Role for P2X Receptors in Long-Term Potentiation

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The Journal of Neuroscience, October 1, 2002, 22(19):8363-8369

Role for P2X Receptors in Long-Term Potentiation
Yuri V. Pankratov, Ulyana V. Lalo, and Oleg A. Krishtal
Department of Cellular Membranology, Bogomoletz Institute of Physiology, 01024 Kiev, Ukraine

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

ATP receptors participate in synaptic transmission and intracellular calcium signaling in the hippocampus by providing a componentof the excitatory input to CA1 pyramidal neurons. The activationof P2X purinoreceptors generates calcium influx that does notrequire cell depolarization, but this response desensitizes atincreased rates of stimulation. Here we show that inhibition ofP2X receptors dramatically facilitates the induction of long-termpotentiation (LTP). High-frequency stimulation (HFS) (1 sec) inducedLTP in CA1, whereas brief HFS (0.2 sec) caused only short-termpotentiation. However, when P2X receptors were inhibited by PPADS(pyridoxal phosphate-6-azophenyl-2'-4'-disulphonic acid) or desensitizedby the nonhydrolyzable ATP analog $alpha$ , $beta$ -methyleneATP, brief HFSreliably induced LTP. Inhibition of P2X receptors had no facilitatoryeffect on LTP when NMDA receptors were blocked. We hypothesizedthat P2X receptors affect the threshold for LTP by altering Ca²⁺-dependent inactivation of NMDA receptors. In isolated pyramidalCA1 neurons and hippocampal slices, activation of P2X receptorsdid cause inhibition of NMDA receptor-mediated current. We suggestthat, by controlling the background calcium and thus the activityof NMDA receptors at low firing frequencies, P2X receptors actas a dynamic low-frequency filter so that weak stimuli do notinduceLTP.

Key words: P2X receptors; long-term potentiation; NMDA receptor inactivation; $alpha$ , $beta$ -methyleneATP; PPADS; CA1 neurons

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The activity-dependent phenomenon long-term potentiation (LTP) provides excitatory synapses with Hebbian properties and mayserve as the basis of learning and memory. High-frequency stimulation(HFS) leads to LTP in hippocampal CA3-CA1 synapses because itallows postsynaptic NMDA receptors to create a powerful calciumsignal in dendritic spines of depolarized pyramidal neurons. Thelevel of intracellular calcium determines whether the efficacyof synaptic connections is enhanced or depressed (Artola and Singer,1993; Debanne and Thompson, 1994; Malenka and Nicoll, 1999). Previously,NMDA receptors and voltage-gated Ca channels have been consideredas the main source of calcium influx, particularly for CA1 hippocampalneurons. However, a role for a purinergic component of synaptictransmission has been demonstrated recently (Pankratov et al.,1999). ATP is released from nerve endings (Illes and Nurenberg,1993; Zimmermann, 1994; Cunha et al., 1996), and ATP receptorsshow a widespread distribution in the brain (Balcar et al., 1995;Collo et al., 1996; Seguela et al., 1996). ATP acting at P2X receptorsmediates synaptic transmission in the medial habenula (Edwardset al., 1992) and hippocampus (Pankratov et al., 1998). Nevertheless,the specific physiological role of ATP receptors in the CNS remainsunclear. The effects of ATP are mediated by ionotropic (P2X) andmetabotropic (P2Y) purinoreceptors. The former depolarizes neuronsand has a considerable calcium permeability (Buell et al., 1996;Edwards et al., 1997; Virginio et al., 1998), whereas the lattercontrols calcium release from intracellular stores (Harden etal., 1995; Ralevic and Burnstock, 1998). The entry of calciumthrough purinoreceptor-operated channels become larger with morenegative membrane voltage in contrast to NMDA receptors for whichcalcium entry requires membrane depolarization. Thus, the purinergiccomponent of synaptic transmission may increase intracellularcalcium when the membrane potential is near its resting level.Correspondingly, the role of ionotropic purinergic component inthe calcium signaling and synaptic plasticity may be quite differentfrom the function of NMDA receptors. Here we show that inhibitionof P2X receptors facilitates the induction ofLTP.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Hippocampal slices. Experiments were performed on transverse 200- to 400-µm-thick hippocampal slices of Wistar rats (19- to-21-d-old animals). The brain was rapidly removed after decapitationand placed into ice-cold artificial CSF (ACSF) containing thefollowing (in mM): 130 NaCl, 3 KCl, 1 MgCl₂, 2 CaCl₂, 1 NaH₂PO₄,26 NaHCO₃, and 15 glucose (gassed with 95% O₂-5% CO₂ to obtaina final pH of 7.4). After dissection, slices were placed in aholding chamber in which they were maintained at room temperature(22-24°C) for 3-6 hr until they were placed in the recording chamber,also at room temperature. During incubation and recording, sliceswere kept in ASCF of the following composition (in mM): 135 NaCl,2 KCl, 2 CaCl₂, 1.0 MgCl₂, 1 NaH₂PO₄, 26 NaHCO₃, and 15 glucose(gassed with 95% O₂-5% CO₂ to obtain a final pH of 7.4).

