Active Role of Glutamate Uptake in the Synaptic Transmission from Retinal Nonspiking Neurons

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The Journal of Neuroscience, August 15, 1999, 19(16):6755-6766

Active Role of Glutamate Uptake in the Synaptic Transmission from Retinal Nonspiking Neurons
Ko Matsui, Nobutake Hosoi, and Masao Tachibana
Department of Psychology, Graduate School of Humanities and Sociology, The University of Tokyo, Tokyo 113-0033, Japan

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We examined the role of glutamate uptake in the synaptic transmission of graded responses from newt retinal bipolar cells(BCs) to ganglion layer cells (GLCs). In dissociated Müller cells(retinal glia), glutamate evoked an uptake current that was effectivelyinhibited by L-trans-pyrrolidine-2,4-dicarboxylic acid (PDC).PDC had no effect on the non-NMDA receptors of dissociated spikingneurons. In the retinal slice preparation, dual whole-cell recordingswere performed from a pair of BC and GLC. A depolarizing pulseapplied to a BC activated the Ca²⁺ current (I_Ca) in the BC and evoked an EPSC in the GLC. Applicationof PDC prolonged both non-NMDA and NMDA receptor-mediated componentsof the evoked EPSC but changed neither the amplitude nor timecourse of I_Ca. When the slice preparation was superfused witha solution containing glutamate but not PDC, the evoked EPSC decreasedin amplitude without changing the time course, suggesting thatthe prolongation of the evoked EPSC is not attributable to a simpleincrease in ambient glutamate concentration after inhibition ofglutamate uptake. Because PDC did not affect the amplitude, timecourse, or frequency of spontaneous EPSCs, it is unlikely thatPDC modified presynaptic and/or postsynaptic mechanisms. Theseresults indicate that inhibition of glutamate uptake slows theclearance of glutamate accumulated in the synaptic cleft by multiplequantal release and prolongs the evoked EPSC. The role of glutamateuptake at synapses in the inner retina is not only to maintainthe extracellular glutamate concentration at a low level but alsoto terminate the light-evoked EPSCsrapidly.

Key words: retina; bipolar cell; ganglion cell; Müller cell; synaptic transmission; glutamate; uptake; transporter; non-NMDA receptor; NMDA receptor; EPSC; spontaneous EPSC

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In synapses in which spikes trigger glutamate release, the slow decay (>100 msec) of the NMDA receptor-mediated EPSC (NMDA-EPSC)is determined mainly by the channel kinetics, which are much slowerthan the decrease of glutamate in the synaptic cleft (Lester etal., 1990). On the other hand, it is unclear what determines therapid decay of the non-NMDA receptor-mediated EPSC (non-NMDA-EPSC),because the time course of glutamate release (Diamond and Jahr,1995), the rate of glutamate clearance (Clements, 1996), and thedeactivation and desensitization rate of non-NMDA receptors (Jonesand Westbrook, 1996) all fall into the order of a fewmilliseconds.

Glutamate extrusion from the synaptic cleft seems to rely entirely on passive diffusion and uptake by glutamate transporters.However, it is still not known whether uptake speeds up the clearancerate of glutamate fast enough to alter the shape of EPSCs. Somepapers report that blockade of glutamate uptake may retard glutamateclearance from the synaptic cleft, but the time course of thespike-induced non-NMDA-EPSC is determined primarily by the propertiesof non-NMDA receptors (Isaacson and Nicoll, 1993; Sarantis etal., 1993). These results suggest that glutamate uptake may beimportant only for maintaining the glutamate concentration ata low level in the synapses in which spikes trigger transmitterrelease.

Retinal bipolar cells (BCs) are nonspiking neurons and respond to photo stimulation in a graded manner (Saito and Kujiraoka,1982). The amount of glutamate release from the terminal of BCincreases as the duration of depolarizing pulses is prolongedup to a few hundred milliseconds (Sakaba et al., 1997). Usingthe retinal slice preparation, we have demonstrated that a depolarizingpulse applied to a single BC evokes an EPSC in a synapticallyconnected ganglion layer cell (GLC) (Matsui et al., 1998). TheEPSC consists of a rapidly activated non-NMDA-EPSC and a slowlyactivated NMDA-EPSC. With increasing the duration of depolarizingpulses applied to the BC, the non-NMDA-EPSC desensitizes substantially,whereas the NMDA-EPSC is prolonged. These results indicate thatsynaptically released glutamate remains elevated for awhile andsuggest that uptake by glutamate transporters may be of particularimportance in determining the decay time course of the evokedEPSC inGLCs.

Using the retinal slice preparation, we investigated whether inhibitors of glutamate uptake affect the shape of the evokedand spontaneous EPSCs in GLCs. We found that introduction of uptakeinhibitors slowed the decay of the evoked non-NMDA-EPSC and NMDA-EPSCbut not the spontaneous EPSC, which consisted only of a non-NMDAcomponent. These results indicate that, at synapses formed betweenBC and GLC in the retina, glutamate uptake has an active rolein the clearance of glutamate and shapes the time course of EPSCsevoked by single depolarizingpulses.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Recordings from the retinal slice preparation. GLCs consist of ganglion cells and displaced amacrine cells (Ball and Dickson,1983). As stated in our previous paper (Matsui et al., 1998),the two cell types could not be readily classified in the newt(Cynops pyrrhogaster) retinal slice preparation with the morphology,the light response, or the membrane current properties. In thepresent study, we did not distinguish between amacrine and ganglioncells.

Whole-cell patch recordings were made from either synaptically connected BC and GLC pairs or GLCs alone. Procedures for preparingthe newt retinal slices were met by the guidelines of the PhysiologicalSociety of Japan and have been described in detail previously(Matsui et al., 1998).

The slices were superfused continuously with the oxygenated control solution S1 (in mM): 110 NaCl, 2 KCl, 2 CaCl₂, 1 MgCl₂,5 glucose, and 5 HEPES titrated to pH 7.8 with NaOH. Picrotoxin(200 µM) and strychnine (10 µM) (both from Sigma, St. Louis, MO)were added to S1 to block the activation of GABA and glycine receptors,respectively. D( $-$ )-2-Amino-5-phosphonopentanoic acid (D-AP-5)(50 µM) was also included to isolate the non-NMDA receptor-mediatedcurrent in most of the experiments. When the NMDA receptor-mediatedcurrent was monitored, either 5 µM 6-nitro-7-sulfamoylbenzo[F]quinoxaline-2,3-dione(NBQX) or 10 µM 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) wassubstituted for D-AP-5. D-AP-5, NBQX, CNQX, L- trans-pyrrolidine-2,4-dicarboxylicacid (PDC), and L( $-$ )-threo-3-hydroxyaspartic acid (THA) were purchasedfrom Tocris Cookson (Bristol,UK).

