Corelease and Differential Exit via the Fusion Pore of GABA, Serotonin, and ATP from LDCV in Rat Pancreatic {beta} Cells

doi:10.1085/jgp.200609658

Axon Instruments microelectrode amplifiers

Published online February 12, 2007
doi:10.1085/jgp.200609658
The Journal of General Physiology, Vol. 129, No. 3, 221-231
The Rockefeller University Press, 0022-1295 $30.00
© 2007 Braun et al.

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ARTICLE

Corelease and Differential Exit via the Fusion Pore of GABA, Serotonin, and ATP from LDCV in Rat Pancreatic ß Cells

Matthias Braun¹, Anna Wendt², Jovita Karanauskaite¹, Juris Galvanovskis¹, Anne Clark¹, Patrick E. MacDonald¹, and Patrik Rorsman¹

¹ Oxford Centre for Diabetes, Endocrinology, and Metabolism, University of Oxford, Churchill Hospital, Oxford OX3 7LJ, UK
² Department of Clinical Sciences, Clinical Research Centre, Lund University, 20502 Malmö, Sweden

Correspondence to Matthias Braun: matthias.braun{at}drl.ox.ac.uk

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The release of ${gamma}$ -aminobutyric acid (GABA) and ATP from rat ßcells was monitored using an electrophysiological assay basedon overexpression GABA_A or P₂X₂ receptor ion channels. Exocytosisof LDCVs, detected by carbon fiber amperometry of serotonin,correlated strongly ( $~$ 80%) with ATP release. The increase inmembrane capacitance per ATP release event was 3.4 fF, closeto the expected capacitance of an individual LDCV with a diameterof 0.3 µm. ATP and GABA were coreleased with serotoninwith the same probability. Immunogold electron microscopy revealedthat $~$ 15% of the LDCVs contain GABA. Prespike "pedestals," reflectingexit of granule constituents via the fusion pore, were lessfrequently observed for ATP than for serotonin or GABA and therelative amplitude (amplitude of foot compared to spike) wassmaller: in some cases the ATP-dependent pedestal was missingentirely. An inward tonic current, not dependent on glucoseand inhibited by the GABA_A receptor antagonist SR95531, wasobserved in ß cells in clusters of islet cells. Noiseanalysis indicated that it was due to the activity of individualchannels with a conductance of 30 pS, the same as expected forindividual GABA_A Cl^– channels with the ionic gradientsused. We conclude that (a) LDCVs accumulate ATP and serotonin;(b) regulated release of GABA can be accounted for by exocytosisof a subset of insulin-containing LDCVs; (c) the fusion poreof LDCVs exhibits selectivity and compounds are differentiallyreleased depending on their chemical properties (including size);and (d) a glucose-independent nonvesicular form of GABA releaseexists in ß cells.

M. Braun and A. Wendt contributed equally to this work.

P.E. MacDonald's present address is Department of Pharmacology,University of Alberta, Edmonton T6G 2E1, Canada.

Abbreviations used in this paper: GABA, ${gamma}$ -aminobutyric acid;LDCV, large dense-core vesicle; SLMV, synaptic-like microvesicle;TIC, transient inward current.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Like neurons, many endocrine cells contain two classes of secretoryvesicles. Large dense-core vesicles (LDCVs) contain peptidehormones, whereas the small synaptic-like microvesicles (SLMVs),store low molecular weight neurotransmitters (Kasai, 1999).In addition to insulin, pancreatic ß-cell LDCVs accumulatea variety of low molecular weight substances, including ATP(Hutton, 1989) and serotonin (Ekholm et al., 1971). SLMVs inß cells are believed to contain ${gamma}$ -aminobutyric acid(GABA) (Reetz et al., 1991). GABA_A (Rorsman et al., 1989; Wendtet al., 2004), GABA_B receptors (Braun et al., 2004b), as wellas purinergic receptors (Salehi et al., 2005) have been identifiedin islets of Langerhans. This suggests that GABA and ATP, releasedby regulated exocytosis from the ß-cell, can serveas paracrine/autocrine regulators.

Exocytosis of LDCVs from pancreatic ß cells is firmlyestablished (for reviews see Barg, 2003; Tsuboi and Rutter,2003). Little is known, however, about the release of SLMVs.Recently, high-resolution on-cell capacitance measurements haveprovided evidence that ß-cell SLMVs are capable ofregulated Ca²⁺-dependent exocytosis (Macdonald et al., 2005).However, the identities of the molecules that are released duringexocytosis of LDCVs and SLMVs have not been established conclusively.Using a technique based on the infection of ß cellswith GABA_A receptor ion channels, we have recently reporteddepolarization-induced quantal release of GABA (Braun et al.,2004a). A similar approach, based on the overexpression of P₂X₂receptor cation channels, can be applied to study exocytoticrelease of adenine nucleotides (Hollins and Ikeda, 1997) andhas been successfully applied to insulin-secreting cells (Hazamaet al., 1998; Obermüller et al., 2005; MacDonald et al.,2006). Based on reports that GAD65, the enzyme involved in GABAsynthesis, associated with SLMVs in ß cells (Reetzet al., 1991) and evidence for transmembrane transport of GABAin SLMV-enriched subcellular fractions (Thomas-Reetz et al.,1993),we postulated that the observed release of GABA was attributableto exocytosis of SLMVs although the amplitude distribution differedsomewhat from that expected for exocytosis of SLMVs (Braun etal., 2004a). Moreover, contrary to our expectations (Kasai,1999; Bruns et al., 2000), the properties of GABA release detectedwith this method were remarkably similar to those of LDCV exocytosisin terms of [Ca²⁺]_i dependence, regulation by cAMP, and kineticsof the individual events (Braun et al., 2004a). Recently, ultrastructuralevidence has been presented suggesting that GABA is not onlystored in the SLMVs but also the insulin-containing LDCVs (Gammelsaeteret al., 2004). If this is the case, exocytosis of the lattertype of vesicles may thus also contribute to GABA release, butthis aspect has so far not been explored. In addition, biochemicalmeasurements suggest that GABA is released at a very high rate(25% of its content per hour) in a seemingly unregulated fashion(Smismans et al., 1997; Winnock et al., 2002). The relationshipbetween this form of GABA release and that which we have documentedpreviously remains unclear.

