Distinctive Glycinergic Currents With Fast and Slow Kinetics in Thalamus

doi:10.1152/jn.01218.2005

Distinctive Glycinergic Currents With Fast and Slow Kinetics in Thalamus

Amer A. Ghavanini¹, David A. Mathers², Hee-Soo Kim¹ and Ernest Puil¹

¹Department of Anesthesiology, Pharmacology, and Therapeutics and ²Department of Cellular and Physiological Sciences, The University of British Columbia, Vancouver, British Columbia, Canada

Submitted 18 November 2005; accepted in final form 15 March 2006

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

We examined functional properties of inhibitory postsynapticcurrents (IPSCs) evoked by medial lemniscal stimulation, spontaneousIPSCs (sIPSCs), and single-channel, extrasynaptic currents evokedby glycine receptor agonists or ${gamma}$ -aminobutyric acid (GABA) inrat ventrobasal thalamus. We identified synaptic currents byreversal at E_Cl and sensitivity to elimination by strychnine,GABA_A antagonists, or combined application. Glycinergic IPSCsfeatured short (about 12 ms) and long (about 80 ms) decay timeconstants. These fast and slow IPSCs occurred separately withmonoexponential decays, or together with biexponential decaykinetics. Glycinergic sIPSCs decayed monoexponentially withtime constants, matching fast and slow IPSCs. These findingswere consistent with synaptic responses generated by two populationsof glycine receptors, localized under different nerve terminals.Glycine, taurine, or $beta$ -alanine applied to excised membrane patchesevoked short- and long-duration current bursts. Extrasynapticburst durations resembled fast and slow IPSC time constants.The single, intermediate time constant (about 22 ms) of GABA_AergicIPSCs cotransmitted with glycinergic IPSCs approximated theburst duration of extrasynaptic GABA_A channels. We noted differencesbetween synaptic and extrasynaptic receptors. Endogenously activatedglycine and GABA_A receptor channels had higher Cl^– permeabilitythan that of their extrasynaptic counterparts. The $beta$ -amino acidsactivated long-duration bursts at extrasynaptic glycine receptors,consistent with a role in detection of ambient taurine or $beta$ -alanine.Heterogenous kinetics and permeabilities implicate molecularand functional diversity in thalamic glycine receptors. Fast,intermediate, and slow inhibitory postsynaptic potential decays,mostly attributed to cotransmission by glycinergic and GABAergicpathways, allow for discriminative modulation and integrationwith voltage-dependent currents in ventrobasal neurons.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Since the discovery of glycinergic transmission in the spinalcord, several studies have demonstrated that glycine mediatesneurotransmission above the level of the cord (Chery and DeKoninck 1999; Donato and Nistri 2000; Dumoulin et al. 2001;Fatima-Shad and Barry 1998). Recently, glycinergic inhibitionhas become recognized in the ventrobasal thalamus (Ghavaniniet al. 2005; cf. Zeilhofer et al. 2005). Medial lemniscal stimulationproduced inhibitory postsynaptic potentials (IPSPs) mediatedonly in part by the prevalent inhibitory transmitter, ${gamma}$ -aminobutyricacid (GABA; Steriade et al. 1997). A combination of strychninewith a GABA_A antagonist completely blocked this inhibition (Ghavaniniet al. 2005). Unexpectedly, glycinergic or GABAergic IPSPs occurredindependently in many neurons, which tended to favor cotransmittingpathways rather than corelease of these amino acids.

Glycine receptors are pentameric complexes containing pore-forming ${alpha}$ subunits, with or without accessory $beta$ subunits (Lynch 2004).Heteromeric ( ${alpha}$ / $beta$ ) receptors localize to the synaptic membrane(cf. Lynch 2004), consistent with the punctate ${alpha}$ subunit stainingin the thalamus (Ghavanini et al. 2005). In the caudal CNS,glycinergic inhibitory postsynaptic currents (IPSCs) exhibitdiverse decay kinetics that correlate to receptor subunit expression.In brain stem and spinal neurons, glycine receptors with ${alpha}$ ₁ or ${alpha}$ ₂ subunits have different kinetic properties (Singer et al.1998; Takahashi et al. 1992). The ${alpha}$ ₁ subunit predominance inthe adult rat bestows fast decay rate for IPSCs. The ${alpha}$ ₂ subunitconfers slow IPSC decay, often seen in developing neurons (Aliet al. 2000; Takahashi et al. 1992). Thus the first objectiveof the present study was to examine glycinergic IPSC decay inventrobasal neurons of the juvenile rat for evidence of kineticheterogeneity. We also searched for evidence of biphasic decaysin spontaneous IPSCs (sIPSCs) sensitive to complete blockadeby strychnine with GABA_A antagonists, indicative of coreleasefrom glycinergic and GABAergic pathways (cf. Dumoulin et al.2001).

Previously, we observed strychnine antagonism of responses toexogenous glycine agonists and diffuse staining for glycinereceptor ${alpha}$ ₁ and ${alpha}$ ₂ subunits (Ghavanini et al. 2005). These observationswere consistent with extrasynaptic receptor populations. However,functional receptors on extrasynaptic membranes of thalamocorticalneurons would require direct demonstration. The second objectiveof the present studies was to determine whether extrasynapticglycine receptors existed and exhibited the expected kineticdiversity.

For the thalamus as elsewhere, it is not known whether extrasynapticglycine receptors exhibit differences from synaptic glycinechannels. In GABAergic pathways, extrasynaptic GABA_A receptorchannels exhibit lower Cl^– conductance than synaptic channels(Yeung et al. 2003). Using fluctuation analysis on evoked andspontaneous IPSCs, our third objective was to compare the conductanceproperties of synaptic and extrasynaptic receptor channels.These studies delineate some unusual facets of glycine receptorsand inhibitory transmission in the thalamus.

METHODS

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Tissue slice preparation

The experimental procedures received approval by the AnimalCare Committee of University of British Columbia. Sprague–Dawleyrats (13- to 15-day-old) were decapitated while under deep halothaneanesthesia. The brain was rapidly removed and submerged in oxygenatedsolution at 4°C containing (in mM): 26 NaHCO₃; 1.25 NaH₂PO₄;2.5 KCl; 2 MgCl₂; 2 CaCl₂; 25 dextrose; and 250 sucrose. Thesolution had an osmolality of 330 mOsmol. The brains were dissectedinto two blocks. Using a Vibroslicer (Campden Instruments, London,UK), the block was sectioned into 250- to 300-µm-thicksagittal slices, showing landmarks of the scaphoid nucleus andmedial lemniscus (Paxinos and Watson 1986). The slices wereincubated for >3 h in artificial cerebrospinal fluid (aCSF)at room temperature (23–25°C), saturated with 95%O₂-5% CO₂. The aCSF contained (in mM): 124 NaCl; 26 NaHCO₃;1.25 NaH₂PO₄; 4 KCl; 2 MgCl₂; 2 CaCl₂; and 10 dextrose. TheaCSF had a pH of 7.3–7.4 and an osmolality of 305 mOsmol.

