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

Enhanced metabolic activity coincides with survival and differentiation of cultured rat retinal ganglion cells exposed to glutamate

Neurotransmitters are prominent candidates for trans-cellular signals that influence the development of the CNS. The present study has examined the effect of glutamate on survival, differentiation and metabolic activity of cultured rat retinal ganglion cells at 3 days in vitro. Retinal cultures from neonatal Wistar rats were treated with glutamate for 48 h. The metabolic activity was markedly increased in the retinal ganglion cells exposed to 20 microM glutamate. This was accompanied by an enhanced survival of these neurons. The number of differentiated retinal ganglion cells as determined by microtubule-associated protein-2 labeling was significantly increased following exposure to low but not higher doses of glutamate. The effect of glutamate on the metabolic activity and differentiation was blocked by tetrodotoxin. The results of the present study shows that glutamate has a significant effect on survival, differentiation and metabolic activity. An increase in the metabolic activity indicates an enhancement in the electrical activity. Thus, our results are consistent with the hypothesis that glutamate is critically involved in the regulation of electrical activity in developing rat retinal ganglion cells.

The calcium response to the excitotoxin kainate is amplified by subsequent reduction of extracellular sodium

The relation between intracellular and extracellular [Na+] and [Ca2+] and membrane potential during stimulation of non-N-methyl-D-aspartate glutamate receptors has been studied in cerebellar granule cells using the fluorescent indicators SBFI, fura-2 and the bisoxonol membrane potential probe DiBaC4(3). Kainate increased both [Ca2+]i (intracellular [Ca2+]) and [Na+]i (intracellular [Na+]) and depolarized the membrane. This elevation of [Ca2+]i was only partially dependent on the presence of extracellular Na+ at the time of kainate addition. Removal of extracellular Na+ itself had a very minor effect on the [Ca2+]i or membrane potential of unstimulated cells. If extracellular Na+ was removed (in order to reverse the [Na+] gradient) or its concentration reduced during stimulation with kainate, the membrane depolarization recovered as expected. However, the intracellular level of sodium recovered only very slowly and the [Ca2+]i rose sharply, rather than recovering as might be expected on repolarization of depolarized cells possessing voltage sensitive calcium channels. This effect of extracellular [Na+] reduction on [Ca2+]i was mimicked by ouabain, another agent that causes accumulation of [Na+] in cells. These results suggest that Na+/Ca2+ exchange may play a major role in calcium homeostasis in stimulated cells, and that the levels of Na+ inside and outside the cell are critical in determining the effect of receptor stimulation on the intracellular [Ca2+].

Potentiation by calcium ions of [3H]MK-801 binding to an ion channel associated with the N-methyl-D-aspartate receptor complex in rat brain

In vitro addition of Ca2+ ions was effective in almost doubling binding of [3H](+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imi ne (MK-801) before equilibrium to an ion channel associated with an N-methyl-D-aspartate (NMDA)-sensitive subclass of brain excitatory amino acid receptors. The addition of inhibitors for phospholipase (PLase) A2 markedly reduced binding in the absence of added Ca2+ ions, while Ca2+ ions restored the reduction to the level found in the absence of the inhibitors. Pretreatment with PLases A2 and C but not D was effective in potentiating [3H]MK-801 binding in a biphasic manner at a concentration range of 5 mU/ml-10 U/ml. Moreover, PLases A2 and C at low concentrations not only suppressed the abilities of 3 different agonists to potentiate [3H]MK-801 binding before equilibrium, but also reduced that of Ca2+ ions. These results suggest that Ca2+ ions may potentiate [3H]MK-801 binding to the NMDA channel highly permeable to Ca2+ ions through a mechanism common to that underlying potentiation by exogenous PLase A2 and/or C.

Supporting evidence for negative modulation by protons of an ion channel associated with the N-methyl-D-aspartate receptor complex in rat brain using ligand binding techniques

