Kainic acid: The neurotoxic breakthrough

Genes of the Glutamatergic System and Tardive Dyskinesia in Patients with Schizophrenia

Background: Tardive dyskinesia (TD) is an extrapyramidal side effect of the long-term use of antipsychotics. In the present study, the role of glutamatergic system genes in the pathogenesis of total TD, as well as two phenotypic forms, orofacial TD and limb-truncal TD, was studied. Methods: A set of 46 SNPs of the glutamatergic system genes (GRIN2A, GRIN2B, GRIK4, GRM3, GRM7, GRM8, SLC1A2, SLC1A3, SLC17A7) was studied in a population of 704 Caucasian patients with schizophrenia. Genotyping was performed using the MassARRAY Analyzer 4 (Agena Bioscience™). Logistic regression analysis was performed to test for the association of TD with the SNPs while adjusting for confounders. Results: No statistically significant associations between the SNPs and TD were found after adjusting for multiple testing. Since three SNPs of the SLC1A2 gene demonstrated nominally significant associations, we carried out a haplotype analysis for these SNPs. This analysis identified a risk haplotype for TD comprising CAT alleles of the SLC1A2 gene SNPs rs1042113, rs10768121, and rs12361171. Nominally significant associations were identified for SLC1A3 rs2229894 and orofacial TD, as well as for GRIN2A rs7192557 and limb-truncal TD. Conclusions: Genes encoding for mGlu3, EAAT2, and EAAT1 may be involved in the development of TD in schizophrenia patients.

Expression and localization of duodenal cytochrome b in the rat hippocampus after kainate-induced excitotoxicity

Brain iron accumulation and oxidative stress are common features of many neurodegenerative diseases, and could be due in part to increased iron influx across the blood-brain interface. The iron transport protein, divalent metal transporter 1 (DMT1) is found in reactive astrocytes of the lesioned hippocampal CA fields after excitotoxicity induced by the glutamate analog kainate (KA), but in order for iron to be transported by DMT1, it must be converted from the ferric to the ferrous form. The present study was carried out to investigate the expression of a ferric reductase, duodenal cytochrome b (DCYTB), in the rat hippocampus after KA injury. Quantitative reverse transcriptase-polymerase chain reaction showed significant increases in DCYTB mRNA expression of 2.5, 2.7, and 5.2-fold in the hippocampus at 1week, 2weeks and 1month post-KA lesions respectively compared to untreated controls, and 3.0-fold compared to 1month post-saline injection. DCYTB-positive cells were double labeled with glial fibrillary acidic protein, and electron microscopy showed that the DCYTB-positive cells had dense bundles of glial filaments, characteristic of astrocytes, and were present as end-feet around unlabeled brain capillary endothelial cells. DMT1 labeling in astrocytes and increased iron staining were also observed in the lesioned hippocampus. Together, the present findings of DCYTB and DMT1 localization in astrocytes suggest that DCYTB is a ferric reductase for reduction of ferric iron, for transport by DMT1 into the brain. We postulate that the coordinated action of these two proteins could be important in iron influx across the blood-brain interface, in areas undergoing neurodegeneration.

Spatial memory is enhanced in long-living Ames dwarf mice and maintained following kainic acid induced neurodegeneration

INTRODUCTION

Age associated cognitive impairment is associated with low levels of IGF-1, oxidative stress, and neuronal loss in the hippocampus. Ames dwarf mice are long-lived animals that exhibit peripheral IGF-1 deficiency. Hippocampal-based spatial memory (a homolog of cognitive function) has not been evaluated in these long-living mice.

MATERIALS AND METHODS

We evaluated the hippocampal-based spatial memory in 3-, 12- and 24-month-old Ames dwarf and wild type mice using the Barnes maze and the T-maze. We also examined the effect of a hippocampal-specific toxin, kainic acid (KA), on spatial memory to determine whether Ames mice were resistant to the cognitive impairment induced by this compound.

RESULTS

We found that Ames dwarf mice exhibit enhanced learning, making fewer errors and using less time to solve both the Barnes and T-mazes. Dwarf mice also have significantly better short-term memory as compared to wild type mice. Both genotypes exhibited neuronal loss in the CA1 and CA3 areas of the hippocampus following KA, but Ames dwarf mice retained their spatial memory.

