Effect of Nitrous Oxide on Excitatory and Inhibitory Synaptic Transmission in Hippocampal Cultures

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The Journal of Neuroscience, December 1, 1998, 18(23):9716-9726

Effect of Nitrous Oxide on Excitatory and Inhibitory Synaptic Transmission in Hippocampal Cultures
Steven Mennerick¹, Vesna Jevtovic-Todorovic², Slobodan M. Todorovic², Weixing Shen¹, John W. Olney¹, and Charles F. Zorumski¹
Departments of ¹ Psychiatry and ² Anesthesiology, Washington University School of Medicine, St. Louis, Missouri 63110

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Nitrous oxide (N₂O; laughing gas) has been a widely used anesthetic/analgesic since the 19th century, although its cellularmechanism of action is not understood. Here we characterize theeffects of N₂O on excitatory and inhibitory synaptic transmissionin microcultures of rat hippocampal neurons, a preparation inwhich anesthetic effects on monosynaptic communication can beexamined in a setting free of polysynaptic network variables.Eighty percent N₂O occludes peak NMDA receptor-mediated (NMDAR)excitatory autaptic currents (EACs) with no effect on the NMDAREAC decay time course. N₂O also mildly depresses AMPA receptor-mediated(AMPAR) EACs. We find that N₂O inhibits both NMDA and non-NMDAreceptor-mediated responses to exogenous agonist. The postsynapticblockade of NMDA receptors exhibits slight apparent voltage dependence,whereas the blockade of AMPA receptors is not voltage dependent.Although the degree of ketamine and Mg²⁺ blockade of NMDA-induced responses is dependent on permeant ionconcentration, the degree of N₂O blockade is not. We also observea slight and variable prolongation of GABA_A receptor-mediated(GABAR) postsynaptic currents likely caused by previously reportedeffects of N₂O on GABA_A receptors. Despite the effects of N₂Oon both NMDA and non-NMDA ionotropic receptors, glial glutamatetransporter currents and metabotropic glutamate receptor-mediatedsynaptic depression are not affected. Paired-pulse depression,the frequency of spontaneous miniature excitatory synaptic currents,and high-voltage-activated calcium currents are not affected byN₂O. Our results suggest that the effects of N₂O on synaptic transmissionare confined to postsynaptictargets.

Key words: NMDA receptor; glutamate; nitrous oxide; GABA; postsynaptic; presynaptic

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Despite much attention, cellular mechanisms underlying general anesthesia remain elusive. Many anesthetics share the abilityto potentiate exogenously or synaptically generated GABA_A receptor-mediated(GABAR) currents (Franks and Lieb, 1994). Halothane, isofluorane,barbiturates, neurosteroids, and propofol are examples of knownanesthetic GABA_A modulators. Some anesthetics like halothane inhibithigh-voltage-activated calcium currents (Herrington et al., 1991;Miao et al., 1995), suggesting the possibility that presynapticeffects contribute to some of the anesthetic actions of theseagents. Inhibitors of NMDA glutamate receptors, like ketamine,phencyclidine, and MK-801, have anesthetic properties, with ketamineenjoying widespread clinical use in pediatricpopulations.

Nitrous oxide (N₂O) has been used as an inhalation anesthetic for over a century and as a recreational drug of abuse sinceat least the 18th century; yet the mechanism(s) of the effectsof nitrous oxide on signaling in the CNS is not understood. N₂Ois widely used clinically because of its good analgesic properties;however, it is a relatively weak anesthetic, requiring high volumepercent and hyperbaric conditions to achieve the minimal alveolarconcentration for anesthesia in 50% of subjects (MAC) (Gonsowskiand Eger, 1994). Because of its low potency, N₂O is often usedin combination with otheranesthetics.

In an initial study, we showed that N₂O possesses several properties of a noncompetitive NMDA receptor antagonist, includingthe ability to protect brain tissue against excitotoxic damage,the ability to damage neurons in posterior cingulate and retrosplenialcortex, and the ability to block NMDA-gated currents in CNS neurons.In addition, N₂O weakly potentiates GABAR currents (Dzoljic andDuiijn, 1998; Jevtovic-Todorovic et al., 1998). A complete understandingof N₂O actions requires an analysis of effects on neural communication,in which potential presynaptic and postsynaptic contributionscan be assessed. To increase understanding of the mechanisms ofN₂O actions, we explored in the current study the actions of N₂Oon neurotransmission in a simple setting of rat hippocampal microcultures(Segal and Furshpan, 1990). Solitary neurons grown in synapticisolation in microcultures form autaptic (self-synaptic) connections(Bekkers and Stevens, 1991; Segal, 1991), thereby allowing theexploration of N₂O synaptic actions in an environment free ofmany complicating variables, such as feedback inhibition and othernetwork properties associated with more intactpreparations.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Hippocampal cultures. Hippocampal cells were prepared from 1-3 d postnatal Sprague Dawley rats. Slices of hippocampus 500-800µm thick were digested with 1 mg/ml papain in oxygenated Leibovitz'sL-15 medium. Digested slices were mechanically triturated in modifiedEagle's medium containing 5% horse serum, 5% fetal calf serum,17 mM D-glucose, 400 µM glutamine, 50 U/ml penicillin, and 50µg/ml streptomycin. Cells (75/mm²) were plated onto plastic culture dishes coated with a layerof collagen microdots over a layer of dried 0.15% agarose (microcultures)as described previously (Mennerick et al., 1995). Cultures weretreated with cytosine arabinoside (10 µM) after 3 d in vitro andwere used for experiments 1-16 d afterplating.

