Differential Effects of omega -Conotoxin GVIA, Nimodipine, Calmidazolium and KN-62 Injected Intrathecally on the Antinociception Induced by beta -Endorphin, Morphine and [D-Ala2,N-MePhe4,Gly-ol5]-enkephalin Administered Intracerebroventricularly in the Mouse

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Vol. 282, Issue 2, 961-966, 1997

Differential Effects of $omega$ -Conotoxin GVIA, Nimodipine, Calmidazolium and KN-62 Injected Intrathecally on the Antinociception Induced by $beta$ -Endorphin, Morphine and [D-Ala²,N-MePhe⁴,Gly-ol⁵]-enkephalin Administered Intracerebroventricularly in the Mouse¹

Hong W. Suh, Dong K. Song, Sung R. Choi, Sung O. Huh and Yung H. Kim

Department of Pharmacology, Institute of Natural Medicine, College of Medicine, Hallym University, Chunchon, Kangwon-Do, 200-702, South Korea

	Abstract

Top Abstract Introduction Methods Results Discussion References

We previously reported that $beta$ -endorphin and morphine administered supraspinally produce antinociception by activating differentdescending pain-inhibitory systems. To determine the role of spinalcalcium channels, calmodulin and calcium/calmodulin-dependentprotein kinase II in the production of antinociception inducedby morphine, [D-Ala²,N-MePhe⁴,Gly-ol⁵]-enkephalin (DAMGO) or $beta$ -endorphin administered supraspinally,the effects of nimodipine (an L-type calcium channel blocker), $omega$ -conotoxin GVIA (an N-type voltage-dependent calcium channelblocker), calmidazolium (a calmodulin antagonist) or KN-62 (acalcium/calmodulin-dependent protein kinase II inhibitor) injectedintrathecally (i.t.) on the antinociception induced by morphine,DAMGO or $beta$ -endorphin administered intracerebroventricularly (i.c.v.)were examined in the present study. Antinociception was assessedby the mouse tail-flick test. The i.t. injection of nimodipine(from 0.024 to 2.4 pmol), $omega$ -conotoxin GVIA (from 0.0033 to 0.33pmol), calmidazolium (from 0.0015 to 0.15 pmol) or KN-62 (from0.0014 to 0.14 pmol) alone did not affect the basal tail-flicklatencies. The i.t. pretreatment of mice with nimodipine, $omega$ -conotoxinGVIA, calmidazolium or KN-62 dose dependently attenuated the inhibitionof the tail-flick response induced by $beta$ -endorphin administeredi.c.v. However, the inhibition of the tail-flick response inducedby morphine or DAMGO administered i.c.v. was not changed by i.t.pretreatment with nimodipine, $omega$ -conotoxin GVIA, calmidazoliumor KN-62. The results suggest that spinally located L- and N-typecalcium channels, calmodulin and calcium/calmodulin-dependentprotein kinase II may be involved in the modulation of antinociceptioninduced by $beta$ -endorphin, but not morphine and DAMGO, administeredsupraspinally.

	Introduction

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Antinociception can be produced by injection of opioid agonists, such as morphine and $beta$ -endorphin, into the supraspinal ventricularspace or spinal subarachnoid space (Suh and Tseng, 1988; Tseng,1981; Tseng et al., 1979; Yaksh, 1981; Yaksh and Rudy, 1978).The periventricular, periaqueductal gray and rostral ventromedialmedulla of the brain and the dorsal horn of the spinal cord arerich in endorphin and opioid receptors, which are compartmentsinvolved in the antinociception (Hokfelt et al., 1977, 1979; Mayerand Price, 1976). Although the exact neuronal circuits involvedin antinociception are not completely understood, it has beendemonstrated that opioid agonists applied to supraspinal brainsites produce their antinociceptive effects through activationof descending pain-inhibitory systems (Dubner and Bennett, 1983;Fields and Basbaum, 1978). In addition to these indirect opioidactions at supraspinal sites, there is evidence of a direct spinalaction of opioids (Suh et al., 1988; Yaksh, 1981; Yaksh and Rudy,1977).

