The high affinity uptake system for excitatory amino acids in the brain

Primary sensory and forebrain motor systems in the newborn brain are preferentially damaged by hypoxia-ischemia

Cerebral hypoxia-ischemia causes encephalopathy and neurologic disabilities in newborns by unclear mechanisms. We tested the hypothesis that hypoxia-ischemia causes brain damage in newborns that is system-preferential and related to regional oxidative metabolism. One-week-old piglets were subjected to 30 minutes of hypoxia and then seven minutes of airway occlusion, producing asphyxic cardiac arrest, followed by cardiopulmonary resuscitation and four-day recovery. Brain injury in hypoxic-ischemia piglets (n = 6) compared to controls (n = 5) was analyzed by hematoxylin-eosin, Nissl, and silver staining, relationships between regional vulnerability and oxidative metabolism were evaluated by cytochrome oxidase histochemistry. Profile counting-based estimates showed that 13% and 27% of neurons in layers II/III and layers of somatosensory cortex had ischemic cytopathology, respectively; CA1 neuronal perikarya appeared undamaged, and < 10% of CA3 and CA4 neurons were injured; and neuronal damage was 79% in putamen, 17% in caudate, but nucleus accumbens was undamaged. Injury was found preferentially in primary sensory neocortices (particularly somatosensory cortex), basal ganglia (predominantly putamen, subthalamic nucleus, and substantia nigra reticulata), ventral thalamus, geniculate nuclei, and tectal nuclei. In sham piglets, vulnerable region generally had higher cytochrome oxidase levels than less vulnerable areas. Postischemic alterations in cytochrome oxidase were regional and laminar, with reductions (31-66%) occurring in vulnerable regions and increases (20%) in less vulnerable areas. We conclude that neonatal hypoxia-ischemia causes highly organized, system-preferential and topographic encephalopathy, targeting regions that function in sensorimotor integration and movement control. This distribution of neonatal encephalopathy is dictated possibly by regional function, mitochondrial activity, and connectivity.

Localization of the glutamate transporter protein GLAST in rat retina

Glutamate is a neurotransmitter in retina. Glutamate transporter proteins keep the resting extracellular glutamate concentration low. This is required for normal neurotransmission and prevents the extracellular concentration of glutamate from reaching toxic levels. Here we describe the light and electron microscopic localization of the glutamate transporter protein GLAST in rat retina using an antibody raised and affinity purified against a peptide corresponding to amino acid residues 522-541. The strongest immunocytochemical labelling was observed in the outer plexiform layer, ganglion cell layer, and optic disc. GLAST was found in Müller cell processes in all retinal layers, notably ensheathing the photoreceptor terminals in the outer plexiform layer, and in astrocytes close to vessels in the inner retina and optic disc. No labelling was observed in neurons. The electrophoretic mobility of GLAST in retina was similar to that in cerebellum. In conclusion, the findings are in agreement with those reported by Derouiche and Rauen [7], except that we did not detect any GLAST in the retinal pigment epithelium.

Evidence for increased cellular uptake of glutamate and aspartate in the rat hippocampus during kainic acid seizures. A microdialysis study using the "indicator diffusion' method

Using a newly developed technique, based on microdialysis, which allows cellular uptake of glutamate and aspartate to be studied in awake animals, we investigated uptake of glutamate and aspartate in the hippocampal formation of rats during limbic seizures induced by systemical administration of kainic acid (KA). With [14C]mannitol as an extracellular reference substance, the cellular extraction of the test substance [3H]D-aspartate was measured at different stages of seizure-activity. The results were compared to those obtained in a sham operated control group. During severe generalized clonic seizures, the extraction of [3H]D-aspartate was increased by 17%. The increase in uptake of [3H]D-aspartate was accompanied by a 24% increase in the extracellular level of aspartate, as obtained by conventional microdialysis. No significant changes were observed in the extracellular level of glutamate. The results indicate that during KA-induced seizures, uptake of glutamate and aspartate is increased, possibly aimed at maintaining the extracellular homeostasis of these two excitatory amino acids.

The unipolar brush cells of the mammalian cerebellum and cochlear nucleus: cytology and microcircuitry

The unipolar brush cell (UBC) is a novel type of small neuron that is characterized by sets of morphological and chemical phenotypes. UBCs occur in the granular layer of the mammalian cerebellar cortex, particularly in folia of the vestibulocerebellum, and in the granule cell domains of the dorsal cochlear nucleus. The UBC is characterized by a single dendrite that terminates with a brush-like tip of dendrioles. The soma, the dendritic stem, and especially the dendrioles emit short, non-synaptic appendages. The dendrioles represent the main synaptic apparatus of the UBC and articulate tightly with a single mossy fiber rosette forming a glomerular array characterized by an extraordinarily extensive synaptic contact. Electron microscopic and electrophysiological observations indicate that the unusual synaptic ultrastructure may produce entrapment of neurotransmitter in the synaptic cleft. While ionotropic glutamate receptors are enriched in correspondence of the postsynaptic density, metabotropic glutamate receptors are situated extrasynaptically and are particularly enriched at the appendages, which usually do not bear synaptic junctions. Some of the UBCs receive their input from choline acetyltransferase-positive mossy rosettes originating from the vestibular nuclei, suggesting that ACh and glutamate are co-released at these synapses. The UBC brush occupies a glomerulus where granule cell dendrites are intermixed with the UBC dendrioles, both of which receive synapses from the same mossy fiber rosette and portions of the Golgi axonal plexus. In addition, the dendrioles are presynaptic to granule cell dendrites, forming dendrodendritic contacts that display features of excitatory synapses. Branches of the UBC axon in the granular layer bear large endings resembling mossy fibers. The UBCs may represent an extraordinary device for feedforward, excitatory links along the mossy fiber pathways of cerebellum and dorsal cochlear nucleus.