Electrophysiology. The extracellular bath solution for synaptic physiology contained (in mM): NaCl 140, KCl 4.0, CaCl₂ 2.0,MgCl₂ 1.0, and HEPES 10. For experiments examining isolated NMDAreceptor-mediated (NMDAR) excitatory autaptic currents (EACs),2,3-dihydroxy-6-nitro-7-sulfamoylbenzo(F)quinoxaline (NBQX; 1µM), glycine (10 µM), and bicuculline (25 µM) were added to thebath, and Mg²⁺ was removed from the bath. For examination of AMPA receptor-mediated(AMPAR) EACs, D-2-amino-5-phosphonovalerate (D-APV; 25 µM) andbicuculline (25 µM) were added to the bath. For examination ofinhibitory autaptic currents (IACs), NBQX (1 µM) and D-APV (50µM) were added. For examination of miniature EPSCs (mEPSCs), tetrodotoxin(500 nM), D-APV (25 µM), and bicuculline (25 µM) were includedin the bath. In experiments in which currents were induced byexogenous NMDA, the extracellular solution contained no addedMg²⁺ and contained reduced Ca²⁺ (0.1-0.5 mM) to diminish calcium-dependent fade of NMDA-inducedcurrents (Mayer and Westbrook, 1985; Zorumski et al., 1989; Legendreet al., 1993). For examination of high-voltage-activated (HVA)calcium currents, 5 mM BaCl₂ replaced CaCl₂ and MgCl₂ and servedas the charge carrier. Additionally, 1 µM tetrodotoxin was presentin the bath. Calcium currents were leak subtracted using a P/5(subpulse) protocol. Voltage pulses from $-$ 70 to $-$ 10 mV deliveredevery 20 sec were used to elicit HVA calciumcurrents.

For addition of gas, the extracellular solution was bubbled with air or N₂O/O₂ mixtures using a bubbling stone. The bubblingcontainer was sealed with Parafilm punctured with a small escapehole. The solution was equilibrated with gas for at least 30 min,at which time gas-equilibrated solutions were drawn into a closedglass syringe. The syringe served as a solution reservoir fora gravity-driven local perfusion system consisting of glass tubesconnecting the reservoirs with a multibarrel pipette (List Electronic,Darmstadt, Germany). The common tip of the multibarrel pipettewas placed 400 µm from the recorded cell. Solution flow rateswere 0.8-1.5 ml/min. The slower flow rates were used for synapticexperiments; faster flow rates (attained with larger-bore glassconnecting tubes) were used for exogenous applications. Basedon junction-current measurements using solutions of differentchloride concentrations, rise times of solution exchanges withthe faster flow rates were <30 msec (10-90% rise) at the tip ofan open recording pipette. For most experiments 80% N₂O/20% O₂was used so that bottled air (80% N₂/20% O₂) could be used asacontrol.

The whole-cell recording pipette solution for studies of EACs contained (in mM): potassium gluconate 130, NaCl 4.0, CaCl₂0.5, EGTA 5.0, HEPES 10, MgATP₂ 2.0, and GTP 0.5. For study ofIACs, gluconate was replaced with chloride. For studies of responsesto exogenous glutamate receptor agonists and for studies of mEPSCs,cesium methanesulfonate replaced potassium gluconate. For studyof the voltage dependence of NMDA-receptor blockade, cesium chlorideor choline chloride replaced potassium gluconate in the patch-pipettesolution. The pH of solutions was adjusted to 7.25.

For evoked synaptic responses, whole-cell, voltage-clamp recordings of autaptic currents were performed from solitary neuronsusing pipettes with an open-tip resistance of 2-5 M $Omega$ and withseries resistance compensated 90-100% using the compensation circuitryof an Axopatch 1-D amplifier (Axon Instruments, Foster City, CA).Neurons were stimulated with a brief (1.5 msec) voltage-commandpulse to 0 mV from a holding potential of $-$ 70 mV. Successive sweepswere triggered at intervals of $>=$ 20 sec to allow recovery fromshort-term depression and facilitation. Paired-pulse stimuli weredelivered at 100 msec intervals for EACs and 500 msec intervalsfor IACs to allow conditioning responses to decay before deliveryof a test stimulus. Averages of two to five sweeps in each conditionwere used for display and analysis. For miniature synaptic currentsand exogenous currents, experiments were not limited to solitary-neuronmicrocultures, and series-resistance compensation was usuallynot used to achieve the lowest background noise levels possible.EAC decays were fit with a single exponential or biexponentialfunction, generated from a Chebychev-transform algorithm (Pclamp6.0; Axon Instruments). Unless otherwise indicated, results arepresented as mean ±SE.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Effect of N₂O on NMDAR EPSCs

Because we showed previously that N₂O blocks NMDAR currents in hippocampal neurons, we first explored the effect of N₂O onNMDAR synaptic currents in hippocampal microcultures. We foundthat a subanesthetic concentration of 80% (volume percent) N₂Oapplied to isolated microculture neurons inhibited peak NMDAREACs by 49 ± 6% (n = 6) compared with control responses ( $-$ 1314± 317 pA) examined in extracellular saline bubbled with air. Thedegree of synaptic blockade was similar to that observed withexogenous applications of NMDA (Jevtovic-Todorovic et al., 1998)(seebelow).

