Modulation by Central and Basolateral Amygdalar Nuclei of Dopaminergic Correlates of Feeding to Satiety in the Rat Nucleus Accumbens and Medial Prefrontal Cortex

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The Journal of Neuroscience, December 15, 2002, 22(24):10958-10965

Modulation by Central and Basolateral Amygdalar Nuclei of Dopaminergic Correlates of Feeding to Satiety in the Rat Nucleus Accumbens and Medial Prefrontal Cortex
Soyon Ahn and Anthony G. Phillips
Department of Psychiatry and the Brain Research Centre, University of British Columbia, Vancouver, Canada V6T 2A1

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Current studies raise the possibility that subregions within the amygdala may interact with the mesocorticolimbic dopamine(DA) system to subserve specific psychological processes underlyingfood reward. The present study compared the effect of reversibleinactivation of the central nucleus (CeN) versus the basolateralamygdala (BLA) on DA efflux in the nucleus accumbens (NAc) andmedial prefrontal cortex (mPFC) in hungry rats that were testedin a food-devaluation procedure. During DA microdialysis experiments,lidocaine, a sodium channel blocker, was delivered via reversedialysis into the CeN or BLA while rats were given two consecutivemeals of Froot Loops. Loss of CeN function impaired the developmentof satiety during an initial meal and, consequently, diminishedthe effect of devaluation by satiety on intake of the same foodduring a second meal. Inactivation of the CeN was also associatedwith decreased basal levels of DA efflux in the NAc before foodintake and attenuated increases in DA efflux related to anticipatoryand consummatory aspects of feeding in both the NAc and mPFC.In contrast, inactivation of the BLA did not affect feeding behavioror DA efflux. Overall, these findings indicate that the CeN andBLA independently modulate DA transmission in both terminal regions.It is proposed that interaction between the CeN and mesocorticolimbicDA activity may be a mechanism by which hunger and satiety signalsinfluence the value of food reward, or alternatively, a mechanismby which memory for a recently consumed food regulates foodintake.

Key words: microdialysis; reverse dialysis; lidocaine; reversible inactivation; incentive devaluation; food reward

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Two dissociable psychological processes are proposed to underlie food reward: an evaluation of the hedonic properties of foodand the motivation to eat (Berridge and Robinson, 1998). Hedonicresponses believed to reflect the "liking" of food depend on benzodiazepinecircuits in the brainstem (Berridge and Treit, 1986; Berridge,1996), as well as GABAergic, glutamatergic, and opioid circuitsin the forebrain (Bechara and van der Kooy, 1992; Bakshi and Kelley,1994; Maldonado-Irizarry et al., 1995; Stratford and Kelley, 1997).Motivation related to "wanting" involves activation of the mesocorticolimbicdopamine (DA) pathway (Mogenson and Phillips, 1976; Berridge,1996). Specifically, DA activity has been hypothesized to mediatethe attribution of incentive salience to environmental stimuliassociated with a primary reward (Robinson and Berridge, 1993),a process that may allow conditioned stimuli to serve as incentivesthemselves or guide an animal into contact with a primaryreward.

Important questions remain regarding the neural mechanisms by which changes in motivation, such as those that accompany satiety,can influence the reward value of food. A key role in this processmay be played by the amygdala, a forebrain structure that receivessensory information (e.g., olfactory and gustatory) from the brainstemand the cortex, as well as physiological signals related to hungerand satiety via brainstem nuclei (Mei, 1994; Zeigler, 1994; Norgren,1995; Shipley et al., 1995; Woods et al., 1998). In previous studies,impairments in food-related behaviors were reported in monkeysand rats with amygdala lesions, including indiscriminate samplingof nonfood items, altered food preferences, and interference withreinforcer devaluation effects (Box and Mogenson, 1975; Aggletonand Passingham, 1982; Murray et al., 1996; Màlkovà et al., 1997).These observations, together with known neuroanatomical connections,suggest that the amygdala may serve to interface external andinternal sensory information with the motivational systems ofthe brain (Rolls, 1999), namely the mesocorticolimbic DA system.More recent studies of functional amygdalar circuitry have focusedon two subregions delineated by anatomical connectivity and immunohistochemicalmarkers, the central nucleus (CeN) and the basolateral amygdala(BLA) (McDonald, 1991; Pitkänen et al., 1997; Swanson and Petrovich,1998) . The significance of each subregion in the rat has beenexamined with several behavioral learning paradigms, in both appetitivelyand aversively motivated contexts (Killcross et al., 1997; Everittet al., 1999; Holland and Gallagher, 1999). Of particular relevanceto food reward are reports that the CeN and the BLA are involvedin the coding of incentive value of food (Kesner et al., 1989;Uwano et al., 1995; Salinas et al., 1996).

In view of the above considerations, an interaction between the CeN and/or the BLA with DA transmission in the nucleus accumbens(NAc) and/or the medial prefrontal cortex (mPFC) may be a mechanismby which internal motivational signals, such as hunger and satiety,determine the incentive value of food. In a recent study, we reportedthat the CeN and the BLA differentially influence basal and feeding-evokedchanges in DA efflux in both terminal regions (Ahn and Phillips,2002). To explore further the relevance of these interactionsin feeding behavior, the present study compared the effect ofreversible inactivation of the CeN versus the BLA on DA effluxin the NAc and mPFC in rats that were tested in a food-devaluationprocedure. During microdialysis experiments, hungry rats werereverse dialyzed with lidocaine, a sodium channel blocker, intothe CeN or the BLA before and during an initial meal of FrootLoops. Forty minutes later, rats were presented with a secondmeal of Froot Loops to investigate possible post-lidocaine effectson intake of food devalued by satiety. A previous finding thatinactivation of the BLA triggers oscillatory changes in DA effluxin the mPFC precluded the assessment of feeding-evoked changesin DA levels in this terminal region (Ahn and Phillips, 2002).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

All experimental protocols were approved by the Committee on Animal Care (University of British Columbia) and were conductedin compliance with guidelines provided by the Canadian Councilof AnimalCare.

