Different Mechanisms Mediate Development and Expression of Tolerance and Dependence for Peripheral ľ-Opioid Antinociception in Rat

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (32)

Citing Articles via Google Scholar

Google Scholar

Articles by Aley, K. O.

Articles by Levine, J. D.

Search for Related Content

PubMed

PubMed Citation

Articles by Aley, K. O.

Articles by Levine, J. D.

Previous Article  |  Next Article

Volume 17, Number 20, Issue of October 15, 1997 pp. 8018-8023
Copyright ©1997 Society for Neuroscience

Different Mechanisms Mediate Development and Expression of Tolerance and Dependence for Peripheral µ-Opioid Antinociception in Rat

Kochuvelikakam O. Aley and Jon D. Levine
Department of Anatomy, Medicine, and Oral Surgery and Division of Neuroscience, University of California, San Francisco, California 94143

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The µ-opioid [D-Ala²,N-Me-Phe⁴,Gly-ol⁵]-enkephalin (DAMGO) exerts a peripheral antinociceptive effect against prostaglandin E₂(PGE₂)-induced mechanical hyperalgesia in the hindpaw of the rat.Tolerance and dependence develop to this effect. We have shownpreviously that tolerance and dependence can be dissociated andare mediated by different second messenger systems. In the presentstudy, we evaluated whether the same or different second messengersystems mediate the development of this peripheral opioid toleranceor dependence compared with the expression of the loss of antinociceptiveeffect or rebound opioid antagonist hyperalgesia (i.e., expressionof tolerance and dependence). DAMGO-induced tolerance was preventedby pretreatment with the nitric oxide synthase inhibitor N^G-methyl-L-arginine (NMLA) but not by the protein kinase C (PKC)inhibitor chelerythrine, the adenylyl cyclase inhibitor 2 $'$ ,5 $'$ -dideoxyadenosine(ddA), or the calcium chelators 3,4,5-trimethoxybenzoic acid 8-(diethylamino)-octylester (TMB-8) and 2-[(2-bis-[carboxymethyl]amino-5-methylphenoxy)-methyl]-6-methoxy-8-bis[carboxymethyl]aminoquinoline(Quin-2). Once established, however, expression of DAMGO tolerancewas acutely reversed by TMB-8 or Quin-2 but not by chelerythrineor NMLA. In contrast, naloxone-precipitated hyperalgesia in DAMGO-tolerantpaws, a measure of dependence, was blocked by pretreatment withchelerythrine but not by NMLA, ddA, TMB-8, or Quin-2. Naloxone-precipitatedhyperalgesia in DAMGO-tolerant paws was acutely reversed by chelerythrine,ddA, TMB-8, or Quin-2 but not by NMLA. Taken together, these resultsprovide the first evidence that different mechanisms mediate thedevelopment and expression of both tolerance and dependence tothe peripheral antinociceptive effect of DAMGO. However, althoughthe development of tolerance and dependence are entirely separable,the expression of tolerance and dependence shares common calcium-dependentmechanisms.
Key words: protein kinase A; protein kinase C; nitric oxide; adenylyl cyclase; calcium; opioids; nociception; prostaglandin E₂

INTRODUCTION

Opioids, which traditionally are thought to produce analgesia by actions in the CNS, also have antinociceptive actions inthe periphery (Levine and Taiwo, 1989; Stein, 1991; Stein et al.,1995). Peripheral analgesic effects of opioids seem to be mediatedvia µ-opioid receptors and a G_i- and G_o-protein-mediated inhibitionof the cAMP second messenger system in primary afferent nociceptors(Levine and Taiwo, 1989). We and others have reported previouslythat tolerance and dependence develop for this peripheral antinociceptiveeffect of µ-opioid agonists (Aley et al., 1995; Kolesnikov etal., 1996). In the CNS a number of intracellular pathways havebeen suggested to play a role in opioid tolerance and dependence(Honore et al., 1997). Among these, Ca²⁺ (Wang et al., 1996), protein kinase C (Mao et al., 1995a,b; Naritaet al., 1995), and nitric oxide (Herman et al., 1995; Pasternaket al., 1995; Vaupel et al., 1995; Dambisya and Lee, 1996; Dunbarand Yaksh, 1996) have been most thoroughly implicated. The mechanismsunderlying peripheral opioid tolerance and dependence are lesscompletely understood. Recent studies from our laboratory indicatea role for nitric oxide in peripheral tolerance and for proteinkinase C (PKC) in peripheral dependence (Aley and Levine, 1997a,b).Because tolerance and dependence are initiated in ~3 hr, but lastfor up to 24 hr, we hypothesized that different cellular signalingpathways may mediate the development of this opioid toleranceand dependence versus the loss of antinociceptive effect or reboundopioid antagonist-induced hyperalgesia (i.e., expression of toleranceand dependence). In the present study, we show that nitric oxideis involved in the development of [D-Ala²,N-Me-Phe⁴,Gly-ol⁵]-enkephalin (DAMGO)-induced peripheral tolerance, whereas calcium-dependentmechanisms play a role in its expression. In contrast, PKC playsa role in the development of DAMGO dependence, whereas PKC, adenylylcyclase, and calcium-dependent mechanisms play a role in its expression;thus, the development of tolerance and dependence are entirelyseparable, whereas the expression of tolerance and dependenceshare common calcium dependence.

