Kainate and glutamate neurotoxicity in dependence on the postnatal development with special reference to hippocampal neurons

Glutamate-mediated excitotoxicity in neonatal hippocampal neurons is mediated by mGluR-induced release of Ca++ from intracellular stores and is prevented by estradiol

Hypoxic/ischemic (HI) brain injury in newborn full-term and premature infants is a common and pervasive source of life time disabilities in cognitive and locomotor function. In the adult, HI induces glutamate release and excitotoxic cell death dependent on NMDA receptor activation. In animal models of the premature human infant, glutamate is also released following HI, but neurons are largely insensitive to NMDA or AMPA/kainic acid (KA) receptor-mediated damage. Using primary cultured hippocampal neurons we have determined that glutamate increases intracellular calcium much more than kainic acid. Moreover, glutamate induces cell death by activating Type I metabotropic glutamate receptors (mGluRs). Pretreatment of neurons with the gonadal steroid estradiol reduces the level of the Type I metabotropic glutamate receptors and completely prevents cell death, suggesting a novel therapeutic approach to excitotoxic brain damage in the neonate.

Hippocampal mossy fiber sprouting and elevated trkB receptor expression following systemic administration of low dose domoic acid during neonatal development

We have previously reported that serial systemic injections of low-dose (subconvulsive) domoic acid (DOM) during early postnatal development produces changes in both behavior and hippocampal cytoarchitecture in aged rats (17 months) that are similar to those seen in existing animal models of temporal lobe epilepsy. Herein we report further hippocampal changes, consisting of mossy fiber sprouting and associated changes in the trkB receptor population in young adult (3 months) rats, and further, report that these changes show regional variation throughout the septo-temporal axis of the hippocampus. Groups of Sprague Dawley rat pups were injected daily from postnatal day 8-14 with either saline (n = 23) or 20 microg/kg DOM (n = 25), tested for key indicators of neonatal neurobehavioral development, and then left undisturbed until approximately 90 days of age, at which time brain tissue was removed, hippocampi were dissected, fixed and processed using either Timm's stain to visualize hippocampal mossy fiber sprouting (MFS) or trkB immunohistochemistry to visualize full length trkB receptors. Multiple sections from dorsal, mid, and ventral hippocampus were analyzed separately and all measures were conducted using image analysis software. The results indicate significant increases in MFS in the inner molecular layer in treated animals with corresponding changes in trkB receptor density. Further we identified significant increases in trkB receptor density in the hilus of the dentate gyrus and area CA3 and report increased mossy fiber terminal density in the stratum lucidum in treated rats. The magnitude of these changes differed between sections from dorsal, mid, and ventral hippocampus. We conclude that low dose neonatal DOM produces cytoarchitectural changes indicative of abnormal development and/or synaptic plasticity that are progressive with age and show regional variation within the hippocampal formation.

Estradiol modulation of kainic acid-induced calcium elevation in neonatal hippocampal neurons

The developing hippocampus of both males and females is exposed to high levels of the gonadal steroid estradiol. The impact of this estradiol exposure on developing hippocampal neurons is essentially unknown. In the rat, the newborn hippocampus is relatively insensitive to excitotoxic brain injury, which in adults is associated with the release of amino acids, in particular glutamate, resulting in a significant increase in intracellular calcium and eventual cell death. We have shown previously in the rat that administration of the glutamate agonist, kainic acid (KA), on the day of birth results in limited hippocampal damage, which is ameliorated by treatment with the gonadal steroid, estradiol. We now show that KA induces an increase in intracellular calcium through L-type voltage-sensitive calcium channels early in development and, later in development, through polyamine-sensitive alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors with a modest increase through N-methyl-D-aspartate receptors. Pretreatment with the gonadal steroid, estradiol, decreases the percentage of neurons responding to KA and decreases the peak amplitude of the calcium transient early in development but has no effect later in development. Taken together, these data suggest that there is a developmental shift in the route of KA-induced intracellular calcium and estradiol modulates KA-induced intracellular calcium to a time restricted to early development, but whether this is the basis of the neuroprotective effect of estradiol remains to be determined.

Intracerebroventricular kainic acid administration to neonatal rats alters interneuron development in the hippocampus

The effects of neonatal exposure to excitotoxins on the development of interneurons have not been well characterized, but may be relevant to the pathogenesis of neuropsychiatric disorders. In this study, the excitotoxin, kainic acid (KA) was administered to rats at postnatal day 7 (P7) by intracerebroventricular (i.c.v.) infusion. At P14, P25, P40 and P60, Nissl staining and immunohistochemical studies with the interneuron markers, glutamic acid decarboxylase (GAD-67), calbindin-D28k (CB) and parvalbumin (PV) were performed in the hippocampus. In control animals, the total number of interneurons, as well as the number of interneurons stained with GAD-67, CB and PV, was nearly constant from P14 through P60. In KA-treated rats, Nissl staining, GAD-67 staining, and CB staining revealed a progressive decline in the overall number of interneurons in the CA1 and CA3 subfields from P14 to P60. In contrast, PV staining in KA-treated rats showed initial decreases in the number of interneurons in the CA1 and CA3 subfields at P14 followed by increases that approached control levels by P60. These results suggest that, in general, early exposure to the excitotoxin KA decreases the number of hippocampal interneurons, but has a more variable effect on the specific population of interneurons labeled by PV. The functional impact of these changes may be relevant to the pathogenesis of neuropsychiatric disorders, such as schizophrenia.

Sex differences in response to kainic acid and estradiol in the hippocampus of newborn rats

Premature and full-term human infants are at considerable risk of excitotoxic-mediated brain damage due to hypoxia-ischemia, infection or other trauma. Glutamate receptor activation is a major source of excitoxicity in the adult and developing brain, and the hippocampus is particularly vulnerable to damage. The seven-day-old rat is a widely used model of pediatric brain damage, in large part due to the relative insensitivity of the brain to exogenous glutamate treatment prior to this age. We have reexamined the possible role of glutamate in pediatric brain damage in the newborn rat using kainic acid treatment and attending to the sex of the animal as well as the effects of pretreatment with the gonadal steroid estradiol. Consistent with previous studies, we found no evidence of damage 7 days posttreatment in the CA1 region of the hippocampus in males or females. There was also little to no damage in the CA2/3 or dentate gyrus of males. In females, however, kainic-acid treatment induced substantial damage in the dentate gyrus and moderate damage in CA2/3, as assessed by neuron number and regional volume. Pretreatment with estradiol was protective against kainic acid-induced damage in females but was permissive for damage in the dentate gyrus of males. Estradiol treatment in the absence of kainic acid treatment was also neuroprotective in females in that it increased neuron number and volume throughout the hippocampal formation, suggesting that the basis of the sex difference observed in hippocampal volume was hormonally mediated. There was no effect of exogenous estradiol given to males in the absence of kainic acid. We conclude that the newborn female rat brain, but not the male, is sensitive to glutamate-mediated toxicity and that gonadal steroids play a complex role in both naturally occurring sex differences in hippocampal volume and response to injury.

