Selective Roles for Hippocampal, Prefrontal Cortical, and Ventral Striatal Circuits in Radial-Arm Maze Tasks With or Without a Delay

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Volume 17, Number 5, Issue of March 1, 1997 pp. 1880-1890
Copyright ©1997 Society for Neuroscience

Selective Roles for Hippocampal, Prefrontal Cortical, and Ventral Striatal Circuits in Radial-Arm Maze Tasks With or Without a Delay

Stan B. Floresco, Jeremy K. Seamans, and Anthony G. Phillips
Department of Psychology, University of British Columbia, Vancouver, British Columbia, Canada V6T 1Z4

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The hippocampus, the prefrontal cortex, and the ventral striatum form interconnected neural circuits that may underlie aspectsof spatial cognition and memory. In the present series of experiments,we investigated functional interactions between these areas inrats during the performance of delayed and nondelayed spatiallycued radial-arm maze tasks. The two-phase delayed task consistedof a training phase that provided rats with information aboutwhere food would be located on the maze 30 min later during atest phase. The single-phase nondelayed task was identical tothe test phase of the delayed task, but in the absence of a trainingphase rats lacked previous knowledge of the location of food onthe maze. Transient inactivation of the ventral CA1/subiculum(vSub) by a bilateral injection of lidocaine disrupted performanceon both tasks. Lidocaine injections into the vSub on one sideof the brain and the prefrontal cortex on the other transientlydisconnected these two brain regions and significantly impairedforaging during the delayed task but not the nondelayed task.Transient disconnections between the vSub and the nucleus accumbensproduced the opposite effect, disrupting foraging during the nondelayedtask but not during the delayed task. These data suggest thatserial transmission of information between the vSub and the prefrontalcortex is required when trial-unique, short-term memory is usedto guide prospective search behavior. In contrast, exploratorygoal-directed locomotion in a novel situation not requiring previouslyacquired information about the location of food is dependent onserial transmission between the hippocampus and the nucleus accumbens.These results indicate that different aspects of spatially mediatedbehavior are subserved by separate, distributed limbic-cortical-striatalnetworks.
Key words: ventral CA1/subiculum; prelimbic cortex; nucleus accumbens; spatial memory; neural networks; lidocaine-induced reversible lesions; rats

INTRODUCTION

The ability to locate and retrieve food efficiently is an essential survival strategy for rodents and other mammals, and theneural substrates of foraging behavior have been studied extensivelyusing radial-arm maze procedures pioneered by Olton and Samuelson(1976). Much of this work has focused on the role of the hippocampusin mediating foraging behavior using spatial cues (Olton and Papas,1979; Jarrard, 1993). However, recent data have emphasized a rolefor other neural structures, such as the prelimbic (PL) regionof the rat prefrontal cortex (PFC) and nucleus accumbens (N.Acc.)in spatially based foraging behaviors on a radial maze (Seamansand Phillips, 1994; Seamans et al., 1995). The ventral CA1/subiculum(vSub) region of the hippocampus projects to both the PL (Jayand Witter, 1991; Conde et al., 1995) and the medial N.Acc. (Groenewegenet al., 1987; Brog et al., 1993). In addition, the PL sends denseprojections to the N.Acc. (Groenewegen et al., 1987; Sesack etal., 1989). Using these pathways, spatial information essentialfor foraging behavior could be relayed from the hippocampus tothe N.Acc. and/or PFC to guide foraging behavior according tothe demands of specific radial-arm maze tasks.

The PL appears to play a selective role in a delayed choice but not a nondelayed version of the radial-arm maze task (Seamanset al., 1995). Delayed tasks such as this one (see Fig. 1A) biasrats to forage prospectively (Cook et al., 1985; Kesner, 1989),suggesting that the PL is involved in the planning of motor responsestrategies to ensure that food is located efficiently. Impairmentson delayed spatial tasks after lesions to either the PFC (Kesner,1989; Dunnett, 1990; Seamans et al., 1995) or the hippocampalformation (Kesner and DiMattia, 1987; Dunnett, 1990) suggest thatthese two brain regions may interact when an animal is foragingunder these conditions.
Fig. 1. Diagrams of the delayed spatial win-shift (SWSh) and the random foraging (RF) eight-arm radial-maze tasks. A, The delayedSWSh task consists of a training and a test phase. During thetraining phase, 4 of 8 arms on a radial maze are randomly blocked,and the 4 remaining open arms are baited. Once the animal hasretrieved the 4 pieces of food from the open arms, it is removedfrom the maze for a delay (ranging from 5 to 30 min). After thedelay, the animal is placed back onto the maze for the test phase.The arms that were blocked previously are now open and baited.The rat must remember which arms were previously blocked and enterthem to receive the food reward. B, The nondelayed RF task consistsof one phase. Four arms are randomly baited each day. The optimalforaging strategy entails entering the arms in a nonrepetitivemanner. Unlike the test phase of the delayed SWSh task, the animalhas no previous knowledge of the location of food at the beginningof a nondelayed RF trial.
[View Larger Version of this Image (23K GIF file)]

Unlike the PL, the N.Acc. is involved in both delayed spatial win-shift (SWSh) and nondelayed random foraging (RF; see Fig.1B) versions of radial-arm maze foraging tasks (Seamans and Phillips,1994), indicating a general role for the N.Acc. in goal-directedlocomotion (Kelley and Stinus, 1985; Mogenson et al., 1993). Innondelayed radial-arm maze tasks, both place- and movement-consistentfiring have been recorded from neurons in the N.Acc. (Lavioe andMizumori, 1994), resembling similar activity observed from vSubneurons (Barnes et al., 1990; Jung et al., 1994; Poucet et al.,1994). Moreover, lesions of either the N.Acc. or the vSub disruptperformance on single-trial foraging tasks (Jarrard, 1993; Seamansand Phillips, 1994). These findings are consistent with an importantrole for a vSub-N.Acc. circuit in situations in which the ratmust navigate in a spatial environment without the benefit ofprevious knowledge of the probable location of food. This processis distinct from those using a prospective strategy to guide foragingthat may be mediated by separate neural circuits involving thePFC-vSub or PFC-N.Acc.

