Effect of Chronic Social Stress on delta -Opioid Receptor Function in the Rat

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Vol. 290, Issue 1, 196-206, July 1999

Effect of Chronic Social Stress on $delta$ -Opioid Receptor Function in the Rat¹

Larissa A. Pohorecky, Anna Skiandos, Xiaoyan Zhang², Kenner C. Rice² and Daniel Benjamin

Neuropharmacology Laboratory, Center of Alcohol Studies, Rutgers University, Piscataway, New Jersey (L.A.P., A.S., D.B.)

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

Previous studies have shown that stressors modify endogenous opioid systems. However, the consequences of social stress onthe function of endogenous opioid systems is not well documented.The present studies investigated the effect of rank and housingcondition on response to SNC-80, a $delta$ receptor agonist. Triad-housedrats were assessed for dominance status by their behavior andalteration in body weights. At 3 and 50 days, triad- and individuallyhoused rats were injected with SNC-80 (35 mg/kg i.p.) or saline,and evaluated using a test battery consisting of open field behaviors,rectal temperature, analgesia, and air-puff-induced ultrasonicvocalizations. After 50 days of housing, plasma corticosterone,adrenal catecholamines, and the density of cyclic[D-penicillamine²-D-penicillamine²]enkephalin-stimulated guanylyl 5'-[ $gamma$ [³⁵S]thio]-triphosphate binding in the prefrontal cortex, the amygdala,nucleus accumbens, thalamus, arcuate, and median eminence werealso determined. The first 24 h of triad housing resulted in lossof body weight in subdominant ( $beta$ s and $gamma$ s) but not dominant $alpha$ rats.SCN-80-induced hypothermia was smaller, and there was no depressionof headpoke and locomotor behavior in the periphery and the centerof the field of $alpha$ rats, in contrast to subdominant and singlyhoused rats. Rank status did not influence SNC-80's analgesiceffect or its inhibition of air-puff-induced ultrasonic vocalizations.Plasma corticosterone levels of $alpha$ s and $gamma$ s were lower comparedwith $beta$ s and singly housed rats. Agonist stimulation of $delta$ receptorguanylyl 5'-[ $gamma$ [³⁵S]thio]-triphosphate binding was lateralized in prefrontal cortexand amygdala, but not nucleus accumbens. Binding was highest inall brain areas of singly housed rats and lowest in the thalamusof $beta$ and of $gamma$ rats. Lateralized binding in amygdala, high locomotoractivity, and sensory sensitivity correlated positively with greatersensitivity to SNC-80-induced depression in these measures. Higherbinding in the right amygdala correlated with higher plasma corticosteronelevels. These findings indicate that dominant rats displayed stimulantrather than depressant responses to $delta$ -opioid activation. Thereforein rodents rank-related stress can alter responsiveness of theendogenous opioid system, and dominance can increase the excitatoryeffects of $delta$ agonists.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

The $delta$ -opioid receptor, which binds enkephalins with high affinity (Mansour et al., 1987), is coupled to Gi proteins and inhibitsadenylate cyclase (Wood et al., 1981; Mansour et al., 1995). Functionally, $delta$ receptors are important mediators of analgesia, locomotor activation,appetitive, and drug reward behaviors (Calenco-Choukroun et al.,1991; Devine and Wise, 1994; Froehlich et al., 1991; Jiang etal., 1990). In contrast to peptide $delta$ receptor agonists, the highlyselective nonpeptidic $delta$ -opioid agonist SNC-80 ([(+)-4-[(a-R)-a-((2S,5r)-4-allyl-2,5-dimethyl-1-piperazinyl)-3-methoxybenzyl-N,N-diethylbenzamide];Calderon et al., 1994), crosses the blood-brain barrier, whichfacilitates the investigation of the function of central $delta$ -opioidreceptors (Bilsky et al., 1995).

Stress can alter the response to opioid drugs and psychoactive agents. Morphine analgesia was greater in rats stressed bycold water swimming (Vanderah et al., 1993). Morphine producedhyperthermia in nonstressed rats and hypothermia in stressed rats(Ushijima et al., 1985). Stressors also alter endogenous opioids(Vaswani et al., 1987), but can differ in their capacity to alteropioid binding in brain. Ninety hours of water deprivation increased $delta$ receptor binding in the striatum, whereas 20 min of foot shockhad little effect (Stein et al., 1992). However, little is knownabout the interaction of social stressors with opioid systems,particularly in the case of chronic social stress. Previous studieshave documented that not only do neurochemical and neuroendocrinedifferences exist between singly housed and group-housed rats(Blanchard et al., 1993; Fulford and Marsden, 1997), but theyalso exist in group-housed rats of differing rank (Blanchard etal., 1991, 1993). Group-housed male rats readily establish a socialhierarchy with the dominant or $alpha$ rat displaying specific behaviorstoward the subdominant cagemates (Blanchard et al., 1991, 1993;Pohorecky et al., 1995).

The present study characterized the functional expression of $delta$ - opioid central nervous system receptors in long-term differentiallyhoused rats. The impact of psychosocial stress associated withrank status and/or differential housing on $delta$ receptor-mediatedfunction is not known. To assess the functional state of the $delta$ receptors, rats were injected with the $delta$ receptor agonist SNC-80(Bilsky et al., 1995) and receptor function was evaluated usingphysiological and behavioral tests. Rectal temperature response,open field behaviors, tail-flick, ultrasonic vocalizations (USVs),and plasma corticosterone levels were determined. To assess thesignificance of these functional changes, they were correlatedwith the cyclic[D-penicillamine²-D-penicillamine²]enkephalin (DPDPE)-stimulated guanylyl 5'-[ $gamma$ -thio]-triphosphate([³⁵S]GTP $gamma$ S) binding to the $delta$ receptors in brain sections. Agonist-stimulated[³⁵S]GTP $gamma$ S binding is believed to reflect binding to functionallyactive receptors (Sim et al., 1995). It was expected that psychologicalstress would modify specific behavioral and physiological responsesto SNC-80. That is, compared with the $beta$ rat, which displayed somesubmissive behavior and was the recipient of most of the $alpha$ rat'saggression, and with the $gamma$ rats, which displayed only submissivebehavior including prominent USVs, the dominant $alpha$ rat would showless locomotor and exploratory depression after SNC-80 treatmentand less analgesia. Our results confirmed this hypothesis by demonstratingthat, overall, subordinate rats were more responsive to the sedativeeffects of SNC-80, whereas dominant rats exhibited greater activationin response to SNC-80 than singly housed controls. Contrary toexpectation, nociception was not related to rank status, and wasgreater in the singly housed rats. These behavioral and physiologicaldifferences may be due at least in part to the observed differencesin $delta$ receptor function as well as to differences in plasma corticosteronelevels.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