Hippocampal neurogenesis follows kainic acid-induced apoptosis in neonatal rats

The effects of kainic acid (KA) on neurogenesis in the developing rat hippocampus were investigated. Neonatal [postnatal day (P) 7] rats received a single bilateral intracerebroventricular infusion of KA (50 nmol in 1.0 microl) or vehicle. At P14, P25, P40, and P60, the spatial and temporal relationships between the neurodegeneration and neurogenesis induced by KA were explored using terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick end labeling (TUNEL) to detect the dying cells and 5-bromodeoxyuridine (BrdU) to label newly generated cells. There was progressive loss of neurons in the cornu ammonis (CA) 1 and CA3 subfields of the hippocampus at all time points in KA-treated rats. TUNEL staining identified dying cells at P14 through P60, mainly in the CA3 subfield. The number of TUNEL-positive cells decreased with age. Neurogenesis also was observed in the KA-treated hippocampus. The number of BrdU-positive cells in the dentate gyrus was significantly decreased at P14, when the number of TUNEL-positive cells is highest. However, at later time points (P40 and P60) the number of BrdU-positive cells in the dentate gyrus was significantly increased. In addition, the number of BrdU-positive cells was increased in the CA3 subfield at P40 and P60 in KA-treated rats. A substantial proportion (40%) of the newly generated cells in CA3 also expressed markers of immature and mature neurons (class III beta-tubulin and neuronal nuclei). Newly generated cells in the CA3 subfield only rarely expressed glial markers (8%). These results suggest that a single exposure to KA at P7 has both immediate (inhibition) and delayed (stimulation) effects on neurogenesis within the dentate gyrus of developing rats. KA administration resulted in both neuronal apoptosis and neurogenesis within the CA3 subfield, suggesting that the purpose of neurogenesis in the CA3 is to replace neurons lost to apoptosis.

Immediate and delayed hippocampal neuronal loss induced by kainic acid during early postnatal development in the rat

The degree to which the neonatal hippocampus is resistant to the effects of excitotoxins, such as kainic acid (KA) remains uncertain. Previously, we showed delayed loss of hippocampal neurons during pubescence in neonatal rats subjected to intracerebroventricular (i.c.v.) KA administration (10 nmol) at postnatal day 7 (P7). To further characterize the time course as well as the underlying mechanisms of this neuronal loss, we administered i.c.v. KA (10 or 50 nmol) to P7 preweanling rats. Brain sections were then examined at several neurodevelopmental time points (i.e., P8, P14, P25, P40, P60 and P75) using thionin staining and three-dimensional, non-biased cell counting to assess neuronal loss, and immunohistochemistry and electron microscopy to search for evidence of necrosis and apoptosis. Dose-dependent acute neuronal loss was observed at P8-P14 in hippocampal subfields CA3a and CA3c. Transient heat shock protein (HSP-70) immunostaining accompanied this acute neuronal loss. Progressive neuronal loss then continued in CA3 until P75, but without concomitant HSP-70 immunostaining. Progressive neuronal cell loss was also observed in the CA1 subfield of the hippocampus beginning at pubescence (i.e., P40) and continuing until P75. The appearance of TUNEL-positive hippocampal neurons accompanied the delayed neuronal loss in both CA3 and CA1 and electron micrographs confirmed that neurons in these subfields were undergoing apoptosis. KA administration (i.c.v.) to preweanling rats caused both immediate and delayed damage to hippocampal neurons. The effect of KA was dose-dependent, and the delayed neuronal damage occurred through an apoptosis-mediated mechanism. These findings may be relevant to the pathogenesis of some neuropsychiatric disorders, where early CNS injury is not apparent until the onset of clinical symptoms in young adulthood.

Ion Dependence and Receptor Mediation of Glutamate Toxicity in the Immature Rat Hippocampal Slice

Glutamate (glu) is a major excitatory transmitter and a toxin in the brain. In the present study, the immature rat hippocampal slice was used to determine the morphology, topography, ionic mediation and receptor specificity of glu toxicity. Slices were exposed to glu for 30 min, and the damage was evaluated after 3 h of recovery in regular medium. The effects on glu toxicity of changes of [Ca2+], [Cl-] and [Na+] were determined. The receptor preference of glu was assessed by using the N-methyl-D-aspartate (NMDA) antagonist MK-801 and the kainate (KA)/quisqualate (QA) antagonist DNQX, alone or in combination. Further, to see whether glu produces cytotoxicity via osmolysis, the effects of hyperosmolal sucrose on glu toxicity were studied. Glu toxicity was similar to the previously described NMDA toxicity with regard to cytopathology, but differed in some aspects from that caused by KA and QA. The severity of the lesion was determined by the proximity of neurons to the incubation fluid, probably as a consequence of cellular accumulation of the amino acid. Omission of Ca2+ abolished glu toxicity in all neurons except the granule cells of the outer blade. This population was completely protected when Ca2+ was omitted and [Cl-] was reduced. Elevation of [Ca2+] markedly aggravated the lesion caused by glu. Substitution of isethionate for Cl- worsened the glu-induced damage, whilst the amino acid produced qualitatively different neuropathology when choline substituted for Na+. Apparently glu did not damage hippocampal nerve cells through an osmolytic mechanism as medium supplemented with 100 mM sucrose increased the toxicity of glu. Since the lesion produced by glu was more widespread in the presence of high [Ca2+], the effects of receptor antagonists were studied under this condition. MK-801 inhibited glu toxicity whereas DNQX had no effect. Combination of MK-801 and DNQX did not offer better protection than did MK-801 alone. The results suggest that Ca2+ is the main (but not single) determinant of glu toxicity in the immature hippocampal slice. The ionic requirements of glu neurotoxicity are identical to those of NMDA, but differ from those of KA and QA. The notion that glu is a selective NMDA agonist in the present model was confirmed by the protection of MK-801, and by the lack of an effect of DNQX. This is the first report demonstrating that the toxicity of glu is mediated by NMDA receptors in brain tissue which has developed normally. The findings indicate that specific blockade of NMDA receptors may be the most rational strategy in the prevention of glu-related neuronal death occurring in certain neurological anomalies.

Methods for inducing neuronal loss in preweanling rats using intracerebroventricular infusion of kainic acid

Excitotoxins, such as kainic acid (KA), have been shown to produce neuronal degeneration in the adult rat brain. While preweanling rats have been shown to be relatively resistant to the neurotoxicity of lower doses of KA, the presence of neuronal loss at higher doses (of KA) has only begun to be investigated in such animals. A reliable method of producing neuronal loss in preweanling rats is to administer nmol concentrations of KA via intracerebroventricular (i.c.v.) injections on postnatal day 7 (P7). Using a three-dimensional, non-biased cell counting technique, we have shown that neuronal loss is observed in the CA3 subfield of the hippocampal formation at P45 and P75. Further, immunohistochemical studies of markers for cell death may be useful to examine the types of cellular processes associated with such neuronal loss. Data from our own experiments suggest the activation of immediate-early genes in the neuronal loss produced by KA administration at P7. This developmental animal model of neuronal loss may be useful in studying neurodevelopmental disorders where the onset of symptoms or cognitive deficits is thought to follow an early developmental insult.

Nonconvulsive Kainic Acid-Induced Seizures Elicit Age-Dependent Impairment of Memory for the Elevated Plus-Maze

The goal of this study was to evaluate changes in spatial learning in adult and immature rats during and after nonconvulsive seizures. An elevated plus-maze was used in 18- and 25-day-old and adult rats. Kainic acid (KA 6 mg/kg) was administered 60 minutes before the first exposure (Experiment 1) or after a 3-day pretraining (Experiment 2, only adult rats). Animals were retested three times with 24-hour intervals. EEG activity was monitored in 18-day-old rats. KA prolonged the transfer latency (TL) in all age groups. In the youngest group the TL was prolonged 24 hours after KA when epileptic EEG graphoelements were still registered. In both older groups, prolonged TL was measured only 60 minutes after KA. In the pretrained adults, significantly prolonged TLs persisted for 24 hours after KA. KA changed the performance of adult and immature rats in the elevated plus maze not only during nonconvulsive seizures but also 24 hours later.

