Effect of kainate on ATP levels and glutamate metabolism in cerebellar slices

Protective effect of IL-18 on kainate- and IL-1 beta-induced cerebellar ataxia in mice

The pathogenesis of sporadic cerebellar ataxia remains unknown. In this study, we demonstrate that proinflammatory cytokines, IL-18 and IL-1beta, reciprocally regulate kainate-induced cerebellar ataxia in mice. We show that systemic administration of kainate activated IL-1beta and IL-18 predominantly in the cerebellum of mice, which was accompanied with ataxia. Mice deficient in caspase-1, IL-1R type I, or MyD88 were resistant to kainate-induced ataxia, while IL-18- or IL-18R alpha-deficient mice displayed significant delay of recovery from ataxia. A direct intracerebellar injection of IL-1beta-induced ataxia and intracerebellar coinjection of IL-18 counteracted the effect of IL-1beta. Our data firstly show that IL-18 and IL-1beta display differential direct regulation in kainate-induced ataxia in mice. Our results might contribute toward the development of a new therapeutic strategy for cerebellar ataxia in humans.

Protection against kainate-induced excitotoxicity by adenosine A2A receptor agonists and antagonists

The neuroprotective role of adenosine receptor agonists in various models of ischaemia and neuronal excitotoxicity has been attributed to adenosine A1 receptor activation. In this study we examine the role of the A2A receptor in the kainate model of excitotoxicity. Kainate (10 mg/kg) was administered systemically 10 min after the intraperitoneal injection of adenosine analogues. The A2A agonist 2-p-(2-carboxyethyl)phenethylamino-5'-N-ethylcarboxamidoadenosine hydrochloride (CGS21680) protected the hippocampus at concentrations of 0.1 and 0.01 mg/kg, but not at 2 microg/kg. The addition of the centrally acting adenosine A1 receptor antagonist 8-cyclopentyl-1,3-dipropylxanthine partially reduced protection only in the CA3a region, suggesting that only a small proportion of the protection was attributable to the A1 receptor. A less potent A2A agonist, N6-[2-(3,5-dimethyoxyphenyl)-2-(2-methylphenyl)-ethyl]adenosine (1 mg/kg), provided only partial protection against kainate. 4-(2-[7-Amino-2-[2-furyl][1,2,4]triazolo[2,3-a][1,3,5]triazin-5-yl -amino]ethyl)phenol, a selective A2A antagonist, also showed protection against kainate-induced neuronal death, when administered alone or in combination with CGS21680. These results show that adenosine A2A receptor activation is protective against excitotoxicity. The protection is largely independent of A, receptor activation or blockade.

Assessment of neurotoxicity and "neuroprotection"

Coronal brain slices allow the study of neurotoxicity and "neuroprotection" under conditions where the differentiation-state and interrelationships of the neurones and glial cells are closer to those occurring in the intact tissue than is the case for co-cultured cell systems. The involvement of glial cells in the excitotoxicity of kainate and the potentiation of this toxicity by inhibition of glutamine synthase can be demonstrated. Longer-term toxicity of kainate may also be compounded by depletion of glutathione levels resulting from inhibition of gamma-glutamylcysteine synthase. The involvement of nitric oxide formation in the toxicity of N-methyl-D-aspartate can also be shown. The neurotoxicity of 1-methyl-4-phenylpyridinium can be readily demonstrated in coronal slice preparations. Taurine affords protection against this neurotoxicity. The possible mechanisms of these effects are considered in terms of the cyclic interrelationships between the different events which can lead to cell death.

