Endogenous potentials generated in the human hippocampal formation and amygdala by infrequent events.

Infrequent, attended, auditory and visual stimuli evoke large potentials in the human limbic system in tasks that usually evoke endogenous potentials at the scalp. The limbic potentials reverse polarity over small distances and correlate with unit discharges recorded by the same electrodes, indicating that they are locally generated.

Induced expression of NMDAR2 proteins and differential expression of NMDAR1 splice variants in dysplastic neurons of human epileptic neocortex.

Immunocytochemistry was used to study the expressions of glutamate receptor subunit proteins for NMDAR2A/B, NMDAR1 splice variants, and AMPA Glu-R2/3 in human brain resected for intractable epilepsy associated with cortical dysplasia. NMDAR2A/B intensely labeled dysplastic neurons showing staining in both the cell bodies and dendritic profiles. However, nondysplastic neurons were not immunoreactive to NMDAR2A/B. The antibody selective to NMDAR1 splice variants of NR1-1a. -1b, -2a, and -2b labeled dysplastic neurons, but few nondysplastic neurons. In contrast, the antibody to splice variants of NR1-1a, -1b, 2a, -2b, -3a, -3b, -4a, and -4b labeled both dysplastic and nondysplastic neurons. The different labeling patterns by these two antibodies indicate that variants of NMDAR1-3a, -3b, -4a, and -4b are present in nondysplastic neurons. Both dysplastic neurons and nondysplastic neurons were immunoreactive to AMPA GluR2/3, but denser immunoreactivity was observed in dysplastic neurons. We also found that the locations of dysplastic neurons labeled by NMDAR2A/B were related to focal epileptic EEG seizure onsets or spiking and to focal behavioral seizure types. Our results suggest that there is hyperexcitability of dysplastic cortical regions, at least in part, from the presence of NMDAR2 subunits and selectively expressed NMDAR1 splice variants in dysplastic neurons.

Distribution of glutamate-decarboxylase-immunoreactive neurons and synapses in the rat and monkey hippocampus: light and electron microscopy.

We have studied the distribution of gamma-aminobutyric acid (GABA) neurons, axons, and synapses in the rat and monkey hippocampal formation by using glutamate decarboxylase (GAD) immunocytochemistry together with Nissl stains, electron microscopy, and double-labeled retrograde transport of horseradish peroxidase. The numbers of GAD-containing (putative GABA) neurons and their percentages compared to all Nissl-stained neurons were calculated throughout all the various fields and strata of the mammalian hippocampus. Although their numbers are greatest in the polymorph region of the fascia dentata (FD) and in the principal cell layers stratum pyramidale (SP) and stratum granulosum (SG), GAD immunoreactive (GAD-IR) cells are numerous in other strata that contain mostly dendrites and scattered cells. These GAD-IR (putative GABA) neurons in dendritic regions may be involved in feedforward dendritic inhibition or may directly inhibit nearby neurons. We used a postmortem delay technique, which resulted in apparent diffusion of GAD into dendrites and axons and allowed better visualization of the extensive dendritic domain of GAD-IR neurons. Computerized image analysis of GAD-IR puncta indicated that putative GABA terminals were numerous on apical and basilar dendrites of all pyramidal cells but unexpectedly highest in the monkey presubiculum. In the rat, GAD-IR neurons projected axons ipsilaterally from every region to the fascia dentata and CA1; however, commissural GAD-IR axons to the fascia dentata arose from GAD-IR neurons in only the contralateral fascia dentata and subiculum. Electron microscopy of GAD-stained hippocampus identified GAD-IR neurons with non-GAD-IR (possibly excitatory) synapses and GAD-IR terminals on somata and dendrites, 80% being the symmetric type and 20% the asymmetric type. In contrast, non-GAD-IR terminals were asymmetric 80% of the time.

Hippocampal neuron loss and memory scores before and after temporal lobe surgery for epilepsy.

