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Place conditioning training procedure. Conditioned place preference/avoidance training occurred in a three-compartment apparatus. Two large side chambers (28 × 21 × 21 cm) surrounded a smaller central compartment (12 × 21 × 21 cm). One side compartment was brightly lit and had black-colored walls and a wire grid floor. The other side compartment was darkened and had white walls and a wire mesh floor. Before this experiment, the effectiveness of our place conditioning procedure was confirmed using a separate group of rats, successfully conditioned to have a place preference for a compartment paired with diazepam administration (1 mg/kg, i.p) (Spyraki et al., 1985
The Journal of Neuroscience, August 15, 2002, 22(16):7308-7320
Positive and Negative Motivation in Nucleus Accumbens Shell: Bivalent Rostrocaudal Gradients for GABA-Elicited Eating, Taste "Liking"/"Disliking" Reactions, Place Preference/Avoidance, and Fear
Sheila M. Reynolds and Kent C. Berridge Department of Psychology, University of Michigan, Ann Arbor, Michigan 48109-1109
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Microinjection of the GABAA agonist muscimol in the rostral medial accumbens shell in rats elicits appetitive eating behavior, but in the caudal shell instead elicits fearful defensive treading behavior. To further test the hypothesis that rostral shell muscimol microinjections produce positive motivational states, whereas caudal shell muscimol produces negative states, we measured behavioral place preference/avoidance conditioning and affective hedonic and aversive orofacial expressions of taste-elicited "liking" and "disliking" (gapes, etc.) in addition to fear and feeding behaviors. Farthest rostral muscimol microinjections (75 ng) caused increased eating behavior and also caused positive conditioned place preferences and increased positive hedonic reactions to the taste of sucrose. By contrast, caudal shell microinjections elicited negative defensive treading and caused robust negative conditioned place avoidance and negative aversive reactions to sucrose or quinine tastes. Intermediate rostral microinjections elicited effects of mixed positive/negative valence (positive appetitive eating behavior but negative place avoidance and negative taste reactions at mid-rostral sites, and sometimes positive eating simultaneously with fearful defensive treading more caudally). These results indicate that GABAergic neurotransmission in local microcircuits in nucleus accumbens mediates motivated/affective behavior that is bivalently organized along rostrocaudal gradients.
Key words: accumbens shell; GABA; food intake; reward; appetite; ingestive behavior; motivation; glutamate; mesolimbic; extended amygdala; pallidal; dopamine; glutamate; fear; defense; muscimol; microinjection; taste; palatability; pleasure; affect; aversion
INTRODUCTION
How do positive and negative motivational functions of the nucleus accumbens relate to each other? Mapping of motivational valence in accumbens is a major puzzle for contemporary affective neuroscience. Mesolimbic systems are widely thought to be involved in both positive (appetitive/reward) and negative (stress/defense) motivational functions (Koob and Bloom, 1988
; Salamone, 1994
Recent studies suggest that GABAergic neurotransmission in medial accumbens shell might map positive/negative motivational functions along a rostrocaudal gradient. Eating behavior and food intake, often regarded as appetitive or positively motivated, are increased in rats by rostral shell microinjections of a GABAA agonist (Stratford and Kelley, 1997
The rostrocaudal segregation of feeding versus fearful behaviors in medial shell after GABAA agonist microinjections suggests that the accumbens shell contains multiple functional microcircuits (Pennartz et al., 1994
The conditioned place preference/avoidance paradigm is a traditional measure of both reward and aversive properties of drugs (Tzschentke, 1998
In this study we tested whether rostrocaudal gradients exist in accumbens shell for motivational/affective valence produced by muscimol microinjections. We found that GABA receptor activation in far rostral shell increased positive eating, place preference, and positive hedonic reactions to sucrose taste ("liking"). Conversely, caudal muscimol microinjections caused negative fearful behavior, conditioned avoidance, and negative affective reactions to taste. Intermediate shell GABAergic activation produced combined positive and negative motivational effects. These observations support the hypothesis that GABAergic modulation of microcircuits in accumbens shell globally generates bivalent motivational functions along rostrocaudal gradients.