We previously demonstrated that i.c.v. morphine and $beta$ -endorphin produce their antinociceptive effects by the stimulation ofdifferent types of opioid receptors followed by the activationof different descending pain control systems that use differentneurotransmitters and receptors in the spinal cord. The antinociceptioninduced by morphine is mediated by the stimulation of mu opioidreceptors and release of norepinephrine and serotonin acting onalpha-2 adrenoceptors and serotonin receptors in the spinal cord(Jung et al., 1994; Kuraishi et al., 1978, 1979, 1983; Suh etal., 1988, 1989; Wigdor and Wilcox, 1987; Yaksh, 1979). The antinociceptioninduced by $beta$ -endorphin is mediated by the stimulation of epsilonopioid receptors and subsequent release of [Met⁵]enkephalin acting on delta-2 opioid receptors in the spinal cord(Suh et al., 1988, 1989, 1992a, 1994; Suh and Tseng, 1990b, 1990c;Tseng et al., 1985, 1986; Tseng and Suh, 1989).

Previous studies have demonstrated that calcium may play an important role in modulating nociception. For example, i.t. injectionof $omega$ -conotoxin GVIA (an N-type calcium channel blocker) potentiatesi.t. injected morphine- and clonidine-induced inhibition of thetail-flick response (Roerig and Wei, 1995). In addition, the systemicinjection of L-type calcium calcium channel blockers such as nimodipine,nifedipine, verapamil and diltiazem produces antinociception inthe formalin, writhing and hot-plate tests (Miranda et al., 1992).Malmberg and Yaksh (1994, 1995) reported that both acute i.t.injection and continuous i.t. infusion of $omega$ -conopeptides produceantinociception in the formalin and hot-plate tests. On the otherhand, i.t. injection of calcium paradoxically potentiates morphine-inducedantinociception in the tail-flick test (Lux et al., 1988). Furthermore,calcium injected i.t. also produces antinociception (Hornfeldtet al., 1992; Lux et al., 1988). However, the roles of spinalcalcium channels and calcium-associated proteins such as calmodulinand calcium/calmodulin-dependent protein kinase II in the regulationof antinociception induced by opioids administered supraspinallyhave not been characterized. The present study was designed toexamine the effects of $omega$ -conotoxin GVIA, nimodipine (an L-typecalcium channel blocker), calmidazolium (a calmodulin antagonist)and KN-62 [(a calcium/calmodulin-dependent protein kinase II inhibitor);(S)-5-isoquinolinesulfonic acid,4-[2-[(5-isoquinolinyl- sulfonyl)methylamino]3-oxo-3-(4-phenyl-1-piperazinyl)-propyl]phenylester] injected i.t. on the inhibition of the tail-flick responseinduced by morphine, DAMGO or $beta$ -endorphin administered i.c.v.in mice.

	Methods

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Experimental animals. Male ICR mice weighing 23 to 25 g were used for all experiments. The animals were housed five per cage in a room maintainedat 22 ± 0.5°C with an alternating 12-hr light/dark cycle. Foodand water were available ad libitum. Animals were used only once.

Assessment of antinociception. Antinociception was determined by the tail-flick test (D'Amour and Smith, 1941). For measurement of the latency of the tail-flickresponse, mice were gently held with one hand with the tail positionedin the apparatus (model TF6; EMDIE Instrument Co., Maidens, VA)for radiant heat stimulation. The tail-flick response was elicitedby applying radiant heat to the dorsal surface of the tail. Theintensity of heat stimulus in the tail-flick test was adjustedso that the animal flicked its tail within 3 to 5 sec. The tail-flicklatency was measured before (T₀) and after (T₁) the injectionof opioid agonists. The inhibition of the tail-flick responsewas expressed as percent maximal possible effect (% MPE), whichwas calculated as [(T₁ $-$ T₀)/(T₂ $-$ T₀)] × 100, where the cutofftime (T₂) was set at 10 sec.

The i.c.v. and i.t. injections. The i.c.v. administration was performed according to Haley and McCormick (1957). The i.t. administration was performed accordingto Hylden and Wilcox (1980) using a Hamilton syringe with a 30-gaugeneedle. The i.c.v. and i.t. injection volumes were 5 µl. The i.c.v.injection sites were verified by injecting the same volume of1% methylene blue and observing the distribution of injected drugsor dye in the ventricular space and spinal cord. The dye injectedi.c.v. was found to be distributed in ventricular spaces and ventralsurface of the brain, and the dye was found in upper cervicalportion of the spinal cord. The dye injected i.t. was distributedboth rostrally and caudally but at a short distance (~1 cm), andno dye was found in the brain. When the success rate for injectionwas consistently >95%, the experiment was performed.

