Glutamate Neurotoxicity Is Independent of Calpain I Inhibition in Primary Cultures of Cerebellar Granule Cells

Glutamate-induced neurotoxicity and calpain activity were studied in primary cultures of rat cerebellar granule neurons and glial cells. Calpain activation, as monitored by quantitative immunoblotting of spectrin, required micromolar concentrations of Ca2+ in neuronal homogenates (calpain I) and millimolar Ca2+ concentrations in glial homogenates (calpain II). Glutamate-induced toxicity and calpain activation were observed in neuronal, but not in glial, cultures. In neurons, calpain I activation by glutamate was dose-dependent and persisted after withdrawal of neurotoxic doses of glutamate. Natural (GM1) and semisynthetic (LIGA4) gangliosides or the glutamate receptor blocker MK-801 prevented calpain I activation and delayed neuronal death elicited by glutamate. GM1 and LIGA4 had no effect on calpain I activity in neuronal homogenates, however. Furthermore, two calpain I inhibitors (leupeptin and N-acetyl-Leu-Leu-norleucinal) prevented glutamate-induced spectrin degradation, but failed to affect glutamate neurotoxicity. These results thus suggest that glutamate-induced neurotoxicity is independent of calpain I activation.     

Neuronal membrane depolarization and the control of cholinergic muscarinic receptors: selective effect on different neuronal cell types

1. The possibility that a long-lasting neuronal activation regulates the expression of muscarinic cholinergic receptors was studied with three cultured neuronal cell lines. 2. Continuous depolarization of a subclone of the neuroblastoma-glioma NG108-15 hybrid cells with potassium chloride increased by 45-75% the number of cholinergic muscarinic receptors, monitored with 3H-QNB, whereas a short incubation with KCl for 10 min or 6 hr had no effect. 3. The calcium channel blocker verapamil increased the effect of KCl. 4. Two cell lines, named SC9 and WC5, that originate from the rat brain, also bind 3H-QNB. They were therefore used to test whether the effect of chronic depolarization is universal. Depolarized SC9 and WC5 cells, in the presence or absence of verapamil, did not show an increased 3H-QNB binding. 5. Muscarinic receptors of both SC9 and WC5 cells have a higher affinity to pirenzepine than the M-3 receptor subtype of the neuroblastoma-glioma cells, suggesting therefore that the two rat brain cell lines possess M-1 or M-2 receptors. 6. The physiological significance of this differential role of depolarization on the expression of different muscarinic receptors is discussed in the context of their postreceptor second messengers.     

Glutamine synthetase enhances the clearance of extracellular glutamate by the neural retina

Clearance of synaptic glutamate by glial cells is required for the normal function of excitatory synapses and for prevention of neurotoxicity. Although the regulatory role of glial glutamate transporters in glutamate clearance is well established, little is known about the influence of glial glutamate metabolism on this process. This study examines whether glutamine synthetase (GS), a glial-specific enzyme that amidates glutamate to glutamine, affects the uptake of glutamate. Retinal explants were incubated in the presence of [(14)C]glutamate and glutamate uptake was assessed by measurement of the amount of radioactively labeled molecules within the cells and the amount of [(14)C]glutamine released to the medium. An increase in GS expression in Müller glial cells, caused by induction of the endogenous gene, did not affect the amount of glutamate accumulated within the cells, but led to a dramatic increase in the amount of glutamine released. This increase, which was directly correlated with the level of GS expression, was dependent on the presence of external sodium ions, and could be completely abolished by methionine sulfoximine, a specific inhibitor of GS activity. Our results demonstrate that GS activity significantly influences the uptake of glutamate by the neural retina and suggest that this enzyme may represent an important target for neuroprotective strategies.     