The pipette solution for BC recordings consisted of P1 (in mM): 84 CsCH₃SO₄, 4 CsCl, 10 TEA-Cl, 5.5 MgCl₂, 0.2 BAPTA, 20 HEPES,5 ATP disodium salt, and 0.5 GTP trisodium salt. The pipette solutionfor GLC recordings consisted of P2 (in mM): 65-70 CsCH₃SO₄, 3CsCl, 5 CsF, 10 TEA-Cl, 5.5 MgCl₂, 0.5 CaCl₂, 5 EGTA, 20 HEPES,and 5 ATP. Both solutions were titrated to pH 7.7-7.8 with CsOHand supplemented with 0.25% Lucifer yellow CH dipotassium salt.Liquid junction potentials were corrected for allrecordings.

BCs and GLCs were whole-cell voltage-clamped with two EPC-7 (List, Darmstadt, Germany) patch-clamp amplifiers. Current recordswere typically low-pass filtered at 1 kHz and digitized at 5 kHz.The fast capacitance compensation was adjusted to cancel the transientcurrent caused by the pipette capacitance. The series resistancewas between 20 and 50 M $Omega$ but was notcompensated.

Rundown of the evoked EPSC was relatively fast (10-30 min) after the whole-cell clamp configuration was established. Becausethe glutamate-evoked current in GLCs and the light-induced currentin both BCs and GLCs lasted for >1 hr, the postsynaptic mechanismsof cells under voltage clamp would not be responsible for therapid rundown of the evoked EPSC. Rapid rundown of transmitterrelease has been reported in isolated goldfish BCs (Minami etal., 1998). This rapid rundown allowed us to exchange only a coupleof bath solutions to be tested for each cellpair.

The retinal slices were set in a light-tight Faraday cage and observed under the microscope equipped with infrared (IR) illuminationand an IR-sensitive camera. To photostimulate the retinal slices,a white light, the intensity of which ranged between 0.5 and 5lux at the position of the retinal slice, was applied throughthe condenser lens of the microscope. The light-evoked responseswere very well preserved in all cell types under these conditions,although the retinal slices were prepared under room light. Recordingswere done within 2 hr after preparation of theslices.

Cell types were identified by their light-evoked responses and morphology, which was visualized by Lucifer yellow stainingafter the recording. Whether presynaptic ON-type BC or OFF-typeBC was stimulated, there were no significant differences in theevoked EPSCs recorded from the synaptically connected GLCs. Thelight-evoked responses of GLCs were usually of ON/OFF-transienttype. Thus, all data shown here were obtained from pairs of anON-type or OFF-type BC and an ON/OFF-transient typeGLC.

Dissociation of retinal cells. Müller cells and spiking neurons were dissociated from the newt retina with the similar proceduresdescribed by Tachibana and Okada (1991). The isolated retinaswere treated with a low-Ca²⁺ solution containing hyaluronidase (0.1 mg/ml; Sigma) and thenwith cysteine (5 mM; Wako Pure Chemical, Tokyo, Japan)-activatedpapain (30-50 mg/ml; Wako). The low-Ca²⁺ solution contained (in mM): 120 NaCl, 2.6 KCl, 1 NaHCO₃, 0.5NaH₂PO₄, 1 NaPyruvate, 4 HEPES, and 16 glucose titrated to pH7.2 with NaOH. The retinas were rinsed with the control saline(S1) several times and then mechanically triturated with a glasspipette.

Recordings from isolated cell preparation. Müller cells could be readily identified by their characteristic morphology (Schwartzand Tachibana, 1990; Barbour et al., 1991). The intracellularsolution for Müller cell recordings consisted of either P2 orP3 (in mM): 95 KCl, 5 NaCl, 7 MgCl₂, 1 CaCl₂, 5 EGTA, 5 HEPES,and 5 ATP titrated to pH 7.0 with KOH. External solution containedeither S1, the control saline, or S2 (in mM): 105 NaCl, 2.5 KCl,3 CaCl₂, 0.5 MgCl₂, 6 BaCl₂, 15 glucose, and 5 HEPES titratedto pH 7.3 with NaOH. Ba²⁺ was included in S2 to block the anomalous rectifier K⁺ channels in Müller cells (Barbour et al., 1991). P2 and S1 wereused for the experiment shown in Figure 1A, and P3 and S2 wereused for the experiments shown in Figure 1, B-E.

Amacrine and ganglion cells are the only neurons known to generate Na⁺ action potentials in the retina. Isolated cells were identifiedas spiking neurons when a large (more than a few hundred picoamperes)and rapid (decay time constant less than a few milliseconds) Na⁺ current was evoked by a depolarizing pulse under voltage clamp.For recordings from spiking neurons, the pipette and externalsolutions were P2 and S1,respectively.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Glutamate uptake and its inhibition by PDC in isolated Müller cells

Müller cells are the predominant type of glial cells in the vertebrate retina. Their processes fill much of the extracellularspace, and they envelope somas and processes of all retinal neurons(Dowling, 1987). Fine processes of Müller cells extend throughthe inner plexiform layer (IPL) in which BCs make synaptic contactwith ganglion and amacrine cells. Because Müller cells are knownto possess glutamate transporters in various species (Brew andAttwell, 1987; Schwartz and Tachibana, 1990; Eliasof et al., 1998;Harada et al., 1998; Rauen et al., 1998), these transporters maycontribute to the clearance of glutamate in the IPL. We firstexamined physiologically whether the glutamate transporters areactually present in Müller cells of the newtretina.

Müller cells dissociated from the newt retina were voltage-clamped in the whole-cell recording configuration. To block possibleactivation of ionotropic glutamate receptors, 5 µM NBQX and 50µM D-AP-5 were included in both the bath and puff solutions. Whenglutamate (1 mM) was applied via a puff pipette, a large inwardcurrent was evoked in the Müller cell held at $-$ 80 mV. When theholding potential was shifted positively, the response decreasedin amplitude without changing its polarity (Fig. 1A).

