{kappa} Opioid Receptor Antagonism and Prodynorphin Gene Disruption Block Stress-Induced Behavioral Responses

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The Journal of Neuroscience, July 2, 2003, 23(13):5674-5683

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${kappa}$ Opioid Receptor Antagonism and Prodynorphin Gene Disruption Block Stress-Induced Behavioral Responses
Jay P. McLaughlin, Monica Marton-Popovici, and Charles Chavkin
Department of Pharmacology, University of Washington, Seattle, Washington 98195-7280

   Abstract

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Previous studies have demonstrated that stress may increaseprodynorphin gene expression, and ${kappa}$ opioid agonists suppressdrug reward. Therefore, we tested the hypothesis that stress-inducedrelease of endogenous dynorphin may mediate behavioral responsesto stress and oppose the rewarding effects of cocaine. C57Bl/6mice subjected to repeated forced swim testing (FST) using a modified Porsolt procedure at 30°C showed a characteristicstress-induced immobility response and a stress-induced analgesiaobserved with a tail withdrawal latency assay. Pretreatmentwith the ${kappa}$ opioid receptor antagonist nor-binaltorphimine (nor-BNI;10 mg/kg, i.p.) blocked the stress-induced analgesia and significantlyreduced the stress-induced immobility. The nor-BNI sensitivityof the behavioral responses suggests an activation of the ${kappa}$ opioid receptor by a stress-induced release of dynorphin peptides.Supporting this hypothesis, transgenic mice possessing a disruptedprodynorphin gene showed no increase in immobility or stress-induced analgesia after exposure to repeated FST. Because both stressand the ${kappa}$ opioid system can modulate the response to drugs ofabuse, we tested the effects of forced swim stress on cocaine-conditionedplace preference (CPP). FST-exposed mice conditioned with cocaine(15 mg/kg, s.c.) showed significant potentiation of place preferencefor the drug-paired chamber over the responses of unstressedmice. Surprisingly, nor-BNI pretreatment blocked stress-inducedpotentiation of cocaine CPP. Consistent with this result, mice lacking the prodynorphin gene did not show a stress-inducedpotentiation of cocaine CPP, whereas wild-type littermatesdid. The findings suggest that chronic swim stress may activatethe ${kappa}$ opioid system to produce analgesia, immobility, and potentiationof the acute rewarding properties of cocaine in C57Bl/6 mice.

Key words: ${kappa}$ ; opioid; dynorphin; stress; depression; cocaine; conditioned place preference

   Introduction

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Stress is a normal element of life, serving to evoke adaptiveresponses of an organism to the environment. This responseto stress may be of survival value, as demonstrated by thephenomena of stress-induced analgesia (SIA; Maier et al., 1980).However, persistent and inescapable stressors that overwhelman organism's adaptive abilities can be harmful, leading todetrimental behaviors such as drug abuse (Rhoads, 1983; Kostenet al., 1986; Najavits et al., 1998). Animal studies correlateexposure to an inescapable stressor with increases in both the rewarding properties and self-administration of drugs ofabuse (Piazza et al., 1990; Shaham and Stewart, 1994; Willet al., 1998; Kosten et al., 2000). The mechanisms mediatingthis stress-induced enhancement are unclear. In one possiblemechanism, stress-induced activation of the hypothalamo-pituitary-adrenalaxis may subsequently activate the endogenous ${kappa}$ opioid system(Przewlocki et al., 1987; Nabeshima et al., 1992; Watanabeet al., 1995) presumably thereby modulating drug reward and self-administration (Mello and Mendelson, 1997; Carlezon etal., 1998; Kreek and Koob, 1998). However, Schenk et al. (1999) have suggested that the ${kappa}$ system actually opposes drug-rewardingeffects, because administration of the ${kappa}$ agonist U69,593 bothdecreases cocaine self-administration and blocks cocaine sensitization.Further understanding of the role of the ${kappa}$ opioid system inmediating the response to stress would likely provide new insightsinto the issues of stress adaptation and drug abuse.
Endogenous opioid systems have been implicated in multiple stress-induced behavioral responses, making them logical candidates for study.For example, SIA induced after a forced swim test (FST) stresswas absent in mice lacking ${beta}$ -endorphin (Rubinstein et al., 1996). Moreover, ${delta}$ opioid receptors have been associated withstress–response behaviors, because ${delta}$ agonists reduced the immobility of rats in a forced swim test (Broom et al., 2002).
The involvement of the endogenous ${kappa}$ opioid system in the behavioral response to stress is less clear. Although ${kappa}$ agonists producea dysphoria similar to that noted in depression and chronicstress (Pfeiffer et al., 1986), ${kappa}$ opioid receptor (KOR) knock-outmice demonstrated responses similar to those of wild-type micein a single brief trial of the FST, prompting the authors tosuggest that KOR is not involved (Filliol et al., 2000). However,stress-induced analgesia was blocked by peripheral administrationof the KOR antagonist nor-binaltorphimine (nor-BNI) in multiplestudies with both rats and mice (Takahashi et al., 1990; Watkinset al., 1992; Menendez et al., 1993). These results are supportedby the finding that intracerebroventricular administrationof dynorphin A (1–17) or a stable analog, E2078, potentiatesthe immobility response to a stressor, an effect blocked byopioid antagonists (Katoh et al., 1990). Moreover, subanalgesicdoses of dynorphin A (1–13) and (1–10) prolongedSIA in forced swim-stressed mice but not unstressed controls(Starec et al., 1996). Finally, expression of herpes simplexvirus-cAMP response element-binding protein (CREB) in rat brainelevated CREB levels to produce an increase in immobility inthe FST that was reduced by expression of a dominant negativemutant of CREB and prevented by nor-BNI treatment, thereby suggesting that CREB-mediated induction of prodynorphin gene expressionmay have mediated the stress-induced immobility (Pliakas et al., 2001). Overall, these reports suggest that activation ofthe endogenous ${kappa}$ opioid systems may potentiate the immobilityand analgesic responses to a stressor.
In this study, we tested the hypothesis that repeated exposureto stress activates the endogenous ${kappa}$ opioid system to producechanges in behavioral immobility, pain threshold, and drugreward. Supporting this, we report that mice exposed to forcedswimming stress demonstrated a nor-BNI-sensitive, dynorphin-mediatedincrease in pain threshold and behavioral immobility as wellas a subsequent potentiation of cocaine conditioned place preference.

