Neuromuscular synaptic transmission in Limulus polyphemus--I. Actions of aspartate, glutamate and the natural transmitter

Aspartate and glutamate were examined as excitatory transmitter candidates for the tibia flexor muscle of the chelicerate arthropod, Limulus polyphemus. Bath application of aspartate or glutamate caused dose-dependent depolarizations of Limulus muscle fibers and contractions of the whole muscle. Glutamate was about 10 times more potent than aspartate. Aspartate and glutamate depolarizations were associated with a conductance increase in muscle fibers, although aspartate depolarizations were dependent on external sodium, while glutamate depolarizations persisted in the absence of sodium. Although the Limulus excitatory postsynaptic potential (epsp) was associated with a conductance increase the ionic basis of the epsp could not be determined. If, however, the Limulus epsp, like other arthropod epsps, is sodium-dependent then the sodium-dependence of the aspartate depolarization is consistent with the action of the natural excitatory transmitter. The sodium-independence of glutamate action, however, is not consistent with generally accepted models of arthropod neuromuscular transmitter action. The rank order of potency for amino acid agonists indicates that the Limulus neuromuscular junction is pharmacologically very similar to other arthropod junctions which are well-accepted to be glutamatergic. Pentobarbital reversibly attenuated the amplitudes of the epsp and aspartate and glutamate depolarizations, and it was found to be the only useful antagonist in Limulus.     

Modulation of transmission at a glutamate synapse.

The amino acid L-aspartate markedly potentiates the responses elicited by L-glutamate at excitatory neuromuscular synapses in lobster walking limbs. Results are consistent with the idea that aspartate increases the affinity between glutamate and its binding sites in the postsynaptic receptor. Although complications due to release from other amino acid sources are a serious qualification, studies of neurally induced release of glutamate and aspartate suggest that both amino acids are released from excitatory nerve terminals. Experiments comparing the potentiating action of a variety of amino acids with their ability to inhibit glutamate uptake are not supportive of the notion that inhibition of agonist removal is the primary mode of action in the potentiation process. However, this idea, as well as the suggestion that aspartate may induce release of glutamate from extrajunctional entrapment sites, are not ruled out. Indeed, it is likely that the modulatory process embodies a multiplicity of reactions with given ones dominating from preparation to preparation.     

Autoreceptor Regulation of Glutamate and Aspartate Release from Slices of the Hippocampal CA1 Area

Slices of hippocampal area CA1 were employed to test the hypothesis that the release of glutamate and aspartate is regulated by the activation of excitatory amino acid autoreceptors. In the absence of added Mg2+, N-methyl-D-aspartate (NMDA)-receptor antagonists depressed the release of glutamate, aspartate, and gamma-aminobutyrate evoked by 50 mM K+. Conversely, the agonist NMDA selectively enhanced the release of aspartate. The latter action was observed, however, only when the K+ stimulus was reduced to 30 mM. Actions of the competitive antagonists 3-[(+/- )-2-carboxypiperazin-4-yl]-propyl-l-phosphonic acid (CPP) and D-2-amino-5-phosphonovalerate (D-AP5) differed, in that the addition of either 1.2 mM Mg2+ or 0.1 microM tetrodotoxin to the superfusion medium abolished the depressant effect of CPP without diminishing the effect of D-AP5. These results suggest that the activation of NMDA receptors by endogenous glutamate and aspartate enhances the subsequent release of these amino acids. The cellular mechanism may involve Ca2+ influx through presynaptic NMDA receptor channels or liberation of a diffusible neuromodulator linked to the activation of postsynaptic NMDA receptors. (RS)-alpha-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid, a selective quisqualate receptor agonist, and kainate, an agonist active at both kainate and quisqualate receptors, selectively depressed the K(+)-evoked release of aspartate. Conversely, 6-cyano-7-nitro-quinoxaline-2,3-dione, an antagonist active at both quisqualate and kainate receptors, selectively enhanced aspartate release. These results suggest that glutamate can negatively modulate the release of aspartate by activating autoreceptors of the quisqualate, and possibly also of the kainate, type. Thus, the activation of excitatory amino acid receptors has both presynaptic and postsynaptic effects.     

Cooperative interaction of glutamate and aspartate with receptors in the neuromuscular excitatory membrane in walking limbs of the lobster.

