G-Protein-Coupled Modulation of Presynaptic Calcium Currents and Transmitter Release by a GABAB Receptor

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The Journal of Neuroscience, May 1, 1998, 18(9):3138-3146

G-Protein-Coupled Modulation of Presynaptic Calcium Currents and Transmitter Release by a GABA_B Receptor
Tomoyuki Takahashi, Yoshinao Kajikawa, and Tetsuhiro Tsujimoto
Department of Neurophysiology, University of Tokyo Faculty of Medicine, Tokyo 113, Japan

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Presynaptic GABA_B receptors play a regulatory role in central synaptic transmission. To elucidate their underlying mechanismof action, we have made whole-cell recordings of calcium and potassiumcurrents from a giant presynaptic terminal, the calyx of Held,and EPSCs from its postsynaptic target in the medial nucleus ofthe trapezoid body of rat brainstem slices. The GABA_B receptoragonist baclofen suppressed EPSCs and presynaptic calcium currentsbut had no effect on voltage-dependent potassium currents. Thecalcium current-EPSC relationship measured during baclofen applicationwas similar to that observed on reducing [Ca²⁺]_o, suggesting that the presynaptic inhibition generated by baclofenis caused largely by the suppression of presynaptic calcium influx.Presynaptic loading of the GDP analog guanosine-5'-O-(2-thiodiphosphate)(GDP $beta$ S) abolished the effect of baclofen on both presynaptic calciumcurrents and EPSCs. The nonhydrolyzable GTP analog guanosine 5'-O-(3-thiotriphosphate)(GTP $gamma$ S) suppressed presynaptic calcium currents and occluded theeffect of baclofen on presynaptic calcium currents and EPSCs.Photoactivation of GTP $gamma$ S induced an inward rectifying potassiumcurrent at the calyx of Held, whereas baclofen had no such effect.We conclude that presynaptic GABA_B receptors suppress transmitterrelease through G-protein-coupled inhibition of calcium currents.

Key words: GABA_B receptor; presynaptic inhibition; Gprotein; calcium currents; inwardly rectifying potassium currents; the calyx of Held; presynaptic recording

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

GABA_B receptors are widely distributed in the presynaptic and postsynaptic membranes of vertebrate central neurons, and theymodulate synaptic transmission by either suppressing transmitterrelease or hyperpolarizing postsynaptic cells (Thompson et al.,1993; Kaupmann et al., 1997). At neuronal somata, GABA_B receptorsare known to activate G-proteins, thereby enhancing inwardly rectifyingpotassium channels (Andrade et al., 1986; Sodickson and Bean,1996) or suppressing calcium channels (Dolphin and Scott, 1987;Scholtz and Miller, 1991; Mintz and Bean, 1993). Compared withthe wealth of information on the postsynaptic mechanism of GABA_Breceptors, much less is known about their presynaptic mechanismof action. In particular, it is not known whether the effectorof presynaptic GABA_B receptors is a potassium channel (Saint etal., 1990; Thompson and Gahwiler, 1992), a calcium channel (Scholtzand Miller, 1991; Pfrieger et al., 1994; Wu and Saggau, 1995;Dittman and Regehr, 1996, 1997), or exocytotic machinery downstreamof calcium influx (Scanziani et al., 1992; Dittman and Regehr,1996; Rohrbacher et al., 1997). Also, an involvement of G-proteinsin GABA_B receptor-mediated presynaptic inhibition remains to bedirectly demonstrated (Thompson et al., 1993). The calyx of Heldis an ideal preparation for directly testing these issues usingpatch-clamp techniques (Forsythe, 1994; Borst et al., 1995; Takahashiet al., 1996). The presynaptic terminal possesses GABA_B receptorsas well as metabotropic glutamate receptors and adenosine receptors(Barnes-Davies and Forsythe, 1995). Here we demonstrate that theG-protein-coupled inhibition of calcium channels underlies theGABA_B receptor-mediated presynaptic inhibition.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Preparation and solutions. Transverse slices of the superior olivary complex were prepared from 14- to 19-d-old Wistar ratskilled by decapitation under halothane anesthesia. The medialnucleus of trapezoid body (MNTB) neurons and calyces were viewedwith a 40×, 63× (Zeiss), or 60× (Olympus Optical, Tokyo, Japan)water immersion lens attached to an upright microscope (Axioskop,Zeiss). Each slice was perfused with artificial CSF (aCSF) containing120 mM NaCl, 2.5 mM KCl, 26 mM NaHCO₃, 1.25 mM NaH₂PO₄, 2 mM CaCl₂,1 mM MgCl₂, 10 mM glucose, 0.5 mM myo-inositol, 2 mM sodium pyruvate,0.5 mM ascorbic acid, and 4 mM lactic acid, pH 7.4, with 5% CO₂and 95% O₂. To isolate Ca²⁺ currents, 10 mM tetraethylammonium (TEA) chloride and 1 µM tetrodotoxin(TTX) were included in the aCSF. The postsynaptic patch pipettewas filled with a solution (A) containing 97.5 mM potassium gluconate,32.5 mM KCl, 10 mM HEPES, 5 mM EGTA, and 1 mM MgCl₂, pH adjustedto 7.4 with KOH. N-(2,6-diethylphenylcarbamoylmethyl)-triethyl-ammoniumbromide (QX314, 5 mM) was included in the postsynaptic pipettesolution to suppress action potential generation when aCSF didnot contain TTX. For recording EPSCs, the aCSF routinely containedbicuculline (10 µM) and strychnine (0.5 µM) to block spontaneousinhibitory synaptic currents. For recording presynaptic calciumcurrents (IpCa), the presynaptic pipette was filled with a solution(B) containing 110 mM CsCl, 40 mM HEPES, 0.5 mM EGTA, 1 mM MgCl₂,2 mM ATP, 0.5 mM GTP, 12 mM Na₂ phosphocreatinine, and 10 mM TEA,pH adjusted to 7.4 with CsOH. Presynaptic potassium currents wererecorded with solution A. The presynaptic pipette solutions routinelycontained 2 mM ATP (ATP-Mg salt), 12 mM phosphocreatinine, and0.5 mM GTP, unless noted otherwise. For paired recordings 10 mMpotassium glutamate or cesium glutamate (equimolar replacementof KCl or CsCl) was also included in the presynaptic pipette solution(Borst et al., 1995; Takahashi et al., 1996).