   Materials and Methods

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Animals and housing. Male C57Bl/6 mice (Charles River Laboratories,Wilmington, MA) weighing 23–33 gm were used in these experiments. All mice used were adult males, ranging from 12to 16 weeks of age. Breeding pairs of heterozygous prodynorphinknock-out (KO) mice (Sharifi et al., 2001) backcrossed 12generations onto the C57Bl/6 background were used to generate KO and wild-type (WT) littermate controls for this study. TheC57Bl/6 mouse strain was chosen for this work because it hasbeen demonstrated to produce robust immobility in the FST (Dalviand Lucki, 1999; Lucki et al., 2001) and is a well characterizedbackground strain for transgenic studies (Banbury Conference, 1997). The prodynorphin gene-disrupted animals show no discernible differences from wild-type littermates in growth, life span,overt behavior, or locomotor activity (Sharifi et al., 2001).All mice used were group-housed, four to a cage, in self-standingplastic cages (28 cm long x 16 cm wide x 13 cm high) usingBed-A-Cob for home bedding within the Animal Core Facility atthe University of Washington, and maintained in a specificpathogen-free housing unit. All mice tested were transferred1 week before use into a colony room adjacent to the testingroom to acclimate to environment. All housing rooms were illuminatedon a 12 hr light/dark cycle with lights on at 7 A.M. Food pelletsand water were available ad libitum. All procedures with mice were approved by the institutional Animal Care and Use Committeein accordance with the 1996 National Institutes of Health Guidefor the Care and Use of Laboratory Animals, and mice were inspectedregularly by veterinary staff to ensure compliance.
Genotyping of prodynorphin wild-type and knock-out mice by PCR. The presence or absence of the prodynorphin gene was confirmedin genomic DNA isolated from tail tissue samples taken fromeach mouse using PCR analysis and a procedure described previously(Sharifi et al., 2001). Briefly, a fraction of isolated DNAwas used in PCR assays using the following primers: dynorphin,exon 3, 5'-GTGCAGTGAGGATTCAGGATGGG; and neomycin, 5'-ATCCAGGAAACCAGCAGCGGCTAT.PCR products were resolved on a 1.5% agarose gel with ethidiumbromide and then photographed for analysis. Homologous prodynorphinKO animals produce PCR products with the neomycin but not dynorphinprimer, whereas homologous prodynorphin WT mice produce PCR products with the dynorphin but not neomycin primer. Heterologousprodynorphin mice yield both PCR products, thereby allowingtheir exclusion from the study.
FST. To induce stress, C57Bl/6 mice were exposed to a modified forced swim test. Testing was performed on the basis of methodspreviously described by Porsolt et al. (1977a,b). The modifiedPorsolt forced swim test paradigm used was a 2 d procedure in which mice swam without the opportunity to escape. In all trials,mice were placed in an opaque 5 l beaker (40 cm tall x 25 cmin diameter) filled with 3.5 l of 30°C water. After thetrial, mice were removed, dried with towels, and returned totheir home cages for at least 7 min before further testing.On day 1, animals were placed in water to swim for a singletrial of 15 min. The time spent immobile in the last 4 minof the trial was recorded. On day 2, animals were again placedin water to swim but through a series of four trials, each6 min long; trials were separated by a 7–12 min return to a home cage. Multiple trials were used to determine the effectsof extended exposure to the inescapable stressor. The secondday of FST was typically marked by a facilitated immobilitycharacterized by a rapid and prolonged adoption of the immobileposture. Immobility is defined as the time at which the miceinitiate and maintain a stationary posture. In this characteristic posture, the mouse's forelimbs are motionless and directed forward,the tail is directed outward, and the hind legs are in limitedmotion. To qualify as immobility, this posture must be clearlyvisible and sustained for a minimum of 2 sec. Difficulty inswimming or staying afloat were criteria for exclusion; however,no mice met these criteria in this study. When mice were pretreatedwith a drug, experiments were performed with the experimenterblind to the pretreatment.
Measurement of mouse body temperature. Reports elsewhere showthat mice exposed to forced swimming in 20°C water demonstrateopioid-sensitive stress-induced analgesia coinciding with asignificant decrease in body temperature, an example of hypothermia (Mogil et al., 1996). To reduce possible complicating effectsof hypothermia in this study, the water used in all forcedswim trials was maintained at 30°C. The effect of forcedswimming under these conditions on body temperature was further monitored using temperature transponders implanted subcutaneously(above the shoulder blades) in mice 1 d before swim testing(IPTT-200; Biomedic Data Systems Inc., Seaford, DE). Body temperaturewas read remotely (DAS5007 pocket scanner; Biomedic Data SystemsInc.) before, immediately after the last 6 min swim in the2 d protocol, and 10 min after forced swim. Before forced swimming,mice had an average body temperature of 36.7 ± 0.15°C. These values were not significantly changed by vehicle or nor-BNIpretreatment alone. Immediately after forced swim, mice showeda transient decrease in body temperature to 33.8 ± 0.39°Cbut recovered within 10 min to 36.1 ± 0.61°C, avalue not statistically different from the baseline (preswim)temperature. Mice receiving nor-BNI 60 min before the forcedswim also showed a transient drop in body temperature (34.3± 0.43°C), which was not significantly differentfrom that of vehicle-treated mice. In the conditioned placepreference (CPP) training protocol used (see below), mice repeatedlyexposed to forced swimming were next put into the cocaine-conditioningchamber. Body temperatures were measured immediately beforeand then 15 and 30 min after administration of cocaine or vehicle,and no significant differences between groups were found. Forexample, at the end of the 30 min conditioning session, micenot exposed to forced swimming that did not receive cocainewere at 38.4 ± 0.14°C; mice that had not swum buthad received cocaine (15 mg/kg, s.c.) were at 38.0 ± 0.23°C; mice that had swum but had not received cocainewere at 37.4 ± 0.18°C; mice that had swum and hadreceived cocaine were at 37.4 ± 0.63°C; mice receivingnor-BNI (10 mg/kg, i.p.) before swimming but not cocaine wereat 37.8 ± 0.25°C; and mice receiving nor-BNI beforeswimming and cocaine were at 37.8 ± 0.25°C. In thesetests, no treatment produced a statistically significant differencein body temperature compared with untreated, unstressed mice (F_(5,3,15) = 1.54; p > 0.05).
Antinociceptive testing with the 55°C warm water tail withdrawal assay. The 55°C water is a commonly used nociceptive stimulusfor opioid analgesia testing (Vaught and Takemori, 1979).Latency to withdraw the tail was taken as the end point, withthe duration of tail immersion (or latency of response) measured by stopwatch. After determining baseline latencies, mice receiveda single intraperitoneal dose of vehicle (saline, 0.9%) orthe ${kappa}$ opioid receptor antagonist nor-BNI before forced swimtesting (detailed above). The antinociceptive effect of theforced swim stressor was measured 5–9 min after conclusionof the forced swim testing for that day. If the mouse failed to remove its tail within 15 sec, it was removed, and the animalwas assigned a maximal antinociceptive score. Note that noneof the animals used in this study had a baseline tail withdrawallatency longer than 5 sec, thereby requiring exclusion.
CPP. C57Bl/6 wild-type or prodynorphin knock-out mice were usedin place-conditioning studies using a three-compartment box,similar to methods used by Carlezon et al. (1998). The compartmentalizedbox was divided into two equal-sized outer sections (25 x 25x 25 cm) joined by a small central compartment (8.5 x 25 x25 cm) accessed through a single doorway (3 x 3 cm). The compartmentsdiffered in wall striping (vertical vs horizontal alternating black and white lines, 1.5 cm in width), floor texture (woodchips vs Bed-A-Cob), and lighting intensity. Mice were testedon the morning of day 1 before any treatment to establish preconditioningresponses and any possible box bias. Testing involved placingindividual animals in the small central compartment and allowingthem to freely explore the entire apparatus for 30 min. Thetime each mouse spent in the two outer compartments was recordedby stopwatch for the full 30 min period, using the placementof the front and rear paws as the determining factor. Animalsthat demonstrated a baseline preference >18 min spent ina particular compartment on the first day were rejected fromthe study. (Note that only one animal was rejected.)
Mice on average showed a slight preconditioning preference betweenthe two chambers that was statistically significant (94 ±33 sec; n = 51; F_(1,100) = 12.4; p < 0.05) for the chamber with horizontal stripes and Bed-A-Cob flooring. A "biased" approach was used wherein individual animals were given cocainein the less preferred compartment identified in the preconditioningtest. This method has been shown to produce reliable conditionedplace preference responses comparable with other experimentaldesigns (for discussion, see Bardo et al., 1995). On day 2, mice were injected subcutaneously with 15 mg/kg cocaine, a dosedemonstrated previously to produce a measurable but not maximalconditioned place preference in C57Bl/6 mice (Miner, 1997;Romieu et al., 2002; Zhang et al., 2002), and immediatelyconfined for 30 min to the drug-paired outer compartment. Fourhours later, mice received saline conditioning by administrationof saline (0.3 ml/30 gm of body weight) and immediate confinementfor 30 min to the opposite, vehicle-paired, outer compartment.On day 3, mice again were conditioned first with cocaine, followedby saline 4 hr later, in the appropriate compartments. On day4, testing of conditioned preference was conducted in the morningto conclude the experiment. Mice were placed in the preferenceapparatus for 30 min, and the time spent in each compartmentwas measured.
To examine the effect of forced swim stress on cocaine CPP,mice were exposed to 2 d of vehicle or nor-BNI (10 mg ·kg ^–¹ · d ^–¹, i.p.) pretreatment and forcedswim testing after preconditioning preference testing as describedabove. Ten minutes after the second day forced swim session,mice were injected with cocaine (15 mg/kg, s.c.) and placedin the non-preferred compartment for 30 min to begin conditioningas described above. The experiment concluded on day 4 withtesting of conditioned place preference.
Because the duration of stress-induced potentiation affectingthe conditioning might be transient, the acquisition of cocaineCPP was monitored with an altered CPP protocol. Preconditioningtesting and forced swim exposure (when used) were performedduring days 1 and 2 as described above. Cocaine place preferenceconditioning began 10 min after the last FST trial on day 2. Instead of receiving a second training session with saline,animals were returned to their home cage to separate the salinetreatment from stress. On the morning of day 3 and each subsequentmorning to the conclusion of the experiment, mice were testedfor conditioned preference in the preference apparatus for30 min, with the time spent in each compartment measured. Onthe afternoon of day 3, saline conditioning was performed byadministration of saline (0.3 ml/30 gm of body weight) andimmediate confinement to the opposite, vehicle-paired, outercompartment for 30 min. Mice were tested again for conditionedpreference on day 4 and subsequently conditioned with cocaine that afternoon in the same compartment used on day 2. On day5, mice were tested again for conditioned preference and subsequentlyconditioned with saline that afternoon in the same compartmentused on day 3. On day 6, final testing of conditioned preferencewas conducted in the morning to conclude the experiment. Notethat all results are plotted as the difference in the times spent on the drug-paired side versus the vehicle-paired side.Therefore, a positive value demonstrates the animals' preferencefor the drug-paired side.
Data analysis. All data were analyzed by repeated measures ANOVA. Significant results demonstrated by ANOVA were further analyzedfor significance with Student's t test for significant pair-wise comparisons. Dependent variables were expressed as the timespent immobile during forced swimming in all FST experimentsand the latency of time spent before removing the tail in thetail withdrawal tests. Comparisons were analyzed for swim-stressedgroups receiving nor-BNI or vehicle pretreatment, with theadditional factor of wild-type or prodynorphin gene disruption.All CPP experiments express the dependent variable as the differencein time spent in the drug- and saline-paired compartments.Data for all CPP groups were analyzed for cocaine or vehicleconditioning, with the additional factors of swim-stressedversus unstressed groups, nor-BNI or vehicle pretreatment, and wild-type or prodynorphin gene disruption. Analysis compareddifferences in time spent in the (eventual) drug- and saline-pairedcompartments before and after FST exposure. Seconds spent inthe drug-paired, saline-paired, and neutral zone compartmentswere additionally analyzed separately. Body temperature readingscollected in triplicate were averaged together by mouse andthen treatment group, with the dependent variable expressedas the body temperature (in degrees Celsius). Data for alltemperature groups were analyzed for swimming or no swimmingeffects with the additional factor of nor-BNI or vehicle pretreatmentbefore swimming. Moreover, the effects of cocaine or vehicleadministration on body temperature in the conditioning apparatuswere analyzed, with the additional factors of unstressed versus swim-stressed groups and nor-BNI or vehicle pretreatment. Alldata are presented as means ± SEM of the animal treatmentgroup, with significance set at p < 0.05.

