The Effects of Acute Nicotine on the Metabolism of Dopamine and the Expression of Fos Protein in Striatal and Limbic Brain Areas of Rats during Chronic Nicotine Infusion and Its Withdrawal

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The Journal of Neuroscience, September 15, 1999, 19(18):8145-8151

The Effects of Acute Nicotine on the Metabolism of Dopamine and the Expression of Fos Protein in Striatal and Limbic Brain Areas of Rats during Chronic Nicotine Infusion and Its Withdrawal
Outi Salminen, Tiina Seppä, Helena Gäddnäs, and Liisa Ahtee
Division of Pharmacology and Toxicology, Department of Pharmacy, University of Helsinki, FIN-00014 Helsinki, Finland

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The effects of acute nicotine (0.5 mg/kg, s.c.) on dopamine (DA) metabolism and Fos protein expression in striatal and limbicareas of rats on the seventh day of chronic nicotine infusion(4 mg · kg¹ · d¹) and after 24 or 72 hr withdrawal were investigated. In saline-infusedrats, acute nicotine elevated striatal and limbic 3,4-dihydroxyphenylaceticacid (DOPAC) and homovanillic acid (HVA) concentrations significantly.During the nicotine infusion, no such increases were seen in thestriatum, but limbic HVA was somewhat elevated. After 24 hr withdrawalwhen no nicotine was found in the plasma, acute nicotine elevatedstriatal DOPAC and HVA and limbic HVA. However, the limbic DOPACwas unaffected. Acute nicotine increased Fos immunostaining (IS)in the caudate-putamen (CPU), the core of nucleus accumbens (NAcc),the cingulate cortex (Cg), and the central nucleus of amygdala(ACe) significantly. During nicotine infusion the nicotine-inducedresponses were attenuated in CPU and NAcc, whereas in ACe andCg Fos immunostaining was increased as in saline-infused rats.After 24 hr withdrawal, acute nicotine did not increase Fos immunostainingin CPU, NAcc, and Cg, but increased it clearly in ACe. After 72hr withdrawal, nicotine's effects were restored. Our findingssuggest that the nicotinic receptors in the striatal areas aredesensitized more easily than those in the limbic areas. Furthermore,the effects of nicotine on various DA metabolites differ. We alsofound evidence for long-lasting inactivation of nicotinic receptorsin vivo regulating limbic dopamine metabolism and Fos expressionin striatal and limbic areas. These findings might be importantfor the protective effects of nicotine in Parkinson's diseaseand in its dependence-producingproperties.

Key words: nicotine; constant infusion; striatal dopamine metabolism; limbic dopamine metabolism; Fos protein; desensitization; tolerance

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Acute nicotine enhances striatal and limbic dopamine (DA) turnover and metabolism (Nose and Takemoto, 1974; Haikala et al.,1986; Grenhoff and Svensson, 1988). Nicotine increases ³H-DA release in vitro from striatal slices and synaptosomes (Westfall,1974; Rapier et al., 1988; Grady et al., 1992) and from the nucleusaccumbens (NAcc) (Rowell et al., 1987). Nicotine also elevatesextracellular DA in the striatum (Imperato et al., 1986) and inthe NAcc (Imperato et al., 1986; Benwell and Balfour, 1992). Thereis evidence that nicotine activates the limbic DA system moreeasily than the striatal one (Imperato et al., 1986; Grenhoffand Svensson, 1988; Benwell and Balfour, 1997). We recently foundthat in mice tolerance develops to the nicotine-induced increaseof striatal dopamine metabolism at 24 hr after withdrawal from7 week oral nicotine administration (Pietilä et al., 1996). Theeffect of chronic nicotine treatment seems to depend on the methodof administration. During prolonged constant nicotine infusionthe acute nicotine-evoked increase of extracellular DA in theNAcc and dorsal striatum was inhibited, and the elevation of accumbalDA metabolites was attenuated, suggesting desensitization of thereceptors mediating nicotine-induced mesolimbic and nigrostriatalDA responses (Benwell et al., 1995; Benwell and Balfour, 1997).On the other hand, Damsma et al. (1989) and Nisell et al. (1996)reported no change in the nicotine-induced increase of DA releasein the NAcc of rats when nicotine was given by repeated injections.After intermittent nicotine treatment, even sensitization of thenicotine response has been reported (Benwell and Balfour, 1992;Shoaib et al., 1994; Marshall et al., 1997).