IPSC recording

For recording, the slices were placed in a Perspex recordingchamber (approximately 2 ml volume) and were immobilized witha polypropylene mesh. They were perfused with oxygenated aCSFat room temperature, at a rate of 1.5–2 ml/min. Ventrobasalneurons were identified under a differential interference contrastmicroscope at x400 (Axioskop 2, Carl Zeiss, Oberkochen, Germany).Recording microelectrodes were made using a Narishige pullerfrom thin-wall borosilicate glass tubing (World Precision Instruments,Sarasota, FL), and filled with a solution containing (in mM):133 K-gluconate; 12 KCl; 4 NaCl; 0.5 CaCl₂; 10 EGTA; 3 Mg-ATP;0.3 Na₂-GTP; 2.7 Na₂-phosphocreatine, and 10 N-[2-hydroxyethyl]piperazine-N'-[2-ethanesulfonicacid] (HEPES). The pH was adjusted to 7.3–7.4. The calculatedNernst potentials for this normal patch solution were –53mV for Cl^– (E_Cl) and –84 mV for K⁺ (E_K). Electroderesistances ranged between 4 and 5 M ${Omega}$ .

Whole cell recording of IPSCs was performed using amplifiers(Axoclamp 2A, Axon Instruments, Foster City, CA; and List EPC-7,HEKA, Lambrecht, Germany) in the current- and voltage-clampmodes. The neurons were voltage clamped at V_h = –80 mVto minimize contributions of infrequently occurring GABA_B currents.As previously (Ghavanini et al. 2005), ionotropic glutamatergiccurrents were blocked with kynurenate (1 mM). In 14 neurons,Cs⁺ (145 mM) and QX-314 (3 mM) were applied intracellularlyto suppress K⁺ and Na⁺ currents, and Ni²⁺ (500 µM) wasapplied extracellularly to block T-type Ca²⁺ currents. In suchexperiments, the [Cl^–] was adjusted such that E_Cl was0 mV. Signals, filtered at 3 kHz and digitized at 10 kHz witha 16-bit data acquisition system, were analyzed using pClampsoftware (Axon Instruments).

IPSCs were evoked by stimulation at <0.5 Hz with a bipolarelectrode placed in the medial lemniscus outside the thalamus,at 1–2 mm from the ventrobasal nuclei. The resistanceof the stimulating electrode was 5.5 M ${Omega}$ . We activated glycinereceptors by electrical stimulation of the medial lemniscus,evoking IPSCs during ionotropic glutamate receptor blockade.The stimulus intensity was adjusted to evoke stable amplituderesponses, without failures. The stimulus parameters were arheobasic current of 3.9 ± 0.9 µA and a chronaxieof 245 ± 37 µs (n = 21).

Spontaneous IPSCs were recorded during intracellular applicationof Cs⁺ and QX-314 in neurons that were voltage clamped at –60mV. Single sIPSCs were visually selected for averaging and creationof search templates. We used the sliding-template procedureof pClamp software, setting the template match stringency toa medium level. Given the observed variability of sIPSC timecourses, multiple template searches were required for precisedetection of all sIPSCs. The events were monitored visuallyduring the entire procedure, for rejection of sIPSPs with morethan a single peak and noise.

We used pClamp, Prism GraphPad, and CorelDraw software for analysis.Exponential functions were fitted to the decay phase of singlesIPSCs, and evoked IPSCs averaged from five to ten individualcurrents. The double-exponential function was the sum of twoterms, A₁ · exp(–t/ ${tau}$ ₁) + A₂ · exp(–t/ ${tau}$ ₂),where A₁ and A₂ were the amplitudes with time constants ${tau}$ ₁ and ${tau}$ ₂, respectively.

Nonstationary noise analysis

We subjected the IPSCs to nonstationary fluctuation analysisto reveal the properties of synaptic channels activated by endogenoustransmitters (De Koninck and Mody 1994; Traynelis et al. 1993).We confirmed the stability of quantal release in the IPSCs beforesubjecting them to nonstationary noise analysis. The amplitudeof evoked IPSCs did not significantly change with the stimulusnumber, which implied no change in quantal release at stimulationfrequencies <0.5 Hz. We grouped three successive responsesand calculated the coefficients of variation for each triplet.The coefficients of variation did not change with triplet number,confirming stable quantal release (cf. Scheuss and Neher 2001).

We averaged ten successive IPSCs, after aligning their peaksin time. Starting at the IPSC peak, the decays were binned at1.5 ms. I_mean(t), or the average current of each bin (t), wascalculated from the relationship, I_mean(t) = ${sum}$ I_(t)j/n, whereI_(t)j was the current amplitude for trial j for bin t, and nwas the number of trials.

The variance ( ${sigma}$ ²) of each bin was calculated from the differencebetween the scaled average evoked or spontaneous IPSCs, andthe individual currents (cf. Traynelis et al. 1993). Using aleast-squares algorithm, the resulting plot was fitted witha quadratic function, ${sigma}$ _(t)² = i_Cl · I_mean(t) – I_mean(t)²/N+ ${sigma}$ _th(t)², where ${sigma}$ _th(t)² denoted residual noise and i_Cl was theelementary current through the agonist-gated channel. The parameterN (total number of channels at the synaptic site) was not consideredfurther because scaling the average IPSC to individual IPSCincreases the accuracy of i_Cl but decreases the accuracy ofN (Traynelis et al. 1993). We also obtained i_Cl as the slopeof the initial part of the variance-to-mean current relationship,fitted by linear regression. The results of the two estimateswere in good agreement.

The channel Cl^– permeability (P_Cl) was calculated fromthe Goldman–Hodgkin–Katz (GHK) constant-field relationship,P_Cl = i_Cl · (RT/VF²) · {(1 – e^V^F/RT)/([Cl^–]_i– [Cl^–]_o · e^V^F/RT)}, where R, T, and F hadtheir usual meanings, V was membrane potential, and [Cl^–]_iand [Cl^–]_o were the intracellular and extracellular Cl^–concentrations, respectively. We applied a similar procedureto calculate the P_Cl from single-channel currents.

Dissociated neuron preparation

For single-channel recording, acutely dissociated neurons wereprepared from horizontal slices containing the ventrobasal complex.The slices were initially incubated at room temperature for10 min in oxygenated, Ca²⁺-free media composed of (in mM): 120NaCl; 5 KCl; 1 MgCl₂; 5 D-glucose; 20 1,4 piperazine-bis-(2-ethanesulfonicacid) (PIPES); ethylene-glycol-bis(2-aminoethylether)-N,N,N',N'-tetraaceticacid (EGTA), and 2 mg/ml bovine serum albumin (BSA) at pH =7.3. The tissue was then stirred at 32°C for 45 min in asolution of composition (in mM): 120 NaCl; 5 KCl; 1 MgCl₂; 1CaCl₂; 20 PIPES; 2 mg/ml BSA; and 14 units/ml papain at pH =7.0. The tissue was rinsed and left for 15 min at room temperature.The cells were mechanically dispersed in 2 ml of Ca²⁺- and BSA-freePIPES solution and plated on uncoated 35-mm tissue-culture dishes.The cells remained in PIPES buffered solution at room temperatureuntil needed for recording.

Single-channel recording and data analysis

We recorded single-channel currents at room temperature (Kimet al. 2004). Dispersed ventrobasal neurons were bathed in asaline containing (in mM): 4 KCl; 135 NaCl; 10 CaCl₂; 1 MgCl₂;10 HEPES; and, 5 D-glucose (pH 7.3). Patch pipettes (10–15M ${Omega}$ ) contained a solution (pH 7.3) composed of (in mM): 135 CsCl;1 MgCl₂; 0.267 CaCl₂; 10 HEPES; 3 EGTA; and 5 D-glucose. E_Clwas 0 mV in these recordings.