Electrophysiological recordings. Using an RK-400 amplifier (Bio-Logic, Claix, France), the EPSCs were recorded in the conventionalwhole-cell configuration with the patch pipette (2-5 M $Omega$ ) filledwith the following intracellular solution containing (in mM):80 K₂HPO₄, 20 KCl, and 10 HEPES, pH 7.3 ("phosphate" solution).Two solutions were also used to test the role of intracellularcalcium in the observed phenomena (in mM): 110 CsCl, 10 NaCl,10 HEPES, pH 7.3, 2 MgATP, and 0.1 EGTA ("CsCl 0.1 mM EGTA" solution);and 110 CsCl, 10 NaCl, 10 HEPES, pH 7.3, 2 MgATP, 1 CaCl₂, and10 EGTA ("CsCl 10 mM EGTA" solution). The series and the inputresistances were 7 ± 3 and 300 ± 150 M $Omega$ , respectively, and variedfor <20% in the cells accepted for analysis. All of the recordingsof excitatory synaptic currents were made in the presence of 100µM picrotoxin in the superfusing solution. The field EPSPs wererecorded from the stratum radiatum of area CA1 using glass microelectrodesfilled with ACSF (impedance, 1-2 M $Omega$ ). The Schaffer collateral-commissuralpathway was stimulated with a 50-µm-thick Ni-Cr bipolar electrodepositioned on the slice surface in the stratum radiatum. Stimulusintensity was adjusted to evoke EPSPs at ~30-40% of the maximalresponse.

[Ca²⁺]_i measurement. The hippocampal neurons were loaded with the calcium indicator fura-2 by a 25-min-long incubation of thehippocampal slices in the ACSF supplemented with fura-2 AM (10µM) and pluronic F-127 detergent (0.02%) at 35°C. For the periodof dye loading, slices were kept under a controlled air environment(5% CO₂-95% O₂). Subsequently, the slices were incubated in ACSFfor an additional 40 min to ensure fura-2 AM deetherification.For fura-2 excitation, cells were illuminated at a wavelengthof 390 nm. The emitted light was collected at 530 ± 10 nm by aphotomultiplier controlled by a fura-2 Data Acquisition System(Luigs & Neumann, Ratingen, Germany) and a TIDA interface (HekaElectronik, Lambrecht/Pfalz, Germany). To reduce the backgroundfluorescence and select the region of interest, the UV illuminationwas attenuated by an adjustable diaphragm installed in the lightpath. Dye-loaded neurons were positioned in such a way that thefluorescent signal was collected from their somata. Relative changesin the [Ca²⁺]_i were quantified as changes in F/F₀, where F₀ and F are thefluorescence before and during neuronal activity (corrected forbleaching during recording). The bleaching was corrected by measuringthe fluorescence in the neuron without stimulation. Tissue autofluorescencewas subtracted after the measurement of fluorescence at a parallellocation in the slice away from the dye-filledcell.

Acutely isolated pyramidal neurons. After dissection, hippocampal slices were placed in the ACSF supplemented with 0.8 mg/mltrypsin (type XI; Sigma, St. Louis, MO) and incubated at 32°Cfor 20 min. After that, the slices were rinsed of the enzyme andmaintained at room temperature (22-24°C) for 4-6 hr. Single CA1neurons were isolated by successive triturating through severalpipettes with opening diameters from 0.5 to 0.1 mm. After dissociation,neurons were placed in the extracellular solution containing thefollowing (in mM): 150 NaCl, 5 KCl, 2 CaCl₂, 1 MgCl₂, and 10 HEPES,pH 7.3. The cells were suitable for recording within 2-3 hr. Onlycells of characteristic pyramidal shape were used for the experiments.Whole-cell conventional patch-clamp recordings were performedby using the patch pipette (2-4 M $Omega$ ) filled with the followingintracellular solution (in mM): 120 CsCl, 10 NaCl, 10 HEPES, 2MgATP, and 0.1 EGTA, pH 7.3. The series and input resistance were6 ± 2 and 800 ± 200 M $Omega$ ,respectively.