NMDAR EACs in microcultures decay with a biexponential time course (Clements et al., 1992). In the present experiment, controlEACs decayed with time constants of 89.5 ± 4.6 and 491 ± 16 msec,with the fast component representing 53 ± 3% of the initial amplitudeof the EAC (Fig. 1B). The time course of NMDAR EACs was not significantlyaffected by the application of 80% N₂O (Fig. 1A,B). The lack ofN₂O effect on NMDAR EAC time course has interesting implicationsfor the mechanism of action of N₂O. Ketamine, another anestheticknown to inhibit NMDA receptor function, is a slowly dissociatingantagonist that requires channel opening to inhibit NMDA receptors(MacDonald et al., 1987). When we examined the effect of 5-10µM ketamine, we found a degree of peak NMDAR EAC inhibition similarto that induced by 80% N₂O (Fig. 1A,C; 45 ± 4% depression withbaseline amplitudes of $-$ 1545 ± 248 pA; n = 5). However, in contrastto N₂O, ketamine also significantly decreased the decay time ofthe NMDAR EAC. The decrease in decay time in the presence of ketaminewas expressed as a decrease in both the fast and slow time constantsof decay as well as an increase in the relative amplitude of thefast component of decay (Fig. 1D). These effects of ketamine aresimilar to the effects of MK-801 (Rosenmund et al., 1993) at NMDAreceptors and to the actions of slowly dissociating barbituratesacting on neuromuscular endplate currents (Adams, 1976).

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Figure 1. Effect of N₂O and noncompetitive NMDA receptor antagonists on NMDAR EACs. A, Effect of N₂O on peak amplitude and on time course of NMDAR EACs is shown. Left, The effect of N₂O on peak NMDAR responses. Control responses were obtained in the presence of extracellular solution bubbled with air and exhibit the larger peak current. Right, The EAC in the presence of N₂O scaled to the peak NMDAR response in the absence of N₂O. No effect of N₂O could be detected on the time course of NMDAR EACs. B, Bar graphs summarize the effect of N₂O (hashed bars) on the biexponential decay of NMDAR EACs. Open bars represent EACs in the presence of air. No significant difference was detected either in the time constant or in the relative contribution of the two components to the total amplitude (n = 6; paired t test). C, Effect of 5 µM ketamine on NMDAR EACs is shown. Note the speeding of the NMDAR EAC apparent in the scaled traces. D, Ketamine induced speeding of both the fast and slow time constant of decay and an increase in the relative contribution of the fast component (an asterisk indicates p < 0.02; n = 5; paired t test). E, F, Mg²⁺ (15 µM) has effects on peak and time course similar to those of N₂O. No significant effect on time course was detected in six cells. For synaptic current traces in this and subsequent figures, stimulus transients have been partially blanked and truncated for clarity of presentation.

In contrast to the actions of ketamine and of N₂O on NMDAR EACs, classical open-channel blockers, like procaine or methyprylone,acting at neuromuscular nicotinic receptors prolong the late phaseof endplate currents (Kordas, 1970; Adams, 1976) by increasingthe burst duration of channels (Neher and Steinbach, 1978). Ourdata suggest that N₂O acts neither like a classical open-channelblocker nor like a use-dependent, slowly reversible channel blocker.As a representative of another class of NMDA channel blockers,we examined the effects of the noncompetitive antagonist Mg²⁺. At a concentration of 15 µM, a concentration lower than thatat which presynaptic effects of Mg²⁺ are observed (Tong and Jahr, 1994a), Mg²⁺ occluded peak NMDAR EACs by an amount similar to that obtainedwith ketamine and N₂O (Fig. 1E). Like N₂O, Mg²⁺ had no detectable effect on the EAC decay (Fig. 1F). These effectsof Mg²⁺ are consistent with the rapid block by Mg²⁺ of NMDA receptor channels, the ability of NMDA channels to closewith Mg²⁺ still bound, and the lack of prolongation of channel burst duration(Nowak et al., 1984). These results suggest that if N₂O acts viaa channel block mechanism, the mechanism is unlikely that of aclassical open-channel blocker or of a slowly dissociating open-channelblocker likeketamine.

Effect of N₂O on responses to exogenous NMDA

To explore further the effects of N₂O at NMDA receptors and to compare these effects with the other clinically used NMDA receptorantagonist/anesthetic, we examined the effects of ketamine andN₂O on NMDA-induced currents. We found that ketamine blockadedeveloped more slowly than did N₂O blockade when the antagonistwas rapidly coapplied with NMDA (Fig. 2). This slow blockade resultedprimarily from the use dependence of ketamine actions rather thanfrom slow binding of ketamine, because ketamine preapplied for2 sec before the addition of NMDA resulted in peak NMDAR currentsnearly equal in amplitude to those responses obtained with simultaneouscoapplications of agonist and antagonist (Fig. 2A). In contrastto ketamine blockade, N₂O blockade was nearly immediate when theapplication of agonist and antagonist was simultaneous (Fig. 2B).This indicates that the N₂O effect develops more rapidly thandoes that of ketamine. In combination with the lack of effectof N₂O on NMDAR EAC time course, this result suggests that N₂Oblockade is not dependent on channel opening.

