Neuronal Soluble Factors Differentially Regulate the Expression of the GLT1 and GLAST Glutamate Transporters in Cultured Astroglia

Abstract: The glutamate transporters in the plasma membranes of neural cells secure termination of the glutamatergic synaptic transmission and keep the glutamate levels below toxic concentrations. Astrocytes express two types of glutamate transporters, GLAST (EAAT1) and GLT1 (EAAT2). GLT1 predominates quantitatively and is responsible for most of the glutamate uptake activity in the juvenile and adult brain. However, GLT1 is severely down-regulated in amyotrophic lateral sclerosis, a progressive neurodegenerative disease. Furthermore, selective loss of this transporter occurs in cultured astroglia. Expression of GLAST, but not of GLT1, seems to be regulated via the glutamate receptor signalling. The present study was undertaken to examine whether neuronal factors, other than glutamate, influence the expression of astroglial glutamate transporters. The expression of GLT1 and GLAST was examined in primary cultures of cerebellar granule neurons, cortical neurons, and astrocytes under different experimental conditions, including those that mimic neuron-astrocyte interactions. Pure astroglial cultures expressed only GLAST, whereas astrocytes grown in the presence of neurons expressed both GLAST (at increased levels) and GLT1. The induction of GLT1 protein and its mRNA was reproduced in pure cortical astroglial cultures supplemented with conditioned media from cortical neuronal cultures or from mixed neuron-glia cultures. This treatment did not change the levels of GLAST. These results suggest that soluble neuronal factors differentially regulate the expression of GLT1 and GLAST in cultured astroglia. Further elucidation of the molecular nature of the secreted neuronal factors and corresponding signalling pathways regulating the expression of the astroglial glutamate transporters in vitro may reveal mechanisms important for the understanding and treatment of neurological diseases.     

Neuronal-induced and glutamate-dependent activation of glial glutamate transporter function

The activity of high-affinity glutamate transporters is essential for the normal function of the mammalian central nervous system. Using a combined pharmacological, confocal immunocytochemical, enzyme-based microsensor and fluorescence imaging approach, we examined glutamate uptake and transporter protein localization in single astrocytes of neuron-containing and neuron-free microislands prior to pre-synaptic transmitter secretion and during functional neuronal activity. Here, we report that the presence or absence of neurons strikingly affects the uptake capacity of the astroglial glutamate transporters GLT1 and GLAST1. Induction of transporter function is activated by neurons and this effect is mimicked by pre-incubation of astrocytes with micromolar concentrations of glutamate. Moreover, increased glutamate transporter activation is reproduced by endogenous release of glutamate via activation of neuronal nicotinic receptors. The increase in transport activity is dependent on neuronal release of glutamate, is associated with the local redistribution (clustering) of GLT1 and GLAST1 but is independent of transporter synthesis and of glutamate receptor activation. Together, these results suggest an activity-dependent neuronal feedback system for rapid astroglial glutamate transporter regulation where neuron-derived glutamate is the physiological signal that triggers transporter function.     

Plasma membrane expression of the neuronal glutamate transporter EAAC1 is regulated by glial factors: evidence for different regulatory pathways associated with neuronal maturation

At the glutamatergic synapse the neurotransmitter is removed from the synaptic cleft by high affinity amino acid transporters located on neurons (EAAC1) and astrocytes (GLAST and GLT1), and a coordinated action of these cells is necessary in order to regulate glutamate extracellular concentration. We show here that treatment of neuronal cultures with glial soluble factors (GCM) is associated with a redistribution of EAAC1 and GLAST to the cell membrane and we analysed the effect of membrane cholesterol depletion on this regulation.

In enriched neuronal culture (90% neurons and 10% astrocytes), GCM treatment for 10 days increases EAAC1 and GLAST cell surface expression with no change in total expression. In opposite, GLT1 surface expression is not modified by GCM but total expression is increased. When cholesterol is acutely depleted from the membrane by 10 mM methyl-beta-cyclodextrin (β5-MCD, 30 min), glutamate transport activity and cell surface expressions of EAAC1 and GLAST are decreased in the enriched neuronal culture treated by GCM. In pure neuronal culture addition of GCM also increases EAAC1 cell membrane expression but surprisingly acute treatment with β5-MCD decreases glutamate uptake activity but not EAAC1 cell membrane expression. By immunocytochemistry a modification in the distribution of EAAC1 within neurons was undetectable whatever the treatment but we show that EAAC1 was no more co localized with Thy-1 in the enriched neuronal culture treated by GCM suggesting that GCM have stimulated polarity formation in neurons, an index of maturation.