OBJECTIVE: To assess the relationship of hippocampal neuron loss to intellectual and memory measures before and after temporal lobe surgery. DESIGN: Pyramidal cell loss, as determined on the resected tissue, of hippocampal subregion CA1 correlated highest with other subregional cell loss and thus was used as the primary indicator of hippocampal neuron loss. Groups of patients with left and right temporal lobe seizures were subdivided according to degree of CA1 neuron loss. Behavioral performances of patient groups were compared before and after surgery. SETTING: Patient data were obtained from a university program of surgery for epilepsy. CASES: Twenty-five patients who had intractable epilepsy. MAIN OUTCOME MEASURES: Wechsler Adult Intelligence Scale IQ scores, verbal and nonverbal memory measures adapted from the Wechsler Memory Scale, and the Rey-Osterrieth recall score. RESULTS: Degree of hippocampal cell loss selectively related to learning of unrelated word pairs, both preoperatively and postoperatively, in patients with left but not right temporal lobe seizures. Patients with severe loss of left hippocampal neurons performed worse than those with mild-moderate neuron loss both before and after surgery. Immediate recall of logical prose did not relate to hippocampal neuron loss, although scores decreased following left temporal lobe surgery. CONCLUSION: These findings support a role for the left hippocampus in rote verbal memory, ie, learning of unrelated word pairs. Semantically complex verbal learning, ie, recall of logical prose, is more dependent on extrahippocampal temporal lobe regions. Finally, patients with severe as compared with minimal left hippocampal neuron loss may be at risk for lower memory functioning postoperatively.

Memory following intracarotid amobarbital injection contralateral to hippocampal damage.

We examined the relationship between memory performance and hippocampal damage in temporal lobe epileptics undergoing the intracarotid amobarbital sodium procedure (IAP). Overall memory performance in the course of IAP was correlated with seizure lateralization. The hemisphere of seizure focus had impaired IAP memory in 63% (19/30) of the patients. The IAP memory performance following perfusion of the hemisphere contralateral to severe hippocampal lesions was impaired in five of six patients. These patients also exhibited hypometabolism of the impaired temporal lobe as determined independently by positron emission tomography. The single patient with a severely damaged hippocampus who did not demonstrate IAP memory impairment with contralateral hemisphere injection did not exhibit perfusion of the ipsilateral posterior cerebral artery with amobarbital. Memory performance following intracarotid amobarbital injection contralateral to a less severely damaged hippocampus was impaired in 14 of 24 patients and was not related to extent of hippocampal damage, temporal lobe hypometabolism of labeled glucose, perfusion of the ipsilateral posterior cerebral artery, hemispheric language dominance, or order of injection. These results indicate that impaired memory performance during IAP may reflect severe hippocampal damage and/or epileptogenic abnormality.

Synaptic reorganization by mossy fibers in human epileptic fascia dentata.

This study was designed to identify whether synaptic reorganizations occur in epileptic human hippocampus which might contribute to feedback excitation. In epileptic hippocampi, (n = 21) reactive synaptogenesis of mossy fibers into the inner molecular layer of the granule cell dendrites was demonstrated at the light microscopic and electron microscopic levels. There was no inner molecular layer staining for mossy fibers in autopsy controls (n = 4) or in controls with neocortex epilepsy having no hippocampal sclerosis (n = 2). Comparing epileptics to controls, there were statistically significant correlations between Timm stain density and hilar cell loss. Since hilar neurons are the origin of ipsilateral projections to the inner molecular layer, this suggests that hilar deafferentation of this dendritic zone precedes mossy fiber reafferentation. Quantitative Timm-stained electron microscopy revealed large, zinc-labelled vesicles in terminals with asymmetric synapses on dendrites in the inner molecular and granule cell layers. Terminals in the middle and outer molecular layers did not contain zinc, were smaller and had smaller vesicles. These histochemical and ultrastructural data suggest that in damaged human epileptic hippocampus, mossy fiber reactive synaptogenesis may result in monosynaptic recurrent excitation of granule cells that could contribute to focal seizure onsets.

In contrast to kindled seizures, the frequency of spontaneous epilepsy in the limbic status model correlates with greater aberrant fascia dentata excitatory and inhibitory axon sprouting, and increased staining for N-methyl-D-aspartate, AMPA and GABA(A) receptors.