Recording and data analysis. Whole-cell patch-clamp recordings were made from MNTB neurons, presynaptic calyces, or simultaneouslyfrom both structures (Takahashi et al., 1996). EPSCs were evokedat 0.1 Hz by extracellular stimulation of presynaptic axons nearthe midline of a slice with a bipolar platinum electrode (Barnes-Daviesand Forsythe, 1995) in a relatively thick slice (250 µm) or bypresynaptic action potentials or Ca²⁺ currents elicited by a whole-cell pipette in thin slice (150µm). The electrode resistances were 4-7 M $Omega$ for the postsynapticpipette and 6-10 M $Omega$ for the presynaptic pipette. The series resistanceof presynaptic recording was typically 10-20 M $Omega$ and was compensatedby 60-90%. Current or potential recordings were made with a patch-clampamplifier (Axopatch 200B, Axon Instruments, Foster City, CA).Unless noted otherwise, records were low-pass-filtered at 2.5-20kHz and digitized at 5-50 kHz by a CED 1401 interface (CambridgeElectronic Design). Leak currents were subtracted for presynapticcurrents by a scaled pulse divided by n (P/N) protocol. The liquidjunctional potential between the pipette solution and aCSF was+7.5 mV for solution A and +3.3 mV for solution B. The value ofreversal potentials (see Fig. 6C) was corrected for these junctionpotentials.

Drug application. GABA_B receptor agonists were bath-applied by switching superfusates by solenoid valves. Caged GTP $gamma$ S [S-(DMNPE-caged)GTP $gamma$ S; Molecular Probes, Eugene, OR] was applied at 38 µM intocalyces by dialysis from whole-cell pipettes. Care was taken toprotect the compound from short wavelength light during this procedure.A flash of light was given from a mercury lamp light source (50W) through a filter (360 ± 20 nm) by opening a shutter for a givenperiod (2-4 sec). Application of the light flash without loadingcaged compound had no effect on the synaptic transmission or IpCaunder normal experimental conditions, although an excessive illuminationsometimes induced a transient potentiation of IpCa or an increasein the frequency of spontaneous synaptic currents. Experimentswere carried at room temperature (22-26°C).