DISCUSSION

Our results show that Ames dwarf mice retained their spatial memory despite neurodegeneration when compared to wild type mice at an "equiseizure" dose of KA.

Temporal Profile of Clinical Signs and Histopathologic Changes in an F-344 Rat Model of Kainic Acid–induced Mesial Temporal Lobe Epilepsy

Since there is limited information in the literature, the purpose of this study was to investigate clinical signs, morphology, and temporal progression of lesions from Days 3 to 168 in a kainic acid (KA)-induced Fischer-344 (F-344) rat model of mesial temporal lobe epilepsy (MTLE). Following a single KA subcutaneous dose of 9 mg/kg to young adult male rats, 95% survived, 93% exhibited status epilepticus, and 80% eventually developed spontaneous motor seizures. Histopathology included hematoxylin and eosin (H&E), autofluorescence, Fluoro-Jade B, Timm’s, ED-1/CD68, GFAP, doublecortin, and Ki-67. Neuronal degeneration occurred on Day 3 in the hippocampal CA1, CA3, and dentate hilar regions; amyg-daloid and thalamic nuclei; and frontoparietotemporal, entorhinal and piriform cortices. Degeneration severity peaked on Day 6 and decreased progressively until Day 168. Aberrant mossy fiber (MF) sprouting was present in the inner molecular layer of dentate gyrus on Days 6–168. Microliosis and astrogliosis peaked on Day 28 and generally colocalized with the distribution of neuronal degeneration. Important correlates to human MTLE included induction of spontaneous seizures, more severe neuronal damage of CA1 than CA3 (in contrast to other animal models but similar to humans), hilar neuronal loss, activated microgliosis and astrogliosis, aberrant MF sprouting, and dentate granule cell neurogenesis. Aberrant MF sprouting prior to spontaneous motor seizures and reduced seizure frequency with a decrease in aberrant MF sprouting support the hypothesis that MF sprouts are necessary for spontaneous seizure generation and maintenance.

Neuroprotective effect of citicoline against KA-induced neurotoxicity in the rat retina

We examined whether citicoline has neuroprotective effect on kainic acid (KA)-induced retinal damage. KA (6 nmol) was injected into the vitreous of rat eyes. Rats were injected intraperitoneally with citicoline (500 mgkg-1, i.p.) twice (09:00 and 21:00) daily for 1, 3 and 7 days after KA-injection. The neuroprotective effects of citicoline were estimated by measuring the thickness of the various retinal layers. In addition, immunohistochemistry was conducted to elucidate the expression of choline acetyltransferase (ChAT) and tyrosine hydroxylase (TH). Morphometric analysis of retinal damage in KA-injected eyes showed a significant cell loss in the inner nuclear layer (INL) and inner plexiform layer (IPL) of the retinas at the 1, 3 and 7 days after KA injection, but not in the outer nuclear layers (ONL). At 1 and 3 days after citicoline treatment, no significant changes were detected in the retinal thickness and immunoreactivities of ChAT and TH. The immunoreactivities of ChAT and TH had almost disappeared in the retina after 7 days of KA injection. However, prolonged citicoline treatment for 7 days significantly attenuated the reduction of retinal thickness and immunoreactivities of ChAT and TH. The present study suggests that treatment with citicoline has neuroprotective effect on the retinal damage due to KA-induced neurotoxicity.

Kainic acid (KA)-induced seizures in Sprague-Dawley rats and the effect of dietary taurine (TAU) supplementation or deficiency

Male Sprague-Dawley rats received TAU supplementation (1.5% in drinking water) or TAU deficient diets for 4 weeks to test for a possible neuroprotective role of TAU in KA-induced (10 mg/kg s.c.) seizures. TAU supplementation significantly increased serum and hippocampal TAU levels, but not TAU content in temporal cortex or striatum. TAU deficient diets did not attenuate serum or tissue TAU levels. Dietary TAU supplementation failed to decrease the number or latency of partial or clonic-tonic seizures or wet dog shakes, whereas a TAU deficient diet decreased the number of clonictonic and partial seizures. This study does not support previous observations of an anticonvulsant effect of TAU against KA-induced seizures. KA-treatment decreased alpha 2-adrenergic receptor binding sites and TAU content in the temporal cortex across all dietary treatment groups, supporting previous evidence of severe KA-induced damage and neuronal loss in this brain region.