Subjects and surgery
Twenty-six Long-Evans male rats (Charles River Canada, St. Constant, Quebec, Canada) were housed in a colony room maintainedat ~21°C with a 12 hr light/dark cycle (lights on at 6:00 A.M.).Rats weighting 300 ± 20 gm were assigned randomly to one of threegroups based on the structures of interest (CeN-NAc, CeN-mPFC,and BLA-NAc) and implanted with guide cannulas under xylazine(7 mg/kg, i.p.) and ketamine hydrochloride (100 mg/kg, i.p.) anesthesia.Stereotaxic coordinates for the CeN, BLA, NAc, and mPFC were basedon Paxinos and Watson (1997). Nitric acid-passivated stainlesssteel guide cannulas (19 gauge, 15 mm) for reverse dialysis wereimplanted bilaterally 1 mm below dura, directly above either theCeN [ $-$ 2.3 mm anteroposterior (AP) and ±4.0 mm mediolateral (ML)from bregma, $-$ 7.7 mm dorsoventral (DV) from dura] or BLA ( $-$ 3.0mm AP and ±5.0 mm ML from bregma, $-$ 8.4 mm DV from dura). Similarly,guide cannulas for microdialysis probes were implanted above theNAc (+1.7 mm AP and ±1.1 mm ML from bregma, $-$ 8.0 mm DV from dura)or the mPFC (+3.0 mm AP and ±0.6 mm ML from bregma, $-$ 4.5 mm DVfromdura).
After surgery, rats were housed individually in plastic bins with corncob bedding. After a 1 week period of recovery, ratswere placed on a restricted feeding schedule (20-25 gm daily;Rat Diet 5012; PMI Feeds, Delta, British Columbia, Canada) tomaintain their body weight at 85-90% of free-feeding weight. Waterwas available ad libitum. Novel objects (e.g., sterilized eggand milk cartons) were introduced into home bins weekly to promoteexploratory and playbehavior.

Microdialysis and HPLC
Microdialysis probes were concentric in design with silica inlet-outlet lines. The active surface consisted of a semipermeablemembrane 2 mm in length (340 µm outer diameter; 65,000 molecularweight cutoff; Filtral 12; Hospal, Neurnberg, Germany). Probeswere flushed continuously at 1 µl/min with a modified Ringer'ssolution [i.e., "perfusate" (in mM): 10 sodium phosphate, 1.2CaCl₂, 3.0 KCl, 1.0 MgCl₂, and 147.0 NaCl, pH 7.4] using a 2.5ml gastight syringe (Hamilton, Reno, NV) and a syringe pump (model22; Harvard Apparatus, South Natick, MA). Typical in vitro proberecoveries of DA conducted at room temperature were 18 ± 1% ofa standard DA solution. DA was separated from other chemical speciespresent in microdialysis samples by HPLC and quantified by electrochemicaldetection. The details of the HPLC methods have been describedpreviously (Fiorino et al., 1997; Ahn and Phillips, 1999).

Reverse dialysis of lidocaine
Probes used for reverse dialysis of lidocaine were a modified version of the microdialysis probes described above. The lengthof the active membrane surface was adjusted to cover the maximaldorsoventral extent of each structure: 1.2 mm for the CeN and1.8 mm for the BLA (Paxinos and Watson, 1997). Reverse dialysisof lidocaine involved replacing normal perfusate that flowed throughthe probe with perfusate containing 2% lidocaine hydrochloride(20 mg/ml; Research Biochemicals, Natick, MA) for a 70 min interval.The rate of flow through the probe was maintained at 1 µl/minat alltimes.

Apparatus and protocol for feeding paradigm
All habituation sessions and experiments were conducted from 8:00 A.M. to 2:: 00 P.M. in a Plexiglas chamber (42 × 38 × 38cm) fitted with a perforated screen and a two-channel liquid swivel(Instech Laboratories, Plymouth Meeting, PA). Two weeks into therestricted feeding schedule described above, rats were habituatedtwice (days 1 and 2) to being tethered to the liquid swivel bya stainless steel coil and also presented with the test food FrootLoops, a fruit-flavored cereal (Kellogg Canada, London, Ontario,Canada), to overcome neophobia. On day 3, rats were given a trialrun of the two-meal feeding paradigm. At the start of each meal,3 gm of Froot Loops was presented in the food bin behind a screenfor 10 min (the appetitive period), during which animals couldsee and smell the food. The screen was then removed, and animalshad access to the food for 10 min, after which the remaining food,if any, was replaced by another 3 gm of food every 10 min fora total of 40 min (the consummatory period). After a 40 min recess,a second meal of Froot Loops was presented in the same manneras the firstmeal.

Microdialysis experiments
On days 5 and 6, microdialysis experiments were conducted during the two-meal feeding paradigm described above. Each animalwas tested in two conditions in random order, one involving bilateralreverse dialysis of lidocaine in the CeN or BLA and the othercontinuous flushing of the probe with normalperfusate.
Fourteen to 16 hr before the collection of the first sample, microdialysis probes were implanted unilaterally into eitherthe NAc or mPFC, and reverse-dialysis probes were placed bilaterallyinto either the CeN or BLA. For the purpose of controlling forpotential hemispheric differences, the left and right NAc or mPFCof each subject were randomly assigned to the lidocaine or controlcondition. Animals remained overnight in the test chamber, withtheir daily ration of food and ad libitum access to water. Inthe morning, dialysis samples were collected at 10 min intervals(i.e., 10 µl) from the NAc or mPFC and immediately assayed forDA using HPLC and electrochemical detection. Baseline samplingcontinued until four consecutive microdialysis samples showed<5% fluctuation in DA content before beginning reverse dialysisof lidocaine or vehicle (normal perfusate) into the CeN or BLAfor a total of 70 min. After the initial 20 min of perfusion witheither lidocaine or normal perfusate, the first meal of FruitLoops was presented behind the screen. A second meal of the samefood was presented 40 min after termination of lidocaine administration(i.e., when DA efflux had returned to baselinelevels).