Alteration of Striatal Glutamate Release After Glutamine Synthetase Inhibition

The effect of the glutamine synthetase (GS) inhibitor, methionine sulfoximine (MSO), on glutamate levels in, and glutamate release from, rat striatal tissue was examined. Tissue levels of glutamate were unchanged 24 h after an intraventricular injection of MSO, but tissue glutamine levels were decreased 50%. Calcium-dependent, potassium-stimulated glutamate release was diminished in tissue prisms from animals pretreated with MSO compared to controls. The decreased release of glutamate correlated over time with the inhibition of GS following an intraventricular injection of MSO. The maximum diminution of calcium-dependent, potassium-stimulated glutamate release (50%) and the maximum inhibition of GS activity (51%) were observed 24 h after MSO. The addition of 0.5 mM glutamine to the perfusion medium completely reversed the effects of MSO pretreatment on calcium-dependent, potassium-stimulated glutamate release. Since GS is localized in glial cells and the measured glutamate release is presumed to occur from neurons, the data support the contention that astroglial glutamine synthesis is an important contributor to normal neuronal neurotransmitter release.     

Effect of pleiotrophin on glutamate-induced neurotoxicity in cultured hippocampal neurons

Pleiotrophin (PTN) is a secreted heparin-binding cytokine that signals diverse functions, including lineage-specific differentiation of glial progenitor cells, axonal outgrowth and angiogenesis. Neurotoxicity mediated by glutamate receptor is thought to play a role in various neurodegenerative disorders. In the present study, we examined the effect of PTN on the neuronal viability of hippocampal neurons in vitro by using the immunostaining of MAP2 and permeability of propidium iodide. PTN significantly prevented glutamate-induced neurotoxicity when hippocampal neurons were treated with PTN after the glutamate stimulation. PTN significantly promoted glutamate-induced neurotoxicity, when cells were incubated with PTN before and after the glutamate stimulation. Thus, the effect of PTN on the neuronal viability of hippocampal neurons largely depends on the timing of the treatment of PTN. The treatment of PTN promoted dendrite-specific expression of MAP2, indicating that PTN stabilizes microtubule system at dendrites. The data suggest that PTN may be relevant to be concerned with glutamate-induced neurotoxicity of hippocampal neurons.     

Neuronal Glutamine Utilization: Glutamine/Glutamate Homeostasis in Synaptosomes

The synaptosomal metabolism of glutamine was studied under in vitro conditions that simulate depolarization in vivo. With [2-15N]glutamine as precursor, the [glutamine]i was diminished in the presence of veratridine or 50 mM KCl, but the total amounts of [15N]glutamate and [15N]aspartate formed were either equal to those of control incubations (veratridine) or higher (50 mM [KCl]). This suggests that depolarization decreases glutamine uptake and independently augments glutaminase activity. Omission of sodium from the medium was associated with low internal levels of glutamine which indicates that influx occurs as a charged Na(+)-amino acid complex. It is postulated that a reduction in membrane potential and a collapse of the Na+ gradient decrease the driving forces for glutamine accumulation and thus inhibit its uptake and enhance its release under depolarizing conditions. Inorganic phosphate stimulated glutaminase activity, particularly in the presence of calcium. At 2 mM or lower [phosphate] in the medium, calcium inhibited glutamine utilization and the production of glutamate, aspartate, and ammonia from glutamine. At a high (10 mM) medium [phosphate], calcium stimulated glutamine catabolism. It is suggested that a veratridine-induced increase in intrasynaptosomal inorganic phosphate is responsible for the enhancement of flux through glutaminase; calcium affects glutaminase indirectly by modulating the level of free intramitochondrial [phosphate]. Because phosphate also lowers the Km of glutaminase for glutamine, augmentation of the amino acid breakdown may occur even when depolarization lowers [glutamine]i. Reducing the intrasynaptosomal glutamate to 26 nmol/mg of protein had little effect on glutamine catabolism, but raising the pH to 7.9 markedly increased formation of glutamate and aspartate. It is concluded that phosphate and H+ are the major physiologic regulators of glutaminase activity.     

