Divergent GABAA Receptor-Mediated Synaptic Transmission in Genetically Seizure-Prone and Seizure-Resistant Rats

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The Journal of Neuroscience, November 15, 2002, 22(22):9922-9931

Divergent GABA_A Receptor-Mediated Synaptic Transmission in Genetically Seizure-Prone and Seizure-Resistant Rats
Dan C. McIntyre¹, Bruce Hutcheon¹^,², Kerstin Schwabe³, and Michael O. Poulter¹^,²
¹ Neuroscience Research Institute, Carleton University, Ottawa, Ontario, Canada K1S 5B6, ² Laboratory of Molecular Neuropharmacology, Institute for Biological Sciences, National Research Council of Canada, Ottawa, Ontario, Canada K1A 0R6, and ³ Department of Pharmacology, Toxicology, and Pharmacy, School of Veterinary Medicine, D-30559 Hannover, Germany

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Recent evidence suggests that abnormal expression of GABA_A receptors may underlie epileptogenesis. We observed previouslythat rats selectively bred to be seizure-prone naturally overexpressed,as adults, GABA $alpha$ subunits ( $alpha$ 2, $alpha$ 3, and $alpha$ 5) seen at birth, whereasthose selected to be seizure-resistant overexpressed the adult, $alpha$ 1 subunit. In this experiment, we gathered GABA miniature IPSCs(mIPSCs) from these strains and correlated their attributes withthe subunit expression profile of each strain compared with anormal control strain. The mIPSCs were collected from both corticalpyramidal and nonpyramidal neurons. In seizure-prone rats, mIPSCswere smaller and decayed more slowly than in normal rats, whichin turn were smaller and slower than in seizure-resistant rats.A detailed analysis of individual mIPSCs revealed two kinds ofpostsynaptic responses (those with monoexponential vs biexponentialdecay) that were differentially altered in the three strains.The properties of monoexponentially decaying mIPSCs did not differbetween pyramidal and nonpyramidal neurons within a strain butdiffered between strains. In contrast, an interaction was observedbetween cell morphology and strain for biexponentially decayingmIPSCs. Here, the mIPSCs of pyramidal neurons in the seizure-resistantrats formed a distinct subpopulation compared with the seizure-pronerats; yet in the latter rats, it was the mIPSCs of the nonpyramidalneurons that were unique. Given these differences, we were surprisedto find that the total inhibitory charge transfer between thestrains was similar. This suggests that the timing of inhibition,particularly slow inhibitory neurotransmission between nonpyramidalneurons, may be a contributing factor in seizuregenesis.

Key words: subunits; epilepsy; GABA_A receptors; inhibitory currents; interneurons; perirhinal cortex

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Numerous studies have shown that GABA_A receptor behavior varies with subunit expression (Verdoorn et al., 1990; Angelottiand Macdonald, 1993; Verdoorn, 1994; Dominguez-Perrot et al.,1995; Zhu et al., 1995; Tia et al., 1996; Burgard et al., 1999;Haas and Macdonald, 1999; McClellan and Twyman, 1999; Hutcheonet al., 2000). From one brain region to the next, the geneticexpression is diverse, giving rise to differing functional profilesof GABAergic inhibition that are hypothesized to control the rhythmicityof neural networks. This control of neural network rhythmicityis altered in many neurological disorders (Traub et al., 1999),including temporal lobe epilepsy(TLE).

Although the structural origins and expression of complex partial seizures in human TLE are varied, the hippocampus, amygdala,and adjacent cortical areas are thought to be significant contributorsto the syndrome (Gloor, 1991). As a result, alterations in inhibitionwithin these structures have been the focus of many studies. Recently,the search for a molecular basis of epilepsy has received strong,convergent support from several experimental models, suggestingthat the expression of GABA_A receptors in these brain areas isabnormal (Brooks-Kayal et al., 1998, 1999; Schwartzkroin, 1998;Sperk et al., 1998; Loup et al., 2000). Indeed, in our geneticallybased amygdala kindling models of TLE (Racine et al., 1999), wehave shown that differential kindling rates (McIntyre et al.,1999) are correlated with differences in GABA_A subunit expression(Poulter et al., 1999). In these models, a genetic predispositionto amygdala kindling in adult rats is correlated with an overexpressionof the GABA_A receptor subunits that normally predominate in theimmature brain ( $alpha$ 2, $alpha$ 3, and $alpha$ 5). Conversely, overexpression ofthe major adult $alpha$ subunit ( $alpha$ 1) is associated with resistance tokindling. Because GABA-mediated neurotransmission not only truncatesaction potential generation but also synchronizes and/or timesthe output of neural circuits (Whittington et al., 1995; Wangand Buzsaki, 1996), it has been suggested (Poulter et al., 1999)that the abnormal expression of certain GABA_A receptors may resultin the periodic failure of the brain to prevent excessive synchronyacross neuralnetworks.

The purpose of the present study was to correlate the electrophysiological properties of GABA_A receptor-mediated synaptictransmission in rats that have different GABA_A receptor subunitexpression and predispositions to epileptogenesis. We have hypothesizedthat differences in subunit expression underlie altered neuralnetwork timing profiles and, in turn, seizure vulnerability. Asa first step, we wanted to understand how the inhibitory synapticcurrents are different in these different rat strains. To thisend, we show for the first time that differing behaviors of GABA_Areceptor-mediated synaptic transmission are correlated to ourpreviously reported subunit expression profiles (Poulter et al.,1999). These results suggest that the observed differences ininhibitory activity between the strains may underlie both theseizure-prone and seizure-resistantphenotypes.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

All experiments were conducted in accordance with the guidelines of the Canadian Council on Animal Care and protocols approvedby the Carleton University and National Research Council of CanadaAnimal CareCommittees.

Animals. The seizure-prone and seizure-resistant rat strains were originally developed at McMaster University (Hamilton, Ontario,Canada) from an outbred parent population consisting of a Long-Evanshooded and Wistar cross (Racine et al., 1999). For 11 generations,these rats were selectively bred for their differential ratesof amygdala kindling. The resulting two strains [called "Fast"and "Slow" by Racine et al. (1999)] now are bred nonselectivelywithin each strain in a manner to preclude brother-sister or first-cousinpairings and are maintained at Carleton University. The seizure-proneand -resistant rats used in the present project were taken fromgenerations 41-44. As "normal" rats, one of the original two parentstrains (Long-Evans hooded) was used; they were purchased fromCharles River Canada (St. Constant P.Q.,Canada).