Here we have investigated exocytosis of LDCVs and SLMVs usingrat ß cells engineered to express ionotropic ATP andGABA receptors. These measurements were combined with amperometricdetection of serotonin preloaded into pancreatic ßcells, widely used as an insulin proxy (Kennedy et al., 1993).This approach enabled us to explore the extent to which thesecompounds are released by the same or distinct exocytotic pathwaysand to provide some insight into the nature of the unregulatedform of GABA release from pancreatic ß cells.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Adenovirus Construction
AdP₂X₂-GFP.
AdP₂X₂-GFP was created using the Adeno-X Expression system (BDBiosciences; CLONTECH Laboratories, Inc.). In short, cDNA encodingthe rat P₂X₂ receptor linked to GFP (provided by B. Khakh, Cambridge,UK) was subcloned into pShuttle. The expression cassette wasthen excised using PI-Sce1 and I-CeuI and ligated into pAdeno-Xand the resulting adenoviral DNA transfected into HEK293 cells.Viral titer was determined by counting the number of green fluorescentcells.

AdGABA_A ${alpha}$ 1 and AdGABA_Aß1.
The construction of adenoviruses containing the human GABA_A ${alpha}$ 1subunit (AdGABA_A ${alpha}$ 1) and the human GABA_Aß1 subunit (AdGABA_Aß1)has been described elsewhere (Braun et al., 2004a). AdGABA_A ${alpha}$ 1and AdGABA_Aß1 were cotransfected to create functionalGABA_A receptors (Birnir et al., 1995).

Islet Cell Preparation and Adenoviral Infection
Sprague Dawley rats were killed by inhalation of CO₂ followedby cervical dislocation. All experimental procedures involvinganimals were approved by the ethical committee in Lund, andexperiments in the UK were performed according to a Schedule1 procedure. After excision of the pancreas, islets were isolatedby collagenase digestion and dispersed into single cells essentiallyas detailed elsewhere (Ämmälä et al., 1993).For amperometry (Figs. 3 and 4), 0.5 mM 5-HT and 0.5 mM 5-HTP(Sigma-Aldrich) were added to the cell culture >4 h beforethe electrophysiological experiments. The ß-cellswere infected with AdP₂X₂-GFP and/or AdGABA_A ${alpha}$ 1 and AdGABA_Aß1at a concentration of 10–100 pfu/cell and used 24–48h after infection.

Electrophysiology
Patch pipettes were pulled from borosilicate glass, coated withSylgard and fire polished. They had a tip resistance 3–6M ${Omega}$ when filled with the intracellular solutions. All electrophysiologicalmeasurements were performed using the standard whole-cell configurationof the patch-clamp technique. The recordings were performedusing an EPC9 patch clamp amplifier (HEKA Electronics) and Pulsesoftware (version 8.53, HEKA). ß cells were identifiedbased on their size (cell capacitance >5 pF) and the inactivationproperties of the voltage-gated Na⁺ current (Hiriart and Matteson,1988; Göpel et al., 1999). In Fig. 2, exocytosis of LDCVswas detected as changes in cell capacitance estimated by theLindau-Neher technique (Gillis, 1995) implementing the Sine+ DC feature of the lock-in module of the pulse software.

Amperometry
A carbon fiber electrode (tip diameter 5 µm; ProCFE, DaganCorp.) was connected to the second headstage of an EPC-9/2 amplifier(HEKA) and held at +650 mV. The carbon fiber was positionedwithin 1 µm of the cell membrane during all experiments.The amperometric current was filtered at 333 Hz, digitized at1 kHz, and digitally filtered at 100 Hz before analysis.