Histology
After the final microdialysis session, animals were anesthetized with chloral hydrate and perfused intracardially with 0.9%sodium chloride solution and then 3.7% paraformaldehyde solution.Brains were then removed and stored in Formalin with 20% w/v sucrosefor a few days, sliced into 50 µm coronal sections, and then stainedwith cresyl violet for verification of probe placements. Animalswith tracts in both the (1) prelimbic-infralimbic region of themPFC or shell-core region of the NAc and (2) CeN in the rostralamygdala or BLA in the caudal amygdala of both hemispheres wereincluded in the statisticalanalyses.

Data analyses
Anticipatory behaviors. Anticipatory behaviors, defined as orienting and approach toward food placed behind a perforated screen,sniffing, and increased locomotor activity, were scored on a categoricalrating of 1, for display of anticipatory behavior, or 0, for nobehavior. These scores were then compared using the nonparametricstatistic $chi$ ².
Consummatory behavior and DA efflux. For the purposes of statistical analyses and graphical representation, DA efflux datawere normalized to a baseline value (calculated by averaging theconcentration of DA in the three samples preceding the final baselinesample). Consummatory behavior (i.e., amount of food consumed)and DA data were analyzed using repeated-measures ANOVAs, followed,when appropriate, by tests of simple main effects. In the lattertests, the significance level was adjusted according to the totalnumber of tests to maintain a family-wise rate of type I errorat p < 0.05. DA data were further analyzed using Dunnett's methodfor comparisons from baseline and Dunn's tests for comparisonsbetween the control and lidocaine conditions. The Huynh-Feldtcorrection for nonsphericity was applied to the degrees of freedomfor all within-subject analyses. Statistical analyses were performedusing Systat (Evanston, IL) or SPSS (Chicago, IL) statisticalpackages.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Basal concentration of DA in microdialysates collected from the mPFC and NAc

The average concentration of DA uncorrected for probe recovery in the last three samples before administration of lidocaineby reverse dialysis in the CeN and the BLA were 0.14 ± 0.19 nMin the mPFC (CeN-mPFC group) and 3.03 ± 0.92 nM in the NAc (CeN-NAcand BLA-NAcgroups).

Effects of inactivation of the CeN on feeding behavior and DA efflux

Feeding behavior
Reverse dialysis of lidocaine into the CeN increased overall intake of Froot Loops when compared with the normal perfusatecondition in each of the CeN-NAc and CeN-mPFC groups (F_{(7, 49)}= 3.555, p = 0.004 and F_{(7, 56)} = 3.286, p = 0.005, respectively).Because there was no significant difference in food intake betweenthe two lidocaine conditions or between the two normal perfusateconditions, the data were collapsed across the two CeN groupsinto one lidocaine and one normal perfusate condition for subsequentstatistical analyses. There was a significant interaction of condition× time on the amount of food consumed per 10 min over the two40 min meals (F_(7,112) = 4.616; p < 0.001).
In the control condition (Figs. 1A, 2A, bar graphs), food-deprived rats were continuously dialyzed with normal perfusate inthe CeN while they were presented with two meals of a highly palatablefood, Froot Loops. Presentation of the initial meal behind a perforatedscreen elicited anticipatory behaviors ranging from sniffing andorienting toward the food bin behind the screen, approach towardthe screen, as well as rearing and pacing in front of the screen.When the screen was removed, these control rats quickly approachedthe food and started to eat. There was a gradual decrease in theamount of food intake over the initial meal, a pattern consistentwith the development of satiety. During the recess, when the screenwas placed back into the testing chamber, animals were observedto return to a corner, groom, and then sleep. When a second mealof the same food was presented, animals did not show anticipatoryresponses toward the food source and, after removal of the screen,took much longer to approach the food bin. Occasional samplingof small amounts of food indicated the rats' satiated state. Overall,control rats consumed significantly more food during the firstmeal compared with the second meal (6.63 and 1.34 gm, respectively;p < 0.05).

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Figure 1. Effect of reversible inactivation of the CeN on DA efflux in the NAc associated with a food-devaluation protocol. Perfusion of the CeN with normal perfusate (A; n = 8) or perfusate containing 2% lidocaine (B; n = 8). Changes in DA efflux (line graph) and amount of food consumed (bar graph) per 10 min bins are represented as mean + SEM. Samples 4 and 13 represent periods during which a palatable food was presented behind a perforated screen, and changes in DA efflux during these periods are highlighted by dashed lines. Samples 5-8 and 14-17 represent periods during which animals had access to the food. Sample 1 (white circle) represents the baseline value used as the control mean in Dunnett's tests (*p < 0.05). Comparisons between perfusate only and lidocaine conditions were conducted using Dunn's tests ( $dagger$ p < 0.05).

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Figure 2. Effect of reversible inactivation of the CeN on DA efflux in the mPFC associated with a food-devaluation protocol. Perfusion of the CeN with normal perfusate (A; n = 8) or 2% lidocaine (B; n = 10). For additional explanation, see Figure 1 legend. *p < 0.05; p < 0.05.