Electrophysiology. Patch-clamp recordings were performed on brain slices isolated from adult rats (60-200 d of age). To obtainviable slices, heavily anesthetized rats (sodium pentobarbital,80 mg/kg, i.p.) were perfused with an ice-cold Ringer's solutionin which sodium was replaced by choline (composition in mM: 110choline Cl, 2.5 KCl, 1.2 NaH₂PO₄, 25 NaHCO₃, 0.5 CaCl₂, 7 MgCl₂,2.4 Na pyruvate, 1.3 ascorbate, and 20 dextrose), thus coolingand neuroprotecting the brain in situ. Specifically, this wasdone by opening the thoracic cavity, clamping off the descendingaorta, and cutting the right atrium. The left ventricle of theheart was subsequently punctured with an 18 gauge needle and perfusedwith 50 ml of the ice-cold choline solution. After perfusion,the brain was rapidly removed from the skull, and the temporallobe area was excised as a block. The block was subsequently sliced(coronally) with a Vibratome (200- to 400-µm-thick sections).The slices were incubated at 35°C for 30 min and subsequentlymoved to a room-temperature bath, where they were maintained untilneeded. Slicing, incubation, and storage were all performed inthe choline solution. The Ringer's solution used during electricalrecordings was similar to the choline solution except that pyruvateand ascorbate were removed, equimolar NaCl replaced the cholineCl, and CaCl₂ and MgCl₂ were both used at a 2 mMconcentration.

We used KCl patch electrodes having an internal composition (in mM) of 145 KCl, 10 NaCl, 2 CaCl₂, 10 EGTA (yielding a freeCa²⁺ concentration of 100 nM), 2 MgATP, 10 dextrose, and 10 HEPES(300-320 mOsm; pH adjusted to 7.3-7.4). The input resistance ofthese electrodes was 3-8 M $Omega$ , and their shanks were coated in beeswaxto reduce electrode capacitance. Recordings from neurons in layers3 and 5 of the perirhinal cortex were made with an Axopatch 200Bamplifier (Axon Instruments, Carver City, CA). Series resistancecompensation was performed in all recordings. Acceptable recordingswere those in which the initial access resistance was <20 M $Omega$ andcould be compensated by 70-80% (100 µsec lag). The series resistancewas monitored throughout the recordings, and if it rose irreversiblyabove 20 M $Omega$ , the recording was terminated. Under these conditionsand on the basis of the size of the currents monitored (20-200pA), the remaining uncompensated series resistance caused a voltageerror of <1%, whereas filtering errors werenegligible.

Neurons were visualized with differential interference contrast optics. Both voltage-clamp and current-clamp recordings weremade to compare the voltage-gated membrane currents and excitability.Spontaneously occurring miniature IPSCs (mIPSCs) were collectedin the presence of 200-500 nM tetrodotoxin (TTX; Alomone Laboratories,Tel Aviv, Israel), 10 µM dinitroquinoxaline-2,3-dione (DNQX; ResearchBiochemicals, Natick, MA), and 20 µM 2-amino phosphonopentanoicacid (APV; Research Biochemicals). Recordings were performed atroom temperature (22-26°C), because at higher temperatures, mIPSCsarrived too quickly and were rarely separated from one anotherenough to permit useful fitting and analysis. Putative mIPSCswere acquired as brief, negative-going transients in the currentnecessary to hold the membrane potential at $-$ 60mV.

Analysis of mIPSCs. The deactivation phases of the mIPSCs were individually fitted with exponential functions. Monoexponentialand biexponential fits were performed on each mIPSC. The residualdeviations were subsequently compared to decide which fit to retain,as described by Hutcheon et al. (2000). Fits and subsequent sortingand analysis of the data were performed automatically by use ofthe macro facility in Clampfit (Axon Instruments) and a macrowritten in house in Visual Basic to control the operations ofMicrosoft (Redmond, WA) Excel worksheets. In all analyses, mIPSCswere sorted to eliminate events with 10-90% rise times of >1.5msec, half-width durations of <4 msec (i.e., events that weretoo brief to be considered genuine GABAergic synaptic transients),and events that were not considered to be caused by a single mIPSC.After sorting by these criteria, ~80% of the collected eventswere rejected [i.e., ~30% of the mIPSCs had rise times that were>1.5 msec, ~40% could not be fitted because another mIPSC occurredduring the fitting window, and ~10% were false events (shiftsin the baseline)].

For comparisons between rat strains and morphological cell type, 45-65 mIPSCs were randomly selected from the recordings ofeach cell, and the parameter values derived from the correspondingindividual fits were pooled with those of other cells. Limitingthe number of mIPSCs from each cell in this way ensured that eachneuron was equally represented in the analysis while preservingthe variability of the measured attributes. Because our criteriafor automated sorting were highly conservative, some recordingshad too few mIPSCs to be included in this part of the analysis,although they could be retained in other analyses (averaging;see below). For this reason, the number of cells from the individualmIPSC analysis is not the same as that for the data in which anaverage of the mIPSCs wascalculated.

This initial analysis permitted the comparison of attributes of the individual mIPSCs within strains (on the basis of theirpyramidal and nonpyramidal cell morphology) and between strainsby generating six different distributions: (1) time constantsof monoexponential mIPSCs and (2) their amplitudes; (3) the fastand (4) the slow time constants of deactivation of biexponentialmIPSCs and (5) their amplitudes; and (6) the percentage componentof fast deactivation of the biexponential mIPSCs. None of thesequantities were normally distributed (as determined by Kolmogorov-Smirnovnormality tests); hence, all representative data are reportedas medians with interquartileranges.

Statistical tests were performed to detect differences in the median values of data from the same morphological cell typesin the three different strains. That is, data from pyramidal neuronsin one strain were tested against pyramidal neurons in the otherstrains but not against data from nonpyramidal neurons. For statisticalcomparisons of the medians, a Kruskal-Wallis test was first usedwith a level of significance set at p = 0.01. If a significantdifference between medians was detected, then post hoc comparisonsbetween individual medians were calculated on the basis of Dunn'stest. Mann-Whitney U tests were used to detect differences inthe median values of pyramidal and nonpyramidal neurons in thesamestrain.

