Partial Hippocampal Kindling Decreases Efficacy of Presynaptic GABAB Autoreceptors in CA1

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Volume 17, Number 23, Issue of December 1, 1997

Partial Hippocampal Kindling Decreases Efficacy of Presynaptic GABA_B Autoreceptors in CA1

Chiping Wu and L. Stan Leung
Department of Clinical Neurological Sciences and Physiology, University of Western Ontario, London, Ontario, Canada N6A 5A5

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The effect of partial hippocampal kindling, a model of temporal lobe seizure, on monosynaptic inhibition mediated by GABAwas studied. Kindled rats were given 15 nonconvulsive hippocampalafterdischarges, and control rats were given low frequency orno stimulations. At 1-2 d after kindling, paired-pulse depression(PPD) of the IPSCs recorded in CA1 neurons in vitro was significantlysmaller in kindled as compared with control rats. The differencein PPD persisted for at least 21 d after kindling. The decreasein PPD of the IPSCs after partial hippocampal kindling was likelycaused by a reduced GABA autoinhibition after downregulation ofpresynaptic GABA_B receptors. The GABA_B antagonist CGP35348 (1mM) suppressed PPD of the IPSCs more strongly in control thanin kindled rats. Direct activation of the presynaptic GABA_B receptorsby baclofen suppressed the monosynaptic IPSCs significantly morein control than in kindled rats. The decay rate of a single-pulseIPSC was faster in kindled than in control rats on day 1 or day21 after partial kindling. The difference in IPSC decay betweenkindled and control rats was found with or without a GABA_B receptorantagonist. The low efficacy of the presynaptic GABA_B receptorsin kindled rats may provide compensatory stabilization of thepostsynaptic membrane against further seizures or plasticity.
Key words: inhibitory postsynaptic current; presynaptic inhibition; GABA_B receptors; paired-pulse depression; kindling; seizures; hippocampus

INTRODUCTION

The modulation of inhibition mediated by GABA is important for normal brain functions (Krnjevi $c'$ , 1991). A local and transientloss of inhibition may mediate physiological plasticity and memorystorage (Davies et al., 1991; Mott and Lewis, 1991; Wilson andMcNaughton, 1993; Buzsaki et al., 1994). GABAergic interneuronsare subjected to various local and extrinsic control (Freund andBuzsaki, 1996). In addition, GABA release is controlled by autoinhibitionvia presynaptic GABA_B receptors (Deisz and Prince, 1989; Thompsonand Gahwiler, 1989; Davies et al., 1990, 1991; Nathan and Lambert,1991; Silvilotti and Nistri, 1991; Bowery, 1993; Lambert and Wilson,1994; Olpe et al., 1994; Pitler and Alger, 1994; Misgeld et al.,1995; Kaupmann et al., 1997). However, it is not known whetherthe presynaptic GABA_B receptors are themselves regulated by neuronalactivity.

GABA neurotransmission has long been associated with seizure activity. GABA_A antagonists induce seizures (Gale, 1992; Schwartzkroin,1993), and drugs that enhance GABA neurotransmission are effectiveanticonvulsants (Macdonald and McLean, 1986). Acute seizures suppressGABA function (Stelzer et al., 1987; Kapur et al., 1989). However,a decrease of GABA function in chronic epilepsy is still controversial(Babb et al., 1989; Engel, 1995).

In the kindling model of epilepsy, repeated stimulations are delivered to the brain that progressively evoke longer afterdischarges(ADs) and more severe convulsions (Goddard et al., 1969; McNamaraet al., 1993). Full kindling refers to stimulations that evokedgeneralized tonic-clonic convulsions, whereas partial kindlingevoked no convulsions. Partial hippocampal kindling is a goodmodel of human temporal lobe seizures, which may not result inconvulsions. Furthermore, the AD evoked by partial hippocampalkindling was mainly restricted to structures closely connectedto the hippocampus (Leung et al., 1997), and no cell loss wasdetected (Cavazos et al., 1994). After hippocampal or amygdalakindling, paired-pulse inhibition of population spikes was increasedin the dentate gyrus (Tuff et al., 1983; Oliver and Miller, 1985a;Zhao and Leung, 1992) but decreased in CA1 (Kamphuis et al., 1988;Zhao and Leung, 1991). The different paired-pulse response inthe dentate gyrus and CA1 after kindling is consistent with thechange in GABA_A receptor binding (Titulaer et al., 1994, 1995),but not with the change in GABA immunoreactivity (Kamphuis etal., 1989) or GABA release (Kamphuis et al., 1991). In addition,EPSPs showed an increase in paired-pulse facilitation after kindling(Zhao and Leung, 1991, 1993).

The purpose of this study was to characterize the paired-pulse monosynaptic inhibitory response. At the time we began ourstudy, the effect of kindling on monosynaptic inhibition and GABAautoinhibition was not known. Recently, Buhl et al. (1996) founda decrease in paired-pulse depression (PPD) of the IPSCs in dentategyrus granule cells after full kindling of the perforant path.This study documents a similar finding in CA1 neurons after partialhippocampal kindling. In addition, we show that the kindling-induceddecrease in PPD of the IPSCs was specifically mediated by a downregulationof presynaptic GABA_B autoreceptors and lasted 3 weeks after partialkindling.

A brief summary of the work has been published previously (Wu and Leung, 1996; Leung et al., 1997).