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Figure 1. PDC blocked glutamate uptake in Müller cells isolated from the newt retina. A, Glutamate (1 mM) was puff applied (100 msec; timing indicated as the bar at the top) to a Müller cell that was whole-cell voltage-clamped at various potentials (noted on the left). The glutamate-induced uptake current did not reverse its polarity at positive potentials. B, I-V curves obtained in the presence of 1 mM glutamate (Glu) and 200 µM PDC. Membrane currents were measured by applying voltage ramps (130 mV/300 msec). Each I-V curve was derived from the difference between the average of three current traces in the presence and absence of the chemicals, which were applied via the Y-tube microflow system. C, The uptake currents induced by various concentrations (top) of glutamate (Glu) or PDC. Both traces were obtained from the same cell voltage-clamped at $-$ 75 mV. D, Dose-response curves for glutamate (top panel) or PDC (bottom panel). Means ± SEM are illustrated (pooled data from 16 cells). Data points were fitted by the Michaelis-Menten equation. E, Inhibition of the glutamate-induced uptake current by PDC (200 µM). The concentration of glutamate (Glu) was 200 µM (left and middle) and 1 mM (right). The cell was held at $-$ 75 mV. F, Estimation of the uptake rate of glutamate in the presence of PDC. A simple competitive inhibition model was used with the values of K_Glu and K_PDC obtained in D. The concentration of PDC is shown at the right of the curves.

The current-voltage (I-V) relationship was derived from the difference between the response to voltage ramps in the presenceand absence of 1 mM glutamate (Fig. 1B, Glu). In this example,glutamate was applied via a Y-tube microflow system (Suzuki etal., 1990) to reach rapidly a constant concentration. The I-Vrelationship showed strong inward rectification, and no obviousoutward current was observed, even at large positive potentials.These properties are similar to those of the glutamate transportercurrent reported in other species (Schwartz and Tachibana, 1990;Barbour et al., 1991).

Various concentrations of glutamate were applied to examine the affinity of glutamate to the transporter (Fig. 1C, top). Thedose-response curve was obtained, and the Michaelis-Menten equationwas fitted to the data (Fig. 1D, top). The value of apparent K_mfor glutamate (K_Glu) was 10.8 µM (n = 16), which is similar tothe value reported in Müller cells of the tiger salamander retina(19.8 µM) (Barbour et al., 1991).

Because our strategy was to compare the time course of the evoked and spontaneous EPSCs before and after the blockade of theglutamate transporter, it was essential to understand the propertiesof its blocker. PDC is known to bind with high-affinity glutamatetransporters (Bridges et al., 1991). Therefore, PDC may competewith glutamate in binding and may be subsequently transportedat a slower rate than glutamate, resulting in a reduction of theuptake rate of glutamate (Sarantis et al., 1993). When PDC (200µM) was applied alone to Müller cells, an inward current wasinduced. The I-V relationship was similar in shape to that ofglutamate, but the amplitude was consistently smaller (Fig. 1B,PDC). The working range of PDC was similar to that of glutamate(Fig. 1C, bottom). Apparent K_m for PDC (K_PDC) was 16.6 µM (n =16) (Fig. 1D, bottom).

We next examined how PDC inhibited the glutamate uptake. PDC (200 µM) induced an inward current (Fig. 1E, PDC), which was40.8 ± 2.4% (pooled data are expressed as mean ± SEM for thisand all subsequent data; n = 3) of the current evoked by a saturatingdose of glutamate (Fig. 1E, Glu 1 mM). Addition of glutamate (200µM) to PDC (200 µM) evoked a small response (Fig. 1E). The glutamate-inducedcurrent reduced to 44.3 ± 2.8 (1 mM glutamate) and 26.6 ± 1.3%(200 µM glutamate) of its control value (application of 1 mM glutamatealone). With the values of K_Glu and K_PDC obtained above, the currentsevoked by 1 mM and 200 µM glutamate are estimated to be reducedby 200 µM PDC to 54.6 and 36.6%, respectively (Sarantis et al.,1993). These estimated values are similar to the values obtainedexperimentally.

Using a simple competitive inhibition model (Sarantis et al., 1993), we estimated the extent to which PDC reduced the rateof glutamate uptake. The curves shown in Figure 1F indicate therelative rate of glutamate uptake in the presence and absenceof PDC. With 200 µM PDC, the uptake rate is reduced to 88.6 (1mM glutamate) and 61.8% (200 µM glutamate) of control at the steadystate. In the slice preparation, the concentration of PDC maybe somewhat lower at the synaptic cleft than in the bath, becausePDC itself is taken up by the glutamate transporters. This mayreduce the effectiveness of PDC in inhibiting the glutamateuptake.

No effect of PDC on non-NMDA receptors of isolated spiking neurons

Because glutamate and PDC have similar affinity to the glutamate transporters (Fig. 1), high concentrations of PDC may berequired to inhibit uptake of a high concentration of glutamate(~1 mM), which is estimated to be reached in the synaptic cleft(Clements et al., 1992). To use PDC as a selective inhibitor ofglutamate uptake, it is essential to confirm that a high concentrationof PDC has little effect on glutamate receptors. Therefore, weexamined whether PDC had a direct effect on the non-NMDA receptorsof spiking neurons isolated from the newt retina. To isolate non-NMDAreceptor-mediated current, 50 µM D-AP-5 (a specific blocker ofNMDA receptors) was included in both the superfusate and the puffpipettesolution.

Brief puff application of 200 µM glutamate produced an inward current in an isolated spiking neuron maintained at $-$ 80 mV (Fig.2A). When PDC (200 µM) was bath applied, the holding current remainedthe same and the glutamate-induced current did not change in amplitudeor time course (Fig. 2B). The glutamate-induced current was completelyabolished with addition of 5 µM NBQX (a specific blocker of non-NMDAreceptors) to the superfusate (Fig. 2C). Similar results wereobtained from four spiking neurons. These results suggest thatPDC has little or no effect on non-NMDA receptors of isolatedspiking neurons.

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Figure 2. The current through non-NMDA receptors was not affected by PDC. A, A spiking neuron isolated from the newt retina was voltage-clamped at $-$ 80 mV. Both the superfusate and the puff pipette solution included 50 µM D-AP-5 to block the current through NMDA receptors. A 20 msec puff-application (top) of 200 µM glutamate (Glu) induced an inward current. B, The glutamate-induced current was not affected by the presence of 200 µM PDC. C, Application of NBQX (5 µM) to the superfusate completely blocked the response to a 100 msec puff of glutamate.

Enhancement of the glutamate-induced, non-NMDA receptor-mediated current in GLCs of the retinal slice by PDC

We next examined the effect of PDC on the glutamate-induced, non-NMDA receptor-mediated current in GLCs of the retinal slicepreparation. Synaptic inputs to GLCs were blocked by totally replacingdivalent cations in the control superfusate with 3 mM Co²⁺. This concentration of Co²⁺ effectively blocks the Ca²⁺ current in BCs and subsequently suppresses the evoked EPSCs inGLCs (Matsui et al., 1998). In the present experiment, the blockadeof synaptic transmission by Co²⁺ was confirmed by monitoring the photoresponses in GLCs; the photoresponsesdisappeared within a couple of minutes after the application ofCo²⁺. D-AP-5 (50 µM) was included in both the superfusate and thepuff pipette solution. Glutamate (200 µM) was applied briefly(10-100 msec) via a puff pipette. The position of the pipettetip was adjusted along the IPL to find the "hot spot" of the voltage-clampedGLC.