Experimental protocol. In the first group, mice were pretreated i.t. with nimodipine (0.024-2.4 pmol), $omega$ -conotoxin GVIA (0.0033-0.33 pmol), calmidazolium(0.0015-0.15 pmol) or KN-62 (0.0014-0.14 pmol) for 10 min. Then,morphine (3 nmol), DAMGO (10 pmol) or $beta$ -endorphin (0.3 nmol) wasadministered i.c.v. The second group of mice was injected, i.t.,with a fixed dose of nimodipine (2.4 pmol), $omega$ -conotoxin GVIA (0.33pmol), calmidazolium (0.15 pmol) or KN-62 (0.14 pmol) for 10-min.Then, various doses of morphine, DAMGO or $beta$ -endorphin were administeredi.c.v. The tail-flick response was tested 30, 20 and 30 min afterthe i.c.v. injection of morphine, DAMGO and $beta$ -endorphin, respectively.The times used were chosen based on preliminary time course studies;at these times, mice produced a maximal inhibition of the tail-flickresponses induced by each opioid agonist.

Statistical analysis. Values are mean ± S.E.M. One-way analysis of variance, followed by Dunnett's multiple-comparison test when more than one dosewas administered, was used for statistical evaluation. The medianantinociceptive doses (ED₅₀) and their 95% confidence intervalswere calculated according to Litchfield and Wilcoxon (1949), withthe aid of a computer program described by Tallarida and Murray(1981). Values of P < .05 were considered to indicate statisticalsignificance.

Drugs. Morphine hydrochloride was purchased from Sam-Sung Pharm. Co. (Seoul, Korea). $beta$ -Endorphin and DAMGO were purchased from PeninsulaLaboratory Inc. (Belmont, Calif.). Nimodipine, $omega$ -conotoxin GVIA,calmidazolium chloride and KN-62 were purchased from ResearchBiochemicals Inc. (Natick, MA). Morphine, $beta$ -endorphin, $omega$ -conotoxinGVIA and DAMGO were dissolved in sterile saline (0.9% NaCl solution).Nimodipine chloride, calmidazolium and KN-62 were dissolved in20% dimethylsulfoxide.

	Results

Top Abstract Introduction Methods Results Discussion References

Involvement of spinal calcium channels in the production of antinociception induced by opioids administered supraspinally. To determine whether spinal L- and N-type calcium channels are involved in the antinociception induced by opioids administeredsupraspinally, the effect of nimodipine or $omega$ -conotoxin GVIA i.t.pretreatment on the inhibition of the tail-flick response inducedby $beta$ -endorphin, DAMGO or morphine administered i.c.v. was examined.The tail-flick latencies in mice pretreated i.t. with nimodipineor $omega$ -conotoxin GVIA alone were not significantly different fromthose in mice injected i.t. with vehicle (figs. 1 and 2). Thetail-flick response was measured at 30, 30 and 20 min after i.c.v.administration of $beta$ -endorphin, morphine and DAMGO, respectively. $beta$ -Endorphin (0.6 nmol), morphine (3 nmol) and DAMGO (10 pmol)increased the inhibition of the tail-flick response (fig. 1 anddata not shown). Pretreatment of mice i.t. with nimodipine or $omega$ -conotoxin GVIA dose-dependently attenuated the inhibition ofthe tail-flick response induced by $beta$ -endorphin administered i.c.v.(figs. 1 and 2). However, the inhibition of the tail-flick responseinduced by morphine or DAMGO administered i.c.v. was not changedby the i.t. pretreatment with nimodipine or $omega$ -conotoxin GVIA (datanot shown). In the dose-dependent experiments, pretreatment ofmice i.t. with nimodipine or $omega$ -conotoxin GVIA antagonized thetail-flick inhibition induced by $beta$ -endorphin administered i.c.v.and the response curve of $beta$ -endorphin was shifted to the right(table 1). The ED₅₀ values for $beta$ -endorphin, morphine and DAMGOadministered i.c.v. for the tail-flick inhibition in mice pretreatedwith saline or nimodipine i.t. are shown in table 1. The ED₅₀value of $beta$ -endorphin for tail-flick inhibition was increased ~4-foldabove the controls in mice pretreated i.t. with nimodipine or $omega$ -conotoxin GVIA. In contrast to the effect on $beta$ -endorphin, theED₅₀ values of morphine and DAMGO administered i.c.v. for tail-flickinhibition in mice pretreated i.t. with nimodipine or $omega$ -conotoxinGVIA were not significantly different from those in mice treatedi.t. with vehicle (table 1).