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Presynaptic inhibition mediated by GABA_B receptors at the calyx of Held

A single extracellular stimulation evoked a large and rapidly decaying EPSC in a principal cell of the medial nucleus of trapezoidbody (MNTB) under whole-cell voltage clamp. As reported previously(Barnes-Davies and Forsythe, 1995), bath-application of the GABA_Breceptor agonist baclofen suppressed EPSCs in a reversible manner(Fig. 1A). This baclofen effect was detectable at 0.2 µM, increaseddose-dependently, and reached a maximal at ~20 µM (Fig. 1B). Similarly,the inhibitory transmitter GABA suppressed EPSCs (Fig. 1). The50% inhibitory concentration (IC₅₀) of baclofen was estimatedfrom the dose-response curve to be 0.8 µM, whereas that for GABAwas 10 µM (Fig. 1B). Thus baclofen was about 10 times more potentthan GABA in inhibiting EPSCs at this synapse. The inhibitoryeffects of both baclofen and GABA were largely attenuated by theGABA_B receptor antagonist CGP35348 (100 µM) (Fig. 1A), indicatingthat the effects of baclofen and GABA were indeed mediated bythe GABA_B receptor.

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Figure 1. Inhibitory effects of GABA_B receptor agonists on EPSCs. EPSCs were evoked by extracellular stimulation. A (top row), Reversible inhibition of EPSCs by baclofen (2 µM) and attenuation of the baclofen effect by CGP35348 (100 µM) in an MNTB neuron. Bottom row, Inhibitory effect of GABA (20 µM) and its attenuation by CGP35348 in another MNTB neuron. The magnitude of inhibition by CGP35348 on the effect of baclofen and GABA was 82.8 ± 2.3% (n = 3) and 60.7 ± 11% (n = 3), respectively. B, Dose-dependent suppression of EPSCs by baclofen and GABA. Cumulative dose-dependent effects of baclofen (top) and GABA (bottom) on the amplitude of EPSCs recorded from MNTB neurons. Sample records from individual MNTB neurons are shown in the inset. Calibration: 2 nA, 10 msec. The curves fitted to data points derived from the following equation: magnitude of inhibition (%) = maximal inhibition (%)/[1 + (IC₅₀/agonist concentration)ⁿ]. For baclofen and GABA, maximal inhibition was 82.0 and 90.8%, IC₅₀ was 0.77 and 9.97 µM, and Hill coefficient (n) was 0.90 and 1.21, respectively. Magnitude of EPSC suppression by 20 µM baclofen was 80.1 ± 2.6% at the cumulative-dose application (n = 4), which was not significantly different (p = 0.13; Student's t test) from that at the single-dose application (72.5 ± 4.3%; n = 8).

Involvement of G-proteins in GABA_B receptor-mediated presynaptic inhibition

An EPSC was evoked by a presynaptic action potential in a simultaneous whole-cell recording from the calyx of Held and a targetMNTB cell (Fig. 2A). Baclofen suppressed the EPSC without affectingthe presynaptic action potential. The magnitude of suppressionof EPSCs by baclofen (20 µM) was 78.5 ± 0.71% (mean ± SEM; n =4 cells), which was comparable with that for the extracellularlyevoked EPSCs (Fig. 1 and legend). The presynaptic action potentialhad a peak amplitude of 90.5 ± 12 mV and a half-width of 0.76± 0.19 msec (n = 4 calyces), which remained at 99.0 ± 2.4% and113 ± 25%, respectively, during baclofen application. Baclofenhad no effect on the presynaptic membrane potential or conductance(see below).

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Figure 2. Baclofen-induced suppression of EPSCs is blocked by GDP $beta$ S. Simultaneous presynaptic and postsynaptic recordings at the calyx-MNTB synapse. EPSCs were evoked by action potentials elicited by a depolarizing current pulse (2-10 msec) applied to a calyx through a whole-cell patch pipette. The postsynaptic holding potential was $-$ 70 mV. A, Reversible suppression of EPSCs by baclofen (20 µM). B, Blocking effect of GDP $beta$ S (tri-lithium salt, 3 mM) in the pipette on baclofen-induced suppression of EPSCs (a, b). A lower concentration of GDP $beta$ S (0.2 mM) did not prevent the effect of baclofen (data not shown). After the pipettes were retracted, a second paired recording was made from the same structures with a presynaptic pipette containing GTP (0.5 mM) instead of GDP $beta$ S. Baclofen clearly suppressed the EPSCs (c, d), which gradually recovered after washout (e). Complete recovery of EPSCs took 5-10 min (Fig. 7). When LiCl (9 mM) was included in the presynaptic pipette the baclofen effect was not attenuated (not shown). The amplitudes of EPSCs were normalized against the mean of the first seven (with GDP $beta$ S) or six (with GTP) data points before baclofen application in each experiment; the data point represents means and the error bars represent SEMs derived from paired recording experiments at three different synapses. Vertical calibration scales indicate 80 mV for presynaptic membrane potentials (A and B) and 1.25 nA (A) or 0.6 nA (B) for EPSCs. Scale bars, 10 msec.