To provide insight into how simultaneous mIPSCs might be combined in neurons, 50-100 individual events were chosen in eachcell, aligned by their rising phases (<1.5 msec), and averagedtogether. The resulting signals, denoted by a subscripted andappended "av" (hence, mIPSC_av), then had their declining phasesfitted with sums of exponentials as in the analysis of individualmIPSCs described above. This yielded one set of fitted parametersper neuron. These averages for individual neurons were subsequentlygrouped by rat strain and cellular morphology to yield categorizeddistributions of the parameters. Because these distributions werefound to be normal, they are summarized throughout as means ±SEM. A one-way ANOVA was used to test for differences in meansbetween similar cell types in different strains (significancelevel, p = 0.01). If a difference was detected, a Newman-Keulspost hoc test was used to compare individual means. Differencesbetween the attributes of pyramidal and nonpyramidal neurons inthe same strain were detected using Student's ttests.

Histocytochemistry. Cells from which recordings were made were filled with 0.5% biocytin (Sigma-Aldrich, Oakville, Ontario,Canada) and subsequently visualized by streptavidin conjugatedto the fluorescent 6-((7-amino-4-methylcoumarin-3-acetyl)aminohexonic acid molecule (Jackson ImmunoResearch, West Grove, PA).A series of digital photos in the z-axis (1.5 µM apart) were takenwith a Photometrics Star 1 camera (25× magnification; 580 × 380pixel resolution). The stack of images was subsequently deconvolvedusing a commercially available software package (Exhaustive PhotonReassignment; Scanalytics, McClean, VA). The entire cell morphologywas visualized by projecting the deconvolved optical sectionsonto a single plane. Background and imperfections were subtractedor retouched using Corel (Ottawa, Ontario, Canada) Photopaintto produce a final duotone image. Classification of the cellsas either pyramidal or nonpyramidal was based on the morphologyof the soma, the existence and orientation of a dominant dendrite,and the projection of theaxon.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Using brain slices obtained from adult normal, seizure-prone, or seizure-resistant rat strains (Racine et al., 1999), we maderecordings from >300 neurons in the perirhinal cortex, a structurethat has been strongly implicated in the secondary generalizationof limbic-kindled seizures (Kelly and McIntyre, 1996; Ferlandet al., 1998) and in which the magnitude and timing of inhibitionis probably very important. Recordings were selected for analysison the basis of the criteria stated in Materials and Methods (low-accessresistance and adequate resistance compensation). These recordingswere subsequently selected for inclusion in the results reportedbelow only if the morphology of the neuron could be ascertained(see Materials and Methods). On the basis of these criteria, thisgave 82 recordings that are describedbelow.

We found that whole-cell recordings from neurons in layers 3 or 5 of the perirhinal cortex showed similar voltage-currentproperties across the different rat strains. Although the highsynaptic activity and spontaneous action potential generationoften made it difficult to reliably characterize the spiking propertiesin many recordings, we identified rapidly accommodating, fast,regular, and intermittent spiking, and occasionally bursting neuronsin all three strains. The average resting membrane potentialsfor neurons in all three strains were similar (approximately $-$ 65mV). The membrane time constants, measured with hyperpolarizingcurrent pulses near the resting potential, were also the samebetween strains and were fit by the sum of two exponentials, one~2-4 msec and the other ~50-80msec.

Averaged time courses of miniature synaptic events (mIPSC_avs)

In the presence of TTX (200-500 nM), DNQX (10 µM), and APV (20 µM), we collected mIPSCs while maintaining the neurons at aholding potential of $-$ 60 mV. The mIPSCs were clearly mediatedby activation of GABA_A receptors, because they were blocked bythe application of either 10 µM gabazine or 20 µM bicuculline(10 of 10cells).

For each neuron, after collecting sufficient mIPSCs, we constructed an averaged time course (mIPSC_av) as described in Materialsand Methods. This traditional method of analysis increases thesignal-to-noise ratio in the synaptic signal for the purposesof determining synaptic kinetics. A drawback is that the actualnonstochastic variability between individual synaptic signalsmay be masked by the averaging procedure. On a different level,however, the mIPSC_av may be understood as an idealized representationof synaptic integration such as would result from a synchronousactivation of GABA_Aergicsynapses.

As depicted in Figure 1, mIPSC_avs from the three different strains were readily distinguished on the basis of their size andtime course of decay. To quantify these differences, we fittedexponential functions to the declining phase of mIPSC_avs. Themajority of mIPSC_avs were best fitted by the sum of two exponentialcomponents. Table 1 gives the means of the parameter values obtainedfrom these biexponential fits after grouping by strain and morphologicalcell type. It can be seen that the mIPSC_avs of both seizure-resistantand seizure-prone strains differed significantly from those ofnormal rats in the values of their fast ( $tau$ ₁) and slow ( $tau$ ₂) timeconstants for decay and in their amplitudes.

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Figure 1. Examples of average mIPSCs from a normal rat (A), a seizure-resistant rat (B), a seizure-prone rat nonpyramidal neuron (C), and a seizure-prone rat pyramidal neuron (D). Each example shows the basic characteristics found in each strain. In seizure-resistant rats, the average time course was faster and the amplitude larger than in normal rats. Within each of these strains, both pyramidal and nonpyramidal neurons had similar mIPSC_avs. In contrast, in seizure-prone rats, the average time courses were slower and the synaptic events smaller than in normal rats. This was more pronounced in the nonpyramidal population (see Table 1 for summary). In E and F, we show examples of the morphological reconstructions that were done for all recordings. E, Typical neuron that was classified as pyramidal; F, example of one kind of nonpyramidal cell morphology, which as expected was more variable in morphology than pyramidal. Calibration: 10 msec, 10 pA. The smooth line through each average time course shows the fitted time course. Arrows indicate axonal projection.


