Rat cultured astrocytes release guanine-based purines in basal conditions and after hypoxia/hypoglycemia

Brain ischemia stimulates release from astrocytes of adenine-based purines, particularly adenosine, which is neuroprotective. Guanosine, which has trophic properties that may aid recovery following neurological damage, is present in high local concentrations for several days after focal cerebral ischemia. We investigated whether guanine-based purines, like their adenine-based counterparts, were released from astrocytes and whether their release increased following hypoxia/hypoglycemia. HPLC analysis of culture medium of rat astrocytes showed spontaneous release of endogenous guanine-based purines at a higher rate than their adenine-based counterparts. The concentration of guanosine (≈120 nM) and adenosine (≈43 nM) in the culture medium remained constant, whereas concentrations of adenine and guanine nucleotides, particularly GMP, and their metabolites increased with time. Exposure of the cultures to hypoxia/hypoglycemia for 30 min increased the extracellular concentration of adenine-based purines by 2.5-fold and of guanine-based purines by 3.5-fold. Following hypoxia/hypoglycemia extracellular adenine nucleotide levels increased further. Adenosine concentration increased, but not proportionally to nucleotide levels. Accumulation of adenosine metabolites indicated it was rapidly metabolized. Conversely, the concentrations of extracellular guanine-based nucleotides remained elevated and the concentration of guanosine continued to increase. These data indicate that astrocytes are a major source of guanine-based purines, the release of which is markedly increased following hypoxia/hypoglycemia, permitting them to exert neurotrophic effects. GLIA 25:93–98, 1999. © 1999 Wiley-Liss, Inc.     

Mechanisms of apoptosis induced by purine nucleosides in astrocytes

Astrocytes release adenine-based and guanine-based purines under physiological and, particularly, pathological conditions. Thus, the aim of this study was to determine if adenosine induced apoptosis in cultured rat astrocytes. Further, if guanosine, which increases the extracellular concentration of adenosine, also induced apoptosis determined using the TUNEL and Annexin V assays. Adenosine induced apoptosis in a concentration-dependent manner up to 100 microM. Inosine, hypoxanthine, guanine, and guanosine did not. Guanosine or adenosine (100 microM) added to the culture medium was metabolized, with 35% or 15%, respectively, remaining after 2-3 h. Guanosine evoked the extracellular accumulation of adenosine, and particularly of adenine-based nucleotides. Cotreatment with EHNA and guanosine increased the extracellular accumulation of adenosine and induced apoptosis. Inhibition of the nucleoside transporters using NBTI (100 microM) or propentophylline (100 microM) significantly decreased but did not abolish the apoptosis induced by guanosine + EHNA or adenosine + EHNA, respectively. Apoptosis produced by either guanosine + EHNA or adenosine + EHNA was unaffected by A(1) or A(2) adenosine receptor antagonists, but was significantly reduced by MRS 1523, a selective A(3) adenosine receptor antagonist. Adenosine + EHNA, not guanosine + EHNA, significantly increased the intracellular concentration of S-adenosyl-L-homocysteine (SAH) and greatly reduced the ratio of S-adenosyl-L-methioine to SAH, which is associated with apoptosis. These data demonstrate that adenosine mediates apoptosis of astrocytes both, via activation of A(3) adenosine receptors and by modulating SAH hydrolase activity. Guanosine induces apoptosis by accumulating extracellular adenosine, which then acts solely via A(3) adenosine receptors.     

Extracellular conversion of guanine-based purines to guanosine specifically enhances astrocyte glutamate uptake

Guanosine (GUO) has been shown to stimulate glutamate uptake in primary astrocyte cultures. The purpose of this study was to determine the effect and specificity of guanine- or adenine-based purines on glutamate and GABA uptake in cultured astrocytes. Stimulatory effect on glutamate uptake was observed with GUO, GMP or GTP. Simultaneous exposure with these guanine-based purines did not show an additive effect. We also investigated a possible interconversion of guanine-based purines during incubation time. Action by GTP was excluded since the hydrolysis resistant GTP analog, GMP-PNP did not stimulate glutamate uptake. Addition of an ecto-5'-nucleotidase inhibitor abolished GMP-stimulatory effect on glutamate uptake, without affecting GUO action. Taken together, these results suggest that GUO is the guanine-based purines responsible for glutamate uptake activation. In addition, the stimulatory effect on glutamate uptake was not observed with adenine-based purines. Moreover, GABA uptake was not activated by GUO. These results point to specificity in the interaction between GUO and the astrocyte glutamate uptake system.     

