GABAergic and glycinergic IPSCs in Ganglion Cells of Rat Retinal Slices

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Volume 17, Number 16, Issue of August 15, 1997 pp. 6075-6085
Copyright ©1997 Society for Neuroscience

GABAergic and glycinergic IPSCs in Ganglion Cells of Rat Retinal Slices

Dario A. Protti¹, Hersch M. Gerschenfeld², and Isabel Llano¹
¹ Arbeitsgruppe Zelluläre Neurobiologie, Max-Planck-Institut für biophysikalische Chemie, 37070 Göttingen, Germany, and ² Laboratoire de Neurobiologie, Ecole Normale Supérieure, 75005 Paris, France

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

GABAergic and glycinergic IPSCs were studied in identified retinal ganglion cells (RGCs) of light-adapted rat retinal slices,using whole-cell recording techniques. GABAergic IPSCs were blockedspecifically by SR95531 (3 µM) and bicuculline (3 µM) and glycinergicIPSCs by strychnine (0.3 µM). From 37 RGCs studied, 25 showedexclusively GABAergic IPSCs, 6 presented only glycinergic IPSCs,and 6 showed both. This distribution may result from differencesin amacrine cells input rather than from receptor heterogeneity,because both GABA and glycine elicited Cl-selective currents in all RGCs tested. TTX markedly reduced GABAergicIPSCs frequency, whereas glycinergic IPSCs were unaffected. Ca²⁺-free media, with or without high Mg²⁺, blocked TTX-resistant GABAergic and glycinergic IPSCs. Theseresults suggest that GABAergic IPSCs in RGCs can be elicited eitherby Na⁺-dependent action potentials or by local Ca²⁺ influx in medium or large dendritic field GABAergic amacrinecells, whereas glycinergic IPSCs are generated by action potential-independentCa²⁺ influx in narrow field glycinergic amacrine cells. Both typesof IPSCs had fast rise times and biexponential decays, but glycinergicIPSC decay was significantly slower than that of GABAergic IPSCs.An elementary conductance of 54 pS for the glycine-gated channelswas estimated from single-channel events, clearly detected inthe falling phase of glycinergic IPSCs, and from responses toexogenous glycine.
Key words: synaptic currents; GABA; glycine; retina; patch-clamp; neurotransmitter receptors

INTRODUCTION

Two main inhibitory neurotransmitters are involved in the organization of the receptive fields of retinal ganglion cells (RGCs):GABA and glycine (Wässle and Boycott, 1991). Both neurotransmittersare found in mammalian amacrine cells, which in their majorityare presynaptic to RGCs. GABA immunoreactivity (Agardh et al.,1986; Mosinger et al., 1986; Osborne et al., 1986; Mosinger andYazulla, 1987; Vaney and Young, 1988; Chun and Wässle, 1989;Wässle and Chun, 1989; Koontz and Hendrickson, 1990) and uptakeof both [³H]GABA (Pourcho, 1980) and [³H]muscimol (Pourcho, 1980; Pourcho and Goebel, 1983; Wässle etal., 1987) have been detected in amacrine cells. Glutamic aciddecarboxylase (GAD), the GABA-synthesizing enzyme, was found immunocytochemically(Mosinger and Yazulla, 1987; Brecha et al., 1988) and by in situhybridization with GAD mRNA in amacrine cells (Sarthy and Fu,1989). Glycine accumulates in other amacrine cells of mammalianretinas (Marc and Liu, 1985), where it also was detected immunocytochemically(Hendrickson et al., 1988; Davenger et al., 1991; Pourcho andOwarczak, 1991; Koontz et al., 1993).

GABA_A receptor subunits have been localized in RGCs and in the inner plexiform layer, possibly at RGC dendrites (Hughes etal., 1989, 1991; Grünert et al., 1993; Greferath et al., 1994a;Koulen et al., 1996). Glycine receptor subunits also have beenfound at similar sites (Pourcho and Owarczak, 1991; Grünert andWässle, 1993; Greferath et al., 1994b). Moreover, receptors toboth transmitters are segregated spatially in clusters on thesomatodendritic membranes of rat RGCs (Koulen et al., 1996).

On the basis of the effects of strychnine and bicuculline on light-evoked unitary activity of cat RGCs, Saito (1983) proposeda differential distribution of GABAergic versus glycinergic synapsesin the ON versus the OFF pathways. Other work has failed to confirmthese results: GABA and glycine suppressed, whereas strychnineand bicuculline enhanced, the light-evoked responses recordedfrom cat RGCs, regardless of their type (Bolz et al., 1985a,b).Hence, the precise role of inhibitory inputs on RGCs remains highlycontroversial.

More recently, GABA and/or glycine were found to induce currents in cultures of goldfish (Ishida and Cohen, 1988; Cohen etal., 1989; Ishida, 1992) and murine RGCs (Tauck et al., 1988),in isolated rat retinas (Rörig and Grantyn, 1993), and in primateretinal slices (Zhou et al., 1994). The action of both transmitterson RGCs involves a Cl conductance increase (Tauck et al., 1988; Cohen et al., 1989).Nevertheless, with the exception of infrequent GABAergic IPSCsobserved in 5-d-old rats (Rörig and Grantyn, 1993), no studyhas been performed on the GABAergic and glycinergic IPSCs of RGCs.

In the present work we have analyzed GABAergic and glycinergic IPSCs in RGCs of light-adapted rat retinal slices. We havefound marked differences between these two classes of IPSCs concerningtheir time course, their distribution among the ganglion cellpopulation studied, and their sensitivity to tetrodotoxin andremoval of external Ca²⁺ ions. Some of these results have been reported in preliminaryform (Protti et al., 1996).