Altered glutamatergic transmission in neurological disorders: from high extracellular glutamate to excessive synaptic efficacy

This review is a critical appraisal of the widespread assumption that high extracellular glutamate, resulting from enhanced pre-synaptic release superimposed on deficient uptake and/or cytosolic efflux, is the key to excessive glutamate-mediated excitation in neurological disorders. Indeed, high extracellular glutamate levels do not consistently correlate with, nor necessarily produce, neuronal dysfunction and death in vivo. Furthermore, we exemplify with spreading depression that the sensitivity of an experimental or pathological event to glutamate receptor antagonists does not imply involvement of high extracellular glutamate levels in the genesis of this event. We propose an extension to the current, oversimplified concept of excitotoxicity associated with neurological disorders, to include alternative abnormalities of glutamatergic transmission which may contribute to the pathology, and lead to excitotoxic injury. These may include the following: (i) increased density of glutamate receptors; (ii) altered ionic selectivity of ionotropic glutamate receptors; (iii) abnormalities in their sensitivity and modulation; (iv) enhancement of glutamate-mediated synaptic efficacy (i.e. a pathological form of long-term potentiation); (v) phenomena such as spreading depression which require activation of glutamate receptors and can be detrimental to the survival of neurons. Such an extension would take into account the diversity of glutamate-receptor-mediated processes, match the complexity of neurological disorders pathogenesis and pathophysiology, and ultimately provide a more elaborate scientific basis for the development of innovative treatments.

Glutamate receptor agonists up-regulate glutamate transporter GLAST in astrocytes

Long-term treatment of astrocytes in primary culture with L-glutamate (0.1-3 mM) resulted in a dose-dependent increase in D-[3H]aspartate uptake. The effect was abolished by an antagonist of kainate/AMPA receptors, CNQX, and mimicked by kainate, but not by AMPA or tACPD. Both glutamate and kainate caused a dramatic up-regulation (82% and 69%, respectively) of GLAST, a predominant glutamate transporter in cultured astroglia, though the mRNA levels appeared unaffected. Long-term treatment of cultures with dBcAMP stimulated D-[3H]aspartate uptake as well as GLAST expression. Apart from glutamate, none of the agonists used was capable of increasing further the uptake capacity of the dBcAMP-treated astroglia. The glutamate receptor-dependent modulation of glutamate transport in astroglial cultures may represent a novel feedback regulatory mechanism for glutamate uptake in the brain.

Involvement of the glutamatergic metabotropic receptors in the regulation of glutamate uptake and extracellular excitatory amino acid levels in the striatum of chloral hydrate-anesthetized rats

The microdialysis technique was used to assess in vivo the putative functional role of metabotropic excitatory amino acid receptors in regulating extracellular levels of the excitatory amino acids glutamate and aspartate in the striatum of chloral hydrate-anesthetized rats. Addition of the metabotropic glutamate receptor antagonist (+)-alpha-methyl-4-carboxyphenylglycine (MCPG) (10(-3) or 4 x 10(-3) M) in the dialysis probe did not modify the basal extracellular levels of glutamate and aspartate but induced a significant dose-dependent decrease in the KCl-elicited elevation of glutamate and aspartate extracellular levels. The effect of MCPG on glutamate extracellular concentration under K+ stimulation was reduced by the simultaneous superfusion of the metabotropic glutamate receptor agonist (2S,3S,4S)-alpha-(carboxycyclopropyl)glycine) (L-CCG) (10(-3) M) which had no significant effect when tested alone. In contrast, L-CCG alone significantly potentiated the KCl-elicited elevation of aspartate extracellular concentrations but failed to modify the MCPG effect on this amino acid concentration. In a parallel series of experiments, high-affinity glutamate uptake was measured ex vivo 20 min after an in vivo injection of 10 pmol of MCPG in the striatum. MCPG was found unable to modify the glutamate uptake rate. In vitro, MCPG (1-1000 microM) again had no effect on glutamate transport rate. These data suggest that metabotropic excitatory amino acid receptors (1) may act to increase the extracellular levels of glutamate and aspartate under depolarizing conditions, and (2) may not have a major role in the regulation of high affinity glutamate uptake under basal conditions. In addition, it can be assumed that the control of glutamate and aspartate extracellular levels may involve different metabotropic receptors.