Solutions
The standard extracellular solution consisted of (in mM) 118NaCl, 20 TEACl, 5.6 KCl, 2.6 CaCl₂, 1.2 MgCl₂, 5 HEPES, and5 glucose (pH 7.4, adjusted with NaOH). The pipette solutionfor Ca²⁺ infusion experiments and amperometric measurements(Figs. 1, A and B; Figs. 3 and 4) contained (in mM) 138 CsCl,1 MgCl₂, 10 HEPES, 3 MgATP, 0.1 cAMP, 5 HEDTA (pH 7.15 withCsOH), and 0.57 CaCl₂. The free [Ca²⁺] was estimated to be 2µM. For simultaneous recording of ATP release and capacitance(Fig. 2), the pipette solution was composed of (in mM) 110 glutamate,10 KCl, 10 NaCl, 1 MgCl₂, 3 MgATP, 0.1 cAMP, 5 HEPES, 6 CaCl₂,and 10 EGTA (pH 7.2 with CsOH; estimated free [Ca²⁺] 230 nM).The intracellular solution for recording first latencies (Fig. 1, C and D)contained (in mM) 125 Cs-glutamate, 10 CsCl, 10 NaCl, 1 MgCl₂,5 HEPES, 50 µM EGTA, 3 MgATP, and 0.1 cAMP (pH 7.15 withCsOH). The simultaneous recording of GABA and ATP release (Fig. 5;Fig. S2, available online at http://www.jgp.org/cgi/content/full/jgp.200609658/DC1)was performed using a pipette solution consisting of 135 Cs-glutamate,1 MgCl₂, 3 MgATP, 10 HEPES, 0.1 cAMP, 10 EGTA, and 5 CaCl₂ (pH7.2 with CsOH). The total [Cl^–]_i was 12 mM and the estimatedfree [Ca²⁺]_i was 0.16 µM. For measuring tonic activityof GABA_A receptors (Fig. 6), the extracellular solution consistedof (in mM) 138 NaCl, 5.6 KCl, 2.6 CaCl₂, 1.2 MgCl₂, 5 HEPES,and 1 glucose (pH 7.4 with NaOH), and the pipette solution contained120 CsCl, 1 MgCl₂, 10 EGTA, 1 CaCl₂, 10 HEPES, 3 MgATP (pH 7.2with CsOH).

Electron Microscopy
Isolated rat islets were fixed in 2.5% glutaraldehyde in phosphatebuffer, post-fixed in 1% osmium, dehydrated, and embedded inSpurr's resin. Ultrathin sections cut onto nickel grids wereimmunolabeled for GABA using optimally diluted (1/1,000) rabbitpolyclonal antibody to GABA (Sigma-Aldrich) and protein A gold(15 nm; Biocell). Sections were viewed with a Joel 1010 microscope,accelerating voltage 80 kV. Gold particle density on differentß-cell organelles was estimated by image analysis(Scion Image, Scion Corporation). Background labeling was obtainedon pancreatic exocrine tissue and subtracted.

Analysis and Statistical Evaluation
Data are given as mean values ± SEM unless indicatedotherwise. Statistical significances were evaluated using Student'st test for unpaired data. The GABA- and ATP-induced transientinward currents (TICs) and the amperometric events were analyzedusing the MiniAnalysis software (Synaptosoft). In Figs. 3 and4, amperometric currents, which occurred within a period shorterthan their own rise times following a purinergic or GABAergicTIC (maximally 20 ms), were regarded as simultaneous with thereceptor-activated current. Stationary fluctuation analysis(Hille, 2001) was performed using MATLAB software (MathworksInc.).

To evaluate the temporal coincidence of GABAergic TICs and amperometricevents, the two corresponding time series of transient currentswere characterized with the probability density function, andthe probability for an amperometric event to occur during atime interval ${Delta}$ t (20 ms) after a GABA-induced TIC was calculatedand compared with the probability observed experimentally. Adetailed description of these procedures is provided as onlinesupplemental material.

Online Supplemental Material
The supplemental material is available at http://www.jgp.org/cgi/content/full/jgp.200609658/DC1.Fig. S1 shows the distribution of time intervals between adjacentGABAergic TICs and amperometric events, respectively, and containsa description of the procedure for evaluating the temporal coincidenceof both types of events. Fig. S2 relates to the assay for thesimultaneous detection of GABA and ATP release.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Kinetics of Quantal Release of ATP and GABA from ß Cells
To investigate the release of the low molecular weight transmittersATP and GABA from pancreatic ß cells, we used patchclamp–based secretion assays as described previously (Braunet al., 2004a; Obermüller et al., 2005). In brief, "autosynapses"were created in isolated rat ß cells by overexpressionof GABA_A or P₂X₂ receptor ion channels using adenoviral vectors(Fig. 1, A and B). Vesicular release of GABA and ATP activatestheir respective receptors and thus gives rise to transientinward currents (TICs) similar to inhibitory postsynaptic currents(IPSCs) in nerve terminals. Fig. 1 (A and B, bottom) shows examplesof TICs observed in ß cells infected with GABA_A receptor ${alpha}$ ₁/ß₁ subunits (Fig. 1 A) or P₂X₂ receptors (Fig. 1 B)when exocytosis was stimulated by intracellular applicationof 2 µM free [Ca²⁺]_i via the recording electrode. Someof the characteristics of these TICs (rise times and halfwidths)have been reported elsewhere (Braun et al., 2004a; MacDonaldet al., 2006).

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Figure 1. Quantal GABA and ATP release in rat ß cells monitored by overexpression of the ionotropic membrane receptors GABA_A and P₂X₂. Examples of GABA- (A) and ATP-activated (B) TICs recorded from ß cells infected with GABA_A and P₂X₂ receptors, respectively. Cells were held at –70 mV and exocytosis elicited by intracellular application of 2 µM free Ca²⁺. The cartoons above the current traces illustrate schematically the protocols used. (C) Samples of GABA (transient outward currents; top trace) and ATP release events (transient inward currents; bottom trace) triggered by 500-ms depolarizations from –70 to 0 mV. The latency between the beginning of the depolarizing pulse and the onset of the first exocytotic event during the pulse (L₁) was measured. (D) Cumulative frequency of the first latencies of GABA release (black squares) and ATP release (open circles).

