Modulation of Hippocampal and Amygdalar-Evoked Activity of Nucleus Accumbens Neurons by Dopamine: Cellular Mechanisms of Input Selection

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The Journal of Neuroscience, April 15, 2001, 21(8):2851-2860

Modulation of Hippocampal and Amygdalar-Evoked Activity of Nucleus Accumbens Neurons by Dopamine: Cellular Mechanisms of Input Selection
Stan B. Floresco¹, Charles D. Blaha², Charles R. Yang³, and Anthony G. Phillips¹
¹ Department of Psychology, University of British Columbia Vancouver, British Columbia, Canada V6T 1Z4, ² Department of Psychology, Macquarie University, Sydney, New South Wales, Australia 2109, and ³ Eli Lilly Company, Neuroscience Research, Lilly Corporate Center, Indianapolis, Indiana 46285-0510

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Inputs from multiple sites in the telencephalon, including the hippocampus and basolateral amygdala (BLA), converge on neuronsin the nucleus accumbens (NAc), and dopamine (DA) is believedto play an essential role in the amplification and gating of thesedifferent limbic inputs. The present study used extracellularsingle-unit recordings of NAc neurons in combination with chronoamperometricsampling of mesoaccumbens DA efflux to assess the importance ofDA in the integration of different limbic inputs to the NAc. Tetanicstimulation of the fimbria potentiated hippocampal-evoked firingactivity of NAc neurons and increased DA extracellular levels.Systemic administration of the D₁ receptor antagonist SCH23390or the NMDA receptor antagonist CPP abolished the potentiationof hippocampal-evoked activity and produced a D₂ receptor-mediatedsuppression of evoked firing. In neurons that received converginginput from the hippocampus and BLA, fimbria tetanus potentiatedhippocampal-evoked firing activity and suppressed BLA-evoked activityin the same neurons. Both D₁ and NMDA receptors participated inthe potentiation of fimbria-evoked activity, whereas the suppressionof BLA-evoked activity was blocked by either D₁ receptor antagonismwith SCH23390 or the adenosine A₁ antagonist 8-cyclopentyl-1,2-dimethylxanthine.Coincidental tetanus of both the fimbria and BLA resulted in potentiationof both inputs, indicating that DA and adenosine-mediated suppressionof BLA-evoked firing was activity-dependent. These data suggestthat increases in mesoaccumbens DA efflux by hippocampal afferentsto the NAc play a critical role in an input selection mechanism,which can ensure preferential responding to the information conveyedfrom the hippocampus to the ventralstriatum.

Key words: nucleus accumbens; hippocampus; basolateral amygdala; dopamine; NMDA; adenosine; gating

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Neural mechanisms for the selection of adaptive behaviors in response to constantly changing environmental conditions areessential for survival in all species. Different adaptive responsescan be influenced by multiple memory systems involved in specificcognitive operations which in turn control specific patterns ofbehavior (Sherry and Schacter, 1987; Nadel, 1992; McDonald andWhite, 1993). It remains to be determined how the brain integratesinputs from different information-processing systems to producecomplex sequences of behavior appropriate to different environmentalstimuli. For example, in ambiguous situations when an organismmust choose between a variety of response options, which cellularmechanisms enable one neural network to have preferential accessto motor effector sites, while inhibiting other potentially competingcircuits?

The nucleus accumbens (NAc) is well situated for the integration of inputs from separate neural networks such as the hippocampalformation, which computes spatial and contextual information,or the basolateral amygdala (BLA), which processes stimulus-rewardassociations (Eichenbaum, 1996; Robbins and Everitt, 1996). TheNAc receives excitatory glutamatergic afferents from limbic regionssuch as the BLA, prefrontal cortex, and hippocampus (Groenewegenet al., 1991; Brog et al., 1993; Mogenson et al., 1993; Pennartzet al., 1994; Meredith and Totterdell, 1999) and in many instances,inputs from these anatomically and functionally distinct regionsconverge on the same medium spiny neurons (Callaway et al., 1991;O'Donnell and Grace, 1995; Mulder et al., 1998). The NAc alsoreceives a dense projection from dopaminergic neurons in the ventraltegmental area (VTA) ( Nauta et al., 1978; Björklund and Lindvall,1984; Voorn et al., 1986). Recent neurochemical studies have shownthat glutamatergic limbic inputs from the hippocampus and BLAcan also exert direct control over phasic increases in mesoaccumbensDA release, in addition to release mediated by bursting activityof VTA neurons (Chergui et al., 1994). Brief, higher-frequency(>5 Hz) electrical stimulation of the ventral hippocampus or theBLA produces robust and long-lasting increases in mesoaccumbensDA efflux, and these effects appear to be mediated in part byglutamate-dependent mechanisms localized within the NAc (Blahaet al., 1997; Floresco et al., 1998; Taepavarapruk et al., 2000).

The effects of DA on striatal neurons are complex and can either inhibit (Yang and Mogenson, 1984, 1986; White and Wang, 1986;Pennartz et al., 1991; Mogenson et al., 1993; Harvey and Lacey,1997) or facilitate (Pennartz et al., 1991; Gonon and Sundstrom,1996; Harvey and Lacey, 1997; Hernández-López et al., 1997;Cepeda and Levine, 1998) synaptic activity of medium spiny neuronsevoked by excitatory glutamatergic afferents. Similarly, DA canalso exert differential effects on synaptic plasticity of striatalneurons, promoting either long-term potentiation or depressionof glutamate inputs to medium spiny neurons, as a function ofspecific experimental conditions. Bath application of DA promoteslong-term depression, whereas similar applications of DA in absenceof extracellular Mg²⁺, or pulsatile administration of DA coincidental with tetanicstimulation of corticostriatal afferents facilitates long-termpotentiation (Wickens et al., 1996; Calabresi et al., 2000; Nicolaet al., 2000). These opposing actions of DA suggest that mesoaccumbensDA may play an important role in the integration and gating ofdifferent limbic signals to the NAc, by amplifying one subsetof inputs while concurrently inhibiting activation of medium spinyneurons evoked by other afferent projections (Oades, 1985; Mogensonet al., 1993; Pennartz et al., 1994; Ikemoto and Panksepp, 1999;Redgrave et al., 1999). Although this remains a distinct possibility,previous studies investigating the effects of DA have focusedindependently on either its suppressive or facilitatory effects.Differential modulation by DA of separate limbic inputs convergingon the same neurons in the NAc has yet to be demonstrated. Thepresent study used electrophysiological recordings from NAc neuronsthat responded to either hippocampal stimulation alone or bothhippocampal and BLA stimulation to assess (1) the relation betweenevoked efflux of DA in the NAc measured by chronoamperommetryand post-tetanic potentiation of the hippocampal-NAc pathway,(2) the effect of this potentiation on subsequent activity evokedby stimulation of the BLA on neurons receiving convergent input,and (3) the involvement of specific DA, glutamate, and adenosinereceptors in these forms of homosynaptic facilitation and heterosynapticdepression.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals and surgical preparations. A total of 111 male hooded rats (Long-Evans, Charles River, St. Constant, Quebec, Canada)weighing 250-350 gm were used. Animals were housed in individualstainless steel cages at constant room temperature (24°C, 60%relative humidity) and maintained on a 12 hr light/dark cycle(lights on at 7:00 A.M.). Food and water were available ad libitum.