Drug application. A modified "square-pulse" concentration clamp method (Pankratov et al., 2001) was used for the rapid 200-msec-longapplication of agonist containing solutions with immediate washout.The tip of the recording pipette, attached to a neuron, was insertedinto a glass tube (1 mm inner diameter) through a tiny opening(0.6 mm inner diameter). The lower end of the tube was submergedinto the external solution in the chamber. The upper end of thetube was connected via the V-shaped plastic tube and computer-controlledvalves to the sources of negative and positive pressures allowingthe suction of drug-containing solution or backward washout withclear extracellularsolution.

To examine the Ca²⁺ signals in pyramidal cells, ATP or $alpha$ , $beta$ -methyleneATP ( $alpha$ , $beta$ -meATP) (100 µM) were applied by pressure ejection(5-10 kPa) from a pipette with a 200-300 µm internal diameterThe pressure was switched by a solenoid valve controlled by computer.The pipette was positioned perpendicularly to the flow of thebath perfusing solution near the edge of stratum radiatum. Theagonist was applied in the presence of 10 µM (2,3-dioxo-6-nitro-1,2,3,4-tetrahydro-benzo[f]quino-xaline-7-)sulfonamide(NBQX) and 50 µM 2-amino-5-phosphovaleric acid (D-APV) at 5 minintervals using 10 secpulses.

Data analysis. All data are expressed as mean ± SD. The statistical analysis was performed using Origin 6.0 software (MicrocalSoftware, Northampton, MA). The standard paired t test was usedfor analysis of changes in the EPSP, and linear regression analysiswas used to estimate the relationship between inactivation ofNMDA receptors and P2X receptor-mediated current. The significancelevel of linear correlation was evaluated as probability, p, ofnull hypothesis, H₀, as defined by Ftest.

Materials. The following compounds were purchased from Tocris Cookson (Bristol, UK): NBQX, D-APV, and pyridoxal phosphate-6-azophenyl-2'-4'-disulphonicacid (PPADS). Fura-2 AM was delivered by Molecular Probes (Eugene,OR). All other chemicals were fromSigma.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Figure 1 shows that, with low-frequency stimulation of the Schaffer collaterals, a small fraction of the fast EPSC recordedin CA1 cells is mediated by ATP. After blocking glutamate receptorswith NBQX and D-APV, the residual component can be inhibited by20 µM PPADS (55 ± 25%; n = 20). This ATP-mediated component comprised5-20% of the total synaptic current depending on the holding potential.With AMPA receptors only blocked, the residual postsynaptic currentat $-$ 80 mV is almost completely purinergic. At $-$ 40 mV, the purinergiccomponent is approximately one-fifth of the NMDA component. Thepurinergic component of the EPSC declined steeply when the stimulationfrequency was increased to 0.2 Hz (Fig. 1b). A similar effectwas seen by applying 20 µM $alpha$ , $beta$ -meATP, a nonhydrolyzable ATP receptoragonist (Buell et al., 1996), and we ascribe the disappearanceof the purinergic component to the desensitization, which is commonlyobserved for P2X receptors. It should be noted that the effectsof PPADS and $alpha$ , $beta$ -meATP, as well as the rate of desensitizationof the ATP-mediated EPSCs, showed large cell to cell variations.A small fraction of the current (5-25%) persists after applicationof PPADS and repeated episodes of high-frequency stimulation.This variability is most probably attributable to the differentialexpression of several P2X receptor subtypes, presumably P2X3,P2X4, and P2X6, as well as their heteromers (Seguela et al., 1996;Ralevic and Burnstock, 1998). These receptors have different sensitivityto PPADS and $alpha$ , $beta$ -meATP, as well as different desensitization kinetics.