Release of both GABA and ATP can also be elicited by membranedepolarization (Braun et al., 2004a

; Obermüller et al.,2005

). We measured the latency between the onset of membranedepolarization and the occurrence of the first exocytotic eventduring 500-ms voltage clamp depolarizations from –70 to0 mV (Fig. 1 C). No detectable difference in the first latenciesof GABA and ATP release was observed. GABA was released withan average first latency of 249 ± 19 ms (n = 51 eventsin six cells), whereas the corresponding value for ATP was 249± 13 ms (n = 104 events in 15 cells; Fig. 1 D).

Parallel Recordings of P₂X₂ Currents and Cell Capacitance
We combined whole-cell capacitance measurements with the monitoringof ATP secretion in ß cells overexpressing P₂X₂ receptors.The cells were held at –70 mV and exocytosis was elicitedby infusion of 230 nM free Ca²⁺. This [Ca²⁺]_i is sufficientto trigger exocytosis at a low rate but does not elicit endocytosisin ß cells (Eliasson et al., 1996; Renstrom et al.,1997). The progressive increase in cell capacitance (Fig. 2 A,bottom trace) following establishment of the whole-cell configurationwas associated with the occurrence of numerous TICs (Fig. 2 A,top trace). Fig. 2 B compares the cell capacitance (C_m) asa function of the cumulative number of TICs ( ${Sigma}$ N) measured over60 s. The slope of the linear fit (dotted line) provides anestimate of the unitary increase in cell capacitance per exocytoticevent and amounted to 3.2 fF/event. In a series of eight experiments,the average capacitance increase per TIC was 3.4 ± 0.48fF.

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Figure 2. Estimation of the unitary LDCV capacitance increase. (A) P₂X₂ receptor–mediated TICs (top) and increase in whole-cell capacitance (bottom) recorded simultaneously in the same cell. Exocytosis was elicited by inclusion of 230 nM free Ca²⁺ in the pipette solution. Each segment (5 s) was preceded by a brief prepulse with a sine wave to measure the cell capacitance. (B) Plot of the cumulative number ( ${Sigma}$ N) of purinergic TICs vs. membrane capacitance (C_m) from the same experiment. A linear fit (dotted line) with a slope of 3.18 fF/event is superimposed.

Corelease of ATP and Serotonin
Serotonin is taken up by pancreatic ß cells from theculture medium and selectively accumulates in insulin-containingLDCVs (Ekholm et al., 1971

; Kasai, 1999

). The detection of serotoninrelease by carbon fiber amperometry has been used extensivelyas an assay for LDCV exocytosis in ß cells (Zhou andMisler, 1996

; Takahashi et al., 1997

; Aspinwall et al., 1999

).We combined amperometric detection of serotonin with patch-clamprecordings of GABA or ATP release in rat ß cells overexpressingeither P₂X₂ or GABA_A receptors. The cells were clamped at –70mV and exocytosis was triggered by infusion of 2 µM Ca²⁺through the patch pipette. Fig. 3 A shows a parallel recordingof ATP and serotonin release in the same cell. In this experiment,a total of 77 amperometric events and 194 P₂X₂ TICs were detected.Thus, the latter outnumber the former by a factor of 2.5. Thisis expected because the carbon fiber (d = 5 µm) only coversa fraction of this cell, whereas the P₂X₂ receptors will detectATP release in the entire cell. In most cells there was a goodcorrelation between amperometric spikes and ATP-dependent TICs.In a series of nine experiments, 77 ± 4% of all amperometricspikes were accompanied by a simultaneous ATP release event.If we instead calculated the fraction of ATP-dependent TICsassociated with amperometric responses (i.e., the reverse analysis),a value of 29 ± 4% was obtained. This is again a consequenceof the carbon fiber only monitoring exocytosis in $~$ 35–40%of the ß-cell.

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Figure 3. Parallel recordings of exocytotic events combining amperometry with overexpression of P₂X₂ receptors. The cells were held at –70 mV and exocytosis elicited by intracellular application of 2 µM free Ca²⁺. (A) Parallel recording of ATP release–induced TICs (top) and serotonin release measured by amperometry (bottom) in a single ß-cell. The dotted lines indicate the simultaneous occurrence of TICs and amperometric spikes. (B) Cubic root of the charge of the P₂X₂-mediated TICs (n = 34 events recorded in the same cell) plotted against the cubic root of the charge of simultaneously recorded amperometric spikes. A linear fit is superimposed. (C) Examples of amperometric spikes (top red traces, 5-HT) and simultaneously recorded ATP release–induced TICs (bottom black trace). Prespike feet are indicated by arrows.

If ATP and serotonin are released by exocytosis of the samevesicles, then the amplitude of the associated events shouldcorrelate. We therefore compared the charges (Q) of simultaneouslyoccurring P₂X₂-mediated TICs and amperometric spikes. To allowlinear correlation, the data are expressed as the cubic rootof the current charges (³ ${surd}$ Q). This parameter is expected to benormally distributed given that the vesicle diameter followsa Gaussian distribution (Finnegan et al., 1996

). To excludeexocytotic events occurring far away from the carbon fiber,with resultant diffusional loss of serotonin and distortionof the signal, only amperometric events with a rise time <15ms were included. It is evident that ³ ${surd}$ Q of purinergic TICs andamperometric currents are linearly related to each other (correlationcoefficient R = 0.83; P < 0.001; Fig. 3 B). In a series offive experiments with a total of 101 events, the correlationcoefficient R averaged 0.82 ± 0.05.

