects on MP shedding, including the P2X 7 antagonists Brilliant Blue G (100 nM) and KN-62 (10 μM), the P2X 2,4 antagonist TNP-ATP (3 nM), the Rho-effector kinase inhibitor Y-27632 dihydrochloride (100 μM) and the actin polymerisation inhibitor cytochalasin D (2 μg/ml), as well as perturbants of Ca 2+ homeostasis, such as the Ca 2+ chelators EDTA (500 μM) and BAPTA (30 μM) and the Ca 2+ ionophore ionomycin (10 μM). Phorbol ester PMA (1 μM) was also used as positive control for the shedding process. The results of this analysis indicated that BzATP-induced MP shedding in astrocytes requires both P2X 7R activation and cytoskeleton reorganisation, and it is dependent on both extracellular and cytoplasmic Ca 2+ (). Time course analysis of MP release in the medium indicated a gradual increase that is already significant 5 min after P2X7R stimulation reaching a plateau after 20 min (). Consistent with these data, time-lapse video microscopy indicated that MP shedding starts in about 1 and 2 min after P2X7R activation and persists for several minutes in the continuous presence of the receptor agonist (not shown). Biochemical and morphological characterisation of distinct types of vesicles released from glial cells To define the nature of fluorescent MPs shed from the PM distinguishing them from exosomes, we analysed the size and molecular features of both extracellular vesicle populations, MPs and exosomes, released from glial cells under these conditions. To this aim, the supernatants of glial cells were subjected to differential centrifugation ( Supplementary data) followed by negative staining electron microscopy, fluorescence microscopy and western blotting analysis. By this combined approach, we could analyse also small vesicles pinching off from the PM and exosomes that could not be sized at video microscopy resolution. Vesicles of distinct sizes were detected by negative staining electron microscopy in the P2 (1200 g), P3 (10 000 g) and P4 (110 000 g) pellets. The P4 pellet consisted of cup-shaped vesicles in the range of 30–80 nm, corresponding to exosome size, whereas the P3 and P2 pellets contained relatively larger vesicles, characterised by a mean diameter of 155±6 and 426±51 nm, respectively (). Similar results were obtained with N9 microglia ( Supplementary Figure 2A). Given that PM-derived MPs, differently from exosomes, present high levels of PS exposed to the outer membrane, we used this information to further characterise P2–P4 populations. Vesicles present in P2, P3 and P4 pellets were imaged by fluorescence microscopy after incubation with NBD C 6-HPC (3 μM), to stain vesicle membrane, or with FITC-annexin V (4.2 μg/ml), indicative of the presence of PS on the outer membrane. We found that PS is exposed on the surface of P2 and P3 but not P4 vesicles, thus, suggesting that P2 and P3 MPs mainly derive from PM blebbing. Although optical resolution is approximately 200 nm, we excluded that the lack of annexin V signal in P4 vesicles was due to resolution limits, as P4 vesicles could be visualised, although not sized, when treated with NBD (; Supplementary Figure 2B). Indeed quantitative analysis of annexin V binding to vesicles by flow cytometry analysis (FACS) indicated the presence of PS on the outer membrane in 70% P2, 36% P3 but only 5% of P4 vesicles (). P2–P4 vesicles were also analysed by western blotting ( Supplementary data; ; Supplementary Figure 2D), and/or fluorescence microscopy () for some PM and exosome markers, to further characterise the nature of P2–P4 vesicles. Typical exosome markers, such as CD63 and heat shock protein HSP70 were clearly found in the P4 pellet, identifying P4 vesicles as exosomes. Few CD63 positive MPs were also present in P3 fraction (), although not detectable by western blotting (), probably due to the lower sensitivity of the antibody in immunoblotting than in immunocytochemistry. Conversely, P2 and P3 vesicles were positive for different PM markers including the cannabinoid receptor CB1, the glutamate transporter GLAST and Na +/K + ATPase (; Supplementary Figure 2D). However, only CB1, among PM markers, was exclusively detected in P2 and P3 MPs ( Supplementary Figure 2D). Both Na +/K + ATPase and GLAST were indeed detectable also in the P4 exosome fraction (). This finding is consistent with the presence in exosomes of specific cell-surface proteins including integrins and cell adhesion molecules ( Smalheiser, 2007). We then evaluated which vesicle populations mediate IL-1β in astrocytes. Notably, western