The present study was designed to test the hypotheses that (1) foraging in a nondelayed condition is dependent on a directinteraction between the vSub and N.Acc., whereas (2) foragingguided by trial unique information stored in memory during a delayis mediated by a transcortical network connecting the hippocampusand the PL region of the PFC (Doyère et al., 1991; Jay and Witter,1991; Conde et al., 1995). An asymmetric disconnection procedurewas used to block the transmission of information within specificpathways in each hemisphere. Specifically, a unilateral lidocaine-inducedlesion of the origin of parallel efferent pathways in one hemispherewas used in combination with a contralateral lidocaine-inducedlesion in one of the target areas of the efferent projection inthe other hemisphere. This procedure has proven to be particularlyuseful in defining the route of serial information transfer betweendifferent brain regions in both rats (Everitt et al., 1991) andprimates (Gaffan and Harris, 1987; Gaffan et al., 1988, 1989).Two patterns of bilateral inactivation were used in the followingexperiments: unilateral reversible lesions of the vSub in combinationwith a contralateral lesion of either (1) the PL region of thePFC or (2) the N.Acc. Bilateral inactivations occurred beforethe test phase of the delayed SWSh task or before the nondelayedRF task.

Previous research in our laboratory has investigated the effects of bilateral inactivation of the PL (Seamans et al., 1995)and the N.Acc. (Seamans and Phillips, 1994) but not the vSub.The asymmetric disconnection procedure is based on the assumptionthat bilateral lesions of each of the target areas will producea specific behavioral deficit. Thus, an initial experiment assessedthe effect of bilateral reversible lesions of the vSub beforethe training or test phase of the delayed SWSh or before the RFtask. This experiment, in combination with the disconnection experimentsdescribed above, provides a detailed analysis of the role of thesecortico-limbic networks in spatially guided choice behavior inthe radial-arm maze.

Some of these findings were reported in abstract form at the Annual Meeting of the Society for Neuroscience, San Diego (1995).

MATERIALS AND METHODS
Subjects The subjects were male Long-Evans rats weighing between 300 and 450 gm before surgery. All rats were given free access towater and were maintained at 85% of their free-feeding weightby providing 25-30 gm of Purina lab chow pellets once daily. Ratswere tested 5-7 d per week.
Surgery Rats were anesthetized with 100 mg/kg ketamine hydrochloride and 7 mg/kg xylazine. Twenty-three gauge stainless-steel guidecannulae were implanted into the brain regions of interest usingstandard stereotaxic techniques. The stereotaxic coordinates (flatskull) were derived from Paxinos and Watson (1986). For the bilateralvSub inactivation experiments, one set of cannulae were implantedbilaterally into the vSub region of the hippocampus: AP, $-$ 6.0mm from bregma; ML, ±5.5 mm from midline; DV, $-$ 5.3 ± 0.3 mm fromdura. Rats in the disconnection experiments were implanted withtwo sets of bilateral cannulae, one pair into the vSub and a secondpair into either the PL region of the medial PFC (AP, +2.6 mm,ML, ±0.7 mm from bregma; DV, $-$ 3.0 mm from dura) or the medialshell region of the N.Acc. (AP, +1.6 mm from bregma, ±1.3 mm frommidline, $-$ 6.0 mm from dura). Thirty-gauge obdurators flush withthe end of the guide cannulae remained in place until the injectionswere made. Each rat was given at least 7 d to recover from surgerybefore testing.
Microinfusion procedure On injection days, the obdurators were removed and 30-gauge stainless-steel injection cannulae were inserted 0.8 mm beyondthe tip of the guide cannulae. Lidocaine (20 µg in 0.5 µl of saline,Astra Pharmaceuticals and Research Biochemicals) or vehicle injectionswere delivered at a rate of 0.5 µl/1.2 min by a microsyringe pump(Sage Instruments, Model 341). Injection cannulae were left inplace for an additional 1 min after each injection to allow fordiffusion. Each rat remained in its home cage for an additional3 min before being placed on the maze.

There are different estimates of the functional spread of lidocaine within the brain that appear to depend on the concentrationand rate of infusion. Using an infusion rate of 1 µl/min, Welshand Harvey (1991) estimated that the functional spread of 20 µgof lidocaine in 1 µl of saline is 1.4 mm in the cerebellum fromthe site of infusion. The functional spread of the same concentrationof lidocaine in the occulomotor nucleus was estimated to be 0.5mm with an infusion rate of 4 µl/15 min (Albert and Madryga, 1980).Furthermore, infusions of 20 µg of lidocaine in 1 µl of salineat a rate of 1 µl/2 min into either the PL or the anterior cingulatecortex of the rat, which are separated by 1.5 mm, produced distinctlydifferent patterns of impairment on a battery of radial-arm mazetasks (Seamans et al., 1995). These results are consistent withan effective functional spread of lidocaine being no greater than1.5 mm. Because half the volume (0.5 ul) was used the presentstudy, a functional spread of no greater than 1 mm would be expected.
Apparatus An eight-arm radial maze was used for all experiments. The maze had an octagonal center platform 40 cm in diameter connectedto eight, equally spaced arms, each measuring 50 cm × 9 cm, witha cylindrical food cup at the end (see Fig. 1). Removable piecesof white opaque plastic (9 cm × 13 cm) were used to block thearms of the maze. The maze was elevated 40 cm from the floor andwas surrounded by numerous extra maze cues (i.e., cupboards, posters,doors, the experimenter, etc.) in a room 4 m × 5 m × 3 m, whichwas illuminated with overhead fluorescent lights (100 W).
Foraging tasks The two foraging tasks used in the present study were the delayed SWSh task and the nondelayed RF task.