MATERIALS AND METHODS
Tissue preparation. Vertical slices were prepared from the retinas of adult rats (4-7 weeks old). Animals were anesthetizeddeeply with Metofane (1.4 gm of methoxyflurane and 0.15 mg of2,6-di-tributyl-p-cresol per 120 ml; Janssen GmbH, Russelsheim,Germany) and decapitated. The initial dissection followed theprocedures described by Boos et al. (1993). Briefly, eyes wereenucleated rapidly and transferred to a beaker filled with ice-coldphysiological saline [bicarbonate-buffered saline (BBS); see Solutionsand Drug Application]. After the cornea was cut along the oraserrata, lens and vitreous were removed and the retina was separatedfrom the sclera. Then the retina was cut into four pieces witha scalpel blade, one of the fragments was embedded in 2% agardissolved in BBS (kept at a constant temperature of 38°C), andthe resulting block was cooled rapidly. The block was transferredto a microslicer (Dosaka EM, Kyoto, Japan) where 200-µm-thickslices were cut. The slices were kept at 33°C in BBS for 1 hrbefore their use for electrophysiological recording.

Electrophysiological recordings and analysis. Experiments were performed at 20-23°C with an upright microscope (Zeiss Axioskop,Oberkochen, Germany) equipped with Nomarski differential interferencecontrast optics and a water immersion objective (63×, 0.9 numericalaperture). The criteria for RGCs identification will be describedin Results. The dissection, as well as the incubation and recording,was done under laboratory light conditions. Consequently, theretinal slices were light-adapted. Nevertheless, light responseswere observed on some occasions. The recording chamber was perfusedat a rate of 1-1.5 ml/min with BBS.

All of the experiments were performed with the tight-seal whole-cell recording (wcr) configuration of the patch-clamp technique(Hamill et al., 1981). Seal formation was achieved without previouscleaning of the neuronal surface by maintaining a moderate positivepressure in the pipette while approaching the cell. Recordingswere performed with an EPC-9 amplifier and borosilicate glasspipettes having resistances of 3.5-5 M $Omega$ when filled with Cl-containing intracellular solution (S1; see below). Pipettes werecoated with dental wax to decrease their capacitance. In wcr,capacitive currents were canceled, and series resistance compensationwas applied in the range of 60-80%. Only cells with uncompensatedR_s $<=$ 20 M $Omega$ were used in this study. The average capacitance ofRGCs was 5.03 ± 0.55 pF, and their input resistance, when dialyzedwith a CsCl solution (S1; see below), was 2.95 ± 0.15 G $Omega$ (n =42; mean ± SEM). Membrane potential values were corrected forliquid junction potentials.

For the study of effects of various drugs on IPSCs parameters, membrane currents were recorded in control saline for 4 min,the bath was exchanged to the drug containing solution, and dataacquisition was interrupted during 3-4 min to allow for completeequilibration of the test solution within the slice. After thisperiod, data acquisition continued. In general, we acquired 4min of data in each experimental condition.

Membrane currents were digitized on-line at 200 µsec/point and stored in disk for subsequent analysis. Detection and analysisof IPSCs were performed with a program written by Dr. P. Vincent,as described in Vincent and Marty (1993). Unless otherwise noted,a detection threshold of 7-10 pA was used. Each detected eventwas inspected visually to discard from the analysis glutamatergicsynaptic currents, which were characterized by a decay time constantof the order of 1 msec (see Results). Amplitude distributionsof IPSCs were constructed from the events with IGOR software (WaveMetrics,Lake Oswego, OR). Noise histograms were produced from events-freesections of the recordings; 1000 measurements of the differencein mean current between two 1 msec segments, separated by 1.5msec, were taken at random positions in the recording; the resultingdistribution was scaled to the peak number of events of the datahistogram. For the analysis of IPSCs decay, individual eventswere aligned at their onset, averaged, and fit by a double-exponentialfunction. All data point histograms of single-channel currentsand the corresponding fits with gaussian functions were performedwith IGOR software. Statistical values are given as the mean ±SEM.

Solutions and drug application. The standard external solution (BBS) consisted of (in mM): 125 NaCl, 2.5 KCl, 2 CaCl₂, 1 MgCl₂,1.25 NaH₂PO₄, 26 NaHCO₃, and 10 glucose (pH of 7.4 when equilibratedwith a mixture of 95% O₂/5% CO₂). Most of the experiments wereperformed with an intracellular solution (S1) having a Cl concentration close to that in the extracellular solution. Itscomposition was (in mM): 150 CsCl, 4.6 MgCl₂, 0.1 CaCl₂, 1 EGTA,10 HEPES-Cs, 0.4 Na-GTP, and 4 Na-ATP, pH 7.3. In experimentsdesigned to establish the Cl selectivity of agonist-induced currents, an internal solutionwith low Cl concentration, close to physiological levels, was used. Thissolution contained (in mM): 150 Cs gluconate, 4.6 MgCl₂, 0.1 CaCl₂,1 EGTA, 10 HEPES-Cs, 0.4 Na-GTP, and 4 Na-ATP. In some experimentsa solution equivalent to S1, but with K⁺ replacing Cs⁺ as the main cation, was used. Neurobiotin 2 mg/ml was includedin the recording pipettes.

Bicuculline methochloride, GABA, glycine, and 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) were purchased from Tocris Neuramin(Bristol, UK), SR95531 from Research Biochemicals (RBI; Natick,MA), and all other chemicals from Sigma (Deisenhofen, Germany).Drug stocks were prepared as follows: 10 mM GABA, 10 mM glycine,2 mM strychnine, and 10 mM bicuculline prepared in H₂0. CNQX andNBQX were prepared in 1 mM NaOH. Tetrodotoxin (TTX) was purchasedin 1 mg aliquots containing 5 mg of citrate buffer, and the stockwas prepared in H₂O at 0.2 mM. Stocks were aliquoted, frozen,and dissolved daily in BBS to reach the desired concentration.