Outside-out membrane patches were voltage clamped with a ListEPC-7 amplifier at a holding potential, V_h = –60 mV. Aminoacids were applied by exchange and perfusion in bath. Responsesto agonists reached a steady state within 30 s of switchingfrom control to agonist solutions. The duration of each applicationwas about 5 min. The currents were filtered at DC to 1 kHz,digitized (8 kHz), and analyzed off-line with commercial software(Instrutech, Port Washington, NY). Single-channel openings weredetected as transients exceeding 50% of the difference betweenthe averaged baseline and open channel currents, disregardingevents briefer than 180 µs. Channel open probability,P_o, was calculated as P_o = (T₁ + 2T₂ +... + NT_N)/T_tot ·N, where N was the number of channels in the patch, T_tot thetotal duration of the record, and T₁ + 2T₂ +... + NT_N were thetimes when $≥$ 1, 2, ..., N channels were open.

Distributions of open channel times were fitted by a triexponentialfunction. Closed time distributions were fitted by four exponentialterms. Exponential fitting was performed using Simplex maximizationof likelihood. We defined groups of openings as bursts, providedthat the openings were separated by gaps shorter than t_c, aspecified critical time. We calculated t_c by solving 1 –exp(–t_c/ ${tau}$ _c3) = exp(–t_c/ ${tau}$ _c2). Here, ${tau}$ _c2 and ${tau}$ _c3 werethe time constants of the second and third fastest componentsin closed time distributions (Colquhoun and Sakmann 1985; Twymanand Macdonald 1991), as appropriate for a DC to 1 kHz recordingbandwidth. Using Simplex methods, we fitted one or two Gaussianterms to the amplitude distributions of single-channel currents.Mean channel conductance was calculated as the weighted sumof the Gaussian-fit components.

Chemicals and drugs

All chemicals, including glycine, $beta$ -alanine, taurine, strychnine,GABA, bicuculline methiodide, gabazine, kynurenate, and QX-314were purchased from Sigma Chemical (St. Louis, MO). Drugs wereapplied either by perfusion of slices or to the external faceof outside-out membrane patches.

Statistics

Using bootstrap methods, we estimated the 95% confidence intervalfor parabolic fits to variance-to-mean current relationships.Data are expressed as means ± SE and n denotes numberof neurons or patches. The Kolmogorov–Smirnov (KS) testwas used to assess goodness-of-fit to normal and Gaussian distributions.For normally distributed data, we used ANOVA for multiple comparisons,and a Tukey post hoc test for comparing group pairs. Student'st-test was used for comparing two groups. For nonnormally distributeddata, Wilcoxon and Kruskal–Wallis tests were used forcomparing two groups or for multiple comparisons, respectively.Significance was defined as P < 0.05.

RESULTS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Characteristics of IPSCs

We studied IPSCs evoked by medial lemniscal stimulation in 21neurons, recorded with the normal solution in the patch electrode.Complete blockade of IPSCs in 14 neurons required coapplicationof strychnine (1 µM) with a GABA_A antagonist, either bicuculline(25 µM) or gabazine (10 µM; Fig. 1A). The IPSCsin seven remaining neurons showed exclusive sensitivity to eitherstrychnine or GABA_A antagonist. Strychnine eliminated the IPSCsin three neurons, unaffected by prior bicuculline application.Bicuculline or gabazine eliminated IPSCs in four neurons, unaffectedby strychnine. We refer to currents requiring both strychnineand GABA_A antagonists for elimination, as "mixed IPSCs."

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FIG. 1. Medial lemniscal mixed inhibitory postsynaptic currents (IPSCs) resolved into glycinergic and GABA_Aergic currents reversed at E_Cl. A, top: 10 µM gabazine slightly reduced control IPSC, yielding a large glycinergic current that was eliminated by coapplied gabazine and 1 µM strychnine (Gbz and Str). Subtraction of current during gabazine from control IPSC yielded a small GABA_Aergic current. A, bottom: 10 µM gabazine greatly suppressed control IPSC in a second neuron, yielding a small glycinergic current eliminated by coapplied gabazine and 1 µM strychnine. Subtraction of current during gabazine from control IPSC yielded a large GABA_Aergic current. Currents were averaged from 10 IPSCs. B: reversal potentials for glycinergic (11 neurons) and GABA_Aergic (14 neurons) components of mixed IPSCs were identical to E_Cl (arrows). Mean peak values of glycinergic and GABA_Aergic components did not differ at V_h = –80 mV (ANOVA, P > 0.05).

We first compared the rise times of glycinergic and GABA_Aergiccomponents in the mixed IPSCs. The mean rise time for the glycinergiccurrents isolated by application of a GABA_A antagonist in neuronsheld at V_h = –80 mV was 2.6 ± 0.5 ms (n = 7). Thisvalue did not differ from the mean rise time (3.0 ± 0.5ms, n = 7) for GABA_Aergic currents isolated by strychnine application(t-test, P > 0.05). Figure 1A shows the glycinergic and GABA_Aergiccurrents of two mixed IPSCs, obtained by subtraction of thecurrents during glycine- and GABA_A-receptor antagonism fromthe control. The peak amplitudes of glycinergic and GABA_Aergiccurrents often differed between neurons (cf. Fig. 1A). The averagepeak amplitudes were not different between the two groups atsix tested holding potentials (ANOVA, P < 0.05; cf. Fig. 1B).The resolved glycinergic and GABA_Aergic currents had reversalpotentials at E_Cl (Fig. 1B), implicating Cl^– dependencywith little or no contribution from other ion species (cf. Bormannet al. 1987

Decay kinetics of IPSCs

Glycinergic currents often displayed more complex decay kineticsthan the GABA_Aergic currents, all of which decayed monoexponentiallywith a normal distribution of constants (Fig. 2, A and C). Elevenof 17 glycinergic IPSCs exhibited a monoexponential decay (cf.Fig. 2A). The decay time constants for these IPSCs were notwell fitted by a normal distribution (P < 0.05, KS test),and likely represented two populations. One population had ashort decay time constant, ${tau}$ _str(short) = 10 ± 1.4 ms (n= 8), whereas the other had a long decay time constant, ${tau}$ _str(long)= 70 ± 4.0 ms in three neurons (ANOVA, P < 0.01).These values remained stable over a period of 1.5 h, indicatingstationarity of decay kinetics.

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FIG. 2. Resolved currents had different decays. A: glycinergic and GABA_Aergic currents were peak aligned and scaled to the same amplitude for comparison of time courses in different neurons. Glycinergic current decayed faster in the neuron of Aa, and slower in the neuron of Ab, when compared with the GABA_Aergic currents. B: decay phase of the glycinergic current in another neuron was well fitted by the sum of 2 exponential terms (top trace, smooth curve). Bottom trace shows these terms and their time constants. C: frequency distribution histograms of decay time constants for glycinergic and GABA_Aergic currents. Arrowheads indicate mean values. V_h = –80 mV, E_Cl = –53 mV. A and B show averages of 10 IPSCs.