Rats were anesthetized with urethane (1.5 gm/kg, i.p.) and mounted in a stereotaxic frame. Body temperature was maintainedat 37°C with a temperature-controlled heating pad (American HospitalSupplies, McGraw Park, IL). Rats were implanted with concentricbipolar electrical stimulating electrodes (SNE-100; Rhodes MedicalCompany, Kopf) in the fimbria and the BLA. The stereotaxic coordinateswere: flat skull, fimbria electrode = anteroposterior (AP) $-$ 1.3mm (bregma), mediolateral (ML) +1.6 mm, dorsoventral (DV) $-$ 4.0mm (cortex); BLA electrode = AP $-$ 3.2 mm, ML +5.0 mm, DV $-$ 7.0mm.

In some rats, stearate-modified graphite paste electrochemical recording electrodes that permit in vivo measurement of changesin DA efflux without interference from other oxidizable compoundsin brain extracellular fluid (Blaha and Phillips, 1996; cf. theirreferences) were implanted stereotaxically into the NAc, ipsilateralto both stimulating electrodes (AP +1.5, ML $-$ 1.0 at 15° angle,DV $-$ 6.5 mm). In these preparations, an Ag-AgC1 reference and stainlesssteel auxiliary electrode combination was placed in contact withcortical tissue 4 mm posterior tobregma.

Extracellular recordings. Extracellular single-unit activity was recorded with glass microelectrodes (5-10 M $Omega$ ; filled withFast Green dye and 0.5 M sodium acetate). Single-unit activitywas filtered (bandpass 500-5000 Hz), and individual action potentialsfrom single units were separated from noise using a window discriminatorand sampled on-line by a computer connected to a Data TranslationDT 2821 analog-to-digital board interface. Peristimulus time histogramswere constructed on-line. For rats that had electrochemical recordingelectrodes implanted in the NAc, the placement of the microelectrodewas set to the same anterior plane as the electrochemical recordingelectrode (~AP +1.5), and was 0.9-1.3 mm lateral from the midlineand 5.0-7.0 mm ventral from the top of the cortex. This medialregion of the NAc exhibits the greatest proportion of neuronsthat receive converging input from both the hippocampus and theBLA (Mulder et al., 1998), as opposed to the NAc core, which hasvery few neurons that receive converging inputs (Finch, 1996).The arrangement of electrodes ensured that the glass microelectrodewould be in close proximity to the electrochemical recording electrode.Microelectrodes were lowered slowly into the medial shell regionof the NAc using a hydraulic microdrive. Cells that displayeda signal-to-noise ratio of <3:1 were not included in the analysis.Likewise, cells that displayed spontaneous activity of >5 spikes/secwere also not used in theanalysis.

Electrochemical recordings. Repetitive chronoamperometric measurements of oxidation current using an electrometer (Echempro,Vancouver, British Columbia, Canada) were made by applying a potentialpulse from $-$ 0.15 to +0.25 V versus Ag-AgCl to the recording electrodefor 1 sec at 30 sec intervals and monitoring the oxidation currentat the end of each 1 sec pulse. The timing of the potential pulsewas set so that it would occur >300 msec after electrical stimulationof either the fimbria or the BLA to ensure that the artifact producedby the pulse would not overlap with evoked activity of NAc neurons.Prestimulation baseline currents were normalized to zero currentvalues with stimulated changes in the baseline signal presentedas absolute changes (increases as positive and decreases as negativevalues) in DA oxidation current (for details, see Blaha et al.,1997).

Stimulation protocol. After the glass microelectrodes had been lowered to the dorsal border of the NAc, a cell-searching procedurebegan. In this procedure, alternating stimuli were delivered tothe fimbria and the BLA (1800 µA) at 750 msec intervals, whilethe microelectrode was lowered incrementally through the NAc.Cathodal constant current pulses (0.2 msec duration) were deliveredto the fimbria and BLA through an Iso-Flex optical isolator (A.M.P.I.,Jerusalem, Israel) via a Master-8 programmable pulse generator(A.M.P.I.) using parameters noted below. Once a cell was detected,the position of the microelectrode was adjusted to maximize thespike amplitude relative to background noise. Neurons that respondedonly to fimbria stimulation or received converging input fromboth the hippocampus and the BLA, were identified by their robustexcitatory response after fimbria stimulation alone or by responseto both fimbria and BLA stimulation. Cells that did not exhibita monosynaptic response component to fimbria stimulation (latencyrange 6-11 msec; Mulder et al., 1998) were not used in the dataanalysis.

Once a cell was isolated, stimulation currents were adjusted to approximately half-maximal stimulation intensity (range, 200-1900µA), so that ~50 action potentials were evoked in response toa train of 100 fimbria or BLA stimulations delivered at 2 Hz frequencies.Evoked spike probabilities were calculated by dividing the numberof action potentials observed by the number of stimuli administered.Changes in spike probabilities were used as an index of changesin the influence that hippocampal and BLA inputs exert over NAcneuronal activity. For neurons that responded only to fimbriastimulation, trains of 2 Hz stimulation to the fimbria (100 pulsesfor 50 sec) were delivered every 3-5 min. Once stable levels ofevoked-spiking activity were obtained (<15% variation in spikeprobability over 5-10 min), one tetanic stimulation of the fimbriawas administered (200 pulses at 20 Hz for 10 sec, suprathresholdintensity). Previous investigations in our laboratory have shownthat this tetanus parameter produces a reliable and robust increasein DA efflux in the NAc (Blaha et al., 1997; Taepavarapruk etal., 2000). Two minutes after tetanus (assigned as time 0), trainsof 2 Hz fimbria stimulation were applied (100 pulses for 50 secat the same current as before tetanus), and this was repeatedat 5 min intervals for another 25 min. Data were normalized tothe spike probability of the sample 2 min before tetanus, andthe data were analyzed in terms of percent change in spikeprobability.