When applied to lobster muscle fibers, L-glutamate, L-aspartate, and combinations of the two amino acids can induce membrane depolarization. Under normal conditions, a quantitative analysis of the depolarization response or change in membrane conductance was precluded by nonlinearities in the voltage-current relationship of the membrane. By including gamma-aminobutyrate (GABA) in the bathing medium, the voltage-current relationship was made linear in the depolarizing direction over a range of 15-20 mV from the resting potential. However, a meaningful examination of the increase in membrane conductance caused by glutamate and aspartate was still not possible. Therefore, the depolarization responses caused by the excitatory amino acids were taken as a quantitative reflection of receptor activation in the excitatory postsynaptic membrane. In the presence of GABA, aspartate by itself, at concentrations up to 10 mM, had little excitatory activity, whereas glutamate effected an appreciable membrane depolarization at concentrations of 0.1 to 0.2 mM. Aspartate, at concentrations which exhibited no activity alone, markedly enhanced the excitatory action of glutamate. Aspartate shifted the glutamate dose-response curve to the left, but did not appear to affect the maximum depolarization response elicited by glutamate. These observations are consistent with the concept that aspartate increases the affinity between glutamate and the glutamate binding sites. Limiting slopes of log-dose versus log-response curves for the excitatory action of glutamate suggest that the interaction of glutamate with excitatory receptors is a cooperative process. The possibility exists that individual receptors contain multiple and distinct glutamate and aspartate binding sites. These results support the view that neuromuscular excitation in the lobster is mediated by glutamate and aspartate functioning synergistically.     

Cooperative interaction of glutamate and aspartate with receptors in the neuromuscular excitatory membrane in walking limbs of the lobster

When applied to lobster muscle fibers, L-glutamate, L-aspartate, and combinations of the two amino acids can induce membrane depolarization. Under normal conditions, a quantitative analysis of the depolarization response or change in membrane conductance was precluded by nonlinearities in the voltage—current relationship of the membrane. By including γ-aminobutyrate (GABA) in the bathing medium, the voltage—current relationship was made linear in the depolarizing direction over a range of 15–20 mV from the resting potential. However, a meaningful examination of the increase in membrane conductance caused by glutamate and aspartate was still not possible. Therefore, the depolarization responses caused by the excitatory amino acids were taken as a quantitative reflection of receptor activation in the excitatory postsynaptic membrane. In the presence of GABA, aspartate by itself, at concentrations up to 10 mM, had little excitatory activity, whereas glutamate effected an appreciable membrane depolarization at concentrations of 0.1 to 0.2 mM. Aspartate, at concentrations which exhibited no activity alone, markedly enhanced the excitatory action of glutamate. Aspartate shifted the glutamate dose-response curve to the left, but did not appear to affect the maximum depolarization response elicited by glutamate. These observations are consistent with the concept that aspartate increases the affinity between glutamate and the glutamate binding sites. Limiting slopes of log-dose versus log-response curves for the excitatory action of glutamate suggest that the interaction of glutamate with excitatory receptors is a cooperative process. The possibility exists that individual receptors contain multiple and distinct glutamate and aspartate binding sites. These results support the view that neuromuscular excitation in the lobster is mediated by glutamate and asparate functioning synergistically.     

Relationship of glutamate and aspartate to the periaqueductal gray-raphe magnus projection: analysis using immunocytochemistry and microdialysis.

This study tested the hypothesis that the excitatory amino acid transmitters glutamate and/or aspartate are associated with the periaqueductal gray (PAG)-raphe magnus (NRM) projection. Retrograde neuroanatomical tracing procedures utilizing the tracers WGA-HRP or D-[3H]-aspartate were combined with immunocytochemical localization of glutamate or aspartate to determine if glutamate and/or aspartate immunostained neurons projected to the NRM. Both glutamate- and aspartate-immunoreactive cells in the PAG were found to project to the NRM. Double labeling immunocytochemichemical procedures indicated that glutamate and aspartate are co-localized in many PAG neurons, suggesting the following possibilities: (a) one of these two amino acids may serve as a precursor to the other; (b) both amino acids may be co-released from the same PAG neuron; or (c) both amino acids are present in high levels in the perikarya for metabolic purposes. At the EM level, both glutamate- and aspartate-immunoreactive terminals were identified in the NRM, strengthening the concept that both amino acids participate in synaptic transmission in this medullary nucleus. To determine if glutamate and aspartate are in fact released from PAG-NRM axons, the PAG was stimulated chemically with homocysteic acid (HCA) and amino acids were collected from the NRM using a microdialysis probe. Microinjection of HCA, but not vehicle, into the PAG resulted in the release of both glutamate and aspartate in the nucleus raphe magnus. These data suggest that both glutamate and aspartate are released from PAG fibers terminating in the NRM and provide strong support for the hypothesis that excitatory amino acids play a neurotransmitter role in the PAG-NRM pathway.     

