Neuropharmacology50(2006)788e806 www.elsevier.com/locate/neuropharm Influence of the anabolic-androgenic steroid nandrolone on cannabinoid dependence Evelyne Ce´le´riera, Therese Ahdepil b, Helena Wikanderb, Fernando Berrendero a, Fred Nybergb, Rafael Maldonado a,* aLaboratoriofNeurofarmacologia,FacultatdeCie´nciesdelaSalutidelaVida,UniversitatPompeuFabra, C/DoctorAiguader80,08003Barcelona,Spain bDepartmentofPharmaceuticalBiosciences,UniversityofUppsala,Box591Biomedicum,S75124Uppsala,Sweden Received8April2005;receivedinrevisedform29November2005;accepted29November2005 Abstract Theidentificationofthepossiblefactorsthatmightenhancetheriskofdevelopingdrugaddictionandrelatedmotivationaldisordersiscrucial to reduce the prevalence of these problems. Here, we examined in micewhether the exposure to the anabolic-androgenic steroid nandrolone wouldaffect thepharmacological and motivational effects inducedby D9-tetrahydrocannabinol (THC), the principalpsychoactive component of Cannabis sativa. Mice received nandrolone using pre-exposure (during 14days before THC treatment) or co-administration (1h before eachTHCinjection)procedures.Bothnandrolonetreatmentsdidnotmodifytheacuteantinociceptive,hypothermicandhypolocomotoreffects of THC or the developmentof tolerance after chronic THC administration. Nandrolone pre-exposure blocked THC- and food-induced condi- tionedplacepreferenceandincreasedthesomaticmanifestationsofTHCwithdrawalprecipitatedbytheCB1cannabinoidantagonistrimona- bant (SR141617A). The aversive effects of THC were not changed by nandrolone. Furthermore, nandrolone pre-exposure attenuated the anxiolytic-likeeffectsofalowdoseofTHCwithoutalteringtheanxiogenic-likeeffectsofahighdoseinthelit/darkbox,openfieldandelevated plus-maze.BiochemicalexperimentsshowedthatchronicnandrolonetreatmentdidnotmodifyCB1receptorbindingandGTP-bindingprotein activationinthecaudate-putamenandcerebellum.Takentogether,ourresultssuggestthatchronicnandrolonetreatmentaltersbehaviouralre- sponsesrelated to cannabinoidaddictive properties. (cid:1)2005Elsevier Ltd.Allrightsreserved. Keywords:Anabolic-androgenicsteroid;Nandrolone;THC;Dependence;Anxiety;Mice 1. Introduction (AAS),usedasdopingsubstances,asariskfactorforthecon- sumption of drugs of abuse such as cannabis. Considerable efforts are now devoted to the study of risk Derivates from Cannabis sativa, whose main psychoactive factors that may increase individual vulnerability to drugs of constituent is the D9-tetrahydrocannabinol (THC) (Mechoulam abuse. An important factor that could enhance the risk for etal.,1970),are today the most consumed illicit drugs world- an addictive process and motivational related disorders is the wide (Smart and Ogborne, 2000). Cannabinoid effects are exposure to pharmacological compounds able to modify the mediatedbytheactivationoftworeceptors,theCB1cannabi- physiological equilibrium of the rewarding system (Koob noid receptor highly abundant in the central nervous system, and Le Moal, 2001). The purpose of the present study was and the CB2 receptor, mainly located in the cells of the to investigate the effects of anabolic-androgenic steroids immune system (Ameri, 1999). The cannabinoid system is closely related to several neurobiological pathways involved in motivation, mood and addictive behaviours, particularly the dopaminergic and the opioid system (for reviews, see Manzanares et al., 1999; Maldonado and Rodr´ıguez de * Correspondingauthor.Tel.:þ34935422845;fax:þ34935422802. E-mailaddress:[email protected](R.Maldonado). Fonseca). Accordingly, cannabinoids have been reported to 0028-3908/$-seefrontmatter(cid:1)2005ElsevierLtd.Allrightsreserved. doi:10.1016/j.neuropharm.2005.11.017 E.Ce´le´rieretal./Neuropharmacology50(2006)788e806 789 produce behavioural and biochemical changes in animals treatmentwithTHCwereevaluated.Inordertomimichuman similar to other drugs of abuse and leading to dependence abuseregimes,supraphysiologicdosesofnandroloneweread- (Maldonado and Rodr´ıguez de Fonseca, 2002). However, ministeredusingtwodifferentprotocols,i.e.co-administration one important aspect of marijuana activity is the complexity during THC treatment and pre-exposure before THC of evoked emotional/affective responses and the possibility treatment. of dual euphoric-dysphoric effects (Halikas et al., 1985). In- deed,reinforcingandaversiveaswellasanxiolyticandanxio- 2.Methods genic effects have been reported after the administration of THC and other cannabinoid agonists (Chaperon and Thie´bot, 2.1.Animals 1999; Ghozland et al., 2002; Berrendero and Maldonado, 2002). Albino male CD-1 mice (CRIFFA, France) weighing 20e22g were housed five per cages and maintained at a controlled temperature AAS are synthetic derivates of testosterone widely used in (21(cid:1)1(cid:2)C)andhumidity(55(cid:1)10%)environment.Themiceweregivenac- theclinicasandrogen replacementtherapy andaschemother- cesstofoodandwateradlibitum.Lightingwasmaintainedat12-hcycles(on apy for certain types of cancer (Wilson and Griffin, 1980). at7a.m.andoffat7p.m.).Alltheexperimentswereperformedduringthe During the last five decades, AAS has been used at doses lightphaseofthedark/lightcycle.Theanimalswerehabituatedtotheexper- 10e100 times the therapeutic range by many athletes and imentalroomandhandledfor1weekbeforethestartoftheexperiments.All animalproceduresmettheguidelinesoftheNationalInstituteofHealthde- bodybuilders to enhance their physical performance, increase tailedinthe‘‘GuidefortheCareanduseofLaboratoryAnimals’’,theEuro- muscle mass and intensify training regimens (Wilson, 1988; peanCommunitiesdirective86/609/EECregulatinganimalresearchandwere Lukas, 1993; Yesalis and Bahrke, 1995). The chronic use of approvedbytheLocalEthicalCommittees.Allexperimentswereperformed highdosesofAAShasbeenreportedtocauseseveralphysical withtheinvestigatorsbeingblindtothetreatmentconditions. andpsychologicalside-effectssuchasliverdysfunction,coro- naryheartdisease,reproductivedysfunction,acne,depression, 2.2.Drugs personality changes and aggressive behaviour (Williamson and Young, 1992; Pope and Katz, 1994; Bahrke et al., THC and the AAS nandrolone decanoate were purchased