Synaptically Evoked GABA Transporter Currents in Neocortical Glia

doi:10.1152/jn.00037.2002

Synaptically Evoked GABA Transporter Currents in Neocortical Glia

Gregory A. Kinney¹^,²^,⁴ and William J. Spain¹^,³^,⁴

¹Veterans Affairs Puget Sound Health Care System, Seattle, 98108; and Departments of ²Rehabilitation Medicine, ³Neurology, and ⁴Physiology and Biophysics, University of Washington School of Medicine, Seattle, Washington 98195

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Kinney, Gregory A. and William J. Spain. Synaptically Evoked GABA Transporter Currents in Neocortical Glia. J. Neurophysiol. 88: 2899-2908, 2002. The presence, magnitude, and time course of GABA transporter currents were investigated in electrophysiologically characterizedneocortical astrocytes in an in vitro slice preparation. On stimulationwith a bipolar-tungsten stimulating electrode placed nearby, themajority of cells tested displayed long-lasting GABA transportercurrents using both single and repetitive stimulation protocols.Using subtype-specific GABA transporter antagonists, long-lastingGABA transporter currents were identified in neocortical astrocytesthat originated from at least two subtypes of GABA transporters:GAT-1 and GAT-2/3. These transporter currents displayed slow risetimes and long decay times, contrasting the time course observedfor glutamate transporter currents, and are indicative of a longextracellular time course of GABA as well as a role for glialGABA transporters during synaptictransmission.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

It has been well established that glial transporters play a role in the determination of the time course of a synaptic responsefollowing evoked release. Block of transporter action has beenshown to increase the duration of synaptically evoked responsesin numerous systems, presumably by increasing the duration ofthe neurotransmitter transient (Barbour et al. 1994; Isaacsonet al. 1993; Mager et al. 1993; Mennerick et al. 1999; Otis etal. 1996; Overstreet et al. 1999; Thompson and Gähwiler 1992).In addition to the role transporters play in the regulation ofsynaptic events at the nerve terminal, they may be important inregulating "spillover" of transmitter from neighboring nerve terminalsat certain synapses within the brain (Barbour et al. 1994; Isaacsonet al. 1993; Rossi and Hanaman 1998). Thus neurotransmitter transportersmay be critically important in the determination of the time courseof synaptic responses, the termination of the actions of transmitterfollowing release, and the regulation of excitability and excitotoxicitythroughout thebrain.

Numerous investigations into the function of glutamate transporters during synaptic transmission have been undertaken in recentyears (Bergles and Jahr 1997, 1998; Diamond and Jahr 1997; Mennericket al. 1999; Otis et al. 1997; Overstreet et al. 1999) and haveresulted in a wealth of information regarding the function ofthese transporters during synaptic events. However, at present,much less is known about the function of GABA transport duringsynaptic transmission. It has been demonstrated that in the hippocampus,pharmacological block of GABA transport results in a notable increasein the time course of the GABA_A receptor-mediated response (Dingledineand Korn 1985; Draguhn and Heinemann 1996; Isaacson et al. 1993;Roepstorff and Lambert 1992, 1994; Thompson and Gähwiler 1992).However, it is unclear whether these transporters have a neuronalor glial localization. In addition, it is not known whether theGABA transporter actively removes GABA during a synaptic eventor serves as a buffer as has been suggested for the glutamatetransporter (Diamond and Jahr 1997; Tong and Jahr 1994; but seeMennerick et al. 1999). In the cortex, glial uptake of GABA mayserve to primarily regulate paracrine levels of GABA rather thanparticipate in uptake of GABA during a synaptic event (Conti etal. 1998; Ribak et al. 1996; Spreafico et al. 1993), althoughthere is some evidence that glial GABA transporters in the cortex(Minelli et al. 1996) and elsewhere in the brain (De Biasi etal. 1998) are located at sites very close torelease.

Currently, there are three cloned GABA transporters in the rat CNS: GAT1, GAT2, and GAT3 (Borden et al. 1992; Clark et al.1992; Guastella et al. 1990; for review, see Borden 1996). GAT-1expression within the cortex has been shown to be high and islocalized to puncta and fibers and astrocytic processes as wellas a few pyramidal cells; its expression has been shown to havea high correlation with the soma and proximal dendrites of unlabeledpyramidal cells, indicative of localization at inhibitory synapses(Conti et al. 1998; DeFelipe and González-Albo 1998; Durkin etal. 1995; Minelli et al. 1995). GAT-3 has been shown to be expressedprimarily in glia (Clark et al. 1992; Durkin et al. 1995; Minelliet al. 1996; Yan and Ribak 1999); its expression in the cortexhas been shown to be low in the adult (Minelli et al. 1996; Yanand Ribak 1999) and may be developmentally regulated (Jursky andNelson 1999). GAT-2 expression is localized predominantly to theleptomeninges (Durkin et al. 1995), with some expression in corticalneurons and astrocytes (Conti et al. 1999).