The motornervous system of Ascaris: electrophysiology and anatomy of the neurons and their control by neuromodulators

Analysis of the electrical properties of neurons in the motornervous system of Ascaris sutom suggests that it is largely an analogue system. The motorneurons do not conduct action potentials and they release transmitter tonically at their normal resting potential; transmitter release is increased or decreased as a continuous function of membrane potential. Despite extensive physiological descriptions of the electrical properties of the neurons and their synapses, as well as morphological descriptions of the synaptic circuitry of the system, the predicted activities of the neurons in the circuit differ from those observed by direct recording in semi-intact behaving animals. We conclude that the description of the circuit is incomplete. There are several possibilities for the missing elements, including chemical, proprioceptive, and additional neuronal components. Recently, attention has been focussed most heavily on the intercellular chemical signalling systems; in addition to those mediated by classical neurotransmitters, a surprisingly complex array of neuropeptides has been identified. One family of these peptides, the AF peptides, has been analyzed in detail. It comprises at least 20 peptides, and they fall into sequence-related subfamilies. One of these subfamilies, containing 6 peptides, is encoded by a single transcript, suggesting that the AF peptides are under multiple genetic control. All AF peptides tested have potent activity on the motornervous system and/or on muscle. There are multiple physiological activities, and cellular localization studies show multiple patterns of cellular expression. Studies on Panagrellus and Caenorhabditis emphasize the diversity of this family and its genetic control.

Impairment of baroreceptor reflexes following kainic acid lesions of the lateral tegmental field

We examined the effects of kainic acid lesions of the lateral tegmental field on baroreceptor function in the anesthetized cat. Kainic acid lesions prevented the reflex inhibition of inferior cardiac sympathetic nerve activity observed during an increase in blood pressure. The temporal locking of sympathetic slow waves to the cardiac cycle was also abolished following tegmental field lesions. Finally, the periodicity of sympathetic nerve discharge shifted to a higher frequency range following kainic acid lesions. These observations are consistent with the conclusion that lesions of the lateral tegmental field impair baroreceptor reflexes.

Lateral tegmental field involvement in the central sympathoinhibitory action of 8-OH-DPAT

This study examined the effects of kainic acid and NMDA microinjections into the lateral tegmental field on the sympatholytic effect of the 5-HT1A agonist 8-OH-DPAT. Kainic acid has been reported to destroy cell bodies while leaving fibers of passage intact while NMDA excites the cell bodies but not the axons of neurons. Microinjection of kainic acid was found to block the usual sympatholytic effect of 8-OH-DPAT but not the sympathoinhibition produced by the alpha 2 agonist clonidine. Microinjection of NMDA elicited profound pressor responses related to an increase in sympathetic activity. Sympatholytic effects of 8-OH-DPAT and clonidine were transiently overridden by microinjections of NMDA, but not glutamate. A role for the lateral tegmental field in the generation of sympathetic tone and in the sympatholytic mechanism of 8-OH-DPAT is supported by the chemical lesion and stimulation studies.

Excitotoxic cell death

Excitotoxicity refers to the ability of glutamate or related excitatory amino acids to mediate the death of central neurons under certain conditions, for example, after intense exposure. Such excitotoxic neuronal death may contribute to the pathogenesis of brain or spinal cord injury associated with several human disease states. Excitotoxicity has substantial cellular specificity and, in most cases, is mediated by glutamate receptors. On average, NMDA receptors activation may be able to trigger lethal injury more rapidly than AMPA or kainate receptor activation, perhaps reflecting a greater ability to induce calcium influx and subsequent cellular calcium overload. It is possible that excitotoxic death may share some mechanisms with other forms of neuronal death.

Behavioral effects of fetal neural transplants: relevance to Huntington's disease

Animal models of Huntington's disease (HD) and other neurological disorders have proven useful for examining the anatomical, neurochemical, and behavioral alterations in these diseases. Investigators have taken advantage of new excitotoxic models that appear to successfully simulate the neurobiological and behavioral characteristics of HD with remarkable homology. Selective excitotoxic compounds allow for a more precise and controlled lesion with which to examine the relationship between striatal damage and behavioral abnormalities. In addition, these models provide new approaches for developing and testing various treatments for HD. Fetal neural tissue transplanted into the excitotoxin-lesioned animal can integrate with the host brain and promote neurochemical and functional recovery. Neural grafting paradigms may be viewed as potential therapies for treating neurodegenerative diseases and as aids in deciphering the regenerative mechanisms of the central nervous system. Further research is necessary, however, to determine the negative and positive effects of neural transplantation. In addition, existing behavioral models need to be refined to allow for better evaluation of the subtle topographic changes in behavior resulting from fetal tissue transplantation.

