Distinct Ionotropic GABA Receptors Mediate Presynaptic and Postsynaptic Inhibition in Retinal Bipolar Cells

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The Journal of Neuroscience, April 1, 2000, 20(7):2673-2682

Distinct Ionotropic GABA Receptors Mediate Presynaptic and Postsynaptic Inhibition in Retinal Bipolar Cells
Colleen R. Shields¹^,³, My N. Tran¹, Rachel O. L. Wong²^,³, and Peter D. Lukasiewicz¹^,²^,³
¹ Department of Ophthalmology and Visual Sciences, ² Department of Anatomy and Neurobiology, and ³ Neuroscience Program, Washington University School of Medicine, St. Louis, Missouri 63110

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Ionotropic GABA receptors can mediate presynaptic and postsynaptic inhibition. We assessed the contributions of GABA_A andGABA_C receptors to inhibition at the dendrites and axon terminalsof ferret retinal bipolar cells by recording currents evoked byfocal application of GABA in the retinal slice. Currents elicitedat the dendrites were mediated predominantly by GABA_A receptors,whereas responses evoked at the terminals had GABA_A and GABA_Ccomponents. The ratio of GABA_C to GABA_A (GABA_C:GABA_A) was highestin rod bipolar cell terminals and variable among cone bipolars,but generally was lower in OFF than in ON classes. Our resultsalso suggest that the GABA_C:GABA_A could influence the time courseof responses. Currents evoked at the terminals decayed slowlyin cell types for which the GABA_C:GABA_A was high, but decayedrelatively rapidly in cells for which this ratio was low. Immunohistochemicalstudies corroborated our physiological results. GABA_A $beta$ 2/3 subunitimmunoreactivity was intense in the outer and inner plexiformlayers (OPL and IPL, respectively). GABA_C $rho$ subunit labeling wasweak in the OPL but strong in the IPL in which puncta colocalizedwith terminals of rod bipolars immunoreactive for protein kinaseC and of cone bipolars immunoreactive for calbindin or recoverin.These data demonstrate that GABA_A receptors mediate GABAergicinhibition on bipolar cell dendrites in the OPL, that GABA_A andGABA_C receptors mediate inhibition on axon terminals in the IPL,and that the GABA_C:GABA_A on the terminals may tune the responsecharacteristics of the bipolarcell.

Key words: GABA; ionotropic GABA receptors; GABA_A receptors; GABA_C receptors; retinal bipolar cells; cone bipolar cells; rod bipolar cells; presynaptic inhibition; postsynaptic inhibition

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Throughout the CNS, GABA is an abundant and important inhibitory neurotransmitter. There are two distinct ionotropic GABAreceptors, GABA_A and GABA_C, which are physiologically, pharmacologically,and molecularly distinct (for review, see Bormann and Feigenspan,1995; Lukasiewicz, 1996; Hevers and Lüddens, 1998). For example,GABA elicits currents that decay more slowly when mediated byGABA_C receptors than by GABA_A receptors (Qian and Dowling, 1993,1995; Amin and Weiss, 1994; Lukasiewicz and Wong, 1997; Lukasiewiczand Shields, 1998a), and the affinity for GABA is greater at GABA_Creceptors than at GABA_A receptors (Amin and Weiss, 1994; Feigenspanand Bormann, 1994). Understanding how GABA modulates neuronalexcitation thus requires knowledge of how GABA_A and GABA_C receptorscontribute to the overall GABAergic response of theneuron.

In the retina, in which there is an abundance of GABA_A and GABA_C receptors, there are distinct patterns of expression forthese two receptor subtypes (for review, see Lukasiewicz and Shields,1998b). Retinal neurons that possess both GABA_A and GABA_C receptorsare thus good models for understanding how spatial localizationof distinct receptors and their relative expression can shapesynaptic responses. One such cell is the retinal bipolar cell,which has dendrites located in the outer plexiform layer (OPL)in which inhibition affects responses to photoreceptor input,and axon terminals located in the inner plexiform layer (IPL)in which inhibition modulates transmission from bipolar cellsto ganglion cells. Although these cells have been demonstratedby both electrophysiology and immunocytochemistry to have GABA_Aand GABA_C receptors, it is not yet fully understood how each receptorsubtype contributes to inhibition at the dendrites and axon terminalsof thecell.

To examine the contributions of GABA_A and GABA_C receptors to inhibition at the dendritic and axon arbors of bipolar cells,it is necessary to selectively activate GABA receptors in theOPL or IPL. In this study, bipolar cell responses to GABA wereexamined under whole-cell voltage clamp in slices of mature ferretretina using a brief, focal application of GABA (puff) at theOPL or IPL. The contribution of each receptor subtype to thesecurrents was determined pharmacologically, and the time coursesof the evoked responses were measured. We also compared the physiologicalratio of GABA_A and GABA_C receptors on the terminals of differentbipolar cell classes and examined the patterns of immunolabelingfor these two receptors, because differences in their relativeexpression may allow functionally distinct cell classes to generatediverse inhibitoryresponses.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Preparation of ferret retinal slices. Ferrets (postnatal day 28 to adult) were obtained from Marshall Farms (North Rose, NY).Housing, care, and use of ferrets are in accordance with the WashingtonUniversity Animal Studies Committee and National Institutes ofHealth guidelines. Animals were deeply anesthetized with 4-5%halothane (Halocarbon Laboratories, River Edge, NJ), eyes wereenucleated, and animals were killed with an overdose of halothaneor with an intracardiac (or intraperitoneal) injection of sodiumpentobarbital (The Butler Company, Columbus,OH).

Immediately after enucleation, the anterior portion of the eye (lens and cornea) and vitreous were removed. Retinae were dissectedin cold, oxygenated extracellular medium (see Electrode and bathsolutions) buffered with 20 mM HEPES to pH 7.4 and maintainedin this medium at room temperature. Slices were prepared as describedpreviously (Lukasiewicz and Wong, 1997).

Whole-cell patch recordings. Whole-cell patch recordings (Hamill et al., 1981) were obtained from rod and cone bipolar cellsin ferret retinal slices. The microscope system and recordingprocedures have been described in detail previously (Lukasiewiczand Roeder, 1995). Electrodes were pulled from borosilicate glass(TW150F-4; World Precision Instruments, Sarasota, FL) with a Sachs-Flamingpuller (Sutter Instruments, Novato, CA) and had measured resistancesof <5 M $Omega$ . Patchit software (White Perch Software, Somerville,MA) was used to generate voltage command outputs, acquire data,gate the drug perfusion valves, and trigger the Picospritzer (GeneralValve, Fairfield, NJ). The data were digitized and stored witha 486 personal computer using a Labmaster DMA data acquisitionboard (Scientific Solutions, Solon, OH). Responses were filteredat 1 kHz with the four-pole Bessel low-pass filter on the Axopatch200B (Axon Instruments, Foster City, CA) and sampled at 0.3-2kHz.

Data analysis. Tack software (White Perch Software) was used to average records and to determine the charge transfer. Leak-subtractedresponses (n = 2-4) were averaged to obtain the current tracesdepicted in the figures. The decay of the current was not easilyfit by exponentials. Thus, the decay was measured from peak to37% of peak current amplitude (D₃₇). Sigma Plot software (SPSS,Chicago, IL) was used to calculate the D₃₇ and to determine thetime from the GABA puff to peak current amplitude. Data in textand figure legends are expressed as mean ± SE. Levels of significancewere determined using the Student's ttest.