MATERIALS AND METHODS
Animals. Experiments were performed on male Sprague Dawley rats (250-300 gm; Bantin-Kingman, Fremont, CA). Animals were housedin groups of two under a 12 hr light/dark cycle. Food and waterwere available ad libitum. All testing was done between 10:00A.M. and 4:00 P.M. Experiments were performed under approval ofthe Institutional Animal Care Committee of the University of California,San Francisco.

Behavioral testing. The nociceptive flexion reflex was quantified with a Basile Analgesymeter (Stoelting, Chicago, IL), whichapplies a linearly increasing mechanical force to the dorsum ofthe rat's hindpaw. Before the experiments, rats were exposed tothe paw withdrawal testing procedure for 3 d (1 hr daily at 5min intervals); on the day of the experiment, rats were exposedto the same procedure, and the baseline threshold was determinedas the mean of the six readings before the administration of testagents. The mean baseline threshold for the rats used in theseexperiments was 112.9 ± 0.4 gm (mean ± SEM; n = 316). The mechanicalnociceptive threshold was redetermined at three time points (15,20, and 25 min) after treatments. The mean of these three readingswas considered the paw withdrawal threshold attributable to drugadministration, and this value was used to calculate the percentagechange from the baseline threshold.

Drug administration. The drugs used in this study were prostaglandin E₂ (PGE₂; an inflammatory mediator; 100 ng), naloxonemethyliodide (NAL; a quaternary opioid antagonist; 200 ng), 3,4,5-trimethoxybenzoicacid 8-(diethylamino)-octyl ester (TMB-8; a calcium chelator;1 µg), 2-[(2-bis-[carboxymethyl]amino-5-methylphenoxy)-methyl]-6-methoxy-8-bis[carboxymethyl]aminoquinoline(Quin-2; a calcium chelator; 1 µg), N^G-methyl-L-arginine (NMLA; a nitric oxide synthase inhibitor; 1µg), and dimethylsulfoxide (DMSO; a vehicle), all from Sigma (St.Louis, MO); DAMGO (a µ-opioid receptor agonist; 1 µg) from ResearchBiochemicals (Natick, MA); chelerythrine-HCl (Ch; a PKC inhibitor;1 µg) from L. C. Laboratories (Woburn, MA); and 2 $'$ ,5 $'$ -dideoxyadenosine(ddA; an adenylyl cyclase inhibitor; 1 µg), a generous gift fromDr. Roger Johnson (State University of New York, Stony Brook,NY). The selection of the drug doses used in this study was basedon the dose-response curves determined during previous studies(Aley and Levine, 1997a,b). The stock solution of PGE₂ (10 µg/2.5µl) was prepared in pure ethanol, and further dilutions were madein saline; the final concentration of ethanol was $<=$ 1%. DAMGO,naloxone, and NMLA were dissolved in saline. Chelerythrine wasdissolved in deionized water. TMB-8 and Quin-2 were dissolvedin DMSO. All drugs administered intradermally were in a totalvolume of 2.5 µl/paw. Whenever an antagonist was included, itwas injected first. When drug combinations were used, they wereadministered from the same syringe in such a way that the drugmentioned first reached the intradermal site first. The drugswere separated in the syringe by a small air bubble to preventdrugs mixing while in the syringe; each bubble was 2.5 µl.

Statistical analysis. Data are presented as mean ± SEM of six or more observations in each of the experimental groups. Statisticalsignificance was determined by ANOVA followed by Scheffe's posthoc test, in which p < 0.05 was considered statistically significant.The data for groups in some experiments are repeated in more thanone figure for ease of comparison.