Release of ATP and Serotonin during Prespike Feet
In chromaffin cells, the rapidly rising phase of amperometricevents is often preceded by a small pedestal ("foot"), whichrepresents release of transmitter through the fusion pore (Chowet al., 1992). Such prespike feet have also been described inß cells (Zhou and Misler, 1996), suggesting that serotonincan also exit via the fusion pore. It has also been argued,however, that the pedestals in ß cells represent anartifact that results from the superimposition of two separateevents occurring at different distances from the electrode (Smithet al., 1999). During parallel recordings of ATP and serotoninrelease, we observed pedestals preceding both the amperometricspikes (37 out of 124 events) and the simultaneously recordedATP-induced TICs (17 out of 124 events; Fig. 3 C, trace ii).The shape of the ATP-induced TICs is independent of the localizationof the exocytotic event (Obermüller et al., 2005). We canthereby discard the possibility that the pedestals result fromsummation of release events; if they did, we should have beenable to observe two full-sized ATP-induced TICs in rapid succession.Interestingly, the foot signal of ATP-induced TICs had a loweramplitude relative to the spike phase than the correspondingamperometric currents (12 ± 2% for ATP vs. 28 ±3% for serotonin, P < 0.001, n = 17 in 11 cells) and contributedsubstantially less to the total charge of the event (3.6 ±1% for ATP vs. 20 ± 5% for serotonin; P < 0.001).Moreover, many amperometric events consisting of both foot andspike signals were accompanied by simultaneous ATP-dependentTICs displaying only the rapid spike-like signal with no signof a pedestal (traces iii and iv in Fig. 3 C; n = 20 in 11 cells).Taken together, these data indicate that ATP is less readilyreleased than serotonin during the prespike feet. Amperometricfeet with simultaneous ATP-induced foot signals were significantlylonger than amperometric feet without ATP release (28 ±5 ms vs. 13 ± 3 ms, P < 0.01) and tended to contributemore to the total charge of the event (20 ± 5% vs. 14± 3%).

Corelease of GABA and Serotonin
We also combined amperometric monitoring of serotonin releasewith patch-clamp measurements of GABA release in ßcells overexpressing GABA_A receptors. Although simultaneousrelease of GABA and serotonin was sometimes observed (Fig. 4 A),only 6.3 ± 1.4% of the amperometric events correlatedwith simultaneous GABA release in a series of eight experiments. We considered the possibility that ATP appears more stronglycorrelated with serotonin release than GABA because ATP-dependentTICs were more frequent; normalized to the frequency of amperometricevents, the number of ATP-dependent TICs was 15-fold higherthan the number of GABA-evoked TICs under these experimentalconditions (unpublished data). We therefore determined the fractionof GABA-induced TICs associated with simultaneous serotoninrelease (i.e., the reverse analysis) and obtained an averagevalue of 22 ± 5% (n = 8). This value is not statisticallydifferent from the percentage of ATP-induced TICs associatedwith serotonin release and is sevenfold larger (P < 0.01)than that expected for simultaneous release of GABA and serotoninby independent events (see Materials and methods and onlinesupplemental material).

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Figure 4. Corelease of GABA and serotonin by exocytosis of LDCVs. (A) Parallel recording of GABA-induced TICs (top) and serotonin release (bottom) in a single ß-cell. The cell was held at –70 mV and exocytosis elicited by intracellular application of 2 µM free Ca²⁺. (B) Examples of GABA-induced TICs displaying prespike feet. (C) Immunogold labeling of GABA in rat pancreatic ß cells. Labeling over the insulin-containing LDCVs (arrows) was less than that in the cytoplasm and was variable in density. (m = mitochondria; Bar, 200 nm). (D) Distribution of cubic roots of integrated GABA-dependent TICs (³ ${surd}$ Q) in a single representative experiment. A total of 200 events (N) were analyzed. A Gaussian fit is superimposed. The CV in this particular experiment was 0.49.

We measured the charge of the amperometric spikes occurringsimultaneously with GABAergic TICs and compared it with thosethat were not associated with GABA release. In a series of sixexperiments, the cubic root of charge of the amperometric eventsaccompanied by GABA release averaged 94 ± 3% (n = 44)of that of isolated amperometric spikes. There was likewiseno difference in the rise time (defined as the time requiredfor the current to increase from 10 to 90% of its final amplitude)between amperometric events that associated with GABA releaseand those that did not (16 ± 3 ms vs. 16 ± 2 ms)and their half-widths (33 ± 4 vs. 32 ± 3 ms).We also compared the GABA-activated TICs that associated withserotonin release with those that did not. The cubic root ofcharge of GABA-activated TICs associated with serotonin releasewas 98 ± 7% of isolated GABAergic TICs (n = 30, not statisticallysignificant).

Finally, evidence for GABA release during pedestals precedingthe spike was also obtained (Fig. 4 B). We observed 22 clearpedestals with an average relative amplitude (relative to thepeak) of 28.7 ± 2.5%, accounting for 6.4 ± 1%of the total charge.

Subcellular Localization of GABA in Rat ß cells
We reanalyzed the subcellular distribution of GABA in rat ßcells (Fig. 4 C). Labeling was high in the nuclei and distributedthroughout the cytoplasm. Based on the analysis of 1,017 granulesfrom nine different cells and in agreement with our previousfindings (Braun et al., 2004a), the average particle densitywas lower in LDCVs (6.2 particles/µm²) than in the othercompartments (15.1 particles/µm²). The latter value doesnot, at variance with our previous study, include the nuclei,which contain a high density of gold particles, and this accountsfor the lower intracellular density we observe here. Interestingly,17% of the LDCVs were labeled by the antibody. This suggeststhat a subpopulation of LDCVs accumulates significant amountsof GABA. The particle density in these granules averaged 36particles/µm².