   Results

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Stress-induced analgesia is mediated by dynorphin peptides.C57Bl/6 wild-type mice were treated with vehicle and exposedto the forced swim test over 2 d. On both days, tail withdrawallatency in the 55°C warm-water tail withdrawal assay wassignificantly increased (day 1, F_(1,50) = 28.49; p < 0.001;day 2, F_(1,47) = 91.90; p < 0.001) threefold after forcedswim testing (Fig. 1A,B, left). The SIA induced by FST exposurewas blocked by pretreatment with the KOR antagonist nor-BNIbefore FST exposure (Fig. 1A,B, center; day 1, F_(1,41) = 2.50;p > 0.05; day 2, F_(1,39) = 0.57; p > 0.05). Notably,nor-BNI alone had no acute effect on baseline tail withdrawalresponse in mice not exposed to forced swimming (Fig. 1A,center left; F_(1,12) = 0.04; p > 0.05). These results suggestthat endogenous opioids were released by exposure to the forcedswim stressor to produce the change in tail withdrawal latency.To test this, C57Bl/6 mice lacking prodynorphin gene productsand their wild-type littermates were administered vehicle andexposed to forced swim testing. Consistent with previous results,swim-stressed wild-type mice demonstrated a significant increasein tail withdrawal latency at the end of testing on day 1(from2.4 ± 0.31 to 5.6 ± 0.7 sec; n = 9; F_(1,16) =18.43; p < 0.001) and day 2 (2.4 ± 0.3 to 4.6 ±0.4 sec; F_(1,16) = 18.16; p < 0.001). In contrast, prodynorphinknock-out mice demonstrated no significant change (day 1, F_(1,16)= 0.19; p > 0.05; day 2, F_(1,16) = 0.14; p > 0.05) intail withdrawal latency after forced swimming on either day (Fig. 1A,B, right). For wild-type mice, the stress-inducedincrease in tail flick latency on day 2 was not significantlydifferent from the increase on day 1 (F_(1,48) = 1.77; p >0.05), suggesting that there was comparable activation of thenor-BNI-sensitive endogenous opioid system on both days.