Four glycinergic IPSCs decayed with a biexponential time course(cf. Fig. 2B and Ghavanini et al. 2005

). Their biexponentialtime course remained stable over a period of 1.5 h, indicatingstationarity of decay kinetics. The two remaining IPSCs haddiscernible fast and slow components, but additionally exhibitedlong tails. We did not further study these IPSCs because ofuncertainties in their exponential fits. The decay time constants( ${tau}$ ₁ and ${tau}$ ₂) for biexponential IPSCs had means of 13 ± 2.1and 93 ± 10 ms, respectively (n = 4). These values donot differ from ${tau}$ _str(short) and ${tau}$ _str(long), obtained from monoexponentialfits (t-test, P > 0.05). On pooling the data obtained frommono- and biexponential fits, ${tau}$ _str(short) was 12 ± 1.1ms (n = 12) and ${tau}$ _str(long) was 80 ± 6.8 ms (n = 7), asshown in the frequency histogram of Fig. 2C. These time constantsdiffered not only from each other (ANOVA, P < 0.01), butalso from ${tau}$ _GABA = 22 ± 1.5 ms (n = 18; Fig. 2C).

Decay kinetics of spontaneous IPSCs

We studied spontaneous IPSCs in seven neurons, recorded withCs⁺ and QX-314 in the patch electrode. We observed spontaneousinward currents of small amplitude in all neurons. These eventsoccurred at an average frequency of 3.8 ± 0.9 Hz (cf.Fig. 3A). These events reversed at a V_h near E_Cl. There wasno correlation between the amplitude, rise time, and decay timeconstant of the events (R² < 0.01). Thus the events likelyrepresented genuine sIPSCs rather than random noise.

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FIG. 3. Spontaneous IPSCs (sIPSCs) recorded with Cs⁺ and QX-314 in patch electrode. A: sample records of about 1-min duration show currents from neuron in control, strychnine (Str, 1 µM), as well as strychnine and gabazine (Gbz, 10 µM) conditions. Strychnine decreased frequency of sIPSCs. Coapplication of Str and Gbz abolished the sIPSCs. B: frequency distribution of decay time constants from 7 neurons. Before strychnine application, the distribution was well described with sum of 3 Gaussian functions with mean time constants (arrowheads) of 11 ± 0.1, 22 ± 0.1, and 74 ± 2.4 ms. Strychnine abolished fast and slow sIPSCs, but not the sIPSCs, fitted with a single intermediate mean time constant (arrowhead) of 22 ± 0.2 ms. C: examples of unaveraged sIPSCs, scaled to the same amplitude, show fast, intermediate, and slow decay time courses. Smooth curves represent single exponential fits to the peak-aligned sIPSCs (indicated decay time constant, ${tau}$ ). Slow sIPSC that had a longer decay time constant than the average time constant of the slow sIPSC (cf. D) was selected for illustrative clarity. D: mean decay time constants for glycinergic sIPSCs did not differ from evoked IPSCs (P > 0.05, ANOVA). Numbers of neurons are indicated in parentheses. For sIPSCs, V_h = –60 mV and E_Cl = 0 mV.

Strychnine application (1 µM) decreased the frequencyof sIPSCs to 0.8 ± 0.3 Hz in all neurons (P < 0.05,paired t-test). Application of strychnine or gabazine occasionallyproduced outward changes in the holding current. The averagechange was 20 ± 15 pA for strychnine (n = 4) and 52 ±54 pA for gabazine (n = 4). The means did not significantlydiffer from zero (P > 0.05, Student's t-test). Coapplicationof strychnine and gabazine (10 µM) abolished the sIPSCs(Fig. 3A). The average amplitude of the sIPSCs decreased from–33 ± 0.5 to –26 ± 1.0 pA after theapplication of strychnine (P < 0.05, paired t-test). Theaverage rise time of the sIPSCs was 0.9 ± 0.02 ms beforeand 1.1 ± 0.05 ms after strychnine. This rise time wassignificantly shorter than the average for synaptically evokedIPSCs (P < 0.05, ANOVA). The longer rise times of evokedresponses possibly arose from temporal dispersion among developingpathways. Thus in contrast to medial lemniscal IPSCs the sIPSCswere not likely multiquantal events.

After we aligned the peaks and scaled the sIPSCs to the sameamplitude, three distinct time courses were evident in all neurons(cf. Fig. 3C). Fast sIPSCs completely decayed within 100 ms,whereas intermediate sIPSCs required 100 to 200 ms and slowsIPSCs required 500 to 1,000 ms for complete decay. The majorityof sIPSCs had a decay phase that was well fitted with a singleexponential function (Fig. 3C). A biexponential function wasrequired for an appropriate fit in <6% of sIPSCs. The meanamplitude of biexponential sIPSCs (–40 ± 1.9 pA)was slightly higher than the mean for monoexponential IPSCs(–32 ± 0.5 pA) IPSCs (P < 0.05, unpaired t-test).We observed a higher percentage of biexponential decays in IPSCsevoked by medial lemniscal stimulation (nearly 24%) of neuronsdisplaying mixed IPSCs than in sIPSCs (<6%). The reasonsfor the higher percentage are unclear. One possibility is thatelectrical stimulation coactivated different nerve fibers, producingmore biphasic responses.

Figure 3C illustrates the frequency distribution of decay timeconstants for the sIPSCs. Before strychnine application, thedistribution was well described with the sum of three Gaussianfunctions (P < 0.05, KS test). This fit implied three populationsof sIPSCs. Strychnine abolished the fastest and the slowestsIPSCs with average time constants of 11 ± 0.1 and 74± 2.4 ms, but not the GABA_Aergic sIPSCs with an averagetime constant of 22 ± 0.2 ms (Fig. 3B). Thus glycinergicsIPSCs had distinct fast and slow decay kinetics. The decaytime constants of glycinergic and GABA_Aergic sIPSCs matchedthe respective time constants of evoked IPSCs (Fig. 3D, P >0.05, ANOVA). Thus the three decay time constants of sIPSCslikely represent genuine findings and decay kinetics of synapticreceptors.

Kinetic properties of extrasynaptic receptors

Application of glycine, taurine, and $beta$ -alanine induced inward,single-channel currents in membrane patches (Fig. 4A). Beforeagonist application, the outside-out patches infrequently displayedspontaneous currents at –60 mV. Glycine (20 µM)activated currents in 11 of 27 patches. In separate experiments,taurine (20 µM) activated currents in 12 of 28 patches,and $beta$ -alanine (20 µM) activated currents in eight of 30patches. The means of P_o for activations by glycine (0.029 ±0.018, n = 11), taurine (0.029 ± 0.031, n = 10), and $beta$ -alanine (0.042 ± 0.013, n = 7) were not different (P> 0.05, ANOVA). P_o had a tendency to decline during agonistapplication and thus we did not test more than one agonist onindividual patches. When strychnine (1 µM) was coappliedwith glycine, taurine, or $beta$ -alanine, single-channel currentsoccurred very infrequently (overall P_o < 0.001). An observedreversal potential near E_Cl and sensitivity to strychnine implicatedglycine receptors in the agonist-evoked currents.