Electrode and bath solutions. The standard bathing medium [normal ferret ringer (NFR)] contained (in mM) 128 sodium chloride,1 magnesium chloride, 5 potassium chloride, 2 calcium chloride,10 glucose, and 20 HEPES. The standard intracellular electrodesolution for puff experiments consisted of (in mM) 118 cesiumchloride, 10 tetraethylammonium chloride (TEA), 0.4 magnesiumchloride, 1 EGTA, and 10 sodium HEPES, adjusted to pH 7.3 withhydrochloric acid. Synaptic responses were recorded using a low-chlorideelectrode solution containing cesium gluconate (118 mM) in placeof cesium chloride. Cesium and TEA were included in recordingelectrodes to block voltage-gated potassium channels (Lukasiewiczand Werblin, 1988). In some experiments, slight variations ofthe above electrode and bath solutions were used or the bathingsolution was Ames medium (Ames and Nesbett, 1981). For experimentsusing Ames medium, the intracellular electrode solution differedfrom the standard in cesium concentration and contained (in mM)105.3 cesium chloride or cesium gluconate. No differences werefound between solutions. Unless otherwise indicated, all chemicalswere obtained from Sigma (St. Louis,MO).

In NFR bathing solution, the calculated E_Cl was $-$ 2 mV (cesium chloride electrodes) or $-$ 58.5 mV (cesium gluconate electrodes).For experiments in which Ames medium was substituted for NFR,E_Cl was $-$ 2 mV (cesium chloride electrodes) or $-$ 65 mV (cesium gluconateelectrodes). Membrane potential values given in this paper werecorrected for junction potentials. Liquid junction potentialswere calculated using Junction Potential Calculator (Cell MicroControls,Virginia Beach, VA) and were typically $-$ 5.2 and $-$ 14.5 mV in NFRfor cesium chloride and cesium gluconate electrodes, respectively.When Ames medium was substituted for NFR, the liquid junctionpotentials were $-$ 3.5 mV (cesium chloride electrodes) and $-$ 13.5mV (cesium gluconateelectrodes).

The control bathing solution used in these slice experiments was formulated to pharmacologically isolate bipolar cell responsesto GABA. In all experiments, glycine receptors were antagonizedwith strychnine (2 µM) (Belgum et al., 1984). For GABA puff experiments,AMPA/kainate (AMPA/KA) receptors were blocked with 6-cyano-7-nitroquinoxaline-2,3-dione(10 µM) (CNQX) [Research Biochemicals (RBI), Natick, MA] (Mittmanet al., 1990). GABA_A receptors were antagonized with bicucullinemethbromide (200 µM; RBI), and GABA_C receptors were blocked with3-aminopropyl [methyl]-phosphinic acid (500 µM) (3-APMPA) (RBIor Precision Biochemicals, Inc., Vancouver, British Columbia,Canada) (Woodward et al., 1993; Pan and Lipton, 1995). Picrotoxincould not be used to selectively block GABA_A receptors, becauseit is an antagonist at both GABA_A and GABA_C receptors in the ferret(Lukasiewicz and Wong, 1997). Antagonists were applied to a regionof the slice under study (several millimeters in width) by a gravity-drivensuperfusion system as described previously (Lukasiewicz and Roeder,1995).

Puffing agonist onto bipolar cell terminals or dendrites. GABA (200 µM) was puffed onto either the terminals or dendritesof bipolar cells in the slice preparation with a Picospritzerat 45 or 60 sec intervals. The puff pressure and/or duration (typically10-30 msec) were adjusted to give no larger than a half-maximalresponse. The pipette was positioned to give the fastest possibleresponse rise time. The location of the puff pipette in relationto the terminals or dendrites could be determined with Luciferyellow included in the recording pipette. Because the slice wascontinuously superfused (diluting the puff) and puff durationand pressure were submaximal, the GABA concentration at the receptorswas most likely much less than the pipette concentration. Formost experiments in which GABA was puffed onto the terminals,the direction of superfusion flow was from photoreceptors to ganglioncells to prevent activation of dendritic GABA receptors by diffusionof the GABA puff. For experiments in which slices were in theopposite orientation, the puff pressure, duration, and positioncould be adjusted to focally activate GABA receptors. Cells wererejected when there was evidence of a double peak in the response,which indicated the activation of receptors on both the dendritesand axonterminals.

Evoking GABAergic IPSCs. GABAergic IPSCs were evoked in bipolar cells by puffing kainate (250 or 500 µM) in the IPL to depolarizeamacrine cell processes. GABA receptors were pharmacologicallyisolated as described above by including strychnine (2 µM) inthe bathing medium. IPSCs were recorded using cesium gluconateelectrodes, and bipolar cells were voltage clamped to 0 mV, thereversal potential for nonspecific cationcurrents.

Identification and classification of bipolar cells. Bipolar cell class was determined with Lucifer yellow (0.015-0.02%) includedin the recording electrode. Bipolar cells were documented by photographingand/or drawing by hand at the conclusion of each experiment. Rodbipolar cells (see Fig. 2A, cells 1, 2) stratified close to theborder of the inner plexiform and ganglion cell layers and hadthe morphology described for rat rod bipolar cells (Euler andWässle, 1995). ON cone bipolar cells (see Fig. 2A, cells 3, 4)stratified in the proximal two-thirds of the IPL, and OFF conebipolar cells (see Fig. 2A, cells 5-7) stratified in the distalone-third of the IPL, similar to the ON and OFF sublaminae inthe cat IPL (Famiglietti and Kolb, 1976; Nelson et al., 1978;Peichl and Wässle, 1981).

Immunolabeling. Eyecups were prepared as described above and fixed by immersion in 4% paraformaldehyde in 0.1 M phosphatebuffer, pH 7.4, for 25-30 min. The paraformaldehyde-fixed eyecupswere rinsed (three times for 10 min each) in 0.1 M phosphate buffer,and the retinae were isolated carefully. The retinae were placedin warmed (37°C) 4% agarose for 30 min and then in 4% agar, whichwas then allowed to solidify. Vibratome sections (50 µM) werecut, washed (10 min) in a solution of 0.01 M PBS (145 mM NaCl,pH 7.35) and 0.5% Triton X-100 (T-X), and then incubated at roomtemperature for 1 hr in a blocking solution consisting of 10%normal goat serum (NGS) (Vector Laboratories, Burlingame, CA)and 0.5% T-X in 0.01 M PBS. Sections were incubated overnightat room temperature in the following primary antibodies made upin the blocking solution at the specified dilutions: PKC [1:1000(rabbit polyclonal antibody to $alpha$ , $beta$ , and $gamma$ isozymes; Chemicon,Temecula, CA)], calbindin [1:1000 (mouse monoclonal anti-calbindin-D;Sigma)], recoverin [1:300 (rabbit polyclonal; gift of A. Dizhoor,Kresge Eye Institute, Wayne State University, Detroit, MI)], GABA_A[1:10 (mouse monoclonal antibody to $beta$ 2/3 (clone bd 17) subunitof the receptor; Boehringer Mannheim, Indianapolis, IN)], andGABA_C [1:100 (rabbit polyclonal antibody to $rho$ ₁, $rho$ ₂, and, $rho$ ₃ subunitsof the receptor; gift of Ralf Enz, Johns Hopkins University, Baltimore,MD)]. As a control, the primary antibodies were omitted from onesection on eachslide.