blotting of P2–P4 fractions for IL-1β indicated that the bulk of the pro-cytokine is present in PM-derived MPs pelleted in the P2 fraction. This analysis was carried out in both astrocytes () and N9 microglial cells ( Supplementary Figure 2D) exposed to BzATP for 15 min, a time point when about 80% of the released cytokine is detected inside MPs having PS on the membrane ( Bianco et al, 2005). Overall, these results clearly indicate that PM-derived MPs and not exosomes mainly contributes to IL-1β release from glial cells. A-SMase is enriched in glia-derived MPs SMases catalyse the hydrolysis of SM into ceramide and phosphorylcholine thus controlling PM fluidity. Three forms of SMases with an optimal acidic, neutral, or alkaline pH have been described ( Gulbins et al, 2000). Among SMases, A-SMase is activated rapidly on stimulation of various receptors, being recruited to the PM to mediate receptor-dependent signalling ( Grassmé et al, 2001; Gulbins, 2003; Marchesini and Hannun, 2004). To investigate whether A-SMase may be involved in the P2X 7R-induced budding and release of MPs, we evaluated by western blotting the expression of A-SMase in MPs released from glial cells, isolated either by differential centrifugation (; Supplementary Figure 2D) or by binding to annexin V coated beads (), a method that allows selective enrichment of MPs exposing PS ( Supplementary data). A significant enrichment of A-SMase in the PM-derived MPs was observed as compared with glial lysates. A-SMase mediates P2X7R-dependent MP shedding To investigate the specific involvement of A-SMase in MP production, we directly measured A-SMase activity in microglia exposed for different time points to BzATP. Kinetic analysis of A-SMase activity revealed a peak of enzyme activity at 2 min after agonist addition (), indicating that the enzyme acts as a downstream effector of the receptor. Although A-SMase activation period is shorter than that of MP release (), it is plausible that increased generated ceramide has long-lasting effects on membrane fluidity required for P2X7-dependent blebbing. Activation of A-SMase by P2X7R was accompanied by enzyme translocation to the PM outer leaflet, as shown by the increased A-SMase staining detected by FACS in intact cells (). A-SMase translocation to the PM outer leaflet on P2X7R activation was confirmed by biotynilation and western blotting experiments that revealed surface expression of the enzyme in cultured astrocytes during BzATP exposure (). Finally, A-SMase translocation was also suggested by movement of the enzyme from the exosomal fraction (P4) to PM-derived fractions, P2 and P3, on BzATP stimulation of microglial cells (). Interestingly, FACS analysis of intact P2, P3 and P4 vesicles for A-SMase revealed immunoreactivity for the enzyme in P2 and P3 but not in P4 pellet (). P4 vesicles were negative for outer A-SMase also under non-stimulating conditions (not shown), when these vesicles have highest luminal concentration of the enzyme (). These results, together with the presence of A-SMase in P4 fraction ( and ), indicated both association of the enzyme to the outer leaflet of MPs and luminal localisation of A-SMase in exosomes. Furthermore, FACS experiments on intact vesicles doubled labelled with A-SMase and annexin V revealed that A-SMase immunoreactivity represented 87±5% of total MPs exposing PS (not shown), indicating that the presence of the enzyme on MPs is instrumental for vesicle budding from PM. To investigate whether A-SMase activity could facilitate formation of membrane protrusions and membrane vesiculation, microglia were exposed to exogenous recombinant SMase (r-SMase), which has an acid pH optima and displays little activity at neutral pH. Spectrophotometric quantification of the amount of MPs shed on exposure to r-SMase revealed that the enzyme is by itself sufficient to stimulate MP shedding. Similar results were obtained when astrocytes were exposed to bacterial SMase (b-SMase), thus indicating that ceramide generation is the key player in the shedding process (). Consistent with the activation of the enzyme downstream of P2X7R, cell exposure to r-SMase also triggered MP shedding either in a P2X7-deficient microglial cell clone () or when P2X7R activation was prevented by specific antagonists, such as KN-62 (). To directly prove the involvement of endogenous A-SMase in MP shedding, we then evaluated the effects of the A-SMase inhibitor imipramine (10 μM) on the amount of MPs. A clear inhibition of MP shedding from astrocytes () and microglia ( Supplementary Figure 3A) was detected with imipramine. No inhibitory effect was instead observed in cultures treated with inhibitors of neutral SMase (N-SMase) such as manumicyn (1 μM) or GW4869 (5 μM), which has been recently described to control exosome release ( Trajkovic et al, 2008). Given that imipramine is not very specific for A-SMase and can interfere with other enzyme activities, the role of A-SMase in vesicle shedding was also proven in astrocyte cultures established from A-SMase heterozygous or knockout (KO) mice (). MP shedding was completely abolished in astrocytes from A-SMase KO and significantly reduced in astrocytes from heterozygous mice as compared with wild-type cultures (). Addition of r- or b-SMase efficiently induced MP shedding in KO astrocytes, as well as in heterozygous cultures, further indicating that SMase activity is sufficient to induce release of PM-derived MPs. A-SMase activity mediates P2X7-dependent IL-1β release We then examined whether pharmacological inhibition of A-SMase activity or genetic deficiency of A-SMase could affect IL-1β release from either microglia or cortical astrocytes, which also release the cytokine on BzATP stimulation (Bianco et al, unpublished data). ELISA of IL-1β levels in the supernatants from cells pre-treated with imipramine indicated a strong reduction of cytokine release (; Supplementary Figure 3B). Furthermore, IL-1β release was completely abolished or strongly reduced in astrocyte cultures prepared from A-SMase KO or heterozygous mice, respectively (). Although an IL-1β expression reduction of about 50% was detected by optical density analysis in astrocyte homogenates from A-SMase KO cultures as compared with controls ( for an example of western blotting), exposure to r- or b-SMases partially restored BzATP-induced IL-1β release (), thus, excluding that block of cytokine secretion depends on non-specific effects in A-SMase KO astrocytes. These data clearly indicate that A-SMase activity has an important function in IL-1β release by controlling P2X 7-dependent vesiculation. Src kinase-dependent phosphorylation of p38 MAPK is involved in P2X7-induced A-SMase activation P2X 7R is a ligand-gated ion channel, which induces the opening of large membrane pores, recently identified as pannexin-1 hemichannels ( Pelegrin and Surprenant, 2006, 2007; Locovei et al, 2007). Independently of the molecular entity of the pore, several pieces of evidence indicate that P2X 7-induced pore formation requires activation of p38 MAPK cascade ( Suzuki et al, 2004). We observed by western blotting that a brief BzATP exposure induces a prompt p38 MAPK phosphorylation in microglia (not shown) and cortical astrocytes (). p38 phosphorylation peaked 2–5 min after receptor stimulation and then slowly declined, being still above control levels 30 min after agonist addition. BzATP-induced p38 phosphorylation was prevented by the p38 specific inhibitor SB-203580 (400 nM, ), by the kinase inhibitor genistein (50 μM, ), and the src-kinase inhibitor PP2 (10 μM, not shown), indicating that p38 phosphorylation is mediated by an src-kinase family member, as suggested previously ( Suzuki et al, 2004). BzATP-induced p38 activation was independent of the channel activity of the receptor, as it efficiently occurred also in the absence of extracellular Na + and Ca 2+ and in the presence of high extracellular K + ions (). Consistent with the involvement of an src-family protein kinase in P2X 7-mediated p38 activation, exposure of astrocytes to BzATP in the presence of either PP2, genistein as well as SB203580 failed to induce pore opening, as assayed by YO-PRO-1 uptake (). To evaluate whether P2X7-mediated p38 phosphorylation and large pore formation could be relevant for A-SMase activation and vesiculation, A-SMase activity and MP shedding were analysed in microglial cells pre-treated with inhibitors of the p38 cascade. Inhibition of p38 strongly reduced A-SMase activity in microglia () as well as the enzyme translocation to the PM (), thus indicating that A-SMase activation and membrane recruitment occur downstream of P2X7-mediated p38 phosphorylation. As a consequence, MP shedding from either microglia (not shown) or cortical astrocytes () pre-exposed to either SB-203580, genistein or PP2 was strongly reduced. No significant attenuation of MP shedding was induced by the ERK1/2 inhibitor U126 (10 μM) (). Moreover, IL-1β detection by ELISA on supernatants of astrocytes treated with SB-203580, PP2 or genistein