Inactivation of the CeN altered both anticipatory and consummatory behaviors associated with food. During administration oflidocaine into the CeN, rats became aroused briefly and startedto explore the testing chamber indiscriminately. In contrast tothe control condition, none of the lidocaine-treated rats showedanticipatory responses toward the food ( $chi$ ² = 34.0; p < 0.001). Specifically, when the first meal of FrootLoops was presented behind the screen, rats did not make normalorienting or approach responses toward the food. In fact, severalanimals returned to a corner of the chamber and assumed a sleepposture or satmotionless.
When the screen was removed, lidocaine-treated rats took slightly longer than control rats to approach the food bin (>1 vs<1 min, respectively) and consume the food. These rats manipulatedand tasted each morsel of the food but they did not eat efficientlyand repetitively discarded partially eaten pieces of Froot Loops.Furthermore, the rats did not show a typical decrease in the amountof intake over time associated with the development of satietyduring a large extended meal (as reported by Ahn and Phillips,1999). Rather, the amount consumed per 10 min remained relativelystable throughout the first meal (Figs. 1B, 2B, bar graphs). Aftera 40 min recess, during which normal perfusate replaced the lidocainein the probe, animals were presented with a second meal of FrootLoops behind the screen. This elicited normal anticipatory behaviors,including increased locomotion, approach toward the screen, andsniffing toward the food. After removal of the screen, all ratsimmediately approached the food bin and began to eat. A gradualdecrease in amount of food intake during the second meal was consistentwith the development of satiety. Although these lidocaine-treatedrats consumed a significantly larger quantity of food during theinitial meal (6.64 gm) compared with the second meal (3.34 gm;p < 0.05), the amount consumed in the second meal was significantlygreater than that consumed in the second meal by control subjects(1.34 gm; p < 0.05).

DA in the NAc
A two-way repeated-measures ANOVA confirmed a significant condition × time interaction on DA efflux in the NAc (F_(16,112)= 7.602; p < 0.001). Additional analyses revealed a simple maineffect of time in both the lidocaine (F_(16,112) = 6.089; p < 0.001)and control (F_(16,112) = 6.607; p < 0.001)conditions.
Reverse dialysis of normal perfusate did not alter basal levels of DA efflux in the NAc (Fig. 1A, line graph). Presentationof the first meal behind the screen (the anticipatory period)was accompanied by significant increases in DA efflux (+17%; p< 0.05). When the screen was removed and animals were allowedto consume the food (the consummatory period), there was an immediatesignificant increase in DA efflux that reached a maximal valueof +42% (p < 0.05). This was followed by a gradual decline inDA efflux that mirrored the decreasing amount of food intake,and, during the recess period, DA levels returned to baselinevalues. Presentation of the second meal behind the screen or samplingof the food once the screen was removed failed to elicit additionalchanges in DAlevels.
When lidocaine was reverse dialyzed into the CeN, basal DA efflux in the NAc was decreased significantly to values 19-21%below baseline (p < 0.05) (Fig. 1B, line graph). While the CeNremained inactivated, presentation of the first meal behind ascreen did not evoke any anticipatory changes in DA efflux (sample4). Consumption of the first meal elicited a significant, albeitsmall, increase in DA efflux (+19% from the suppressed basal DAlevels; p < 0.05) that remained at pre-lidocaine baseline levelsthrough the first meal. At the start of the recess, replacementof lidocaine with normal perfusate in the CeN probes did not changeDA efflux from baseline. Presentation of the same food as a secondmeal did not elicit anticipatory changes in DA efflux (sample13); however, after consumption of this meal, there was a significantincrease in DA efflux that reached a maximal value of +33% (p< 0.05). The subsequent decrease in amount of food intake per10 min was accompanied by a gradual decline toward baseline inlevel of DAefflux.

DA in the mPFC
A two-way repeated-measures ANOVA confirmed a significant condition × time interaction on DA efflux in the mPFC (F_(16,128)= 8.331; p < 0.001). Additional analysis revealed a simple maineffect of time in both the lidocaine (F_(16,128) = 4.561; p < 0.001)and control (F_(16,128) = 11.708; p < 0.001)conditions.
In the control condition, administration of normal perfusate in the CeN did not alter basal levels of DA efflux in the mPFC(Fig. 2A, line graph). In general, the pattern of DA efflux inthe mPFC closely mirrored the pattern of food intake. Presentationof the first meal elicited significant increases in DA effluxduring the anticipatory period (+43%; p < 0.05). Removal of thescreen was accompanied by a significant feeding-related increasein DA efflux (+92%; p < 0.05) that gradually decreased towardbaseline values as animals reached satiety for the food. Duringthe second meal, neither anticipatory nor consummatory-relatedchanges in DA efflux wereobserved.
In contrast to the effects on DA efflux in the NAc, administration of lidocaine into the CeN did not alter basal DA effluxin the mPFC (Fig. 2B, line graph) but did prevent anticipatoryincreases in DA efflux during the first meal (sample 4). Furthermore,as described above, the unusual pattern of food intake displayedby rats treated with lidocaine in the CeN was associated withan increase in DA efflux that was significantly attenuated comparedwith the control condition (+20 vs +94% during the first 10 min,respectively; p < 0.05). DA levels remained near baseline forthe remainder of the meal, as well as throughout the recess period.Presentation of the second meal elicited significant increasesin DA efflux associated with anticipatory behaviors (+43%; p <0.05) and consumption of food (maximal increase of +58%; p < 0.05).

