Enhanced Food-Related Motivation after Bilateral Lesions of the Subthalamic Nucleus

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The Journal of Neuroscience, January 15, 2002, 22(2):562-568

Enhanced Food-Related Motivation after Bilateral Lesions of the Subthalamic Nucleus
Christelle Baunez¹, Marianne Amalric¹, and Trevor W. Robbins²
¹ Laboratoire de Neurobiologie Cellulaire et Fonctionnelle, Centre National de la Recherche Scientifique, 13402 Marseille cedex 20, France, and ² Department of Experimental Psychology, University of Cambridge, CB2 3EB, Cambridge, United Kingdom

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
Apparatus
Statistical analysis
Surgery
Histology
RESULTS
DISCUSSION
REFERENCES

Although inactivation of the subthalamic nucleus (STN) has beneficial effects on motor symptoms of parkinsonism, little isknown of possible actions on nonmotor symptoms of cognition ormood. Here, we used several forms of converging evidence to showthat STN lesions can enhance behavioral motivation. Thus, bilateralfiber-sparing lesions of the STN in rats reduced the time requiredto eat a standard number of food reward pellets, without affectingfood intake, and altered performance on a number of behavioralmeasures consistent with enhanced motivation for food. Thus, STN-lesionedrats showed greater levels of locomotor activity conditioned tofood presentation, enhanced control over responding by food-relatedconditioned reinforcers, and a higher breaking point associatedwith elevated rate of lever press under a progressive ratio scheduleof reinforcement. These results reveal a new functional role schedulefor STN, possibly because of its involvement in ventral, as wellas dorsal, striatal circuitry and are relevant to the therapeuticeffects of STN stimulation in Parkinson'sdisease.

Key words: basal ganglia; conditioned behavior; consummatory behavior; incentive motivation; progressive ratio; feeding

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
Apparatus
Statistical analysis
Surgery
Histology
RESULTS
DISCUSSION
REFERENCES

The subthalamic nucleus (STN) is part of the basal ganglia, a group of structures classically considered to be involved inmotor functions, because various lesions affecting these cerebralstructures induce obvious motor deficits, such as Parkinson'sdisease (PD). Experimental data have suggested that hyperactivityof the STN could be responsible for some of the deficits in parkinsonism.Recently, the STN has proven to be a promising target for thesurgical treatment of PD. Lesions or high-frequency stimulationof STN in PD patients (Limousin et al., 1995) and in animal modelsof PD (Bergman et al., 1990, Benazzouz et al., 1993; Baunez etal., 1995; Henderson et al., 1999) indeed improve motor symptoms.However, inactivation of the STN in these conditions can alsoimpair additional aspects of behavior (Baunez et al., 1995; Hendersonet al., 1999; Trépanier et al., 2000; Krack et al., 2001). Becausethe STN is a key structure involved in the classical parallelloops linking the basal ganglia to various cortical areas (Alexanderet al., 1986) with motor, associative, and limbic components,the STN might influence a wide range of behavioral functions.Thus, it is important to characterize the behavioral role of theSTNfurther.

Initial studies of STN lesions focused on obvious motor effects. For example, a consequence of selective STN lesions in humansand nonhuman primates induced ballism (Whittier, 1947; Whittierand Mettler, 1949). In rats, bilateral STN lesions increase anticipatoryresponding in a reaction time task (Baunez et al., 1995), whereasunilateral lesions induce either rotation (Kafetzopoulos and Papadopoulos,1983) or postural impairment (Phillips et al., 1998). Only recentlyhave the cognitive roles of the STN been investigated. STN excitotoxiclesions affect visual attentional performance (Baunez and Robbins,1997, 1999), as well as mechanisms of response selection and workingmemory (Baunez et al., 2001). However, there has been no detailedinvestigation of possible roles of the STN in motivational processes,although perseverative behavior induced by STN lesions was amelioratedby prefeeding (Baunez and Robbins, 1997).