from Sigma (Poole, UK). The selective CB1 cannabinoid receptor antagonist 1996). Interestingly, a concurrent abuse of AAS has also SR141617A (rimonabant) was generously provided by Sanofi Research been reported among addicts and others not connected to (France).Nandrolonewasdissolvedinvehicle(10%ethanol/10%cremophor sports (DuRant etal.,1993;Lukas, 1993;Yesalis andBahrke, EL/80% distilled water) and injected intramuscularly (i.m.) in a volume of 1995; Kindlundh et al., 1999). Several studies have suggested 2ml/gbodyweight.THCwasdissolvedinvehicle(5%ethanol/5%cremophor theassociationbetweenuseofAASandconsumptionofalco- EL/90% distilled water) and injected intraperitoneally (i.p.) in a volume of 10ml/g body weight. Rimonabant was dissolved in vehicle (10% ethanol/ hol, tobacco and illicit drugs, such as cannabis, opiates, am- 10% cremophor EL/80% distilled water) and injected i.p. in a volume of phetamine and ecstasy (DuRant et al., 1993; Yesalis and 20ml/gbodyweight.Controlmicereceivedequivolumicvehicleinjections. Bahrke, 1995; Kindlundh et al., 1999; Kanayama et al., 2003). Based on these clinical and epidemiological studies, 2.3.Behaviouralexperiments AAS exposure has been proposed to serve as a ‘‘gateway’’ for the misuse of other drugs of abuse (Arvary and Pope, The effects of nandrolone treatment on acute and chronic THC effects 2000). In line with this hypothesis, recent animal studies were evaluated. Two different protocols (pre-exposure or co-administration) have shown that AAS can be self-administered by laboratory were used for nandrolone administration in an attempt to mimic conditions similartothoseusedduringhumanabuseregimes:drugintakeconcomitant animals (Ballard and Wood, 2005). AAS have also been re- tonandroloneuseordrugintakewithapastoflong-termconsumptionofnan- ported to evoke neurobiochemical and behavioural alterations drolone.Inthefirstprotocol(pre-exposure),nandrolonewaschronicallyad- related to dependence, mood and motivation in rodents espe- ministered once daily during 14days before starting THC treatment. In the cially by affecting the endogenous opioid and dopamine sys- secondprotocol(co-administration),nandrolonewasadministered1hbefore tem (Lukas, 1993; Menard et al., 1995; Clark et al., 1996; eachTHCinjection.Thei.m.injectionsofnandroloneweregivenalternatively intheleftandtherighthindlegwhenrepeatedadministrationwasrequired.A Le Greve`s et al., 1997; Johansson et al., 1997, 2000a,b; supra-therapeutic dose of nandrolone (15mg/kg) was chosen (i) because it Thiblin et al, 1999; Hallberg et al., 2000; Schlussman et al., mimicsthedoseself-administeredbyheavynandroloneabusers(Williamson 2000; Ce´le´rier et al., 2003; Kindlundh et al., 2003 and for re- andYoung,1992)and(ii)becauseithasbeenpreviouslyshowntoinducebio- view, see Clark and Henderson, 2003). chemicalchangesintheendogenousopioidanddopaminesysteminrodents Interactions between sex-steroids and the endocannabinoid (Johanssonetal.,1997). system on reproduction and endocrine responses have been well documented (Gonzalez et al., 2000; MacCarrone et al., 2.3.1.AcuteeffectsofTHC TheacuteeffectsinducedbydifferentdosesofTHC(5,10or20mg/kg, 2000; Corchero et al., 2001). However, the possible influence i.p.) on nociception, locomotion, and rectal temperature were evaluated in oftheseinteractionsonthebehaviouralresponsesmediatedby eachexperimentalgroup. the central nervous system remains to be elucidated. In the Twonociceptivetestswereused,thetail-immersionandthehot-plate.In present study, we use different behavioural models in mice thetail-immersiontest,miceweregentlyplacedinarestrainercylinder.The to evaluate the effects of the AAS nandrolone on several nociceptive threshold was assessed as described previously (Janssen et al., 1963),bymeasuringthetimetowithdrawthetailimmersedinathermostated THC behavioural responses related to its addictiveproperties. waterbath(50(cid:1)0.1(cid:2)C)(Clifton-ScientificInstruments,England),withacut Forthispurpose,theeffectsofnandroloneexposureonthebe- offlatencyof15stopreventtissuedamage.Nociceptiveresponseswerealso haviouralandsomaticresponsesinducedbyacuteandchronic measuredusingahot-plateanalgesiameter(Colombus,Ohio,USA).Aglass 790 E.Ce´le´rieretal./Neuropharmacology50(2006)788e806 cylinder(19cmhigh,19cmdiameter)wasusedtokeepthemiceontheheat- 523s; mean time spent in dotted compartment: 553s). After this session, edsurfaceoftheplate,whichwasmaintainedatatemperatureof52(cid:1)0.1(cid:2)C. micewererandomized for pairingto drug orvehicle administration andfor Thelatencyforjumpingwasevaluatedasthenociceptivethreshold,withacut- assignment to a compartment. Care was taken to ensure that treatments offtimeof240s. werecounterbalancedascloselyaspossiblebetweencompartmentstoensure Locomotor responses were evaluated using locomotor activity boxes anunbiasedprocedure.ToevaluateTHCrewardingeffects,micewereexposed (9(cid:3)20(cid:3)11cm; Imetronic, Lyon, France). The boxes contained a line of toapriminginjectionofTHC(1mg/kg)24hbeforestartingtheconditioning photocells2cmabovethefloortomeasurehorizontalmovementsandanother phase,aspreviouslyreported(ValjentandMaldonado,2000).Duringthecon- linelocated6cmabovethefloortomeasureverticalactivity(rearing).Onthe ditioningphase,micewerealternativelytreatedfor10consecutivedayswith experimentalday,themicewereindividuallyplacedintheboxesandtheam- THC(1mg/kg)orvehicle.ToevaluateTHCaversiveeffects,micewerenot bulatory,horizontal(ambulatorymovementsplussmallmovements)andver- exposedtoanypriminginjectionandwerealternativelytreatedfor10consec- ticalactivitieswererecordedduring10mininalowluminosityenvironment utive days withTHC (5mg/kg) or vehicle during the conditioning phase as (5e15lx). previouslyreported(ValjentandMaldonado,2000). Micein thedruggroup Rectaltemperaturewasmeasuredineachmouseusinganelectronicther- receivedTHCondays1,3,5,7and9intheirassignedcompartment,andve- mocoupleflexibleprobe(Panlab,Barcelona,Spain).Theprobewaslubricated hicleondays2,4,6,8and10intheoppositecompartment.Controlmicere- andplaced3cmintotherectumofthemicefor20sbeforethetemperature ceivedvehicleinbothcompartmentsalternatively.Doorsmatchingthewalls