Antisense Mapping of the MOR-1 Opioid Receptor Clone: Modulation of Hyperphagia Induced by DAMGO

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Vol. 282, Issue 3, 1402-1407, 1997

Antisense Mapping of the MOR-1 Opioid Receptor Clone: Modulation of Hyperphagia Induced by DAMGO¹

Liza Leventhal, Lesley B. Stevens, Grace C. Rossi, Gavril W. Pasternak and Richard J. Bodnar

Neuropsychology Doctoral Subprogram and Department of Psychology, Queens College, City University of New York (L.L., L.B.S., R.J.B.) and Department of NeuroOncology, Memorial Sloan-Kettering Cancer Center (G.C.R., G.W.P.), New York City, New York

	Abstract

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The mu opioid receptor mediates ingestive behavior: mu-selective agonists stimulate food intake and antagonists reduce intakein many ingestive situations. Antisense oligodeoxynucleotidesdirected against each of the four exons of the MOR-1 clone wereequally effective in reducing spontaneous food intake and bodyweight in rats. However, antisense probes directed against onlyexon 1 or 4 of the MOR-1 clone reduced mu-mediated analgesia.The present study examined whether central administration of antisenseprobes directed against each of the four exons of the MOR-1 cloneor a missense control altered hyperphagia elicited by the mu agonistDAMGO across a range of doses. Antisense probes directed againstonly exon 1 or 4 blocked hyperphagia at agonist doses of 0.5 and1.0 µg; this pattern was identical to that observed for mu-mediatedanalgesia. A missense control failed to exert significant effects,which suggests specificity of antisense actions. The effectiveantisense probes failed to reduce hyperphagia at a higher (5 µg)agonist dose, a result consistent with limitations in down-regulationof receptor proteins by antisense. The mu antagonist $beta$ -funaltrexamineproduced a similar pattern of effects on mu-mediated hyperphagia.The selective actions of antisense probes directed against differentexons of the MOR-1 clone in reducing hyperphagia induced by DAMGOsuggest that multiple splice variants of the MOR-1 clone existand raise the possibility of further opioid receptor subclassifications.

	Introduction

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A role for the endogenous opioid system in the central regulation of many types of ingestive behaviors has been characterizedby using selective opioid agonists and antagonists (see reviews:Bodnar, 1996; Gosnell and Levine, 1996; Morley et al., 1983).Agonists for all three major classes of opioid receptors (mu,kappa and delta) typically stimulate spontaneous food intake,whereas general opioid antagonists decrease spontaneous intakeand body weight. Further, specific opioid receptor subtype antagonistsagainst mu, kappa and delta receptors differentially reduce foodintake as a function of the ingestive situation.

The initial cloning of DOR-1 (Evans et al., 1992; Kieffer et al., 1992) quickly led to the identification of other structurallyrelated G protein-mediated receptors (MOR-1, KOR-1, KOR-3, ORL-1;see review: Uhl et al., 1994) and has opened new areas of research,including investigation of the relationship of the cloned receptorsto opioid actions in vivo. The cloning of the specific opioidreceptors made possible the identification of short (15-25 bases)AS ODN sequences that are complementary to specific regions ofmRNA that can down-regulate receptor proteins. The efficacy andspecificity of AS ODNs directed against opioid receptor cloneshave been confirmed functionally and biochemically (see review:Pasternak and Standifer, 1995), particularly in analgesic assays.AS ODNs directed against the 5 $'$ -untranslated regions of DOR-1,MOR-1 or KOR-1 selectively and respectively reduced delta-mediated(Bilsky et al., 1994; Lai et al., 1994; Standifer et al., 1994;Tseng et al., 1994), mu-mediated (Chen et al., 1995; Rossi etal., 1994, 1995a, 1995b) and kappa₁-mediated (Adams et al., 1994;Chien et al., 1994) forms of analgesia.