revealed a strong reduction of cytokine release, thus indicating a clear involvement of p38 cascade in the process of cytokine release (). We then investigated whether p38-dependent activation of A-SMase could be involved in P2X 7-induced pore formation. An efficient YO-PRO-1 uptake was observed in microglial pre-treated with imipramine (; Supplementary data), indicating that A-SMase inhibition does not alter the capability of P2X 7R to open large membrane pores. Accordingly, no significant differences in YO-PRO-1 uptake kinetics were detected in astrocytes from A-SMase KO and heterozygous mice as compared with astrocytes from wild-type animals (). These data suggest that MP shedding and pore opening are two P2X 7-dependent processes that are regulated by two parallel pathways, downstream of p38 phosphorylation (). A-SMase is required for MP shedding in glial cells In this study, we show that P2X7-dependent shedding of PM-derived MPs is not restricted to microglia in the brain, as also astrocytes can shed MPs containing IL-1β. Glia-derived MPs present in the CNS, besides containing leaderless molecules relevant for neuroinflammation, could also represent a general mechanism used for signalling to other cells, such as neurons, through the intercellular transfer of protein/lipid components. All these reasons prompted us to further investigate the molecular mechanisms involved in glial MP formation and shedding. Here, we show that budding and shedding of MPs is triggered by P2X 7R stimulation that activates and recruits A-SMase. Of note, these results are consistent with previous evidence supporting a role of SMases in the budding of vesicles from microspheres ( Nurminen et al, 2002), budding of exosomes into MVB ( Trajkovic et al, 2008) and in apoptotic blebbing ( Tepper et al, 2000), and with recent observation that P2X 7R activation induces ceramide accumulation ( Lepine et al, 2006). Both apoptotic blebbing and budding of exosomes into MVB result, however, from the activation of N- rather than A-SMase. The role of N-SMase in exosome release from oligodendrocytes ( Trajkovic et al, 2008), together with the involvement of A-SMase in MP formation from glial cells (this study), indicate that different members of the SMase family specifically control the release of distinct populations of extracellular vesicles in the CNS. Here, we provide evidence of a causal relationship between A-SMase activity and MP shedding and show that A-SMase is both sufficient and necessary for the shedding process in glial cells. First, A-SMase becomes promptly activated and translocated onto the PM on P2X7R stimulation, and the time course of its activation is consistent with that of MP shedding. Second, addition of exogenous r-SMase efficiently stimulates MP shedding, also in P2X7-deficient microglia or in cells where the receptor activation is pharmacologically prevented. Finally, evidence obtained in cultures from KO mice indicates that absence of A-SMase completely abolishes MP release, which can be, however, rescued by addition of exogenous r- or b-SMase. Although the complex changes in lipid storage and cholesterol trafficking consequent to A-SMase absence need further investigation, our results rule out the possibility that block of MP release may be caused by secondary non-specific problems of KO animals. Up to 90% of SM is localised in the outer membrane leaflet ( Koval and Pagano, 1991), thus, it is fully accessible for the enzyme shifted into the membrane. However, if SM is hydrolyzed extracellularly, ceramide has to redistribute within the lipid bilayer, as clustering of ceramide into the inner leaflet, due to the spontaneous negative curvature of the lipid, can facilitate formation of PM protrusions ( Goni and Alonso, 2006). Previous studies have shown that A-SMase may have an extracellular action, as showed by the enzyme secretion and the capability to move onto the cell surface in response to such stimuli such as CD95 or Pseudomonas aeruginosa infection ( Grassmé et al, 2001). Enrichment of A-SMase in MPs suggests that formation of membrane protrusions occurs from specific PM domains, the so-called lipid rafts, where accumulation of ceramide by local translocation of A-SMase can promote the enlargement of these domains ( Garcia-Marcos et al, 2006) and facilitate membrane blebbing. In such domains, cytoskeleton/membrane proteins, possibly directly interacting with the P2X 7R- and P2X 7R-dependent signalling components, could be recruited. Interestingly, a domain analogous