Ultrastructural analysis of kainic acid lesion to cerebellar cortex

Barrel rotation and prostration by vasopressin and nicotine in the vestibular cerebellum

The aim of this study was to determine whether the primary sites for the action of vasopressin and nicotine in producing barrel rotation and prostration in rats were located in the modular cerebellum, i.e., lobule X. When arginine vasopressin was administered into either the fourth ventricles or directly into the nodular cerebellum via chronically implanted cannulae, the rats displayed intermittent barrel rotation and clonic convulsions. The administration of nicotine into the same areas resulted in prostration, atonia and, occasionally, clonic convulsions. A few days after the nodular cerebellum was lesioned with kainic acid, the motor disturbances resulting from either agent were virtually abolished. Histologic studies revealed that kainic acid had destroyed Purkinje and other large neurons, but had left the granular neurons relatively intact. The administration of procaine into either the fourth ventricles or nodular cerebellum blocked the behavioral responses of either vasopressin or nicotine given into the fourth ventricles. It was concluded that the nodular cerebellum is a primary site for the motor disturbances produced by vasopressin and nicotine.

Reversible and irreversible neuronal damage caused by excitatory amino acid analogues in rat cerebellar slices

Slice preparations of the developing rat cerebellum were used to investigate the light and electron microscopic correlates of reversible and irreversible neuronal injury caused by the neurotoxic excitatory amino acid receptor agonists, kainate and N-methyl-D-aspartate. The slices were examined after various periods of exposure to the agonists (up to 30 min) with or without a 90 min recovery period in agonist-free medium. N-Methyl-D-aspartate (100 microM) caused necrosis of deep nuclear neurons and differentiating granule cells, the exposure times necessary to induce non-recoverable damage (leading to necrosis), being, respectively, 10 min and 20-30 min. Exposure periods of only 2-4 min with kainate (100 microM) were needed for Golgi cells to subsequently undergo necrosis. Other cell types (Purkinje, granule and deep nuclear neurons) were altered histologically by kainate but most recovered fully from 30 min exposures. Before the recovery period, the worst affected of these cells (deep nuclear neurons) displayed increased cytoplasmic and nuclear electron density and microvacuolation due to swelling of Golgi cisterns but little or no chromatin clumping or mitochondrial expansion. The neurons which were injured irreversibly by the agonists within 30 min displayed, near the time of lethal injury, increased cytoplasmic and nuclear electron lucency, marked focal aggregation of chromatin and swelling of Golgi apparatus. Mitochondrial swelling did not appear to precede lethal injury and even after exposure times sufficient, or more than sufficient, to lead to necrosis, large numbers of mitochondria remained in a condensed configuration. The significance of the histological changes is discussed and they are compared with those occurring in other pathological conditions. The time scales required for the receptor agonists to induce irreversible cellular lesions would be consistent with this being a process which is responsible for acute neuronal necrosis in the brain.

Morphologic evidence of a primary response of gila to kainic acid administration into the rat neostriatum; studied in vivo and in vitro

Glial changes that follow kainic acid administration were studied in the rat neostriatum at many different time intervals after the lesion, both in the animal model of Huntington's chorea and in an organotypic culture of striatum. The glial reaction showed striking similarities between in vivo and in vitro conditions and resulted in extensive production and accumulation of gliofilaments leading to transformation of the protoplasmic type of astroglia into the fibrous type. The earliest ultrastructural study in vivo revealed severe swelling of the astrocytic cytoplasm and additional morphologic changes of cytoplasmic organelles, i.e., enlargement of mitochondria, dilation of rough endoplasmic reticulum, and presence of numerous vacuoles. The glial pathology progressed parallel to neuronal degeneration. The same reaction was observed in culture both in the explanted tissue in which neurons remained intact and in the distant outgrowth zone containing a pure population of glial cells. This study proved that kainic acid might act directly on astroglia cells and that glial changes were independent of neuronal damage. Because kainic acid is a structural analog of glutamate, the presented results may be interpreted to reflect changes in the metabolism of this amino acid occurring in astroglia independently of neuronal changes. This interpretation is consistent with the existence of two independent metabolic compartments of glutamate.

Mapping second messenger systems in the brain: differential localizations of adenylate cyclase and protein kinase C

[3H]Forskolin and [3H]phorbol 12,13-dibutyrate have been used to map the adenylate cyclase and phosphatidylinositol systems respectively in brain slices by light-microscopic autoradiography. [3H]Forskolin binding to brain sections is displaced potently by forskolin (KD approximately equal to 15 nM) and is enhanced by fluoride and GTP analogs, agents which activate the stimulatory GTP-binding regulatory protein of adenylate cyclase, Gs. Highest [3H]forskolin binding occurs in the corpus striatum, substantia nigra, hippocampus, and molecular layer of the cerebellum. Lesion studies demonstrate that binding sites in the substantia nigra are associated with striatal afferents, while hippocampal sites are localized to granule cell dendrites and mossy fiber terminals, and the intense binding in the cerebellar molecular layer is largely associated with granule cell axons and terminals. Protein kinase C mediates the activity of hormones and neurotransmitters, which act through the phosphatidylinositol cycle, and is labeled with high affinity by [3H]phorbol 12,13-dibutyrate. At many synapses, maps of adenylate cyclase and protein kinase C reveal reciprocal distributions, which may have implications for second messenger regulation of synaptic transmission.

