Quantal Release of ATP in Mouse Cortex

doi:10.1085/jgp.200609693

Published online February 26, 2007
doi:10.1085/jgp.200609693
The Journal of General Physiology, Vol. 129, No. 3, 257-265
The Rockefeller University Press, 0022-1295 $30.00
© 2007 Pankratov et al.

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ARTICLE

Quantal Release of ATP in Mouse Cortex

Yuriy Pankratov, Ulyana Lalo, Alexei Verkhratsky, and R. Alan North

Faculty of Life Sciences, University of Manchester, Manchester M13 9PT, UK

Correspondence to R. Alan North: alan.north{at}manchester.ac.uk

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Transient currents occur at rest in cortical neurones that reflectthe quantal release of transmitters such as glutamate and ${gamma}$ -aminobutyricacid (GABA). We found a bimodal amplitude distribution for spontaneouslyoccurring inward currents recorded from mouse pyramidal neuronesin situ, in acutely isolated brain slices superfused with picrotoxin.Larger events were blocked by glutamate receptor (AMPA, kainate)antagonists; smaller events were partially inhibited by P2Xreceptor antagonists suramin and PPADS. The decay of the largerevents was selectively prolonged by cyclothiazide. Stimulationof single intracortical axons elicited quantal glutamate-mediatedcurrents and also quantal currents with amplitudes correspondingto the smaller spontaneous inward currents. It is likely thatthe lower amplitude spontaneous events reflect packaged ATPrelease. This occurs with a lower probability than that of glutamate,and evokes unitary currents about half the amplitude of thosemediated through AMPA receptors. Furthermore, the packets ofATP appear to be released from vesicle in a subset of glutamate-containingterminals.

Abbreviations used in this paper: CNQX, 6-cyano-7-nitroquinoxaline-2,3-dione;D-APV, D-2-amino-5-phosphonovalerate; GABA, ${gamma}$ -aminobutyric acid;eEPSC, evoked excitatory postsynaptic current; mEPSC, miniatureEPSC; NBQX, 2,3-dihydroxy-6-nitro-7-sulfamoyl-benzo(f)quinoxaline;PPADS, pyridoxaphosphate-6-azophenyl-2'-4'-disulphonic acid;SYM2081, [2S,4R]-4-methylglutamic acid.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

An elementary event of synaptic transmission is a spontaneousrelease of packet or quantum of transmitter. At the neuromuscularjunction this corresponds to the acetylcholine content of asingle vesicle (Katz and Miledi, 1963), although in the centralnervous system the situation is more complex (Redman, 1990;Auger and Marty, 2000). Such spontaneous neurotransmitter releaseis manifest electrically by miniature excitatory postsynapticcurrents (mEPSCs) and miniature inhibitory postsynaptic currents(mIPSCs). In the mammalian central nervous system, the transmittersproducing mEPSCs and mIPSCs are thought to be almost exclusivelyglutamate and ${gamma}$ -aminobutyrate (GABA).

Ionotropic P2X receptors, at which extracellular ATP directlygates a cation-permeable channel, are widely expressed throughoutthe central nervous system (Collo et al., 1996; Verkhratskyet al., 1998; Norenberg and Illes, 2000; Verkhratsky and Steinhauser,2000; Khakh, 2001; North, 2002; North and Verkhratsky, 2006).Evoked synaptic transmission mediated by ATP acting at P2X receptorshas been reported in several regions of CNS in situ, includingmedial habenula (Edwards et al., 1992; Edwards et al., 1997),hippocampus (Pankratov et al., 1998; Mori et al., 2001), locuscoeruleus (Nieber et al., 1997), dorsal horn (Bardoni et al.,1997; Jo and Schlichter, 1999), and cerebral cortex (Pankratovet al., 2002, 2003). However, the amplitude of the evoked synapticcurrents remaining after block of glutamate receptors (and presumedto be purinergic) is typically very small; some 5–15%of that of the initial unblocked current. The identificationof such evoked synaptic currents has been hampered by theirsmall amplitude and lack of highly selective P2X receptor blockers.

