Antisense Mapping of MOR-1 in Rats: Distinguishing between Morphine and Morphine-6beta -glucuronide Antinociception

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MORPHINE

Vol. 281, Issue 1, 109-114, 1997

Antisense Mapping of MOR-1 in Rats: Distinguishing between Morphine and Morphine-6 $beta$ -glucuronide Antinociception¹

Grace C. Rossi, Liza Leventhal , Ying-Xin Pan, Jessica Cole, Wendy Su, Richard J. Bodnar and Gavril W. Pasternak

The Cotzias Laboratory of Neuro-Oncology, Memorial Sloan-Kettering Cancer Center, New York, New York (G.C.R., L.L., Y.-X.P., W.S., G.W.P.); Departments of Neurology & Neuroscience and Pharmacology, Cornell University Medical College, New York, New York (G.W.P.); Neuropsychology Doctoral Sub Program, City University of New York, New York, New York (L.L., J.C., R.J.B.); and Department of Psychology, Queens College, City University of New York, Flushing, New York (R.J.B.)

	Abstract

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In an effort to correlate the recently cloned MOR-1 receptor with the pharmacological actions of morphine and morphine-6 $beta$ -glucuronide(M6G), we have used an antisense paradigm. Rats were injectedintracerebroventricularly (i.c.v.) with antisense oligodeoxynucleotideson days 1, 3 and 5 and tested for analgesia on day 6 after administrationof morphine or M6G i.c.v. or after microinjection of morphinedirectly into either the periaqueductal gray or the locus coeruleus.When given i.c.v., the antisense oligodeoxynucleotide targetingthe 5 $'$ -untranslated region of exon 1 significantly decreased theanalgesic actions of morphine administered i.c.v. or microinjecteddirectly into the periaqueductal gray or locus coeruleus, withthe most profound inhibition occurring in the periaqueductal gray.Thus, antisense oligodeoxynucleotides administered into the lateralventricle can diffuse into the brainstem and interfere with morphineactions. A mismatch antisense oligodeoxynucleotide with the samebase composition in which the sequence of four bases was changedwas inactive. This same exon 1 antisense oligodeoxynucleotide,which was active against morphine analgesia, failed to block M6Ganalgesia. In contrast, antisense sequences from exons 2 and 3decreased M6G, and not morphine, analgesia. The antisense oligodeoxynucleotideagainst exon 4 slightly decreased both morphine and M6G antinociception.These results confirm the antisense mapping studies on exons 1,2 and 3 of MOR-1 in mice, which implied the presence of a novelµ receptor subtype responsible for M6G analgesia that may representa splice variant of MOR-1. Unlike in mice, the probe against exon4 had a small effect on M6G analgesia.

	Introduction

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Morphine is a potent analgesic when administered into any one of a number of brainstem structures (Tsou and Jang, 1964; Jacquetand Lajtha, 1973; Pert and Yaksh, 1974; Jensen and Yaksh, 1986;Smith et al., 1988; Bodnar et al., 1988, 1990). Further studieshave established complex interactions among many of these regions,with profound synergy when morphine is given into more than onebrainstem structure (Rossi et al., 1993, 1994b). For example,multiplicative interactions are observed between the PAG, theLC and the rostro-ventral medulla. Mapping of these brainstemregions has been done primarily with morphine, a selective µ-opioid(for review, see Pasternak, 1993). Other opioid receptors alsocan elicit analgesia within the brainstem. Although $kappa$ ₁ agonistsare inactive in the PAG, the $delta$ ₂ agonist [D-Ala²,Glu⁴]deltorphin can produce modest analgesia (Rossi et al., 1994b).