Delayed neuronal loss after administration of intracerebroventricular kainic acid to preweanling rats

Excitotoxins, such as kainic acid (KA), have been shown to produce both immediate and delayed neuronal degeneration in adult rat brain. While preweanling rats have been shown to be resistant to the immediate neurotoxicity of KA, the presence of delayed neuronal loss has not been investigated in such animals. To determine whether intracerebroventricular (i.c.v.) administration of KA would produce delayed neuronal loss, preweanling rats were administered 5 nmol or 10 nmol KA i.c.v. on postnatal day 7 (P7) and then examined at P14, P45, and P75. Using three-dimensional, non-biased cell counting, neuronal loss was observed in the CA3 subfield of the hippocampal formation at P45 and P75 in animals administered 10 nmol KA, as compared to animals administered 5 nmol KA or artificial cerebrospinal fluid. Further, the amount of immunoreactivity to jun, the protein product of the immediate early gene, c-jun, adjusted for the number of remaining neurons was increased in the same brain areas. Antibody labeling of inducible heat shock protein and glial fibrillary acidic protein was not similarly increased in animals administered i.c.v. KA. The data suggest that while i.c.v. KA does not produce immediate neuronal loss in preweanling rats, the hippocampus is altered so that neuronal loss occurs after a delay, perhaps through apoptosis. These findings may be relevant to the pathogenesis of neuropsychiatric disorders, such as schizophrenia, that are characterized by early limbic-cortical deficits but onset of illness in young adulthood.

Changes in NADPH-diaphorase positivity induced by status epilepticus in allocortical structures of the immature rat brain

The distribution and time course of changes of nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-d) positivity were studied in immature rats (12 and 25 days old) surviving motor status epilepticus (SE) induced by a high dose of pilocarpine. Motor SE characterized by continuous convulsions was interrupted after 2 h by an injection of clonazepam (0.5 mg/kg or 1 mg/kg in 12- and 25-day-old rats, respectively) in order to reduce mortality. Correlation between electroencephalographic and behavioral seizure activity was confirmed using animals with electrodes implanted bilaterally in the hippocampus and sensorimotor cortex. Brains were examined 2, 6, 13, and 21 days after motor SE using NADPH-diaphorase histochemistry. Two types of changes were found in both age groups: (a) decrease of NADPH-d positivity occurred in both neuropil and cell bodies in piriform, periamygdalar, and entorhinal cortices; and (b) NADPH-d positivity was induced in the cell bodies in the hippocampal fields CA1/2, CA3, and dentate gyrus. These changes were more intense in animals surviving SE at postnatal day 25 than in younger age group, and they peaked 2 days after SE. The changes observed after SE disappeared quickly in 12-day-old rat pups, where only moderate changes could be observed in piriform, periamygdalar, and entorhinal cortices 6 days after SE, whereas the changes in the histochemical positivity persisted in older animals even 21 days after SE.

Residual granule cells can maintain susceptibility of CA3 pyramidal cells to kainate-induced epileptiform discharges

Slices of adult rat hippocampus made from animals exposed neonatally to X-ray irradiation were studied with electrophysiological techniques. A single dose of 6 Gy irradiation of the pup's head significantly but unevenly reduced the number of granule cells in the dentate gyrus. A larger reduction was detected in the septal than in the temporal hippocampus. The number of hilar cells decreased also. Effects of irradiation were confirmed with histological techniques. Field potential responses to mossy fiber stimulation in the pyramidal layer of the CA3 subfield was smaller in irradiated than in normal rats. Superfusion of the slices with kainic acid (KA, 300-500 nM) induced spontaneously recurrent paroxysmal activity (SRPA) in about 40% of irradiated slices in contrast with nearly 90% of slices cut from nonirradiated rats. Intracellular recordings from CA3 pyramidal cells in irradiated rats revealed recurrent bursts of action potentials on top of large depolarizing waves after KA application. Cells impaled in slices from the septal half of hippocampus of irradiated rats failed more often to respond with bursts to KA than cells in slices cut from the temporal half. Removal of mossy fiber input can therefore reduce KA induced hyperexcitability of CA3 pyramidal cells, but quantitative factors such as proportional loss of granule and hilar cells may explain the considerable differences found among cells and slices. Removal of 80% of granule cells reduces hyperexcitability consistently, while SRPA can be found in slices where as much as 50% of granule cells are missing. Intracellular findings suggest that failures of detection of SRPA following KA application to hippocampal slices of irradiated rats does not necessarily mean that CA3 pyramidal cells are no longer responding to KA with epileptiform bursting.

Convulsant action of D,L-homocysteic acid and its stereoisomers in immature rats

PURPOSE

We wished to characterize the convulsant effect of homocysteic acid (HCA) in developing rats.

METHODS

Seizures were induced in 7-, 12-, 18-, and 25-day-old rats by intraperitoneal (i.p.) administration of D,L-HCA and in 12-day-old rats by i.p. injection of L- and D-stereoisomers of HCA. The animals were observed for 30 min after injection. The incidence, latencies, pattern of motor seizures, and all behavioral phenomena were noted. Fifty percent convulsant dose (CD50) values were calculated by probit analysis. Electrocorticograms (ECoG) were recorded after injection.

RESULTS

HCA did not elicit minimal clonic seizures whereas generalized tonic-clonic seizures (GTCS) occurred in all the age groups studied. Flexion (emprosthotonic) convulsions occurred to postnatal day 18. ECoG recordings exhibited delta activity in younger pups and sharp graphoelements in older pups, but electroclinical correlation was poor. Young animals were more sensitive to the convulsant effect of D,L-HCA. In addition, D-HCA was significantly more effective than L-HCA in inducing both flexion and generalized seizures.

CONCLUSIONS

Our data clearly indicate that seizures induced by HCA differ from those evoked by homocysteine. There are no qualitative differences in the motor pattern of seizures induced by the two stereoisomers of HCA, but marked differences were apparent in the very first signs of their action. These differences might be due to interaction with different glutamate receptor subtypes.

Epilepsy in the developing brain: lessons from the laboratory and clinic

Children with epilepsy present unique challenges to the clinician. In addition to having differences in clinical and EEG phenomena, children differ from adults in regard to etiological factors, response to antiepileptic drugs (AEDs), and outcome. It is now recognized that the immature brain also differs from the mature brain in the basic mechanisms of epileptogenesis and propagation of seizures. The immature brain is more prone to seizures due to an imbalance between excitation and inhibition. gamma-Aminobutyric acid (GABA), the major CNS inhibitory neurotransmitter in the mature brain, can lead to depolarization in the hippocampal CA3 region in very young rats. There are also age-related differences in response to GABA agonists and antagonists in the substantia nigra, a structure important in the propagation of seizures. These age-related differences in response to GABAergic agents provide further evidence that the pathophysiology of seizures in the immature brain differs from that in the mature brain. Although prolonged seizures can cause brain damage at any age, the extent of brain damage after prolonged seizures is highly age dependent. Far less histological damage and fewer disturbances in cognition result from prolonged seizures in the immature brain than from seizures of similar duration and intensity in mature animals. However, detrimental effects of AEDs may be greater in the immature brain, than in the mature brain. These lessons from the animal laboratory raise questions about the appropriateness of current therapeutic approaches to childhood seizure disorders.

Age-dependent effects of glutamate toxicity in the hippocampus

While prolonged seizures can cause brain damage at any age, the extent of brain damage following prolonged seizures is highly age-dependent. Seizures in the immature brain are followed by far less histological damage than seizures of similar duration and intensity in mature animals. The reasons for this age-related phenomenon are unclear. Seizure-induced cell death may be due to the neurotoxic effects of excessive glutamate release, we tested the hypothesis that the immature brain is less vulnerable to glutamate-induced neurotoxicity than the mature brain. We administered equal amounts of glutamate (0.5 mumol in 1.0 microliter) unilaterally into the CA1 subfield of the hippocampus of rats at postnatal (P) days 10, 20, 30, and 60. Equal volumes of saline were injected in the contralateral hippocampus. Rats were killed 7 days later and their brains were examined for hippocampal cell loss. The size of the resultant hippocampal lesion was highly age-dependent. Minimal cell loss was noted in the P10 rats, lesions in the P20 rats were smaller than those at P30 and P60, which were similar in extent. This study demonstrates that the extent of glutamate neurotoxicity in the hippocampus is highly age-dependent, with immature hippocampi relatively resistant to glutamate-induced cell death.