to the TNFR1 death domain has been described in the C-terminus of the P2X 7R, which could target the receptor to lipid rafts. P2X7-induced signalling pathway of MP shedding This study provides novel insights into the signalling pathway downstream of P2X 7Rs, which regulates MP shedding in glial cells. Our data support a model () in which, among the multiple intracellular signals coupled to P2X 7R, p38 MAPK cascade is required for the shedding process; indeed we found that P38 becomes promptly phosphorylated on P2X 7R activation, also in the absence of extracellular Na + and Ca 2+ and in high extracellular K +, indicating that P2X 7R regulates p38 activation by a metabotropic pathway independent of the channel function of the receptor. Inhibition of p38 phosphorylation by PP2 indicates the involvement of an src-protein tyrosine kinase as a link between P2X 7R and p38, as also suggested by Suzuki et al (2004). The Src homology 3 (SH3) domains of these soluble kinases may well interact with the SH3-binding motif present in the C-terminus of the P2X 7R ( Denlinger et al, 2001). P-p38 induces translocation of endogenous A-SMase into the outer membrane leaflet and stimulates the enzyme activity, thus, inducing SM breakdown and ceramide generation. Although how P-p38 can induce A-SMase translocation and activation remains to be completely elucidated, our data clearly indicate that P-p38 acts upstream of A-SMase activity. P2X7-induced vesicle shedding and large pore opening So far controversial results have been published concerning P2X 7-dependent p38 activation, opening of large membrane pores and release of IL-1β. In THP-1 monocytes, p38 inhibition does not alter IL-1β release although it inhibits large pore opening ( Donnelly-Roberts et al, 2004). Inhibition of pore formation by p38 blockers has also been reported in peritoneal macrophages ( Faria et al, 2005), whereas no effect has been detected in peripheral macrophages ( Da Cruz et al, 2006). Our data indicate that YO-PRO uptake is blocked by agents that interfere with p38 cascade, downstream of P2X 7R. Recently, the large pore that opens on P2X 7R activation has been identified with pannexin-1, a membrane protein that forms gap junctions when expressed in oocytes and epithelial cells. Blockade of pannexin-1 abolishes caspase-1 processing and IL-1β release, thus, indicating a role of pannexin-1 in cytokine processing and secretion ( Pelegrin and Surprenant, 2006, 2007). However, P2X 7R-mediated, pannexin-1-dependent dye uptake is unlikely responsible for caspase-1 activation and IL-1β processing, because dye uptake occurs in high extracellular K +, when IL-1β release is abrogated ( Pelegrin and Surprenant, 2007). Our finding that A-SMase inhibitors and genetic deficiency of A-SMase do not affect the ability of the P2X 7R to induce dye uptake, while strongly inhibiting the cytokine release, further confirms that pore opening is not directly involved in IL-1β processing and release. Pore opening and IL-1β release through MP shedding are, in fact, two parallel events occurring downstream of P2X 7R-dependent p38 phosphorylation (). Furthermore, although P2X 7R-dependent p38 phosphorylation (this study) and blebbing do not require ion influx through the receptor, extracellular Ca 2+ is necessary for MP shedding ( MacKenzie et al, 2001; Bianco et al, 2005) and processing of IL-1β, at least in some cell types as microglia and monocytes ( Brough et al, 2003; Gudipaty et al, 2003). Imipramine, an old drug for inhibiting IL-1β release in brain pathologies? Other pathways besides MP shedding have been proposed to mediate IL-1β release from monocytes/macrophages, including exocytosis of secretory lysosomes and exosomes ( Andrei et al, 1999; Qu et al, 2007). Complete blockade of MP shedding and IL-1β release from A-SMase KO astrocytes indicates that release of MPs from PM represents the major mechanism mediating secretion of the cytokine from glial cells. Concerning the possible contribution of secretory lysosomes, although it has been recently reported that IL-1β release is not affected in macrophages isolated from mice carrying a mutated Lyst gene, which have impaired lysosomal secretion ( Brough and Rothwell, 2007), our results do not allow to exclude the contribution of these organelles to the cytokine release. Consistent with the role of A-SMase in IL-1β secretion, reduced levels of IL-1β have been reported in the brain of A-SMase KO mice ( Ng and Griffin, 2006), although A-SMase might not be necessary for the cytokine