Adenosine Release Mediates Cyanide-Induced Suppression of CA1 Neuronal Activity

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Volume 17, Number 7, Issue of April 1, 1997 pp. 2355-2364
Copyright ©1997 Society for Neuroscience

Adenosine Release Mediates Cyanide-Induced Suppression of CA1 Neuronal Activity

Ping Jun Zhu and Kresimir Krnjevi $c'$
Anesthesia Research and Physiology Departments, McGill University, Montréal, Québec, Canada H3G 1Y6

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The rapid suppression of CNS function produced by cyanide (CN) was studied by field, intracellular, and whole-cell recordingin hippocampal slices (at 33-34°C). Population spikes and fieldEPSPs were depressed by 4-5 min bath applications of 50-100 µMCN (IC₅₀ was 18 µM for spikes and 72 µM for EPSPs). The actionsof CN were reversibly suppressed by the adenosine antagonists8-sulfophenyltheophylline (8-SPT; 10 µM) and 8-cyclopentyl-1,3-dipropylxanthine(DPCPX; 0.2 µM), potentiated by the adenosine transport inhibitordipyridamole (0.5 µM), but unaffected by the K_ATP channel blockerglyburide (10 µM). Therefore the CN-induced reductions of synapticefficacy and postsynaptic excitability $---$ demonstrated by synapticinput:output plots $---$ are mediated mainly by adenosine. In whole-cellor intracellular recordings, CN depressed EPSCs and elicited anincrease in input conductance and an outward current, the reversalpotential of which was approximately $-$ 90 mV (indicating that K⁺ was the major carrier). These effects also were attenuated by8-SPT. In the presence of 1 mM Ba, CN had no significant postsynapticaction; Cs (2 mM) also prevented CN-induced outward currents butonly partly blocked the increase in conductance. Another 8-SPT-sensitiveaction of CN was to depress hyperpolarization-activated slow inwardrelaxations (Q current). At room temperature (22-24°C), althoughit did not change holding current and slow inward relaxations,CN raised the input conductance; this effect also was preventedby 8-SPT (10 µM), but not by glyburide (10 µM). Adenosine releasethus appears to be the major link between acute CN poisoning andearly depression of CNS synaptic function.
Key words: adenosine antagonists; K_ATP channel blocker; synaptic transmission; outward current; input conductance; barium; cesium

INTRODUCTION

Cyanide (CN) is a specific inhibitor of cytochrome oxidase, which is essential for mitochondrial ATP production (Keilin, 1930;Isom and Way, 1984). Its use as a suicidal, homicidal, chemicalwarfare, and genocidal agent is well known. CN has a characteristicallyrapid action, especially on the CNS. In cases in which a lethaldose has been administered, it frequently has been noted thatthe electrical activity of the brain has stopped although theheart is still beating (Bernthal et al., 1928; Dixon and Elliott,1929; Barcroft, 1931).

CN quickly but reversibly depresses synaptic transmission in hippocampal slices (Aitken and Braitman, 1989). CN causes a hyperpolarizationof some neurons (Biscoe and Duchen, 1989; Duchen, 1990; Cumminset al., 1991; Murphy and Greenfield, 1991; Latha et al., 1994)but sharply depolarizes others (Haddad and Jiang, 1993; Sun andReis, 1994). The exact links between CN-induced metabolic inhibitionand the almost immediate suppression of CNS function remain unclear.

Several authors have suggested that the opening of ATP-sensitive K channels (Noma, 1983) by a fall in [ATP]_i may explain thedepressant action of CN on various cells (Nichols and Lederer,1990; Murphy and Greenfield, 1991; Findlay, 1993; Schwanstecherand Panten, 1993).