ATP induces the death of developing avian retinal neurons in culture via activation of P2X7 and glutamate receptors

Previous data suggest that nucleotides are important mitogens in the developing retina. Here, the effect of ATP on the death of cultured chick embryo retina cells was investigated. In cultures obtained from retinas of 7-day-old chick embryos (E7) that were cultivated for 2 days (E7C2), both ATP and BzATP induced a ～30 % decrease in cell viability that was time- and dose-dependent and that could be blocked by 0.2 mM oxidized ATP or 0.3 μM KN-62. An increase in cleaved caspase-3 levels and in the number of TUNEL-positive cells was observed when cultures were incubated with 3 mM ATP and immunolabeling for cleaved-caspase 3 was observed over neurons but not over glial cells. ATP-dependent cell death was developmentally regulated, the maximal levels being detected by E7C2-3. Nucleotides were able to increase neuronal ethidium bromide and sulforhodamine B uptake in mixed and purified neuronal cultures, an effect that was blocked by the antagonists Brilliant Blue G and oxidized ATP. In contrast, nucleotide-induced cell death was observed only in mixed cultures, but not in purified cultures of neurons or glia. ATP-induced neuronal death was blocked by the glutamatergic antagonists MK801 and DNQX and activation of P2X7 receptors by ATP decreased the uptake of [³H]-d-aspartate by cultured glial cells with a concomitant accumulation of it in the extracellular medium. These results suggest that ATP induces apoptosis of chick embryo retinal neurons in culture through activation of P2X7 and glutamate ionotropic receptors. Involvement of a P2X7 receptor-mediated inhibition of the glial uptake of glutamate is suggested.     

Mechanism by which GABA, through its GABA(A) receptor, modulates glutamate release from rat cortical neurons in culture

In cortical neurons, the GABA(A) agonist, muscimol, increases: (a) basal glutamate release (with a EC50 of 99 +/- 7 microM); (b) intracellular calcium and (c) membrane potential, all of these in a dose-dependent manner. These muscimol effects were specific since they were reversed by bicuculline, a GABA(A) antagonist. When the action of muscimol was measured at different KCl concentrations, an increase or decrease of the glutamate secretion was observed, depending on the KCl concentration in the medium. At low KCl concentration (5.6 mM of KCl), it depolarized, at 20 mM of KCl it had no effect, but at higher KCl concentrations (30-100 microM of KCl), it produced a hyperpolarization in these cells. The mechanism by which the GABA-Cl(-)-channel permits Cl- fluxes, inward or outward, depending on the membrane potential.     

Ammonia assimilation and glutamate formation in the anaerobe Selenomonas ruminantium.

Selenomonas ruminantium was found to possess two pathways for NH4+ assimilation that resulted in net glutamate synthesis. One pathway fixed NH4+ through the action of an NADPH-linked glutamate dehydrogenase (GDH). Maximal GDH activity required KCl (about 0.48 M), but a variety of monovalent salts could replace KCl. Complete substrate saturation of the enzyme by NH4+ did not occur, and apparent Km values of 6.7 and 23 mM were estimated. Also, an NADH-linked GDH activity was observed but was not stimulated by KCl. Cells grown in media containing non-growth-rate-limiting concentrations of NH4+ had the highest levels of GDH activity. The second pathway fixed NH4+ into the amide of glutamine by an ATP-dependent glutamine synthetase (GS). The GS did not display gamma-glutamyl transferase activity, and no evidence for an adenylylation/deadenylylation control mechanism was detected. GS activity was highest in cells grown under nitrogen limitation. Net glutamate synthesis from glutamine was effected by glutamate synthase activity (GOGAT). The GOGAT activity was reductant dependent, and maximal activity occurred with dithionite-reduced methyl viologen as the source of electrons, although NADPH or NADH could partially replace this artificial donor system. Flavin adenine dinucleotide, flavin mononucleotide, or ferredoxin could not replace methyl viologen. GOGAT activity was maximal in cells grown with NH4+ as sole nitrogen source and decreased in media containing Casamino Acids.     