RESULTS

Tolerance
Three hourly injections of DAMGO (1 µg) produced tolerance to its antinociceptive effect against PGE₂-induced hyperalgesia.That is, when DAMGO was administered with PGE₂ 1 hr after thelast injection of DAMGO alone, DAMGO was not antinociceptive againstPGE₂-induced hyperalgesia (Fig. 1A, DAMGO+PGE₂ vs DAMGO×3,DAMGO+PGE₂;p < 0.05).
Fig. 1. A, Role of NO in development of peripheral opioid tolerance. Effects of PGE₂ (100 ng; PGE₂; n = 16), DAMGO (1 µg) plus PGE₂(DAMGO+PGE₂; n = 16), three hourly injections of DAMGO followedby DAMGO plus PGE₂ at the fourth hour (DAMGO×3,DAMGO+PGE₂; n =12), saline (n = 6), NMLA (1 µg) plus PGE₂ (NMLA+PGE₂; n = 8),NMLA alone (NMLA; n = 6), three hourly injections of NMLA followedby PGE₂ at the fourth hour (NMLA×3,PGE₂; n = 6), and three hourlyinjections of NMLA plus DAMGO followed by DAMGO plus PGE₂ [(NMLA+DAMGO)×3,DAMGO+PGE₂;n = 12] on mechanical paw withdrawal threshold in rats. In thisand all subsequent figures, an asterisk indicates p < 0.05, andNS indicates not significant statistically. B, Lack of role ofPKC in development of peripheral opioid tolerance. Effects ofPGE₂ (100 ng; PGE₂; n = 16), DAMGO (1 µg) plus PGE₂ (DAMGO+PGE₂;n = 16), three hourly injections of DAMGO followed by DAMGO plusPGE₂ (DAMGO×3,DAMGO+PGE₂; n = 12), chelerythrine (1 µg) alone(Ch; n = 6), chelerythrine plus PGE₂ (Ch+PGE₂; n = 6), chelerythrineplus DAMGO plus PGE₂ (Ch+DAMGO+PGE₂; n = 6), and three hourlyinjections of chelerythrine plus DAMGO followed by DAMGO plusPGE₂ [(Ch+DAMGO)×3,DAMGO+PGE₂; n = 6] on mechanical paw withdrawalthreshold in rats. C, Lack of role of cAMP in development of peripheralopioid tolerance. Effects of PGE₂ (100 ng; PGE₂; n = 16), DAMGO(1 µg) plus PGE₂ (DAMGO+PGE₂; n = 16), three hourly injectionsof DAMGO followed by DAMGO plus PGE₂ (DAMGO×3,DAMGO+PGE₂; n =12), ddA (1 µg) plus PGE₂ (ddA+PGE₂; n = 6), ddA alone (ddA; n= 6), three hourly injections of ddA followed by PGE₂ at the fourthhour (ddA×3,PGE₂; n = 6), and three hourly injections of ddA (1µg) plus DAMGO followed by DAMGO plus PGE₂ at the fourth hour[(ddA+DAMGO)×3,DAMGO+PGE₂; n = 12] on mechanical paw withdrawalthreshold in rats. D, Lack of role of calcium in development ofperipheral opioid tolerance. Effect of PGE₂ (100 ng; PGE₂; n =16), DAMGO (1 µg) plus PGE₂ (DAMGO+PGE₂; n = 16), three hourlyinjections of DAMGO followed by DAMGO plus PGE₂ (DAMGO×3,DAMGO+PGE₂;n = 12), TMB-8 (1 µg) alone (TMB; n = 6), TMB-8 plus PGE₂, (TMB+PGE₂;n = 6), TMB-8 plus DAMGO plus PGE₂ (TMB+DAMGO+PGE₂; n = 6), andthree hourly injections of TMB-8 plus DAMGO followed by DAMGOplus PGE₂ at the fourth hour [(TMB+DAMGO)×3,DAMGO+PGE₂; n = 6]on mechanical paw withdrawal threshold in rats. E, Lack of roleof calcium in development of peripheral opioid tolerance. Effectsof PGE₂ (100 ng; PGE₂; n = 16), DAMGO (1 µg) plus PGE₂ (DAMGO+PGE₂;n = 16), three hourly injections of DAMGO followed by DAMGO plusPGE₂ (DAMGO×3,DAMGO+PGE₂; n = 12), Quin-2 (1 µg) alone (Quin;n = 6), Quin-2 plus PGE₂ (Quin+PGE₂; n = 6), Quin-2 plus DAMGOplus PGE₂ (Quin+DAMGO+PGE₂; n = 6), and three hourly injectionsof Quin-2 plus DAMGO followed by DAMGO plus PGE₂ at the fourthhour [(Quin+DAMGO)×3,DAMGO+PGE₂; n = 6] on mechanical paw withdrawalthreshold in rats.
[View Larger Version of this Image (29K GIF file)]

Second messengers involved in the development of tolerance When NMLA (1 µg), which interferes with the production of the second messenger nitric oxide (NO), was combined with threehourly injections of DAMGO, the induction of DAMGO-induced tolerancewas prevented [Fig. 1A, DAMGO×3,DAMGO+PGE₂ vs (NMLA+DAMGO)×3,DAMGO+PGE₂;p < 0.05]. NMLA had no effect on baseline threshold (Fig. 1A,NMLA) but attenuated PGE₂-induced hyperalgesia (Fig. 1A, NMLA+PGE₂).However, 1 hr after three hourly doses (i.e., when tolerance toDAMGO was tested), there was no residual effect of NMLA on PGE₂-inducedhyperalgesia (Fig. 1A, NMLA×3,PGE₂). These results suggest thatNO plays a role in development of DAMGO-induced tolerance.