Effects of inactivation of the BLA on feeding behavior and correlated DA efflux

Feeding behavior
In contrast to the CeN-lidocaine group, rats with BLA inactivation did not show behavioral activation coincident with lidocaineadministration. No statistical differences in the pattern of foodintake were observed between the lidocaine and control conditions(F_(1,8) = 2.918; p < 0.126). Nevertheless, the slightly higherrate of consumption in the lidocaine compared with the controlcondition (Fig. 3, bar graphs) suggests that inactivation of theBLA may have some residual effect on satiety. Alternatively, theseresults may be viewed to fall within the normal range of variabilityin the pattern and amount of food intake, especially during thesecond and third bins, of the initial meal of other animals inthe present study (Figs. 1A, 2A). In this respect, a normal patternof feeding to satiety was observed in both conditions, with ratsconsuming significantly less food during the second meal in thelidocaine (8.3 ± 1.3 vs 1.9 ± 0.9 gm; p < 0.05) and control (6.1± 1.1 vs 1.1 ± 0.4 gm; p < 0.05) conditions (Fig. 3, bar graphs).

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Figure 3. Effect of reversible inactivation of the BLA on DA efflux in the NAc during a food-devaluation protocol. Perfusion of the BLA with normal perfusate (A; n = 8) or 2% lidocaine (B; n = 9). For additional explanation, see Figure 1 legend. *p < 0.05.

DA in the NAc
There were no statistically significant differences in DA efflux in the NAc between the lidocaine and control conditions (F_(1,8)= 0.848; p < 0.384). There was a significant main effect of timein each of the lidocaine (F_(16,128) = 1.745; p < 0.05) and control(F_(16,128) = 5.729; p < 0.001) conditions. Presentation of thefirst meal behind the screen (Fig. 3, line graphs) elicited anticipatoryincreases in DA efflux that were significant in the control condition(+16%; p < 0.05) but not in the lidocaine condition (+12%). Consumptionof the meal was associated with significant increases in DA efflux,with a maximal increase of +30 and +31% in the lidocaine and controlconditions, respectively (p < 0.05). The second presentation ofthe same meal did not elicit significant changes in DA effluxassociated with anticipatory or consummatory phases of the experimentin eithercondition.

Histology

As illustrated in Figure 4, tracts left by microdialysis probes were located in the prelimbic-infralimbic region of the mPFC(+3.2 to +2.7 mm AP) or straddled the shell-core region of theNAc (+2.2 to +1.6 mm AP). Tracts left by reverse-dialysis probeswere located mainly in the CeN and but included some surroundingregions, such as the intercalated masses and substantia inominata( $-$ 1.8 to $-$ 2.6 mm AP). BLA tracts were seen in the basal and lateralnuclei and, in two animals, in the lateral aspect of the caudalCeN ( $-$ 2.8 to $-$ 3.3 mm AP).

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Figure 4. Location of reverse dialysis and microdialysis probes in the CeN and NAc (A), CeN and mPFC (B), and BLA and NAc (C), respectively. Vertical lines represent the dialyzing lengths of microdialysis probes (2.0 mm) in the NAc and mPFC and reverse dialysis probes in the CeN (1.2 mm) and BLA (1.8 mm). Drawings of coronal sections were adapted from Paxinos and Watson (1997). Distance from bregma is indicated.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Separate mechanisms underlie the modulation of DA efflux by the CeN and BLA

DA transmission in the mesocorticolimbic system is influenced by discrete manipulations of the CeN or the BLA (Floresco etal., 1998; Jackson and Moghaddam, 2001; Ahn and Phillips, 2002;Howland et al., 2002). The present effects on DA activity afterlidocaine-induced inactivation of the CeN show that this regionof the rat amygdala is involved in maintaining basal levels ofDA efflux in the NAc and modulating feeding-evoked increases inDA efflux in both the NAc and mPFC. The same manipulation of theBLA, however, had little effect on basal or feeding-related changesin DA efflux in the NAc. In a previous study, we observed thatinactivation of the BLA triggered large fluctuations in DA effluxin the mPFC, which indicates that the BLA may exert a stabilizinginfluence on basal levels of DA in the mPFC (Ahn and Phillips,2002). A recent study from our laboratory used electrical stimulationto examine amygdala-DA interactions and reported a dissociationeffect complementary to the present data (Howland et al., 2002).A brief 10 sec stimulation of the BLA, but not the CeN, causeda significant increase in DA efflux in the NAc. The combined resultsof these experiments suggest a double dissociation in the modulationof DA neurotransmission by the CeN and BLA. Specifically, basalor tonic levels of DA efflux are determined in part by tonic CeNinputs, whereas evoked or phasic increases in DA efflux are mainlyinfluenced by excitatory inputs from theBLA.

The present results indicate that the CeN and the BLA belong to separate circuits that function in parallel to modulate themesocorticolimbic DA system. The anatomical basis of this differentialinfluence on DA efflux in the NAc and the mPFC most likely involvesamygdalar projections to different levels of the DA system. Modulationof tonic levels of DA efflux in the NAc may involve a GABAergicprojection from the CeN to the midbrain, including the ventraltegmental area, the substantia nigra, and the retrorubral field(Phillipson, 1979; Wallace et al., 1992; Sun and Cassell, 1993).On the other hand, phasic changes in DA efflux may require excitatoryinputs from the BLA, which have been shown to terminate in closeproximity to DA varicosities in the NAc (Johnson et al., 1994).Thus, there exists in the NAc an anatomical arrangement consistentwith a presynaptic mechanism for modulation of DA efflux by theBLA. A similar arrangement of BLA and DA inputs to the mPFC hasyet to bedemonstrated.

Different roles for the CeN and BLA in food-related behaviors

Although many behavioral responses are sensitive to manipulations of both the CeN and the BLA, performance of specific classesof behavior can be impaired by lesions of the CeN but not theBLA and vice versa (for review, see Cardinal et al., 2002). Thepresent study used a free-feeding protocol that allowed rats toeat a palatable food to satiety during an initial meal and, duringa subsequent meal, tested whether the reward value of the samefood had been devalued by satiety. This protocol requires ratsto make simple behavioral responses to the smell or taste of food,a process that may recruit pavlovian orienting or approach responsestoward cues associated with food (Gallagher et al., 1990; Parkinsonet al., 2000a). The present disruptive effects of inactivationof the CeN on anticipatory and consummatory measures and associatedchanges in DA efflux in the NAc are consistent with previous reportsthat the CeN-NAc circuitry is involved in mediating approach responsestoward incentive stimuli (Everitt et al., 1999). Furthermore,the attenuating effect of CeN inactivation on feeding-evoked DAefflux in the mPFC serves, according to our knowledge, as thefirst indication that the CeN and its influence on DA mechanismsin the mPFC may be a neural substrate of foodreward.

