Strychnine: A Potent Competitive Antagonist of alpha -Bungarotoxin-Sensitive Nicotinic Acetylcholine Receptors In Rat Hippocampal Neurons

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Vol. 284, Issue 3, 904-913, March 1998

Strychnine: A Potent Competitive Antagonist of $alpha$ -Bungarotoxin-Sensitive Nicotinic Acetylcholine Receptors In Rat Hippocampal Neurons¹

Hiroaki Matsubayashi, Manickavasagom Alkondon, Edna F. R. Pereira, Karen L. Swanson and Edson X. Albuquerque

Department of Pharmacology and Experimental Therapeutics, University of Maryland School of Medicine, Baltimore, Maryland (H.M., M.A., E.F.R.P., K.L.S., E.X.A.) and Department of Clinical and Basic Pharmacology, Institute of Biomedical Sciences, Federal University of Rio de Janeiro, Rio de Janeiro, RJ 21944, Brazil (E.X.A.)

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

In our study, evidence is provided that strychnine, a competitive antagonist at glycine-gated Cl channels, is also a potent competitive antagonist at native $alpha$ -7-containing, $alpha$ -bungarotoxin-sensitive nicotinic acetylcholine receptor (nAChRs).To address the effects of strychnine on two types of nicotinicresponses, the whole-cell mode of the patch-clamp technique wasapplied to rat hippocampal neurons in culture. Type IA and typeII nicotinic currents evoked by acetylcholine (ACh) were inhibitedby strychnine in a concentration-dependent manner with IC₅₀s of1.2 and 38 µM, respectively. Strychnine (2 µM) decreased the peakamplitude of the $alpha$ -bungarotoxin-sensitive type IA current in avoltage-independent manner and prolonged the decay phase of thiscurrent. The concentration-response curve for ACh in evoking typeIA current showed a parallel shift to the right in the presenceof strychnine (2 µM); the EC₅₀ for ACh was increased from 0.4to 0.8 mM. These findings suggest that strychnine acts as a competitiveantagonist of ACh at the $alpha$ 7 nAChRs that subserve type IA current.In contrast, the inhibition by strychnine of type II current wasstrongly voltage dependent, and the decay phase of this currentwas markedly accelerated by the toxin, suggesting an open-channelblockade by strychnine of the $alpha$ 4 $beta$ 2 nAChRs subserving type II currents.Preexposure of the neurons to strychnine enhanced its abilityto decrease the peak amplitude of type II currents, indicatingthat the toxin may also act on $alpha$ 4 $beta$ 2 nAChR channels that are notopen. It is concluded that strychnine is a potent competitiveantagonist of ACh at neuronal $alpha$ 7 nAChRs and a noncompetitive antagonistat the $alpha$ 4 $beta$ 2 nAChR.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

Although strychnine (fig. 1) is a well-known competitive antagonist of glycine at glycine-gated Cl channels (Saitoh et al., 1994), its binding to glycine-resistantsites has been recognized for many years. For instance, numerousreports have provided evidence that strychnine can inhibit cholinergictransmission at the neuromuscular junction and in sympatheticganglia (Lanari and Luco, 1939; Alving, 1961). A presynaptic nicotinicmechanism appears to account for the ability of the toxin (1-100µM; Koelle and McKinstry, 1976) to block the release of ACh fromsympathetic ganglia (Collier and Katz, 1970) and to block therelease of catecholamines from adrenal medullary chromafin cells(10-30 µM; Kuijpers et al., 1994). However, it is unlikely thatstrychnine poisoning could be accounted for by these effects,because they are observed at concentrations that are considerablygreater than those at which the alkaloid exerts its excitatoryand depressant effects in the CNS (Franz, 1975). Nevertheless,findings that strychnine produces spiking in the cortex (Amatoet al., 1969; García Ramos et al., 1977), where glycine receptorsare rare (Frostholm and Rotter, 1985), strongly support the notionthat some of the toxic effects of this alkaloid can be accountedfor by its action on receptors other than the glycine receptorsin the CNS.

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Fig. 1. Structure of strychnine.

In contrast to the previously noted low potency of strychnine at nonneuronal nAChRs, the toxin has been shown to have potentactions on certain subtypes of neuronal nAChRs. On the outer haircells of the vestibular system, strychnine is even more potentthan curare or $alpha$ -BGT in antagonizing the nicotinic actions ofACh (Bartolami et al., 1993; Erostegui et al., 1994; Guth et al.,1994). The anticholinergic effects of strychnine in the auditorysystem (Guth et al., 1994) have been observed at concentrationsas low as 0.01 µM (Doi and Ohmori, 1993), and strychnine bindsto the neuronal nAChRs of the outer hair cells with a K_d of approximately35 nM (Lawoko et al., 1995). Of interest, in addition to the outerhair cell nAChRs, which are likely to be made up of the $alpha$ 9 subunit(Elgoyhen et al., 1994), homomeric $alpha$ 7 nAChRs, homomeric $alpha$ 8 nAChRsand homomeric $alpha$ 9 nAChRs ectopically expressed in Xenopus oocytesare highly sensitive to inhibition by toxicologically relevantconcentrations of strychnine (Anand et al., 1993; Elgoyhen etal., 1994; Gerzanich et al., 1994; Peng et al., 1994).