Delayed SWSh task. This task was adapted from Packard et al. (1990) and has been described in detail elsewhere (Seamans andPhillips, 1994; Seamans et al., 1995) (see Fig. 1A). On the first2 d of testing, rats were habituated to the maze environment.Subsequent training trials were given once daily. These trialsconsisted of a training phase and a test phase, separated by adelay. Before the training phase, a set of four arms was chosenrandomly and blocked. Food pellets (Bioserv, Frenchtown, NJ) wereplaced in the food cups of the four remaining open arms. Duringthe training phase, each rat was given 5 min to retrieve the pelletsfrom the four open arms and then was returned to its home cagefor the delay period (see below). During the test phase of eachdaily trial, all arms were open, but only the arms that were previouslyblocked contained food. Rats were allowed a maximum of 5 min toretrieve the four pellets during the test phase.

The initial delay between training and test phases was 5 min. After achieving criterion performance in which all four pelletswere retrieved in five or fewer choices during the test phasefor two consecutive days, the delay was increased to 30 min. Thefirst intracranial injections were administered after attainingtwo consecutive days of criterion performance at a 30 min delay.After the first injection day, animals were again retrained toa criterion performance. The next day, a second intracranial injectionwas administered. This procedure was repeated until an animalhad received all of the designated sequence of injections accordingto the protocols described below (see Design and Procedure).

On injection days, the number and order of arm entries were recorded. An arm entry was recorded when a rat moved down theentire length of an arm and reached the food cup at the end ofthe arm. Errors were scored as entries into nonbaited arms andfurther broken down into two error subtypes. An across-phase errorwas defined as any initial entry to an arm that had been enteredpreviously during the training phase. A within-phase error wasany reentry into an arm that had been entered earlier during thetest phase. The latencies to reach the food cup of the first armvisited and to complete the phase were also recorded.

Nondelayed RF task. This task has also been described elsewhere (Seamans and Phillips, 1994; Seamans et al., 1995) (see Fig.1B). Habituation to the maze during the first 2 d of trainingwas identical to the delayed SWSh procedure described above. Onsubsequent daily trials, animals were required to forage for pelletsplaced at random in the food cups of 4 of the 8 arms. A novelset of arms was baited each day. Animals were trained to a criterionof no more than one reentry error per daily trial for four consecutivedays. The day after criterion performance was achieved, the firstintracranial injections were administered. After the first injectionday, animals were retrained to criterion for two consecutive days.As with the delayed SWSh task, this procedure was repeated untileach animal had received all of the designated injections.

Errors were scored as reentries into arms entered previously within a trial. These errors were broken down further into reentriesinto baited arms (arms that had been baited at the start of thetrial) and reentries to nonbaited arms (arms that were not baitedbefore the start of the trial). The number of reentries errorsmade on each of the injection days was recorded and used for dataanalysis. As with the delayed SWSh paradigm, the latencies toreach the first food cup (either baited or nonbaited) after beingplaced on the maze and the time required to retrieve all fourpellets were also recorded.
Design and procedure Experiment 1: reversible, bilateral vSub lesions. A within-subjects design was used for all three parts of Experiment 1. Threegroups of rats with bilateral cannulae implanted into the vSubwere trained on either the delayed SWSh task or the RF task. Onthe first injection days, three separate groups of rats receivedbilateral infusions of either lidocaine or saline into the vSubbefore the nondelayed RF task (group 1), before the training phase(group 2), or before the test phase of the delayed SWSh (group3). Animals were subsequently retrained until they re-attainedcriterion performance. On the day after criterion was re-attained,a second infusion of either saline or lidocaine was administeredin a counterbalanced order.

Experiment 2: disconnection lesions between the vSub and the PL or the N.Acc. A within-subjects design was used for all fourparts of Experiment 2. Two groups of rats were implanted bilaterallywith two sets of cannulae into both the vSub and the PL. Afterrecovery from surgery, they were trained on either the delayedSWSh task or the nondelayed RF task. Two other groups of animalswith cannulae implanted bilaterally into the vSub and the N.Acc.also were trained on either task.

Animals in each of the disconnection lesion experiments received a total of four injection days, either before the test phaseof the delayed SWSh task or before the nondelayed RF task. Thefollowing combinations of asymmetrical bilateral inactivationswere used: (1) a unilateral inactivation of the vSub in combinationwith a contralateral inactivation of either the PL or the N.Acc.(disconnection); (2) a unilateral inactivation of the vSub incombination with a saline injection into the contralateral PLor N.Acc.; (3) a unilateral inactivation of the PL or N.Acc. incombination with a saline injection into the contralateral vSub;and (4) unilateral injections of saline into the vSub and salineinjections into either the contralateral PL or the N.Acc. Theorder of injections was counterbalanced between animals usinga quasi-Latin square design. The counterbalancing was designedto ensure that a given sequence of injections was not repeated.The hemisphere (left or right) used for the first injection wasalso counterbalanced and was alternated for subsequent injections.Each animal was tested separately on the same foraging task, andthe injection procedure was repeated until the animal had beentested four times with each sequence of intracranial injections.
Histology After completion of behavioral testing, the rats were killed in a carbon dioxide chamber. Brains were removed and fixed ina 10% formalin solution. The brains were frozen and sliced in50 µm sections before being mounted and stained with cresyl violet.Placements were verified with reference to the neuroanatomicalfindings of Jay and Witter (1991), Brog et al. (1992), Conde etal. (1995), Groenewegen et al. (1987), and Paxinos and Watson(1986).
Data analysis The number and type of errors made on the day before the first injection sequence and for all injection days for each experimentwere analyzed using separate three-way, between/within, mixeddesign ANOVAs with the Injection order (lidocaine or saline first)as a between-subjects factor, and Treatment day and Error typeas two within-subjects factors. Main effects of treatment wereanalyzed further using Tukey's post hoc tests for repeated measures.Whenever a significant main effect of treatment was observed,one planned comparison was made, analyzing the number of eachtype of error made on lidocaine injection days.