Mechanisms of ATP release have proved controversial, with proposalsincluding mechanical deformation, gap junction hemichannels(Pearson et al., 2005), or the chloride channels of the cysticfibrosis conductance regulator (for review see Sperlagh andVizi, 2001). However, any central neurotransmitter role forATP should be associated with the quantal release of ATP-storingvesicles, as was originally reported for the release of ATPfrom sympathetic nerves (Burnstock and Holman, 1961). In neuronescultured from the lateral hypothalamus of the embryonic chickor neonatal mouse, spontaneous mEPSCs have also been observedin the presence of blockers of glutamate and GABA receptors(Jo and Role, 2002). Similarly ATP-mediated mEPSCs were occasionallydetected in neurones from medial habenula (Edwards et al., 1997).Nevertheless, there has been no biophysical analysis of suchevents, no systematic reports of their occurrence in intactneuronal tissue and, more crucially, no effort to determinewhether they correspond to the unitary events underlying evokedpurinergic transmission. The purpose of the present experimentswas to test the hypothesis that ATP was released from vesiclesin the cerebral cortex, and to measure the quantal parametersof ATP-mediated component of evoked and spontaneous EPSCs.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Electrophysiology
CBL57 mice (15–45-d-old) were killed according to UK legislation.Brains were removed rapidly and placed into ice-cold saline(in mM) NaCl 138, KCl 3, CaCl₂ 0.5, MgCl₂ 2.5, NaH₂PO₄ 1, NaHCO₃25, glucose 15, pH 7.4 gassed with 95% O₂–5% CO₂. Transverseslices ( $~$ 300 µm) were kept for 1–4 h before recordingat 22–24°C, in the above solution but with (in mM)CaCl₂ 2.5, MgCl₂ 1. Somatosensory cortex layer 2/3 neuroneswith pyramidal shaped somata were selected using an infrareddifferential interference contrast optics, and recordings weremade with patch pipettes (4 M ${Omega}$ ) filled with (in mM) 50 KCl, 55K-gluconate, 10 NaCl, 10 HEPES, 2 MgATP, 0.1 EGTA, pH 7.35.In some experiments, the intracellular solution was used toset the chloride reversal potential at –60 mV; it contained(in mM) 3 CsCl, 102 Cs-gluconate, 10 NaCl, 10 HEPES, 2 MgATP,0.1 EGTA, pH 7.35. The membrane potential was set at –80mV unless stated otherwise. Junction potentials were nulledwith an open electrode in the recording chamber before eachexperiment. The series and the input resistances were 4–12M ${Omega}$ and 500–1,300 M ${Omega}$ , respectively; in cells accepted foranalysis these varied by <20%.

EPSCs were evoked by stimulating axons originating from layerV neurones with a bipolar glass electrode (2–3-µmtip diameter) containing extracellular solution. The electrodewas placed in layer V close to the layer IV border, stimulusduration was 100 µs, and the frequency was 0.3 Hz. Theintensity was set either at a minimal level (10–20% higherin intensity than threshold at which EPSC appeared; typically0.7–1.2 µA) or at a stronger level (evoked EPSCswith amplitude two to four times greater than those evoked byminimal stimulation, but also failures in at least 10–20%of trials, typically 1.5–3 µA). Minimal level stimulationwas set to meet the criteria of single-axon stimulation (Yoshimuraet al., 2000) including all-or-none synaptic response, littlevariation in EPSC latencies, and absence of change in the meansize or shape of the EPSC with 20–50% increase in stimulusintensity. Hence minimal stimulation most likely activates asingle fiber (Yoshimura et al., 2000; Rubio and Soto, 2001)whereas stronger stimulation would presumably activate severalaxons.

Spontaneous miniature excitatory synaptic currents (mEPSCs)were recorded in tetrodotoxin (1 µM) and picrotoxin (100µM), except where stated. Currents were monitored usingan EPC-9 amplifier (HEKA), filtered at 3.9 kHz, and digitizedat 10 kHz. Experiments were controlled by PULSE/PULSEFIT software(HEKA) and data were analyzed by self-designed software.