Subjects and Environment. The subjects were 48 male Long Evans rats (Harlan Sprague-Dawley, Indianapolis, IN) weighing approximately 300 g at the beginningof the study. Rats were individually housed in hanging wire mesh,stainless steel cages for 14 days before triad housing, and weretransferred to the appropriate housing cages on day 1 of the experiment.Purina chow and water were available ad libitum throughout thestudy. The vivarium was kept at 21 ± 1°C, with controlled humidityand a reverse light/dark cycle (12 h each, lights off at 12:30PM). The study was run as two consecutive cohorts of 24 rats each,for a total of 36 triad-housed and 12 individually housed rats.The housing cages were made of Plexiglas and had a wire mesh floor,one of the cage walls had either one (single cages) or two (triadcages) 1-cm openings for a drinking spout. The cages for individuallyhoused rats were square (25 × 25 × 30 cm), and those for the triadhousing cages were rectangular (26 cm wide × 82 cm long × 30 cmhigh). The animal facilities have been certified by American Associationof Laboratory Animal Care, and all the experimental protocolswere approved by the Rutgers University Animal Care and UseCommittee.

Triad Housing. Although subjects were randomly assigned to triad or individual housing, triad assignments were based on body weights to avoida possible effect of body size on the development of dominance.The initial body weights were 363.10 ± 15.69 g, 363.42 ± 15.14g, 362.70 ± 11.63 g, and 364.20 ± 13.02 g for the $alpha$ , $beta$ , $gamma$ , andsingly housed rats, respectively. Rats in two triads were euthanizedafter only 3 days of differential housing, and the remaining behavioraland physiological data was collected from 10 triad- and 10 singlyhoused rats tested after 3 and 50 days of differential housing.The 12 triad rats differed in the level of aggression, with 4triad rats showing highly significant agonistic behavior untilthe end of the study, whereas another 4 triad rats did not. Inone of the highly aggressive triads, the $beta$ rat died without showingsigns of physical injury, and in another two triads, the subdominantrats showed accelerated loss of body weight during the secondhalf of the study, suggesting a high level of stress. The $alpha$ ratin these triads had to be separated from its cagemates by a wirescreen cage divider. This divider was removed for a 10-min periodevery day until the end of the study, and the body weights ofthese triad rats were monitoredcarefully.

Agonistic Behavior Rating. Agonistic behaviors were first assessed at the time the triads were formed. Rats assigned to a triad were placed into theirnovel cage, and social interactions were noted during the next30 min. Offensive and defensive aggressive behaviors (includingroll-tumble fights, aggressive grooming, on-top, lateral threat,freezing, on-back, defensive upright, and fleeing) were scoredusing the method described by Peterson and Pohorecky (1989). Additionalmeasures of aggression, such as signs of bodily attack by the $alpha$ rat on the cohabitants, were also recorded. Lesions were seenmost frequently on the tail but were also found on other partsof the body. The behaviors and signs of bodily attack were ratedand the the rank status of $alpha$ , $beta$ , or $gamma$ was assigned. The $alpha$ or dominantrat displayed offensive aggressive behavior toward his cagemates.The rat that was least aggressive and had lost the most body weight24 h after triad formation, the $gamma$ rat, rapidly developed strategiesto diminish further contact with the $alpha$ rat. Although the fullscope of communication signals is uncertain, it included immobilityand USVs when approached by the $alpha$ rat. Conversely, the $beta$ rat displayedfew defensive behaviors, and consequently was involved in morefrequent aggressive interactions with the $alpha$ rat (overall scorefor the interaction with $beta$ s and $gamma$ s was 19.0 ± 5.4 and 9.3 ± 4.5,respectively). The $beta$ rat did not appear to change its patternof behavioral interaction with the $alpha$ rat, frequently initiatingan interaction leading to a roll and tumblefight.

Experimental Protocol. Rats were extensively habituated to handling before testing. The 3-day post-triad formation test day was selected as a compromiseto examine the acutely versus chronically induced neurobiologicaland behavioral consequences of rank-associated stress. Each ratwas subjected to a series of behavioral tests over a 40-min period,beginning with the presumably least stressful and ending withthe most intrusive of the tests. The experimental protocol andtesting schedule are outlined in Table 1. Testing was conductedbetween 1:00 and 6:00 PM. Each rat was tested after an injectionof vehicle and SNC-80 and the test battery was repeated after50 days of differential housing. After basal rectal body temperaturewas measured (Digi-Sense Thermistor Thermometer), vehicle (acidifiedsaline) or SNC-80 (35 mg/kg) was administered i.p., and aftera 5-min period, the subject was tested in a modified open field(100 cm × 100 cm divided into 20 quadrants, with 8 equidistantlydistributed 4-cm diameter holes). The onset, frequency, and totalduration of crossover activity, rearing, grooming, headpoke, andcenter entry were quantified over a 10-min period with the aidof an IBM-XT computer equipped with a manually operated interface,as previously described (Pohorecky et al., 1989). Fifteen minutesafter injection, rectal temperature was again recorded and therat was tested in a tail-flick analgesiometer (Columbus Instruments,Columbus, OH). The time in seconds for the rat to retract itstail away from a focused beam of light was recorded as the latencyfor tail-flick; if the rat failed to respond within 40 s, thetest was terminated and a maximized score of 40 s was assigned.Twenty minutes after injection, the rat was tested for emissionof 22 KHz USVs (QMS Mini Bat Detector, QMC Instruments Ltd., London,England) in response to 2.8 psi air puffs delivered by an AirstimInstrument (San Diego Instruments, San Diego, CA) directed overthe rat's head. Once vocalizations were initiated, the administrationof air puffs ceased, and the number of bouts of vocalizationswas recorded; the test was terminated when no vocalizations wereheard during the next 3 min (Knapp and Pohorecky, 1995). Thirtyminutes after injection, rectal body temperature was measuredagain, followed by a tail-flick test.