To directly address an involvement of presynaptic G-proteins in the action of baclofen, the GDP analog guanosine-5'-O-(2-thiodiphosphate)(GDP $beta$ S, 3 mM) was included in the presynaptic whole-cell pipette.In this condition, baclofen no longer suppressed EPSCs (102 ±2.6%; n = 4 pairs) (Fig. 2B). After the whole-cell pipette containingGDP $beta$ S was retracted, another paired recording was made again atthe same synapse, this time with a presynaptic pipette solutioncontaining GTP. Baclofen clearly suppressed EPSCs by 67 ± 14%(n = 3 pairs after GDP $beta$ S washout) (Fig. 2B). Thus presynapticGDP $beta$ S blocked the effect of baclofen in a reversible manner. Similarly,when the nonhydrolyzable GTP analog guanosine 5'-O-(3-thiotriphosphate)(GTP $gamma$ S, 200 µM) was included in the presynaptic whole-cell pipette,baclofen had no effect on EPSCs (105 ± 7.6%; n = 3 pairs; datanot shown). These results indicate that the effect of baclofenon EPSCs is indeed presynaptic and that G-proteins are involvedin the GABA_B receptor-mediated presynaptic inhibition.

Inhibition of presynaptic calcium currents by baclofen

To identify an effector of the presynaptic GABA_B receptor, we first examined whether presynaptic calcium currents (IpCa) couldbe modulated by baclofen. As illustrated in Figure 3A, baclofenslowed activation kinetics of IpCa and reduced its amplitude.When measured at the peak of the control current (1.3 msec fromonset) at $-$ 10 mV, the magnitude of IpCa suppression was 38.0 ±3.8% (n = 6). The baclofen-induced suppression of IpCa was notassociated with a shift in the current-voltage (I-V) relationship(Fig. 3C). As shown in Figure 3A,B, after a 10 msec depolarizingpulse (to $-$ 10 mV) IpCa deactivated exponentially with a fast timeconstant (0.14 ± 0.03 msec; n = 8). Baclofen had no effect onthis deactivation time constant (0.14 ± 0.05 msec after baclofen).This suggests that baclofen has little effect on the presynapticCa²⁺ channel open time. These characteristics of the baclofen-inducedinhibition of IpCa are similar to those reported for somatic Ca²⁺ currents (Dolphin and Scott, 1987; Scholtz and Miller, 1991;Mintz and Bean, 1993; Lambert and Wilson, 1996).

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Figure 3. Suppression of presynaptic Ca²⁺ currents by baclofen. The calyx was voltage-clamped at $-$ 80 mV, and IpCa was evoked by a 10 msec depolarizing pulse. In this experiment, [Ca²⁺]_o was reduced to 1 mM to allow better voltage-clamp performance. A, IpCa induced in a calyx by a depolarizing voltage step to $-$ 10 mV in the absence and presence of baclofen (20 µM, superimposed). B, The tail currents are normalized at the peak and superimposed. C, Current-voltage relationships of IpCa before (open circles) and after (filled circles) baclofen application. Mean values ± SEMs obtained from six calyces are shown.