Data Analysis
Quantal analysis of evoked synaptic currents was as previouslydescribed (Pankratov and Krishtal, 2003). Spontaneous inwardcurrents of amplitude higher than two SD of baseline noise wereselected, each analyzed in a 140-ms window (40 ms before and100 ms after peak). The mEPSC peak amplitude was determinedusing a computer routine based on the fitting of each currenttrace by the model curve with single exponential rise and decayphases. The minimal square root procedure was used to determinethe amplitude of the model curve, while the time constants andoffset were optimized by the gradient method to minimize themean square error. The mean square error of the fit was <25%amplitude. A set of 800–1,500 mEPSCs or EPSCs was recordedand used for statistical analysis in each cell tested. Amplitudedistributions were analyzed with probability density functionsand likelihood maximization techniques (Stricker et al., 1996a,b).The distributions of amplitude and decay time of spontaneousmEPSCs were fitted with bimodal function consisting with variablepeak location, width, and amplitude, and weights were calculatedas the integrals of the corresponding Gaussian functions. Amplitudedistributions of evoked EPSCs were fitted with multiquantalbinomial or single-quantal models comprising two Gaussian functions,with one peak location fixed at zero and the second variablepeak.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Two Populations of mEPSCs
Amplitudes of mEPSCs showed a clear bimodal distribution withpeaks at 7.1 ± 2.9 and 13.4 ± 4.8 pA (Fig. 1);in all 61 neurones this was best fit by two Gaussians (maximumlikelihood method, P < 0.05). The overall mean amplitude(in 1 µM tetrodoxin and 100 µM picrotoxin) was 11± 4 pA (n = 61), and the frequency was 1.6 ± 0.7Hz (n = 61; Fig. 1 A). The high-amplitude mEPSCs were selectivelyand reversibly blocked by glutamate receptor antagonists (AMPA/kainatereceptor blockade: 50 µM 6-cyano-7-nitroquinoxaline-2,3-dione[CNQX]; NMDA receptor blockade: 30 µM D-2-amino-5-phosphonovalerate[D-APV]; kainate receptor desensitization: 10 µM [2S,4R]-4-methylglutamicacid [SYM2081]; Fig. 1 B; we used a mixture of several ionotropicglutamate receptors antagonists and kainate receptor desensitizingagent SYM2081 to ascertain complete inhibition of glutamatetransmission). In this antagonist cocktail, mEPSCs of loweramplitude were observed in 41 of the 45 cells at 0.49 ±0.28 Hz; their mean amplitude (7.6 ± 2.8 pA) was thesame as that of the lower peak of the control bimodal distribution;their amplitude was unchanged even in a higher CNQX concentration(100 µM; n = 8). Selective inhibition of the higher amplitudemEPSCs was also observed with (a) AMPA/kainate receptor blocker2,3-dihydroxy-6-nitro-7-sulfamoyl-benzo(f)quinoxaline (NBQX,100 µM) and D-APV (30 µM), n = 8; (b) CNQX (50 µM)and the nonspecific glutamate receptor blocker kynurenic acid(2 mM), n = 5; and (c) the noncompetitive AMPA receptor (±)-4-(4-aminophenyl)-1,2-dihydro-1-methyl-2-propylcarbamoyl-6,7-methylenedioxyphthalazine (SYM 2206, 50µM) with SYM2081 (10 µM) and D-APV (30 µM),n = 7. These results strongly suggest that the residual lowamplitude population of mEPSCs does not involve ionotropic glutamatereceptors.

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Figure 1. Two populations of mEPSC amplitudes. (A) Control mEPSCs in TTX (1 µM) and picrotoxin (100 µM), after addition (red) and washout (blue) of CNQX (50 µM), SYM2081 (3 µM), and D-APV (30 µM). (B) Amplitude histogram of mEPSCs from the cell shown in A. Note the disappearance of the larger peak after the inhibition of glutamate receptors (red) and washout (blue).

The low-amplitude mEPSCs were partially inhibited by PPADS (3µM, Fig. 2 A) and suramin (10 µM, Fig. 2 B), whichboth block most of P2X receptor subtypes (North and Surprenant,2000

). PPADS (3 µM) reduced the amplitude (by 24 ±16%, n = 14) and frequency (by 43 ± 27%, n = 8) of low-amplitudemEPSCs. When suramin was washed out and replaced by glutamatereceptor blockers (CNQX, SYM2081, and D-APV), the low-amplitudemEPSCs reappeared and the higher amplitude events were blocked(Fig. 2, B and C). When added in the presence of NBQX and D-APV,suramin (10 µM) also reduced the amplitude (by 55 ±8%, n = 7) and frequency (47 ± 24%, n = 7) of the low-amplituderesidual mEPSCs (unpublished data). This effect was mimickedby the suramin analogue 8,8'-(carbonylbis(imino-4,1-phenylenecarbonylimino-4,1-phenylenecarbonylimino)) bis(1,3,5-naphthalenetrisulfonicacid) (NF279, 1 µM; see Rettinger et al., 2000

), whichalso substantially blocked the residual mEPSCs when added inthe presence of NBQX and D-APV; the amplitude of mEPSCs wasreduced by 31 ± 9% and their frequency by 44 ±20% (n = 5). 8-Cyclopentyl-1,3-dipropylxanthine (DCPCX, 1 µM;an adenosine A₁ receptor antagonist) and hexamethonium (100µM; a nicotinic receptor blocker) had no effect on themEPSCs.

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Figure 2. Selective block of high and low amplitude mEPSCs. (A) mEPSCs in control conditions, in CNQX (50 µM), SYM2081 (10 µM), and D-APV (30 µM, 5 min; red), and after the further addition of PPADS (3 µM, 5 min; blue). Right panel shows distributions of mEPSC amplitudes. Glutamate receptor blockade removed the high amplitude mEPSCs (red), and subsequent addition of PPADS reduced the amplitude of the remaining mEPSCs (blue). (B) mEPSCs in control conditions, in suramin (10 µM, 5 min; blue), and after further addition of CNQX (50 µM), SYM2081 (10 µM), and D-APV (30 µM, 5 min; red). Right panel shows distributions of EPSC amplitudes. Note that suramin blocked the lower amplitude mEPSCs (blue), and subsequent addition of glutamate receptor blockers strongly reduced the occurrence of the larger mEPSCs (red). (C) Summary of the differential sensitivity of low- and high-amplitude mEPSCs to suramin and ionotropic glutamate receptor antagonists. All recordings were made in TTX (1 µM) and picrotoxin (100 µM).