Chelerythrine (1 µg), a protein kinase C inhibitor, did not have any effect on baseline paw withdrawal threshold, PGE₂-inducedhyperalgesia, antinociceptive effect of DAMGO against PGE₂-inducedhyperalgesia, or the development of DAMGO-induced tolerance [Fig.1B, Ch+PGE₂, Ch+DAMGO+PGE₂, (Ch+DAMGO)×3,DAMGO+PGE₂].

ddA (1 µg), an inhibitor of adenylyl cyclase, had no effect on baseline paw withdrawal threshold (Fig. 1C) but attenuatedPGE₂-induced hyperalgesia (Fig. 1C, ddA+PGE₂). After three hourlydoses of ddA, there was no residual effect at the next hour onPGE₂-induced hyperalgesia (Fig. 1C, ddA×3, PGE₂). ddA did notprevent the development of DAMGO-induced tolerance [Fig. 1C, (ddA+DAMGO)×3,DAMGO+PGE₂].

TMB-8 (1 µg) and Quin-2 (1 µg), intracellular calcium chelators, did not have any effect on baseline paw withdrawal threshold,PGE₂-induced hyperalgesia, the antinociceptive effect of DAMGOagainst PGE₂-induced hyperalgesia, or the induction of DAMGO-inducedtolerance [Fig. 1, D, TMB+PGE₂, TMB+DAMGO+PGE₂, (TMB+DAMGO)×3,DAMGO+PGE₂;E, Quin+PGE₂, Quin+DAMGO+PGE₂, (Quin+DAMGO)×3, DAMGO+PGE₂]. DMSO(vehicle for TMB-8 and Quin-2) did not have a significant effecton baseline paw withdrawal threshold (data not shown).

These data suggest that nitric oxide, but not PKC, adenylyl cyclase, or calcium-dependent mechanisms affected by TMB-8 orQuin-2, plays a role in the development of tolerance.
Expression of tolerance In DAMGO-tolerant paws, TMB-8 or Quin-2 with DAMGO plus PGE₂ at the fourth hour was found to block the expression of tolerance(Fig. 2, DAMGO×3,DAMGO+PGE₂ vs DAMGO×3, TMB+DAMGO+PGE₂, DAMGO×3,DAMGO+PGE₂vs DAMGO×3,Quin+DAMGO+PGE₂; p < 0.05 for all comparisons), indicatingthat calcium-dependent mechanisms are involved in the expressionof tolerance. NMLA, which prevented the development of tolerance,and chelerythrine had no effect on the expression of DAMGO-inducedtolerance (Fig. 2, DAMGO×3,DAMGO+PGE₂ vs DAMGO×3,Ch+DAMGO+ PGE₂,DAMGO×3,DAMGO+PGE₂ vs DAMGO×3,NMLA+ DAMGO+PGE₂; p > 0.05 for allcomparisons), indicating that neither PKC nor nitric oxide playsa role in the expression of DAMGO-induced peripheral tolerance.In the DAMGO-tolerant animal, NMLA did not exert an antinociceptiveeffect against PGE₂-induced hyperalgesia, as it does in the nontolerantanimal (data not shown).
Fig. 2. Calcium but not PKC or NO plays a role in the expression of peripheral opioid tolerance. Effects of PGE₂, (PGE₂; n = 16),DAMGO plus PGE₂ (DAMGO+PGE₂; n = 16), three hourly injectionsof DAMGO followed by DAMGO plus PGE₂ (DAMGO×3, DAMGO+PGE₂; n =12), three hourly injections of DAMGO followed by TMB-8 plus DAMGOplus PGE₂ at the fourth hour (DAMGO×3,TMB+DAMGO+PGE₂; n = 6),three hourly injections of DAMGO followed by Quin-2 plus DAMGOplus PGE₂ at the fourth hour (DAMGO×3,Quin+DAMGO+PGE₂; n = 6),three hourly injections of DAMGO followed by chelerythrine plusDAMGO plus PGE₂ at the fourth hour (DAMGO×3,Ch+DAMGO+PGE₂; n =12), and three hourly injections of DAMGO followed by NMLA plusDAMGO plus PGE₂ at the fourth hour (DAMGO×3,NMLA+DAMGO+PGE₂; n= 6) on mechanical paw withdrawal threshold in rats.
[View Larger Version of this Image (18K GIF file)]