Kainic acid-induced seizures in aged rats: neurochemical correlates

This study was conducted to assess the functional integrity of the kainate receptor-mediated seizure response in aged rats. Kainic acid was administered systemically to aged female Long-Evans (LE) rats and aged male F344 rats and the proconvulsant actions of kainic acid was compared to adult controls. The effects of kainic acid on brain regional content of monoamines and amino acids was also determined in the aged female LE and adult control rats. The latency to full clonic-tonic seizures was significantly reduced in aged female LE rats, and the number of seizures was significantly increased above that of the controls. There was increased mortality and a reduction in the latency to exhibit wet dog shakes in the aged F344 rats. Studies were also conducted to evaluate the role of ovarian hormones, route of administration, and dose of kainic acid in mediating the enhanced proconvulsant actions of kainic acid in aged rats. The neurochemical studies suggested that kainic acid significantly enhanced the release of ASP, GLU, and norepinephrine (NE) in the aged rats exhibiting clonic-tonic seizures. The adult rats given the same dose of kainic acid (15 mg/kg, IP) did not exhibit any significant change in brain content of monoamines or amino acids except for a reduction in mediobasal hypothalamic NE. An in vitro study was also conducted using brain slices from adult and aged F344 and it was found that aged rats released significantly more ASP than adults in response to kainic acid. These neurochemical findings were discussed in relation to previous studies of age-related alterations in excitatory amino acids (EAAs) and the role of EAA and NE in modulating limbic seizures. This study has clearly demonstrated that aged rats may be more susceptible to the excitotoxic action of EEAs acting through kainetic receptors.

Domoic acid toxicity in rats and mice after intracerebroventricular administration: comparison with excitatory amino acid agonists

A behavioural study of the domoic acid (DOM)-induced convulsive behaviour after intracerebroventricular administration was carried out in rats and mice. DOM-induced behaviours were compared to those elicited by other excitatory amino acid (EAA) agonists N-methyl-D-aspartate (NMDA), alpha-amino-3- hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) and kainic acid (KA), in such a way as to assess the possible similarities between DOM-induced effects and EAA subtype receptor activation in vivo. In rat, DOM (0.03-3 nmol/rat) caused a complex pattern of convulsive behaviour, quantified by means of a 15-point rating scale. DOM-induced behavioural profile was characterized at the lower doses by "preconvulsive" behaviours as wet dog shakes, hypermotility, mild facial clonus. At higher doses, DOM caused clonic convulsions followed by the "status epilepticus" syndrome (wet dog shakes, forelimb clonus, rearing, salivation). Rats treated with KA (0.3-10 nmol/rat) showed an almost identical behavioural profile. AMPA (1-10 nmol/rat)-induced convulsive behaviour was similar to DOM and KA only at the higher doses. NMDA (0.25-10 nmol/rat) caused clonic convulsions but not "status epilepticus". In mice, similar results were obtained: all the tested drugs induced generalized seizures, but only animals treated with DOM, KA and AMPA showed a prolonged sequence of seizures with forelimb clonus. Our results confirm the findings reported in the literature and support the hypothesis that DOM and KA act at the same EAA receptor.

Experimental oral toxicity of domoic acid in cynomolgus monkeys (Macaca fascicularis) and rats. Preliminary investigations