Electrophysiological properties of lemniscal afferents in rat after kainic acid lesions in the ventrobasal thalamus

Kainic acid (KA) has been largely used as a neurotoxin, and its axon-sparing effect being repeatedly emphasized, on the basis of anatomical and biochemical data. The present study examines this 'axon-sparing' effect from an electrophysiological point of view and demonstrates that lemniscal fibers retain the capacity to convey somesthetic information 5-60 days after an injection of KA in the ventrobasal complex of the thalamus depriving these afferent fibers of their target cells.

Degeneration of cholinergic neurons in the basal nucleus following kainic or N-methyl-D-aspartic acid application to the cerebral cortex in the rat

The effect on cholinergic neurons in the basal nucleus of exposing the cortex to excitotoxic amino acids was examined in the rat. Kainic or N-methyl-D-aspartic acid were applied extradurally over the cerebral cortex of one side. This resulted in a severe depletion in the numbers of neurons in the underlying cortex. The immunohistochemically identified cholinergic neurons of the ipsilateral basal nucleus showed a significant shrinkage, -31% of their mean cell area, which was comparable with the retrograde degeneration seen following direct mechanical damage of the cortex. These findings suggest that cholinergic neurons of the basal nucleus can undergo transneuronal retrograde degeneration.

Kainic acid selectively alters auditory dendrites connected with cochlear inner hair cells

Cochleas of adult guinea pigs and rats, and 6-day-old rat pups, were injected, through the round window, with 2 microliters of artificial classical Konishi perilymph containing 1 nmol kainic acid (KA). 5 min later, they were fixed, removed, and processed for electron microscopy. In all KA-treated cochleas, the injection resulted in a severe swelling of auditory dendrites below the inner hair cells (IHCs). Below the outer hair cells (OHCs), the swelling appeared only in the 6-day-old rats, not in adult animals. These results are significant in three different ways: (1) They confirm the strong difference between afferents innervating the IHCs and the OHCs in adult cochleas. (2) They shed some light on the synaptic plasticity found at the OHC level during synaptogenesis. (3) They support the hypothesis that glutamate, or a related substance, is the IHC neurotransmitter.

The dentate gyrus in hypoglycemia: pathology implicating excitotoxin-mediated neuronal necrosis

A detailed light- and electron-microscopic study of the damage to the rat dentate gyrus in hypoglycemia was undertaken, in view of the previously advanced hypothesis that hypoglycemic nerve cell injury is mediated by a released neurotoxin. The distribution of neuronal necrosis showed a relationship to the subarachnoid cisterns. Electron microscopy of the dentate granule cells and their apical dendrites revealed dendrosomal, axon-sparing neuronal pathology. Dentate granule cells were affected first in the dendrites in the outer layer of the stratum moleculare, sparing axons of passage and terminal boutons. Subsequently, the neuronal perikarya were affected, and Wallerian degeneration of axons followed. Cell membrane abnormalities preceded the appearance of mitochondrial flocculent densities and degradation of the cytoskeleton, and are suggested to be early lethal changes. The observed early dendrotoxic changes, and the dendrosomal, axon-sparing nature of the lesion implicate an excitotoxin-mediated neuronal necrosis in hypoglycemia.

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.

Ultrastructural study of colchicine neurotoxicity in septohabenulointerpeduncular system

Colchicine is selectively neurotoxic towards some neuronal populations and causes the death of sensitive neurons. Electron microscopic examination of the neural damage caused by stereotaxic injections of colchicine has been used to demonstrate neuroanatomical connections in the septohabenulointerpeduncular system of the rat brain. Colchicine injections in the medial habenula were selectively neurotoxic towards some neurons of the medial habenula and resulted in degeneration of S and crest terminals, the most common type of interpeduncular synapses. Control injections in the stria medullaris, rostral to the habenular complex, caused only sparse degeneration in the interpeduncular nucleus and did not involve S and crest terminals. Colchicine injections that caused neuronal degeneration in the supracommissural septum resulted in substantial terminal degeneration in the interpeduncular nucleus. A large number of degenerated terminals was also present, in these cases, in the medial habenula. Colchicine administration in the various areas caused, to a different extent, lesion or minor ultrastructural damage to axons crossing the injected area. The potential usefulness of colchicine neurotoxicity for neuroanatomical purposes is discussed and the limitation derived from damage of fibers of passage is considered. Colchicine can be confidently used in experimental studies only when erroneous interpretation caused by damage of fibers of passage can be excluded. In the present investigation, this prerequisite could be achieved either by controls made possible by the peculiar arrangement of neuronal circuits or by comparison with known anatomical data.