M6G is an exceptionally potent analgesic in the brain, with an activity >100-fold greater than that of morphine (Shimomuraet al., 1971; Pasternak et al., 1987; Abbott and Palmour, 1988;Sullivan et al., 1989; Paul et al., 1989). However, this extraordinaryactivity in vivo contrasts with its potency in binding assays,where M6G labels the traditional µ receptors slightly less potentlythan does morphine (Paul et al., 1989). Similar results are seenin Chinese hamster ovary cells stably expressing the µ-opioidreceptor clone MOR-1 (G. Brown and G. W. Pasternak, unpublishedobservations). This discrepancy between functional activity andbinding affinity cannot be explained by differences in efficacybetween the two drugs. In human neuroblastoma cell lines expressingµ receptors, both morphine and M6G inhibit cyclase, with potenciescorresponding to results from the binding assays (G. Brown andG.W. Pasternak, unpublished observations). In these studies thetwo agents had similar maximal effects, suggesting similar efficacies.Understanding the receptor mechanisms underlying the actions ofthese two analgesics would be a major advance in the design anduse of opioid analgesics.

The recent cloning of the $delta$ -opioid receptor (Evans et al., 1992; Kieffer et al., 1992) was soon followed by clones encodingµ (MOR-1) (Chen et al., 1993; Fukuda et al., 1993; Thompson etal., 1993; Reisine and Bell, 1993; Wang et al., 1993, 1994b; Uhlet al., 1994; Zastawny et al., 1994; Kozak et al., 1994; Min etal., 1994), $kappa$ ₁ (KOR-1) (Yasuda et al., 1993; Uhl et al., 1994;Zhu et al., 1995; Yakovlev et al., 1995; Knapp et al., 1995) and $kappa$ ₃-related (KOR-3 or ORL-1) (Pan et al., 1994, 1995; Uhl et al.,1994; Chen et al., 1994; Keith et al., 1994; Wick et al., 1994;Wang et al., 1994a; Mollereau et al., 1994; Bunzow et al., 1994;Fukuda et al., 1994; Lachowicz et al., 1995) opioid receptors.Antisense strategies (Wahlestedt, 1994) have proven invaluablein correlating these clones with in vivo opioid receptor pharmacology(Pasternak and Standifer, 1995). Antisense oligodeoxynucleotidesagainst DOR-1, a $delta$ -opioid receptor, selectively block [³H]DPDPE binding in neuroblastoma cells and spinal $delta$ analgesiainduced by either DPDPE ( $delta$ ₁) or deltorphin ( $delta$ ₂) (Standifer etal., 1994). These effects correlate well with the down-regulationof mRNA and $delta$ receptor protein levels (Standifer et al., 1995).These initial studies examining DOR-1 have been confirmed andextended by others, and the approach has been applied to the KOR-1( $kappa$ ₁) and MOR-1 (µ) clones (Chien et al., 1994; Pan et al., 1994;Tseng et al., 1994; Adams et al., 1994; Bilsky et al., 1994; Laiet al., 1994a,b; Rossi et al., 1995a; Chen et al., 1995).

The ability to coordinate the molecular biology of opioid receptors with their pharmacological activity offers a powerfulapproach to exploring these systems. Antisense approaches havebeen successfully used against different portions of the mRNAencoding opioid receptors (Standifer et al., 1994), which permitsan assessment of the presence of individual exons within the potentialreceptor subtypes mediating selected responses. Detailed antisensemapping of all four exons of MOR-1 in mice reveal that morphineanalgesia is blocked by oligodeoxynucleotides targeting eitherexon 1 or exon 4 of the µ-opioid receptor, but not those directedagainst exons 2 or 3 (Rossi et al., 1995a; Pasternak and Standifer,1995). In contrast, the sensitivity of M6G analgesia shows a verydifferent pattern (Rossi et al., 1995a,b; Pasternak and Standifer,1995). The antisense probes against exons 2 and 3 of MOR-1, whichwere inactive against morphine, blocked M6G analgesia, whereasthose targeting exons 1 and 4 were ineffective. Differences betweenmorphine and M6G analgesia were also observed using probes targetingdistinct G_i $alpha$ subunits (Rossi et al., 1995b). Down-regulation ofG_i $alpha$ 2 lowered morphine but not M6G analgesia, whereas the lossof G_i $alpha$ 1 blocked M6G analgesia but not that seen with morphine.The present study analyzes the extent, specificity and time courseby which antisense oligodeoxynucleotides based upon MOR-1 canmodulate opioid analgesia in selected brain regions of rats.