Although MOR-1 encodes a mu opioid receptor, its relationship to the pharmacologically defined mu receptor subtypes has beenunclear. Using the AS ODN technique to map individual exons withinMOR-1, we were able to determine which individual exons modulatemu-mediated analgesia (Rossi et al., 1995a, 1995b, 1996, 1997).AS ODN probes directed against exons 1 and 4 of MOR-1 blockedmorphine and mu agonist-mediated analgesia, whereas probes targetedagainst exon 2 or 3 of MOR-1 were ineffective. In contrast, ASODN probes directed against exon 2 or 3 of MOR-1 blocked analgesiainduced by the morphine metabolite M6G, whereas AS ODNs directedagainst exon 1 or 4 of MOR-1 were ineffective. Analgesic responsesinduced by heroin, fentanyl and etonitazine are reduced by ASODNs directed against either exon 1 or 2 of MOR-1 (Rossi et al.,1996). Thus these studies raised the possibility that variousmu receptor subtypes could result from alternative splice variantsof MOR-1 (Pasternak and Standifer, 1995).

The AS ODN strategy has recently been applied to opioid modulation of ingestive behavior (Leventhal et al., 1996). Body weightand food intake were significantly reduced by AS ODNs directedagainst each of the four exons of MOR-1. In contrast, a MS ODNcontrol was ineffective. The sensitivity of spontaneous intakeand body weight to all four exons suggests that the receptor responsiblefor this action is encoded by MOR-1. mu-selective opioid agonistssuch as morphine and DAMGO stimulate food intake after systemicand central administration (Bakshi and Kelley, 1993; Gosnell etal., 1986a, 1986b; Sanger and McCarthy, 1980), and this effectis blocked by mu-selective opioid antagonists (Levine et al.,1991). The first goal of the present study was to determine whetherAS ODNs directed against MOR-1 would block hyperphagia elicitedby the mu agonist DAMGO. If so, the second goal was to determinewhether the profile of MOR-1 AS ODN effects mirrored those effectsobserved for mu agonist analgesia (only exons 1 and 4 AS ODNseffective) or those effects observed for spontaneous food intakeand body weight (all four exons effective). Thus the present studyexamined whether i.c.v. administration of AS ODNs directed againstexon 1, 2, 3 or 4 of MOR-1 or administration of a MS ODN alteredhyperphagia elicited by the selective mu agonist DAMGO. AlthoughAS ODNs produce quite dramatic behavioral and physiological effects,they are accompanied by rather modest (30%-40%) reductions inreceptor protein levels (see review: Pasternak and Standifer,1995). Therefore, it is possible that the presence or absenceof AS ODN effects on agonist-induced hyperphagia depends on thedose of the agonist employed as well as on the efficacy of theAS ODN. Thus our third goal was to determine whether effectiveAS ODNs would block DAMGO-induced hyperphagia across a range ofeffective DAMGO doses. Finally, the present study confirmed thatDAMGO-induced hyperphagia was a mu-mediated effect by blockingthis response with the mu antagonist $beta$ FNA (Levine et al., 1991).

	Materials and Methods

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Subjects. Male albino Sprague-Dawley rats (90-120 days of age, Charles River Laboratories, Kingston, NY) were housed individually inwire mesh cages and maintained on a 12-h light: 12-h dark cyclewith water and rat chow available ad libitum. Each rat was pretreatedwith chlorpromazine (3 mg/kg i.p.) and anesthetized with KetamineHCl (120 mg/kg i.m.). A stainless steel guide cannula (22-gauge,Plastics One, Roanoke, VA) was implanted stereotaxically (KopfInstruments, Tujunga, CA) into the left lateral ventricle usingthe following coordinates: incisor bar (+5 mm), 0.5 mm anteriorto the bregma suture, 1.3 mm lateral to the sagittal suture and3.6 mm from the top of the skull. Cannulas were secured to theskull by three anchor screws with dental acrylic. All animalswere allowed at least 2 weeks to recover from stereotaxic surgerybefore behavioral testing began. Rats weighed between 275 and300 g before surgery and weighed 400 to 550 g after completionof testing. After completion of behavioral testing, all animalswere killed with an overdose of anesthetic, and cannula placementswere verified visually.

AS ODNs and opioid agonists and antagonists. All phosphodiester oligodeoxynucleotides (Midland Certified Reagent Company, Midland, TX) were dissolved (5 µg/µl) in 0.9%normal saline and purified in our (G.W.P., G.C.R.) laboratory.AS ODNs (19-22 bases long) were directed against four regionsof MOR-1 (table 1). An AS ODN control consisted of a MS ODN inwhich four bases from the AS1 sequence were switched without alteringthe remaining sequence. All sequences are specific to MOR-1 andare not present in other opioid receptor cDNAs. Three infusionswere administered i.c.v. at 48-h intervals over 15 s through astainless steel internal cannula (28-gauge, Plastics One, Roanoke,VA). DAMGO (0.5-5 µg, Peninsula Laboratories, Belmont, CA) and $beta$ FNA (0.2-20 µg, Research Biochemicals Intl., Natick, MA) weredissolved in 0.9% normal saline and administered i.c.v. in 5-µlvolumes over 30 s through an internal cannula. $beta$ FNA was administered24 h before agonist administration to allow for full developmentof irreversible mu antagonist effects (Portoghese et al., 1980).