Role of group I metabotropic glutamate receptors and NMDA receptors in homocysteine-evoked acute neurodegeneration of cultured cerebellar granule neurones

Hyperhomocysteinemia is a risk factor in neurodegeneration. It has been suggested that apart from disturbances in methylation processes, the mechanisms of this effect may include excitotoxicity mediated by the N-methyl-D-aspartate (NMDA) receptors. In this study we demonstrate that apart from NMDA receptors, also group I metabotropic glutamate receptors participate in acute homocysteine (Hcy)-induced neurotoxicity in cultured rat cerebellar granule neurones. Primary neuronal cultures were incubated for 30 min in the Mg(2+)-free ionic medium containing homocysteine and other ligands, and neurodegenerative changes were assessed 24h later using propidium iodide staining. D,L-Homocysteine given alone appeared to be a weak neurotoxin, with EC(50) of 17.4mM, whereas EC(50) for L-glutamate was 0.17 mM. Addition of 50 microM glycine enhanced homocysteine neurotoxicity, and only that portion of neurotoxicity was abolished by 0.5 microM MK-801, an uncompetitive NMDA receptor antagonist. The net stimulation of 45Ca uptake by granule cells incubated in the presence of 25 mM D,L-homocysteine with 50 microM glycine was only 3% of the net uptake evoked by 1mM glutamate. Application of an antagonist of group I metabotropic glutamate receptors (mGluRs) LY367385 at 25 and 250 microM concentrations, induced a dose-dependent partial neuroprotection, whereas given together with MK-801 completely prevented neurotoxicity. In the absence of glycine, LY367385 and MK-801 given alone failed to induce neuroprotection, while applied together completely prevented homocysteine neurotoxicity. Agonist of group I mGluRs, 10 trans-azetidine-2,3-dicarboxylic acid (t-ADA) induced significant neurotoxicity. This study shows for the first time that acute homocysteine-induced neurotoxicity is mediated both by group I mGluRs and NMDA receptors, and is not accompanied by massive influx of extracellular Ca(2+) to neurones.     

Expression of mutant huntingtin in glial cells contributes to neuronal excitotoxicity

Huntington disease (HD) is characterized by the preferential loss of striatal medium-sized spiny neurons (MSNs) in the brain. Because MSNs receive abundant glutamatergic input, their vulnerability to excitotoxicity may be largely influenced by the capacity of glial cells to remove extracellular glutamate. However, little is known about the role of glia in HD neuropathology. Here, we report that mutant huntingtin accumulates in glial nuclei in HD brains and decreases the expression of glutamate transporters. As a result, mutant huntingtin (htt) reduces glutamate uptake in cultured astrocytes and HD mouse brains. In a neuron-glia coculture system, wild-type glial cells protected neurons against mutant htt-mediated neurotoxicity, whereas glial cells expressing mutant htt increased neuronal vulnerability. Mutant htt in cultured astrocytes decreased their protection of neurons against glutamate excitotoxicity. These findings suggest that decreased glutamate uptake caused by glial mutant htt may critically contribute to neuronal excitotoxicity in HD.     