	Materials and Methods

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Adult male Sprague-Dawley rats (250-400 g; Charles River Laboratories, Raleigh, VA) were housed individually and maintainedon a 12-hr light/12-hr dark cycle, with food and water availablead libitum. All phosphodiester oligodeoxynucleotides were synthesizedby Midland Certified Reagent Co. (Midland, TX). Antisense oligodeoxynucleotides(table 1) were directed against four regions of the MOR-1 clone(exons 1, 2, 3 and 4). The 19- to 22-base oligodeoxynucleotideswere dissolved in 0.9% normal saline. A mismatch antisense oligodeoxynucleotidein which the sequence of four bases from the antisense A sequencehas been switched, without altering the remaining sequence, wasused as a control. All sequences are specific to the MOR-1 cloneand are not present in the other opioid receptor cDNAs. Morphinewas a gift from the Research Technology Branch of the NationalInstitute on Drug Abuse.

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TABLE 1
Oligodeoxynucleotide sequences

Rats were anesthetized with chlorpromazine (3 mg/kg i.p.) and ketamine HC1 (100 mg/kg i.m.) and cannulated either in the lateralventricle alone or in the lateral ventricle and one of two sites,the PAG or the LC. For the ventricular cannulation, a stainlesssteel guide cannula (22 gauge; Plastics One, Roanoke, VA) wasplaced stereotaxically (Kopf Instruments) 0.2 mm above the leftlateral ventricle, by using the following coordinates: incisorbar (+5 mm), 0.5 mm anterior to the bregma suture, 1.3 mm lateralto the saggital suture and 3.6 mm from the top of the skull. Coordinatesfor the PAG were as previously described (Rossi et al., 1993,1994b). With the incisor bar at $-$ 5 mm, the coordinates for theLC were 1.5 mm posterior to the lambda suture, 2.0 mm lateralto the saggital suture, 6.9 mm from the top of the skull and angledtoward the saggital plane at 8.2 degrees. Cannulae were securedto the skull with three anchor screws and dental acrylic and keptpatent with dummy cannulae. All animals were allowed 1 week torecover from cannula surgery and clearing of the anesthetic beforethe initiation of behavioral testing.

All rats received a test dose of morphine (7.5 µg i.c.v. or 2.5 µg into either the PAG or LC) and assessed in the tail-flickassay to ensure proper cannula placement. Rats were given at least1 week after this test dose to recover. Groups of rats receivedvehicle or the chosen antisense oligodeoxynucleotide (i.c.v.,10 µg in 2-5 µl; PAG and LC, 10 µg in 1 µl) on days 1, 3 and 5,and analgesia was tested with the stated dose of morphine or M6Gon day 6. Analgesia was assessed in a graded manner in the tail-flickassay (D'Amour and Smith, 1941) using the radiant heat assay (IITC,Woodland Hills, CA). Base-line latencies ranged from 1.8 to 3.2sec. A maximal cut-off latency of 12 sec was used to minimizetissue damage. All animals displayed reproducible latencies inbase-line and vehicle testing. The evaluation of the antinociceptiveresponse of the animals was made by an observer blind to the experimentalgroups. Cannula placement was further evaluated histologicallyin all rats not used for biochemical studies, as previously reported(Rossi et al., 1993, 1994b).

Analgesia was assessed using both peak effects and areas under the time-action curve. Peak effects were determined at 30 min.Areas under the curve were calculated as previously described(Rossi et al., 1994b) and the area corresponding to base-linevalues was subtracted, leaving only the area due to the drug.Statistical significance (P < .05) was assessed with Student'st test or analysis of variance followed by Tukey's protected ttest.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Efficacy and selectivity of an antisense oligodeoxynucleotide to MOR-1 administered into the PAG. Prior studies from our laboratory have established the ability of an antisense oligodeoxynucleotide targeting the 5 $'$ -untranslatedregion of the MOR-1 clone to block morphine analgesia (Rossi etal., 1994a). [D-Ala²,Glu⁴]Deltorphin, a highly selective $delta$ receptor ligand, also producesanalgesia when administered into the PAG (Rossi et al., 1994b).To explore the selectivity of the antisense treatment, we microinjectedthe same MOR-1 antisense oligodeoxynucleotide (antisense A, 10µg) (table 1) into the PAG on days 1, 3 and 5 and examined bothmorphine and [D-Ala²,Glu⁴]deltorphin analgesia on day 6 (fig. 1). As previously observed,the antisense treatment virtually eliminated the analgesic actionsof morphine administered into the PAG (P < .001). In contrast,the analgesic activity of [D-Ala²,Glu⁴]deltorphin in these same animals was virtually identical to thatin untreated animals (Rossi et al., 1994b). The mismatch antisenseoligodeoxynucleotide was inactive. Thus, the actions of antisenseA are selective for µ analgesia.