Studies directed at determining the ability of centrally acting compounds to interact with native neuronal nAChRs have beenhelpful in improving the understanding of the functions of thesereceptors in the CNS. For instance, studies of the interactionsof epibatidine, $alpha$ -conotoxin-ImI and amantadine with neuronal nAChRshave suggested that different subtypes of these receptors arelikely to be involved in analgesia, convulsions and Parkinson'sdisease. In fact, 1) epibatidine, a toxin isolated from the skinof the frog Epipedobates tricolor and known to cause analgesiawhen injected i.p. in mice (Badio and Daly, 1994), is a potentagonist at $alpha$ 4 $beta$ 2-containing nAChRs in hippocampal neurons (Alkondonand Albuquerque, 1995); 2) $alpha$ -conotoxin-ImI, a toxin isolated fromthe venom of Conus imperialis and shown to cause convulsions wheninjected intracerebroventricularly in mice and rats (Johnson etal., 1995), is a competitive antagonist selective for native $alpha$ 7-bearingnAChRs (Pereira et al., 1996) and 3) at therapeutically relevantconcentrations, amantadine, a drug used to treat Parkinson's disease,acts as a noncompetitive antagonist of ACh at $alpha$ 7-containing nAChRsin hippocampal neurons (Matsubayashi et al., 1997).

Considering that, 1) homomeric $alpha$ 7 nAChRs heterologously expressed in Xenopus oocytes are sensitive to blockade by strychnine(Peng et al., 1994), 2) convulsions are among the well-documentedtoxic effects of strychnine, 3) hippocampal foci can be developedas a consequence of exposure to strychnine (Baker, 1965), and4) $alpha$ 7-bearing nAChRs, which are expressed in the majority of thehippocampal neurons (Alkondon and Albuquerque, 1993), appear tobe involved in convulsions, we decided to investigate the interactionsof the toxin with the different subtypes of nAChRs (includingthe $alpha$ 7-bearing receptors) present on hippocampal neurons. As reportedpreviously, hippocampal neurons can respond to nicotinic agonistswith at least one of three pharmacologically and kinetically distincttypes of nicotinic currents, namely types IA, II and III thatarise from the activation of nAChRs composed of $alpha$ 7, $alpha$ 4 $beta$ 2, and $alpha$ 3 $beta$ 4 subunits, respectively (Alkondon and Albuquerque, 1993; Alkondonet al., 1994; Ishihara et al., 1995; Barbosa et al., 1996).

Our study demonstrates that strychnine inhibits both $alpha$ 7 nAChR-mediated type IA currents and $alpha$ 4 $beta$ 2 nAChR-mediated type II currentsrecorded from rat hippocampal neurons. It is likely that someof the symptoms of strychnine-induced intoxication are associatedwith its ability to block $alpha$ 7 nAChRs in the CNS, because we provideevidence that the concentrations at which strychnine inhibitsthe activation of native $alpha$ 7 nAChRs present on hippocampal neuronsare similar to those at which it interacts with glycine receptorsin the CNS.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Tissue culture. Cultured hippocampal neurons were prepared by a procedure similar to that described previously (Alkondon and Albuquerque,1993). The hippocampi of 17- to 18-day-old rat fetuses (Sprague-Dawleystrain) were dissected out, minced and incubated with 0.25% trypsin(Gibco BRL, Grand Island, NY) for 30 min at 36°C. Using a sterilePasteur pipette, hippocampal neurons were dissociated and platedat a density of approximately 700,000 cells per 35-mm culturedish precoated with collagen (Vitrogen 100, Celtrix Laboratories,Palo Alto, CA). The cells were cultured in an incubator at 36°Cin a water-saturated, 10%-CO₂/90%-air atmosphere. The medium surroundingthe cells, which consisted of MEM (Gibco BRL) enriched with fetalbovine serum (10%; Gibco BRL), horse serum (10%, Gibco BRL), glutamine(2 mM, Sigma Chemical Co., St. Louis, MO) and DNase (40 µg/ml,Sigma), was replaced twice a week with fresh medium consistingof MEM supplemented with horse serum (10%) and glutamine (2 mM).On the 7th day after plating the cells, uridine (final concentration= 6.7 µg/ml) and 5-fluoro-2 $'$ -deoxyuridine (final concentration= 13.3 µg/ml) were added for 24 hr to the culture medium to inhibitthe proliferation of nonneuronal cells. Neurons cultured for 14to 30 days were used throughout this study.

Whole-cell current recording. Nicotinic currents were recorded from hippocampal neurons according to the standard whole-cell patch-clamp technique usingan LM-EPC-7 patch-clamp system (List Electronic, Darmstadt, FRG)(Hamill et al., 1981). Patch pipettes were pulled from borosilicatecapillary glass and had resistances between 2 and 5 M $Omega$ when filledwith internal solution. The series resistance of the patches was10 to 25 M $Omega$ and was not compensated. Currents were filtered at3 kHz and either sampled directly by a microcomputer using theprogram pCLAMP (Axon Instruments, Foster City, CA) or stored foroff-line analysis on videocassette tapes after passage througha pulse code modulation device (Neuro-Corder DR-384; Neuro-DataInstruments Corp., New York, NY). All experiments were performedat room temperature (20-22°C).

The external bath solution (340 mOsm) consisted of (in mM): NaCl, 165; KCl, 5; CaCl₂, 2; glucose, 10 and HEPES, 5; the pHof the solution was adjusted to 7.3 with NaOH. The neurons wereperfused continuously at a rate of 1.5 to 2.0 ml/min with externalsolution containing atropine (1 µM) and tetrodotoxin (200 nM).In some experiments, specified in "Results," DH $beta$ E (0.1 µM) wasadded to the standard external solution described above. The patchpipettes were filled with ATP-RS, which has been shown to reducethe extent of the rundown of type IA current (Alkondon et al.,1994

). The ATP-RS consisted of (in mM): CsCl, 60; CsF, 60; Cs-EGTA,10; HEPES, 10; MgCl₂, 2; Tris adenosine 5 $'$ -triphosphate, 5 andTris phosphocreatine, 20. After adding creatine phosphokinase(50 U/ml) to this solution, a small amount of CsOH (8 mM) wasadded to adjust the pH of the solution to 7.3. The final osmolarityof the solution was 340 mOsm.