GLUCOSE AND AMINO ACID METABOLISM IN ISOLATED NEURONAL AND GLIAL CELL FRACTIONS IN VITRO

Abstract—

• 1 The metabolism of three substrates, [U-¹⁴C]glucose, [U-¹⁴C]pyruvate and [U-¹⁴C]glutamate has been studied in vitro in neuronal and glial cell fractions obtained from rat cerebral cortex by a density gradient technique.
• 2 The mixed cell suspension, after washing, metabolized glucose and glutamate in a manner essentially similar to the tissue slice. Exceptions were a reduced ability to generate lactate from glucose and alanine from glutamate, and a lowered effect of added glucose in suppressing the production of aspartate from glutamate.
• 3 After 2 hr incubation with [U-¹⁴C]glucose, the concentration of the amino acids glutamate, glutamine, GABA, aspartate and alanine were raised in the neuronal, compared to the glial fraction to 234 per cent, 176 per cent, 202 per cent, 167 per cent and 230 per cent respectively although both were lower than in the tissue slice. Incorporation of radio-activity was absolutely lower in the neuronal fraction, however, and the specific activities of the amino acids were: glutamate 12 per cent, GABA 18 per cent, aspartate 34 per cent, and alanine 33 per cent of those in the glial fraction.
• 4 After the incubation with [U-¹⁴C]pyruvate, the pool size of the amino acids were higher than after incubation with glucose, except for GABA, which was reduced to one-third. The concentrations of the amino acids glutamate, glutamine, GABA, aspartate, and alanine in the neuronal fraction were respectively 46 per cent, 143 per cent, 105 per cent, 97 per cent, and 57 per cent of those in the glial. Thus, with the exception of alanine, the specific activity of the neuronal amino acids compared to the glial was little increased when pyruvate replaced glucose as substrate.
• 5 After 2 hr incubation with [U-¹⁴C]glutamate in the presence of non-radioactive glucose, the pool sizes of all the amino acids were increased in both neuronal and glial fractions, with the exception of neuronal alanine and glial glutamine. The concentrations of the amino acids glutamine, GABA, aspartate and alanine were raised in the neuronal fraction, compared to the glial, to 425 per cent, 187 per cent, 222 per cent, and 133 per cent respectively. The specific activities of all the amino acids were higher than with glucose alone with the exception of alanine, and neuronal GABA. Neuronal glutamine and aspartate had specific activities respectively 102 per cent and 84 per cent of glial.
• 6 An unidentified amino acid, with R_F comparable to that of alanine and specific activity close to that of glutamate, was also present after incubation. It was relatively concentrated in the neuronal fraction.
• 7 The distribution of the enzymes glutamate dehydrogenase, aspartate aminotransferase, glutamate decarboxylase and glutamine synthetase between the cell fractions was studied. With the exception of glutamine synthetase, none of the enzymes was lost from the cell fractions during their preparation. Only 14 per cent of the glutamine synthetase, compared with 75 per cent of total protein, was recovered in the fractions. Of the enzymes, glutamate dehydrogenase activity was 406 per cent, and glutamate synthetase activity 177 per cent in the neuronal fraction compared to the glial in the absence of detergent. In the presence of detergent, glutamate dehydrogenase control was 261 per cent, aspartate aminotransferase activity 237 per cent is the neuronal as compared to the glial fraction.
• 8 Incorporation of radioactivity into acid-insoluble material from either glutamate or pyruvate was twice as high into the neuronal as the glial fraction.
• 9 The extent to which these differences may be extrapolated back to the intact tissue is considered, and certain correction factors calculated. The significance of the observations for an understanding of the compartmentation of amino acid pools and metabolism in the brain, and the possible identification of such compartments, is discussed.

     

Role of retinal glial cells in neurotransmitter uptake and metabolism

In addition to photoreceptors and neurons, glial cells (in particular Müller cells) contribute to the removal and metabolization of neurotransmitters in the neural retina. This review summarizes the present knowledge regarding the role of retinal glial cells in the uptake of glutamate, N-acetylaspartylglutamate, γ-aminobutyric acid, glycine, and d-serine, as well as the degradation and removal of purinergic receptor agonists. Some major pathways of glutamate metabolism in Müller cells are described; these pathways are involved in the glutamate–glutamine cycle of the retina, in the defense against oxidative and nitrosative stress via the production of glutathione, and in the production of substrates for the neuronal energy metabolism. In addition, the developmental regulation of the major glial glutamate transporter, GLAST, and of the glia-specific enzyme glutamine synthetase is described, as well as the importance of a malfunction and even reversal of glial glutamate transporters, and a downregulation of the glutamine synthetase, as pathogenic factors in different retinopathies.     

Alteration in Neuronal-Glial Metabolism of Glutamate by the Neurotoxin Kainic Acid

The effect of the excitotoxin kainic acid on glutamate and glutamine metabolism was studied in cerebellar slices incubated with D-[2-14C]glucose, [U-14C]gamma-aminobutyric acid, [3H]acetate, [U-14C]glutamate, and [U-14C]glutamine as precursors. Kainic acid (1 mM) strongly inhibited the labeling of glutamine relative to that of glutamate from all precursors except [2-14C]glucose and [U-14C]glutamine. Kainic acid did not inhibit glutamine synthetase directly. The data indicate that in the cerebellum kainic acid inhibits the synthesis of glutamine from the small pool of glutamate that is thought to be associated with glial cells. Kainic acid also markedly stimulated the efflux of glutamate from cerebellar slices and this release was not sensitive to tetrodotoxin. Kainic acid stimulated efflux of both glucose- and acetate-labeled glutamate. In contrast, veratridine released glucose-labeled glutamate preferentially via a tetrodotoxin-sensitive mechanism. Kainic acid did not release [U-14C]glutamate from synaptosomal fractions. These results suggest that the bulk of the glutamate released from cerebellar slices by kainic acid comes from nonsynaptic pools.     

