Effects of kainic acid on ion distribution and ATP levels of striatal slices incubated in vitro

Visualization of spatiotemporal energy dynamics of hippocampal neurons by mass spectrometry during a kainate-induced seizure

We report the use of matrix-assisted laser desorption/ionization (MALDI) imaging mass spectrometry combined with capillary electrophoresis (CE) mass spectrometry to visualize energy metabolism in the mouse hippocampus by imaging energy-related metabolites. We show the distribution patterns of ATP, ADP, and AMP in the hippocampus as well as changes in their amounts and distribution patterns in a murine model of limbic, kainate-induced seizure. As an acute response to kainate administration, we found massive and moderate reductions in ATP and ADP levels, respectively, but no significant changes in AMP levels--especially in cells of the CA3 layer. The results suggest the existence of CA3 neuron-selective energy metabolism at the anhydride bonds of ATP and ADP in the hippocampal neurons during seizure. In addition, metabolome analysis of energy synthesis pathways indicates accelerated glycolysis and possibly TCA cycle activity during seizure, presumably due to the depletion of ATP. Consistent with this result, the observed energy depletion significantly recovered up to 180 min after kainate administration. However, the recovery rate was remarkably low in part of the data-pixel population in the CA3 cell layer region, which likely reflects acute and CA3-selective neural death. Taken together, the present approach successfully revealed the spatiotemporal energy metabolism of the mouse hippocampus at a cellular resolution--both quantitatively and qualitatively. We aim to further elucidate various metabolic processes in the neural system.

Kainic acid: insights into excitatory mechanisms causing selective neuronal degeneration

Kainic acid, an acidic pyrolidine isolated from the seaweed Digenea simplex, is the most potent of the commonly used exogenous excitotoxins. The neurotoxic threshold of kainic acid is nearly two magnitudes lower than that of the other receptor-specific agonists, N-methyl-D-aspartic acid and quisqualic acid. Neurophysiological and ligand-binding studies indicate that the neurotoxic action of kainic acid is mediated by a specific receptor which exhibits a remarkably broad phylogenetic distribution in the nervous system of vertebrates and invertebrates. The mechanism of neurotoxicity of kainic acid appears to be indirect and requires the functional integrity of excitatory afferents to vulnerable neurons. Consistent with the excitotoxin hypothesis, kainic acid depletes high-energy phosphates and glucose at sites of neurotoxic action; nevertheless, the proximate cause of neurotoxicity may involve increases in intraneuronal calcium levels and the activation of calcium-dependent proteases. Kainic acid neurotoxicity provides a useful animal model for selective neuronal vulnerability that may shed light on the pathophysiology of a number of neurodegenerative disorders, including Huntington's disease and temporal lobe epilepsy.

Exacerbation of excitotoxic neuronal death induced during mitochondrial inhibition in vivo: relation to energy imbalance or ATP depletion?

During the past two decades a close relationship between the energy state of the cell and glutamate neurotoxicity has been suggested. We have previously shown that increasing the extracellular concentration of glutamate does not cause neuronal death unless a deficit in energy metabolism occurs. The mechanisms of glutamate-induced neuronal death have been extensively studied in vitro and it has been associated with a rapid and severe decrease in ATP levels, accompanied with mitochondrial dysfunction. In this study we aimed to investigate the time course of the changes in energy metabolites during glutamate-induced neuronal death, in the presence of a moderate inhibition of mitochondrial metabolism in the rat striatum in vivo. We also aimed to study whether or not, as reported in vitro, changes in ATP levels are related to the extension of neuronal death. Results show that glutamate-induced lesions are exacerbated when rats are previously treated with a subtoxic dose of the mitochondrial toxin 3-nitropropionic acid (3-NP). However, changes in nucleotide levels were similar in rats injected with glutamate alone and in rats injected with glutamate and previously treated with 3-NP. In spite of the presence of an extensive striatal lesion, nucleotide levels were recovered in 3-NP-treated rats 24 h after glutamate injection. Results show that 3-NP pre-treatment induced an imbalance in nucleotide levels that predisposed cells to glutamate toxicity; however it did not influence the bioenergetic changes induced by glutamate alone. Enhancement of glutamate neurotoxicity in 3-NP pre-treated rats is more related to a sustained nucleotide imbalance than just to a rapid decrease in ATP levels.