MATERIALS AND METHODS
The kindling procedures and the in vitro slice preparation were reported previously (Leung et al., 1994). Briefly, repeatedelectrical stimulations were delivered through chronic, indwellingelectrodes implanted in stratum radiatum of hippocampal CA1 ofmale Long-Evans rats. Experimental rats were given the kindlingstimulus (1 sec, 100 Hz, pulses of 0.1 msec). About half of thecontrol rats were given low-frequency stimulations (LFSs), eachconsisting of 100 pulses at 0.167 Hz, and the others were implantedwith electrodes but not given any stimulations. There was no significantdifference between the responses of the two types of control rats,and their data were combined into a single control group. ADs/LFSswere given hourly, 5 per day, for a total of 15 ADs/LFSs in 3d.

On day 1-2 (day 1 group) or day 21-23 (day 21 group) after the last kindling or control treatment, the rat was anesthetizedwith halothane and decapitated. Most kindled and control ratswere paired, and the experiments were done on consecutive days,with the experimenter unaware of the stimulation history of eachrat. The hippocampus on the stimulated side was dissected outand 400-µm-thick transverse slices were obtained from the midseptotemporallevel (Leung et al., 1994). The slices were placed in an interfacechamber and perfused with artificial cerebrospinal fluid at 32± 1°C of the following composition (in mM): NaCl 124, KCl 5, NaH₂PO₄.H₂O1.25, MgSO₄.7 H₂O 2, CaCl₂.6 H₂O 2, NaHCO₃ 26, and glucose 10.A concentric bipolar stimulating electrode was placed in stratumradiatum in CA1 (on the CA3 side) ~0.3 mm from the recording site.Sharp micropipettes (3 M potassium acetate; impedance 60-100 M $Omega$ )were used to impale CA1 neurons in the pyramidal cell layer. QX-314(167 mM) was added to the potassium acetate in the micropipetteto block fast Na⁺ channels (Connors and Prince, 1982; Leung and Yim, 1991) andGABA_B responses (Nathan et al., 1990; Andrade, 1991; Otis andMody, 1992). To isolate the IPSC without excitation, an NMDA antagonistD-2-amino-5-phosphonopentanoic acid (D-AP5; 20 µM) and a non-NMDAantagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 20 µM)were added to the perfusate. Single-electrode voltage clamp wasmade by an Axoclamp 2A amplifier at 4.5-5.0 kHz switching frequency,and the voltage before the sample-and-hold device was monitoredto ensure that the transients had decayed before being sampled.Because inhibitory synapses were predominantly located near thecell body, lack of space clamp (Rall and Segev, 1985) was nota significant problem. Paired-pulse stimulations were given at0.12 Hz, 2 or 4 × threshold intensity (0.2 msec duration), andan interpulse interval (IPI) of 50-500 msec, with the cell clampedat a potential of $-$ 40 to $-$ 120 mV. The threshold intensity wasdetermined as the lowest intensity that evoked a detectable fieldresponse in each slice before the perfusion of glutamate antagonists,and typically only one (occasionally two) neuron was recordedper slice. The potentials were amplified, digitized at 10 KHz,averaged (n = 4), and stored on line by a custom program. In someexperiments, GABA_B receptor antagonist CGP35348 (1 mM) or GABA_Breceptor agonist baclofen (1-10 µM) was added to the medium containingCNQX and D-AP5.

In voltage clamp, PPD was evaluated by the ratio of the peak of the IPSC evoked by the second pulse divided by that evokedby the first pulse. All IPSC measures were evaluated at $-$ 50 mVholding potential if not otherwise specified. In current clamp,PPD was evaluated by the ratio of the peak IPSP evoked by thesecond pulse to that evoked by the first pulse. The reversal potentialof the IPSC was estimated by a linear interpolation of the twoIPSCs (recorded every 10 mV of the holding potential) yieldingpositive and negative responses, respectively. The latter reversalpotential was within a few millivolts of the estimate given bylinear regression analysis of the IPSC versus the holding potential(range $-$ 50 to $-$ 100 mV).

Statistical differences between measures in different groups were tested by a nonparametric Wilcoxon test, using either cellsor rats as the basic unit. For "per cell" statistics, all of thecells studied were included; however, to minimize bias from asingle rat, no more than four cells were selected from the samerat. For the "per rat" statistics, the average measure for allof the cells recorded for one rat (n = 1-6 cells) was used, andthe sample number was the number of rats. In experiments in whichrepeated time measures were made, e.g., after drug perfusion,a repeated-measure ANOVA was applied, followed by post hoc t tests.

The half-peak durations of the IPSC1 [t_0.5(1)] and IPSC2 [t_0.5(2)] was estimated as the time interval from the onset of anIPSC (~2.4 msec after a stimulus) to the time the IPSC decayedto half the peak value. The falling phase of the IPSC was fittedby a single exponential IPSC(t) = I_o e^t/, with initial amplitude I_o and time constant $tau$ . The time constantsof the first- and second-pulse-evoked IPSC were named $tau$ 1 and $tau$ 2respectively; the values reported here were derived from regressionyielding R² > 0.85. In most neurons, the single exponential decay was ableto fit the IPSC well for a duration of 80 msec after the IPSCpeak, and reducing the fitted duration did not substantially change $tau$ . In some neurons (~15%), the $tau$ value was estimated using a IPSCduration of 50-80 msec, if the shorter duration improved the fit(as estimated by R²).