Drug treatments affecting dopaminergic transmission modulate the expression of Fos protein encoded by c-fos proto-oncogenein the striatum (Graybiel et al., 1990; Robertson et al., 1990;Herrera and Robertson, 1996; Moratalla et al., 1996). Acute nicotineelevates Fos expression in various brain regions, including dopaminergictarget areas (Ren and Sagar, 1992; Matta et al., 1993; Pang etal., 1993; Kiba and Jayaraman 1994; Panagis et al., 1996; Salminenet al., 1996; Valentine et al., 1996). Fos expression is alsoelevated in rats trained to self-administer intravenous nicotine(Pagliusi et al., 1996; Merlo Pich et al., 1997). Dopamine D₁-receptormediates nicotine-induced Fos expression in striatum, NAcc, andmedial prefrontal cortex because D₁-antagonist SCH 23390 completelyblocks this effect (Kiba and Jayaraman, 1994; Nisell et al., 1997).

In this study we investigated the effects of acute nicotine on dopamine metabolism in the striatum and limbic forebrain ofrats during chronic nicotine infusion and after 24 or 72 hr withdrawal.The estimated dopamine metabolites 3,4-dihydroxyphenylacetic acid(DOPAC) and homovanillic acid (HVA) are considered indicatorsof different aspects of DA dynamics. DOPAC is formed by monoamineoxidase mainly intraneuronally and thus can be used as an indicatorof intraneuronal synthesis and metabolism. HVA is formed by bothmonoamine oxidase and catechol-O-methyltransferase, indicatingthe sum of DA synthesis, metabolism, and release (Roffler-Tarlovet al., 1971; Westerink and Spaan, 1982). Also we studied theexpression of Fos protein in dopaminergic target areas to determinewhether the nicotine-induced changes in DA metabolism could bedetected in postsynaptic neurons at the level of immediate-earlygenes.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Male Wistar rats (body weight 200-300 gm at the beginning of experiments) bred locally in the Laboratory Animal Center, Universityof Helsinki, were divided randomly into nicotine-receiving andcontrol animals. The experimental animals were maintained in accordancewith internationally accepted principles, and the experimentalsetup was approved by the Committee for Animal Experiments ofthe Faculty of Science of the University of Helsinki. The ratshad free access to food and water and were housed singly aftersurgery. The lights were on from 6 A.M. until 6 P.M., and theambient temperature was kept at 20-22°C. Osmotic minipumps (Alzet2001) containing saline or nicotine hydrogen tartrate (Sigma,St.Louis, MO) solutions were implanted subcutaneously under halothaneanesthesia. Nicotine was infused at a dose of 4 mg · kg¹ · d¹ for 7 d. The dose refers to the base. Withdrawal was inducedby removing the minipumps surgically on the seventh day of chronictreatment.

The rats received 0.9% NaCl solution (saline, s.c.) or acute nicotine (0.5 mg/kg s.c.) 1 hr before decapitation on the seventhday with the minipumps still in place and after 24 or 72 hr withdrawal.For injections (0.1 ml/100 gm) ( $-$ )-nicotine base (Fluka, Buchs,Switzerland) was diluted with 0.9% NaCl solution, and the finalsolution was adjusted to 7.0-7.4 pH with 0.05 M HCl in 0.9% NaClsolution. After decapitation the striatum and the limbic forebrain(containing inter alia the olfactory tubercles, medial part ofthe nucleus accumbens, the central nucleus of amygdala, and partof the paleocortex) were dissected and collected on dry ice within5 min. Tissues were weighed and stored at $-$ 80°C until assayed.When estimating dopamine and its metabolites, nicotine and cotinineconcentrations, and performing Fos immunohistochemistry, all fourtreatment groups (saline infusion + acute saline, saline infusion+ acute nicotine, nicotine infusion + acute saline, nicotine infusion+ acute nicotine) were analyzed simultaneously. However, the 7d, 24 hr, and 72 hr withdrawal experiments were performed andanalyzedseparately.