This study determined whether there were differences in hippocampal neuron loss and synaptic plasticity by comparing rats with spontaneous epilepsy after limbic status epilepticus and animals with a similar frequency of kindled seizures. At the University of Virginia, Sprague-Dawley rats were implanted with bilateral ventral hippocampal electrodes and treated as follows; no stimulation (electrode controls; n=5): hippocampal stimulation without status (stimulation controls; n=5); and limbic status from continuous hippocampal stimulation (n=12). The limbic status group were electrographically monitored for a minimum of four weeks. Four rats had no recorded chronic seizures (status controls), and all three control groups showed no differences in hippocampal pathology and were therefore incorporated into a single group (controls). Eight limbic status animals eventually developed chronic epilepsy (spontaneous seizures) and an additional eight rats were kindled to a similar number and frequency of stage 5 seizures (kindled) as the spontaneous seizures group. At the University of California (UCLA) the hippocampi were processed for: (i) Niss1 stain for densitometric neuron counts; (ii) neo-Timm's histochemistry for mossy fiber sprouting; and (iii) immunocytochemical staining for glutamate decarboxylase, N-methyl-D-aspartate receptor subunit 2, AMPA receptor subunit 1 and the GABA(A) receptor. In the fascia dentata inner and outer molecular layers the neo-Timm's stain and immunoreactivity was quantified as gray values using computer image analysis techniques. Statistically significant results (P<0.05) showed the following. Compared to controls and kindled animals, rats with spontaneous seizures had: (i) lower neuron counts for the fascia dentata hilus, CA3 and CA1 stratum pyramidale; (ii) greater supragranular inner molecular layer mossy fiber staining; and (iii) greater glutamate decarboxylase immunoreactivity in both molecular layers. Greater supragranular excitatory mossy fiber and GABAergic axon sprouting correlated with: (i) increases in N-methyl-D-aspartate receptor subunit 2 inner molecular layer staining; (ii) more AMPA receptor subunit 1 immunoreactivity in both molecular layers; and (iii) greater outer than inner molecular layer GABA(A) immunoreactivity. Furthermore, in contrast to kindled animals, rats with spontaneous seizures showed that increasing seizure frequency per week and the total number of natural seizures positively correlated with greater Timm's and GABAergic axon sprouting, and with increases in N-methyl-D-aspartate receptor subunit 2 and AMPA receptor subunit 1 receptor staining. In this rat limbic status model these findings indicate that chronic seizures are associated with hippocampal neuron loss, reactive axon sprouting and increases in excitatory receptor plasticity that differ from rats with an equal frequency of kindled seizures and controls. The hippocampal pathological findings in the limbic status model are similar to those in humans with hippocampal sclerosis and mesial temporal lobe epilepsy, and support the hypothesis that synaptic reorganization of both excitatory and inhibitory systems in the fascia dentata is an important pathophysiological mechanism that probably contributes to or generates chronic limbic seizures.

Activity of human hippocampal formation and amygdala neurons during sleep.

Fine wire microelectrodes were implanted for diagnostic purposes in 17 patients suffering from psychomotor epilepsy. Single- and multiunit activity during waking and natural nocturnal slow wave sleep and REM sleep was recorded in the hippocampus (n = 42), hippocampal gyrus (n = 53), and amygdala (n = 32). The firing rates of hippocampal gyrus units usually decreased during slow wave sleep and then increased to levels equal to or above waking during REM. In contrast, the firing rates of hippocampal neurons generally increased during slow wave sleep and fell to very low levels during REM. The amygdala presented a more mixed pattern. Since the projection from the hippocampal gyrus to hippocampus is excitatory, their opposite patterns during sleep suggest that the tonic firing patterns of HC neurons may be mainly the result of subcortical afferents.

Decreased calmodulin-NR1 co-assembly as a mechanism for focal epilepsy in cortical dysplasia.

The NMDA receptor is one of the ionotropic glutamate receptors essential for excitatory neurotransmission. The NMDAR1 subunit is inactivated by direct interaction with calmodulin. The protein levels of calmodulin, NMDAR1 and their complex were quantified in tissue resected from epileptogenic and non-epileptogenic cortical areas as determined by chronic subdural electrode recordings from three patients (aged 6, 14 and 18 years) with focal epilepsy associated with cortical dysplasia. In all patients, the co-assembly of calmodulin and NMDAR1 was decreased in epileptogenic dysplastic cortex compared with normal appearing non-epileptogenic cortex, while there was no significant difference in the total protein levels of calmodulin or NMDAR1 between the two EEG groups. These results suggest that decreased calmodulin-NMDAR1 co-assembly is a cellular mechanism that contributes to hyperexcitability in dysplastic cortical neurons and in focal seizure onsets.

Aberrant hippocampal mossy fiber sprouting correlates with greater NMDAR2 receptor staining.