Before applying secondary antibodies, the sections were rinsed for 1 hr at room temperature with 0.5% T-X-0.01 M PBS. Nonspecificlabeling was reduced by incubating the sections in a blockingsolution consisting of 3% NGS and 0.5% T-X-0.01 M PBS. Immunofluorescentsecondary antibodies Cy-2 (1:1000) or Cy-3 (1:1000) were dilutedwith the blocking solution and applied for 1 hr at room temperature.The sections were rinsed three times for 5-15 min with PBS andthen were mounted in Immumount (Shandon Lipshaw, Pittsburgh,PA).

The protocols for triple and double labeling are similar (see above for details). Sections were first double labeled by incubatingovernight in blocking solution (10% NGS-0.5% T-X-0.01 M PBS) containingtwo different primary antibodies from two species. The followingday, sections were treated as described above, and the appropriateimmunofluorescent secondary antibodies diluted in 3% NGS and 0.5%T-X-0.01 M PBS were applied for 1 hr. After thorough washing inPBS, sections were incubated overnight in blocking solution containingthe third primary antibody. After incubation, sections were treatedas described above, and the final secondary antibody was appliedfor 1 hr. After rinsing, sections were mounted in Immumount. Wewere unable to use this protocol with the $beta$ 2/3 and calbindin mousemonoclonal antibodies because of interactions between the finalsecondary antibody and the first primary antibody (either anti- $beta$ 2/3or anti-calbindin). Another anti-calbindin antibody (anti-rabbit;Swant, Bellinzona, Switzerland) did not produce specific labelingof this population of ON bipolarcells.

Confocal imaging and image analysis. Confocal images were acquired using the Bio-Rad (Hercules, CA) 1024M microscope (krypton-argonlaser). Images were captured using a 40× water or 60× oil objective(NA 1.4; Olympus Optical, Tokyo, Japan) at a x-y resolution of512 × 512 or 728 × 512 pixels and a z-step appropriate for themagnification of the objective and zoom (typically ranging from0.1-0.3 µm). Confocal stacks were analyzed using the Metamorphthree-dimensional (3-D) analysis package (Universal Imaging Corp.,West Chester, PA). Details of how each image in Results was obtainedare given in the text and figurelegends.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

GABA_A receptors predominate on the dendrites of bipolar cells

In the OPL, inhibition onto bipolar cell dendrites from GABAergic interneurons may modulate bipolar cell responses to photoreceptorinput (Fisher and Boycott, 1974; Kolb and West, 1977; Chun andWässle, 1989; Pourcho and Owczarzak, 1989). Because GABA receptorsubtype influences the characteristics of inhibitory currents,we examined the types of ionotropic GABA receptors expressed onthe dendrites of bipolar cells in the ferret retinalslice.

Currents were evoked by puffing GABA directly onto bipolar cell dendrites in the OPL after blocking glycine and AMPA/KA receptors(see Materials and Methods). The GABA receptor types mediatingthese responses were determined pharmacologically by selectivelyblocking with the GABA_A receptor antagonist bicuculline or withbicuculline plus the GABA_C antagonist 3-APMPA. Figure 1A showscurrents evoked by puffing GABA onto the dendrites of an OFF conebipolar cell. The response reached peak amplitude in 128 msecand decayed to 37% of peak current amplitude (D₃₇) in 226 msec.In a population of bipolar cells, the average D₃₇ and time-to-peakwere 244 ± 24 msec (n = 16) and 100 ± 13 msec (n = 16), respectively(see Fig. 3B,C). Bicuculline effectively blocked the GABA-evokedcurrent depicted in Figure 1A, reducing the charge transfer (measuredby integrating the area under the current trace, see Materialsand Methods) to 18% of control levels, and 3-APMPA abolished thesmall bicuculline-resistant component. Figure 1B illustrates thatsimilar results were observed across a population of bipolar cells,consisting of rod, ON cone, and OFF cone bipolar cell classes.No differences between these bipolar cell types were found. Theseresults suggest that GABAergic inhibition with a large GABA_A componentand a much smaller GABA_C component may modulate bipolar cell responsesto photoreceptor input.

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Figure 1. GABA_A receptors predominate on bipolar cell dendrites. A, Current responses evoked by puffing GABA (200 µM pipette concentration) onto bipolar cell dendrites. Horizontal bar above the current traces denotes the duration of the puff in this and all subsequent figures. The control current had a time-to-peak of 128 msec and a D₃₇ of 226 msec. Bicuculline (200 µM) reduced the response charge transfer to 18% of control (Bic). 3-APMPA (300 µM) decreased the bicuculline-resistant component to 2% of control (Bic & 3A). B, Effects of bicuculline and 3-APMPA on a mixed population of bipolar cells. On average, bicuculline (Bic) reduced the charge transfer to 14 ± 2% (n = 15) of control. The bicuculline-resistant component was reduced to 2.3 ± 0.8% of control by the subsequent addition of 3-APMPA (Bic/3A; n = 12). Currents recovered to 82 ± 6% of control levels upon washout of antagonist (Wash; n = 15).

The time course of GABA-evoked currents at axon terminals varies with bipolar cell class

Mammalian bipolar cell axon terminals in the IPL express both GABA_A and GABA_C receptors and receive input from GABAergic amacrinecells (Chun and Wässle, 1989; Pourcho and Owczarzak, 1989; Feigenspanet al., 1993; Lukasiewicz and Wong, 1997). Currents mediated byGABA_C receptors decay slowly compared with responses mediatedby GABA_A receptors; however, it is unknown how each receptor subtypecontributes to the overall time course of the GABAergic responseof a bipolar cell. Therefore, we examined the characteristicsof currents evoked by puffing GABA onto the axon terminals ofrod, ON cone, and OFF cone bipolar cells. Typical examples ofthese cell types are illustrated in Figure 2A.

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Figure 2. Time course of GABAergic currents varies among distinct classes of bipolar cells. A, Line drawings from photomicrographs of cells included in the recorded rod (1, 2), ON cone (3, 4), and OFF cone (5-7) bipolar cell populations. Scale bar, 20 µm. B, Currents evoked by puffing GABA (200 µM pipette concentration) onto the terminals of an OFF cone and a rod bipolar cell. The current recorded from the OFF cone bipolar had a D₃₇ of 284 msec and a time-to-peak of 71 msec (thick trace, OFF). The D₃₇ and time-to-peak of the response measured in the rod bipolar were 1044 and 213 msec, respectively (thin trace, Rod). C, Average D₃₇ and time-to-peak data for populations of rod, ON cone, and OFF cone bipolar cells. The average D₃₇ values (white bars) were 808 ± 92 msec (n = 18) for rod (Rod), 638 ± 77 msec (n = 18) for ON cone (ON), and 434 ± 44 msec (n = 18) for OFF cone (OFF) bipolar cells. There was a significant difference in the average D₃₇ between OFF and ON cone bipolars (p = 0.01) and between OFF and rod bipolars (p < 0.001), but not between ON cone and rod bipolar cells (p = 0.08). The average time-to-peak values (black bars) were 168 ± 20 msec (n = 18; Rod), 202 ± 25 msec (n = 18; ON), and 150 ± 20 msec (n = 18; OFF). No significant differences in the time-to-peak were found between classes of bipolar cells.