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Fig. 1. Effect of nimodipine injected i.t. on the inhibition of the tail-flick response induced by $beta$ -endorphin administered i.c.v.After measuring the basal tail-flick latency, we pretreated themice with either vehicle (5 µl) or nimodipine (0.0024-2.4 pmol).Then, $beta$ -endorphin (0.6 nmol) was administered i.c.v. The tail-flickresponse was measured 30 min after i.c.v. administration of $beta$ -endorphin.Vertical bars, S.E.M. The number of animals used for each groupwas 10. *P < 0.05 compared with a group of mice injected withvehicle i.t. and $beta$ -endorphin i.c.v.

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Fig. 2. Effect of $omega$ -conotoxin GVIA injected i.t. on the inhibition of the tail-flick response induced by $beta$ -endorphin administeredi.c.v. After pretreating mice with either saline (5 µl) or $omega$ -conotoxinGVIA (0.0033-0.33 pmol), we administered $beta$ -endorphin (0.6 nmol)i.c.v. Vertical bars, S.E.M. The number of animals used for eachgroup was 10. *P < 0.05 compared with group of mice injected withsaline i.t. and $beta$ -endorphin i.c.v.

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TABLE 1
Effects of nimodipine, $omega$ -conotoxin GVIA, calmidazolium and KN-62 injected i.t. on ED₅₀ values for $beta$ -endorphin, morphine andDAMGO administered i.c.v. for the tail-flick inhibition

Involvement of spinal calmodulin and calcium/calmodulin-dependent protein kinase II in the production of antinociception induced by opioids administered supraspinally. To determine the involvement of spinal calmodulin or calcium/calmodulin-dependent protein kinase II in supraspinal opioid-administeredantinociception, the effect of calmidazolium or KN-62 i.t. pretreatmenton the inhibition of the tail-flick response induced by $beta$ -endorphin,morphine or DAMGO administered i.c.v. was examined. The tail-flicklatencies in mice pretreated i.t. with calmidazolium or KN-62were not significantly different from those in mice injected i.t.with vehicle (figs. 3 and 4). Pretreatment of mice i.t. with calmidazoliumor KN-62 dose-dependently attenuated the inhibition of the tail-flickresponse induced by $beta$ -endorphin administered i.c.v. (figs. 3 and4). However, the inhibition of the tail-flick response inducedby morphine or DAMGO administered i.c.v. was not changed by thei.t. pretreatment with calmidazolium or KN-62 (figs. 3 and 4).In the dose-dependent experiments, the ED₅₀ value of $beta$ -endorphinfor tail-flick inhibition was increased ~4-fold above the controlsin mice pretreated i.t. with calmidazolium or KN-62 (table 1).However, the ED₅₀ values of morphine and DAMGO administered i.c.v.for tail-flick inhibition in mice pretreated i.t. with calmidazoliumor KN-62 were not significantly different from those in mice treatedi.t. with vehicle (table 1).

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Fig. 3. Effect of calmidazolium injected i.t. on the inhibition of the tail-flick response induced by $beta$ -endorphin administered i.c.v.After pretreating the mice with either vehicle (5 µl) or calmidazolium(0.0015-0.15 pmol), we administered $beta$ -endorphin (0.6 nmol) i.c.v.Vertical bars, S.E.M. The number of animals used for each groupwas 10. *P < 0.05 compared with group of mice injected with vehiclei.t. and $beta$ -endorphin i.c.v.

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Fig. 4. Effect of KN-62 injected i.t. on the inhibition of the tail-flick response induced by $beta$ -endorphin administered i.c.v. Afterpretreating the mice with either vehicle (5 µl) or KN-62 (0.0014-0.14pmol), we administered $beta$ -endorphin (0.6 nmol) i.c.v. Verticalbars, S.E.M. The number of animals used for each group was 10.*P < 0.05 compared with group of mice injected with vehicle i.t.and $beta$ -endorphin i.c.v.

	Discussion

Top Abstract Introduction Methods Results Discussion References

We previously reported that the antinociceptive effects of morphine and $beta$ -endorphin administered supraspinally are mediatedby the stimulation of different descending pain inhibitory systems.In addition, several lines of evidence have demonstrated thatcalcium channels located in the spinal cord may play importantroles in the regulation of antinociception. In the present study,we found that spinally injected nimodipine, $omega$ -conotoxin GVIA,calmidazolium or KN-62 effectively attenuated the inhibition ofthe tail-flick response induced by $beta$ -endorphin administered supraspinally.However, spinal injection of nimodipine, $omega$ -conotoxin GVIA, calmidazoliumor KN-62 did not affect the inhibition of the tail-flick responseinduced by morphine or DAMGO administered supraspinally. The resultsof the present study indicate that spinal L- and N-type calciumchannels, calmodulin and calcium/calmodulin-dependent proteinkinase II may be involved in the production of antinociceptioninduced by $beta$ -endorphin, but not morphine and DAMGO, administeredsupraspinally, further supporting the hypothesis that morphineand $beta$ -endorphin administered supraspinally produce their antinociceptionby activating different pain-inhibitory systems.