Alteration in the glial cell metabolism of glutamate by kainate and N-methyl-D-aspartate

Incubation of coronal slices of rat brain with neurotoxic concentrations of kainate (300 microM) and N-methyl-D-aspartate (NMDA; 500 microM) for 40 min reduced the activity of the glial enzyme, glutamine synthetase, by 33% and 21%, respectively. The immunoreactivity of the neuronal enzyme, gamma gamma-enolase (neuron-specific enolase), was also decreased, but to a lesser extent than glutamine synthetase. Pre-incubation of the slices with L-methionine-S-sulphoximine (500 microM), an irreversible inhibitor of both glutamine synthetase and gamma-glutamylcysteine synthetase, before addition of either kainate or NMDA produced a supra-additive reduction in the activity of the enzyme in both cases. Neither kainate nor NMDA directly inhibited the activity of glutamine synthetase, but kainate did inhibit gamma-glutamylcysteine synthetase, a rate-limiting enzyme of the gamma-glutamyl cycle, which is responsible for maintaining glutathione levels within cells. Pre-incubation of the slices with L-NG-nitroarginine, a competitive inhibitor of nitric oxide synthase, effectively prevented the NMDA-induced reduction in glutamine synthetase and neuron specific enolase, but did not diminish the kainate-induced decrease in the activity of either enzyme. These results provide evidence that NMDA, as well as kainate, indirectly affects the activity of glutamine synthetase in brain slices, yet does so by a different mechanism from kainate. The results are discussed in terms of the possible mode of action of each toxin in inhibiting the glial cell metabolism of glutamate.

The inhibition of glutamine synthetase in rat corpus striatum in vitro by methionine sulfoximine increases the neurotoxic effects of kainate and N-methyl-D-aspartate

Coronal slices of rat brain were incubated in Krebs bicarbonate medium containing kainate (300 microM), or N-methyl-D-aspartate (500 microM). Degeneration of striatal neurons by both these toxins was apparent after 40 min incubation, and was accompanied by a 33% (kainate) and 21% (N-methyl-D-aspartate) reduction in striatal glutamine synthetase activity. Pre-incubation of the slices with 500 microM L-methionine sulfoximine, an inhibitor of glutamine synthetase, for 20 min prior to the exposure to either kainate or N-methyl-D-aspartate, again showed extensive degeneration of striatal neurons, and a supra-additive reduction in glutamine synthetase activity in the tissue. The activity of the neuronal marker enzyme, neuron-specific enolase, was also reduced by pre-incubation of the slices with L-methionine sulfoximine before the addition of kainate or N-methyl-D-aspartate, but to a much lesser extent than glutamine synthetase. The results are discussed in terms of a possible mechanism of interaction between either kainate or N-methyl-D-aspartate, and glial cell metabolism.

Inhibition of sodium-potassium-ATPase: a potentially ubiquitous mechanism contributing to central nervous system neuropathology

Direct and indirect evidence suggests that Na+/K(+)-ATPase activity is reduced or insufficient to maintain ionic balances during and immediately after episodes of ischemia, hypoglycemia, epilepsy, and after administration of excitotoxins (glutamate agonists). Recent results show that inhibition of this enzyme results in neuronal death, and thus a hypothesis is proposed that a reduction and/or inhibition of this enzyme contributes to producing the central neuropathy found in the above disorders, and identifies potential mechanisms involved. While the extent of inhibition of Na+/K(+)-ATPase during ischemia, hypoglycemia and epilepsy may be insufficient to cause neuronal death by itself, unless the inhibition is severe and prolonged, there are a number of interactions which can lead to a potentiation of the neurotoxic actions of glutamate, a prime candidate for causing part of the damage following trauma. Presynaptically, inhibition of the Na+/K(+)-ATPase destroys the sodium gradient which drives the uptake of acidic amino acids and a number of other neurotransmitters. This results in both a block of reuptake and a stimulation of the release not only of glutamate but also of other neurotransmitters which modulate the neurotoxicity of glutamate. An exocytotic release of glutamate can also occur as inhibition of the enzyme causes depolarization of the membrane, but exocytosis is only possible when ATP levels are sufficiently high. Postsynaptically, the depolarization could alleviate the magnesium block of NMDA receptors, a major mechanism for glutamate-induced neurotoxicity, while massive depolarization results in seizure activity. With less severe inhibition, the retention of sodium results in osmotic swelling and possible cellular lysis. A build-up of intracellular calcium also occurs via voltage-gated calcium channels following depolarization and as a consequence of a failure of the sodium-calcium exchange system, maintained by the sodium gradient.