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TABLE 1
Study chronology and testing schedule

DPDPE Stimulated [³⁵S]GTP $gamma$ S Binding Autoradiography. The assay was carried out as described by Sim et al. (1995). Briefly, brains were sectioned at 20 µm using a cryostat setat $-$ 20°C. Sections were thaw-mounted onto subbed slides, whichwere stored at $-$ 80°C until use. Slides were incubated in assaybuffer (50 mM Tris·HCl, 3 mM Mg Cl₂, 0.2 mM EGTA, and 100 mM NaCl,pH 7.4) at 25°C for 15 min. DPDPE-stimulated activity was determinedby incubation in 1 mM DPDPE, 0.04 1 nM [³⁵S]GTP $gamma$ S, and 1 mM GDP in assay buffer at 25°C for 2 h. Basal activitywas assessed with GDP in the absence of agonist, and nonspecificbinding in the presence of 10 mM unlabeled [ $gamma$ S]GTP without GDP.Slides were then rinsed twice in ice-cold Tris buffer (50 mM Tris·HCl,pH 7.5 at 25°C), and once briefly in deionized water. After dryingovernight, slides were exposed to Hyperfilm-BioMax 20 for 24 h.Films were digitized using a video camera and analyzed using theNIH IMAGE (Scion 1.59) program for Macintosh computers. For quantificationof images, densitometric analysis was carried based on standardsmade with ³⁵S-spiked brainpaste.

Plasma Corticosterone Determination. Trunk blood was collected on day 52. After centrifugation at 2000g for 10 min, plasma was frozen at $-$ 70°C until analysis.Duplicate 10-µl samples of plasma were used for quantificationof corticosterone concentration by radioimmunoassay using ICNkits (ICN Radiochemicals, Irvine,CA).

Adrenal Catecholamine Determination. Adrenals were rapidly frozen on dry ice and stored at $-$ 70°C until analysis. After homogenization in 0.4 N perchloric acidand centrifugation for 20 min at 15,000g, fractions of dilutedsupernatant were analyzed by high-pressure chromatography (Spectra-Physicsmodel SP8770 dual piston pump, and a Biophase ODS C-18 reversedphase column 5 mm, 250 × 4.6 mm i.d. from Bioanalytical Systems,West Lafayette, IN). The detector (LC-4C, BAS) was set at a +0.72V potential between the glassy carbon electrode and the Ag/AgClreference electrode. The filtered and degassed mobile phase (0.10M citric acid, 0.10 M sodium phosphate dibasic and 10% methanol)was pumped at a rate of 1.0 ml/min. Quantification was againstexternalstandards.

SNC-80 Dose Determination. An optimal effective dose of 35 mg/kg of SNC-80 (10 mg SNC in acidified saline) was determined by testing the effect of variousSNC-80 doses (100, 50, 40, 30, and 25 mg/kg) on rectal temperatureand locomotor behavior. At 100 mg/kg, rats showed extreme myoclonus,severe temperature depression, and total loss of locomotor activityfor approximately 15 min after injection. Reaction to the drugwas not as severe at 50 and 40 mg/kg, however loss of locomotoractivity was still prominent for up to 8 min. At the dose of 25mg/kg, no drug effect wasobserved.

Statistical Data Analysis. The data are presented as means and S.E.M. The data were analyzed using a SYSTAT-based repeated measures ANOVA. Correlationsbetween measures were determined with the Pearson's product momentcorrelation using uncorrected probabilities. The between subjects'factor was the rats' housing and rank status ( $alpha$ , $beta$ , $gamma$ , single).The within subjects' factor was drug treatment (saline vehicleor SNC-80). The repeated measures parameter was duration of differentialhousing (3 and 50 days), and in the case of rectal temperatureand tail-flick, the time at which these measures were assessed(T = $-$ 1, 15, 30, and 40 min for rectal temperature and T = 15and 30 min for the analgesia test). Additionally, Bonferroni adjustedlinear contrasts were used for the planned comparisons betweencell means within the ANOVA. Significance level was set at p $<=$ .05.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

Body Weight Changes

Differential triad housing resulted in significant rank-related long-term changes in the body weights of all rats (Fig. 1).After the initial 24 h of housing, the overall body weights oftriad-housed rats were lower than their pretriad weights (F2,32= 12.942, p < .001). However, the body weight loss of only the $beta$ and $gamma$ rats reached statistical significance (p < .001 for both).The rank-related differences in body weight were maintained throughoutthe study (F3,36 = 7.942, p < .001). The $alpha$ rats gained significantlymore body weight (39%) over the course of the study than did thesubdominant rats (about 19%, p < .001 for both) or the singlyhoused rats (22%, p < .001).

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Fig. 1. Effect of rank status and housing condition on body weight loss at 1 day, and body weight gain at 50 days post-triad formation. Columns and error bars represent mean ± S.E.M. (n = 12/group). * and $diamond$ , indicate significant difference from the corresponding $alpha$ rats (p $<=$ .001).

Rectal Temperature

Basal rectal temperature was dependent on housing condition and rank status (F3,76 = 6.259, p = .001; Fig. 2A), and was lowerat the 50-day compared with the 3-day test (F1,76 = 3.988, p =.049). The basal temperature of singly housed rats was lower thanthat of triad-housed rats (p $<=$ .026 and p $<=$ .007 for the 3- and 50-daytests, respectively), but the basal temperatures of $beta$ rats tendedto be higher at the 50-day compared with the 3-day test. SNC-80treatment decreased the rectal temperature of all rats (F1,33= 5.599, p = .024), with greater hypothermia 30 min after injection(F3,66 = 53.755, p < .001) (Fig. 2B). At the 3-day test all ratswere similarly affected by SNC-80 treatment. However, after 50day, rank and housing status modified the hypothermic effect ofSNC-80 (F3,32 = 3.653, p = .021). SNC-80-treated $alpha$ rats were lesshypothermic compared with $gamma$ rats and singly housed rats (p = .034and p = .004, respectively).

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Fig. 2. Effect of rank status and housing condition and of treatment with SNC-80 (35 mg/kg, i.p.) on body temperature measured at 3 and 50 days after triad formation. Temperature was measured before and at 15, 30, and 40 min following SNC-80 injection. A, basal rectal temperatures before injection. B, decline in rectal temperature 30 min after SNC-80 treatment. Control rats were injected with an equivalent volume of saline. Columns and error bars represent mean ± S.E.M. (n = 8-12/group). + and *, indicate significant differences from singly housed rats at the 3- and 50-day tests (p = .05). $diamond$ , indicates significant differences from the corresponding 3-day groups (p $<=$ .05).