A nonparametric technique was also used to compare IPSC durations between ensemble of neurons recorded in different conditions.The mean IPSC of each recorded neuron was normalized by the firstIPSC peak, and then the normalized IPSCs from different neuronswere averaged at fixed times (0.1 msec bins for 250 msec duration).The ensemble SEM at each bin was also calculated. Because theIPSCs from different neurons were triggered at a fixed time bya digital pulse generator (Master 8, A.M.P.I., Jerusalem), theirstimulation pulses were precisely lined up in time. When the ensembleaverages of two conditions were compared, the lack of overlapbetween the SEMs of the two ensembles (compare Fig. 2) suggestsa statistical difference between the ensembles, which was moreprecisely evaluated by a repeated-measure ANOVA followed by apost hoc t test, using samples at every 5-10 msec intervals.
Fig. 2. Ensemble averages of IPSCs from neurons recorded in CNQX and D-AP5 medium. For each pair of traces, the top trace is the ensemblemean + 1 SEM and the bottom trace is the ensemble mean $-$ 1 SEM.The kindled group is blue, and the control group is red. Day 1(A) and day 21 (B) averages of kindled and control groups, withoutGABA_B antagonist CGP35348. C, Day 1 groups recorded with CGP35348.All IPSCs were recorded using 2 × threshold stimulus intensity,100 msec interpulse interval, and $-$ 50 mV holding potential. Foreach neuron, the recorded trace was normalized by the first-pulseIPSC peak, and then all neurons in the same group were combinedin the ensemble average (see Materials and Methods). Number ofneurons in kindled (K) and control (C) groups: A, C = 14, K =16; B, C = 11, K = 18; C, C = 17, K = 17. Note faster decay ofthe first-pulse IPSC in the kindled as compared with control groupunder all conditions.
[View Larger Version of this Image (28K GIF file)]

RESULTS

Kindling and CA1 cell characteristics
The duration of the hippocampal AD, recorded in the homotopic CA1 contralateral to the stimulated CA1, increased with thenumber of ADs delivered, similar to previous results (Leung etal., 1994, their Fig. 1). In the group of nine kindled rats usedfor day 1 recordings (data in Table 1), the first AD measured31.5 ± 4.2 sec (mean ± SEM) and the fifteenth (last) was 93.7± 17.9 sec. The increase in AD duration from the first to thelast AD was statistically significant. Similar results were obtainedin other kindled rats. No behavioral convulsion was observed duringthe ADs.

Table 1. Measures of monosynaptic IPSCs on day 1 after partial kindling or control procedures

2 × threshold
4 × threshold

Kindled (21) Control (16) Kindled (11) Control (13)

Peak IPSC1 (nA) 0.8 ± 0.07 0.98 ± 0.18 0.94 ± 0.13 1.08 ± 0.21

Peak IPSC2 (nA) 0.68 ± 0.07 0.68 ± 0.16 0.81 ± 0.12 0.75 ± 0.18

Paired-pulse depression 0.85 ± 0.03^*** 0.63 ± 0.04 0.85 ± 0.03^** 0.65 ± 0.05

Half-duration IPSC1 46.1 ± 1.7^** 57.7 ± 3.2 31.8 ± 2.1^** 45.5 ± 3.2

  t_0.5(1) (msec)

Half-duration IPSC2 42.6 ± 1.6 42.3 ± 2.0 27.7 ± 1.7 30.4 ± 2.2

  t_0.5(2) (msec)

Time constant IPSC1 35.2 ± 3.3^* 49.9 ± 5.4 (15)

   $tau$ 1 (msec)

Time constant IPSC2 39.9 ± 5.3 44.8 ± 5.9 (15)

   $tau$ 2 (msec)

IPSCs were recorded at $-$ 50 mV holding potential, after paired-pulse stimulation (100 msec interpulse interval) of stratumradiatum in a medium with 20 µM CNQX and 20 µM D-AP5, at either2 × or 4 × threshold stimulus intensity. Paired-pulse depressionwas estimated by the ratio (peak IPSC2/peak IPSC1). ^*** p < 0.001; ^** p < 0.01; ^* p < 0.05 kindled different from control group for the same stimulus intensity.

The resting membrane potential from cells recorded at the CA1 cell layer was $-$ 58.3 ± 0.7 mV (mean ± SEM; n = 138); restingmembrane potential was not different between kindled and controlgroups. The input resistance was 61.5 ± 5.5 M $Omega$ (n = 22). WithQX-314 in the recording micropipette, slow, presumed Ca²⁺ spikes of >10 msec duration could be evoked if a neuron was depolarizedto approximately $-$ 45 mV (Leung and Yim, 1991).