The addition of L-glutamic acid (Glu) alone, both Glu and glycine (Gly) or Glu/Gly/spermidine (SPD) was effective in potentiating [3H]5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10- imine (MK-801) binding before equilibrium to an ion channel associated with the N-methyl-D-aspartate (NMDA) receptor complex in brain synaptic membranes extensively washed and treated with Triton X-100. The binding dependent on Glu almost linearly increased in proportion to decreasing proton concentrations at a pH range of 6.0 to 9.0 in external incubation medium, while a Gly-dependent portion of the binding increased with decreasing proton concentrations up to a pH of 7.5 with a plateau thereafter. In contrast, the SPD-dependent binding increased in proportion to decreasing proton concentrations up to a pH of 7.0 with a gradual decline thereafter. Similar profiles were also obtained with [3H]MK-801 binding at equilibrium, with an exception that significant binding of [3H]MK-801 was detected in the absence of any added agonists. The potency of SPD to potentiate [3H]MK-801 binding before equilibrium increased in proportion to decreasing proton concentrations, with those of both Glu and Gly being unchanged. In contrast, the ability of (+)MK-801 to displace [3H]MK-801 binding at equilibrium was not significantly affected by a decrement of external proton concentrations from pH 7.5 to pH 8.5 in the presence of Glu/Gly and Glu/Gly/SPD added. However, similar changes in external proton concentrations did not similarly affect binding of several radioligands for the NMDA and Gly domains on the receptor complex. Decreasing proton concentrations were effective in exponentially potentiating binding of [3H]SPD at a pH range of 6.0 to 9.0 without virtually altering [3H]D,L-alpha-amino-3- hydroxy-5-methyl-isoxazole-4-propionic acid binding. In addition, [3H]kainic acid binding markedly decreased with decreasing proton concentrations only in the presence of Ca2+ ions. These results suggest that protons negatively modulate neuronal responses mediated by the NMDA receptor ionophore complex through interference with opening mechanisms of the channel domain without disturbing association processes of the endogenous agonists with the respective recognition domains in rat brain. Moreover, possible modulation by protons of responses mediated by the kainate receptor in the presence of Ca2+ ions at concentrations that occur in vivo is also suggested.

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.

Partial characterization of kainic acid-induced striatal dopamine release using in vivo microdialysis

The aim of this study was to characterize interactions between striatal kainate (KA) receptors and dopamine (DA) release using in vivo microdialysis. After insertion of a microdialysis probe and establishment of baseline DA release, each preparation was standardized with a pulse of an iso-osmotic solution of 100 mM KCl in Ringer's solution. DA release following pharmacological manipulation was compared to potassium-induced release and expressed as a percent value. In one group of animals, KA (12.5 mM in Ringer's solution) was administered via the microdialysis probe in 2, 3, 5 or 10 min pulses 30 min following standardization with potassium resulting in release of DA which was 15.7 +/- 3.9, 30.3 +/- 11.3, 67.5 +/- 15.0 and 92.9 +/- 19.8% of potassium-induced DA release, respectively. Perfusion of CdCl2 (0.6 mM in Ringer's solution) 30-45 min prior to a 10 min KA pulse significantly reduced KA-induced DA release compared to control values. Intrastriatal administration of kynurenate (Kyn) attenuated KA-induced DA release in a dose-dependent manner. Levels of DA metabolites in striatal perfusates were significantly reduced following KA administration. This effect was partially reversed by cadmium pretreatment but not affected by Kyn pretreatment. Findings of this study indicate that KA induces striatal DA release in a dose-dependent manner, and this effect is at least partially dependent upon activation of calcium channels. Results also indicate dose-dependent inhibition of KA-induced striatal DA release by the excitatory amino acid receptor antagonist, Kyn, suggesting that this compound interacts with striatal KA receptors and that these receptors are involved with modulating striatal DA release in vivo.

The glutamate-mediated release of dopamine in the rat striatum: further characterization of the dual excitatory-inhibitory function

A push-pull cannula supplied with an artificial cerebrospinal fluid containing the tritiated precursor of dopamine, [3H]tyrosine, was implanted in the caudate nucleus of rats anesthetized with halothane. The extracellular dopamine and dihydroxyphenylacetic acid were measured in successive 20 min fractions (both in their tritiated and unlabeled form) and the ratio between the two forms calculated. Glutamate was added to the superfusing cerebrospinal fluid to investigate its role in the process of dopamine release. The release of dopamine and the efflux of dihydroxyphenylacetic acid were activated by a low concentration (10(-8) M) of glutamate. In contrast, a higher concentration (10(-4) M) of the amino acid reduced the release of dopamine. These results first confirmed the presence of a dual mechanism of control, by glutamate, of the dopamine release in the striatum depending on the extracellular concentration. Secondly, these treatments affected the dihydroxyphenylacetic acid amount and predominantly the tritiated form of dopamine, suggesting that the glutamate induces an important increase of the amine synthesis, in spite of a moderate effect on the release. The reversal of the inhibition by applications of tetrodotoxin (5 x 10(-7) M) and bicuculline (10(-4) M) confirmed that it was mediated by an indirect mechanism involving a GABAergic neurotransmission. In addition, the increase of the spontaneous dopamine release during bicuculline application suggested the existence of a tonic mechanism of inhibition of dopamine release in the striatum. This was confirmed by the fact that local xylocaine-induced anesthesia of the sensory motor cortex increased the spontaneous release of dopamine in the striatum.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibition of N-methyl-D-aspartate- and kainic acid-induced neurotransmitter release by omega-conotoxin GVIA