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Figure 1. Forced swim stress-induced analgesia is blocked by pretreatment with nor-BNI or prodynorphin (Dyn) knock-out. Tail withdrawal latencies presented were obtained 5–9 min after the forced swimming on the first (A) or second (B) day. Mice were tested in the 55°C warm water tail withdrawal assay before (open bars) and after (hatched bars) exposure to the forced swim test, as described in Materials and Methods. On either day, C57Bl/6 mice pretreated with vehicle (0.3 ml/30 gm of body weight) demonstrated a tail withdrawal response that was increased nearly threefold after forced swim stress (A, B, left pair). Pretreatment 60 min before FST with the ${kappa}$ -selective antagonist nor-BNI (10 mg/kg, i.p.) did not significantly change baseline tail withdrawal latencies (A, left center pair) but blocked the increase in stress-induced analgesia produced by forced swimming (A, B, right center pair). Likewise, disruption of the prodynorphin gene prevented forced swim stress-induced analgesia (A, B, right pair). Wild-type littermates of the prodynorphin knock-out mice displayed SIA not significantly different from that of vehicle-treated C57Bl/6 mice (data in Results). *Significantly different from matching preswim latencies; p < 0.05, as determined by ANOVA followed by Student's t test. Bars represent n = 20–24 wild-type animals or 9 each of prodynorphin KO mice in swim test trials and 7 wild-type animals in tests of nor-BNI effect without FST exposure.

Opioid receptor antagonist selectivity of nor-BNI assessed
Although nor-BNI is reported to be a KOR-selective antagonist (Takemori et al., 1988; Horan et al., 1992), selectivity underthese experimental conditions was directly assessed. Nor-BNI (10 mg/kg, i.p., 1 hr before testing) effectively blocked theincrease in tail withdrawal latency produced by the KOR agonist. (trans)-3,4-Dichloro-N-methyl-N-[2-(1-pyrrolidinyl)-cyclohexyl]benzeneacetamide (U50,488; 25 mg/kg, i.p.) alone produced a tail withdrawal latencyof 11.0 ± 1.61 sec, but it was 3.13 ± 0.33 secin the presence of nor-BNI (not significantly different frombaseline latency). In contrast, the µ opioid receptorpreferring agonist morphine (10 mg/kg, i.p.) increased tailwithdrawal latency to 9.33 ± 1.27 sec alone and to 11.1± 2.42 sec in the presence of nor-BNI (not significant;p > 0.05). The ${delta}$ opioid receptor-selective agonist (+)-4-[( ${alpha}$ R)- ${alpha}$ -((2S,5R)-4-allyl-2,5-dimethyl-1-piperazinyl)-3-methoxybenzyl]-N,N-diethylbenzamide (SNC-80; 100 nmol, i.c.v.) increased latency to 13.2 ±0.7 sec alone and to 11.3 ± 1.82 sec in the presenceof nor-BNI (not significant; p > 0.05). Moreover, nor-BNI(10 mg/kg, i.p.) injected twice to duplicate its use in the2 d forced swim protocol also blocked the increase in tailwithdrawal latency induced by U50,488 but not morphine or SNC-80 (Fig. 2). Although the receptor-mediating the effects of theendogenously released opioid by forced swim were not directlyidentified by this pharmacological assay, these results suggestthat the nor-BNI treatments used in this study selectively blockedthe ${kappa}$ opioid receptor.

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Figure 2. Demonstration of nor-BNI selective antagonism of the ${kappa}$ opioid receptor. Mice were either untreated or pretreated once daily for 2 d with nor-BNI (10 mg/kg, i.p.). On the second day, 30 min after administration of the second dose of nor-BNI, mice were administered the opioid-selective agonists U50,488 (25 mg/kg, i.p., for the ${kappa}$ receptor), morphine sulfate (10 mg/kg, i.p., for the µ receptor), and SNC-80 (100 nmol, i.c.v., for the ${delta}$ receptor). Preliminary dose–response curves with morphine and SNC-80 demonstrated that the doses used here produced submaximal analgesia comparable with the magnitude produced by U50,488. Animals were then tested in the 55°C warm water tail withdrawal assay 30 min after agonist administration, with the latency of the mouse to withdraw its tail from the water bath taken as the end point. As a control for the SNC-80 experiment, intracerebroventricular administration of vehicle did not produce a significant change in tail withdrawal latency (n = 4; data not shown). Pretreatment with this dose of nor-BNI blocked U50,488- but not morphine- or SNC-80-induced antinociception, suggesting that nor-BNI under these dosing conditions did not significantly occupy µ or ${delta}$ opioid receptors. *Significantly different from baseline response; p < 0.05, as determined by Student's t test. Bars represent n = 4–10 mice.

Endogenous ${kappa}$ -opioid systems mediate the motor response to the second day of forced swim stress
Animals exposed to forced swimming display a characteristicimmobility response as described in Materials and Methods.If endogenous ${kappa}$ opioids contribute to this response, the nor-BNItreatment effective in reducing SIA would also be expectedto reduce the duration of immobility in the FST. Consistentwith results using KOR knock-out mice presented by Filliol etal. (2000), C57Bl/6 WT mice pretreated 1 hr with vehicle ornor-BNI demonstrated no differences in time spent immobileon the first day of testing (Fig. 3A, left side, trial 1;F_(1,44) = 0.136; p > 0.05). However, when mice were challengedwith forced swim testing the next day, nor-BNI pretreatmentsignificantly reduced (F_(1,44) = 4.47; p < 0.05) the timespent immobile in the first trial of the day (the second swimtrial overall) compared with the time of the vehicle-treated set (Fig. 3A, trial 2). The differences resulting from nor-BNIpretreatment were also significant on repeated trials (F_(7,20,140)= 15.73; p < 0.05; Fig. 3A, trials 3–5). Althoughthe reduction in immobility is small (15–20%), the effectis consistent with that produced by established antidepressantdrugs (Lucki et al., 2001).