Cyclothiazide reduces desensitization of AMPA receptors (Partinet al., 1993

). Cyclothiazide (50 µM) prolonged the decayof a subset of mEPSCs (Fig. 3). Thus, in cyclothiazide thedistribution of ${tau}$ _decay changed from unimodal to bimodal (Fig. 3 C; ${tau}$ _decay 8.9 ± 1.6 and 16.8 ± 2.5 ms, n = 5). Thetime constants of rise and decay of mEPSCs were not affectedby CNQX (50 µM; control: ${tau}$ _rise 1.1 ± 0.6 ms, ${tau}$ _decay9.5 ± 1.9 ms, n = 65 cells; CNQX: ${tau}$ _rise 1.2 ± 0.5ms and ${tau}$ _decay 9.8 ± 2.1 ms, n = 61 cells), but cyclothiazidedid not change the decay of mEPSCs in the presence of CNQX (50µM; Fig. 3 A). In cyclothiazide, PPADS (3 µM) substantiallyblocked the rapidly decaying mEPSCs, without much affectingthe slower mEPSCs (Fig. 3). We hypothesize from these resultsthat the population of smaller amplitude, cyclothiazide-insensitivemEPSCs are mediated by ATP acting on P2X receptors.

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Figure 3. Cyclothiazide selectively prolongs larger mEPSCs. (A) A large mEPSC that is markedly prolonged by cyclothiazide (50 µM, red) and a smaller mEPSC that is unaffected by cyclothiazide. In PPADS (3 µM), cyclothiazide (50 µM) increased the duration of all mEPSCs, but in CNQX (50 µM), cyclothiazide had no effect on mEPSCs. (B) Distribution of decay time constants ( ${tau}$ _decay) of mEPSCs. Black, control; red, cyclothiazide (50 µM); Blue, cyclothiazide and PPADS (3 µM). Note the appearance of slowly decaying mEPSCs in cyclothiazide and the selective inhibition of faster decaying mEPSCs by PPADS. (C) mEPSC amplitude vs. decay time constant for control (top, 1,700 events) and cyclothiazide (bottom, 900 events) for five cells. All recordings were in TTX (1 µM) and picrotoxin (100 µM).

Both populations (low and high amplitude) of mEPSCs were enhancedby ${alpha}$ -latrotoxin, which is a potent stimulator of vesicular exocytosis(Ushkaryov et al., 2004

); latrotoxin (300 nM, 5–10 min)increased frequency of control mEPSCs by 84 ± 9% (n =6) and low-amplitude nonglutamatergic mEPSCs by 127 ±12% (n = 6; unpublished data). Bafilomycin blocks vesicularrefilling (Zhou et al., 2000

); bafilomycin (1 µM, 2 h)reduced the frequency of mEPSC in control conditions by 95%(n = 4) and completely eliminated the low- amplitude mEPSC infour cells tested.

ATP mEPSCs Are Independent of Glutamate and GABA Release
The asynchrony between the two populations of mEPSCs indicatesthat the release of ATP and glutamate is unrelated. However,there is evidence from cultured hypothalamic neurones that ATPmight be coreleased with GABA (Jo and Role, 2002). To test forthe corelease of ATP with GABA, we recorded spontaneous synapticcurrents in the presence of CNQX (50 µM) and D-APV (30µM) but without picrotoxin. We used a cesium gluconateintracellular solution to separate the cationic currents throughP2X receptors (reversal potential $~$ 0 mV) and chloride currentsthrough GABA receptors (reversal potential about –60 mV;the extracellular solution contained TTX [1 µM] as well).Spontaneous events at –80 mV (Fig. 4 A) comprised of twotypes of inward current: one had smaller amplitude (6.9 ±2.1 pA) and faster decay ( ${tau}$ _decay 9.7 ± 1.9 ms; 44 ±10% of events), and the other larger amplitude (13.8 ±3.7 pA) and slower decay ( ${tau}$ _decay 19.2 ± 5.5 ms; n = 6;56 ± 11% of events; n = 6 throughout).

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Figure 4. ATP release is asynchronous with GABA release. (A) Representative spontaneous currents recorded in TTX (1 µM), CNQX (50 µM), and D-APV (30 µM), in neurones with cesium-gluconate intracellular solution (E_Cl = –60 mV). At –80 mV, all currents are inward, but some decay more slowly than others. At –40 mV, GABA-mediated currents are outward (red arrows) and ATP-mediated currents are inward (blue arrows). Bicuculline (30 µM) completely inhibited outward currents. (B) Distribution of inactivation time constants ( ${tau}$ _decay) of currents recorded at –80 mV (binominal distribution corresponding to two populations of currents) and at –40 mV. At –40 mV, the outward currents (GABA mediated, red) decay much more slowly than the inward currents (ATP mediated, blue).