1. The role of voltage-sensitive calcium channels (VSCC) in N-methyl-D-aspartate (NMDA)- and kainic acid (KA)-evoked neurotransmitter release from rat cortical and hippocampal brain slices was evaluated by determining the effects of omega-conotoxin GVIA, an inhibitor of neuronal L- and N-type VSCC, and PN 200-110, a selective inhibitor of L-type VSCC. 2. Selective antagonists of the NMDA receptor ionophore complex, Mg2+, CPP and MK-801, inhibited NMDA- but not KA-evoked release of [3H]-noradrenaline from hippocampal and cortical brain slices. This suggests that cortical and hippocampal receptors are similar and that NMDA and KA act at distinct excitatory amino acid receptor subtypes. 3. [3H]-noradrenaline release induced by both NMDA and KA was similarly inhibited (approximately 30%) by omega-conotoxin GVIA. In contrast, PN 200-110 had no significant effect, although there was a tendency towards inhibition. 4. The results suggest that although NMDA- and KA-receptors are pharmacologically distinct, the N-type, but not the L-type, VSCC plays a small but significant role in neurotransmitter release induced by both NMDA and KA. It remains to be determined whether the N-type VSCC are involved in the physiological and/or pathological manifestations of excitatory amino acid receptor stimulation.

Lack of excitatory amino acid-induced effects on calcium fluxes measured with 45Ca2+ in rat cerebral cortex synaptosomes

Ca2+ uptake was measured in purified rat cerebral cortex synaptosomes (P3 pellets) using 45Ca2+ as a tracer. Ca2+ influx increased in time, and with an increase in external K+ concentration and temperature. The net (external K+-induced, depolarization-dependent) uptake follows a two-component course. The exponential term, due to the opening of voltage-operated calcium channels (VOC), has a rate constant which increases with an increase in the depolarization level (1.04 versus 0.54 nmol/s/mg protein for 50 mM - versus 15 mM [K+]-dependent net influx). The linear term, due to the Na+/Ca2+ exchange system, has a similar rate constant at all depolarization levels (0.16 +/- 0.05 and 0.11 +/- 0.02 nmol/s/mg protein). Excitatory amino acids (glutamate, kainate and n-methyl-d-aspartate-NMDA-) were tested on this preparation at doses ranging between 5 x 10(-5) M and 5 x 10(-3) M and at multiple incubation times, under resting conditions and under two depolarizing conditions (partial depolarization: 15 mM external K+ and maximal depolarization: 50 mM external K+). NMDA was also tested in the absence of Mg2+. No effect was detectable under any of these experimental conditions. Hypotheses to interpret these data are discussed. Further studies on other preparations are needed in order to directly investigate the presynaptic effects of excitatory amino acids.

N-methyl-D-aspartate receptor-mediated increase in intracellular calcium is reduced by ketamine and phencyclidine

L-Glutamate, N-methyl-D-aspartate, quisqualate and potassium chloride enhanced Ca2+ accumulation by rat cortical slices as determined using 45Ca2+ uptake and Ca2+ mobilisation in cortical synaptosomes as determined using quin-2 fluorescence. Quinolinate and kainate were ineffective. Responses to L-glutamate and N-methyl-D-aspartate were blocked by non-competitive (ketamine, phencyclidine, Mg2+) and competitive (2-amino-5-phosphonovalerate) antagonists. These data suggest that activation of excitatory amino acid receptors in the cortex results in enhanced Ca2+ mobilisation which can be blocked by selective antagonists. Such effects may be related to neurotoxic properties of the excitatory amino acids and the neuroprotection afforded by excitatory amino acid antagonists.