We found that distinct bipolar cell classes exhibited variations in the time course of GABA-elicited currents. The currenttraces in Figure 2B illustrate the marked difference in the timecourses of GABA-evoked currents in an OFF cone and a rod bipolarcell. The response of the OFF bipolar cell reached peak amplitudein 71 msec and decayed to 37% of peak amplitude in 284 msec. Thetime-to-peak and D₃₇ of the rod bipolar cell response were 213and 1044 msec, respectively. The average D₃₇ and time-to-peakdata for three populations of bipolar cells are summarized inthe bar graph in Figure 2B. These data show a general trend forGABA-evoked currents to decay slowly in rod, somewhat faster inON cone, and most rapidly in OFF cone bipolar cells, but do notreveal differences among these bipolar cells in the time requiredto reach peak currentamplitude.

Consistent with previous studies in expression systems, isolated rod bipolar cells, and retinal slices, our current findingsdemonstrated that the kinetics of GABA_A receptor-mediated responseswere much faster than those of GABA_C receptor-mediated currents(Qian and Dowling, 1993, 1995; Amin and Weiss, 1994; Lukasiewiczand Wong, 1997; Lukasiewicz and Shields, 1998a). We recorded responsesevoked by puffing GABA onto the axon terminals in the presenceof either the GABA_A antagonist bicuculline or the GABA_C antagonist3-APMPA. Figure 3A shows pharmacologically isolated GABA_A andGABA_C receptor-mediated currents recorded from a rod bipolar cell.For comparison, the GABA_A response is scaled to the amplitudeof the GABA_C response. The GABA_A receptor-mediated current reachedits peak amplitude in 58 msec and had a D₃₇ of 112 msec, whereasthe GABA_C component reached peak amplitude in 170 msec and hada D₃₇ of 1037 msec. Figure 3, B and C, shows that, across allclasses of bipolar cells, the average D₃₇ and time-to-peak forresponses evoked at the terminals were significantly faster forGABA_A than for GABA_C receptors. Note that the average D₃₇ andtime-to-peak of currents mediated by GABA_A receptors on the terminalswere similar to those of responses evoked at the dendrites inwhich GABA_A receptors predominate. Likewise, neither the peakamplitude nor the total charge transfer were significantly differentbetween GABA_A receptor-mediated currents elicited at the terminalsand total currents evoked at the dendrites. In contrast, the peakamplitude was similar (p = 0.26) and the total charge transferwas greater (p < 0.001) in total currents evoked at the axon terminalscompared with total responses elicited at the dendrites. Thisresult is consistent with the idea that GABA_C receptors are abundantat bipolar cell axon terminals but primarily absent from the dendrites.

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Figure 3. GABA_A and GABA_C receptor-mediated currents have distinct time courses. A, Current responses evoked by puffing GABA (200 µM pipette concentration) onto the axon terminals of a single rod bipolar cell in the presence of either bicuculline (200 µM) (thin trace, GABA_C) or 3-APMPA (300 µM) (thick trace, GABA_A). For comparison, the trace marked GABA_A has been scaled to the amplitude of the trace marked GABA_C. Vertical calibration bar: GABA_C, 50 pA; GABA_A, 27 pA. In the presence of 3-APMPA, the GABA_A receptor-mediated current had a D₃₇ of 112 msec and a time-to-peak of 58 msec. The GABA_C component, recorded in the presence of bicuculline, had a D₃₇ of 1037 msec and a time-to-peak of 170 msec. B, C, Time course data for currents evoked at the dendrites or axon terminals in a mixed population of bipolar cells. B, The average D₃₇ of currents evoked at the dendrites (black bar) was 244 ± 24 msec (n = 16). For responses evoked at the terminals (white bars), the average D₃₇ of currents mediated by GABA_A receptors (labeled A) was 225 ± 20 msec (n = 36) and by GABA_C receptors (labeled C) was 677 ± 66 msec (n = 40). The average D₃₇ of GABA_A receptors on the axon terminals was significantly different from GABA_C receptors on the terminals (p < 0.001), but not from GABA receptors on the dendrites (p = 0.3). C, Currents evoked at the dendrites (black bar) reached peak amplitude in an average of 100 ± 13 msec (n = 16). For currents evoked at the axon terminals (white bars), the average time-to-peak of the GABA_A component (labeled A) was 120 ± 12 msec (n = 36) and of the GABA_C component (labeled C) was 192 ± 15 msec (n = 40). The average time-to-peak of GABA_A receptors on the terminals was significantly different from GABA_C receptors on the terminals (p < 0.001), but not from dendritic GABA receptors (p = 0.1).

The relative expression of GABA_A and GABA_C receptors varies with bipolar cell class

Because of the distinct kinetics of GABA_A and GABA_C receptors, their relative expression on bipolar cell terminals could underliedifferences in the time course of GABAergic inhibition betweencell classes. To determine whether the relative expression ofGABA_A and GABA_C receptors on bipolar cell terminals could accountfor the differences in response time course, we recorded GABA-evokedcurrents in the presence and absence of specific GABA receptorantagonists.

Our pharmacological studies revealed differences among rod, ON cone, and OFF cone bipolar cells in the proportion of GABA_Aand GABA_C receptors present on axon terminals. The current tracesin Figure 4 were recorded from a rod, an ON cone, and an OFF conebipolar cell. Bicuculline and 3-APMPA differed in their abilityto antagonize GABA-evoked currents in these three morphologicallydistinct bipolar cells. As shown in Figure 4A-C (left column,Bicuculline), the GABA_A antagonist bicuculline reduced GABA-evokedcurrents most effectively in the OFF cone, less in the ON cone,and least in the rod bipolar cell. The GABA_C antagonist 3-APMPA(right column, 3-APMPA), however, was most effective in the rodbipolar cell and least effective in the OFF cone bipolar cell.

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Figure 4. Effects of bicuculline and 3-APMPA on currents evoked in three morphologically distinct bipolar cells. Thin traces (Control in A) are currents elicited by puffing GABA (200 µM pipette concentration) onto the axon terminals in the absence of GABAergic antagonists. A-C, Compared with control levels, bicuculline (200 µM) (left column, thick traces, Bic) reduced the charge transfer to 82% in a rod (A), 53% in an ON cone (B), and 33% in an OFF cone bipolar cell (C). Relative to control, 3-APMPA (300 µM) (right column, thick traces, 3-A) decreased the charge transfer to 11% in the rod (A), 34% in the ON cone (B), and 57% in the OFF cone bipolar cell (C). The combination of bicuculline and 3-APMPA abolished responses in each of the three bipolar cells (0-6% of control levels; data not shown).