Information regarding the concentration time course of GABA following release is of considerable interest. The time courseof evoked GABA_A receptor-mediated responses in the hippocampushas been shown to be regulated by transporters; this is indicativeof an extended presence of GABA in the synaptic cleft followingrelease. In addition, GABA is reported to diffuse, or "spill over"to neighboring terminals at sufficient concentration followingevoked release to activate receptors at these synapses, indicatingthat GABA has a relatively long extrasynaptic concentration timecourse. Finally, it is believed that GABA may remain bound toGABA_A receptors for an extended period of time following release,(Jones and Westbrook 1995), which may contribute to a relativelylong extracellular concentration time course. The recording ofGABA transporter currents from astrocytes during synaptic transmissioncould provide direct evidence of the time course of GABA followingrelease as well as insight into the functional role of GABA uptakeby neocorticalastrocytes.

Here we report that electrophysiologically characterized neocortical astrocytes [co-] express at least two types of GABA transporters,GAT-1 and GAT-2/3, as well as glutamate transporters. Currentsmediated by the GABA transporters are slow rising and long-lasting,contrasting what is observed for glutamate transporter currents,and are active during both single and repetitivestimulation.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Preparation of brain slices

Experiments were performed on neocortical slices (300 µM) obtained from rats aged 7-28 days postnatal. Animals were anesthetizedwith a mixture of 1:3 xylazine/ketamine dissolved in an equalvolume of saline by intraperitoneal injection (1.8. ml/kg). Asection of the cortex was then rapidly removed by dissection andglued to the stage of a vibrating tissue chopper (Vibratome).The tissue was immediately immersed in ice-cold cutting solutioncomposed of (in mM) 5 KCl, 1.25 KH₂PO4, 26 NaHCO₃, 5 MgCl₂, 20TEA-Cl, 105 choline-Cl, 20 sucrose, and 10 dextrose (320 mosM).Coronal sections of 300 µm thickness were cut and transferredto a holding chamber filled with artificial cerebrospinal fluid(ACSF) and kept at 35°C for 1 h The ACSF was composed of (in mM)130 NaCl, 3 KCl, 2 CaCl₂, 1.25 NaH₂PO₄, 26 NaHCO₃, 2 MgCl₂, and10 dextrose, kept at pH = 7.3-7.4 by bubbling with carbogen (5%CO₂-95% O₂). After this initial period, the slices were storedat roomtemperature.

For recording, one slice was transferred to a submersion chamber mounted on a fixed stage under the objective of a moveablemicroscope. The slice was then submerged and perfused continuouslywith carbogenated ACSF (32-34°C) flowing at a rate of 2-3 ml/min.Initially, the slice was viewed at ×10 with DIC optics to allowfor gross placement of stimulating and recording electrodes. Individualastrocytes in layers 2/3 and 5 were then visualized at high powerusing a ×63 long-distance water-immersion lens coupled with a×0.5-2zoom.

Whole cell recording and stimulation

Patch pipettes are pulled on a Flaming-Brown Horizontal puller using a multi-stage pull, to resistances of 2-5 M $Omega$ . The standardpatch pipette solution is composed of (in mM) 135 KCH₃SO₄, 2 MgCl₂,5 KCl, 10 HEPES, 2 Na₂ATP, 0.5 Na-GTP, and 0.1 EGTA (pH = 7.2-7.3with KOH; osM = 295). For some initial experiments (n = 16), CsClwas substituted for KCH₃SO₄ in an effort to decrease membraneconductance. Experiments done in CsCl had an average input resistance25.58 ± 1.62 M $Omega$ and an average resting membrane potential of $-$ 88.27± 2.89 mV. This was a modest increase in input resistance (17.22± 0.64 M $Omega$ ; see RESULTS). However, CsCl was not utilized for experimentsincluded in this study due to concerns for the long equilibrationtimes necessary as a consequence of cell coupling. For experimentsusing biocytin or Lucifer yellow, a fixed amount of the requiredcompound was simply added to the above mixture to give a concentrationof 0.025% wt/vol. The liquid junction potential is measured withrespect to ACSF, and all membrane potential recordings are correctedaccordingly ( $-$ 10mV).

Standard techniques were used to obtain whole cell recordings. Briefly, the electrodes were visually guided onto glial cellbodies while applying gentle positive pressure to the back ofthe pipette to prevent clogging. On contact with the cell, negativepressure is applied until a tight seal (>1 G $Omega$ ) is formed. Furthernegative pressure was applied until the underlying membrane isruptured and whole cell configuration is established. Voltage-clampwas obtained through the use of an Axopatch 200A amplifier (AxonInstruments). Whole cell current (low-pass filtered at 2-5 kHz;8-pole Bessel filter) and membrane potential were amplified andrecorded on a videocassette recorder with pulse-code modulation(sampling rate: 20 kHz) for later analysis. In all experiments,membrane voltage and current traces were also digitized on-lineby data-acquisition software (pCLAMP; Axon Instruments) and storedin computermemory.

Synaptic inputs to glial cells (and nearby neurons) were stimulated using a bipolar tungsten-stimulating electrode placedin the slice in the vicinity of the target cell (50-200 µm). Singlestimuli were evoked using intensities of between 20 and 200 µAat a duration of 100 µs. Repetitive stimuli were evoked usingthe same parameters at a frequency of 100 Hz. All experimentswere done at the cell resting membranepotential.