A similar stimulation protocol and analysis was used for NAc neurons that received converging limbic input. Once isolated,stimulation currents for both inputs were adjusted to 50% maximalresponding at 2 Hz frequency. Stimulation by single pulses at2 Hz (100 pulses for 50 sec) was administered to the BLA followedby an identical train to the fimbria. After stable baseline spikeprobabilities, a tetanus was delivered to the fimbria (200 pulses,20 Hz for 10 sec). After tetanic stimulation (time 0), trainsof 2 Hz stimuli (100 pulses for 50 sec) were delivered to theBLA at time points 15 sec, 2 min, and every 5 min thereafter;identical trains were delivered to the fimbria at time points1 min, 3 min, and every 5 min after, to a maximum of 25 min. Nomore than two tetani to the fimbria were administered per animal,and the interval between tetanic stimulations was at least 3hr.

Pharmacological manipulations. To permit administration of pharmacological antagonists, separate groups of rats were implantedwith intravenous jugular catheters, consisting of PE 10 tubingattached to a 30 gauge needle and a 1 cc syringe. During theseexperiments, no electrochemical recordings were obtained. Unlessotherwise specified, all drugs were administered 10-15 min beforetetanic stimulation of the fimbria. The selective D₁ receptorantagonist SCH23390 (0.5, 0.05, or 0.005 mg/kg; Research Biochemicals,Natick, MA) and the selective NMDA receptor antagonist CPP (1.0or 0.1 mg/kg; Research Biochemicals) were dissolved in physiologicalsaline. The selective D₂ receptor antagonist sulpiride (5.0 mg/kg;Research Biochemicals) was dissolved in a drop of NaOH and PBS.The adenosine A₁ receptor antagonist 8-cyclopentyl-1,2-dimethylxanthine(DPCPX) (2.5 mg/kg; Research Biochemicals) was dissolved in DMSO.The concentrations of these solutions were set so that injectionvolumes would range between 0.15 and 0.30 ml. No more than twodrug injections were given per animal, and in the interval betweeninjections was at least 3.5hr.

Histological assessment. After completion of each experiment, an iron deposit was made in the fimbria and BLA stimulationsites by passing DC current (100 µA for 10 sec) through the stimulatingelectrode. A dye deposit was made in the NAc recording site byejecting Fast Green with a 20 µA anodal current for 10 min. Thebrain was removed and placed in 10% buffered formalin containing0.1% potassium ferricyanide. After fixation, 50 µm sections werecut on a freezing microtome and stained for Nissl substance withcresyl violet. A Prussian Blue spot resulting from a redox reactionof ferricyanide marked the stimulation site. The placements ofelectrochemical recording electrode, glass microelectrode, andstimulating electrodes were determined under a light microscopeand are represented in Figure 1.

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Figure 1. Histology. A, Schematic of coronal sections of the rat brain showing representative placements of electrochemical electrodes (squares), location of NAc neurons that responded only to stimulation of the fimbria (black circles), and neurons that received input from both the hippocampus and BLA (black and gray circles), recorded from control rats and rats whose data are presented in Figures 3A-D and 4C. Brain sections correspond to the atlas of Paxinos and Watson (1997). Numbers correspond to millimeters from bregma. B, C, Photograph of a representative placement of a stimulating electrode in the fimbria (B) and the BLA (C). Arrows highlight the location of stimulating electrode placements. cc, Corpus callosum; CPu, caudate putamen; opt, optic tract.

Data analysis. For the electrochemical recordings, pre-tetanus baseline currents were normalized to zero current values, andstimulated changes in the baseline signal were presented as absolutechanges (increases as positive and decreases as negative values)in DA oxidation current. These data were analyzed using a one-way,repeated measures ANOVA with time as a within-subjects factor.Multiple comparisons were made versus the sample taken 2 min beforetetanus and for data points at time 0 (tetanus) and at time pointswhen either the fimbria or BLA were stimulated at 2 Hz. Analysisof the extracellular recording data required that pre-tetanusbaseline spike probabilities be normalized to the spike probabilityof the sample 2 min before tetanus, so that the relative changein spike probability at this time point would be 0. These datawere then converted to percent change in spike probability, usingthe formula: (sample spike probability $-$ baseline spike probability) $divide$ baseline spike probability. Thus, a +100% change in spike probabilityafter fimbria tetanus would indicate that twice as many actionpotentials were elicited over a 100 pulse train of 2 Hz stimulation,relative to the number of action potentials that were observedusing the same stimulation current before tetanus. Statisticalcomparisons were made with the spike probability recorded 7 minbeforetetanus.

Data obtained from cells which responded only to fimbria stimulation but not the BLA were analyzed using a two-way, between-and within-subjects ANOVA, with drug condition as the between-subjectsfactor and time as the within-subjects factor. Data from neuronsthat received converging input from both the fimbria and BLA wereanalyzed using a three-way, between- and within-subjects ANOVA,with drug condition as the between-subjects factor, and time andinput (fimbria or BLA) as two within-subjects factors. Multiplecomparisons for both the electrochemical and electrophysiologicalanalyses were made using two-tailed Dunnett's test for repeatedmeasures.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Dopaminergic and glutamatergic mechanisms mediating the potentiation of hippocampal-evoked spiking activity of NAc neurons

Data from a total of 93 NAc neurons that responded only to stimulation of the fimbria, but not the BLA, were used in the presentanalysis (63% of all neurons tested). In these cells, fimbriastimulation evoked a short-latency, monosynaptic spike (latencyrange, 6-11 msec), and in some cells, a longer latency polysynapticspike (latency range, 19-31 msec; n = 33; see Mulder et al., 1998).The mean baseline spike probability for all cells was 0.464 ±0.02. The baseline spike probabilities did not differ betweentreatment groups (F_(8,61) = 0.99;NS).