Figure 5A shows that bicuculline most effectively reduced the charge transfer of GABA-elicited responses in OFF cone bipolarcells, but was less effective in ON cone and least effective inrod bipolar cells. In contrast, Figure 5B shows that the effectsof 3-APMPA were smallest in OFF cone, greater in ON cone, andgreatest in rod bipolar cells. These results suggest that theratio of GABA_C to GABA_A receptors expressed on axon terminalsvaries among cell types. The GABA_C component was highest in rodbipolar cells, generally intermediate in ON cone bipolar cells,and lowest in OFF cone bipolar cells. Within the ON and OFF conebipolar cell populations, however, there are exceptions to thistrend that were not readily apparent in the population data.

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Figure 5. Differential effects of GABAergic antagonists on currents evoked in distinct classes of bipolar cells. A, Effects of bicuculline on the charge transfer of currents evoked by puffing GABA (200 µM pipette concentration) onto the axon terminals. Relative to control, bicuculline (200 µM) reduced the charge transfer to 83 ± 4% (n = 12) in rod (Rod), 71 ± 4% (n = 11) in ON cone (ON), and 54 ± 6% (n = 15) in OFF cone (OFF) bipolar cells. The percent blockade by bicuculline was significantly different between rod and ON cone (p = 0.03), rod and OFF cone (p < 0.001), and ON cone and OFF cone (p = 0.01) bipolar cell populations. B, Relative to control levels, 3-APMPA (300 µM) reduced the charge transfer to 15 ± 3% (n = 9) in rod (Rod), 37 ± 6% (n = 10) in ON cone (ON), and 65 ± 6% (n = 12) in OFF cone (OFF) bipolar cells. The reduction by 3-APMPA was significantly different between populations of rod and ON (p = 0.005), rod and OFF (p < 0.001), and ON and OFF bipolar cells (p = 0.003). In all cells, the combination of bicuculline and 3-APMPA abolished GABA-evoked currents (2.4 ± 0.4% of control levels; n = 50; data not shown).

As shown in Figures 2 and 3, OFF cone bipolar cell responses were very brief compared with those of rod and ON cone bipolarcells, and currents mediated by GABA_A receptors were very transientcompared with those mediated by GABA_C receptors. Together withthe finding that the relative expression of GABA_A and GABA_C receptorson axon terminals varies with cell class, our time course datasuggest that the relative expression of GABA receptor subtypesmay influence response kinetics. That is, currents in cells witha high GABA_C to GABA_A ratio are longer lasting relative to currentsin cells with a lower GABA_C to GABA_A ratio. Although there isa possibility for additional contributions from other factors,such as differences in GABA uptake mechanisms, receptor subunitcomposition, and barriers to diffusion, our data support a rolefor the relative expression of GABA_A and GABA_C receptors in determiningthe time course of GABAergic inhibition in mammalian retinalneurons.

GABAergic IPSCs in bipolar cells

The data reported above confirm that ferret bipolar cell terminals express functional GABA_A and GABA_C receptors but do notindicate whether both receptor classes participate in synapticresponses. To determine whether synaptic stimuli activate oneor both receptor subtypes, we recorded GABAergic IPSCs evokedby puffing kainate (500 µM) in the IPL to depolarize amacrinecell processes. The IPSC depicted in Figure 6 was partially blockedby bicuculline (200 µM) and completely abolished with the additionof 3-APMPA (300 µM). In six bipolar cells, bicuculline reducedthe charge transfer of the IPSC to 29 ± 12% of control. 3-APMPAdecreased the charge transfer to 8.8 ± 2.3% (n = 8) of controlvalues. In all cells, the combination of bicuculline and 3-APMPAblocked the response (1.8 ± 1.3% of control), and IPSCs recoveredto 62 ± 5.8% of control (n = 10).

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Figure 6. GABA_A and GABA_C receptors mediate GABAergic IPSCs. Current responses evoked in an ON cone bipolar cell by puffing kainate (500 µM) in the IPL. Bicuculline (200 µM) decreased the response charge transfer to 31% (Bic), and 3-APMPA (300 µM) reduced the bicuculline-resistant component to 4% of control (Bic & 3A). Upon washout of antagonist, the IPSC charge transfer recovered to 75% of control.

Immunolabeling for GABA_A and GABA_C receptors in the OPL and IPL

Our physiological recordings suggest that responses evoked by puffing GABA in the OPL are dominated by GABA_A receptors, whereasresponses to puffing in the IPL comprised GABA_A and GABA_C components.To correlate this finding with the anatomical distribution ofthese receptor subtypes, we immunolabeled ferret retinal sectionsfor the $beta$ 2/3 subunit of the GABA_A receptor and for the $rho$ subunitof the GABA_C receptor (Fig. 7). Immunoreactivity for the $beta$ 2/3subunit (Fig. 7A) was intense in both the IPL and OPL. In addition,some cell bodies in the inner nuclear layer (INL) and the dendriticprocesses of these cells also appeared labeled (Fig. 7A). Strong,punctate immunolabeling for the $rho$ subunit was also clearly evidentin the IPL (Fig. 7B). However, $rho$ subunit labeling differed from $beta$ 2/3 subunit staining in two ways. Unlike $beta$ 2/3 subunit labeling, $rho$ subunit immunoreactivity was strongly concentrated in two bandsin the IPL, one band in the proximal (ON) and the other in thedistal (OFF) sublamina. In addition, $rho$ subunit immunoreactivityin the OPL was relatively weak, if at all present (Fig. 7B). Together,these data suggest that the patterns of immunostaining in theferret retina were distinct for the GABA_A and GABA_C subunits.In addition, the pattern of immunolabeling for GABA_A and GABA_Creceptor subunits lends support to the physiological findingsthat GABA-evoked responses in the ferret OPL are mainly mediatedby GABA_A receptors and that responses in the IPL are mediatedby both GABA_A and GABA_C receptors.

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Figure 7. Confocal images of GABA_A (A) and GABA_C (B) receptor immunostaining in the adult ferret retina. Arrows in A point to two putative bipolar cells that showed dendritic labeling. C, Control section for GABA_C staining in which the primary antibody was omitted. Images in B and C were acquired with the same objective (40×) and at the same laser intensity, gain, and black level.

Immunolabeling for GABA_A and GABA_C receptors on distinct bipolar cell classes

Our physiological recordings also suggest that the relative proportions of GABA_A and GABA_C receptors on the axons of bipolarcells varied with cell type. In particular, rod bipolar cellsappeared to have responses mediated predominantly by GABA_C receptors,whereas ON and OFF cone bipolar cells showed a variety of responsesthat could reflect differences in receptor complements. To relatethe physiological results to the anatomical expression of thetwo ionotropic GABA receptor subtypes, we compared the patternsof immunolabeling for the GABA_A receptor $beta$ 2/3 subunit and theGABA_C $rho$ subunit with immunolabeling for rod and cone (ON and OFF)bipolarcells.