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-enhanced release of D-[3H]aspartate from cerebral cortex and striatum: reversal by baclofen and pentobarbital

A study was made of the actions of the excitant neurotoxin, kainic acid, on the uptake and the release of D-[2,3-3H]aspartate (D-ASP) in slices of guinea pig cerebral neocortex and striatum. The slices took up D-ASP, reaching concentrations of the amino acid in the tissue which were 14-23 times that in the medium. Subsequently, electrical stimulation of the slices evoked a Ca2+-dependent release of a portion of the D-ASP. Kainic acid (10(-5)-10(-3) M) produced a dose-dependent inhibition of D-ASP uptake. The electrically evoked release of D-ASP was increased 1.6-2.0 fold by 10(-5) and 10(-4)M kainic acid. The kainate-enlarged release was Ca2+-dependent. Dihydrokainic acid, an analogue of kainic acid with little excitatory or toxic action, did not increase D-ASP release but depressed D-ASP uptake. Attempts were made to block the action of kainic acid with baclofen and pentobarbital, compounds which depress the electrically evoked release of L-glutamate (L-GLU) and L-aspartate (L-ASP). Baclofen (4 X 10(-6)M), an antispastic drug, and pentobarbital (10(-4)M), an anesthetic agent, each inhibited the electrically evoked release of D-ASP and prevented the enhancement of the release above control levels usually produced by 10(-4)M kainic acid. It is proposed that 10(-5) and 10(-4)M kainic acid may enhance the synaptic release of L-GLU and L-ASP from neurons which use these amino acids as transmitters. This action is prevented by baclofen and pentobarbital. In view of the possibility that cell death in Huntington's disease could involve excessive depolarization of striatal and other cells by glutamate, baclofen might be effective in delaying the loss of neurons associated with this condition.

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.

Autoradiographic localization of high-affinity [3H]kainic acid binding sites in the rat forebrain

Utilizing in vitro autoradiographic techniques, we have studied the distribution of high affinity [3H]kainic acid ([3H]KA) binding sites in intact sections of the rat forebrain. These sites have the same kinetic and pharmacological characteristics as the [3H]KA site described in tissue homogenates. Moderate to high levels of specific binding were observed in several discrete brain regions. These include lamina I, V and VI of the neo- and cingulate cortex, superficial layers of the pyriform cortex, striatum, external plexiform and granule cell layers of the olfactory bulb, olfactory tubercle, the stratum lucidum of CA3 of the hippocampus, molecular layer of the dentate gyrus, reticular nucleus of the thalamus, the hypothalamic median eminence, and the granule cell layer of the cerebellum. Low levels of specific binding were associated with other discrete regions such as the lateral septum, bed nucleus of the stria terminalis, medial geniculate, superficial layers of the superior colliculus, nuclei of the central grey, interpeduncular nucleus and the molecular layer of the cerebellum. Moderate uniform levels of specific binding were observed over the hypothalamus, zona incerta and the amygdala. One of the important factors in KA neurotoxicity seems to be the presence of KA receptors, and regions that are susceptible to the toxic effects of KA after local administration, such as the striatum, hippocampus, amygdala and pyriform cortex, have moderate to high levels of binding. Thus, these data provide a useful map for studying the relationship between receptor-mediated and seizure-induced neuronal damage following KA administration.

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.

Neurotoxic effect of kainic acid on ultrastructure and GABAergic parameters in the goldfish cerebellum

Kainic acid administration into the cerebellar dorsal lobe of the goldfish causes selective degeneration of some neuronal types. Stellate and Golgi neurons are very sensitive to the neurotoxin and undergo rapid degeneration. On the basis of their differential responses to kainic acid, Purkinje cells can be divided in two distinct sub-populations (i.e. sensitive and insensitive neurons). The degenerative changes of the Purkinje neurons are in addition remarkably slow in comparison with the same cells in mammals or with stellate and Golgi neurons in the goldfish. Granule cells, as well as the cerebellar afferent fiber system, are not significantly affected. Six days after kainic acid administration, the level of glutamate decarboxylase in the cerebellar dorsal lobe drops to about 40% of the control value. This result suggests that the neurons sensitive to kainic acid neurotoxicity are, at least in part, GABAergic. Light- and electron-microscopic autoradiography of cerebellar elements selectively accumulating [3H]GABA, supports this idea. Moderate decreases of acetylcholinesterase and protein content were also noticed in the kainic acid-treated cerebellar dorsal lobe.