Anticonvulsant effect of GMP depends on its conversion to guanosine

Studies on the purinergic system normally deal with adenine-based purines, namely, adenine nucleotides and adenosine. However, a guanine-based purinergic system may also have important neuromodulatory roles. Guanine-based purines exert trophic effects on neural cells, protect brain slices in a model of hypoxia and stimulate glutamate uptake. In vivo, both guanosine 5'-monophosphate (GMP) and guanosine (GUO) protected against seizures. In this study, we investigated if the anticonvulsant effect of GMP is mediated by guanosine and if guanosine or GMP treatments were able to increase adenosine levels. Intraperitoneal (i.p.) treatments with 7.5 mg/kg GMP or guanosine prevented 50% of seizures by quinolinic acid (QA) and increased guanosine cerebrospinal fluid (CSF) levels around twofold and threefold, respectively; GMP and adenosine levels remained unchanged. Intracerebroventricular treatment with 960 nmol GMP prevented 80% of seizures and the 5'-nucleotidase inhibitor alpha-beta-methyleneadenosine 5'-diphosphate (AOPCP), when injected 3 min before, reduced this anticonvulsant effect to 30% protection as well as significantly decreased the conversion of GMP into guanosine measured in the CSF. This study shows that the previously reported effect of GMP as an anticonvulsant seems to be related to its ability to generate guanosine through the action of ecto-5'-nucleotidase.     

Stimulation of astrocyte proliferation by purine and pyrimidine nucleotides and nucleosides

Proliferation of brain astrocytes as a result of cell death has been well documented in vivo. Dying cells release purine and pyrimidine nucleosides and nucle-otides and their deoxy derivatives both from soluble intracellular pools and from DNA and RNA. Previously, we have observed that purine nucleosides and nucleotides stimulate chick astrocyte proliferation in vitro. To further our analysis, we questioned whether pyrimidines or the deoxy derivatives of purine nucleosides and nucleotides might also be astrocyte mitogens. Pyrimidine nucleosides, nucleotides, and their deoxynucleotide derivatives were uniformly inactive. In contrast, deoxyguanosine, deoxyadenosine, and their mono-, di-, and triphosphates stimulated thymidine incorporation into astrocytes at concentrations similar to those at which their ribonucleoside and ribonucleotide analogues were active. Inosine, IMP, ITP, and hypoxanthine were active, whereas xanthine and xanthosine were not. However, XMP, XDP, and XTP stimulated thymidine incorporation. The effects of the nucleosides and deoxynucleosides were inhibited by antagonists of adenosine A₂ receptors. These data indicate that most purine nucleosides, deoxynucleosides, and their 5′ mono, di-, and triphosphate derivatives released from damaged cells are capable of stimulating astrocyte proliferation in vitro and may contribute to astrocyte proliferation in vivo following injury to the CNS.     

Neuroprotective effect of adenine on purkinje cell survival in rat cerebellar primary cultures

Although adenosine or ATP is known to control various physiological functions in the brain, including synaptic transmission, neuronal cell death, and neurite outgrowth via P1 or P2 purinergic receptors in the nervous system, little is known about the functions of many other purine derivatives. We examined the effects of various purines on survival in the cerebellar cortex of Purkinje cells with large cell bodies and highly branched dendrites, and it was found that some purine and pyrimidine derivatives influence Purkinje cell survival. Treatment with adenine, guanine, guanosine, guanine nucleotides, and uracil nucleotides protected Purkinje cells from cell death in the cerebellar primary cultures. Among the effective compounds, adenine had the most potent survival activities on Purkinje cells. Other adenine-based purines such as adenosine, AMP, ADP, and ATP did not promote Purkinje cell survival. Furthermore, metabolic inhibitors of adenine had no effect on the protective ability of adenine for Purkinje cells, suggesting that adenine itself, not adenine metabolites, maintains Purkinje cell survival. These results suggest that adenine is involved in the control of Purkinje cell survival in cerebellar primary cultures via a novel adenine-dependent mechanism.     