Early changes in extracellular amino acids and calcium concentrations in rabbit hippocampus following complete 15-min cerebral ischemia

The effect of cerebral ischemia on extracellular amino acids and calcium content and on the permeability of the blood-brain barrier was studied by in vivo dialysis of rabbit hippocampus. This was combined with physiological and neurophysiological measurements. It was found that immediately after 15-min ischemia extracellular concentrations of glutamate, aspartate and taurine increased 3-, 2- and 6-fold, respectively, whereas a maximal, 7-fold increase of phosphoethanolamine and persistent elevation of glutamate were observed 45 min after ischemia. Extracellular calcium concentration, monitored with 45Ca2+, increased by 10% during the initial phase of ischemia, and decreased to approx. 74% of the basal level 10 min after ischemia. Recovery of extracellular calcium content was not attained until 45 min of recirculation, at which time the first signs of return of bioelectric activity were noted. Increased permeability of the blood-brain barrier to fluoresceine developed immediately after ischemia and persisted up to 2 h of recirculation. The obtained results are discussed in reference to the noted simultaneity of changes in extracellular excitatory amino acids and calcium concentrations and of brain bioelectric activity during and after ischemia. Causal relations between these effects are suggested.

Quinolinic acid-induced seizures, but not nerve cell death, are associated with extracellular Ca2+ decrease assessed in the hippocampus by brain dialysis

Seizures, neuronal damage and extracellular Ca2+ concentration were studied in rats unilaterally injected in the dorsal hippocampus with quinolinic acid, a brain metabolite with excitotoxic properties. In freely moving animals, in the first 2 h after the injection of a convulsant and neurotoxic dose (156 nmol), quinolinic acid induced a tetrodotoxin-insensitive decrease in the extracellular Ca2+ concentration (nadir 40%) in the injected area, as assessed by brain dialysis coupled to a fluorimetric method for Ca2+ detection. Blockade of quinolinic acid-induced decrements in Ca2+ by 15.6 nmol D-(-)2-amino-7-phosphonoheptanoic acid indicated that this effect was receptor-mediated. Dose-response relationships showed a close association between seizure activity (measured by EEG) and extracellular Ca2+ changes in the injected area. Changes in Ca2+ were apparent at the site of injection prior to the onset of focal seizures and they were not found in the homotypic structure where seizures were conducted. Drugs effective in blocking seizures (carbamazepine and flunarizine) prevented the fall in extracellular Ca2+, while drugs without anticonvulsant activity (ethosuximide and nifedipine) did not. Destruction of nerve cells by quinolinic acid was not prevented by treatment with carbamazepine and flunarizine. The results suggest that the fall in extracellular Ca2+ observed in the first 2 h after quinolinic acid, probably reflecting the ion influx into neurons, is involved in triggering focal seizures but is not related to the occurrence of nerve cell death.

Imaging of the degeneration of neurons and their processes in rat or cat brain by 45CaCl2 autoradiography or 55CoCl2 positron emission tomography

The possibility of using radiolabeled divalent cations to visualize nerve cell degeneration in the brain was investigated after intoxication with neurotoxins. At different survival times after the intracerebral injection of kainic acid or 6-hydroxydopamine, autoradiographs were made from brain sections of rats that had received 45CaCl2 intravenously 24 h before death. Brain sections, adjacent to those used for autoradiography, of the 6-hydroxydopamine-treated rats were used for histofluorescence of catecholamines to check the neurochemical effect of the treatment. These experiments show that radioactive Ca accumulates in brain tissue during a particular phase of degeneration. Not only could degenerating cell bodies be traced by 45Ca autoradiography, but also degenerating nerve terminals in the striato-nigral and nigro-striatal projection systems. In positron emission tomography (PET) studies, 55CoCl2 was used as a marker for Ca2+. Unilateral lesions of the cat forebrain, produced by kainic acid, could be imaged in vivo by PET with 55CoCl2. PET with this radiolabel may provide diagnostic potentials for human neurodegenerative disorders.

The neurotoxicity of intrahippocampal kainic acid injection in rats is not accompanied by a reduction of Timm stain

Histopathological changes induced by intrahippocampal injections of low doses of kainic acid (17.5 ng/site) were investigated in rats. Kainic acid produced a selective loss of CA3 pyramidal and hilar neurons. The development of kainic acid-induced neuronal injury was not accompanied by any detectable loss of histologically demonstrable zinc as assessed by means of a modified Timm's sulphide-silver method. It is suggested that the selective injury of hippocampal neurons induced by kainic acid is not contingent on the release of zinc from mossy-fiber terminals.