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Figure 1. Purinergic synaptic input in hippocampal CA1 neurons. a, EPSCs elicited by stimulation of the Schaffer collaterals. The current was measured at two membrane voltages always in the presence of NBQX (10 µM). Right column, Application of PPADS (20 µM) on the background of NBQX. Each trace is the average of five consecutive responses. Note that, at a holding potential of $-$ 80 mV, the EPSC consists almost entirely of P2X-mediated current. Bottom diagrams demonstrate the relative contribution of the AMPA, NMDA, and ATP receptor-mediated currents to the total EPSC. Each column represents the mean ± SD for 15 cells. b, The desensitization of the ATP-mediated EPSC, measured in the presence of NBQX (10 µM) and D-APV (50 µM) at a holding voltage of $-$ 75 mV. The top left graph demonstrates that the amplitude of the purinergic component of the EPSC in CA1 neurons is stable when the frequency of stimulation is 0.05 Hz but quickly fades when the frequency is increased to 0.2 Hz. The top right graph demonstrates the disappearance of the purinergic component of the EPSC after bath application of 20 µM $alpha$ , $beta$ -meATP, a nonhydrolyzable analog of ATP, with stimulation frequency of 0.05 Hz. The representative current traces obtained at the times indicated by the arrows are demonstrated below the graphs.

We measured [Ca²⁺]_i transients evoked in CA1 pyramidal cells by fast application of 100 µM ATP to hippocampal slices (Fig. 2).Prominent signals were observed in 20 of 25 cells, and these wereinhibited by 45 ± 25% in the presence of PPADS (20 µM; n = 12).They were unaffected by 1 µM tetrodotoxin and/or glutamate receptorblockers. $alpha$ , $beta$ -meATP at the concentration of 100 µM also evokedcalcium transients in 17 of 22 cells (30-60% of the amplitudeof those caused by ATP). $alpha$ , $beta$ -meATP does not activate P2Y receptors(Ralevic and Burnstock, 1998), so this experiment indicates thata substantial fraction of the rise in [Ca²⁺]_i results from influx through P2X receptors. Blocking of refillingof the intracellular Ca²⁺stores by thapsigargin (Lytton et al., 1991) decreased the calciumsignal, indicating some contribution of the metabotropic signaland/or Ca²⁺-induced Ca²⁺ release (Fig. 2b). However, a substantial residual componentremained (50 ± 15%; n = 6), demonstrating a substantial ionotropicP2X receptor-mediated component.

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Figure 2. ATP-induced [Ca²⁺]_i transients in CA1 pyramidal neurons. a, Examples of [Ca²⁺]_i transients induced in the pyramidal cells by fast application of ATP (100 µM) and $alpha$ , $beta$ -methyleneATP (100 µM) to the hippocampal slice in control and after bath application of 20 µM PPADS. All traces were recorded in one and the same cell at 5 min intervals. Note the substantial amplitude of the response to $alpha$ , $beta$ -methyleneATP, which is only attributable to the calcium influx via ionotropic ATP-receptors. b, Examples of [Ca²⁺]_i transients induced by repetitive fast application of ATP (100 µM) in the presence of 1 µM thapsigargin at 5 min time intervals. It is worth noting that the amplitudes of the third and the following transients, which are attributable to entry of the extracellular calcium via ionotropic ATP receptors, comprise ~40% of the initial response, which represents the combined activity of P2X and P2Y purinoreceptors.

An increase in postsynaptic calcium is widely believed to play a key role in synaptic plasticity (Bliss and Collingridge,1993; Cummings et al., 1996; Malenka and Nicoll, 1999). The purinergiccomponent of the EPSC might play an important role in long-termplasticity because the P2X-receptor mediated calcium entry wouldprogressively increase with hyperpolarization. This is in contrastto the activation of NMDA receptors, in which current decreaseswith hyperpolarization beyond approximately $-$ 40 mV. We elicitedLTP at CA3-CA1 synapses according to established protocols andmeasured it as the slope of the field EPSP. In control conditions,high-frequency stimulation (100 Hz, 1 sec) increased the slopeby 125 ± 45%, and this increase persisted for up to 3 hr (Fig.3a). A train of 100 Hz for 0.2 sec did not cause LTP, even whenthe train was repeated (Fig. 3b). However, in the presence ofthe P2X receptor blocker PPADS (20 µM), even the short train evokedsubstantial LTP (Fig. 3b). The field EPSP slope increased by 69± 34% at 1 hr, and this effect was highly significant (n = 15;p < 0.01; Student's t test).

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Figure 3. The changes in the CA1 field potentials induced by 100 Hz stimulation delivered to the Schaffer collateral in the control and after inhibition of the ATP receptors. a, The time course of the potentiation evoked by 0.2 and 1 sec of 100 Hz stimulation trains in control conditions. Examples of field EPSPs recorded before and 60 min after the 1-sec-long HFS train are indicated in the inset. Each trace represents the average of 10 EPSPs. b, c, The time course and magnitude of the potentiation evoked by the 0.2 sec HFS train in control and after bath application of 20 µM PPADS and $alpha$ , $beta$ -methyleneATP, respectively. Baseline stimulation frequency is 0.08 Hz.