At –40 mV, both inward (cationic) and outward (chloride)currents were observed (Fig. 4 A, bottom traces). Inward currentshad ${tau}$ _decay of 9.9 ± 2.3 ms; they were resistant to bicucullineand inhibited by PPADS (3 µM: by 26 ± 12%, n =4). They occurred at 41 ± 13% of the frequency of theevents recorded at –80 mV (n = 6). Outward currents had ${tau}$ _decay of 21.1 ± 8.5 ms; they were abolished by bicuculline(30 µM, n = 6). They occurred at 50 ± 15% (n =6) of the control frequency. Therefore, these two distinct populationsof spontaneous events are likely to be mediated by P2X receptors(inward, faster kinetics) and GABA receptors (outward, slowerkinetics).

We infer that ATP is not released synchronously with GABA, becausethe superimposition of inward and outward currents at –40mV would result in currents of very small net amplitude andtherefore lead to a decrease in the amplitude and frequencyof apparent spontaneous currents. In fact, the sum of the frequenciesof fast inward (ATP-mediated) and slow outward (GABA-mediated)mEPSCs recorded at –40 mV was not different from thatof all mEPSCs at –80 mV (Fig. 4 B), which is consistentwith the hypothesis of noncoordinated release.

Quantal Analysis of Evoked EPSCs
Experiments using receptor antagonists suggested that a smallcomponent of the evoked EPSC (eEPSC) in rat cortical neuronesresults from ATP acting at P2X receptors (Pankratov et al.,2002, 2003). This implies that unitary components of the eEPSCcorresponding to the ATP-mediated mEPSC should be detectableat this synapse. Vertical axons originating from layer V neuroneswere stimulated with either minimal or stronger stimulation(see Materials and methods). Minimal stimulation most likelyactivated a single fiber providing input to the pyramidal neurone(Gil et al., 1999; Yoshimura et al., 2000), whereas strongerstimulation presumably activated several axons. We recordedexcitatory synaptic currents, evoked and spontaneous, firstin picrotoxin (100 µM) and D-AP5 (30 µM), whichwere our control condition and then again after further additionof CNQX (50 µM) and SYM2081 (10 µM; Fig. 5).

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Figure 5. Evoked and spontaneous EPSCs. (A) Minimal stimulation evoked EPSCs, which often fail; these are blocked by CNQX (50 µM) and SYM2081 (10 µM). Stronger stimulation evoked EPSCs, which sometimes fail, but which are incompletely blocked by the glutamate antagonists. (B) Amplitude distributions of the EPSCs evoked by minimal (top panel) and stronger stimulation (bottom panel) before and after adding glutamate receptor blockers (50 µM CNQX and 10 µM SYM2081). (C) Time course of experiment such as illustrated in A. Top graph shows the amplitudes of evoked EPSCs and bottom graph shows amplitudes of spontaneous mEPSCs, recorded in between the stimulations. All in picrotoxin (100 µM) and D-APV (30 µM).

The results were of two kinds. In 19 out of 35 cells, the EPSCevoked by minimal stimulation was completely blocked by CNQXand SYM2081 (Fig. 5 A, top). The amplitude distribution of theevoked EPSC had a single peak located at $~$ 4–12 pA (Fig. 5 B,top); it was better fit by a single-quantal model than by aunimodal nonquantal model (confidence level ${alpha}$ < 0.01, n =19) or a multi-quantal binomial model ( ${alpha}$ < 0.05 for 14 of19 cells). The average quantal size was 9.3 ± 5.2 pA;the difference between quantal size of the unitary evoked EPSCand the mean amplitude of spontaneous glutamatergic mEPSC wasnot statistically significant (P > 0.05, ANOVA test). Withstronger stimulation in these cells, eEPSCs were observed inthe presence of glutamate receptor antagonists in all 19 cellstested (Fig. 5 B, bottom); these residual eEPSCs were decreasedin amplitude by 39 ± 17% in PPADS (10 µM, n = 4),similar to previous results (Pankratov et al., 2002

, 2003

).The eEPSC amplitude distribution exhibited multiple peaks (Fig. 5 B,bottom) and was well fit by a multiquantal binomial model (confidencelevel ${alpha}$ < 0.05) for all 19 cells. The maximal number of quantawas 2.4 ± 1.3, the mean quantal content (product of numberof quanta and release probability) was 1.4 ± 0.8 (n =19), and the quantal size was 9.2 ± 5.5 pA. This amplitudedistribution became single quantal in glutamate receptor antagonists(CNQX, SYM2081; in 14 of 19 cells; Fig. 5 B, bottom). The averagequantal size of the residual component was 6.8 ± 2.9pA; the maximal number of quanta was 1.6 ± 0.9, and themean quantal content was 0.36 ± 0.15 (n = 19). Theseresults indicate that the minimal stimulation results in synaptictransmission at a single synapse that does not have any purinergiccomponent, but that an increase in the stimulus strength recruitsfurther fibers that result in synaptic transmission at additionalsynapses, some of which do have a purinergic component.