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Figure 2. N₂O exhibits rapid block of NMDAR currents. A, Responses to 20 µM NMDA (0.5 mM Ca²⁺ and nominally 0 mM Mg²⁺ present in the extracellular recording solution) in the presence or absence of 3 µM ketamine. The horizontal bars over the traces indicate the timing of NMDA and ketamine applications. B, The same application protocol performed on another cell using N₂O as the antagonist. Note the rapid development of block with coapplication of agonist and antagonist.

We also compared the voltage dependence of N₂O and ketamine blockade. For these experiments antagonists were coapplied withagonists during the steady-state phase of agonist-induced responses(Fig. 3). When the degree of blockade of antagonists was comparedat $-$ 60 and +60 mV, blockade with both drugs exhibited significantvoltage dependence. However, N₂O exhibited much weaker voltagedependence than did ketamine (Fig. 3D) at a concentration thatyielded an equivalent amount of block when effects were collapsedacross voltages (Fig. 3D, legend). When the complete current-voltagerelationships for ketamine and N₂O were examined, currents bothin the presence and in the absence of antagonist showed reversalpotentials near 0 mV (data not shown). We also examined the voltagedependence of Mg²⁺ blockade, which, as expected, exhibited strong voltage dependence,similar to that of ketamine (55 ± 1% block relative to baselineamplitude of $-$ 195 ± 37 pA at $-$ 60 mV and 2 ± 1% block relativeto baseline of +222 ± 40 pA at +60 mV; data not shown).

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Figure 3. Voltage dependence of N₂O and ketamine block of NMDA receptors. A-C, Raw traces at holding potentials of $-$ 60 mV (inward currents) and +60 mV (outward currents) exemplifying the effects of ketamine (A), N₂O (B), and air (C) on NMDAR currents. Baseline holding currents have been subtracted. The horizontal bars over the traces indicate the timing of drug applications. D, Summary data showing fractional inhibition of steady-state NMDAR currents by ketamine (5 µM; closed circles) or N₂O (80%; open circles) at $-$ 60 and +60 mV. Collapsed across voltages, there was no significant difference between antagonists (at the concentrations used) in the amount of block [repeated measures ANOVA with drug as a between-cell variable and voltage as a within-cell variable, F_(1,17) = 0.66; p = 0.42; n = 9 ketamine and 10 N₂O cells]. There was significant voltage dependence to the degree of inhibition [F_(1,17) = 156.4; p < 0.001]. Post hoc comparisons revealed that both drugs exhibited significant voltage dependence (p < 0.001 for both drugs, paired t test). However, there was also a significant interaction between antagonist and voltage [F_(1,17) = 16.7; p = 0.001], indicating that ketamine exhibits significantly stronger voltage dependence than N₂O exhibits.

The voltage dependence of N₂O blockade of NMDA receptors, although weak, is puzzling because N₂O is an uncharged molecule.Some ion channel blockers derive some of their apparent voltagedependence from direction of current flow rather than from voltageper se. For instance, derivatives of tetraethylammonium exhibitless block of potassium channels when the membrane potential ismaintained but when the driving force on potassium is decreasedby elevating extracellular potassium concentration (Armstrong,1971). In addition, the degree of potassium channel block by bothBa²⁺ and charybdotoxin can be influenced by permeant ion concentration(Armstrong et al., 1982; MacKinnon and Miller, 1988).

To investigate the possibility that this mechanism might underlie the apparent voltage dependence of N₂O, we used a pipettesolution of either cesium chloride or choline chloride and examinedthe effect of N₂O on NMDA responses. As expected, when cholinewas used as the main intracellular cation, reversal potentialsfor NMDA currents were shifted to approximately +50 mV from thetypical 0 mV (data not shown). When examined at $-$ 30 mV, N₂O blockof inward NMDA currents was not significantly different betweencesium- and choline-loaded cells (Fig. 4A-C). However, when 5µM ketamine was used as an antagonist, blockade of NMDA currentsat $-$ 30 mV was significantly enhanced in choline-loaded cells versuscesium-loaded cells (Fig. 4D-F). The blockade of NMDA currentsby Mg²⁺ (15 µM) was also greater in choline-loaded cells than in cesium-loadedcells examined at the same membrane potential (Fig. 4G-I). Theseresults suggest that enhancing the inward driving force on ionsthrough NMDA receptors does not affect the degree of block byN₂O and make it unlikely that the apparent voltage dependenceof N₂O blockade can be explained by an effect of current flowthrough the NMDA channel. On the other hand, current flow throughthe NMDA channel significantly interacts with ketamine and Mg²⁺ blockade, suggesting this mechanism plays a role in the apparentvoltage dependence of ion channel block.