In conclusion we suggest that different regulatory mechanisms are involved after GCM treatment, glutamate transporter trafficking to and from the plasma membrane in enriched neuronal culture and modulation of EAAC1 intrinsic activity and/or association with regulatory proteins at the cell membrane in the pure neuronal culture. These different regulatory pathways of EAAC1 are associated with different neuronal maturation stages.     

Developmental expression and activity of high affinity glutamate transporters in rat cortical primary cultures

The expression and activity of glutamate transporters (EAAC1, GLAST and GLT1) were examined during the development of cortical neuron-enriched cultures. Protein content and mitochondrial respiration both increased during the first 7 days, later stabilized and decreased from DIV14. Glutamate transport and extracellular concentration were relatively constant from DIV3 to 18. The kinetic parameters of glutamate transport were at DIV7:K_m=19±3 μM and V_max=1068±83 pmol/mg protein/min and at DIV14: K_m=40.8±9.3 μM and V_max=1060±235 pmol/mg protein/min. The shift in K_m towards higher values suggest a more important participation of GLAST after DIV14. At DIV7 and 14, glutamate transport was poorly sensitive to dihydrokaïnate (DHK) suggesting a weak participation of GLT1 in glutamate transport. Western blot experiments and immunocytochemistry showed that EAAC1 was expressed by neurons whatever the stage of the culture. GLAST was found in astrocytes as soon as DIV3 and labeling increased during the development of the culture. There was little neuronal GLT1 immunoreactivity at DIV7, only detected by immunocytochemistry. From DIV10 to 18, an increasing astrocytic expression of GLT1 was observed, also detected by Western blotting. These results show that: (1) glutamate uptake remains stable all along the development of the cultures although the pattern of expression of the different transporters is changing, suggesting that glutamate transport is highly regulated; (2) neuronal EAAC1 may play a critical role during the early stages of the culture when it is expressed alone; and (3) the developmental expression pattern of glutamate transporters in cortical neuron-enriched cultures is quite similar to that observed in vivo during early postnatal development.     

GLT1, glial glutamate transporter, is transiently expressed in neurons and develops astrocyte specificity only after midgestation in the ovine fetal brain.

Glutamate transport is a primary mechanism for regulating extracellular levels of glutamate in the central nervous system. GLT1, the most abundant of the known high-affinity glutamate transporters, is found exclusively in astrocytes in adult brain of several species, but we and others have recently identified neurons that transiently express GLT1 protein in the developing brain. We now demonstrate the development of cell type specificity for GLT1 expression at 60, 71, and 136 days' gestation in the developing sheep brain (term = 145 days). At 60 and 71 days of gestation, GLT1 colocalizes with calbindin in Purkinje cells in the cerebellum, and this expression pattern has a novel distribution that is reminiscent of the parasagittal zebrin-like bands. GLT1 immunoreactivity simultaneously occurs in periventricular white matter, anterior commissure, and striatal white matter, dissipating by 136 days. GLT1 protein expression within astrocytes is developmentally regulated, appearing first in vimentin positive radial glia at 60 and 71 days and then switching to GFAP positive parenchymal and perivascular astrocytes at 136 days. Expression of GLT1 in subsets of vimentin-positive astrocytes persists in white matter but not in cortex. These results identify a novel compartmentation within cerebellar cortex and neuronal and axonal pathway localization of GLT1, suggesting the participation of this glutamate transporter in the development of the topographic organization of cerebellar cortex and a transient neuronal function for GLT1 in developing brain. In addition, GLT1 expression is highly plastic, being neither exclusively astroglial nor uniformly expressed in different populations of astrocytes during brain development.     

The GLT-1 and GLAST glutamate transporters are expressed on morphologically distinct astrocytes and regulated by neuronal activity in primary hippocampal cocultures

The GLT-1 and GLAST astroglial transporters are the glutamate transporters mainly involved in maintaining physiological extracellular glutamate concentrations. Defects in neurotransmitter glutamate transport may represent an important component of glutamate-induced neurodegenerative disorders (such as amyotrophic lateral sclerosis) and CNS insults (ischemia and epilepsy). We characterized the protein expression of GLT-1 and GLAST in primary astrocyte-neuron cocultures derived from rat hippocampal tissues during neuron differentiation/maturation. GLT-1 and GLAST are expressed by morphologically distinct glial fibrillary acidic protein-positive astrocytes, and their expression correlates with the status of neuron differentiation/maturation and activity. Up-regulation of the transporters paralleled the content of the synaptophysin synaptic vesicle marker p38, and down-regulation was a consequence of glutamate-induced neuronal death or the reduction of synaptic activity. Finally, soluble factors in neuronal-conditioned media prevented the down-regulation of the GLT-1 and GLAST proteins. Although other mechanisms may participate in regulating GLT-1 and GLAST in the CNS, our data indicate that soluble factors dependent on neuronal activity play a major regulating role in hippocampal cocultures.     