Effects of glutamate, quisqualate, and N-methyl-D-aspartate in neonatal brain

The intracerebral injection of the excitotoxins, glutamate (GLU), or its analogues, quisqualic acid (QA) and N-methyl-D-aspartate (NMDA), produces neuropathologic changes which resemble those induced by hypoxic-ischemic injury. We employed proton magnetic resonance spectroscopy to investigate the acute biochemical changes which follow injection of these excitotoxins in the neonatal rat brain. Aspartate and GLU increased in animals injected with GLU or NMDA. Alanine, glycine, and taurine increased with all three excitotoxins. There was no decrease in phosphocreatine (PCr) or glucose and only a modest increase in lactate after excitotoxin injection, but there was substantial change in these metabolites after hypoxia. GABA rose only after hypoxic-ischemic injury. Although NMDA and QA produced morphological changes which resembled those following hypoxic-ischemic injury, the effect of these excitotoxins on levels of PCr, glucose, and excitatory and inhibitory amino acids was considerably different.

Release of [3H]L-glutamate and [3H]L-glutamine in rat cerebellum slices: a comparison of the effect of veratridine and electrical stimulation

Depolarization-elicited release of neurotransmitter glutamate was studied in rat cerebellar slices previously loaded with either [3H]L-glutamate or [3H]L-glutamine. Both depolarization conditions used (e.g. long-lasting tonic depolarization elicited by veratridine, or short repetitive electrical pulses) increased 6 to 8 folds the release of labelled glutamate and of another compound, presumably alpha-ketoglutarate, without modifying the release of labeled glutamine. Because of the position of the label in the precursor radioactive molecules, GABA was weakly labeled and aspartate was unlabeled. The properties of the evoked glutamate release from cerebellar slices were those of a neurotransmitter since it was inhibited by tetrodotoxin and was Ca2+-dependent. Alpha-ketoglutarate is either coreleased from nerve terminals or is released from astrocytes and could participate in glutamate recycling. The data confirm the generally accepted model implying the presence of two neurotransmitter glutamate pools, a neuronal pool of newly synthesized glutamate and an astrocytic storage pool, but in addition indicate that the former is in rapid isotopic equilibrium with the extracellular compartment. Our present results also indicate that the glutamate/glutamine cycle is not activated in depolarizing conditions.

Excitatory amino acid-induced toxicity in chick retina: amino acid release, histology, and effects of chloride channel blockers

Acute excitotoxicity in embryonic chick retina and the ability of Cl- channel blockers to prevent toxicity were evaluated by measurement of endogenous amino acid release and histology. Treatment of retina with kainate, quisqualate, or N-methyl-D-aspartate resulted in a large dose-dependent release of gamma-aminobutyric acid and taurine, moderate release of glutamine and alanine, and no measurable release of glutamate or aspartate. Concentrations inducing maximal gamma-aminobutyric acid release were 50 microM quisquaalate, 100 microM kainate, and 100 microM N-methyl-D-aspartate. Treatment with 1 mM glutamate resulted in significant gamma-aminobutyric acid release, as well as an elevation in medium aspartate levels. Typical excitotoxic retinal lesions were produced by the agonists and, at the lower concentrations tested, revealed a regional sensitivity. There was a positive correlation between the amount of gamma-aminobutyric acid release and the extent of tissue swelling, suggesting that release may be secondary to toxic cellular events. Omission of Cl- completely blocked cytotoxic effects due to kainate or glutamate. Likewise, addition of the Cl-/bicarbonate anion channel blocker 4,4'-diisothiocyanatostilbene-2,2'-disulfonate at 600 microM protected retina from cytotoxic damage from all excitotoxic analogs and restored amino acid levels to baseline values. Furosemide, which blocks Na+/K+/2Cl- cotransport, was only minimally effective in reducing amino acid release induced by the agonists. Consistent with the latter, histological examination showed the continued presence of the lesion but with general reduction of cellular edema. These results indicate that although influx of Cl- is a central component of the acute excitotoxic phenomenon, mechanisms other than passive Cl- flux may be involved.