Identification/characterization of cells

Experimental cells were identified by visual inspection under a ×63 water-immersion lens coupled with a ×0.5-2 zoom (Fig.1A), electrophysiological characterization of membrane properties,and labeling with Lucifer yellow or Alexa 594 in a number of cellsand confirming ultrastructure post hoc. Neocortical astrocytesare known to be relatively small cells, with cell bodies in therange of 6-15 µm. This size criterion was the basis for the initialselection of an experimental cell; identity was also establishedelectrophysiologically: astrocytes are characterized by theirhigh negative resting membrane potentials (RMPs), low input resistances,and passive, linear current-voltage relationships (e.g., Berglesand Jahr 1997; Chvatal et al. 1995; D'Ambrosio et al. 1998; Schwartzkroinand Prince 1979; but see Bordey and Sontheimer 1998). Based onthese electrophysiological criteria, we characterize the cellsin this study as neocortical astrocytes.

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Fig. 1. Cellular properties of neocortical astrocytes. A: photograph of a typical neocortical astrocyte recorded from in this study with recording electrode attached. Cells recorded from usually had a slightly irregular circular appearance with a few processes visible with infrared DIC optics. B: current responses to 10-mV voltage steps in a typical astrocyte. C: current-voltage relationship for the cell in B. D: plot of resting membrane potential vs. age for astrocytes recorded from in this study. Astrocytes showed a pronounced, significant dependence of resting membrane potential on age (data fitted with a linear regression; slope is significantly nonzero).

In $approx$ 40 cells, Lucifer yellow or Alexa 594 was included in the pipette, and cells were examined following recording (via anepifluorescence attachment to the microscope) to confirm astrocyteidentity via cell morphology. Under epifluorescent illumination,individual cells displayed multiple processes branching from thesoma, characteristic of astrocytes (Kosaka and Hama 1986).

In five slices in which we recorded a GAT transport current using a biocytin containing electrode, we saw dye coupling of>50 cells with astrocytic morphology similar to what was has previouslybeen reported for the CA1 region of hippocampus (D'Ambrosio etal. 1998). Slices were processed with a standard DAB reaction(Horikawa and Armstrong 1988).

Application of drugs

Drugs were dissolved in distilled water and applied by bath perfusion with the exception of direct application of GABA, whichwas applied using focal ejection from a glass micropipette usinga picospritzer (General Valve). All chemicals and drugs were obtainedfrom Sigma Chemical with the exception of (2S)-3-[[(1S)-1-(3,4-Dichlorophenyl)ethyl]amino-2-hydroxypropyl](phenylmethyl)phosphinicacid (CGP-55845) (gift of Ciba Giegy), 1-[2-[[(Diphenylmethylene)imino]oxy]ethyl]-1,2,5,6-tetrahydro-3-pyridinecarboxylicacid hydrochloride (NO-711) (RBI), L-trans-Pyrrolidine-2,4-dicarboxylicacid (L-trans-PDC) and 1-(4,4-Diphenyl-3-butenyl)-3-piperidinecarboxylicacid hydrochloride (SKF-89976A) (Tocris Cookson), and Alexa 594and Lucifer yellow (MolecularProbes).

Methods of analysis

Anatomical characterization of astrocytes: for the purpose of anatomical characterization and confirmation of cell identity,a group of recordings was made with the inclusion of Lucifer yellowor Alexa 594 in the intracellular recording media. Cell identitywas confirmed following the experiment using a UV source attachedto themicroscope.

Statistical analysis: for unpaired t-tests, P < 0.05 values were taken as a significant difference. Data are expressed inmeans ± SE. Cells that did not respond to experimental manipulationwere excluded fromanalysis.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Cellular properties of neocortical astrocytes

Recordings were made from 210 neocortical glial cells, in layer 5 as well as layer 2/3, using whole cell voltage-clamp protocols.Approximately 85% of recorded cells had RMPs in the range of $-$ 80to $-$ 95 mV ( $-$ 90.4 ± 0.31 mV; Fig. 1D; estimated EK $congruent$ $-$ 100 mV),a linear I-V relationship (Fig. 1, B and C) and low input resistances(17.22 ± 0.64). In a minority of cells (~15%), much higher inputresistances (162.0 ± 28.4 M $Omega$ ), outward rectification on depolarization,and more hyperpolarized average RMPs ( $-$ 93.8 ± 0.70 mV) were observed.This group of cells was excluded from further study since theyrarely exhibited any response to even high-intensity synapticstimulation (see DISCUSSION). All cells included in this studydisplayed electrophysiological characteristics (and dye couplingwith biocytin in 5 of 5 filled cells) consistent with other reportsfor astrocytes recorded from in in vitro slice preparations (Berglesand Jahr 1997; D'Ambrosio et al. 1998; Schwartzkroin and Prince1979), and are thus presumed to be astrocytes. For the purposesof experiments investigating the presence of GABA uptake currents,only cells with stable, high-negative resting membrane potentials(<-80 mV), linear current voltage relationships, and low inputresistances wereused.