Open Field Behavior Locomotor Activity

Locomotor activity of triad-housed rats was lower compared with singly housed rats (F3,29 = 4.044, p = .016; Table 2). Althoughrats were less active overall at the 50-day compared with the3-day test (F1,27 = 4.368, p = .046), this effect was less prominentin $beta$ and $gamma$ rats. SNC-80-treated rats were more hypoactive comparedwith saline-injected rats (F1,27 = 25.090, p < .001; Fig. 3A).This depressant effect of SNC-80 was dependent on the durationof differential housing (F1,27 = 5.465, p = .027). Although atthe 3-day test SNC-80 depressed locomotor activity of all rats,at the 50-day test the drug did not produce hypoactivity in the $alpha$ rats. As a consequence, the $alpha$ rats and singly housed SNC-80-treated rats differed in locomotor activity at the 50-day butnot the 3-day test (F1,27 = 6.487, p = .017).

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TABLE 2
Locomotor activity in open field of triad-housed and singly housed rats following saline injection
Data represent mean ± S.E.M. of horizontal locomotor activity during 10-min open field test of saline-injected rats differentially housed for 3 or 50 days.

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Fig. 3. Effect of SNC-80 (35 mg/kg, i.p.) on open field behavior of rats tested at 3 and 50 days after triad formation. Controls were injected with an equivalent volume of saline. Columns and error bars represent percentage of change in the activity of rats injected with drug versus those of rats injected with saline ± S.E.M. (n = 7-10/group). A, frequency of locomotor activity in the peripheral area of the open field. B, frequency of locomotor activity in the central area of the open field. C, frequency of headpoke behavior. *, indicates significant differences from $alpha$ rats at 3 days (p = .02). $diamond$ , indicates significant difference from corresponding $alpha$ rats.

Locomotor Activity in Central Area. Singly housed rats entered the central area more frequently than did triad-housed rats (F3,27 = 37.004, p = .046; Table 3).At the 50-day test, triad-housed rats, particularly the $alpha$ rats,made fewer entries to the central area compared with the singlyhoused rats (p = .05). Compared with saline injection, SNC-80treatment depressed center entries at the 3-day test (F1,27 =3.944, p = .057; Fig. 3B). After 50 days of differential housing,SNC-80-treated singly housed rats still made few entries to thecenter of the field, but the $alpha$ rats made comparatively more entriesthan saline-injected rats. Because of differences in the SNC'seffect on locomotor activity in the center versus periphery ofthe field, the ratio of center entries to total activity in theopen field was calculated (Table 4). Interestingly, althoughSNC-80-treated triad-housed rats increased center entries by 96%by the 50-day test, there was no change in singly housed rats.Thus, these long-term triad-housed rats differentially increasedentries to the central area in contrast to singly housed rats.

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TABLE 3
Frequency of entries to central area of open field test of saline-injected triad-housed and singly housed rats
Data represent mean ± S.E.M. for frequencies of entries to the central area of the open field of saline injected rats differentially housed for 3 or 50 days.

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TABLE 4
Entries to central area as a percentage of total locomotor activity in open field of saline- and SNC-80-injected rats housed differentially for 3 and 50 days
Data represent mean ± S.E.M. of frequency of entries made into central area as a percentage of total horizontal locomotor activity during open field of rats differentially housed for 3 or 50 days. Rats were injected i.p. with saline or SNC-80 before the test.

Headpoke Behavior. Chronicity of differential housing also depressed the frequency of headpoke behavior (F1,24 = 6.396, p = .018), particularlyin the $alpha$ rats (Table 5). SNC-80 treatment decreased the frequencyof headpoke behavior (F1,24 = 47.253, p < .001; Fig. 3C). SNC-80'seffect on headpoke frequency depended on the rank and durationof housing (F3,24 = 3.099, p = .046). Again the $alpha$ rats showedno drug-induced depression of headpoking at the 50-day test, andheadpoked more frequently than $beta$ rats or singly housed rats (p= .09 and p = .015, respectively).

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TABLE 5
Frequency of headpoke and rearing behaviors in open field of saline-injected triad-housed and singly housed rats
Data represent mean ± S.E.M. for the frequency of headpoke and rearing behaviors during 10-min open field test in rats differentially housed for 3 or 50 days.

Rearing Behavior. Saline-injected triad-housed rats reared less frequently than did saline-injected singly housed rats (F3,26 = 2.991, p = .049),particularly at the 50-day test (Table 5). SNC-80 treatment abolishedthe rearing behavior of all rats (F1,26 = 15.591, p = .001 andF1,26 = 114.028, p < .001 for the 3- and 50-day tests,respectively).

Grooming Behavior. About 84% of all the saline-injected rats engaged in grooming behavior during the open field test. Grooming was almost entirelyabolished in rats treated with SNC-80 (F1,28 = 47.637, p < .001).None of the $alpha$ and $gamma$ rats and only 10% of the $beta$ rats and singlyhoused SNC-80-treated rats engaged in groomingbehavior.

Fecal Boli. Overall, saline-injected rats defecated little during the open field test. After SNC-80 treatment defecation by triad-housedrats declined further. Interestingly, drug-treated singly housedrats showed a remarkable increase in defecation (3.5-fold at theday-3 test and 5-fold at the day-50test).

Analgesia

Compared with saline-injected rats, SNC-80-treated rats had longer tail-flick latencies (F1,28 = 255.65, p < .001; Table 6).Irrespective of the duration of differential housing, this analgesicdrug effect was similar in triad-housed and singly housed rats;moreover, there were no rank-related differences.

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TABLE 6
Response latency in tail-flick test of saline-injected triad-housed and singly housed rats
Data represent mean ± S.E.M. of latencies for tail-flick response in rats differentially housed for 3 or 50 days. Rats were injected i.p. with saline or SNC-80 15 min before test.

USV

Housing condition, but not rank status of rats, had a significant effect on USVs induced by air-puff stimuli (Table 7). Comparedwith triad-housed rats, saline-injected singly housed rats hadshorter latencies, and emitted fewer USVs, irrespective of theduration of differential housing (F1,37 = 11.667 and F1,38 = 8.275,p = .007, respectively). SNC-80 treatment completely suppressedUSVs by all rats.

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TABLE 7
USV to air-puff stimuli of saline-injected triad-housed and singly housed rat
Data represent mean ± S.E.M. for USV induced by air-puff stimuli of rats differentially housed for 3 or 50 days. Rats were tested after i.p. injection of saline or SNC-80.