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Fig. 1. Effect of MOR-1 antisense oligodeoxynucleotide treatment on morphine or deltorphin in the PAG. Groups of rats received salineor antisense A (10 µg) into the PAG on days 1, 3 and 5 and weretested with morphine (2.5 µg, n = 4) or deltorphin, a $delta$ ₂ agonist(20 µg, n = 7), in the PAG on day 6. Morphine analgesia in thePAG was significantly reduced by antisense A (P < .001), but deltorphinanalgesia was not. A mismatch antisense oligodeoxynucleotide wasinactive (data not shown). Statistically significant conditionsare shown (*P < .01, **P < .001).

Efficacy of i.c.v. antisense A in morphine analgesia. We next assessed the actions of antisense oligodeoxynucleotides administered directly into the lateral ventricle. Using thesame treatment paradigm, antisense A markedly diminished the analgesicactivity of i.c.v. morphine, assessed as either peak effects orareas under the curve (P < .001) (fig. 2). The mismatch controlfailed to reduce the analgesic actions of morphine. The loss inmorphine sensitivity after treatment with antisense A graduallyreturned to control levels over several days (fig. 3). The actionsof the i.c.v. antisense A were dose-dependent (fig. 3). The lowestdose, 2.5 µg, had little effect on the analgesic actions of morphine,whereas the highest dose, 25 µg, virtually eliminated the analgesicactions of morphine, lowering the tail-flick latencies to base-linelevels. Unlike the 10 µg dose, the 25 µg group failed to showany signs of analgesic recovery over the time period tested.

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Fig. 2. Effect of i.c.v. MOR-1 antisense oligodeoxynucleotide treatment on morphine analgesia. Groups of rats were administered saline,antisense A (10 µg) or the mismatch sequence i.c.v. on days 1,3 and 5 and were challenged with morphine (7.5 µg) on day 6. Resultsare presented as mean ± S.E.M. of the tail-flick latencies (A)or the area under the curve (B). The antisense treatment (n =6) significantly reduced morphine analgesia (P < .001), shownby either peak effects or areas under the time-action curve (sec·min),whereas the mismatch group (n = 6) showed no significant differencefrom the saline controls (n = 7). Statistically significant conditionsare shown (*P < .001).

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Fig. 3. Duration and dose-dependence of antisense A treatments against morphine analgesia. Groups of rats were given either salineor antisense A at three different doses (2.5 µg i.c.v., n = 3;10 µg i.c.v., n = 6; 25 µg i.c.v., n = 6) on days 1, 3 and 5 andwere challenged with morphine (7.5 µg i.c.v.) on day 6 and againon days 8, 10 and 12 to determine analgesic recovery. The lowestantisense oligodeoxynucleotide dose, 2.5 µg, produced no effect.Rats treated with 10 µg showed a significant decrease in morphineantinociception (P < .001) on days 6 and 8, after which theirresponses returned to normal. The 25 µg antisense oligodeoxynucleotidedose produced a significant decrease (P < .001) in morphine analgesiaat all times tested. Statistically significant conditions areshown (*P < .001).

We next examined the ability of i.c.v. antisense A to modulate morphine analgesia in selected brain regions. After treatingrats with i.c.v. antisense oligodeoxynucleotide, we assessed theanalgesic actions of morphine microinjected directly into eitherthe PAG or the LC (fig. 4). Antisense A virtually eliminated theanalgesic actions of morphine in the PAG. Indeed, the inhibitionin the PAG exceeded that seen after i.c.v. administration of morphine.The i.c.v. antisense oligodeoxynucleotide also significantly decreasedmorphine analgesia in the LC, but not as effectively as in thePAG. In both regions, analgesic sensitivity recovered over 5 to7 additional days.