A recent outbreak of marine food poisoning in humans was attributed to the consumption of blue mussels (Mytilus edulis L.) contaminated with domoic acid (DA) that was produced by the diatom Nitzschia pungens. The clinical and morphological effects of single oral doses of extracts of mussels contaminated with DA or of DA isolated from toxic mussels were investigated in small groups (one to six) of cynomolgus monkeys (Macaca fascicularis; 0.5-10 mg DA/kg body weight) and of Sprague-Dawley rats (60 to 80 mg DA/kg body weight). Control animals were either given saline or were not treated. To test whether monosodium glutamate, present in the food consumed by some affected humans, and dimethylsulphoxide, suspected of being present in the plankton, enhanced the response, monosodium glutamate (at 0.25% of mussel extract bolus) or dimethylsulphoxide (at 1 g per bolus) were co-administered to two (one each) of the DA-treated monkeys. DA-treated monkeys developed transient excitation characterized by vomiting. DA-treated rats showed withdrawal followed by hyperexcitation and death (in one case). Mild to moderate central nervous system lesions consistent with neuroexcitation were present in both monkeys and rats. The addition of monosodium glutamate and dimethylsulphoxide had no significant effect on the appearance and severity of central nervous system clinical signs and lesions. The wide variations in the response of test animals to orally administered DA were attributed to the protective effect of vomiting, and to suspected incomplete or slow gastro-intestinal absorption of the toxic agent. The results reinforce the view that DA is an emetic and that under appropriate conditions may also inflict excitotoxic central nervous system damage.

Neural basis of behavior: animal models of human conditions

A variety of neurological disorders including Alzheimer's, Parkinson's, and Huntington's diseases are characterized by abnormalities within specific neuroanatomical and/or neurochemical systems. Approaches to the treatment of these and other neurological disorders are limited. The development and refinement of animal models which closely mimic human disease states would help elucidate the underlying neurobiological mechanisms of the disease as well as suggest novel therapeutic strategies for their prevention or alleviation. This symposium presents a variety of animal models that have helped us in understanding the human condition. The present introduction presents some clinically relevant findings obtained from basic experimental studies with animal models of Huntington's disease (HD) and Tourette Syndrome (TS). These studies demonstrate that animal models can provide a greater understanding of the symptomatology of disease states as well as suggest innovative new treatments.

Kainic acid on the rat ventral medullary surface depresses hypoxic and hypercapnic ventilatory responses

Kainic acid, topically applied to the ventral surface of the medulla immediately caudal to the trapezoid body in the urethane/chloralose anaesthetised rat, led to a depression of ventilation and a sustained rise in blood pressure; ventilatory responses to hypercapnia (10% carbon dioxide) and hypoxia (11% oxygen) were slightly depressed. Widespread application of kainic acid to an area at and slightly rostral to the rootlets of the hypoglossal nerve produced a stimulation of ventilation and an unsustained rise in blood pressure. Apnea ensued 12-28 min after application. Ventilatory responses to hypercapnia and hypoxia were markedly attenuated; more discrete bilateral application revealed two regions, one immediately rostral and lateral to the hypoglossal rootlets and the other over the point of exit of the hypoglossal nerve rootlets, which specifically contributed to the diminution of the chemosensory responses. These results raise questions about the medullary circuitry which mediates the chemoreflex regulation of breathing.

Neuropathology of excitatory neurotoxins: the domoic acid model

A novel type of intoxication in Canada in 1987 was traced to consumption of cultivated mussels contaminated with the excitotoxin domoic acid. Studies carried out in rats and monkeys revealed that parenterally administered domoic acid induces in rats neuroexcitatory phenomena culminating in seizures. Monkeys respond with gagging, emesis and less clearly evident seizure activity. CNS damage consisting of dendrotoxic and gliotoxic edema and nerve cell degeneration occurs in structures of the limbic system and the retina in both species. CNS lesion distribution similarities in animals treated with domoic acid or kainic acid suggest that these excitotoxins share a common pathogenesis mediated by glutamic acid, a putative endogenous excitatory neurotransmitter.

Acute neurotoxicity of domoic acid in the rat

A recent outbreak of human food poisoning, characterized by severe gastrointestinal and neurologic abnormalities, with a fatal outcome in 3 patients, was attributed to the consumption of poisonous mussels containing domoic acid at an abnormally high concentration. The purpose of the present study was to determine if domoic acid, a glutamate analogue extracted from poisonous mussel, was neurotoxic to rats. Groups of female Sprague-Dawley rats were dosed once intraperitoneally with 0, 1, 2, 4, or 7.5 mg domoic acid/kg of body weight and observed for a maximum period of 24 hr. Clinically, control rats and rats in the 1 mg/kg group were unremarkable. Seventy-five percent of the animals in the 2 mg/kg group had equivocal transient behavioral signs. One that was given 2 mg/kg and all rats given in excess of 4 mg/kg of body weight developed unequivocal behavioral and neurologic signs culminating in partial seizures and status epilepticus. Histopathologically, severely affected rats developed selective encephalopathy characterized by neuronal degeneration and vacuolation of the neuropil in the limbic and the olfactory systems, and retinopathy characterized by neuronal hydropic degeneration of the inner nuclear layer and vacuolation of the external plexiform layer. The results of this study suggest that domoic acid is excitotoxic and causes a characteristic syndrome with clinical signs and histopathologic lesions similar to those reported for kainic acid.