MATERIALS AND METHODS
General design. This study compared the effects of shell GABAergic activation on four types of motivated or affective behaviors (feeding behavior, defensive treading behavior, conditioned place preference/avoidance, and positive/negative affective reactions to tastes). To limit the number of microinjections required per rat, this was done in two separate experiments. In experiment 1, muscimol-elicited place preference/avoidance conditioning was compared with fear and feeding behavior elicited by microinjections at the same site on a within-subject basis. In experiment 2 the effects of muscimol microinjection on affective taste reactivity patterns elicited by oral infusions of sucrose or quinine were compared with fear versus feeding elicited at the same microinjection sites.
Subjects. Eighty-six male and female Sprague Dawley rats (280-320 gm at the time of surgery) were group housed (~21°C; 12 hr light/dark cycle) with ad libitum food (Purina Rat Chow) and water (tap water).
Microinjection cannula surgery. Rats were pretreated with 0.1 ml of atropine sulfate and anesthetized with a mixture of ketamine HCl (80 mg/kg, i.p.) and xylazine (5 mg/kg). The stereotaxic incisor bar was set at 5.0 mm above interaural zero to achieve a slanted cannula angle and avoid penetrating the lateral ventricles. Chronic microinjection guide cannulas (23 gauge) were implanted bilaterally 2 mm above rostral or caudal sites in the medial nucleus accumbens shell. Coordinates for rostral versus caudal shell sites were chosen from our earlier study (Reynolds and Berridge, 2001
5.7], and 33 rats received cannulas targeted in the caudal shell half (AP +2.1, ML ±1.2, DV
Oral cannula surgery (for taste reactivity test). A subgroup of 32 rats (16 with rostral shell sites; 16 with caudal shell) were also implanted in the same surgery with bilateral oral cannulas to permit taste reactivity tests, which require the direct infusion of taste solutions into the mouth. Oral cannulas (heat-flared polyethylene-100 tubing) entered the mouth just lateral to the first maxillary molar, ascended lateral to the skull, and exited the head at the dorsal skull, where they were attached to 19 gauge steel tubing. All cannulas were anchored to the skull with screws and acrylic cement. Each rat received prophylactic penicillin (aquacillin; 45,000 U, i.m.) after surgery and every 2 d for ~1 week. At least 14 d were allowed for recovery after surgery before behavioral testing.
Drugs and intracerebral microinjections. Muscimol (Sigma, St. Louis, MO) was dissolved in sterile 0.15 M saline, which was also used for vehicle control microinjections (0.5 µl). We chose the muscimol dose (75 ng per side, resulting in a total dose of 150 ng) that elicited maximum eating behavior when administered in rostral accumbens shell in our previous study and that also elicited substantial defensive treading behavior when administered in caudal shell (Reynolds and Berridge, 2001
Behavioral eating/defensive treading tests. The ability of muscimol to elicit appetitive eating behavior and defensive treading behavior was assessed simultaneously in the same test procedure (Reynolds and Berridge, 2001
Video scoring of eating/defensive treading. The videotapes were scored by an experimenter who was blind to drug treatment. Behavior was analyzed for time spent eating and time spent defensive treading (both measured in seconds; intake was also measured as grams of food consumed).
Histology. Rats were deeply anesthetized with sodium pentobarbital at the end of the experiment, given microinjections of ink for anatomical localization of cannula sites (0.5 µl), and perfused transcardially with buffered saline, followed by 4% paraformaldehyde solution. Their brains were removed, postfixed, sectioned (40 µm), mounted on slides, and stained with cresyl violet. Cannula placements were mapped onto a stereotaxic atlas (Paxinos and Watson, 1997
Construction of functional maps. To construct anatomical maps of functional localization within the accumbens shell, functional criteria were set to record the significant occurrence of each of the five types of motivated behavior (eating, defensive treading, place conditioning, hedonic reactions to sucrose, aversive reactions to quinine). Muscimol microinjection sites that met the criteria described below were plotted on digitized stereotaxic atlas maps that depicted the intensity of behavior elicited at various shell sites.