Agonist-induced currents were elicited either by bath perfusion or by local application through a puffer pipette connectedto a Picospritzer. In the latter case, pipettes with ~5 µm tipdiameter were positioned at 25 µm from the recorded cell. Thesepipettes were filled with 20 µl of a HEPES saline solution [(inmM) 145 NaCl, 2.5 KCl, 2 CaCl₂, 1 MgCl₂, 10 HEPES-Na, pH 7.3]containing the agonists at the indicated concentration.

Histology. After electrophysiological recordings, the patch pipette was removed carefully to preserve the structure of thecell, and the slice was processed for histological examination,following the procedure described by Horikawa and Armstrong (1988).Briefly, slices were fixed overnight at 4°C in a 0.1 M PBS, pH7.4, containing 4% paraformaldehyde. After a thorough rinsingin PBS, endogenous peroxidases were quenched in a solution containing1% H₂O₂, 10% absolute methanol, and 89% PBS. Then the slices wereincubated for 2 hr in avidin-biotin-horseradish peroxidase complex(ABC; Vector Labs, Burlingame, CA) in PBS containing 0.4% TritonX-100. The slices were rinsed in PBS and then reacted in a solutioncontaining 0.05% diaminobenzidine and 0.15% nickel ammonium sulfatefor 30 min; 0.03% H₂O₂ was added for the last 5 min of the incubation.Then the slices were mounted in a 10-90% solution of glycerol-PBSand sodium amide. The coverslips were sealed with fingernail polishfor storage. Mounts were examined with a 100× oil immersion lens.

RESULTS

Identification and membrane properties of RGCs
In this study RGCs were selected on the basis of their size and location. The soma of the cells studied (12-20 µM) were thelargest of the ganglion cell layer (GCL) and were located in theproximal border of this layer, next to the vitreal surface. Theiridentification as RGCs was confirmed by histological examinationafter biocytin staining of the recorded cells (see Materials andMethods). The pattern of the dendritic arborization was variable,but the dendrites always projected to the inner plexiform layer;in some cases it was possible to visualize the axon running inthe most external border of the GCL (data not shown).

RGCs were characterized by spontaneous action potential firing, routinely recorded in the cell-attached configuration, andby prominent voltage-gated currents observed under wcr. The latterconsisted of a fast inactivating inward current caused by Na⁺ channel activity, as it was blocked by addition of TTX (0.4 µM),followed by a noninactivating voltage-dependent outward currentassociated with the opening of voltage-gated K⁺ channels. A small slow inward current persisted in TTX and wassuppressed by the removal of external Ca²⁺ from the bathing solution (data not shown). The average densityof the peak Na⁺ current in 28 cells ranged from 20 to 1650 pA/pF (mean ± SEM= 393 ± 86 pA/pF).

Synaptic input to retinal RGCs
Synaptic currents recorded from different RGCs of light-adapted slices corresponded either to EPSCs, which could be blockedby the AMPA receptor antagonists CNQX and NBQX, or to IPSCs, theamplitude of which was unaffected by these blockers. Excitatoryand inhibitory events could be distinguished unambiguously bytheir characteristic kinetic parameters, because the former decayedwithin 1-2 msec whereas IPSCs had considerably longer decays (seeFig. 4). EPSCs have been observed in salamander RGCs, albeit withslower decay time course ( $tau$ _decay ~3.8 msec; Taylor et al., 1995).In this paper we have used the difference in decay kinetics todistinguish the inhibitory from the excitatory synaptic events,thus avoiding the use of glutamatergic antagonists, which in preliminaryexperiments (results not shown) were observed to induce changesin IPSC frequency, probably by affecting retinal circuits.
Fig. 4. Comparative kinetics of GABAergic IPSCs, glycinergic IPSCs, and glutamatergic EPSCs. A, Average of 73 GABAergic IPSCs. Onlythose IPSCs separated from other IPSCs by >150 msec were includedin the average. The decay phase was fit by the sum of two exponentialfunctions with time constants of 8.9 and 34.5 msec (amplitudecoefficients of $-$ 36 and $-$ 24.5 pA, respectively); the fit is superimposedon the averaged trace. B, Average of 182 glycinergic IPSCs. Onlythose IPSCs separated from other IPSCs by >500 msec were includedin the average. The decay phase was approximated by a double-exponentialfunction with time constants of 17.6 and 79.6 msec (amplitudecoefficients, $-$ 41 and $-$ 49 pA, respectively). The fit is superimposedon the averaged trace. C, Average of 33 glutamatergic EPSCs. Superimposedon the trace is the fit of the decay phase by a single exponentialwith a time constant of 0.91 msec. These fast EPSCs were abolishedby CNQX (10 µM; data not shown).
[View Larger Version of this Image (21K GIF file)]

A survey of the inhibitory synaptic events recorded in different RGCs revealed that they were heterogeneous and belonged totwo different classes: GABAergic and glycinergic. The occurrenceof these classes of IPSCs varied from cell to cell. From 37 RGCsanalyzed in this study, the majority (25 cells) showed exclusivelyGABAergic IPSCs, six cells presented only glycinergic IPSCs, andthe remaining six cells received mixed GABAergic and glycinergicinputs.