Basic fibroblast growth factor: a potential inhibitor of glutamine synthetase expression in injured neural tissue

Basic fibroblast growth factor (bFGF) was recently shown to promote the survival of neural cells and tissues, raising hopes for its therapeutic potential in degenerative disorders of the CNS. Here we examine the effect of bFGF on the expression of glutamine synthetase, a key enzyme in the detoxification of the neurotransmitter glutamate. Expression of this enzyme is regulated by systemic glucocorticoids and, in chick neural retina tissue, is restricted to Müller glial cells. We report that exogenous supply of bFGF to retinal explants inhibits hormonal induction of glutamine synthetase expression. This inhibition appears to be mediated by the c-Jun protein which accumulated, in response to bFGF, exclusively in Müller glial cells. Ischemic conditions, which reportedly stimulate the release of endogenous bFGF, also led to an increase in c-Jun protein and a decline in glutamine synthetase expression. This decline could be competitively prevented by a soluble fibroblast growth factor receptor but not by a soluble epidermal growth factor receptor. The finding that endogenous release of bFGF or its exogenous supply down-regulates glutamine synthetase expression suggests that in addition to its reported neuroprotective effect, bFGF may exacerbate glutamate mediated neurotoxicity through direct down-regulation of glutamine synthetase.     

Quinolinic acid stimulates synaptosomal glutamate release and inhibits glutamate uptake into astrocytes

Quinolinic acid (QA) is an endogenous neurotoxin involved in various neurological diseases, whose action seems to be exerted via glutamatergic receptors. However, the exact mechanism responsible for the neurotoxicity of QA is far from being understood. We have previously reported that QA inhibits vesicular glutamate uptake. In this work, investigating the effects of QA on the glutamatergic system from rat brain, we have demonstrated that QA (from 0.1 to 10mM) had no effect on synaptosomal L-[3H]glutamate uptake. The effect of QA on glutamate release in basal (physiological K+ concentration) or depolarized (40 mM KCl) conditions was evaluated. QA did not alter K+-stimulated glutamate release, but 5 and 10mM QA significantly increased basal glutamate release. The effect of dizolcipine (MK-801), a noncompetitive antagonist of N-methyl-D-aspartate (NMDA) receptor on glutamate release was investigated. MK-801 (5 microM) did not alter glutamate release per se, but completely abolished the QA-induced glutamate release. NMDA (50 microM) also stimulated glutamate release, without altering QA-induced glutamate release, suggesting that QA effects were exerted via NMDA receptors. QA (5 and 10mM) decreased glutamate uptake into astrocyte cell cultures. Enhanced synaptosomal glutamate release, associated with inhibition of glutamate uptake into astrocytes induced by QA could contribute to increase extracellular glutamate concentrations which ultimately lead to overstimulation of the glutamatergic system. These data provide additional evidence that neurotoxicity of QA may be also related to disturbances on the glutamatergic transport system, which could result in the neurological manifestations observed when this organic acid accumulates in the brain.     

Measurements of the anaplerotic rate in the human cerebral cortex using 13C magnetic resonance spectroscopy and [1-13C] and [2-13C] glucose

Recent studies in rodent and human cerebral cortex have shown that glutamate-glutamine neurotransmitter cycling is rapid and the major pathway of neuronal glutamate repletion. The rate of the cycle remains controversial in humans, because glutamine may come either from cycling or from anaplerosis via glial pyruvate carboxylase. Most studies have determined cycling from isotopic labeling of glutamine and glutamate using a [1-(13)C]glucose tracer, which provides label through neuronal and glial pyruvate dehydrogenase or via glial pyruvate carboxylase. To measure the anaplerotic contribution, we measured (13)C incorporation into glutamate and glutamine in the occipital-parietal region of awake humans while infusing [2-(13)C]glucose, which labels the C2 and C3 positions of glutamine and glutamate exclusively via pyruvate carboxylase. Relative to [1-(13)C]glucose, [2-(13)C]glucose provided little label to C2 and C3 glutamine and glutamate. Metabolic modeling of the labeling data indicated that pyruvate carboxylase accounts for 6 +/- 4% of the rate of glutamine synthesis, or 0.02 micromol/g/min. Comparison with estimates of human brain glutamine efflux suggests that the majority of the pyruvate carboxylase flux is used for replacing glutamate lost due to glial oxidation and therefore can be considered to support neurotransmitter trafficking. These results are consistent with observations made with arterial-venous differences and radiotracer methods.     