Measurement of dopamine and its metabolites. The striatal and limbic concentrations of DA and its metabolites, DOPAC and HVA,were measured by HPLC with electrochemical detection after SephadexG-10 gel chromatographic cleanup of samples. Tissue samples werehomogenized in 1 ml 0.2 M HClO₄, and the homogenates were adjustedto 2.4 pH by KOH/HCOOH buffer. After centrifugation (15 min, 28,000× g, 4°C), 1 ml of supernatant was put on an acidic (0.01 M HCl)Sephadex G-10 column (bed height 8 mm) prepared in a long Pasteurpipette. After the supernatants had passed through the columns,the compounds were eluted, and a 200 µl portion of each collectedfraction was injected through a high-pressure injection valvein an HPLC column. The C-18 reverse-phase (Spherisorb octadecylsilane2 µm) HPLC column (25 cm, 4.6 mm inner diameter) was connectedto the electrochemical detector (Coulochem II, ESA). The assayis described in detail by Haikala (1987).

Measurement of nicotine and cotinine. The plasma concentrations of nicotine and cotinine were measured on the seventh dayof chronic nicotine infusion and after 24 hr withdrawal usinggas chromatography-mass spectrometry. The trunk blood of ratswas collected by decapitation 60 min after a challenge injectionof 0.5 mg/kg nicotine or saline. Blood samples were treated andmeasured according to Leikola-Pelho et al. (1990).

Fos immunohistochemistry. The nicotine- or saline-infused rats received saline or nicotine (0.5 mg/kg, s.c.) 1 hr before thepentobarbital (Orion Pharma, Espoo, Finland) anesthesia (100 mg/kg,i.p.) and intracardial perfusion on the seventh day with the minipumpsstill in place and after 24 or 72 hr withdrawal. Rats were perfusedwith 0.9% PBS followed by 4% paraformaldehyde in 0.1 M sodiumphosphate buffer, pH 7.4. The brains were post-fixed with thesame fixative for 4 hr at room temperature after perfusion. Thebrains were immersed in a 20% sucrose solution at 4°C until used.The sections (40 µm) were cut on a cryostat. The sections werefirst incubated in 2% normal rabbit serum (NRS) (Vector Laboratories,Burlingame, CA) in PBS + 0.5% Tween 20 + 0.2% NRS for 60 min toblock nonspecific staining. The sections were then incubated inprimary fos antibody (OA-11-824, Genosys Biotechnologies, Cambridge,UK) diluted 1:1000 (experiments during chronic nicotine) or 1:2000(withdrawal experiments) in PBS (in 0.5% Tween 20 + 4% NRS) for72 hr at 4°C. The antibody used was sheep polyclonal antibodyto fos oncoproteins to a synthetic peptide Met-Phe-Ser-Gly-Phe-Asn-Ala-Asp-Tyr-Glu-Ala-Ser-Ser-Ser-Arg-Cys,selected from a conserved region of mouse and human c-fos (vanStraaten et al., 1983). The sections were processed with the avidin-biotinmethod (Vectastain Kit, Vector Laboratories) with diaminobenzidine(Sigma) as the chromagen. The sections were then mounted on gelatin/chromealum-coated slides, air-dried, dehydrated through graded ethanolsto xylene, and coverslipped with DePex (BDH Laboratory Supplies,Poole, England). Controls for the immunostaining, which includedomission of either primary or secondary antibody, demonstratedno Fos immunostaining. The atlas of Paxinos and Watson (1986)was used to identify the brain areas. Figure 1 shows the areasin which Fos-positive nuclei were counted. The Fos-positive nucleiwere counted with a 10× objective with the assistance of a LEICAQWin image analysis system on selected brain areas within a rectangulararea of 480 × 360 µm. A group mean (±SEM) was determined fromthe counts of four to seven rats in each treatment group.

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Figure 1. Schematic drawings indicating areas [according to Paxinos and Watson (1986)] in which Fos-positive nuclei were counted. Cg, Cingulate cortex; NAcc, core of nucleus accumbens; CPU, caudate-putamen; ACe, central nucleus of amygdala.