The initial experiment assessed the effect of tetanic stimulation of the fimbria on both changes in mesoaccumbens DA releaseand fimbria-evoked neuronal spiking activity. Extracellular singleunit recordings were obtained from nine individual NAc neuronsthat responded to stimulation of the fimbria, but not the BLA.These recordings were taken from six rats that had electrochemicalrecording electrodes implanted into the ipsilateral NAc. Tetanicstimulation of the fimbria resulted in a transient increase inDA efflux that was time-locked to the presentation of the tetanus.This was followed promptly by a brief period of inhibition, andthen a second, more prolonged increase in DA efflux that was significantlyelevated 25 min after tetanic fimbria stimulation, as reportedpreviously (Blaha et al., 1997) (F_(7,42) = 3.6, p < 0.005 andDunnett's, p < 0.05) (Fig. 2A). In seven of nine (78%) NAc neuronsrecorded simultaneously with electrochemical measures of DA oxidationcurrents, tetanic stimulation of the fimbria also produced a robustshort-term potentiation (lasting 25 min) in fimbria-evoked spikingactivity (F_(6,48) = 2.2, p < 0.05 and Dunnett's, p < 0.01) (Fig.2B,C). Thus, high-frequency stimulation of glutamatergic hippocampalinputs to the NAc increased mesoaccumbens DA release, which wasaccompanied by an increase in the excitability of NAc neuronsin response to fimbria stimulation.

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Figure 2. Tetanic stimulation of hippocampal afferents in the fimbria increases mesoaccumbens DA efflux and enhances hippocampal-evoked spiking activity in NAc neurons. A, Mean changes in DA oxidation currents in the NAc recorded by chronoamperometry. Tetanic stimulation of the fimbria (20 Hz, 10 sec; open arrow) produced a significant increase in DA efflux. Asterisks denote significant difference from baseline (white circle) at p < 0.05. B, Mean percent change (+ SEM) in fimbria-evoked spiking activity recorded from NAc neurons in the same animals from which the chronoamperometric recordings were obtained. Gray squares represent percent change in fimbria-evoked spiking probability normalized to the spike probability obtained 2 min before tetanus. Vertical filled arrows indicate time points at which trains of 2 Hz fimbria stimulation were administered. Double asterisks denote significance from baseline spike probability (sample 7 min before tetanus) at p < 0.01. C, Peristimulus time histograms showing the typical response from a NAc neuron 2 min before and 2, 10, and 20 min after fimbria tetanus. This neuron displayed a baseline spiking probability of 0.6 at a stimulation current of 650 µA. After tetanic stimulation of the fimbria (gray bar), the spiking probability of the neuron (at the same stimulation current) was increased to ~1.0. Arrows represent time points when trains of 2 Hz fimbria stimulation were administered.

To ascertain the receptor mechanisms mediating the potentiation of hippocampal-evoked spiking activity, separate groups ofrats (86 cells recorded from 65 animals) received intravenousadministration of selective DA or NMDA receptor antagonists. Theoverall analysis of these data revealed a significant time × drugtreatment interaction (F_(6,366) = 1.9; p < 0.001).

Injection of the D₁ antagonist SCH23390 (0.5 mg/kg) abolished the potentiation of fimbria-evoked spiking activity in all cellstested (nine of nine; 100%). Furthermore, pretreatment with SCH23390resulted in a significant (p < 0.01) long-lasting depression infimbria-evoked spiking activity (eight of nine neurons; 89%) thatlasted throughout the 25 min recording session (Fig. 3A,B). Theeffects of SCH23390 were dose-dependent (n = 6 for each dose)(Table 1). This depression was not caused by a nonselective actionof SCH23390 by itself, because injection of SCH23390 without applyingfimbria tetanus produced no significant change in firing activityevoked by 2 Hz fimbria stimulation (n = 5; F_(7,28) = 0.28, NS)(Fig. 3E). Injections of the D₂ receptor antagonist sulpiridealone (5 mg/kg) did not block the potentiation of fimbria-evokedspiking activity by fimbria tetanus, observed in 7 of 11 neurons(63%) (Fig. 3A). However, SCH23390 (0.5 mg/kg) and sulpiride (5mg/kg) in combination resulted in only a transient (2 min) post-tetanicdepression of fimbria-evoked activity (n = 8) (Fig. 3A). It isalso noteworthy that repetitive trains of 2 Hz stimulation ofthe fimbria over a 20 min period without tetanic stimulation producedno change in fimbria-evoked spiking activity (Fig. 3E), indicatingthat repeated trains of 2 Hz stimulation do not produce changesin synaptic efficacy in the NAc.

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Figure 3. Potentiation of hippocampal-evoked spiking activity in NAc neurons is dependent on both D₁ and NMDA receptors. For all figures, symbols represent mean percent change (+SEM) in fimbria-evoked spiking activity of NAc neurons. A, Change in fimbria-evoked spiking activity under control conditions (gray squares) and after treatment with the D₁ receptor antagonist SCH23390 (0.5 mg/kg; black circles), the D₂ receptor antagonist sulpiride (5.0 mg/kg; white circles), and a combination of SCH23390 and sulpiride (gray hexagons). Arrow in the bottom left corner indicates time point of drug injection. B, Peristimulus time histograms showing a typical response from a single NAc neuron pretreated with SCH23390 10 min before tetanus, at baseline (2 min before), and 2, 10, and 20 min after fimbria tetanus. Baseline spiking probability was 0.62 (800 µA), and after fimbria tetanus (gray bar), the spiking probability decreased by >50%. Arrows represent time points at which trains of 2 Hz fimbria stimulation were administered. C, Change in fimbria-evoked spiking from control neurons (gray squares), after pretreatment with the NMDA receptor antagonist CPP (1.0 mg/kg; black squares), and after pretreatment with a combination of CPP and sulpiride (white hexagons). D, Change in fimbria-evoked spiking activity after post-tetanus injection of SCH23390 (black circles) or CPP (black squares). Arrow indicates time point when the drugs were administered (3 min after tetanus). E, Change in fimbria-evoked spiking activity recorded from NAc neurons after 20 min of 2 Hz stimulation in the absence of drug and another 25 min of 2 Hz stimulation after injection of either SCH23390 or CPP. For all figures, double asterisks denote significance from baseline spiking probabilities at p < 0.01 (Dunnett's test).