The latency data to reach the first food cup and the average time per subsequent choice on injection days were analyzed witha one-way repeated-measures ANOVA. The average time per subsequentchoice was calculated using the following formula: [(Time to completetrial $-$ Time to initiate trial)/(Number of choices for trial)].

Whenever a significant main effect of treatment was observed in Experiment 2, three one-way ANOVAs were conducted, assessingthe number of errors made on tests after a unilateral inactivationof the vSub, PL, or N.Acc., as well as after disconnection inactivations,with the side of the injection as a between-subjects factor. Thisanalysis was conducted to rule out the possibility that unilateralinactivations in one hemisphere would lead to a greater increasein errors than inactivations of the other hemisphere.

RESULTS

Experiment 1: reversible, bilateral vSub lesions
Histology The location of the cannulae tips for all animals tested in Experiment 1 are shown in Figure 2. Some placements encroachedslightly on the CA3/CA1-dentate gyrus border, but the behaviorof these animals did not differ from those in which placementswere located within the vSub region.
Fig. 2. Histology from the bilateral vSub inactivation experiments. Location of cannulae tips (black circles) for all rats used fordata analysis in Experiment 1. Plates are computer-generated adaptationsfrom Swanson (1992) that were modified to resemble those fromPaxinos and Watson (1986). Numbers beside each slide correspondto millimeters from bregma.
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Nondelayed RF Before a daily trial of the nondelayed RF task, eight rats received bilateral infusions of lidocaine or saline into the vSub,on separate days. The analysis of these data revealed a significantmain effect of Treatment (F_(2,12) = 21.89, p < 0.001). Tukey'spost hoc analysis showed that rats made significantly more errorson lidocaine injection days relative to saline injection daysor to the day before the first injection (p < 0.001; Fig. 3A).Subsequent analysis of the type of errors made on injection daysrevealed that animals receiving lidocaine infusions showed noperseverative tendencies and made the same number of revisitsto both baited and nonbaited arms (F_(1,7) = 0.04, not significant;see Fig. 3A, inset). There were no significant effects of Orderof injection or Order × Treatment interactions (all F < 1.2, notsignificant). There also were no significant differences in thelatencies to reach the first food cup or on the average time persubsequent choice for all three injection days (all F < 2.2, notsignificant).
Fig. 3. The effects of bilateral inactivation of the vSub on performance of delayed and nondelayed radial-arm maze tasks. A, Numberof errors (mean ± SEM) made by rats on the day before the firstinjection (open bar) and after infusions of saline (hatched bar)and lidocaine (black bar) into the vSub before the nondelayedrandom foraging task. **p < 0.001 relative to saline and day previous.Inset shows number of revisits to baited arms and nonbaited armson saline (hatched bar) and lidocaine (black bar) injection days.B, Number of errors (mean ± SEM) made by rats during the testphase on the day before the first injection (open bar) and afterinfusions of saline (hatched bar) and lidocaine (black bar) intothe vSub before the training phase of the delayed spatial win-shifttask. Inset shows number of errors made during the training phaseon the day before the first injection (open bar) and on saline(hatched bar) and lidocaine (black bar) injection days. C, Numberof errors (mean ± SEM) made by rats during the test phase on theday before the first injection (open bar) and after infusionsof saline (hatched bar) and lidocaine (black bar) into the vSubbefore the test phase of the delayed spatial win-shift task. **p< 0.001 relative to saline and day previous. Inset shows numberof across-phase errors (cross-hatched bar) and within-phase errors(stripped bar) made by rats on lidocaine injection days. **p <0.01.
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Delayed SWSh, pretraining injections Before the training phase of the delayed SWSh task, eight animals received bilateral infusions of lidocaine or saline intothe vSub on separate days. There were no significant differencesin the number of errors made on either the training phase (F_(2,12)= 0.33, not significant; see Fig. 3B, inset) or the test phase(F_(2,12) = 2.45, not significant; see Fig. 3B) on the day beforethe first injection and on saline or lidocaine injection days.There were also no significant effects of Injection Order or Order× Treatment interactions (all F < 2.0, not significant). In addition,there were no significant differences in latencies to reach thefirst food cup or in the average time per subsequent choice ofarms on both the test and training phases (all F < 1.3, not significant).
Delayed SWSh, pretest injections Before the test phase of the delayed SWSh task, nine rats received bilateral infusions of lidocaine or saline into the vSubon separate days. Analyses of the number of errors made on theday before the first injection and on saline and lidocaine injectiondays revealed a significant main effect of Treatment (F_(2,14)= 25.05, p < 0.001; see Fig. 3C). Tukey's post hoc analysis forrepeated measures showed that animals made significantly moreerrors on lidocaine injection days relative to both the day beforethe first injection and the saline injection days (p < 0.001).Subsequent planned comparisons on the type of errors made on lidocaineinjection days revealed that rats made significantly more across-phaseerrors than within-phase errors (p < 0.01; see Fig. 3C, inset).There were no significant effects of Injection Order or Treatment× Order interactions (all F < 1, not significant). Likewise, therewere no significant differences between injection days on thelatencies to reach the first food cup or on the average time persubsequent choice (all F < 1.7, not significant).
Discussion Bilateral inactivation of the vSub disrupts performance on both the delayed and the nondelayed radial-arm maze tasks. Thisis consistent with a role for this region of the hippocampus inspatial memory. In a recent experiment, similar reversible lesionsof the vSub in naive rats disrupted the acquisition of an escaperesponse guided by spatial information in a Morris water maze(Floresco et al., 1996). This effect is attributed to a temporaryblockade of access to information encoding the location of theescape platform, because rats were able to escape as efficientlyas controls after the effect of lidocaine had dissipated. Thesedata along with those of Poucet et al. (1991) support the theorythat the ventral hippocampus is involved in the short-term processingof spatial information, but not its storage over a delay. Thesedata, in addition to the present set of experiments, are consistentwith an extensive series of behavioral and electrophysiologicalstudies implicating both the dorsal and ventral hippocampus inthe formation of cognitive maps (O'Keefe and Nadel, 1978; Barneset al., 1990; Morris et al., 1991; Jung et al., 1994; Sharp andGreen, 1994). Disruption of spatially mediated foraging behaviorby lidocaine injections into vSub, during both the delayed andthe nondelayed tests, may be attributed to the blockade of transferof spatial information, processed initially by the hippocampalformation, to forebrain structures required for subsequent processingand motor integration. This hypothesis was tested directly inExperiment 2 (see below).