GABAergic IPSCs
Figure 1A illustrates an example of the IPSCs observed in the majority of RGCs from a continuous wcr in a ganglion cell heldat $-$ 60 mV in symmetrical Cl conditions. In this recording, as in the majority of RGCs studied,inward current transients, the amplitude of which ranged froma few picoamps up to >150 pA, appeared with low frequency at random.Bath application of SR95531 (3 µM), a specific GABA_A antagonist,blocked the IPSCs, and this effect was partially reversible. Toquantify the effects of GABA and glycine receptors antagonists,we analyzed experiments in terms of the overall synaptic activity,measured as the sum of the amplitudes of all synaptic events duringintervals of 20 sec, as shown in Figure 1B. Then the percentageof block by a given antagonist was calculated from the ratio ofthe mean current/20 sec in the test period over that in controlcondition. Using this protocol, we determined that 3 µM SR95531blocked 96.6 ± 2.8% of the IPSCs (n = 4), whereas bicuculline(3 µM) induced a 95.6 ± 1.4% block of the IPSCs (n = 4). Pooleddata are shown in Figure 5B.
Fig. 1. GABAergic IPSCs in RGCs. A, Selected traces from a continuous current recording obtained in symmetrical Cl conditions. Holding potential, $-$ 60 mV. The inward current transientspresent in a, corresponding to IPSCs, are reversibly blocked bybath application of 3 µM SR95531 (b), a blocker of GABA_A receptors.B, Plot of the sum of the amplitudes of all synaptic events detectedduring 20 sec intervals against time for the cell shown in A incontrol saline (a), in the presence of 3 µM SR95531 (b), and afterremoval of the antagonist (c). In this and subsequent figurespresenting plots of synaptic activity per unit of time, the gapsin the time axes correspond to periods in which data acquisitionwas interrupted, allowing for complete equilibration of the drugtested (see Materials and Methods). C, Amplitude distributionsof the IPSCs recorded at $-$ 60 mV in control condition (left) andin the presence of 0.4 µM TTX (right). The corresponding scalednoise distributions (1000 events each) are displayed in black;bin widths: 5 pA for the IPSCs, 0.5 pA for the scaled noise histogram.The total sampling time was the same for both IPSC histograms(4 min). TTX decreased IPSC frequency without affecting theirmean amplitude; the mean IPSC amplitude is 35 pA in the controlhistogram (450 events, corresponding to a frequency of 1.87 Hz)and 31 pA in the TTX histogram (244 events, corresponding to afrequency of 1.02 Hz). D, The cumulative amplitude distributionsfor the same experiment are displayed. E, Data pooled from 11cells on the effects of TTX on mean amplitude (left) and meanfrequency (right) of GABAergic IPSCs recorded at $-$ 60 mV. The verticallines correspond to the SEM; asterisks indicate that the two groupsare statistically different at the 0.001 level (Student's t test).
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Fig. 5. Pharmacological profile of agonist-induced currents and IPSCs. A, Left, The effect of various blockers on the currents inducedby bath application of 20 µM GABA (two cells were studied foreach blocker). Right, The effects of these blockers on the currentselicited by bath application of 50 µM glycine (number of cellsincluded: three for 3 µM bicuculline, one for 3 µM SR95531, fourfor 0.3 µM strychnine, and one for 10 µM bicuculline). B, Pooleddata on the effect of various blockers on the synaptic activity,studied as the sum of all events detected per unit of time (seeGABAergic IPSCs). Four cells were studied in each group. The errorbars in A and B correspond to the SEM, calculated for groups inwhich n $>=$ 3. C, Display of the effects of bicuculline and strychnineon the IPSCs recorded from another RGC, which had a mixed populationof IPSCs. Holding potential, $-$ 60 mV. In this cell the GABA_A inhibitorbicuculline produced a 40% block of IPSCs; the remaining activitywas abolished by 0.3 µM strychnine.
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Effect of tetrodotoxin and Ca²⁺-free media on GABAergic IPSCs
In RGCs recorded in symmetrical Cl conditions and held at $-$ 60 mV, the addition of TTX (0.4 µM) to the external solution induceda marked decrease in the frequency of GABAergic synaptic events.The histograms of Figure 1C present results from one of theseexperiments. Amplitude distributions are shown for control conditions(left) and in the presence of TTX (right). In this experimentTTX reduced IPSC frequency by 45% without significantly affectingthe mean amplitude. The mean amplitude was 35 pA in control, whereasthe value in the presence of TTX was 31 pA. The lack of effectof TTX on IPSCs amplitude was confirmed by the cumulative amplitudedistributions displayed in Figure 1D, where no significant shiftis observed between the two curves. Figure 1E summarizes datafrom a pool of 11 RGCs showing that, whereas the mean IPSC frequencyin TTX amounts to less than one-half of the frequency in controlsaline, IPSCs amplitude for the same cells do not differ significantlyin the two conditions.

Next, the sensitivity of TTX-resistant IPSCs to external Ca²⁺ ions was investigated. In two RGCs Ca²⁺ was removed while keeping the Mg²⁺ concentration at 1 mM. The frequency of TTX-resistant GABAergicIPSCs was reduced by 22% in one cell and 45% in the other. Infour other RGCs in which Ca²⁺ was removed and the concentration of Mg²⁺ was increased to 4 mM, the frequency of GABAergic IPSCs was suppressedby 90.2 ± 5%.