The question arises whether the observed phenomenon is attributable to the presynaptic or postsynaptic action(s) of PPADS.This substance blocks both P2X and P2Y receptors (Buell et al.,1996). Metabotropic P2Y receptors are known to downregulate transmitterrelease by partial inhibition of Ca channels (Ralevic and Burnstock,1998). Correspondingly, PPADS might enhance synaptic transmissionvia a presynaptic mechanism. In fact, we observed a small increasein the field EPSP in the presence of PPADS. The effect reached6 ± 4% for the mean amplitude and 8 ± 6% for the coefficient ofvariation (n = 15). This minor effect does not seem to be capableof causing a profound facilitation of LTP, but we further addressedthe problem by using $alpha$ , $beta$ -meATP as a desensitizing agonist, whichis selective for P2X receptors (Ralevic and Burnstock, 1998).This substance did not increase the amplitude of EPSP but completelyreproduced the effect of PPADS: LTP could be elicited by a 0.2sec stimulus train in the presence of 20 µM $alpha$ , $beta$ -meATP (Fig. 3c),and the slope of the field EPSP was increased by 45 ± 22% at 1hr (n = 10; p < 0.02; Student's ttest).

These results imply that the observed facilitation of LTP induction is predominantly related to the inhibition of the ionotropicP2X receptors. The experiments on isolated pyramidal neurons (seebelow) suggest that the affected P2X receptors arepostsynaptic.

The LTP at the CA1 synapse is NMDA receptor dependent (Bliss and Collingridge, 1993; Cummings et al., 1996). We checked whetherthe role of NMDA receptors in LTP induction remained crucial underconditions of inhibited P2X receptors. Figure 4a shows that, inthe presence of D-APV, high-frequency stimulation induces onlybrief potentiation, followed by a modest long-term depression(LTD) of the field EPSP. This effect is reversible, and, afterremoving D-APV from the bath solution, LTP can be induced. Theconversion of the effect of brief tetanic stimulation from LTPto LTD as a result of NMDA receptor inhibition has been reportedpreviously (Cummings et al., 1996). PPADS did not alter this phenomenon,confirming that the intrinsic properties of LTP induction weresimilar. Under simultaneous action of D-APV and PPADS, 1 sec HFSinduced depression instead of potentiation, but, during washoutof D-APV, the 0.2 sec HFS train induced LTP (Fig. 4b). These observationsprovide support for the hypothesis that the direction of the changein synaptic transmission depends on the level of the activity-dependentrise in [Ca²⁺]_i (Malenka and Nicoll, 1999; Luscher et al., 2000).

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Figure 4. Inhibition of purinoreceptors does not affect the "NMDA paradigm." The changes in the field EPSP slope evoked by the 1 sec HFS train after bath application of 25 µM D-APV (a) and simultaneous application of 25 µM D-APV and 20 µM PPADS (b). The inhibition of NMDA receptors reversibly blocks the induction of LTP independently of the activity of P2X receptors. Baseline stimulation frequency is 0.08 Hz.

The above results suggest that ATP, coreleased with glutamate, causes an inhibition of LTP at low frequencies of backgroundtonic stimulation. At higher frequencies of background stimulation,ATP loses its postsynaptic action attributable to desensitizationof P2X receptors. One mechanism by which P2X receptors might affectthe machinery of LTP could be through the Ca²⁺-dependent inactivation of NMDA-mediated responses (Rosenmundet al., 1995; Kyrozis et al., 1996). This hypothesis was tested,and the results are shown in Figure 5. The Schaffer collateralswere continuously stimulated in the presence of NBQX. The currentmeasured at $-$ 40 mV represented the NMDA component of the EPSC,whereas an exclusively purinergic component was present at $-$ 80mV (compare with Fig. 1a). The NMDA component was strongly inhibitedafter each episode of low-frequency stimulation at $-$ 80 mV (Fig.5a). The gradual recovery of NMDA current during the stimulationat $-$ 40 mV is incomplete because of the calcium influx via NMDAreceptor-operated channels. However, after a period without stimulation,the amplitude of NMDA receptor-mediated EPSC completely recovered(Fig. 5a). As already reported (Rosenmund et al., 1995; Kyroziset al., 1996), NMDA receptors recover from inactivation when thecalcium concentration falls back to resting levels. The inhibitionof NMDA component was abolished by PPADS, suggesting that NMDAreceptors were inhibited by the activity of P2X receptors (Fig.5a).