In addition to the disruption of spatial information processing, hippocampal lesions also are associated with response perseveration(Devenport et al., 1981; Issacson, 1982; Packard et al., 1989).Superficially, the preponderance of "across-phase" errors duringthe test phase of the delayed SWSh task, after bilateral vSubinactivations, could be interpreted as a disruption of behavioralflexibility (i.e., predominately reentering arms that had beenbaited previously during the training phase). However, if behavioralinflexibility is a consistent effect of ventral hippocampal lesions,it follows that errors in the nondelayed RF task should consistprimarily of reentries into previously baited arms. This patternwas not observed because baited and nonbaited arms were revisitedwith equal frequency in this latter task. Rather, the patternof errors observed after pretest inactivation of the vSub in thedelayed SWSh task may be better explained as a temporally gradedspatial memory deficit (i.e., a greater disruption of memory forlocations visited 30 min before the test phase vs arms visitedmore recently during the test phase). This interpretation is consistentwith the finding that rats with fornix lesions demonstrated delay-dependentimpairments on a delayed-matching-to-position paradigm (Dunnett,1990).

Experiment 2: disconnection lesions between the vSub and the PL or the N.Acc.
PL-vSub disconnections Nondelayed RF. Rats (n = 8) with two sets of bilateral cannulae implanted into the PL, and the vSub received the injectionprotocol described above before the nondelayed RF task on fourseparate days. Statistical analysis on the performance of theserats revealed no main effect of Treatment (F_(4,16) = 0.67, notsignificant; see Fig. 4A). Similarly, there were no main effectsof Injection Order, Error type, or any significant interaction(all F < 1.2, not significant). A separate analysis confirmedthat there were no significant differences between treatment conditionsin the latency to reach the first food cup or on the average timeper subsequent choice (all F < 1.1, not significant).
Fig. 4. The effects of PL-vSub disconnections on performance of a radial-arm maze test battery. A, Nondelayed random foraging. Numberof errors (mean ± SEM) made by rats on the day before the firstinjection (open bar), after unilateral infusions of saline intoboth the PL and the vSub (hatched bar), unilateral infusions oflidocaine (Lido) into the PL and contralateral saline in the vSub(gray bar), unilateral infusions of Lido into the vSub and contralateralsaline into the PL (stripped bar), and unilateral Lido into thevSub and contralateral Lido into the PL (disconnection; blackbar) before the nondelayed RF task. B, Delayed spatial win-shift.Number of errors (mean ± SEM) made by rats on the day before thefirst injection (open bar), after unilateral infusions of salineinto both the PL and the vSub (hatched bar), unilateral infusionsof lidocaine (Lido) into the PL and contralateral saline in thevSub (gray bar), unilateral infusions of Lido into the vSub andcontralateral saline into the PL (stripped bar), and unilateralLido into the vSub and contralateral Lido into the PL (disconnection;black bar) before the test phase of the delayed SWSh task. **p< 0.001 versus all other treatment conditions. Inset shows numberof across-phase (cross-hatched bar) versus within-phase (horizontal-strippedbar) errors made by rats during Lido/Lido (disconnection) injectiondays. C, Location of cannulae tips (black circles) for all ratsused for data analysis receiving PL-vSub disconnections beforeeither the nondelayed RF task or the delayed SWSh task. Platesare computer-generated adaptations from Swanson (1992) that weremodified to resemble those from Paxinos and Watson (1986). Numbersbeside each plate correspond to millimeters from bregma. For clarity,C represents the location of cannulae tips on sides that receivedinfusions on disconnection injection days. All animals receivedinfusions of either lidocaine or saline in each hemisphere.
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Delayed SWSh. A separate group of rats (n = 7) with two sets of bilateral cannulae implanted into the PL, and the vSub receivedthe injection protocol described above before the test phase ofthe delayed SWSh task on four occasions. The analysis revealeda highly significant main effect of Treatment (F_(4,12) = 10.99,p < 0.001). Tukey's post hoc analysis for repeated measures revealedthat rats made significantly more errors on the injection daysin which the PL and the vSub were disconnected versus all otherinjection days (p < 0.001; see Fig. 4B). There were no other significantdifferences in the number of errors made on any of the other injectiondays. Subsequent planned comparisons on the type of errors madeafter PL-vSub disconnections showed no significant differencesin the number of across- versus within-phase errors (F_(1,6) =0.517, not significant; see Fig. 4B, inset). Furthermore, therewere no significant effects of Injection Order, Error type, orany significant interactions (all F < 2.1, not significant). Aseparate series of tests was conducted to assess any hemisphericbiases on the number of errors made after unilateral vSub inactivations,unilateral PL inactivations, and disconnection lesions. This analysisrevealed no significant effects of the side of injection on thenumber of errors made by rats on the three injection days (allF < 1.0, not significant).