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Figure 3. Immobility response to forced swim stress is reduced on the second day of testing by pretreatment with nor-BNI or by disruption of the prodynorphin gene. The time mice spent immobile during the last 4 min of the forced swim test was measured during multiple trials over 2 d. A, Mice received either vehicle (open bars) or nor-BNI (10 mg/kg, i.p., filled bars) in a bolus of 0.3 ml/30 gm of body weight 1 hr before daily swimming. Mice exposed to a single 15-min forced swim demonstrated no difference in immobility response on the first day, regardless of pretreatment (left-most bars). However, mice pretreated with nor-BNI spent significantly less time immobile in the FST on the second day during the four 6 min trials than vehicle-treated mice. Bars represent n = 20–24 animals. Note that mice did not demonstrate significant differences in body temperature 10 min after forced swimming on either day from unstressed mice, regardless of pretreatment. B, Wild-type, littermates (open bars) or prodynorphin gene knock-out mice (filled bars) were pretreated with vehicle in a bolus of 0.3 ml/30 gm of body weight 1 hr before daily swimming. Mice exposed to a single 15 min forced swim demonstrated no difference in immobility response on the first day, regardless of genotype. In contrast, on the second day, mice lacking dynorphin peptides through disruption of the prodynorphin gene spent significantly less time immobile in the last two 6 min trials of the FST than wild-type littermates. *Significant difference between immobility responses of stress-exposed vehicle-treated and nor-BNI treated mice (A) or between immobility responses of wild-type and prodynorphin gene-disrupted mice (B); p < 0.05, as determined by ANOVA followed by Student's t test. Bars represent n = 9 animals.

These results suggest that endogenous stimulation of KOR contributedto the immobility response during forced swimming. To testthis, prodynorphin knock-out mice and their wild-type littermateswere pretreated with vehicle and examined in the FST. Therewas no significant difference (F_(1,16) = 1.49; p > 0.05)between the immobility responses of either the knock-out orwild-type mice after the first day of forced swimming (Fig. 3B, left side, trial 1). However, repeated trials on the secondday of FST revealed a significant reduction (F_(7,8,56) = 4.12;p < 0.01) in later trials in the duration of immobilitydisplayed by the prodynorphin knock-out mice compared withtheir wild-type littermates (Fig. 3B, trials 4, 5). The significantreduction in immobility during the later forced swim trialsevident for the prodynorphin knock-out mice (Fig. 3B) is consistentwith the effects of nor-BNI on wild-type mice (Fig. 3A).
Endogenous ${kappa}$ opioids mediating swim stress also potentiate the conditioned place preference response to cocaine
We next asked whether the forced swim stress would affect cocaine-conditionedplace preference by a nor-BNI-sensitive or prodynorphin-dependentmechanism. A variety of stressors have been shown to potentiatecocaine-conditioned place preference (Haile et al., 2001; Kabbaj et al., 2001), and activation of the ${kappa}$ receptor has beendemonstrated to regulate behavioral as well as mesolimbic dopaminergicresponses to cocaine (Spanagel et al., 1992; Glick et al.,1995; Mello and Negus, 1998). Thus, we predicted that stress-inducedactivation of KOR by endogenous dynorphin would suppress cocaine-conditionedplace preference.
In the conditioned place preference assay, C57Bl/6 mice spendgreater amounts of time in environments associated with therewarding effects of cocaine (Carr et al., 1989; Miner, 1997; Romieu et al., 2002). Initially, C57Bl/6 mice were tested inthe conditioned place preference apparatus before drug treatmentto obtain preconditioning responses for subsequent comparisons.Animals were exposed to forced swim stress over 2 d or leftidle in home cages before conditioning on the afternoon of day2 with cocaine (15 mg/kg, s.c.), followed by saline (see protocol; Fig. 4A). On day 4, unstressed control C57Bl/6 mice demonstrateda measurable increase in the difference in time spent in thedrug-versus saline-paired chamber over the same differenceshown before conditioning, an example of cocaine-conditioned place preference (307 ± 114 sec preference for the cocaine-paired chamber, significantly greater than the preconditioning response; F_(1,21) = 15.43; p < 0.01; Fig. 4B). Mice pretreated withvehicle and exposed to forced swim stress before cocaine conditioningdemonstrated a significant twofold greater cocaine CPP response over that shown by unstressed mice (F_(2,36) = 4.17; p <0.05; Fig. 4B). Notably, nor-BNI pretreatment of FST-exposedmice blocked the potentiation of the cocaine CPP response (Fig. 4B). Swim-stressed nor-BNI-pretreated mice demonstrateda significant cocaine CPP response over the preconditionedresponse (F_(1,22) = 16.29; p < 0.01) that was not significantlydifferent from the response produced by the unstressed mice(F_(1,21) = 0.01; p > 0.05; Fig. 4B).

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Figure 4. Exposure to forced swim stress produces a nor-BNI-sensitive potentiation of cocaine-conditioned place preference.A, Schematic of training paradigm. The CPP protocol was as described in Materials and Methods. Preference testing allowed mice to move freely for 30 min in the morning to measure preconditioning and subsequent responses for either of two conditioning chambers, as described in Materials and Methods (represented here by triangles). After assessment of preconditioning preference, mice were exposed to repeated forced swim stress over the next 24 hr, as detailed in Materials and Methods (diamonds), or allowed to remain in home cages without swimming. Within 10 min after forced swim testing on day 2, mice were administered cocaine (15 mg/kg, s.c.) and confined to the drug-paired box for a 30 min conditioning session (squares). Four hours later, mice were administered vehicle and confined to the vehicle-paired box for a 30 min conditioning session (circles). Cocaine and saline conditioning was repeated the next day, separated again by 4 hr (represented by joined square and circle, day 3). On day 4, the final preference test was performed blind to determine the effect of treatment and conditioning on place preference. B, Preference test data demonstrating a nor-BNI-sensitive, FST-induced potentiation of cocaine CPP. Preferences are given as the difference between time spent in the drug-paired chamber and time in the saline-paired chamber during the 30 min trial. A positive value represents time spent in the drug-paired chamber. Mice were divided into three groups. The first group was unstressed, remaining in home cages and not exposed to swim stress before 2 d of cocaine and saline conditioning, as described in Materials and Methods (black bar). The second group was administered vehicle and exposed to the forced swim stressor before 2 d of cocaine and saline conditioning (light gray bar). The third group was administered nor-BNI, exposed to the forced swim stressor as described above, and then conditioned over 2 d with cocaine and saline (dark gray bar). After conditioning, all three groups demonstrated an increase in time spent in the cocaine-paired chamber that was significantly greater than the time spent in that chamber before conditioning, an example of conditioned place preference. Control unstressed mice and nor-BNI-treated, FST-exposed mice demonstrated an equivalent degree of cocaine CPP. In contrast, vehicle-treated mice exposed to FST demonstrated a significant potentiation over the unstressed animals responses. Note that mice did not demonstrate significant differences in body temperature from unstressed mice immediately after forced swimming, immediately before place conditioning, or 30 min after cocaine administration. *Significant difference in cocaine CPP compared with CPP for both unstressed and nor-BNI-treated mice; p<0.05, as determined by ANOVA followed by Student's t test. Bars represent n = 11–16 mice.