Puff-applied glutamate induced an inward current in GLC maintained at $-$ 80 mV. The time course of the glutamate-induced currentvaried from cell to cell but was always slower than that observedin isolated cells. The slow time course may be caused by the delayof glutamate diffusion into the slice, and the variability maybe caused by the distance between the glutamate receptors of agiven voltage-clamped GLC and the surface of the slice preparation.When PDC (200 µM) was added to the superfusate, the glutamate-inducedcurrent increased in both amplitude and decay time (Fig. 3A).The ratio of the peak amplitude with and without PDC was comparedwith the ratio of the total charge (i.e., the time integral ofthe glutamate-induced current) with and without PDC (Fig. 3B).The relative increase in total charge was always larger than theincrease in amplitude, indicating that the glutamate-induced currentwas prolonged after application of PDC. We also measured the half-decaytime of the glutamate-induced current, which should provide anothermeasure of changes in time course. The half-decay time in thepresence of PDC was always slower than that of the control (Fig.3C).

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Figure 3. Effect of PDC on the non-NMDA receptor-mediated current in GLCs of the retinal slice. A, A GLC was voltage-clamped at $-$ 80 mV, and glutamate (200 µM) was puff applied for 100 msec. The tip of the puff pipette was carefully positioned above the IPL to evoke a large response. In both the bath and puff solutions, divalent cations were replaced with Co²⁺ to suppress the synaptic transmission, and D-AP-5 (50 µM) was included to block the NMDA receptor-mediated current. The glutamate-induced current in the presence of 200 µM PDC (thick trace) was larger in amplitude and decayed more slowly than control (thin trace). After scaling (dotted trace), it is clear that PDC prolonged the glutamate-induced current through non-NMDA receptors. B, Relative increase in the peak amplitude (Peak) and total charge (Charge) before and after the application of PDC. Data were obtained from three cells and are illustrated with different symbols. Duration of the puff was 10 (open), 50 (half-tone), or 100 (filled) msec. The averaged values are shown with large filled circles. C, The scatter diagram illustrates the relationship between the half-decay time of the glutamate-induced current in the absence (Control) and presence of PDC. All symbols correspond to those shown in B. D, The current was evoked in a GLC by a 50 msec puff of glutamate in the presence of 200 µM PDC. The holding potential was changed to various values. The current traces are shifted arbitrarily for a better view. All of the current traces were superimposable after scaling (bottom traces). E, The peak amplitude of the glutamate-induced current was plotted against the command potential of GLC. The linear relationship confirmed that the glutamate-induced current was caused by the activation of non-NMDA receptors.

Although a high concentration (50 µM) of competitive antagonist D-AP-5 was included in both the superfusate and the puff pipettesolution, inhibition of the glutamate uptake by PDC could haveraised the glutamate concentration in the synaptic cleft to alevel high enough to activate NMDA receptors, which have highaffinity for glutamate. This possibility was examined by recordingthe glutamate-induced current at various command potentials inthe presence of PDC (Fig. 3D). The current traces at all potentialstested (between $-$ 80 and +40 mV) were superimposable after scaling(Fig. 3D, bottom traces). The I-V relationship was linear andreversed at ~0 mV (Fig. 3E). These results indicate that the NMDAcomponent of the glutamate-induced current did not emerge in thepresence of 200 µM PDC and 50 µM D-AP-5.

This series of control experiments indicates that the effects of PDC observed in GLCs of the slice preparation are not ascribableto changes in the postsynaptic mechanisms. Selective inhibitionof glutamate transporters by PDC is consistent with the assumptionthat the enhanced amplitude of the response to puff-applied glutamateis caused by the increase in glutamate concentration reachingnon-NMDA receptors of GLCs in the slice preparation. The prolongedtime course of the glutamate-induced current could be also interpretedas a slowdown of glutamate extrusion byPDC.

Enhancement of the light-evoked non-NMDA-EPSC by PDC

In the previous section, the effect of PDC was evaluated by exogenously applying glutamate to the slice preparation. We nextinvestigated the effect of PDC on the non-NMDA receptor-mediatedresponse of GLC to endogenoustransmitter.

When a full-field white light stimulus was applied to the retinal slice, an ON/OFF-transient response was evoked in the GLCvoltage-clamped at $-$ 80 mV (Fig. 4A, Control). When 200 µM PDCwas bath applied, both ON and OFF transients were enhanced andtheir decay was prolonged (Fig. 4A, PDC). To relieve Mg²⁺ block of NMDA receptors (Nowak et al., 1984), the holding potentialwas shifted to $-$ 40 mV, and the same light stimulus was applied.In the presence of PDC, the photoresponse at the holding potentialof $-$ 40 mV (Fig. 4B, thin trace) was superimposable to that at $-$ 80 mV (Fig. 4B, thick trace) after scaling (Fig. 4B, dotted trace).Although the time course of the photoresponse was slow, unblockingof NMDA receptors could result in drastic changes of the responsewaveform at the holding potential of $-$ 40 mV (Mittman et al., 1990).Therefore, as was the case of exogenously applied glutamate (Fig.3), 50 µM D-AP-5 was strong enough to inhibit the NMDA componentof the photoresponse, and no additional activation of NMDA receptorswas unveiled with the addition of 200 µM PDC. Similar resultswere obtained from three GLCs.

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Figure 4. The light-evoked responses in GLC were enhanced by PDC. A, With full-field illumination (Light), an ON/OFF transient response (thin trace) was evoked in GLC of the retinal slice, which was superfused with the solution containing D-AP-5 (50 µM). Both ON and OFF transients were prolonged by application of 200 µM PDC (thick trace). GLC was held at $-$ 80 mV. B, The photoresponses were recorded in the presence of PDC. The holding potential was set at $-$ 80 (thick trace) and $-$ 40 (thin trace) mV. After scaling (dotted trace), both traces were superimposable, indicating that the NMDA receptor-mediated current was not emerged by application of PDC.

The onset delay of the ON transient was slightly increased by 17.5 ± 8.7 msec (n = 6) after application of PDC (Fig. 4A).This effect may be ascribed to the actions of PDC in the outerplexiform layer (OPL). In the OPL, light stimulation reduces therelease of glutamate from photoreceptors. Thus, the blockade ofglutamate transporters in the OPL by PDC would slow down the uptakeof glutamate released from photoreceptors (Gaal et al., 1998),resulting in the slow onset of depolarization in ON-type bipolarcells, which would in turn cause the onset delay of the ON transientinGLCs.