Alanine and glutamine synthesis and release from skeletal muscle. I. Glycolysis and amino acid release.

The synthesis and release of alanine and glutamine were investigated with an intact rat epitrochlaris muscle preparation. This preparation will maintain on incubation for up to 6 hours, tissue levels of phosphocreatine, ATP, ADP, lactate, and pyruvate closely approximating those values observed in gastrocnemius muscles freeze-clamped in vivo. The epitrochlaris preparation releases amino acids in the same relative proportions and amounts as a perfused rat hindquarter preparation and human skeletal muscle. Since amino acids were released during incubation without observable changes in tissue amino acids levels, rates of alanine and glutamine release closely approximate net amino acid synthesis. Large increases in either glucose uptake or glycolysis in muscle were not accompanied by changes in either alanine or glutamine synthesis. Insulin increased muscle glucose uptake 4-fold, but was without effect on alanine and glutamine release. Inhibition of glycolysis by iodacetate did not decrease the rate of alanine synthesis. The rates of alanine and glutamine synthesis and release from muscle decreased significantly during prolonged incubation despite a constant rate of glucose uptake and pyruvate production. Alanine synthesis and release were decreased by aminooxyacetic acid, an inhibitor of alanine aminotransferase. This inhibition was accompanied by a compensatory increase in the release of other amino acids, such as aspartate, an amino acid which was not otherwise released in appreciable quantities by muscle. The release of alanine, pyruvate, glutamate, and glutamine were observed to be interrelated events, reflecting a probable near-equilibrium state of alanine aminotransferase in skeletal muscle. It is concluded that glucose metabolism and amino acid release are functionally independent processes in skeletal muscle. Alanine release reflects the de novo synthesis of the amino acid and does not arise from the selective proteolysis of an alanine-rich storage protein. It appears that the rate of alanine and glutamine synthesis in skeletal muscle is dependent upon the transformation and metabolism of amino acid precursors.     

Extracellular levels of brain aspartate, glutamate and GABA during an inhibitory avoidance response in the rat

The extracellular levels of aspartate, glutamate and GABA were measured by microdialysis, coupled with an HPLC method, in rat prefrontal cortex (mPFC) and ventral hippocampus (VH) before and during the performance of a step-down inhibitory task. The basal levels of glutamate were about 50% higher than those of aspartate, and GABA levels were about 20-folds smaller than those of the excitatory amino acids. There were no significant differences in the basal levels of any of the three amino acids between the two brain regions. The extracellular levels of aspartate increased during acquisition and recall trials in both VH and mPFC, whereas those of glutamate increased in the VH during acquisition only. A significant increase in GABA levels was also detected during acquisition but only in the mPFC. The neuronal origin of the increased extracellular levels of aspartate, glutamate and GABA was demonstrated by administering tetrodotoxin directly into the mPFC or VH by reverse dialysis. These findings, together with previous evidence from our and other laboratories, indicate a differential release of aspartate and glutamate from excitatory neurons during the performance of behavioral responses, and therefore, distinct roles for the two excitatory amino acids should be envisaged.     

A possible mechanism for the hypoxia-hypoglycemia-induced release of excitatory amino acids from cultured hippocampal astrocytes