Neurotoxic and neuroprotective effects of the glutamate transporter inhibitor DL-threo-beta-benzyloxyaspartate (DL-TBOA) during physiological and ischemia-like conditions

Maintenance of low extracellular glutamate ([Glu](O)) preventing excitotoxic cell death requires fast removal of glutamate from the synaptic cleft. This clearance is mainly provided by high affinity sodium-dependent glutamate transporters. These transporters can, however, also be reversed and release glutamate to the extracellular space in situations with energy failure. In this study the cellular localisation of the glutamate transporters GLAST and GLT-1 in organotypic hippocampal slice cultures was studied by immunofluorescence confocal microscopy, under normal culture conditions, and after a simulated ischemic insult, achieved by oxygen and glucose deprivation (OGD). In accordance with in vivo findings, GLAST and GLT-1 were primarily expressed by astrocytes under normal culture conditions, but after OGD some damaged neurons also expressed GLAST and GLT-1. The potential damaging effect of inhibition of the glutamate transporters by DL-threo-beta-benzyloxyaspartate (DL-TBOA) was studied using cellular uptake of propidium iodide (PI) as a quantitative marker for the cell death. Addition of DL-TBOA for 48 h was found to induce significant cell death in all hippocampal regions, with EC(50) values ranging from 38 to 48 microM for the different hippocampal subregions. The cell death was prevented by addition of the glutamate receptor antagonists NBQX and MK-801, together with an otherwise saturating concentration of DL-TBOA (100 microM). Finally, the effect of inhibition of glutamate release, via reverse operating transporters during OGD, was investigated. Addition of a sub-toxic (10 microM) dose of DL-TBOA during OGD, but not during the subsequent 48 h recovery period, significantly reduced the OGD-induced PI uptake. It is concluded: (1) that the cellular expression of the glutamate transporters GLAST and GLT-1 in hippocampal slice cultures in general corresponds to the expression in vivo, (2) that inhibition of the glutamate transporters induces cell death in the slice cultures, and (3) that partial inhibition during simulation of ischemia by OGD protects against the induced PI uptake, most likely by blocking the reverse operating transporters otherwise triggered by the energy failure.     

Expression of glutamate transporters in human and rat retina and rat optic nerve

l-Glutamate is the major excitatory transmitter in the vertebrate retina and plays a central role in the transmission of the various retinal neurons. Glutamate is removed from the extracellular space by at least five different glutamate transporters. The cellular distribution of these has been studied so far mainly using immunocytochemistry. In the present study non-radioactive in situ hybridisation using complementary RNA probes was applied in order to identify the cell types of rat retina and optic nerve expressing generic GLT1, GLT1 variant (GLT1v or GLT1B), GLAST and EAAC1. The results were compared with immunocytochemical data achieved using affinity-purified antibodies against transporter peptides. In the immunohistochemical studies the human retina was included. The study showed that in the rat retina GLT1v and EAAC1 were coexpressed in various cell types, i.e. photoreceptor, bipolar, horizontal, amacrine, ganglion and Müller cells, whereas GLAST was only detected in Müller cells and astrocytes. In the rat optic nerve GLT1v and EAAC1 were preferentially expressed in oligodendrocytes, whereas GLAST was revealed to be present mainly in astrocytes. Generic GLT1 could not be detected in the retina or optic nerve. The cellular distribution of glutamate transporters (only immunocytochemistry) in the human retina was very similar to that of the rat retina. Remarkable results of our studies were that generic GLT1 was not detectable in the rat (and human) retina and that GLT1v and EAAC1 were demonstrable in most cell types of the retina (including photoreceptor cells and their terminals).     