The present study is the first to investigate directly the involvement of STN in various aspects of motivation. We measuredeffects of STN lesions on both consummatory behavior (latencyto eat 100 food pellets) and appetitive behavior, assessed inthree ways: (1) locomotor activity conditioned to food presentation,a direct measure of incentive motivation (Campbell and Sheffield1953; Jones et al., 1990); (2) the efficacy of a food-relatedconditioned reinforcer to support new learning (Robbins et al.,1989); and (3) responding under a progressive ratio (PR) scheduleof reinforcement in which rats are required to make increasinglylarge numbers of responses to obtain standard food reinforcement(Hodos, 1961).

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
Apparatus
Statistical analysis
Surgery
Histology
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DISCUSSION
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Animals

Male Long-Evans Rats (Janvier, Le Genest St. Isles, France) and Lister hooded (Charles River, Kent, UK) [for the conditionedreinforcement (CR) experiment] were housed in pairs and maintainedon a 12 hr light/dark cycle (lights on at 7:00 A.M.). During theexperiments using food reinforcement, they were kept at 80-85%of their free feeding weight by restricting their food to 15-17gm/d per rat. Water was provided ad libitum, except during experimentalsessions. All procedures were conducted in accordance with eitherthe requirements of the United Kingdom Animals (Scientific Procedures)Act 1986 or the French Agriculture and Forestry Ministry decree87-849.

  Apparatus

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INTRODUCTION
MATERIALS AND METHODS
Apparatus
Statistical analysis
Surgery
Histology
RESULTS
DISCUSSION
REFERENCES

Eight 26.5 × 22× 20 cm standard operant boxes (Med Associates Inc., St. Albans, VT) were used. Four boxes had a retractablelever and a stimulus light located above the food magazine. Nextto the lever, a magazine (60 × 50 mm) connected with a food pelletdispenser provided access to reward. The apparatus and on-linedata collection was controlled by a computer and an interface(MedPC; Med Associates Inc.). Four other boxes had two retractablelevers and a stimulus light located in the magazine located betweenthe levers and connected with a sucrose solution dipper providingaccess to reward. The apparatus and on-line data collection wascontrolled by a computer (Acorn Computers, Cambridge, UK) andan interface (Paul Fray Ltd., Cambridge, UK). All boxes were equippedwith photocell beams at 15 mm from the entrance of the magazine.Breaks of these beams registered frequency and duration of magazineentries.

Sixteen individual 370 × 227 × 235 mm Perspex locomotor activity cages with a grid floor were used. Each cage was traversedby two parallel infrared photocell beams located at the front(100 mm from the entrance) and at the rear (100 mm from the end)of the cage. Beam breaks were recorded in 10 min bins on-lineby a computer equipped with an Imetronic (Bordeaux, France)extension.

Behavioral procedure

Food consumption test
Animals (sham, n = 13; STN, n = 18; some of which had undergone measures of conditioned locomotor activity and others respondingunder the progressive ratio) were placed, one after the other,in a plastic home cage measuring 42 × 25 × 12 cm. In one corner,100 45 mg sweet Noyes-type pellets were placed, and the time takenfor the rat to eat the pellets was timed in seconds. The box wasthen cleaned with alcohol and left for a few minutes before thenext rat was placed in the box with another 100 pellets. Animalsfrom sham and STN groups were tested in a randomorder.
Another group of animals (sham, n = 7; STN, n = 9) was used to test consumption by measuring the quantity of food eaten ina fixed time duration. One week after surgery, while they werefed ad libitum, all rats were placed individually in the locomotoractivity cages with a determined amount of chow. Absorbent paperwas placed on the floor to prevent food falling through the gridfloor. The amount of food eaten in grams (±SEM) was measured after30 min, 60 min, and at the end of the session (120 min), correctingfor any spillage. A few days later, the same experiment was performed,replacing lab chow by sucrose food pellets in the individual cages.In individual home cages, the total intake of lab chow was alsomeasured after 24 hr for 3 consecutive days and then averaged.The same animals were then food-deprived for 1 week, during whichthey were fed only with 15 gm/d. Under this food restriction regimen,their intake was assessed again in the locomotor activity cagesfor 2 hr. On one day, a fixed amount of lab chow was placed, andthe amount consumed was measured after 30, 60, and 120 min. Ona different day, the same procedure was followed with sucrosepellets.