In order to elucidate the mechanism of release of excitatory amino acid (EAA) induced by hypoxiahypoglycemia (in vitro ischemia) from cultured hippocampal astrocytes, we compared the EAA release by in vitro ischemia with those by other treatments. The EAA release induced by in vitro ischemia treatment was rapid and reversible. The amount of released aspartate was comparable to that of glutamate, although the endogenous content of aspartate was one sixth that of glutamate. High-K (100 mM) treatment and the addition of 5 mM NaCN induced a rapid EAA release and the glutamate release was much greater than aspartate. Addition of 5 mM iodoacetate, a glycolysis inhibitor, induced a slow EAA release, and the amount of released aspartate was much higher than that of glutamate. On the other hand, the in vitro ischemia treatment and the addition of 5 mM NaCN induced only 20% reduction in ATP content for initial 5 min, whereas the addition of 5 mM iodiacetate induced a marked reduction. Our data suggest that ischemia-induced EAA release from astrocytes is a complex process in which local energy failure, inhibition of glycolysis, and depolarization of the cell membrane are involved.Abbreviations used EAA excitatory amino acids - PEI polyethyleneimine - DMEM Dulbecco's modified Eagle medium - HKR Hepesbuffered Krebs-Ringer solution     

Effect of Impact Trauma on Neurotransmitter and Nonneurotransmitter Amino Acids in Rat Spinal Cord

N-Methyl-D-aspartate (NMDA) administration exacerbates neurological dysfunction after traumatic spinal cord injury in rats, whereas NMDA antagonists improve outcome in this model. These observations suggest that release of excitatory amino acids contributes to secondary tissue damage after traumatic spinal cord injury. To further examine this hypothesis, concentrations of free amino acids were measured in spinal cord samples from anesthetized rats subjected to various degrees of impact trauma to the T9 spinal segment. Levels of excitatory and inhibitory neurotransmitter amino acids [gamma-aminobutyric acid (GABA), glutamate, aspartate, glycine, taurine] and levels of nonneurotransmitter amino acids (asparagine, glutamine, alanine, threonine, serine) were determined at 5 min, 4 h, and 24 h posttrauma. Uninjured surgical (laminectomy) control animals showed modest but significant declines in aspartate and glutamate levels, but not in other amino acids, at all time points. In injured animals, the excitatory amino acids glutamate and aspartate were significantly decreased by 5 min posttrauma, and remained depressed at 4 h and 24 h as compared with corresponding laminectomy controls. In contrast, the inhibitory amino acids, glycine, GABA, and taurine, were decreased at 5 min postinjury, had partially recovered at 4 h, and were almost fully recovered at 24 h. The nonneurotransmitter amino acids were unchanged at 5 min posttrauma and significantly increased at 4 h, with partial recovery at 24 h. At 4 h postinjury, severe trauma caused significantly greater decreases in aspartate and glutamate than did either mild or moderate injury. These findings are consistent with the postulated role of excitatory amino acids in CNS trauma.     

Relationships among seizures, extracellular amino acid changes, and neurodegeneration induced by 4-aminopyridine in rat hippocampus: a microdialysis and electroencephalographic study

4-Aminopyridine is a powerful convulsant that induces the release of neurotransmitters, including glutamate. We report the effect of intrahippocampal administration of 4-aminopyridine at six different concentrations through microdialysis probes on EEG activity and on concentrations of extracellular amino acids and correlate this effect with histological changes in the hippocampus. 4-Aminopyridine induced in a concentration-dependent manner intense and frequent epileptic discharges in both the hippocampus and the cerebral cortex. The three highest concentrations used induced also a dose-dependent enhancement of extracellular glutamate, aspartate, and GABA levels and profound hippocampal damage. Neurodegenerative changes occurred in CA1, CA3, and CA4 subfields, whereas CA2 was spared. In contrast, microdialysis administration of a depolarizing K+ concentration and of tetraethylammonium resulted in increased amino acid levels but no epileptic activity and no or moderate neuronal damage. These results suggest that seizure activity induced by 4-aminopyridine is due to a combined action of excitatory amino acid release and direct stimulation of neuronal firing, whereas neuronal death is related to the increased glutamate release but is independent of seizure activity. In addition, it is concluded that the glutamate release-inducing effect of 4-aminopyridine results in excitotoxicity because it occurs at the level of nerve endings, thus permitting the interaction of glutamate with its postsynaptic receptors, which is probably not the case after K+ depolarization.     