Prolongation of the evoked non-NMDA-EPSC in GLCs of the retinal slice by PDC

In the previous section, it was confirmed that synaptic input to GLC was enhanced by PDC. However, it is difficult to identifythe sites of PDC action because glutamate mediates synaptic transmissionin both the OPL and IPL. Therefore, we performed dual whole-cellrecordings from BC and GLC pairs to investigate how PDC enhancedthe synaptic transmission in the IPL. Depolarization of a singleBC activates both non-NMDA and NMDA receptors of a synapticallyconnected GLC (Matsui et al., 1998). In this section, we focusedon the non-NMDA component of the evoked EPSC. The NMDA componentwas suppressed by D-AP-5 (50 µM) in the bathsolution.

A BC was depolarized from the holding potential of $-$ 68 to $-$ 8 mV for 50 msec. A sustained inward current was induced in BC,and an evoked EPSC (peak amplitude, 16.6 ± 3.5 pA; n = 6) wasrecorded from GLC voltage-clamped at $-$ 80 mV (Fig. 5A, thin line).The inward current in the BC has been demonstrated to be a Ca²⁺ current (I_Ca) (Matsui et al., 1998). When PDC (200 µM) was bathapplied, the peak amplitude of I_Ca did not change significantly(control, 63.4 ± 6.2 pA; PDC, 62.1 ± 6.6 pA; n = 13; p = 0.55;levels of statistical significance were determined using pairedStudent's t tests), but the decay of the evoked EPSC was prolonged(Fig. 5A, thick line). The evoked EPSC in the presence of PDCwas blocked entirely with addition of CNQX (10 µM) to the superfusate(data not shown), indicating that the evoked EPSC was generatedonly by the activation of non-NMDA receptors.

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Figure 5. The evoked non-NMDA-EPSC was prolonged by PDC. A, A 50 msec depolarizing pulse (from $-$ 68 to $-$ 8 mV; top) applied to BC activated I_Ca (middle; thin trace) in BC and evoked non-NMDA-EPSC in GLC voltage-clamped at $-$ 80 mV (bottom; thin trace). After application of 200 µM PDC, neither the amplitude nor time course of I_Ca (thick trace) was affected, but the decay of the non-NMDA-EPSC was significantly prolonged (thick trace). D-AP-5 (50 µM) was included in the bath solution. The current traces of BC for this and the subsequent figures are shown after leak subtraction. B, Relative increase in the peak amplitude (Peak) and total charge (Charge) of the evoked non-NMDA-EPSC before and after application of PDC. Data were obtained from six cell pairs. The averaged values are shown by large filled circles. C, The half-decay time of the evoked non-NMDA-EPSC in the absence (Control) and presence of PDC. Asterisks in this and subsequent figures indicate that the difference is statistically significant (p < 0.05). Data were obtained from six cell pairs.

The ratio of the peak amplitude before and after the application of PDC varied among cell pairs (1.13 ± 0.13 of control; n= 6) (Fig. 5B), but the ratio of the total charge (2.93 ± 0.44of control) was always larger than that of the peak amplitude.The half-decay time of non-NMDA-EPSC also prolonged significantlyin the presence of PDC (control, 15.7 ± 2.9 msec; PDC, 25.7 ±6.1 msec; p = 0.04) (Fig. 5C).

We examined the effect of another type of glutamate uptake inhibitor, THA, on the evoked non-NMDA-EPSC of GLCs. THA is a substrateof glutamate transporters with a broad spectrum; it is "aspartate-like"in length but is less conformationally constrained than PDC (Bridgeset al., 1991). THA has been reported to suppress the glutamateuptake current in Müller cells isolated from the tiger salamanderretina (Barbour et al., 1991). We confirmed that the evoked non-NMDA-EPSCin the GLC was prolonged by application of THA (100 µM). The peakamplitude and total charge of the evoked non-NMDA-EPSC changedto 0.84 ± 0.12 and 4.68 ± 1.86 (n = 3) of control, respectively(data notshown).

These results indicate that glutamate uptake plays an active role in shaping the non-NMDA-EPSC in GLCs that is evoked by asingle depolarizing pulse applied to a BC. However, we could notdistinguish whether the shaping of the EPSC was caused by theactual uptake of glutamate by transporters or by the mere bindingof glutamate to transporters without translocation (Diamond andJahr, 1997). In the tiger salamander retina, it has been demonstratedthat there are five distinct subtypes of glutamate transportersand that multiple subtypes coexist in a single Müller cell, aswell as in a single neuron (Eliasof et al., 1998). Because subtype-specificblockers of glutamate transporters are not available, we couldnot determine which type of cells and which subtype of glutamatetransporters were responsible for the clearance of glutamate fromthe IPL of the newtretina.

Suppression of the evoked non-NMDA-EPSC by tonic elevation of ambient glutamate concentration

Inhibition of the glutamate uptake may cause tonic accumulation of released glutamate in the synaptic cleft, which would changethe state of presynaptic and/or postsynaptic glutamate receptors.Prolongation of EPSCs might be caused by such a side effect onglutamate receptors. This possibility was investigated by treatingthe slice preparation with exogenously applied glutamate (20-100µM) to raise the ambient glutamate concentration tonically withoutapplying PDC. The glutamate concentration in the synaptic cleftshould be lower than that in the bath solution because of theglutamate uptake. D-AP-5 was applied to isolate the non-NMDA componentof the evokedEPSC.

A raise in glutamate concentration in the superfusate resulted in the decrease of both the peak amplitude and total chargeof the evoked non-NMDA-EPSC (Fig. 6B). With application of 20µM glutamate, the peak amplitude and total charge decreased to0.68 ± 0.09 and 0.52 ± 0.15 (n = 5) of control, respectively.The shape of the non-NMDA-EPSC was not affected by 20 µM glutamate(Fig. 6C). With higher concentrations of glutamate, the evokednon-NMDA-EPSC decayed rapidly (data not shown). The effects ofglutamate were readily reversible after washout. Because tonicelevation of the ambient glutamate concentration suppressed theamplitude of the evoked non-NMDA-EPSC but never prolonged itstime course, it is clear that prolongation of the evoked non-NMDA-EPSCby PDC (Fig. 5) cannot be ascribed simply to the tonic accumulationof glutamate. In the present study, we did not further analyzethe mechanisms by which the ambient glutamate suppressed the evokednon-NMDA-EPSC (Zorumski et al., 1996).