The quinolinic acid model of Huntington's disease: locomotor abnormalities

In contrast to other excitotoxins, such as kainic acid, quinolinic acid (QA) may spare a specific population of striatal neurons that is also spared in Huntington's disease (HD). Although several histological and biochemical experiments support the use of QA as a model for HD, to date no behavioral experiments have been performed to examine the suitability of this model. The present study explored the behavioral effects of bilateral intrastriatal microinjections of four doses (75, 150, 225, 300 nmol) of QA in the male rat. Using a multidimensional analysis of spontaneous locomotion (Digiscan activity) and a record of metabolic indicators, such as weight loss, a dose-dependent effect was found. The 75-nmol dose had no significant effect on locomotion or feeding behavior. In contrast, the 150- and 225-nmol doses induced hyperactivity and weight loss, whereas the 300-nmol dose was lethal. The results obtained suggest that striatal injections of 150-225 nmol of QA induce behavioral deficits qualitatively similar though quantitatively less than those which are seen after similar injection of 3 nmol of kainic acid and which have been reported to be comparable to the symptomatology of HD. Together with QA's possible greater histological selectivity, the present results support the use of QA-induced striatal lesions as a behavioral model of Huntington's disease.

Behavioural, electroencephalographic and neuropathological effects of the intrahippocampal injection of the venom of the South American rattlesnake (Crotalus durissus terrificus)

Venom was microinjected into the dorsal hippocampus of rats and electroencephalographic recordings were obtained from the hippocampus and occipital cortex. Behavioural alterations consisted of circling, wet shaking and scratching that evolved to head and body jerks and isolated clonic episodes and then to wild running followed by tonic-clonic generalized seizures and status epilepticus. Electroencephalographic alterations consisted of high frequency and high voltage spikes together with epileptiform seizures beginning in the hippocampus and evolving to the cortex. However there was only a poor electrographic-behavioural correlation between the generalized tonic-clonic seizures preceded by wild running and the electrical recordings from hippocampus and occipital cortex. Histology revealed lesions at the site of injection as well as at distant sites. Severity of neuronal damage was associated with seizure intensity. Damaged areas were almost the same as found within other models of epilepsy. Nevertheless a remarkable difference was the highly lesioned hypothalamus seen in this experiment. We discuss our results in relation to results obtained with other methods of inducing epilepsy. This venom may be a useful tool for studying the nervous system.

Quinolinic acid effects on amino acid release from the rat cerebral cortex in vitro and in vivo

1. The effect of quinolinic acid, N-methyl-D,L-aspartate (NMDLA) and kainate on the release of endogenous and exogenous amino acids from the rat cerebral cortex in vitro and in vivo was studied. 2. Neither quinolinic acid nor NMDLA had any effect on the basal or potassium-evoked release of [3H]-D-aspartate from slices of rat cerebral cortex either in the presence or absence of magnesium. Kainic acid failed to modify the basal efflux of [3H]-D-aspartate but significantly inhibited (by 34.4% +/- 0.04%, P less than 0.05) the potassium-evoked release. 3. Neither quinolinate nor NMDLA had any effect on the basal efflux of endogenous amino acids from rat cortical slices either in the presence or absence of magnesium ions at concentrations between 10 microM and 5 mM. 4. Both NMDLA (1 mM) and quinolinate (5 mM) produced an efflux of endogenous aspartate (371.4% +/- 11.6%; 389.3% +/- 12.1%) and glutamate (405.4% +/- 13.6%; 430.1 +/- 8.7%) respectively from the rat cerebral cortex in vivo (P less than 0.01). The quinolinic acid-evoked efflux was abolished by the NMDLA antagonist, 2-amino-5-phosphonovaleric acid (200 microM). 5. Kainic acid also caused an efflux of endogenous amino acids from the rat cerebral cortex in vivo. However, the profile of this release was different from that produced by quinolinate and NMDLA. 6. The results add further support to the suggestion that quinolinic acid acts at the NMDLA-preferring receptor and may also explain the requirement for intact afferent projections for the neurotoxic effects of quinolinate to be manifested.