Brain glutamate transporter proteins form homomultimers

Removal of excitatory amino acids from the extracellular fluid is essential for synaptic transmission and for avoiding excitotoxicity. The removal is accomplished by glutamate transporters located in the plasma membranes of both neurons and astroglia. The uptake system consists of several different transporter proteins that are carefully regulated, indicating more refined functions than simple transmitter inactivation. Here we show by chemical cross-linking, followed by electrophoresis and immunoblotting, that three rat brain glutamate transporter proteins (GLAST, GLT and EAAC) form homomultimers. The multimers exist not only in intact brain membranes but also after solubilization and after reconstitution in liposomes. Increasing the cross-linker concentration increased the immunoreactivity of the bands corresponding to trimers at the expense of the dimer and monomer bands. However, the immunoreactivities of the dimer bands did not disappear, indicating a mixture of dimers and trimers. GLT and GLAST do not complex with each other, but as demonstrated by double labeling post-embedding electron microscopic immunocytochemistry, they co-exist side by side in the same astrocytic cell membranes. The oligomers are held together noncovalently in vivo. In vitro, oxidation induces formation of covalent bonds (presumably -S-S-) between the subunits of the oligomers leading to the appearance of oligomer bands on SDS-polyacrylamide gel electrophoresis. Immunoprecipitation experiments suggest that GLT is the quantitatively dominant glutamate transporter in the brain. Radiation inactivation analysis gives a molecular target size of the functional complex corresponding to oligomeric structure. We postulate that the glutamate transporters operate as homomultimeric complexes.

Ischemic disruption of glutamate homeostasis in brain: quantitative immunocytochemical analyses

More than 10 years ago, it was shown by microdialysis that the excitatory transmitter glutamate accumulates in the interstitial space of brain subjected to ischemic insult. This was one of the key observations leading to the formulation of the "glutamate hypothesis' of ischemic cell death. It is now assumed that even a transient glutamate overflow may set in motion a number of events that ultimately cause cell loss in vulnerable neuronal populations. The aim of the present review is to discuss the intracellular changes that underlie the dysregulation of extracellular glutamate during and after ischemia, with emphasis on data obtained by postembedding, electron microscopic immunogold cytochemistry. While the time resolution of this approach is necessarily limited, it can reveal, quantitatively and at a high level of spatial resolution, how the intracellular pools of glutamate and metabolically related amino acids are perturbed during and after an ischemic insult. Moreover, this can be done in animals whose extracellular amino acid levels are monitored by microdialysis, allowing a direct correlation of extra- and intracellular changes. Immunogold analyses of brains subjected to ischemia have identified dendrites and neuronal somata as likely sources of glutamate efflux, probably mediated by reversal of glutamate uptake. The vesicular glutamate pool has been found to be largely unchanged after 20 min of ischemia. Ischemia causes an increased glutamate content and an increased glutamate/glutamine ratio in glial cells, as revealed by double immunogold labelling. This argues against the idea that glial cells contribute to the extracellular overflow of glutamate in the ischemic brain.

Comparison of effects induced by toxic applications of kainate and glutamate by glucose deprivation on area CA1 of rat hippocampal slices

Baseline and stimulus-induced changes in [Ca2+]o and [K+]o as well as field potentials (fp's) were studied during application of the excitatory amino acids kainate or glutamate, or during glucose deprivation in area CA1 and CA3 of rat hippocampal slices. Bath application of kainate in concentrations of 1, 2, 5, 8 and 10 mM induced a sudden rapid fall of [Ca2+]o in area CA1, associated with a negative shift of the slow fp. Kainate induced disappearance of stratum radiatum (SR) as well as alveus stimulation-evoked postsynaptic fp's, with partial recovery after application of up to 2 mM kainate, but no recovery after 5 mM kainate. Only afferent volleys and repetitive SR stimulation-induced decreases of [Ca2+]o recovered after 5 mM kainate. Similar observations were made with glutamate. Only when glutamate was applied with 20 mM, irreversible disappearance of postsynaptic fp's was noted. Glucose deprivation for 60-90 min led to an initial slow decline of [Ca2+]o in area CA1 and CA3, associated with increases in [K+]o, but no significant changes in the fp baseline. Before reaching the lowest level in [Ca2+]o, stimulation of afferent and efferent fibres in area CA1 and CA3 evoked epileptiform discharges. After reaching the lowest level in [Ca2+]o, all postsynaptic potential components were irreversibly abolished, sparing afferent volleys and SR stimulation-induced decreases in [Ca2+]o. The application of the glutamate receptor antagonists 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 30 microM) and L-2-amino-5-phosphonovalerate (2AVP, 30 microM) during glucose deprivation did not prevent irreversible loss of alveus and SR stimulation-induced postsynaptic signals. These findings suggest that glutamate release during glucose deprivation is not the main factor of acute cell damage.

New views on synapse-glia interactions

Although glial cells ensheath synapses throughout the nervous system, the functional consequences of this relationship are uncertain. Recent studies suggest that glial cells may promote the formation of synapses and help to maintain their function by providing nerve terminals with energy substrates and glutamate precursors.