Kainic acid versus carbachol induced emotional-defensive response in the cat

The emotional-defensive response (EDR) and accompanied neurotoxic and electroencephalographic (EEG) effects induced by injection of kainic acid (KA, 0.1; 0.2 microgram) into the midbrain periaqueductal grey region (PAG) and antero-medial hypothalamus (AMH) in the cat were examined and compared with EDR and accompanied neurotoxic and EEG effects induced by injection of cholinergic agent, carbachol (CCH), into the same sites. The injections of KA (0.2 microgram) into the PAG induced EDR which closely resembled the defense behavior typically observed after administration of CCH. However, in contrast to CCH-induced EDR, the defensive response induced by KA was found to be accompanied by EEG symptoms of epileptiform activity in the limbic cortex and a massive cell loss in the site of injection. It is proposed that KA-induced EDR and seizure activity may have resulted from the activation of different cell populations localized either in the vicinity of the injection (i.e., PAG region) and in the area remote from the injection loci, the limbic cortex. KA induced activation of PAG neuronal network would trigger the 'local response' (emotional-defensive response) and produce a remote effect-epileptiform activity.

Lack of correlation between glutamate-induced depletion of ATP and neuronal death in primary cultures of cerebellum

The aim of this work was to identify, using primary cultures of cerebellar neurons, the receptors involved in glutamate-induced depletion of ATP and to assess whether there is a correlation between glutamate-induced ATP depletion and neuronal death. Glutamate induced a rapid depletion of ATP (40% decrease at 5 min). After 60 min incubation with 1 M glutamate ATP content decreased by 60-70%. Similar effects were induced by glutamate, NMDA and kainate while quisqualate, AMPA or trans-ACPD did not affect significantly ATP content. The EC50 were approximately 6, 25 and 30 microM for glutamate, NMDA and kainate, respectively. DNQX and AP-5, competitive antagonists of kainate and NMDA receptors, respectively, prevented in a dose-dependent manner the glutamate-induced depletion of ATP. These results indicate that glutamate-induced depletion of ATP is mediated by activation of kainate and NMDA receptors. Glutamate-induced neuronal death was prevented by MK-801, calphostin C, H7, carnitine, nitroarginine and W7. However, only MK-801 and W7 prevented glutamate-induced depletion of ATP, while calphostin C, H7, carnitine and nitroarginine did not. This indicates that there is not a direct correlation between ATP depletion and neuronal death.

The biochemical mechanisms of the excitotoxicity of kainic acid. Free radical formation

Kainic acid (KA) is a known potent neuroexcitotoxin, although the biochemical mechanism producing its underlying neurotoxic effect is not quite clear. Histopathological examination of gerbil brains 24 h after systemic injection of KA revealed severe neuronal lesions in different regions of the brain, especially the cerebellar and hippocampal areas. We have detected free radical formation in the brain 1 h after KA administration by using an in vivo spin trapping technique. We have also observed increased lipid peroxidation in the brain after KA-treatment by analyzing thiobarbituric acid reactive substances and conjugated diene formation. Diminished brain specific (Na+, K+)-ATPase activity was also found 2 h after KA injection and persisted to 24 h. It is possible that the free radical reaction is a primary cause of neuronal degeneration after KA administration.

Stimulation of 22Na+ efflux from rat forebrain membrane vesicles by L-glutamic acid, L-aspartic acid and kainic acid

A glass fiber filter assay method is described for measuring 22Na+ efflux stimulated by L-glutamic acid, L-aspartic acid and kainic acid from osmotically sensitive membrane vesicles prepared from rat brain. L-Glutamic acid and L-aspartic acid showed the greatest efficacy for the stimulation of 22Na+ efflux with EC50 values of 3 microM. Kainic acid produced 28% of the maximal efflux seen with L-glutamic acid or L-aspartic acid with an EC50 value of 1.5 microM. Quisqualic acid never showed statistically significant increases in 22Na+ efflux over control experiments. N-Methyl-D-aspartic acid showed no detectable efflux activity in this preparation. DL-2-Amino-4-phosphonobutyric acid (APB) inhibited up to 40% of the 50 microM L-glutamic acid-stimulated or 50 microM L-aspartic acid-stimulated 22Na+ efflux with an IC50 value of 1.5 nM. Calcium was required for the inhibitory action of APB, but not for the stimulatory actions of L-glutamic, L-aspartic, or kainic acids. L-Glutamic, L-aspartic, and kainic acids at concentrations above 100 microM were found to inhibit rather than to stimulate 22Na+ efflux. Veratridine (1 microM) had no influence on the 22Na+ efflux component which was produced by L-glutamic or kainic acids. We are unable to firmly establish the mechanism for the stimulated 22Na+ efflux.

Differential sensitivity of calbindin and parvalbumin immunoreactive cells in the striatum to excitotoxins

The neurotoxic effects of ibotenic acid, quinolinic acid and kainic acid on cells in the rat striatum were investigated using immunocytochemistry with antibodies to the calcium binding proteins, calbindin and parvalbumin. The results showed that both ibotenic acid and quinolinic acid affected calbindin and parvalbumin cells to the same extent. However, parvalbumin immunopositive neurons were more sensitive than calbindin immunopositive neurons to the neurotoxic effects of kainic acid. Although the reason for this increased sensitivity of parvalbumin striatal neurons to kainic acid is unclear, these results suggest that the neurotoxicity produced by kainic acid is different to that occurring with quinolinic acid and ibotenic acid.