Plasma Corticosterone

Rank status and housing condition significantly altered plasma corticosterone levels (F3,28 = 3.262, p = .036; Fig. 4). $alpha$ and $gamma$ rats had lower corticosterone levels compared with the $beta$ rats (p = .018 and p = .033, respectively). Corticosterone levelsof $alpha$ rats were also lower compared with singly housed rats (p= .042).

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Fig. 4. Plasma corticosterone concentration of rats housed for 50 days in triads or singly. Columns and error bars represent the mean concentration of corticosterone in plasma of rats injected with drug versus saline ± S.E.M. (n = 8-9/group). *, indicates significant difference from $beta$ rats (p $<=$ .033). +, indicates significant difference from singly housed rats (p = .042).

Adrenal Catecholamines

After 50 days of differential housing, the concentration of adrenal catecholamines was similar in triad-housed and singlyhoused rats, and was not correlated with rank status (Table 8).

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TABLE 8
Concentration of adrenal catecholamines of rats differentially housed for 50 days
Adrenal catecholamines, expressed as nanograms per gland, were quantified by HPLC with electrochemical detection. Data represent mean ± S.E.M. of groups of eight rats.

Correlations between Rank Status/Housing and Behavioral and Physiological Measures

The drug-induced hypothermia correlated with several of the measures assessed in the open field test. In long-term triad-housedrats, SNC-80-induced hypothermia correlated positively with drug-inducedhypoactivity, with the frequency of entries to the center of thefield, and with the frequency of headpoking (r = .673, p < .001,r = .719, p = .029 and r = .792, p = .014, respectively). Drug-inducedhypothermia also correlated positively with the frequency of groomingbehavior of saline-injected rats (r = 1.00, p < .001). Additionally,frequency of locomotor activity correlated negatively with tail-flicklatencies of SNC-80-treated rats (r = $-$ .776, p < .001).

Locomotor activity following saline injection correlated positively with adrenal norepinephrine (r = .968, p = .032). Plasmacorticosterone correlated negatively with tail-flick latency followingsaline injection (r = $-$ .429, p = .018), and positively with locomotoractivity of the $beta$ rats (r = .835, p = .039). Additionally, plasmacorticosterone levels correlated positively with adrenal epinephrineand norepinephrine (r = .834, p = .039 and r = .661, p = .05,respectively).

DPDPE-Stimulated [³⁵S]GTP $gamma$ S Binding

DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the left prefrontal cortex (PFCx) depended on the subject's rank and housing condition(F3,20 = 4.928, p = .010; Fig. 5A). Singly housed and $beta$ rats hadmore binding in the left PFCx compared with $alpha$ rats (p = .018)and $gamma$ rats (p = .002). Moreover, DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the right PFCx of singly housed rats was higherthan that of triad-housed rats, which showed no rank-related differencesin binding.

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Fig. 5. DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the PFCx (A) and the central nucleus of the amygdala (B) of rats housed in triads or singly for 50 days. The columns and error bars represent the stimulation in fmol of [³⁵S]GTP $gamma$ S bound per mg tissue ± S.E.M. * Indicates significant difference from corresponding singly housed rats (p = .01). +, indicates significant difference from corresponding $alpha$ rats (p = .05).

In the central nucleus of the amygdala, rank status and differential housing also altered DPDPE-stimulated [³⁵S]GTP $gamma$ S binding (F3,20 = 3.82, p = .03 for the right, and F3,20= 4.68, p = .01 for the left side; Fig. 5B). Binding in the leftamygdala of singly housed rats was also higher than that of triad-housedrats (p = .003 and p < .001 for $alpha$ and $gamma$ rats, respectively). Similarly,in the right amygdala, DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in singly housed rats was higher than that of $alpha$ , $beta$ , and $gamma$ rats (p = .033, p < .001, and p < .001, respectively);moreover, the binding in $alpha$ rats was higher compared with the $beta$ rats (p = .017). It should be stressed that, as in the PFCx, DPDPE-stimulated[³⁵S]GTP $gamma$ S binding in the amygdala was lateralized (F3,11 = 4.527,p = .037). Lateralization of binding in the amygdala was significantfor the $alpha$ rats (p = .039), $beta$ rats (p = .047), and singly housed(p = .012)rats.

In the posterior aspects of the nucleus accumbens DPDPE-stimulated [³⁵S]GTP $gamma$ S binding was dependent on the subject's rank status andhousing condition (F3,25 = 6.35, p < .001). However, in contrastto the PFCx and the amygdala, there was no lateralization of bindingin this brain area (Fig. 6A). Singly housed rats had higher DPDPE-stimulated[³⁵S]GTP $gamma$ S binding in the accumbens compared with $alpha$ , $beta$ , and $gamma$ rats(p < .0001, p = .05 and p = .0002, respectively). Among the triad-housedrats, the $beta$ rats had the highest binding (p = .033 and p = .04compared with $alpha$ and $gamma$ rats, respectively).

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Fig. 6. DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the nucleus accumbens (A), the median eminence (B), the arcuate nucleus (C), and the thalamus (D) of rats housed in triads or singly for 50 days. The columns and error bars represent the stimulation in fmol of [³⁵S]GTP $gamma$ S bound per mg tissue ± S.E.M. *, indicates significant difference from singly housed rats for A, B, and D (p $<=$ .01). +, indicates significant difference from $beta$ rats from A and B and from $gamma$ rats for D (p $<=$ .01).

In the median eminence (Fig. 6B) and the thalamus (Fig. 6D), DPDPE-stimulated [³⁵S]GTP $gamma$ S binding was also related to rank status and housing condition(F3,25 = 3.965, p = .012, and F3,25 = 4.007, p = .009, respectively).In the median eminence, the binding in $alpha$ and $gamma$ rats was lowercompared with $beta$ rats (p = .006 and p = .007, respectively) andsingly housed rats (p = .001 and p = .002, respectively). In thethalamus, binding in $gamma$ rats was lower compared with $alpha$ , $beta$ , andsingly housed rats (p = .004, p = .019 and p = .003, respectively).Finally, in the arcuate nucleus, differential housing conditionhad no effect on $delta$ receptor-mediated binding, possibly becauseof the larger variability of the data (Fig. 6C). The trend inbinding, however, indicated a pattern similar to that in the nucleusaccumbens and medianeminence.