2-chloroadenosine attenuates kainic acid-induced toxicity within the rat straitum: relationship to release of glutamate and Ca2+ influx

1. The mechanism by which 2-chloroadenosine (2-chloroado) exerts a neuroprotective action against the excitotoxic effect of kainic acid (KA) when injected into the rat striatum was investigated. 2. Histological examination two weeks after a single injection of KA (2.2 nmol) into rat striatum revealed widespread neuronal damage. Co-injection of 2-chloroado (6-25 nmol) with the neurotoxin afforded dose-dependent neuroprotection. This effect was reversed by administration of an equimolar concentration of the adenosine receptor antagonist theophylline. 3. Both K+ (30 mM) and KA (1 mM) enhanced the release of endogenous glutamate from guinea-pig purified cerebrocortical synaptosomes in a predominantly (approximately 70%) Ca2+-dependent manner. 2-Chloroado (10 nM-1 microM) inhibited the release of glutamate evoked by both KA and K+. These effects were partially reversed by the selective A1-adenosine receptor antagonist 8-cyclopentyltheophylline (CPT) (1 microM). 4. Crude rat cortical synaptosomes were loaded with the fluorescent calcium indicator quin-2 and Ca2+ influx monitored following two successive depolarising stimuli (30 mM K+; 'S1' and 'S2'). 2-Chloroado (10 nM-1 microM) produced a dose-dependent reduction in the S2:S1 ratio when added before the S2 period of stimulation. This effect was reversed by 1 microM theophylline. However, KA (1 mM) failed to enhance Ca2+ influx in the same preparation. 5. These results suggest that the anti-excitotoxic action of 2-chloroado is mediated primarily through a specific presynaptic receptor mechanism involving reduction of transmitter glutamate release, possibly occurring through an inhibition of Ca2+ influx.

Mechanism of kainate toxicity to cerebellar neurons in vitro is analogous to reperfusion tissue injury

The neuroexcitotoxin kainate has been used as a selective lesioning agent to model the etiology of a number of neurodegenerative disorders. Although excitotoxins cause susceptible neurons to undergo prolonged or repeated depolarization, the proximate metabolic pathology responsible for neuronal necrosis has remained elusive. We report here that kainate-induced death of cerebellar neurons in culture is prevented by inhibiting the enzyme xanthine oxidase, a cellular source of cytotoxic superoxide radicals (O2-.). Moreover, neurons are also protected from excitotoxin-induced death by the addition to the culture medium of either superoxide dismutase or mannitol, which scavenge superoxide and hydroxyl radicals, respectively, or serine protease inhibitor, which forestalls formation of xanthine oxidase. These findings indicate that excitotoxin-induced neuronal degeneration is mediated by superoxide radicals generated by xanthine oxidase, a mechanism partially analogous to that proposed for tissue damage seen upon reperfusion of ischemic tissues.

ATP as a marker of excitotoxin-induced nerve cell death in vivo

In an attempt to find an marker for nerve cell death in vivo, the ATP content was measured in the rat dorsal hippocampus within hours or days following in the local injection of the excitotoxins quinolinic or kainic acid. Beginning or completed neuronal degeneration is accompanied by significant decreases in ATP levels. Selective blockade of the quinolinic acid-induced decrement in ATP content by D-(-) 2-amino-7-phosphonoheptanoic acid indicates that ATP measurements may of value for the rapid in vivo screening of the anti-neurotoxic properties of pharmacologically distinct excitatory amino acid receptor antagonists.

Effects of systemic kainic acid administration on regional Na+, K+-ATPase activity in rat brain

Changes in the activity of Na+,K+-ATPase and in the water, Na+, and K+ levels in the parietal cortex, hippocampus, and thalamus were investigated in rats 1, 3, 6, and 24 h following systemic kainic acid injection. An increase in Na+,K+-ATPase activity was observed in all three regions 3 h after the treatment, with a subsequent decrease in enzyme activity. The elevation in Na+,K+-ATPase activity was accompanied by an increase in the Na+ content and a decrease in the K+ content. These changes are presumed to occur because of repeated discharges and excessive prolonged depolarization in response to kainic acid. The decreases in Na+,K+-ATPase activity 6 and 24 h following kainic acid treatment coincide with neuropathological damage and edema formation, mainly in the hippocampus and thalamus.