Eating: mapping criterion. A rat was classified as an eater if muscimol microinjection caused it to eat >200% of the amount of food it ate after vehicle microinjection and spent >200% more time engaged in eating behavior (Reynolds and Berridge, 2001
Defensive treading: mapping criterion. A rat was classified as a defensive treader if it emitted at least 100 sec of cumulative defensive treading behavior after muscimol microinjection (rats generally emitted zero defensive treading after vehicle microinjections). A defensive treading score was calculated for each rat and mapped onto its microinjection cannula sites in the stereotaxic atlas.
Note: If a rat met criteria for both defensive treading and eating, it was classified as both. Animals that met neither criterion were classified as negative for these behaviors.
Place conditioning: mapping of preference versus avoidance. Place conditioning scoring procedures corrected for initial place biases by dividing the time a rat spent in its muscimol-paired chamber during test by the mean time spent in that same chamber by all rats across all treatments. The result was expressed as a percentage score, which could be either positive (conditioned place preference) or negative (conditioned place avoidance). Place preference or avoidance scores were calculated for each rat and mapped onto its microinjection cannula sites using a stereotaxic atlas.
For the purpose of quantifying place conditioning results in the final map, each microinjection site was assigned to one of the following categories: more than +20% increase in place preference after pairings with muscimol (compared with vehicle microinjection at the same site), >10% preference, no change in place preference/avoidance (less than +9 to
Taste reactivity: mapping of positive hedonic enhancement. Positive affective taste reactions normally elicited by sucrose infusions were totaled separately for each rat (Berridge, 2000
Mapping of negative taste aversion. Affectively negative aversive reactions, best elicited by quinine taste, were similarly totaled separately after muscimol microinjections and compared with reactions after vehicle microinjections at the same site. The aversive percentage score could reflect an increase (more aversive after muscimol) or suppression (less aversive). An aversive change score was plotted for each rat and mapped onto its microinjection cannula sites according to the following criteria: more than
Experiment 1: place preference/avoidance conditioning versus feeding/fear
Experimental design. Forty-two rats (25 with cannula aimed at the rostral shell; 17 caudal shell) were trained and tested for place conditioning. One day after the place conditioning test, rats were also tested for muscimol-elicited eating behavior and defensive treading behavior.Experiment 2: affective positive/negative taste reactivity versus feeding/fear
Taste reactivity test. Immediately after microinjection, each rat's oral cannula was connected to a stimulus delivery line (PE-50 tubing attached to a PE-10 nozzle), and the rat was placed into a transparent test chamber. A mirror positioned beneath the transparent floor reflected a view of the rat's face and mouth into the close-up lens of a video camera to permit videotaping of affective facial and body reactions to oral infusions of sucrose or quinine taste stimuli. Solutions of either 0.1 M sucrose or 3 × 105 M quinine HCl were infused into the rat's mouth through the oral cannula by a syringe pump over an exposure period of 1 min (1 ml/60 sec). Each rat received a 1 ml intra-oral taste infusion of the same solution at three points in time: 10, 30, and 60 min after the microinjection (each test lasted 1 min). Rats received only one taste (sucrose or quinine) per day, and the order of taste/drug testing was counterbalanced. Affective reactions elicited by the taste stimuli were videotaped for subsequent analysis. After-reactions that occurred within a 30 sec interval after the end of the infusion were also recorded for separate scoring because a previous report suggested that after-reactions during the 30 sec period after sucrose infusions may be more sensitive to mild shifts in palatability than reactions that occur during oral infusions, because of release from response constraints imposed by the physical solution in the mouth (Grill et al., 1996
RESULTS
Experiment 1: place preference/avoidance conditioning versus feeding/fear
Muscimol-elicited feeding versus fear
Muscimol microinjection into the rostral two-thirds of the accumbens shell (2.7-1.2 mm anterior to bregma) (Figs. 1, 7, 8) elicited robust increases in food intake: rats consumed >400% more food than after vehicle microinjection [ANOVA (drug) F(1,41) = 53.29; p < 0.001] and spent >500% more time in eating behavior [ANOVA (drug) F(1,41) = 23.46; p < 0.001], consistent with previous reports (Stratford and Kelley, 1997