In contrast to the CeN, the BLA and its input to the NAc become critical in complex situations that involve learning voluntaryinstrumental actions to obtain both conditioned or natural rewards(Killcross et al., 1997; Everitt et al., 1999; Holland and Gallagher,1999). For example, instrumental responding for food reward, second-orderpavlovian conditioning, and conditioned reinforcement are allimpaired after bilateral lesions of the BLA or functional dissociationof the BLA from the NAc via asymmetrical lesions (Simmons andNeill, 2001; Parkinson et al., 2000a; Setlow et al., 2002). Thepresent data also provide indirect support for this proposed function,because inactivation of the BLA did not affect free feeding orfeeding-evoked increases in DA efflux in the NAc. In general,the CeN appears to mediate stimulus-reward associations as occursduring feeding, whereas the BLA is involved when the value ofreward must be used in conjunction with a learning rule to performatask.

Role of the CeN and its interaction with the DA system in food reward

In the rat, the CeN receives important inputs involved in the regulation of food intake, including gustatory and olfactoryinformation, as well as feedback regarding the motivational stateof the animal (Mei, 1994; Zeigler, 1994; Norgren, 1995; Shipleyet al., 1995; Woods et al., 1998). Accordingly, manipulationsof the CeN have a wide range of effects related to feeding (Boxand Mogenson, 1975; Galaverna et al., 1993; Hatfield et al., 1996).In the present study, inactivation of the CeN had two distincteffects. During the initial meal, rats failed to display a gradualdecrease in food intake. During the second meal, when normal perfusatereplaced lidocaine in the CeN and normal function was restored,rats surprisingly consumed a second meal of the same food presumablydevalued to some degree, at least by preexposure, if not by satiety(Figs. 1B, 2B, bar graphs). These observations suggest that temporaryloss of CeN function impaired the development of satiety duringan initial meal (a "resistance to satiety" effect) and, consequently,diminished the effect of devaluation-by-satiety on intake of thesamefood.

Resistance to satiety may reflect a disruption of neural processes by which development of a satiety state devalues the hedonicqualities of the smell or taste of food. Alternatively, resistanceto satiety may be attributable to a failure to establish an associationbetween the sensory properties of a palatable food and the positivehedonic effect of consuming that food. It is noteworthy that,in monkeys, amygdala neurons that respond to food also respondto novel stimuli (Rolls, 1999). These electrophysiological datasupport Rolls' suggestion that "when relatively novel stimuliare encountered, they are investigated, e.g., by being smelledand then placed in the mouth, to assess whether the new stimuliare foods." In the absence of CeN function, animals may engagein excessive and prolonged oral examination of food, as observedin the present study and by Box and Mogenson (1975).

A key finding in the present study is that the CeN modulates important neurochemical correlates of free feeding, namely DAefflux in mesocorticolimbic terminal regions (Bassareo and DiChiara, 1997; Ahn and Phillips, 1999). In the present study, inactivationof the CeN altered both anticipatory- and consummatory-relatedchanges in DA efflux in the NAc and mPFC. Given the proposal thatDA activity is closely linked to the incentive valence of food(Bassareo and Di Chiara, 1997; Berridge and Robinson, 1998; Ahnand Phillips, 1999), interaction between the CeN and the mesocorticolimbicDA activity may be a mechanism by which an animal's current stateof hunger or satiety influences the incentive sensory propertiesof food (e.g., the olfactory or gustatory properties of food).Furthermore, the resistance to satiety effect after inactivationof the CeN suggests that this region of the rat amygdala mediatesadjustments in behavioral responses to changes in incentive valueof food (Galaverna et al., 1993; Salinas et al., 1996). However,this proposed role of the CeN remains controversial, because reinforcerdevaluation effects have been reported to be unaffected by lesionsof the CeN (Hatfield et al., 1996). In this regard, it is importantthat consummatory-related increases in DA efflux in the NAc andmPFC were attenuated rather than blocked during the second mealafter reverse dialysis of lidocaine in the CeN (Figs. 1B, 2B,line graphs). This raises the possibility that modulatory influenceson DA activity associated with food reward may originate fromother limbic regions, including the hippocampus and prefrontalcortex (Blaha et al., 1997; Parkinson et al., 2000b; Taepavarapruket al., 2000).

The disruption of satiety in rats after inactivation of the CeN may also be related to the concept of "oral metering," whichrefers to the memory of what and how much has been eaten. Thisconstruct is exemplified in rare case studies, in which the eatingbehavior of densely amnesic but otherwise normal patients, includingpatient H.M., was carefully monitored (Hebben et al., 1985; Rozinet al., 1998). All had suffered damage to the mediotemporal lobe,including the hippocampus and amygdala. These individuals wouldconsume a fairly large meal and, 10-20 min later, were unableto recall having the meal and, consequently, willingly acceptedand consumed a second and sometimes a third identical meal (Rozinet al., 1998). In one instance, a subject reported "his stomachfelt a little tight" before refusing a subsequent meal, suggestingthat, within the physiological limits of satiety (i.e., physicalfullness), memory for what has been consumed recently is an importantdeterminant of the initiation and termination of food intake.Final acceptance of the hypothesis that the amygdala is involvedin memory-based mediation of satiety must await evidence of similareffects in patients with selective damage to theamygdala.