wasrecorded. ofthecompartmentallowedtheconfinementofthemicefor45minimmedi- Inordertohabituatetheanimalstothetestenvironmentandtoobtainasta- atelyafterTHCorvehicleinjection.Finally,thetestphasewasconducted24h blebaseline,tail-immersionresponsewasmeasuredfor2daysbeforetheex- afterthelastconditioningsessionexactlyas wasthepreconditioningphase, periment. On the experimental day, basal tail-immersion latency and rectal i.e.withfreeaccesstobothcompartmentsfor20min. temperaturewereevaluatedbeforestartingthetreatment.Locomotoractivity Foodrewardwasevaluatedinanimalswithlimitedaccesstofoodandha- wasevaluated20minafterTHCinjectionduring10min.Thetail-immersion bituatedtosucroseconsumptionfor5daysbeforethetest.Afixedamountof testwasperformed30minafterTHCinjectionandwasimmediatelyfollowed foodequivalentto15%ofmousebodyweightwasappliedperday,asprevi- by the hot-plate test. Rectal temperature was measured 45min after THC ouslyreported(Elmeretal.,1995).Animalsweremaintainedonthesamediet injection. throughout theexperimentalperiod.Duringthepreconditioningphase,mice wereplacedinthemiddleoftheneutralareaandtheirlocationwasrecorded for18min.Miceconditionedtofoodhadfreeaccesstoit(normalmousefood 2.3.2.TolerancetoTHCeffects plussucrose)intheconfinedcompartmentondays1,3and5,andhadnoac- Asinthepreviousexperiment,thebasaltail-immersionresponsewaseval- cesstofoodintheothercompartmentondays2,4and6.Controlanimalswere uatedfor2daysbeforethebeginningofTHCinjections.THC(20mg/kg,i.p.) alternativelyexposedtobothcompartmentsduringthisphaseandhadnoac- wasadministeredtwiceaday(10a.m.and7p.m.)during5days.Everymorn- cesstofoodintheassignedcompartment.Micewereconfinedinthecondi- ingbeforeanyTHCinjection,bodyweight,tail-immersionlatencyandrectal tioning compartments during a period of 20min. The testing phase was temperature were measured. Locomotor activity was recorded 20min after conducted24hafterthefinalconditioningsessionexactlyastheprecondition- eachmorningTHCinjectionfor10min.Tail-immersionandrectaltempera- ingphase,i.e.freeaccesstoeachcompartmentfor18min. tureweremeasured30and45min,respectively,aftereachmorningTHCin- InbothTHCandfoodexperiments,ascorewascalculatedforeachmouse jection.Thehot-platetestwasonlyperformedthefirstandlastdayofTHC asthedifferencebetweenthepost-conditioningandthepre-conditioningtime treatment(day1and5),immediatelyafterthetail-immersionexposure. spentinthedrug-pairedcompartment. 2.3.3.Rimonabant-precipitatedTHCwithdrawal 2.3.5.THCeffectsonanxiety-likeresponses Mice chronically treated with THC (20mg/kg, i.p., twice daily during The anxiolytic- and anxiogenic-like effects of THC were evaluated by 5days)fortheevaluationoftolerancetoitspharmacologicaleffectsreceived using three experimental procedures: lit/dark box, open-field and elevated anadditionalTHCmorninginjectiononday6(20mg/kg,i.p.).Fourhourslat- plus-maze.Behaviouraltestswereperformed30minafterTHCadministration. er,cannabinoidwithdrawalwasprecipitatedbyinjectionoftheselectiveCB1 Anxiolytic-likeeffectsofTHCwereinducedbyusingalowdose(0.2mg/kg), receptorantagonistrimonabant(10mg/kg,i.p.).Themicewereplacedindivid- whereasahigherdoseofTHC(7.5mg/kg)inducedtheanxiogenic-likeeffects. uallyintotestchamberstoevaluatethebehaviouralsignsofwithdrawal.The Inthelit/darkboxprocedure(Fillioletal.,2000),micewereindividually chambersconsistedoftransparentroundplasticboxes(30cmindiameterand exposed for 5min to a box consisting of a small dark compartment 50cminheight)withawhitefloor.Somaticsignsofwithdrawalwereevalu- (15(cid:3)20(cid:3)25cm)withblackfloorandwalls,dimlylit(5e10lx)connected ated15minbeforeand45minafterrimonabantchallenge.Thenumberofwet bya4cmlongtunneltoalargerlitcompartment(30(cid:3)20(cid:3)25)withwhite dogshakes,frontpawtremorsandsniffingwerecounted.Ptosiswasscored,1 floorandwalls,exposedtointenseillumination(500lx).Linesweredrawnon forappearanceand0fornon-appearance,withineach5mintimeperiod.Tak- thefloorofbothcompartmentstoallowmeasurementsoflocomotoractivity ingintoaccountalltheindividualsigns,aglobalwithdrawalscorewascalcu- bycountingthenumbersofsquares(5(cid:3)5cm)crossed.Theselinesalsodi- lated for each mouse by giving each individual sign a relative weight as videthelitcompartmentintothreeequalzones,fromthetunneltotheopposite previouslyreported(Hutchesonetal.,1998). wall,designatedasproximal,centralanddistalzones.Tostarttheexperiment, eachmousewasplacedinthedarkcompartmentfacingthelitarea.Thepa- 2.3.4.RewardingeffectsofTHCandfood rametersrecordedwerelatencyforfirstentranceintothelitarea,timespent TherewardingeffectsofTHCandfoodwereevaluatedbyusingthecon- ineachcompartment,numberofsquarescrossedineachcompartment,loco- ditionedplacepreferenceparadigm.Theplacepreferenceapparatusconsisted motoractivity(numbertotalofsquarescrossed)andnumberofentriesineach oftwodifferentcubiccompartments(15(cid:3)15(cid:3)15cm)separatedbyatrian- compartmentandintoeachzoneofthelitcompartment. gularneutralarea(15cmperside).Thetwocompartmentshadvisualandtac- Theopen-fieldconsistedofarectangulararea(70cmwide,90cmlongand tiledifferences,whereonecompartmenthaddottedwallsandroughfloorand 60cmhigh)brightlyilluminatedfromthetop(500lx).Atotalof63squares theothercompartmenthadstripedwallsandsmoothfloor.Themovementand (10(cid:3)10cm)weredrawnwithblacklinesonthewhitefloordividingthefield location of the mice were recorded by computerized monitoring software into central and peripheral areas. To start the experiment, each mouse was (Smart(cid:2) Videotrack, Panlab., Barcelona, Spain) with images relayed from placedinthecentralareaofthefield.Thefollowingeventswererecordeddur- a camera placed above the apparatus. The place preference conditioning inganobservationperiodof5min:latencyto gooutfromthe centralarea, schedule consisted of three phases. During the preconditioning phase, the numbersofsquarescrossedineacharea,numberofrearing,numberofentries mousewas placed in the middle of the neutral area and allowed to explore intothecentralareaandlocomotoractivity(totalnumberofsquarescrossed). both compartments, and the time spent in each compartment was measured