PPD of the IPSCs 1 d after partial hippocampal kindling
Monosynaptic IPSCs/IPSPs were obtained by direct stimulation of the stratum radiatum in the presence of CNQX and D-AP5 (seeMaterials and Methods). The recorded IPSC was mediated by GABA_Areceptors, because it was abolished by GABA_A antagonist bicuculline(not shown). No postsynaptic GABA_B current was detected, and theamplitude of the single-pulse IPSCs was not decreased by GABA_Bantagonist CGP35348 (Fig. 1A). In neurons from control rats recordedafter paired-pulse stimulation, the amplitude and duration ofthe IPSC after the second pulse (IPSC2) was smaller than the respectivemeasure of the first-pulse IPSC (IPSC1) (Fig. 1 A), as reportedpreviously (McCarren and Alger, 1985; Davies et al., 1990; Lambertand Wilson, 1994; Olpe et al., 1994). In control neurons, thePPD ratio (peak IPSC2/peak IPSC1) was 0.63 ± 0.04 (n = 16) atan IPI of 100 msec (holding potential of $-$ 50 mV and using 2 ×threshold intensity stimuli, i.e., 50 ± 1 µA, 0.2 msec durationpulses). In neurons from kindled rats, IPSC2 was strikingly similarin size and duration to IPSC1 (Fig. 1A). PPD was significantlysmaller (p < 0.01) in kindled than in control rats at an IPI of50, 100, and 150 msec but not 500 msec (Fig. 1B; Table 1). Therewas no difference in the stimulus intensities used to evoke theIPSCs in the kindled and control groups. The latency to reachthe IPSC1 or IPSC2 peak did not differ between control and kindledrats (12 ± 1 msec). Also, the peak amplitudes of the monosynapticIPSCs after single-pulse radiatum stimulation were not significantlydifferent (p > 0.3; Wilcoxon) between the two groups (Table 1).
Fig. 1. Kindled seizures reduced PPD of GABA_A mediated IPSCs recorded at a holding potential of $-$ 50 mV. A, Examples of paired-pulseIPSCs in CA1 neurons from control and kindled rat, evoked by stratumradiatum stimuli of 2 × threshold intensity in the presence ofCNQX and D-AP5, before and after perfusion with a CGP35348 (1mM) medium. Peaks of IPSC1 and IPSC2 indicated by peak1 and peak2,respectively. Resting membrane potential of control and "kindled"neuron was $-$ 59 and $-$ 60 mV, respectively. Filled circles indicateshock artifacts. B, Plot of the ratio of the peak IPSC evokedby the second pulse (peak IPSC2) to that evoked by the first pulse(peak IPSC1), in the absence of CGP35348, as a function of interpulseinterval. Error bars are one SEM. Control group (C) = 8 neuronsand kindled group (K) = 10 neurons, except for 500 msec interpulseinterval data, where C = 6 and K = 4 neurons. ** (p < 0.01) indicatessignificant difference between control and kindled groups of neuronsas assessed by the nonparametric Wilcoxon test.
[View Larger Version of this Image (19K GIF file)]

If the stimulus intensity was doubled from 2 to 4 × threshold, IPSCs increased slightly, but the PPD ratio was not significantlychanged (Table 1). The difference between the kindled and controlgroups was also significant (p < 0.01; Wilcoxon) at 4 × thresholdintensity (Table 1).

The time course of the IPSCs appeared to be different in kindled as compared with control rats (Fig. 1A). The duration ofthe IPSC1 [t_0.5(1)] was significantly longer in control than inkindled rats (Table 1). Time constant $tau$ 1 was estimated to be~50 msec in the control group, a value similar to that estimatedby Roepstorff and Lambert (1994) or the slower time constant ofPearce (1993), and significantly larger (p < 0.05) than that inthe kindled group (Table 1). The ensemble averages (normalizedby the peak IPSC1 of each neuron) show that the average IPSC1in the kindled group decayed much more rapidly than that of thecontrol group (Fig. 2A). The ensemble averages of IPSC1 were significantlydifferent from each other at 30-100 msec after the pulse (p <0.05; post hoc t test after significant group, time, and group× time effects with repeated-measure ANOVA). Other than the differencenear the peak of the IPSC2 (10-30 msec after the second pulse),the late time course of the IPSC2 was not different between theensemble averages of the kindled and control groups (p > 0.05;post hoc t test) (Fig. 2A).

The differences between kindled and control groups were robust and were shown using either per cell or per rat statistics(see Materials and Methods). Per rat statistics also revealedsignificant differences between kindled (n = 9) and control rats(n = 9) in the PPD, t_0.5(1), and $tau$ 1 measures.

Current-clamp recordings on day 1 after kindling-control procedures
Some neurons were also recorded in a discontinuous current-clamp mode, and the results were congruent with the voltage clampdata. Radiatum stimulation at a prepulse membrane potential of $-$ 50 mV (maintained by current injection) yielded a ratio of IPSPpeaks that was significantly larger (p < 0.01) in the kindledthan in the control group. Similar results were found at 2 and4 × threshold stimulus intensity (Table 2).

Table 2. Ratio of the IPSP peaks evoked by paired pulses at 100 msec interpulse interval, recorded in discontinuous current clamp modeat $-$ 50 mV membrane potential on day 1 or 21 after kindling/controlprocedures. Stimulation was at either 2 × or 4 × threshold stimulusintensity

2 × threshold
4 × threshold

Kindled Control Kindled Control

Day 1 0.84 ± 0.04 (16)^* 0.67 ± 0.05 (16) 0.82 ± 0.03 (11)^* 0.61 ± 0.05 (15)

Day 21 0.70 ± 0.05 (13) 0.53 ± 0.11 (5)

^* p < 0.01, difference between kindled and control groups.