Identification of transporter uptake currents in neocortical astrocytes

We have identified the presence of putative GABA transporter currents in electrophysiologically characterized neocorticalastrocytes in slices obtained from rats age 10-30 days old, usingselective antagonists for the GAT transporters. The transportablesubstrate nipecotic acid is an effective blocker of GAT-1 witha much lesser degree of effectiveness at the GAT-2 and GAT-3 transporters. $beta$ -alanine, which is also transportable, acts competitively atboth GAT-2 and GAT-3 (Borden et al. 1995b). In addition, the nonsubstrateantagonists SKF-89976A and NO-711 show a high selectivity forthe GAT-1 transporter (Borden et al. 1994b; Sudzak et al. 1992),while the compound (s)-(-)-1-[2-[tris-(4-methoxyphenyl)methoxy]ethyl]-3-piperidinecarboxylicacid ((S)-SNAP-5114) is highly selective for the GAT-2 and GAT-3transporters (Borden et al. 1994a). Direct application of GABA(1 mM: 50- to 100-ms pulse, 6-9 psi) via a puffer pipette in thepresence of gabazine (10 µM), CGP-55845A (2 µM), and 6-cyano-7-nitroquinoxalene-2,3-dione(CNQX, 10 µM-to block epileptiform discharges) resulted in aninward current with a peak amplitude of $-$ 22.71 + 3.34 pA, a 10/90%rise time of 789.9 ± 24.77 ms, and a 10/90% decay time of 2,201± 198.6 ms (n = 3). Application of the GAT-1 and GAT-2/3 transporterinhibitors NO-711 (20 µM) and $beta$ -alanine (250 µM) resulted in a52.46 ± 1.85% inhibition of the peak and a 64.26 ± 3.51% inhibitionof the area (n = 3; Fig. 2). GABA receptor antagonists were includedin the puffer pipette, but transporter antagonists were not; thismay account for the lack of 100% block by the transporter antagonistsas some displacement of the antagonists may occur during the puff.

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Fig. 2. Direct application of GABA to a neocortical astrocyte. GABA (1 mM) applied to a layer 5 neocortical astrocyte via a puffer pipette induces an inward current (control). Subsequent application of the transporter antagonists NO-711 and $beta$ -alanine results in a reduction of the GABA-evoked current. GABA_A and GABA_B antagonists were present in the pipette as well as the bath. Transporter antagonists were added to the bath only.

Direct stimulation to the surface of the neocortex via a bipolar tungsten-stimulating electrode resulted in large inward currentsrecorded at rest in neocortical astrocytes. Application of ionotropicglutamate receptor antagonists and GABA_A and GABA_B receptor antagonists[CNQX (10 µM), D,L-2-amino-5-phosphonopentanoic acid (D,L-AP5,50 µM), bicuculline (10-20 µM) or gabazine (10 µM), and CGP-55845A(2 µM); present for all experiments] resulted in a substantialreduction in the size of the evoked current, presumably by reducingfeed forward excitation within the slice. Responses were evokedwith both single (Fig. 3A-D) and repetitive (Fig. 4) stimulationprotocols. In ~70% of the cells tested, a significant (10-50%)portion of the current remaining following application of glutamateand GABA receptor antagonists was blocked by the GAT-1 transporterantagonists SKF89967A (100 µM), NO-711 (20 µM), or nipecotic acid(100-200 µM; Figs. 3 and 4). As the results were similar witheach of these antagonists, the data were pooled. The average reductionof the peak current for single stimuli-evoked responses was 25.97± 3.02% (n = 11), while the average reduction of the peak currentfor repetitive stimuli-evoked responses was 26.53 ± 1.95% (n =12).

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Fig. 3. Single stimulation evoked uptake currents in neocortical astrocytes. A single shock is delivered to the tissue within ~100 µM from the recorded cell. A and B: in the presence of glutamate and GABA receptor antagonists, a biphasic current is evoked (control). Application of the GAT-1 transporter antagonists NO-711 and SKF-89976A results in a partial block of the late phase of the evoked response. A digital subtraction of these currents to better illustrate the GAT-1 transporter current time course is shown in B. C and D: glutamate uptake component for the same cell as in A. Application of L-trans PDC (in the presence of the GABA uptake antagonists) causes a reduction in the early component of the evoked current. The digital subtraction (D), reveals the glutamate uptake current. As was observed in most cells, the glutamate uptake component showed a fast rise and decay, relative to the GABA uptake current. Application of L-trans PDC in this cell also causes an inward current ( $-$ 190 pA). In this and in subsequent figures, offsets are zeroed out for presentation purposes.

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Fig. 4. The GAT-1 transporter mediates a long-lasting current during repetitive stimulation. A and B: repetitive stimulation evokes a long-lasting uptake current in a neocortical astrocyte. A: 20 shocks at 100 Hz were applied to the tissue while recording from a layer 5 neocortical astrocyte (control). Application of the GAT-1 transporter antagonists NO-711 and SKF-89976A results in a reduction of the late phase of the current (GAT-1 inhibitors). B: digital subtraction from A, demonstrating the long time course of the GABA transporter current.

Both types of stimulation protocols induced a response that was sensitive to the uptake antagonists. GAT-1-mediated responsesto a single shock were found to have primarily a slow phase (11/14cells tested; as determined from digital subtractions; Fig. 3,A-D). The slow component had an average amplitude of $-$ 18.81 ±4.07 pA, a 10/90% rise time of 471.9 ± 100.8 ms (time to peak= 691.0 ± 116.7), and a 10/90% decay time of 1,238 ± 309.8 ms.Repetitive stimulation protocols (4-20 stimuli at 100 Hz) alsoyielded long-lasting GAT-1 transporter currents with an averageamplitude of $-$ 32.44 ± 12.46 pA, a time to peak of 481.1 ± 62.72ms, and a 10/90% decay time of 3,841 ± 500.3 ms (n = 12; Fig.4, A and B).