Dependence
Naloxone methyliodide given at its dose to produce 80% inhibition (ID₈₀) for the inhibition of the antinociceptive effectof DAMGO (200 ng) (Aley and Levine, 1997a,b), when injected 1hr after the third of three hourly injections of DAMGO, precipitatedwithdrawal hyperalgesia (Fig. 3, DAMGO×3,V vs DAMGO×3, NAL; p< 0.05).
Fig. 3. PKC but not NO, cAMP, or calcium plays a role in the development of peripheral opioid dependence. Effects of PGE₂, (PGE₂;n = 16), DAMGO plus PGE₂ (DAMGO+PGE₂; n = 16), three hourly injectionsof DAMGO followed by vehicle at the fourth hour (DAMGO×3,V; n= 6), three hourly injections of DAMGO followed by naloxone atthe fourth hour (DAMGO×3,NAL; n = 12), three hourly injectionsof chelerythrine plus DAMGO followed by naloxone at the fourthhour [(Ch+DAMGO)×3,NAL; n = 6], three hourly injections of NMLAplus DAMGO followed by naloxone at the fourth hour [(NMLA+DAMGO)×3,NAL;n = 12], three hourly injections of ddA plus DAMGO followed bynaloxone at the fourth hour [(ddA+DAMGO)×3,NAL; n = 6], threehourly injections of TMB-8 plus DAMGO followed by naloxone atthe fourth hour [(TMB+DAMGO)×3,NAL; n = 6], and three hourly injectionsof chelerythrine plus DAMGO followed by naloxone at the fourthhour [(Quin+DAMGO)×3,NAL; n = 6] on mechanical paw withdrawalthreshold in rats.
[View Larger Version of this Image (19K GIF file)]

Development of dependence When chelerythrine (1 µg) was coinjected with three hourly injections of DAMGO, naloxone-precipitated withdrawal hyperalgesiawas prevented [Fig. 3, DAMGO×3,NAL vs (Ch+DAMGO)×3,NAL; p < 0.05],indicating a role for PKC in the development of DAMGO-induceddependence. Chelerythrine did not have any effect on the baselinepaw withdrawal threshold (Fig. 1B).

Coadministration of NMLA, ddA, TMB-8, or Quin-2 with three hourly injections of DAMGO had no effect on the development ofnaloxone-precipitated withdrawal hyperalgesia [Fig. 3, DAMGO×3,NALvs (NMLA+DAMGO)×3,NAL, DAMGO×3,NAL vs (ddA+DAMGO)×3,NAL, DAMGO×3,NAL vs (TMB+DAMGO)×3,NAL, DAMGO×3,NAL vs (Quin+DAMGO)×3,NAL; allp > 0.05]. These results indicate that nitric oxide, adenylylcyclase, and calcium-dependent mechanisms dependent on TMB-8 orQuin-2 do not play a role in the development of DAMGO-inducedperipheral tolerance.
Expression of dependence Coadministration of chelerythrine, ddA, TMB-8, or Quin-2 with naloxone at the fourth hour after three hourly injections ofDAMGO blocked precipitated withdrawal hyperalgesia (Fig. 4, DAMGO×3,NALvs DAMGO×3,Ch+NAL, DAMGO×3,NAL vs DAMGO×3,ddA+NAL, DAMGO×3,NALvs DAMGO×3,TMB +NAL, DAMGO×3,NAL vs DAMGO×3,Quin+NAL; all p <0.05). Coadministration of NMLA with naloxone at the fourth hourafter three hourly injections of DAMGO did not block naloxone-precipitatedwithdrawal hyperalgesia (Fig. 4, DAMGO×3,NAL vs DAMGO×3,NMLA+NAL;p > 0.05). These results indicate that PKC, adenylyl cyclase,and calcium-dependent mechanisms, but not nitric oxide, are involvedin the expression of DAMGO-induced peripheral dependence (naloxone-precipitatedwithdrawal hyperalgesia).
Fig. 4. PKC, calcium, and cAMP, but not NO, play a role in expression of peripheral opioid dependence. Effects of PGE₂ (PGE₂; n =16), DAMGO plus PGE₂ (DAMGO+PGE₂; n = 16), three hourly injectionsof DAMGO followed by naloxone at the fourth hour (DAMGO×3,NAL;n = 12), three hourly injections of DAMGO followed by chelerythrineplus naloxone at the fourth hour (DAMGO×3,Ch+NAL; n = 10), threehourly injections of DAMGO followed by ddA plus naloxone at thefourth hour (DAMGO×3,ddA+NAL; n = 6), three hourly injectionsof DAMGO followed by TMB-8 plus naloxone at the fourth hour (DAMGO×3,TMB+NAL;n = 12), three hourly injections of DAMGO followed by Quin-2 plusnaloxone at the fourth hour (DAMGO×3, Quin+NAL; n = 12), and threehourly injections of DAMGO followed by NMLA plus naloxone at thefourth hour (DAMGO×3,NMLA+NAL; n = 8) on mechanical paw withdrawalthreshold in rats.
[View Larger Version of this Image (15K GIF file)]

A summary of the second messengers implicated in the development and/or expression of tolerance and dependence to the peripheralantinociceptive effects of the µ-opioid DAMGO is shown in Table1.