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TABLE 1
Sequence of AS ODNs and the MS ODN

Protocols. All rats were tested over 4 to 10 days at 3 to 9 h into the light cycle to ensure the stability of base-line spontaneous foodintake. Preweighed pellets were placed directly on the floor ofthe wire mesh cages to optimize accessibility, because this factorcan interfere with DAMGO-induced feeding (Badiani et al., 1995).Cumulative intakes were assessed 2 and 4 h before and after eachcondition, adjusting for spillage that was collected on paperplaced under the cage. After intake stabilization, all rats receiveda VEH condition (PRE-VEH, 5 µl of 0.9% normal saline i.c.v.).Because DAMGO is known to produce sedative and hypoactive effects,we treated each animal twice with DAMGO (1 µg i.c.v.) withoutmeasuring intake. In the assessment of DAMGO-induced hyperphagia,rats received one of three (0.5, 1 or 5 µg) doses (PRE-DAMGO),and intake was assessed after 2 and 4 h. Intake elicited by eachDAMGO dose was matched across the subgroups of rats receivingAS ODNs and the MS ODN control. During the test phase of the experiment,rats received one of four AS ODN sequences (AS1, AS2, AS3 or AS4:10 µg, 2 µl, i.c.v.) or a mismatch sequence (MS1) (table 1) ondays 1, 3 and 5 as previously described (Leventhal et al., 1996).This AS ODN dose was most efficacious in analgesic dose-responseassays (Rossi et al., 1997). This time course of treatment bothdown-regulates the synthesis of new receptors and permits theturnover of existing receptors (see review: Pasternak and Standifer,1995). Twenty-four hours after the last AS ODN or MS ODN treatment(day 6), rats were retested with their respective DAMGO dose (0.5-5µg), and food intake was assessed after 2 and 4 h.

In order to confirm the mu-selective actions of DAMGO-induced hyperphagia, separate but identically screened groups of ratsscreened for DAMGO-induced hyperphagia received the mu-selectiveantagonist $beta$ FNA (0.2-20 µg: Arjune et al., 1990

; Levine et al.,1991

; Ukai and Holtzman, 1988

) 24 h before DAMGO treatment. Cumulativeintakes were again assessed after 2 and 4 h.

Statistics. Separate split-plot analyses of variance were performed on cumulative food intake data at 2 and 4 h for different doses ofDAMGO (0.5, 1 and 5 µg) as a function of either AS ODN treatment(AS1, AS2, AS3, AS4 or MS1) or $beta$ FNA treatment. Significant differencesin intake measures were determined for each subgroup relativeto both corresponding VEH control values and corresponding DAMGOdoses before AS ODN or antagonist treatment (Tukey comparisons,P < .05).

	Results

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DAMGO-induced hyperphagia. Significant dose-dependent differences in DAMGO-induced hyperphagia were observed after 2 [F(3,86) = 217.89, P < .0001] and4 [F = 291.43, P < .0001] h. DAMGO significantly increased foodintake relative to VEH after 4 h (fig. 1). These effects weredose-dependent in that the effect of the 5-µg dose was significantlygreater than those of the 0.5- and 1-µg doses, and the effectof the 1-µg dose was significantly greater than that of the 0.5-µgdose (fig. 1). The patterns of effects after 2 h in this and theother conditions were identical.

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Fig. 1. Alterations (mean ± S.E.M.) in food intake after i.c.v. administration of 0 (n = 87), 0.5 (n = 24), 1.0 (n = 39) or 5.0 (n= 24) µg of DAMGO. Significant differences are denoted relativeto vehicle ( $phi$ ), 0.5 µg (*) or 1.0 µg (#) DAMGO doses (Tukey comparisons,P < .01).