Theelevatedplus-mazeconsistedoftwoarms(length30cm;width7cm) during20min.Noinitialpreferenceoraversionwasrevealedforanycompart- formingtheshapeofaplussituatedonaplatform80cmaboveground.Oneof ment in any of the experiments (mean time spent in striped compartment: thearmswasopenandtheotherclosed(14cm).Numberofentriesandtime E.Ce´le´rieretal./Neuropharmacology50(2006)788e806 791 spentintotheopenandclosedarmwererecordedduringanobservationperiod (nandrolone/vehicleandTHC/vehicletreatments).Whenrequired,thethree- of5min. wayANOVAwasfollowedbycorrespondingtwo-wayandone-wayANOVAs. Statistical analyses of data from CB1 receptor bindingand activation of 2.4.Biochemical experiments GTP-bindingproteinwereassessedbyusingtheunpairedtwo-tailedStudent’s t-test. StatisticalsignificancecriterionwasP<0.05inallcases. CB1receptorbindingandactivationofGTP-bindingproteinwasinvesti- gatedintwobrainareasrelatedtocannabinoidbehaviouralresponsesandde- pendenceinanimals:thecaudate-putamenandthecerebellum(Navarroetal., 3. Results 2001;Castan˜e´ etal.,2004).Thestudieswereperformedinmicechronically treated with nandrolone (15mg/kg) or vehicle once daily during 14days. 3.1. Effects of nandrolone exposure on acute THC On day 15, mice were decapitated and their brains were quickly removed andfrozenbyimmersionin2-methyl-butanesurroundedbydryice.Allsam- responses ples were stored at (cid:4)80(cid:2)C during a similar short period of time until pro- cessedforanalysis. Theinfluenceofnandroloneexposureontheacutepharma- cological effects of THC(5, 10, and 20mg/kg,i.p.) was eval- 2.4.1.NandroloneeffectsoncannabinoidCB1receptor uated by measuring the responses induced in nociception, binding body temperature and locomotor activity. Nandrolone TheprotocolusedwasbasicallythemethoddescribedbyHerkenhametal. (1991).Briefly,brainstructureswereincubatedfor2.5hat37(cid:2)Cinabuffer (15mg/kg, i.m.) or vehicle was administered using the two containing50mMTriswith5%bovineserumalbumin(fattyacid-free),pH different protocols: co-administration and pre-exposure. Con- 7.4,and10nM[3H]CP-55,940(PerkinElmerLifeSciences)preparedinthe trol experiments showed that nandrolone had no intrinsic same buffer, in the absence or presence of 10mM non-labelled CP-55,940 effect in any of the parameters studied when injected in (Tocris) to determine total and non-specific binding,respectively. Following combination with vehicle. this incubation, slides were washed in 50mM Tris buffer with 1% bovine serumalbumin(fattyacid-free),pH7.4,for4h(2(cid:3)2h)at0(cid:2)C,dippedin ice-colddistilledwater,thendriedunderastreamofcooldriedair.Autoradio- 3.1.1. THC antinociceptive effects gramsweregeneratedbyapposingthelabelledtissues,togetherwithautora- Chronic nandrolone pre-exposure for 14days did not sig- diographic standards ([3H]Microscales, Amersham), to tritium-sensitive film (Hyperfilm-[3H], Amersham) for a period of 10days and developed for nificantly modify THC acute antinociceptive effects in the 4minat20(cid:2)C.Developedfilmswereanalysedandquantifiedinacomputer- tail-immersion and the hot-plate test (Table 1). In the tail- izedimageanalysissystem(MCID,St.Catharines,Ontario,Canada)usingthe immersion test, significant antinociceptive effects of 10and standardcurvegeneratedfrom3Hstandards. 20mg/kg of THC were observed in both vehicle and nandro- lonepre-exposedmice.Two-wayANOVArevealedsignificant 2.4.2.NandroloneeffectsoncannabinoidCB1receptor THC effect (F(3,87)¼23.60, P<0.001), but no nandrolone activationofGTP-bindingprotein TheprotocolusedwasbasicallythemethoddescribedbySimetal.(1995). effect (F(1,87)¼1.03, NS) and no THC/nandrolone interac- Briefly, the brain structure were rinsed in assay buffer (50mM Tris, 3mM tion (F(3,87)¼1.44, NS). In the hot-plate test, significant MgCl2,0.2mMEGTA,100mMNaCl,and0.5%bovineserumalbuminfatty antinociceptive effects of 10 and 20mg/kg were found inve- acid-free,pH7.4)at25(cid:2)Cfor10min,thenpretreatedfor15minwithanex- hicle, but not in nandrolone pre-exposed mice. Two-way cessconcentration(2mM)ofGDP(SigmaChemicalCo.,Madrid,Spain)inas- ANOVA showed significant THC effect (F(3,87)¼8.22, say buffer containing 0.04nM [35S]GTPgS (Amersham), 2mM GDP, and 5mM WIN 55 212-2 (Sigma Chemical Co., Madrid, Spain). Basal activity P<0.001), no nandrolone effect (F(1,87)¼0.07, NS) and wasassessedintheabsenceofagonist,whereasnon-specificbindingwasmea- no THC/nandrolone interaction (F(3,87)¼1.18, NS). suredinthepresenceof10mMunlabelledGTPgS.Sliceswererinsedtwicein Similarly, nandrolone co-administration did not modify 50mMTrisbuffer,pH7.4,at4(cid:2)Canddeionizedonceinwater,thendriedun- THC acute antinociceptive effects as evaluated in the tail- derastreamofcooldryair.Autoradiogramsweregeneratedbyapposingthe immersion and the hot-plate test (Table 1). In the tail-immer- labelledtissuestofilm(KodakBiomaxMR)foraperiodof2daysanddevel- oped for 4min at 20(cid:2)C. Developed films were analysed and quantified in sion test, significant antinociceptive effects of 5, 10 and a computerized image analysis system (MCID, St. Catharines, Ontario, 20mg/kg of THC were observed in both vehicle and nandro- Canada). lone co-treated mice. Two-way ANOVA revealed significant THCeffect(F(3,105)¼26.11,P<0.001),butnonandrolone 2.5.Statistical analysis effect (F(1,105)¼0.03, NS) nor THC/nandrolone interaction (F(3,105)¼0.40,NS).Inthehot-platetest,significantantino- The data obtained for acute THC pharmacological responses, food and ciceptiveeffectsof10and20mg/kgofTHCwereobservedin THC effects in the place conditioning paradigm, rimonabant-precipitated both vehicle and nandrolone co-treated mice. Two-way THCwithdrawalandTHCeffectsonanxiety-likeresponsewereanalysedby usingatwo-wayANOVAwithnandrolone/vehicleandTHC/vehicletreatment ANOVA revealed significant THC effect (F(3,104)¼11.25, asfactorsofvariation.One-wayANOVAwasusedtorevealthemainTHCor P<0.001), but no nandrolone effect (F(1,104)¼3.81, NS) nandroloneeffects,followedwhenappropriatebycorrespondingposthoccom- or THC/nandrolone interaction (F(3,104)¼0.22, NS). parisons(Dunnett’stest)toindicategroupssignificantlydifferentfromcontrol. Inaddition,individualcomparisonsoftimespentinthedrug-pairedcompart- mentduringpreconditioningandtestphasesweremadeinplaceconditioning 3.1.2. THC