Stress Preferentially Increases Extraneuronal Levels of Excitatory Amino Acids in the Prefrontal Cortex: Comparison to Hippocampus and Basal Ganglia

Abstract: The technique of intracerebral microdialysis was used to assess the effect of stress on the extracellular concentrations of excitatory amino acids, glutamate and aspartate, in the rat medial prefrontal cortex, hippocampus, striatum, and nucleus accumbens. A 20-min restraint procedure led to an increase in extracellular glutamate in all regions tested. The increase in glutamate levels was significantly higher in the prefrontal cortex than that observed in other regions. With the exception of the striatum, extracellular levels of aspartate were increased in all regions. Furthermore, the increase in aspartate levels was significantly higher in prefrontal cortex compared to hippocampus and nucleus accumbens. Local perfusion of tetrodotoxin during the restraint procedure significantly decreased the stress-induced increase in extracellular excitatory amino acids. In order to ensure that the above results were not an artifact of restraint not associated with stress (e.g., decreased mobility), we also examined the effect of swimming stress on the extracellular levels of excitatory amino acids in selected regions, i.e., striatum and medial prefrontal cortex. Both regions displayed a significant increase in extracellular levels of aspartate and glutamate following 20 min of swimming in room temperature water. This study provides direct evidence that stress increases the neuronal release of excitatory amino acids in a regionally selective manner. The implications of the present findings for stress-induced catecholamine release and/or hippocampal degeneration are discussed.     

Excitatory amino acid receptors and transmitter release in the retina

The effects of excitatory amino acids and some analogues on the release of GABA and ACh from amacrine cells were studied. The release of endogenous GABA from the isolated rat retina was measured by HPLC. When animals were pretreated with γ-vinyl-GABA (GVG), glutamate evoked a large efflux of GABA but kainate, quisqualate and (NMDA) were relatively ineffective. The glutamate evoked release of GABA was calcium dependent and was blocked by the antagonist, piperidine-dicarboxylic acid (PDA) indicating that activation of excitatory amino acid receptors was involved in the response. The release of [³H]ACh from the rabbit retina was strikingly increased by homocysteate and this effect was blocked by NMDA. Since NMDA also blocked the light evoked release of [³H]ACh but not the effects of exogenous glutamate or aspartate, it is possible that homocysteate may be a bipolar cell transmitter released onto cholinergic amacrine cells.     

Kainate-induced stimulation of amino acid release from primary astroglial cultures of the rat hippocampus

The effects of the excitatory amino acid analogs kainate (KA) and N-methyl- -aspartate (NMDA) on release of amino acids from astrocytes in primary culture were investigated. Under basal conditions, glutamine was present in the medium at 15 μM. The levels of serine and taurine were 1.5 and 2.0 μM, respectively, while the concentration of other amino acids was below 1 μM. At 10 μM, KA did not affect amino acid release, whereas 100 μM KA enhanced glutamine release by 34% and taurine release by 85%. At 1 mM, KA stimulated the release of all amino acids measured. However, while most amino acids increased by 50–150%, glutamate and aspartate were elevated by more than 3000%. The effect of KA was greatly reduced by 1 mM kynurenate, an excitatory amino acid receptor antagonist. 1 mM NMDA did not stimulate amino acid release from the cultures. The results indicate that astrocytes are endowed with KA-receptive sites, but they do not seem to possess NMDA receptors.     

Glutamate and γ-Aminobutyric Acid Neurotransmitter Systems in the Acute Phase of Maple Syrup Urine Disease and Citrullinemia Encephalopathies in Newborn Calves

Cerebral cortex tissue was obtained at autopsy from neonatal Poll Hereford calves with clinically confirmed maple syrup urine disease (MSUD), neonatal Holstein-Friesian calves with clinically confirmed citrullinemia, and matched controls. From this, synaptosomes were prepared for studies of neurotransmitter amino acid uptake and stimulus-induced release, and synaptic plasma membranes were obtained for studies of associated postsynaptic receptor binding sites. As well as having abnormal brain tissue concentrations of the pathognomic plasma amino acids (markedly increased levels of the branched-chain compounds valine, isoleucine, and leucine in MSUD; marked elevation of citrulline levels in citrullinemia), both groups of diseased animals showed reduced brain tissue concentrations of each of the transmitter amino acids glutamate, aspartate, and gamma-aminobutyric acid (GABA). Nontransmitter amino acids were generally unaffected in either disease. Citrullinemic calves showed a marked increase in brain glutamine concentration; in calves with MSUD, the glutamine concentration was raised, but to a much lesser extent. The Na(+)-dependent synaptosomal uptake of both glutamate and GABA was markedly reduced (to less than 50% of control values in both cases) in citrullinemic calves but was unaltered in calves with MSUD. Whereas synaptosomes from normal calves showed the expected stimulus-coupled release of transmitter amino acids, especially glutamate and aspartate, and no response to stimulus of nontransmitter amino acids, there was no increased release of transmitter amino acids in response to depolarization in synaptosomes from citrullinemic calves.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alanine and glutamine synthesis and release from skeletal muscle. III. Dietary and hormonal regulation.