We have also analyzed the distribution of the cubic roots (³ ${surd}$ Q)of the charges of the GABA-dependent TICs. Fig. 4 D shows arepresentative experiment. In a series of 11 experiments includinga total of 996 events, the average coefficient of variation(CV) averaged 0.43 ± 0.03. For comparison, the CV forthe pooled ³ ${surd}$ Q values of the amperometric spikes was 0.30.

Simultaneous Detection of GABA and ATP Release
If GABA coreleased with serotonin reflects exocytosis of LDCVs,then GABA release should also associate with ATP release. Weaddressed this by overexpression of GABA_A and P₂X₂ receptorsin the same ß cells. To resolve both GABA- and ATP-evokedtransient currents, the intracellular medium contained 12 mMCl^–, and the membrane potential was alternated between+10 and –60 mV with a period of 20 ms (Fig. 5 A, inset). With the combination of extra- and intracellular solutions usedfor this series of experiments, these voltages are close tothe reversal potentials of the currents flowing through theP₂X₂ and GABA_A receptors, respectively. Exogenous applicationof a mixture of GABA and ATP confirmed that both current typescould be detected simultaneously using this protocol (Fig. S2).The peak outward (GABA) and inward (ATP) currents evoked by0.1 mM of either agonist averaged 1.8 ± 0.4 nA and –5.4± 1.2 nA, respectively (n = 7).

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Figure 5. Parallel monitoring of GABA and ATP release. (A, inset) Schematic of voltage protocol used to near-simultaneously resolve GABAergic and purinergic transient currents in cells infected with both GABA_A and P₂X₂ receptors. The membrane potential was rapidly (50 Hz) alternated between E_Cl (–60 mV) and E_P2X2 (+10 mV). (A) Sample recording showing ATP-induced inward currents (black arrows) and GABA-induced outward currents (white arrows) in a double-infected ß-cell. Exocytosis was triggered by infusion of 0.2 µM free Ca²⁺ through the recording electrode. The largest inward currents have been truncated for display purposes. (B) Examples of an ATP-induced inward current and a GABA-induced outward response, marked by dashed boxes in A, shown on an expanded time base. In the right part, the current artifacts when switching between –60 and +10 mV have been removed and only current components at +10 and –60 mV are shown. The segments of the current recordings at the respective voltages have been connected by gray lines. (C) Examples of different types of events with a dominant inward current component: (i) inward current in isolation; (ii) clear out- and inward components; (iii) an outward component superseded by the activation of the inward current. The inward currents at –60 mV have been truncated for display purposes.

Fig. 5 A shows a recording of spontaneous events from a ß-cellinfected with both P₂X₂ and GABA_A receptors. Exocytosis wasstimulated by inclusion of 0.2 µM free Ca²⁺ in the pipettesolution. Several transient GABA-induced outward currents (whitearrows) and ATP- dependent inward currents (black arrows) aresuperimposed on the oscillating background current. Fig. 5 Bshows an outward and an inward current from Fig. 5 A on an expandedtime base. In 11 cells, a total of 109 isolated outward currentsat +10 mV (reflecting GABA release) and 607 isolated inwardcurrents at –60 mV (representing ATP release) were observed.The current amplitude in the outward and inward directions averaged25 ± 4 pA and –341 ± 98 pA, respectively.We also detected 16 events (in eight cells, 2.6% of all ATP-inducedTICs), which showed both inward and outward current components(Fig. 5 C, traces ii and iii). In these 16 events, the outwardand inward currents averaged 30 ± 6 and –234 ±60 pA, respectively. In some cases, the outward current wasvery short-lived and rapidly superseded by the development ofan inward current (Fig. 5 C, trace iii).

Analysis of Tonic Activity of GABA_A Receptors
Biochemical measurements have shown that ß cells release25% of their GABA contents per hour in the presence of 3 mMglucose (Smismans et al., 1997). Since insulin is not releasedat this low glucose concentration, exocytosis of the LDCVs isunlikely to account for this release. We have performed patch-clampexperiments on islet cell clusters overexpressing GABA_A receptorsin the presence of 1 mM extracellular glucose. The patch-clampedcell was held at –70 mV and infused with a high concentrationof EGTA to suppress Ca²⁺-dependent exocytosis. GABAergic TICswere observed extremely rarely under these conditions (<1event/h). However, even in the absence of identifiable vesicularrelease, bath application of the GABA_A receptor antagonist SR95531(10 µM) reversibly blocked a part of the holding current(Fig. 6 A) and reduced the current noise (Fig. 6, B and C). In a series of five experiments, SR95531 reduced the mean holdingcurrent by 30 ± 10 pA (P < 0.05) and the current varianceby 74 ± 6% (P < 0.05). No SR95531-sensitive currentwas observed in individual glucagon-producing ${alpha}$ cells infectedwith the GABA_A receptors to about the same extent as the ßcells. The unitary amplitude of the events contributing to theexcess (SR95531-sensitive) noise was estimated by stationaryfluctuation analysis (Hille, 2001). In a series of four experiments,a unitary amplitude of 2.0 ± 0.2 pA was obtained. Witha reversal potential of –5 mV (as expected for a Cl^–current with the ionic gradients used in this experiment), thiscurrent amplitude corresponds to a unitary conductance of 31± 6 pS (n = 4). A similar value (27 pS) was obtainedby noise analysis of the current that develops when a low concentrationof GABA (1 µM) is applied to isolated outside-out patches(unpublished data).