This study determined in temporal lobe epilepsy patients and rats injected with intrahippocampal kainate (KA) whether fascia dentata molecular layer mossy fiber sprouting was associated with increases in NMDAR2 immunoreactivity (IR). Patients with hippocampal sclerosis (n = 11) were compared with those with temporal mass lesions (n = 7) and material obtained at autopsies (n = 4); and unilateral KA-injected rat hippocampi (n = 7) were compared with the contralateral saline-injected side and non-lesioned animals (n = 7; control). Hippocampi were studied for neo-Timm's stained mossy fiber sprouting and NMDAR2 IR. The staining was quantified as gray values (GV) using computer image analysis. Hippocampal sclerosis patients and KA-injected rats showed the greatest inner molecular layer (IML) mossy fiber sprouting and NMDAR2 staining. Compared with autopsies and patients with mass lesions, hippocampal sclerosis patients had greater IML neo-Timm's (p = 0.0018) and NMDAR2 staining (p = 0.0063). Similarly, compared with controls and saline-injected rats, KA-injected hippocampi showed greater IML mossy fiber sprouting and NMDAR2 IR (p = 0.0001). Furthermore, IML mossy fiber sprouting positively correlated with greater IML NMDAR2 staining in both human and experimental rat groups (p < 0.0099). These results support the hypothesis that in severely damaged hippocampi abnormal mossy fiber sprouting and concordant increases in IML NMDAR2 receptor staining may contribute or partially explain granule cell hyperexcitability and the pathophysiology of hippocampal epilepsy.

Demonstration of caudally directed hippocampal efferents in the rat by intracellular injection of horseradish peroxidase.

Axonal projections of rat hippocampal neurons were demonstrated by intracellular injections of horseradish peroxidase. The data indicated a prominent caudally directed projection from pyramidal neurons of hippocampal field CA1, provided evidence that the subiculum is one of its targets, and suggested that the caudally directed efferents from CA1 are more numerous than rostrally directed ones.

Inhibition in subicular and entorhinal principal neurons in response to electrical stimulation of the fornix and hippocampus.

We performed experiments studying the responses of rat subicular and entorhinal neurons to electrical stimulation of the fornix and hippocampus. Four main results were obtained: (1) extracellular recordings from principal neurons showed prolonged inhibition in response to stimulation, and intracellular recordings showed prominent IPSPs; (2) neither fornical nor commissural afferents were necessary for the inhibitory responses; they were present even in animals that had received prior surgical sections of the fornix and hippocampal commissures; (3) antidromic responses to fornix or hippocampal stimulation were recorded in neurons of the subicular complex; and (4) 3 cells in the subicular and entorhinal cortex were encountered that showed some of the properties associated with interneurons. The results suggest that principal neurons of the subicular complex share a number of properties with hippocampal pyramidal cells, including intrinsic recurrent inhibitory circuitry. Further study is required to determine the pathway for entorhinal inhibitory responses.

Neurophysiology of the caudally directed hippocampal efferent system in the rat: projections to the subicular complex.

We studied the responses of rat subicular neurons to electrical stimulation of the hippocampus. Four main results were obtained: (1) orthodromic excitatory responses were recorded in neurons of the subicular complex following electrical stimulation of the ipsilateral hippocampus. Responses were usually characterized by a single action potential immediately followed by an inhibitory period. Intracellular recordings showed that spikes were triggered by EPSPs. Preliminary data indicated that the excitatory effects extend to the entorhinal cortex as well; (2) neither fornical nor commissural afferents were necessary for the responses; they were present even in animals that had received surgical sections of the fornix and hippocampal commissures prior to the neurophysiological experiments; (3) some neurons showed evidence of frequency potentiation when stimulated at 5/sec or 10/sec; and (4) neurons in hippocampal fields CA1 and CA3 with the physiological characteristics of pyramids could be antidromically activated by electrical stimulation of subicular white matter. The results indicate an excitatory, caudally directed hippocampal efferent system that originates in fields CA1 and CA3, and that projects to all ventrocaudal regions of the subicular complex.

Excitatory projection of the rat subicular complex to the cingulate cortex and synaptic integration with thalamic afferents.

We studied the responses of rat cingulate cortex neurons to electrical stimulation of the subicular complex. Intracellular and 'quasi-intracellular' recordings from layer V posterior cingulate neurons showed that stimulation of the presubiculum or postsubiculum evoked EPSPs and action potentials. These were usually followed by shallow IPSPs averaging 122 ms in duration. Frequency potentiation of an EPSP was demonstrated in one case. Laminar analysis of field potentials provided evidence for a source of excitatory synaptic drive in layer II-III of the posterior cingulate cortex, where the subicular projections terminate, presumably on apical dendrites of layer V pyramids. Intracellular HRP injection of neurons showing EPSPs after subicular complex stimulation established that these responsive neurons were layer V pyramids. One cell with physiological properties characteristic of inhibitory interneurons was recorded in layer V. Stimulation of the thalamic nuclei lateralis and anterior ventralis also evoked EPSPs and action potentials in layer V cingulate neurons. In one cell it was possible to show that EPSPs evoked by presubicular stimulation and by nucleus anterior ventralis summed. These results indicate that subicular and thalamic afferents make excitatory synaptic contact onto dendrites of the same layer V cingulate neurons; that spatial summation can integrate the input from these two sources; and that inhibition from local interneurons limits the duration of this excitatory influence.