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Table 1. Comparison of mIPSC_av attributes in morphologically identified neurons of seizure-resistant, normal, and seizure-prone rat strains

The attributes of seizure-resistant and seizure-prone rats diverged in opposite directions from those of normal rats. Thatis, parameter values obtained from the exponential fits to mIPSC_avsin normal rats were intermediate to those of seizure-resistantand seizure-prone rats. Overall, mIPSC_avs from neurons encounteredin seizure-resistant rats were larger and decayed more quicklythan those from normal rats, and these in turn were larger anddecayed more quickly than those from seizure-prone rats (Fig.1, Table 1).

We also directly compared the properties of mIPSC_avs in pyramidal versus nonpyramidal neurons in each strain. This comparisonshowed that in normal and seizure-resistant rats, the averagedsynaptic time courses for these two cell types were statisticallysimilar (p > 0.25 for all comparisons of fitted parameters). Thiswas not true in seizure-prone rats, in which the average synaptictime courses measured in pyramidal and nonpyramidal cells wereclearly different (p < 0.03). In this case, mIPSC_avs in pyramidalneurons decayed significantly faster than those of nonpyramidalneurons. In contrast, the amplitudes of mIPSC_avs did not differbetween pyramidal and nonpyramidal neurons within a strain (p> 0.3; although, as stated above, there were large differencesbetweenstrains).

Time courses of individual miniature synaptic events

We also examined the properties of individual mIPSCs from normal, seizure-resistant, and seizure-prone rats. The decay phaseof each mIPSC in the database was fitted with a sum of exponentials,and the calculated parameters were pooled by strain and morphologicaltype as described in Materials and Methods. Using this analysiswe found that, in almost all neurons, two populations of mIPSCsexisted: those having monoexponential decay kinetics and thosehaving biexponential decay kinetics. As in the analysis of mIPSC_avsdescribed above, this analysis revealed marked differences betweenthe strains (Table 2). We now show that the differences in monoexponentialand biexponential kinetics are directly responsible for the differencesin mIPSC_avs noted above, because the relative proportions of thesetwo populations of synaptic events were similar (~3:1) acrossall strains and cell types (a single exception is described ina separate section below).


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Table 2. Comparison of mIPSC attributes in morphologically identified neurons of seizure-resistant, normal, and seizure-prone rat strains

Monoexponential mIPSCs, which constitute the most common type of synaptic behavior in each neuron, exhibited highly significantdifferences in all possible comparisons between strains (Table2). In contrast, the biexponential mIPSCs showed more restricteddifferences. Specifically, pyramidal neurons of seizure-resistantrats had larger, more quickly decaying biexponential mIPSCs thanthose of normal rats, but there was no such difference betweennonpyramidal neurons. Conversely, in seizure-prone rats, nonpyramidalneurons had smaller, more slowly decaying mIPSCs than in normalrats, but there was no such difference in the pyramidal neurons(Fig. 2).

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Figure 2. Two kinds of synaptic responses identified in nonpyramidal (Non-PYR) and pyramidal (PYR) neurons of all strains. Here, we show individual representative monoexponential (top) and biexponential (bottom) mIPSCs in seizure-resistant (pyramidal neuron), normal (pyramidal neuron), and seizure-prone (nonpyramidal neuron) rats. The mIPSCs were chosen to have attributes corresponding to the median values (amplitude and time course) found in each population. Calibration: 10 msec, 10 pA. The smooth line through each mIPSC shows the fitted time course. For illustration here, the fit window for each mIPSC was adjusted so that other events did not affect the fit of deactivation phase.

Within-strain comparison of mIPSC attributes in pyramidal and nonpyramidal neurons

Inhibition-related differences in seizure generation in the strains may depend more on the relative balance of inhibitoryproperties on pyramidal and nonpyramidal neurons than on strain-to-straindifferences of the cell types. We therefore performed within-strainstatistical comparisons of the attributes of mIPSCs in pyramidaland nonpyramidal neurons. In normal rats, we found no significantdifferences in the properties of mIPSCs on pyramidal and nonpyramidalneurons. Seizure-resistant rats similarly showed few differences,with the exception that the biexponential mIPSCs in pyramidalneurons were ~25% bigger than those in nonpyramidal neurons (p< 0.01). Seizure-prone rats, in contrast, had many differencesin the attributes of their mIPSCs recorded from pyramidal andnonpyramidal neurons. Specifically, in the seizure-prone strain,the biexponential mIPSCs were larger in pyramidal neurons thanin nonpyramidal neurons (p < 0.001), and both monoexponentialand biexponential mIPSCs decayed more quickly in pyramidal neuronsthan in nonpyramidal neurons (monoexponential, p < 0.001; biexponential,p < 0.03 and p < 0.001 for the fast and slow $tau$ values, respectively).The amplitudes of monoexponential events did not differ significantly(p > 0.1).

Between-strain comparisons of mIPSC attributes

Because significant within-strain differences were detected between the attributes of mIPSCs in pyramidal and nonpyramidalneurons (see previous section), we separated the between-straincomparisons on the basis of cell morphology. We first comparedmIPSCs in nonpyramidal neurons in the different strains. The resultsare highlighted by the cumulative distributions of fitted monoexponentialand biexponential parameters for mIPSC decays shown in Figure3. Statistical significance and summary measures are given inTable 2. Although there was substantial variability in the valuesof most parameters, differences in the cumulative distributionsare evident. For monoexponentially decaying mIPSCs, all possiblecomparisons showed significant differences following the overalltrend that mIPSCs in seizure-resistant rats were larger and morequickly decaying than those in normal rats, which, in turn, werelarger and more quickly decaying than those in seizure-prone rats.For biexponentially decaying mIPSCs in nonpyramidal neurons, onlythe seizure-prone rats formed a distinctive population, becausethey had smaller, more slowly decaying synaptic signals than theother two strains. There were no corresponding significant differencesbetween seizure-resistant and normal rat strains.

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Figure 3. Cumulative distributions for the fitted attributes of mIPSCs from nonpyramidal neurons in each strain. The distribution of values for the seizure-prone rats is consistently different from those of normal and seizure-resistant rat strains, which tend to be similar to each other (see Table 2 for summary).

Partially contrasting results were obtained when pyramidal cell mIPSCs were compared across strains (Fig. 4, Table 2). Onceagain, for monoexponential mIPSCs, all possible comparisons betweenstrains showed statistically significant differences, with thesame relative trends as for the nonpyramidal neurons. For biexponentialmIPSCs, however, differences were restricted to seizure-resistantrather than seizure-prone rats, as was the case for nonpyramidalneurons. Thus, for pyramidal neurons, it is the seizure-resistantrats that had a distinctive population of biexponentially decayingmIPSCs, in this case a population of large, quickly decaying synapticsignals.