Drug applications. The drugs were delivered to the neurons according to the method described previously (Albuquerque et al., 1991). A U-shapedtube ("U-tube") with a pore of 250 to 400 µm in diameter at theapex was positioned about 50 µm directly above the neuronal soma.The input to the U-tube was connected to a manual switch valve,which was used to select the desired drug solution. The outletof the U-tube was connected via an electric valve to a polyethylenetube for removal of drug solution from the neuronal surroundings.To prevent any leakage of the drug solution through the pore ofthe U-tube, the outlet was under continuous vacuum so that thedrug solution and a small amount of the bath solution from thedish were removed when the valve was not activated. Upon activationof the valve by a 0.5 to 2-sec electric pulse, the drug solutionflowed rapidly out of the apical pore and displaced completelythe solution surrounding the neuronal soma and dendrites. Usingthis U-tube system, pulses of ACh alone or in an admixture withstrychnine (0.1-300 µM) were applied to the neurons. Alternatively,in some experiments, strychnine was applied through the externalbath perfusion system, in which case the same concentration ofstrychnine was added to the agonist-containing solution in theU-tube.

Data analysis. The peak amplitude, the rise time (10-90%) and the exponential decay-time constant ( $tau$ ) of the whole-cell currents were determinedusing the pCLAMP program. EC₅₀, IC₅₀ and the n_H values were determinedwith the SigmaPlot program according to the following equationfor activation:

I=I<UP>max</UP>×<FR><NU>[ACh]nH</NU><DE>[ACh]nH+ECnH50</DE></FR>

and for inhibition:

I=I<UP>max</UP>−<FR><NU>I<UP>max</UP>×[strychnine]nH</NU><DE>[strychnine]nH+ICnH50</DE></FR>

where I, I_max, [ACh] and [strychnine] were the peak whole-cell current, the maximum obtainable peak current, the concentrationof ACh, and the concentration of strychnine, respectively. Valueswere expressed as the mean ± S.E.M.

Drugs used. Acetylcholine chloride, tetrodotoxin, atropine sulfate and strychnine hydrochloride were obtained from Sigma. Dihydro- $beta$ -erythroidinehydrobromide was a gift from Merck, Sharp & Dohme Research Laboratories(Rahway, NJ). ATP (Tris salt), phosphocreatine (di-Tris salt)and creatine phosphokinase (type I) were obtained from Sigma ChemicalCo.

Statistical analysis. Two-way ANOVA was used to determine the significance of the results.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Nicotinic whole-cell currents were elicited by pulse application (0.5-2 sec) of ACh via the U-tube to hippocampal neuronsin culture. In this study, 80 of the 121 neurons tested respondedto ACh with type IA current, characterized by rapid onset afterthe start of the ACh pulse and rapid decay in the continued presenceof ACh (fig. 2, top row; Alkondon and Albuquerque, 1993). TypeII current, characterized by its slow decay phase (fig. 2, bottomrow; Alkondon and Albuquerque, 1993), was recorded from 40 neurons.Type IB current, which is comprised of the rapidly decaying typeIA current and the slowly decaying type II current (Alkondon andAlbuquerque, 1993; Alkondon et al., 1994), was recorded from onlyone neuron. In our study, the percent probability of finding hippocampalneurons that responded to ACh with type II currents was somewhathigher than that reported previously (Alkondon and Albuquerque,1993, 1995; Alkondon et al., 1994).

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Fig. 2. Inhibitory effects of strychnine (10 µM) on the two major types of ACh (1 mM)-induced nicotinic currents in hippocampal neurons.Each row shows recording samples of one type of nicotinic current,each of which was recorded from a single neuron. ACh was appliedto the neurons via the U-tube 1 min before (left column) and after(right column) the application of the admixture of ACh plus strychnine(10 µM) (middle column). ACh-evoked currents that decayed rapidlywere characterized as type IA currents (top row) and were sensitiveto reversible inhibition by strychnine. ACh-evoked currents thatdecayed slowly were characterized as type II currents (bottomrow) and were insensitive to blockade by strychnine at the concentrationshown. Holding potential, $-$ 60 mV.

Effects of strychnine on ACh-induced currents recorded from hippocampal neurons in culture. Application of an admixture of ACh (1 mM) plus strychnine (10 µM) to neurons that responded to ACh (1 mM) with type IA currentsresulted in activation of currents whose amplitudes were approximately60% smaller than those of currents evoked by ACh alone (fig. 2).The effect of strychnine on type IA currents was completely reversiblewithin 1 min after washing of the neurons with external solution.In contrast, the peak amplitude and the kinetics of ACh (1 mM)-evokedtype II currents were not affected when strychnine (10 µM) wasapplied to the neurons exclusively in admixture with ACh (1 mM)(fig. 2). Thus, strychnine was apparently more selective in inhibitingthe $alpha$ 7 nAChR activity subserving type IA currents than in inhibitingthe $alpha$ 4 $beta$ 2 nAChR activity subserving type II currents.

The potency and the mechanism of action of strychnine on type IA nicotinic currents recorded from hippocampal neurons. Because a single hippocampal neuron can express both $alpha$ 7 and $alpha$ 4 $beta$ 2 nAChRs (Alkondon and Albuquerque, 1993), contamination oftype IA currents by slowly decaying currents corresponding tothe activation of $alpha$ 4 $beta$ 2 nAChRs was avoided by the continuous perfusionof the neurons with DH $beta$ E (0.1 µM)-containing external solution.At 0.1 µM, DH $beta$ E selectively inhibits the activation of whole-cellcurrents subserved by $alpha$ 4 $beta$ 2 nAChRs (Alkondon and Albuquerque, 1993).Except in experiments where the voltage dependence of the effectof strychnine on nicotinic currents was addressed, the neuronswere held at $-$ 60 mV.