Rod and cone bipolar cells can be distinguished in the ferret retina by immunolabeling for PKC, recoverin, and calbindin (Figs.8, 9, all shown in green) (Miller et al., 1999). Rod bipolar cellsare immunoreactive for PKC, subpopulations of ON and OFF conebipolar cells label for recoverin, and a subset of ON cone bipolarsexpress calbindin. Figure 8 illustrates the spatial distributionof the axon terminals of ferret rod and cone bipolar cells relativeto the distribution of GABA_A (Fig. 8, blue) and GABA_C subunits(Figs. 8, 9, red). Rod bipolar cells (PKC-positive) had axon terminalsthat stratified in the inner two-fifths of the IPL in a regionthat overlaps with the inner band of GABA_C $rho$ subunit staining(Fig. 8A). Two major subsets of recoverin-positive bipolar cellscould be identified; one population had axon terminals that stratifiedin the outer IPL, corresponding to the outer $rho$ subunit band, whereasthe terminals of the other population stratified primarily inthe sublamina of the IPL that had only weak or sparse GABA_C staining(Fig. 8C). Calbindin-positive bipolar cells had axon terminalsthat also stratified primarily in the inner band strongly labeledfor GABA_C receptors (Fig. 8E).

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Figure 8. Top. Confocal images (each panel represents the maximum intensity projection of a stack of 10-15 images) demonstrating patterns of immunostaining for bipolar cells, GABA_A, and GABA_C receptors in the adult ferret retina. GABA_C receptor immunolabeling is encoded in red, whereas GABA_A receptors are in shown in blue. PKC (A, B), recoverin (C, D), and calbindin (E) immunolabeling for bipolar cells are shown in green.

Figure 9. Bottom. High magnification of the maximum intensity projections of short z-stacks of 10-15 images of the IPL showing colabeling of GABA_C receptors (red) with bipolar cell axon terminals (green). Bipolar cell terminals were labeled for PKC (A), recoverin (C), and calbindin (E). Silhouettes of the labeled bipolar terminals in A, C, and E are shown in B, D, and F, respectively. Colocalization with GABA_C staining is represented by the red profiles, determined after 3-D rotation of the image stacks.

GABA_A $beta$ 2/3 subunit staining showed no unique spatial correspondence to the PKC- or recoverin-positive terminals (Fig. 8B,D).The spatial relationship between the location of the axon arborand the distribution of GABA_A $beta$ 2/3 subunit could not be assessedfor calbindin labeling (see Materials andMethods).

To more directly associate the spatial distribution of GABA receptors with the axon terminals of the bipolar cells, we obtainedhigh-magnification 3-D reconstructions of the IPL in the immunolabeledsections. GABA_A $beta$ 2/3 subunit staining was extremely dense andthe puncta small compared with $rho$ -subunit staining, rendering itdifficult to observe colocalization of this receptor subunit withaxonal profiles. We thus focused our analysis on the colocalizationof $rho$ subunit staining with PKC-, recoverin-, and calbindin-labeledaxon terminals. We first obtained a short stack of confocal imagesthrough the region of interest at fine z-steps (0.1 µm) and thenreconstructed and rotated the images in 3-D. This enabled us tomore confidently follow and confirm colocalization of receptorpuncta with immunolabeling for the various bipolar cell markers.Only $rho$ subunit-positive staining or puncta that merged with anaxonal profile in all 3-D views were considered to be colocalizedwith the process. These regions are shaded within an outline ofthe axon terminals that were reconstructed and represented asa z-projection of the stack in Figure 8, B, D, and F.

There was clear and qualitatively extensive colocalization of $rho$ subunit staining with PKC-immunoreactive terminals in theIPL (Fig. 9A,B), supporting the physiological finding that responsesevoked by puffing at the axon terminals of these cells are primarilymediated by GABA_C receptors. Recoverin-positive terminals showedtwo contrasting patterns of colocalization. Terminals in the outerIPL were heavily colocalized with $rho$ subunit immunostaining, whereasthose in the inner IPL had relatively little GABA_C staining (Fig.9C,D). Thus, some OFF cone bipolar cells with a relatively largeGABA_C-mediated component in their physiological response may correspondto recoverin-positive cells with terminals in the distal IPL.Finally, like ON recoverin-positive bipolar cells, the axon terminalsof calbindin-labeled bipolar cells also bore little GABA_C staining,despite their stratification within the inner band of GABA_C expression(Fig. 9E,F).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Differential distribution of ionotropic GABA receptors on axons and dendrites

GABA_A and GABA_C receptors differ in their kinetics and affinity for GABA. In this study, we show that these subtypes of GABAreceptors have a differential spatial distribution on ferret bipolarcells. Our physiological results demonstrated that bipolar celldendrites primarily expressed GABA_A receptors and the axon terminalspossessed combinations of GABA_A and GABA_C receptors, which variedwith bipolar cell type. Consistent with the different functionalproperties of GABA_A and GABA_C receptors, we found that GABA responsesat the dendrites and axon terminals were temporally distinct.Our immunocytochemical staining for GABA receptor subunits corroboratedour physiological data. Similar to results in other mammalianspecies, our immunolabeling for GABA_A and GABA_C subunits showeda differential spatial distribution in which label for the GABA_Asubunit was intense in the IPL and OPL, and staining for the GABA_Csubunit was strong in the IPL but weak in the OPL. (Greferathet al., 1993, 1994, 1995; Enz et al., 1996; Koulen et al., 1997).

GABA_A receptors and postsynaptic inhibition

Postsynaptic inhibition mediated by dendritic GABA_A receptors is a common feature of most CNS neurons and presumably functionsto modulate neuronal responses to excitatory inputs. Our physiologicaland immunocytochemical data demonstrate that GABA_A receptors playthe major role in mediating dendritic GABA responses in all bipolarcell classes. In contrast, GABA_C receptors contribute minimallyto dendritic responses and exhibit only weak labeling in the OPL.Dendritic GABA_A receptors most likely receive GABAergic inputfrom interplexiform and horizontal cells (Fisher and Boycott,1974; Kolb and West, 1977; Chun and Wässle, 1989; Pourcho andOwczarzak, 1989). The function of dendritic GABA receptors ininformation processing is unknown. A possible role for these GABAreceptors would be to modulate the inhibitory surround of bipolarcells, but the results of recent studies in salamander conflictwith this possibility (Hare and Owen, 1996; Cook and McReynolds,1998). Although the precise function of GABA receptors on bipolarcell dendrites is unclear, they likely function in regulatingresponses to glutamatergic input, similar to other dendritic GABA_Areceptors in theCNS.

Relative roles of GABA_A and GABA_C receptors in presynaptic inhibition

In the CNS, the activation of ionotropic receptors on the axon terminal can modulate the release of neurotransmitters (forreview, see MacDermott et al., 1999). Glutamate release from theaxon terminals of salamander retinal bipolar cells is most likelymodulated by two types of ionotropic GABA receptors (Lukasiewiczand Werblin, 1994; Dong and Werblin, 1998). These two receptorsubtypes can be simultaneously activated by GABA puffed onto theterminals or by GABA released from presynaptic amacrine cells.Both our time course and pharmacological data reveal two componentsin the GABA-evoked response, indicating that both GABA_A and GABA_Creceptors mediate these currents in ferret bipolar cell terminals.These observations are corroborated by our immunocytochemicalstaining for GABA_A and GABA_C receptorsubunits.