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FIG. 4. Glycine receptor agonists activate short- or long-duration bursts of channel openings. A: representative currents obtained from separate membrane patches. Channel openings appear as downward deflections from baseline (inward currents). Arrows indicate currents associated with a substate conductance. Inset under the long-duration bursts activated by $beta$ -alanine shows a segment of the main trace with higher amplification and time base. Current levels indicative of closed channel (c), substate conductance (s, arrow), and full open conductance (o) states are indicated by dashed lines. B: distribution of closed times (n = 2,742 events) for glycine-activated currents from an additional patch showing fit by the sum of 4 exponential terms, with areas and time constants (arrowheads): A₁ = 0.45, ${tau}$ ₁ = 0.2 ms; A₂ = 0.28, ${tau}$ ₂ = 8.1 ms; A₃ = 0.19, ${tau}$ ₃ = 19.8 ms; A₄ = 0.08, ${tau}$ ₄ = 173 ms. C: distributions of burst durations for taurine-activated currents in 2 additional patches showing short- and long-duration bursts. Each distribution was well fitted by the sum of 3 exponentials with A₁ = 0.03, ${tau}$ ₁ = 3.0 ms; A₂ = 0.88, ${tau}$ ₂ = 20.1 ms; A₃ = 0.09, ${tau}$ ₃ = 103 ms, ${tau}$ _c = 9.0 ms and mean duration = 26.7 ms for short-duration bursts (n = 552 bursts), and A₁ = 0.42, ${tau}$ ₁ = 15.7 ms; A₂ = 0.40, ${tau}$ ₂ = 84.7 ms; A₃ = 0.18, ${tau}$ ₃ = 730 ms; ${tau}$ _c = 5.7 ms and mean duration = 172 ms for long-duration bursts (n = 506 bursts). Arrowheads indicate time constants. D: mean durations of short- and long-duration bursts activated by glycine receptor agonists. Numbers in parentheses indicate patches. Mean durations of short-duration bursts activated by taurine and $beta$ -alanine were significantly different from long-duration bursts activated by the same agonist (* ${dagger}$ P < 0.05, ANOVA). Agonists were applied at 20 µM to outside-out patches. V_h = –60 mV, E_Cl = 0 mV.

To compare the burst durations of agonist-induced currents,we calculated the critical time, ${tau}$ _c, from channel closed timedistributions. The closed time distributions were well describedby the sum of four exponentials, as exemplified for glycinein Fig. 4B. The calculated values of ${tau}$ _c did not differ betweenchannels that displayed short- or long-duration bursts (P >0.05, ANOVA). The mean ${tau}$ _c for glycine (7.3 ± 0.8 ms, n= 11), taurine (8.3 ± 0.8 ms, n = 10), and $beta$ -alanine (8.9± 0.9 ms, n = 7) did not differ (P > 0.05, ANOVA).

The currents activated by the $beta$ -amino acids displayed eithershort- or long-duration bursts (Fig. 4A). Glycine activatedshort-duration bursts in 10 of 11 patches (Fig. 4A), and long-durationbursts in only one patch. Taurine-activated currents were characterizedby short-duration bursts of openings in six of ten patches andlong-duration bursts in the remaining four patches. $beta$ -Alanineactivated short-duration bursts in four of seven patches andlong-duration bursts in the remaining three patches.

As exemplified by taurine (Fig. 4C), burst-duration distributionswere well described by the sum of three exponentials. The meanburst duration for glycine-activated channels was 19 ±4 ms, whereas the sole long-duration burst averaged 87 ms. Thetaurine-activated short-duration bursts had a mean of 26 ±4 ms, whereas long-duration bursts averaged 88 ± 8 ms.The $beta$ -alanine–activated short-duration bursts had a meanof 21 ± 4 ms, whereas long-duration bursts averaged 137± 5 ms. The average lifetimes of short-duration burstsdid not depend on the nature of the agonist (cf. Fig. 4D). Theaverage lifetimes of long-duration bursts activated by taurineor $beta$ -alanine did not differ (P > 0.05, ANOVA). For the $beta$ -aminoacids, short and long bursts differed significantly from eachother in duration, and likely represented two populations (cf.Fig. 4D, P < 0.05, ANOVA).

Conductance of synaptic and extrasynaptic receptors

To estimate the Cl^– permeability of synaptic receptorchannels for comparison with the extrasynaptic channels, thefirst step was to determine the elementary current, i_Cl, duringsynaptic activation. The variance-to-mean current relationshipsfor both short- and long-duration glycinergic IPSCs were welldescribed by a quadratic function (Fig. 5A). From these fits,the mean i_Cl for short-duration IPSCs (–0.6 ± 0.2pA; n = 12) did not differ from the mean i_Cl for long-durationIPSCs (–0.8 ± 0.2 pA, n = 8; ANOVA, P > 0.05).These means were not significantly different from the mean i_Clfor GABA_Aergic IPSCs (–0.6 ± 0.1 pA, n = 18; P> 0.05, ANOVA).

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FIG. 5. Estimation of elementary channel currents from nonstationary noise analysis of glycinergic currents. A: 10 successive, short- and long-duration glycinergic IPSCs in 2 neurons, and 37 short-duration sIPSCs in one neuron. Current variance was plotted as a function of mean current for the neurons. Variance–mean relationships were fitted with ${sigma}$ _(t)² = i_Cl · I_mean(t) – I_mean(t)²/N + ${sigma}$ _th(t)² (dark curves). i_Cl was also obtained from the slopes of the initial part in the variance–average current relationships, fitted by linear regression. Two methods yielded similar values of i_Cl. Estimates were i_Cl = –0.9 pA for a short-duration–evoked IPSC (left), i_Cl = –0.5 pA for a long-duration–evoked IPSC (middle), and i_Cl = –3.3 pA for a short-duration sIPSC (right). When averaged, i_Cl did not differ for short and long IPSCs (n = 20; P > 0.05, ANOVA). Gray lines show 95% confidence intervals. For evoked IPSCs, V_h = –80 mV, E_Cl = –53 mV. For sIPSCs, V_h = –60 mV, E_Cl = 0 mV. B: I–V relationship for glycinergic and GABA_Aergic sIPSCs (3 neurons). E_Cl = 0 mV. C: comparison of P_Cl values estimated for short- and long-duration sIPSCs and evoked IPSCs. Numbers in parentheses indicate numbers of neurons. There were no differences between fast and slow responses, or between spontaneous and evoked responses (P > 0.05, ANOVA).

Estimates of i_Cl from multiquantal IPSCs can undergo distortionfrom fluctuations in transmitter release on a trial-to-trialbasis, as well as from other factors (cf. Diamond and Jahr 1995

).We sought to overcome this limitation by calculating i_Cl fromsIPSCs with E_Cl = 0 mV, which have a predominantly monoquantalnature (cf. Fig. 5A). For short-duration sIPSCs, we found amean i_Cl = –3.5 ± 0.6 pA (n = 6). For long-durationsIPSCs, the mean i_Cl was –2.8 ± 0.8 pA (n = 6).These values did not differ from each other or from the valueof –2.5 ± 0.5 pA (n = 7) obtained for GABA_AergicsIPSCs (P > 0.05, ANOVA). Current–voltage (I–V)relationships for the i_Cl values calculated from glycinergicand GABA_Aergic sIPSCs were linear and showed apparent reversalpotentials near E_Cl (Fig. 5B). The single-channel conductancesfor fast (58 ± 10 pS, n = 6) and slow (46 ± 14pS, n = 6) glycinergic sIPSCs did not differ from each otheror from the conductance (41 ± 9 pS, n = 7) from GABA_AergicsIPSCs (P > 0.05, ANOVA).