Analysis of the latency data revealed no significant differences in the latency to reach the first food cup across all injectiondays (F_(4,24) = 0.098, not significant). In contrast, analysisof the average time per subsequent arm choice did show a significanteffect of Treatment (F_(4,24) = 3.76, p < 0.05). Tukey's post hoctest for repeated measures revealed that animals took significantlylonger (p < 0.05) on average for each choice (M = 38.1 sec) aftersaline injections into both the PL and the vSub versus latencieson unilateral PL inactivation injection days (M = 23.3 sec) orthe day before the first injection (M = 17.3 sec). Given thatanimals receiving saline treatments in all other experiments ofthe present study did not differ in this latency measure whencompared to the day before the first injection, or to latencieson lidocaine injection days, it appears that increased responselatency after saline/saline treatments in the PL and the vSubis an anomalous finding.

Histology. The location of the cannulae tips for all animals receiving PL-vSub disconnections are represented in Figure 4C.Bilateral placements in the vSub were similar to those observedin Experiment 1. Similarly, bilateral placements in the PL werewithin the same region of the PFC as those observed by Seamanset al. (1995). Note that Figure 4C represents the asymmetric disconnectionlesions (see legend for details).
N.Acc.-vSub disconnections Nondelayed RF. One group of rats (n = 8) with two sets of bilateral cannulae implanted into the N.Acc. and the vSub receivedthe injection protocol described above four times before a dailytrial of the nondelayed RF task. Analysis of these data revealeda highly significant main effect of Treatment (F_(4,16) = 10.56,p < 0.001). Tukey's post hoc test for repeated measures revealedthat rats made significantly more errors after disconnection lesionsversus all other injection days (p < 0.001), and no other injectiondays differed significantly from each other (see Fig. 5A). Subsequentplanned comparisons of the type of errors made after bilateralsaline or disconnection lesions revealed that rats made an equalnumber of reentries into baited and nonbaited arms after eitherbilateral saline infusions or disconnection lesions (F_(1,7) =0.44, not significant; see Fig. 5A, inset). There were no maineffects of Injection Order, Error type, or any significant interactions(all F $<=$ 1.6, not significant). Similarly, there were no hemisphericbiases on the number of errors made after either unilateral vSubinactivations, unilateral N.Acc. inactivations or vSub/N.Acc.disconnections (all F < 3.0, not significant). In addition, therewere no significant differences among all treatment conditionson the latencies to reach the first food cup or on the averagetime per subsequent choice (all F < 2.2, not significant).
Fig. 5. The effects of N.Acc.-vSub disconnections on performance of a radial-arm maze test battery. A, Nondelayed random foraging.Number of errors (mean ± SEM) made by rats on the day before thefirst injection (open bar), after unilateral infusions of salineinto both the N.Acc. and the vSub (hatched bar), unilateral infusionsof lidocaine (Lido) into the N.Acc. and contralateral saline inthe vSub (gray bar), unilateral infusions of Lido into the vSuband contralateral saline into the N.Acc. (stripped bar), and unilateralLido into the vSub and contralateral Lido into the N.Acc. (disconnection;black bar) before the nondelayed RF task. **p < 0.001 versus allother treatment conditions. Inset shows number of reentries tobaited arms and nonbaited arms on saline/saline (hatched bar)and Lido/Lido disconnection (black bar) injection days. B, Delayedspatial win-shift. Number of errors (mean ± SEM) made by ratson the day before the first injection (open bar), after unilateralinfusions of saline into both the N.Acc. and the vSub (hatchedbar), unilateral infusions of lidocaine (Lido) into the N.Acc.and contralateral saline in the vSub (gray bar), unilateral infusionsof Lido into the vSub and contralateral saline into the N.Acc.(stripped bar), and unilateral Lido into the vSub and contralateralLido into the N.Acc. (disconnection; black bar) before the delayedSWSh task. C, Location of cannulae tips (black circles) for allrats used for data analysis receiving N.Acc.-vSub disconnectionsbefore either the nondelayed RF task or the delayed SWSh task.Plates are computer-generated adaptations from Swanson (1992)that were modified to resemble those from Paxinos and Watson (1986).Numbers beside each plate correspond to millimeters from bregma.For clarity, C represents the location of cannulae tips on sidesthat received infusions on disconnection injection days. All animalsreceived infusions of either lidocaine or saline in each hemisphere.
[View Larger Version of this Image (39K GIF file)]

Delayed SWSh. A separate group of rats (n = 9) with two sets of bilateral cannulae implanted into the N.Acc. and the vSubreceived the injection protocol described above on four occasionsbefore the test phase of the delayed SWSh task. Analysis of thesedata revealed no significant main effect of Treatment (F_(4,20)= 0.82, not significant; see Fig. 5B). There was a significantmain effect of Error type (F_(1,5) = 15.05, p < 0.05), indicatingthat animals made significantly more across-phase errors thanwithin-phase errors during all treatment conditions. There wereno significant main effects of Injection order or any significantinteractions (all F < 1.0, not significant). Similarly, therewere no significant differences among treatment conditions inthe latencies to reach the first food cup or on the average timeper subsequent choice (all F < 1.7, not significant).