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Figure 6. Elevation of the ambient glutamate concentration did not prolong the evoked non-NMDA-EPSC. A, BC was depolarized from $-$ 68 to $-$ 8 mV for 50 msec, and the evoked non-NMDA-EPSC was recorded from GLC voltage-clamped at $-$ 80 mV. Activation of NMDA receptors was blocked by 50 µM D-AP-5 in the bath solution. B, Addition of 20 µM glutamate to the bath solution reduced the amplitude of the evoked non-NMDA-EPSC. C, After scaling of the trace shown in B (dotted trace), both current traces were superimposable.

No effect of PDC on spontaneous EPSCs

It has been demonstrated that spontaneous EPSCs in GLCs are mediated solely by the activation of non-NMDA receptors (Tayloret al., 1995; Matsui et al., 1998). We examined whether PDC prolongedspontaneous EPSCs, similar to the evoked non-NMDA-EPSC.

At the holding potential of $-$ 80 mV, the mean peak amplitude of the spontaneous discrete events (spontaneous EPSCs) was 6.6± 2.2 pA (five cells). In the presence of 50 µM D-AP-5, applicationof PDC slightly increased the inward holding current at $-$ 80 mV(4.6 ± 1.0 pA; n = 28) and baseline fluctuations (Fig. 7A). Additionof 5 µM NBQX could suppress the increased holding current andbaseline fluctuations. Thus, the increase in the holding currentand baseline fluctuations is probably induced by the activationof non-NMDA receptors of GLCs by elevated ambient glutamate.

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Figure 7. Spontaneous EPSCs were not affected by PDC. A, The membrane current was recorded continuously (4 sec records are displayed) from a GLC voltage-clamped at $-$ 80 mV. Spontaneous EPSCs were clearly observed. The slice preparation was superfused with the solution containing D-AP-5 (50 µM; Control) and then with the solution containing D-AP-5 and PDC (200 µM). B, The cumulative amplitude distribution of spontaneous EPSCs obtained in the absence (thick line) and presence (thin line) of PDC. C, The waveforms of the averaged spontaneous EPSCs in the absence (thick line) and presence (thin line) of PDC. D, Relative changes of the peak amplitude and total charge of the averaged spontaneous EPSCs in the absence and presence of PDC (n = 5). The averaged values of five data are shown by large filled circles. E, The decay phase of the averaged spontaneous EPSC was well fitted by a single exponential function. The time constant of the decay ( $tau$ _decay) was not affected by PDC. Data were obtained from five cells.

PDC (200 µM) did not affect the frequency of spontaneous EPSCs significantly (control, 3.3 ± 0.6 Hz; PDC, 3.0 ± 0.4 Hz; n= 5; p = 0.69). The cumulative amplitude distribution remainednearly the same (Fig. 7B). Small events may have been slightlyobscured by the increased baseline fluctuations in the presenceof PDC. Nonoverlapping events were isolated, aligned at the risingphase of 50% amplitude of the peak, and averaged for each condition.The two traces could be superimposed (Fig. 7C). Neither the peakamplitude (0.98 ± 0.09 of control) nor the total charge (0.96± 0.07 of control) of the average waveform of spontaneous EPSCswas affected by the application of PDC in all cells analyzed (fivecells) (Fig. 7D). The decay of spontaneous EPSCs was well fittedby a single exponential function (Taylor et al., 1995; Matsuiet al., 1998), and the time constant did not change significantlyafter application of PDC (control, 4.3 ± 0.5 msec; PDC, 4.2 ±0.5 msec; n = 5; p = 0.86).

The uptake inhibitor PDC prolonged the decay time course of the evoked non-NMDA-EPSC but not spontaneous EPSCs. This suggeststhat, when only a few synaptic vesicles are fused to the presynapticplasma membrane of BC, as is the case of spontaneous EPSCs, passivediffusion may be sufficiently fast in removing glutamate fromthe synaptic cleft. On the other hand, when multiple synapticvesicles are fused simultaneously or in close succession, as isthe case of the evoked EPSC, a significant amount of glutamatemay accumulate in the extracellular space. In this situation,passive diffusion may take a long time to extrude glutamate, andthus glutamate transporters may play an active role in removingglutamate from the synaptic cleft, contributing to rapid terminationof the evoked non-NMDA-EPSC.

Prolongation of the evoked NMDA-EPSC by PDC

Non-NMDA receptors mediate the early component of the evoked EPSC, whereas NMDA receptors mediate its late component in GLCsof the newt retina (Matsui et al., 1998). The NMDA component increaseswith increasing duration of depolarizing pulses given to a BC.We have proposed that non-NMDA receptors are located at the postsynapticregion immediately beneath each release site, whereas NMDA receptorsare located slightly away from that region. Because PDC prolongedthe evoked non-NMDA-EPSC seen above, it seemed natural to assumethat the evoked NMDA-EPSC was also affected by PDC. This predictionwas further reinforced by the fact that NMDA receptors have considerablyhigher affinity for glutamate than non-NMDA receptors (Patneauand Mayer, 1990) and are better suited for detection of a lowlevel ofglutamate.

Bridges et al. (1991) reported that PDC not only inhibits the glutamate uptake but also weakly interacts with NMDA receptors.Therefore, we first examined whether PDC has any effect on theNMDA receptor-mediated current in spiking neurons isolated fromthe newt retina. NBQX (5 µM), glycine (10 µM), and strychnine(10 µM) were included in both the superfusate and the puff pipettesolution to block non-NMDA receptors, to potentiate NMDA receptors(Johnson and Ascher, 1987) and to inhibit activation of glycinereceptors, respectively. Brief puff application of 200 µM glutamateproduced an inward current in a spiking neuron maintained at $-$ 40mV (Fig. 8A). Application of PDC reduced the amplitude of theglutamate-induced current to 0.48 ± 0.05 (n = 5) of control, withoutchanging its time course (Fig. 8B). The suppression was reversibleafter washout (Fig. 8C). The glutamate-induced current was completelyabolished with addition of 50 µM D-AP-5 in the superfusate (datanot shown). Because PDC partially suppresses the NMDA receptor-mediatedcurrent in isolated spiking neurons, caution was taken in evaluatingthe effect of PDC on the evoked NMDA-EPSC.

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Figure 8. Effect of PDC on the NMDA receptor-mediated current in an isolated spiking neuron. A, A 100 msec puff (top) of glutamate (200 µM) evoked an inward current in an isolated spiking neuron voltage-clamped at $-$ 40 mV. Both the superfusate and the puff pipette solution included 5 µM NBQX, 10 µM glycine, and 10 µM strychnine. B, Bath application of PDC (200 µM) reduced the amplitude of the glutamate-induced current. C, The suppressive effect of PDC reversed after washout.