Conditioned locomotor activity
All testing was conducted from 10:00 A.M. to 12:00 A.M., during the light period and followed a schedule described previouslyto test effects of basal forebrain cholinergic lesions (Olmsteadet al., 1998).

Habituation
Eighteen rats (sham, n = 11; STN lesions, n = 7) were placed in the activity cages for 120 min at the same time each day untilstable baseline activity was established. During this phase, feeding(restricted to 15 gm/rat) was done in home cages at varying andunpredictable intervals after testing (2-6hr).

Conditioning
During this phase, rats were fed in the activity cages. The food (in the same restricted amount) was presented 30 min afterthe recording of locomotor activity had started. The animals remainedin the cages for 90 min after delivery of the food (total of 120min session). The beam breaks were recorded during the 30 minprefeeding period, over 10 sessions. No feeding occurred in thehomecages.

Extinction
During this phase, feeding was switched back to the home cages, in similar conditions to those of habituation. This phaselasted until activity returned to baselinelevels.

Prefeeding
During this phase, the locomotor activity was assessed when rats were prefed. Before the test, rats were given 1 hr accessto food ad libitum in their home cage. After this 1 hr period,rats were placed in locomotor activity cages for 120min.

Conditioned reinforcement
Training. Eleven rats underwent a Pavlovian conditioning procedure in which presentation of a conditioned stimulus (CS) (5sec illumination of the tray light and house light off) precededthe unconditioned stimulus (US) (5 sec elevation of the sucrosesolution dipper). The CS-US pairing was presented 30 times persession at random variable intervals varying such that the sessionwould last ~30 min. Twenty sessions were required before stableperformance was attained. This was evaluated as a ratio calculatedas the mean number of magazine entries during the CS period asa percentage of the mean number of magazine entries during a comparableinterval of the variable interval period (5 sec × 30 trials).All rats underwent then surgery (sham, n = 7; STN, n = 6) andwere given 1 week recovery period. They were then given threeto four retraining sessions to reestablish the baseline beforethe start of thetesting.
Testing. Sucrose was no longer available. Two levers were introduced into the test box, and depression of one lever [no conditionedreinforcer (NCR)] had no programmed consequences, whereas depressionof the second lever (CR) resulted in the presentation of the CS(under a random ratio 2 schedule). Assignment of CR and NCR leverswas counterbalanced within groups to avoid side-preference effects.Because rats were tested in extinction, they were not tested formore than four sessions. The number of responses on each leverand number of magazine entries were recorded during the 30 minsessions.

Progressive ratio
As described previously (Eagle et al., 1999), rats (sham, n = 8; STN, n = 7) were initially trained to press a lever to obtaina food pellet under a continuous reinforcement schedule. Everylever press had as a consequence the onset of a light locatedabove the magazine and the delivery of a food pellet. Additionallever presses had no consequence until the rat's nose was detectedin the magazine. The session ended when 100 pellets were deliveredor 30 min had elapsed. After 10 sessions under this schedule,all rats had acquired stable performance and were moved to thePR schedule. Rats were then reinforced for lever pressing underan arithmetically increasing fixed-ratio (FR) schedule in stepsof 5, with three repetitions of each step (i.e., 1, 1, 1, 5, 5,5, 10, 10, 10, 15, 15, 15... ). The lever press that completed eachFR within this PR schedule induced the onset of the light abovethe magazine and the delivery of a single pellet. The light remainedon until the rat's nose was detected in the magazine. Additionallever presses (perseverative lever presses) had no consequencesbut were counted. A session ended if the rat failed to press thelever for 5 consecutive min or 90 min had elapsed. Training onthe PR schedule was undertaken after surgery only and for 10 consecutivesessions (one session per day). For each session, the value ofthe last completed ratio was recorded, as well as the perseverativelever presses, the number of magazine entries, and the durationof the session. Therefore, the rate of lever presses could beestimated by summation of total lever presses (appropriate plusperseverative lever presses) divided by the session duration expressedinminutes.