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Figure 5. NMDA component of EPSC is inactivated by low-frequency stimulation at a strongly negative voltage. This effect is inhibited by PPADS and depends on the Ca²⁺-buffering capacity of the intracellular saline. a, EPSCs comprising NMDA and purinergic components were continuously recorded at two membrane potentials, first at $-$ 40 mV (practically pure NMDA component) and then at $-$ 80 mV (only the purinergic component is responsible for the measured inward current). Note a substantial inhibition of the NMDA component after return of the voltage to $-$ 40 mV (the EPSCs measured at the moments indicated by the numbers are demonstrated in the inset, and each trace is the average of 5 EPSCs). The kinetics of the EPSC recorded again at $-$ 40 mV become faster because of the decrease in the NMDA receptor-mediated fraction. Application of PPADS (20 µM) to the same cell leads to the complete disappearance of this effect. b, A decrease in the NMDA receptor-mediated component of EPSC ( $Delta$ I_NMDA) has been measured as shown in a using different compositions of intracellular solution (see Materials and Methods). The buffering of intracellular calcium by 10 mM EGTA prevents the inactivation of NMDA receptors.

The inhibition of the NMDA component of the EPSC appears to be dependent on the calcium buffering capacity of the intracellularsolution. Three compositions of intracellular solution were tested:one containing K₂HPO₄ (phosphate solution) and two CsCl-basedsolutions, with the solution with 10 mM EGTA providing very strongbuffering of Ca²⁺ and the solution with 0.1 mM of EGTA allowing large variationsin the intracellular Ca²⁺ concentration. These solutions may be ranked according to theirpotency as Ca²⁺ buffers from higher to lower: 10 mM EGTA solution, phosphatesolution, and 0.1 mM EGTA solution. The inhibitory effect wasevaluated as the difference in the steady level of amplitude ofNMDA current before and after stimulation at $-$ 80 mV. We did notobserve the inhibition of NMDA currents in all of the cells perfusedwith 10 mM EGTA (n = 10). As to the cells perfused with 0.1 mMEGTA (n = 15), the inhibition of NMDA current was even largerthan in the case of the phosphate solution (Fig. 5b).

So, the stronger the buffering of intracellular Ca²⁺ was, the weaker was the inhibition of NMDA currents observed after a periodof low-frequency stimulation at strongly negative membrane voltages.The inhibition of NMDA receptors could also be prevented by thepurinergic antagonist PPADS. The above results suggest that Ca²⁺ influx mediated by purinoreceptors may bring a contribution inthe inactivation of NMDA receptors. To obtain direct evidenceof interaction between P2X and NMDA receptors, we performed experimentson dissociated pyramidal CA1 neurons. The inward currents evokedby application of ATP were observed in 19 of 24 cells tested.The amplitude of the response to 20 µM ATP was in the range of20-120 pA at a holding potential of $-$ 80 mV. The mean density ofATP-induced current was 4 ± 2 pA/pF. The decay of current hadbiexponential kinetics with time constants of 28 ± 8 and 850 ±150 msec, with the ratio of fast to slow components measuring0.44 ± 0.25. These observations are consistent with the participationof different P2X receptor subtypes. All of the tested cells demonstrateda response to NMDA whose amplitude (200-300 pA) was stable duringrepetitive application of agonist at 2 min intervals. The amplitudeof current evoked by the application of 30 µM NMDA at $-$ 40 mV wastypically two to three times higher than the amplitude of theresponse to 20 µM ATP at $-$ 80mV.

When the response to NMDA was evoked in a few seconds after a short (200 msec) application of ATP, the amplitude of NMDA currentdid not alter significantly. At the same time, when ATP was appliedfor a much longer time (10 sec) at a holding potential of $-$ 80mV, the amplitude of the NMDA response decreased considerably(Fig. 6a). The larger the response to ATP was, the higher wasthe decrease in the amplitude of NMDA receptor-mediated current.On the other hand, the inhibition of NMDA receptors was not observedin the cells that did not respond to ATP. The dependence of decreasein the amplitude of response to NMDA (I_NMDA) on the relative amplitudeof P2X receptor-mediated current (I_P2X/I_NMDA) is shown in Figure6b.