MOR-1 AS ODNs and DAMGO (0.5 µg)-induced hyperphagia. Significant differences in food intake were observed among conditions after 2 [F(5,23) = 67.92, P < .0001] and 4[F = 69.87,p < .0001] h. The 0.5-µg dose of DAMGO significantly increasedintake after 2 and 4 h, and this effect was significantly reducedby pretreatment with either AS1 (76%) or AS4 (70%) (fig. 2A).In contrast, neither AS2 (17% increase) nor AS3 (10% increase)significantly altered DAMGO hyperphagia (fig. 2A).

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Fig. 2. Alterations (mean ± S.E.M.) in DAMGO-induced hyperphagia at doses of 0.5 (panel A, n = 24) or 1.0 (panel B, n = 38) µg afteri.c.v. administration of AS ODNs directed against exons 1 (AS1:panel A, n = 7; B, n = 8), 2 (AS2: A, n = 6; B; n = 8), 3 (AS3:A, n = 5; B, n = 8) or 4 (AS4: A, n = 6; B, n = 8) of MOR-1 ora missense control (MS1: B, n = 6). Panel C depicts alterationsin food intake as a function of the DAMGO dose (0.5-5.0 µg i.c.v.)after the administration of effective (AS1 and AS4) AS ODNs ofMOR-1. Significant differences are denoted relative to eitherVEH-VEH ( $phi$ ) or VEH-DAMGO (*) values (Tukey comparisons, P < .01).

MOR-1 AS ODNs and DAMGO (1.0 µg)-induced hyperphagia. Significant differences in food intake were observed among conditions after 2 [F(6,37) = 66.42, P < .0001] and 4 [F = 73.38,P < .0001] h. The 1.0-µg dose of DAMGO significantly increasedintake after 2 and 4 h, and this effect was significantly reducedby pretreatment with either AS1 (100%) or AS4 (53%) (fig. 2B).In contrast, neither AS2 (10% increase) nor AS3 (7% increase)significantly altered DAMGO hyperphagia (fig. 2B). Further, MS1failed to alter DAMGO-induced hyperphagia significantly at thisdose (fig. 2B).

MOR-1 AS ODNs and DAMGO (5.0 µg)-induced hyperphagia. Significant differences in food intake were observed among conditions after 2 [F(4,17) = 15.93, P < .0001] and 4 [F = 21.74,P < .0001] h. The 5.0-µg dose of DAMGO significantly increasedintake after 2 and 4 h. In contrast to the differential effectivenessof AS ODNs on DAMGO-induced hyperphagia at lower doses, neitherAS1 nor AS4 significantly altered hyperphagia induced by a 5-µgdose of DAMGO (fig. 2C). Again, MS1 also failed to affect DAMGO-inducedhyperphagia at this dose (data not shown).

$beta$ FNA and DAMGO-induced hyperphagia. Significant differences were observed for DAMGO-induced hyperphagia among conditions for doses of 0.5 [F(2,23) = 91.24, P< .0001], 1.0 [F(4,37) = 112.28, P < .0001] and 5.0 [F(2,17) =31.53, P < .0001] µg. A fixed 20-µg dose of $beta$ FNA significantlyand dose-dependently reduced DAMGO-induced hyperphagia at dosesof 0.5 (88%), 1.0 (100%) and 5.0 (59%) µg (fig. 3A). Further,hyperphagia induced by a fixed 1.0-µg dose of DAMGO was significantlyreduced by a dose range (0.2-20 µg) of $beta$ FNA (80%-100%; fig. 3B).

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Fig. 3. A) Alterations (mean ± S.E.M.) in DAMGO-induced hyperphagia after pretreatment with a fixed (20-µg) dose of the mu opioidantagonist $beta$ FNA as a function of the DAMGO dose. B) Alterations(mean ± S.E.M.) in DAMGO (1.0 µg)-induced hyperphagia after pretreatmentwith different doses (0.2-20 µg) of $beta$ FNA. Significant differencesinduced by $beta$ FNA (n = 5 or 6/dose) are denoted relative to eitherVEH-VEH ( $phi$ ) or VEH-DAMGO (*) values (Tukey comparisons, P < .01).