To determine whether the potentiating effect of stress workedto increase the rate of acquisition for cocaine CPP, we modifiedthe paradigm to measure CPP at intermediate times. In thismodified protocol, cocaine and saline conditioning was performedseparately on sequential days, with preference testing performedeach morning before the conditioning sessions. Mice received cocaine conditioning after the second FST exposure on day 2and then were tested the morning of the next day (day 3) forplace preference. In the afternoon of day 3, mice receivedvehicle conditioning in the opposite chamber and were testedthe morning of the next day (day 4) for place preference. This alternation was repeated on days 4 (cocaine conditioning) and5 (vehicle conditioning) with testing for place preferenceeach morning. Place preference was assessed on day 6 to endthe experiment (see protocol; Fig. 5A). Control mice weretreated by the same cocaine-conditioning protocol but not exposedto forced swimming. Although the modified (repeated testing)paradigm might contribute to extinction, it has the advantageof assessing how stress affects the rate of acquisition ofcocaine place preference.

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Figure 5. Exposure to forced swim stress results in rapid, long-lasting nor-BNI-sensitive potentiation of cocaine conditioned place preference. A, Schematic of modified CPP paradigm. The CPP protocol was modified to allow one preference test and one conditioning session per day, alternating between cocaine (15 mg/kg, s.c.; squares) and saline (circles), such that the study extended over 6 d. Preference testing allowed mice to move freely for 30 min in the morning to measure preconditioning and subsequent responses for either of two conditioning chambers, as described in Materials and Methods (represented here by triangles). After assessing preconditioning preferences, some of the mice were exposed to repeated forced swim stress over the next 24 hr, as detailed in Materials and Methods (diamonds). On day 2, unstressed mice or FST-treated mice within 10 min after forced swim were administered cocaine (15 mg/kg, s.c.; squares), confined to the drug-paired box for a 30 min conditioning session, and then returned to the home cage overnight. Preference testing followed the next day (triangle, day 3), with animals then administered vehicle and confined to the vehicle-paired box for a 30 min conditioning session (circle). The monitoring of cocaine CPP acquisition continued on days 4 and 5 to ascertain a steady-state response, with one more cocaine-conditioning session (day 4) and vehicle-conditioning session (day 5) preceding the final preference test on day 6. B, Daily preference test data demonstrating acquisition of cocaine CPP and nor-BNI-sensitive potentiation by exposure to FST. Summarized results of daily preference tests (represented by triangles in A) are plotted in seconds to highlight time spent on the drug-paired side of the apparatus. Grouped mice on day 1 demonstrate a 94-sec preconditioning preference for the chamber that would subsequently be vehicle-paired. Mice were then divided into three groups. The first group was administered vehicle and exposed to the forced swim stressor (open circles); the second group was administered nor-BNI 60-min before FST (open squares); and the third group was returned to home cages and not exposed to swim stress (filled circles). All mice were subsequently used in cocaine CPP testing, with daily preference testing done blind to monitor the acquisition of cocaine CPP as detailed in A. Both control, unstressed mice and swim-stressed mice pretreated with nor-BNI demonstrated rapid acquisition of cocaine CPP on day 3, indicated by a time spent in the drug-paired chamber that was significantly (p < 0.05) greater after cocaine conditioning than before. Moreover, the preferences shown in subsequent tests with these animals were not significantly different from the day 3 response (filled circles). Vehicle-treated mice exposed to FST demonstrated the same rapid acquisition of cocaine CPP, also reaching a stable, peak response by day 5, but the response on each day was significantly potentiated twofold to fourfold over the unstressed animals responses. *Significant difference between cocaine CPP mice and preconditioning preference, as determined by ANOVA followed by Student's t test. Points represent means for six to eight animals.

Unstressed control C57Bl/6 mice demonstrated a measurable placepreference on day 3 (147 ± 135 sec preference for drug-pairedside; F_(1,15) = 10.0; p < 0.01; Fig. 5B). After the secondconditioning sessions with cocaine and saline, place preferencereached a stable level on day 6 (358 ± 85 sec) thatwas not significantly different from that on days 3–5(F_(3,28) = 0.62; p > 0.05; Fig. 5B). The modified conditioningparadigm produced the same level of cocaine-conditioned placepreference as the original paradigm, suggesting that extinctionwas not a significant effect. In contrast, mice exposed tothe forced swim stressor over 2 d demonstrated significantly greater cocaine-conditioned place preference on each day oftesting than demonstrated by the untreated control mice (p< 0.05 each day; Fig. 5B). This twofold to fourfold potentiationof place preference occurred rapidly and remained significantlyelevated over the preference responses of unstressed mice, reaching 693 ± 105 sec on day 6 (F_(1,12) = 7.42; p <0.05; Fig. 5B). Importantly, swim stress induced a fourfold potentiation of cocaine CPP on day 3, after the first cocaineconditioning session, and the potentiation was not significantlyincreased by subsequent cocaine or saline training sessions(F_(3,20) = 1.00; p > 0.05).
Pretreatment of mice with nor-BNI (10 mg/kg, i.p.) on days 1and 2 before forced swim testing blocked the potentiation ofsubsequent conditioned place preference in this modified paradigm(Fig. 5B). There was no significant difference between stress-exposed,nor-BNI-treated mice and unstressed mice in the cocaine-conditionedplace preference trials on any day. In the absence of stress,mice pretreated with nor-BNI did not show a significant differencein cocaine CPP compared with untreated mice (F_(1,10) = 0.11; p > 0.05; Fig. 6A). Thus, in the absence of stress, nor-BNIdoes not affect cocaine place preference in this conditioningparadigm.

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Figure 6. Control experiments. A, nor-BNI has no effect on cocaine CPP in the absence of stress Mice were pretreated twice over 2 d with vehicle or nor-BNI (10 mg/kg, i.p.) and either exposed to the forced swim stressor as detailed in Material and Methods or allowed to sit in their home cages before the development of cocaine-conditioned place preference as described in Figure 5. By the final day of preference testing, nor-BNI pretreatment of unstressed mice showed cocaine CPP that was not significantly different from the cocaine CPP of unstressed, untreated control mice. *Significant difference in matching cocaine CPP response of unstressed mice; p < 0.05 for all, as determined by ANOVA followed by Student's t test. B, Swim stress alone does not produce place preference in the absence of cocaine. Three sets of mice were pretreated with vehicle and either exposed to the forced swim stressor or left in their home cages. Conditioned place preference testing was performed as described in Figure 5A, but vehicle was substituted for cocaine in all conditioning sessions for the two sets of mice. Mice conditioned with saline on both sides of the apparatus did not show place preference significantly different from the animal's preconditioning responses. *Significant difference in time spent on the drug paired side compared with time spent on the drug paired side by saline-conditioned animals; p < 0.05 for all as determined by ANOVA followed by Student's t test. Bars represent n = 3–8 animals.