IPSCs/IPSPs on day 21 after kindling
At 21 d after kindling, neurons from kindled rats also showed significantly smaller PPD than did neurons from control rats(p < 0.01; Fig. 2B). At 100 msec IPI, the PPD ratio was 0.77 ±0.05 (n = 18) in neurons of kindled rats as compared with 0.55± 0.06 (n = 11) in neurons of control rats (Table 3). Interestingly,IPSC1 amplitudes were similar among the day 21 neurons, and meanIPSC2 amplitude was larger in the kindled than the control group(Table 3). However, at 500 msec IPI, no significant differencein PPD was found between kindled and control groups (Table 3).

Table 3. Measures of IPSCs recorded on day 21 after kindling/control procedures at $-$ 50 mV holding potential, in a medium with 20 µMCNQX and 20 µM D-AP5

100 msec IPI
500 msec IPI

Kindled (18) Control (11) Kindled (14) Control (6)

IPSC1 peak (nA) 0.72 ± 0.07 0.69 ± 0.07 0.65 ± 0.08 0.72 ± 0.10

IPSC2 peak (nA) 0.51 ± 0.04^* 0.37 ± 0.05 0.57 ± 0.06 0.60 ± 0.09

Paired-pulse depression 0.77 ± 0.05^** 0.55 ± 0.06 0.90 ± 0.02 0.85 ± 0.05

Half-duration IPSC1 43.8 ± 3.3^** 62.0 ± 4.8 44.1 ± 3.2 66.2 ± 7.6

  t_0.5(1) (msec)

Half-duration IPSC2 32.9 ± 1.3 36.3 ± 1.1 37.8 ± 2.2 50.9 ± 3.1

  t_0.5(2) (msec)

Time constant IPSC1 38.1 ± 4.6^** 64.0 ± 7.2

   $tau$ 1 (msec)

Time constant IPSC2 37.2 ± 4.2^* 60.2 ± 7.5

   $tau$ 2 (msec)

Stimulation was at 2 × threshold stimulus intensity and either 100 or 500 msec interpulse interval (IPI). ^** p < 0.01; ^* p < 0.05, kindled different from control groups for the same IPI.

The difference in IPSC decay between kindled and control rats also persisted 21 d after partial hippocampal kindling (Fig.2B). The measures t_0.5(1), $tau$ 1, and $tau$ 2 were significantly smallerin the kindled than the control group (Table 3). Ensemble averagesof the IPSCs (Fig. 2B) revealed that the decay time course ofIPSC1 or IPSC2 was faster in the kindled than the control groupat >20 msec latency (p < 0.01; post hoc t test after repeated-measureANOVA, which gave significant group, time, and group × time effects).

When statistics per rat were performed, the day 21 kindled rats (n = 6) also showed significantly smaller t_0.5(1), $tau$ 1 (p <0.05; Wilcoxon) than a pooled control group consisting of fiveday 21 control rats and nine day 1 controls. The control ratswere pooled because there was no difference in any measure betweenthe day 21 and day 1 control rats. PPD was also significantlydifferent (p < 0.05) in day 21 kindled rats than in the pooledcontrol rats.

IPSC reversal potentials and holding potentials
The reversal potentials of IPSC1 (RP1) were not significantly different between cells from day 1 kindled (n = 8 cells) andcontrol groups (n = 13 cells) or between day 21 kindled (n = 15)and control groups (n = 12). Similarly, the reversal potentialof IPSC2 (RP2) was not different between kindled and control groups,on either day 1 or day 21. However, when RP2 was compared withRP1 in the same neuron (Fig. 3), RP2 was more positive than RP1by 4.3 ± 1.1 mV (n = 13) in control day 1 neurons and by 2.2 ±0.6 mV in kindled day 1 neurons (n = 8). In the day 1 groups,RP1 and RP2 were 82.3 ± 7.1 mV and 78.3 ± 6.8 mV (n = 13), respectively,in the control group, as compared with 84.0 ± 3.3 mV and 82.9± 3.3 mV (n = 8) in the kindled group. The slight but significant(paired Wilcoxon; p < 0.01) depolarizing shift of RP2 with respectto RP1 was the main reason that PPD appeared to be weaker or absentat holding potentials of $-$ 80 to $-$ 110 mV (Fig. 3A). When the chordconductance of IPSC1 (GI1) and IPSC2 (GI2) was estimated at eachholding potential [by peak IPSC/(holding minus reversal potential)],the paired conductance ratio (GI2/GI1) was similar across holdingpotentials for a particular group of neurons. The conductanceratio (GI2/GI1) was significantly different (p < 0.05) betweenday 1 kindled and control neurons at all holding potentials used( $-$ 50 to $-$ 120 mV). At $-$ 50 mV holding potential, the conductanceratio was ~15% higher than peak IPSC ratio, but the differencebetween day 1 kindled and control groups was similarly robust(p < 0.001) using either ratio of conductances or ratio of peakcurrents.
Fig. 3. Average IPSC (n = 4 sweeps) versus voltage relation, in a medium with CNQX and D-AP5 but without CGP35348, at $-$ 50 to $-$ 110mV holding potentials for a neuron from (A) day 1 control and(B) day 1 kindled rat. Outward rectification was seen in bothneurons. A depolarizing shift of the reversal potential for IPSC2as compared with IPSC1 is shown in A. At all holding potentials,PPD of the IPSCs was observed in A but not in B.
[View Larger Version of this Image (27K GIF file)]

Effect of GABA_B antagonist on paired IPSCs
To investigate the role of presynaptic GABA_B receptors in the PPD of IPSCs, GABA_B receptor antagonist CGP35348 (1 mM) wasadded to the medium with CNQX and D-AP5. Recordings were made1 d after kindling and control procedures. In a medium with CGP35348,the mean PPD at 100 msec IPI was slightly smaller in the kindledas compared with the control group (Fig. 2C; Table 4), but thedifference between groups was not statistically significant (p= 0.09).