Glutamatergic connections of the auditory midbrain: selective uptake and axonal transport of D-[3H]aspartate

D-[3H]aspartate was used to identify potential glutamatergic connections of the chinchilla inferior colliculus (IC). High-affinity uptake of D-[3H]aspartate is considered a selective marker for glutamatergic synapses, and neurons retrogradely labeled from such injections are believed to use glutamate, or a closely related compound, as a transmitter. Injections of D-[3H]aspartate suggest that glutamatergic endings in the IC arise primarily from intrinsic connections, the opposite IC, layer 5 of temporal cortex, nucleus sagulum, and lateral lemniscal nuclei. Neurons giving rise to the principal sensory (lemniscal) projections to the IC, i.e., those from the cochlear nuclei, superior olive, and the majority of projections from the lateral lemniscal nuclei, did not label in these experiments, indicating that their synapses do not recognize D-[3H]aspartate as a suitable substrate and may use inhibitory or other excitatory transmitters. After IC injections, fiber and diffuse labeling was found ipsilaterally in the medial geniculate body, superior colliculus, and dorsolateral pontine nuclei, contralaterally in the IC, and bilaterally in the superior olive and cochlear nuclei. Such labeling was attributed to anterograde transport of D-[3H]aspartate within the efferent collaterals of labeled IC neurons, suggesting that many of the IC's efferent projections may also be glutamatergic. This interpretation was confirmed in separate experiments in which D-[3H]aspartate, injected in the medial geniculate body, retrogradely labeled neurons in the IC as well as in layer 6 of temporal cortex. Finally, the mesencephalic trigeminal nucleus and tract labeled in some cases and may have local glutamatergic connections.

The competitive transport inhibitor L-trans-pyrrolidine-2, 4-dicarboxylate triggers excitotoxicity in rat cortical neuron-astrocyte co-cultures via glutamate release rather than uptake inhibition

We studied the early and late effects of L-trans-pyrrolidine-2,4-dicarboxylate (PDC), a competitive inhibitor of glutamate uptake with low affinity for glutamate receptors, in co-cultures of rat cortical neurons and glia expressing spontaneous excitatory amino acid (EAA) neurotransmission. At 100 or 200 microM, PDC induced different patterns of electrical changes: 100 microM prolonged tetrodotoxin-sensitive excitation triggered by synaptic glutamate release; 200 microM produced sustained, tetrodotoxin-insensitive and EAA-mediated neuronal depolarization, overwhelming synaptic activity. At 200 microM, but not at 100 microM, PDC caused rapid elevation of the glutamate concentration ([Glu]o) in the culture medium, resulting in NMDA receptor-mediated excitotoxic death of neurons 24 h later. The increase in [Glu]o was largely insensitive to tetrodotoxin, independent of extracellular Ca2+, and present also in astrocyte-pure cultures. By the use of glutamate transporters functionally reconstituted in liposomes, we showed directly that PDC activates carrier-mediated release of glutamate via heteroexchange. Glutamate release and delayed neurotoxicity in our cultures were suppressed if PDC was applied in a Na(+)-free medium containing Li+. However, replacement of Na+ with choline instead of Li+ did not result in an identical effect, suggesting that Li+ does not act simply as an external Na+ substitute. In conclusion, our data indicate that alteration of glutamate transport by PDC has excitotoxic consequences and that active release of glutamate rather than just uptake inhibition is responsible for the generation of neuronal injury.

Inhibition of the high-affinity uptake of D-[3H]aspartate in rate by L-alpha-aminoadipate and arachidonic acid

The mechanism of inhibition of the high-affinity sodium-dependent transport of D-[3H]aspartate by the gliotoxin, L-alpha-aminoadipate, and also by the endogenous fatty acid, arachidonic acid (cis-5,8,11,14 eicosatetraenoic acid), into rat brain synaptosomes has been investigated. L-alpha-Aminoadipate competitively inhibited the transport of D-[3H]aspartate with a K1 value of 192 microM. Superfusion of coronal slices of rat brain for 40 min with 1 mM L-alpha-aminoadipate reduced the glutathione concentration of the tissue by 20%. Neither glutamate nor kainate depleted the glutathione level of the slices. Pre-incubation of synaptosomes with arachidonic acid (10 microM) for 10-60 min produced a marked potentiation of the inhibition of D-[3H]aspartate transport, compared to experiments in which the acid was added concurrently with the D-[3H]aspartate ('co-incubation' experiments). Inhibition of D-[3H]aspartate transport by arachidonic acid was not blocked by addition of nordihydroguaretic acid to the pre-incubation medium. Staurosporine (50 nM) reduced the inhibition of transport occurring during pre-incubation with 10 microM arachidonic acid, and there was no longer any significant difference from the level of inhibition obtained in co-incubation experiments. Phorbol, 12-myristate, 13-acetate (1 microM) reduced the transport of D-[3H]aspartate to 73% of control after 20 min pre-incubation of the synaptosomes. This study highlights the fact that inhibition of glutamate transport may affect brain function in a number of different ways. Competitive inhibition by a structural analogue of glutamate, such as L-alpha-aminoadipate, leads to a reduction in the glutathione level, which may be an important factor in L-alpha-aminoadipate-mediated toxicity. On the other hand, the more long-term effects of non-competitive inhibition of glutamate transport by arachidonic acid, in a mechanism involving protein kinase C, may represent a physiological means for regulation of transporter activity in the brain.