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Fig. 4. Effect of i.c.v. antisense A treatment on morphine analgesia in the PAG and LC. Groups of rats were given antisense A (10µg i.c.v.) on days 1, 3 and 5 and challenged with morphine onday 6, given i.c.v. (7.5 µg, n = 6) (A) or directly into eitherthe PAG (2.5 µg, n = 4) (B) or the LC (5 µg, n = 7) (C). Statisticallysignificant conditions are shown (*P < .05, **P < .01, ***P <.001).

Antisense mapping of MOR-1. Previous studies in mice from our laboratory using antisense oligodeoxynucleotides targeting the various exons of MOR-1 displayeddiffering activities against morphine and M6G analgesia (Rossiet al., 1995a,b; Pasternak and Standifer, 1995). We thereforeexamined the actions of i.c.v. antisense oligodeoxynucleotidesdirected against all four exons of rat MOR-1 against morphineand M6G analgesia (fig. 5). Both antisense A, targeting the untranslatedregions of exon 1, and antisense D, directed against the codingregion of exon 4, potently blocked i.c.v. morphine analgesia,whereas the oligodeoxynucleotides directed against exons 2 (antisenseB) and 3 (antisense C) were inactive. As in our earlier studiesin mice (Rossi et al., 1995a) and in the PAG of rats (Rossi etal., 1995b), antisense A was inactive against M6G analgesia. Conversely,the oligodeoxynucleotide antisense probes against exons 2 and3, which were inactive against morphine analgesia, potently blockedthe analgesic actions of M6G. Unlike our studies in mice, antisenseD (exon 4) decreased both morphine and M6G analgesia in this ratmodel.

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Fig. 5. Antisense mapping of MOR-1 for morphine and M6G analgesia. Groups of rats received the indicated antisense oligodeoxynucleotides(antisense A, n = 6; antisense B, n = 4; antisense C, n = 4; antisenseD, n = 4) on days 1, 3 and 5 and were tested for morphine (7.5µg i.c.v.) (A) or M6G (0.7 µg i.c.v.) (B) analgesia on day 6.Tail-flick latencies were calculated as the maximal percent effect,where maximal percent effect = (experimental score $-$ base-linescore)/(maximal score $-$ base-line score), and data are shown aspercentage of control values. There was significant inhibitionof tail-flick latencies and area under the curve (AUC) valuesfor morphine analgesia by antisense A (P < .001) and antisenseD (P < .01). M6G analgesia was lowered by antisense B (P < .001)and antisense C (P < .001) and to a lesser degree by antisenseD (P < .01, area under the curve only). *P < .01; **P < .001.

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

The current study continues our studies of the MOR-1 clone in rats. First, we confirmed the selectivity of the antisense treatment.The profound inhibition of morphine analgesia contrasts sharplywith the lack of effect on the analgesic actions of the $delta$ drug[D-Ala²,Glu⁴]deltorphin. We next examined the effectiveness of i.c.v. administrationof the oligodeoxynucleotides. Prior studies in mice have shownthe utility of this approach and our current studies, along withthose of other groups, confirm its applicability to rats in anumber of regions. As in the initial study examining DOR-1 (Standiferet al., 1994), the activity of the antisense A (10 µg) graduallyresolves over a number of days. This time course is similar toestimates of the turnover of the receptor (Pasternak et al., 1980a,b).The lack of return of analgesic sensitivity with the highest dosetested, 25 µg, is difficult to understand. Although the very highdoses of oligodeoxynucleotide used may simply prolong the actions,the possibility of a toxic or nonspecific action cannot be excluded.High doses have been associated with dose-dependent toxicity withinthe central nervous system, particularly with phosphorothioates(Chiasson et al., 1994; Meeker et al., 1995). By using the minimaldoses of antisense oligodeoxynucleotides needed to see an effect,the possibility of nonspecific actions can be minimized.