On the other hand, adenosine is known to be released in the brain by anoxia and ischemia (Berne et al., 1974; Van Wylen etal., 1986; Richardt et al., 1987, 1994); in some isolated neuralpreparations, CN suppresses adenosine reuptake and so causes itsextracellular accumulation (Thampy and Barnes, 1983; Maire etal., 1984; Kurbat et al., 1993). Adenosine is one of the mostpotent neuromodulators (Phillis and Wu, 1981; Dunwiddie, 1985;Snyder, 1985; Greene and Haas, 1991): it inhibits neuronal activityby enhancing K⁺ conductance, which causes hyperpolarization (Greene and Haas,1985; Proctor and Dunwiddie, 1987; Trussell and Jackson, 1987),and by decreasing Ca²⁺ currents in nerve endings, it reduces transmitter release (Scholzand Miller, 1991; Mogul et al., 1993; Wu and Saggau, 1994). Therefore,adenosine release could be responsible for the nearly immediateloss of synaptic transmission produced by CN $---$ in keeping with thedemonstrated involvement of adenosine in the block of synaptictransmission in hippocampal slices produced by other types ofenergy deprivation, such as anoxia and hypoglycemia (Fowler, 1993;Zhu and Krnjevi $c'$ , 1993, 1997).

In the present experiments we examined the cellular mechanisms of the action of CN in hippocampal slices. The results provideclear evidence that adenosine is an important mediator of theaction of CN on neuronal activity.

A preliminary report of some of these results has appeared in abstract form (Zhu and Krnjevi $c'$ , 1995).

MATERIALS AND METHODS
Hippocampal slices from male Sprague Dawley rats were prepared from halothane-anesthetized Sprague Dawley rats (Charles River,Québec, Canada) weighing 110-180 gm. After decapitation, thebrain was removed quickly into cold artificial cerebrospinal fluid(ACSF) at ~4°C, well oxygenated with 95% O₂/5% CO₂ (carbogen).Its composition was (in mM): NaCl 124, KCl 3, MgCl₂ 1.3, CaCl₂2.0, NaH₂PO₄ 1.2, and glucose 11, pH 7.3. For all extracellularand some intracellular recordings, 450-µm-thick transverse sliceswere cut with a McIlwain tissue chopper. Especially for whole-cellrecordings, 350-400 µm slices were cut with a Vibroslice (CampdenInstruments, UK). The slices were allowed to recover in carbogenatedACSF at room temperature for >1 hr before recordings began. Allexperiments were performed on fully submerged slices kept at 33-34°C(Zhu and Krnjevi $c'$ , 1994).

Field recordings were made with 2 M NaCl electrodes from the CA1 pyramidal layer or stratum radiatum. To evoke synaptic responses,we applied stimuli at 0.1 Hz through insulated nickel-chromiumwires placed in the stratum radiatum. Intracellular recordingswere obtained with 3 M KCl electrodes (70-90 M $Omega$ ). Whole-cell recordingswere done "blind" (Blanton et al., 1989), with patch pipettes(4-6 M $Omega$ ) filled with (in mM): 150 KMeSO₄, 10 HEPES, 2 MgCl₂, 0.1CaCl₂, 1.1 EGTA, 2 ATP, and 0.4 GTP. An Axoclamp 2A amplifier(Axon Instruments, Foster City, CA) was used for all experiments,including voltage-clamping in the discontinuous mode, at a switchingfrequency of 3.5-6.0 kHz. The head stage output was monitoredcontinuously to ensure adequate settling in each duty cycle.

Drugs were obtained as follows: kynurenate, bicuculline, and dipyridamole from Sigma (St. Louis, MO); KCN from J. T. Baker(Phillipsburg, NJ); 8-cyclopentyl-1,3-dipropylxanthine (DPCPX)and 8-sulfophenyltheophylline (8-SPT) from Research Biochemicals(Natick, MA); tetrodotoxin (TTX) from the Qinhuangdao TradingCorporation (Qinhuangdao, China). Glyburide was a gift from HoechstCanada (Montréal, Canada). The data are expressed as mean ± SEM;whenever possible, differences between means were examined bythe paired t test.