  Statistical analysis

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Statistical analysis
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The data were analyzed using ANOVA with the Statview program (Statview 5; SAS Institute, Cary, NC). The results are expressedas means for each of the variables (i.e., time required to eat100 pellets, number of lever presses on the CR lever, NCR lever,last ratio reached in the PR procedure, session duration, etc.)in the different groups ofanimals.

For each variable, the data were submitted to mixed-design ANOVAs, with group (sham vs STN lesions) as the between-subjectfactors and sessions as the within-subject factors when appropriate.When significant effects were found, post hoc comparisons betweenmeans were made using simple main effectsanalysis.

  Surgery

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Statistical analysis
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All animals were anesthetized with xylazine (15 mg/kg, i.m.) and ketamine (100 mg/kg, i.m.) and secured in a Kopf stereotaxicapparatus (Phymep, Paris, France). Twenty rats received bilateralinjection of ibotenic acid (9.4 µg/µl, i.e., 53 mM; Research Biochemicals,Illkirch, France), and 26 rats received the vehicle alone (0.1M phosphate buffer). The volume injected was 0.5 µl per side infusedover 3 min using a 10 µl Hamilton microsyringe, connected by Tygontubing fitted to the 30 gauge stainless steel injector needles,and fixed on a micropump calibrated to deliver the exact volumeover a period of 3min.

The injection coordinates were taken as the average of interaural and bregma coordinates from the atlas of Paxinos and Watson(1986) (from the bregma): anteroposterior, $-$ 3.8 mm; lateral, +2.4mm; dorsoventral, $-$ 8.35 mm (from skull); incisor bar set at $-$ 3mm. As mentioned previously (Baunez et al., 1995), while recoveringfrom anesthesia, STN rats exhibit a short-lasting self-bitingbehavior that completely disappears when they wake up. Therefore,protection of the paws was provided by bandaging and removed immediatelyafter the animals had recovered fromanesthesia.

  Histology

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After completion of the behavioral testing, all of the animals were perfused under deep chloral hydrate anesthesia (400 mg/kg,i.p.) with 4% paraformaldehyde solution through the left cardiacventricle. The brains were removed and post-fixed overnight at4°C in the same fixative. They were then put into a 10% sucrosesolution to be further frozen. Frontal 30- to 40-µm-thick sectionsof the STN were cut by use of a cryostat (Leica, Nussloch, Germany)and collected for cresyl violet staining. Only rats showing abilateral lesion of the STN, characterized by loss of body cellsand intense gliosis reaction leading to a shrinkage of the STN,as illustrated in Figure 1, were included in the data analysis.Lesions were restricted to the STN, and, in most cases, few neuronswere spared in the very lateral tip. The extent of the lesionis shown in Figure 1. Two animals with mislocated lesions werediscarded after the histological examination conducted blind tothe behavioral findings. Their performance in the CR experimentwas in fact different from that of rats with accurate STN lesions.

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Figure 1. Photomicrographs of frontal sections stained with cresyl violet, at the level of the STN outlined by dashed lines, illustrating an STN in a sham (A) and in a lesioned (B) animal.

  RESULTS

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RESULTS
DISCUSSION
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Consummatory behavior

Rats with bilateral lesions of the STN were faster to eat 100 food pellets than controls (mean time to eat in seconds, 788± 57 vs 1343 ± 178; group, F_(1,29) = 12.21; p < 0.01). The mean± SEM body weights of the two groups, when measured under foodrestriction were as follows: sham, 401 ± 15.28 gm; STN, 384 ±10.41 gm. When measured after 10 d of ad libitum feeding, themean body weight average was 427 ± 16.77 and 421 ± 11.5 gm forthe sham and STN groups, respectively. Although there was a significanteffect of the feeding across both groups (ANOVA; F_(1,14) = 77.43;p < 0.01), there was no significant group × feeding interaction(F_(1,14) = 2.46; p > 0.05).