Application of the compound $beta$ -alanine (250 µM), which is reported to act predominantly on the rat GAT-2 and GAT-3 transporters(Borden et al. 1995b; Clark and Amara 1994) also resulted in areduction in the amplitude of the evoked response (Fig. 5). Themagnitude of inhibition was 29.12 ± 6.147% (n = 7) at 250 µM forall stimulation protocols (1-10 stimuli at 100 Hz). Digital subtractionof the $beta$ -alanine-sensitive component (250 µM) revealed GAT transportercurrent with an average amplitude of $-$ 63.53 ± 13.90 pA, time topeak of 438.6 ± 28.10 ms (n = 6), and a 10/90% decay time of 2,336± 123.3 ms (n = 4). Application of a lower dose (50 µM) of $beta$ -alanineresulted in a significant slowing of the rise of the response(time to peak 623.0 ± 31.90 ms; n = 3; P < 0.05). Such a resultwould be expected of a competitive antagonist; at nonsaturatingdoses, $beta$ -alanine would interfere with but not eliminate the bindingof GABA to the GAT-2/3 transporters, causing GABA to remain inthe extracellular space for a greater length of time and to diffusegreater distances before being transported.

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Fig. 5. GAT-1 and GAT-3 transporters are expressed in neocortical astrocytes. A: a brief repetitive stimulus (5 stimuli at 100 Hz) is delivered to the tissue within 100 µm from the recorded cell. In the presence of glutamate and GABA receptor antagonists, a biphasic current is evoked (control). Application of the GAT transporter antagonist $beta$ -alanine (100 µM), which does not act on the GAT-1 transporter, results in the block of a portion of the late phase of the evoked response. Subsequent application of the GAT-1 antagonist SKF-89976A (100 µM) blocks a larger portion of the late phase of the evoked response. B: digital subtraction revealing the $beta$ -alanine-sensitive current. C: digital subtraction revealing the SKF-sensitive current.

Sequential application of the GAT-1 and GAT-2/3 antagonists resulted in a summing inhibition in 7 of 11 cells tested, indicatingthat these transporters are likely present on the same astrocytes(but see DISCUSSION). $beta$ -alanine also induced an inward current( $-$ 49.95 ± 12.16 pA, n = 10), consistent with it acting as a substratefor the GATtransporters.

The presence of L-glutamate transport currents was also investigated using the L-glutamate transporter antagonists L-trans-PDC(100 µM) or L-threo-hydroxyaspartate (L-THA) (300 µM). In mostcells tested, a fast rising and fast decaying response was observed( $-$ 23.60 ± 2.93 pA, 10/90% rise time of 5.98 ± 0.38 ms; n = 13;Fig. 2, C and D). Interestingly, the fast glutamate uptake currentwas observed on cells that also responded to the GABA uptake antagonistsand showed a dramatically different timecourse.

Because astrocytes are also efficient potassium (K⁺) buffers, it is probable that a significant portion of the current notblocked by GABA and glutamate transporter antagonists is a K⁺ current. Block of synaptic transmission by application of 100µM cadmium eliminated 61.43 ± 3.05% of the evoked current (Fig.6, middle; n = 15). The remaining current was blocked by the K⁺ channel antagonist Ba²⁺ (1 mM; Fig. 6, top; n = 2), indicating it is likely aK⁺ current resulting from the accumulation of extracellular K⁺ extruded from nearby cells (Henn et al. 1972). In addition, applicationof 1 mM Ba²⁺ resulted in a large inward current in the astrocytes ( $-$ 182.4± 0.5pA; n = 2), as has been previously observed (e.g., Andersonet al. 1995; Ballanyi et al. 1987; Perillan et al. 1999; Ransomand Sontheimer 1995).

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Fig. 6. Ba²⁺ blocks the nonsynaptic component of the evoked current. Application of the Ca²⁺ channel antagonist Cd²⁺ (100 µM) blocks a large portion of the current evoked by 15 stimuli at 100 Hz. Subsequent application of the K⁺ channel antagonist Ba²⁺ (1 mM) blocks the remaining portion and also results in a large inward current ( $-$ 182 pA) (subtracted from the baseline for presentation purposes).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

To our knowledge, this is the first study to provide direct measurement of a GABA transporter current during synaptic transmissionin an intact brain slice preparation. Recordings from neocorticalastrocytes demonstrate that the electrical properties of thesecells are similar to those reported for astrocytes elsewhere inthe brain and in culture. In addition, the glutamate transportcurrents recorded here have similar temporal characteristics tothose in previous reports (Bergles and Jahr 1997, 1998; Bergleset al. 1997). However, the characteristics of GABA transport recordedhere differ greatly from previous descriptions of glutamate transportand indicate a different functional role for GABA verses glutamatetransport in thesecells.