Stimulation of reactive astrogliosis in vivo by extracellular adenosine diphosphate or an adenosine A2 receptor agonist

Adenosine and its nucleotides adenosine triphosphate (ATP) and adenosine diphosphate (ADP) stimulate the proliferation of brain astrocytes in vitro and augment the effects of other growth factors. Following brain injury, hypoxia, or around solid tumors with necrotic centers, such as glioblastoma multiformes, high concentrations of adenine nucleotides and adenosine are released into the extracellular space; extracellular adenosine concentrations can rise 30–100-fold to a concentration in excess of 100 μM. Increased concentrations of extracellular adenosine and adenine nucleotides may contribute to reactive astrocytic proliferation following brain injury. To test this hypothesis, adenosine, an adenosine analog 5′-(N-cyclopropyl)-carboxamidoadenosine (CPCA), or ADP was microinjected into rat cortex. The number of glial fibrillary acidic prtein-immunopositive cells was compared between the treated and contralateral saline-injected hemispheres. Within 48 hr, astrocyte density around the CPCA (100 μM) infusion site was almost double that around the control saline infusion site. In hemispheres into which CPCA was infused, there was an increase in astrocytes in the subpial region along fiber tracts and around blood vessels, characteristic of Scherer's secondary structures found in association with malignant astrocytic brain tumors. The increased astrogliosis elicited by CPCA was abolished by coinfusion of the adenosine A₂ receptor antagonist 1,3-dipropyl-7-methylxanthine (DPMX). While microinjection of adenosine (1 mM) failed to stimulate astrogliosis, microinjection of ADP (500 μM) also resulted in a significant reactive astrogliosis and accumulation of astrocytes similar to Scherer's secondary structures. These data indicate that purine nucleosides and nucleotides may play a role in reactive astrogliosis following injury and may also play a role in stimulating the astrocyte migration responsible for Scherer's secondary structures around astrogliomas. © 1994 Wiley-Liss, Inc.     

Hypothesized deficiency of guanine-based purines may contribute to abnormalities of neurodevelopment, neuromodulation, and neurotransmission in Lesch-Nyhan syndrome

The Lesch-Nyhan syndrome is a devastating sex-linked recessive disorder resulting from almost complete deficiency of the activity of hypoxanthine phosphoribosyltransferase (HPRT). The enzyme deficiency results in an inability to synthesize the nucleotides guanosine monophosphate and inosine monophosphate from the purine bases guanine and hypoxanthine, respectively, via the "salvage" pathway and an accelerated biosynthesis of these purines via the de novo pathway. The syndrome is characterized by neurologic manifestations, including the very dramatic symptom of compulsive self-mutilation. The neurologic manifestations may result, at least in part, from a mixture of neurodevelopmental (eg, a failure to "arborize" dopaminergic synaptic terminals) and neurotransmitter (eg, disruption of GABA and glutamate receptor-mediated neurotransmission) consequences. HPRT deficiency results in elevated extracellular levels of hypoxanthine, which can bind to the benzodiazepine agonist recognition site on the GABA(A) receptor complex, and the possibility of diminished levels of guanine-based purines in discrete "pools" involved in synaptic transmission. In addition to their critical roles in metabolism, gene replication and expression, and signal transduction, guanine-based purines may be important regulators of the synaptic availability of L-glutamate. Guanine-based purines may also have important trophic functions in the CNS. The investigation of the Lesch-Nyhan syndrome may serve to clarify these and other important neurotransmitter, neuromodulatory, and neurotrophic roles that guanine-based purines play in the central nervous system, especially the developing brain. A widespread and general deficiency of guanine-based purines would lead to impaired transduction of a variety of signals that depend on GTP-protein-coupled second messenger systems. This is less likely in view of a prominent localized pathologic effect of HPRT deficiency on presynaptic dopaminergic projections to the striatum. A possible more circumscribed effect of a deficiency of guanine-based purines could be interference with modulation of glutamatergic neurotransmission. Guanosine has been shown to be an important modulator of glutamatergic neurotransmission, promoting glial reuptake of L-glutamate. A deficiency of guanosine could lead to dysregulated glutamatergic neurotransmission, including possible excitotoxic damage. Unfortunately, although the biochemical lesion has been known for quite some time (ie, HPRT deficiency), therapeutically beneficial interventions for these affected children and adults have not yet emerged based on this elucidation. Conceivably, guanosine or its analogues and excitatory amino acid receptor antagonists could participate in the pharmacotherapy of this devastating disorder.     