To determine the apparent potency of strychnine in inhibiting the nAChR activity subserving type IA currents, neurons thatresponded to 1-sec pulses of ACh (1 mM) with type IA current wereexposed 1 min later to a pulse of an admixture of ACh (1 mM) plusone of various concentrations of strychnine. The reversibilityof the effect of strychnine on type IA currents was tested subsequentlyby the application of ACh (1 mM) to the neurons. These experimentswere performed on neurons exposed to concentrations of strychnineranging from 0.1 to 30 µM. The peak amplitude of type IA currentwas decreased by strychnine in a concentration-dependent manner;the IC₅₀ for the toxin was approximately 1.9 µM (fig. 3A; table1).

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Fig. 3. Concentration-dependent inhibition of type IA current by strychnine and the mechanism underlying the action of the toxin.A, Concentration-response relationship for the inhibitory effectof strychnine on type IA currents. The peak amplitude of ACh (1mM)-evoked currents was taken as 100% and was used to normalizethe peak amplitude of the currents evoked in the presence of strychnine.The curves were fitted to the Hill equation. Symbols and barsrepresent the mean ± S.E.M. of results obtained from four to sevenneurons. Holding potential, $-$ 60 mV. The IC₅₀ and the n_H valuesfor strychnine obtained are shown in table 1. B, Effect of strychnineon the concentration-response relationship for ACh in evokingtype IA currents. In each experiment, the peak amplitude of currentsevoked by ACh (10 mM) was taken as 100% and was used to normalizethe peak amplitude of currents evoked by other concentrationsof ACh in the presence or in the absence of strychnine. Each symboland bar represent the mean ± S.E.M. (n = 5-25). The EC₅₀ and n_Hfor ACh in evoking type IA currents are shown in table 2.

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TABLE 1
Apparent potency of strychnine for inhibition of nicotinic currents

To verify whether the toxin interacts with $alpha$ 7 nAChR channels that are not opened, after the recording of ACh (1 mM)- evokedtype IA current, the neurons were continuously perfused with strychnine(0.1-30 µM)-containing external solution, and 10 min after theperfusion had begun, they were exposed to an admixture of ACh(1 mM) plus the proper concentration of strychnine. Under thisexperimental condition, strychnine decreased the peak amplitudeof type IA currents in a concentration-dependent manner, and theIC₅₀ for the toxin was about 1.2 µM (fig. 3A; table 1). The IC₅₀sfor strychnine were significantly different according to the ANOVA(F_5,74 = 8.4; P < .01). The apparent potency of strychnine ininhibiting the nAChR activity subserving type IA currents increased1.6-fold when the neurons were preexposed to the toxin, a findingthat may indicate an action on the nAChR channels that are notopened.

Based on the IC₅₀s determined above, 2 µM strychnine was selected for studies to probe the mechanism of inhibition of typeIA currents by the toxin. The peak amplitude of type IA currentsevoked by 0.5-sec pulses of ACh increased as the concentrationof ACh was increased from 0.05 to 10 mM (fig. 3B). When each testconcentration of ACh was applied to the neurons as an admixturewith strychnine (2 µM), the peak amplitude of type IA currentswas smaller than the peak amplitude of the currents evoked bythe corresponding concentration of ACh in the absence of the toxin,and the magnitude of the blockade by strychnine of type IA currentsdecreased with increasing concentrations of the agonist. The resultsobtained from experiments in 25 neurons were combined by normalizingthe peak amplitude of type IA currents to the amplitude of thecurrents elicited by 10 mM ACh in the absence of strychnine. TheACh concentration-response relationship in the absence of strychnineyielded an EC₅₀ of 0.4 mM for ACh in evoking type IA current (fig.3B; table 2). In the presence of strychnine (2 µM), the ACh concentration-responsecurve was shifted to the right in a parallel manner (fig. 3B),yielding an EC₅₀ of about 0.8 mM for ACh in eliciting type IAcurrents (table 2). Strychnine did not alter the maximal responseto ACh, but decreased the apparent potency of ACh in evoking typeIA currents.

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TABLE 2
Effect of strychnine on the apparent potency for ACh in eliciting type IA current

In a second set of experiments the neurons were perfused for 10 min with strychnine (2 µM)-containing external solution afterthe control responses were recorded. Under this experimental condition,the peak amplitude of type IA currents evoked by subsequent applicationof an admixture of ACh plus strychnine was smaller than that ofthe currents evoked by the corresponding concentration of AChin the absence of the toxin. Further, the magnitude of the inhibitoryeffect of strychnine decreased with increasing concentrationsof ACh, such that the concentration-response relationship forACh in evoking type IA currents was shifted to the right in thepresence of strychnine. Based on the results obtained from thisset of experiments in which the neurons were allowed to equilibratewith strychnine before their exposure to the admixture of AChplus the toxin, there was no change in the maximal response ofthe receptors to ACh, but the apparent EC₅₀ for ACh in evokingtype IA currents increased from 0.4 to 0.8 mM (see table 1).The findings from this two series of experiments indicated thatACh and strychnine compete for the agonist binding site on the $alpha$ 7 nAChR.

Analysis of the voltage dependence of the effects of strychnine on the peak amplitude of type IA currents and investigationof the effects of the toxin on the kinetics of these currentsprovided further evidence that strychnine acts as a competitiveantagonist at the $alpha$ 7 nAChR on hippocampal neurons. Type IA currentsevoked by 0.5-sec pulses of ACh (0.3 mM) were recorded from sevenneurons as the holding potential was changed from $-$ 120 mV to +60mV in 20 mV steps. Then, 10 min after perfusing the neurons withstrychnine (1 µM)-containing solution, an admixture of ACh plusstrychnine (1 µM) was applied through the U-tube to the same neurons(fig. 4A). The data were combined by normalizing all the responsesrelative to the peak amplitude of the ACh (0.3 mM)-evoked currentsat $-$ 120 mV (fig. 4B). The ratio of the amplitude of type IA currentsevoked by ACh in the presence of strychnine to the amplitude ofthe currents evoked by ACh alone did not change significantlyat any holding potential (fig. 4C). Therefore, the reduction bystrychnine (1 µM) of the peak amplitude of type IA current wasvoltage independent.