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Figure 6. Evidence for tonic GABA release from ß cells. (A) The recording was made in a ß-cell overexpressing GABA_A receptor Cl^– channels within a cell cluster. The holding current at –70 mV was measured in the presence of 1 mM extracellular glucose with intracellular solution containing 10 mM EGTA. The GABA_A receptor antagonist SR95531 (10 µM) was added to the bath as indicated by the bar. A segment of $~$ 2 min during the washout of SR95531 has been removed. (B) Current segments marked by asterisks (*) in A shown at expanded time base. (C) Variance of current before, during, and after addition of SR95531 (as indicated by the horizontal line).

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The role of GABA in the pancreas and the cellular processesinvolved in its release from the ß-cell remain obscure.We have investigated whether GABA and insulin are released bythe same or a distinct exocytotic pathway. Here we attempt tohighlight some of the more important implications of the datathat have emanated from this work.

ATP and Serotonin Are Coreleased by Exocytosis of LDCV
Using a modified carbon fiber electrode, Aspinwall et al. (1999)demonstrated corelease of insulin and serotonin. We now demonstratethat almost 80% (in some experiments being close to 100%) ofthe exocytotic events detected as the release of serotonin alsoassociated with ATP release. Thus, measurements of ATP can beregarded as an endogenous reporter of LDCV exocytosis in pancreaticß cells. The fact that this P₂X₂ receptor-based methodmonitors exocytosis in the entire cell (and not just in thepart of the membrane closest to the carbon fiber) makes it possibleto directly correlate changes in cell capacitance to the numberof exocytotic events (Fig. 2). We were thereby able to estimatethat the release of one ATP quantum was associated with an averagecapacitance increase of 3.4 fF (Fig. 2). This value correspondsto vesicle with a diameter of 310 nm (assuming spherical geometryand a specific capacitance of 9 fFµm^–2), close tothe 330 nm determined for ß-cell LDCVs by electronmicroscopy (Braun et al., 2004a).

Low Molecular Weight Granule Constituents Are Differentially Released via the Fusion Pore
We have previously reported that ATP and serotonin can be releasedvia the fusion pore that connects the granule lumen with theextracellular space (MacDonald et al., 2006). Here we have characterizedthe GABA-, ATP-, and serotonin-dependent pedestals in greaterdetail. Based on the relative amplitudes of the pedestals, itappears that the fusion pore restricts the passage of ATP significantlymore than that of serotonin and GABA. Occasionally, there wasno sign of a pedestal in the ATP measurements although it wasprominent in the amperometric recording. This may contributeto the finding that the correlation between serotonin and ATPrelease was <100% in some experiments (see above). The dimensionsof ATP, serotonin, and GABA are $~$ 1.6 x 1.1 x 0.5 nm, $~$ 1.0 x 0.5x 0.2 nm, and 0.75 x 0.3 x 0.2 nm, respectively. The diameterof the ß-cell LDCV fusion pore is $~$ 1.4 nm (MacDonaldet al., 2006). This predicts that whereas GABA and serotoninwill be easily accommodated within the fusion pore, the movementsof ATP will be more restricted. The occurrence of isolated GABA-inducedTICs without simultaneous ATP release (Fig. 5, A and B) we attributeto partial opening of the fusion pore, sufficient to allow theexit of the GABA but not of the bigger ATP molecule. The above"permeability sequence" ATP < serotonin < GABA for thefusion pore is precisely that predicted from their relativesize. Evidence for the fusion pore to "filter" small moleculeshas also been obtained in synaptic vesicles (Gandhi and Stevens,2003). Thus, exocytosis through fusion pores ("kiss-and-run")provides cells with a mechanism to differentially release smallmolecular weight transmitters from individual vesicles.

Is GABA Released by Exocytosis of SLMVs, LDCVs, or Both?
Serotonin is a selective marker of the insulin-containing LDCVs(Kasai, 1999) and our value for the CV of the distribution ofthe amperometric charges as well as that reported by others(Finnegan et al., 1996) are consistent with this conclusion.We found that 22% of the GABA-dependent TICs associated withsimultaneous serotonin release. This argues that some GABA isreleased by exocytosis of LDCVs. This conclusion is reinforcedby the observation that there were no differences in the risetime, halfwidth, and charge between amperometric events thatassociated with GABA release and those that did not. If a subpopulationof the amperometric events was due to exocytosis of SLMVs, thisshould be reflected in different amplitudes and kinetics ofthe events (compare Bruns et al., 2000). The conclusion thatGABA is released by exocytosis of the insulin granules is alsounderpinned by ultrastructural data indicating that ß-cellLDCVs do contain GABA (Gammelsaeter et al., 2004; this study).

How big is the relative contribution of LDCVs to the GABA releaseobserved? If we take the 29% of the ATP-induced TICs that associatedwith serotonin release as the maximum, then at least 75% ofthe GABA release events (i.e., 22%/29%) are attributable toexocytosis of LDCVs. Thus, we conclude that exocytosis of LDCVsaccounts for most (if not all) depolarization-evoked GABA release.Three observations provide further support of this conclusion.First, GABA-induced TICs associated with amperometric eventshad the same charge as those occurring without release of serotonin.Second, the first latencies of the GABA- and ATP-induced TICwere the same (Fig. 1, C and D), a finding not consistent withthe idea that GABA is released by exocytosis of SLMVs sinceexocytosis of SLMVs has been shown to give rise to a rapid phaseof the capacitance response after elevation of [Ca²⁺]_i in ratß cells (Takahashi et al., 1997). Third, histogramsof the charge distribution of GABA-induced TICs consistentlyshowed only one peak (Braun et al., 2004a; this study, Fig. 4 D),compatible with one population of GABA-releasing vesicles.