Table 1. Summary of mechanisms involved in development and expression of peripheral opioid tolerance and dependence

Tolerance
Dependence

Development Expression Development Expression

NO Ca²⁺ PKC PKC, cAMP, Ca²⁺

DISCUSSION
In the present study, we have begun to dissect the mechanisms involved in the development compared with the expression ofopioid tolerance and dependence in the model of peripheral antinociceptionproduced by the µ-opioid agonist DAMGO (Aley et al., 1995). Asreported previously (Aley and Levine, 1997b), we found that NOseems to be involved in tolerance, whereas PKC seems to be involvedin dependence (Aley and Levine, 1997b). We have now shown thatthese systems are involved in development but not at all in expressionor in conjunction with other systems for expression. Unlike us,previous investigators found that NO synthase inhibitors can reducesigns of opioid dependence, but nociception was not evaluatedin any of these studies (e.g., Adams et al., 1993; Thorat et al.,1994; Bhargava, 1995; London et al., 1995). Our finding is consistentwith the observation that although the NO synthase inhibitor NMLAprevents morphine tolerance, acutely it does prevent expressionof tolerance (Kolesnikov et al., 1993; London et al., 1995; Dambisyaand Lee, 1996; Dunbar and Yaksh, 1996). Interestingly, althoughmechanisms of development are distinct for tolerance and dependence,there are some common mechanisms of expression, namely calcium.Our results suggest that the development of tolerance and thedevelopment of dependence use discrete second messenger systemsand that there is a partial overlap in mechanisms for the expressionphase of tolerance and dependence. The generally reported observationof the coexistence of tolerance and dependence may be based inpart on the contribution by this common second messenger system(Mao et al., 1995a,b).

Our results agree with the finding that chronic administration of calcium channel blockers can attenuate the expression ofopioid tolerance in the CNS (Bongianni et al., 1986; Ruiz et al.,1993; Berstein and Welch, 1995; Diar et al., 1995; Diaz et al.,1995; Garaulet et al., 1996). Although the mechanism by whichcalcium is involved in expression of tolerance and dependenceis uncertain, activation of PKC may influence neurons by changingconductances of ion channels (Alkon et al., 1986), including thosefor calcium. The importance of calcium may result from effectsof opioids on calcium currents, an action shown to be mediatedby G-proteins linked directly to a calcium channel (Hescheleret al., 1987). Also, during opioid withdrawal, phosphatidylinositolhydrolysis or PKC activity has been found to be greatly enhanced(Busquets et al., 1995; Mao et al., 1995a,b).

We observed in our experimental protocol that NMLA had an inhibitory effect on PGE₂-induced hyperalgesia. Interestingly, inthe DAMGO-tolerant animal, NMLA no longer exerted such an effect.This observation suggests that the NMLA effect may involve a commonmechanism with one by which opioids act to produce tolerance.

In the experiments on naloxone-induced withdrawal hyperalgesia, ddA was able to prevent the expression of dependence. However,although not affecting baseline threshold, ddA inhibited PGE₂-inducedhyperalgesia. Therefore, although the findings with ddA suggestthat cAMP is involved in expression of dependence, it is possiblethat the results reflect a less specific ability of ddA to bluntthe production of hyperalgesic states, not specifically naloxone-inducedhyperalgesia in DAMGO-treated rats.

In summary, the experiments presented here provide evidence that mechanisms reported previously to mediate opioid toleranceand dependence play differential roles in terms of developmentand expression in the model of µ-opioid peripheral antinociception.Specifically, previously implicated second messengers are involved,and the second messenger calcium plays a role in expression ofboth tolerance and dependence. We hypothesize that these effectsare occurring in the primary afferent nociceptor. However, althoughPGE₂ hyperalgesia and DAMGO antinociception are known to occurby direct action on the primary afferent nociceptor, the sitesof action of the second messenger inhibitors are not known. Therefore,intercellular effects are possible. In vitro studies would beneeded to answer this question.

The presence of different second messengers mediating development and expression of opioid tolerance and dependence providesa new experimental construct for opioid pharmacology in generaland suggests the possibility of novel therapeutic interventionsthat might prevent the development and continued presence of thesetwo phenomena, which have a significant negative impact on theutility of opioid analgesia in humans.

FOOTNOTES

Received June 6, 1997; revised August 1, 1997; accepted August 1, 1997.

This study was funded by National Institutes of Health Grant DE08973. We acknowledge our many discussions with Drs. Paul Green,Philip Heller, Gordon McCarter, David Reichling, and KimberlyTanner.

Correspondence should be addressed to Dr. Jon D. Levine, Department of Anatomy, Box 0452, University of California, San Francisco,CA 94143-0452.