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Fig. 4. Inhibitory effect of strychnine (1 µM) on the peak amplitude of ACh (0.3 mM)-evoked type IA current at various holding potentials.A, Sample recordings of type IA currents evoked by applicationof ACh or ACh plus strychnine to a neuron held at various holdingpotentials. The admixture of ACh plus strychnine was applied viathe U-tube to the neuron after its 10-min perfusion with strychnine-containingexternal solution. B, In each experiment, the peak amplitudesof the ACh-elicited currents at $-$ 120 mV were taken as 100% andwere used to normalize the amplitude of the currents evoked byACh in the presence or in the absence of strychnine at all otherholding potentials. C, The relationship between the holding potentialand the ratio of the amplitude of the currents evoked in the presenceof strychnine (1 µM) to the corresponding amplitude of the currentsevoked in the absence of strychnine at all holding potentialsis shown. Symbols and bars represent the mean ± S.E.M. from experimentsusing seven neurons.

The effects of increasing concentrations of strychnine (0.3-3 µM) on the decay and the rising phase of type IA currents werestudied after 10-min perfusion of the neurons with solution containingone of the test concentrations of the toxin. For illustrativepurposes, the nicotinic currents recorded in the presence of strychninewere normalized to the corresponding control currents (fig. 5).The rise time of ACh (0.3 mM)-evoked currents ranged from 15 to27 msec and was prolonged in a concentration-dependent mannerby strychnine (table 3).

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Fig. 5. Concentration-dependent prolongation of decay phase of type IA current by strychnine. Top traces, Sample recordings of typeIA currents evoked by application of ACh (0.3 mM) in the absenceand in the presence of strychnine (0.3-3 µM) to neurons held at $-$ 60 mV. Each pair of traces was obtained from one neuron. To illustratethe effects of strychnine on the kinetics of type IA currents,the peak amplitudes of the currents evoked by ACh in the presenceof strychnine were scaled to match those of the currents evokedby ACh alone. Bottom graph, The relationship between the membranepotentials and the decay-time constants of the currents evokedby ACh (0.3 mM) alone ( $open circle$ ) or in the presence of 1 µM strychnine( $bullet$ ) shows the voltage independence of the strychnine-induced prolongationof the decay phase of type IA currents. Only the values of thefast component of the decay phase of type IA currents are shown.Quantification of the effects of strychnine on the decay phaseand on the rising phase of type IA currents is shown in table3.

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TABLE 3
Strychnine-induced changes in the kinetics of type IA currents

Of 14 neurons tested, 11 neurons responded to ACh with type IA currents that showed single-exponential decays with time constants( $tau$ ) of 15.2 to 52.1 msec under the control condition. Althoughstrychnine prolonged the decay phase of these currents, they stillshowed a single exponential decay in the presence of the toxin.The decay phase of the currents recorded from the other threeneurons were better fitted to double-exponential decay functionsunder the control condition; the fast decay component had $tau$ _b of14.6 to 22.7 msec and the slow decay components had $tau$ _s of 219to 294 msec. These three currents also showed double-exponentialdecays in presence of strychnine (0.3 µM), and the $tau$ values wereincreased by the toxin in a concentration-dependent manner. Theeffect of various concentrations of strychnine on the fast componentof all ACh-evoked type IA currents is shown in table 3.

The effect of membrane potential on the strychnine-induced prolongation of the decay phase of type IA currents was studiedin neurons that were perfused for 10 min with strychnine (1 µM)-containingsolution before their exposure to ACh plus strychnine. The responsesof the neurons were recorded at membrane potentials that rangedfrom $-$ 120 to $-$ 20 mV in steps of 20 mV. Four neurons respondedto ACh with currents that had a single-exponential decay with $tau$ values of 21 to 40 msec. Three other neurons responded to AChwith type IA currents that had a double-exponential decay: thefast decay component had a $tau$ _f of 14 to 31 msec and the slow decaycomponent had a $tau$ _s of 91 to 958 msec. In the analysis, only the $tau$ _f was considered when averaging the results. In the presenceof strychnine (1 µM), the decay phase of the currents recordedfrom these seven neurons was better fitted by a single-exponentialfunction, and was prolonged in a voltage-independent fashion (fig.5).

The potency and the mechanism of action of strychnine as an inhibitor of the $alpha$ 4 $beta$ 2 nAChR activity subserving type II currents in hippocampal neurons. Because type II currents elicited by ACh (1 mM) were insensitive to strychnine (10 µM) (see fig. 2), the effects of the toxinon these currents were investigated at concentrations 10-foldhigher than those used to test the inhibition of the type IA current.

The amplitudes of the currents evoked by the application of an admixture of ACh (0.3 mM) plus increasing concentrations ofstrychnine (1-300 µM) to eight neurons that responded to ACh (0.3mM) with type II currents were smaller than those of the currentsevoked by ACh alone; this effect of strychnine, which was reversiblewithin 1 min after washing of the neurons with external solution,was also concentration dependent (fig. 6). The concentration-responserelationship revealed that the IC₅₀ for strychnine in blockingtype II currents was about 118 µM (fig. 6; table 1). In a secondset of experiments, neurons that responded to ACh with type IIcurrents were continuously perfused with strychnine-containingexternal solution for 10 min before their exposure to an admixtureof ACh plus the corresponding concentration of the toxin. Underthis experimental condition, the apparent potency of strychninein reducing the peak amplitude of type II currents was substantiallyincreased, indicating that the toxin is able to interact with $alpha$ 4 $beta$ 2 nAChR channels that are not open; the IC₅₀ for strychninewas approximately 38 µM (fig. 6; table 1), i.e., 0.3 times theIC₅₀ obtained when strychnine was applied to the neurons exclusivelyvia the U-tube. It is unlikely that strychnine acts as a competitiveantagonist at the $alpha$ 4 $beta$ 2 nAChRs, because its effect on type II currentshad the same magnitude regardless of whether ACh was used at theconcentration of 0.3 or 1 mM.