Demonstration of axonal projections of neurons in the rat hippocampus and subiculum by intracellular injection of HRP.

Hippocampal formation neurons of rat were injected intracellularly with horseradish peroxidase in order to trace intrinsic and extrinsic axonal projections. CA3 pyramids (n = 9) projected axons rostrally toward the fimbria, one or more Schafer collaterals toward CA1, and in two cases fibers that crossed the hippocampal commissure. Pyramids of CA1 (n = 5) projected axons to the alveus where they proceeded caudally toward the subiculum. A subset (n = 3) also projected an axonal branch rostrally toward the fimbria. These findings confirm not only major target regions of Ammon's horn pyramids, but also emphasize their divergent axonal projections that are not necessarily lamellar in organization. Axons from subicular pyramids (n = 12) projected rostrally, caudally, or in both directions. They could be traced to several other cortical regions, specifically Ammon's horn, entorhinal cortex and cingulate cortex. The results further confirm that subicular neurons are the recipient of input from the hippocampus proper and are a principal source of efferents from the hippocampal formation. A multi-process neuron in CA1 with physiologic properties associated with inhibitory interneurons was filled and traced in detail. It most resembled the poligonal basket cells that Lorente de Nó described, having long radially oriented dendrites extending as far as stratum lacunosum-moleculare. The presence of putative inhibitory interneuron dendrites in stratum lacunosum-moleculare suggests some role other than traditional recurrent inhibition for these dendritic segments, and two possible circuits are described.

Postnatal expressions of non-phosphorylated and phosphorylated neurofilament proteins in the rat hippocampus and the Timm-stained mossy fiber pathway.

Neurofilament proteins (NFPs), the cytoskeletal proteins that are essential for axogenesis and maintenance of neuron shape in the nervous system, were studied for their spatial distributions at nine postnatal days (PN 3, 5, 7, 10, 14, 17, 21, 28, and 120). Simultaneously non-phosphorylated (SMI-32; 150/200 kDa; Sternberger) and phosphorylated (SMI-31; 200 kDa) NFP immunoreactivity in the entire developing rat hippocampus was studied, quantified, and compared to that of mossy fiber (MF) axons and terminals using Neo-Timm's histochemistry, the most selective, sensitive, and reproducible technique. Differential developmental expressions were observed between the two NFP states. SMI-32 was initially expressed on PN 3 only in the perikarya of pyramidal neurons in CA3. As early as PN 5, SMI-31 appeared in the MF pathway, in parallel to the growth of MF axons. By contrast, SMI-32 did not appear at any age in the MF pathway, including the MF terminal zone of stratum lucidum. At PN 14, the distribution of both NFPs in the MF system (MFs and their target neurons, i.e., CA3/CA4 pyramidal neurons and hilar neurons) was nearly complete; however, the peak densities of SMI-32 and SMI-31 were later at PN 21 and statistically equal to the most adult level (PN 120). The temporal regulation and maximal levels of SMI-32 and SMI-31 expressions on MF target neurons (CA3: SMI-32) and in the MF terminal zone (stratum lucidum: SMI-31) were nearly parallel to the progressive and rapid PN growth of the MF axons and terminals occurring between PN 14 and PN 17, suggesting that the mechanisms for maturation of MF synaptogenesis occur after PN 17.

Increased densities of AMPA GluR1 subunit proteins and presynaptic mossy fiber sprouting in the fascia dentata of human hippocampal epilepsy.