To summarize, DPDPE-stimulated [³⁵S]GTP $gamma$ S binding was lateralized in the PFCx and in the amygdala but not in the nucleus accumbens.The data indicate that after 50 days of differential housing, $delta$ receptor activation in the right PFCx, the amygdala, and thenucleus accumbens was higher in singly compared with triad-housedrats. In triad-housed rats, $delta$ receptor activation tended to behighest in the $beta$ rats.

Correlations between Rank and Housing and Functional $delta$ Receptor Binding

To further assess the significance in the obtained measures, correlations between behavioral and physiological parametersand the functional binding of the $delta$ receptor were determined.Laterality of DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the PFCx correlated positively with the frequencyheadpokes of SNC-80-treated rats (r = .695, p = .015). Lateralizationin DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the amygdala also correlated positively withlocomotor activity of saline-injected rats (r = .611, p = .012)and negatively with SNC-80- induced hypothermia (r = $-$ .61, p =.013).

In saline-injected $beta$ rats, locomotor activity correlated negatively with DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the left amygdala (r = $-$ .993, p = .007). Alsoin saline- but not in SNC-80-treated rats, locomotor activitycorrelated positively with binding in median eminence (r = .606,p = .010) and the arcuate (r = .509, p = .040). Frequency of rearingof SNC-80-treated rats correlated positively with the bindingin amygdala and in arcuate nucleus (r = .645, p = .04 and r =.709, p = .02, for the left and right amygdala, and r = .60, p= .050 for the arcuate). Both the frequency and duration of vocalizingof SNC-80-treated rats, and latencies to tail-flick, correlatedpositively with DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the left amygdala (r = .453, p = .50, r = .484,p = .042, and r = .612, p = .035,respectively).

Lastly, plasma corticosterone concentrations correlated positively with DPDPE-stimulated [³⁵S] GTP $gamma$ S binding in the right amygdala (r = .858, p = .003). Adrenalnorepinephrine correlated negatively with DPDPE-stimulated bindingin the left amygdala (r = $-$ .735, p = .03) and in the median eminence(r = $-$ .759, p = .02), and positively with binding in the leftPFCx of $gamma$ and singly housed rats (r = 1.00, p = .010, and r =.968, p = .032, respectively). Therefore, rats with greater bindingin the left amygdala had lower norepinephrine levels in theiradrenals, whereas those with higher binding in the right amygdalahad higher plasma corticosteronelevels.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

The present data demonstrate that in rats the stress of housing and of rank status altered the functional activity of $delta$ -opioidreceptors. Moreover, housing and rank status influenced the physiologicaland behavioral effects produced by SNC-80 stimulation of the $delta$ -opioidreceptors. $gamma$ and singly housed rats showed the largest analgesiaafter SNC-80 treatment, whereas triad-housed rats were more resistantto the drug's analgesic effect. The behavior of SNC-80-treated $beta$ and $gamma$ rats in the open field differed from that of $alpha$ rats. Ingeneral, rats with higher stress levels were more sensitive tothe depressant effects of SNC-80.

Housing Stress and Body Weight Changes. Although all rats regained the initially lost body weight within 5 days after triad formation, $alpha$ rats continued to weigh morethan their cagemates. Rank- and housing-associated differencesin body weight have been reported for rats (Blanchard et al.,1993; Pohorecky et al., 1995) and marmosets (Johnson et al., 1996).Surprisingly, the weight gain of singly housed rats was similarto that of subdominant rats. Thus body weight responds readilyto housing conditions and socialstressors.

The mechanism(s) by which rank status and housing conditions affect body weight gain are not known. Based on evidence that $delta$ agonists produce hyperphagia (Yu et al., 1997

), and that therewas differential DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in triad-housed and singly housed rats, the higherweight gain in $alpha$ and singly housed rats may reflect greater activationof the $delta$ opioidsystem.

Housing Stress and Body Temperature. SNC-80- induced hypothermia was similar in all short-term differentially housed rats, despite the higher basal temperaturesof triad-housed rats. As rats adjusted to their new housing conditions,their basal temperatures declined. Probably because $beta$ rats werethe more frequent recipients of the offensive aggression of $alpha$ rats, their basal temperature did not habituate. $delta$ Receptors canmodulate body temperature, and DPDPE decreased temperature ofboth nonstressed and stressed subjects (Spencer et al., 1988).However, because the $delta$ receptor-mediated [³⁵S]GTP $gamma$ S binding did not correlate with rectal temperature, itis doubtful that the hypothermia was directly mediated by thesereceptors, although an effect in drug-induced hypoactivity issuggested by its positive correlation with thebinding.

Housing Stress and Open Field Behaviors. Time- related habituation to housing conditions and the testing apparatus is evident from the decline in locomotor activityfrom the 3-day to the 50-day test. In contrast to singly housedrats, triad-housed rats became desensitized to novel environments,in support of the "hyperarousal" theory for isolated rats (Einonand Morgan, 1978). Group-housed rats are known to be less activein the open field than singly housed rats (Dalrymple-Alford andBenton, 1981).

Behavioral sensitivity to SNC-80 was modified by chronicity of differential housing. Although SNC-80-induced hypoactivitywas similar for all rats at the 3-day test, at the 50-day test $gamma$ and singly housed rats were more sensitive to its depressanteffects, whereas $alpha$ rats were sensitized to its activating effectson locomotor and exploratory (headpoke) behaviors. This stimulantaction of SNC-80 in $alpha$ rats is reminiscent of the hyperactivitytypically produced by low doses of opiates, whereas high dosesproduce locomotor depression (Reid et al., 1996

). Enkephalinsand the $delta$ -2 agonist deltorphin II also produced hyperactivityin rats (Calenco-Choukroun et al., 1991

). It is more likely that $alpha$ rats were sensitized to SNC-80 rather than becoming tolerantto the drug. Development of tolerance would have put the $alpha$ ratsin the activating phase of the dose-response curve. Moreover,one would have also expected that tolerance would have developedwith such measures as the tail-flick and USVs.

The greater sensitivity of $beta$ s and $gamma$ rats to the depressant action of SNC-80 was reflected by the negative correlation of locomotoractivity and DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the amygdala. The mechanism for this sensitizationis likely to be downstream by one or more synapses from the neuronswith $delta$ receptors because differences in G protein activation didnot appear to be sufficient to fully account for the differencesin locomotion. This assertion is supported by the binding data,which indicates that the functional receptor binding in $gamma$ ratsdid not differ from that of $alpha$ rats, whereas there were substantialdifferences in locomotor activity between $alpha$ and $gamma$ rats. Because $delta$ agonists given directly into the ventral temgental area canincrease extracellular levels of dopamine and its metabolites(Devine et al., 1993

), enhanced release of dopamine in the nucleusaccumbens may mediate the hyperactivity of SNC-80 andopioids.