Dexamethasone potentiates NMDA receptor-mediated neuronal injury in the postnatal rat

The present study investigated the effect of a synthetic glucocorticoid, dexamethasone, on excitatory amino acid receptor-mediated neurotoxicity in the 7-day-old rat. Pretreatment with dexamethasone (0.7 mg/kg i.p.) 1 h prior to unilateral intrastriatal injection of excitotoxin enhanced damage resulting from N-methyl-D-aspartate (NMDA), but not alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA), or kainate receptor activation. The glucocorticoid-induced enhancement of NMDA toxicity was dose dependent. The time of dexamethasone administration appeared critical since only treatment 1 h prior to, but not 24 h prior to, simultaneously with, or 1 h after NMDA injection, affected toxicity. The administration of the adrenal mineralocorticoid aldosterone, or the phospholipase A2 inhibitor mepacrine, did not affect excitotoxicity. Quantitative receptor autoradiography was performed to assess the effect of dexamethasone on NMDA-sensitive [3H]glutamate receptor binding. Neither pretreatment in vivo nor the addition of dexamethasone in vitro affected NMDA-sensitive binding in the striatum. Possible explanations for these observations are discussed.

Delayed effects of neonatal hippocampal damage on haloperidol-induced catalepsy and apomorphine-induced stereotypic behaviors in the rat

The developmental effects of neonatal excitotoxic ventral hippocampal (VH) damage on behaviors related to dopaminergic (DA) transmission in the basal ganglia were investigated in the rat. Ibotenic acid (in Lesion) or artificial cerebrospinal fluid (in Sham) was infused into the VH of 7-day-old (PD7) rat pups. Haloperidol-induced (1 mg/kg, i.p.) catalepsy and apomorphine-induced (0.75 mg/kg, s.c.) stereotypic behaviors as well as locomotion were assessed in Sham and Lesion rats prior to (PD35) and after puberty (PD56). On PD35, Lesion and Sham animals did not differ in induced catalepsy or stereotypy. On PD56, however, Lesion animals were less cataleptic following haloperidol injection and manifested supersensitivity to apomorphine as compared to Sham rats. At both, PD35 and PD56, locomotor activity after apomorphine was significantly increased in Lesion animals as compared with controls. These results indicate that the neonatal excitotoxic VH lesion results in a unique time-dependent pattern of behavioral changes related to striatal DA transmission. Moreover, the response to apomorphine differs qualitatively from that previously reported after the analogous lesion induced in adult animals in which stereotypy was reduced. These findings suggest that early hippocampal deafferentation affects the development of other brain regions, such as the medial prefrontal cortex, that are also involved in the regulation of striatal DA function.

Action of antiepileptic drugs against kainic acid-induced seizures and automatisms during ontogenesis in rats

Kainic acid (KA 4-14 mg/kg) administered intraperitoneally (i.p.) produces automatisms (scratching until third postnatal week, "wet dog" shakes thereafter), and clonic and tonic-clonic seizures in rats aged 7, 12, 18, 25, and 90 days. Administration of carbamazepine (CBZ) i.p. (25 or 50 mg/kg), phenobarbital (PB 20-80 mg/kg), clonazepam (CZP 0.2 or 1 mg/kg), or valproate (VPA 200 mg/kg) influenced neither incidence nor latency of automatisms. Clonic seizures that are regularly observed after the third postnatal week in controls were either abolished or substantially suppressed by any of the aforementioned antiepileptic drugs (AEDs). Tonic-clonic seizures observed in the first 3 postnatal weeks were suppressed only by solvent [including propyleneglycol (PEG), ethanol, and water]; the effect of AEDs on tonic-clonic seizures was proconvulsant instead. The automatisms were most resistant to AED therapy. These results induce some doubts about the adequacy of the KA model for identifying AEDs effective against complex partial seizures, but forthcoming AEDs that suppress automatisms in the KA rat model might also be active against human complex partial seizures.

Susceptibility of brain to AMPA induced excitotoxicity transiently peaks during early postnatal development

The excitatory and excitotoxic actions of the endogenous excitatory amino acid (EAA) neurotransmitter, glutamate, are mediated by activation of three common subtypes of EAA receptors: N-methyl-D-aspartate (NMDA), alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA)/quisqualate and kainate receptors. EAA neurotransmitter systems play a number of physiological roles in the regulation and organization of neural systems during development. However, excessive activation of this neurotransmitter system is also implicated in the pathophysiology of several forms of acute and chronic brain injury. In this study, the susceptibility of the developing rat brain to AMPA/quisqualate receptor mediated injury was examined at eight postnatal ages (1-90 days). The receptor agonists, AMPA (25 nmol) or quisqualate (100 nmol), were stereotaxically microinjected unilaterally into the anterior striatum. The severity of resulting brain injury was assessed 5 days later by comparison of reductions in regional cortical and striatal cross-sectional areas. Microinjection of AMPA (25 nmol) produced widespread unilateral forebrain injury in the intermediate postnatal period (days 5-28). The severity of injury resulting from microinjection of a fixed dose of AMPA (25 nmol) transiently exceeded the severity of injury in adults between PND 5-28 with peak sensitivity occurring near PND 10. At PND 1, microinjection of AMPA produced a 24.5 +/- 1.7% reduction in striatal cross-sectional area, which is similar to the response observed in adult animals, and the lesion was confined to the injection site. Susceptibility to AMPA toxicity increased 2-fold from PND 1 to PND 5. At PND 10, the age of maximal sensitivity, the excitotoxic reaction to AMPA extended throughout the entire cerebral hemisphere and the mean striatal cross-sectional area was reduced by 81.7 +/- 3.9%. With advancing postnatal age, the severity of injury progressively diminished and the lesion became confined to the injection site. The developmental pattern of sensitivity to AMPA toxicity in other brain regions differed although peak sensitivity consistently occurred near PND 10. Microinjection of quisqualate produced a developmental pattern of striatal susceptibility similar to AMPA although quisqualate was a considerable less potent neurotoxin. In additional experiments, the in vivo pharmacology of AMPA and quisqualate mediated brain injury was evaluated in a PND 7 rat model in order to determine the neurotoxic characteristics and specificity of these agonists in vivo. The severity of brain injury was assessed 5 days after intrastriatal excitotoxin injection by comparison of cerebral hemisphere weights.(ABSTRACT TRUNCATED AT 400 WORDS)

Differential expression of three glutamate receptor genes in developing rat brain: an in situ hybridization study

Non-N-methyl-D-aspartate glutamate receptors (GluRs) are encoded by a gene family, known members of which are designated GluR-1, -2, -3, -4, and -5. The present study examined the developmental pattern of GluR-1, -2, and -3 gene expression in rat brain. In situ hybridization revealed different spatial patterns throughout the brain for the cognate mRNAs at all ages examined, as well as different temporal patterns during development. In the adult all three mRNAs were expressed prominently in the pyramidal and granule layers of the hippocampus and in the Purkinje cell layer of the cerebellum, where detailed differences were apparent at the cellular level. In neocortex, GluR-2 mRNA exhibited prominent lamination and regional differences, which were less marked for GluR-1 and -3 mRNAs. In caudate-putamen GluR-2 mRNA was at high levels, but GluR-1 and -3 mRNAs were not. At early ages transcripts were transiently elevated relative to adult levels. GluR-1 mRNA reached peak expression in cortex at postnatal day 14 (P14) (225% of adult), in striatum at P4 (255% of adult), in hippocampus at P14 (195% of adult), and in cerebellum at P21 (150% of adult). GluR-3 exhibited more modest peaks in neocortex and hippocampus. In contrast, GluR-2 mRNA was at near adult levels throughout the first days of postnatal life and exhibited a peak only in cerebellum at P14 (168% of adult). The finding of differential developmental regulation of the GluR-1, -2, and -3 genes indicates that the receptors they encode may have different influences on synaptic plasticity, neuronal survival, and susceptibility to excitatory amino acid toxicity.