hypothermic effects experiments in each experimental group by using the paired two-tailed Chronic nandrolone pre-exposure during 14days and nan- Student’st-test. droloneco-administrationdidnotmodifyTHCacutehypother- DatafromthestudyoftolerancetoTHCantinociception,hypothermiaand miceffects(Table1).Similarsignificanthypothermiceffectsof hypolocomotoreffectswereanalysedbyusingathree-wayANOVAwithtime as the within subjects factor of variation and two between subjects factors THC were observed in vehicle and nandrolone exposed mice 792 E.Ce´le´rieretal./Neuropharmacology50(2006)788e806 Table1 EffectsofnandroloneontheacutepharmacologicaleffectsofD9-tetrahydrocannabinol(THC) THCdoses Tail-withdrawal Hot-plate Rectal Totalhorizontal latency(s) jumping(s) temperature locomotoractivity ((cid:2)C) (counts) Pre-exposure 0mg/kg VEH 2.51(cid:1)0.12 47(cid:1)4 1.13(cid:1)0.59 265(cid:1)21 ND 2.50(cid:1)0.17 53(cid:1)12 1.81(cid:1)0.65 230(cid:1)23 5mg/kg VEH 2.70(cid:1)0.11 57(cid:1)5 (cid:4)1.46(cid:1)0.86 258(cid:1)25 ND 2.55(cid:1)0.16 66(cid:1)8 (cid:4)1.56(cid:1)0.74* 204(cid:1)32 10mg/kg VEH 4.84(cid:1)0.36** 108(cid:1)15** (cid:4)5.56(cid:1)1.08** 96(cid:1)12** ND 3.73(cid:1)0.46* 92(cid:1)9 (cid:4)3.32(cid:1)1.04** 149(cid:1)23* 20mg/kg VEH 5.38(cid:1)0.37** 99(cid:1)14** (cid:4)7.52(cid:1)0.92** 104(cid:1)12** ND 5.52(cid:1)0.36** 100(cid:1)16 (cid:4)7.87(cid:1)0.84** 94(cid:1)9** Co-administration 0mg/kg VEH 2.22(cid:1)0.06 48(cid:1)3 1.24(cid:1)0.34 206(cid:1)13 ND 2.48(cid:1)0.13 58(cid:1)5 0.78(cid:1)0.26 213(cid:1)13 5mg/kg VEH 3.76(cid:1)0.50** 72(cid:1)11 (cid:4)3.14(cid:1)1.29** 135(cid:1)35* ND 3.96(cid:1)0.39** 107(cid:1)17 (cid:4)4.83(cid:1)0.93** 106(cid:1)23** 10mg/kg VEH 4.89(cid:1)0.39** 107(cid:1)12** (cid:4)5.38(cid:1)0.86** 66(cid:1)11** ND 4.39(cid:1)0.41** 124(cid:1)16** (cid:4)5.53(cid:1)0.90** 83(cid:1)17** 20mg/kg VEH 5.44(cid:1)0.44** 113(cid:1)19** (cid:4)6.71(cid:1)1.33** 97(cid:1)18** ND 5.45(cid:1)0.60** 131(cid:1)20** (cid:4)7.87(cid:1)1.42** 86(cid:1)16** VEH,vehicle;ND,nandrlone.*P<0.05,**P<0.05;Dunnet’stest,comparisonwithcontrolgroupreceivingvehicle. underbothprotocols.Inthepre-exposureexperiment,two-way was administered using the two different protocols, i.e., ANOVA revealed significant THC effect (F(3,87)¼38.40, co-administration and pre-exposure. P<0.001), but no nandrolone effect (F(1,87)¼0.92, NS) or THC/nandrolone interaction (F(3,87)¼1.18, NS). In the 3.2.1. Tolerance to THC antinociceptive effects co-administration experiment, two-wayANOVA revealedsig- Nandrolone pre-exposure and co-administration did not nificantTHCeffect(F(3,105)¼32.39,P<0.001),butnonan- produceanychangeinthedevelopmentoftolerancetoantino- drolone effect (F(1,105)¼1.15, NS) or THC/nandrolone ciception induced by chronic THC in the tail immersion interaction(F(3,105)¼0.13,NS). (Fig. 1) and the hot-plate (data not shown) tests. Both proto- cols of nandrolone treatment did not modify the nociceptive 3.1.3. THC hypolocomotor effects responses in these two tests in vehicle-treated mice. In THC Chronic nandrolone pre-exposure during 14days and nan- chronically treated mice, tolerance to the antinociceptive droloneco-administrationdidnotinfluenceTHCacuteeffects effectsofTHCinthetail-immersionandhot-platetestsdevel- onhorizontallocomotoractivity(Table1).Significanthypolo- oped similarly in both vehicle and nandrolone pre-exposed comotoreffectsofTHCwereobservedinvehicle-pre-exposed mice. Similar results were obtained in THC mice co-treated mice and nandrolone pre-exposed mice under both protocols. with nandrolone. (see three-way ANOVA in Table 2). In the pre-exposure experiment, two-way ANOVA revealed significant THC effect (F(3,92)¼26.67, P<0.001), but no 3.2.2. Tolerance to THC hypothermic effects significant effect of nandrolone (F(1,92)¼0.66, NS) or Nandrolone pre-exposure and co-administration did not THC/nandrolone interaction (F(3,92)¼0.07, NS). In the co- produce any change in the development of tolerance to the administration experiment, two-way ANOVA also revealed hypothermic effects of THC (Fig. 1). Both protocols of nan- significant THC effect (F(3,78)¼26.06, P<0.001), but no drolone treatment did not modify body temperature in vehi- significant effect of nandrolone (F(1,78)¼0.09, NS) or cle-treated mice. In THC chronically treated mice, tolerance THC/nandrolone interaction (F(3,78)¼0.52, NS). to the hypothermic effects of THC developed similarly in bothvehicleandnandrolonepre-exposedmice.Similarresults 3.2.Effectsofnandrolonetreatmentsonthedevelopment were obtained in THC mice co-treated with nandrolone (see of tolerance to THC effects three-way ANOVA in Table 2). Changes in nociceptive thresholds, rectal temperature and 3.2.3. Tolerance to THC hypolocomotor effects locomotor activity were evaluated every day during chronic Nandrolone pre-exposure and co-administration did not administration of THC (20mg/kg, i.p., twice a day for produceanychangeinthedevelopmentoftolerancetothehy- 5days) or vehicle. Nandrolone (15mg/kg, i.m.) or vehicle plocomotor effects of THC (Fig. 1). Both protocols of E.Ce´le´rieretal./Neuropharmacology50(2006)788e806 793 A: Nandrolone pre-exposure B: Nandrolone co-administration VEH-VEH 7 7 ND-VEH ** ** VEH-THC awal (s) 456 ** **** ** ** * 456 ** **** ** ** *N*D-THC hdr 3 ** ** 3 ** ** wit 2 2 ail 1 1 T 0 0 0 1 2 3 4 5 0 1 2 3 4 5 Days Days 4 4 mperaturesal value) --4202 ** *** --4202 **** **** * ea ectal t% of b --86 ** ** --86 ** R( -10 -10 ** ** -12 -12 1 2 3 4 5 1 2 3 4 5 Days Days 300 ** 300 vity 250 250 ** actis) 200 ** 200 ** motor (count 110500 *** ** ** ** 110500 * ** o * c ** o 50 50 ** L 0 0 0 1 2 3 4 5 0 1 2 3 4 5 Days Days Fig.1.EffectsofnandrolonetreatmentsonthedevelopmentoftolerancetoTHC-inducedantinociceptive,hypothermicandhypolocomotoreffects.THC(20mg/ kg,i.p.)waschronicallyadministeredtwiceadayduring5days.Tolerancedevelopmentwasevaluatedinmicepre-exposed(A)toorco-treated(B)withnan- drolone(ND)orvehicle(VEH).Locomotoractivitywasrecorded20minaftereachmorningTHCinjectionduring10min.Antinociceptiveeffectswereevaluated 30minaftereachmorningTHCinjectionbyusingthetail-immersiontest.Therectaltemperaturewasmeasuredjustbeforeand45minaftereachmorningTHC injection.Thenumberofmicepergroupinthenandrolonepre-exposureexperimentswas10e13.Thenumberofmicepergroupinthenandroloneco-treatment experimentswas11e15.Dataareexpressedasmean(cid:1)SEM.