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Figure 4. Effect of changing the reversal potential of the NMDAR current on blockade of NMDAR responses. A, B, Raw traces from two different cells illustrate the N₂O block with cesium loading (A) and choline loading (B). The horizontal bars over the traces indicate the timing of drug applications. C, At a holding potential of $-$ 30 mV, the degree of N₂O block in cesium-loaded cells was not significantly different from the degree of block in cells loaded with choline (p > 0.3, unpaired t test; n = 14 cesium- and 11 choline-loaded cells). Choline loading changed the reversal potential of currents from ~0 to approximately +50 mV. D, E, Raw traces from two different cells illustrate the ketamine block in cesium- versus choline-filled cells. F, At a holding potential of $-$ 30 mV, the degree of ketamine (5 µm) block in choline-loaded cells was significantly greater than the block in cesium-loaded cells (p < 0.001, unpaired t test; n = 7 cesium- and 6 choline-loaded cells). G-I, A protocol similar to that shown in A-C and D-F was used except that Mg²⁺ was used as the antagonist and the holding potential was $-$ 60 mV. Raw traces in all panels have been filtered at 10 Hz for display.

Effect of N₂O on AMPAR EACs and tests of presynaptic N₂O effects

We next examined the effect of N₂O on AMPAR EACs in the presence of 25-50 µM D-APV and 1 mM Mg²⁺ to block the NMDAR component of EACs. AMPAR EACs were also inhibitedby N₂O, but less than were NMDAR EACs (Fig. 5). The inhibitionby N₂O of both NMDAR and AMPAR EACs compared with air controlsmay suggest a presynaptic effect of N₂O because AMPAR and NMDAREACs are similarly affected by presynaptic manipulations (Tongand Jahr, 1994a). To determine whether the effects on AMPAR EACswere caused by presynaptic or postsynaptic effects of N₂O, wefirst examined paired-pulse modulation, a form of plasticity thatis susceptible to presynaptic modulation both in situ and in microcultures(McNaughton, 1980; Mennerick and Zorumski, 1995). Previously,we found that many different presynaptic modulators alter thedegree of paired-pulse depression of microculture AMPAR EACs (Mennerickand Zorumski, 1995). However, N₂O failed to significantly changethe degree of paired-pulse depression observed in response topaired stimulation delivered 100 msec apart (Fig. 5C,D).

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Figure 5. Effect of N₂O on AMPAR EACs. A, Averaged waveforms of interleaved AMPAR EACs in the presence of air or N₂O are shown. B, Average depression induced by 80% N₂O on peak AMPAR EACs (n = 8) is shown. Depression was calculated as: (P_n/P_a) $-$ 1, where P_n is the peak response in the presence of N₂O, and P_a is the peak response in the presence of air. C, D, Paired-pulse depression of AMPAR EACs was unaffected by N₂O. C, Example currents are from the same cell shown in A. Paired-pulse interval was 100 msec. D, The degree of paired-pulse modulation was calculated by subtracting 1 from the test peak (P₂)/conditioning peak (P₁) ratio (P₂/P₁). Therefore, depression yields negative values, and facilitation yields positive values.

As another test for presynaptic effects of N₂O, we examined the frequency of AMPAR mEPSCs (recorded with 500 nM tetrodotoxinin the extracellular recording solution) in the presence of airand N₂O. In six neurons we could detect no change in mEPSC frequencywith exchange of N₂O for air in the extracellular bath (1.1 ±0.7 Hz in air; 1.1 ± 0.6 Hz in N₂O; data not shown). However,we were also unable to detect a significant change in mEPSC amplitudein the presence of N₂O in this experiment. For instance, in thecell with the highest frequency of mEPSCs, mEPSC peak amplitudewas $-$ 33.7 ± 2.1 pA in air (n = 118 events) and $-$ 36.1 ± 1.9 pAin N₂O (n = 146 events; p > 0.4). Although this could representa lack of postsynaptic effect, the negative result is more likelyattributable to the small effect of N₂O on peak synaptic responsescoupled with the large variability in mEPSC amplitudes (Bekkerset al., 1990).

As a third experiment to determine whether N₂O might have presynaptic effects, we examined effects on voltage-gated calciumcurrents in hippocampal neurons. Because a common target of manymodulators of presynaptic function is HVA calcium channels (Miller,1990; Wu and Saggau, 1997), we first examined the effect of N₂Oon HVA calcium current in hippocampal neurons. We found no reliableeffect of 80% N₂O on soma HVA currents in these cells comparedwith currents in the presence of air (98.7 ± 1.5% of control;control peak amplitude, $-$ 327 ± 74 pA; n = 5; Fig. 6). Becauseof the difficulty of spatially voltage-clamping cultured neurons,we also examined HVA calcium currents in acutely dissociated ratdorsal root ganglia neurons, which do not have extensive processes.These results also showed no effect of N₂O on HVA currents (datanot shown).

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Figure 6. Effect of N₂O on HVA calcium currents in hippocampal neurons. A, Superimposed leak-subtracted traces from a hippocampal neuron in the presence of air and 80% N₂O. Voltage pulses from $-$ 70 to $-$ 10 mV were used to elicit the currents; 5 mM BaCl₂ was used as the charge carrier as detailed in Materials and Methods. B, Time course plot showing the lack of effect of N₂O on the amplitude of leak-subtracted barium current in another neuron.