Reduction of glial glutamate transporters in the parietal cortex and hippocampus of the EL mouse

There is extensive experimental evidence indicating a crucial role for glutamate in epileptogenesis and epileptic activity. The glial glutamate transporters GLT1 and GLAST are proposed to account for the majority of extracellular glutamate re-uptake. In the present study, polyclonal antibodies specific to GLT1 and GLAST were generated and characterized, revealing distribution patterns for the two transporters confirming those previously reported. In situ hybridization and immunoblotting were then used to compare levels of these two transporters in the parietal cortex and hippocampus of unstimulated and stimulated EL mice with DDY control mice. Additionally, HPLC determined tissue glutamate concentrations in the same regions of these animals. These experiments revealed reductions in GLT1 mRNA and protein in the parietal cortex of unstimulated and stimulated EL mice compared with DDY controls, accompanied by an increase in tissue glutamate concentration in the stimulated EL mice group. GLT1 mRNA was also reduced in the CA3 hippocampal subfield of both unstimulated and stimulated EL mice. GLAST protein was reduced in the hippocampus of the stimulated EL mice group, while no changes in GLAST mRNA or protein were detected in the parietal cortex of EL mice when compared with DDY controls. The glial glutamate transporter down-regulation reported here may play a role in seizure initiation, spread and maintenance in the EL mouse.     

GLT1, glial glutamate transporter,is transiently expressed in neurons and develops astrocyte specificity only after midgestation in the ovine fetal brain

Glutamate transport is a primary mechanism for regulating extracellular levels of glutamate in the central nervous system. GLT1, the most abundant of the known high‐affinity glutamate transporters, is found exclusively in astrocytes in adult brain of several species, but we and others have recently identified neurons that transiently express GLT1 protein in the developing brain. We now demonstrate the development of cell type specificity for GLT1 expression at 60, 71, and 136 days' gestation in the developing sheep brain (term = 145 days). At 60 and 71 days of gestation, GLT1 colocalizes with calbindin in Purkinje cells in the cerebellum, and this expression pattern has a novel distribution that is reminiscent of the parasagittal zebrin‐like bands. GLT1 immunoreactivity simultaneously occurs in periventricular white matter, anterior commissure, and striatal white matter, dissipating by 136 days. GLT1 protein expression within astrocytes is developmentally regulated, appearing first in vimentin positive radial glia at 60 and 71 days and then switching to GFAP positive parenchymal and perivascular astrocytes at 136 days. Expression of GLT1 in subsets of vimentin‐positive astrocytes persists in white matter but not in cortex. These results identify a novel compartmentation within cerebellar cortex and neuronal and axonal pathway localization of GLT1, suggesting the participation of this glutamate transporter in the development of the topographic organization of cerebellar cortex and a transient neuronal function for GLT1 in developing brain. In addition, GLT1 expression is highly plastic, being neither exclusively astroglial nor uniformly expressed in different populations of astrocytes during brain development. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 515–526, 1999     

Effect of topiramate and dBcAMP on expression of the glutamate transporters GLAST and GLT-1 in astrocytes cultured separately, or together with neurons

The mechanism of the antiepileptic drug topiramate is not fully understood, but interaction with the excitatory neurotransmission, e.g. glutamate receptors, is believed to be part of its anticonvulsant effect. The glutamate transporters GLAST and GLT-1 are responsible for the inactivation of glutamate as a neurotransmitter and it was therefore investigated if topiramate might affect the expression of GLAST and GLT-1 in astrocytes cultured separately or together with neurons. Since expression and membrane trafficking of glutamate transporters are affected by the protein kinase C system as well as by dBcAMP it was also investigated if these signalling pathways might play a role. In astrocyte cultures expressing mainly GLAST treatment with dBcAMP (0.25 mM) led to an increased expression of the total amount of GLAST as well as of its membrane association. The enhanced expression in the membrane was particularly pronounced for the oligomeric form of GLAST. No detectable effect on the expression of GLAST in astrocytes treated with topiramate in the presence and absence of protein kinase C activators or inhibitors was observed. Astrocytes co-cultured with neurons expressed both GLAST and GLT-1. In these cultures prolonged exposure to 30 muM topiramate (10 days) led to a statistically significant increase (P<0.025) in the membrane expression of GLAST. In case of GLT-1, culture in the presence of 30 microM topiramate for 1 and 10 days led to alterations in the total, cytoplamic and membrane expression of the oligomeric form of the transporter.     