Adenosine released by astrocytes contributes to hypoxia-induced modulation of synaptic transmission

Astrocytes play a critical role in brain homeostasis controlling the local environment in normal as well as in pathological conditions, such as during hypoxic/ischemic insult. Since astrocytes have recently been identified as a source for a wide variety of gliotransmitters that modulate synaptic activity, we investigated whether the hypoxia-induced excitatory synaptic depression might be mediated by adenosine release from astrocytes. We used electrophysiological and Ca2+ imaging techniques in hippocampal slices and transgenic mice, in which ATP released from astrocytes is specifically impaired, as well as chemiluminescent and fluorescence photometric Ca2+ techniques in purified cultured astrocytes. In hippocampal slices, hypoxia induced a transient depression of excitatory synaptic transmission mediated by activation of presynaptic A1 adenosine receptors. The glia-specific metabolic inhibitor fluorocitrate (FC) was as effective as the A1 adenosine receptor antagonist CPT in preventing the hypoxia-induced excitatory synaptic transmission reduction. Furthermore, FC abolished the extracellular adenosine concentration increase during hypoxia in astrocyte cultures. Several lines of evidence suggest that the increase of extracellular adenosine levels during hypoxia does not result from extracellular ATP or cAMP catabolism, and that astrocytes directly release adenosine in response to hypoxia. Adenosine release is negatively modulated by external or internal Ca2+ concentrations. Moreover, adenosine transport inhibitors did not modify the hypoxia-induced effects, suggesting that adenosine was not released by facilitated transport. We conclude that during hypoxia, astrocytes contribute to regulate the excitatory synaptic transmission through the release of adenosine, which acting on A1 adenosine receptors reduces presynaptic transmitter release. Therefore, adenosine release from astrocytes serves as a protective mechanism by down regulating the synaptic activity level during demanding conditions such as transient hypoxia.     

The antiapoptotic effect of guanosine is mediated by the activation of the PI 3-kinase/AKT/PKB pathway in cultured rat astrocytes

Guanosine has many trophic effects in the CNS, including the stimulation of neurotrophic factor synthesis and release by astrocytes, which protect neurons against excitotoxic death. Therefore, we questioned whether guanosine protected astrocytes against apoptosis induced by staurosporine. We evaluated apoptosis in cultured rat brain astrocytes, following exposure (3 h) to 100 nM staurosporine by acridine orange staining or by oligonucleosome, or caspase-3 ELISA assays. Staurosporine promoted apoptosis rapidly, reaching its maximal effect (approximately 10-fold over basal apoptotic values) in 18-24 h after its administration to astrocytes. Guanosine, added to the culture medium for 4 h, starting from 1 h prior to staurosporine, reduced the proportion of apoptotic cells in a concentration-dependent manner. The IC50 value for the inhibitory effect of guanosine is 7.5 x 10(-5) M. The protective effect of guanosine was not affected by inhibiting the nucleoside transporters by propentophylline, or by the selective antagonists of the adenosine A1 or A2 receptors (DPCPX or DMPX), or by an antagonist of the P2X and P2Y purine receptors (suramin). In contrast, pretreatment of astrocytes with pertussis toxin, which uncouples Gi-proteins from their receptors, abolished the antiapoptotic effect of guanosine. The protective effect of guanosine was also reduced by pretreatment of astrocytes with inhibitors of the phosphoinositide 3-kinase (PI3K; LY294002, 30 microM) or the MAPK pathway (PD98059, 10 microM). Addition of guanosine caused a rapid phosphorylation of Akt/PKB, and glycogen synthase kinase-3beta (GSK-3beta) and induced an upregulation of Bcl-2 mRNA and protein expression. These data demonstrate that guanosine protects astrocytes against staurosporine-induced apoptosis by activating multiple pathways, and these are mediated by a Gi-protein-coupled putative guanosine receptor.     