In the second group (16 of 35 cells), the EPSC evoked with minimalstimulation was not completely blocked by the glutamate receptorantagonists (Fig. 6 A); the residual current was partially inhibitedby purinergic antagonist PPADS. The amplitude distributionof eEPSCs at minimal stimulation was very different from thatseen in the first group of cells, because it exhibited several(typically three) peaks; this changed to a single peak afterblockade of glutamate receptors (Fig. 6 B). The initial amplitudedistribution was best fit by a compound model with two separateunderlying components (Fig. 6 B). The first was single quantalin all 16 cells and had lower release probability and smallerquantal size, similar to the quantal size of the current remainingin CNQX and SYM2081 (component "1," Fig. 6 C). The second componenthad a larger quantal size and was single quantal in 11 cells( ${alpha}$ < 0.01) and multiquantal in five cells ( ${alpha}$ < 0.05 forthree cells and < 0.1 for two cells; component "2," Fig. 6 C).The mean quantal content of the ATP-mediated and glutamate-mediatedcomponents were 0.23 ± 0.9 and 0.82 ± 0.44 (n= 16), respectively; the quantal size of these components were6.2 ± 3.3 pA and 9.1 ± 5.7 pA, respectively (n= 16). These values agree with the quantal size of purinergicand glutamatergic EPSCs in the first group of cells.

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Figure 6. ATP-mediated current evoked at minimal stimulation. (A) EPSCs before and after CNQX (50 µM) and SYM2081 (10 µM). (B) Time course of block by CNQX and SYM2081. (C) Amplitude distribution of EPSCs in control conditions (black line, peaks at 4.7 and 7.9 pA) and in CNQX and SYM2081 (red). Dotted lines are fits of the distributions; binomial with single quantal size (7.9 pA, green dots; component 1) and compound fit with two quantal sizes (4.7 and 7.9 pA, blue triangles; component 2).

The value of quantal size in the evoked EPSC gives an estimatefor the unitary properties of the synaptic current, whetherthis corresponds to a single postsynaptic site or a single synapticvesicle (Auger and Marty, 2000

); these estimates can thereforebe compared with the properties of the spontaneous mEPSCs. Thequantal size of the evoked purinergic EPSC was 74 ± 16%(n = 35) of the control evoked EPSC (i.e., before adding glutamatereceptor blockers). The corresponding value for the mEPSCs inthe same cells was 73 ± 11% (n = 35). After glutamatereceptor blockade, there was also no difference between themean amplitude of the unitary evoked EPSC and the spontaneousmEPSC (P < 0.01, ANOVA test). These results suggest thatboth evoked EPSCs and spontaneous ATP-mediated mEPSCs originatefrom the same synapses.

This conclusion is supported by the effect of changing the intensityof stimulation on ATP-mediated spontaneous currents. We observedthat the frequency of ATP-mediated mEPSCs recorded between stimulationswas higher when the stronger stimulation was applied (Fig. 5).The increase in the purinergic mEPSC frequency was 91 ±57% as compared with that recorded in between episodes of minimalstimulation (n = 8). This indicates the appearance of new spontaneousevents after activation of additional axons/terminals by thestronger stimulus. One feasible explanation for this could bean enhancement of the release due to a residual increase inthe background calcium level in the presynaptic terminals afterrepetitive stimulation. Another explanation might be the recruitmentof P2X receptors to the synaptic membrane following the glutamatereceptor activation. Whatever the mechanism, the appearanceof new spontaneous events suggests that they occur at the sameterminals as the evoked currents.

Unitary purinergic currents were observed in $~$ 45% cases of single-fiber(minimal) stimulation and in 100% cases of multifiber (stronger)stimulation. At the same time, the purinergic EPSC was alwaysaccompanied by a glutamate-mediated unitary current; in all35 cells tested there was no case of a purely purinergic currentby single-fiber stimulation. On this ground, the existence ofspecific purinergic axons seems unlikely. Our result is bestascribed to the vesicular release of ATP at some of the samesynapses as glutamate.