  FOOTNOTES

Received July 22, 2002; revised Sept. 3, 2002; accepted Oct. 1, 2002.

This work was funded by a research grant from the Canadian Institutes for Health Research (A.G.P.). We gratefully acknowledgethe assistance of Dr. Natalia Gorlova for advice on the procedurefor reverse dialysis of lidocaine and Kitty So for her meticulouswork in preparing the dialysisprobes.

Correspondence should be addressed to Dr. A. G. Phillips, Department of Psychiatry, University of British Columbia, 2255 WesbrookMall, Vancouver, British Columbia, Canada V6T 2A1. E-mail: aphillips{at}cortex.psych.ubc.ca.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Aggleton JP, Passingham RE (1982) An assessment of the reinforcing properties of foods after amygdaloid lesions in rhesus monkeys. J Comp Phyiol Psychol 96:71-77.
Ahn S, Phillips AG (1999) Dopaminergic correlates of sensory-specific satiety in the medial prefrontal cortex and the nucleus accumbens of the rat. J Neurosci 19:RC29[Abstract/Free Full Text](1-6).
Ahn S, Phillips AG (2002) Independent modulation of basal and feeding-evoked dopamine efflux in the nucleus accumbens and medial prefrontal cortex by the central and basolateral amygdalar nuclei in the rat. Neuroscience, in press.
Bakshi VP, Kelley AE (1994) Sensitization and conditioning of feeding following multiple morphine microinjections into the nucleus accumbens. Brain Res 648:342-346[Medline].
Bassareo V, Di Chiara G (1997) Differential influence of associative and nonassociative learning mechanisms on the responsiveness of prefrontal and accumbal dopamine transmission to food stimuli in rats fed ad libitum. J Neurosci 17:851-861[Abstract/Free Full Text].
Bechara A, van der Kooy D (1992) A single brain stem substrate mediates the motivational effects of both opiates and food in nondeprived rats but not in deprived rats. Behav Neurosci 106:351-363[ISI][Medline].
Berridge KC (1996) Food reward: brain substrates of wanting and liking. Neurosci Biobehav Rev 20:1-25[ISI][Medline].
Berridge KC, Robinson TE (1998) What is the role of dopamine in reward: hedonic impact, reward learning, or incentive salience? Brain Res Rev 28:309-369[Medline].
Berridge KC, Treit D (1986) Chlordiazepoxide directly enhances positive ingestive reactions in rats. Pharmacol Biochem Behav 24:217-221[ISI][Medline].
Blaha CD, Yang CR, Floresco SB, Barr AM, Phillips AG (1997) Stimulation of the ventral subiculum of the hippocampus evokes glutamate receptor-mediated changes in dopamine efflux in the rat nucleus accumbens. Eur J Neurosci 9:902-911[ISI][Medline].
Box BM, Mogenson GJ (1975) Alternations in ingestive behaviors after bilateral lesions of the amygdala in the rat. Physiol Behav 15:679-688[Medline].
Cardinal RN, Parkinson JA, Hall J, Everitt BJ (2002) Emotion and motivation: the role of the amygdala, ventral striatum, and prefrontal cortex. Neurosci Biobehav Rev 26:321-352[ISI][Medline].
Everitt BJ, Parkinson JA, Olmstead MC, Arroyo M, Robledo P, Robbins TW (1999) Associative processes in addiction and reward: the role of amygdala-ventral striatal subsystems. Ann NY Acad Sci 877:412-438[ISI][Medline].
Fiorino DF, Coury A, Phillips AG (1997) Dynamic changes in nucleus accumbens dopamine efflux during the Coolidge effect in male rats. J Neurosci 17:4849-4855[Abstract/Free Full Text].
Floresco SB, Yang CR, Phillips AG, Blaha CD (1998) Basolateral amygdala stimulation evokes glutamate receptor-dependent dopamine efflux in the nucleus accumbens of the anaesthetized rat. Eur J Neurosci 10:1241-1251[ISI][Medline].
Galaverna OG, Seeley RJ, Berridge KC, Grill HJ, Epstein AN, Schulkin J (1993) Lesions of the central nucleus of the amygdala. I. Effects on taste reactivity, taste aversion learning and sodium appetite. Behav Brain Res 59:11-17[ISI][Medline].
Gallagher M, Graham PW, Holland PC (1990) The amygdala central nucleus and appetitive pavlovian conditioning: lesions impair one class of conditioned behavior. J Neurosci 10:1906-1911[Abstract].
Hatfield T, Han JS, Conley M, Gallagher M, Holland P (1996) Neurotoxic lesions of basolateral, but not central, amygdala interfere with pavlovian second-order conditioning and reinforcer devaluation effects. J Neurosci 16:5256-5265[Abstract/Free Full Text].
Hebben N, Corkin S, Eichenbaum H, Shedlack K (1985) Diminished ability to interpret and report internal states after bilateral medial temporal resection: case H. M. Behav Neurosci 99:1031-1039[Medline].
Holland PC, Gallagher M (1999) Amygdala circuitry in attentional and representational processes. Trends Cogn Sci 3:65-73[ISI][Medline].
Howland JG, Taepavarapruk P, Phillips AG (2002) Glutamate receptor-dependent modulation of dopamine efflux in the nucleus accumbens by basolateral, but not central, nucleus of the amygdala in rats. J Neurosci 22:1137-1145[Abstract/Free Full Text].
Jackson ME, Moghaddam B (2001) Amygdala regulation of nucleus accumbens dopamine output is governed by the prefrontal cortex. J Neurosci 21:676-681[Abstract/Free Full Text].
Johnson LR, Aylward RLM, Hussain Z, Totterdell S (1994) Input from the amygdala to the rat nucleus accumbens: its relationship with tyrosine hydroxylase immunoreactivity and identified neurons. Neuroscience 61:851-865[ISI][Medline].