I_Ca and the evoked NMDA-EPSC were recorded simultaneously from a pair of BC and GLC in the slice preparation. The slice preparationwas superfused with the solution containing 5 µM NBQX to blockthe non-NMDA receptors. The membrane potential of the GLC wasmaintained at $-$ 40 mV to relieve the Mg²⁺ block of NMDA receptors (Matsui et al., 1998, their Fig. 4).PDC (200 µM) had no effect on I_Ca in the BC, whereas the evokedNMDA-EPSC in the GLC was significantly prolonged (Fig. 9A). Theratio of the peak amplitude with and without PDC did not changesignificantly (0.98 ± 0.09 of control; n = 4), but the ratio ofthe total charge with and without PDC always increased (2.52 ±0.47 of control; n = 4). The relationship shown in Figure 9B issimilar to that illustrated in Figure 5B in which the evoked non-NMDA-EPSCwas examined. The half-decay time was increased significantlyfrom 18.5 ± 3.6 (control) to 32.5 ± 6.7 msec (PDC) (n = 4; p =0.04) (Fig. 9C). Further addition of 50 µM D-AP-5 blocked theevoked NMDA-EPSC completely (n = 3; data not shown).

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Figure 9. The evoked NMDA-EPSC was prolonged by PDC. A, In the slice preparation, dual whole-cell recordings were performed. A 50 msec depolarizing pulse (from $-$ 68 to $-$ 8 mV; top) applied to BC activated I_Ca (middle; thin trace) in BC and evoked the NMDA-EPSC in GLC voltage-clamped at $-$ 40 mV (bottom; thin trace). Bath application of 200 µM PDC did not change I_Ca (middle; thick trace) but prolonged the evoked NMDA-EPSC (bottom; thick trace). The superfusate always contained 5 µM NBQX. B, Relative increase in the peak amplitude (Peak) and total charge (Charge) of the evoked NMDA-EPSC before (Control) and after application of PDC (n = 4). The averaged values are shown by large filled circles. C, The half-decay time of the evoked NMDA-EPSC in the absence (Control) and presence of PDC.

Application of PDC in the presence of NBQX induced a small inward shift of the holding current (1.8 ± 1.6 pA at $-$ 40 mV; n= 7), which was suppressed with addition of 50 µM D-AP-5. Thisincrease in the holding current is probably caused by the activationof NMDA receptors by elevated ambient glutamate. It would be interestingto see whether the application of PDC without blockers of ionotropicglutamate receptors (NBQX and D-AP-5) would newly uncover theNMDA component of spontaneous EPSCs, which was never detectedwith intact glutamate transporters. However, without blockersof glutamate receptors, the holding current largely fluctuatedafter application of PDC, making it difficult to reliably isolatethe small spontaneousevents.

PDC directly reduced the amplitude of the glutamate-induced current through NMDA receptors in isolated spiking neurons (Fig.8B). However, the evoked NMDA-EPSC did not change significantlyin amplitude and was obviously prolonged in duration after applicationof PDC (Fig. 9B). These results indicate that the effect of PDCon glutamate transporters overwhelmed its direct effect on postsynapticNMDA receptors. The enhancement of the evoked NMDA-EPSC furthersupports the idea that inhibition of glutamate uptake inducesthe accumulation of glutamate in the synaptic cleft and slowsthe clearance ofglutamate.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The effect of PDC was to slow the clearance of glutamate from the synaptic cleft

We found that 200 µM PDC effectively reduced the glutamate-induced uptake current in Müller cells isolated from the newtretina (Fig. 1). PDC at this concentration did not affect postsynapticnon-NMDA receptor-mediated current of isolated spiking neurons(Fig. 2). However, the evoked non-NMDA-EPSC was prolonged by PDC(Fig. 5). The evoked NMDA-EPSC was also enhanced by PDC, althoughPDC suppressed partially the current through NMDA receptors (Fig.8). These results indicate that the release-triggered transientglutamate increase in the synaptic cleft is prolonged after inhibitionof the glutamate uptake byPDC.

PDC may not affect presynaptically

We cannot exclude the possibility that PDC may affect presynaptic BCs. However, it seems unlikely that the prolongation ofthe evoked EPSCs would be ascribed only to the presynaptic influence.First, PDC affected neither the time course nor the amplitudeof I_Ca in BCs, which triggers and controls transmitter release(Figs. 5, 9). PDC did not shift the I_Ca-V relationship to eitherside along the voltage axis (data not shown). Second, PDC didnot change the frequency of spontaneous EPSCs consistently (Fig.7). The change in the frequency of spontaneous EPSCs is oftenused as a measure of changes in release probability. Third, weused THA, another type of uptake inhibitor, and found that ithad similar effects on the evoked EPSCs as PDC (see Results).This observation indicates that prolongation of the evoked EPSCsis not attributable to nonspecific actions of PDC. Fourth, wemeasured membrane capacitance increase associated with exocytosisusing axon terminals of ON-type bipolar cells isolated from thegoldfish retina and found that the amplitude of membrane capacitancechanges was not affected significantly by PDC (depolarizationfrom $-$ 70 to $-$ 10 mV for 50 msec; 46.5 ± 7.0 fF in control; 43.8± 7.9 fF with PDC; n = 4; p = 0.27) (our unpublished observations).This evidence is rather indirect because BC terminals were obtainedfrom different species, but goldfish BC terminals are the onlypreparation among retinal BCs that allow direct capacitance measurementsto thisdate.

PDC might work indirectly on presynaptic terminals of BC; inhibition of glutamate uptake increases ambient glutamate concentration,which may in turn activate the presynaptic metabotropic glutamatereceptors. However, in cultured hippocampal neurons, an increasein ambient glutamate concentration decreases presynaptic transmitterrelease (Maki et al., 1994; Zorumski et al., 1996).

The effect of tonic increase in ambient glutamate on postsynaptic non-NMDA receptors

Inhibition of glutamate uptake with PDC in the presence of D-AP-5 induced a small steady inward current, which could be attributableto glutamate accumulation (Isaacson and Nicoll, 1993). Becauseneither the amplitude nor the shape of spontaneous EPSCs was affectedby PDC (Fig. 7), it was suggested that the rise in ambient glutamatewas not high enough to substantially alter the kinetics of non-NMDAreceptors. Bath application of glutamate without PDC to the slicepreparation reduced the peak amplitude and total charge of theevoked non-NMDA-EPSC (Fig. 6). Therefore, even if inhibition ofglutamate uptake resulted in a buildup of ambient glutamate, thiscould not explain the PDC-induced prolongation of the evoked non-NMDA-EPSC.