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Figure 4. Cumulative distributions for the fitted attributes of mIPSCs from pyramidal neurons in each strain. In contrast to the situation for nonpyramidal neurons, the distributions of attributes for seizure-resistant rats were distinct from those of either normal or seizure-prone rats, which tended to be similar (see Table 2 for summary).

Overall, then, and in common with the earlier analysis of mIPSC_avs, we found that the parameter values characterizing mIPSCsin seizure-resistant and seizure-prone rats diverged from eachother, with normal rats presenting intermediate values. This wastrue in both pyramidal and nonpyramidal neurons and for monoexponentiallyand biexponentially decaying mIPSCs. The only extracted parameterfor which this was not true was the percentage of the total signaldevoted to the fast component of decay, which for the most part,did not vary systematically between strains. Differences betweenthe strains, however, were found to be concentrated in differentneuronal populations. Seizure-resistant rats had a special setof biexponentially decaying mIPSCs in their pyramidal neurons,whereas seizure-prone animals had a special set of biexponentiallydecaying mIPSCs in their nonpyramidalneurons.

Monoexponential and biexponential mIPSCs are distinct populations

A potential problem with the above analysis is the possibility that many small-amplitude, monoexponential mIPSCs are reallymisclassified biexponential mIPSCs (i.e., fittings may periodicallyfail because of a low signal-to-noise ratio). To test this possibility,we reduced the signal-to-noise ratio by decreasing the amplitudeof mIPSCs ~20% using a low dose (2-5 µM) of bicuculline. In agreementwith the hypothesis that misclassifications in fact were rare,we found that there was no statistical difference (p > 0.05) inthe relative proportion of monoexponential versus biexponentialevents after exposure to bicuculline. Thus, there was a high degreeof tolerance in the fitting routines. Moreover, bicuculline didnot alter the kinetics of the mIPSCs [control series: monoexponential, $tau$ = 13.8, 11.2 msec (median, intraquartile range); biexponential, $tau$ ₁ = 3.4, 0.9 msec, $tau$ ₂ = 35.5, 5.5 msec; bicuculline series: monoexponential, $tau$ = 14.4, 16.7 msec; biexponential, $tau$ ₁ = 3.3, 1.3 msec, $tau$ ₂ = 35.6,17.8 msec; n = 5 cells; p > 0.05 for all comparisons]. Overall,these data indicate that in perirhinal neurons, monoexponentialand biexponential synaptic transients arise either from synapseswith distinct types of GABA_A receptors or synapses with the samereceptor in different functionalstates.

A unique population of nonpyramidal neurons in seizure-prone rats

In one population of nonpyramidal cells from seizure-prone rats, mIPSC_avs decayed with a single exponential component (n =4) (Fig. 5). The mean value of the exponential decay time constantin these cells was similar to the values of the slower biexponentialdecay time constant in the pyramidal neurons in seizure-pronerats (Table 1). Two additional neurons from seizure-prone ratsalso had monoexponential kinetics, although in these cases, wewere unable to determine their somatic morphologies. In contrast,in the other 64 morphologically identified recordings from theother two rat strains (and another 100 or so others without morphologicalidentification), only one cell from a normal rat and none fromseizure-resistant rats had an mIPSC_av with monoexponential deactivation.An analysis of individual events was also performed on the fourrecordings with monoexponential mIPSC_avs as described above. Incontrast to all other neurons encountered, in these nonpyramidalneurons from seizure-prone rats, ~90% of the mIPSCs had monoexponentialdecays. This represents a substantial subpopulation of neuronsin the seizure-prone strain of rats (4 of 19 identified recordings)having distinctive synaptic kinetics that appears to be rare orperhaps nonexistent in the normal or seizure-resistant strains,respectively.

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Figure 5. Analysis of amplitude and deactivation kinetics for GABAergic mIPSCs recorded from a subpopulation of four nonpyramidal neurons in a seizure-prone strain. A, In contrast to most other recordings in normal and seizure-resistant rats, the averaged mIPSCs from this population were small and deactivated with a monoexponential deactivation time course. B, The cumulative data for mIPSC attributes in these four recordings show an under-representation (10% compared with 25-35% in other recordings) of biexponential events. Also, there was no difference in the mIPSC amplitudes for the two types of events (p > 0.05). Thus, the summated inhibition in these cells arises from a predominance of one population of events over the other. The arrow indicates axonal projection.

Time course of the synaptic signal versus charge transfer

To isolate the properties of inhibitory synaptic signaling that are most likely to cause functional differences between normal,seizure-resistant, and seizure-prone rats, we first calculatedthe charge transfer during the decay phase of the mIPSC_avs forthe three different strains and two morphological cell types.In normal and seizure-resistant rats, the charge transfers forpyramidal and nonpyramidal neurons were not calculated separately,because their attributes were shown previously to be statisticallysimilar. The results are shown graphically in Figure 6, whichalso includes calculated charge transfers for the four nonpyramidalneurons in seizure-resistant rats whose synaptic decay was primarilymonoexponential. Surprisingly, despite the strain-dependent differencesin peak amplitudes of mIPSC_avs, the mean total charge transfershowed no significant variation between strains (Fig. 6A). Functionaldifferences in GABA_Aergic signaling between the strains thereforedo not arise simply from each synapse delivering either more orfewer negative ions into neurons when stimulated.

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Figure 6. Comparison of the magnitude and time course of inhibition in the three strains. A, Calculated total charge transfer (holding potential, $-$ 60 mV; Cl reversal potential, ~0 mV) for averaged mIPSCs in various subpopulations, as described in Materials and Methods and shown in Figure 1. For normal and seizure-resistant strains, data shown are pooled between pyramidal (Pyr) and nonpyramidal (Non-Pyr) neurons. Despite differences in the peak amplitude of mIPSCs between the strains, there were no significant differences in the total charge transfer. B, Plot of deviations of average mIPSCs of the same subpopulations as above from the time course of the average mIPSC in normal rats. Data are presented as a percentage of the peak amplitude of the average mIPSC in normal rats. Inhibitory synapses in seizure-resistant (SR) rats pass more charge than those in normal rats over the first 10-20 msec. Synapses of seizure-prone (SP) rats, conversely, pass up to 50% less charge over the same time period compared with normal rats. These differences are compensated over the succeeding 100 msec to yield no net differences in charge transfer.