The effect of kainic, quinolinic and beta-kainic acids on the release of endogenous amino acids from rat brain slices

It has been suggested that the neurotoxic properties of quinolinic acid and kainic acid may, at least in part, involve an indirect action on nerve terminals containing glutamate. In the present study it is confirmed that kainate causes the release of endogenous glutamate from rat hippocampal slices, but that quinolinic acid does not share this activity. In addition beta-kainic acid was found to depress the potassium evoked release of endogenous glutamate at relatively high concentrations and this effect may underlie the anticonvulsant properties of this substance.

Cellular localization of MAO A and B in brain: evidence from kainic acid lesions in striatum

The cellular localization of the two forms of monoamine oxidase (MAO A and MAO B) was studied by measuring their activities in rat striatum following unilateral stereotaxic injection of kainic acid to produce selective degeneration of striatal neurons and subsequent proliferation of astrocytes. The results demonstrated a persistent loss of 15-20% in MAO A activity, whereas MAO B activity decreased initially by 25% and then increased to more than twice the control value by 54 days after lesions. The changes in activity were compared to parallel estimates of the postsynaptic neuronal enzyme markers glutamic acid decarboxylase (GAD) and neuron-specific enolase (NSE), astroglial enzyme markers glutamine synthetase (GS) and non-neuronal enolase (NNE), and the presynaptic enzyme marker DOPA decarboxylase (DDC). The results suggest that a small amount of striatal MAO A is present in kainic acid-sensitive postsynaptic striatal neurons and that MAO B is probably localized in both neurons and astrocytes.

Autoreceptor-mediated changes in dopaminergic terminal excitability: effects of increases in impulse flow

The effect of spontaneous and stimulation-induced alterations in impulse flow on the antidromic excitability of nigrostriatal dopaminergic neurons were investigated in urethane-anesthetized rats. Terminal excitability was found to be inversely related to the rate of spontaneous activity of nigral neurons. Conditioning stimulation applied to dopaminergic axons in the medial forebrain bundle was found to decrease terminal excitability, but axonal conditioning stimulation was without effect on antidromic responses evoked from the medial forebrain bundle. Decreases in terminal excitability induced by medial forebrain bundle stimulation could be blocked by local infusions of haloperidol into the region of the terminal fields, suggesting that the effect was receptor-mediated. These results are consistent with the proposal that nigrostriatal dopaminergic neurons may modulate the impulse-dependent release of dopamine from striatal nerve terminals as a function of firing rate by autoreceptor-mediated alterations in the electrical properties of the terminal membrane.

L-pyroglutamate: an alternate neurotoxin for a rodent model of Huntington's disease

Intrastriatal injections of L-Pyroglutamate (L-PGA) in mice produced behavioral and neuropathological effects that resemble in part the kainate-injected rat striatal model of Huntington's Disease (HD). The behavioral responses induced after unilateral injections of L-PGA included circling, postural asymmetry of head and trunk and possible dyskinesias. The neuropil in the injected striatum contained dilated profiles, degenerating neurons and oligodendroglia, and numerous phagocytic microglial-like cells. A dose response relation existed. The size of the lesion (expressed as a percent volume of the striatum destroyed) ranged from 1 +/- 0.18% at 0.02 mumoles to 20.2 +/- 3.97% at 200 mumoles L-PGA (pH = 7.3). L-PGA is a weak neurotoxin when compared to kainic acid. Several factors raise interest in the possible role of L-PGA in HD, including the recently reported elevated plasma levels of L-PGA in some HD patients, and these considered in the discussion.