This conclusion is opposed to our previous study (Braun et al.,2004a), where we postulated that the observed release of GABAis due to exocytosis of SLMVs. This was largely based on earlierpublications associating these vesicles with uptake and storageof GABA and GAD65 (Reetz et al., 1991; Thomas-Reetz et al.,1993), and our own morphological data showing relative exclusionof GABA from LDCVs. While we confirmed the latter in this study(Fig. 4 C), in depth analysis suggests that a subpopulation( $~$ 15%) of LDCVs does contain GABA and may therefore account forthe observed current transients. Release of GABA from a subpopulationof LDCVs comprising 10–20% of the total granule numberis in fact in good agreement with the earlier finding that thenumber of GABA-induced TICs is only $~$ 10% of the number of LDCVsundergoing exocytosis suggested by the capacitance increasemeasured in parallel (Braun et al., 2004a). Uneven loading ofLDCVs with the transmitter (some containing less, some morethan the average) would also explain why the CV in histogramsof GABA-induced TIC charges (0.43) is twice as large as thatexpected from the distribution of LDCV diameters (CV 0.22; Finneganet al., 1996; Braun et al., 2004a).

The observation that corelease of GABA and ATP was rarely observedmay appear in conflict with the conclusion that GABA is principallyreleased by LDCV exocytosis. However, this may be attributableto the presence of a small inward current during ATP-inducedevents even at +10 mV (i.e., at the voltage used to detect GABArelease), amounting to $~$ 5% of the current amplitude at –60mV (Fig. S2; Fig. 5 C, i). As the average amplitude of thiscomponent (5% of 340 pA = 17 pA) is close to the average amplitudeof the GABA release–induced outward currents (25 pA),it may conceal the GABAergic signal in many cases (see alsoFig. 5 C, iii).

Are SLMVs Involved in Unregulated Release of GABA?
Biochemical measurements indicate that ß cells release1 amol of GABA per ß-cell and second in a way largelyunaffected by glucose as well as pharmacological and hormonalregulators of insulin secretion (Winnock et al., 2002). Thissuggests that, in addition to the vesicular release of GABAgiving rise to the TICs discussed above, ß cells arealso equipped with a second pathway for release of the neurotransmitter.It is possible that the SR95531-inhibitable current observedin ß cells within islet cell clusters in the absenceof stimulatory glucose concentration (Fig. 6) reflects thisbackground release of GABA. Our noise analysis of the SR95531-sensitivecurrent indicates that the conductance of the unitary eventis $~$ 30 pS. This value is close to the single-channel conductanceof GABA_A receptor Cl^– channels (Conley, 1996). Thus, backgroundrelease of GABA only triggers opening of individual channelswith no indication of phasic responses, which would be expectedif GABA was released in a quantal fashion. It is therefore unlikelythat exocytosis of SLMVs accounts for the background releaseof GABA.

Concluding Remarks
The data presented here argue that GABA can be released by glucose-dependent(vesicular) and -independent (nonvesicular) pathways, and thatvesicular release of GABA involves exocytosis of LDCVs. In thelatter pathway, GABA is often coreleased with ATP and insulin,although we demonstrate that release through the early fusionpore is strongly molecule dependent. While evidence exists indicatingthat SLMVs in ß cells both store GABA (Reetz et al.,1991; Gammelsaeter et al., 2004) and undergo exocytosis (MacDonaldet al., 2005), the role of SLMVs in GABA release has not beenpossible to document. We acknowledge that if the GABA contentper SLMV is <10% of an LDCV (the intravesicular concentrationof GABA in the SLMVs would still be greater than fivefold higherthan in the LDCVs; cf. Gammelsaeter et al., 2004), the TIC wouldbe below our detection limit. SLMV exocytosis has been reportedto proceed initially at very high rates (500 SLMVs being releasedover 50 ms; Fig. 2 A of Takahashi et al., 1997). Accordingly,even if every SLMV delivers only a small quantum of GABA, exocytosisof many SLMVs may, at least transiently, contribute significantlyto ß-cell GABA release.

Nonetheless, the observation of parallel regulated and unregulatedGABA release pathways suggests roles for this inhibitory neurotransmitterin modulating both the baseline excitability of islet cellsand their response to glucose stimulation. Further investigationof these two pathways will provide important insight into theintra-islet regulation of hormone release.

ACKNOWLEDGMENTS

This work was supported by the Wellcome Trust (WT072289) andthe European Union through the Network of Excellence BioSim(LSHB-CT-2004-005137) and Integrated Project Eurodia (LSHM-CT-2006-518153).P. Rorsman is a Wolfson-Royal Society Merit Award Research Fellow.

Olaf S. Andersen served as editor.

Submitted: 30 August 2006
Accepted: 26 January 2007

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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				W. H. Roden, J. B. Papke, J. M. Moore, A. L. Cahill, H. Macarthur, and A. B. Harkins Stable RNA interference of synaptotagmin I in PC12 cells results in differential regulation of transmitter release Am J Physiol Cell Physiol, December 1, 2007; 293(6): C1742 - C1752. [Abstract] [Full Text] [PDF]