Glutamate neurotoxicity and the inhibition of protein synthesis in the hippocampal slice

In some animal models of ischemia, neuronal degeneration can be prevented by the selective antagonism of the N-methyl-D-aspartate (NMDA) glutamate receptor subtype, suggesting that glutamate released during ischemia causes injury by activating NMDA receptors. The rat hippocampal slice preparation was used as an in vitro model to study the pharmacology of glutamate toxicity and investigate why NMDA receptors are critical in ischemic injury. Acute toxicity was assessed by quantifying the inhibition of protein synthesis, which we confirmed by autoradiography to be primarily neuronal. The effect of NMDA was prevented by the specific antagonists MK-801 and ketamine, as well as by the less selective antagonist kynurenic acid. The less selective antagonists kynurenic acid and 6,7-dinitroquinoxaline-2,3-dione antagonized the effects of quisqualate and NMDA. In contrast to previous observations with dissociated neurons in tissue culture, the toxicity of glutamate was unaffected by antagonists, regardless of the glutamate concentration, the duration of exposure, or the presence of magnesium. The high concentration of glutamate required to inhibit protein synthesis and the inability of receptor antagonists to block the effect of glutamate suggest that either glutamate acts through a non-receptor-mediated mechanism, or that the receptor-mediated nature of glutamate effects are masked in the slice preparation, perhaps by the glial uptake of glutamate. The altered physiology induced by ischemia must potentiate the neurotoxicity of glutamate, because we observed with a brain slice preparation that only high concentrations of glutamate caused neurotoxicity in the presence of oxygen and glucose and that these effects were not reversed by glutamate receptor antagonists.

Glutamate in the mammalian CNS

The excitatory amino acid glutamate plays an important role in the mammalian CNS. Studies conducted from 1940 to 1950 suggested that oral administration of glutamate could have a beneficial effect on normal and retardate intelligence. The neurotoxic nature of glutamate resulting in excitotoxic lesions (neuronal death) is thought possibly to underlie several neurological diseases including Huntington's disease, status epilepticus. Alzheimer's dementia and olivopontocerebellar atrophy. This neurodegenerative effect of glutamate also appears to regulate the formation, modulation and degeneration of brain cytoarchitecture during normal development and adult plasticity, by altering neuronal outgrowth and synaptogenesis. In addition to its function as a neurotransmitter in several regions of the CNS, glutamate seems to be specifically implicated in the memory process. Long-term potentiation (LTP) and long-term depression (LTD), two forms of synaptic plasticity associated with learning and memory, both involve glutamate receptors. Studies with antagonists of glutamate receptors reveal a highly selective dependency of LTP and LTD on the N-methyl-D-aspartate and quisqualate receptors respectively. The therapeutic value of glutamate receptor antagonists is being actively investigated. The most promising results have been obtained in epilepsy and to some extent in ischaemia and stroke. The major drawback remains the inability of antagonists to permeate the blood-brain barrier when administered systemically. Efforts should be directed towards finding antagonists that are lipid soluble and able to cross the blood-brain barrier and to find precursors that would yield the antagonist intracerebrally.

Histochemical representation of regional ATP in the brain using a firefly luciferase-immobilized membrane in a multilayer film format

The enzymatic bioluminescence of firefly luciferase has been used in sensitive pictorial assays of ATP. We describe a method using a membrane with immobilized luciferase in a multilayer film format for the histochemical representation of brain ATP content. The multilayer film consisted of a transparent support, a reagent layer, and a pigment layer. The reagent layer contained all necessary reagents, including immobilized luciferase. The pigment layer was effective for high image resolution. An unfixed slice of frozen brain 16 microns thick was placed on the film. The chemical energy of brain ATP was converted into luminescent energy in the reagent layer and the bioluminescence emitted was recorded photographically with high spatial resolution. A close linear relationship was obtained between the optical density of the bioluminescent images and logarithmic plots of the brain ATP content. With this film, the regional ATP content in fine anatomical structures of gerbil brains was clearly demonstrated in both physiological and pathological states.