Effect of various calcium channel blockers on three different models of limbic seizures in rats

Voltage-dependent calcium channel-blockers were studied for their ability to modulate limbic seizures induced in rats by injection of quinolinic acid and kainic acid into the hippocampus or by hippocampal kindling. Flunarizine, at 40 mg/kg (but not 20 mg/kg), reduced the total number of seizures and total time spent in seizures induced by quinolinic acid by 75%; at 60 mg/kg, both parameters were reduced more than 90%, while at 80 mg/kg seizures induced by kainic acid were not affected. Forty and 60 mg/kg of flunarizine protected hippocampal-kindled rats from fully developed convulsions (Stage 5). Nifedipine, at 20 and 40 mg/kg, was ineffective on seizures induced by both quinolinate and kainate. However, at 20 mg/kg, 57% of the kindled animals were protected from Stage 5 and total protection was achieved at 40 mg/kg. Verapamil, at 40 mg/kg, reduced by respectively, 88% and 78%, the total number of seizures and the total time spent in seizures induced by quinolinic acid, but had no effect on seizures induced by kainate and Stage 5 seizures. The results suggest that, while seizures induced by kainic acid were refractory to all voltage-dependent calcium channel blockers, binding sites affected by flunarizine and verapamil in the brain may selectively facilitate ictal activity induced by quinolinic acid. Binding sites for dihydropyridine might contribute to the increased hippocampal excitability in kindled animals. The role of calcium entry through voltage-dependent calcium channels in the occurrence of seizures in these models of limbic epilepsy is discussed.

Potentiation by kainate of excitatory amino acid release in striatum: complementary in vivo and in vitro experiments

The effect of kainate on extracellular levels of amino acids in corpus striatum was investigated in vitro and in vivo, to elucidate the mechanism underlying its neurotoxicity. Kainate increased extracellular glutamate and aspartate in both striatal slices in vitro and intact striatum in vivo, as previously reported. Both in vitro and in vivo, DL-threo-3-hydroxyaspartate increased extracellular glutamate and aspartate levels (to between 150 and 200% of basal), and also enhanced their kainate-evoked release. The action of kainate in vivo was reduced by prior frontal decortication, whereas in vitro the kainate-evoked responses were only slightly reduced by tetrodotoxin, and remained above control values. These results confirm that kainate increases extracellular glutamate and aspartate, and provide evidence that this is due to synaptic release evoked by an action on receptors on glutamatergic neurone terminals. These findings may be relevant to the understanding of epilepsy.

In vivo microdialysis studies on the effects of decortication and excitotoxic lesions on kainic acid-induced calcium fluxes, and endogenous amino acid release, in the rat striatum

The in vivo effects of kainate (1 mM) on fluxes of 45Ca2+, and endogenous amino acids, were examined in the rat striatum using the brain microdialysis technique. Kainate evoked a rapid decrease in dialysate 45Ca2+, and an increase in the concentration of amino acids in dialysates in Ca2+-free dialysates. Taurine was elevated six- to 10-fold, glutamate two- to threefold, and aspartate 1.5- to twofold. There was also a delayed increase in phosphoethanolamine, whereas nonneuroactive amino acids were increased only slightly. The kainic acid-evoked reduction in dialysate 45Ca2+ activity was attenuated in striata lesioned previously with kainate, suggesting the involvement of intrinsic striatal neurons in this response. The increase in taurine concentration induced by kainate was slightly smaller under these conditions. Decortication did not affect the kainate-evoked alterations in either dialysate 45Ca2+ or amino acids. These data suggest that kainate does not release acidic amino acids from their transmitter pools located in corticostriatal terminals.

Regional cerebral glucose phosphorylation and blood flow after insertion of a microdialysis fiber through the dorsal hippocampus in the rat

Local cerebral glucose metabolism (LCMRglc) and local cerebral blood flow (LCBF) were studied following implantation of a microdialysis fiber in rat dorsal hippocampus. Recovery time after implantation varied from 0 to 24 h. All rats showed pronounced disturbances in LCMRglc and LCBF during the first 2 h of implantation. The changes consisted of (a) a general decrease in blood flow and glucose phosphorylation and (b) small areas (spots) around the fiber with increased glucose phosphorylation and decreased blood flow. Animals allowed to recover for 24 h demonstrated a near normalization of LCMRglu and LCBF, and the focal disturbances (spots) of glucose phosphorylation and blood flow disappeared. The slight reduction in blood flow and glucose metabolism at this time must be accepted, because extension of the recovery period beyond 24 h may give interpretation problems due to the developing gliosis.