Glycinergic IPSCs
In six of the RGCs studied, IPSCs had electrophysiological features that differed from those of GABAergic IPSCs. The two toptraces of Figure 2A illustrate an example of IPSCs recorded ina ganglion cell held at $-$ 80 mV in symmetric Cl conditions. These IPSCs had a fast rising phase, but their timecourse of decay was slower than that of GABAergic IPSCs (see comparisonin Fig. 4). Moreover, the decay phase showed discrete currentsteps because of the closing and opening of single ionic channels.Current fluctuations persisted for some time after the macroscopiccurrent had reached a level close to baseline and correspondedto openings and closings of single glycine-gated channels. Thebottom trace in Figure 2A shows a segment of the middle traceat higher time resolution and increased magnification.
Fig. 2. Glycinergic IPSCs and single-channel events in RGCs. A, Representative traces of glycinergic IPSCs recorded at $-$ 80 mV undersymmetrical Cl conditions. The inset in the lowest panel displays at an expandedtime scale a section on the decay phase of an IPSC in which discretecurrent fluctuations, corresponding to the opening and closingof single channels, are clearly detected. The predominant amplitudeof the elementary currents was ~4-5 pA at $-$ 80 mV, correspondingto a single-channel conductance of ~50 pS. B, Display of the IPSCsamplitude distribution for the same cell. The IPSC histogram (binwidth, 7 pA) contains 638 events, with a mean amplitude of 80pA. The solid line corresponds to the fit of the data by a singlegaussian function; fit parameters were a mean of 60 pA and SDof 30 pA. A relatively high detection threshold (15 pA) was usedin the analysis to avoid including single-channel events. Thescaled noise distribution (1000 events; bin width, 0.7 pA) isdisplayed in black. C, The upper panel shows single-channel eventselicited at $-$ 100 mV by bath-applied glycine (50 µM). The leftplot in the lower panel illustrates an all-point histogram fromthe same experiment in which two channels with the same elementarycurrent can be identified (6 sec recording; bin width, 0.2 pA;the leak current has been subtracted for clarity). The solid linescorrespond to the fit of the data by three gaussian functions;fit parameters (mean ± SD, in pA) for each gaussian were 0.02± 0.04, $-$ 5.5 ± 0.7, and $-$ 10.8 ± 0.9. The right lower panel displaysthe I-V relation for the elementary glycine-activated currentdetermined from all-point histograms at three different membranepotentials; the solid line corresponds to the fit of the databy a linear function, yielding an estimated single-channel conductanceof 55 pS. D, Glycinergic synaptic activity is displayed as thesum of the amplitudes of all IPSCs detected during 20 sec intervalsas a function of time. The addition of the GABA_A antagonist SR95531(b) did not affect synaptic activity, whereas strychnine at 0.3µM (c) exerted a profound block on IPSCs and eliminated synapticactivity at 2 µM (d). Holding potential, $-$ 60 mV.
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The histogram of Figure 2B illustrates the amplitude distribution of IPSCs for the same RGC as in Figure 2A. The analysisof these IPSCs was performed by setting the detection thresholdat 15 pA to exclude single-channel events. The amplitude distributionpresents a single peak with a mean amplitude of 80 pA that, onthe basis of the elementary current of the predominant singlechannels, would correspond to the opening of ~16-18 single transmitter-gatedchannels. In five cells studied, the mean amplitude of IPSCs identifiedas glycinergic on the basis of pharmacological criteria (see below)was 36.11 ± 9.23 pA, whereas their frequency was 0.73 ± 0.14 Hz.

The elementary conductance of the glycine-gated receptor-channel complex was estimated in symmetrical chloride solutions byanalyzing (1) the discrete events present in the falling phaseof IPSCs (two cells) and (2) the single-channel currents elicitedby bath applications of glycine (two cells). A typical trace showingglycine-gated channels after a bath application of glycine inan RGC held at $-$ 100 mV is illustrated in Figure 2C (top trace).The left lower panel shows an all-point histogram for this experimentcharacterized by a multimodal distribution with a peak at 0 pA,representing the closed state, and two equally separated peakscorresponding to two channels with the same mean elementary current.The right lower panel displays the I-V relation for this experiment,which has a slope conductance of 55 pS. In the four cells analyzed,the mean slope conductance was 54 ± 2.4 pS (n = 4).

The experiments of Figure 2D demonstrate the glycinergic nature of these IPSCs. The plots present the sum of the amplitudesof IPSCs recorded during sample intervals of 20 sec against thetime of recording in control saline (Fig. 2Da) and under the effectof several drugs. The application of SR95531 (3 µM) induced onlya very weak diminution of IPSCs activity (Fig. 2Db), whereas thepresence of the classic glycinergic antagonist strychnine (0.3µM) in the saline elicited a remarkable depression of the IPSCs(Fig. 2Dc); increasing the strychnine concentration to 2 µM abolishedthe IPSCs (Fig. 2Dd). It can be concluded from these experimentsthat the second class of IPSCs is mediated by glycine. In fourcells strychnine (0.3 µM) blocked the IPSCs by 94.6 ± 3.6% (pooleddata are shown in Fig. 5B). In one of the cells a dose-responsecurve for the block of IPSCs by strychnine was performed, yieldingan IC₅₀ of 22 nM (data not shown).

Effect of TTX and removal of external Ca²⁺ on glycinergic IPSCs
Figure 3 illustrates one of the experiments performed in two different RGCs in which the effects of TTX (0.4 µM) on the amplitudeand frequency of glycinergic IPSCs were analyzed. The histogramsplot the mean amplitude (top panels) and mean frequency (bottompanels) of the glycinergic IPSCs for 20 sec periods against thewhole-cell recording time. Figure 3, Aa and Ba, corresponds tothe measurements of these parameters when the cell was bathedin normal saline. The addition of TTX affected neither the meanIPSC amplitude (Fig. 3Ab) nor the mean frequency (Fig. 3Bb). Incontrast, removing Ca²⁺ from the extracellular medium in the presence of TTX and of 2mM Mg²⁺ reduced the mean IPSC frequency by 90% (Fig. 3Bc). Ca²⁺ removal did not change significantly the mean amplitude (Fig.3Ac). The irregular pattern in Figure 3Ac is attributable to thesmall sample number in each 20 sec bin. The initial values formean IPSC amplitude and frequency were restored when the normalCa²⁺ concentration was reestablished in the TTX-containing saline(Fig. 3Ad,Bd). The application of SR95531 did not affect the TTX-treatedIPSCs (Fig. 3Ae,Be) whereas, as expected, 0.3 µM strychnine markedlyreduced both the mean amplitude and frequency of the TTX-treatedglycinergic IPSCs (Fig. 3Af,Bf). The same pattern of behaviorwas observed in the other ganglion cell tested.
Fig. 3. Lack of effect of TTX on glycinergic IPSCs. Shown are plots of the mean amplitude (A) and mean frequency (B) of glycinergicIPSCs detected during 20 sec sample intervals against time inwhole-cell recording. Neither the amplitude nor the frequencywas affected by the addition of TTX (0.4 µM) to the bathing solution(panels b). However, removal of external Ca²⁺ led to a drastic reversible reduction in IPSC frequency (panelsc, d). The glycinergic nature of the IPSCs was confirmed by thelack of effect of SR95531 (panels e) and the block by a low concentrationof strychnine (panels f).
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In two other experiments conducted in the presence of TTX, all Ca²⁺ was removed from the extracellular medium while 4 mM Mg²⁺ was added. TTX-resistant glycinergic IPSCs were blocked by 85%in one of these RGCs and by 100% in the other.