Table 1 shows the mean ± SEM food intake for the STN and sham groups for short (2 hr) and long (24 hr) consumption tests.For the 2 hr consumption test, food intake is also shown whenstandard lab chow or sucrose pellets are proposed under eithersated or food-deprived conditions. Separate ANOVAs for the 2 and24 hr revealed no significant main effect of STN lesion in eithercase (2 hr sated condition, F_(1,14) = 0.09; food-deprived condition,F_(1,14) = 3.99; 24 hr, F_(1,14) = 0.12), although there was a nonsignificanttrend for STN rats to exhibit less consumption (Table 1) in food-deprivedconditions. There were also no significant interactions of lesionwith either food type or food deprivation conditions (three-wayANOVA; all F_(1,14) values < 1.8; p > 0.05). For the 24 hr consumption,repeated measures over 3 consecutive days showed no differencebetween sated STN-lesioned rats and sated sham rats in their foodintake (group effect, F_(1,14) = 0.12; p > 0.05). This was notaffected over the 3 d (day effect, F_(2,28) = 0.27; p > 0.05).


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Table 1. Food intake for the STN and sham groups

Conditioned responses to food reward expectation

Reward-related learning: conditioned locomotor activity
This task allows the measurement of anticipatory locomotor responses elicited by expectation of food reward in various phases:initial conditioning (i.e., Pavlovian learning), extinction (omissionof food reward), and afterprefeeding.
In the very first phases of exposure to a novel environment, STN-lesioned rats were more active than control rats when fooddeprived (F_(1,16) = 12.06; p < 0.01), although this effect disappearedwith repeated exposures to this environment (no significant groupeffect for the last four sessions) (Fig. 2A). During the nextstage, when food was provided in the locomotor activity cagesafter 30 min, no difference between groups could be found duringthe preceding 30 min of the first session (p > 0.05) because animalscould not predict the presentation of food pellets in the cages.However, from the second day of this conditioning phase, animalsincreased their activity over the sessions, as an expression ofexpectation of the food presentation (sessions, F_(9,144) = 38.38;p < 0.01), this effect being stronger in the STN group (group× sessions interaction, F_(9,144) = 3.33; p < 0.01) (Fig. 2B).This response diminished when food was no longer presented inthe locomotor activity cages but given in the animal holding roominstead. Although extinction was slower in the STN group (group× sessions interaction, F_(13,208) = 3.84; p < 0.01), no significantdifference was recorded between the two groups for the last threesessions (sessions 11-14, p > 0.05) (Fig. 2C, left). When allanimals were prefed (after access to food ad libitum for 1 hrbefore testing), no significant difference was recorded betweenthe two groups (group, F_(1,16) = 0.42; p > 0.05) (Fig. 2C, right).

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Figure 2. Effects of bilateral STN lesions on conditioned locomotor response for food over the various phases: habituation (A), conditioning (B), and extinction and prefeeding (C). Each point represents the mean ± SEM number of cell-beam crosses during the first 30 min for the various daily sessions (abcissas). The activity is illustrated for sham control animals (open circles; n = 11) and for STN-lesioned rats (filled squares; n = 7).

Conditioned reinforcement
Conditioned reinforcement reflects the process whereby a previously conditioned stimulus acts as the reinforcer for an instrumentalaction (Mackintosh, 1974). This test allows, in two separate phases,the measurement of the following: (1) the strength of Pavlovianconditioning (i.e., association between a CS (a light) and a US(sucrose solution); and (2) the rewarding properties of the stimulusthat was paired previously with foodreward.
After recovery from surgery, the rats were given four sessions of the Pavlovian conditioning phase to check for the effectsof the lesion on the CS-US pairing. There was no significant differencebetween the sham- and STN-lesioned rats during this phase. Asshown in Figure 3, when rats have the choice between the CR lever(having for consequence the occurrence of the CS associated previouslywith the sucrose solution) and the NCR lever (having no consequence),they press preferentially on the CR lever (lever effect, F_(1,18)= 25.90; p < 0.01). The number of lever presses on the CR leverwas significantly higher in the STN lesion group than in the shamcontrol group (group, F_(1,18) = 6.71; p < 0.05) (group × leverinteraction; F_(1,18) = 5.16; p < 0.05).