Astrocyte characteristics

In this study we recorded from two distinct populations of cells, both of which had characteristics of glial cells. The maingroup of cells had very low input resistances, high negative restingmembrane potentials, linear current voltage relationships anddye coupling, consistent with previous reports of astrocyte propertiesfrom studies completed elsewhere in the brain (Bergles and Jahr1997; D'Ambrosio et al. 1998; Schwartzkroin and Prince 1979).These cells constituted the large majority of cells (85%) in thisstudy and all of the cells in which evoked transporter currentswere studied. The second group of cells exhibited some of theelectrophysiological properties of glial astrocytes, includinga high negative resting membrane potential and a lack of sodiumconductances. However, they displayed much higher input resistancesand demonstrated strong outwardly rectifying conductances. Furthermorethese cells did not respond to even high-intensity synaptic stimulation.Such cells have been previously described as a class of GFAP-negativecells, termed "complex" cells (D'Ambrosio et al. 1998; Steinhauseret al. 1994).

Uptake currents

In this study we were able to measure GABA transporter currents mediated by GAT-1 and GAT-2/GAT-3 transporters, as determinedby antagonist sensitivity. Results obtained using antagonistsfor both types of transporter currents were similar with the exceptionof the presence of an inward current upon application of $beta$ -alanine.This current is likely the result of the fact that $beta$ -alanine isa transportable substrate for the GAT transporters and elicitsits antagonist actions in this manner. Although nipecotic acidis a GAT-1 transportable antagonist, for most experiments it wasused in combination with SKF-89976A or N0-711, which are not;thus any transport of it would have beenblocked.

One concern in a study in which the identity of the current depends on the selectivity of the antagonists being used is whetherthe transporter antagonists themselves have an effect on GABA_Areceptors, and, conversely, whether the GABA_A receptor antagoniststhemselves have an effect on GABA transporters. Numerous studieshave shown no effect of bicuculline on GAT-1 transporter currents(Bonanno and Raiteri 1987; Cammack and Schwartz 1993; Cory etal. 1994; Dong et al. 1994; Haugh-Scheidt et al. 1995; Takahashiet al. 1992). The effects of the GAT-1 transporter inhibitorsSKF-89976a and NO-711 are also minimal on GABA receptors (Bordenet al. 1994b; Sudzak et al. 1992). $beta$ -alanine is a partial agonistat the GABA_A receptor; however, in all experiments where it wasapplied, GABA_A (and GABA_B) receptors wereblocked.

One important observation in this study is that the time course of the GABA transporter currents was exceedingly long. A fastercomponent was occasionally observed, but this component is difficultto interpret due to its small size and infrequent appearance.The late component, however, was present in all cells that demonstrateda GABA transportercurrent.

It is possible that the slow time course of the transporter current reflects the slow turnover rate of the transporter forGABA. It is estimated that for the GAT-1 transporter, a singletransport cycle takes ~25 ms at $-$ 90 mV (Hilgemann and Lu 1999;Lu and Hilgemann 1999a), during which one molecule of GABA andone net positive charge are co-transported into the cell (Kavanaughet al. 1992; Lu and Hilgemann 1999a,b). Thus the slow rise anddecay times obtained for the single stimulus data might simplyreflect the slow turnover rate of the transporter. However, previousstudies of glutamate transporters have shown that despite theirslow reported turnover rates, the time course of the underlyingcurrent does accurately reflect the time course of glutamate inthe extracellular space (Bergles et al. 1997). Evidence showsthat at high negative membrane potentials, the rate-limiting stepfor the GAT-1 transport cycle is the actual transport of GABAitself; furthermore, the charge transfer takes place very rapidly,prior to the binding and transport of GABA (Hilgemann and Lu 1999;Lu and Hilgemann 1999a,b). Consequently, when GABA binds, it istranslocated prior to any charge movement: in this study, theinitial current recorded is actually occurring following the delayof one transport cycle. The current would then follow the timecourse of the translocation reactions, with an ~25-ms time constant(Hilgemann and Lu 1999). In this scenario, the slow rise and decayof the current would reflect the time course of extracellularGABA, as GABA diffuses away from the synaptic cleft, to the glialtransporters. The GABA that does not bind initially would continueto diffuse until it encounters free transporters, resulting ina significant period of extracellular freedom and degree of diffusionaldistance.

Data obtained from the time course of the transporter currents support the notion of a large, continuous population of transporterslocated further from the synaptic cleft than glutamate transporters.The 10/90% rise time of the single stimulus-evoked GABA transportercurrents was 471.9 ± 100.8 ms, while the 10/90% rise time of theglutamate transporter current was 5.98 ± 0.38 ms. Presuming thatthe glutamate transporter current reflects glutamate uptake ator near the synaptic cleft (as the rise time indicates), theseresults are suggestive of an extrasynaptic origin for the GABAtransporter currents werecorded.

The time to peak of the single and repetitive stimulus-evoked GABA transporter currents had similar values (691.0 ± 116.7vs. 481.1 ± 62.72 ms, respectively; P > 0.1, unpaired t-test),while the amplitudes ( $-$ 18.81 ± 4.07 vs. $-$ 32.44 ± 12.46 pA) and10/90% decay times (1,238 ± 309.8 and 3,841 ± 500.3 ms, respectively;P < 0.01) increased significantly with stimulus number. Time topeak was utilized due to the fact that stimulus artifacts interferedwith 10/90% rise time measurements for repetitive stimuli data.The prolongation of the decay of the transporter current observedfor repetitive verses single stimulus-evoked responses impliesthat when inputs are stimulated repetitively, excess GABA diffusesfurther to unoccupied transporters due to the slow recovery rateof the GAT-1 transporter and implies that GABA has a significantdegree of extracellular freedom followingrelease.