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Figure 6. Interaction between P2X and NMDA receptors in acutely isolated CA1 pyramidal neurons. a, examples of inward currents evoked by short (200 msec) applications of NMDA and ATP. The traces represent (from left to right) the control response to NMDA, the response to ATP, the control response to NMDA evoked 5 sec after a 200 msec application of ATP, the response to NMDA evoked after a 10 sec preapplication of ATP, and the control response to NMDA. b, Inhibition of NMDA receptors correlates with the amplitude of response to ATP. The relative decrease in the amplitude of NMDA-evoked current (I_NMDA) caused by 10-sec-long application of P2X agonists (ATP, 20 µM, filled squares; $alpha$ , $beta$ -methyleneATP, 20 µM, open triangles) is plotted against the ratio of current mediated by P2X receptors to the current mediated by NMDA receptors (I_P2X/I_NMDA). Each point represents a single cell tested. The inhibition of NMDA receptors is higher for the cells exhibiting larger P2X receptors-mediated currents. The inhibition did not occur in the cells that did not exhibit the response to ATP. Several exclusions observed under ATP, but not $alpha$ , $beta$ -methyleneATP, can be tentatively attributed to the activity of P2Y receptors in those particular three cells. The dotted line represents the result of linear regression analysis. A high (correlation coefficient, R = 0.72) and significant (p < 0.01) correlation shows that ATP receptors can strongly influence the NMDA receptors. c, Substitution of calcium in the extracellular solution for barium eliminates the ATP-induced inactivation of NMDA receptors. The traces represent (from left to right) the control response to NMDA, the response to ATP after substitution of extracellular Ca²⁺ for Ba²⁺, the response to NMDA evoked after a 10 sec preapplication of ATP in the Ba²⁺-containing medium, and the control response to NMDA. NMDA (30 µM) was applied on the background of 10 µM glycine at a holding potential of $-$ 40 mV; ATP (20 µM) was applied at $-$ 80 mV. Intracellular solution contained 0.1 mM EGTA.

The 10-sec-long preapplication of $alpha$ , $beta$ -meATP (20 µM) also inhibited the NMDA current (Fig. 6b), indicating that this effectis mediated predominantly by ionotropic P2X receptors. Moreover,the inhibitory effect of both P2X receptor agonists correlatedwith the amplitude of the ATP-evoked current (Fig. 6b). The linearregression analysis gave the correlation coefficient R > 0.7 witha significance level p < 0.01, indicating toward the strong modulatoryeffect of ATPreceptors.

For several cells, although they demonstrated a relatively small response to ATP, the inhibition of NMDA receptor-mediatedcurrents by preapplication of ATP was very high, whereas sucha deviation from the main correlation was not observed for $alpha$ , $beta$ -meATP.This fact implies that metabotropic P2Y receptors may also contributeto the rise in intracellular calcium and subsequent inhibitionof NMDAreceptors.

To prove the role of calcium in the inactivation of NMDA receptors, we reproduced the same protocol after substitution ofextracellular calcium for barium. As shown in Figure 6c, applicationof ATP failed to induce NMDA receptor inactivation in the absenceof calcium ions in the extracellular medium. Hence, the influxof calcium through P2X receptor channels is crucial for ATP-inducedinactivation of NMDAreceptors.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Our data demonstrate that ATP receptors mediate a minor component of excitatory synaptic current and participate in the intracellularcalcium signaling in CA1 pyramidal neurons. Although P2X receptor-mediatedsynaptic input is small compared with the AMPA component, it mayplay an important role, providing a calcium influx at low membranepotentials when NMDA receptors are not active. Another importantfeature of purinergic synaptic current is its tendency to desensitizationwith increased stimulation frequency. Similar behavior was reportedfor purinergic EPSC in the medial habenula (Edwards et al., 1997),in which the number of failures increased at higher stimulationfrequencies. The decline of purinergic EPSC may be related tothe desensitization of postsynaptic P2X receptors, as well asdownregulation of synaptic transmission by extracellular ATP viapresynaptic P2Y purinoreceptors (Koizumi et al., 1997; Ralevicand Burnstock, 1998). Although presynaptic P2Y receptors may playa certain role in the synaptic plasticity, the effect of LTP facilitationobserved in the present paper should be attributed mainly to P2Xreceptors, because a similar effect may result from the desensitizationof P2X receptors by their selective agonist $alpha$ , $beta$ -meATP.