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Table 1. Mean percent change in fimbria-evoked spiking probability (±SEM) before tetanus and averaged over the first 20 min after tetanus for control neurons and for neurons treated with either SCH23390 (0.5, 0.05, and 0.005 mg/kg) or CPP (1.0 and 0.1 mg/kg)

The enhancement of the response of NAc neurons to fimbria stimulation was critically dependent on the initial increase inDA efflux that occurred coincidentally with tetanic activationof hippocampal inputs. Administration of SCH23390 (0.5 mg/kg)3 min after fimbria tetanus, before the secondary prolonged increasein NAc DA efflux, failed to block the potentiation of fimbria-evokedspiking activity in all neurons tested (n = 7/7, 100%; F_(7,35)= 3.0, p < 0.05) (Fig. 3D). In fact, injections of SCH23390 aftertetanus prolonged the time course of the potentiation, with allcells displaying an enhancement of evoked spiking activity 30min after tetanus. Collectively, these data indicate that theshort-term potentiation of hippocampal-evoked spiking activityin NAc neurons after tetanic stimulation of the fimbria is mediatedby the transient increase in DA efflux that is time-locked tothe arrival of higher frequency inputs. Of particular interestis the finding that during D₁ receptor blockade, activation ofD₂ receptors resulted in a long-lasting depression (>30 min) ofevoked spiking activity, as may be inferred from the reversalof this effect by coadministration ofsulpiride.

Previous studies have shown that synaptic plasticity in the hippocampal-NAc pathway is dependent on NMDA receptor activation(Pennartz et al., 1993; Feasy-Trugger and ten Bruggencate, 1994).In accordance with these findings, the NMDA receptor antagonistCPP [1.0 (n = 7) or 0.1 (n = 6) mg/kg, i.v.] produced a dose-dependenteffect similar to that of SCH23390, because it blocked the tetanus-inducedpotentiation of fimbria-evoked spiking activity and caused a significant(p < 0.01), long-lasting depression of fimbria-evoked spikingactivity in 100% of the neurons tested (Fig. 3C, Table 1). CPPalone without fimbria tetanus had no significant effect on fimbria-evokedspiking activity (n = 5) (Fig. 3E). As observed after fimbriatetanus in the presence of D₁ receptor blockade, D₂ receptorsagain played a role in the inhibition of evoked spiking activityafter NMDA receptor blockade. Coadministration of CPP and sulpiride(5 mg/kg) resulted in a shorter lasting ((10 min), nonsignificantreduction in fimbria-evoked spiking activity (Fig. 3C).

Unlike the effects observed with SCH23390, administration of CPP 3 min after tetanus abolished or attenuated the potentiationof fimbria-evoked spiking activity in six of seven neurons (86%)tested (F_(7,42) = 0.5, NS) (Fig. 2D). This confirms that activationof NMDA receptors is necessary for both the induction and maintenanceof the DA-mediated potentiation of fimbria-evoked spiking activityin NAc neurons. A separate series of experiments demonstratedthat a systemic injection of CPP did not block mesoaccumbens DAefflux evoked by tetanic stimulation of the fimbria (n = 6; meanpeak increases in DA oxidation current, control = 0.83 nA, CPP= 0.90 nA). It should be noted however that intra-NAc administrationof APV has been shown to block increases in mesoaccumbens DA effluxevoked by tetanic stimulation of hippocampal inputs to the NAcin both anesthetized (Blaha et al., 1997) and freely moving rats(Taepavarapruk et al., 2000). The lack of effect in the presentstudy suggests that at the present dose, route of administration,or specific pharmacological actions of this NMDA antagonist (i.e.,CPP) was not sufficient to block hippocampal-mediated DA releasethat is regulated by NMDA receptors in the NAc. Thus, the potentiationof hippocampal-evoked spiking activity of NAc requires a cooperativeaction of both D₁ and NMDA receptors, and after blockade of eitherof these receptors, there remains a D₂-receptor mediated reductionin cellexcitability.

The role of dopamine in homosynaptic facilitation of hippocampal-evoked spiking activity and heterosynaptic depression of BLA-evoked activity of NAc neurons

A sub-population of NAc neurons receives converging input from both the hippocampus and the BLA (Callaway et al., 1991; O'Donnelland Grace, 1995; Mulder et al., 1998). Tetanic stimulation ofthe fimbria can evoke long-term potentiation of fimbria-evokedfield potentials in the NAc while simultaneously causing long-termdepression of the BLA-NAc pathway (Mulder et al., 1998). The latterstudy did not specify whether the homosynaptic potentiation ofthe hippocampal inputs and heterosynaptic depression of the BLAinputs to the NAc occurs in neurons that receive converging inputfrom both regions. Moreover, the underlying cellular mechanismsthat mediated these opposing effects on synaptic plasticity oflimbic inputs to the NAc are poorly understood. In light of thepresent data, showing that tetanic stimulation of fimbria resultsin DA-dependent changes in evoked firing activity of NAc neurons,it is possible that the opposing effects on synaptic plasticityof different converging inputs to the NAc were mediated in partby mesoaccumbens DA transmission. Therefore, extracellular single-unitrecordings were made from 55 NAc neurons (37% of all cells) thatreceived converging input from both the hippocampus andBLA.

Stimulation of the fimbria produced a robust excitatory response with spike latencies that were similar to those observedin neurons that only responded to fimbria stimulation. These cellsalso exhibited monosynaptic responses to BLA stimulation (latencyrange, 11-29 msec). The mean baseline spike probability for allcells was 0.502 ± 0.02 for fimbria-evoked responses and 0.533± 0.03 for BLA-evoked responses (F_(1,49) = 0.76; NS). The baselinespike probabilities for both fimbria- and BLA-evoked spiking activitydid not differ between treatment groups (F_(5,49) = 0.16; NS).We were unable to record from three control cells continuouslyfor the entire 25 min recording period. Thus, only the data fromthe first 15 min after tetanus were used in thisanalysis.

In six rats, tetanic stimulation of the fimbria produced a transient increase in DA efflux, as measured by chronoamperometry,that was time-locked to the presentation of the tetanus, followedby a longer lasting decrease in extracellular DA levels (F_(5,35)= 4.69, p < 0.005 and Dunnett's, p < 0.05). Interestingly, whenboth the fimbria and BLA were stimulated at 2 Hz after fimbriatetanus, the prolonged increase in DA release that was observedpreviously (Blaha et al., 1997) (Fig. 2A) was absent after thisstimulation protocol (Fig. 4A). This effect may be attributableto activation of metabotropic glutamate receptors by low frequencystimulation of both hippocampal and BLA inputs to the NAc (Blahaet al., 1997; Floresco et al., 1998).