Swelling of Müller cells induced by AP3 and glutamate transport substrates in rat retina

Previous studies have shown that a single systemic injection of 2-amino-3-phosphonopropionate (AP3), an agonist/antagonist at metabotropic glutamate receptors, produces marked swelling of rodent Müller cells. To investigate the effects of AP3 on Müller cells, we used in vitro retinal segments prepared from 30 day old rats. Incubation with AP3 for 1 h or more caused severe swelling of Müller cells with the appearance of mitotic cellular profiles in the outer nuclear layer. The Müller cell swelling was mimicked by substrates for glutamate transporters, suggesting that AP3 may produce its effects via transport into glial cells. To determine whether AP3 is a substrate for glutamate transporters, we studied cultured rat hippocampal astrocytes using whole-cell patch clamp recordings. In hippocampal astrocytes, AP3 activated currents via an Na(+)-dependent glutamate transporter. Consistent with this, substitution of extracellular sodium with choline blocked Müller cell swelling in the rat retina. These results indicate that the acute glial swelling produced by AP3 results primarily from a fluid shift that accompanies the transport of AP3 and sodium into Müller cells.

Modulation of excitatory synaptic transmission by low concentrations of glutamate in cultured rat hippocampal neurons

1. The effects of low micromolar concentrations of glutamate on fast excitatory synaptic responses were studied in microcultures of postnatal rat hippocampal neurons using whole-cell patch clamp recordings. 2. Glutamate depressed the alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor component of excitatory autaptic currents (EACs) with an EC50 of 3.8 microM. 3. Both pre- and postsynaptic effects contributed to the depression of AMPA receptor-mediated EACs. Cyclothiazide and wheatgerm agglutinin, agents which inhibit AMPA receptor desensitization, partially reversed the depression produced by glutamate, as did pertussis toxin, an agent that blocks presynaptic inhibition mediated by metabotropic glutamate receptors. 4. In neurons in which both the AMPA and N-methyl-D-aspartate (NMDA) receptor components of EACs were examined, low concentrations of glutamate depressed the NMDA component of EACs to a greater extent. The EC50 for inhibiting the NMDA component was 1.3 microM. 5. Calcium-dependent desensitization of postsynaptic NMDA receptors contributed to the depression of NMDA receptor-mediated synaptic responses. Both depolarization of postsynaptic neurons to +70 mV to decrease Ca2+ influx via NMDA channels and inclusion of high concentrations of a calcium chelator in recording pipettes decreased the depression of NMDA receptor-mediated EACs. 6. Threo-3-hydroxy-aspartate (THA), an inhibitor of glutamate transport, depressed EACs by about 10% and increased the degree of depression produced by 2.5 microM glutamate, suggesting that glutamate transport in microcultures helps to control ambient glutamate levels. 7. Because the normal extracellular concentration of glutamate is about 1 microM, these results suggest that the ambient glutamate level is an important determinant of synaptic efficacy. Relatively small changes in extracellular glutamate can alter fast excitatory synaptic transmission by both presynaptic and postsynaptic mechanisms.

Glutamate responses of bipolar cells in a slice preparation of the rat retina

Whole-cell currents from >70 voltage-clamped bipolar cells were recorded in a slice preparation of the rat retina. The recorded cells were identified and classified by intracellular staining with Lucifer yellow. Glutamate, the specific agonists (+/-)-2-amino-4-phosphonobutyric acid (AP-4) and kainate (KA), and the antagonist 6-cyanoquinoxaline-2,3-dione (CNQX) were applied. The cells could be isolated from presynaptic influences by the co-application of bicuculline, strychnine, and cobalt ions. Responses to AP-4 were elicited only from bipolar cells with axons stratifying in the inner part of the inner plexiform layer (IPL). AP-4 caused an outward current in these cells attributable to the closure of nonspecific cation channels. Responses to kainate representing a direct action of the drug on the recorded cells were observed only in bipolar cells with axons stratifying in the outer part of the IPL. KA caused a CNQX-sensitive inward current in these cells, associated with openings of nonspecific cation channels. The results predict that cone bipolar (CB) cells with axons terminating in the outer IPL are OFF-bipolars, whereas those with axons terminating in the inner IPL are ON-bipolars. Most of the cells expressed GABA-gated Cl- conductances. In rod bipolar and in some CB cells, only part of the GABA-induced currents could be blocked by the application of bicuculline, suggesting the presence of GABAc receptors in addition to GABAA receptors.