release outside the nervous system ( Grassmé et al, 2003). Under this respect it might be tempting to speculate that the increased frequency of infections observed both in A-SMase KO animals and in patient affected with Niemann Pick type A and B diseases ( Minai et al, 2000; Ikegami et al, 2003) might be related with the capability of A-SMase to control cytokine release ( Leventhal et al, 2001) and consequently to regulate the immune responses. A-SMase can, therefore, represent a new suitable target for the pharmacological treatment of pathologies, like multiple sclerosis (MS), where IL-1β is implicated. Previous studies have described that interference with the IL-1β-mediated inflammatory pathway has a positive outcome in experimental autoimmune encephalomyelitis (EAE) mice, a well-characterised model of MS ( Martin and Near, 1995; Wiemann et al, 1998; Furlan et al, 1999). Interestingly, the antidepressant drug imipramine, besides improving depression symptoms ( Pollak et al, 2002), was found to reduce EAE-mice mortality and body weight loss. Our study, showing that imipramine, which is also a A-SMase inhibitor, blocks release of IL-1β vesicles by hampering A-SMase mediated MP shedding, defines the possible molecular mechanisms underlying previous observations in EAE-mice. Given that the efficacy of current therapies for MS is rather limited and is mainly aimed at slowing the progression of the disease, the present identification of imipramine, a widely used tricyclic antidepressant, as a potent blocker of IL-1β release could be of great relevance as a starting point to identify more efficacious drugs for the pharmacological treatment for this pathology. Cell cultures and cell stimulation Vesicle isolation by differential centrifugation Quantification of PM-derived MPs Fluorescence microscopy of vesicles P2, P3 and P4 pellets were obtained from BzATP-stimulated, confluent astrocytes or N9 cells by differential centrifugation and stained as described in Supplementary data. FACS analysis P2, P3 and P4 pellets were obtained from BzATP-stimulated, confluent astrocytes (24 × 10 6 cells) or confluent N9 cells (42 × 10 6 cells) by differential centrifugation and analysed as described in Supplementary data by a FacsCalibur flow cytometer (Becton Dickinson). Analysis of surface A-SMase in intact cells by FACS was carried out as described in Supplementary data. A-SMase cell surface labelling and immunoprecipitation Analysis of A-SMase cell surface exposure was carried out by biotinylation and subsequent western blotting as described in Supplementary data. Electron microscopy of vesicles P2, P3 and P4 pellets from BzATP-stimulated astrocytes or N9 cells were fixed with 4% paraformaldehyde in PBS for 12 h at 4°C and processed for negative staining electron microscopy ( Supplementary data). Measurement of A-SMase activity IL-1β ELISA Cells were primed for 6 h with 100 ng/ml LPS. A mouse IL-1β ELISA kit (Pierce Endogen, Italy) was used to quantify the presence of IL-1β in the supernatant of astrocytes and microglia cells stimulated with 100 μM BzATP. Chemicals and antibodies For chemicals see Supplementary data. Rabbit Ab versus ribophorin (1:2000) were kindly provided by Dr Kreibich (New York University, New York, NY, USA). Mouse Ab versus Na +/K + ATPase (1:5000) and rabbit Ab versus GLAST N-epitope (1:150) were provided by Dr Pietrini, University of Milan, Italy. Rabbit Ab versus P-p38 MAPK (1:400) was from Cell Signalling Technology (USA) and goat Ab versus IL-1β (1:1000) was from R&D (USA). The anti-A-SMase rabbit polyclonal Ab (1:500) was generated in the lab and described in Perrotta et al (2007). Example of specificity of this Ab in western blotting is shown in Supplementary Figure 4. Mouse monoclonal anti-HSP70 Ab (BRM-22 clone, 1:1000) and mouse monoclonal GFAP Ab (G-A-5 clone, 1:1000) were from Sigma. Goat polyclonal anti-CD63/LAMP3 Ab (clone M-13, 1:50) was from Santa Cruz Biotech. Rabbit polyclonal anti-Cathepsin B Ab (1:200) was from Chemicon. Rabbit polyclonal anti-CB1 Ab (1:500) was kindly provided by Dr Mackie, University of Washington, Seattle, USA. Statistical analysis All data are presented as means±s.e. from the indicated number of experiments. Statistical significance was evaluated using either Student's t-test or one-way ANOVA analysis of variance. The differences were considered to be significant if P<0.05 and are indicated by an asterisk; those at P<0.01 are indicated by double asterisks. 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