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Figure 4. Tetanic stimulation of the fimbria increases mesoaccumbens DA efflux, enhances neural activity evoked by fimbria stimulation, and suppresses BLA-evoked spiking activity of NAc neurons. A, Mean changes in DA oxidation currents in the NAc recorded by chronoamperometry. Tetanic stimulation of the fimbria (open arrow) produced a significant increase in DA efflux. Asterisks denote significant difference from baseline (white circle) at p < 0.05. B, Mean percent change (± SEM) in fimbria (black bars)- and BLA (gray bars)-evoked spiking activity recorded from NAc neurons that received converging input from both brain regions. Histograms represent percent change in fimbria- and BLA-evoked spiking probability normalized to the spike probabilities obtained 2 min before tetanus. Location of the histograms on the abscissa indicates time points at which trains of 2 Hz stimulation of either the fimbria or BLA were administered. Tetanic stimulation of the fimbria increased fimbria-evoked spiking probability while suppressing BLA-evoked spiking activity in the same neurons. C, Mean percent change (± SEM) in fimbria (black histograms) and BLA-evoked (gray) spiking activity recorded from NAc neurons averaged over the first 12 min after fimbria tetanus for control treatment, SCH23390 (0.5 mg/kg), sulpiride (5.0 mg/kg), CPP (1.0 mg/kg), the adenosine A₁ antagonist DPCPX (2.5 mg/kg), and tetanic stimulation of both the fimbria and the BLA. Baseline spike probabilities for each condition have been omitted for clarity. Asterisks and double asterisks denote significance from baseline spike probability (sample 7 min before tetanus) at p < 0.05 and 0.01, respectively.

In these same animals, fimbria-evoked spiking activity of NAc neurons was potentiated, in a manner similar to that describedabove, which was apparent 1 min after tetanus (eight of nine neurons,89%) (Fig. 4B, black bars). However, tetanic stimulation of thefimbria resulted in a depression of BLA-evoked spiking activity,in these same neurons (seven of nine neurons; 78%) (Fig. 4B, graybars) (time × input interaction, F_(3,24) = 6.9, p < 0.01 and Dunnett's,p < 0.01). BLA-evoked spiking activity was depressed maximally(~50% decrease) during the sample taken immediately after fimbriatetanus, when DA oxidation currents reached peak values and slowlyreturned to baseline levels over the next 10-15min.

Separate pharmacological experiments (n = 34 rats) revealed that both the potentiation of fimbria-evoked spiking activityand suppression of BLA-evoked spiking activity after fimbria tetanuswere abolished by pretreatment with SCH23390 (0.5 mg/kg, i.v.;n = 9) (Fig. 4C), suggesting that D₁ receptors mediate both ofthese effects. However, considering the dose of SCH23390 usedin this experiment, we cannot rule out the possibility that a5-HT2 receptor mechanism may also play a role in the suppressionof BLA-evoked activity (Bischoff et al., 1986). Injections ofsulpiride (5 mg/kg; n = 11) had no effect (Fig. 4C). CPP blockadeof NMDA receptors (1.0 mg/kg; n = 9), abolished the potentiationof fimbria-evoked spiking activity, but had no effect on the suppressionof BLA-evoked spiking activity (Fig. 4C).

Presynaptic inhibition of glutamatergic inputs to the NAc by D₁ receptor activation can be co-mediated by adenosine, actingas a retrograde messenger to inhibit glutamate inputs presynapticallyvia the A₁ receptor (Harvey and Lacey, 1997). We observed thatthe adenosine A₁ antagonist DPCPX (2.5 mg/kg, i.v.) markedly reducedthe suppression of BLA-evoked spiking activity after fimbria tetanusin a separate group of neurons (n = 10) but had no effect on thepotentiation of hippocampal-evoked spiking activity (Fig. 4C).This is consistent with the role of adenosine as an inhibitoryretrograde signal. Thus, a brief increase in DA efflux evokedby high-frequency activity in hippocampal afferents to the NAcis sufficient to enhance fimbria-evoked spiking activity, whilesimultaneously causing a suppression of BLA-evoked spiking activityin the same neurons. The homosynaptic potentiation of hippocampalevoked activity requires both D₁ and NMDA receptor activity, whereasthe heterosynaptic suppression of BLA-evoked firing is dependenton both D₁ and adenosine A₁receptors.

The differential modulation by DA over hippocampal and BLA-evoked activity may have been attributable to the fact that therewas a selective increase in the activity in the hippocampal-NAcpathway at the time when DA was released, while at the same time,inputs from the BLA were quiescent. It follows therefore thatthe inhibitory effects of DA on BLA-evoked spiking activity shouldbe reversed if BLA inputs were active at the time of DA release.Consistent with this hypothesis, coincidental tetanic stimulationof both the fimbria and the BLA [100 pulses for each input, alternatingbursts, 10 bursts at 10 pulses per burst (20 Hz), 500 msec interburstinterval] resulted in potentiation of both hippocampal and BLA-evokedspiking activity in the same neurons (n = 7) (Fig. 4C). We haveshown previously that tetanic stimulation of the BLA evoked anincrease in mesoaccumbens DA efflux (Floresco et al., 1998), anda separate study confirmed that the potentiation of BLA-evokedspiking activity after BLA tetanus was mediated by the D₁ receptor(Blaha et al., 1998).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The present data suggest that DA transmission in the NAc plays a critical role in an input selection mechanism that permitscertain inputs to have preferential, but temporary, influenceover neural activity in the NAc. Higher-frequency activity inthe glutamatergic hippocampal-NAc pathway can directly facilitatethe release of mesoaccumbens DA. This transient increase in NAcDA activity, which is time-locked to the tetanic depolarizationof NAc neurons, is sufficient to facilitate subsequent hippocampal-evokedneural activity of NAc neurons, whereas the subsequent increasein DA does not appear to play a role in this potentiation. Furthermore,the cooperative interaction between D₁ and NMDA receptors playsa key role in this potentiation. Blockade of either D₁ or NMDAreceptors reveals a D₂-mediated suppression of fimbria-evokedspiking activity. In addition, DA release facilitated by high-frequencyhippocampal inputs also exerts an activity-dependent inhibitionof BLA inputs converging on the same NAc neuron. This effect mayoccur via a presynaptic mechanism that involves a cooperativeinteraction between D₁ and adenosine A₁ receptors. Therefore,the modulation of mesoaccumbens DA release by hippocampal afferentsprovides an intrinsic activity-dependent coincidence detectionmechanism. The release of DA that occurs when this input pathwayis active serves two functions: the hippocampal input is amplified,whereas subsequent activity in BLA projections to the same neuronisinhibited.