Time course of synaptic currents
Besides their distinct pharmacological profile and different sensitivity to TTX, GABAergic and glycinergic IPSCs were distinguishedeasily by their kinetics properties. In RGCs of slices bathedin control saline and recorded with CsCl-filled pipettes, theGABAergic IPSCs showed a characteristic time course exemplifiedby the average of 73 traces, shown in Figure 4A. The 10-to-90%rise time of the averaged IPSC in this case was 0.86 msec, whereasits decay phase was best approximated by two exponentials withtime constants of 8.9 ( $tau$ ₁) and 34.5 ( $tau$ ₂) msec [the ratio of theiramplitude coefficients (A2/A2 + A1) being 0.42]. Similar featureswere found in the eight RGCs receiving GABAergic input, whichwere analyzed in a similar manner with average values for the10-to-90% rise time of 1.11 ± 0.2; 6.52 ± 1.13 msec for $tau$ ₁ and40.3 ± 3.34 msec for $tau$ ₂, the ratio between the amplitude coefficientsbeing 0.67 ± 0.06. In the presence of TTX, GABAergic IPSCs showedkinetics indistinguishable from those in control saline; 10-to-90%rise time was 0.93 ± 0.2 msec, and biexponential decays had timeconstants of $tau$ ₁, 7 ± 0.6 msec and $tau$ ₂, 40.4 ± 8.3 msec (n = 4).

Glycinergic IPSCs were characterized by much slower decays, as illustrated by the example in Figure 4B, which shows the averageof 182 glycinergic IPSCs. The 10-to-90% rise time of this averagedIPSC was 0.89 msec, and the decay phase could be approximatedby two exponentials with values for $tau$ ₁ and $tau$ ₂ of 20 and 80 msec,respectively (the ratio between the amplitude coefficients was0.53). In contrast to the GABAergic IPSCs, in this second classof IPSCs the time course parameters showed a marked diversityfrom cell to cell. Thus in four RGCs the 10-to-90% rise time ofaveraged IPSCs varied between 0.47 and 1.12 msec (mean ± SEM,0.78 ± 0.14), the fast component of the decay ranged from 4.8to 65 msec (mean $tau$ ₁, 25.2 ± 13.68), and the slow component variedbetween 80 and 285 msec (mean $tau$ ₂, 147.75 ± 46.62), the ratio betweenthe amplitude coefficients, A2/(A2 + A1), being 0.54 ± 0.08.

As mentioned before, RGCs also showed EPSCs blocked by bath application of 10 µM CNQX. Their time course was drastically differentfrom that of IPSCs, as shown by the averaged trace in Figure 5C.Note the difference in time scales.

Comparative pharmacology of the responses induced by GABA and glycine
With the purpose of establishing the specificity of various antagonists on RGCs of rat retinal slices, we performed a seriesof experiments in which GABA or glycine were bath-applied, andthe effects of bath application of either GABA or glycine antagonistson the responses to these transmitters and on the two classesof IPSCs were compared.

The first interesting observation of these experiments performed in RGCs showing either GABAergic or glycinergic IPSCs isthat all of the cells analyzed responded to the application ofboth transmitters independently of the nature of their synapticinput, i.e., that all RGCs were endowed with both GABA_A and glycinergicreceptors. Similar results were reported previously in culturesof mammalian RGCs (Tauck et al., 1988; Cohen et al., 1989).

The histograms in Figure 5 summarize the results of our experiments. The left panel shows that bath application of strychnine(0.3 µM) does not affect at all the currents induced by bath-appliedGABA (20 µM), whereas when the strychnine concentration was increasedto 2 µM, a 57% blockade of the GABA-induced currents was obtained.Bicuculline (3 µM) was more effective, because it blocked GABA-inducedcurrents by 75% whereas SR95531 (3 µM) completely blocked theGABA-induced responses. The right panel of Figure 5A shows theeffects of antagonists on the currents induced by bath-appliedglycine (50 µM). These currents were blocked by 87% by a low concentrationof strychnine (0.3 µM) whereas SR95531 (3 µM), which totally blockedthe GABA-induced responses, did not affect glycine-induced currents.Bicuculline (3 µM) had a very weak effect on glycine-induced currents,but when its concentration was increased to 10 µM, it could blockthese responses by ~15%. Figure 5B shows pooled data on the effectsof GABA and glycine antagonists on synaptic activity analyzed,as detailed before, in terms of the sum of IPSCs amplitude perunit of time. In view of the antagonist profile shown in Figure5A, we conclude that the pharmacological criteria used in previoussections to distinguish GABAergic from glycinergic IPSCs can beapplied safely in the study of RGCs inhibitory synapses.

RGCs with mixed synaptic inputs
In six RGCs the recordings showed IPSCs of both GABAergic and glycinergic nature, as evidenced by their characteristic electrophysiologicalfeatures. In these six cells applications of bicuculline (3 µM)and strychnine (0.3 µM) helped us to ascertain the mixed natureof the synaptic input. An example is shown in Figure 5C in whichapplication of bicuculline (3 µM) blocks nearly one-half of thesynaptic events (Fig. 5Cb) while strychnine (0.3 µM) blocks theremaining IPSCs (Fig. 5Cc).