Statistics. Because the metabolite results consisted of several experiments, the statistical analyses were performed by three-wayANOVA (experiment × chronic treatment × acute challenge). Becauseno significant interactions between the experiment and other factorswere observed, the randomized block two-way ANOVA was performedusing experiments as blocks. If there were significant chronic× acute nicotine interactions (p < 0.1), the analysis was continuedby comparing appropriate cell means with linear contrasts. TheFos immunostaining data were analyzed by Kruskal-Wallis nonparametricANOVA followed by the Mann-Whitney U test. The data concerningplasma nicotine and cotinine concentrations were analyzed by Student'sttest.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Plasma nicotine and cotinine concentrations

As shown in Table 1, the plasma nicotine and cotinine concentrations were clearly elevated on the seventh day of chronicinfusion, but at 24 hr after removal of the minipumps no nicotineand only traces of cotinine were found in the plasma. Acutelyadministered 0.5 mg/kg nicotine elevated the plasma nicotine andcotinine concentrations in the withdrawn rats to the same degreeas in the control rats, but did not clearly increase the nicotineor the cotinine concentrations in the plasma of rats with theminipumps still in place.


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Table 1. Plasma nicotine and cotinine concentrations in rats infused chronically with nicotine for 7 d at 60 min after acute saline or nicotine

Striatal dopamine metabolism

As shown in Figure 2, in saline-infused control rats acute nicotine (0.5 mg/kg, s.c., 60 min) elevated DOPAC and HVA concentrationssignificantly in the striatum (DOPAC by 24-40%, HVA by 20-46%,respectively). No such increases were seen when acute nicotinewas given on the seventh day of chronic nicotine infusion. Neitherchronic nicotine infusion nor nicotine withdrawal (24 and 72 hr)altered DOPAC and HVA concentrations. At 24 and 72 hr after removalof the minipumps, acute nicotine elevated DOPAC (24 hr, 16%; 72hr, 22%) and HVA (24 hr, 33%; 72 hr, 22%) in the nicotine-infusedrats to almost the same extent as in the saline-infused rats.Striatal DA concentrations were not altered by any treatment.

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Figure 2. The effect of an acute nicotine challenge (0.5 mg/kg, s.c., 60 min) on the striatal dopamine (DA), dihydroxyphenylacetic acid (DOPAC), and homovanillic acid (HVA) concentrations in rats on the seventh day of chronic nicotine infusion (4 mg · kg¹ · d¹) with the minipumps still in place, and at 24 or 72 hr after removal of the minipumps. Given are the mean striatal concentrations of DA and the metabolites (columns) ± SEM (vertical bars) of 7-14 observations. *p < 0.05, **p < 0.01, ***p < 0.001 as compared with the control rats given acute saline subcutaneously; ^oop < 0.01, ^ooop < 0.001 as compared with the control rats given acute nicotine; $black-diamond$ p < 0.05, $black-diamond$ $black-diamond$ p < 0.01 as compared with chronic nicotine rats given saline acutely. White columns, Sham-operated control rats + acute saline; dotted columns, control rats + acute nicotine; checkered columns, chronic nicotine + acute saline; black columns, chronic nicotine + acute nicotine.

Limbic dopamine metabolism

Figure 3 shows that in saline-infused control rats acute nicotine (0.5 mg/kg, s.c., 60 min) elevated DOPAC and HVA concentrationsin the limbic areas (DOPAC by 49-70% and HVA by 66-86%). Neitherchronic nicotine nor nicotine withdrawal altered the limbic DOPACconcentration, whereas HVA concentration was significantly elevatedin rats with the minipumps still in place but not in rats fromwhich the nicotine-infusing minipumps had been removed. Acutenicotine did not elevate the limbic DOPAC concentration on theseventh day of chronic infusion or at 24 hr after its withdrawal,but after 72 hr withdrawal acute nicotine elevated DOPAC by 82%.On the seventh day of chronic nicotine infusion, acute nicotinesomewhat increased the limbic HVA concentration, although significantlyless than in the control rats. After 24 and 72 hr withdrawal,the nicotine-induced elevations of HVA in the nicotine-infusedrats were similar to those of the controls (24 hr, 73%; 72 hr,55%). Limbic DA was not altered by any of the treatments.