By contrast, muscimol microinjection into the caudal third of the accumbens shell (1.2-0.48 mm anterior to bregma) (Figs. 1, 7, 8) elicited strong defensive treading behavior, averaging >300 sec cumulative treading after muscimol [compared with virtually 0 sec after vehicle; ANOVA (drug) F(1,27) = 47.69; p < 0.001]. Mounds of wood shavings were typically constructed by this defensive treading behavior (10-20 cm length, 5-10 cm height and width) (Reynolds and Berridge, 2001
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Figure 1. Experiment 1: food intake, defensive treading behavior, and place conditioning (mean ± SEM) after vehicle or 75 ng muscimol microinjection. Food Intake (top left), Rostral shell muscimol microinjection robustly increased food intake, whereas caudal muscimol strongly suppressed intake, compared with vehicle (cumulative grams of chow intake over 60 min; results in terms of time spent eating were similar). Defensive Treading (top right), Caudal muscimol elicited robust defensive treading behavior, whereas rostral muscimol elicited minimal treading behavior (cumulative over 60 min). Ground squirrel drawing depicts similar defensive treading behavior by Spermophilus beecheyi directed toward predatory rattlesnake [modified from Owings and Morton (1998)
Conditioned place preference/avoidance
Muscimol microinjections within the accumbens shell caused conditioned place preference at most rostral sites but conditioned place avoidance at most caudal sites [ANOVA (drug × region) F(1,73) 7.15; p < 0.01) (Fig. 1). Muscimol-conditioned positive place preferences (>100 sec increase in the muscimol-paired chamber on average) were produced by muscimol microinjection sites located primarily in the most anterior 25% of the shell, that is, more than +1.6 mm anterior to bregma (n = 7 of 10 sites; mean preference = 33%; ANOVA F(1,19) = 11.20; p < 0.005). Each of these rats with far-rostral sites (>20% place preference) also met criteria to be positive eaters (Figs. 1, 7, 8). However, most rostral sites (65%) between +1.6 and +1.1 mm anterior to bregma actually produced muscimol-conditioned place avoidance, instead of preferences, although all still elicited eating behavior. When microinjection sites for individual rats were plotted separately, 48% of rostral eating sites (those mainly located in the farthest rostral shell) produced at least 20% conditioned place preference, 38% of rostral sites produced 10-50% conditioned place avoidance (most of these sites less rostral than sites that produced place preference, but still in the rostral half of the shell), and 14% of rostral sites produced no change. A rostrocaudal gradient for place preference conditioning became even clearer when caudal shell sites were considered, because muscimol caused the strongest negative conditioned place avoidance at sites in the caudal half of the shell, that is, 1.1-0.5 mm anterior to bregma (F(1,73) = 7.15; p < 0.01 for strength of muscimol avoidance in rostral versus caudal shell; p < 0.02 at 15 min; and p < 0.01 at 30 min for muscimol versus vehicle avoidance effect in caudal shell) (Fig. 1). The strongest conditioned avoidance (>25%) was produced by muscimol at sites caudal to +1.0 mm bregma, at points just above and caudal to the islands of Calleja, and roughly above the rostral emergence of the nucleus of the vertical limb diagonal band. All of the rats with these caudal shell sites for place avoidance also met criteria for defensive treading. Conversely, 85% of caudal defensive treading sites produced at least >10% conditioned place avoidance after muscimol, and the remaining 15% produced no change. No caudal sites produced conditioned place preferences. For the entire shell, there was a significant correlation between degree of rostrocaudal placement and degree of conditioned place preference/avoidance (r = 0.35; p = 0.03). Medial shell sites rostral to approximately +1.6 mm produced mild place preference, sites between +1.6 and +1.1 mm produced mild place avoidance, and sites caudal to +1.1 produced robust place avoidance (Fig. 1). In summary, muscimol microinjection into the entire rostral half of the shell reliably elicited increased food intake, but only the most far rostral sites also produced conditioned place preference. The majority of muscimol sites in the less extreme rostral half of the medial shell caused a negative conditioned place avoidance, despite increasing appetitive eating behavior. Conversely, muscimol microinjections into the caudal shell uniformly caused both negative conditioned place avoidance and negative defensive treading behavior (while suppressing food intake). Muscimol thus appears to influence place conditioning along a positive-to-negative rostrocaudal gradient within the medial shell, which overlaps roughly but not perfectly with the gradient for eliciting feeding versus fear.Experiment 2: affective positive/negative taste reactivity versus feeding/fear
Muscimol-elicited eating behavior and defensive treading behavior.