To study further the involvement of G-proteins in the baclofen-induced suppression of IpCa, caged GTP $gamma$ S (38 µM) was loadedinto a calyx through a whole-cell patch pipette (Fig. 4A). Afterit was confirmed that baclofen reversibly suppressed IpCa (a-c),a flash of ultraviolet light (UV, 340-380 nm) was applied for2-4 sec (arrow) to induce a photo-release of the caged GTP $gamma$ S compound.After the flash, IpCa gradually diminished in amplitude and slowedin its rising phase (c, d). After IpCa amplitude reached a steadylevel, a second application of baclofen no longer attenuated IpCa(d, e). In agreement with this result, when GTP $gamma$ S (200 µM) wasincluded in the presynaptic whole-cell pipette, IpCa exhibiteda similarly slow rise, and baclofen had no significant effecton the current amplitude (99.8 ± 1.6%; n = 4) (Fig. 4B). WhenGDP $beta$ S (3 mM) was included in the pipette, IpCa had a normal risetime, but baclofen was again ineffective on IpCa (96.9 ± 1.2%;n = 5) (Fig. 4C). These results indicate that the inhibitory effectof baclofen on the presynaptic calcium current is mediated byG-proteins.

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Figure 4. Block of baclofen-induced IpCa suppression by GTP $gamma$ S or GDP $beta$ S. A, Occlusion of baclofen effect by GTP $gamma$ S. IpCa was evoked in a calyx by a 20 msec depolarizing step from $-$ 70 mV to $-$ 13 mV. Baclofen (20 µM) suppressed IpCa, which recovered partially (a-c, superimposed). After a light flash given at an arrow for 2 sec, IpCa diminished gradually (c, d). A second application of baclofen after the flash had no effect on IpCa (d, e). Essentially the same result was obtained in two other calyces. B, C, Little effect of baclofen on IpCa (evoked by a 20 msec depolarizing pulse from $-$ 80 mV to $-$ 10 mV) was observed in the presence of GTP $gamma$ S (200 µM, B) or GDP $beta$ S (3 mM, C) in the presynaptic pipette. B and C are from different calyces. A similar result was obtained in another calyx for each case.

Lack of baclofen effect on presynaptic potassium currents

We next examined whether baclofen might modulate potassium currents. Voltage-dependent outward potassium currents were evokedby depolarizing a presynaptic terminal in the presence of TTX(1 µM) (Forsythe, 1994). As illustrated in Figure 5, the potassiumcurrent before and after baclofen application was nearly identicalat all voltages examined. Thus, GABA_B receptors do not seem tobe coupled with voltage-gated potassium channels at the presynapticterminal.

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Figure 5. Lack of baclofen effect on voltage-gated potassium currents. Inset, Outward potassium currents evoked by 20 mV depolarizing steps from the holding potential of $-$ 80 mV to +20 mV in the presence of TTX before (left) and after (middle) baclofen (20 µM) application. The superimposed traces before and after baclofen application overlapped almost completely (right). The amplitude of the potassium current was normalized against the value at 0 mV and mean ± SEMs of five calyces before (open circles) and after (filled triangles) baclofen application are plotted against membrane potential.

In neuronal somata, baclofen enhances inwardly rectifying potassium currents by activating G-proteins (Andrade et al., 1986;Sodickson and Bean, 1996). We examined whether baclofen mightsimilarly enhance the inward rectifying potassium current at thepresynaptic terminal. As illustrated in Figure 6A, baclofen appliedat $-$ 70 mV holding potential had no effect on the holding currentor the membrane conductance (98.5 ± 1.8%; n = 9) measured by aramp command voltage pulse (Fig. 6C). The inwardly rectifyingpotassium current is known to be blocked by a low concentrationof Ba²⁺ (Hagiwara et al., 1978). Bath-application of Ba²⁺ (100 µM) caused a small inward current accompanied by a slightdecrease in membrane conductance (to 84.5 ± 4.6%; n = 6) (Fig.6A), suggesting that the inwardly rectifying channels might weaklycontribute to the resting conductance of the presynaptic terminal.After a calyx was loaded with caged GTP $gamma$ S, photo-release of GTP $gamma$ Sby a flash (Fig. 6B, arrow) induced a prominent outward currentaccompanied by an increase in membrane conductance. After theoutward current reached a steady level, subsequent applicationof Ba²⁺ (100 µM) largely abolished this current. When Ba²⁺ was washed out, the outward current gradually recovered, withan increase in membrane conductance (not shown). The Ba²⁺-sensitive current induced by GTP $gamma$ S was extracted as a differencecurrent before and after the Ba²⁺ application (Fig. 6B, a and b). This current rectified inwardlyand reversed at $-$ 92 ± 1.1 mV (n = 4) close to the theoreticalpotassium equilibrium potential (99.5 mV; Fig. 6C, arrow), indicatingthat it is a G-protein-activated inwardly rectifying potassiumcurrent (GIRK) (Kubo et al., 1993). Thus GIRK is present in thepresynaptic terminal but cannot be activated by GABA_B receptors.