Effect of N₂O on exogenously activated AMPAR currents

The above experiments suggest that presynaptic depression does not contribute to the depression of excitatory synaptic transmission.Therefore, we designed experiments to assess more directly thepossibility of postsynaptic modulation of AMPA glutamate receptorsby N₂O. We examined the effect of N₂O on currents elicited bykainic acid, a weakly desensitizing agonist at AMPA receptors.Steady-state responses to 50 µM kainate averaged $-$ 568 ± 146 pAin the presence of air and were inhibited by 32 ± 2% at $-$ 60 mV(n = 10). With a higher concentration of agonist (1 mM KA), thedegree of blockade was similar ( $-$ 29 ± 2% change; n = 11; datanot shown). When blockade at $-$ 60 and +60 mV was compared, a similardegree of antagonism was observed at both potentials (p > 0.15,paired t test; Fig. 7). These results suggest that like blockadeof NMDA receptors, N₂O blockade of AMPA receptors appears noncompetitive.However, unlike the blockade of NMDA receptors, there is no detectablevoltage dependence to the block. The effects observed are unlikelyto be caused by blockade of high-affinity kainate receptors, becausethese receptors are rapidly desensitized with the drug applicationprotocols used (Wilding and Huettner, 1997). Also, at the highconcentration of kainate, mostly AMPA receptors are activatedin hippocampal cells because of the greater numbers of these receptors.Therefore, the similar degree of block at the two concentrationssuggests that blockade is primarily of postsynaptic AMPA receptors.

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Figure 7. Effect of N₂O on kainic acid (KA)-induced currents. A, Exemplar traces obtained from one neuron at $-$ 60 mV (inward current trace) and at +60 mV (outward current trace). Drug applications were made during the periods indicated by the horizontal bars. B, Summary of the effect of N₂O on the responses to 50 µM KA at $-$ 60 and at +60 mV (n = 10).

Tests of N₂O interaction with presynaptic metabotropic receptors and with glutamate transporters

Because the present results show that N₂O interacts with both NMDA and non-NMDA subtypes of ionotropic glutamate receptors,we also assessed whether N₂O targets presynaptic metabotropicglutamate receptors. We showed previously that activation of metabotropicreceptors causes presynaptic depression at microculture autapticsynapses (Mennerick and Zorumski, 1995). Similarly, in the presentstudy we found that the combination of 100 µM 1S,3R-1-aminocyclopentane-1,3-dicarboxylicacid (1S,3R-ACPD) plus 100 µM L-AP-4 to activate groups I, II,and III metabotropic receptors (Conn and Pin, 1997) depressedAMPAR EACs by 36 ± 9% from a baseline amplitude of $-$ 3379 ± 859pA (all responses recorded in the presence of air; n = 7). Theeffect of N₂O on peak AMPAR EAC was similar in the absence orpresence of metabotropic agonists ( $-$ 13 ± 2% N₂O-induced changerelative to responses in the absence of metabotropic agonists; $-$ 11 ± 2% change relative to responses in the presence of metabotropicagonists; n = 8; Fig. 8). From this experiment, we conclude thatN₂O does not interact with the metabotropic receptors involvedin mediating depression of synaptic responses. We cannot excludean effect of N₂O on other physiological effects of metabotropicreceptors, such as phosphoinositide hydrolysis.

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Figure 8. N₂O does not interact with metabotropic glutamate receptor-induced synaptic depression. Left, The effect of N₂O on the AMPAR EAC obtained in the absence of metabotropic agonists (air vs N₂O). Right, The effects of N₂O after the addition of 100 µM 1S,3R-ACPD plus 100 µM L-AP-4, which depressed transmission.

Glutamate transporters are another class of plasma membrane glutamate-binding proteins that might be a target for N₂O actions.Glutamate transporters in situ and in culture rapidly bind glutamateafter synaptic release (Mennerick and Zorumski, 1994; Tong andJahr, 1994b). Under certain conditions, transport inhibitors caninfluence the peak glutamate concentration obtained (Tong andJahr, 1994b) or increase the effective lifetime of glutamate actingat postsynaptic receptors (Mennerick and Zorumski, 1994). Additionally,glutamate transporters may be the target of other volatile anesthetics(Hirofumi et al., 1997). For these reasons, we directly testedthe possibility that glutamate transporters are a target of N₂Oactions by exploiting the electrogenicity of glutamate transporters(Brew and Attwell, 1987). We examined the effect of N₂O on D-aspartatecurrents elicited from microculture glia filled with a potassiumgluconate solution. Under the conditions of this experiment, thecurrent generated by D-aspartate application should result fromthe electrogenic transport current produced by the net influxof positive charge on each transporter cycle but not from therecently described anion conductance also gated by glutamate transporteractivation (Wadiche et al., 1995). In four glial cells, D-aspartatecurrents averaged $-$ 45.5 ± 21 pA. We observed little change inthe D-aspartate current with coapplication of 80% N₂O (+8 ± 2%change compared with the current with D-aspartate in the presenceof air). In two additional cells there was an apparent enhancementof the glutamate transporter current when D-aspartate and N₂Owere coapplied (the trace shown in Fig. 9 is an example of a modestenhancement). However, this apparent change was unrelated to aneffect on glutamate transporter currents, because the currentwas elicited by N₂O alone in the absence of D-aspartate (datanot shown) and was present in one cell despite an undetectableD-aspartate current. Furthermore, the response to N₂O alone wasnot observed in all glial cells in which transporter currentswere detected. Finally, transporter currents under the presentconditions reverse direction at potentials more positive than+50 mV (Brew and Attwell, 1987), whereas the N₂O-induced glialcurrent reversed direction near $-$ 70 mV (data not shown). Becauseof its small amplitude and variability, the direct effect of N₂Oon glial membrane conductance was not studied further in the presentwork.