$alpha$ Rats also made the most and singly housed rats the least entries to the center of the field at the 50-day test. Thus $alpha$ ratsshowed less anxiety-like behavior and/or, again, sensitizationto the excitatory effects of the drug. Because stressed rodentsgenerally exhibit greater anxiety-like behavior in novel testsituations (Bardo et al., 1996

), this may have been the case withthe singly housed SNC-80-treated rats compared with triad-housedrats. Singly housed saline-treated rats had fewer fecal boli andmade fewer center entries than did triad-housed rats. Fewer centerentries and more fecal boli in SNC-80-treated singly housed ratssuggests that they were more emotional (Gentsch et al., 1981

).Because center entries correlated with the DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the amygdala, PFCx, and thalamus, whereas activityin the periphery of the field correlated only with binding inthe amygdala, activity in different parts of the open field mayhave involved distinct neurobiologicalsubstrates.

Housing Stress and Sensory Reactivity. The longer tail-flick latencies of SNC-80-treated rats attested to its analgesic effect, originally described in mice (Bilskyet al., 1995). There were no rank- and housing-related differencesin nociception, as previously reported (Woodworth and Johnson,1988), although longer latencies in isolated rats have also beenreported (Naranjo and Fuentes, 1985). Latencies for tail-flickcorrelated positively with DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the amygdala, corroborating the role of thesereceptors in nociception (Spencer et al., 1988; Calcagnetti etal., 1989). The analgesia of rats with high corticosterone levelssupports the finding that glucocorticoids decrease opioid nociception(Ratka et al., 1988). Because stress produces tolerance to DPDPE-inducednociception (Calcagnetti et al., 1989), tolerance of $delta$ receptorsmay explain the lack of rank-related differences in nociceptionin saline-injected triad-housed rats. Thus both $delta$ -opioid receptorsand glucocorticoids may have modulated nociception in the presentstudy.

Control triad-housed rats had longer latencies, and vocalized less frequently, than singly housed rats in the USV test. However,no change in tactile startle was found in rats socially isolatedfor 29 days (Woodworth and Johnson, 1988

). This discrepancy mayreflect differences in housing conditions and in testing procedures.Activation of $delta$ -opioid receptors by SNC-80 almost entirely blockedUSVs induced by air puffs. Latency to vocalize correlated negativelywith DPDPE-stimulated [³⁵S]GTP $gamma$ S binding in the right amygdala. These results reiteratethe findings that DPDPE and enkephalins decreased the frequencyof USVs (Haney and Miczek, 1995

). In view of the postulated sensory"hyperirritability" of individually housed rodents (Cairns, 1973

),enhanced sensory reactivity, rather than an anxiety-like state,of singly housed rats might explain their higher vocalizationrate. Taken together, the present findings indicate that $delta$ receptorsare particularly important for the regulation of sensoryinputs.

Housing Stress and Adrenocortical and Adrenomedullary Hormones. $alpha$ and $gamma$ rats had lower plasma corticosterone levels compared with $beta$ and singly housed rats. The level of control subjectshave in stressful conditions may determine the severity of thestress response and the balance between the hypothalamo-pituitary-adrenalaxis and sympathoadrenal activity (Henry, 1992). Because plasmacorticosterone levels are generally taken to reflect the levelof stress, $alpha$ and $gamma$ rats appeared to have implemented successfulcoping strategies. The high plasma corticosterone levels of $beta$ rats, on the other hand, suggests that their coping strategieswere not successful, because they continued to be challenged bythe $alpha$ rats. Corticosterone levels of singly housed rats were similarto those of $beta$ rats, and of rats sacrificed 3 days after triadformation (227.80 ± 9.53 ng/ml, n = 4), when colonies were stillhighly unstable. By this measure, individual housing of rats appearedto have beenstressful.

The present findings of a positive correlation of plasma corticosterone levels with $delta$ receptor binding in the right amygdalaare in line with the role of opioids in cortisol release (Parrottand Thornton, 1989

). Furthermore, brain areas involved in theregulation of the hypothalamic-pituitary-adrenal (HPA) axis (amygdala,arcuate, and median eminence) showed a consistent pattern of activated $delta$ receptor binding that corresponded to the pattern of plasmacorticosterone (e.g., highest binding in $beta$ and singly housedrats).

Although there were no rank and housing-related differences in adrenal catecholamines, medullary catecholamines and locomotoractivity, correlated with $delta$ -opioid-mediated [³⁵S]GTP $gamma$ S binding in the amygdala and PFCx. SNC-80-induced hypoactivityshowed positive correlation with adrenal epinephrine levels. Inline with the proposal of Benus and associates (Benus et al.,1991

), the more active rats had higher adrenal norepinephrine.Moreover, $alpha$ rats with higher epinephrine also had higher corticosteronelevels in plasma. The sympathomedullary system is preferentiallyactivated when stressors are controllable, whereas the HPA systempredominates in the face of loss of control. Aggressive territorialrats with an active coping style have high baseline plasma levelsof norepinephrine and a highly reactive sympathetic nervous system(Sgoifo et al., 1996

). Nonaggressive rats show a passive copingstyle and a more reactive HPA system. Benus and associates (Benuset al., 1991

) suggested that these coping styles represent alternativeadaptations to stressfulsituations.