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Figure 3. Effects of post-training bilateral STN lesions on acquisition of responding with a conditioned reinforcer (CR). The number of lever presses on the lever producing the CS (CR lever) and on the control lever (NCR) are illustrated for sham (filled and open circles, respectively; n = 7) and lesioned (filled and open squares, respectively; n = 4) animals. Vertical bar, SEM.

Evaluation of the reinforcing property of food (progressive ratio schedule)

Under progressive ratios, the measure of the last ratio reached (also called "breaking point") allows to assess the amountof effort a rat is willing to expend to obtain the food reinforcer.Under this procedure, rats with bilateral STN lesions reacheda significantly higher breaking point than sham control animals(group effect, F_(1,13) = 6.47; p < 0.05) (Fig. 4A). STN-lesionedrats exhibited a higher rate of lever presses (group effect, F_(1,13)= 4.73; p < 0.05) (Fig. 4B), worked longer, and completed thesession after the sham rats (group effect, F_(1,13) = 8.74; p <0.05) (data not shown).

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Figure 4. Effects of bilateral STN lesions on performance in the PR task evaluated by the mean ± SEM last ratio reached during the session (i.e., breaking point) (A) and the rate of responding measured as the total number of lever presses per minute (±SEM) (B). Sham control animals (n = 8; open circles) and STN-lesioned animals (n = 7; filled squares) performance is illustrated over 10 sessions.

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
Apparatus
Statistical analysis
Surgery
Histology
RESULTS
DISCUSSION
REFERENCES

In this series of studies, we obtained converging results from several different paradigms for measuring food-motivated respondingto show that bilateral lesions of the STN can enhance these aspectsof appetitive motivation, thus providing a novel perspective onthe functional interactions of this nucleus within the outflowcircuitry of the basal ganglia. Rats with lesions of the STN consumedfood reward pellets more quickly, exhibited heightened activityconditioned to food presentation, showed an exaggeration of theconditioned reinforcing properties of stimuli formerly predictiveof food delivery, and increased breaking points on a progressiveratio schedule designed to assess motivation to work for foodreward. The results may have some clinical significance in viewof reports of effects of STN high-frequency stimulation alteringmood, and also feeding, in PDpatients.

The behavioral analysis required the use of several paradigms to demonstrate the generality of the enhanced appetitive motivationin STN-lesioned rats. The conditioning of locomotor activity tothe periodic presentation of food has traditionally been regardedas a powerful demonstration of incentive motivation for food,i.e., a state in which general increases in behavior are generatedby a central motive state of eating (Bolles, 1972; Bindra, 1978).Thus, the greatly elevated levels of locomotor activity in anticipationof food presentation in STN-lesioned rats is consistent with heightenedincentive motivation. The demonstration of enhanced Pavlovianconditioning was complemented by the finding that food-relatedconditioned reinforcers exert greater control over instrumentalresponding in the STN-lesioned animals. Finally, in a situationin which such influences may combine to influence the amount ofeffort invested by the animals in obtaining food, STN-lesionedrats showed greater propensity to work for food reward under aprogressive ratio schedule. This was shown from the fact thatsham-operated controls ceased operant responding before rats withSTN lesions as the required number of responses for each standarddelivery of food was progressivelyincreased.