Table 4. IPSC measures recorded in a CGP35348 (1 mM) medium with CNQX and D-AP5, 1 day after kindling/control procedures, using 100msec interpulse interval and $-$ 50 mV holding potential, at 2 ×or 4 × threshold stimulus intensity

2 × threshold
4 × threshold

Kindled (17) Control (17) Kindled (16) Control (15)

Peak IPSC1 (nA) 0.99 ± 0.09 0.92 ± 0.10 1.00 ± 0.07 0.89 ± 0.10

Peak IPSC2 (nA) 0.94 ± 0.08 0.76 ± 0.08 0.93 ± 0.07 0.75 ± 0.09

Paired-pulse depression 0.96 ± 0.02 0.89 ± 0.04 0.92 ± 0.03 0.86 ± 0.03

Half-duration IPSC1 45.0 ± 3.3^* 58.7 ± 3.5 49.7 ± 3.4 56.2 ± 2.6

  t_0.5(1) (msec)

Half-duration IPSC2 49.1 ± 3.4 55.6 ± 1.5 51.7 ± 2.2 54.7 ± 2.0

  t_0.5(2) (msec)

Time constant IPSC1 30.0 ± 2.9 (16)^** 53.1 ± 6.1

   $tau$ 1 (msec)

Time constant IPSC2 33.1 ± 2.6 (16)^* 61.9 ± 6.4

   $tau$ 2 (msec)

^** p < 0.01; ^* p < 0.05 kindled different from control group for the same stimulus intensity.

The faster IPSC decay in the kindled than in the control group of neurons persisted in a medium with CGP35348. In the lattermedium, t_0.5(1) and $tau$ 1 were significantly different between kindledand control groups (Table 4), and in addition, a significantdifference was found for $tau$ 2 (Table 4). Significant differences(p $<=$ 0.05; Wilcoxon) in t_0.5(1), $tau$ 1, and $tau$ 2 between kindled (n= 6 rats) and control (n = 8 rats) groups were also found if perrat statistics were used.

The ensemble averages (Fig. 2C) reveal the differences graphically. The IPSC1 ensemble averages of control and kindled groupswere statistically different at 20-100 msec after the first pulse(p < 0.01; post hoc t test, after repeated-measure ANOVA revealedsignificant group, time, and group × time effects). In a mediumwith CGP35348, IPSC2 ensemble averages were also different betweencontrol and kindled groups at 20-140 msec after the second pulse(p < 0.01; post hoc t test after repeated-measure ANOVA yieldingsignificant group, time, and group × time effects).

Single neurons were assessed before, during, and after washout of 1 mM CGP35348 (Fig. 1A). In the day 1 control group, CGP35348decreased PPD and increased IPSC2 duration in all five neurons(Fig. 1A; p < 0.05; paired Wilcoxon). In the same group, CGP35348had no consistent effect on IPSC amplitudes, but it increased $tau$ 1 or t_0.5(1) in four of five neurons (Fig. 1A; 0.05 < p < 0.1).In eight neurons from the day 1 kindled group, CGP35348 decreasedPPD significantly (p < 0.05; Fig. 1A), although the PPD decreasewas smaller than that in the control group. This suggests thatthe GABA_B antagonist was still effective in blocking autoinhibitionin the kindled group, but its effect was reduced as compared withthe control group. CGP35348 increased t_0.5(1) and $tau$ 1 significantly(p < 0.05) in the day 1 kindled group of neurons.

Effects of GABA_B agonist baclofen on paired IPSCs
A decrease in GABA release and an increase in uptake may limit the activation of the presynaptic GABA_B receptors (Isaacsonet al., 1993; Roepstorff and Lambert, 1994). Thus, the GABA_B agonistbaclofen (10 µM in the bath) was used to directly activate thepresynaptic GABA_B receptors (Davies et al., 1990; Thompson andGahwiler, 1992; Misgeld et al., 1995). Baclofen reduced IPSC1in neurons from both control and kindled rats, but the reductionwas significantly stronger in control than in kindled rats (Fig.4A). The effect of baclofen was detected at 5 min after perfusionand was near maximal by 10 min (Fig. 4B). At 15 min after baclofen,the peak IPSC1 of the control group was 23 ± 3% of the baseline(seven neurons), whereas that of the kindled group was 44 ± 5%(nine neurons) (Fig. 4B). The effect of baclofen was predominantlyon presynaptic inhibition because QX-314 in the micropipette alreadyblocked the postsynaptic GABA_B conductance (Nathan et al., 1990;Andrade, 1991).
Fig. 4. Partial hippocampal kindling reduced the effect of GABA_B agonist baclofen in suppressing IPSCs. A, Examples of paired-pulseIPSCs in CA1 neurons from control and kindled rat, recorded at $-$ 50 mV holding potential, before and after the perfusion of 10µM baclofen (added to the CNQX and D-AP5 medium). Resting membranepotential for control and "kindled" neuron was $-$ 60 and $-$ 63 mV,respectively. Filled circles indicate shock artifacts. B, Baclofenreduced the first IPSC in neurons from both kindled and controlrats, but the effect was significantly larger in control as comparedwith kindled rats. C, The difference in the PPD (ratio of IPSCpeaks) between kindled and control rats was abolished after 5min of baclofen perfusion. * (p < 0.05), ** (p < 0.01) indicatesignificant difference between kindled and control groups (Wilcoxon)at a fixed time after baclofen.
[View Larger Version of this Image (13K GIF file)]