Glutamate-operated channels: developmentally early and mature forms arise by alternative splicing

The expression of two alternative splice variants, Flip and Flop, in mRNAs encoding the four AMPA-selective glutamate receptors (GluR-A, -B, -C, and -D) was studied in the developing brain by in situ hybridization. These receptors are expressed prominently before birth, and patterns of distribution for Flip versions remain largely invariant during postnatal brain development. In contrast, the Flop versions are expressed at low levels prior to postnatal day 8. Around this time, the expression of Flop mRNAs increases throughout the brain, reaching adult levels by postnatal day 14. Thus, receptors carrying the Flop module appear to participate in mature receptor forms.

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

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

Parallel development of excitotoxic vulnerability to N-methyl-D-aspartate and kainate in dispersed cultures of the rat cerebral cortex

The development of excitotoxic cell death caused by L-glutamate, N-methyl-D-aspartate, quinolinate and kainate was examined in dispersed primary cultures of the rat cerebral cortex. Cell death was evaluated by phase-contrast microscopy and quantified by the measurement of lactic dehydrogenase activity in the culture medium. Cells obtained from embryonic cerebral cortex on days 16-18 of pregnancy, and maintained in a serum-supplemented medium, started to respond to glutamate N-methyl-D-aspartate quinolinate and kainate by cell death on day 7 in vitro. The sensitivity to the neurotoxins increased rapidly, and in a similar fashion, during the second week and remained unchanged up to day 21. Our findings indicate that, unlike the cerebral cortex in situ, the sensitivity of cultured cortical cells to the cytotoxicity mediated by N-methyl-D-aspartate and kainate receptors develops in a nearly parallel fashion.

Magnesium sulphate subcutaneously injected protects against kainate-induced convulsions and neurodegeneration: in vivo study on the rat hippocampus

Kainate, an agonist of a unique subclass of glutamate receptors (kainate receptor), was injected intracerebroventricularly in rats to induce convulsive reactions and hippocampal damage in order to model glutamate-mediated brain injury. Rats treated with magnesium sulfate (subcutaneously injected, up to 600 mg/kg) were found to be protected from kainate neurotoxicity depending on the dose and time of application. Results were largely consistent with those obtained previously by using quinolinate as an excitotoxic N-methyl-D-aspartate-receptor agonist. Magnesium is discussed as being a natural and relatively safe therapeutic in cases of glutamate-induced (hypoxic, ischemic, traumatic, or convulsive) disorders of the brain.

Effects of MK-801, ketamine and alaptide on quinolinate models in the maturing hippocampus

The ability of the N-methyl-D-aspartate receptor antagonists, MK-801, ketamine and alaptide [a newly synthesized cyclo(1-amino-1-cyclopentane-carbonyl-L-alanyl) with protective properties in models of hypoxia], to prevent neuronal degeneration caused by intracerebroventricular application of quinolinic acid was investigated. Neurodegenerative effects of quinolinate in the hippocampal formation were found to increase with the degree of maturity of glutamatergic target structures. A protective potency of the N-methyl-D-aspartate receptor antagonists was observed at all developmental stages studied (12- and 30-day-old and adult rats). MK-801 showed the highest efficacy, alaptide the lowest. These findings suggest a parallelism in maturity of glutamatergic transmission processes as one prerequisite of quinolinate vulnerability and postnatal increases of target fields of the protectives. Application of MK-801 or ketamine after quinolinate injection intensified their protective effects when compared to simultaneous or preadministration. This observation is interpreted as indicating that quinolinate is a prompter of a delayed neurodegenerative process rather than acting immediately as a toxicant.

Excitatory amino acids in the developing brain: ontogeny, plasticity, and excitotoxicity

Besides their role as neurotransmitters, excitatory amino acids (EAAs) in the developing brain are crucially involved in plasticity and excitotoxicity which are modified by their distinct ontogeny. Along with incomplete neuritogenesis and synaptogenesis, presynaptic markers of the EAA system are immature in the developing brain; however, postsynaptic EAA system activities, particularly of the N-methyl-D-aspartate and quisqualate receptors, are transiently enhanced early in life. This transient enhancement is presumably beneficial to the immature brain because physiologic activation of the EAA system plays a critical role in plasticity of early learning and morphogenesis. At the same time, this transient hypersensitivity renders the immature brain vulnerable to pathologic excitation of the EAA system (excitotoxicity) as observed during neonatal hypoxia-ischemia.

Quinolinate neurotoxicity and glutamatergic structures

Neurotoxic properties of quinolinic acid following intracerebroventricular application were investigated in the hippocampal formation of 12- and 30-day-old rats. Quinolinic acid neurodegenerative potency was found to depend on the survival time, the dose applied and the developmental stage of the animal. Pretreatment with kynurenic acid and ketamine as well as the transection of the perforant path were noted to protect major parts of the hippocampal cell layers from quinolinic acid-induced degenerative effects. The results are interpreted in view of a putative dependence of quinolinic acid neurotoxicity on the presence of established synaptic, in particular glutamatergic, processes which play a major role in the hippocampal formation and mature during the first postnatal weeks. For comparison, we studied local effects of quinolinic acid on superior cervical and dorsal root ganglia in which glutamate inputs obviously do not occur; no signs of neuronal vulnerability were seen.

Immunohistochemical demonstration of glutamate dehydrogenase in the postnatally developing rat hippocampal formation and cerebellar cortex: comparison to activity staining

Distribution patterns of activity and immunohistochemical staining for glutamate dehydrogenase were compared during the postnatal development of rat hippocampal formation and cerebellar cortex. On postnatal day 5, dendritic layers of the hippocampal formation showed only a very weak enzyme activity. Similarly, when studied at the same age, the external granule cell layer and Purkinje cells of the cerebellar cortex exhibited a very faint and moderate staining, respectively. With advancing age, in both brain regions a marked postnatal increase in glutamate dehydrogenase activity occurred in neuropil area as glutamatergic structures matured. However, compared to activity staining, both brain regions of early postnatal stages showed a relatively high level of glutamate dehydrogenase-like immunoreactivity. In this case, the immunohistochemical staining of hippocampal dendritic layers and of the molecular layer of the cerebellar cortex was rather diffuse, being not very similar to parameters of the maturation of the respective glutamatergic structures. In contrast to the activity staining for the enzyme, the immunohistochemical labelling in adult rats revealed a selective predominance of immunoreactivity in astroglial cells from postnatal day 5 onwards. The Bergmann glia in the cerebellar cortex exhibited the strongest intensity of immunoreactivity. Generally, the patterns of immunoreactivity were found to depend on the fixation procedure adopted. Concluding from our results, glutamate dehydrogenase is demonstrable in glial and in neuronal cell elements as well. Therefore, it is recommended that activity staining and the immunohistochemical procedure be combined to study qualitative and quantitative aspects of glutamate dehydrogenase in nervous tissues.