*P<0.05,**P<0.01(one-wayANOVA,comparisonwiththerespectivebasalvalue). nandrolonetreatmentdidnotmodifylocomotoractivityinve- injection of rimonabant in vehicle control mice co-treated or hicle-treatedmice.InTHCchronicallytreatedmice,tolerance pre-exposed to nandrolone. Rimonabant injection in chronic to the hypolocomotor effects of THC developed similarly in THC treated mice with vehicle pre-exposure precipitated bothvehicleandnandrolonepre-exposedmice.Similarresults a withdrawal syndrome manifested by the presence of wet were obtained in THC mice co-treated with nandrolone (see dog shake (one-way ANOVA, F(1,24)¼15.07, P<0.01), three-way ANOVA in Table 2). front paw tremor (F(1,24)¼33.09, P<0.001), ptosis (F(1,24)¼29.25, P<0.001) and a significant global with- 3.3. Effects of nandrolone treatments on drawal score (F(1,24)¼62.53, P<0.01), as revealed by rimonabant-precipitated THC withdrawal syndrome one-way ANOVA (Fig. 2). The intensity of THC withdrawal was increased in nandrolone pre-exposed mice (Fig. 2) (see THC withdrawal was precipitated by the administration of two-way ANOVA in Table 3). One-way ANOVA revealed the selective CB1 receptor antagonist, rimonabant (10mg/kg a significant increase of sniffing (F(1,21)¼4,61, P<0.05) i.p.), in mice receiving chronic administration of THC and global withdrawal score (F(1,21)¼5.12, P<0.05) in (20mg/kg, i.p., twice daily during 6days) or vehicle. No sig- micepre-exposedtonandroloneincomparisonwiththegroup nificant signs of withdrawal were observed in any group of pre-exposed to vehicle. mice during the 15min behavioural observation performed Incontrast,theintensityofTHCwithdrawalwasnotmodified beforetheadministrationofrimonabant.Moreover,nobehav- by the co-administration of nandrolone (Fig. 2). Rimonabant- ioural manifestations of withdrawal were observed after the precipitated THC withdrawal was manifested in vehicle 794 E.Ce´le´rieretal./Neuropharmacology50(2006)788e806 Table2 3.4.1. THC rewarding properties NandroloneeffectsontolerancetoD9-tetrahydrocannabinol(THC)pharmaco- In the nandrolone pre-exposure experiment, two-way AN- logicaleffects OVA revealed no significant THC (F(1,56)¼1.48, NS) and Nandrolonepre-exposure Nandroloneco-administration nandrolone (F(1,56)¼0.80, NS) effects, but significant F P F P THC/nandrolone interaction (F(1,56)¼4.64, P<0.05). Re- THCantinociceptiveeffects(tail-flicktest) wardingeffectsofTHC(1mg/kg)wereobservedinmicepre- THC (1,43)¼63.36 <0.001 (1,48)¼101.25 <0.001 viously receiving intramuscular vehicle for 14days (Fig. 3A) Time (4,172)¼15.11 <0.001 (4,192)¼15.39 <0.001 as revealed by the score values (one-way ANOVA; ND (1,43)¼0.03 NS (1,48)¼0.36 NS F(1,29)¼5.37, P<0.05) and the increase in the time spent THC(cid:3)time (4,172)¼14.41 <0.001 (4,192)¼16.29 <0.001 inthedrug-pairedcompartmentduringthetestvs.theprecon- THC(cid:3)ND (1,43)¼0.14 NS (1,48)¼0.22 NS ND(cid:3)time (4,172)¼0.08 NS (4,192)¼0.09 NS ditioning phase (Student’s t-test, t(1,14)¼(cid:4)3.27, P<0.01). THC(cid:3)ND(cid:3) (4,172)¼1.02 NS (4,192)¼0.13 NS On the contrary, THC did not induce rewarding effects in time mice pre-exposed to nandrolone, as revealed by the similar timespentinthedrug-pairedcompartment duringtheprecon- THCantinociceptiveeffects(hot-platetest) ditioningandtestphase(Student’st-test,t(1,14)¼0.193,NS) THC (1.43)¼7.10 <0.05 (1,47)¼13.48 <0.01 Time (4,172)¼42.53 <0.001 (4,188)¼163.17 <0.001 and the scorevalues (one-way ANOVA, F(1,29)¼0.47, NS). ND (1,43)¼0.36 NS (1,47)¼2.48 NS Significant differences were also observed in THC-treated THC(cid:3)time (4,172)¼7.58 <0.01 (4,188)¼3.17 NS mice when compared with vehicle and nandrolone pre- THC(cid:3)ND (1,43)¼0.19 NS (1,47)¼0.35 NS exposed mice (one-way ANOVA, F(1,29)¼4.87, P<0.05). ND(cid:3)time (4,172)¼0.73 NS (4,188)¼0.01 NS The influence of chronic nandrolone co-administration on THC(cid:3)ND(cid:3) (4,172)¼1.04 NS (4,188)¼0.02 NS time THCrewardingeffects could notbeassessed dueto the inter- ference of the previous intramuscular injection. Two-way THChypothermiceffects ANOVA revealed no significant THC (F(1,53)¼1.81, NS) THC (1.43)¼74.85 <0.001 (1,47)¼87.73 <0.001 and nandrolone (F(1,53)¼1.20, NS) effects, and no signifi- Time (4,172)¼25.10 <0.001 (4,188)¼21.74 <0.001 cant THC/nandrolone interaction (F(1,53)¼0.01, NS). THC ND (1,43)¼0.04 NS (1,47)¼6.31 <0.05 THC(cid:3)time (4,172)¼36.79 <0.01 (4,188)¼21.48 <0.001 (1mg/kg, s.c.) did not induce conditioned place preference THC(cid:3)ND (1,43)¼2.61 NS (1,47)¼1.07 NS when mice received an intramuscular injection of vehicle or ND(cid:3)time (4,172)¼0.76 NS (4,188)¼0.44 NS nandrolone 1h before the conditioning session (Fig. 3B), as THC(cid:3)ND(cid:3) (4,172)¼1.55 NS (4,188)¼1.06 NS revealedbythesimilartimespentinthedrug-pairedcompart- time mentonthepreconditioningandtestphaseintheTHC-treated THChypothermiceffects mice(Student’st-test,t(1,11)¼0.42,NS,inthevehiclegroup THC (1.43)¼46.84 <0.001 (1,47)¼28.36 <0.001 andt(1,11)¼0.68,NSinthenandrolonegroup)andscoreval- Time (4,172)¼41.88 <0.001 (4,188)¼36.01 <0.001 ues (one-way ANOVA, F(1,25)¼0.37, NS, in the vehicle ND (1,43)¼1.13 NS (1,47)¼0.56 NS group and one-way ANOVA, F(1,25)¼0.19, NS, in the nan- THC(cid:3)time (4,172)¼7.8 <0.001 (4,188)¼5.60 <0.001 drolone group). On the contrary, a significant conditioned THC(cid:3)ND (1,43)¼3.62 NS (1,47)¼0.21 NS ND(cid:3)time (4,172)¼0.51 NS (4,188)¼1.75 NS place preference was observed in a positive control group of THC(cid:3)ND(cid:3) (4,172)¼1.63 NS (4,188)¼0.31 NS mice receiving THC alone under the same experimental con- time ditions without any intramuscular administration, as revealed Three-wayANOVAwithTHCandnandrolone(ND)(betweensubjects)and by the increase in the time spent in the drug-paired compart- time(withinsubjects)asfactorsofvariations.NS,notsignificant. ment during the test phase (Student’s t-test, t(1,9)¼(cid:4)2.39, P<0.05), and the score values (one-way ANOVA, co-administrated mice