Tyrosine kinase signaling involved in glutamate-induced astrocyte proliferation.

Proliferation of astrocytes is a common response of the CNS to injury and disease. The mechanisms controlling the proliferation of astrocytes are of great interest. In this paper, the signaling pathways underlying glutamate-induced astrocyte proliferation are investigated. Glutamate stimulates the proliferation of non-synchronized, subconfluent cultures of rat cortical astrocytes. Glutamate-induced cell proliferation is not prevented by inhibitors of G protein, protein kinase A, protein kinase C, phosphatidylinositol 3 kinase, extracellular signal-regulated kinase, or phospholipase A2. However, the tyrosine kinase inhibitors Genistein and Herbimycin A inhibit the glutamate-induced proliferation. Moreover, this proliferation is mediated by the activation of glutamate metabotropic receptors. These results suggest that glutamate induces astrocyte proliferation through a tyrosine kinase pathway.     

Light‐controlled astrocytes promote human mesenchymal stem cells toward neuronal differentiation and improve the neurological deficit in stroke rats

Astrocytes are key components of the central nervous system (CNS) and release factors to support neural stem cell proliferation, differentiation, and migration. Adenosine 5'‐triphosphate (ATP) is one of the key factors released upon activation of astrocytes that regulates the neural stem cell's function. However, it is not clear whether ATP derived from the depolarized astrocytes plays a vital role in promoting the neuronal differentiation of mesenchymal stem cells (MSCs) in vitro and in vivo. Herein, for the first time, we co‐cultured MSCs with light‐stimulated‐channelrhodopsin‐2 (ChR2)‐astrocytes, and observed that the neuronal differentiation of MSCs was enhanced by expressing more neuronal markers, Tuj1 and NeuN. The ChR2‐astrocyte‐conditioned medium also stimulated MSCs differentiating into neuronal lineage cells by expressing more Tuj1 and Pax6, which was blocked by the P2X receptor antagonist, TNP‐ATP. Then we found that light‐depolarization of astrocytes significantly increased ATP accumulation in their bathing medium without impairing the cell membrane. We further found that ATP up‐regulated the Tuj1, Pax6, FZD8 and β‐catenin mRNA levels of MSCs, which could be reversed by application of TNP‐ATP. Together these in vitro data provided convergent evidence that ATP from light‐depolarized‐astrocytes activated the wnt/β‐catenin signaling of MSCs through binding to the P2X receptors, and promoted the neuronal differentiation of MSCs. Finally but importantly, our study also demonstrated in stroke rats that light‐controlled astrocytes stimulated endogenous ATP release into the ischemic area to influence the transplanted MSCs, resulting in promoting the MSCs towards neuronal differentiation and improvements of neurological deficit. GLIA 2013;62:106–121     

Microglia modulate gliotransmission through the regulation of VAMP2 proteins in astrocytes