It was possible that pairing the termination of stress witha chamber could, by itself, lead to a place preference. Toassess the possibility that removal from the swim test andimmediate placement in a conditioning chamber could createa preference for that chamber, animals were conditioned with saline in both chambers (i.e., no cocaine-training sessionsbut placement in one of the chambers 10 min after the terminationof FST). As shown, vehicle-conditioned mice did not developsignificant place preference when either unstressed (F_(1,5)= 0.01; p > 0.05) or exposed to FST (F_(1,6) = 0.08; p >0.05; Figure 6B). Thus, nor-BNI in the absence of stress didnot affect cocaine CPP, and exposure to the forced swim stressin the absence of subsequent cocaine did not produce CPP. Surprisingly,the nor-BNI data suggest that a stress-induced release of endogenousopioids may have potentiated rather than suppressed cocaine CPP.
The possible involvement of the endogenous ${kappa}$ opioid system inthe stress response was assessed using prodynorphin knockoutmice and their wild-type littermates. Neither group showedsignificant chamber preference before cocaine conditioning(F_(1,19) = 0.006; p > 0.05; Fig. 7, left pair of bars).Unstressed prodynorphin knock-out mice and their wild-type littermates used in cocaine CPP assays demonstrated similar place preferenceresponses (Fig. 7) that were not statistically different fromeach other (F_(1,7) = 0.01; p > 0.05; center pair of bars)or from the response of unstressed C57Bl/6 mice (prodynorphinKO mice, F_(1,11) = 0.003; p > 0.05; wild-type littermates,F_(1,11) = 0.005; p > 0.05). Consistent with the previousdata, wild-type littermates exposed to 2 d forced swim stressdeveloped significantly greater cocaine CPP than unstressedwild-type littermate mice, as measured by comparing the differencesin time spent in the drug- and saline-paired chambers betweenthe two sets of animals (F_(1,8) = 7.57; p < 0.05). The cocaineCPP of swim-stressed prodynorphin wild-type littermate micewas not significantly different from that of swim-stressed control C57Bl/6 mice on day 6 (F_(1,10) = 0.10; p > 0.05).In contrast, prodynorphin knock-out mice exposed to 2 d swim stress developed cocaine CPP that was not significantly differentfrom the preference displayed by the unstressed prodynorphinknock-out littermates (F_(1,9) = 0.07; p > 0.05) or C57Bl/6mice (F_(1,11) = 0.003; p > 0.05) but that was significantlysmaller than their swim-stressed wild-type littermates (F_(1,10)= 10.8; p < 0.01; Fig. 7, right pair of bars). Thus, anormal prodynorphin gene was required for stress-induced potentiation of cocaine CPP.

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Figure 7. Disruption of the prodynorphin gene prevents the forced swim stress-induced potentiation of cocaine-conditioned place preference. Prodynorphin gene knock-out or wild-type littermate mice were exposed to 2 d forced swim stress or left in their home cages and then used in cocaine-conditioned place preference assays as detailed in Figure 5A and Materials and Methods. All animals demonstrated cocaine CPP by day 6 that was significantly different from matching preconditioning responses displayed on day 1. However, FST-exposed wild-type littermates demonstrated cocaine CPP on day 6 that was double the preference responses of the unstressed wild-type littermates or swim-stressed prodynorphin knock-out mice. The horizontal dashed line designates for comparison the cocaine CPP response of unstressed C57Bl/6 mice obtained on the same testing day (see Fig. 6). *Significant difference in time spent on the drug paired side after cocaine conditioning compared with baseline response; significant difference in matching cocaine CPP response of FST-exposed prodynorphin wild-type versus unstressed wild-type or FST-exposed knock-out mice; p<0.05 for all as determined by ANOVA followed by Student's t test. Bars represent n = 4–10 animals.