Rostral shell microinjections increased eating behavior. Food intake was again increased by rostral shell muscimol microinjections by ~500% over vehicle levels (see Figs. 3, 7, and 8) [ANOVA (drug) F(1,21) = 49.09; p < 0.001). Time spent in eating behavior was similarly elevated by >500% after rostral shell muscimol at all three time points in the hour after microinjection [10, 30, 60 min; ANOVA (drug) F(1,65) = 49.83; p < 0.001) (Fig. 2). Only a few seconds of cumulative defensive treading behavior were elicited by rostral muscimol on average [ANOVA (drug) F(1,21) = 8.32; p < 0.02], and most rats in this group showed no defensive treading at all.
Caudal shell microinjection elicited defensive treading behavior. Caudal shell muscimol again elicited robust defensive treading behavior and tended to decrease food intake rather than increase it. Defensive treading was increased by >1000% of vehicle levels (typically eliciting >400 sec of cumulative treading behavior compared with only 0-5 sec after vehicle; F(1,24) = 88.75; p < 0.001] (Fig. 2). Defensive treading was especially high during the second half hour of the 1 hr trial (drug × time interaction F(2,83) = 91.66; p < 0.001; final two periods each p < 0.001 compared with vehicle).
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Figure 2. Experiment 2: time spent eating and defensive treading (mean ± SEM) after vehicle or 75 ng muscimol microinjection. Rostral shell muscimol increased eating behavior immediately and continuously (results in terms of grams of food intake were similar) but elicited minimal defensive treading. Caudal muscimol microinjection elicited robust defensive treading behavior but never increased eating behavior (cumulative over 60 min trial). **p < 0.001; *p < 0.05.
Rostral muscimol: mixed enhancement/suppression of positive hedonic reactions
Sucrose infusions. Positive hedonic reactions elicited by the taste of sucrose were increased by 50% in the two rats that had the most far rostral placements of the rostral group in experiment 2 [mean vehicle = 18.2 ± 2.8, muscimol = 27.5 ± 3.8; 51% enhancement; ANOVA (drug) F(1,11) = 6.35; p = 0.053] (see Figs. 7, 8). The largest enhancement of positive hedonic taste reactions was observed in the same rat that also showed the largest increase in food intake. In general, there was a significant correlation between a rat's amount of muscimol-elicited food intake and its change in hedonic reactions to sucrose (r = +0.71; r2= 0.50; p < 0.05) (Fig. 3, inset).
All 11 rats with sites in the rostral half of the shell showed robust muscimol-elicited eating behavior, however, and not just the two that met criterion for positive increases in hedonic taste reactivity. Surprisingly, the positive correlation between intake and hedonic change resulted chiefly from muscimol-induced suppression of hedonic reactions to sucrose in rats whose placements were less rostral than approximately +1.7 mm anterior to bregma (i.e., not in the most rostral one-fourth of the shell) (Fig. 3, 7, 8). All rats ate after rostral muscimol microinjections regardless of whether they had hedonic suppression, but those that had the smallest hedonic suppression tended to eat more than those that had larger suppression of positive hedonic reactivity to the sucrose taste. For the entire group with sites in the rostral half of shell, in fact, overall hedonic reactions tended to be suppressed by muscimol (Fig. 3) [one-way ANOVA (drug) F(1,65) = 3.41; p = 0.07]. When the two rats that displayed increased hedonic reaction were excluded, the suppression of hedonic reaction by muscimol in rostral shell became significant [ANOVA (drug) F(1,53) = 14.86; p < 0.001]. Breaking down the positive affective taste reactivity category into separate reactivity components for these rats, rhythmic tongue protrusions were significantly suppressed by shell muscimol during sucrose infusions (p < 0.02) (Fig. 3), and paw licking (p = 0.065) and lateral tongue protrusions (p = 0.03) were significantly suppressed during the 30 sec period immediately after the sucrose infusion in which rats normally still emit a few affective "after-reactions." By contrast, negative aversive reactions were rarely elicited by sucrose infusions after vehicle microinjections