Cellular mechanisms for the DA-mediated potentiation of hippocampal-NAc pathway

There are a number of potential cellular mechanisms by which D₁ receptor activation could facilitate hippocampal evoked-spikingactivity of NAc neurons. These include (1) inhibition of Na⁺/K⁺ATPase (Betrorello et al., 1990), (2) enhancement of L-type Ca²⁺ channels (Hernández-López et al., 1997; Cepeda and Levine,1998), or (3) direct augmentation of NMDA receptor activity viaphosphorylation of NMDA channels by protein kinase A and C-mediatedsecond messenger cascades (Blank et al., 1997; Cepeda and Levine,1998; Chergui and Lacey, 1999). Thus, activation of D₁ receptorsafter DA release, in combination with tetanic depolarization ofNAc neurons (both of which are achieved by stimulation of hippocampalafferents), could activate a number of different cellular mechanismsthat would lead to a longer lasting depolarization of these cells.Under these circumstances, medium spiny neurons are more responsiveto subsequent stimulation of glutamate inputs from the hippocampus,thereby increasing probability of cell firing (Fig. 5). Blockadeof NMDA receptors, either before or after tetanic stimulationof the fimbria, abolished the potentiation of hippocampal-evokedactivity, suggesting that the enhancement of NMDA receptor activityis involved critically in the induction and maintenance of thepotentiated neuronal excitability in NAc neurons.

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Figure 5. Diagram of hippocampal, BLA, and DA inputs, synapsing on separate dendrites of an individual medium spiny neuron in the NAc, illustrating the processes that may mediate the differential effects of DA D₁ receptor activity on NAc neuron firing. On the left spine, glutamatergic inputs from the hippocampus can activate both the postsynaptic NAc dendrite and facilitate the release of DA. DA activates postsynaptic D₁ receptors and can depolarize this dendrite by modulation of postsynaptic NMDA receptors. The net effect would be an enhancement of hippocampal-evoked activity. Stimulation of D₁ receptors can also lead to the formation of adenosine. On the right spine, adenosine, released from the postsynaptic NAc neuron, may act as a retrograde signal (Harvey and Lacey, 1997) to inhibit glutamate inputs from the BLA, which are inactive at the time of DA release, via A₁ receptors, putatively (?) located on presynaptic glutamate terminals originating from the BLA. The net effect would be a suppression of BLA-evoked activity. The size of the arrows represents the relative strength of the response evoked by each input after DA modulation of neural activity.

Our finding of a D₂-mediated suppression of evoked firing activity after blockade of either D₁ or NMDA receptors is particularlyintriguing. It suggests that under some conditions, D₁ and D₂receptors may act in an antagonistic manner, with D₁ receptorspromoting an increase in neural excitability and D₂ receptor activityproducing an inhibition of firing. Other studies have shown acooperative interaction between D₁ and D₂ receptors in the NAc(White and Wang, 1986; Hu and White, 1994). However, in thesestudies, DA agonists were applied iontophoretically to the NAcneurons, and coactivation of D₁ and D₂ receptors exerted synergisticsuppressive actions on glutamate-induced firing activity. It isapparent, therefore, that in addition to inhibiting the activityof NAc neurons via a cooperative interaction with D₂ receptors,D₁ receptors can also facilitate neural activity by a cooperativeinteraction with NMDA receptors, and this can work in an oppositemanner to the effects of D₂ receptor stimulation. Consistent withthe present findings, other studies have shown that the D₁ antagonistSCH23390 blocks long-term potentiation of neurons in the dorsalstriatum after high-frequency stimulation of corticostriatal fibers,whereas administration of the D₂ antagonist sulpiride enhancedthe potentiation (Calabresi et al., 2000). The competition betweenD₁ and D₂ receptors may be mediated through intracellular secondmessenger such as adenylyl cyclase systems or by modulation ofdifferent ionic conductances by D₁ and D₂ receptors (Surmeierand Kitai, 1993; Nestler, 1994; Cepeda and Levine, 1998).

Activity-dependent modulation by DA over BLA-evoked activity of NAc neurons

The present finding that DA release facilitated by high-frequency hippocampal inputs also exerts an activity-dependent suppressionof BLA inputs converging on the same NAc neuron is of particularrelevance to the issue of input selection. The fact that mesoaccumbensDA release enhances hippocampal-evoked activity of NAc neuronswhile simultaneously suppressing firing evoked by BLA stimulationsuggests that the inhibitory actions of D₁ receptors may occurvia a presynaptic mechanism (Yim and Mogenson, 1986; Mogensonet al., 1993). However, given the use of systemic administrationof antagonists in the present study, we cannot rule out the possibilitythat postsynaptic actions of DA may also play a role in this suppressionof BLA-evoked spiking activity. Nevertheless, the hypothesis thatDA inhibits BLA-evoked firing presynaptically is supported bya number of in vivo and in vitro studies demonstrating that DAor D₁ receptor agonists can inhibit glutamatergic inputs to theNAc originating from a number of limbic and cortical regions (Yangand Mogenson, 1984, 1986; Yim and Mogenson, 1986; Pennartz etal., 1991; Nicola et al., 1996; Harvey and Lacey, 1997; Nicolaand Malenka, 1997).