GDNF pre-treatment aggravates neuronal cell loss in oxygen-glucose deprived hippocampal slice cultures: a possible effect of glutamate transporter up-regulation

Besides its neurotrophic and neuroprotective effects on dopaminergic neurons and spinal motoneurons, glial cell line-derived neurotrophic factor (GDNF) has potent neuroprotective effects in cerebral ischemia. The protective effect has so far been related to reduced activation of N-methyl-D-aspartate receptors (NMDAr). This study tested the effects of GDNF on glutamate transporter expression, with the hypothesis that modulation of glutamate transporter activity would affect the outcome of cerebral ischemia. Organotypic hippocampal slice cultures, derived from 1-week-old rats, were treated with 100 ng/ml GDNF for either 2 or 5 days, followed by Western blot analysis of NMDAr subunit 1 (NR1) and two glutamate transporter subtypes, GLAST and GLT-1. After 5-day exposure to GDNF, expression of GLAST and GLT-1 was up-regulated to 169 and 181% of control values, respectively, whereas NR1 was down-regulated to 64% of control. However, despite these changes that potentially would support neuronal resistance to excitotoxicity, the long-term treatment with GDNF was found to aggravate the neuronal damage induced by oxygen-glucose deprivation (OGD). The increased cell death, assessed by propidium iodide (PI) uptake, occurred not only among the most susceptible CA1 pyramidal cells, but also in CA3 and fascia dentata. Given that glutamate transporters are able to release glutamate by reversed action during energy failure, it is suggested that the observed increase in OGD-induced cell death in the GDNF-pretreated cultures was caused by the build-up of excitotoxic concentrations of extracellular glutamate released through the glutamate transporters, which were up-regulated by GDNF. Although the extent and consequences of glutamate release via reversal of GLAST and GLT-1 transporters seem to vary in different energy failure models, the present findings should be taken into account in clinical trials of GDNF.     

Decreased expression of glutamate transporters in genetic absence epilepsy rats before seizure occurrence

In absence epilepsy, epileptogenic processes are suspected of involving an imbalance between GABAergic inhibition and glutamatergic excitation. Here, we describe alteration of the expression of glutamate transporters in rats with genetic absence (the Genetic Absence Epilepsy Rats from Strasbourg: GAERS). In these rats, epileptic discharges, recorded in the thalamo-cortical network, appear around 40 days after birth. In adult rats no alteration of the protein expression of the glutamate transporters was observed. In 30-day-old GAERS protein levels (quantified by western blot) were lower in the cortex by 21% and 35% for the glial transporters GLT1 and GLAST, respectively, and by 32% for the neuronal transporter EAAC1 in the thalamus compared to control rats. In addition, the expression and activity of GLAST were decreased by 50% in newborn GAERS cortical astrocytes grown in primary culture. The lack of modification of the protein levels of glutamatergic transporters in adult epileptic GAERS, in spite of mRNA variations (quantified by RT-PCR), suggests that they are not involved in the pathogeny of spike-and-wave discharges. In contrast, the alteration of glutamate transporter expression, observed before the establishment of epileptic discharges, could reflect an abnormal maturation of the glutamatergic neurone-glia circuitry.     

Beta-amyloid enhances glial glutamate uptake activity and attenuates synaptic efficacy

Although amyloid beta-protein (A beta) has long been implicated in the pathogenesis of Alzheimer's disease, little is known about the mechanism by which A beta causes dementia. A beta leads to neuronal cell death in vivo and in vitro, but recent evidence suggests that the property of the amnesic characteristic of Alzheimer's disease can be explained by a malfunction of synapses rather than a loss of neurons. Here we show that prolonged treatment with A beta augments the glutamate clearance ability of cultured astrocytes and induces a dramatic decrease in glutamatergic synaptic activity of neurons cocultured with the astrocytes. Biotinylation assay revealed that the enhancement of glutamate uptake activity was associated with an increase in cell-surface expression of GLAST, a subtype of glial glutamate transporters, without apparent changes in the total amount of GLAST. This phenomenon was blocked efficiently by actin-disrupting agents. Thus, A beta-induced actin-dependent GLAST redistribution and relevant synaptic malfunction may be a cellular basis for the amnesia of Alzheimer's disease.     