For comparison of i_Cl values obtained from IPSCs and sIPSCsunder differing holding potentials and E_Cl values, we used theGHK equation to convert the values to chloride permeability,P_Cl. Mean P_Cl for short-duration glycinergic IPSCs was 1.6 ±0.5 x 10^–13 cm³/s for evoked (n = 12) and 1.1 ±0.2 x 10^–13 cm³/s for spontaneous (n = 6) responses. MeanP_Cl for long-duration glycinergic IPSCs was 1.7 ± 0.4x 10^–13 cm³/s for evoked (n = 8) and 0.9 ± 0.3x 10^–13 cm³/s for spontaneous (n = 6) responses. As shownin Fig. 5C, P_Cl values from evoked and spontaneous IPSCs werenot different (P > 0.05, unpaired t-test). The glycinergicP_Cl values did not differ from evoked (1.5 ± 0.3 x 10^–13cm³/s, n = 18) and spontaneous (0.8 ± 0.2 x 10^–13cm³/s, n = 7) GABA_Aergic P_Cl values (P > 0.05, ANOVA).

All three agonists evoked extrasynaptic currents of small andlarge amplitude (Figs. 4A and 6, A and B). Smaller currentswere seen only in the presence of larger-amplitude currents.Thus the small currents likely reflected openings to a substateconductance, nearly 70% of the full conductance. Amplitude distributionsfor the currents were well described by the sum of two Gaussianterms (Fig. 6A). The I–V relationships were linear overthe range of 0 to –60 mV (Fig. 6B). From these relationships,the mean conductances from short-duration bursts were 15 ±1 pS (n = 10), 21 ± 2 pS (n = 6), and 22 ± 3 pS(n = 4) for glycine, taurine, and $beta$ -alanine, respectively. Themean conductances from long-duration bursts were 19 pS (n =1), 33 ± 1 pS (n = 4), and 30 ± 4 pS (n = 3) forglycine, taurine, and $beta$ -alanine, respectively. These conductanceswere not different (P > 0.05, ANOVA).

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FIG. 6. Conductance of single channels activated by glycine receptor agonists. A: amplitude distributions for agonist-activated currents (V_h = –60 mV) were fitted by the sum of 2 Gaussian terms (smooth curves). Means (arrowheads) were –1.2 and –0.96 pA for glycine (n = 1,473 transitions), –1.6 and –1.2 pA for taurine (n = 2,465 transitions), and –1.7 and –1.3 pA for $beta$ -alanine (n = 1,144 transitions). B: single-channel I–V relationships for the full and substate conductances of glycine-activated receptor channels. Data were obtained from 12 patches. Linear regression fits indicated mean values of 13 and 17 pS for the substate and full conductances, respectively. In all panels, agonists were applied at 20 µM to outside-out patches with E_Cl = 0 mV. C: comparison of P_Cl values for short- and long-duration channel bursts, activated by glycine receptor agonists. Numbers in parentheses indicate number of patches. There were no significant differences in values obtained (P > 0.05, ANOVA).

P_Cl of synaptic and extrasynaptic receptors

For comparison, we converted extrasynaptic single-channel currentsto P_Cl values. In view of the similar values of P_Cl from evokedand spontaneous IPSCs, as well as the similar extrasynapticP_Cl values for the agonists, we pooled the data into synapticand extrasynaptic categories. Table 1 shows the distinct natureof P_Cl values of synaptic and extrasynaptic channels. The short-and long-duration, glycinergic synaptic channels yielded valuesof P_Cl that were higher than the estimates from short- and long-durationbursts activated by the agonists (P < 0.05, unpaired t-test).The GABA_Aergic synaptic channels yielded P_Cl values that werehigher than the estimates from extrasynaptic channels (P <0.05, unpaired t-test) for currents obtained from Kim et al.(2004).

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TABLE 1. Chloride permeability of synaptic and extrasynaptic glycine and GABA_A receptors

We tested the possibility that voltage-dependent currents contributedto a higher estimate of P_Cl, by blocking voltage-dependent currentswith Ni²⁺, QX-314, and Cs⁺ in seven neurons. sIPSCs were observedonly infrequently during extracellular Ni²⁺ application in allneurons. No glycinergic IPSCs were observed in these neurons,possibly because of pre- and postsynaptic blocking actions ofNi²⁺ (e.g., postsynaptic; Doi et al. 1999

). The average P_Clof GABA_Aergic IPSCs was 1.7 ± 0.8 x 10^–13 cm³/sand did not differ from P_Cl in the absence of Ni²⁺, QX-314,and Cs⁺ (t-test, P > 0.05).

DISCUSSION

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INTRODUCTION
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These studies have revealed some unusual facets of inhibitorytransmission in thalamus. Spontaneous IPSCs mediated by glycine-and GABA_A receptors were monophasic, showing fast, intermediate,and slow decays. IPSCs evoked by medial lemniscal stimulationalso showed fast, intermediate, or slow decays, alone or incombination. Biphasic IPSCs with an intermediate decay componentlikely resulted from cotransmission by a GABA_A-receptor–mediatedpathway. Strychnine antagonized the fast and slow synaptic currents,mediated by glycinelike amino acids. Extrasynaptic receptors,activated by glycine agonists in membrane patches, displayedthe predicted short- or long-duration burst openings (cf. INTRODUCTION).The dual kinetics of synaptic and single-channel currents implicatefunctional diversity in glycine receptors at a juvenile stageof rat development.

The chief finding of these studies was glycinergic sIPSCs andcomponents of mixed IPSCs, decaying with fast or slow kinetics.Most sIPSCs (>94%) exhibited monoexponential decays withfast (11 ms) or slow (74 ms) time constants. The fast and slowtime constants of sIPSCs, which largely represented monoquantalpackets of transmitter, matched the fast (12-ms) and slow (80-ms)time constants of evoked IPSCs. This finding provided assurancethat spontaneous and evoked IPSCs were attributable to the sameglycine-receptor populations. The observations were consistentwith the activation of two kinetically distinct populationsof glycine receptors. Another important finding was that fastor slow synaptic currents occurred separately in different neurons.These IPSCs also decayed in a monoexponential manner, suggestingthat the slow IPSCs were not likely attributable to a spilloverof transmitter to perisynaptic receptors (see Chery and De Koninck1999). Based on the observations on spontaneous and evoked IPSCs,we suggest that the receptor populations are predominantly localizedunder separate nerve terminals.

Our observations of fast and slow monoquantal sIPSCs contrastwith the literature. In embryonic zebrafish (Ali et al. 2000),sIPSCs have biexponential decay arising from co-localizationof receptors with fast and slow kinetics at the same synapticsites. Spontaneous IPSCs decay monoexponentially with a fast(4 to 8 ms) time constant in rat spinal neurons (Chery and DeKoninck 1999; Gonzáles-Forero and Alvarez 2005) and witha slow (about 63 ms) time constant in mouse retinal ganglioncells (Tian et al. 1998). Apparently, thalamic neurons in juvenilerats have a predominant ability to segregate two populationsof glycine receptors with fast and slow kinetics.

The fast and slow kinetics of the synaptic currents are likelyexplained by structurally distinct receptor populations. The ${alpha}$ ₁ and ${alpha}$ ₂ receptor subunits (Ghavanini et al. 2005) determinesynaptic decays of fast and slow IPSCs (Singer and Berger 1999;Takahashi et al. 1992). Given their very long burst duration,receptors containing ${alpha}$ ₂, but not ${alpha}$ ₁, subunits (Mangin et al. 2003),may account for the long decay tails of two atypical IPSCs inthis study. Coassembly of ${alpha}$ ₁ and ${alpha}$ ₂ subunits likely occurs indeveloping neurons, where slow IPSCs are common (Ali et al.2000; Takahashi et al. 1992). Thus persistence of ${alpha}$ ₁/ ${alpha}$ ₂ receptorsin thalamic neurons may have resulted in the slow kinetics.Slow glycinergic inhibition contrasts with metabotropic GABAergicinhibition (Browne et al. 2001), mostly suppressed in our recordings.Another possibility is that posttranslational phosphorylationof glycine receptor channels (Agopyan et al. 1993) produceddiverse kinetics.