Ionic selectivity of GABAergic and glycinergic receptors
Figure 6 illustrates examples from a series of experiments in which we analyzed the Cl dependence of the responses to local applications of GABA andglycine. In Figure 6A1, in symmetrical Cl conditions the holding potential was driven to levels rangingbetween $-$ 80 to +60 mV, and GABA (20 µM) was puff-applied (seeMaterials and Methods). The puff applications of GABA elicitedinward currents at negative holding potentials, which reversedpolarity at membrane potentials beyond 0 mV. As shown by the peakcurrent-to-voltage (I-V) relations in Figure 6A2, GABA-inducedcurrents presented marked voltage-dependent outward rectification,both in symmetrical Cl solutions (open circles) or when most of the intracellular Cl was replaced by gluconate (open triangles). Rectifying I-V relationswere observed in all RGCs tested with GABA puffs, as previouslyreported for GABA-gated Cl channels in hippocampal neurons (Gray and Johnston, 1985) andin spinal cord neurons (Bormann et al., 1987). In five RGCs recordedin symmetrical Cl conditions, currents induced by puff-applied GABA had a reversalpotential of 4.8 ± 1.8 mV, whereas in five cells studied withlow intracellular Cl, the reversal potential was $-$ 57 ± 1.5 mV. Both values are closeto those predicted by the Nernst equation for a Cl-selective conductance. GABAergic IPSCs recorded at differentmembrane potentials in symmetrical Cl (Fig. 6A3) share the main features of the agonist-induced currents,namely strong voltage-dependent outward rectification and reversalpotential close to the predicted value for a Cl-selective conductance.
Fig. 6. Cl-selective GABA_A and glycine receptors in ganglion cells. A1, Current responses to 250 msec puffs of 10 µM GABA obtainedin a cell dialyzed with CsCl at membrane potentials ranging from $-$ 80 to +60 mV. In all of the experiments in which agonist-evokedcurrents were studied as a function of membrane potential, theholding potential was held at $-$ 60 mV, changed to the desired value2 sec before the puff application, and maintained at that levelfor 2 additional sec while data were acquired. The current previousto the agonist application was subtracted from the traces. A2,Relation between membrane voltage and the peak of the GABA-inducedcurrent for the experiment shown in A1 ( $open circle$ ) and for a differentcell dialyzed with low Cl ( $triangle$ ). A3, GABAergic IPSCs recorded at the membrane potentials,indicated at the left of the traces for the cell shown in A1.B1, Representative responses to 150 msec puffs of 50 µM glycineobtained from a cell dialyzed with CsCl at membrane potentialsranging from $-$ 100 to +60 mV. B2, The I-V relation for the cellshown in A2 ( $open circle$ ) and for a different cell dialyzed with low Cl ( $triangle$ ). The experimental protocol was similar to that describedfor A. B3, Glycinergic IPSCs recorded in the cell shown in B1at different holding potentials, indicated at the left of thetraces.
[View Larger Version of this Image (30K GIF file)]

Similar experiments were performed for glycinergic currents. Representative currents elicited by puffs of glycine (50 µM)at different holding potentials are shown in Figure 6B1 for aRGC recorded in symmetrical Cl concentrations. In contrast to those observed for the responsesto GABA, glycine-induced currents showed no voltage-dependentrectification in symmetrical Cl (Fig. 6B2, open circles) but had some rectification in low intracellularCl (Fig. 6B2, open triangles). Furthermore, the time course of recoveryof the glycine-evoked currents was much slower than that of thecurrents induced by GABA. As in the case of responses to GABA,the Cl selectivity of the glycine currents was confirmed by reversalpotential determinations, which were 4.9 ± 1.2 mV (n = 5) in symmetricalCl conditions and $-$ 55.5 ± 1.3 mV (n = 5) in cells dialyzed withCs gluconate. Glycinergic IPSCs reversed close to the expectedreversal potential for Cl in symmetrical Cl conditions, as shown by the example illustrated in Figure 6B3.

DISCUSSION

Differences in RGCs synaptic inputs
The results presented here show that GABAergic and glycinergic IPSCs occur in RGCs. Nevertheless, it is not known to whatextent the IPSCs observed in rat retinal slices, which are a commonfinding in slice preparations from different CNS regions, areattributable to the light-adapted conditions in which the experimentswere performed.

The pharmacological dissection of inhibitory synaptic inputs was based on the specific block of GABAergic synaptic eventsby low concentrations (3 µM) of SR95531 and bicuculline and ofglycinergic IPSCs by 0.3 µM strychnine. Actually, higher concentrationsof these compounds were shown in the present experiments, as inthe previous ones of Cohen et al. (1989), to affect the responsesto both amino acids. A distinct class of bicuculline-insensitiveGABA receptors, the GABA_C receptors, is present in several retinalneurons (for review, see Bormann and Feigenspan, 1995). Enz etal. (1996) have shown that mammalian RGCs lack GABA_C $rho$ receptorsubunits. In agreement, we find that all of the GABAergic IPSCs,as well as the responses to exogenous GABA, were blocked completelyby bicuculline, thus ruling out the presence of functional GABA_Creceptors in RGCs.

Despite the presence of receptors to both amino acids in all RGCs examined, GABAergic synapses predominate in the majorityof the RGCs analyzed. The wider distribution of GABAergic inputsamong RGCs in comparison with the more restricted occurrence ofthe glycinergic ones may arise from differences in the dendriticfield of the amacrine cells involved. As previously reported (seeVaney, 1990), glycine-accumulating amacrine cells in mammalianretinas have much narrower dendritic fields than GABAergic amacrines,which generally are endowed with medium or large dendritic fields.However, RGCs are a morphologically and functionally heterogeneouspopulation (Wässle and Boycott, 1991), and inhibitory synapticinputs may depend on RGC subtype and on the light conditions thatdetermine which retinal circuits are active. Because no correlationbetween morphological type and/or response to light stimuli withthe synaptic input has been established in the present work, wecannot elucidate this point.