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Fig. 6. Concentration-dependent inhibition of type II current by strychnine. Traces, top row, Sample recordings of type II currentsrecorded from a hippocampal neuron exposed at 1-min intervalsto ACh (0.3 mM) (left trace) and ACh (0.3 mM)-plus strychnine(100 µM) (right trace). Traces, bottom row, Sample recordingsof ACh-evoked type II current recorded from a neuron before (lefttrace) and after (right trace) its 10-min perfusion with strychnine(100 µM)-containing external solution. Right graph, Concentration-responserelationship for the inhibitory effect of strychnine on type IIcurrents. In each experiment, the peak amplitude of ACh (0.3 mM)-evokedcurrents was taken as 100% and was used to normalize the peakamplitude of the currents evoked in the presence of strychnine.The curves were fitted to the Hill equation; the EC₅₀ and then_H for strychnine in blocking type II currents under the two experimentalconditions are shown in table 1. Symbols and bars represent themean ± S.E.M. of results obtained from six to nine neurons. Holdingpotential, $-$ 60 mV.

The mechanisms by which strychnine inhibited the activation of type II currents were further investigated by examining thekinetics of the currents in the presence and in the absence ofthe toxin and by investigating the voltage dependence of the effectof the toxin on the peak amplitude of these currents.

In agreement with earlier studies (Alkondon and Albuquerque, 1993

, 1995

; Alkondon et al., 1994

), ACh (0.3 mM)- evoked typeII currents displayed a very strong inward rectification (fig.7). Four neurons that responded to ACh with type II currents werecontinuously perfused for 10 min with strychnine (30 µM)-containingexternal solution, and then exposed to the admixture of ACh plusstrychnine (fig. 7A). The peak amplitude of all currents was normalizedto the peak amplitude of the ACh-evoked current at $-$ 120 mV andused to plot the current-voltage relationship. The reduction bystrychnine of the peak amplitude of type II currents became moreintense as the membrane potential was made more negative (fig.7B). The ratio of the peak current amplitude in the presence ofstrychnine to the corresponding amplitude in the absence of thetoxin also showed the toxin's voltage-dependent effect on thepeak amplitude of type II currents (fig. 7C).

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Fig. 7. Voltage-dependent inhibition by strychnine of type II currents evoked by ACh (0.3 mM). A, Sample recordings of type II currentsevoked by application of ACh or ACh plus strychnine to a neuronheld at various membrane potentials. The admixture of ACh plusstrychnine was applied to the neuron after its 10-min perfusionwith strychnine-containing external solution. B, In each experimentthe peak amplitude of the ACh-elicited currents at $-$ 120 mV wastaken as 100% and was used to normalize the amplitude of the currentsevoked at all other holding potentials by ACh in the presenceor in the absence of strychnine. C, The relationship between theholding potentials and the ratio of the amplitude of the currentsevoked in the presence of strychnine (30 µM) to the correspondingamplitude of the currents evoked by ACh alone at all holding potentialsis illustrated. Symbols and bars represent the mean ± S.E.M. fromexperiments using three neurons.

When strychnine (10, 30 or 100 µM) was applied to the neurons exclusively as an admixture with ACh (0.3 mM), in addition tothe reduction of the peak current amplitude, there was an accelerationof the decay phase of the ACh-evoked type II currents (fig. 8A).The decay phases of the currents recorded from 3 of 10 neuronssampled were better fitted to a single-exponential function eitherin the absence or in the presence of strychnine, and the decayphase of the currents recorded from the remaining seven neuronswas fitted by a double exponential function either in the presenceor in the absence of the toxin. The decay-time constant of typeII currents evoked by ACh was shortened by strychnine in a concentration-dependentmanner (table 4; fig. 8A). In addition, perfusion of the neuronswith strychnine does not appear to affect the interaction of thetoxin with the open state of the $alpha$ 4 $beta$ 2 nAChR channel, given thatthe magnitude of the effect of strychnine on the decay phase oftype II currents was not altered by allowing the neurons to equilibratewith strychnine before their exposure to the admixture of AChplus toxin (fig. 8B). These findings suggest that strychnine caninteract with the open state of the nAChR channel subserving typeII currents. Also, as illustrated on table 4, in the presenceof the highest tested concentration of strychnine (i.e., 100 µM),the rise time of type II currents was accelerated, a finding thatcould be accounted for by the substantial acceleration of thedecay phase of the currents.

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Fig. 8. Concentration-dependent effect of strychnine on the decay phase of type II currents. The peak amplitudes of type II currentsevoked by ACh (0.3 mM) in the presence of increasing concentrationsof strychnine were scaled to match the peak amplitudes of thecurrents evoked by ACh alone. Each pair of traces was obtainedfrom one neuron. A, Strychnine was applied to the neurons exclusivelyas an admixture with ACh. B, The admixture of strychnine plusACh was applied to the neurons after their 10-min perfusion withstrychnine-containing external solution. Holding potential, $-$ 60mV. The quantification of the effect of strychnine applied tothe neurons via the bath and the U-tube on the decay phase oftype II currents is shown in table 4.

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TABLE 4
Strychnine-induced changes in the kinetics of type II currents

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

Our study revealed that strychnine, a toxin well known for its convulsant effects and for its ability to block glycine-activatedCl channels, acts as a competitive nicotinic antagonist at the $alpha$ 7nAChRs, which give rise to type IA currents in hippocampal neurons,and inhibits via noncompetitive mechanisms the $alpha$ 4 $beta$ 2 nAChR activity.On the basis of the IC₅₀ values obtained in our study, strychnineappears to be 30 times more potent in blocking type IA currents(IC₅₀ = 1.2 µM) than in blocking type II currents (IC₅₀ = 38 µM).