The kinetics of extrasynaptic glycine receptor channels resembledthe decays of glycinergic currents. The average lifetimes ofshort- and long-duration bursts activated by glycine, taurine,and $beta$ -alanine were close to decay time constants for fast andslow IPSCs. The multiple congruencies in kinetics seem unlikelyto have occurred by chance, although burst duration may dependon high agonist concentrations (cf. Beato et al. 2002) at glycinergicsynapses.

There are reasons for postulating differences between synapticand extrasynaptic glycine receptors. We observed that synapticchannels had higher P_Cl values than those of extrasynaptic channels.The P_Cl estimates were similar when measured with an optimizedspace clamp and were not likely the result of vagaries in fluctuationanalysis (cf. Benke et al. 2001). The unitary conductance obtainedfrom sIPSCs was in the same range as that in other preparationsunder similar conditions (cf. Poncer et al. 1996; Singer andBerger 1999). The synaptic GABA_Aergic channels had a higherconductance than that of extrasynaptic channels, as found elsewhere(Yeung et al. 2003). The low conductances of extrasynaptic glycinereceptors were compatible with embryonic receptor channels (Rajendraet al. 1997) and extrasynaptic receptors on hippocampal neurons(Fatima-Shad and Barry 1995). Given these considerations, wesuggest that the conductance differences were genuine. Extrasynapticreceptors, usually considered as high conductance homomers (Lynch2004), in this case may have reduced conductance, reflectingposttranslational modification (cf. Caraiscos et al. 2002).

The present results are compatible with cotransmission by glycinergicand GABA_Aergic pathways, rather than corelease of glycinelikeamino acids and GABA. An appreciable number of neurons showedexclusively glycinergic or GABAergic responses to medial lemniscalstimulation, consistent with cotransmission by independent pathways.If corelease of glycinelike amino acids and GABA were to occur(Jonas et al. 1998), we would expect a prevalence of multiphasicsIPSCs in each neuron, converting on strychnine applicationto monophasic GABA_Aergic currents (see Dumoulin et al. 2001).In contrast, the majority of sIPSCs in seven tested neuronsshowed a monophasic decay, with or without strychnine application.We conclude that if present in thalamic inhibition, coreleasewas a less common occurrence than cotransmission.

Physiological implications

Fast synaptic kinetics allow rapid phasic transfer of informationfor somatotopic representations of rapidly adapting receptors(cf. Tsumoto and Nakamura 1974). Slow IPSP decays affect hyperpolarization-activatedcurrents, remove Ca²⁺ channel inactivation, and promote low-thresholdCa²⁺ bursting (cf. Steriade et al. 1997). The glycinergic IPSCcomponents were kinetically distinct from GABA_Aergic IPSCs (about22 ms; cf. Dumoulin et al. 2001). The cooccurrence of fast andslow glycinergic IPSPs with intermediate GABA_Aergic IPSPs wouldconfer fine-tuning of inhibitory transmission by modulationof voltage-dependent currents in somatosensory thalamus. Thehigher P_Cl of synaptic receptors ensures high transmission efficacy.

Despite the differences in P_Cl, the striking similarities betweenIPSC decay and extrasynaptic channel burst duration imply thatglycine, taurine, and $beta$ -alanine each could mediate inhibition.When applied at the same concentration, glycine, taurine, and $beta$ -alanine activated channels with comparable open probabilities.The abilities of $beta$ -amino acids, relative to glycine, to activatelong-duration bursts was greater at extrasynaptic receptorsthan most receptor variants (cf. Flint et al. 1998; Martin andSiggins 2002). The lower Cl^– permeability may suit extrasynapticreceptors for the detection of ambient $beta$ -amino acids, tonic inhibition,and receptor modulation (cf. Berger et al. 1998; Flint et al.1998; Mori et al. 2002).

Thalamocortical neurons segregate ionotropic glycine receptorsshowing fast and slow decay kinetics. Cotransmission with GABA_Areceptors showing intermediate kinetics, and known metabotropicGABA_B receptors, facilitate postsynaptic discrimination of inputsin neurons of somatosensory nuclei.

GRANTS

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ACKNOWLEDGMENTS
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This work was supported by grants from the Canadian Institutesfor Health Research to E. Puil and D. A. Mathers and the JeanTempleton Hugill Foundation Chair to E. Puil. A. A. Ghavaninireceived a University Graduate Fellowship through the Universityof British Columbia Neurosciences Program.

ACKNOWLEDGMENTS

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We thank V. Dobrovinska and C. Caritey for technical assistance.

Present address of H.-S. Kim: Department of Anesthesiology,College of Medicine, Seoul National University, Seoul, Korea.

FOOTNOTES

The costs of publication of this article were defrayed in partby the payment of page charges. The article must therefore behereby marked "advertisement" in accordance with 18 U.S.C. Section1734 solely to indicate this fact.

Address for reprint requests and other correspondence: D. Mathers, 2146 Health Sciences Mall, Vancouver BC V6T 1Z3, Canada (E-mail: mathers{at}interchange.ubc.ca)

REFERENCES

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Agopyan N, Tokutomi N, and Akaike N. Protein kinase A-mediated phosphorylation reduces only the fast desensitizing glycine current in acutely dissociated ventromedial hypothalamic neurons. J Neurosci Methods 56: 605–615, 1993.

Ali DW, Drapeau P, and Legendre P. Development of spontaneous glycinergic currents in the Mauthner neuron of the zebrafish embryo. J Neurophysiol 84: 1726–1736, 2000.[Abstract/Free Full Text]

Beato M, Groot-Kormelink PJ, Colquhoun D, and Sivilotti LG. Openings of the rat recombinant ${alpha}$ 1 homomeric glycine receptor as a function of the number of agonist molecules bound. J Gen Physiol 119: 443–466, 2002.[Abstract/Free Full Text]

Benke TA, Lüthi A, Palmer MJ, Wikström MA, Anderson WW, Isaac JTR, and Collingridge GL. Mathematical modelling of non-stationary fluctuation analysis for studying channel properties of synaptic AMPA receptors. J Physiol 537: 407–420, 2001.[Abstract/Free Full Text]

Berger AJ, Dieudonné S, and Ascher P. Glycine uptake governs glycine site occupancy at NMDA receptors of excitatory synapses. J Neurophysiol 80: 3336–3340, 1998.[Abstract/Free Full Text]

Bormann J, Hamill OP, and Sakmann B. Mechanism of anion permeation through channels gated by glycine and ${gamma}$ -aminobutyric acid in mouse cultured spinal neurons. J Physiol 385: 243–286, 1987.[Abstract/Free Full Text]

Browne SH, Kang J, Akk G, Chiang LW, Schulman H, Huguenard JR, and Prince DA. Kinetic and pharmacological properties of GABA_A receptors in single thalamic neurons and GABA_A subunit expression. J Neurophysiol 86: 2312–2322, 2001.[Abstract/Free Full Text]

Caraiscos VB, Mihic SJ, MacDonald JF, and Orser BA. Tyrosine kinases enhance the function of glycine receptors in rat hippocampal neurons and human ${alpha}$ ₁ receptors. J Physiol 539: 495–502, 2002.[Abstract/Free Full Text]