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Figure 6. Effects of baclofen and GTP $gamma$ S on presynaptic holding current and membrane conductance. A calyx was voltage-clamped at the holding potential of $-$ 70 mV, and a ramp command voltage from $-$ 50 to $-$ 130 mV (C, top left) was applied every 20 sec. A, Baclofen (20 µM) had no effect on the holding current or input conductance. Ba²⁺ (100 µM) caused a slight inward current associated with a decrease in conductance in the same calyx. B, In another calyx, photo-release of GTP $gamma$ S by a UV flash (arrow) induced an outward current accompanied by an increase in input conductance. This current was suppressed by Ba²⁺ (100 µM, b). Application of the light flash without loading caged compound had no effect on the holding current or membrane conductance. The outward current was not observed after GTP $gamma$ S photolysis with the Cs⁺-based internal solution for IpCa recordings (Fig. 4A). C, Currents (a, b, bottom) corresponding to a command voltage (top) after photolysis of caged GTP $gamma$ S compound before (a) and after (b) application of Ba²⁺. Right, Ba²⁺-sensitive current extracted as a difference current (a-b). Arrow indicates theoretical equilibrium potential for potassium ions calculated from the internal and external potassium activities. The difference current between before and after photolysis had a similar reversal potential, but inward rectification was less prominent (data not shown). Membrane potential was corrected for the liquid junction potential between the external and internal solution (+7.5 mV) for this current-voltage relationship. The data in this figure were low-pass-filtered at 100 Hz and sampled at 1 kHz.

Similar to Ba²⁺, extracellular Cs⁺ blocks inwardly rectifying potassium currents (Hagiwara et al., 1976; Sodickson and Bean,1996) as well as the inwardly rectifying cationic currents I_h(Halliwell and Adams, 1982; Takahashi, 1990). Bath-applicationof Ba²⁺ or Cs⁺ (both at 1 mM) had no effect on EPSCs evoked extracellularly(Fig. 7). Baclofen applied in the presence of Ba²⁺ or Cs⁺ suppressed EPSCs to a similar extent as in control: 72.5 ± 4.3%in control (n = 8), 72.6 ± 2.0% in Ba²⁺ (n = 4), and 74.8 ± 1.5% in Cs⁺ (n = 4), respectively. These results suggest further that neitherGIRK nor I_h is involved in the GABA_B receptor-mediated presynapticinhibition at the calyx-MNTB synapse.

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Figure 7. Effect of external Ba²⁺ and Cs⁺ on GABA_B receptor-mediated presynaptic inhibition. EPSCs were evoked in MNTB principal cells by extracellular stimulation. A, Baclofen-induced suppression of EPSCs was similar before and after Ba²⁺ application (1 mM). EPSCs before, during baclofen application (20 µM), and after washout are superimposed on top in the absence (left) and presence (right) of Ba²⁺. Note the small polysynaptic EPSC component observed at the decay of monosynaptic EPSC. B, Baclofen suppressed EPSCs similarly in the absence and presence of external Cs⁺ (1 mM). EPSCs before and after baclofen application are superimposed on top in the absence (left) and presence (right) of Cs⁺. A and B are from different cells.

Lack of contribution of exocytotic machinery to GABA_B receptor-mediated presynaptic inhibition

To examine whether the exocytotic process downstream of Ca²⁺ influx is involved in GABA_B receptor-mediated presynaptic inhibition,we made simultaneous pre- and postsynaptic recordings and comparedthe IpCa-EPSC relationship between two conditions: first afterbaclofen application and then after reduction of [Ca²⁺]_o (Takahashi et al., 1996). When baclofen was applied, EPSCsdiminished concomitantly with IpCa (Fig. 8A, i, ii). Similarly,when [Ca²⁺]_o was reduced by replacement with [Mg²⁺]_o, both EPSCs and IpCa were diminished in parallel (Fig. 8A,iii, iv). When the IpCa-EPSC relations were plotted for data obtainedafter baclofen application and after [Ca²⁺]_o reduction, the two relationships largely overlapped with eachother (Fig. 8B). At the seven synapses examined, the slope inthe regression lines after baclofen application was similar tothat after [Ca²⁺]_o reduction (Fig. 8B, inset) (no significant difference in pairedt test). The result was essentially the same when the charge insteadof the peak amplitude for IpCa and EPSCs was compared. Thus, thebaclofen-induced suppression of EPSCs can be explained mostlyby a reduction of IpCa.