It is interesting to estimate the glutamate concentration at the synaptic sites when 20 µM glutamate was bath applied to theslice preparation (Fig. 6). In microcultures of hippocampal neurons,20 µM glutamate was high enough to completely abolish the excitatoryautaptic current (Zorumski et al., 1996). In the tiger salamanderretina, the dose (glutamate)-response curve obtained in isolatedhorizontal cells was shifted to a lower range along the concentrationaxis than that obtained in horizontal cells of the slice preparation,even in the presence of glutamate uptake inhibitor (Gaal et al.,1998). Based on the data of Gaal et al., 1998 (their Fig. 2),it can be assumed that 20 µM glutamate applied to the slice preparationin the presence of glutamate uptake inhibitor would be reducedto ~10 µM at the synaptic sites. In the present experiment shownin Figure 6 in which glutamate uptake inhibitor was not applied,the glutamate concentration at the synaptic sites would be loweredfurther (less than ~10 µM). Non-NMDA receptors in patch membranesexcised from area CA1 pyramidal cells are half desensitized at4.2 µM of glutamate (Colquhoun et al., 1992). Because the amplitudeof the evoked non-NMDA-EPSC was nearly halved by bath-applied20 µM glutamate (Fig. 6), we estimate that the effective glutamateconcentration at the synaptic site was probably as low as ~4 µM.

Factors that determine the shape of spontaneous and evoked EPSCs

The time course of spontaneous EPSCs was not affected by the application of PDC (Fig. 7). It seems possible that the glutamatetransient induced by the fusion of a single synaptic vesicle maybe slightly prolonged by PDC (Tong and Jahr, 1994). However, suchprolongation of the glutamate transient may not be sufficientenough to affect the decay of spontaneous EPSCs, which is probablydetermined by the kinetics of non-NMDA receptors (Diamond andJahr, 1997).

The evoked EPSCs (both non-NMDA- and NMDA-EPSCs) were obviously prolonged by PDC (Figs. 5, 9). Multiple fusion of synapticvesicles must have occurred when the BC was stimulated with singledepolarizing pulses. Because the total charge of the evoked EPSCincreases as the pulse duration is increased (Matsui et al., 1998),fusion of synaptic vesicles is not locked to the onset of depolarizationbut continues during depolarization. It has been suggested ingoldfish retinal BCs that fusion of synaptic vesicles continuesat a high rate for ~200 msec after the onset of depolarization(von Gersdorff and Matthews, 1994; Sakaba et al., 1997). Theseresults indicate that a large amount of transmitter is releasedduring depolarization of a single BC and must accumulate in thesynaptic cleft. In addition, transmitters released from multipleactive zones of a single BC may cause "cross-talk" among clustersof postsynaptic receptors in a GLC. Therefore, released glutamatemay stay for a long period if glutamate is extruded from the synapticcleft only by passive diffusion. The present results indicatethat glutamate uptake must play an important role in determiningthe time course of the evokedEPSCs.

Based on the values of K_Glu and K_PDC obtained from the isolated Müller cells (Fig. 1), it is estimated that the uptake rateof 1 mM glutamate (the estimated peak concentration of the glutamatetransient induced by a presynaptic spike) (Clements et al., 1992)is reduced to 88.6% in the presence of 200 µM PDC. The effectiveconcentration of PDC at the synaptic site should be lower than200 µM because PDC itself is taken up by glutamate transporters.Thus, the rate of the glutamate uptake would be reduced only slightly.However, a small change in the uptake rate induced by bath-applied200 µM PDC was effective in significantly altering the time courseof the evoked non-NMDA-EPSC (Fig. 5). We should consider a spatialgradient of glutamate in the synaptic cleft: high at the releasesite and low at regions away from the release site. Inhibitionof glutamate uptake by PDC is more effective at lower glutamateconcentrations (Fig. 1F). Therefore, it is likely that at leastpart of the decay phase of the evoked non-NMDA-EPSC may be shapedby the non-NMDA receptors experiencing relatively low concentrationsof glutamate at which PDC is more effective (i.e., the non-NMDAreceptors at peripheral regions of the synapticcleft).

Using cyclothiazide (CTZ), a pharmacological agent that slows desensitization of non-NMDA receptors, we have demonstratedthat rapid desensitization of non-NMDA receptors greatly shapesthe decay phase of the evoked non-NMDA-EPSC (Matsui et al., 1998).However, in the present experiment, we found that inhibition ofthe glutamate uptake prolonged the evoked non-NMDA-EPSC withoutapplying CTZ. This indicates that the shape of the evoked non-NMDA-EPSCis not exclusively determined by receptor desensitization. Thetime course of glutamate release, receptor desensitization, anduptake all contribute to the shaping of the evoked non-NMDA-EPSCin the innerretina.

Graded synaptic transmission versus spike-triggered synaptic transmission

It is interesting to compare the present results obtained from nonspiking, graded synaptic transmission in the inner retinawith those from spike-triggered synaptic transmission. Isaacsonand Nicoll (1993) recorded from pyramidal cells in area CA1 ofthe hippocampal slice and reported that an uptake inhibitor failsto alter the kinetics of the EPSC. They have suggested that glutamateis rapidly cleared from the synaptic cleft by diffusion. Mennerickand Zorumski (1994) have reported in microcultured single neuronsthat prolongation of postsynaptic current by uptake inhibitoris only visible in the presence of CTZ. Otis et al. (1996) havereported in calyceal somatic synapse made in chick nucleus magnocellularisthat uptake inhibitors selectively enhance the slower phase ofEPSC. These different views seem to arise from variations in physiologicaland morphological features of synapses. These features may bedifferentiated and selected for appropriate functioning of eachCNSsynapse.

Addendum

After this paper had been submitted for publication, Higgs and Lukasiewicz (1999) reported the contribution of glutamate transportersto synaptic transmission in the tiger salamander retina. Theystimulated multiple BCs extracellularly and observed prolongationof EPSCs recorded from ganglion cells with application of uptakeinhibitors. Using double patch recordings from BC and GLC pairs,we support their conclusions, and furthermore we demonstrate theactive role of transporters in clearance of released glutamatefrom the synapticcleft.

  FOOTNOTES

Received April 7, 1999; revised May 25, 1999; accepted May 27, 1999.

This work was supported by a Grant-in Aid for Scientific Research 09480238 from The Ministry of Education, Science, Sports,and Culture to M.T. K.M. is a research fellow of Japan Societyfor Promotion of Science. We thank Lawrence H. Pinto for criticalreading of this manuscript, and Naotoshi Minami and Ken Berglundfor excellent technical assistance on dissociation and recordingsfrom isolated retinalcells.
Correspondence should be addressed to Masao Tachibana, Department of Psychology, Graduate School of Humanities and Sociology,The University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-0033,Japan.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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