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Figure 9. Effect of N₂O on glial glutamate transporter currents induced by 100 µM D-aspartate. The trace shows the response of a microculture glial cell to the application of 100 µM D-asp in the presence of air and N₂O. The horizontal bars denote application times.

N₂O and GABAR IACs

Approximately 50% of the neurons in postnatally derived hippocampal microcultures are GABAergic (Bekkers and Stevens, 1991;Segal, 1991). We studied the effect of N₂O on IACs by replacinggluconate in the whole-cell pipette with chloride to cause IACsto appear as inward currents at $-$ 70 mV. Consistent with weak effectsof N₂O on GABA_A receptor-mediated currents in response to exogenousGABA (Dzoljic and Duiijn, 1998; Jevtovic-Todorovic et al., 1998),we observed small effects of N₂O on GABAR IACs. Peak GABAR IACswere not affected by 80% N₂O (2 ± 3% potentiation compared withair; n = 21). Measured using the 10-90% decay time to quantifythe IAC time course, IAC decays were variably affected, rangingfrom no effect to 50% prolongation (n = 21; Fig. 10). Overall,N₂O resulted in a 15 ± 5% increase in the IAC charge transfer(n = 21). As a comparison we used pentobarbital, an anestheticknown to potentiate GABAergic transmission (Franks and Lieb, 1994).Because 80% N₂O is approximately one-half the MAC required toproduce anesthesia in rats (Jevtovic-Todorovic et al., 1998),we used 25 µM pentobarbital, which should represent an anestheticconcentration equivalent to 80% N₂O (Franks and Lieb, 1994), asa comparison. Slowing of IAC decays was much more pronounced withpentobarbital compared with N₂O; pentobarbital treatment increasedthe IAC charge transfer by 86 ± 13%, with little effect on IACpeak amplitude (8 ± 7% change; n = 4; Fig. 10A,B). Paired-pulsedepression of IACs was not affected or was slightly reduced byN₂O ( $-$ 36 ± 4% paired-pulse change in air vs $-$ 27 ± 7% change inN₂O; n = 14; p > 0.08, paired t test; Fig. 10C), suggesting thata presynaptic potentiation of IACs is unlikely. As another anestheticcomparison, we examined the effect of ketamine on IPSCs. At 100µM, a concentration approximately two orders of magnitude higherthan anesthetic concentrations (Franks and Lieb, 1994), ketaminehad no effect on peak IACs or on total IAC charge transfer ( $-$ 4± 8% change in peak; 6 ± 9% change in charge; n = 4).

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Figure 10. Effect of N₂O on GABAergic IACs. A, Left, The effect of N₂O on the IAC in baseline conditions. Right, The effect of 25 µM pentobarbital (Pb) on IACs from the same neuron. After the experiment, 25 µM bicuculline (Bic) was added to confirm that the response was a GABAergic IAC. Average peak amplitude of 21 baseline IACs was $-$ 4029 ± 797 pA. B, Summary data showing the effect of 80% N₂O (n = 21) and 25 µM Pb (n = 4) on the 10-90% decay time of GABAR IACs. The average 10-90% decay time for 21 baseline IACs was 101.4 ± 18.1 msec. C, Paired-pulse stimulation of the GABAergic neuron depicted in A demonstrating that there is no change in paired-pulse depression in cells that show a prolonged IAC. Responses are superimposed IACs in the presence of air and N₂O.

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Our results show that synaptic targets of the widely used inhalation anesthetic N₂O are confined to postsynaptic sites inhippocampal microcultures. Although a lack of effect of N₂O onGABA_A receptors has been reported previously (Little and Thomas,1986), a recent paper using isolated hippocampal neurons and alocal perfusion system similar to that used here found potentiationof responses to exogenously applied muscimol (Dzoljic and Duiijn,1998). Similarly, a study of invertebrate glutamate receptorsreported blockade by N₂O (Macdonald and Ramsey, 1995). Our presentresults combined with our previous results (Jevtovic-Todorovicet al., 1998) suggest that several postsynaptic effects may contributeto the anesthetic/analgesic effects of N₂O.

As part of our effort to examine possible presynaptic targets of N₂O, we examined HVA calcium currents, the general classof calcium current thought to underlie fast neurotransmitter releaseat glutamate and GABA synapses. We conclude that presynaptic effectsvia calcium channels are unlikely to underlie the modulation ofsynaptic transmission observed. Although we cannot eliminate thepossibility that the presynaptic terminal may possess a differentcomplement of calcium channels than those examined in the somata,previous studies suggest that effects on soma calcium currentsare predictive of synaptic effects (Wu and Saggau, 1997).