We also reconstructed representative time courses of GABA_Aergic signaling using the mean values of mIPSC_avs from Table 1.Figure 6B plots the instantaneous deviations of the reconstructedsynaptic currents from the normal strain. This shows that thestrains differ markedly during the early period of the synapticsignal (<10 msec) (Fig. 6B). During this initial interval, synapsesin neurons from seizure-prone rats pass far less current thanthose in neurons from either seizure-resistant or normal rats.Likewise, synapses in seizure-resistant rats pass far more inhibitorycurrent early than do either seizure-prone or normal rats. Thesedifferences suggest that the timing of synaptic deactivation isthe most important functional difference in inhibitory signalingbetween thestrains.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Our results demonstrate that inhibitory synaptic signals differ considerably in strains of rats that have different profilesof GABA_A receptor subunit expression and concomitant genetic predispositionsfor or against kindling. Over the initial 20 msec time window,it is likely that these differences in timing are important forcontrolling the quality of the inhibition that closely followsan excitatory input to truncate excess action potential generation(i.e., inhibition that limits bursting). The significantly lowerthreshold for afterdischarge activity reported in the perirhinalcortex of seizure-prone versus seizure-resistant rats (McIntyreet al., 1999) probably reflects these differences in initial IPSCtime course and amplitude. The increased magnitude of the inhibitionduring this epoch may then account primarily for the seizure-resistantphenotype, although other timing issues may play a role also (seebelow).

The strain-related differences we describe in synaptic deactivation kinetics correlate well with previously described differencesin GABA_A receptor subunit expression. Thus, in seizure-prone rats,in which the $alpha$ 3 and $alpha$ 5 GABA_A receptor subunits are abundant, theobserved slow deactivation profiles of mIPSCs are qualitativelysimilar to those in immature brain at a time when $alpha$ 3 and $alpha$ 5 levelsare high (Brickley et al., 1996; Tia et al., 1996; Dunning etal., 1999; Hutcheon et al., 2000; Okada et al., 2000). Similarly,in the laterodorsal thalamus during ontogeny, the deactivationkinetics of inhibitory synapses speeds up as the GABA_A subunitexpression shifts from $alpha$ 2 to $alpha$ 1 forms (Okada et al., 2000). Moreover,the average monoexponential and biexponential kinetics of nonpyramidal(presumably inhibitory) neurons in the seizure-prone strain correspondswell to the average mIPSC kinetics in inhibitory neurons of thereticular nucleus of the adult thalamus (Huntsman and Huguenard,2000), a structure with high $alpha$ 3 expression (Fritschy and Mohler,1995). Similar slow deactivation kinetics also has been describedfor cells expressing recombinant $alpha$ 5 $beta$ 3 $gamma$ 2 receptors (Burgard etal., 1999). Monoexponential decays have been described for both $alpha$ 2 and $alpha$ 3 subunit-containing recombinant receptors (Gingrich etal., 1995; Lavoie et al., 1997; McClellan and Twyman, 1999). Likewise,in normal and seizure-resistant rats, the fast deactivation kineticsof GABA_A receptors is similar to those in regions of the adultbrain in which $alpha$ 1 is the predominant GABA_A receptor subunit (Galarretaand Hestrin, 1997). Thus, both in other studies and in our twogenetic models of differential seizure susceptibility, there isa good correlation between the different expression patterns ofGABA_A receptor subunits and their associated synaptickinetics.

On pyramidal neurons, we consistently found that peak mIPSC amplitudes in seizure-resistant rats were greater than in normalrats, which, in turn, were greater than those in seizure-pronerats. Because the single-channel conductance of GABA_A receptorscontaining $alpha$ $beta$ $gamma$ subunits appears to vary little with subunit expression(Neelands et al., 1998; Burgard et al., 1999; Haas and Macdonald,1999), one possibility that may account for the small amplitudesof mIPSCs in seizure-prone rats may be a relative inability toefficiently cluster the particular subunit combinations they express.Indeed, our recent work shows that, during cortical development,GABA_A synapses preferentially recruit receptors with fast kinetics(Hutcheon et al., 2000), presumably containing $alpha$ 1 and not $alpha$ 3 or $alpha$ 5 receptor subunits (Poulter et al., 1997; Hutcheon et al., 2000).Similarly, a recent study by Vicini et al. (2001) has shown thatknocking out the $alpha$ 1 subunit prevents the functional maturationof inhibitory synapses characterized by the development of thefast phase ofdeactivation.

Thus, immature $alpha$ 3 and $alpha$ 5 subunits that are highly expressed in perirhinal cortex of seizure-prone rats may not be recruitedefficiently into synapses, resulting in lower peak mIPSC amplitudes.Neurons may have specialized synaptic anchoring proteins for receptorscontaining the $alpha$ 1 subunit and cannot efficiently harbor receptorswith immature $alpha$ subunit combinations. Conversely, the relativelylarger amplitudes of mIPSCs observed in seizure-resistant ratsare probably caused by synapses with higher than normal densitiesof GABA_A receptors. This could simply reflect a higher abundanceof the preferred $alpha$ 1-containing receptors available for inclusionin the synapses, because the $alpha$ 1 subunit is upregulated in theperirhinal cortex of seizure-resistant rats. Alternatively, theturnover rate of these receptors may be faster (in seizure-prone)or slower (in seizure-resistant), disfavoring or favoring theaccumulation of receptors in synapticsites.