Rat C6 and human astrocytic tumor cells express a neuronal type of glutamate transporter

C6 glioma cells take up aspartate and glutamate by a Na(+)-dependent transporter. Using the polymerase chain reaction and degenerate oligonucleotide primers corresponding to conserved regions of previously cloned glutamate transporters, we isolated from these cells a partial cDNA clone with a sequence of the neuronal type EAAC1 glutamate transporter. The cells express a 4.4 kb message that hybridizes to this cDNA, and they do not express either of the previously described glial type glutamate transporters, GLT-1 or GLAST. The cells were sensitive to the toxic aspartate analog alanosine, which enters the cells by a glutamate transporter. Several human brain tumors examined, including some astrocytic tumors, expressed the EAAT3 glutamate transporter, which is the human homolog of the rodent EAAC1 transporter. Some of the tumors also expressed the other types of glutamate transporter.

Selective excitatory amino acid uptake in glutamatergic nerve terminals and in glia in the rat striatum: quantitative electron microscopic immunocytochemistry of exogenous (D)-aspartate and endogenous glutamate and GABA

To characterize glutamate/aspartate uptake activity in various cellular and subcellular elements in the striatum, rat striatal slices were exposed to 10 and 50 mu M exogenous (D)-aspartate. After fixation with glutaraldehyde/formaldehyde the distribution of (D)-aspartate was analysed by postembedding immunocytochemistry and the ultrastructural distribution was compared with the distributions of endogenous glutamate and GABA. Light microscopically, (D)-aspartate-like immunoreactivity was localized in conspicuous dots along very weakly labelled dendritic profiles and neuron cell bodies. At the electron microscope level gold particles signalling (D)-aspartate occurred at highest density in nerve terminals making asymmetrical contacts with postsynaptic spines (i.e. resembling synapses of cortical afferents). Astrocytic processes also contained gold particles, but at a lower density than nerve endings. In contrast, dendritic spines were only weakly (D)-aspartate-positive. The difference in labelling at 10 and 50 mu M (D)-aspartate was consistent with 'high-affinity' uptake. Neighbouring sections processed with other antibodies showed that the D-aspartate labelling. Occurred in nerve terminals strongly immunoreactive for glutamate, rather than in terminals very weakly glutamate-immunopositive or in nerve endings immunoreactive for GABA. Glutamate labelling of perfusion-fixed striatum confirmed that terminals forming asymmetrical synaptic contacts with spines were enriched with gold particles, suggesting that these terminals use glutamate as a transmitter. This study demonstrates that high-affinity uptake sites for excitatory amino acids in the striatum are most strongly expressed on presumed glutamatergic nerve terminals and on astrocytes.

Amino-acid release from human cerebral cortex during simulated ischaemia in vitro

The aim of the present study was to investigate the release of amino-acids in human cerebral cortex during membrane depolarization and simulated ischaemia (energy deprivation). Superfluous tissue from temporal Iobe resections for epilepsy was cut into 500 microns thick slices and incubated in vitro. Membrane depolarization with 50 mM K+ caused a release of glutamate, aspartate, GABA and glycine, but not glutamine or leucine. The release of glutamate and GABA was Ca(++)-dependent. Slices were exposed to simulated ischaemia (energy deprivation; ED) by combined glucose/oxygen deprivation. This caused a Ca(++)-independent release of glutamate, aspartate, GABA, glycine, and taurine which started after 8 min, peaked at the end or shortly after the 27 min period of ED, and returned to control levels within 11 min following termination of ED. Preloaded D-[3H]aspartate was released both during K(+)-stimulation and ED. Release of D-[3H]aspartate during ED was delayed compared to glutamate supporting an initial phase of synaptic glutamate release. Uptake of L-[3H]glutamate was increased during the period of glutamate release, suggesting passive diffusion across the cell membrane or enhanced transport efficacy in cellular elements with functioning uptake mechanisms.

Cloning and expression of a neuronal rat brain glutamate transporter

Glutamate is the major excitatory transmitter in the mammalian central nervous system. Glutamate transporters, which keep the extracellular glutamate concentration low, are required both for normal brain function and for protecting neurons against harmful glutamatergic overstimulation. We have isolated the cDNA for a rat brain glutamate transporter (REAAC1) which has 90% amino acid and 86% nucleotide identity to the rabbit EAAC1. When REAAC1 was expressed in HeLa cells using a recombinant vaccinia-T7 virus expression system, a sodium dependent glutamate uptake was observed. The affinity of the carrier to various substrates was typical of brain "high affinity' glutamate uptake: threo-3-hydroxyaspartate, (R)-aspartate, (S)-glutamate and (S)-trans-pyrrolidine-2,4-dicarboxylic acid were strong inhibitors, but not (R)-glutamate or gamma-aminobutyrate. High resolution, non-radioactive in situ hybridization histochemistry in rat brain revealed the mRNA in several types of glutamatergic as well as non-glutamatergic neurons, but not in glial cells.

The neurotransmitter candidature of sulphur-containing excitatory amino acids in the mammalian central nervous system

While L-glutamate (L-Glu) is considered to be the predominant excitatory amino acid transmitter in the mammalian CNS, other amino acids have come under scrutiny as possible rivals for such a role. These include four sulphur-containing analogues of L-Glu and L-aspartate known as the SAAs. The L-Glu analogues are L-homocysteic acid and L-homocysteine sulphinic acid, while the L-aspartate analogues are L-cysteic acid and L-cysteine sulphinic acid. They are mixed agonists of excitatory amino acid receptors on a variety of neurones and are reported to be present in and released from mammalian CNS tissue. This review serves to summarize the current state of research into the possibility that one or more of these compounds is indeed a transmitter within the mammalian CNS.