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Figure 8. Comparison of IpCa-EPSC relationships during baclofen application and [Ca²⁺]_o reduction. Paired recording from a calyx and its target cell. A, Effects of baclofen (20 µM; i, ii) and [Ca²⁺]_o reduction (iii, iv) on IpCa (Pre) and EPSCs (Post). IpCa was evoked by 1 msec depolarizing command pulse from $-$ 70 mV to $-$ 10 mV. Records before and after baclofen application or [Ca²⁺]_o reduction are superimposed on top row. B, Double logarithmic plot of IpCa-EPSC relation during baclofen application (filled circles with a dotted regression line) and [Ca²⁺]_o reduction (open circles with a solid regression line). Data points above 90% in EPSC amplitude were excluded from these plots to minimize constrainment. The slope value was 2.29 for baclofen and 2.33 for [Ca²⁺]_o reduction, respectively. Excluding the minimal point from each relationship had no significant effect on the slope values (2.15 and 2.09, respectively, for baclofen and [Ca²⁺]_o reduction). Inset graph, The slope value of regression lines compared between [Ca²⁺]_o reduction and baclofen application at seven synapses. No significant difference with p = 0.24 in paired t test. The mean slope value was 1.73 ± 0.17 for baclofen and 1.77 ± 0.17 for [Ca²⁺]_o reduction, respectively.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Inhibition of calcium currents and transmission by GABA_B receptor through G-protein

In this study, using paired whole-cell recordings from the brain stem giant presynaptic terminal and postsynaptic cell, wehave demonstrated that presynaptic GABA_B receptors are linkedthrough G-proteins to Ca²⁺ channels, thereby suppressing transmitter release. The IpCa atthe calyx-MNTB synapse is almost exclusively P-type at the agerange examined (Forsythe et al., 1998). It is possible that $beta$ $gamma$ complex of heterotrimeric G-protein may interact with the $alpha$ _1Asubunit, thereby suppressing P-type Ca²⁺ channel activity (De Waard et al., 1997). Such a membrane-delimitedmechanism is consistent with our finding that the magnitude ofthe baclofen-induced suppression of EPSCs evoked via a presynapticwhole-cell pipette was similar to that of EPSCs evoked via anextracellular pipette. Thus diffusible intracellular messengers,likely to be washed out during whole-cell recording, may not beessentially involved in the baclofen-induced suppression of EPSCs.IpCa is also suppressed by a metabotropic glutamate receptor (mGluR)agonist (Takahashi et al., 1996). It remains to be seen whethera common G-protein mediates the presynaptic inhibition by mGluRsand GABA_B receptors.

Presynaptic potassium channels are not coupled with GABA_B receptor

Presynaptic potassium conductances are thought to be important in the regulation of transmitter release (Augustine, 1990).The receptor-mediated inhibition of a potassium conductance isknown to enhance synaptic efficacy in invertebrate nervous systems(Kandel and Schwartz, 1982). At mammalian neuronal somata, GABA_Breceptors potentiate transient potassium currents (Saint et al.,1990) or activate inwardly rectifying potassium currents throughG-protein activation (Andrade et al., 1986; Sodickson and Bean,1996). It has been postulated that an enhancement of presynapticpotassium currents may underlie GABA_B receptor-mediated presynapticinhibition (Saint et al., 1990; Thompson and Gahwiler, 1992).However, direct recordings from the calyx presynaptic terminalsrevealed that baclofen had no effect on the voltage-gated potassiumcurrents or inwardly rectifying potassium currents. Furthermore,the inward rectifier channel blockers Ba²⁺ or Cs⁺ had no effect on the baclofen-induced inhibition of EPSCs. Theseresults indicate that potassium conductances are not significantlyinvolved in the GABA_B receptor-mediated presynaptic inhibitionat this fast excitatory synapse.