but were increased by >200% after muscimol in rostral shell (F(1,65) = 5.45; p < 0.03). As might be expected, no aversive increase was seen in the two rats that had the most rostral microinjection placements, which had instead increased positive hedonic reactions elicited by sucrose. Breaking down the negative aversive affective reaction category into specific component responses elicited by sucrose infusions, forelimb flails (p < 0.04) and face washing (p = 0.06) were both increased after muscimol in rostral shell. Similar results were found in each taste reactivity test at all three time points tested (10, 30, and 60 min after microinjection) (Fig. 3) and in reactions both during the infusion and immediately after. Quinine infusions. Taste reactivity to quinine was also made more negative overall by muscimol microinjections, even in the rostral half of the shell. The effect of muscimol microinjections on reactions to quinine was primarily to further suppress positive reactions [one-way ANOVA (drug) F(1,65) = 4.14; p < 0.05] and potentiate aversive reactions by roughly 150% (F(1,65) = 3.64; p = 0.065) (Fig. 4), just as it did for reactions to sucrose. Again, an exception to this aversive enhancement was seen in the two rats that had the farthest rostral placements in the anterior 25% of the shell, which showed no change in aversive reactions after muscimol. When these farthest rostral two rats were excluded from the analysis, the increase in aversion to quinine by muscimol became significant for the rostral group overall (F(1,53) = 6.51; p < 0.02).
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Figure 3. Experiment 2: affective taste reactivity to sucrose infusions after rostral shell microinjections (mean ± SEM; number of total hedonic, neutral, and aversive taste reactions). Overall a small shift toward aversive reaction patterns to sucrose taste were produced by rostral shell muscimol microinjections (left bars). For reference purposes, top photographs show prototypical disgust gape expression in human infant and the homologous gape component in adult rat that was measured here [from Steiner et al. (2001)
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Figure 4. Experiment 2: affective taste reactivity to quinine after rostral shell microinjections (mean ± SEM reactions). Overall a moderate suppression of positive affective reactions and shift toward increased aversion to quinine taste was produced by rostral muscimol microinjections. Middle bars indicate breakdown of affective reaction categories into component facial and body reactions. Similar effects occurred for all infusions (bottom). *p < 0.05.
Caudal shell muscimol: negative affective reactions to sucrose and quinine
Hedonic reactions elicited by sucrose were even more suppressed after caudal shell muscimol than after rostral microinjections (F(1,148) = 13.74; p < 0.001), and negative aversive reactions were even more increased after muscimol in caudal shell than in rostral shell (F(1,148) = 11.20; p = 0.001). Component hedonic responses suppressed during sucrose infusions included paw licks and rhythmic tongue protrusions (both p < 0.001; overall hedonic suppression for caudal shell muscimol versus vehicle, F(1,81) = 26.04; p < 0.001). Conversely, several aversive component reactions to sucrose were increased by caudal muscimol by >200% over vehicle baseline: gapes, headshakes, face washing, and chin rubs (all p < 0.05; overall aversive increase for caudal shell muscimol versus vehicle, F(1,81) = 5.60; p < 0.03) (Fig. 5).
In response to oral quinine infusions, caudal muscimol similarly increased the already higher number of aversive reactions >300% above vehicle levels to the bitter taste [ANOVA (drug) F(1,81) = 8.59; p < 0.01] (Figs. 6, 7, 8), whereas it suppressed most the level of hedonic reactions to quinine 50% below vehicle levels (F(1,81) = 19.48; p < 0.001). Furthermore, the magnitude of aversive enhancement grew over the course of the hour after microinjection [comparing tests at 10, 30, and 60 min ANOVA (interaction of drug × time) F(2,81) = 3.81; p = 0.04]. This temporal pattern was true for both sucrose and quinine infusions and for the 30 sec post-infusion after-reaction periods (F(1,81) = 11.78; p < 0.005).