Vesicular release is one of the release mechanisms of various signaling molecules. In neurons, the molecular machinery involved in vesicular release has been designed through evolution to trigger fast and synchronous release of neurotransmitters. Similar machinery with a slower kinetic and a slightly different molecular assembly allows astrocytes to release various transmitters such as adenosine triphosphate (ATP), glutamate, and D‐serine. Astrocytes are important modulators of neurotransmission through gliotransmitter release. We recently demonstrated that microglia, another type of glia, release ATP to modulate synaptic transmission using astrocytes as intermediate. We now report that microglia regulate astrocytic gliotransmission through the regulation of SNARE proteins in astrocytes. Indeed, we found that gliotransmission triggered by P2Y1 agonist is impaired in slices from transgenic mice devoid of microglia. Using total internal reflection fluorescence imaging, we found that the vesicular release of gliotransmitter by astrocytes was different in cultures lacking microglia compared to vesicular release in astrocytes cocultured with microglia. Quantification of the kinetic of vesicular release indicates that the overall release appears to be faster in pure astrocyte cultures with more vesicles close to the membrane when compared to astrocytes cocultured with microglia. Finally, biochemical investigation of SNARE protein expression indicates an upregulation of VAMP2 in absence of microglia. Altogether, these results indicate that microglia seems to be involved in the regulation of an astrocytic phenotype compatible with proper gliotransmission. The mechanisms described in this study could be of importance for central nervous system diseases where microglia are activated.     

Activation of glutamate uptake by guanosine in primary astrocyte cultures

Guanine-based purines have been shown to modulate the effects of glutamate, which is essential for brain function and mediates excitotoxicity. In the search for a mechanism involving the interaction between purine nucleoside guanosine and glutamate, we found that guanosine dose-dependently, significantly (63%) and potently (EC50 =2.47 microM) enhanced glutamate uptake in cultured astrocytes. This effect was not inhibited by the blocker of nucleoside transporter dipyridamole nor by the adenosine antagonist theophylline, suggesting an extracellular site of action without the involvement of adenosine receptors. These results indicate a regulatory role of guanosine on extracellular levels of glutamate, possibly contributing for protecting neural cells against glutamate-induced excitotoxicity.     

Astrocytes as eicosanoid-producing cells

A variety of prostaglandins and leukotrienes, together with thromboxane and prostacyclin metabolites, can be detected in central nervous tissues and in cerebrospinal fluid. Defined cultures of astrocytes have revealed these cells to be a major source of eicosanoids. In common with other eicosanoid-producing cells, agents such as calcium ionophores and phorbol esters are potent stimuli for promoting release. While in other tissues agonists for receptors linked to calcium mobilisation prompt eicosanoid release, this does not seem to be the case in astrocytes, though a range of such receptors are present. The notable exceptions to this observation are adenosine triphosphate and adenosine diphosphate, presumably acting through P2 purinergic receptors. Many cell types in the CNS are targets for eicosanoids, possessing receptors linked to adenylate cyclase or phospholipase C. An appreciation of the functional significance of activation of these receptors is just now beginning. Eicosanoids have effects in the CNS that involve not only the vascular supply but also synaptic modulation and immune regulation.     

L-PGDS (Betatrace Protein) Inhibits Astrocyte Proliferation and Mitochondrial ATP Production in Vitro

L-PGDS is the most abundant protein present in the cerebrospinal fluid (CSF). Although CSF was believed to be homogenous in content, a previous study has showed that a marked concentration gradient of L-PGDS exists between the spinal CSF and the CSF in the subarachnoid space of patients with optic nerve disease (papilledema and normal-tension glaucoma). Astrocytes play a critical role in maintaining the integrity of axon function in the central nervous system and specifically in the optic nerve, and we therefore investigated the biochemical effects of L-PGDS on the proliferation of astrocytes and on the production of adenosine triphosphate (ATP) by astrocyte mitochondria. We found an inhibitory effect of L-PGDS on both proliferation of astrocytes and production of astrocyte ATP. The concentrations that inhibited astrocyte proliferation and ATP production were in the range measured in patients with idiopathic intracranial hypertension and in patients with normal-tension glaucoma. As the CSF is in contact with axons and mitochondria of the optic nerve (Bristow et al. Archives of Ophthalmology, 120, 791–796, 2002), we postulate that a change in the concentration of CSF protein such as L-PGDS could exercise a harmful effect on these structures.     