The glutathione content of retinal Müller (glial) cells: effect of pathological conditions

Maintenance of isolated retinal Müller (glial) cells in glutamate-free solutions over 7 h causes a significant loss of their initial glutathione content; this loss is largely prevented by the blockade of glutamine synthesis using methionine sulfoximine (5 mM). Anoxia does not reduce the glutathione content of Müller cells when glucose (11 mM), glutamate and cystine (0.1 mM each) are present. In contrast, simulation of total ischemia (i.e., anoxia plus removal of glucose) decreases the glutathione levels dramatically, even in the presence of glutamate and cystine. Less severe effects are caused by high extracellular K+ (40 mM). Reactive oxygen species are generated in the retina under various conditions, such as anoxia, ischemia, and reperfusion. One of the crucial substances protecting the retina against reactive oxygen species is glutathione, a tripeptide constituted of glutamate, cysteine and glycine. It was recently shown that glutathione can be synthesized in retinal Müller glial cells and that glutamate is the rate-limiting substance. In this study, glutathione levels were determined in acutely isolated guinea-pig Müller cells using the glutathione-sensitive fluorescent dye monochlorobimane. The purpose was to find out how the glial glutathione content is affected by anoxia/ischemia and accompanying pathophysiological events such as depolarization of the cell membrane. Our results further strengthen the view that glutamate is rate-limiting for the glutathione synthesis in glial cells. During glutamate deficiency, as caused by e.g., impaired glutamate uptake, this amino acid is preferentially delivered to the glutamate-glutamine pathway, at the expense of glutathione. This mechanism may contribute to the finding that total ischemia (but not anoxia) causes a depletion of glial glutathione. In situ depletion may be accelerated by the ischemia-induced increase of extracellular K+, decreasing the driving force for glutamate uptake. The ischemia-induced lack of glutathione is particularly fatal considering the increased production of reactive oxygen species under this condition. Therefore the therapeutic application of exogenous free radical scavengers is greatly recommended.     

Long-term kainic acid exposure reveals compartmentation of glutamate and glutamine metabolism in cultured cerebellar neurons

Glutamate neurotoxicity is implicated in most neurodegenerative diseases, and in the present study the long-term effects of the glutamate agonist kainic acid (KA) on cerebellar neurons are investigated. Primary cell cultures, mainly consisting of glutamatergic granule neurons, were cultured in medium containing 0.05 or 0.50 mM KA for 7 days and subsequently incubated in medium containing [U-¹³C]glutamate or [U-¹³C]glutamine. The amount of protein and number of cells were greatly reduced in cultures exposed to 0.50 mM KA compared to those exposed to 0.05 mM KA. Glutamine consumption was not affected by KA concentration, whereas that of glutamate was decreased by high KA, confirming reduction in glutamate transport reported earlier. Neurons cultured with 0.50 mM KA and incubated with glutamate contained decreased amounts of glutamate, aspartate and GABA compared to those cultured with 0.05 mM KA. Incubation of cells exposed to 0.50 mM KA with glutamine led to an increased amount of glutamate compared to cells exposed to 0.05 mM KA, whereas the intracellular amounts of aspartate and GABA remained unaffected by KA concentration. Furthermore, mitochondrial metabolism of -[U-¹³C]ketoglutarate derived from [U-¹³C]glutamate and [U-¹³C]glutamine was significantly reduced by 0.50 mM KA. The results presented illustrate differential vulnerability to KA and can only be understood in terms of inter- and intracellular compartmentation.