Housing Stress and $delta$ Receptor-Activated Binding. Although the presence of $delta$ -opioid receptors and its mRNA in brain is well known (Mansour et al., 1995), to our knowledge,lateralization of receptor binding has not been reported. It isinteresting that lateralization of $delta$ receptor binding in boththe PFCx and amygdala was totally absent in $gamma$ rats, was prominentin $alpha$ rats, which in contrast to the other rats, showed sensitizationrather than depression to SNC-80 in open field behaviors. Similarly,rats with left-biased amphetamine-induced rotation were reportedto be more sensitized by stress (LaHosta et al., 1988). Rats withlateralized $delta$ receptor binding in the amygdala were more activein the open field. Those with greater binding in the left amygdalawere more sensitive to air-puff-induced vocalizations, but theSNC-80- treated rats were less motorically active, and showedless sensory sensitivity (air puffs and pain). Thus, lateralizedbinding in the amygdala, high locomotor activity, and sensorysensitivity correlated positively with greater sensitivity toSNC-80-induced depression in these measures. Higher right amygdalabinding in $beta$ rats, on the other hand, correlated positively withmore headpoke behavior and higher plasma corticosterone levels.The higher corticosterone of $beta$ rats most likely reflects the stressfrom frequent interactions with $alpha$ rats. These findings are inagreement with the notion that activation of the amygdala is crucialfor the retrieval and analysis of information relevant to a stressor,for the stimulation of the HPA axis and the sympatho-adrenomedullarysystem by emotional stressors (Huether,1996), and for amygdala'srole in vocalizations and reactions to pain (Garcia et al., 1998).Saline-injected $gamma$ and singly housed rats with higher left PFCxbinding had higher adrenal norepinephrine levels. $beta$ and singlyhoused rats with higher PFCx binding made more center entries,moreover $beta$ rats with lateralized binding in the PFCx engaged inmore exploratory headpoke behavior, suggesting that the $beta$ ratsmay have had a greater impulsive drive, which is supported bytheir engagements with the $alpha$ rats. These findings are consistentwith the currently held view that psychological stressors activatethe PFCx. By interpreting sensory and emotional stimuli, the PFCxis crucial for the assessment of potential danger, the generationof fear and anxiety, and the activation of the HPA axis (Huetheret al., 1996).

Singly housed rats with the highest functional $delta$ receptor binding in the thalamus, had the highest analgesia and USVs, consistentwith the thalamus's role as a sensory relay station, includingtactile and visual inputs associated with agonistic interactions(Kani and Adams, 1978

Some functions in brain are lateralized. For example, muricide behavior in rats was activated by the right hemisphere andinhibited by the left (Garbanati et al., 1983

). Although the significanceof the lateralization of $delta$ -opioid receptors is unknown, it probablycontributes to the expression of individual differences in physiologyand behavior of organisms under basal and challenging conditions,as when stressed. For example, restraint stress produced an initialincrease in dopamine metabolism only in the left cortex of rats(Carlson et al., 1991

) and produced greater elevations in plasmacorticosterone in mice that consumed food with the left ratherthan with the right paw (Neveu and Moya, 1997

). Also rhesus monkeysthat had higher right frontal electroencephalographic activityhad higher cortisol levels and displayed a fearful temperament(Kalin et al., 1998

). Moreover, children that showed behavioralinhibition, believed to reflect a fearful temperament, also hadhigher right prefrontal brain activation (Davidson, 1992

The present data indicate that changes in behavioral and physiological parameters associated with rank status and housingcondition reflect changes in functionally active $delta$ receptors quantitatedusing agonist stimulated [³⁵S]GTP $gamma$ S binding. $delta$ Receptor-activated [³⁵S]GTP $gamma$ S binding is considered to reflect receptor-mediated couplingto G proteins (Sim et al., 1995

). Enhanced binding may indicateexistence of more $delta$ receptors, and/or of more functionally activereceptors, or receptors with a greater affinity for the G protein(Gold et al., 1997

); it is unlike to reflect changes in G proteinsbecause of their known stability (Selley et al., 1998

). Radioligandsused for $delta$ receptor binding exhibit high nonspecific binding,therefore are not as specific as previously thought. Consideringthe chronicity of stressor employed, it is likely that greater $delta$ receptor-activated binding reflects adaptation to lower neuronalrelease of enkephalins. On the other hand, a decrease in $delta$ receptor-mediatedbinding may reflect adaptive down-regulation of the receptor inthe face of excessive stimulation. Stress, whether via changesin glucocorticoids or other trophic factors, may alter not onlythe synthesis and/or metabolism of enkephalins, but also of $delta$ receptors. Therefore, further elucidation of the observed functionalreceptor-mediated binding, and receptor-mediated functional effects,must await additional information on enkephalin release, synthesis,and degradation. Reverse transcription-polymerase chain reactionstudies might be useful to determine the activation state of themet-enkephalin gene (prepro-enkephalin).

The present studies indicate that social stress modifies the functional effects mediated by $delta$ opioid receptors. The dominantrats had lower plasma corticosterone levels and were less sensitiveto the depressant effects of the $delta$ receptor agonist SNC-80 comparedwith the subdominant $beta$ rats. The rapid development of toleranceto $delta$ receptor-mediated elevation of corticosterone (Gonzalvezet al., 1991

) and nociception (Zhao and Bhargava, 1996

), may indicatethat there was tolerance to the stress-induced endogenously releasedopioid neuropeptides, which may have modified the responsivenessto the exogenously administered $delta$ agonist.

In summary, rats with the least psychological stress, associated with rank status in triad-housed rats, showed stimulant ratherthan depressant effects of the $delta$ opioid agonist, SNC-80. Thisindicates that $delta$ opioid activation was enhanced by the stressof differential housing. Many of the changes observed in triad-housedrats show similarities to symptomatology associated with humandepression.

	Acknowledgments

We thank to Dr. Efraim Azmitia and Gregory Blakley for critical reading of themanuscript.

	Footnotes

Accepted for publication March 25, 1999.

Received for publication June 17, 1998.

¹ This research was supported in part by funds from Sigma Xi, the Rutgers University Honors Program, and National Institutesof Health Grant AA10124. Presented in part at the 27th and 28thAnnual Meetings of the Neuroscience Society, 1997 and 1998,respectively.

² Current address: Laboratory of Medicinal Chemistry, National Institute of Diabetes and Digestive and Kidney Diseases, NationalInstitutes of Health, Bethesda, MD20892.

Send reprint requests to: Larissa A. Pohorecky, Ph.D., Neuropharmacology Laboratory, Center of Alcohol Studies, Rutgers University, 607 Allison Rd., Piscataway, NJ 08854-8001. E-mail: Larissa{at}RCI.Rutgers.edu

	Abbreviations

DPDPE, cyclic[D-penicillamine²-D-penicillamine²]enkephalin; HPA, hypothalamo-pituitary-adrenal axis; GTP $gamma$ S, guanylyl 5'-[ $gamma$ -thio]-triphosphate; PFCx, prefrontal cortex; SNC-80, [(+)-4-[(a-R)-a-((2S,5r)-4-allyl-2,5-dimethyl-1-piperazinyl)-3-methoxybenzyl-N,N-diethylbenzamide]; USVs, ultrasonic vocalizations.

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