In human hippocampal epilepsy, there is a consistent pathology of cell loss and reactive synaptic reorganization of 'excitatory' mossy fibers (MF) into the inner molecular layer (IML) of the fascia dentata (FD). In this study, neo-Timm's histochemistry of MFs and immunocytochemistry of GluR1 were used to determine, in patients with or without hippocampal sclerosis (HS), if there was a correlation between aberrant supragranular (IML) mossy fiber sprouting and increased densities of AMPA GluR1 subunit proteins in the IML of the FD. Computerized quantified densitometric grey values of Timm and GluR1 densities were corrected for the densities of granule cell losses using cell counts. In the IML of the HS group, despite the losses of granule cells, mossy fiber sprouting was significantly greater (P<0.000001) and GluR1 protein densities were significantly higher (P<0.0005) than those of the non-HS group. Unlike supragranular mossy fiber sprouting, which was limited to the IML, the increased GluR1 stainings were distributed throughout the whole molecular layer. For all cases, MF synaptic reorganization in the supragranular ML was correlated with GluR1 subunit protein densities in the IML (R=0.784, P<0.0093). These data demonstrate that in the human epileptic fascia dentata, there are significantly increased AMPA GluR1 subunit proteins associated with aberrant MF synaptic reorganizations. This suggests that the hyperexcitability of sclerotic hippocampus occurs, at least in part, from the associated changes of both presynaptic mossy fiber glutamatergic neoinnervation and increased GluR1 subunit proteins in the dendritic domains of the FD.

Neurophysiology of limbic system pathways in the rat: projections from the subicular complex and hippocampus to the entorhinal cortex.

We studied the responses of rat entorhinal neurons to electrical stimulation of the dentate gyrus, hippocampus and subicular complex. Three main results were obtained. Excitatory postsynaptic potentials were recorded in entorhinal neurons in response to electrical stimulation. Cell in layers II, III and V of the entorhinal cortex were responsive. Frequency potentiation of excitatory responses was observed when 10/s stimulation was used. Excitatory responses were followed by inhibitory postsynaptic potentials. The results provide evidence for an excitatory projection from the hippocampus and subiculum to the entorhinal cortex, and are consistent with the existence of feed-forward inhibition of entorhinal principal neurons.

Children with severe epilepsy: evidence of hippocampal neuron losses and aberrant mossy fiber sprouting during postnatal granule cell migration and differentiation.

Surgically resected hippocampi from children with extrahippocampal seizures and structurally non-atrophic brains were examined to determine the relationship of neuron losses and aberrant mossy fiber (MF) sprouting to the postnatal migration and differentiation of the fascia dentata (FD) granule cells (GC). Percent neuron loss compared to age-matched autopsy controls was determined by quantitative cell densities, and aberrant MF sprouting by neo-Timm histochemistry. Postnatal immature GC migration and differentiation was demonstrated by the transient but GC-specific expression of the immature form of neural cell adhesion molecule (NCAM-H). Results showed that the hippocampi from children with seizures appeared microanatomically intact without focal areas of damage. However, significant neuron losses were found by neuron counts in the fascia dentata (P < 0.01), CA4 (P < 0.01), and CA2 (P < 0.05). Aberrant supragranular inner molecular layer MF sprouting was found in hippocampi of children with seizures, and the MFs showed smaller puncta in specimens resected under 2 years of age (n = 3) compared to the larger puncta in older children (n = 5). Hippocampi from children under 2 years of age also demonstrated NCAM-H positive primitive cells in the infragranular and stratum granulosum of the fascia dentata consistent with the postnatal migration and differentiation of GCs, the parent neurons of the MFs. These results indicate that seizures in the immature but structurally intact human hippocampus are associated with decreased neuron densities and aberrant MF sprouting very early in postnatal development. The data also show that aberrant MF sprouting is found during postnatal migration, differentiation and axogenesis of GCs.(ABSTRACT TRUNCATED AT 250 WORDS)

Increased NR1-NR2A/B coassembly as a mechanism for rat chronic hippocampal epilepsy.

The N-methyl-D-aspartate receptors (NMDAR) produce physiologically functional channels for enhanced excitatory neurotransmission when they exist as heteromeric complexes containing the NMDAR1 subunit combined with NMDAR2. We examined the expressions of NMDAR1 and 2A/B protein in the kainic acid induced rat chronic epileptic hippocampus. Immunoreactivities of both NMDAR1 and NDMAR2A/B were increased in the inner molecular layer of the dentate gyrus, while they were decreased in the hilar and CA3/4 pyramidal zones. Immunoblot analysis demonstrated that the overall level of NMDAR1-2A/B coassembly was increased in the whole hippocampus. These results indicate that the increase of the NMDAR1-2A/B complex in the inner molecular layer is a significant cellular mechanism that contributes to focal hyperexcitability in rat chronic hippocampal epilepsy.