RESULTS

Field recordings
Figure 1A illustrates the gradual disappearance of field potentials when 100 µM CN was applied for 5 min: first, populationspikes and then fEPSPs. After washout of CN, fEPSPs returned beforethe population spikes. In 13 slices, 50-100 µM CN fully suppressedpopulation spikes (down by 99 ± 1.3%).
Fig. 1. CN-induced depression of CA1 excitatory synaptic transmission is blocked by an adenosine receptor antagonist. A, CA1 populationspikes were elicited by stimulating stratum radiatum at 0.1 Hz.The initial positive slope reflects the rising phase of the EPSP,and the sharp downward (negative) deflection is the populationspike (50% maximal). Bath application of 100 µM KCN for 5 minreversibly depressed transmission. B, Dot plots of CA1 populationspike amplitude in another slice. Top, Time course of CN-induceddepression. Middle, The action of CN was strongly attenuated by8-SPT. Bottom, Partial recovery of the action of CN after washingslice for 60 min. CN superfusion is marked by arrows. C, D, Dose-responsecurves for depression of EPSP (C) and population spike (D); 8-SPTshifted both dose-response curves to the right. One hundred percentrepresents full suppression of fEPSP and population spikes. IC₅₀for CN action is indicated by dashed lines. Data from severalexperiments were pooled to obtain mean ± SEM (n = 5-9).
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Adenosine antagonists
To detect a possible role of adenosine in the mechanism of action of CN, we applied the adenosine antagonist 8-SPT (Brunset al., 1980). As shown in Figure 1B, the CN-induced depressionwas attenuated markedly (n = 25): in 10 µM 8-SPT, 50 µM CN reducedpopulation spikes by only 14 ± 8.4% (n = 5) and 100 µM CN by 41± 4.4% (n = 8); these effects of 8-SPT were readily reversible.The dose-response curves for CN thus were shifted to the rightby 8-SPT (Fig. 1C,D): IC₅₀ values for the action of CN on fEPSPsand population spikes were 72 and 18 µM, respectively, under controlconditions and ~4 times higher, 254 and 85 µM, in the presenceof 10 µM 8-SPT. A more selective A₁ adenosine antagonist, DPCPX(Bruns et al., 1987), had a similar action: in 200 nM DPCPX, 100µM CN depressed population spikes by only 51 ± 2.5% (n = 5).

Adenosine transport block
We also looked at the effect of dipyridamole, which raises extracellular levels of adenosine by blocking adenosine transport(Young and Jarvis, 1983; Phillis et al., 1989). Bath applicationsof dipyridamole (0.5 µM) did not delay the block of populationspikes (half-block time was 139 ± 6.4 sec in control runs and138 ± 5.4 sec in the presence of 0.5 µM dipyridamole), but theydelayed significantly the recovery of population spikes afterthe end of CN applications (by 47 ± 10%, for n = 6, p < 0.01,from the control value of 199 ± 1.6 sec), thus confirming a significantinvolvement of adenosine.

K_ATP channel block
Because CN blocks ATP synthesis, we considered whether CN might act by opening ATP-sensitive K (K_ATP) channels. This coulddepress synaptic transmission by hyperpolarizing either pre- orpostsynaptic elements (or both). In six slices, however, the specificblocker of K_ATP channels, glyburide (10 µM), did not prevent thedepression of EPSPs by CN (Fig. 2). The mean times to half-block(from the start of the application of CN) and half-recovery (afterits end) were 127 ± 13.5 and 186 ± 14.6 sec, respectively, incontrol runs; in the presence of 10 µM glyburide, they were virtuallyidentical, 133 ± 10.4 and 191 ± 14.0 sec, respectively.
Fig. 2. K_ATP channel blocker did not attenuate CN-induced depression of synaptic transmission. CA1 population spike (50% maximal)amplitudes are expressed as dot plots. The time of CN applicationis indicated by thick horizontal line in A. Top, Control run.Bottom, In presence of K_ATP channel blocker glyburide (10 µM).
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Synaptic sites of CN action
To identify the site of CN action, we looked for selective changes in the afferent volley (the compound action potential ofafferent axons), EPSP and population spike. In Figure 3A the peak-to-peakamplitude of the afferent volley is plotted as function of stimulusstrength: the lack of effect of CN shows that CN did not alteraxonal excitability.
Fig. 3. Analysis of the site of CN action. A, Plots of afferent volley (peak-to-peak amplitude) as function of stimulus duration showthat neither CN alone (top) nor CN in presence of 8-SPT (bottom)affects the afferent volley. B, The efficacy of synaptic transmissionwas examined by plotting the initial rate of rise of EPSPs asfunction of the size of the afferent volley. Top, CN reduces theslope of the plot and therefore the efficacy of synaptic transmission.Bottom, This effect was nearly abolished by 8-SPT. C, Plots ofpopulation spike as function of initial slope of EPSP (E-S coupling).Top, For a given EPSP, CN decreases corresponding population spike;reduced coupling indicates that CN also affects postsynaptic mechanisms.Bottom, 8-SPT also attenuated this CN action. A and B were recordedfrom CA1 stratum radiatum of same slice. Data in C were recordedfrom CA1 pyramidal layer of another slice.
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The efficacy of synaptic transmission was assessed by plotting the initial rate of rise of fEPSPs as function of afferentvolley size (Fig. 3B); 50 µM CN, applied for 5 min, reduced theslope of such plots by 18 ± 3.5% (for n = 5, p < 0.01). This effectwas prevented by 8-SPT (in the bottom plots of Fig. 3B, CN changedthe slopes by only 2 ± 1.4%, n = 5).