Comparative effects of kainic, quisqualic, and ibotenic acids on phenylethanolamine-N-methyltransferase-containing cells of rat retina

Phenylethanolamine-N-methyltransferase (PNMT) activity is located in a subpopulation of amacrine cells in the inner nuclear layer of the rat retina. Kainic, quisqualic, and ibotenic acids, all of which are analogues of glutamic acid, were injected intravitreally to the right and saline to the contralateral left eyes of adult male rats in order to determine the effect of these agents upon retinal PNMT activity. Animals were sacrificed 1 week later for tissue removal. The effect of these agents was measured by radiometric assay for PNMT. The fall in PNMT activity was used to measure the sensitivity of the PNMT-containing cells to these agents. Kainic acid was the most potent, producing the greatest reduction in PNMT activity in the smallest doses. Quisqualic acid was intermediate in potency to that of kainic and ibotenic acids. Ibotenic acid reduced PNMT activity only in extremely high doses. The PNMT-containing cells are sensitive to the toxic actions of kainic and quisqualic acids, but relatively insensitive to the actions of ibotenic acid.

Kainic acid inhibits the synaptosomal plasma membrane glutamate carrier and allows glutamate leakage from the cytoplasm but does not affect glutamate exocytosis

Kainate inhibits the exchange of D-aspartate into guinea-pig cerebrocortical synaptosomes. Kainate inhibits the Ca2+-independent efflux of endogenous glutamate in the presence of a trapping system for the released amino acid but potentiates a Ca2+-independent net efflux of endogenous and labelled glutamate and aspartate in the absence of the trap. Dihydrokainate has a similar effect. No discrepancy is seen between the release of endogenous and exogenously accumulated amino acid. These results are consistent with the presence of a slow leak of glutamate or aspartate from the cytoplasm independent of the kainate-sensitive Na+-cotransport pathway. In the presence of the trap, glutamate effluxes by both pathways, whereas in the absence of the trap, the Na+-cotransport pathway opposes the leak. Neither in the presence or absence of the glutamate trap does kainate induce, inhibit, or otherwise affect the Ca2+-dependent release of endogenous glutamate. The results enable many of the apparent complexities in the presynaptic actions of kainate to be resolved.

The toxin kainic acid: a study of avian nerve and glial cell response utilizing tritiated kainic acid and electron microscopic autoradiography

Three questions are asked regarding the toxin kainic acid (KA). Does it destroy specific glial cells as well as neurons? Does KA gain access to the cytoplasm in intact cells and to which organelles does it bind? Intracerebral injections of tritiated KA into the pigeon (Columba livia) paleostriatal complex (basal ganglia) coupled with electron microscopic autoradiography revealed the following major points. Kainic acid destroyes oligodendrocytes, with pathophysiology apparent by 30 min after challenge with KA leading to cell destruction by 4 h. The response of astrocytes at the longest observation period (4 h) involves swelling of perivascular endfeet and processes in the neuropil. Reactive microglial-like cells show an accumulation of label in their cytoplasm, but no apparent morphological changes. The label appears in the cytoplasm of intact cells, both glia and neurons early after challenge with the toxin. Label is associated (bound) with mitochondria at an incidence significantly above chance at 30 min, 2 and 4 h after challenge with KA. Two hours after exposure to KA is the critical period where metabolic, physiological and morphological changes occur that lead to cell death. Cell destruction may be a consequence of KA-induced energy depletion. Kainate may interfere with adequate energy production by uncoupling glycolysis and the Krebs cycle in the mitochondria.

Effects of kainic acid on brain calcium fluxes studied in vivo and in vitro

The effect of in vivo administration of kainic acid into the rabbit hippocampus was studied with brain dialysis and subsequent determination of the Ca2+ concentration in the dialysate. When included in the perfusing medium, kainic acid as well as veratridine induced a decrease in extracellular Ca2+. The effect of kainic acid (but not of veratridine) was insensitive to tetrodotoxin. In vitro studies revealed no effect of kainic acid on 45Ca2+ uptake by isolated astrocytes, but showed an enhancement of synaptosomal 45Ca2+ accumulation. This was, however, only 25% of the stimulatory effect of high K+ depolarization. Glutamate activated synaptosomal Ca2+ uptake, whereas dihydrokainate had no effect. The uptake evoked by kainate and glutamate was independent of the K+ level in the medium which indicates the involvement of other than voltage-sensitive Ca2+ channels. The results confirm previous finding that kainic acid promotes the uptake of Ca2+ in brain cells. Kainate affects Ca2+ fluxes pre- and postsynaptically. Presynaptic Ca2+ influx may be mediated by chemically gated mechanisms.