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Figure 3. The effect of an acute nicotine challenge (0.5 mg/kg, s.c., 60 min) on the limbic dopamine (DA), dihydroxyphenylacetic acid (DOPAC), and homovanillic acid (HVA) concentrations in rats on the seventh day of chronic nicotine infusion (4 mg · kg¹ · d¹) with the minipumps still in place and at 24 and 72 hr after removal of the minipumps. Given are the mean limbic concentrations of DA and the metabolites (columns) ± SEM (vertical bars) of 7-14 observations. **p < 0.01, ***p < 0.001 as compared with the control rats given acute saline subcutaneously; ^op < 0.05 as compared with the control rats given acute nicotine; p < 0.001 as compared with chronic nicotine rats given saline acutely. White columns, Sham-operated control rats + acute saline; dotted columns, control rats + acute nicotine; checkered columns, chronic nicotine + acute saline; black columns, chronic nicotine + acute nicotine.

Fos immunohistochemistry

Figure 4 shows that in saline-infused control rats acute nicotine (0.5 mg/kg, s.c., 60 min) increased the number of Fos-positivenuclei in the dorsomedial CPU, in the NAcc, in the Cg, and inthe ACe. The increase of Fos expression by acute nicotine occurredmainly in the core part of the NAcc, whereas no change in thenumber of Fos-positive nuclei was observed in the shell (datanot shown). Therefore, Fos-positive nuclei were counted only inthe area shown in Figure 1. On the seventh day of chronic nicotineinfusion or 24 or 72 hr after removal of the minipumps, the numbersof Fos-positive nuclei in the areas studied were similar in nicotine-infusedand saline-infused control rats. Thus, chronic nicotine infusionor its withdrawal did not alter the Fos expression.

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Figure 4. The effect of an acute nicotine challenge (0.5 mg/kg, s.c., 60 min) on Fos immunostaining in rat brain striatal and limbic areas on the seventh day of chronic nicotine infusion (4 mg · kg¹ · d¹) with the minipumps still in place and at 24 and 72 hr after removal of the minipumps. Given are the mean numbers of Fos-positive nuclei (columns) ± SEM (vertical bars) of four to seven observations. *p < 0.05, ** p < 0.01 as compared with control rats given acute saline subcutaneously; ^op < 0.05, ^oop < 0.01 as compared with the control rats given acute nicotine. White columns, Control rats + acute saline; dotted columns, control rats + acute nicotine; checkered columns, chronic nicotine + acute saline; black columns, chronic nicotine + acute nicotine. CPU, Dorsomedial caudate-putamen; NAcc, core of nucleus accumbens; Cg, cingulate cortex; ACe, central nucleus of amygdala.

On the seventh day of the chronic nicotine infusion, the effect of acute nicotine on the number of Fos-positive nuclei varied.Thus, in the CPU of rats infused chronically with nicotine, acutenicotine had no effect, and in the NAcc there was a slight increaseof Fos-IS, which was significantly less, however, than in saline-infusedcontrol rats. In the ACe and Cg, acute nicotine increased Fos-ISin nicotine-infused rats to the same extent as it did in saline-infusedrats. No increases of Fos-IS were seen in the CPU, in the NAcc,or in the Cg when acute nicotine was given to rats withdrawn for24 hr from 7 d nicotine infusion. However, in the ACe of thesenicotine-withdrawn rats acute nicotine increased the Fos-IS inthe same way as in the control rats. At 72 hr after removal ofthe nicotine-releasing minipumps, acute nicotine elevated Fos-ISin all four brain areasstudied.

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

On the seventh day of constant nicotine infusion, we found profound attenuation of nicotine's effects on striatal and limbicDA metabolism. After 24 hr withdrawal, nicotine's effects on DAmetabolism were fully recovered, except that on limbic DOPAC,which was still attenuated. The postsynaptic effects of nicotinein major dopaminergic target areas as estimated by Fos expressionwere attenuated on the seventh day of nicotine infusion, and acutenicotine did not activate Fos expression in these areas at 24hr after nicotine withdrawal. Nicotine's effects that were studiedwere restored after 72 hrwithdrawal.