We were unable to distinguish between the ATP-mediated eEPSCs(i.e., in 50 µM CNQX and 10 µM SYM2081) and theglutamate-mediated eEPSCs (i.e., in control conditions) by arange of further properties. First, we did not observe any significantdifference in the latency of purinergic and glutamatergic evokedsynaptic currents. Second, the paired-pulse ratio (see Materialsand methods) was 1.01 ± 0.25 (n = 24) for the former,and 1.04 ± 0.21 (n = 16) for the latter (unpublisheddata); in individual cells the paired-pulse ratio was well correlatedfor the glutamatergic and purinergic currents (R > 0.99,P < 0.02). Baclofen (3 µM) decreased the amplitudeof the first and second EPSCs, increased the number of failures(zero synaptic responses) and increased the paired-pulse ratio;the effects were the same for both control currents and currentsafter glutamate receptor blockade. It is well attested thatmetabotropic glutamate receptors (mGluRs) modulate synapticstrength in glutamatergic synapses (Simkus and Stricker, 2002;Schoepp 2001). In particular, activation of mGluRs group I (whichactivated InsP₃-dependent Ca²⁺ release form intracellular stores)enhances (Simkus and Stricker, 2002), whereas stimulation ofmGluRs group III suppresses (Schoepp, 2001) synaptic transmission.We tested the effects of mGluR group III receptor agonist (1S,3R,4S)-1-aminocyclopentane-1,2,4-tricarboxylicacid (ACPT-1; 10 µM; n = 5), which decreased the averageamplitudes, increased the number of failures and decreased thepaired-pulse ratio for both ATP-mediated and glutamate-mediatedevents. Finally, ${alpha}$ -latrotoxin (330 nM; n = 4) increased the averageamplitudes, decreased the failure rate and increased the paired-pulseratio (unpublished data). All in all, experiments describedabove did not reveal any significant difference in the behaviorof glutamatergic and purinergic EPSCs.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The main finding of the present work is that two populationsof mEPSC are found in mouse layer 2/3 cortical pyramidal cells.They can be distinguished by their amplitudes and pharmacologicalproperties. The small mEPSCs have about one-half the amplitudeof the predominant EPSCs, they persist in very high concentrationsof AMPA receptor blockers and agents promoting kainate receptordesensitization, and they are unaffected by cyclothiazide. Thesesmall mEPSCs correspond in their properties to a component ofthe evoked EPSC. They are partially blocked by antagonists ofP2X receptors, but firm conclusions about the identity of theunderlying P2X receptor are not possible yet. The most abundantP2X receptor subunits in the cortex are P2X₄ and P2X₆, but othersare also present (Collo et al., 1996; Rubio and Soto, 2001).The pharmacological properties of mouse P2X₄ receptors do notcorrespond in detail to those of the mEPSCs. When expressedin HEK 293 cells, homomeric P2X₄ receptors are insensitive tosuramin (100 µM) but blocked by PPADS (IC₅₀ $~$ 10 µM;Jones et al., 2000). The mEPSCs in our experiments were partiallyblocked by suramin and PPADS, but these are far from reliableantagonists with which to identify the subunit specificity ofP2X receptors. Not only are their effects species and subunitdependent, but they also block a range of other ion channels(North and Surprenant, 2000).

In our experiments we used rather moderate concentration ofPPADS to ensure washout. In our previous experiments (e.g.,Pankratov et al., 1998, 2003) we observed that effects of 10–30µM of PPDAS were only partially reversible. We considereddemonstration of reversible effect of antagonist being morepreferable for pharmacological characterization; the interpretationof irreversible block might be somewhat ambiguous. The IC₅₀of PPADS for different subtypes of P2X receptors lies in therange 1–10 µM (North and Surprenant, 2000), so 3µM should effectively inhibit P2X-mediated currents. Onthe other hand, one might not expect complete inhibition ofpurinergic current in the central nervous system because theP2X₄ subunit is most abundant, and receptors containing P2X₄subunits are insensitive to suramin and PPADS (North and Surprenant,2000).

Another possibility, that the small amplitude mEPSCs resultsfrom activation of kainate receptors (Cossart et al., 2002)seems very unlikely in view of their persistence in 50 µMCNQX, or 100 µM NBQX or 10 µM SYM2081. To excludepossible involvement of acetylcholin-mediated transmission,we treated cortical slices with hexametonium. The latter isa classical open-channel blocker (Buisson and Bertrand, 1998),which effectively inhibits nicotinic cholinoreceptors when thecells are kept at hyperpolarized potentials (–80 mV inour case). The absence of any effect of hexamethonium (100 µM)does not fully exclude a contribution from nicotinic receptors,given that it is a relatively weak blocker of some central nicotinicreceptors (e.g., ${alpha}$ 3ß4 receptors; Winzer-Serhan andLeslie, 1997; Xiao et al., 1998). These caveats notwithstanding,we proceed on the assumption that the small mEPSCs reflect activationof P2X receptors by ATP.