REFERENCES

Adams ML, Kalicki JM, Meyer ER, Cicero TJ (1993) Inhibition of the morphine withdrawal syndrome by a nitric oxide synthase inhibitor, NG-nitro-L-arginine methyl ester. Life Sci 52:PL245-PL249[Web of Science][Medline].
Aley KO, Levine JD (1997a) Multiple receptors involved in peripheral $alpha$ ₂, µ, and A1 antinociception, tolerance, and withdrawal. J Neurosci 17:735-744[Abstract/Free Full Text].
Aley KO, Levine JD (1997b) Dissociation of tolerance and dependence for opioid peripheral antinociception in rats. J Neurosci 17:3907-3912[Abstract/Free Full Text].
Aley KO, Green PG, Levine JD (1995) Opioid and adenosine peripheral antinociception are subject to tolerance and withdrawal. J Neurosci 15:8031-8038[Abstract].
Alkon DL, Kubota M, Neary JT, Naito S, Coulter D, Ramussen H (1986) C-kinase activation prolongs CA⁺⁺-dependent inactivation of K⁺ currents. Biochem Biophys Res Commun 134:1245-1253[Web of Science][Medline].
Bernstein MA, Welch SP (1995) Alterations in L-type calcium channels in the brain and spinal cord of acutely treated and morphine-tolerant mice. Brain Res 696:83-88[Web of Science][Medline].
Bhargava HN (1995) Attenuation of tolerance to, and physical dependence on, morphine in the rat by inhibition of nitric oxide synthase. Gen Pharmacol 26:1049-1053[Web of Science][Medline].
Bongianni F, Carla V, Moroni F, Pellegrini-Giampietro DE (1986) Calcium channel inhibitors suppress the morphine-withdrawal in rats. Br J Pharmacol 88:561-567[Web of Science][Medline].
Busquets X, Escriba PV, Sastre M, Garcia-Sevilla JA (1995) Loss of protein kinase C-alpha beta in brain of heroin addicts and morphine-dependent rats. J Neurochem 64:247-252[Web of Science][Medline].
Dambisya YM, Lee TL (1996) Role of nitric oxide in the induction and expression of morphine tolerance and dependence in mice. Br J Pharmacol 117:914-918[Web of Science][Medline].
Diaz A, Ruiz F, Florez J, Hurlé MA, Pazos A (1995) Mu-opioid receptor regulation during opioid tolerance and supersensitivity in rat central nervous system. J Pharmacol Exp Ther 274:1545-1551[Abstract/Free Full Text].
Dunbar S, Yaksh TL (1996) Effect of spinal infusion of L-NAME, a nitric oxide synthase inhibitor, on spinal tolerance and dependence induced by chronic intrathecal morphine in the rat. Neurosci Lett 207:33-36[Web of Science][Medline].
Garaulet JV, Laorden ML, Milanes MV (1996) Effect of chronic administration of dihydropyridine Ca²⁺ channel ligands on sufentanil-induced tolerance to mu- and kappa-opioid agonists in the guinea pig ileum myenteric plexus. Regul Pept 63:1-8[Web of Science][Medline].
Herman BH, Vocci F, Bridge P (1995) The effects of NMDA receptor antagonists and nitric oxide synthase inhibitors on opioid tolerance and withdrawal. Medication development issues for opiate addiction. Neuropsychopharmacology 13:269-293[Web of Science][Medline].
Hescheler J, Rosenthal W, Trauwein W, Schultz G (1987) The GTP-binding protein, G_o, regulates neuronal calcium channels. Nature 325:445-447[Medline].
Honore P, Catheline G, LeGuen S, Besson JM (1997) Chronic treatment with systemic morphine induced tolerance to the systemic and peripheral antinociceptive effects of morphine on both carrageenan induced mechanical hyperalgesia and spinal c-Fos expression in awake rats. Pain 71:99-108[Web of Science][Medline].
Kolesnikov YA, Pick CG, Ciszewska G, Pasternak GW (1993) Blockade of tolerance to morphine but not to kappa opioids by a nitric oxide synthase inhibitor. Proc Natl Acad Sci USA 90:5162-5166[Abstract/Free Full Text].
Kolesnikov YA, Jain S, Wilson R, Pasternak GW (1996) Peripheral morphine analgesia: synergy with central sites and a target of morphine tolerance. J Pharmacol Exp Ther 279:502-506[Abstract/Free Full Text].
Levine JD, Taiwo YO (1989) Involvement of the mu-opiate receptor in peripheral analgesia. Neuroscience 32:571-575[Web of Science][Medline].
London ED, Kimes AS, Vaupel DB (1995) Inhibitors of nitric oxide synthase and the opioid withdrawal syndrome. NIDA Res Monogr 147:170-181[Medline].
Mao J, Price D, Phillips L, Lu J, Mayer D (1995a) Increases in protein kinase C gamma immunoreactivity in the spinal cord of rats associated with tolerance to the analgesic effects of morphine. Brain Res 677:257-267[Web of Science][Medline].
Mao J, Price DD, Mayer DJ (1995b) Experimental mononeuropathy reduces the antinociceptive effects of morphine: implications for common intracellular mechanisms involved in morphine tolerance and neuropathic pain. Pain 61:353-364[Web of Science][Medline].
Narita M, Mizoguchi H, Tseng LF (1995) Inhibition of protein kinase C, but not of protein kinase A, blocks the development of acute antinociceptive tolerance to an intrathecally administered mu-opioid receptor agonist in the mouse. Eur J Pharmacol 280:R1-R3[Web of Science][Medline].
Pasternak GW, Kolesnikov YA, Babey AM (1995) Perspectives on the N-methyl-D-aspartate/nitric oxide cascade and opioid tolerance. Neuropsychopharmacology 13:309-313[Web of Science][Medline].
Ruiz F, Dierssen M, Florez J, Hurle MA (1993) Potentiation of acute opioid-induced respiratory depression and reversal of tolerance by the calcium antagonist nimodipine in awake rats. Naunyn Schmiedebergs Arch Pharmacol 348:633-637[Web of Science][Medline].
Stein C (1991) Peripheral analgesic actions of opioids. J Pain Symptom Management 6:119-124[Web of Science][Medline].
Stein C, Schäfer M, Hassan AH (1995) Peripheral opioid receptors. Ann Med 27:219-221[Web of Science][Medline].
Thorat SN, Barjavel MJ, Matwyshyn GA, Bhargava HN (1994) Comparative effects of NG-monomethyl-L-arginine and MK-801 on the abstinence syndrome in morphine-dependent mice. Brain Res 642:153-159[Web of Science][Medline].
Vaupel DB, Kimes AS, London ED (1995) Nitric oxide synthase inhibitors. Preclinical studies of potential use for treatment of opioid withdrawal. Neuropsychopharmacology 13:315-322[Web of Science][Medline].
Wang Z, Arden J, Sadee W (1996) Basal phosphorylation of mu opioid receptor is agonist modulated and Ca²⁺-dependent. FEBS Lett 387:53-57[Web of Science][Medline].