by the presence of wet dog shake (one- F(1,25)¼5.06, P<0.05). way ANOVA, F(1,25)¼30.09, P<0.001), front paw tremor (F(1,25)¼25.76, P<0.001), sniffing (F(1,25)¼4.72, P< 3.4.2. THC aversive properties 0.05), ptosis (F(1,25)¼40.76, P<0.001) and a significantly In the nandrolone pre-exposure experiment, two-way globalwithdrawalscore(F(1,25)¼40.94,P<0.01),asrevealed ANOVA revealed significant THC effect (F(1,51)¼13.68, by one-way ANOVA. Two-way ANOVA (Table 3) revealed P<0.01), but no effect of nandrolone (F(1,51)¼0.76, NS) similar manifestations of all the withdrawal signs in chronic or THC/nandrolone interaction (F(1,51)¼0.05, NS). Signifi- THCtreatedmiceco-administeredwithvehicleornandrolone. cant aversive effects of THC (5mg/kg) were observed in mice previously receiving intramuscular vehicle for 14days (Fig. 3A), as revealed by the score values (one-way ANOVA, 3.4.EffectsofnandrolonetreatmentsonTHCrewarding F(1,27)¼8.87, P<0.01) and the decrease in the time spent and aversive properties inthedrug-pairedcompartmentduringthetestvs.theprecon- ditioning phase (Student’s t-test, t(1,12)¼(cid:4)3.25, P<0.01). The influence of nandrolone exposure on THC rewarding Nandrolone pre-exposure did not modify THC aversive ef- andaversiveeffectswasinvestigatedbyusingtheplacecondi- fects, as revealed by the score values (one-way ANOVA, tioned paradigm (Fig. 3). F(1,27)¼0.41, NS) and the decrease in the time spent in E.Ce´le´rieretal./Neuropharmacology50(2006)788e806 795 A: Nandrolone pre-exposure kes 60 mor ** Wet dog sha 24000 VEH *T*H*C* Front paw tre 1200000 VEH *T*HC al score 111024000 VNEDH *#* w g 12 *#* 6 **** withdra 6800 ** Sniffin 48 Ptosis 24 Global 2400 0 0 0 VEH THC VEH THC VEH THC B: Nandrolone co-administration kes 60 **** mor **** Wet dog sha 24000 VEH THC Front paw tre 1200000 VEH THC al score 111024000 VNEDH ** ** w a 80 12 6 **** hdr 60 Sniffing 48 *** Ptosis 24 obal wit 2400 Gl 0 0 0 VEH THC VEH THC VEH THC Fig.2.Effectsofnandrolonetreatmentsontherimonabant-precipitatedTHCwithdrawalsyndrome.AbstinenceisprecipitatedbytheadministrationoftheCB1 receptorantagonistrimonabant(10mg/kg,i.p.)inmicereceivingachronictreatmentofTHC(20mg/kg,i.p.),twiceadayduring6days.Micewerepre-exposed (A)toorco-treated(B)withnandrolone(ND)orvehicle(VEH).Somaticsignsofwithdrawalwereobservedfor45minimmediatelyaftertherimonabantad- ministration.Theglobalwithdrawalscorewascalculatedforeachanimalbygivingeachindividualsigna relativeweight.Thenumberofmicepergroupin thenandrolonepre-exposureexperimentswas10e13.Thenumberofmicepergroupinthenandroloneco-treatmentexperimentswas10e15.Dataareexpressed asmean(cid:1)SEM.*P<0.05,**P<0.01(one-wayANOVA,comparisonwiththerespectivebasalvalue)and#P<0.05(one-wayANOVA,VEH-vsND-treated mice). the drug-paired compartment during the test vs. precondition- couldnotbeassessedduetotheinterferenceofthepreviousin- ing phase (Student’s t-test, t(1,12)¼4.55, P<0.01). No dif- tramuscular injection. Two-way ANOVA revealed no signifi- ferences were observed in the aversive effects of THC when cant THC (F(1,65)¼2.19, NS) and nandrolone (F(1,65)¼ compared vehicle and nandrolone pre-exposed mice (one- 0.27, NS) effects, and no significant THC/nandrolone interac- way ANOVA, F(1,25)¼0.31, NS). tion(F(1,65)¼1.17,NS).THC(5mg/kg,s.c.)didnotinduce Similartothepreviousexperiment,theinfluenceofchronic conditionedplaceaversionwhenmicereceivedanintramuscu- nandrolone co-administration on THC aversive properties lar injection of vehicle or nandrolone 1h before the Table3 Nandroloneeffectsonrimonabant-precipitatedD9-tetrahydrocannabinol(THC)withdrawal THC P ND P Interaction P Nandrolonepre-exposure Wetdogshakes (1,43)¼43.24 <0.001 (1,43)¼1.55 NS (1,43)¼2.99 NS Frontpawtremor (1,43)¼68.20 <0.001 (1,43)¼4.91 <0.05 (1,43)¼4.58 <0.05 Sniffing (1,43)¼12.31 <0.01 (1,43)¼5.28 <0.05 (1,43)¼5.28 <0.05 Ptosis (1,43)¼66.32 <0.001 (1,43)¼3.94 NS (1,43)¼0.01 NS Globalwithdrawalscore (1,43)¼109.13 <0.001 (1,43)¼6.31 <0.05 (1,43)¼5.49 <0.05 Nandroloneco-administration Wetdogshakes (1,46)¼47.82 <0.001 (1,46)¼0.04 NS (1,46)¼0.07 NS Frontpawtremor (1,46)¼41.15 <0.001 (1,46)¼0.07 NS (1,46)¼0.10 NS Sniffing (1,46)¼5.81 <0.05 (1,46)¼3.01 NS (1,46)¼3.01 NS Ptosis (1,46)¼46.17 <0.001 (1,46)¼0.16 NS (1,46)¼1.08 NS Globalwithdrawalscore (1,46)¼60.45 <0.001 (1,46)¼0.09 NS (1,46)¼0.12 NS Two-wayANOVAwithTHCandnandrolone(ND)(betweensubjects)asfactorsofvariations.NS,notsignificant. 796 E.Ce´le´rieretal./Neuropharmacology50(2006)788e806 A: Nandrolone pre-exposure B: Nandrolone co-administration * THC (1 mg/kg) # 120 * 120 80 80 40 40 e or 0 0 c S -40 -40 -80 -80 VEH ND VEH ND VEH ND VEH ND _ -120 VEH VEH THC THC -120 VEH VEH THC THC THC THC (5mg/kg) 120 120 80 80 40 40 e cor 0 0 S -40 -40 -80 -80 -120 * -120 ** VEH ND VEH ND VEH ND VEH ND *_ VEH VEH THC THC VEH VEH THC THC THC Food # * 160 160 * 120 120 80 80 e or 40 40 c S 0 0 _ VEH ND VEH ND VEH ND VEH ND -40 _ _ FD FD -40 _ _ FD FD FD -80 -80 Fig.3.EffectsofnandrolonetreatmentsonrewardingandaversivepropertiesofTHCandfood.Thedosesof1and5mg/kg(i.p.)ofTHCwereusedtoinduce conditionedplacepreferenceandaversion,respectively,inmicepre-exposedto(A)orco-treated(B)withnandrolone(ND)orvehicle(VEH).Food(FD)-induced conditionalplacepreferencewasassessedonlightlyfooddeprivedmice.Ascorewascalculatedforeachmouseasthedifferencebetweenthepost-conditioning and the pre-conditioning time spent in the drug- or food-paired compartment. The number of mice per group was 10e15. *P<0.05, **P<0.01 (one-way ANOVA,comparisonwiththerespectivebasalvalue)and#P<0.05(one-wayANOVA,VEH-vsND-treatedmice). conditioningsession(Fig.3B),asrevealedbythesimilartime aversion was observed in a positive control group receiving spentinthedrug-pairedcompartmentduringtheprecondition- THC alone under the same experimental conditions without ingandtestphase(Student’st-test,t(1,14)¼(cid:4)0.60,NS,inthe any intramuscular administration, as revealed by the increase vehiclegroupandt(1,14)¼0.88,NSinthenandrolonegroup) in the time spent in the drug-paired compartment during andscorevalues(one-wayANOVA,F(1,29)¼0.15,NS,inthe the test phase (Student’s t-test, t(1,9)¼(cid:4)2.81, P<0.05) vehicle group and