Kesner RP, Walser RD, Winzenried G (1989) Central but not basolateral amygdala mediates memory for positive affective experiences. Behav Brain Res 33:189-195[Medline].
Killcross S, Robbins TW, Everitt BJ (1997) Different types of fear-conditioned behaviour mediated by separate nuclei within amygdala. Nature 388:377-380[Medline].
Maldonado-Irizarry CS, Swanson CJ, Kelley AE (1995) Glutamate receptors in the nucleus accumbens shell control feeding behavior via the lateral hypothalamus. J Neurosci 15:6779-6788[Abstract/Free Full Text].
Màlkovà L, Gaffan D, Murray EA (1997) Excitotoxic lesions of the amygdala fail to produce impairment in visual learning for auditory secondary reinforcement but interfere with reinforcer devaluation effects in rhesus monkeys. J Neurosci 17:6011-6020[Abstract/Free Full Text].
McDonald AJ (1991) Organization of amygdaloid projections to the prefrontal cortex and associated striatum in the rat. Neuroscience 44:1-14[ISI][Medline].
Mei N (1994) Role of digestive afferents in food intake regulation. In: Appetite: neural and behavioural bases (Legg CR, Booth D, eds), pp 86-97. Oxford: Oxford UP.
Mogenson GJ, Phillips AG (1976) Motivation: a psychological construct in search of a physiological substrate. Prog Psychobiol Physiol Psychol 6:189-243.
Murray EA, Gaffan EA, Flint Jr RW (1996) Anterior rhinal cortex and amygdala: dissociation of their contributions to memory and food preference in rhesus monkeys. Behav Neurosci 110:30-42[ISI][Medline].
Norgren R (1995) Gustatory system. In: The rat nervous system (Paxinos G, ed), pp 751-771. San Diego: Academic.
Parkinson JA, Robbins TW, Everitt BJ (2000a) Dissociable roles of the central and basolateral amygdala in appetitive emotional learning. Eur J Neurosci 12:405-413[ISI][Medline].
Parkinson JA, Cardinal RN, Everitt BJ (2000b) Limbic cortical-ventral striatal systems underlying appetitive conditioning. Prog Brain Res 126:263-285[ISI][Medline].
Paxinos G, Watson C (1997) In: The rat brain in stereotaxic coordinates. Toronto: Academic.
Phillipson OT (1979) Afferent projections to the ventral tegmental area of Tsai and interfascicular nucleus: a horseradish peroxidase study in the rat. J Comp Neurol 187:117-144[ISI][Medline].
Pitkänen A, Savander V, LeDoux JE (1997) Organization of intra-amygdaloid circuitries in the rat: an emerging framework for understanding functions of the amygdala. Trends Neurosci 20:517-523[ISI][Medline].
Robinson TE, Berridge KC (1993) The neural basis of drug craving: an incentive-sensitization theory of addiction. Brain Res Rev 18:247-291[Medline].
Rolls ET (1999) The brain control of feeding and reward. In: The brain and emotion, pp 8-58 New York: Oxford UP.
Rozin P, Dow S, Moscovitch M, Rajaram S (1998) What causes human beings to begin and end a meal? A role for memory for what has been eaten, as evidenced by a study of multiple meal eating in amnesic patients. Psychol Sci 9:392-396.
Salinas JA, Parent MB, McGaugh JL (1996) Ibotenic acid lesions of the amygdala basolateral complex or central nucleus differentially effect the response to reductions in reward. Brain Res 742:283-293[Medline].
Setlow B, Holland PC, Gallagher M (2002) Disconnection of the basolateral amygdala complex and nucleus accumbens impairs appetitive pavlovian second-order conditioned responses. Behav Neurosci 116:267-275[ISI][Medline].
Shipley MT, McLean JH, Ennis M (1995) Olfactory system. In: The rat nervous system (Paxinos G, ed), pp 899-926. San Diego: Academic.
Simmons DA, Neill DB (2001) Functional interaction between the basolateral amygdala and the ventral striatum underlies incentive motivation of a food reward. Soc Neurosci Abstr 26:959.15.
Stratford TR, Kelley AE (1997) GABA in the nucleus accumbens shell participates in the central regulation of feeding behavior. J Neurosci 17:4434-4440[Abstract/Free Full Text].
Sun N, Cassell MD (1993) Intrinsic GABAergic neurons in the rat central extended amygdala. J Comp Neurol 330:381-404[ISI][Medline].
Swanson LW, Petrovich GD (1998) What is the amygdala? Trends Neurosci 21:323-331[ISI][Medline].
Taepavarapruk P, Floresco SB, Phillips AG (2000) Hyperlocomotion and increased dopamine efflux in the rat nucleus accumbens evoked by electrical stimulation of the ventral subiculum: role of ionotropic glutamate and dopamine D₁ receptors. Psychopharmacology 151:242-251[Medline].
Uwano T, Nishijo H, Ono T, Tamura R (1995) Neuronal responsiveness to various sensory stimuli, and associative learning in the rat amygdala. Neuroscience 68:339-361[ISI][Medline].
Wallace DM, Magnuson DJ, Gray TS (1992) Organization of amygdaloid projections to brainstem dopaminergic, noradrenergic, and adrenergic cell groups in the rat. Brain Res Bull 28:447-454[ISI][Medline].
Woods SC, Seeley RJ, Porte Jr D, Schwartz MW (1998) Signals that regulate food intake and energy homeostasis. Science 280:1378-1383[Abstract/Free Full Text].
Zeigler HP (1994) Brainstem orosensorimotor mechanisms and the neural control of ingestive behaviour. In: Appetite: neural and behavioural bases (Legg CR, Booth D, eds), pp 54-85. Oxford: Oxford UP.

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