These effects are unlikely simply to reflect nonspecific motor disinhibition, as has been suggested previously to accountfor increases in impulsive responding in reaction time settings(Baunez et al., 1995; Phillips and Brown, 1999). This is becausethe increases in response output observed here after STN lesionsare situation dependent. For example, STN lesion-induced locomotorhyperactivity is restricted to novel test situations, not extendingover the full 120 min testing period or repeated sessions of testing.Moreover, the hyperactivity was contingent on the presence ofstate of feeding motivation: prefeeding or extinction removedtheeffect.

When STN-lesioned rats were tested after pretraining to approach a food magazine during a food-predictive CS, they did notexhibit nonspecific tendencies to approach when the CS was notpresented, again demonstrating a lack of nonspecific behavioraldisinhibition. Instrumental responding for conditioned reinforcementinvolved a choice situation, in which pressing a control leverhad no effect but was equivalent in motoric terms to respondingon the lever providing conditioned reinforcement. The STN lesionsselectively enhanced responding on this conditioned reinforcementlever but did not affect responding on the control lever. It seemsmost parsimonious to conclude that the STN-lesioned rats wereexhibiting higher levels of motivation with respect to food-relatedbehaviors than simple motor disinhibition. This conclusion isalso supported by the finding that these rats ate food pelletsmore quickly in a consumption test. It is unlikely that the ratshave primary changes in hunger, because their weight was equivalentto that of controls when food deprived and they gained weightnormally when allowed ad libitum access to food. The present experimentsmeasuring food intake directly argue against an effect of STNlesion on primary motivation or hunger. Overall, however, it isapparent that STN lesions affect food-seeking, appetitive ratherthan consummatorybehavior.

As in previous studies (Baunez et al., 1995; Baunez and Robbins, 1997, 1999; Baunez et al., 2001), the bilateral STN lesionselectively damaged all sectors of the STN bilaterally, sparingonly a few cells in the most lateral portions of the nucleus.Lesions were restricted to the STN, but some rats exhibited sparingof the nucleus and were excluded from the behavioral analyses.In all cases, these animals performed similarly to sham-operatedcontrols.

Therefore, it appears that the behavioral effects arose from damage to the STN, which would disrupt outflow from the striatumfor behaviors generally associated with ventral, rather than dorsal,striatal function. Previous work has indicated the important roleof the STN as part of the "indirect pathway" implicated in modulatingthe balanced output from the dorsal striatum at the level of theglobus pallidus, internal segment (GPi) substantia nigra (Wichmannet al., 1994; Baunez and Amalric, 1996). Those studies in generalhave emphasized the role of the STN in the control of responseoutput, for example, in reaction time settings, consistent withthe hypothesis that the dorsal striatum is concerned with thecontrol of motor output and some aspects of cognitive function(Graybiel et al., 1994; Baunez et al., 1995). The present study,in contrast, has studied some aspects of behavior that have beenlinked with the functioning of the nucleus accumbens, for example,responding for conditioned reinforcement (Beninger et al., 1981;Robbins et al., 1989, Kelley and Delfs, 1991), conditioned locomotoractivity (Jones et al., 1990), and schedule-controlled respondingwith progressive ratios (Bowman and Brown, 1998; Eagle et al.,1999). For example, responding with conditioned reinforcementis relatively less affected by dopamine depletion in the dorsal,compared with ventral, striatum (Taylor and Robbins, 1986). Moreover,although PR responding is affected by dorsal striatal damage,this generally reflects motor or executive, rather than motivational,effects (Eagle et al., 1999). Thus, the excitotoxic lesions ofthe lateral striatum produced perseverative responding and someslowing of responding but did not affect breaking point per se.Moreover, medial striatal lesions mainly slowed the latency tocollect earned food rather than affecting the breaking point forinstrumental responding. In contrast, Bowman and Brown (1998)showed that excitotoxic lesions of the nucleus accumbens increasedthe breaking point, analogous to the effects of STN lesions. Finally,consistent with this analysis, the control of locomotor activityis generally associated with the ventral striatal circuitry ratherthan that from dorsal striatum (Kelly et al., 1975). However,the increased feeding seen after STN lesions might be associatedwith dorsal (Pisa, 1988), as well as ventral, striatal (Kelley,1999) outflow because regions within the rat striatum are implicatedin the control of consummatory behavior. More recently, the excitatorySTN projections to the ventral pallidum have been shown to playa major role in ventral pallidal activity (Turner et al., 2001).Thus, some of the effects observed after STN lesions on feedingbehavior may be mediated through the ventral pallidum, in whichpharmacological manipulations have been shown to affect feedingbehavior (Stratford et al., 1999). Overall, our data are consistentwith the STN being implicated in the expression of several componentsof motivation, including both consummatory and appetitive aspects,under control of both the dorsal and ventralstriatum.