Pre-incubation of synaptosomes with arachidonic acid potentiates inhibition of [3H]D-aspartate transport

The ability of low micromolar concentrations of the polyunsaturated fatty acid, arachidonic acid (cis-5,8,11,14-eicosatetraenoic acid) to inhibit the high-affinity, sodium-dependent transport of [3H]D-aspartate into purified synaptosomes of rat brain has been examined. Pre-incubation of the synaptosomes with arachidonic acid for 10-60 min produced a marked potentiation of the response to 10 microM arachidonic acid compared to co-incubation, and the threshold for inhibition of [3H]D-aspartate transport occurred at a concentration of 1 microM. Minimal inhibition of transport was seen with the unsaturated fatty acids, cis-oleic (cis-9-octadecenoic acid) and cis-linolenic (cis-9,12,15-octadecatrienoic acid), nor with the 20-carbon saturated fatty acid, arachidic acid (n-eicosanoic acid). Inclusion of the cyclo-oxygenase inhibitor, nor-dihydroguaretic acid (NDGA), in the presence of 5 microM arachidonic acid did not alter the inhibition of [3H]D-aspartate transport between 0-10 min, but did enhance the response at longer pre-incubation times. Inhibition of [3H]D-aspartate transport by arachidonic acid persisted during addition of the calcium ionophore, A23187, whereas removal of calcium ions from the incubation medium potentiated the response to arachidonic acid. The results are discussed in terms of the physiological relevance of the inhibition of glutamate transport by arachidonic acid, and suggest that regulation of inhibition of the glutamate transporter by arachidonic acid may be achieved by changes in the extracellular, as well as the intracellular, concentration of calcium ions.

Down-regulation of glial glutamate transporters after glutamatergic denervation in the rat brain

Membrane-localized transporter proteins, expressed in both neurons and glial cells, are responsible for removal of extracellular glutamate in the mammalian CNS. The amounts and activities of these transporters may be under regulatory control. We demonstrate here that cortical lesions, which decrease striatal glutamate uptake in synaptosome-containing homogenates by approximately 50%, also decrease the striatal concentrations of the astrocytic glutamate transporter proteins, GLT-1 and GLAST by approximately 20-30%. Since GABA uptake activity was not decreased and glial fibrillary acidic protein was increased in the same samples, the lesion-induced losses of GLT-1 and GLAST were not caused by a general impairment of neuronal or glial function. The observed reduction in the two astrocytic glutamate transporters after corticostriatal nerve terminal degeneration indicates that their levels of expression are dependent on glutamatergic innervation.

Glutamate transporters in glial plasma membranes: highly differentiated localizations revealed by quantitative ultrastructural immunocytochemistry

The glutamate transporters GLT-1 and GLAST were studied by immunogold labeling on ultrathin sections of rat brain tissue embedded in acrylic resins at low temperature after freeze substitution. Both proteins were selective markers of astrocytic plasma membranes. GLT-1 was much higher in hippocampal astrocytes than in cerebellar astrocytes. Astroglial membrane GLAST densities ranked as follows: Bergmann > cerebellar granular layer approximately hippocampus > cerebellar white matter. No astrocyte appeared unlabeled. Astrocytic membranes facing capillaries, pia, or stem dendrites were lower in glutamate transporters than those facing nerve terminals, axons, and spines. Parallel fiber boutons (glutamatergic) synapsin on interneuron dendritic shafts were surrounded by lower transporter densities than those synapsing on Purkinje cell spines. Our findings suggest the localizations of glutamate transporters are carefully regulated.

Coincidence of L-glutamate/L-aspartate transporter (GLAST) and glutamine synthetase (GS) immunoreactions in retinal glia: evidence for coupling of GLAST and GS in transmitter clearance

Our aim was to identify proteins that mediate the uptake and degradation of synaptically released glutamate, focusing on the rat retina with its well-defined glutamatergic pathways. Immunoreactivity against the L-glutamate/L-aspartate transporter (GLAST) is present in Müller cells. Ultrastructurally, even the finest glial processes, particularly those ensheathing identified structures of glutamatergic transmission (rod spherules), are immunoreactive for GLAST. Further light and electron microscopic observations revealed that also retinal astrocytes and pigment epithelial cells are immunoreactive for GLAST. No neuronal or microglial staining was observed. This is in line with uptake of exogenous [3H]glutamate previously localized specifically in Müller cells and pigment epithelium (Ehinger and Falck: Brain Res 33:157-172, 1971). Since endogenous glutamate can only be demonstrated in Müller cells if glutamine synthetase (GS) is inhibited (Pow and Robinson: Neuroscience 60:355-366, 1994), the immunocytochemical localization of GS was determined. GS immunoreactivity was found in all but only those cell types immunoreactive for GLAST. The light and electron microscopic patterns of immunoreactivity were very similar, particularly in the outer plexiform layer. The three cell types containing both GS and GLAST (Müller cells, astrocytes, and retinal pigment epithelium) are related developmentally. In the light of the two references quoted the present data indicate that the proteins mediating retinal uptake and degradation of synaptically released glutamate may be GLAST and GS, respectively, and that they may operate in concert to terminate the neurotransmitter action of glutamate.