F(1,29)¼0.21, NS, in the nandrolone and the score values (one-way ANOVA, F(1,29)¼4.85, group). On the contrary, a significant conditioned place P<0.05). E.Ce´le´rieretal./Neuropharmacology50(2006)788e806 797 3.5. Effects of nandrolone treatments on the rewarding ANOVA. Anxiolytic-like effects of THC (0.2mg/kg) were properties of food also observed in the lit/dark box (Fig. 4A and see Table 6 for two-way ANOVAs). THC increased the percentage of en- In mice previously receiving intramuscular vehicle for triesinthelitcompartment(F(1,35)¼5.10,P<0.05)andthe 14days (Fig. 3A), two-way ANOVA revealed no significant entriesinthedistalareaofthiscompartment(F(1,35)¼21.63, food (F(1,40)¼2.87, NS) and nandrolone (F(1,40)¼2.90, P<0.001), and decreased the entries in its proximal area NS) effects, but a significant food/nandrolone interaction (F(1,35)¼21.03, P<0.001), as revealed by one-way (F(1,40)¼4.35, P<0.05). Significant conditioned place ANOVA. THC also increased the percentage of squares preference to food was observed in these mice, as revealed crossed in the lit compartment (F(1,35)¼42.22, P<0.001). by the score values (one-way ANOVA, F(1,21)¼0.29, NS) The anxiolytic-like effects of THC (0.2mg/kg) were not re- andtheincreaseinthe timespent inthe food-pairedcompart- vealed in the elevated plus-maze in our experimental condi- ment during the test vs. preconditioning phase (Student’s tions (Fig. 6A and see Table 7 for two-way ANOVA). In t-test, t(1,9)¼3.18, P<0.05). On the contrary, rewarding mice pre-treated with nandrolone, THC (0.2mg/kg) did not effectsoffoodwereabolishedinmicepre-exposedtonandro- produce any anxiolytic-like effect in the open-field lone, as revealed by the similar time spent in the food-paired (Fig. 5A), lit/dark box (Fig. 4A) and elevated plus-maze compartment during the test vs. preconditioning phase (Stu- (Fig. 6A). One-way ANOVA revealed significant differences dent’s t-test, t(1,10)¼0.26, NS) and the score values (one- in THC effects between vehicle and nandrolone pre-treated way ANOVA, F(1,22)¼0.09, NS). Significant differences mice in the open-field (number of rearing: F(1,24)¼44.61, were also observed between vehicle and nandrolone pre- P<0.001; percentage of squares crossed in the central area: exposedmiceconditionedwithfood(F(1,20)¼7.31,P<0.05). F(1,24)¼25.94, P<0.001) and the lit/dark box (entries Similar to the previous experiment, food did not induce into the proximal area of the lit compartment: conditionedplacepreferenceinmicereceivinganintramuscu- F(1,38)¼40.36, P<0.001; entries into the distal area of larinjectionofvehicleornandrolone1hbeforethecondition- the lit compartment: F(1,38)¼32.71, P<0.001, and squares ing session (Fig. 3B), as revealed by the similar time spent in crossedintothelitcompartment:F(1,38)¼30.41,P<0.001). the drug-paired compartment on the preconditioning and test The influence of chronic nandrolone co-administration on phase (Student’s t-test, t(1,11)¼(cid:4)0.51, NS, in the vehicle THC anxiolytic-like effects could not be assessed due to the group and t(1,12)¼(cid:4)0.17, NS in the nandrolone group), interference of the previous intramuscular injection (Figs. and the score values (one-way ANOVA, F(1,25)¼0.12, 4Be6B and Tables 5e7 for two-way ANOVA). Indeed, NS). Two-way ANOVA revealed no significant food THC (0.2mg/kg) did not produce any anxiolytic-like effects (F(2,54)¼1.30,NS)andnandrolone(F(1,54)¼0.11,NS)ef- inanyofthe behaviouraltests whenmice receiveda previous fects, and no food/nandrolone interaction (F(1,54)¼0.03, intramuscular injection of vehicle. NS). On the contrary, a significant place preference was ob- servedinapositivecontrolgroupofmicereceivingfoodunder 3.6.2.Influenceofnandroloneontheanxiogenic-likeeffects the same experimental conditions without any intramuscular of THC (7.5mg/kg) administration, as revealed by the significant increase in the In mice pre-treated with vehicle, the dose of 7.5mg/kg of time spent in the drug-paired compartment during the test THC produced anxiogenic-like effects in the open-field, lit/ phase (Student’s t-test, t(1,10)¼(cid:4)2.88, P<0.05) and the darkboxandelevatedplus-maze(Figs.4Ae6AandseeTables score values (one-way ANOVA, F(1,25)¼4.92, P<0.05). 5e7for two-way ANOVA). Inthe open-field, THC decreased the number of rearing (F(1,24)¼19.00, P<0.001) and the 3.6. Effects of nandrolone treatments on the THC percentage of squares crossed into the central area anxiolytic- and anxiogenic-like responses (F(1,24)¼22.64, P<0.001), as revealed by one-way ANOVA. In the elevated plus-maze, THC decreased the per- The influence of nandrolone on THC-induced changes in centage of time spent in the open arms (one-way ANOVA, anxiety-like responses was evaluated in the lit/dark box, F(1,29)¼4.95, P<0.05). In the lit/dark box test, THC in- open-field and elevated plus-maze (Figs. 4e6) and the global creased the percentage of entries in the proximal area of the results obtainedare summarized inTable 4.Both protocols of lit compartment (F(1,36)¼9.80, P<0.01), and decreased nandrolonetreatmentshadnointrinsiceffectwheninjectedin the entries in its distal area (F(1,36)¼9.57, P<0.01) and combination with vehicle in any of the parameters studied. the squares crossed in the lit compartment (F(1,36)¼8.49, P<0.01), as revealed by one-way ANOVA. In mice pre- 3.6.1. Influence of nandrolone on the anxiolytic-like effects treated with nandrolone, THC (7.5mg/kg) produced similar of THC (0.2mg/kg) anxiogenic-like effects in the open-field, the lit/dark box and In mice pre-treated with vehicle, the dose of 0.2mg/kg of theelevatedplus-maze.Intheopen-field,one-wayANOVAre- THC produced anxiolytic-like effects in the open-field vealed a decrease in the number of rearing (F(1,22)¼17.17, (Fig. 5A and see Table 5 for two-way ANOVA). THC in- P<0.001) and the squares crossed into the central area creased the number of rearing (F(1,24)¼44.10, P<0.001) (F(1,22)¼29.94, P<0.001). In the elevated plus-maze, and the percentage of squares crossed in the central area one-way ANOVA showed a decrease in the time spent in (F(1,24)¼20.07, P<0.001), as revealed by one-way the open arms (F(1,29)¼14.10, P<0.01) and the total