   Discussion

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

The principal findings of this study were that repeated swimstress resulted in immobility, analgesia, and potentiationof cocaine CPP that were blocked by nor-BNI and prodynorphingene disruption. One explanation of these results is that stressinduced the release of the endogenous dynorphins to activatethe ${kappa}$ opioid receptor to mediate these behavioral effects, althoughadditional work is required to establish this hypothesis. First,the conclusion that endogenous opioid peptides were releasedrequires a direct measure of peptide release evoked by swimstress. Second, establishing the role of ${kappa}$ opioid receptorsin mediating the response requires a more direct demonstrationof activation by swim stress. Third, although disruption ofthe prodynorphin gene has been shown to prevent expression ofthe dynorphin peptides (Sharifi et al., 2001) thought to beendogenous ligands for the ${kappa}$ opioid receptor (Chavkin et al., 1982), expression of other prodynorphin products is also blocked. Moreover, interpretation of knock-out studies must be done cautiouslybecause gene deletion can have other nonspecific effects (Troncheet al., 2002). Nevertheless, if verified by additional work,the hypothesis would have important implications, as discussedbelow.
First, the suggestion that dynorphin–KOR interactionscan contribute to stress-induced analgesia would extend ourunderstanding of the diverse mechanisms controlling nociception.Although exposure to a stressor has been demonstrated to increasedynorphin levels (Przewlocki et al., 1987; Nabeshima et al.,1992), an antinociceptive role for the dynorphin–KORsystems has been underappreciated. For example, using a single,brief exposure to a forced swim, ${kappa}$ opioid receptor knock-outmice were found to have normal SIA (Filliol et al., 2000). However, work with rats using the established 2 d procedureof repeated forced swim exposure (Porsolt et al., 1977b) suggestedthat nor-BNI could reduce immobility in the forced swim test(Pliakas et al., 2001). Drawing on this report, the presentstudy extended the forced swim test to the 2 d procedure usingmice to demonstrate the sensitivity of the stress-induced immobilityand analgesia to nor-BNI or prodynorphin gene disruption. Therepeated, prolonged nature of the stressor used in this studycould account for the differences with previous findings to implicate chronic stress-induced KOR activation by dynorphinpeptides.
Other endogenous opioid systems have also been shown to mediatethe response to stressors. When exposed to inescapable tailshock or forced swimming, rats and mice show SIA blocked bythe opioid antagonists naloxone and naltrexone (Maier et al., 1980; Mogil et al., 1996). Therefore, an alternative explanationis that the dynorphin– ${kappa}$ system acts indirectly to modulatethe actions of another endogenous opioid peptide, such as ${beta}$ -endorphin.Previous reports have noted that SIA induced after a forced-swimtest stressor was absent in mice lacking ${beta}$ -endorphin (Rubinstein et al., 1996), and concentrations of this endogenous opioidwere elevated in the periaqueductal gray region of mice demonstratingSIA after exposure to forced walking stress (Nakagawasai etal., 1999). Another alternative possibility is that a prodynorphin-derivedpeptide was released to activate either the ${delta}$ or µ opioidreceptor. Prodynorphin has been shown to be a precursor forLeu⁵enkephalin in brain (Zamir and Quirion, 1985). However,the pharmacological data we obtained suggest that nor-BNI acted selectively at the ${kappa}$ receptor. In addition, the KOR selectivityof nor-BNI is supported by studies using mouse analgesic assaysand recent functional studies using guanosine-5'-O-(3-thio)triphosphate binding (Horan et al., 1992; Thomas et al., 2002). Overall, the most parsimonious explanation of these results is that aprolonged forced swim stress induced the release of dynorphinpeptides to stimulate the ${kappa}$ opioid receptor and to mediate theanalgesia observed; however, this requires further studies.
The forced swim test is an established and predictive animalmodel for the study of depression, with antidepressants typicallyreducing the duration of the immobility exhibited (Porsoltet al., 1977a,b; Dalvi and Lucki, 1999; Lucki et al., 2001).Pliakas et al. (2001, 2002) have previously shown that nor-BNIblocked the swim stress-induced immobility and suggested that ${kappa}$ receptor antagonists may also be effective antidepressantsby blocking endogenous dynorphin function. The reduction ofimmobility caused by the disruption of the prodynorphin genefurther suggests a mediating role for dynorphin in behavioraldepression and supports the suggestion that KOR-selective antagonistsmay provide a new therapeutic approach for the treatment ofdepression.
Forced swim stress potentiated cocaine-conditioned place preference, possibly mediated by the induced release of dynorphin and theactivation of ${kappa}$ opioid receptors. Results from this study showedthat blockade of endogenous ${kappa}$ opioid systems by nor-BNI andprodynorphin gene disruption prevented the potentiation. Stress-inducedpotentiation of the conditioned place preference of rewardingdrugs has been noted previously, such as the potentiation ofmorphine CPP after foot shock stress (Will et al., 1998). However, a positive relationship between dynorphin activation of KORand the potentiation of cocaine CPP would be surprising, givenreports that KOR agonists actually reduce self-administrationof reinforcing drugs. For instance, peripheral administrationof ${kappa}$ agonists U50,488 and spiradoline produced dose-dependentdecreases in morphine and cocaine self-administration in rats,and a series of ${kappa}$ agonists dose-dependently decreased cocaineself-administration in monkeys (Glick et al., 1995; Melloand Negus, 1998). This reduction in drug self-administrationis likely attributable to a ${kappa}$ -opioid-mediated suppression ofdopaminergic signaling in the putative dopamine reward pathwaybecause in vivo microdialysis detected reductions in dopaminereleased in the nucleus accumbens (NAc) of anesthetized ratsin response to administration of ${kappa}$ agonists (Spanagel et al.,1992). This reduction in NAc dopamine release was associatedwith the activation of ${kappa}$ opioid receptors located on synapticterminals in the NAc (Acri et al., 2001). These reports predictthat endogenous ${kappa}$ opioid agonists should suppress conditionedplace preference for cocaine. One way to reconcile the observation that stress-induced release of endogenous dynorphin peptidesresulted in a potentiation of cocaine response might be topresume that the repeated stress actually depleted dynorphinto reduce a tonic ${kappa}$ system tone. However, stress-induced increasesin the tail withdrawal latency immediately before cocaine conditioningwere blocked by nor-BNI and prodynorphin gene disruption, suggestingthe presence, not absence, of dynorphin. Moreover, neither nor-BNI pretreatment nor the prodynorphin gene-disrupted mice showedan elevated cocaine CPP response, as would be expected if decreaseddynorphin levels were in fact responsible for the potentiation.Additionally, there are many important spatial and temporaldifferences between coadministration of a ${kappa}$ drug with cocaineand preactivation of the endogenous dynorphin– ${kappa}$ systemby a prolonged stress exposure preceding cocaine administration.For example, the specific activation by the stressor of thedynorphin– ${kappa}$ system in a subset of brain circuits may differ from a global activation of the ${kappa}$ system. Furthermore, if theactivation of a dynorphin– ${kappa}$ circuit contributes to thestress response, cocaine might have an enhanced rewarding valuebecause it may counteract the dynorphin-mediated stress response.This has been recently demonstrated behaviorally, in whichrats exposed to chronic, unpredictable stress demonstrateda leftward shift in the dose–response relationship of cocaine in CPP and locomotor activity testing (Haile et al.,2001).
Not only is the conditioned place preference test an assay ofthe rewarding properties of a stimulus, it is also a learningtask requiring that the animal form an association betweenthe rewarding drug and the compartment-specific cues (Carret al., 1989). Thus, the potentiation of cocaine CPP observedin this study could have resulted from an enhancement of theacute effects of cocaine or by affecting a step in the learningprocess. Further analysis of the cellular and molecular mechanism of the nor-BNI-sensitive and prodynorphin-dependent potentiationis required to determine whether dynorphin activation of ${kappa}$ opioidreceptors affects the acute response to cocaine or has a moregeneral effect on learning mechanisms. For example, an acuteenhancement of the cocaine response might result from a synergisticaction of the dynorphin– ${kappa}$ system or an effect on the cocainesensitization processes. Examination of the effects of stress-inducedrelease of dynorphin peptides in the brain would help address this question.
In conclusion, the mediation of swim stress-induced behaviorswas shown to be sensitive to nor-BNI pretreatment or prodynorphingene disruption, suggesting that stress induced a release ofdynorphin to activate the ${kappa}$ opioid receptor. The findings furtherour understanding of the neurobiological mechanisms underlyingthe response to stress and illuminate a possible ${kappa}$ opioid connectionamong chronic stress, depression, and drug abuse. Moreover, because stress has been demonstrated to increase both the rewardingpotential and self-administration of drugs of abuse, the demonstrationof endogenous ${kappa}$ opioid involvement might lead to new therapeuticapproaches to the problems of depression and drug abuse.

   Footnotes

Received Jan. 27, 2003; revised May. 5, 2003; accepted May. 5, 2003.
The work was supported by United States Public Health Servicegrants RO1-DA11672, PO1-DA15916, and T32-DA07278 from the NationalInstitute on Drug Abuse. We thank Dr. Ilene Bernstein for criticalreading and suggestions on this manuscript. Dr. Uwe Hochgeschwendergenerously provided the prodynorphin knock-out mice. SumitSud performed the mouse genotyping. Theodore A. Chavkin helpedperform some of the behavioral assays.
Correspondence should be addressed to Dr. Charles Chavkin, Departmentof Pharmacology, Box 357280, University of Washington, Seattle,WA 98195-7280. E-mail: cchavkin{at}u.washington.edu.
Copyright © 2003 Society for Neuroscience 0270-6474/03/235674-10$15.00/0

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Materials and Methods
Results
Discussion
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