Glutamate is concentrated in and released from parallel fiber terminals in the dorsal cochlear nucleus: a quantitative immunocytochemical analysis in guinea pig

The present paper addresses the identity of the neurotransmitter(s) of the parallel fibers in the molecular layer of the dorsal cochlear nucleus, a brainstem center in the pathway for sound perception. The distribution of putative neurotransmitter amino acids was studied by using postembedding single- and double-immunolabeling procedures. Perfusion-fixed brains and immersion-fixed slices from in vitro release experiments were evaluated. Quantitative immunogold analyses revealed that the parallel fiber terminals were significantly enriched with glutamate immunoreactivity compared with other terminals, dendrites, and glial processes. Within the parallel fiber terminals, the gold particles signaling the presence of glutamate were concentrated over vesicle clusters relative to the axoplasmic matrix. Furthermore, the parallel fiber terminals, but not the parent granule cell bodies, could be depleted of glutamate immunoreactivity by exposure to depolarizing concentrations of K+ in vitro. This depletion was partly dependent on Ca2+. In double-labeled preparations, the glutamine:glutamate ratio was by far higher in glial processes than in other types of profile. Aspartate immunoreactivity was mainly concentrated in neuronal cell bodies and dendrites and was very low in fiber terminals, particularly in those of the parallel fibers. These data indicate that parallel fiber terminals contain a glutamate pool that is associated with synaptic vesicles and that can be subject to release. The glial processes that are found in proximity to the terminals may provide them with the glutamine required for glutamate replenishment. No evidence was found for a neurotransmitter role of aspartate in the parallel fibers.

Arachidonic acid inhibits a purified and reconstituted glutamate transporter directly from the water phase and not via the phospholipid membrane

Glutamate is believed to be the major excitatory transmitter in the mammalian central nervous system. Keeping the extracellular concentration of glutamate low, the glutamate transporters are required for normal brain function. Arachidonic acid (AA) inhibits glutamate uptake in relatively intact preparations (cells, tissue slices, and synaptosomes (Rhoads, D.E., Ockner, R. K., Peterson, N. A., and Raghupathy, E. (1983) Biochemistry 22, 1965-1970 and Volterra, A., Trotti, D., Cassutti, P., Tromba, C., Salvaggio, A., Melcangi, R. C., and Racagni, G. (1992b) J. Neurochem. 59, 600-606). The present study demonstrates that the effect of AA occurs also in a reconstituted system, consisting of a purified glutamate transporter protein incorporated into artificial cell membranes (liposomes). The characteristics of the AA effect in this system and in intact cells are similar with regard to specificity, sensitivity, time course, changes in Vmax, and affinity. AA-ethyl ester is inactive, suggesting that the free carboxylic group is required for inhibitory activity. When incubated with proteoliposomes, AA (300 microM, 15 min) mostly partitions to the lipid phase (lipid/water about 95:5). However, uptake inhibition is abolished by rapid dilution (6.5-fold) of the incubation medium (water phase), a procedure that does not modify the amount of AA associated with lipids. On the contrary, inhibition remains sustained if the same dilution volume contains as little as 5 microM AA, a concentration inactive before saturation of liposome lipids with 300 microM AA. The same degree of inhibition (60%) is obtained by 5 microM AA following preincubation with the inactive AA-ethyl ester (300 microM) instead of AA. The lipids apparently inactivate AA by extracting it from the water phase. The results suggest that AA acts on the transporter from the water phase rather than via the membrane. This could be true for other proteins as well since gamma-aminobutyric acid uptake is similarly affected by AA.

Reduced postischemic expression of a glial glutamate transporter, GLT1, in the rat hippocampus

Perturbations of the synaptic handling of glutamate have been implicated in the pathogenesis of brain damage after transient ischemia. Notably, the ischemic episode is associated with an increased extracellular level of glutamate and an impaired metabolism of this amino acid in glial cells. Glutamate uptake is reduced during ischemia due to breakdown of the electrochemical ion gradients across neuronal and glial membranes. We have investigated, in the rat hippocampus, whether an ischemic event additionally causes a reduced expression of the glial glutamate transporter GLT1 (Pines et al. 1992) in the postischemic phase. Quantitative immunoblotting, using antibodies recognizing GLT1, revealed a 20% decrease in the hippocampal contents of the transporter protein, 6 h after an ischemic period lasting 20 min induced by four vessel occlusion. In situ hybridization histochemistry with 35S labelled oligonucleotide probes or digoxigenin labelled riboprobes directed to GLT1 mRNA showed a decreased signal in the hippocampus, particularly in CA1. This reduction was more pronounced at 3 h than at 24 h after the ischemic event. We conclude that the levels of GLT1 mRNA and protein show a modest decrease in the postischemic phase. This could contribute to the delayed neuronal death typically seen in the hippocampal formation after transient ischemia.