The role of P2X receptors is supported by data on the interaction between ATP- and NMDA-induced current. The observation ofATP-induced currents in the pyramidal neurons is important initself as direct evidence of the presence of functional P2X receptors.The percentage of cells that do not exhibit ATP-induced currentsand calcium transients (20-25%) is very close indeed to the percentageof failures in the observation of purinergic EPSCs (Pankratovet al., 1998). On the other hand, the variability of the P2X-mediatedresponse recorded in the somata of isolated cells (Fig. 6b) ishigher than the variability of synaptic current mediated by dendriticP2X receptors. So one could suggest the different levels of P2Xreceptor expression in the soma and dendrites of pyramidal neurons.Our results imply that, in at least 75-80% of pyramidal neurons,activity of P2X receptors may cause Ca²⁺-dependent inactivation of NMDA receptors. It is not an uniqueexample of interaction between P2X and other ligand-gated receptorchannels. The cross-inhibition between P2X and nicotinic acetylcholinereceptors has also been widely reported (Nakazawa, 1994; Zhouand Galligan, 1998; Khakh et al., 2000). The mechanism of thiseffect seems to be different from inactivation of NMDA receptors.It has been demonstrated that interaction between purinergic andcholinergic receptors is Ca²⁺ independent (Zhou and Galligan, 1998) and presumably relatedto the spread of conformational changes from one receptor to itsneighbor (Khakh et al., 2000).

The presented data indicate that the synaptic stimulation of P2X receptors determines the level of activity of NMDA receptorsby regulating dynamic equilibrium between periodical Ca²⁺ transients and mechanisms that bring Ca²⁺ concentration back to the resting levels. The level of intracellularCa²⁺ is known to change the efficacy of synaptic connections in opposingways by regulating phosphorylation and dephosphorylation. Oneof the most widely accepted views is that a moderate rise in theintracellular Ca²⁺ concentration should lead to the activation of phosphatases andcause LTD, whereas a larger rise in [Ca²⁺]_i causes the activation of kinases, primarily of Ca²⁺/calmodulin-dependent (CaM) kinase, subsequently leading to LTP.CaM kinase undergoes autophosphorylation and may remain activeeven after the return of [Ca²⁺]_i to basal level. However, its opposing phosphatase has a 25-100times higher affinity for calcium and can dephosphorylate theautophosphorylated kinase (Debanne and Thompson, 1994). Competitionbetween these mechanisms provides the threshold for bi-directionallong-lasting changes of synaptic connections. Two mutually nonexclusivehypotheses of the expression of synaptic plasticity are most widelyaccepted: (1) direct upregulation and downregulation of AMPA receptors(Malenka and Nicoll, 1999) and (2) morphological changes in thedendritic spines (Edwards, 1995; Luscher et al., 2000). Both hypothesesaccount for bi-directional changes in synaptic efficacy directedby the activity of phosphatases andkinases.

Our results on the participation of P2X receptors in synaptic plasticity are in good agreement with the paradigm concerningthe earlier phase of the LTP induction. Thus, in the vicinityof resting potential (that is, during the intervals between spikesor bursts), purinergic synaptic input may serve as the main sourceof intracellular calcium (Zimmermann, 1994; Cunha et al., 1996).This background calcium influx maintains the tonic activity ofphosphatases and determines the efficiency of the subsequent episodeof activity for the induction of LTP. In the course of such episodes,NMDA receptors available for activation in a given neuron haveto create a sufficient calcium signal. The efficiency of NMDAreceptors is determined, among other factors, by the level ofcalcium-dependent inactivation (Rosenmund et al., 1995). It appearsthat P2X receptors strongly influence the basal level of calcium-dependentinactivation of NMDA receptors and correspondingly determine thethreshold for the induction ofLTP.

In summary, our results indicate that ATP coreleased with glutamate allows calcium to enter the postsynaptic cell and therebyinhibits the effectiveness of NMDA receptors in the inductionof LTP. P2X receptors bring their contribution to synaptic transmissionmainly at low frequencies of stimulation and low membrane potential.In other words, they act as a dynamic low-frequency filter, preventingweak stimuli from inducing long-lasting changes in synapticefficacy.

  FOOTNOTES

Received Jan. 25, 2002; revised June 18, 2002; accepted June 14, 2002.

This work was supported by a Howard Hughes Medical Institute grant and International Association for the Promotion of Cooperationwith Scientists from the New Independent States of the FormerSoviet Union Grant 99-01147. We are grateful to Drs. Urs Gerbert,Frances Edwards, and Alan North for early discussion and helpfulcomments.

Correspondence should be addressed to Prof. Oleg Krishtal, Department of Cellular Membranology, Bogomoletz Institute of Physiology,Bogomoletz Street 4, 01024 Kiev, Ukraine. E-mail: krishtal{at}serv.biph.kiev.ua.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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