Mechanism of action of strychnine on the $alpha$ 7 nAChRs subserving type IA currents. Studies of the concentration-response relationship for ACh in evoking type IA currents in the absence and in the presenceof 2 µM strychnine (a concentration of strychnine that is closeto its IC₅₀ in blocking type IA current) demonstrated that thetoxin decreases the apparent potency of ACh; strychnine increasedthe EC₅₀ for ACh from 0.4 to 0.8 mM. In addition, neither themaximal responsiveness of the $alpha$ 7 nAChRs subserving type IA currentsnor the Hill coefficient for ACh was affected by the toxin. Theseresults suggested that strychnine competes with ACh for the agonistbinding site(s) on the $alpha$ 7 nAChRs. The findings that 1) the reductionof the peak amplitude of type IA currents by strychnine was voltageindependent and 2) the decay phase and the rise time of type IAcurrents were prolonged by the toxin favor the notion that thetoxin is a competitive antagonist of ACh at the $alpha$ 7 nAChRs.

Some insights regarding the kinetics of interaction of strychnine with the $alpha$ 7-containing nAChRs that give rise to type IAcurrents are suggested from the present results. An increase inthe apparent potency of strychnine (change in IC₅₀ from 1.9 to1.2 µM) to inhibit ACh-evoked type IA currents was observed whenthe method of application of strychnine was changed to includea period of preincubation of the neurons with the toxin (see fig.3A). Considering that the activation and inactivation rates ofthe $alpha$ 7 nAChRs subserving type IA currents are very rapid, at thesaturating concentration of the agonist used in our experimentsit is likely that the equilibrium of the receptors with strychnineis not fully achieved when the toxin is applied to the neuronsexclusively during the agonist pulse, and that would account forthe increase in the apparent potency of strychnine when the receptorsare allowed to preequilibrate with the toxin before their exposureto the admixture of strychnine plus ACh. In fact, it has beenshown that at a given agonist concentration, the potency of acompetitive antagonist depends on the rates of antagonist-receptorassociation and dissociation and the rates of receptor activationand inactivation (Benveniste et al., 1990

; 1991

). That strychnineprolongs the rising and decay phases of type IA currents suggestsa rapid dissociation of the antagonist from the receptor and aresistance of the receptor-antagonist bound complex to desensitization.Thus, when ACh displaces strychnine from the agonist-binding site(s)on the $alpha$ 7 nAChR, the receptor can be activated by the agonist.In contrast to strychnine, methyllycaconitine has slower kineticsof dissociation as evidenced by the lack of effect on the risingor the decay phase of the $alpha$ 7-nAChRs-mediated type IA currents(Alkondon et al., 1992

To compare the apparent potency of strychnine as a competitive nicotinic antagonist at the $alpha$ 7 nAChRs in hippocampal neuronsto the reported apparent potency of the toxin as a competitiveantagonist at other receptors, the K_i of the toxin for the $alpha$ 7nAChRs of hippocampal neurons was determined according to theequation of Cheng and Prusoff (1973)

K<SUB>i</SUB>=<FR><NU>IC<SUB>50</SUB></NU><DE>1+[L]/K<SUB>d</SUB></DE></FR>

Using this equation, where [L] and K_d are the concentration of the agonist and its affinity for the selected receptor, IC₅₀and K_i are the concentration of strychnine producing 50% inhibitionof response and its apparent affinity, respectively, we estimatedthat the K_i for strychnine as a competitive antagonist of AChat the $alpha$ 7 nAChRs was 0.68 µM (table 1). This K_i value for strychninein blocking type IA currents is close to the K_is for the toxin-inducedinhibition of rat $alpha$ 7 nAChR homomers ectopically expressed in oocytes(0.14 µM, calculated from data in Séguéla et al., 1993

), aswell as human $alpha$ 7 and $alpha$ 8 homomers ectopically expressed in oocytes(0.46 and 0.72 µM, calculated from data in Gerzanich et al., 1994

Mechanism of action of strychnine on the $alpha$ 4 $beta$ 2 nAChRs subserving type II currents. The acceleration of the decay phase of type II currents and the voltage-dependent reduction of the peak amplitude of thesecurrents by strychnine strongly suggest that the toxin acts asan open-channel blocker of the $alpha$ 4 $beta$ 2 nAChR. This change in thedecay phase of type II currents had the same magnitude regardlessof whether the neurons were allowed to equilibrate with strychnineor were rapidly exposed to the admixture of this toxin with ACh.However, the apparent potency of strychnine in reducing the peakamplitude of type II currents was 3-fold higher when the neuronswere perfused with strychnine-containing external solution beforetheir exposure to the admixture of ACh plus strychnine, thus indicatingthat, in addition to blocking the $alpha$ 4 $beta$ 2 nAChR in its open state,strychnine can also interact with $alpha$ 4 $beta$ 2 nAChRs that are not open.

Structure-activity relationships of strychnine. The pharmacophore for molecules that interact with the glycine receptor appears to bear two negative regions contributed bya coplanar amide nitrogen and phenyl group and by a positive regionat the opposite end of the molecule borne by a nitrogen with itsadjacent carbon. The antagonist property of strychnine is carriedin the carbonyl oxygen of the molecule (Aprison et al., 1995;Galvez-Ruano et al., 1995). In contrast, it has been proposedthat strychnine's role as a nicotinic antagonist is met by thecationic nitrogen and the ether oxygen (fig. 1), both of whichform a hydrogen bond with the nicotinic receptor (Beers and Reich,1970; Sheridan et al., 1986). It is unclear whether the same pharmacophorewould operate for the rat $alpha$ 7-containing nAChR. Nevertheless, thisclass of semi-rigid compounds may provide further insight to thestructure of the neuronal nAChRs bearing the $alpha$ 7 subunit.