The ATP seems not to be released with glutamate (as was proposedfor cultured CA3 neurones by Mori et al., 2001) or with GABA(as was proposed for cultured lateral hypothalamic neuronesby Jo and Role [2002] and spinal neurones by Jo and Schlichter[1999]). In the first case, synchronous release of ATP and glutamateshould lead to summation of mEPSCs, which would result in theappearance of the third, large-amplitude peak on the amplitudehistogram. However, the mechanism of spontaneous ATP releaseclearly shares many features with the vesicular release of glutamate(sensitivity to ${alpha}$ -latrotoxin, bafilomycin). In the second case,GABA- and ATP-mediated currents could be discriminated at –40mV (when E_Cl was –60 mV) because GABA currents were outwardand P2X currents were inward. Obviously, if GABA was coreleasedwith ATP, the summation of inward and outward current eventswould lead to their mutual cancellation, hence reducing theoverall frequency of mEPSCs. In fact, we did not observe anydifference in mEPSC frequency between –80 and –40mV. On the other hand, our studies of eEPSCs provided no evidencefor a pure "purinergic" nerve population. The experiments withpaired-pulse inhibition, and the sensitivity to the presynapticaction of ACPT-1 and baclofen, are consistent with the interpretationthat ATP is released from glutamate-containing fibers runningvertically within the neocortex because thalamocortical inputsare reported to show paired-pulse inhibition (Gil et al., 1999;Reyes and Sakmann, 1999) and to be insensitive to baclofen (Gilet al., 1997).

The analysis of evoked and miniature EPSCs indicates that theamplitude of the unitary event mediated by P2X receptors isabout half the size of the unitary event mediated by AMPA receptors(ratio in the range 0.4–0.8), whereas the probabilityof an ATP-mediated component to the postsynaptic current islower (ratio in the range 0.1–0.3). Our results also demonstratethat maximal number of quanta of ATP-mediated evoked synapticcurrent depends on stimulus strength and, therefore, on thenumber of axons stimulated. The simplest interpretation maytherefore be that ATP is released from a distinct vesicle populationat a subset of glutamatergic synapses. We cannot say with confidencewhether this subset is defined by its ability to release ATPor by the presence of postsynaptic P2X receptors (or both).The latter interpretation would be consistent with the electronmicroscopic finding that P2X₄ subunits are found at about onehalf of excitatory synapses (in hippocampus and cerebellum;Rubio and Soto, 2001). Alternatively, the ATP may be containedwithin vesicle with another "cotransmitter" such as a peptide.While considering all the possibilities outlined above we areacutely aware that the present paper does not answer all questionsregarding quantal release of ATP, and further understandingof the role on mechanisms of ATP release in central synapsesrequires additional experimental efforts.

The overall contribution of ATP to the postsynaptic currentis small because there is a lower probability of release and/ora lower number of ATP-containing vesicles as compared with thosecontaining glutamate. In fact, the mean quantal content of thepurinergic EPSC was three to four times lower than the quantalcontent of glutamate-mediated EPSC. Given that only some 30–50%of synapses either release ATP or express P2X receptors, onecould estimate the relative frequency of ATP-mediated eventsas 10–30%. This agrees with the relative frequency ofpurinergic mEPSCs (10–40% of control) as compared withglutamate mEPSCs. Thus, the purinergic excitatory synaptic inputis minor in comparison to the glutamatergic input, even thoughthe size of unitary ATP-mediated currents is actually aboutone half of the magnitude of glutamate-mediated currents. Neverthelessthe ATP component can bring heterogeneity to the function ofexcitatory synapses, given that P2X receptors provide significantcalcium entry and that, unlike the case for NMDA receptors,this entry does not require postsynaptic depolarization (Pankratovet al., 2002). The calcium entry itself may strengthen the synapticconnection over the longer term, particularly if the changesin intracellular calcium can bring either P2X or AMPA receptorsto the membrane.

ACKNOWLEDGMENTS

This research was supported by The Wellcome Trust.

Olaf S. Andersen served as editor.

Submitted: 6 November 2006
Accepted: 8 February 2007

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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[Abstract/Free Full Text]

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				U. Lalo, Y. Pankratov, S. P. Wichert, M. J. Rossner, R. A. North, F. Kirchhoff, and A. Verkhratsky P2X1 and P2X5 Subunits Form the Functional P2X Receptor in Mouse Cortical Astrocytes J. Neurosci., May 21, 2008; 28(21): 5473 - 5480. [Abstract] [Full Text] [PDF]

				L. Moffatt and R. I. Hume Responses of Rat P2X2 Receptors to Ultrashort Pulses of ATP Provide Insights into ATP Binding and Channel Gating J. Gen. Physiol., July 30, 2007; 130(2): 183 - 201. [Abstract] [Full Text] [PDF]

				D. N. Bowser and B. S. Khakh Vesicular ATP Is the Predominant Cause of Intercellular Calcium Waves in Astrocytes J. Gen. Physiol., June 1, 2007; 129(6): 485 - 491. [Abstract] [Full Text] [PDF]