GABAergic versus glycinergic IPSCs
There were marked differences in the properties of GABAergic and glycinergic IPSCs recorded from RGCs. The decay phase ofglycinergic IPSCs, in contrast to that of GABAergic IPSCs, showedan important cell-to-cell variability. Different glycine receptorsubunits (the $alpha$ ₁, $alpha$ ₂, $alpha$ ₃, and $beta$ subunits) have been detected atthe rat RGC layer by both immunocytochemical and RNA hybridizationtechniques (Greferath et al., 1994b; Koulen et al., 1996). Anunequal distribution of these subunits among RGCs could contributeto the variation in the time course of decay of the glycinergicIPSCs (see Legendre and Korn, 1994). Furthermore, the presenceof visible current jumps on the decay phase, corresponding toclosings of single channels, characterized glycinergic IPSCs.The single-channel conductance (~54 pS) matches that of the mostfrequent subconductance state found via analysis of glycinergicIPSCs in spinal cord neurons (Takahashi and Momiyama, 1991) andin cerebellar Golgi cells (Dieudonné, 1995), as well as the estimatesfrom single-channel recordings in spinal neurons (Bormann et al.,1987) and cerebellar granule cells (Kaneda et al., 1996). Single-channelcurrents trailed the IPSCs. This could arise either from persistenceof transmitter in the synaptic cleft or from glycine receptorsundergoing reopenings after desensitization in the agonist-boundconfiguration, as recently proposed for GABA_A receptors (Jonesand Westbrook, 1995).

Despite the observed variability in their decay kinetics, glycinergic IPSCs were significantly slower than GABAergic ones.This situation differs from that found in the spinal cord, whereGABAergic synaptic potentials have slower decays than glycinergicones (Yoshimura and Nishi, 1995). In RGCs, glycinergic IPSCs decaywas biexponential, the slower time constant falling into the hundredsof milliseconds range. This is in sharp contrast to the very fastmonoexponential decay in zebra fish brain ( $tau$ , 4-6 msec; Legendreand Korn, 1994). The presence of the $alpha$ ₂ subunit in RGCs of adultrats (Koulen et al., 1996) could account for the observed prolongeddecay, because this subunit confers long open times to glycine-gatedcurrents (Takahashi et al., 1992). Furthermore, in the spinalcord a developmental shift from $alpha$ ₂ to $alpha$ ₁ is paralleled by a shorteningof the decay of IPSCs (Takahashi et al., 1992). The high sensitivityto strychnine of RGCs glycinergic IPSCs is surprising becausethe $alpha$ ₂ subunit is considered to be responsible for the relativeimmunity to strychnine poisoning in neonatal rats, and its disappearanceduring development is associated with an increase in sensitivityof the glycine receptor to this alkaloid (Kuhse et al., 1990).

The decay of GABAergic IPSCs in retinal ganglion cells was also biexponential. The observed values for the fast and slow timeconstants are in the same range as those for hippocampal granulecells (Edwards et al., 1990), cerebellar stellate cells (Llanoand Gerschenfeld, 1993), and cerebellar granule cells (Tia etal., 1996). These values differ from those reported by Jones andWestbrook (1995) in their study of cultured hippocampal neurons,which have GABAergic IPSCs with much slower biexponential decays;the authors interpreted IPSCs decay as arising from receptor desensitization.

Effects of TTX and Ca²⁺-free media
Another striking difference between the two classes of IPSCs concerns their behavior in the presence of TTX. The frequencyof GABAergic IPSCs was reduced markedly by TTX, whereas that ofglycinergic IPSCs remained unaffected. Therefore, the releaseof transmitter from glycinergic amacrine cells responsible forthe generation of IPSCs in our RGCs population does not dependon the activation of voltage-gated Na⁺ channels. Although glycinergic amacrine AII cells are able todischarge Na⁺ action potentials, their electrotonic compactness may allow transmitterrelease without the requirement of action potential propagation(Boos et al., 1993). It is also evident that a fraction of theGABAergic IPSCs is generated by transmitter released via a mechanismindependent of voltage-gated Na⁺ channels. The fact that both TTX-resistant GABAergic IPSCs andall of the glycinergic IPSCs were blocked by Ca²⁺-free media suggests that transmitter can be released either bylocal depolarization inducing Ca²⁺ influx into amacrine cell dendrites or by Ca²⁺ influx at resting membrane potential. In synaptic terminals fromgoldfish retinal bipolar cells there is a considerable calciuminflux through L-type Ca²⁺ channels at membrane potentials close to $-$ 55 mV (Kobayashi andTachibana, 1995). A similar mechanism may operate in amacrinecells, because their resting membrane potential is close to $-$ 60mV (Boos et al., 1993), and it has been shown that transmitterrelease at amacrine-amacrine cell synapses in culture dependson L-type Ca²⁺ channels (Gleason et al., 1994).

In conclusion, in our recording (light-adapted) conditions GABAergic IPSCs in RGCs can be elicited either by Na⁺-dependent action potentials or by local Ca²⁺ influx, presumably of medium or large dendritic field GABAergicamacrine cells, whereas glycinergic IPSCs are generated by depolarizationinducing Ca²⁺ influx in narrow field glycinergic amacrine cells.

FOOTNOTES

Received Feb. 26, 1997; revised May 27, 1997; accepted June 2, 1997.

This work was supported by the Max Planck Society and a von Humboldt postdoctoral fellowship to D. A. Protti. We are gratefulto H. Wässle for his advice on the preparation of retinal slices.We thank A. Marty, C. Pouzat, and H. von Gersdorff for discussionsand comments on this manuscript.

Correspondence should be addressed to Dr. Isabel Llano, Arbeitsgruppe Zelluläre Neurobiologie, Max-Planck-Institut für biophysikalischeChemie, Am Fassberg, 37070, Göttingen, Germany.

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GABAergic and glycinergic IPSCs in Ganglion Cells of Rat Retinal Slices

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