In contrast to the saline-infused rats, acute nicotine treatment induced no changes in the striatal DA metabolism in ratson the seventh day of continuous nicotine infusion. Also, thenicotine-induced elevations of the limbic DOPAC and HVA were reducedwhen acute nicotine was given during nicotine treatment. Thesefindings agree with microdialysis studies (Benwell et al., 1994,1995; Benwell and Balfour, 1997) where the effects of acute nicotinechallenge on extracellular concentration of DA in the dorsal striatumand on those of DA, DOPAC, and HVA in the NAcc were attenuatedduring constant nicotine infusion as compared with controls. Thisphenomenon could be caused by the continuous presence of an agonist,in this case nicotine, desensitizing the nicotinic acetylcholinereceptors (nAChRs) regulating the dopaminergic neurons. We foundthat the attenuation of nicotine's effect on DA metabolism occurredwith prolonged exposure to nicotine concentrations approximatelysimilar to those found in the plasma of heavy smokers (Table 1).Furthermore, such plasma concentrations indicate high cerebralnicotine concentrations in rats (Deutsch et al., 1992; Rowelland Li, 1997). Lippiello et al. (1995) observed that nicotinetends to stabilize nAChRs in the high-affinity conformation thatis related to the process of functional desensitization. Thus,our experiments indicate that nAChRs involved in the control ofstriatal and limbic dopamine turnover were desensitized duringconstant nicotineinfusion.

After 24 and 72 hr withdrawal from nicotine infusion, acute nicotine elevated striatal DOPAC and HVA to the same extent innicotine-infused and saline-infused rats. The loss of action ofthe nAChRs regulating striatal DA metabolism during chronic nicotineinfusion thus is a reversible phenomenon that is recovered within24 hr of withdrawal. Acute nicotine also elevated the limbic HVAconcentrations similarly in control and nicotine-withdrawn rats.However, the nicotine-induced elevation of limbic DOPAC was stillabolished after 24 hr withdrawal but not after 72 hr withdrawal.Thus, nAChRs mediating nicotine-induced elevation of limbic DOPACwere still inactivated after 24 hr withdrawal, when no nicotineand only traces of cotinine were detected in the plasma. The lackof response of limbic DOPAC to acute nicotine could be attributedto long-lasting inactivation of nAChR function, which in in vitroexperiments could be distinguished from reversible receptor desensitizationand is caused by the prolonged pretreatment or high concentrationsof nicotine (Rowell and Duggan, 1998). We could not demonstrateany nicotine-induced sensitization in either striatal or limbicDA metabolism when nicotine was withdrawn for 24 or 72 hr. Thisagrees with previous findings when nicotine was given by constantinfusion (Benwell et al., 1995; Marshall et al., 1997).

In agreement with the study of Grenhoff and Svensson (1988), acute nicotine elevated limbic dopamine metabolites somewhatmore than the striatal ones in this study. Furthermore, we nowfound differences in the responses of striatal and limbic DA metabolitesto chronic infusion as well as to acute nicotine administrationin nicotine-infused rats. Our findings suggest that at least someof the limbic nAChRs mediating nicotine's effects on dopamineturnover are less easily desensitized than the striatal ones.This finding agrees with the suggestion of Henningfield et al.(1996) based on in vitro experiments (Rapier et al., 1988; Brodie,1991; Grady et al., 1994) that the somatodendritic nAChRs locatedon mesolimbic DA neurons appear to desensitize much less readilythan nAChRs located on the terminals of the nigrostriatal pathway.In vitro the subunit composition of nAChRs determines the degreeto which receptors are desensitized by various concentrationsof nicotine (Fenster et al., 1997). We have previously suggestedthat nAChRs involved in the regulation of the intraneuronal DAmetabolism are different from those in impulse-mediated DA releaseat least in their response to chronic nicotine administrationin mice (Leikola-Pelho et al., 1990). The differences we now foundin the effect of nicotine on limbic DOPAC and HVA in rats givefurther support to this suggestion. Thus, there may be variationsin the functional states or in the subunit compositions of nAChRsmediating nicotine's various effects on dopaminergic transmissionor differences in receptor distribution in the limbic and striatalareas and their inputareas.