A possible postsynaptic action was investigated by plotting population spike amplitude as function of EPSP rate of rise (Fig.3C). This "E-S relation" is an index of the ability of EPSPs togenerate action potentials (Andersen et al., 1980). As shown bythe top plots of Figure 3C, in the presence of CN EPSPs consistentlygenerated smaller population spikes. In five slices, the meanreduction (estimated by comparing the areas under plots) was by57 ± 10.9% (p < 0.01), but in the presence of 8-SPT CN producedno significant change ( $-$ 1.9 ± 4.5%, n = 5; bottom plots in Fig.3C). Judging by these data, the depression of transmission inducedby a brief CN application $---$ apparently affecting both synaptic efficacyand E-S coupling $---$ is caused mainly by adenosine.

Whole-cell and intracellular recordings
The effect of CN on synaptic transmission was examined further by whole-cell recording under voltage clamp. As shown in Figure4A, 300 µM CN nearly abolished EPSCs elicited by stimulation ofstratum radiatum. In nine neurons, 3-4 min applications of CN(200-300 µM) reduced EPSCs by 94 ± 3.1% from control values of0.39 ± 0.03 nA, at V_H $-$ 70 mV. In the presence of 10 µM 8-SPT,CN was far less effective (Fig. 4B), depressing EPSCs by only21 ± 11.6% (p > 0.10) from control values of 0.44 ± 0.07 nA (n= 4).
Fig. 4. 8-SPT prevents CN-induced suppression of EPSCs. In whole-cell recording from a CA1 neuron, EPSCs were elicited by stimulationof stratum radiatum at 0.1 Hz. Membrane potential was held at $-$ 70 mV throughout. A, Control run. B, From same neuron in presenceof 8-SPT (10 µM).
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Postsynaptic changes
In voltage-clamp recordings with intracellular (3 M KCl) electrodes (Fig. 5A), at V_H approximately $-$ 70 mV, CN elicited verysubstantial outward currents (176 ± 4.0 pA) and increased G_N by20 ± 2.6% (p < 0.001, n = 16) from control values of 20 ± 1.8nS. Both outward current and conductance rise were reduced by10 µM 8-SPT (Fig. 5B). In the presence of 8-SPT, CN elicited anonsignificant inward current of 35 ± 18 pA, and G_N rose by only2.2 ± 1.3% (p > 0.10) $---$ from 23 ± 2.9 nS (n = 6) (Table 1). Thevoltage dependence of CN action is shown by the current-voltageplots of Figure 6: note the reversal potential near $-$ 90 mV (arrowin Fig. 6A). The difference current evoked by CN is plotted inFigure 6C (open circles). Its reversal at $-$ 90 ± 2.2 mV indicatesthat CN probably activates a K conductance.
Fig. 5. Adenosine mediates outward current and increase in input conductance elicited by CN. Intracellular recording (with 3 M KClelectrode) was from a CA1 neuron under voltage clamp in the presenceof 0.5 µM TTX. Transmitter-mediated responses were minimized furtherby 2 mM kynurenate and 10 µM bicuculline. Hyperpolarizing pulses( $-$ 20 mV, 500 msec $---$ monitored on topmost trace) and correspondingcurrents are shown on expanded time scale before, during, andafter CN application. Zero current levels are indicated by horizontalarrows, at left of traces. Note substantial outward current, aswell as increased conductance (A), which was blocked by 8-SPT(B). C was recorded after 45 min wash.
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Table 1. 8-SPT, Ba, and Cs block increase ( $Delta$ ) in input conductance (nS) elicited by CN (300 µM)