Systemic injection of kainic acid: effect on neurotransmitter markers in piriform cortex, amygdaloid complex and hippocampus and protection by cortical lesioning and anticonvulsants

Systemic injection of kainic acid (12 mg/kg) in rats induces a well established pattern of neuronal lesions in different brain regions. These lesions are accompanied by changes in neurotransmitter markers. In the piriform cortex and amygdaloid complex, the kainic acid lesion was accompanied by a reduction in the high affinity uptake of glutamate and in the activities of glutamate decarboxylase and choline acetyltransferase, whereas in the hippocampus there was a reduction in the high affinity uptake of glutamate and in glutamate decarboxylase activity. Hemidecortication, hemitransection, a caudal knife cut in the cortex, or treatment with diazepam, all protected against the effects of kainic acid in the piriform cortex and amygdaloid complex but not in the hippocampus. Diphenylhydantoin had no effect on the neurotoxicity of kainic acid. The results indicate that the neurotoxic effects of kainic acid in the piriform cortex and amygdala are dependent on an intact cortical structure, probably due to a dependence on specific excitatory circuitry. The neurons involved may be glutamergic/aspartergic.

Acetylcholinesterase Histochemistry of the habenulo-interpeduncular pathway in the rat and the effects of electrolytic and kainic acid lesions

The histochemical distribution of acetylcholinesterase (AChE) was studied in the habenulo-interpeduncular pathway of normal rats and after electrolytic and kainic acid lesions of the habenular nuclei. From these combined observations it appears that the AChE-rich projection to the interpeduncular nucleus derives from both the medial and the lateral habenular nuclei. The lateral nucleus of the habenula is the main source of AChE-rich fibres in the fasciculus retroflexus, and a number of stained fibres also derive from the stria medullaris. While total habenular lesion completely deprived the fasciculus retroflexus of AChE-stained fibres, a direct effect on the enzyme distribution in the interpeduncular nucleus was only apparent as its rostral pole. In the remainder of the nucleus the AChE distribution did not undergo obvious changes in comparison with the normal pattern, except for a moderate decrease in overall reaction intensity in cases with subtotal habenular lesion bilaterally. The above results are consistent with the observation derived from experiments involving kainic acid injection into the habenula. The neurotoxic effect of kainic acid was highly selective for specific types of neurons in the lateral habenula, while the neurons of the medial habenula were completely unaffected. The existence of an AChE-rich projection from the lateral habenula to the interpeduncular nucleus was supported by a corresponding decrease in enzyme activity in the lateral habenula and fasciculus retroflexus after kainic acid treatment.

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.

Kainic acid neurotoxicity; effect of systemic injection on neurotransmitter markers in different brain regions

Systemic injection of kainic acid (12 mg/kg) induces necrosis and neuronal degeneration in several brain regions. The most pronounced effects were observed in the piriform cortex, amygdaloid complex, hippocampus and septum. A good correlation between morphological changes and changes in some neurotransmitter markers was observed in these 4 areas. High affinity uptake of L-glutamate, as well as glutamate decarboxylase and choline acetyltransferase activities were reduced in the piriform cortex and amygdaloid complex whereas in the hippocampus and septum only the first two markers were reduced. No morphological changes or decrease in any of these neurotransmitter markers were observed in striatum or globus pallidus. A pronounced neuronal degeneration could be demonstrated in lateral thalamus and geniculate body, but this degeneration was not accompanied by any decrease in the transmitter markers tested.

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.

GABA benzodiazepine and histamine-H1 receptors in the guinea pig cerebellum: effects of kainic acid injections studied by autoradiographic methods

By using kainic acid (KA) to perform chemical lesions in the guinea pig cerebellum, we have caused degeneration of Purkinje cells without affecting cell morphology. Near the injection site we found a large decrease in autoradiographically labeled histamine-H1 and benzodiazepine receptors of the molecular layer while those receptors distant from the injection site were unaffected. GABA receptors in the granule cell layer remained uniformly constant even immediately adjacent to the lesion site. This evidence suggests that histamine-H1 and benzodiazepine receptors are present on neuronal elements (possibly on Purkinje cell dendrites) in the molecular layer of the cerebellum and that GABA receptors area associated with the KA-resistant granule cells.

Kainic acid-induced lesion of rat retina: differential effect on cyclic GMP and benzodiazepine and GABA receptors

Intraocular injection of kainic acid caused a marked decrease in GABA content in the rat retina and the almost complete loss of GAD activity in this tissue, within 3 days. Moreover, kainic acid produced a decrease of approximately 65% in the number of both [3H]diazepam and [3H]GABA binding sites without changing the apparent dissociation constants for their ligands. In contrast to that in brain areas, cyclic GMP content in the retina is neither influenced by kainic acid nor by the systemic administration of diazepam and muscimol.