Like nicotine's effects on striatal DA metabolism, Fos expression in response to acute nicotine was attenuated in the dorsomedialCPU and in the core of the NAcc on the seventh day of nicotineinfusion. Moreover, in agreement with earlier experiments (Nisellet al., 1997), acute nicotine at the dose of 0.5 mg/kg did notsignificantly increase Fos expression in the shell of the NAcc.The core of the NAcc projects to the dorsolateral part of theventral pallidum, which in turn projects to the subthalamic nucleusand substantia nigra (Heimer et al., 1991; Meredith et al., 1992)comprising a striatal sector that takes part predominantly inmotor functions (Deutch and Cameron, 1992). The attenuation ofnicotine-induced Fos expression in these striatal regions maybe attributable to the same kind of desensitization phenomenonas discussed above regarding striatal dopamine during the chronicnicotine infusion. However, at this time point, in the ACe andCg, acute nicotine increased the Fos immunostaining in both thenicotine-infused and saline-infused rats. ACe forms part of themesolimbic DA system; it is a major target of the DA pathway originatinglargely in the A10 and A9 (Loughlin and Fallon, 1983; Kilts etal., 1988) and also from there arises input to substantia nigra(Price and Amaral, 1981; Gonzales and Chesselet 1990). Cg is oneof the terminal regions of the mesocorticolimbic DA pathway (Zillesand Wree, 1995). Thus, like nicotine's effects on limbic DA metabolism,its Fos expression-increasing effects in the limbic brain areasseem to be less easily attenuated during chronic nicotine treatmentthan its effects on the striatal Fos. Thus, nAChRs mediating nicotine'spostsynaptic effects in the striatal areas may desensitize moreeasily than the ones in the limbic areas. The observed differencesin the striatal and limbic areas between nicotine's effects onboth DA metabolites and Fos expression thus suggest that nAChRsin these brain areas mightdiffer.

After 24 hr withdrawal, acute nicotine did not increase the Fos immunostaining in CPU, nor did it alter the Fos immunostainingin NAcc or Cg at this time point. The withdrawal itself (24 or72 hr) did not change the Fos expression. Similar to acute nicotine'seffects on DA metabolites, its effects on Fos expression werefully restored within 72 hr after withdrawal of nicotine infusion.The inability of nicotine to induce Fos expression in CPU andNAcc after 24 hr withdrawal could be caused by the prolonged inactivationof nAChRs, as discussed above (Rowell and Duggan, 1998). It shouldbe noted that on the seventh day of treatment, acute nicotinedid not increase Fos immunostaining in CPU and did so only toa small degree in NAcc. Furthermore, the inability of nicotineto induce Fos expression in NAcc agrees with the finding thatacute nicotine did not elevate limbic DOPAC in rats withdrawnfor 24 hr. However, the inability of acute nicotine to induceFos expression in CPU does not correlate with our findings onDA metabolites. Also the inability of nicotine to increase Fosimmunostaining in Cg after the 24 hr withdrawal is somewhat puzzlingand may be attributed to unspecific response. Dopaminergic pathwaysare not necessarily the only ones involved in mediating nicotine'seffects on Fos protein expression during withdrawal. Corticaland thalamic glutamatergic inputs to the striatum may modulatethe dopaminergic activation of postsynaptic intracellular mechanismsthat lead to changes in Fos expression (Harlan and Garcia, 1998).

In conclusion, we observed differences in the effects of nicotine on dopamine systems as well as on Fos expression in striataland limbic brain areas. The nAChRs in the striatal areas seemto be desensitized more easily than those in the limbic areasduring prolonged nicotine infusion. We also found evidence fora long-lasting inactivation of nAChRs mediating nicotine's effectson limbic dopamine metabolism and on Fos expression in striataland limbic areas in vivo. The variations in responses to nicotineare interesting when studying the protective effect of nicotinein Parkinson's disease as well as in its reinforcing and dependence-producingproperties.

  FOOTNOTES

Received May 4, 1999; revised July 6, 1999; accepted July 7, 1999.

This work was supported by grants from the University of Helsinki, the Research Council for Health of the Academy of Finland,and the Finnish Cultural Foundation. We thank Marjo Vaha for skillfulassistance
Correspondence should be addressed to Outi Salminen, Division of Pharmacology and Toxicology, P.O. Box 56 (Viikinkaari 5),University of Helsinki, FIN-00014 Helsinki,Finland.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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