Time-course of changes in water, sodium, potassium and calcium contents of various brain regions in rats after systemic kainic acid administration

The changes in the water, sodium, potassium and calcium content of the frontoparietal cortex, hippocampus, thalamus and cerebellum in rats were investigated 2, 4, 8, 12 and 24 h and 3 and 7 days after systemic kainic acid administration. The water content was significantly increased in the thalamus and hippocampus 4 and 8 h, respectively, after the kainic acid injection and remained elevated at each subsequent time point. No change was found in the water content of the frontoparietal cortex and cerebellum. The sodium content of the frontoparietal cortex, hippocampus and thalamus was increased 4 h after kainic acid administration, and that of the cerebellum after 8 h. These levels remained elevated throughout the 7 days, with the exception of that for the frontoparietal cortex. A significant potassium decrease was observed in all brain regions investigated. Calcium accumulation was found to begin 4 h after kainic acid administration and was the most pronounced on the 7th day in the thalamus and hippocampus. Electron microscope investigations revealed a mainly intramitochondrial calcium accumulation in these brain regions. Pretreatment with Verapamil did not prevent calcium accumulation. The ion shifts and the development of edema in the thalamus and hippocampus in the early period, and also the changes of the sodium and potassium contents in the frontoparietal cortex and cerebellum in the early and late (12 h and later) periods, can be regarded as concomitant events of epileptic activity. In the hippocampus and thalamus, severe secondary necrotic and hemorrhagic neuropathological damage was accompanied companied by ion shifts and edema in the late period after systemic kainic acid administration.

Kainate-induced uptake of calcium by synaptosomes from rat brain

Kainic acid induces a rapid increase in 45Ca2+ uptake by crude synaptosomal fractions isolated from rat brain. This enhanced Ca2+ permeability occurs with a half-time of approx. 1 s, similar to the fast phase of depolarization-induced calcium uptake. The depolarization-induced uptake of calcium is inhibited 85% by 3 mM CoCl2, 80% by 100 microM quinacrine and 50% by 15 microM trifluoperazine while these agents had little effect on the kainate-induced uptake. It is proposed that kainate induces receptor-mediated opening of a class of calcium channels with properties different from those of the voltage-dependent channels.

Regional calcium accumulation and cation shifts in rat brain by kainate

Following local application of kainic acid, changes in the contents of Na+, K+, Ca2+, and Mg2+ of the striatum, cerebellum, and hippocampus of the rat were observed at various times after surgery. Within 1 h the levels of K+ decreased 20% whereas the levels of Na+ and Ca2+ increased at least 50% and 20%, respectively. These changes persisted for more than 8 weeks. Ca2+ levels rose further, to more than 10-fold during 8 weeks. The Mg2+ levels were slightly and only transiently decreased. Unilateral injections of kainate into the striatum affected the contents of these cations not only in this area, but also in the overlying cerebral cortex, the olfactory tubercle, and the ipsilateral substantia nigra. The Ca2+ increases were less when rats were kept on a diet deficient in Ca2+ and vitamin D. 45Ca2+, intravenously administered, accumulated significantly more in the kainate-lesioned striatum and substantia nigra than in the homotopic contralateral areas. Electron microscopic examination of the localization of Ca2+ with the oxalate-pyroantimonate technique showed the appearance of extracellularly located deposits and the accumulation of Ca2+ in (possibly degenerating) myelinated axons in kainate-lesioned striata. This study provides evidence that calcification of cerebral tissue is closely associated with neurodegenerative processes and shows that kainate may serve as a tool to elucidate the mechanism of brain calcification. The results are discussed in relation to idiopathic calcinosis (striopallidodentate calcinosis, Fahr's disease).

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.

Excitotoxic models for neurodegenerative disorders

In recent years, considerable interest has been shown in the neurotoxin properties of excitatory amino acids and their possible relevance for the study of human neurodegenerative disorders. The term "excitotoxin" has been coined for a family of acidic amino acids which are neuroexcitants and produce a characteristic type of "axon-sparing" neuronal lesion. Intracerebral infusions of kainic and ibotenic acids, the two most commonly used excitotoxins, result in a morphological and biochemical picture in experimental animals which resembles that observed in the brains of Huntington's disease and epilepsy victims. The emergence of such animal models for neurodegenerative disorders has led to the hypothesis that endogenous excitotoxins may exist which are linked to the pathogenesis of human diseases. The most promising candidate discovered so far is quinolinic acid, a hepatic tryptophan metabolite which has recently also been found to occur in brain tissue. The particular excitotoxic properties of quinolinic acid warrant a thorough investigation of its metabolic and synaptic disposition in normal and abnormal brain function. While little is known about the mechanisms by which excitotoxins cause selective neuronal death, most current speculations propose the participation of specific synaptic receptors for acidic amino acids. The recent development of selective antagonists of such receptors has aided in the elucidation of excitotoxic mechanisms. Although a biochemical link between endogenous excitotoxins and human neurodegenerative disorders remains elusive at present, pharmacological blockade of excitotoxicity may constitute a novel therapeutic strategy for the treatment of these disease states.