Before CN $Delta$ in CN After wash n

Control 20 ± 1.8 3.9 ± 0.52^*** 19 ± 2.1 16

8-SPT (10 µM) 23 ± 2.9 0.52 ± 0.29 22 ± 2.8 6

Wash 21 ± 9.9 3.2 ± 0.53^** 21 ± 2.5 6

Control 20 ± 5.4 3.4 ± 0.64^* 19 ± 5.1 3

Ba (1 mM) 12 ± 3.2 0.0 ± 0.003 13.5 ± 3.1 3

Wash 15.5 ± 4.4 2.5 ± 0.25^** 16 ± 5.0 3

Control 20 ± 2.6 4.1 ± 0.91^** 20 ± 2.6 9

Cs (2 mM) 15 ± 2.0 1.8 ± 0.76^* 14.5 ± 1.9 9

Wash 11 ± 0.74 2.6 ± 0.68^* 11.5 ± 0.67 4

Data were obtained by intracellular recording with 3 M KCl electrodes at 34°C; n is number of cells tested. ^*** p < 0.001, ^** p < 0.01, and ^* p < 0.05, all paired t tests.

Fig. 6. Voltage dependence of CN-induced current, from cell illustrated in Figure 5. A, Data obtained before, during, and after CNapplication; note intersection of control and test plots near $-$ 90 mV (indicated by arrow). B, The action of CN was stronglyattenuated by 8-SPT. C, Difference currents $---$ obtained by subtractingcontrol values of currents (before CN application) from currentsrecorded in presence of CN $---$ are the currents activated by the actionof CN. Note that relatively large CN difference current (opencircles) was much reduced by 8-SPT (closed circles).
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As observed with hypoxia (Zhang and Krnjevi $c'$ , 1993), the postsynaptic effects of CN were much smaller in whole-cell recordings:at V_H $-$ 55 mV, CN elicited an outward current of only 80 ± 8.2pA, accompanied by a just significant increase in G_N (6 ± 2.9%;p = 0.05) from a low control level of 12 ± 1.0 nS (n = 15). Inthe presence of 8-SPT, CN evoked an inward current of 16 ± 3.9nA, accompanied by a nonsignificant 2 ± 2.5% decrease in inputconductance from control values of 13 ± 1.0 nS (for n = 12). Allof these data suggest that adenosine release is a major componentof the mechanism of action of CN, which reduces postsynaptic excitabilityby activating K channels.