Why are two ionotropic receptors for GABA necessary to modulate glutamate release from the bipolar terminals? Because of thedistinct affinities and kinetics of the GABA_A and GABA_C receptors,a combination of these receptors on a single axon terminal offersa much larger dynamic range in the summed response to GABA thanthe expression of either subtype alone. For example, comparedwith GABA_A, GABA_C receptors can respond to much lower concentrationsof GABA. Furthermore, activation of GABA_C receptors yields a moresustained inhibition relative to that provided by GABA_A receptors.Because the release of glutamate from bipolar cells can be relativelyslow and sustained compared with that from a spiking neuron, GABA_Creceptors can provide inhibition that is temporally matched tothe kinetics of this release. In contrast, GABA_A receptors, whichmediate fast responses to GABA, offer the ability to rapidly andtransiently suppress glutamate release. The idea that the temporalcharacteristics of inhibitory currents shape the timing of thesuppression of bipolar cell activity was examined by Pan and Lipton(Pan and Lipton, 1995). They demonstrated that inhibitory currentsmediated by GABA_A receptors rapidly and transiently suppresseddepolarization-induced Ca²⁺ currents in dissociated rat bipolar cells. In contrast, GABA_Creceptor-mediated suppression of the Ca²⁺ current was slower in onset and more sustained. Furthermore,Dong and Werblin (1998) showed that GABA_C (and not GABA_A) receptorsare responsible for the inhibition of maintained glutamate releasefrom bipolar cells, which may underlie the generation of transientexcitation in ganglion cells (Dong and Werblin, 1998).

Immunocytochemical staining suggests that GABA_A and GABA_C receptor subunits do not colocalize at the same synaptic sites (Koulenet al., 1998). Apart from the distinct properties of GABA_A andGABA_C receptors, differences in the spatial location of thesereceptor subtypes relative to synaptic sites may also contributeto the regulation of release from bipolar terminals. One possibilityis that low-affinity GABA_A receptors are located at GABAergicsynapses, whereas higher-affinity GABA_C receptors are distributedextrasynaptically in which they could respond to GABA spilloverinto extrasynaptic space. This arrangement exists in the rat cerebellumin which high-affinity extrasynaptic GABA_A receptors with $delta$ subunitsmediate a sustained response, and lower-affinity synaptic GABA_Areceptors without $delta$ subunits mediate transient responses (Nusseret al., 1998). Recent ultrastructural evidence, however, suggeststhat GABA_C receptors cluster at synaptic sites in rat retina (Koulenet al., 1998). Furthermore, our study demonstrated that both GABA_Aand GABA_C receptors mediate GABAergic IPSCs. These findings suggestthat GABA_C receptors can be activated synaptically but do notexclude the possibility of activation by spillover of GABA fromdistant release sites. If GABA_A and GABA_C receptors are locatedat distinct synapses, perhaps each receives input from differenttypes of GABAergic amacrine cells. Such an arrangement has beenobserved in the hippocampus in which two kinetically distinctGABA_A synaptic responses are mediated by different inhibitorycircuits (Banks et al., 1998).

Differences in the relative expression of GABA_A and GABA_C receptors on distinct classes of bipolar cells

Results of experiments in both ferret and rat indicate that the GABA_A to GABA_C receptor ratio varied among different morphologicalclasses of bipolar cells (Euler and Wässle, 1998). In our experiments,focal puffs of GABA onto either the dendritic or axonal arborsof ferret bipolar cells evoked responses that showed differencesin the GABA_A to GABA_C receptor ratio specifically for currentselicited at the axon terminals. In the rat, responses were evokedby bath application of GABA, which presumably activated dendriticas well as axonal GABA receptors (Euler and Wässle, 1998). Theseresponses showed differences in the GABA_A to GABA_C receptor ratiofor currents mediated simultaneously by dendritic and axonal GABAreceptors. Thus, differences in GABA application methodologiesmay explain any discrepancies between these twostudies.

In both ferret and rat (Euler and Wässle, 1998), rod bipolar cells clearly possess the highest GABA_C to GABA_A ratio. Thishigh ratio is confirmed by immunocytochemical localization ofGABA_C receptor staining to PKC-positive bipolar cells in retinaeof the ferret and other species (Enz et al., 1996; Koulen et al.,1997). Our population data also suggest a general trend for thecomponent of the response mediated by GABA_C receptors to increasefrom OFF cone to ON cone to rod bipolar cells. However, thereare some exceptions to this trend within ON and OFF cone populations.For example, a subpopulation of OFF bipolar cells showed a relativelylarge GABA_C component compared with other OFF bipolar cells. Fromour immunocytochemical staining for GABA_C receptors, this populationmay correspond to that which is immunopositive for recoverin.In contrast, some ON bipolar cells appear to have a small GABA_Ccomponent. These cells may be the calbindin- and recoverin-positiveON bipolar cells identified in ourimmunocytochemistry.

Why do distinct classes of bipolar cells express different ratios of GABA_C to GABA_A receptors on their axon terminals? Onepossibility is to match the temporal characteristics of excitatoryand inhibitory responses. The kinetic properties of responsesin the rod and cone pathways are distinct. Rod light responsesare 10 times slower than cone responses, and the kinetics of synaptictransfer are 10 times longer at rod synapses than at cone synapses(Schnapf and Copenhagen, 1982). Noise analysis indicates thatcone-mediated synaptic events in ON bipolar cells were longerthan those in OFF bipolar cells (Ashmore and Copenhagen, 1980),consistent with the notion of slower synaptic transfer in theON cone pathway compared with the OFF cone pathway. These differencesare most likely attributable to the presence of metabotropic glutamatereceptors on ON bipolar cell dendrites (Slaughter and Miller,1981; Nawy and Jahr, 1990) and kainate receptors on OFF bipolarcell dendrites (Devries and Schwartz, 1999). Our results showthat the kinetics of inhibition at the bipolar cell terminalsis matched to the kinetics of the excitatory responses in differentclasses of bipolar cells. Rod bipolar cells have the slowest excitatoryresponses and the largest complement of GABA_C receptors, whereasOFF cone bipolar cells have the fastest excitatory responses andgenerally possess the largest complement of GABA_A receptors. Thisarrangement may ensure that inhibitory currents are sustainedenough to prevent rebound excitation, yet brief enough to permitresponses to subsequentstimuli.

  FOOTNOTES

Received Oct. 8, 1999; revised Jan. 10, 2000; accepted Jan. 21, 2000.