We and others have previously hypothesized that the antinociception induced by morphine given supraspinally is mediated bythe stimulation of mu opioid receptors and the activation of descendingserotonergic and noradrenergic pathways and subsequent stimulationof serotonergic and alpha-2 adrenergic receptors in the spinalcord for the production of antinociception (Suh et al., 1988,1989, 1992b; Suh and Tseng, 1990a, 1990d). On the other hand,the antinociception induced by $beta$ -endorphin given supraspinallyis mediated by the stimulation of epsilon opioid receptors andby releasing [Met⁵]enkephalin from the spinal cord with subsequent stimulation ofopioid receptors in the spinal cord for the production of antinociception(Suh et al., 1988, 1989; Suh and Tseng, 1990a, 1990b, 1990c).The results of the present study raise the possibility that supraspinallyadministered nimodipine, $omega$ -conotoxin GVIA, calmidazolium or KN-62may modulate $beta$ -endorphin-induced antinociception by several actions.First, nimodipine, $omega$ -conotoxin GVIA, calmidazolium or KN-62 maymodulate, presynaptically, the release of [Met⁵]enkephalin from descending neurons activated by $beta$ -endorphin administeredsupraspinally. Llinas et al. (1991) previously demonstrated thatcalcium/calmodulin-dependent protein kinase II injected presynapticallycauses the facilitation of neurotransmitter release. If the calciumchannels are blocked and calmodulin or calcium/calmodulin-dependentprotein kinase II in the presynaptic nerve terminal is inhibited,the release of [Met⁵]enkephalin from the spinal cord induced by $beta$ -endorphin administeredsupraspinally is expected to be reduced. Therefore, the effectsof nimodipine, $omega$ -conotoxin GVIA, calmidazolium or KN-62 on the $beta$ -endorphin-induced release of [Met⁵]enkephalin from the spinal cord should be further investigated.Second, nimodipine, $omega$ -conotoxin GVIA, calmidazolium or KN-62 maymodulate, postsynaptically, the action of [Met⁵]enkephalin, which is released during the activation of epsilonopioid receptors by $beta$ -endorphin administered i.c.v. Although itcannot be directly compared, recent studies have reported thatcalcium channel blockers attenuates the antinociception inducedby delta and kappa but not mu opioid receptor agonists (Barroet al., 1995; Spampinato et al., 1994). However, this speculationis not consistent with other studies. $omega$ -Conotoxin, nimodipineor other calcium blockers injected i.t. showed a potentiatingeffect in the production of antinociception induced by opioidsadministered i.t. (Kuzmin et al., 1994; Roerig and Wei, 1995;Smith and Stevens, 1995; Wong et al., 1994). Therefore, the effectsof nimodipine, $omega$ -conotoxin GVIA, calmidazolium and KN-62 on theantinociception induced by opioid receptor agonists administeredi.t. should be further delineated.

Although not exactly understood at the present time, the differential actions of nimodipine, $omega$ -conotoxin GVIA, calmidazoliumand KN-62 injected spinally toward supraspinally administered $beta$ -endorphin-, morphine- and DAMGO-induced antinociception appearto be due to the stimulation of different opioid receptors byvarious types of opioids. We previously proposed that $beta$ -endorphin,morphine and DAMGO produce their antinociception by stimulatingdifferent types of opioid receptors (Suh et al., 1988; Suh andTseng, 1988, 1990a, 1990d). This hypothesis is based on the findingsthat $beta$ -endorphin(1-27), a selective epsilon opioid receptor antagonist,administered i.c.v. antagonizes the antinociception induced by $beta$ -endorphin but not morphine and DAMGO administered i.c.v. (Suhet al., 1988). $beta$ -Funaltrexamine and D-Phe-Cys-Tyr-D-Try-Orn-Thr-Pen-Thr-NH₂,selective mu opioid receptor antagonists, administered i.c.v.each effectively antagonizes the antinociception induced by morphineand DAMGO, but not $beta$ -endorphin, administered i.c.v. (Suh and Tseng,1988, 1990a). Furthermore, a single injection of morphine or $beta$ -endorphininduces acute antinociceptive tolerance to its own distinctiveopioid receptor and does not induce cross-tolerance to other opioidagonists with different opioid receptor specificities (Suh andTseng, 1990d).