Postnatal development of the excitatory amino acid system in visual cortex of the rat. Changes in ligand binding to NMDA, quisqualate and kainate receptors

The postnatal development of the ligand binding to N-methyl-D-aspartate (NMDA), quisqualate and kainate receptor sites was examined in whole homogenates of the visual cortex of rats, aged 2-360 days. As selective ligands, [3H]CPP (3-(2-carboxypyperazine-4-yl)-propyl-1-phosphonic acid, [3H]AMPA (RS-alpha-amino-3-hydroxy-5-methyl-isoxazole-4-propionic acid) and [3H]KA (kainic acid) were used, respectively. The binding of CPP was low in newborns, rapidly increased from the second postnatal week, reached its maximum between weeks 2 and 3, then slowly declined up to the age of 1 year. In contrast, the binding of AMPA and kainate was high perinatally, increased rapidly up to day 6 after birth to reach an early maximum value, then gradually decreased to adult values which were attained at an age of 3-4 weeks. These age-related changes were derived from alterations in the density of binding sites, which, in the case of AMPA, was accompanied by an increase in binding affinity. The results, compared with the developmental time-course of excitatory synapses, indicate that, in the immature cerebral cortex, NMDA receptors may be primarily involved in synaptic transmission, whereas quisqualate and kainate receptors may play some other (e.g. trophic) roles.

Physiological and pathophysiological roles of excitatory amino acids during central nervous system development

Recent studies suggest that excitatory amino acids (EAAs) have a wide variety of physiological and pathophysiological roles during central nervous system (CNS) development. In addition to participating in neuronal signal transduction, EAAs also exert trophic influences affecting neuronal survival, growth and differentiation during restricted developmental periods. EAAs also participate in the development and maintenance of neuronal circuitry and regulate several forms of activity-dependent synaptic plasticity such as LTP and segregation of converging retinal inputs to tectum and visual cortex. Pre- and post-synaptic markers of EAA pathways in brain undergo marked ontogenic changes. These markers are commonly overexpressed during development; periods of overproduction often coincide with times when synaptic plasticity is great and when appropriate neuronal connections are consolidated. The electrophysiological and biochemical properties of EAA receptors also undergo marked ontogenic changes. In addition to these physiological roles of EAAs, overactivation of EAA receptors may initiate a cascade of cellular events which produce neuronal injury and death. There is a unique developmental profile of susceptibility of the brain to excitotoxic injury mediated by activation of each of the EAA receptor subtypes. Overactivation of EAA receptors is implicated in the pathophysiology of brain injury in several clinical disorders to which the developing brain is susceptible, including hypoxia-ischemia, epilepsy, physical trauma and some rare genetic abnormalities of amino acid metabolism. Potential therapeutic approaches may be rationally devised based on recent information about the developmental regulation of EAA receptors and their involvement in the pathogenesis of these disorders.

The ontogeny of excitatory amino acid receptors in the rat forebrain--II. Kainic acid receptors

The ontogeny of [3H]kainic acid binding in rat forebrain was studied quantitatively using in vitro receptor autoradiography. Specific binding was detectable in ventral thalamus, hippocampus, striatum and olfactory bulb by postnatal day 1. In regions with high densities of receptors in adulthood, such as CA3, dentate gyrus and striatum, binding increased progressively across development peaking at postnatal day 21. In ventral thalamus and the inner lamina of the neocortex, [3H]kainic acid binding was high in the first three postnatal weeks and relatively low thereafter. Saturation studies performed on adults and 14-day-old animals suggest differences in both the affinity and the maximal binding capacity contributed to the observed developmental changes in binding of [3H]kainic acid.

High-affinity glutamine uptake of the rat hippocampus during postnatal development: a quantitative autoradiographic study

Glutamine uptake into hippocampal slices of the rat was investigated autoradiographically. The characteristics of registered [14C]glutamine uptake such as the incubation with the radiolabelled amino acid at a concentration of 3.5 mumol/l, sodium dependency, the distribution pattern of radioactive material, and the postnatal development of uptake capacity are comparable with those of high-affinity uptake of glutamate. Densitometric evaluation of grain density over hippocampal layers exhibited a marked enhancement of uptake capacity in the neuropil areas during the first postnatal weeks. In the strata oriens and radiatum (CA1) radiolabelling increased from day 2 to 25 by about 390 and 410%, in the strata oriens and lacunosum-moleculare of CA3 by about 350 and 375%, respectively. In contrast, the rise in the accumulation rate in cell body layers was negligible. The temporal and topographical profiles of glutamine uptake in the hippocampal neuropil correlated with those of the activity of phosphate-activated glutaminase and parameters of maturation of the glutamatergic transmission system which have fairly similar time characteristics, suggesting a mutually causative relationship of all these factors.

The ontogeny of excitatory amino acid receptors in rat forebrain--I. N-methyl-D-aspartate and quisqualate receptors

The ontogeny of radioligand binding to N-methyl-D-aspartate and quisqualate receptors in rat forebrain was studied quantitatively using in vitro receptor autoradiography. Specific binding to both receptors could be detected by postnatal day 1 in hippocampus and striatum. The adult pattern of binding to N-methyl-D-aspartate receptors emerged by postnatal day 14 with high densities of binding in CA1 (stratum oriens and stratum radiatum), dentate gyrus (molecular layer) and striatum (caudate-putamen). Binding to the outer laminae of frontal cortex was as much as 45% above adult levels during development. Binding of [3H]amino-3-hydroxy-5-methylisoxazole-4-propionic acid to quisqualate receptors showed a similar overshoot during development, but also manifested a unique distribution with CA3 and medial aspects of the amygdala exhibiting transient, intense labeling. Homogenate binding studies with [3H]amino-3-hydroxy-5-methylisoxazole-4-propionic acid demonstrated a 73% increase in quisqualate receptors in whole brain at postnatal day 21 compared with adult levels. The selectivity of excitatory amino acid binding to the quisqualate site in development was similar to the selectivity in adult brain. These data taken with other recent reports, suggest that quisqualate receptors may have a role in development distinct from their function in the adult brain.

Neurotoxicity of excitatory amino acid receptor agonists in young rat hippocampal slices

Hippocampal slices from young (8-day-old) rats were evaluated as a model for investigating the mechanisms underlying the neurotoxic action of excitatory amino acid receptor agonists. The slices were exposed to the agonists for up to 30 min and were then postincubated for 90 min in order to allow irreversibly damaged cells to become visibly necrotic. Under control conditions (greater than or equal to 3 h incubation) all regions of the hippocampus and dentate gyrus displayed good preservation. Exposure of the slices to N-methyl-D-aspartate (NMDA) resulted in widespread, oedematous necrosis of all neuronal types (except undifferentiated granule cells) which was maximal after 20 min exposure to a concentration of 100 microM. With 30 min exposure, the EC50 for NMDA was 30 microM; 10 min exposure to NMDA at a concentration of 100 microM was sufficient to destroy 50% of the neurones. Quisqualate produced a degeneration of most (98%) of the CA3 neurones, a proportion (65%) of CA1 neurons and some (25%) of the dentate granule cells. The occurrence of "dark cell degeneration" was prevalent. Half maximal effects on CA3 neurones were estimated to be produced by a concentration of 15 microM (with 30 min exposure) or by 8 min exposure (at 100 microM concentration). Incubation of the slices with kainate (100 microM for 30 min) did not cause widespread damage but led to the necrosis of a small population of cells scattered in all regions of the hippocampus and dentate gyrus. The patterns of toxicity of the different agonists resemble closely those found after their administration in vivo. It is suggested that the hippocampal slices provide a valuable new model system for studying excitatory amino acid toxicity.