Effects in vitro of L-glutamate and kainic acid on the ATPase activities of synaptosomal membranes from different areas of rat brain

Changes in the activities of enzymes responsible for the active transport of Na+, K+, Ca2+, Mg2+ in synaptosomal membrane (SM) preparations from the cerebral cortex, hippocampus and thalamus with hypothalamus after incubation with L-glutamate (Glu) or kainic acid (KA) were investigated. Glu stimulated Ca,Mg- and Na,K-ATPase activities in cortex but reduced the activities of all the investigated ATPases, except Na,K-ATPase in the hippocampus and thalamus with hypothalamus. KA reduced distinctly the activity of ATPases in the cortex and only slightly in the thalamus with hypothalamus, but stimulated the enzyme activities in the hippocampus. Both, Glu and KA in vitro altered the processes of active transport of cations in SM preparations.

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.

Regional changes in transmitter amino acids during focal and generalized seizures in rats

Measurement of glucose utilization after 20 minutes of seizure activity induced by the systemic administration of convulsants in paralyzed, ventilated rats demonstrates that the initial metabolic activation during kainic acid seizures is confined to the hippocampus. L-allylglycine-induced generalized seizures result in a global metabolic activation, whereas bicuculline seizures in fasted rats have little effect on brain glucose utilization after 20 minutes of seizure activity. Other metabolic changes associated with kainic acid seizures also predominate in the hippocampus, were decreases in the levels of aspartate, glutamate, taurine and glutamine, and an increase in the level of GABA are observed after 20 minutes of seizure activity. L-allylglycine seizures are associated with generalized decreases in regional GABA levels, and increases in regional glutamine levels. Bicuculline-induced changes include increases in hippocampal GABA and taurine levels, and increases in cerebellar glutamine and taurine levels. These changes can be tentatively explained in terms of known biochemical and neurophysiological mechanisms of these convulsants.

Effects of kainic acid in rat brain synaptosomes: the involvement of calcium

The effects of kainic acid were investigated in preparations of rat brain synaptosomes. It was found that kainic acid inhibited competitively the uptake of D-[3H]aspartate, with a Ki of approximately 0.3 mM. Kainic acid also caused release of two excitatory amino acid neurotransmitters, aspartate and glutamate, in a time- and concentration-dependent manner, but had no effect on the content of gamma-aminobutyric acid. Concomitant with the release of aspartate and glutamate, depolarization of the synaptosomal membrane and an increase in intracellular calcium were observed, with no measurable change in the concentration of internal sodium ions. The increase in intrasynaptosomal calcium and decrease in transmembrane electrical potential were prevented by the addition of glutamate, whereas the kainate-induced release of radioactive aspartate was substantially inhibited by lowering the concentration of calcium in the external medium. It is postulated that kainic acid reacts with a class of glutamate receptors located in a subpopulation of synaptosomes, presumably derived from the glutamatergic and aspartatergic neuronal pathways, which possesses high-affinity uptake system(s) for glutamate and/or aspartate. Activation of these receptors causes opening of calcium channels, influx of calcium into the synaptosomes, and depolarization of the synaptosomal plasma membrane with consequent release of amino acid neurotransmitters.

Changes in regional neurotransmitter amino acid levels in rat brain during seizures induced by L-allylglycine, bicuculline, and kainic acid