A new GLT1 splice variant: cloning and immunolocalization of GLT1c in the mammalian retina and brain

We have identified a novel carboxyl-terminal splice-variant of the glutamate transporter GLT1, which we denote as GLT1c. Within the rat brain only low levels of protein and message were detected, protein expression being restricted to end feet of astrocytes apposed to blood vessels or some astrocytes adjacent to the ventricles. Conversely, within the retina, this variant was selectively and heavily expressed in the synaptic terminals of both rod- and cone-photoreceptors in both humans and rats. Double-immunolabelling with antibodies to the carboxyl region of GLT1b/GLT1v, which is strongly expressed in apical dendrites of bipolar cells and in cone photoreceptors revealed that in the rat GLT1c was co-localised with GLT1b/GLT1v in cone photoreceptors but not with GLT1b/GLT1v in bipolar cells. GLT1c expression was developmentally regulated, only appearing at around postnatal day 7 in the rat retina, when photoreceptors first exhibit a dark current. Since the glutamate transporter EAAT5 is also expressed in terminals of rod photoreceptor terminals these data indicate that rod photoreceptors express two glutamate transporters with distinct properties. Similarly, cone photoreceptors express two glutamate transporters. We suggest that differential usage of these transporters by rod and cone photoreceptors may influence the kinetics of glutamate transmission by these neurons.     

Plasticity of astrocytic coverage and glutamate transporter expression in adult mouse cortex

Astrocytes play a major role in the removal of glutamate from the extracellular compartment. This clearance limits the glutamate receptor activation and affects the synaptic response. This function of the astrocyte is dependent on its positioning around the synapse, as well as on the level of expression of its high-affinity glutamate transporters, GLT1 and GLAST. Using Western blot analysis and serial section electron microscopy, we studied how a change in sensory activity affected these parameters in the adult cortex. Using mice, we found that 24 h of whisker stimulation elicited a 2-fold increase in the expression of GLT1 and GLAST in the corresponding cortical column of the barrel cortex. This returns to basal levels 4 d after the stimulation was stopped, whereas the expression of the neuronal glutamate transporter EAAC1 remained unaltered throughout. Ultrastructural analysis from the same region showed that sensory stimulation also causes a significant increase in the astrocytic envelopment of excitatory synapses on dendritic spines. We conclude that a period of modified neuronal activity and synaptic release of glutamate leads to an increased astrocytic coverage of the bouton–spine interface and an increase in glutamate transporter expression in astrocytic processes.     

Glial glutamate transporters mediate a functional metabolic crosstalk between neurons and astrocytes in the mouse developing cortex

Neuron-glia interactions are essential for synaptic function, and glial glutamate (re)uptake plays a key role at glutamatergic synapses. In knockout mice, for either glial glutamate transporters, GLAST or GLT-1, a classical metabolic response to synaptic activation (i.e., enhancement of glucose utilization) is decreased at an early functional stage in the somatosensory barrel cortex following activation of whiskers. Investigation in vitro demonstrates that glial glutamate transport represents a critical step for triggering enhanced glucose utilization, but also lactate release from astrocytes through a mechanism involving changes in intracellular Na(+) concentration. These data suggest that a metabolic crosstalk takes place between neurons and astrocytes in the developing cortex, which would be regulated by synaptic activity and mediated by glial glutamate transporters.     

In vivo evidence that truncated trkB.T1 participates in nociception

Background

Clearance of synaptically released glutamate, and hence termination of glutamatergic neurotransmission, is carried out by glutamate transporters, most especially glutamate transporter-1 (GLT-1) and the glutamate-aspartate transporter (GLAST) that are located in astrocytes. It is becoming increasingly well appreciated that changes in the function and expression of GLT-1 and GLAST occur under different physiological and pathological conditions. Here we investigated the plasticity in expression of GLT-1 and GLAST in the spinal dorsal horn using immunohistochemistry following partial sciatic nerve ligation (PSNL) in rats.

Results

Animals were confirmed to develop hypersensitivity to mechanical stimulation by 7 days following PSNL. Baseline expression of GLT-1 and GLAST in naive animals was only observed in astrocytes and not in either microglia or neurons. Microglia and astrocytes showed evidence of reactivity to the nerve injury when assessed at 7 and 14 days following PSNL evidenced by increased expression of OX-42 and GFAP, respectively. In contrast, the total level of GLT-1 and GLAST protein decreased at both 7 and 14 days after PSNL. Importantly, the cellular location of GLT-1 and GLAST was also altered in response to nerve injury. Whereas activated astrocytes showed a marked decrease in expression of GLT-1 and GLAST, activated microglia showed de novo expression of GLT-1 and GLAST at 7 days after PSNL and this was maintained through day 14. Neurons showed no expression of GLT-1 or GLAST at any time point.

Conclusion

These results indicate that the expression of glutamate transporters in astrocytes and microglia are differentially regulated following nerve injury.