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Figure 5. Experiment 2: affective taste reactivity to sucrose after caudal shell microinjections (mean ± SEM reactions). Caudal shell muscimol strongly shifted affective reactions toward negative aversion and suppressed positive hedonic reactions to sucrose (left). Breakdown of affective reaction categories into component facial and body reactions (middle bars) revealed suppression of positive paw licking and rhythmic tongue protrusions and increased negative gapes, head shakes, face washing, and chin rubs. Similar effects occurred for all infusions (right). *p < 0.05; **p < 0.001.
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Figure 6. Experiment 2: affective taste reactivity to quinine after caudal shell microinjections (mean ± SEM reactions). Caudal shell muscimol increased overall negative reactions to quinine (left). Breakdown of affective reaction categories into component facial and body reactions revealed suppression of positive paw licking, rhythmic tongue protrusions, and lateral tongue protrusions, but increased negative gapes, head shakes, forelimb flails, face washing, and chin rubs (middle bars). Similar effects occurred for all infusions (right). *p < 0.05; **p < 0.001.
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Figure 7. Coronal function maps (experiments 1 and 2). Microinjection sites are plotted for valenced muscimol-elicited effects on eating behavior and defensive treading behavior (left), place preference/avoidance conditioning (second from left), positive affective reactions to sucrose taste (second from right), and negative affective reactions to quinine taste (right). Rostrocaudal gradients of positive-to-negative valence can be observed for all behaviors in medial shell. Several far rostral muscimol microinjections produced positively valenced effects, and caudal microinjections reliably produced negative effects, whereas intermediate sites produced mixed positive effects (eating behavior) and negative effects (conditioned place avoidance and taste aversion). Stereotaxic atlas from Paxinos and Watson (1997)
In conclusion, muscimol microinjection increased both food intake and hedonic reactions to taste in sites at the far rostral region of the shell, although at most rostral sites muscimol increased food intake while actually slightly suppressing hedonic reactions and increasing aversive reactions to tastes. Conversely, muscimol microinjections into caudal shell sites produced both defensive treading behavior and enhanced aversive reactions to both sucrose and quinine tastes. Thus both food intake and affective taste reactions are elicited along positive-to-negative gradients within the medial shell by muscimol. However, these gradients do not perfectly match, because intermediate sites increased positive food intake but suppressed positive hedonic affective reactions to tastes and increased negative aversive reactions.
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Figure 8. Sagittal function maps (experiments 1 and 2). Microinjection sites are plotted (bilaterally, 2 sites for each rat) for valenced muscimol-elicited effects in sagittal plane (0.9 mm lateral from midline). Rostrocaudal gradients can be observed in medial shell for eating behavior and defensive treading behavior (left), place preference/avoidance conditioning (second from left), positive affective reactions to sucrose taste (second from right), and negative affective reactions to quinine taste (right). Far rostral microinjections produced all positively valenced effects (increased eating behavior, positive enhanced sucrose liking, and reduced quinine disliking, positive conditioned place preference). Caudal injections produced all negatively valenced effects (fearful defensive treading behavior, negative taste disliking, negative conditioned place avoidance). Intermediate sites produced mixed positive results (eating behavior) and negative results (conditioned place avoidance and taste disliking). For all behaviors, both the valence and magnitude of muscimol-induced change correlated with site position along a rostrocaudal gradient. Stereotaxic atlas from Paxinos and Watson (1997)
DISCUSSION
Activation of GABAA receptors in the medial shell of nucleus accumbens triggered multiple motivated behaviors and affective reactions that were organized along bivalent rostrocaudal gradients. Muscimol in the most far rostral 25% of the shell caused increased eating, positive hedonic taste enhancement, and conditioned place preferences. Less far rostrally, muscimol still elicited robust eating but caused negative affective reactions to taste and conditioned negative place avoidance. Conversely, muscimol at caudal sites suppressed food intake, caused negative affective reactions to the taste of sucrose, caused an associated place to be avoided, and triggered unconditioned fearful behaviors (i.e., defensive treading behavior during eating/treading tests and escape attempts and distress vocalizations after all tests when rats were retrieved by the experimenter).
Notably, no neutral zone was evident, even at intermediate levels of the shell. Instead, some midway sites simultaneously elicited mixed bouts of both positive eating and negative fearful treading, whereas others elicited only one of these valenced behaviors. No sites had zero motivational/affective valence after GABAA receptor activation under these conditions.