Histology. The location of the cannulae tips for all animals receiving N.Acc.-vSub disconnections is represented in Figure5C. Bilateral placements in the vSub were similar to those observedin Experiment 1. Similarly, bilateral placements in the N.Acc.were within the same regions of the ventral striatum as thoseobserved by Seamans and Phillips (1994). Note that Figure 5C representsthe asymmetric disconnection lesions (see legend for details).

DISCUSSION
The present results reveal that the vSub region of the hippocampus and the PL region of the PFC are part of a neural circuitthrough which spatial information acquired before a delay is usedsubsequently to locate food on a radial-arm maze. In contrast,foraging in the absence of information obtained before a delayappears to depend on a direct interaction between the hippocampusand the N.Acc., and there does not appear to be a role for thePFC. As may be expected, bilateral reversible lesions in the vSubdisrupt foraging with or without a delay, whereas unilateral inactivationhas no effect.

A detailed consideration of the different foraging strategies used by rats in the delayed versus nondelayed foraging tasksmay explain the differences in the effects of vSub/PL as comparedto vSub/N.Acc. disconnections. On the surface, it may appear thatthe delayed SWSh and the nondelayed RF tasks only differ in termsof the duration of the memory requirement. However, a key distinctionbetween these tasks is that rats can predict the location of foodon the maze at the start of the test phase of the delayed task,whereas no previous information about the location of food isavailable before a daily nondelayed RF trial. Previous studiessuggest that insertion of a delay while rats are searching forfood on a radial-arm maze biases rats to forage prospectively(Cook et al., 1985), because they can use information acquiredbefore the delay to predict the probable location of food on themaze (Cook et al., 1985) (S. Floresco and A. Phillips, unpublishedobservations). In this way, the rat approaches arms that are anticipatedto contain food. Conversely, continuous foraging behavior in theabsence of previous information about the location of food biasesan animal to forage retrospectively (Roberts and Smythe, 1979;Cook et al., 1985) (S. Floresco and A. Phillips, unpublished observations).On the nondelayed RF task, rats must first make choices randomlyuntil they gain knowledge about arms that do or do not containfood. As the trial continues, rats can actively avoid arms enteredpreviously. Given these distinctions between prospective and retrospectivecoding on a radial maze, it may be conjectured that a hippocampal-PFCcircuit subserves prospective response strategies, whereas a directconnection between the hippocampus and the N.Acc. is involvedin retrospective foraging in the absence of previous informationabout the location of food.

Interactions between the vSub and the PL region of prefrontal cortex in delayed foraging
The logic underlying the use of disconnection lesions to identify components of a functional neural circuit is based on theassumption that information is transferred serially from one structureto an efferent region, on both sides of the brain in parallel.Furthermore, the design assumes that dysfunction will result fromblockade of neural activity at the origin of a pathway in onehemisphere and the termination of the efferent pathway in thecontralateral hemisphere. It follows that a unilateral inactivationat either site should have no effect on behavior. Using the presentstudy as an example, if successful performance on a task is dependenton a serial connection linking the hippocampus to the PFC, thena unilateral lesion of the vSub would prevent the PFC in the ipsilateralhemisphere from gaining access to information needed to solvethe task. In the other hemisphere, information would be relayedfrom the intact vSub; however, it would go to a dysfunctionalPFC. Thus, after this asymmetric disconnection, the PFC on bothsides of the brain would be deprived of information essentialto form an efficient foraging strategy. The use of different behavioraltasks permits further refinement in specifying the function ofthe neural circuit in question. In the present study, reversibledisconnection lesions produced by lidocaine infusion into theunilateral vSub and contralateral PL produced a selective andsignificant disruption of foraging only during the test phaseof the delayed SWSh task, indicating that afferents arising fromthe vSub and terminating in the PL are essential for performanceof this task (Fig. 6B). In contrast, similar disconnections hadno effect on foraging in the nondelayed RF task, in which theanimal had no previous information about the location of food,suggesting that foraging behavior based on a "retrospective" strategyis not dependent on information from the hippocampus reachingthe PL (Fig. 6C).
Fig. 6. Diagram of the anatomical connections investigated in the present study between the vSub, the PL, and the N.Acc. × representsthe location of the unilateral inactivations to the vSub and PLor N.Acc. for each task. Solid arrows represent intact pathways.Open arrows represent pathways that are not blocked but do notcarry the relevant spatial information because of a concomitantlidocaine-induced lesion upstream of this pathway. T-symbols representblocked, nonfunctional pathways. A, An overview of the ipsi- andcontralateral connections between the three brain regions. Notethe unilateral projections from vSub to the forebrain and thecontralateral projections between the PL and its connections tothe N.Acc. B, Proposed route of information transfer between thevSub and PL during the delayed SWSh task. By disconnecting thePL-vSub pathway, information cannot be processed by the PL togenerate appropriate responses after a delay, thereby disruptingappropriate output (impairment). C, Proposed route of informationtransfer between the vSub and the PL during the nondelayed RFtask. By disconnecting the PL-vSub pathway, information is stillable to access the N.Acc., thereby allowing for appropriate output(no impairment). D, Proposed route of information transfer betweenthe vSub and N.Acc. during the nondelayed RF task. Disconnectionof the N.Acc.-vSub pathway prevents the flow of information fromthe vSub through the N.Acc. to motor output centers (impairment).E, Proposed route of information transfer between the vSub andN.Acc. during the delayed SWSh task. Information from the vSubmay be routed primarily through the PL and subsequently to theN.Acc. Thus, even though the pathway from the vSub to the N.Acc.is disconnected, spatial information may still be transferredfrom the unanesthetized vSub to the ipsilateral PL and subsequentlyrouted to the contralateral N.Acc., allowing for appropriate output(no impairment).
[View Larger Version of this Image (34K GIF file)]