The differential effects of excitatory amino acids on uptake of 45CaCl2 by slices from mouse striatum

Exposure to L-glutamate (10 mM) or 60 mM K+ for 1 min significantly stimulated the uptake of 45Ca2+ in slices from mouse striatum. Glutamate-induced stimulation was antagonized by 30 mM Mg2+ and by 5 or 10 mM L-glutamic acid diethyl ester, but not by 5 microM tetrodotoxin. Under these 1-min incubation conditions, neither kainate nor N-methyl-D,L-aspartate significantly affected the uptake of 45Ca2+ ion. By contrast, following preincubation for 10 min, glutamate and the conformationally restricted analogues, ibotenate, quisqualate, and kainate significantly inhibited the 60 mM K+-induced stimulation of the uptake of 45Ca2+. These effects of glutamate and kainate were not significantly affected by the presence of 1 mM Ca2+ in the preincubation medium. These results suggest that glutamate may activate a receptor directly linked to Ca2+ channels, whereas kainate may indirectly modulate the intracellular disposition of Ca2+.

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.

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.

Kainic acid prevents peroxidase labeling of retinal ganglion cell bodies in the rat: a possible gate in retrograde axonal transport

Kainic acid, a neurotoxic analogue of glutamate, injected into the vitreous body of the eye, interferes with the retrograde transport of the marker enzyme horseradish peroxidase. This interference is expressed by the absence of detectable peroxidase in the cell bodies of the retinal ganglion cells and by the presence of the marker in the intraretinal portions of the optic axons. These results suggest the hypothesis of the existence of some kind of gate at the proximal portion of the axons which would control the entry of retrogradely moving material into the cell body.

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.

Neurotransmitter receptor ligand binding and enzyme regional distribution in the pigeon visual system

The relative importance of acetylcholine, dopamine, endogenous opiates, gamma-aminobutyric acid (GABA), glutamate, glycine, noradrenaline, and serotonin as transmitters in the pigeon visual system was estimated by measuring the activity of choline acetyltransferase (ChAT), glutamic acid decarboxylase (GAD), and aromatic amino acid decarboxylase (AAD) as well as the binding of dihydroalprenolol, etorphine, kainic acid, muscimol, serotonin, spiroperidol, strychnine, and quinuclidinyl benzilate (QNB) in the tectum opticum, nucleus rotundus, ectostriatum, dorsolateral thalamus, and hyperstriatum (Wulst). As a nonvisual reference structure, the paleostriatal complex was included in the examination. The regional distribution of most of these parameters was very similar to data reported in the mammalian CNS supporting the hypothesis that the avian tectofugal and thalamofugal visual systems are homologous to the mammalian tecto-thalamo-cortical and retino-geniculo-striate pathways, respectively. On the basis of the low values of their parameters, some transmitters can be excluded as significant contributors in a number of structures. As a hypothesis for further investigations, the presence of cholinergic and serotoninergic systems in the Wulst, possibly originating in the dorsolateral thalamus and nucleus raphe, respectively, and of glycinergic and dopaminergic terminals in the paleostriatal complex is proposed.

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.

Excitatory amino acid analogues: neurotoxicity and seizures

The neurotoxic and convulsant properties of conformationally restricted and synthetic analogues of excitatory acidic amino acids were examined after stereotaxic injection into the striatum and the dentate gyrus of the hippocampal formation. In the striatum, neurotoxicity was quantified by the reduction in the activity of choline acetyltransferase and glutamate decarboxylase, markers for striatal intrinsic neurons. The following sequence of neurotoxic potencies was defined; kainic acid approximately equal to domoic acid much greater than alpha-keto kainic acid approximately equal to alpha-allo kainic acid greater than ibotenic acid approximately equal to cis-cyclopentyl glutamic acid greater than quisqualic acid approximately equal to N-methyl-D-aspartic acid. When normalized for neurotoxic potencies, a wide variation in the convulsant effects of the agents was observed after hippocampal injection. N-Methyl-D-aspartate produced nearly continuous electroencephalographic seizures for 2 hr after injection, where alpha-keto-kainate and kainate and quisqualate caused seizure activity for 64 and 45% respectively of this period; kainate, alpha-allo kainate and domoate caused intermittent seizure activity during approximately 30% of the recording period; ibotenate and cyclopentylglutamate had minimal convulsant effects. Seizures were associated with a significant reduction in the levels of norepinephrine and with increases in the levels of 5-hydroxyindoleacetic acid in the cortex and hippocampal formation and increases in the levels of gamma-aminobutyric acid in the hippocampal formation. Kainate, domoate, keto-kainate and alpha-allo-kainate caused extensive lesions of the hippocampal formation that also involved the pyriform cortex; ibotenate and cyclopentylglutamate caused uniform but substantial lesions limited to the dentate gyrus, whereas quisqualate and N-methyl-D-aspartate produced small and restricted lesions. The results demonstrate a poor correlation between the neurotoxic and convulsant potencies of these excitatory amino acid analogues and suggest that receptor-specific interactions may account for these disparities.