In general, lowering the temperature greatly reduced the effects of CN (like those of hypoxia; Hochachka and Mommsen, 1983;Morris et al., 1991). Nevertheless, CN increased the input conductance(Fig. 7a,b) even in slices kept at 22-24°C. In seven whole-cellrecordings at V_H $-$ 50 mV, applications of 300 µM CN raised G_N by3.7 ± 1.04 nS (p < 0.01; from 10 ± 2.1 nS), but the holding currentdid not change significantly (by 12 ± 12.1 pA, from the controllevel of 69 ± 16.1 pA) $---$ mainly because of the marked positive shiftin reversal potential for the action of CN (at arrow in Fig. 7a),presumably because of the corresponding shift in E_K or the activationof other ionic channels. At room temperature, glyburide (Fig.7c,d) again failed to prevent the CN-induced rise in G_N (by 4.7± 0.85 nS, p < 0.005, n = 6; from a control value of 7.5 ± 0.70nS). These data further support the conclusion that K_ATP channelsdo not contribute significantly to CN-induced responses of CA1neurons. As before, 10 µM 8-SPT abolished the effect of CN (Fig.7e,f), G_N increasing by only 0.3 ± 1.65 nS (n = 6) from a controlvalue of 5.5 ± 0.40 nS.
Fig. 7. Current-voltage plots illustrate the action of CN at room temperature. Data are from whole-cell recordings. Linear portionsof I-V relations are shown expanded in bottom panels. Open circles,squares, and triangles are data obtained before, during, and afterCN application, respectively. Note relatively positive reversalpotentials. CN increased input conductance (a, b); in 10 µM glyburide,the action of CN on conductance was even enhanced (c, d). In eand f, 8-SPT blocked the action of CN. For further details, seetext.
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Barium and cesium
Both Ba (1 mM) and Cs (2 mM) attenuated the postsynaptic action of CN. As a potent blocker of a variety of K channels, Bacan be expected to be an antagonist of CN. Indeed, Ba (1-2 mM)strongly suppressed CN-induced changes in holding current andG_N, as shown in Figure 8. In three cells held at approximately $-$ 70 mV (intracellular recording), Ba (1 mM) abolished the outwardcurrents elicited by CN (113 ± 37 pA), replacing them by smallinward currents (1.3 ± 0.64 pA). The CN-induced increase in G_Nalso was fully blocked by Ba (n = 3) (Table 1). Similar resultswere obtained in whole-cell recordings (with V_H approximately $-$ 55 mV): in 1 mM Ba, CN (300 µM) elicited no significant shiftin base line current ( $-$ 1.4 ± 5.14 pA, n = 8) from the controlbase line of $-$ 14 ± 6.8 pA and had no effect on G_N (0.8 ± 5.4%increase from 8.6 ± 0.46 nS, n = 8).
Fig. 8. Ba blocks CN-induced outward current and reduces input conductance change. Intracellular recording was from CA1 neuron undervoltage clamp in presence of 0.5 µM TTX, 1 mM kynurenate, and10 µM bicuculline. As in Figure 5, traces were accelerated atintervals for better display of currents evoked by hyperpolarizingpulses (monitored in topmost trace), and zero current levels areindicated by horizontal arrows at left. CN-induced outward currentand increase in input conductance (A) were blocked by 1 mM Ba(B). Trace in C shows partial recovery after wash.
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More surprising was the finding that Cs (2 mM) also diminished the outward currents elicited by CN, both in whole-cell andintracellular recordings (Fig. 9). In nine control intracellularrecordings, CN (300 µM) evoked outward currents of 80 ± 15.5 pA(p < 0.001); after adding 2 mM Cs, they were replaced by nonsignificantinward currents of 13 ± 8.1 pA. However, Cs did not fully suppressCN-induced increases in input conductance (Table 1). These resultssuggest that part of the action of CN is mediated by block ofthe hyperpolarization-activated inward cur-rent (I_Q) (Maccaferriet al., 1993; Perkins and Wong, 1995). Indeed, 300 µM CN sharplyreduced I_Q-like slow inward relaxations seen during hyperpolarizingpulses (Fig. 10A). Such data from six neurons are plotted as afunction of membrane potential in the left panel of Figure 10B.The suppression of this effect of CN by 8-SPT (Fig. 10, right panels)is in agreement with previous reports that adenosine reduces I_hin geniculocortical neurons (Pape, 1993) and mesopontine cholinergicneurons (Rainnie et al., 1994). It provides further evidence thatadenosine is the principal mediator of the actions of CN on membranecurrents. Cooling the slices to 22-24°C prevented the CN-induceddepression of the inward relaxations (Fig. 11; n = 6), perhapsowing to reduction of adenosine release. Thus, the postsynaptichyperpolarizing effect of CN appears to be mediated partly byan increase in G_N (presumably mainly a K conductance) and partlyby depression of an I_Q-like inward current.
Fig. 9. CN-induced outward current also is attenuated by Cs. Arrangement as in Figures 5 and 8: outward current (A) was blocked by2 mM Cs (B). Trace in C shows partial recovery of the effectsof CN after wash. As before, zero current levels are indicatedby horizontal arrows at left. Note that Cs did not fully preventCN-induced increase in input conductance.
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Fig. 10. Adenosine antagonist 8-SPT attenuated CN-induced depression of Q-like current. A, Whole-cell recordings of slow inward relaxationsduring hyperpolarizing pulses (Q-like current) (a), their depressionby 300 µM CN (b), and block of this effect by 8-SPT (c, d). Slowinward relaxations $---$ evoked by 500 msec hyperpolarizing voltagesteps ( $-$ 10 to $-$ 60 mV, from V_H $-$ 50 mV) $---$ were measured by subtractinginstantaneous current from steady-state current for each trace.B, Current-voltage relations of inward relaxations before (opencircles) and during CN applications (closed circles). Left, Controlruns (n = 6); right, CN had little effect in presence of 10 µM8-SPT (n = 5).
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Fig. 11. CN did not significantly depress hyperpolarization-activated Q-like current at room temperature (22-24°C). Slow inward relaxationswere evoked as in Figure 10. Shown is voltage dependence of inwardrelaxation before (open circles) and during CN application (closedcircles); n = 6.
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DISCUSSION
The present results confirm an earlier report that CN reversibly suppresses synaptic transmission in CA1 (Aitken and Braitman,1989). In addition, they show that the action of CN is reducedgreatly by DPCPX or 8-SPT and enhanced by dipyridamole and, therefore,principally caused by adenosine release. The adenosine-mediateddepression of EPSPs is mainly attributable to the block of glutamaterelease (Phillis and Wu, 1981; Dunwiddie, 1985; Snyder, 1985;Greene and Haas, 1991). Precisely how adenosine acts on nerveendings is not yet certain. Are the terminal Ca²⁺ currents affected directly or as a result of G_K increase? Thereis also reason to believe that ATP is essential for glutamaterelease (Nicholls, 1989), which thus could be depressed by evenminor depletions of ATP $---$ such as those observed during hypoxiain areas rich in synapses (Lipton and Whittingham, 1982). However,in view of the striking protective effect of the adenosine antagonists,it seems that adenosine must be the principal agent responsiblefor the block of EPSPs.