Alanine and glutamine formation and release were studied using the intact epitrochlaris preparation of rat skeletal muscle. Alanine release from skeletal muscle was increased by fasting (65%), cortisone (145%), thyroxine (200%), and diabetes (185%). Glutamine release was decreased by cortisone (37%) and diabetes (23%) but not significantly affected by fasting or thyroxine. Tissue levels of alanine were unchanged but tissue glutamine levels were markedly reduced (30 to 60%) in all treatment groups. Insulin added in vitro did not affect amino acid release even with preparations obtained from diabetic animals. Inhibition of glycolysis with 0.2 mM iodoacetate had no effect on the rate of alanine and glutamine formation in any treatment group. Pyruvate generation was increased by all treatments even in the presence of the inhibitor. Total skeletal muscle alanine, aspartate, and branched chain aminotransferase, glutamate dehydrogenase, and malic enzyme activities were not significantly altered in any treatment groups. The addition of 10 mM aspartate, cysteine, branched chain amino acids, and serine significantly increased alanine formation, whereas the maximal rate of glutamine formation in the presence of stimulating amino acids was reduced in each treatment groups--the most marked effects were noted with cortisone and diabetic preparations. Although accelerated muscle proteolysis is an important factor regulating alanine formation in skeletal muscle, the redirection of carbon flow from glutamine toward alanine formation observed in fasting, cortisone, thyroxine-treated, and diabetic rats, indicates that factors other than proteolysis also participate in the control of amino acid release from muscle.     

Stress-Induced Dopamine Release in the Neostriatum: Evaluation of the Role of Action Potentials in Nigrostriatal Dopamine Neurons or Local Initiation by Endogenous Excitatory Amino Acids

Abstract: It has been hypothesized that excitatory amino acids can initiate dopamine release in neostriatum. We examined whether the increase in extracellular dopamine in neostriatum produced by acute stress reflects presynaptic initiation of dopamine release by endogenous excitatory amino acids. Thirty minutes of intermittent tail-shock stress significantly elevated extracellular concentrations of dopamine, glutamate, aspartate, and γ-aminobutyric acid in neostriatum of freely moving rats as measured with in vivo microdialysis. Local infusion of the N -methyl- d -aspartate receptor antagonist 2-amino-5-phosphonovaler-ate or the non- N -methyl- d -aspartate receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione via the dialysis probe did not attenuate the stress-induced increase in extra cellular dopamine. In fact, the increase was prolonged in rats treated with specific excitatory amino acid receptor antagonists. Infusion of tetrodotoxin into medial forebrain bundle increased extra cellular glutamate and aspartate in neostriatum yet reduced basal dopamine in extra cellular fluid to below the limit of detection of the assay and eliminated the stress-induced increase in extra cellular dopamine. These findings fail to support the hypothesis that the stress-induced increase in extra cellular dopamine in neostriatum is initiated locally by excitatory amino acids. Rather, the effects of stress on extra cellular dopamine seem to be determined by impulse propagation in dopamine neurons.     

Release of Endogenous Amino Acids from the Striatum from Developing and Adult Mice in Ischemia

In most other studies the release of amino acid neurotransmitters and modulators in vitro has been studied mostly using labeled preloaded compounds. For several reasons the estimated release may not reliably reflect the release of endogenous compounds. The magnitudes of the release cannot thus be quite correctly estimated using radioactive labels. The basal and K⁺-evoked release of the neuroactive endogenous amino acids γ-aminobutyrate (GABA), glycine, taurine, glutamate and aspartate was now studied in slices from the striatum from 7-day-old to 3-month-old mice under control (normoxic) and ischemic conditions. The release of alanine, threonine and serine was assessed as control. GABA and glutamate release was much greater in 3-month-old than in 7-day-old mice, whereas with taurine the situation was the opposite. Ischemia markedly enhanced the release of all these three amino acids. The release of aspartate and glycine was markedly enhanced as well whereas no effects were discernible in the release of glutamine, alanine, serine and threonine. K⁺ stimulation (50 mM) enhanced the release of GABA, glutamate, taurine, aspartate and glycine in most cases, except with taurine in 3-month-old mice under the ischemic conditions and with aspartate in 7-day-old mice under the control conditions. K⁺ stimulation did not affect the release of glutamine, alanine, serine or threonine. The results on endogenous amino acids are qualitatively similar to those obtained in our earlier experiments with labeled preloaded amino acids. In conclusion, in developing mice only inhibitory taurine is released in such amounts that may counteract the harmful effects of excitatory amino acids in ischemia.     