	Discussion

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The present findings confirmed the major goals of the study. First, specific AS ODNs directed against MOR-1 blocked hyperphagiaelicited by the mu agonist DAMGO. In contrast, a MS ODN controlfailed to alter the magnitude of DAMGO-induced hyperphagia. Second,the observed effects of AS ODNs directed against MOR-1 were specificto the targeted regions of the clone in that AS ODNs directedagainst exon 1 or 4 significantly reduced DAMGO-induced hyperphagia.In contrast, AS ODNs directed against exon 2 or 3 of MOR-1 failedto exert significant effects. This pattern of AS ODN effects formu agonist-induced hyperphagia mirrored the pattern of AS ODNeffectiveness observed for mu agonist-induced analgesia (Rossiet al., 1995a, 1995b, 1996, 1997). The present pattern of resultsfor DAMGO-induced hyperphagia stands in marked contrast to reductionsin spontaneous food intake and body weight after the administrationof AS ODNs directed against each of the four exons of MOR-1 (Leventhalet al., 1996). Third, there are dose-dependent limitations tothe AS ODN approach, such that effective AS ODNs reduced hyperphagiaat DAMGO doses of 0.5 and 1 µg but not at a higher, 5-µg dose.Hence the presence or absence of AS ODN effects on agonist-inducedhyperphagia appears to depend on the dose of the agonist employedas well as on the efficacy of the AS ODN. This pattern can beexplained by the modest (40%) reductions in receptor protein levelsresulting from AS ODN administration (see review: Pasternak andStandifer, 1995). Finally, the ability of the mu-selective antagonist $beta$ FNA to reduce DAMGO-induced hyperphagia confirmed previous findings(Levine et al., 1991). However, the magnitude of mu antagonisteffects on dose-response relationships for DAMGO-induced hyperphagiaparalleled AS ODN effects such that the potency of a fixed (20µg) $beta$ FNA dose to reduce DAMGO-induced hyperphagia declined asa function of increased DAMGO doses.

Our previous study (Leventhal et al., 1996) failed to observe any significant AS ODN effects on hyperphagia elicited by 2-deoxy-D-glucoseor hyperdipsia elicited by angiotensin II, a surprising findinggiven the effectiveness of mu antagonists to block both responses(Arjune et al., 1990; Koch and Bodnar, 1994; Ruegg et al., 1994).This apparent discrepancy might be explained by the present findingsof differential AS ODN effectiveness as a function of the DAMGOdose. The 2-deoxy-D-glucose (500 mg/kg i.p.) and angiotensin II(20 ng i.c.v.) doses utilized in the previous (Leventhal et al.,1996) study were at the high end of their respective dose-responsecurves for hyperphagia and hyperdipsia. It will be important todetermine whether lower effective doses of the two physiologicalcompounds are sensitive to AS ODNs against MOR-1.

The activity of AS ODNs that target various regions of mRNA that encode opioid receptors suggests that alternative splicingof transcripts can be explored by mapping exons with AS ODN probes(see review: Pasternak and Standifer, 1995). This approach wasespecially fruitful in distinguishing the analgesic responsesof morphine and its metabolite M6G (Pasternak et al., 1987; Paulet al., 1989). Supraspinal and spinal mediation of morphine analgesiahave been defined pharmacologically by the respective actionsof mu₁ and mu₂ receptors (see review: Pasternak, 1993). M6G labelsthe traditional mu receptors in binding assays with an affinityslightly less than that of morphine. Yet when it is administeredcentrally in mice, its analgesic potency is 100-fold greater.The efficacy differences between the two drugs raised the possibilitythat M6G might act through a subtype of the mu receptor. Supraspinalmorphine analgesia was significantly and selectively reduced byAS ODNs directed against only exon 1 or 4 of the MOR-1 clone,whereas supraspinal M6G analgesia and heroin analgesia were potentlyand selectively reduced by AS ODNs directed against only exon2 or 3 (Rossi et al., 1995a, 1995b, 1996, 1997). Further, spinalmorphine analgesia is blocked only by AS ODNs directed againstexon 4. Thus the selectivity profiles of the AS ODN probes arenot consistent with a single receptor, which implies that thesesubtypes might represent isoforms of MOR-1 generated by alternativesplicing (Rossi et al., 1995a).