Changes in amino acid concentrations were studied in the cortex, cerebellum, and hippocampus of the rat brain, after 20 min of seizure activity induced by kainic acid, 47 mumol/kg i.v.; L-allylglycine, 2.4 mmol/kg i.v.; or bicuculline, 3.27 mumol/kg i.v. in paralysed, mechanically ventilated animals. Metabolic changes associated with kainic acid seizures predominate in the hippocampus, where there are decreases in aspartate (-26%), glutamate (-45%), taurine (-20%), and glutamine (-32%) concentrations and an increase in gamma-aminobutyric acid (GABA) concentration (+ 26%). L-Allylglycine seizures are associated with generalized decreases in GABA concentrations (-32 to -54%), increases in glutamine concentrations (+10 to +53%), and a decrease in cortical aspartate concentration (-14%). Bicuculline seizures, in fasted rats, are associated with marked increases in the levels of hippocampal GABA (+106%) and taurine (+40%). In the cerebellum, there are increases in glutamine (+50%) and taurine concentrations (+36%). These changes can be explained partially in terms of known biochemical and neurophysiological mechanisms, but uncertainties remain, particularly concerning the cerebellar changes and the effects of kainic acid on dicarboxylic amino acid metabolism.

Acidic amino acid binding sites in mammalian neuronal membranes: their characteristics and relationship to synaptic receptors

This review summarizes studies designed to label and characterize mammalian synaptic receptors for glutamate, aspartate and related acidic amino acids using in vitro ligand binding techniques. The binding properties of the 3 major ligands employed--L-[3H]glutamate, L-[3H]aspartate and [3H]kainate--are described in terms of their kinetics, the influence of ions, pharmacology, molecular nature, localization and physiological/pharmacological function. In addition, the binding characteristics are described of some new radioligands--[3H]AMPA, L-[3H]cysteine sulphinate, L-[35S]cysteate, D-[3H]aspartate, D,L-[3H]APB, D-[3H]APV and D,L-[3H]APH. Special emphasis is placed on recent findings which allow a unification of the existing binding data, and detailed comparisons are made between binding site characteristics and the known properties of the physiological/pharmacological receptors for acidic amino acids. Through these considerations, a binding site classification is suggested which differentiates 5 different sites. Four of the binding site subtypes are proposed to correspond to the individual receptor classes identified in electrophysiological experiments; thus, A1 = NMDA receptors; A2 = quisqualate receptors; A3 = kainate receptors; A4 = L-APB receptors; the fifth site is proposed to be the recognition site for a Na+-dependent acidic amino acid membrane transport process. An evaluation of investigations designed to elucidate regulatory mechanisms at acidic amino acid binding sites is made; hypotheses such as the Ca2+-activated protease hypothesis of long-term potentiation are assessed in terms of the new binding site/receptor classification scheme, and experiments are suggested which will clarify and expand this exciting area in the future.

Kainate-glutamate interactions in rat cerebellar slices

The effects of L-glutamate on the potency of kainate for stimulating guanosine 3',5'-cyclic monophosphate (cyclic GMP) accumulation and for killing neurones in incubated slices of immature (8-day) and adult rat cerebellum were investigated. L-glutamate did not potentiate the cyclic GMP responses to kainate in either the adult or the immature tissue (in contrast to a recent report), nor did it alter the pharmacological characteristics of this postsynaptic action of kainate in the immature cerebellum. Slices incubated for 2 h in the presence of L-glutamate displayed pronounced glial swelling and neuronal damage. These effects were concentration-dependent and neurones in the immature cerebellum proved to be about 10 times more susceptible than in the adult. None of the neuronal cell types appeared to be selectively vulnerable to the toxicity of glutamate. At the lower concentrations tested (300 microM in the immature tissue, 3 mM in the adult), neurotoxicity was largely restricted to regions near the cut edges of the slices, indicating that very effective mechanisms limit the diffusion of glutamate within the cerebellum. Kainate caused selective necrosis of Purkinje cells and inhibitory interneurones in slices of adult cerebellum at concentrations between 5 and 20 microM; 30 microM kainate, however, also affected granule cells. The neurotoxic potency of kainate towards all neuronal cell types was significantly lower in the immature cerebellum and was not enhanced by including glutamate in the incubation medium. Similarly, glutamate did not potentiate the neurotoxicity of kainate towards Purkinje cells and inhibitory interneurones or or towards granule cells in adult slices. It is concluded that the availability of glutamate is unlikely to be a factor which limits the neurotoxicity of kainate either in the immature or in the adult cerebellum. The increase in the neurotoxic potency of kainate with cerebellar maturation can be ascribed, more readily, to be developmentally-related appearance of kainate receptors.