Regarding receptor specificity of strychnine, the glycine, GABA and nicotinic receptors are homologous members of a receptorsuperfamily (Betz, 1990

). Strychnine binds to the glycine receptor $alpha$ subunit at two domains that are homologous to the agonist bindingregions of the nAChR (Vandenberg et al., 1992

). In the first domain,Y161 is invariant in the receptor superfamily. The ligand-bindingdomain just external to the M1 transmembrane segment is suggestedto have amino acids in the antiparallel $beta$ -pleated sheet arrangement(^K_H^Y_N^T) with K200 and Y202 being important for strychnine binding, andY202 and T204 important for glycine binding (Rajendra et al.,1995

). Adjacent to the ACh-binding domain of rat and chick nAChR $alpha$ subunits, the rat nAChR $alpha$ 2, $alpha$ 4 and $alpha$ 7 subunits have the sequences^K_K^Y_D^CC, ^K_K^Y_E^CC or ^R_K^Y_E^CC (Wada et al., 1989

; Séguéla et al., 1993

), respectively. OthernAChR $alpha$ subunits have different, but possibly related nearby sequences:mouse, chick and Torpedo $alpha$ 1 have ^K_H^W_V^Y (Schoepfer et al., 1990

), chick $alpha$ 7 has ^K_R^T_E^S_F^Y and chick $alpha$ 8 has ^K_R^N_E^L_Y^Y (Schoepfer et al., 1990

). Based on these sequences, one wouldexpect that rat brain nAChRs would all be sensitive to strychnine,and that muscle-type receptors and chick brain $alpha$ 7 and $alpha$ 8 nAChRswould be less sensitive to strychnine. Indeed, according to ourresults, the K_i for strychnine as an inhibitor of the $alpha$ 7 nAChRsin rat hippocampal neurons was found to be approximately 0.68µM, whereas according to previous studies the K_i for strychnineas an inhibitor of the activation of the chick $alpha$ 7 nAChRs has beenreported to be approximately 10-fold higher, i.e., about 6 µM(Anand et al., 1993

The relevance of the neuronal nAChR sensitivity to inhibition by strychnine. The toxic effects of strychnine have been associated with its ability to block glycine receptors. However, based on our study,the K_i for strychnine as a competitive antagonist of ACh at the $alpha$ 7 nAChRs is in the submicromolar range, as is the affinity ofthe toxin for the glycine receptors. Direct radioligand analysishas shown that strychnine binds to the glycine receptor with K_iof 32 nM (Saitoh et al., 1994), and according to a pA₂ analysis,strychnine interacts with glycine receptors with a K_d of 270 nM(Ito and Cherubini, 1991). In many studies, strychnine concentrationsof 1 to 10 µM (Mercuri et al., 1990; Ito and Cherubini, 1991)or 10 to 50 µM (Wu et al., 1992) have been used to inhibit glycine-receptor-mediatedresponses. Thus, at the concentrations generally used, the toxinmay block not only the function of the glycine receptors but alsothat of neuronal nAChRs in the CNS. Considering that the degreeof inhibition of receptors in vivo will be determined by the levelof each endogenous agonist versus its affinity for its receptor,a challenge is raised to the common belief that the toxic effectsof strychnine are mediated by its inhibitory action on glycinereceptors. The finding that the activity of the $alpha$ 7-bearing nAChRsin the rat hippocampus was particularly sensitive to inhibitionby strychnine supports the concept that these receptors are likelyto be involved in controlling the overall neuronal excitability(Sargent, 1993; Lindstrom, 1995; Role and Berg, 1996; Albuquerqueet al., 1997).

	Acknowledgments

The authors thank Mr. Ben Cummings, Mrs. Barbara Marrow and Ms. Mabel Zelle for excellent technical assistance.

	Footnotes

Accepted for publication November 17, 1997.

Received for publication August 14, 1997.

¹ This study was supported by United States Public Health Service Grants NS25296 and ES05730 and by PRONEX (Brazil). Some ofthe data have appeared previously in abstract form (Matsubayashiet al., 1996).

Send reprint requests to: Dr. Edson X. Albuquerque, Department of Pharmacology and Experimental Therapeutics, University of Maryland School of Medicine, 655 West Baltimore Street, Baltimore, MD 21201.

	Abbreviations

ACh, acetylcholine; nAChR, nicotinic acetylcholine receptor; $alpha$ -BGT, $alpha$ -bungarotoxin; CNS, central nervous system; GABA, $gamma$ -amino butyric acid; MEM, minimum essential medium; HEPES, (N-[2-hydroxyethyl]piperazine-N $'$ -[2-ethane sulfonic acid]); DH $beta$ E, dihydro- $beta$ -erythroidine; ATP-RS, adenosine 5 $'$ -trisphosphate-regenerating solution; EGTA, ethyleneglycol-bis-( $beta$ -aminoethyl ether)-N,N,N $'$ ,N $'$ -tetraacetic acid; $tau$ , decay-time constant; EC₅₀, agonist concentration that evokes 50% of the maximal response; IC₅₀, antagonist concentration that reduces by 50% the maximal response; n_H, Hill coefficient; ANOVA, analysis of variance; K_i, apparent affinity of an antagonist for the receptor; K_d, apparent affinity of an agonist for the receptor.

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Strychnine: A Potent Competitive Antagonist of -Bungarotoxin-Sensitive Nicotinic Acetylcholine Receptors In Rat Hippocampal Neurons1

Strychnine: A Potent Competitive Antagonist of $alpha$ -Bungarotoxin-Sensitive Nicotinic Acetylcholine Receptors In Rat Hippocampal Neurons¹