The reductions in DAMGO-induced hyperphagia by AS ODNs directed against only exon 1 or 4 parallel effects observed for muanalgesic actions, which suggests that a common splice variantof the MOR-1 clone may be mediating both analgesic and hyperphagicactions. It should be noted that inactivity of a particular ASODN might result from a variety of technical factors, includingunanticipated mRNA structures. This concern is alleviated by thefact that the inactive probes in the DAMGO-induced hyperphagiaparadigm are active in reducing both M6G analgesia (Rossi et al.,1995a, 1995b, 1997) and spontaneous food intake and body weight(Leventhal et al., 1996). Further, although the same mRNA receptorsubstrate mediates both responses, the substrate is probably locatedin different supraspinal loci. Thus mu-mediated analgesic responsesare most potently elicited from the periaqueductal gray, the rostroventromedialmedulla and the locus ceruleus (Bodnar et al., 1988, 1991; Fanget al., 1986; Smith et al., 1988). In contrast, mu-mediated hyperphagicresponses are most potently elicited from the hypothalamic paraventricularnucleus (Koch et al., 1995), the nucleus accumbens (Bakshi andKelley, 1993; Bodnar et al., 1995; Cador et al., 1986; Majeedet al., 1986) and the ventral tegmental area (Mucha and Iversen,1986; Noel and Wise, 1993, 1995). The differential actions ofmultiple MOR-1 splice variants may explain some of the differentmu-mediated ingestive effects obtained using selective opioidantagonists. Thus mu antagonism with $beta$ FNA significantly reducesfood intake under spontaneous, deprivation, glucoprivic and palatableconditions (see review: Bodnar, 1996). In contrast, mu₁ antagonismwith naloxonazine significantly reduces food intake only underspontaneous and deprivation conditions.

Two possible profiles of AS ODN effects on DAMGO-induced hyperphagia were hypothesized: the observed differential patterndescribed in the previous sections and consistent with mu agonist-inducedanalgesia, and equal effectiveness of AS ODNs directed againsteach exon of the MOR-1 clone as observed in spontaneous intakeand weight studies (Leventhal et al., 1996). That the former,but not the latter, hypothesis was confirmed strongly suggeststhat the mu mediation of mu agonist-induced hyperphagia and themu mediation of spontaneous intake and weight are different. Spontaneousfood intake is an outcome of multiple factors acting on organisms,and the experimental alteration of any of them may increase feeding.For instance, mu opioid agonists increase feeding by alteringthe palatability of certain constituents of food, including eitherthe macronutrient itself, such as fat (Marks-Kaufman, 1982; Marks-Kaufmanand Kanarek, 1980), or the preference for a preferred macronutrient(Doyle et al., 1993; Gosnell et al., 1990). It is conceivablethat DAMGO elicits feeding by acting on such specific mechanismsand that AS ODNs directed against exon 1 or 4 block this effect.In contrast, body weight and spontaneous intake may be influencedby additional factors mediated by all four exons of MOR-1. Sucha distinction could not be made in traditional opioid antagoniststudies. The mu antagonist $beta$ FNA both significantly reduced DAMGO-inducedhyperphagia (Levine et al., 1991) and significantly reduced spontaneousintake and weight under both acute (Arjune et al., 1990; Ukaiand Holtzman, 1988) and chronic (Cole et al., 1995) microinjectionconditions. Therefore, the AS ODN approach appears to be a moreprecise tool in dissecting differences in the functional rolesof specific receptors. The selective actions of AS ODNs directedagainst different exons of MOR-1 in reducing DAMGO-induced hyperphagiasupport the hypothesis that multiple splice variants of MOR-1exist and raise the possibility of further opioid receptor subclassifications.

	Footnotes

Accepted for publication May 29, 1997.

Received for publication March 11, 1997.

¹ This research was supported in part by NIDA grants DA05746 (L.L.), DA04194 (R.J.B.), DA07274 (G.W.P.), DA00220 (G.W.P.) andDA00310 (G.C.R.) and by a CUNY Project Ascend undergraduate grant(L.B.S.).

Send reprint requests to: Dr. R. J. Bodnar, Department of Psychology, Queens College, CUNY, 65-30 Kissena Blvd., Flushing, NY 11367.

	Abbreviations

AS ODN, antisense oligodeoxynucleotide; $beta$ FNA, $beta$ -funaltrexamine; KOR-1, kappa opioid receptor clone; KOR-3, kappa₃ opioid receptor clone; MS ODN, mismatch oligodeoxynucleotide; M6G, morphine-6 $beta$ -glucuronide; MOR-1, mu opioid receptor clone; ORL-1, orphanin opioid-like receptor clone; VEH, vehicle; DOR-1 = delta opioid receptor clone., .

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