Copyright ©1997 Society for Neuroscience   0270-6474/1997/178018-06$05.00/0

This article has been cited by other articles:

D. J. Daniels, N. R. Lenard, C. L. Etienne, P.-Y. Law, S. C. Roerig, and P. S. Portoghese
Opioid-induced tolerance and dependence in mice is modulated by the distance between pharmacophores in a bivalent ligand series
PNAS, December 27, 2005; 102(52): 19208 - 19213.
[Abstract] [Full Text] [PDF]

G. Lim, S. Wang, Q. Zeng, B. Sung, L. Yang, and J. Mao
Expression of Spinal NMDA Receptor and PKC{gamma} after Chronic Morphine Is Regulated by Spinal Glucocorticoid Receptor
J. Neurosci., November 30, 2005; 25(48): 11145 - 11154.
[Abstract] [Full Text] [PDF]

A. Tasatargil and G. Sadan
Reduction in [D-Ala2, NMePhe4, Gly-ol5]Enkephalin-Induced Peripheral Antinociception in Diabetic Rats: The Role of the L-Arginine/Nitric Oxide/Cyclic Guanosine Monophosphate Pathway
Anesth. Analg., January 1, 2004; 98(1): 185 - 192.
[Abstract] [Full Text] [PDF]

J. F. Nitsche, A. G. P. Schuller, M. A. King, M. Zengh, G. W. Pasternak, and J. E. Pintar
Genetic Dissociation of Opiate Tolerance and Physical Dependence in delta -Opioid Receptor-1 and Preproenkephalin Knock-Out Mice
J. Neurosci., December 15, 2002; 22(24): 10906 - 10913.
[Abstract] [Full Text] [PDF]

K. O. Aley and J. D. Levine
Role of Protein Kinase A in the Maintenance of Inflammatory Pain
J. Neurosci., March 15, 1999; 19(6): 2181 - 2186.
[Abstract] [Full Text] [PDF]

S. G. Khasar, G. McCarter, and J. D. Levine
Epinephrine Produces a beta -Adrenergic Receptor-Mediated Mechanical Hyperalgesia and In Vitro Sensitization of Rat Nociceptors
J Neurophysiol, March 1, 1999; 81(3): 1104 - 1112.
[Abstract] [Full Text] [PDF]

K. O. Aley, G. McCarter, and J. D. Levine
Nitric Oxide Signaling in Pain and Nociceptor Sensitization in the Rat
J. Neurosci., September 1, 1998; 18(17): 7008 - 7014.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (32)

Citing Articles via Google Scholar

Google Scholar

Articles by Aley, K. O.

Articles by Levine, J. D.

Search for Related Content

PubMed

PubMed Citation

Articles by Aley, K. O.

Articles by Levine, J. D.