It is thought that inhibitory networks play a central role in regulating neural network excitability and timing (Whittingtonet al., 1995; Wang and Buzsaki, 1996). In this context, we foundmajor differences in the inhibitory synapses on nonpyramidal neuronsin the seizure-prone rats, which may account for the previouslyreported strain differences in seizure genesis (Racine et al.,1999). Specifically, differences in the time course of inhibitionon the interneurons in seizure-prone rats could have three effectsthat contribute to seizure genesis: (1) longer-lasting mIPSCsshould summate more efficiently, leading to disinhibition of theprincipal cells and a collapse of network inhibition (Nusser etal., 1998); (2) more slowly decaying IPSCs on the nonpyramidalpopulation would slow interneuron firing and thus slow the oscillationsof the cortical networks (compared with normal or seizure-resistantrats), as reported for IPSCs on interneurons in the hippocampus(Whittington et al., 1995); and/or (3) strain-related timing differencesin IPSCs could differentially interact with action potentialsconveyed electrically through gap junctions to hamper or facilitatesynchronous firing among interneurons (Tamas et al., 2000). Italso interesting to note that the time course of summated inhibitionis well matched between pyramidal and nonpyramidal neurons inboth the normal and seizure-resistant rats but not in the seizure-pronerats. This suggests that a mismatch in inhibitory timing may favorseizure generation as well. Thus, inhibition in the seizure-proneand seizure-resistant strains has attributes that predict differenttiming patterns and efficacy of network entrainment and synchrony.However, because our results are correlative, like other reportson GABA_A receptor expression and epilepsy (Shumate et al., 1998;Sperk et al., 1998; Brooks-Kayal et al., 1999; Loup et al., 2000),it is not known which if any of these mechanisms play a role inseizuregenesis.

In summary, we have shown in seizure-prone rats, which normally kindle twice as fast as normal rats and up to 10 times fasterthan seizure-resistant rats (Racine et al., 1999), that GABA_Areceptor-mediated mIPSCs are smaller in amplitude but longer intime course than those in either normal or seizure-resistant rats.These differences are most pronounced in the nonpyramidal neuronsof seizure-prone rats and the pyramidal neurons of seizure-resistantrats. These observations suggest, therefore, that the selectivebreeding has emphasized processes that localize and choose GABA_Areceptor subunits for insertion into synapses of perirhinal cortexexcitatory and inhibitory neurons. Although these data are purelycorrelational, they still strongly suggest that one genetic faultresponsible for fast epileptogenesis in the seizure-prone strainis the retarded development of expression of $alpha$ subunits for theGABA_A receptor, particularly on nonpyramidal neurons. It shouldbe emphasized that the rats used in these studies were seizurefree, and therefore, the observed differences speak primarilyto the propensity to develop seizures and not necessarily to endpoints reflecting the epileptic state. Extrapolating from thesedata to humans suggests that the pathogenesis of TLE may be morerelated to the timing of GABAergic inhibition than to the totalamount of inhibition received. Finally, in an important parallelobservation, we have reported previously that our seizure-pronerats behaviorally exhibit deficits in attention, with mild hyperactivityand strong impulsivity, in a variety of tests (McIntyre and Anisman,2000). Because attention-deficit hyperactivity with impulsivityin children is strongly associated with epilepsy (>20% of cases)compared with otherwise normal children (<2% of cases), the differencesin inhibitory control shown here may point to the pathogenesisof other related disorders aswell.

  FOOTNOTES

Received April 12, 2002; revised June 21, 2002; accepted Aug. 21, 2002.

This work was supported by the National Research Council of Canada and by the Canadian Institutes of HealthResearch.