In an effort to determine the extent of diffusion of the antisense treatment, we treated animals i.c.v. with an oligodeoxynucleotideand looked for morphine analgesia after direct injections intothe PAG or LC. The treatment dramatically lowered the tail-flicklatencies in the PAG group to base-line levels. Indeed, the inhibitionexceeded that seen with i.c.v. morphine. The effects on the LCwere significant but more modest, perhaps reflecting the greaterdistance of this structure from the ventricle. Many of the structuresmediating morphine analgesia are periventricular, like the PAG,and appear to be readily influenced by the i.c.v. antisense approach.However, deeper structures may not be as susceptible to the antisensetreatments administered i.c.v. This must be considered when designingstudies examining other pharmacological actions.

In the initial opioid receptor antisense study, we demonstrated that probes targeting all three exons of DOR-1 lowered [³H]DPDPE binding in NG108-15 cells to similar degrees (Standiferet al., 1994). The ability to down-regulate the receptors by targetingany exon suggested that we could map the importance of each exonin receptor function. Our first studies suggested that the KOR-3clone and the $kappa$ ₃ receptor shared exons 2 and 3 but not exon 1(Uhl et al., 1994; Pasternak and Standifer, 1995; Pan et al.,1994, 1995). Our most extensive investigations focused on themouse MOR-1 clone (Rossi et al., 1995a,b; Pasternak and Standifer,1995). These antisense mapping studies revealed the importanceof exons 1 and 4, but not exons 2 or 3, in supraspinal morphineanalgesia. When we explored M6G analgesia, we observed very differentresults. In contrast to morphine analgesia, M6G analgesia wassensitive to probes targeting exons 2 and 3 and not those againstexons 1 and 4. These observations led us to suggest the presenceof distinct morphine and M6G receptors in mice, which may representsplice variants of the MOR-1 gene (Rossi et al., 1995a,b; Pasternakand Standifer, 1995). Our current results in rats are similarto those observed in mice. The probe against exon 1 potently blockedmorphine analgesia without altering the analgesic actions of M6G.Conversely, exon 2 and 3 probes blocked M6G and not morphine analgesia.The similar effects of the exon 4 probe against the two agentsdiffers from our prior observations in mice and requires furtherstudy, particularly with the identification of splice variantsof exon 4 (Bare et al., 1994; Zimprich et al., 1994).

In conclusion, antisense approaches have proven valuable in the elucidation of the molecular pharmacology of opioid actions.In addition to confirming the importance of the various opioidreceptor clones in mediating opioid pharmacology, antisense strategiessuggest the potential importance of splice variants in explainingopioid receptor subtypes. Their selectivity and general utilityprovide enormous potential in correlating molecular biology andbehavior within the central nervous system.

	Acknowledgments

We thank Dr. J. Posner for his support and Andre Ragnauth and Wei Zen Yu for their assistance in this study.

	Footnotes

Accepted for publication December 13, 1996.

Received for publication April 9, 1996.

¹ This work was supported, in part, by research grants from the National Institute on Drug Abuse to G.W.P. (DA07242) and toR.J.B. (DA04191) and a core grant from the National Cancer Instituteto Memorial Sloan-Kettering Cancer Center (CA08748). G.C.R. wassupported by a training grant from the National Institute on DrugAbuse (DA07274), Y.-X.P. by a fellowship from the Aaron DiamondFoundation and G.W.P. by a Research Scientist Award from the NationalInstitute on Drug Abuse (DA00220).

Send reprint requests to: Dr. Gavril W. Pasternak, Department of Neurology, Memorial Sloan-Kettering Cancer Center, 1275 York Ave., New York, NY 10021.

	Abbreviations

DPDPE, [D-Pen²,D-Pen⁵]-enkephalin; LC, locus coeruleus; M6G, morphine-6 $beta$ -glucuronide; PAG, periaqueductal gray; i.c.v., intracerebroventricular.

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Antisense Mapping of MOR-1 in Rats: Distinguishing between Morphine and Morphine-6 $beta$ -glucuronide Antinociception¹