There had been no previous reports of membrane effects of CN on CA1 neurons in slices. Studies on other neurons revealed avariety of effects, apparently not because of adenosine. Thus,both in the spinal cord and brainstem, CN has a sharp excitatoryand depolarizing action (Godfraind et al., 1971; Haddad and Jiang,1993; Sun and Reis, 1994) $---$ explained by a rapid activation of Naor Ca currents and quite unlike the hyperpolarizing effect ofadenosine on the same cells (Sun and Reis, 1994). By contrast,Murphy and Greenfield (1991) and Trapp and Ballanyi (1995) observedhyperpolarizing effects on neurons in substantia nigra and dorsalvagal nucleus, respectively, which they ascribed to activationof K_ATP channels, caused by depletion of ATP.

In the present experiments on slices, the hyperpolarizing effect was like that seen in acutely dissociated hippocampal neurons(Cummins et al., 1991). It proved to be quite insensitive to glyburideand so unlikely to be mediated by K_ATP channels, but it was verymuch reduced by adenosine A₁ antagonists: the activation of A₁receptors must, therefore, play an essential role in the underlyingmechanism. This should not be surprising, because CN is knownto release adenosine from nerve cells (Maire et al., 1984; Kurbatet al., 1993), and adenosine has a well known hyperpolarizingeffect on hippocampal neurons, produced by a relatively direct $---$ onlyG-protein-mediated $---$ enhancement of G_K (Greene and Haas, 1985; Trusselland Jackson, 1987).

But why does CN not have the same effect on neurons in other parts of the brain? Moreover, one would expect the hyperpolarizingaction of conventional hypoxia to have a similar mechanism. Sofar, there has been little evidence that the hyperpolarization(as opposed to the synaptic block) produced in slices by hypoxiais caused by adenosine (Leblond and Krnjevi $c'$ , 1989; Spuler andGrafe, 1989) (but cf. Zhu and Krnjevi $c'$ , 1997).

One must, therefore, consider some alternative hyperpolarizing mechanism. It is well known that CN raises cytoplasmic freeCa²⁺ in a variety of cells $---$ including several types of neurons (Biscoeand Duchen, 1990; Duchen et al., 1990; Dubinsky and Rothman, 1991;Duchen and Biscoe, 1992; Kaplin et al., 1996), as well as glia(Brismar and Collins, 1993), vascular smooth muscle (Miller etal., 1993), and chromaffin cells (Latha et al., 1994). CN thuscould produce hyperpolarization by activating a Ca²⁺-sensitive G_K (G_K(Ca)). There is, indeed, evidence that hypoxichyperpolarizations are caused by Ca²⁺ release from an IP₃-dependent store (Belousov et al., 1995),likely initiated by glycolytically produced nicotinamide adeninedinucleotide (NADH) (Kaplin et al., 1996).

Are these mechanisms mutually exclusive? Not necessarily. In several kinds of cells adenosine, acting via A₁ receptors, triggersthe formation of IP₃ (Arend et al., 1988; Kohl et al., 1990; Gerwinsand Fredholm, 1992). This IP₃ may be essential for the actionof NADH, because NADH acts by sensitizing IP₃ receptors (Kaplinet al., 1996). Thus, a synergistic convergence of two effectsof CN, enhanced glycolysis and adenosine release, may be necessaryto raise [Ca²⁺] sufficiently to activate G_K(Ca). In keeping with such a mechanism,adenosine increases slow afterhyperpolarizations of CA1 neurons(Greene and Haas, 1985).