Correspondence should be addressed to Dr. M. O. Poulter, Associate Professor, Neuroscience Research Institute, Departmentof Psychology, Carleton University, 1125 Colonel By Drive, Ottawa,Ontario, Canada, K1S 5B6. E-mail: michael_poulter{at}carleton.ca.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Angelotti TP, Macdonald RL (1993) Assembly of GABA_A receptor subunits: $alpha$ 1 $beta$ 1 and $alpha$ 1 $beta$ 1 $gamma$ 2S subunits produce unique ion channels with dissimilar single-channel properties. J Neurosci 13:1429-1440[Abstract].
Brickley SG, Cull-Candy SG, Farrant M (1996) Development of a tonic form of synaptic inhibition in rat cerebellar granule cells resulting from persistent activation of GABA_A receptors. J Physiol (Lond) 497:753-759[ISI][Medline].
Brooks-Kayal AR, Shumate MD, Jin H, Rikhter TY, Coulter DA (1998) Selective changes in single cell GABA_A receptor subunit expression and function in temporal lobe epilepsy. Nat Med 4:1166-1172[ISI][Medline].
Brooks-Kayal AR, Shumate MD, Jin H, Lin DD, Rikhter TY, Holloway KL, Coulter DA (1999) Human neuronal GABA_A receptors: coordinated subunit mRNA expression and functional correlates in individual dentate granule cells. J Neurosci 19:8312-8318[Abstract/Free Full Text].
Burgard EC, Haas KF, Macdonald RL (1999) Channel properties determine the transient activation kinetics of recombinant GABA_A receptors. Brain Res Mol Brain Res 73:28-36[Medline].
Dominguez-Perrot C, Feltz P, Poulter MO (1995) Recombinant GABA_A receptor desensitization: the role of the $gamma$ 2 subunit and its physiological significance. J Physiol (Lond) 497:145-159[ISI][Medline].
Dunning DD, Hoover CL, Soltesz I, Smith MA, O'Dowd DK (1999) GABA_A receptor-mediated miniature postsynaptic currents and alpha-subunit expression in developing cortical neurons. J Neurophysiol 82:3286-3297[Abstract/Free Full Text].
Ferland RJ, Nierenberg J, Applegate CD (1998) A role for the bilateral involvement of perirhinal cortex in generalized kindled seizure expression. Exp Neurol 151:124-137[Medline].
Fritschy JM, Mohler H (1995) GABA_A-receptor heterogeneity in the adult rat brain: differential regional and cellular distribution of seven major subunits. J Comp Neurol 359:154-194[ISI][Medline].
Galarreta M, Hestrin S (1997) Properties of GABA_A receptors underlying inhibitory synaptic currents in neocortical pyramidal neurons. J Neurosci 17:7220-7227[Abstract/Free Full Text].
Gingrich KJ, Roberts WA, Kass RS (1995) Dependence of the GABA_A receptor gating kinetics on the $alpha$ -subunit isoform: implications for structure-function relations and synaptic transmission. J Physiol (Lond) 489:529-543[ISI][Medline].
Gloor P (1991) Neurobiological substrates of ictal behavioral changes. Adv Neurol 55:1-34[Medline].
Haas KF, Macdonald RL (1999) GABA_A receptor subunit $gamma$ 2 and $delta$ subtypes confer unique kinetic properties on recombinant GABA_A receptor currents in mouse fibroblasts. J Physiol (Lond) 514:27-45[Abstract/Free Full Text].
Huntsman MM, Huguenard JR (2000) Nucleus-specific differences in GABA_A-receptor-mediated inhibition are enhanced during thalamic development. J Neurophysiol 83:350-358[Abstract/Free Full Text].
Hutcheon B, Morley P, Poulter MO (2000) Developmental change in GABA_A receptor desensitization kinetics and its role in synapse function in rat cortical neurons. J Physiol (Lond) 522:3-17[Abstract/Free Full Text].
Kelly ME, McIntyre DC (1996) Perirhinal cortex involvement in limbic kindled seizures. Epilepsy Res 26:233-243[ISI][Medline].
Lavoie AM, Tingey JJ, Harrison NL, Pritchett DB, Twyman RE (1997) Activation and deactivation rates of recombinant GABA_A receptor channels are dependent on a $alpha$ -subunit isoform. Biophys J 73:2518-2526[Abstract/Free Full Text].
Loup F, Wieser HG, Yonekawa Y, Aguzzi A, Fritschy JM (2000) Selective alterations in GABA_A receptor subtypes in human temporal lobe epilepsy. J Neurosci 20:5401-5419[Abstract/Free Full Text].
McClellan AM, Twyman RE (1999) Receptor system response kinetics reveal functional subtypes of native murine and recombinant human GABA_A receptors. J Physiol (Lond) 515:711-727[Abstract/Free Full Text].
McIntyre DC, Anisman H (2000) Anxiety and impulse control in rats selectively bred for seizure sensitivity. In: Contemporary issues in modeling psychopathology (Mysblodsky M, Weiner I, eds). New York: Kluwer Academic.
McIntyre DC, Kelly ME, Dufresne C (1999) FAST and SLOW amygdala kindling rat strains: comparison of amygdala, hippocampal, piriform and perirhinal cortex kindling. Epilepsy Res 35:197-209[Medline].
Neelands TR, Greenfield Jr LJ, Zhang J, Turner RS, Macdonald RL (1998) GABA_A receptor pharmacology and subtype mRNA expression in human neuronal NT2-N cells. J Neurosci 18:4993-5007[Abstract/Free Full Text].
Nusser Z, Hajos N, Somogyi P, Mody I (1998) Increased number of synaptic GABA_A receptors underlies potentiation at hippocampal inhibitory synapses. Nature 395:172-177[Medline].
Okada M, Onodera K, Van RC, Sieghart W, Takahashi T (2000) Functional correlation of GABA_A receptor $alpha$ subunits expression with the properties of IPSCs in the developing thalamus. J Neurosci 20:2202-2208[Abstract/Free Full Text].
Poulter MO, Ohannesian L, Larmet Y, Feltz P (1997) Evidence that GABA_A receptor subunit mRNA expression during development is regulated by GABA_A receptor stimulation. J Neurochem 68:631-639[ISI][Medline].
Poulter MO, Brown LA, Tynan S, Willick G, Williams R, McIntyre DC (1999) Differential expression of $alpha$ 1, $alpha$ 2, $alpha$ 3, and $alpha$ 5 GABA_A receptor subunits in seizure-prone and seizure-resistant rat models of temporal lobe epilepsy. J Neurosci 19:4654-4661[Abstract/Free Full Text].
Racine R, Steingert MO, McIntyre DC (1999) Development of kindling-prone and kindling-resistant rats: selective breeding and electrophysiological studies. Epilepsy Res 35:183-195[ISI][Medline].
Schwartzkroin PA (1998) GABA synapses enter the molecular big time. Nat Med 4:1115-1116[ISI][Medline].
Shumate MD, Lin DD, Gibbs JW, Holloway KL, Coulter DA (1998) GABA_A receptor function in epileptic human dentate granule cells: comparison to epileptic and control rat. Epilepsy Res 32:114-128[ISI][Medline].
Sperk G, Schwarzer C, Tsunashima K, Kandlhofer S (1998) Expression of GABA_A receptor subunits in the hippocampus of the rat after kainic acid-induced seizures. Epilepsy Res 32:129-139[ISI][Medline].
Tamas G, Buhl EH, Lorincz A, Somogyi P (2000) Proximally targeted GABAergic synapses and gap junctions synchronize cortical interneurons. Nat Neurosci 3:366-371[ISI][Medline].
Tia S, Wang JF, Kotchabhakdi N, Vicini S (1996) Developmental changes of inhibitory synaptic currents in cerebellar granule neurons: role of GABA_A receptor $alpha$ 6 subunit. J Neurosci 16:3630-3640[Abstract/Free Full Text].
Traub RD, Jefferys JGR, Whittington MA (1999) In: Fast oscillations in cortical circuits. Boston: MIT Press.
Verdoorn TA (1994) Formation of heteromeric $gamma$ -aminobutyric acid type A receptors containing two different $alpha$ subunits. Mol Pharmacol 45:475-480[Abstract].
Verdoorn TA, Draguhn A, Ymer S, Seeburg PH, Sakmann B (1990) Functional properties of recombinant rat GABA_A receptors depend upon subunit composition. Neuron 4:919-928[ISI][Medline].
Vicini S, Ferguson C, Prybylowski K, Kralic J, Morrow AL, Homanics GE (2001) GABA_A receptor $alpha$ 1 subunit deletion prevents developmental changes of inhibitory synaptic currents in cerebellar neurons. J Neurosci 21:3009-3016[Abstract/Free Full Text].
Wang XJ, Buzsaki G (1996) $gamma$ oscillation by synaptic inhibition in a hippocampal interneuronal network model. J Neurosci 16:6402-6413[Abstract/Free Full Text].
Whittington MA, Traub RD, Jefferys JG (1995) Synchronized oscillations in interneuron networks driven by metabotropic glutamate receptor activation. Nature 373:612-615[Medline].
Zhu WJ, Vicini S, Harris BT, Grayson DR (1995) NMDA-mediated modulation of GABA type A receptor function in cerebellar granule neurons. J Neurosci 15:7692-7701[Abstract].

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