Inhibition of axoplasmic transport in the optic system by kainic acid

Axoplasmic transport along the optic axons was studied after intraocular injections of kainic acid (KA). Transport of labeled material did not initiate from the eye when KA was injected simultaneously with the protein precursor [3H]proline. When KA was injected after axoplasmic transport of labeled proteins had begun, no additional radioactive material moved out of the retinal ganglion cells. However, the labeled material already present in the optic nerve at the time of KA injection continued to move, and accumulated at the nerve endings. Although KA reduces the incorporation of precursor, this effect of KA on axoplasmic transport appears to be more than a consequence of inhibition on precursor uptake or protein synthesis. Recovery from this KA action began 6 h after exposure to KA and was about 50% recovered by 36 h. The extent of the recovery remained at this level for as long as a week, which suggested a partial recovery of the ganglion cells. A second exposure to KA after the inner plexiform layer had virtually disappeared was as effective as the first exposure in preventing the appearance of transported protein in the optic nerve, suggesting a direct action of KA on the ganglion cells. We interpreted the results to indicate that KA interferes with the initiation phase of axoplasmic transport in ganglion cells and this effect is partially reversible.

Glutamate binding in the rat cerebral cortex during ontogeny

Two binding sites for L-glutamate have been identified on adult rat brain cortical membranes. One of these sites is Na+-dependent with Kd of 1.3 micro M and a Bmax of 210 pmol/mg protein. The other is Na+-independent with a Kd of 0.37 micro M and Bmax of 6.2 pmol/mg protein. There is a sharp rise in total number of Na+-independent sites per cortex up to 20 days postnatally followed by a more gradual rise to adult levels at 50 days. Na+-dependent binding is also low at birth rising to a peak at 20 days followed by a drop in total levels of binding to 30 days and then a very sharp rise up to 50 days. The kinetics of binding at 20 days gives a Kd for the Na+-dependent site of 1.77 micro M and a Bmax of 82 pmol/mg protein. The Na+-independent site at 20 days has a Kd = 1.3 micro M and Bmax of 8.47 pmol/mg protein. The ability of several acidic amino acid analogues to displace specifically bound L-glutamate was investigated by estimating IC50 values at 20 and 50 days of age. The Na+-independent site is stereospecific for L-glutamate at both ages, but will also interact with L-aspartate at 20 days. The Na+-dependent site has a similar affinity for L- and D-glutamate and L-aspartate at 50 days. The L-glutamate analogue kainate will not displace any bound L-glutamate.

The stimulation of ion fluxes in brain slices by glutamate and other excitatory amino acids

The stimulation of ion movements by excitatory amino acids in brain slices allows the study of various events related to the process of excitatory neurotransmission. Presynaptic mechanisms of uptake of putative neurotransmitters can be followed by the influx of Na+ ions. Postsynaptic depolarizations due to the activation of action potentials or of ionophores associated with specific receptors can be monitored by measurements of the rate of efflux of radioactive tracer ions. Thus, the pharmacological properties of the excitatory amino acid receptors can be investigated as well as those of their putative endogenous effectors.

Kainic acid produces depolarization of CA3 pyramidal cells in the vitro hippocampal slice

Kainic acid (KA) (10(-6)-10(-8) M) reversibly depolarized CA3 pyramidal cells when applied topically to the apical dendritic area of these cells in the hippocampal slice. The magnitude of membrane depolarization and the time to recovery of resting membrane potential were concentration-related. Application of 10(-5) M KA produced complete membrane depolarization which did not recover in baseline levels. Unlike CA3 neurons cells from the CA1 region were unaffected by KA (10(-6)-10(-8) M). However, 10(-5) M KA also proved effective in depolarizing CA1 cells.

Kainic acid neurotoxiocity in granuloprival cerebellar cultures

Granuloprival cerebellar cultures devoid of cortical presynaptic glutamatergic fibers were exposed to nutrient medium incorporating either 10(-3) M D-glutamic acid or 10(-4) M kainic acid. No changes were evident in cultures exposed to the former, while cortical neurons were destroyed in kainate-treated explants. These results suggest that kainic acid neurotoxic effects can be manifested in the absence of glutamatergic afferent fibers.