GABAergic food intake, affect, and hunger
Several potential explanations could account for eating behavior elicited by rostral GABAergic circuits: natural hunger and palatability enhancement, a coping response to stress, or a fragmentary psychological process such as incentive salience. However, several observations indicate against interpretations of either pure natural hunger or pure stress. Eating was accompanied by positive affective reactions at far rostral sites but by negative affective reactions at intermediate rostral sites. Positive affective enhancement of taste "liking" is consistent with the alliesthesia of natural hunger (Cabanac, 1979
Alternatively, GABAergic eating behavior might be explained by a fragmentary psychological component of hunger and other natural motivations, such as incentive salience or "wanting." For example, Berridge and colleagues suggest that incentive salience is attributed by mesoaccumbens systems to neural representations of food, drugs, or other reward-related stimuli (Berridge and Valenstein, 1991
GABAergic defensive treading, affect, and fear
Similar to rostral eating and hunger, defensive treading behavior elicited by caudal shell GABAergic receptor activation may not correspond fully to any natural state of fear, although it may involve some motivational components shared with natural fearful states. Defensive treading patterns observed here are similar to the natural anti-predator treading reactions that rats deploy against electrified shock prods, that mice use against scorpions, and that ground squirrels use against rattlesnakes that attack their burrow (Owings and Coss, 1977
Defensive treading behavior is an active coping form of fearful reaction, clearly different from passive inhibitory freezing, startle, etc. Albeit speculative, a negative valence extension of the mesolimbic hypothesis of incentive salience could provide one possible explanation for observed fear, feeding, and place conditioning patterns (Berridge and Robinson, 1998
Muscimol-elicited wanting versus liking
Beyond any fearful process, however, the aversive orofacial expressions to sweet tastes observed after caudal muscimol microinjections indicate a more specifically affective form of negative reaction (Fig. 5). Fear of footshock is not ordinarily accompanied by taste "disliking" expressions (Pelchat et al., 1983
GABAergic effects on taste "liking" and food intake corresponded together at positive rostral and negative caudal ends of the shell. However, affective reactions to taste were dissociated from motivation after intermediate rostral muscimol microinjections, which still caused rats to eat food >400% more than normal, but paradoxically to affectively "dislike" sucrose taste. This eating-but-aversive combination appeared similar to previous dissociations of sucrose "wanting" from "liking" caused by mesoaccumbens manipulations (Berridge and Valenstein, 1991
Neuronal microcircuits in accumbens shell
The nucleus accumbens has been proposed to contain distinct ensembles of neurons that in principle could function as segregated microcircuits (Pennartz et al., 1994
Rostrocaudal valence gradients: neurochemical/anatomical interaction
It is important to note that bivalent organization of GABA effects is not a fixed anatomical feature of rostrocaudal microcircuits but rather may reflect specific neurochemical/anatomical interactions. The same anatomical microcircuit may be capable of differently valenced outputs in response to different neurochemical manipulations. For example, dopamine and opioid agonists may have positively valenced motivational effects on behavior, including affective reactions to taste for opioids, even when administered at shell sites that caused negative or mixed effects here (Bakshi and Kelley, 1993
Implications for bivalent human motivation
The existence of GABAergic rostrocaudal gradients for positive/negative motivation in accumbens shell may help illuminate how the nucleus accumbens can participate in both appetitive and aversive motivational functions (Salamone, 1994
FOOTNOTES Received Jan. 10, 2002; revised May 28, 2002; accepted June 5, 2002.
This research was supported by a National Science Foundation grant (IBN 9604408) to K.C.B. and a National Institutes of Health fellowship (National Institute on Drug Abuse F31 DA14679-01) and training grant (National Institute on Deafness and Other Communication Disorders T32 DC00011) to S.M.R. We thank Prof. Craig W. Berridge and Prof. Ann E. Kelley for helpful comments on earlier versions of this manuscript.
Correspondence should be addressed to Sheila M. Reynolds, Department of Psychology, University of Michigan, Ann Arbor, MI 48109-1109. E-mail: sheilar{at}umich.edu or berridge{at}umich.edu.
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