Prenatal ethanol exposure decreases hippocampal 3H-vinylidene kainic acid binding in 45-day-old rats

The effect of prenatal ethanol exposure on the kainate-sensitive subtype of glutamate receptor binding sites was studied using in vitro 3H-vinylidene kainic acid (VKA) autoradiography. Pregnant Sprague-Dawley rats were fed a liquid diet containing either 3.35% or 6.7% ethanol throughout gestation. Pair-fed dams received isocalorically matched liquid diets and a lab chow ad lib group served as control for paired feeding. At 45 days of age, the offspring were sacrificed and their brains analyzed for specific 3H-VKA binding. Compared to pair-fed controls, specific 3H-VKA binding was reduced by 13% to 32% in dorsal and ventral hippocampal CA3 stratum lucidum, entorhinal cortex and cerebellum of 45-day-old rats whose mothers consumed either 3.35% or 6.7% ethanol diets. The binding site reductions were statistically significant only in the ventral hippocampal formation and entorhinal cortex of the 3.35% ethanol diet group rats. Saturation of binding studies in the ventral hippocampal formation of 3.35% ethanol rats indicated that the decrease in specific 3H-VKA binding was due to a decrease in the total number of binding sites. Given the excitatory effect of kainic acid on the spontaneous firing rate of hippocampal CA3 pyramidal neurons, the reduction of kainate-sensitive glutamate binding in this region is consistent with the electrophysiological observation of decreased spontaneous activity of CA3 pyramidal neurons in fetal alcohol rats.

Changes in the activity of gamma-glutamyl transpeptidase induced by kainic acid and surgical lesions of the hippocampal formation in young rats

To study possible functional involvement of gamma-glutamyl transpeptidase (GGT) in glutamate transmitter metabolism we lesioned putative glutamatergic structures of the rat hippocampal formation by intracerebroventricular (i.c.v.) injection of kainic acid (KA) or by surgical CA3 axotomy. Unilateral injection of KA into the left lateral cerebral ventricle of 30-day-old rats resulted in decreased GGT activity in hippocampal areas CA3, Ca1 ipsilaterally, and in the contralateral area CA1, four hours after the induction of the chemical lesion. Four days after the injection, the enzyme activity was decreased in all hippocampal areas with the exception of the contralateral dentate gyrus. Four days after bilateral i.c.v. injection of KA, lower GGT levels were found than was seen after bilateral surgical lesion of the CA3 pyramidal cell axons (Schaffer's collaterals). The surgical lesion was followed by a decrease of GGT only in the stratum pyramidale and stratum radiatum of area CA1. In contrast to the effects in 30-day-old rats, unilateral i.c.v. injection of KA on postnatal day 12 did not alter the GGT activity in any studied hippocampal area presumably because of incomplete maturation of structures required for KA vulnerability.

Histochemically demonstrable activity of phosphate-activated glutaminase in the postnatally developing rat hippocampus

Phosphate-activated glutaminase (PAG) mediating the conversion of glutamine to glutamate and ammonia, appears to be the major glutamate metabolizing enzyme in brain. The functional relevance of PAG in postnatally maturing glutamatergic/aspartatergic structures of the rat hippocampus was studied by means of quantitative enzyme histochemistry as an alternative to immunocytochemical techniques. The calibration of the histochemical PAG reaction as well as several control experiments for specificity were carried out to ensure reliability of findings. PAG activity increased markedly during the first weeks of life with a drastic rise between postnatal days 12 and 15. On the other hand, activity of NADH diaphorase involved in the histochemical PAG assay as an auxiliary enzyme, showed a different distribution pattern as well as a different developmental sequence with high levels early in ontogenesis. The topographical and temporal parallelisms of PAG activity to several other parameters which are putatively associated with postnatally maturing glutamatergic/aspartatergic transmission processes, mutually indicate their significance in such a functional context.

Effects of kainic acid on seizure susceptibility in the developing brain

The short and long-term effects of systemic administration of kainic acid to immature animals were studied in rats. Kainic acid was administered systemically to rats of 1-30 days of age. The rats were monitored for both behavioral and EEG changes. To study the effects of kainic acid on seizure susceptibility, status epilepticus was induced in 12-, 18-, and 27-day-old rats by systemic administration of kainic acid. Seizure susceptibility was assessed 3 days later using the kindling technique. In addition, another group of 27-day-old rats that developed status epilepticus following systemic administration of kainic acid were kindled as adults. Young rats (1 day of age) developed behavioral status epilepticus after kainic acid and ictal electroencephalographic changes were seen beginning at age 6 days. The 15- and 21-day-old rats kindled 3 days after kainic acid administration kindled at the same rate as controls. However, 30-day-old rats that received kainic acid at age 27 days kindled more quickly to stage-5 seizures than controls. Rats that received kainic acid at age 27 days and maintained until adulthood developed spontaneous recurrent seizures and kindled faster as adults than controls. These results demonstrate that the effect of kainic acid on seizure susceptibility is an age-dependent phenomenon.

High-affinity uptake of L-[3H]glutamate and D-[3H]aspartate during postnatal development of the hippocampal formation: a quantitative autoradiographic study

Quantitative autoradiography was used to determine the topographical and time patterns of L-[3H]glutamate and D-[3H]aspartate high-affinity uptake system in the hippocampal formation of the rat during postnatal development. Extended control experiments were performed to verify the specificity of labelling. For short incubation periods of 3-10 min, the data demonstrated a conspicuously low rate of glutamate accumulation in the hippocampal formation of newborn animals and a marked increase in labelling of hippocampal neuropil areas during the first weeks of postnatal life. Our autoradiographic data on developmental increase in glutamate high-affinity uptake levels are consistent, in terms of time and topography, in many ways with other parameters of maturation of glutamatergic and/or aspartatergic structures in the hippocampal formation.

The susceptibility of rats to pilocarpine-induced seizures is age-dependent

Behavioral, electroencephalographic and morphological changes induced by systemic administration of pilocarpine hydrochloride were studied in 3-90-day-old rats. Pilocarpine, 100, 200 and 380 mg/kg, presented a characteristic array of behavioral patterns in developing rats. Hyper- or hypoactivity, tremor, loss of postural control, scratching, head bobbing and myoclonic movements of the limbs dominated the behavior in 3-9-day-old rats. No overt motor seizures were observed in this age group. More intense behavioral signs evolving in some animals to limbic seizures and status epilepticus occurred when pilocarpine was administered in 12-day-old-rats. The electrographic activity in these animals progressed from low voltage spiking registered concurrently in the hippocampus and cortex during the first week of life into localized epileptic activity in the hippocampus, which spread to cortical recordings during the second week of life. No morphological alterations were detected in the brains of 3-12-day-old rats subjected to the action of pilocarpine, 100-380 mg/kg. The adult pattern of behavioral and electroencephalographic sequelae after pilocarpine was encountered in 15-21-day-old rats. Akinesia, tremor and head bobbing progressed in 15-21-day-old rats given pilocarpine, 100-380 mg/kg, to motor limbic seizures and status epilepticus. The lethal toxicity of pilocarpine reached 50% during the third week of life. This increased susceptibility to the convulsant action of pilocarpine was characterized by a shortened latency for behavioral and electrographic signs, and an increased severity of seizures relative to older and younger rats. In 15-21-day-old rats subjected to pilocarpine-induced convulsions high voltage fast activity superposed over hippocampal theta-rhythm, progressed into high voltage spiking and spread to cortical records. The electrographic activity became well synchronized and then developed into seizures and status epilepticus. Morphological analysis of frontal forebrain sections in 15-21-day-old rats which underwent status epilepticus after pilocarpine revealed no damage or an attenuated pattern of damage. In 15-21-day-old rats which presented epilepsy-related brain damage, morphological breakdown was seen in the hippocampus, amygdala, olfactory cortex, neocortex and certain thalamic nuclei. No damage was detected in the substantia nigra and lateral thalamic nucleus. An adult pattern of the damage to the brain, in terms of extent and topography, was present in 4-5-week-old rats.(ABSTRACT TRUNCATED AT 400 WORDS)

Intrahippocampal injection of kainic acid produces significant pyramidal cell loss in neonatal rats

Previous reports have indicated that pyramidal cells in the developing rat hippocampal formation are not destroyed by intraventricular or intraperitoneal administration of kainic acid. We examined the neurotoxic properties of kainic acid and ibotenic acid following intrahippocampal injection in neonatal rats and found significant pyramidal cell death following injection of 1.0 microgram kainic acid in 6, 7 and 9-day-old pups. At doses 2.5 or five times this amount, significant pyramidal cell loss was obtained in 5-day-old rats as well. The susceptibility of pyramidal neurons to kainic acid increased as a function of age. The developing hippocampus was considerably more vulnerable to ibotenic acid compared with kainic acid, in contrast to the order of potency reported in adult rats. The increased sensitivity of CA3 pyramidal cells parallels the development of the mossy fiber innervation to the dendrites of these cells supporting the twofold mechanism suggested by Coyle for kainic acid neurotoxicity; that is, a direct cytotoxic action via postsynaptic receptors as well as increased sensitivity due to the presence of excitatory inputs.