Kainic Acid Differentially Affects the Synaptosomal Release of Endogenous and Exogenous Amino Acidic Neurotransmitters

Presynaptic actions of kainic acid have been tested on uptake and release mechanisms in synaptosome-enriched preparations from rat hippocampus and goldfish brain. Kainic acid increased in a Ca2+-dependent way the basal release of endogenous glutamate and aspartate from both synaptosomal preparations, with the maximum effect (40-80%) being reached at the highest concentration tested (1 mM). In addition, kainic acid potentiated, in an additive or synergic way, the release of excitatory amino acids stimulated by high K+ concentrations. Kainic acid at 1 mM showed a completely opposite effect on the release of exogenously accumulated D-[3H]aspartate. The drug, in fact, caused a marked inhibition of both the basal and the high K+-stimulated release. Kainic acid at 0.1 mM had no clear-cut effect, whereas at 0.01 mM it caused a small stimulation of the basal release. The present results suggest that kainic acid differentially affects two neurotransmitter pools that are not readily miscible in the synaptic terminals. The release from an endogenous, possibly vesiculate, pool of excitatory amino acids is stimulated, whereas the release from an exogenously accumulated, possibly cytoplasmic and carrier-mediated, pool is inhibited or slightly stimulated, depending on the external concentration of kainic acid. Kainic acid, in addition, strongly inhibits the high-affinity uptake of L-glutamate and D-aspartate in synaptic terminals. All these effects appear specific for excitatory amino acids, making it likely that they are mediated through specific recognition sites present on the membranes of glutamatergic and aspartatergic terminals. The relevance of the present findings to the mechanism of excitotoxicity of kainic acid is discussed.     

Accumulation of Extracellular Glutamate by Inhibition of Its Uptake Is Not Sufficient for Inducing Neuronal Damage: An In Vivo Microdialysis Study

Abstract: It is well documented that neurons exposed to high concentrations of excitatory amino acids, such as glutamate and aspartate, degenerate and die. The clearance of these amino acids from the synaptic cleft depends mainly on their transport by high-affinity sodium-dependent carriers. Using microdialysis in vivo and HPLC analysis, we have studied the effect of the administration of inhibitors of the glutamate transporter (l -trans-pyrrolidine-2,4-dicarboxylate and dihydrokainate) on the extracellular concentration of endogenous amino acids in the rat striatum. In addition, we have analyzed whether the changes observed in the concentration of glutamate and aspartate were injurious to striatal cells. Neuronal damage was assessed by biochemical determination of choline acetyltransferase and glutamate decarboxylase activities, 7 days after the microdialysis procedure. In other experiments, pyrrolidine dicarboxylate and dihydrokainate, as well as two other inhibitors of the glutamate carrier, dl -threo-β-hydroxyaspartate and l -aspartate-β-hydroxamate, were microinjected into the striatum, and neuronal damage was assessed, both biochemically and histologically, 7 or 14 days after the injection. Dihydrokainate and pyrrolidine dicarboxylate produced a similar remarkable increase in the concentration of extracellular aspartate and glutamate. However, the former induced also notable elevations in the concentration of other amino acids. Clear neuronal damage was observed only after dihydrokainate administration, which was partially prevented by intraperitoneal injection of (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine maleate or by intrastriatal coinjection of 2,3-dihydroxy-6-nitro-7-sulfamoylbenzo(f)quinoxaline. No cell damage was observed with the other three glutamate carrier inhibitors used. It is concluded that an increased extracellular glutamate level in vivo due to dysfunction of its transporter is not sufficient for inducing neuronal damage. The neurotoxic effects of dihydrokainate could be explained by direct activation of glutamate postsynaptic receptors, an effect not shared by the other inhibitors used.