Degeneration of hippocampal CA3 pyramidal cells induced by intraventricular kainic acid

Degeneration of hippocampal CA3 pyramidal cells was investigated by light and electron microscopy after intraventricular injection of the potent convulsant, kainic acid. Electron microscopy revealed evidence of pyramidal cell degeneration within one hour. The earliest degenerative changes were confined to the cell body and proximal dendritic shafts. These included an increased incidence of lysosomal structures, deformation of the perikaryal and nuclear outlines, some increase in background electron density, and dilation of the cisternae of the endoplasmic reticulum accompanied by detachment of polyribosomes. Within the next few hours the pyramidal cells atrophied and became electron dense. Then these cells became electron lucent once more as ribosomes disappeared and their membranes and organelles broke up and disintegrated. Light microscopic changes correlated with these ultrastructural observations. The dendritic spines and the initial portion of the dendritic shaft became electron dense within four hours and degenerated rapidly, whereas the intermediate segment of the dendrites swelled moderately and became more electron lucent. No degenerative changes were evident in pyramidal cell axons and boutons until one day after kainic acid treatment. Less than one hour after kainic acid administration, astrocytes in the CA3 area swelled, initially in the vicinity of the cell body and mossy fiber layers. It is suggested that the paroxysmal discharges initiated in CA3 pyramidal cells by kainic acid served as the stimulus for this response. Phagocytosis commenced between one and three days after kainic acid administration, but remained incomplete at survival times of 6-8 weeks. Astrocytes, microglia, and probably oligodendroglia phagocytized the degenerating material. These results point to the pyramidal cell body and possibly also the dendritic spines as primary targets of kainic acid neurotoxicity. In conjunction with other data, they support the view that lesions made by intraventricular kainic acid can serve as models of epileptic brain damage.

Phylogenetic distribution of [3H]kainic acid receptor binding sites in neuronal tissue

The phylogenetic distribution of specific binding sites for kainic acid was determined in 14 species including invertebrates and vertebrates. The highest level of binding was observed in brains of the frog (Xenopus laevis), followed by the spiny dogfish (Heterodontus francisci), the goldfish (Carasius auratus) and the chick (Gallus domesticus). Although significant specific binding was noted in some of the lowest forms tested (e.g. Hydra littoralis), this was not a consistent observation in the invertebrates. In most cases, specific binding to both high and low affinity sites was detected; notable exceptions were the cockroach brain (Periplaneta americana), which had negligible high affinity binding, and the crayfish brain (Procambarus) which had negligible low affinity binding. In the spiny dogfish, the smooth dogfish and the chick, the highest level of binding occurred in cerebellum with less in the forebrain and the least in the medulla; in the mammalian species, the highest level of binding occurred in the forebrain structures with less in the cerebellum and least in the medulla. Eadie plots of the saturation isotherms for [3H]kainic acid revealed similar kinetics of binding for frog whole brain, rat forebrain and human parietal cortex with two apparent populations of binding sites: KD1 = 25--50 nM and KD2 = 3--14 nM. While binding in the spiny dogfish forebrain and human caudate nucleus occurred exclusively at a high affinity component, the cerebella of chick, rat and man exhibited only a low affinity binding site. In the 3 species studied most extensively, frog, rat and man, unlabeled kainic acid was the most potent inhibitor of the specific binding of [3H]-kainic acid. L-Glutamic acid was 20--20-fold less potent than kainic acid, and D-glutamic acid was 4--2500-fold less potent than its L-isomer. Reduction of the isopropylene side chain of kainic acid to form dihydrokainic acid decreased the affinity of the derivative 115--30,000-fold. Hill coefficients derived from these displacement curves were 1.0 for unlabeled kainic acid but approximately 0.5 for L- and D-glutamic acids and dihydrokainic acid, which is compatible with negative cooperativity. In summary, these studies demonstrated a widespread distribution throughout the animal kingdom of specific binding sites for kainic acid in neural tissue; the characteristics of these receptor sites are remarkably similar from primitive vertebrates to man.

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

The levels of ATP and amino acids were measured in rat cerebellar slices incubated in the presence of the neurotoxin, kainic acid (KA). 0.1--1 mM KA caused a significant decrease in tissue content of ATP, glutamate, aspartate and glutamine. The levels of glutamate and aspartate, but not glutamine, rose concomitantly in the incubation medium. The results are consistent with a multiaction mechanism for the neurotoxicity of KA.

Kainate neurotoxicity and glutamate inactivation

Dihydrokainate, an inhibitor of high affinity L-glutamate as an excitant of cat spinal neurones in vivo. This action of dihydrokainate was selective in that the effects of excitants taken up actively in vitro by CNS tissue (L-aspartate, D- and L-glutamate and L-homocysteate) were enhanced whereas those of other substances not taken up (acetylcholine, D-homocysteate, kainate and N-methyl-D-aspartate) were not. Since kainate and dihydrokainate have similar potencies as inhibitors of L-glutamate uptake, interference with the inactivation of synaptically released L-glutamate may contribute to the neurotoxic effects of kainate.