Before the perfusion of baclofen, PPD was 0.61 ± 0.04 (n = 7) in control neurons and 0.83 ± 0.01 (n = 9) in "kindled" neurons.The difference in PPD between kindled and control neurons wassignificant (p < 0.01), confirming the result of the earlier experiment(Table 1). Baclofen decreased PPD in control neurons significantlyto 0.92 ± 0.06 (n = 7; repeated-measure ANOVA; p < 0.01), consistentwith the previous literature (Davies et al., 1990; Mott and Lewis,1991). In contrast, baclofen did not significantly change PPDin the kindled rats (Fig. 4C).

DISCUSSION

PPD of IPSCs in CA1
The data on PPD in CA1 neurons in the control rats were in accordance with those reported previously (Davies et al., 1990;Davies and Collingridge, 1993). A notable exception is the findingthat the reversal potential of IPSC2 (RP2) was significantly moredepolarized than that of IPSC1 (RP1) by ~4 mV, similar to theresults of McCarren and Alger (1985). Davies et al. (1990) statedthat PPD "was not associated with any change in reversal potentialof the IPSC," but the resolution of their measures was unclear(see their Fig. 4). At $-$ 50 mV holding potential, the reversalpotential shift contributed ~15% to the PPD, and this relativelysmall contribution did not change the main results of this studyor those of the previous studies (Davies et al., 1990; Daviesand Collingridge, 1993). The shift in reversal potential may indicatea change in intracellular Cl concentration (McCarren and Alger, 1985; Thompson and Gahwiler,1989).

Downregulation of presynaptic GABA_B autoreceptors
As shown previously by Davies et al. (1990), PPD of the IPSC peak amplitudes is mainly a measure of presynaptic inhibitionof GABA release. The larger ratio of paired-pulse IPSC amplitudes(and durations) in kindled as compared with control rats, at day1 or day 21 after partial hippocampal kindling, suggests thatGABA autoinhibition was weaker in kindled than in control rats.We infer that the weaker autoinhibition was mediated by a decreasedefficacy or downregulation of the presynaptic GABA_B receptorson GABA terminals. The PPD of IPSCs in control rats was stronglysuppressed by GABA_B antagonist CGP35348 or GABA_B agonist baclofen(by occlusion), but the PPD of IPSCs in kindled rats was relativelyinsensitive to GABA_B agonist or antagonist. Exogenously appliedGABA_B agonist baclofen suppressed the first-pulse IPSC in controlrats much more than that in kindled rat, confirming that presynapticGABA_B receptor efficacy was reduced in kindled as compared withcontrol rats.

The decrease in presynaptic GABA_B receptor efficacy may be caused by a downregulation of the number of GABA_B receptors ora decrease in the coupling of GABA_B receptors to guanine-nucleotide-bindingproteins (Pitler and Alger, 1994; Misgeld et al., 1995; Kaupmannet al., 1997) or to presynaptic Ca²⁺ currents (Pfrieger et al., 1994; Wu and Saggau, 1997). In thepresence of a GABA_B antagonist, no significant difference in PPDwas detected between kindled and control groups, which does notsuggest a role for non-GABA_B mediated presynaptic inhibition (Lambertand Wilson, 1993; Wilcox and Dichter, 1994).

Effects of GABA_B antagonist and kindling on the IPSC time course
The decay rate of IPSC1 was slowed by GABA_B antagonist CGP35348, whereas the peak amplitude was not consistently changed.CGP35348 has little affinity for the GABA_A receptor (Olpe et al.,1990), and suppression of residual postsynaptic GABA_B currentsdoes not account for the CGP35348 effect, because it should decreaserather than increase the late time course of IPSC1. The mechanismby which CGP35348 slowed the IPSCs is not known. It is possiblethat presynaptic GABA_B inhibition after a single pulse may contributeto a shutdown of further GABA release (20 msec after the afferentstimulus). This is apparently the first time that a GABA_B antagonisthas been shown to affect the kinetics of a single evoked IPSC.It has not been reported before perhaps because of overlap withthe postsynaptic GABA_B currents (Davies et al., 1990; Wan et al.,1996) or a lack of quantitative analysis of the IPSCs.

The decay rate of the IPSC was faster in kindled as compared with control rats, best characterized by smaller $tau$ 1 values inthe kindled than in the control group, and this effect persistedat least 21 d after partial hippocampal kindling. The effect wasfound in the presence of GABA_B antagonist CGP35348, suggestingthat it was independent of GABA_B receptors. The mechanism underlyingthe difference in IPSC decay is not known. The release of GABAmay be less sustained in kindled as compared with control rats.GABA uptake may be increased in the kindled rat, and a changein GABA uptake would affect the decay more than the peak of theIPSC (Isaacson et al., 1993; Roepstorff and Lambert, 1994). Changesin GABA_A receptor subunits or phosphorylation (Stelzer, 1992;Macdonald and Olsen, 1994) may affect the IPSC kinetics, and GABA_Areceptor subunit changes have been reported in CA1 after hippocampalkindling, although the CA1 changes were small and did not lastmore than a few days (Clark et al., 1994; Kokaia et al., 1994;Kamphuis et al., 1995). Otis et al. (1994) found no change inthe time course of miniature IPSCs in dentate granule cells afterfull kindling, but the decay time constant of miniature IPSCs(Collingridge et al., 1984; Ropert et al., 1990; Otis and Mody,1992) is considerably smaller than that of evoked IPSCs (Pearce,1993; Roepstorff and Lambert, 1994; this study).