The results of the present study showed that i.t. injection of nimodipine, $omega$ -conotoxin GVIA, calmidazolium or KN-62 alonedid not affect base-line pain sensitivity in the tail-flick test.This finding suggests that L- and N-type calcium channels, calmodulinand KN-62 located at the spinal level may not be tonically involvedin the antinociceptive process. The activation of spinal calciumchannels, calmodulin and calcium/calmodulin-dependent proteinkinase II may occur when the descending pain-inhibitory systemsare activated by an opioid receptor agonist such as $beta$ -endorphin,leading to the production of antinociception.

In addition to the antagonism of nimodipine, $omega$ -conotoxin GVIA, calmidazolium and KN-62 against the i.c.v. administered $beta$ -endorphin-inducedantinociception in the present study, we found recently that i.t.injection of $omega$ -conotoxin GVIA, calmidazolium or KN-62 pretreatedi.t. effectively attenuated the inhibition of the tail-flick responseinduced by cold-water swimming stress.² Mizoguchi et al. (1995) have shown that the spinal [Met⁵]enkephalin and delta-2 opioid receptors are involved in cold-waterswimming stress-induced antinociception. This contention is supportedby the findings that the blockade of spinal delta-2 opioid receptorsby naltrindole effectively antagonizes cold-water swimming stress-inducedantinociception (Mizoguchi et al., 1995). In addition, the samegroup found that either i.t. pretreatment with the antibody against[Met⁵] enkephalin attenuates the antinociception induced by cold-waterswimming stress, suggesting that cold-water swimming stress causesthe release of [Met⁵]enkephalin from the spinal cord, leading to the production ofantinociception via activation of spinal delta opioid receptors.Vanderah et al. (1993) previously demonstrated that supraspinaldelta-2 opioid receptors also mediate cold-water swimming stressantinociception. This finding and the previous findings that antinociceptioninduced by $beta$ -endorphin administered i.c.v. is mediated by spinaldelta opioid receptors (Suh et al., 1994; Suh and Tseng, 1990b,1990c) suggest that supraspinally located epsilon or delta-2 opioidreceptors may be involved in cold-water swimming stress-inducedantinociception. Thus, it can be speculated that spinally injected $omega$ -conotoxin GVIA, calmidazolium and KN-62 may exert their antagonisticeffects secondarily against the supraspinally administered $beta$ -endorphin-inducedantinociception by modulating spinal delta opioid systems. However,the possibility that supraspinally administered $beta$ -endorphin mayproduce antinociception by stimulating supraspinal delta-2 opioidreceptors should be further assessed.

	Footnotes

Accepted for publication April 9, 1997.

Received for publication April 15, 1996.

¹ This work was supported by Grant 941-0700-009-2 from Korea Science and Engineering Foundation (KOSEF) and Hallym Academy ofSciences, Hallym University (1996).

² H. W. Suh, D. K. Song, S. O. Huh and Y. H. Kim, unpublished observations.

Send reprint requests to: Hong-Won Suh, Ph.D., Department of Pharmacology, College of Medicine, Hallym University, 1 Okchun-Dong, Chunchon, Kangwon-Do, 200-702, South Korea. E-mail: hwsuh{at}sun.hallym.ac.kr

	Abbreviations

DAMGO, [D-Ala²,N-MePhe⁴,Gly-ol⁵]-enkephalin; i.c.v., intracerebroventricular (intracerebroventricularly); i.t., intrathecal (intrathecally).

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Differential Effects of -Conotoxin GVIA, Nimodipine, Calmidazolium and KN-62 Injected Intrathecally on the Antinociception Induced by -Endorphin, Morphine and [D-Ala2,N-MePhe4,Gly-ol5]-enkephalin Administered Intracerebroventricularly in the Mouse1

Differential Effects of $omega$ -Conotoxin GVIA, Nimodipine, Calmidazolium and KN-62 Injected Intrathecally on the Antinociception Induced by $beta$ -Endorphin, Morphine and [D-Ala²,N-MePhe⁴,Gly-ol⁵]-enkephalin Administered Intracerebroventricularly in the Mouse¹