Study of differential effects of kainic acid on metabolic rates, utilizing exogenous or endogenous substrates, in rat brain slices

CO2 production from exogenous glucose of cortical, whole hippocampal, and CA3 region hippocampal slices, as well as O2 consumption of whole hippocampal slices, were measured in the presence of different concentrations of kainic acid. A moderate, significant increase of CO2 production was seen only in the CA3 region hippocampal preparation at kainic acid concentrations of 10(-4)-10(-2) M. The O2 consumption, at the expense of endogenous energy stores of whole hippocampal slices, was substantially increased by 10(-3) M kainic acid when the slices were incubated without exogenous glucose. The effect was partly paralleled by the use of high (50 mM) K+ concentration. Some of the possible factors involved in the differential metabolic responses of brain slices to the action of kainic acid are discussed briefly.

Effects of in vivo administration of kainic acid on the extracellular amino acid pool in the rabbit hippocampus

The effect of local administration of kainic acid in the rabbit hippocampus was studied; the hippocampus was perfused continuously in the freely moving animal with an implanted 0.3-mm dialysis fiber. The pattern of endogenous amino acids in the perfusate, reflecting extracellular amino acids, was monitored with liquid chromatography separation and fluorimetric detection of amino acid derivatives. Kainic acid was included in the perfusion medium for up to 70 min at 0.1-1.0 mM and, with time, induced epileptiform activity. Endogenous glutamic acid, taurine, and phosphoethanolamine levels were increased selectively at the lower perfusion concentrations of kainic acid. Long perfusion periods with higher concentrations increased the levels of virtually all amino acids. Perfusion of the hippocampus with depolarizing concentrations of potassium gave an amino acid response partly similar to that seen with kainic acid treatment. However, one notable difference between the two responses was that the extracellular concentration of glutamine, although not influenced by kainic acid, was significantly decreased after high potassium concentrations. These results confirm previous notions that kainic acid has a primarily excitatory effect, one manifestation of this effect being the release of glutamic acid.

Comparison of ibotenate and kainate neurotoxicity in rat brain: a histological study

The neurotoxic properties of ibotenate and kainate after intracerebral application were compared in several regions of the rat brain. Ibotenate, being 5-10 times less toxic than kainate, caused lesions which were generally found to extend spherically from the tip of the injection cannula. In contrast, kainate injections often resulted in neuronal degeneration distant from the site of infusion, thus severely limiting its use as a tool for causing lesions in neurobiological studies. In some of the brain regions examined (hippocampus, septum), neurons appeared differentially susceptible to kainate but uniformly vulnerable to ibotenate. Some cell groups, such as those in the medial septum and the locus coeruleus, proved highly resistant to kainate but could be selectively ablated by ibotenate. These findings, together with differences between the two toxins in the evolution of neuronal degeneration (exemplified here in the hippocampal formation), appear to support previous suggestions that ibotenate and kainate exert their excitotoxic actions via different mechanisms. On the other hand, neuropathological changes caused in the cerebellum did not differ, since both ibotenate and kainate preferentially destroyed granule cells. Two nuclei, the arcuate nucleus of the hypothalamus and the nucleus of the fifth nerve, were found to be extremely resistant to either neurotoxin.

Kainate, N-methylaspartate and other excitatory amino acids increase calcium influx into rat brain cortex cells in vitro

Kainate (0.62-5 mM) was found to increase the initial rate of influx of 45Ca and of 22Na into the non-inulin space of rat thin brain cortex slices incubated in vitro, and to shorten the equilibration time for both these ions. N-methyl-DL-aspartate (50-1000 microM), L-glutamate (0.62-5 mM), DL-homocysteate (0.62-2.5 mM), and ibotenate (6-170 microM) also significantly increased the influx of 45Ca into the non-inulin space of this preparation, while the non-neurotoxic acidic amino acids N-acetyl-L-aspartate, and alpha-methyl-DL-aspartate (both 1.25-5 mM), did not increase such influx. We suggest that enhanced calcium uptake may represent the basis for the neurotoxic effects of these compounds.