Normal pancreatic and intestinal enzymes in hypophagic growth-retarded rats that received dorsomedial hypothalamic lesions shortly after weaning

Male weanling Sprague-Dawley rats received bilateral electrolytic lesions in the dorsomedial hypothalamic nuclei (DMNL rats). Sham-operated rats served as controls. After being fed lab chow for two postoperative weeks, the animals were divided into four groups. One group of DMNL rats and controls received a high-caloric diet (high-fat diet, chocolate chip cookies, 32% sucrose solution, potato chips and marshmallows), whereas another group of DMNL rats and controls continued to receive lab chow. The experiment was terminated on the 185th postoperative day. In accordance with previous findings, DMNL rats, irrespective of diet, were lighter and shorter than controls. In addition, DMNL rats fed junk food were lighter than DMNL rats fed lab chow, and junk-fed controls weighed as much as chow-fed controls. Both DMNL rats and controls fed junk food were also shorter and showed higher carcass fat than their chow-fed counterparts. Also, DMNL rats fed junk food had less carcass fat than junk-fed sham-operated controls, whereas in accordance with previous findings, there was no difference between chow-fed DMNL rats and chow-fed sham-operated controls. Irrespective of diet, DMNL rats ate less calories than their respective sham-operated controls. Both absolute and percent pancreas weight and protein/pancreas were unaffected in DMNL rats but were reduced in both junk-fed groups in comparison with their chow-fed counterparts. Both concentrations and contents of pancreatic trypsinogen, amylase and lipase were unaffected in DMNL rats but total activities of all three enzymes were dramatically reduced in the junk-fed compared with the chow-fed DMNL rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Location of the area postrema pressor pathway in the dog brain stem

Electrical stimulation of the dog's area postrema (AP) induces a response that mimics the pressor response produced by intravertebral infusion of low-dose angiotensin II, which causes an increase in mean arterial pressure associated with transient tachycardia and increased peripheral resistance. The present study investigated in morphine-chloralose anesthetized dogs whether: 1) the characteristics of the AP pressor response are influenced by the presence of carotid sinus afferents; 2) structures rostral to the medulla influence the AP pressor response; and 3) the pressor pathway is initiated by neurons within the AP. Since bilateral cervical sinovagal denervation, which potentiated the phenylephrine pressor response, did not affect the pressor response to AP stimulation, the data provide evidence for an inhibitory influence exerted upon the central baroreflex mechanism by the AP pressor mechanism. The unaltered AP pressor response after midcollicular transection suggests that the efferent pathway is contained within the brain stem caudal to the pons. Finally, the elimination of the pressor response following kainic acid microinjection into the AP provides evidence that the AP pressor mechanism is initiated by neurons within the AP, rather than by fibers of passage from other pressor centers. These results suggest that the AP produces its facilitation of central sympathetic vasomotor outflow via a pathway contained within the medulla.

Intracortical and intrahippocampal injections of kainic acid in developing rats: an electrographic study

Electrographic patterns induced by neocortical and hippocampal microinjections of kainic acid (KA) have been studied in curarized 4-30-day-old rats. In younger (4-6-day-old) animals, both hippocampal and neocortical KA application induced, with a long delay, the appearance of sequences of slow spikes, simultaneously occurring in the cortex and hippocampus. The same pattern was observed in about 60% of animals 7-9 days old. In the remaining 40% of the rats of this age, epileptic abnormalities, initially localized in the neocortical or hippocampal injection site were obtained. The latter pattern always appeared in 10-14-day-old rats. In some of these status epilepticus was also reached. In older (15-30 days) animals, the hippocampal injection caused the appearance of hippocampal seizures, always evolving into status epilepticus. In neocortically injected animals, cortical bursts of polyspikes appeared, with or without hippocampal involvement. After 40-60 min, typical hippocampal seizures occurred, later leading to status epilepticus. The simultaneous hippocampal and neocortical response observed in younger rats is attributed to a massive activation of the immature brain structures. The focal response seems to be correlated with a maturational process of glutamate and/or kainate receptors at both hippocampal and neocortical levels. This process is completed during the third week, when a typical selective activation of the limbic structures is obtained.

Decreased benzodiazepine receptor binding in amygdala-kindled rat brains

3H-Flunitrazepam (3H-FLU) binding was measured in multiple brain regions of amygdala-kindled rats two weeks following the sixth Stage 5 convulsion. As compared to 'yoked' controls, the kindled animals displayed significant reductions in 3H-FLU binding in the ipsilateral cortex (20%) and in the hypothalamus (20%). Scatchard plots revealed that these reductions were due to changes in the maximal number of available binding sites (Bmax) rather than to alterations in receptor affinity (KD). No significant changes were found in the contralateral cortex, or in either the contralateral or ipsilateral amygdala, hippocampus or striatum. These data suggest that kindling is associated with long-lasting changes in the benzodiazepine receptor system and possibly with related changes in GABA-mediated neural inhibition.