These new results reflect the anatomical relations that have been highlighted recently to exist between the ventral striatumand STN. Thus, the STN also participates in a "ventral loop" encompassingthe nucleus accumbens, ventral pallidum, and STN, which is analogousto the indirect pathway of the dorsal striatum. More specifically,the core region of the nucleus accumbens projects to that ventralpallidal area, which projects to the medial part of the STN (Mauriceet al., 1999). There are successive GABAergic connections fromthe core region to the STN (via the ventral pallidum), suggestingthat lesions of the STN should simulate in part effects of corelesions. However, although our data on locomotor activity andthe progressive ratio performance after STN lesions are consistentwith this simple picture (Bowman and Brown, 1998; Parkinson etal., 1999), it does not fit for the present effects of STN lesionson instrumental responding for conditioned reinforcement (Parkinsonet al., 1999) or food pellet consumption, the latter being moresensitive to manipulations of the nucleus accumbens shell (Kelley,1999). Evidently, the functional role of the STN is not simplyas an output relay of the nucleus accumbens. This complexity isalso evident in comparing effects of STN lesions with those ofdorsal striatal lesions on reaction time or attentional tasks.It is possible that the additional cortical projections to theSTN exert additional influences, which may explain these functionaldifferences.

The present experimental findings may be relevant in part to certain clinical observations of effects of STN lesions or stimulationon mood, feeding, and other forms of motivation (Trillet et al.,1995). For example, a recent case report showed that an STN infarctinduced hypersexuality (Absher et al., 2000). Although there areno reports of changes of feeding motivation after STN lesions,pallidotomies or deep brain stimulation affecting GPi or STN arewell known to enhance appetite and induce weight gain in PD patients(Lang et al., 1997; Moro et al., 1999; Ondo et al., 2000). Finally,STN stimulation has also been reported to have beneficial or detrimentaleffects on mood (Ardouin et al., 2000; Trépanier et al., 2000;Krack et al., 2001), apparently not secondary to simple motoreffects. Our results suggest that it may be profitable to reexaminethese motivational effects of STN stimulation quite closely, notonly for possible benefits in PD, but also in the treatments ofabulic states (Brown and Pluck, 2000) resulting from basal gangliadamage.

  FOOTNOTES

Received July 9, 2001; revised Oct. 10, 2001; accepted Oct. 19, 2001.

This study was supported by the Centre National de la Recherche Scientifique (CNRS), 5th Programme-Cadre de Recherche et deDéveloppement Technologique. Funding Grant QLK6-1999-02173, theFondation France Parkinson (M.A.), CNRS-Royal Society funding,and the Wellcome Trust (T.W.R.). C.B. was supported by Human FrontierScience Program Long-Term Fellowship LT-358/1996 at the beginningof the work. We thank Dr. M. Cador for helpful discussion, Y.Darbaky for helping with the consumption test, D. Terramorsi fortaking care of the animals, and Eric Dubois and Céline Martinfor computer programmingassistance.
Correspondence should be addressed to Christelle Baunez, Laboratoire de Neurobiologie Cellulaire et Fonctionnelle, CentreNational de la Recherche Scientifique, 31 Chemin Joseph Aiguier,13402 Marseille cedex 20, France. E-mail: baunez{at}lncf.cnrs-mrs.fr.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
Apparatus
Statistical analysis
Surgery
Histology
RESULTS
DISCUSSION
REFERENCES

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