Effect of kainic acid, glutamate, and aspartate on CO2 production by goldfish tectal slices

For a study of the excitatory effect of kainate, glutamate, and aspartate in the goldfish optic tectum, these substances were tested on the production of CO2 from radioactive glucose in tectal slices incubated in Krebs-Ringer medium for fish. Kainate increased the rate of CO2 production for up to 30 min in a dose-related manner, the effect being maximum at 0.1 mM concentration and decreasing at higher doses. The effect was blocked by ouabain (1 mM) as well as by the substitution of choline for Na+ in the incubation medium. Glutamate and aspartate exerted a less pronounced excitatory effect on CO2 production at higher concentration than kainate. This effect was also abolished by ouabain. Glutamate, added to the medium at a concentration at least 100-fold higher than kainate, partially reversed the increase in CO2 production induced by kainic acid. No similar effect was noticed for aspartate. The supposed glutamate antagonists glutamic acid diethylester (1 mM) and proline (5 mM) did not affect the excitatory action of kainic acid or exert an antagonistic effect towards glutamate. At higher concentration (10 mM) glutamic acid diethylester increased CO2 production, an effect that was, however, ouabain insensitive. Methyltetrahydrofolic acid (1 mM), a substance reported to compete for the kainate receptor, did not inhibit the effect of kainic acid or increase CO2 production.

Kainic acid receptors and neurotoxicity in adult and immature rat cerebellar slices

The neurotoxic actions of kainate were examined in incubated slices of adult and immature rat cerebellum using light- and electron-microscopy. In the adult, Purkinje cells and inhibitory interneurones became selectively necrotic at concentrations between 5 micro M and 20 micro M. At 30 micro M, granule cells also became affected. In the immature cerebellum, at an age (8 days after birth) when the parallel fibres (thought to use glutamate as transmitter) are largely yet to be developed, selective toxicity was still evident but Purkinje cells and inhibitory interneurones were about 10-fold, and granule cells about 30-fold, less sensitive to kainate than in the adult. Kainate and other excitotoxins also increased cyclic GMP levels in cerebellar slices, apparently through the activation of excitatory amino acid receptors. In the adult tissue, the dose-cyclic GMP response curve to kainate was biphasic suggesting the presence of two components. The lower concentrations of kainate eliciting the first component mirrored those inducing selective necrosis of Purkinje cells and inhibitory interneurones while the second component correlated with necrosis of granule cells. Similar correlations applied to the immature cerebellum, but here kainate neurotoxicity appeared to be associated with the activation of receptor types different from those evident in the adult. It is suggested that kainate receptors, whose activation is associated with both neurotoxic damage and elevation of cyclic GMP levels, are located on all cell types in the adult cerebellum, with Purkinje cells and inhibitory interneurones displaying a higher sensitivity to kainate than granule cells. The lower sensitivity of immature cerebellum to the neurotoxic effect of kainate is probably due to lower levels of kainate receptors.

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.

Effects of kainic acid on high-energy metabolites in the mouse striatum

Intrastriatal injection of either kainic acid (0.35 micrograms) or ibotenic acid (7.0 micrograms) in the mouse causes a profound and selective degeneration of striatal neurons accompanied by a secondary astrocytic response. The kainate injection (0.35 micrograms) resulted in significant decrements in the striatal levels of phosphocreatine and ATP by 30 min. a progressive reduction in adenosine phosphates between 30 min and 48 h, and a decrease in energy charge; whereas lactate levels increased by 44% at 2 h, glucose levels fell by 56%. Two hours after intrastriatal injection of ibotenic acid (7.0 micrograms) similar alternations in striatal high-energy phosphates and glucose disposition were found. Prior decortication protected against the neurotoxic effects of kainate in the mouse striatum and prevented the alterations in high-energy phosphates at 2 h although lactate levels increased by 212%. These findings in vivo are consistent with the hypothesis that the neurotoxic effects of acidic excitatory amino acids involve a profound activation of energy consumption by affected neurons.