Kainic acid-induced terminal degeneration in the dorsal lateral geniculate of tree shrew

The dorsal lateral geniculate nucleus of tree shrews is very susceptible to the neurotoxic effects of kainic acid. In addition to neuronal loss, there is a profound loss of retinal terminals that is manifested through a disruption of anterograde transport of WGA/HRP from the retina to the kainic acid-lesioned area of the geniculate nucleus. The actions of kainic acid upon both the presynaptic terminals and geniculate neurons may be mediated by a glutamatergic pathway and questions the hypothesis that kainic acid is solely neuron-specific in its toxic action.

Excitatory amino acid receptors and depolarization-induced Ca2+ influx into hippocampal slices

Hippocampal brain slices were incubated with depolarizing agents or excitatory amino acids either alone or in the presence of excitatory amino acid antagonists [omega-phosphonic alpha-aminocarboxylic acids--2-amino-4-phosphonobutyric acid (AP4), 2-amino-5-phosphonovaleric acid (AP5), or 2-amino-7-phosphonoheptanoic acid (AP7)--or gamma-D-glutamylaminomethylsulphonic acid (GAMS)] or a calcium-channel blocker, (S)-1-(3-methoxyphenyl)-3-methylaza-7-cyano-7-(3,4-dimethoxyphenyl )-8-methyl- nonane hydrochloride [(-)-D888]. The uptake of 45Ca2+ and the efflux of glutamate or aspartate induced by veratrine or high K+ was blocked (54-76%) by AP7 (IC50 46-250 microM). AP5 and AP4 were less effective. (-)-D888 (10 microM) caused 100% block of evoked 45Ca2+ uptake. Uptake of 45Ca2+ induced by exogenous glutamate, aspartate, and N-methyl-D-aspartate (NMDA) was also inhibited by AP7, whereas GAMS completely blocked the action of kainate and partially blocked that of glutamate. The action of NMDA in stimulating 45Ca2+ uptake was Mg2+-sensitive, low Mg2+ levels in the incubation medium selectively enhancing the response. It is concluded that Ca2+ uptake evoked by excitatory amino acids is receptor-mediated, and that released excitatory amino acids are responsible for a large part of the action of veratrine and high K+ in stimulating 45Ca2+ uptake.

Effects of Ca2+ entry blockers on kainate-induced changes in extracellular amino acids and Ca2+ in vivo

The effect of organic Ca2+ channel blockers and Co2+ on kainate-induced changes in 45Ca2+ efflux and amino acid release was studied in the rabbit hippocampus with the dialysis-perfusion technique. Administration of 1 mM kainate caused a transient, 50% drop of extracellular Ca2+. This effect was insensitive to 100 microM flunarizine or verapamil, 10 microM nimodipine, and 6 mM CoCl2. The organic Ca2+ entry blockers did not significantly influence kainate-induced changes in extracellular amino acids, whereas Co2+ affected both basal and kainic acid stimulated release of amino acids. These results indicate that kainate-regulated Ca2+ ionophores differ from Ca2+ channels in peripheral tissues in terms of sensitivity to Ca2+ entry inhibitors.

Ischemic CA-1 pyramidal cell loss is prevented by preischemic colchicine destruction of dentate gyrus granule cells

Hippocampal CA-1 pyramidal cell damage was produced by 20 min of cerebral ischemia. Colchicine destruction of the dentate gyrus granule cells 11 days before ischemia prevented the CA-1 cell loss. It is suggested that the protective effect of degranulation on ischemic CA-1 pyramidal cell damage is due to reduction of glutamate release in CA-1 during and after ischemia.

Intraendothelial accumulation of calcium in the hippocampus and thalamus of rats after systemic kainic acid administration

The accumulation of calcium in the hippocampal and thalamic vascular endothelium and the perivascular space was detected histochemically by means of the pyroantimonate technique 30, 60 and 120 min after systemic kainic acid administration. An increased number of calcium pyroantimonate deposits was found in the endothelial mitochondria 60 min after kainate injection. The mitochondria were swollen at this time and vacuoles containing deposits were observed. After 120 min a pronounced perivascular glial swelling was conspicuous, besides the numerous endothelial mitochondrial deposits. The swollen glial processes contained a large number of pyroantimonate deposits. It seems likely that the transendothelial calcium transport processes are accompanied by intraendothelial calcium accumulation and mitochondrial calcium sequestration.