Although the above-mentioned studies have suggested that DA inhibits synaptic activity in the NAc via a D₁-receptor mediatedpresynaptic mode of action, anatomical evidence demonstratingthe existence of presynaptic D₁ receptors on glutamate terminalsin the NAc is lacking. Harvey and Lacey (1997) have reported thatthe presynaptic inhibition of glutamate inputs to NAc neuronsproduced by a D₁ agonist was abolished by coadministration ofthe adenosine A₁ receptor antagonist DPCPX. These authors concludedthat postsynaptic activation of D₁ receptors on medium spiny neuronsleads to the formation of adenosine, which acts as a retrogrademessenger to inhibit glutamate release presynaptically. A similarfinding was observed in the present study, in which the inhibitionof BLA-evoked spiking activity involved a cooperative interactionbetween D₁ and adenosine A₁ receptors (Fig. 5). Administrationof either SCH23390 or DPCPX blocked the suppression of BLA-evokedspikingactivity.

The finding that DA and adenosine-mediated suppression of BLA-evoked spiking activity was frequency- and activity-dependenthas important implications. When the release of DA (induced byfimbria tetanus) occurred while BLA inputs were inactive, subsequentBLA-evoked spiking activity of NAc neurons was reduced. However,when both hippocampal and BLA afferents were tetanized simultaneously,firing evoked by both afferents was potentiated. DeFrance et al.(1985) observed that ionotophoretic application of DA suppressedfimbria-evoked field potentials in the NAc when the fimbria wasstimulated at a lower frequency (1 Hz), but had no such effectat a higher stimulation frequency (6 Hz). Similarly, stimulationof the DA cell bodies in the VTA inhibited hippocampal-evokedsynaptic responses in the prefrontal cortex, but facilitated long-termpotentiation in this pathway when the VTA was stimulated coincidentallywith tetanic stimulation of the hippocampus (Gurden et al., 1999).Likewise, Wickens et al. (1996) reported that pulsatile applicationof DA in a corticostriatal slice, coincidental with tetanic stimulationof glutamatergic inputs, resulted in long-term potentiation ofcortically evoked activity, whereas prolonged bath applicationof DA combined with tetanus resulted in long-term depression.It is apparent, therefore, that key determinants of whether DAwill suppress or facilitate subsequent activity of NAc neuronsevoked by a specific limbic afferent are firing frequency of theparticular input and coincidental activation of D₁receptors.

Although the mechanism underlying frequency and activity-dependent modulation by DA and adenosine of glutamate inputs to theNAc is unclear, these effects may be attributable to the differentialeffects of DA (and possibly adenosine) on ionic conductances,as a function of the membrane potential at which the neuron isoperating at a given moment (Surmeier and Kitai, 1993; Hernández-Lópezet al., 1997). With respect to the present study, it is possiblethat the concomitant release of DA when BLA inputs were inactivemay have modulated voltage-gated ion channels located on presynapticglutamate terminals, thereby inhibiting glutamate release. However,when the terminals were active, the voltage-gated ion channelson these terminals would undergo configurational changes thatmay prevent the dopaminergic and adenosinergic modulation of theseionic conductances, offsetting the inhibitory effects of thesetransmitters on glutamate release. As already discussed, facilitationof DA release by high-frequency activity in either hippocampalor BLA afferents to the NAc (Blaha et al., 1997; Floresco et al.,1998) would provide an inherent mechanism to ensure that an increasein mesoaccumbens DA release occurs coincidentally with the glutamatergicactivation of the postsynaptic NAc neuron by a specific limbicafferent. It is interesting to note that a similar mechanism appearsto mediate synaptic plasticity in the hippocampal-prefrontal corticalpathway, whereby tetanic stimulation of the ventral subiculumresults in an increase in mesocortical DA efflux and D₁-receptordependent long-term potentiation of hippocampal afferents to theprefrontal cortex (Gurden et al., 2000).

Functional implications

The present finding that D₁ receptor activity can exert opposite effects on hippocampal and amygdalar inputs synapsing onthe same neuron in the NAc highlights the importance of the mesoaccumbensDA system in input selection. These data are consistent with contemporarytheory regarding the function of DA transmission in the basalganglia, which postulates that D₁ receptor activity serves tostrengthen the most salient inputs while at the same time inhibitingweaker inputs (Oades, 1985; Schultz, 1998; Nicola et al., 2000).The present findings also highlight the importance of the timingof DA release, coincidental to the arrival of higher-frequencyglutamatergic inputs to NAc neurons. DA can potentiate activeglutamatergic inputs while inhibiting those inputs that are inactivewhen D₁ receptor stimulation occurs. It is noteworthy that thefacilitatory effect of DA on the evoked activity of NAc neuronsis consistent with psychopharmacological data, which show thatenhanced mesoaccumbens DA transmission can exert a "gain-amplifyingeffect" on behaviors that are mediated by limbic-striatal circuits,thereby facilitating the influence that information processedby the hippocampus exerts over patterns of behavior mediated bythe ventral striatum (Robbins and Everitt, 1996; Floresco andPhillips, 1999). A combination of selective amplification andinhibition of separate limbic inputs synapsing on the same NAcneurons is also consistent with the hypothesis that the mesoaccumbensDA system plays an important role in response selection or behavioralswitching (Oades, 1985; Van de Bos et al., 1991; Pennartz et al.,1994; Salamone et al., 1997; Ikemoto and Panksepp, 1999; Redgraveet al., 1999). Redgrave et al. (1999) have proposed that DA "couldassist in preparing the animal to deal with the unexpected bypromoting the switching of attentional and behavioral resourcestoward biologically significant stimuli." Accordingly, activity-dependentmodulation by DA of limbic afferents to the ventral striatum mayrepresent a cellular mechanism for input selection that governsthe smooth coordination of behavior, by permitting informationprocessed by one cognitive system to have preferred access tothe motor systems via the NAc and thereby temporarily exert controlover the type and intensity of adaptive behavioralresponses.

  FOOTNOTES

Received Dec. 1, 2000; revised Jan. 22, 2001; accepted Jan. 24, 2001.

This work was supported by a grant from the Natural Science and Engineering Research Council of Canada to A.G.P. S.B.F. isa recipient of a Human Frontiers Science Organization postdoctoralfellowship. We thank Drs. J. K. Seamans, N. Gorelova, H. Moore,and A. West for helpful comments on thismanuscript.
Correspondence should be addressed to Dr. Stan B. Floresco, Department of Neuroscience, University of Pittsburgh, 446 CrawfordHall, Pittsburgh, PA 15260. E-mail: floresco{at}brain.bns.pitt.edu.

Dr. Floresco's present address: Department of Neuroscience, University of Pittsburgh, 446 Crawford Hall, Pittsburgh, PA15260.

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DISCUSSION
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