Histophotometric evaluation of glutamate dehydrogenase activity of the rat hippocampal formation during postnatal development, with special reference to the glutamate transmitter metabolism

Transmitter glutamate/aspartate synthesis is known to proceed along different metabolic pathways. In this light, the functional relevance of glutamate dehydrogenase in postnatally maturing glutamatergic/aspartatergic structures was studied by means of quantitative enzyme histochemistry. The basic requirements concerning the kinetics and calibration of the histochemical glutamate dehydrogenase reaction used were proved to be met in order to obtain valid quantitative data. The histochemically demonstrable activity of glutamate dehydrogenase (EC 1.4.1.3) in the hippocampal formation of the rat increased markedly during postnatal development. On day 30, the distribution pattern observed was similar to that in adult animals. While the enzyme activity rose within cell body layers from day 0 to day 30 by 240-285%, the increase in neuropil layers was found to be up to 830%. Maximum values were seen in the stratum lacunosum-moleculare of CA1 and CA3 and the stratum moleculare of the dentate fascia on day 30. Since the hippocampal neuropil is supposed to be copiously provided with glutamatergic (and aspartatergic?) structures which become functional in rats during the first weeks of postnatal life, the increase in enzyme activity is discussed to be primarily a consequence of maturing synaptic systems using glutamate and/or aspartate as transmitters.

In vitro neurotoxicity of excitatory acid analogues during cerebellar development

The neurotoxic effects of the selective excitatory amino acid receptor agonists, quisqualate, kainate and N-methyl-D-aspartate, were studied in slice preparations of cerebellum from rats at different stages of postnatal development. With increasing age, (i) Purkinje cells became more vulnerable to kainate and quisqualate but remained insensitive to N-methyl-D-aspartate (up to 300 microM); (ii) Golgi cells became more sensitive to kainate, quisqualate and N-methyl-D-aspartate; (iii) granule cells became more sensitive to kainate, less sensitive to N-methyl-D-aspartate and remained unaffected by quisqualate (up to 100 microM), and (iv) basket and stellate cells and, up to 14 days of age, neurones of the deep cerebellar nuclei, became more vulnerable to kainate and quisqualate, but their sensitivity to N-methyl-D-aspartate stayed the same. The neurotoxicity of N-methyl-D-aspartate, but not that of kainate in 8-day-old cerebellar slices was prevented by 2-amino-5-phosphonovaleric acid; tetrodotoxin did not affect the toxicity of the agonists in 8-day-old or adult slices. The results with kainate are consistent with other studies indicating an insensitivity of the immature brain to its neurotoxic effects, but suggest that this property is not a peculiarity of kainate. Alterations in excitatory potency can explain some of the observed developmental changes. However, other observations cannot readily be accounted for on the basis of either changes in excitatory potency, the functional maturation of cerebellar circuits, changes in synaptic density, or the developmental appearance of Ca2+ channels in susceptible cells, suggesting that additional factors play an important role in the neurotoxic effects of the excitants.

Extensive target cell loss during development results in mossy fibers in the regio superior (CA1) of the rat hippocampal formation

The axons of dentate granule cells (mossy fibers) have been reported to appear in the regio superior (CA1) of the rat hippocampal formation following destruction of the pyramidal cells in the regio inferior (CA3). We undertook the present experiments to confirm this finding and to determine the requirements for this dramatic neuronal rearrangement. We found that extensive (greater than 80%) loss of CA3 cells, as well as the presence of surviving CA1 neurons within a narrow period of development (postnatal days 3-5) is necessary, however apparently not sufficient, for the appearance of CA1 mossy fibers. That the absence of normal target cells during a restricted period of mossy fiber development will lead to their association with novel targets suggests that much of the specificity of this developing connection depends on the presence of normal targets during a critical period.

"Epileptic" brain damage is replicated qualitatively in the rat hippocampus by central injection of glutamate or aspartate but not by GABA or acetylcholine

Repeated intraventricular injection of the excitatory amino acids glutamate and aspartate for one hour produced morphologic changes in the hippocampus that were qualitatively identical to the acute and chronic changes seen in the brains of human epileptics and in experimental animals in which hippocampal seizure activity was induced by kainic acid or electrical stimulation of the perforant path. Light and electron microscopy revealed acute effects of glutamate and aspartate consisting of glial and dendritic swelling and neuronal soma necrosis ("dark cell degeneration"). Electron microscopy showed the focal dendritic swelling induced by glutamate or aspartate to be of the axon-sparing type with presynaptic terminals relatively unaffected. Four weeks after injection, irreversible neuron loss and reactive gliosis had occurred. The inhibitory amino acid gamma-aminobutyric acid caused acute glial swelling similar to that caused by glutamate and aspartate but did not produce neurotoxic effects, indicating that glial swelling may not be causally related to neuronal death but may be the result of amino acid uptake. The excitatory non-amino acid acetylcholine produced no direct, periventricular hippocampal damage or glial swelling but did produce dendritic swelling in the CA3 region innervated by the perforant path, presumably as a result of acetylcholine-induced seizure activity in this pathway. Glutamate and aspartate also caused glial and neuronal changes in other periventricular structures, e.g., septum, hypothalamus, caudate and habenula, as well as in the most dorsal portion of the cerebellum. Dendritic swelling induced by glutamate and aspartate in the cerebellar molecular layer was accompanied by acute necrosis of Purkinje cell somata. These results suggest that seizure-associated brain damage is initiated by excessive endogenous excitatory amino acid receptor activation.

Effects of short-term and prolonged aerogenic hypoxia on gamma-glutamyl transpeptidase activity in the brain, liver, and biological fluids of young rats

Posthypoxic fluctuations in the levels of two excitatory amino acids, glutamate and aspartate, may be related to changes in mechanism(s) which are responsible for their reuptake. As gamma-glutamyl transpeptidase (GGT) plays a role in mediating the uptake of glutamate and aspartate into various compartments of the brain, we studied changes in the activity of this enzyme in main regions of the brain in young and adult rats. We found a posthypoxic increase in bound GGT activity in some brain regions of 18-day-old animals after acute exposure, but no changes were observed after prolonged altitude hypoxia, with the exception of a decrease in cortical GGT activity. In contrast, acute hypoxia decreased GGT activity in the cortical capillaries to 59%, but prolonged hypoxic exposure was ineffective. However, the activity of soluble GGT in the cerebrospinal fluid of both groups of rats was several-times elevated in comparison with controls. At the same time, bound GGT activity was increased in the liver after acute or prolonged altitude hypoxia. The soluble GGT activity in plasma was only increased after prolonged exposure. Ninety days after prolonged hypoxic exposure the bound GGT activity was reduced in all brain regions to about 60-70% of controls (significantly higher in females than in males) as long-term developmental sequel from early postnatal hypoxia.