Transporter expression

The demonstration that at least two types of GABA transporter currents, as well as glutamate transporter currents, can beevoked while recording from the same astrocyte provides strongevidence that all are present within the same cell (but see followingtext). While binding studies have localized GAT-1, GAT-2, andGAT-3 expression to astrocytic processes within the cortex (Contiet al. 1998, 1999; Minelli et al. 1995), this study strongly suggeststhat functional, co-localized GAT transporters are expressed onthese cells. While the presence of the GAT-1 transporter can beconfirmed from the use of NO-711/SKF89976a, the identity of the $beta$ -alanine-sensitive current cannot be established because bothGAT-2 and GAT-3 transporters are blocked by $beta$ -alanine at higherdoses (Borden et al. 1995b) and the expression of both transportersubtypes on neocortical astrocytes has been confirmed (Conti etal. 1999; Minelli et al. 1996; Yan and Ribak 1999).

It is interesting to note that the magnitude of repetitive stimulus-evoked GAT-1-mediated currents was on average smallerthan GAT-2/3-mediated currents ( $-$ 32.44 ± 12.46 vs. $-$ 63.53 ± 13.90pA). This could be due to the fact that $beta$ -alanine blocks the activityof both GAT-2 and GAT-3 transporters. Alternatively, it couldrepresent a difference of expression in the transporter subtypes.GAT-3 expression has been reported to be low in the adult andmay be developmentally regulated (Liu et al. 1993; Minelli etal. 1996), whereas GAT-1 expression is reported to be higher inthe adult than the neonate (Yan et al. 1997). Recordings in thisstudy were made on animals primarily over the age of 15 days old,but <26 (19.39 ± 0.46; n = 146). It is possible that the differenceobserved here is a consequence of a developmental regulation oftransporter expression. However, further work needs to be doneto clarify thisissue.

The possible co-expression of glutamate transporters within the same cell is of interest. The time course of the glutamatetransporter currents recorded here are comparable with those reportedelsewhere (e.g., Bergles and Jahr 1997) and are indicative ofa relatively proximal location to the excitatory synaptic cleft.Conversely, the time courses of both subtypes of GABA transportercurrents were remarkably slower. If the underlying current directlyreflects the time course of GABA, as discussed in the precedingtext, then this implies that the location of the transportersto their respective synapses is quite different. It is more difficultto make inferences about the localization of the subtypes of GATtransporters relative to each other. The time courses of bothare similar, indicating they are likely at similar distances fromthe synaptic cleft, although it is unclear whether they are locatedat the same sites on the astrocyte, or at different sites andthus serve different functions. It should be noted, however, thatwe observed dye coupling and since astrocytes are known to displayelectrical coupling (Kettenmann and Ransom 1988), the possibilityexists that the presence of multiple transporter currents observedhere reflects the recording of those currents from more than onecell simultaneously. The fact that GAT-1 and GAT-2/3 transportercurrents have similar amplitudes and time courses argues againstthis, but such a scenario cannot be ruled out. Nevertheless, itis clear that GAT-1 and GAT-2/3 transporter subtypes are expressedon neocortical astrocytes and that they play a prominent rolein the removal of GABA from the extracellular space followingsynapticrelease.

The average block of the late evoked current with all GAT antagonists present was ~39%. There was a significant residual remainingin the presence of 100 µM cadmium ( $approx$ 39%), indicating a currentof nonsynaptic origin. Indeed, application of 1 mM Ba²⁺ blocked the remaining current (n = 2), indicating that it isa K⁺ current (Fig. 6). Approximately 22% of the current of synapticorigin remains unaccounted for (glutamate transporters blockeda negligible portion of the late component). The origin of thisportion of the current is unknown. Antagonism of the GAT transportersmay be incomplete or other subtypes of GABA transporters may bepresent on the astrocytes that are insensitive to the antagonistsused (e.g., Borden et al. 1995a; Conti et al. 1999). Alternatively,there is the possibility that other neurotransmitter or peptidetransporters are present on the astrocytes, which are activatedduring synapticstimulation.

Functional considerations

Based on the data from this study, the function of GABA transporters on neocortical astrocytes may be quite different fromthat of glutamate transporters. The time course of the GABA transportercurrents recorded here are significantly slower than glutamatetransporter currents in the same cells and indicates that GABAis remaining in the extracellular space for a much longer periodof time than does glutamate. The slow rise time observed for theGABA transporter current additionally indicates that GABA is takinga relatively long time to reach the astrocytic GABA transporterpopulation, although a small delay would be expected because thetransporter would have to cycle through one transport cycle beforea current isgenerated.

The slow time course of astrocytic GABA transporter currents recorded here suggests that glial-based GABA transporters maynot play a significant role in sculpting the time course of inhibitoryevents during low-frequency firing. The observation that applicationof GABA transport inhibitors increase the time course of singleevoked inhibitory responses in the hippocampus (Dingledine andKorn 1985; Draguhn and Heinemann 1996; Isaacson et al. 1993; Roepstorffand Lambert 1994; Thompson and Gähwiler 1992), as well as incortex (unpublished observations), indicates that neuronal transportersin the neocortex are likely to play a prominent role in the modulationof the IPSC time course. The direct recording of transporter currentsfrom neurons during synaptic activity would help to resolve thisissue. However, due to the small size of the currents and theirpresumable location at the presynaptic terminal, accurate resolutionof neuronal transporter currents would likely be exceedinglydifficult.