In our present study, Ba²⁺ had no effect on GABA_B receptor-mediated presynaptic inhibition as reported at other central synapses(Allerton et al., 1989; Lambert at al., 1991; Thompson and Gahwiler,1992; Hirata et al., 1995). Although Ba²⁺ was reported to inhibit the effect of baclofen on monosynapticIPSCs in hippocampal CA3 cells (Thompson and Gahwiler, 1992),this was not confirmed in a study using another blocking agentof inward rectifying potassium channels (Lambert and Wilson, 1993).Furthermore, transgenic mice lacking a GIRK gene exhibited a normalmagnitude of GABA_B receptor-mediated presynaptic inhibition athippocampal synapses (Luscher et al., 1997). Thus, so far thereis no direct evidence to indicate an involvement of potassiumconductances in the receptor-mediated presynaptic inhibition atmammalian central synapses.

At the calyx of Held, an inwardly rectifying potassium current could be activated by intracellular application of GTP $gamma$ S butnot by baclofen. This result may imply that the GABA_B receptorsand G-proteins coupled with GIRK are distinct from those coupledwith voltage-gated calcium channels, as proposed previously onthe basis of pharmacological differences between the presynapticand postsynaptic effect of baclofen (Dutar and Nicoll, 1988).However, it is also possible that GIRK is localized outside ofthe functional domain of G-proteins coupled with GABA_B receptorsat the presynaptic nerve terminal.

Baclofen had no effect on presynaptic spike waveform being consistent with the lack of involvement of potassium conductance(also see Dittman and Regehr, 1996). Although baclofen suppressedthe presynaptic calcium conductance, this was not apparent inthe action potential waveform. This might be attributable to thelarge potassium conductance masking the calcium conductance. Infact, even after synaptic transmission was abolished by reducing[Ca²⁺]_o, the presynaptic action potential waveform remained similarat this (our unpublished observation) and other synapses (Sabatiniand Regehr, 1997).

The exocytotic machinery for evoked transmitter release is not affected by GABA_B receptors

The IpCa-EPSC relationship during baclofen application was similar to that during reduction of [Ca²⁺]_o. This suggests that the exocytotic machinery downstream ofCa²⁺ entry is not involved in GABA_B receptor-mediated presynapticinhibition at the calyx-MNTB synapse, as is the case for mGluR-mediatedpresynaptic inhibition (Takahashi et al., 1996). In the case ofbaclofen, similar conclusions were made from studies using Ca²⁺ indicators at hippocampal synapses (Wu and Saggau, 1995; Dittmanand Regehr, 1997) (but see Dittman and Regehr, 1996). The directinvolvement of the exocytotic machinery in receptor-mediated presynapticinhibition has been postulated from the observation that baclofensuppressed the frequency of spontaneous miniature synaptic currentsin a [Ca²⁺]_o-independent manner (Scanziani et al., 1992; Rohrbacher et al.,1997). However, differential modulations of the frequency of miniatureevents and the amplitude of evoked synaptic responses by variousmanipulations are well known (Fu and Poo, 1991; Geppert et al.,1994; Cummings et al., 1996; Hori et al., 1996). A distinct mechanismmay operate in the modulation of synchronous and asynchronoustransmitter release.

In conclusion, this study has demonstrated G-protein-coupled modulation of presynaptic Ca²⁺ channels on activation of GABA_B receptor-mediated presynapticinhibition; neither potassium channels nor modulation of the exocytoticmachinery downstream of Ca²⁺ influx plays a significant role. On binding a ligand, presynapticGABA_B receptors activate G-proteins and suppress Ca²⁺ currents, thereby reducing transmitter release. Given the widedistribution of presynaptic GABA_B receptors at synapses throughoutthe nervous system, this mechanism would be of general application.

  FOOTNOTES

Received Nov. 26, 1997; revised Feb. 11, 1998; accepted Feb. 12, 1998.

This work was supported by the "Research for the Future" Program by The Japan Society for the Promotion of Sciences. We thankM. Farrant, I. D. Forsythe, T. Manabe, and K. Kobayashi for criticallyreading this manuscript. We are also grateful to R. Y. Tsien andV. Lev-Ram for their technical advice on the caged compound photolysissystem and to Novartis Pharma (Basel, Switzerland) for the generousgift of CGP35348.
Correspondence should be addressed to Tomoyuki Takahashi, Department of Neurophysiology, University of Tokyo Faculty of Medicine,Tokyo 113, Japan.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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