Effect of kindling on neuronal excitation and inhibition
The loss of presynaptic GABA_B receptor efficacy on GABA terminals after hippocampal kindling may be ubiquitous and pervasive,as suggested by the decrease in PPD of the IPSCs in the dentategyrus after convulsive kindled seizures (Buhl et al., 1996). Becausekindling induces the same change in PPD of the IPSCs but differentchanges of paired-pulse spike response in CA1 and the dentategyrus (see introductory remarks), PPD of IPSCs cannot be the crucialfactor involved in the paired-pulse population spike response.In CA1 neurons in vitro, the magnitude of IPSC2 was not a significantfactor in the generation of an early latency spike after the secondpulse (Leung and Fu, 1994). However, a faster decay of IPSC1 mayaccount partly for the increased paired-pulse facilitation ofthe population spike in CA1 neurons, which persisted for approximately6 weeks after partial hippocampal kindling (Leung et al., 1994).

We found no significant reduction of the peak of the monosynaptic IPSC1 in CA1 neurons after partial kindling. Similarly,Oliver and Miller (1985b) found no change in CA1 neuronal excitabilityduring recurrent inhibition after kindling. Titulaer et al. (1994,1995) reported a decrease in postsynaptic GABA_A receptor bindingof 10-25% in CA1, which may not be manifested in the IPSCs. Thecomplexity of the inhibitory circuitry and its modulation cannotbe determined by the monosynaptic IPSCs alone. Seizures have beensuggested to selectively shut down afferent pathways to the GABAergicinterneuron (Sloviter, 1991; Bekenstein and Lothman, 1993; Manganet al., 1995). Preliminary studies (L. S. Leung and D. Zhao, unpublishedobservations) revealed that partial hippocampal kindling induceda suppression of PPD of disynaptic inhibition but no apparentloss of single-pulse feedforward inhibition.

Significance of GABA_B autoreceptor regulation
This is the first time that neural activity, in this case electrographic seizure, has been shown to regulate autoinhibitionspecifically through the presynaptic GABA_B receptors. Buhl etal. (1996) showed a suppression of PPD of the IPSCs in dentategranule cells 1-2 d after full kindling (15 stage 5 seizures)of the perforant path but did not show the involvement of GABA_Breceptors. Downregulation of presynaptic GABA_B receptors was proposedafter kainic acid seizures, but not for the autoreceptors on GABAergicterminals (Haas et al., 1996). A decrease in efficacy of presynapticGABA_B receptors on glutamatergic terminals was shown in the basolateralamygdala after amygdala kindling (Asprodini et al., 1992) andin CA1 after partial hippocampal kindling (Wu and Leung, 1997).

Presynaptic GABA_B receptors and autoinhibition may be of great but as yet unproven significance (Bowery, 1993; Misgeld etal., 1995). Release studies (Waldmeier et al., 1993) indicatethat "basal release alone already substantially activated theautoreceptor," whereas no clear presynaptic GABA_B effects havebeen demonstrated in vivo (Olpe et al., 1993; Misgeld et al.,1995). An important function of presynaptic GABA_B receptors onGABA terminals may be to regulate the amount of postsynaptic inhibitionand thus control the postsynaptic excitability that may lead toparoxysmal activity (Ben-Ari et al., 1979). Microinfusion of baclofenin the hippocampus of behaving rats induced seizure activity (Vaurioet al., 1996), which may be mediated by disinhibition throughpresynaptic GABA_B receptors or postsynaptic GABA_B receptors oninhibitory interneurons (Mott et al., 1989). The downregulationof GABA_B receptors after seizures (Haas et al., 1996; this study)may thus serve to prevent more seizures and contribute to therefractory period after seizures (Engel, 1995). A possible trade-offis that normal physiological plasticity such as long-term potentiationmay also be blocked (Hesse and Teyler, 1976; Wu and Leung, 1997).

FOOTNOTES

Received June 11, 1997; revised Aug. 29, 1997; accepted Sept. 19, 1997.

This work was supported by National Institutes of Health Grant NS-25383, a grant from Natural Sciences and Engineering ResearchCouncil, and an internal grant from the London Health SciencesCentre. We thank B. Shen, K. Canning, and K. Wu for technicalassistance and Drs. Peter Cain, Peter Carlen, Karen Gale, RickMcLachlan, Steve Sims, and Kevin Canning for comments and discussions.We thank Novartis, Basel, Switzerland, for the gift of CGP35348and Astra (Westborough) for QX-314.

Correspondence should be addressed to Dr. L. Stan Leung, Department of Clinical Neurological Sciences, University Campus,London Health Sciences Centre, The University of Western Ontario,London, Ontario, Canada N6A 5A5.

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