This work was supported by National Institutes of Health Grants EY08922 (P.D.L.), EY07057 (C.R.S.), EY10699 (R.O.L.W.), andEY02687 (Department of Ophthalmology), and Research to PreventBlindness. We thank Dr. Paul B. Cook, Dr. Carl Romano, and MattHiggs for their insightful comments on thismanuscript.
Correspondence should be addressed to Dr. Peter D. Lukasiewicz, Department of Ophthalmology and Visual Sciences, Campus Box8096, Washington University School of Medicine, St. Louis, MO63110-1093. E-mail: lukasiewicz{at}vision.wustl.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Ames A, Nesbett FB (1981) In vitro retina as an experimental model of the central nervous system. J Neurochem 37:867-877[ISI][Medline].
Amin J, Weiss DS (1994) Homomeric $rho$ 1 GABA channels: activation properties and domains. Receptors Channels 2:227-236[ISI][Medline].
Ashmore JF, Copenhagen DR (1980) Different postsynaptic events in two types of retinal bipolar cell. Nature 288:84-86[Medline].
Banks MI, Li T-B, Pearce RA (1998) The synaptic basis of GABA_A,slow. J Neurosci 18:1305-1317[Abstract/Free Full Text].
Belgum JH, Dvorak DR, McReynolds JS (1984) Strychnine blocks transient but not sustained inhibition in mudpuppy retinal ganglion cells. J Physiol (Lond) 354:273-286[Abstract/Free Full Text].
Bormann J, Feigenspan A (1995) GABA_C receptors. Trends Neurosci 18:515-519[ISI][Medline].
Chun M, Wässle H (1989) GABA-like immunoreactivity in the cat retina: electron microscopy. J Comp Neurol 279:55-67[ISI][Medline].
Cook PB, McReynolds JS (1998) Lateral inhibition in the inner retina is important for spatial tuning of ganglion cells. Nat Neurosci 1:714-719[ISI][Medline].
Devries SH, Schwartz EA (1999) Kainate receptors mediate synaptic transmission between cones and OFF bipolar cells in a mammalian retina. Nature 397:157-160[Medline].
Dong C, Werblin FS (1998) Temporal contrast enhancement via GABA_C feedback at bipolar terminals in the tiger salamander retina. J Neurophysiol 79:2171-2180[Abstract/Free Full Text].
Enz R, Brandstätter JH, Wässle H, Bormann J (1996) Immunocytochemical localization of the GABA_C receptor $rho$ subunits in the mammalian retina. J Neurosci 16:4479-4490[Abstract/Free Full Text].
Euler T, Wässle H (1995) Immunocytochemical identification of cone bipolar cells in the rat retina. J Comp Neurol 361:461-478[ISI][Medline].
Euler T, Wässle H (1998) Different contributions of GABA_A and GABA_C receptors to rod and cone bipolar cells in a rat retinal slice preparation. J Neurophysiol 79:1384-1395[Abstract/Free Full Text].
Famiglietti Jr EV, Kolb H (1976) Structural basis for ON- and OFF-center responses in retinal ganglion cells. Science 194:193-195[Abstract/Free Full Text].
Feigenspan A, Bormann J (1994) Differential pharmacology of GABA_A and GABA_C receptors on rat retinal bipolar cells. Eur J Pharmacol 288:97-104[ISI][Medline].
Feigenspan A, Wässle H, Bormann J (1993) Pharmacology of GABA receptor Cl channels in rat retinal bipolar cells. Nature 361:159-162[Medline].
Fisher SK, Boycott BB (1974) Synaptic connexions made by horizontal cells within the outer plexiform layer of the retina of the cat and the rabbit. Proc R Soc Lond B Biol Sci 186:317-331[Medline].
Greferath U, Müller F, Wässle H, Shivers B, Seeburg P (1993) Localization of GABA_A receptors in the rat retina. Vis Neurosci 10:551-561[ISI][Medline].
Greferath U, Grünert U, Müller F, Wässle H (1994) Localization of GABA_A receptors in the rabbit retina. Cell Tissue Res 276:295-307[ISI][Medline].
Greferath U, Grünert U, Fritschy JM, Stephenson A, Mohler H, Wässle H (1995) GABA_A receptor subunits have differential distributions in the rat retina: in situ hybridization and immunohistochemistry. J Comp Neurol 353:553-571[ISI][Medline].
Hamill OP, Marty A, Neher E, Sakmann B, Sigworth FJ (1981) Improved patch clamp techniques for high resolution current recording from cells and cell-free patches. Pflügers Arch 391:85-100[ISI][Medline].
Hare WA, Owen G (1996) Receptive field of the retinal bipolar cell: a pharmacological study in the tiger salamander. J Neurophysiol 76:2005-2019[Abstract/Free Full Text].
Hevers W, Lüddens H (1998) The diversity of GABA_A receptors: pharmacological and electrophysiological properties of GABA_A channel subtypes. Mol Neurobiol 18:35-86[ISI][Medline].
Kolb H, West RW (1977) Synaptic connections of the interplexiform cell in the retina of the cat. J Neurocytol 6:155-170[ISI][Medline].
Koulen P, Brandstätter JH, Kroger S, Enz R, Bormann J, Wässle H (1997) Immunocytochemical localization of the GABA_C receptor $rho$ subunits in the cat, goldfish and chicken retina. J Comp Neurol 380:520-532[ISI][Medline].
Koulen P, Brandstätter JH, Enz R, Bormann J, Wässle H (1998) Synaptic clustering of GABA_C receptor $rho$ -subunits in rat retina. Eur J Neurosci 10:115-127[ISI][Medline].
Lukasiewicz PD (1996) GABA_C receptors in the vertebrate retina. Mol Neurobiol 12:211-224[ISI][Medline].
Lukasiewicz PD, Roeder RC (1995) Evidence for glycine modulation of excitatory synaptic inputs to retinal ganglion cells. J Neurosci 15:4592-4601[Abstract].
Lukasiewicz P, Shields C (1998a) Different combinations of GABA_A and GABA_C receptors confer distinct temporal properties to retinal synaptic responses. J Neurophysiol 79:3157-3167[Abstract/Free Full Text].
Lukasiewicz PD, Shields CR (1998b) A diversity of GABA receptors in the retina. Semin Cell Dev Biol 9:293-299[ISI][Medline].
Lukasiewicz P, Werblin F (1988) A slowly inactivating potassium current truncates spike activity in ganglion cells of the tiger salamander retina. J Neurosci 8:4470-4481[Abstract].
Lukasiewicz PD, Werblin FS (1994) A novel GABA receptor modulates synaptic transmission from bipolar to ganglion and amacrine cells in the tiger salamander retina. J Neurosci 14:1213-1223[Abstract].
Lukasiewicz PD, Wong ROL (1997) GABA_C receptors on ferret retinal bipolar cells; a diversity of subtypes in mammals? Vis Neurosci 14:989-994[ISI][Medline].
MacDermott AB, Role LW, Sieglbaum SA (1999) Presynaptic ionotropic receptors and the control of transmitter release. Annu Rev Neurosci 22:443-485[ISI][Medline].
Miller ED, Tran MN, Wong GK, Oakley DM, Wong ROL (1999) Morphological differentiation of bipolar cells in the ferret retina. Vis Neurosci 16:1133-1144[Medline].
Mittman S, Taylor WR, Copenhagen DR (1990) Concomitant activation of two types of glutamate receptor mediates excitation of salamander retinal ganglion cells. J Physiol (Lond) 428:175-197[Abstract/Free Full Text].
Nawy S, Jahr CE (1990) Suppression by glutamate of cGMP-activated conductance in retinal bipolar cells. Nature 346:269-271[Medline].
Nelson R, Famiglietti Jr EV, Kolb H (1978) Intracellular staining reveals different levels of stratification for On- and Off-center ganglion cells in cat retina. J Neurophysiol 41:472-483[Abstract/Free Full Text].
Nusser Z, Sieghart W, Somogyi P (1998) Segregation of different GABA_A receptors to synaptic and extrasynaptic membranes of cerebellar granule cells. J Neurosci 18:1693-1703[Abstrac