One question this study raises, of course, is whether the time course of the transporter currents recorded is an accuratereflection of the time course of extracellular GABA. Evidencesuggests that the passage of current occurs immediately followingthe transport of GABA and that this current would then followthe time course of the translocation reactions; however, the relationshipbetween the time course of the transporter current and the timecourse of GABA in an intact preparation may be different. Experimentsusing rapid perfusion techniques on excised patches to directlyinvestigate the temporal dynamics of GAT transporter functionwould clarify this issue. Due to the small size of the currentsrecorded here, such experiments would necessitate the use of anexpression system and therefore are beyond the scope of thisstudy.

So why are inhibitory postsynaptic currents so much shorter in duration than the transport currents we recorded? For our experimentalconditions, we estimate an upper limit increase (i.e., if theGABA transporters are blocked) in extracellular GABA concentrationof $approx$ 6 µM in response to a single stimulus. This is in good agreementwith estimates derived from microdialysis studies in cortex (e.g.,During et al. 1995; Wang et al. 2001) as well as from in vitroslice preparations (e.g., Rossi and Hamann 1998). At a GABA concentrationof 6 µM, most synaptic GABA_A receptors would likely enter intoa desensitized state (Overstreet et al. 2000). However, the activationof GABA_A receptors less susceptible to desensitization (e.g.,Saxena and Macdonald 1994, 1996) may occur via spillover. Theobservation that extrasynaptic GABA concentrations are capableof reaching micromolar concentration levels several millisecondsfollowing release support the notion of crosstalk between neighboringsynapses as has been reported elsewhere (Barbour and Häusser1997; Brickley et al. 1996; Isaacson et al. 1993; Kullmann etal. 1996; Rossi and Hamann 1998).

Our estimate of 6 µM is based on the integral of the stimulus-evoked transporter current. The average integrated transportcurrent measured was 1.7 × 10¹⁰ coulombs (n = 3; 5 stimuli at 100 Hz, from subtraction currentsbefore and during saturating doses of GAT-1 and GAT-2/3 blockers),indicating the transport of ~2 × 10⁸ GABA molecules per stimulus (each electron transferred represents1 GABA molecule) (Lu and Hilgemann 1999a,b). Assuming (based onthe low input resistances) that most of the transport currentwe measured originated from the cell to which our electrode wasattached (and thus ignoring current contribution from coupledcells), the processes from a single astrocyte extend over a corticalvolume of $approx$ 3 × 10⁵ µ³ (Privat et al. 1995), which represents $approx$ 6 × 10⁴ µ³ of extracellular space (using a volume fraction of 0.2) (Nicholson1995). Thus if all GABA transport were blocked, the distributedextracellular concentration of GABA could reach $approx$ 5-6 µM followinga singlestimulus.

Our data imply that one function of GABA transport on neocortical astrocytes is to remove GABA from the extrasynaptic spaceduring both low- and high-frequency firing of inhibitory interneurons.It is clear that during both single and repetitive stimuli, GABAtransporters are active and do participate in the removal of GABAfrom the extracellular space, albeit on a much slower time scalethan that of a single inhibitory postsynaptic potential (10/90%decay $approx$ 50 ms in cortex) (Connors et al. 1988; van Brederode andSpain 1995; unpublished observations). The time course of thetransporter currents implies that the location of the transportersis remote to the synaptic cleft and that GABA is remaining presentin the extracellular space for a significant period of time, whichwould indicate that GABA is available to bind to GABA receptorsas well. Such a scenario is supported by the work of Jones, Overstreet,and Westbrook (Jones and Westbrook 1995; Jones et al. 1999; Overstreetet al. 2000), who propose that synaptically released GABA remainsbound to GABA_A receptors for a several seconds followingrelease.

Of course, glial GABA transporters may have other important functions as well, such as to supply a source of extracellularGABA via reversal of the GABA transporter (Wu et al. 2001) andto regulate paracrine GABA, as has been suggested by others (Contiet al. 1998; Minelli et al. 1996). The relatively distal localizationof glial GABA transporters, as compared with glutamate transporters,suggested by the long transporter current time course is consistentwith thishypothesis.

	ACKNOWLEDGMENTS

We thank A. Berger, R. D'Ambrosio, M. Jones, B. Ransom, and P. Schwindt for helpful discussions and comments on the manuscript.Thanks also to R. Lee for technicalassistance.

This work was supported by a Veterans Affairs Merit Review to W. J. Spain, National Institute of Neurological Disorders andStroke Health Training Grant NS-07395 to G. A. Kinney, and PERCaward to G. A. Kinney and W. J.Spain.

	FOOTNOTES

Address for reprint requests: G. Kinney, Dept. of Rehabilitation Medicine, Harborview Medical Ctr., Box 359740, 325 9th Ave.,Seattle, WA 98104 (E-mail: gkinney{at}u.washington.edu).

REFERENCES

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
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