Like the activation of G_K by adenosine (Trussell and Jackson, 1987; Gerber et al., 1989), the adenosine-evoked formation ofIP₃ is mediated by a (perhaps the same) pertussis-sensitive G-protein(Arend et al., 1988). However, in their experiments on CA1 neuronspretreated with pertussis toxin, Spuler and Grafe (1989) foundno suppression of anoxic (or hypoglycemic) hyperpolarizations,although adenosine applications were ineffective, and thereforeconcluded that adenosine could not be the essential mediator ofthese hyperpolarizations. One can suppose that, under some conditions,G_K(Ca) (or some other G_K) may be activated by ATP depletion orthat another factor is released, which can substitute for adenosine.Whether adenosine or such an alternative mechanism is predominantpresumably will vary with the general metabolic state, as wellas with local conditions at different sites in the brain. Withregard to CA1 neurons, adenosine clearly accounts for a majorportion of the hyperpolarizing effects of CN.

The question remains whether this is mediated by the G_K that is independent of second messengers (Trussell and Jackson, 1987;Gerber et al., 1989) or by the more complex route via IP₃ andG_K(Ca) suggested above. Our finding that Ba suppresses the effectof CN does not help to distinguish between these alternatives,because Ba blocks a variety of K currents, including I_AHP (Connor,1979), I_M (Constanti et al., 1981), and I_K (Armstrong et al.,1982), as well as that elicited by adenosine (Trussell and Jackson,1987; Gerber et al., 1989).

The present experiments show that Cs also attenuates the action of CN, in agreement with its comparable effect on hypoxichyperpolarizations (Leblond and Krnjevi $c'$ , 1989). Bearing in mindthe well known block of the hippocampal Q current by Cs (Maccaferriet al., 1993), it is likely that the CN-evoked outward currentis caused at least partly by adenosine-induced suppression ofongoing Q current. Indeed, the adenosine antagonist 8-SPT attenuatedthe effect of CN on Q current, in keeping with previous studiesin which adenosine decreased Q-like inward currents (Pape, 1993;Rainnie et al., 1994). On the other hand, there is evidence thatCs depresses the M current (Coggan et al., 1994), which also maybe enhanced by a CN-induced rise in cytoplasmic [Ca] (Yu et al.,1994).

There is increasing interest in the effects of CN on CNS (Way, 1984; Jones et al., 1987; Baud et al., 1991; Dubinsky and Rothman,1991; Krieglstein and Rischke, 1991; Brismar and Collins, 1993;Miller et al., 1993; Sturm et al., 1993). CN is a component ofcigarette smoke, and it has been identified as a major cause ofdeath from accidental smoke inhalation (Way, 1984; Jones et al.,1987; Baud et al., 1991). Adenosine attenuates neuronal damageinduced by ischemia or CN (Krieglstein and Rischke, 1991; Sturmet al., 1993), presumably by reducing glutamate release (Patelet al., 1991, 1992; Cai and McCaslin, 1992). Therefore, adenosinerelease caused by CN has a neuroprotective effect in slices invitro. However, CN-induced adenosine release also suppresses CNSfunction, which in turn leads to loss of consciousness and thento loss of respiratory function. The present results point toadenosine as a crucial element in the intrinsic mechanism thatlinks acute CN poisoning with almost immediate depression of CNSfunction.

FOOTNOTES

Received Nov. 16, 1996; revised Dec. 23, 1996; accepted Jan. 22, 1997.

This research was supported financially by the Medical Research Council of Canada and partly by the Fonds pour la Formationde Chercheurs et l'Aide à la Recherche (Québec). We thank MurraySweet for his photographic work.

Correspondence should be addressed to Dr. Kresimir Krnjevi $c'$ , McGill University, McIntyre Medical Sciences Building, Room1208, 3655 Drummond Street, Montréal, Québec, Canada H3G 1Y6.

Dr. Zhu's present address: Departments of Pharmacological and Physiological Sciences, University of St. Louis School of Medicine,1402 South Grand Boulevard, St. Louis, MO 63104.

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