N₂O has somewhat nonselective but differential effects on excitatory and inhibitory synaptic currents. It remains to be determinedwhich of the three postsynaptic effects described here might bemost important in determining the anesthetic/analgesic propertiesof N₂O. Of the three effects of N₂O detected in the present study,blockade of NMDAR EACs was quantitatively the largest effect ofN₂O. Although GABA_A receptors are a common target of many anesthetics,including volatile anesthetics and barbiturates, the effects ofN₂O on IACs were significantly weaker than were the effects ofan anesthetically equivalent concentration of pentobarbital (Franksand Lieb, 1994). An anesthetic with the property of an AMPA receptorantagonist has not been described. Because blockade of glutamatereceptors and potentiation of GABA_A receptors would both tendto dampen CNS excitability, it is possible that all three effectswork in concert to produce clinical anesthesia. It is of notethat the MAC necessary for N₂O to produce anesthesia in 50% ofrats is 150% (v/v) (Gonsowski and Eger, 1994), a concentrationunachievable except under hyperbaric conditions. We assume thatthe effects observed in the present work at subanesthetic concentrationsof N₂O can be extrapolated to anesthetic doses (and may be morepronounced at these doses). However, the extent to which the postsynapticeffects described here underlie the anesthetic/analgesic propertiesof N₂O remains to bedetermined.

Our results do not address the mechanism by which N₂O blocks ionotropic glutamate receptors and potentiates GABA receptors.Because of the larger magnitude of the effect on NMDA receptorsand because of the novelty of this effect, we examined NMDA receptorblockade in most detail. Via these analyses we can make some qualifiedstatements regarding the mechanism of N₂O block of NMDA receptors.Our previous work showed that N₂O exhibits a noncompetitive inhibitionprofile in dose-response relationships (Jevtovic-Todorovic etal., 1998), as does the other clinically used NMDAR antagonistanesthetic ketamine. However, the present work shows that N₂Oblockade of NMDA receptors is much faster and more easily reversiblethan the block exhibited by ketamine. In addition, the lack ofeffect on the NMDAR EAC time course suggests that N₂O is unlikelyto possess a use dependence like that of classical local anestheticagents such as procaine acting at neuromuscular nicotinic acetylcholinereceptors (Neher and Steinbach, 1978). The term "uncompetitiveinhibition" has been used to describe antagonists with a requirementfor agonist binding (Pennefather and Quastel, 1992). Our datashow no evidence of an uncompetitive mechanism for N₂O.

A difference in the blockade of AMPA versus NMDA glutamate receptors is the voltage dependence exhibited by N₂O block of NMDAbut not of AMPA receptors. Because N₂O is not charged, it seemsunlikely that this voltage dependence signifies that N₂O sensesthe transmembrane electrical field and binds within the channelpore. Our results suggest that the direction of current flow isunlikely to impart apparent voltage dependence to the N₂O blockadevia a knock-on/knock-off type mechanism. Rather, because NMDAreceptor gating has been shown to exhibit inherent voltage dependenceaside from physiological blockade by Mg²⁺ (Nowak and Wright, 1992), it is likely that the apparent voltagedependence of N₂O is caused by increased N₂O binding to channelconformations adopted preferentially at negative potentials. Incontrast, changing the reversal potential of NMDAR currents clearlyinfluences the degree of ketamine and Mg²⁺ blockade, suggesting that a knock-on/knock-off mechanism likelyexplains at least part of the apparent voltage dependence of blockadeof these two agents (MacDonald and Nowak, 1990).

Ketamine and Mg²⁺ represent two different classes of molecules that interact with the NMDAR ion channel. Although ketamine exhibitsuse dependence, Mg²⁺ apparently is capable of interacting with the closed NMDAR (Nowaket al., 1984; MacDonald et al., 1987; MacDonald and Nowak, 1990).Despite these differences in mechanism, the degree of block byboth agents shares strong voltage dependence and at least partialdependence on permeant ion concentration (Fig. 4). N₂O sharesneither of these features. Although our data do not definitivelysuggest a mechanism of N₂O action, this dissimilarity betweenN₂O and two known channel blockers makes it less likely that N₂Ointeracts directly with the NMDAR ionchannel.

Although our results suggest that N₂O targets multiple postsynaptic sites, we failed to detect effects on responses generatedby several other classes of transmembrane proteins. We detectedno effect on currents mediated by HVA calcium channels, no effecton electrogenic glutamate transporter currents, and no interactionwith presynaptic metabotropic glutamate receptors. The lack ofN₂O effect on these responses suggests some specificity of actiontoward ligand-gated ion channels. The extent to which N₂O mayinteract with other classes of ligand-gated ion channels awaitsfurtherstudy.

  FOOTNOTES

Received Aug. 10, 1998; revised Sept. 15, 1998; accepted Sept. 21, 1998.

This work was supported by a Lucille P. Markey Postdoctoral Fellowship (S.M.); by a Foundation for Anesthesiology Educationand Research/Abbott New Investigator Award (V.J.-T.); by NationalInstitutes of Health Grants AG11355 (J.W.O), DA05072 (J.W.O),MH45493 (C.F.Z), GM47969 (C.F.Z.), and MH00964 (C.F.Z.); and bya grant from the Bantly Foundation (C.F.Z.). We thank Drs. JimHuettner, Joe Henry Steinbach, and Chris Lingle for advice onthe NMDA receptor experiments and Ann Benz for assistance withthe primarycultures.
Correspondence should be addressed to Dr. Steven Mennerick, Department of Psychiatry, Washington University School of Medicine,4940 Children's Place, St. Louis, MO63110.

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Results
Discussion
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