Adenosine stimulates stellation of cultured rat cortical astrocytes

We investigated the effect of adenosine on astrocyte morphology by using cell cultures prepared from the cerebral cortices of neonatal rats. Cultured rat cortical astrocytes exhibited flattened, polygonal morphology in the absence of stimulation, but differentiated into process-bearing stellate cells in response to adenosine (1–1000 μM). Adenosine-induced astrocyte stellation was abolished by treatment with microtubule inhibitors, colchicine and paclitaxel, indicating the involvement of cytoskeletal elements. The effect of adenosine was mimicked by other adenosine receptor agonists, and blocked by adenosine receptor antagonists and guanosine 5′-O-(2-thiodiphosphate), indicating that the effect of adenosine is mediated by G protein-coupled adenosine receptors. Although adenosine receptors are known to be linked to adenylate cyclase or phospholipase C, adenosine did not change intracellular cyclic AMP level nor intracellular Ca²⁺ concentration in astrocytes. Alternatively, adenosine-induced stellation was abolished by tyrosine phosphatase inhibitors, orthovanadate and phenylarsine oxide, suggesting that adenosine causes astrocyte stellation through tyrosine dephosphorylation. Adenosine may function as a factor regulating astrocyte differentiation.     

Extracellular guanosine increases astrocyte cAMP: inhibition by adenosine A2 antagonists.

Both extracellular guanosine and adenosine stimulated astrocyte proliferation in vitro and increased intracellular cAMP 6-fold within 2 min. The effects of both guanosine and adenosine on proliferation and cAMP levels were inhibited by antagonists of adenosine A2 receptors but augmented by A1 receptor antagonists. The correlation between cAMP accumulation and stimulation of cell proliferation by adenosine and guanosine indicates that increased intracellular cAMP may be one of the second messengers involved in these effects. Guanosine is not an adenosine A2 receptor agonist and does not activate adenylate cyclase. It may exert its effects indirectly by increasing the endogenous extracellular adenosine concentration.     

Mechanisms of glutamate receptor induced proliferation of astrocytes

Astrocytes express mainly metabotropic glutamate receptor 3 and metabotropic glutamate receptor 5 receptor subtypes, which show opposing effects on cellular proliferation upon activation. In this study, we investigated the mechanisms by which activation of these receptors modulates astrocyte proliferation. Activation of metabotropic glutamate receptor 5 with (S)-3,5-dihydroxyphenylglycine increased phospholipase D activity in astrocytes as well as astrocyte proliferation. The 3,5-dihydroxyphenylglycine-induced proliferation was inhibited in the presence of the metabotropic glutamate receptor 5 antagonist (2-methyl-6-(phenylethynyl)pyridine), the protein kinase C inhibitor GF109203X, brefeldin A and 1-butanol. Activation of metabotropic glutamate receptor 3 with (2'S,2'R,3'R)-2-(2',3'-dicarboxycyclopropyl)glycine-IV (DCG-IV) inhibited astrocyte proliferation without affecting metabotropic glutamate receptor 5-mediated phospholipase D activity. Metabotropic glutamate receptor 3 activation, however, only partially inhibited metabotropic glutamate receptor 5-mediated proliferation. In conclusion, metabotropic glutamate receptor 5 stimulates astrocyte proliferation via a protein kinase C-phospholipase D-phosphatidic acid-dependent pathway, whereas metabotropic glutamate receptor 3-mediated inhibition of astrocyte proliferation does not involve phospholipase D, and is independent of metabotropic glutamate receptor 5-mediated effects.     

胶质细胞对共培养的脑微血管内皮细胞增殖及功能的影响

目的 研究体外培养条件下，胶质细胞对脑微血管内皮细胞(BMEC)增殖及功能的影响。方法 模拟血-脑脊液屏障结构及内皮细胞、胶质细胞间相互影响的途径，建立内皮细胞与胶质细胞共培养模型，采用细胞计数、细胞活性检测、酶含量与细胞吞饮量测定对内皮细胞增殖和功能进行研究。结果 共培养和条件培养时，内皮细胞增殖能力减弱，细胞活性以及酶含量增高，细胞吞饮量则无明显变化。结论 胶质细胞可通过两种途径影响内皮细胞的生长。胶质细胞可诱导和维持微血管内皮细胞的脑表型，但并不能促进内皮细胞生长。