Chery N and De Koninck Y. Junctional versus extrajunctional glycine and GABA_A receptor-mediated IPSCs in identified lamina I neurons of the adult rat spinal cord. Neuroscience 19: 7342–7355, 1999.[Medline]

Colquhoun D and Sakmann B. Fast events in single-channel currents activated by acetylcholine and its analogues at the frog muscle end-plate. J Physiol 369: 501–557, 1985.[Abstract/Free Full Text]

De Koninck Y and Mody I. Noise analysis of miniature IPSCs in adult rat brain slices: properties and modulation of synaptic GABA_A receptor channels. J Neurophysiol 71: 1318–1335, 1994.[Abstract/Free Full Text]

Diamond JS and Jahr CE. Asynchronous release of synaptic vesicles determines the time course of the AMPA receptor-mediated EPSC. Neuron 15: 1097–1107, 1995.[CrossRef][ISI][Medline]

Doi A, Kishimoto K, and Ishibashi H. Modulation of glycine-induced currents by zinc and other metal cations in neurons acutely dissociated from the dorsal motor nucleus of the vagus of the rat. Brain Res 816: 424–430, 1999.[CrossRef][ISI][Medline]

Donato R and Nistri A. Relative contribution by GABA or glycine to Cl^–-mediated synaptic transmission on rat hypoglossal motoneurons in vitro. J Neurophysiol 84: 2715–2724, 2000.[Abstract/Free Full Text]

Dumoulin A, Triller A, and Dieudonné S. IPSC kinetics at identified GABAergic and mixed GABAergic and glycinergic synapses onto cerebellar Golgi cells. Neuroscience 21: 6045–6057, 2001.[Medline]

Fatima-Shad K and Barry PH. Heterogenous current responses to GABA and glycine are present in post-natally cultured hippocampal neurons. Brain Res 704: 246–255, 1995.[CrossRef][ISI][Medline]

Fatima-Shad K and Barry PH. Morphological and electrical characteristics of postnatal hippocampal neurons in culture: the presence of bicuculline- and strychnine-sensitive IPSPs. Tissue Cell 30: 236–250, 1998.[CrossRef][ISI][Medline]

Flint AC, Liu X, and Kriegstein AR. Nonsynaptic glycine receptor activation during early neocortical development. Neuron 20: 43–53, 1998.[CrossRef][ISI][Medline]

Ghavanini A, Mathers DA, and Puil E. Glycinergic inhibition in thalamus revealed by synaptic receptor blockade. Neuropharmacology 49: 338–349, 2005.[CrossRef][ISI][Medline]

Gonzalez-Forero D and Alvarez FJ. Differential postnatal maturation of GABA_A, glycine receptor, and mixed synaptic currents in Renshaw cells and ventral spinal interneurons. Neuroscience 25: 2010–2023, 2005.[Medline]

Jonas P, Bischofberger J, and Sandkuhler J. Corelease of two fast neurotransmitters at a central synapse. Science 281: 419–424, 1998.[Abstract/Free Full Text]

Kim HS, Wan X, Mathers DA, and Puil E. Selective GABA-receptor actions of amobarbital on thalamic neurons. Br J Pharmacol 143: 485–494, 2004.[CrossRef][ISI]

Lynch JW. Molecular structure and function of the glycine receptor chloride channel. Physiol Rev 84: 1051–1095, 2004.[Abstract/Free Full Text]

Mangin JM, Baloul M, De Carvahlo P, Rogister B, Rigo JM, and Legendre P. Kinetic properties of the ${alpha}$ ₂ homo-oligomeric glycine receptor impairs a proper synaptic functioning. J Physiol 553: 369–386, 2003.[Abstract/Free Full Text]

Martin G and Siggins GR. Electrophysiological evidence for expression of glycine receptors in freshly isolated neurons from nucleus accumbens. J Pharmacol Exp Ther 302: 1135–1145, 2002.[Abstract/Free Full Text]

Mori M, Gähwiler BH, and Gerber U. $beta$ -Alanine and taurine as endogenous agonists at glycine receptors in rat hippocampus in vitro. J Physiol 539: 191–200, 2002.[Abstract/Free Full Text]

Paxinos G and Watson C. The Rat Brain in Stereotaxic Coordinates. North Ryde, Australia: Academic Press, 1986.

Poncer JC, Durr R, Gähwiler BH, and Thompson SM. Modulation of synaptic GABA_A receptor function by benzodiazepines in area CA3 of rat hippocampal slice cultures. Neuropharmacology 35: 1169–1179, 1996.[CrossRef][ISI][Medline]

Rajendra S, Lynch JW, and Schofield PR. The glycine receptor. Pharmacol Ther 73: 121–146, 1997.[CrossRef][ISI][Medline]

Scheuss V and Neher E. Estimating synaptic parameters from mean, variance, and covariance in trains of synaptic responses. Biophys J 81: 1970–1989, 2001.[Abstract/Free Full Text]

Singer JH and Berger AJ. Contribution of single-channel properties to the time course and amplitude variance of quantal glycine currents recorded in rat motoneurons. J Neurophysiol 81: 1608–1616, 1999.[Abstract/Free Full Text]

Singer JH, Talley EM, Bayliss DA, and Berger AJ. Development of glycinergic synaptic transmission to rat brain stem motoneurons. J Neurophysiol 80: 2608–2620, 1998.[Abstract/Free Full Text]

Steriade M, Jones EG, and McCormick DA. Neurotransmitter actions in the thalamus. In: Thalamus, edited by Steriade M, Jones EG, and McCormick DA. Amsterdam: Elsevier, 1997.

Takahashi T, Momiyama A, Hirai K, Hishinuma F, and Akagi H. Functional correlation of fetal and adult forms of glycine receptors with developmental changes in inhibitory synaptic receptor channels. Neuron 9: 1155–1161, 1992.[CrossRef][ISI][Medline]

Tian N, Hwang TN, and Copenhagen DR. Analysis of excitatory and inhibitory spontaneous synaptic activity in mouse retinal ganglion cells. J Neurophysiol 80: 1327–1340, 1998.[Abstract/Free Full Text]

Traynelis SF, Silver RA, and Cull-Candy SG. Estimated conductance of glutamate receptor channels activated during EPSCs at the cerebellar mossy fiber-granule cell synapse. Neuron 11: 279–289, 1993.[CrossRef][ISI][Medline]

Tsumoto T and Nakamura S. Inhibitory organization of the thalamic ventrobasal neurons with different peripheral representations. Exp Brain Res 21: 195–210, 1974.[ISI][Medline]

Twyman RE and Macdonald RL. Kinetic properties of the glycine receptor main and sub-conductance states of mouse spinal cord neurons in culture. J Physiol 435: 303–331, 1991.[Abstract/Free Full Text]

Yeung JYT, Canning KJ, Zhu G, Pennefather P, MacDonald JF, and Orser BA. Tonically activated GABA_A receptors in hippocampal neurons are high-affinity, low-conductance sensors for extracellular GABA. Mol Pharmacol 63: 2–8, 2003.[Abstract/Free Full Text]

Zeilhofer HU, Studler B, Arabadzisz D, Schweizer C, Ahmadi S, Layh B, Bösl MR, and Fritschy J-M. Glycinergic neurons expressing enhanced green fluorescent protein in bacterial artificial chromosome transgenic mice. J Comp Neurol 482: 123–141, 2005.[CrossRef][ISI][Medline]

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