Reversible disconnection lesions between the vSub and the PL produced precisely the same pattern of results as those observedafter bilateral lidocaine infusions into the PL region of therat PFC (Seamans et al., 1995). On the basis of those results,it was suggested that the PL plays a role in the retrieval ofspatial information required to predict the probable locationof food during the test phase of the delayed SWSh task. Furthermore,it was conjectured that spatial information, stored in the temporallobe during the 30 min delay, may be accessed by the PL, whichorganizes the prospective sequence of motor responses necessaryfor efficient foraging behavior. The present results with thevSub-PL disconnection lesions further substantiate this hypothesis.As such, these data also provide direct support for theories suggestingthat the neural circuit linking the hippocampus and PFC providesan essential pathway by which spatial information can be integratedinto the cognitive and motor planning processes mediated by thePFC (Goldman-Rakic, 1987; Fuster, 1991; Doyère et al., 1993).These findings are also consistent with other theories implicatingthe rat PFC by itself, or its interactions with the hippocampus,in the mediation of planning (Kesner and DiMattia, 1987; Granonand Poucet, 1995).

One point that deserves further consideration is the finding that rats made a significant number of within-phase errors afterPL/vSub disconnections on the delayed task (Fig. 5B, inset), whereassimilar lesions did not cause a significant increase in reentryerrors on the nondelayed task (Fig. 5A). It must be noted thata comparable number of across-phase errors was also recorded onthe delayed tasks. This pattern of results was also observed afterbilateral inactivations of the PL (Seamans et al., 1995) and highlightsthe differences between the delayed and nondelayed tasks. It isimportant to emphasize that a comparable number of within- andacross-phase errors on the delayed task, coupled with few reentryerrors on the nondelayed task, is indicative of a failure to executea prospective foraging strategy, not an inability to rememberrecent arm choices during a trial. Therefore, these data againare consistent with the hypothesis that circuits linking the PLand vSub are involved in the execution of a prospective foragingstrategy rather than the retention of information over a delay.Inactivations of the PL bilaterally, or disconnections of thevSub and PL, may have caused both across- and within-phase errorson the delayed task because they severely disrupted the executionof the prospective foraging strategy, which is required to solvethe task.

The present study differed from most other delayed-response tasks that have been used to assess the role of the PFC in short-termmemory processes in the use of a longer, 30 min delay interval,compared to <60 sec used in previous studies. Electrophysiologicalstudies have shown that information relating to the spatial locationof a stimulus over a short delay is encoded in the electricalactivity of subsets of neurons in the dorsolateral PFC (Goldman-Rakic,1990). This activity is thought to provide a neural substratefor the short-term retention of information required for the generationof a subsequent motor response and can be disrupted by reversibleinactivations of the temporal cortex (Fuster et al., 1985). Previousdata indicate that spatial information, such as that obtainedin the delayed SWSh task, is not stored in the PFC but, rather,is accessed by the PFC at a time when prospective planning isdependent on recently acquired spatial information (Seamans etal., 1995). This dependence on a cortical network that spans severalcortical areas is consistent with Fuster's (1995) conceptual frameworkof a distributed memory system in which memories are "content-addressed"by many associated elements and may be activated by one aspectof this configuration (i.e., spatial location). Once activated,the specific memory can be maintained by neural activity in localand transcortical reentrant circuits. The present data supportthe idea that reciprocal connections between the vSub-PFC-temporallobe via multisynaptic connections through the entorhinal cortex(Amaral and Witter, 1994) could provide a distributed neural networkinvolving the frontal and temporal cortices, underlying the retrievaland use of trial-unique spatial information over extended delays.

A role for the hippocampal-ventral striatal pathway in spatially mediated foraging behavior
Disconnections between the vSub and the N.Acc. disrupted foraging behavior in rats during the nondelayed RF task. These datasupport the hypothesis that inputs from the vSub to the N.Acc.are involved in the initiation and guidance of exploratory locomotion(Mogenson et al., 1993). Chemical stimulation of the vSub resultsin an increase in exploratory behavior in an open field, whichis attenuated after pharmacological manipulations within the N.Acc.(Yang and Mogenson, 1987). The present data expand on Mogenson'sinitial hypothesis by suggesting that the hippocampal-N.Acc. pathwayalso is involved in goal-directed food searching behavior in acomplex, spatially cued environment when an animal initially hasno previous information about the location of food. This conjectureregarding hippocampal-ventral striatal interactions is supportedfurther by the observation that N.Acc. neurons recorded in ratsforaging on a radial-arm maze demonstrate place- and movement-correlatedactivity (Lavoie and Mizumori, 1994), as do cells in the vSub(Barnes et al., 1990; Jung et al., 1994; Poucet et al., 1994).Moreover, the fact that disconnections between the PL and thevSub did not disrupt foraging behavior on the nondelayed RF taskstrongly suggests that, when rats do not have previous informationabout the location of food, the direct transfer of spatial informationfrom the vSub to the N.Acc. is used to control efficient foragingbehavior. Accordingly, a unilateral inactivation of the vSub coulddeprive the N.Acc. in one hemisphere of essential spatial information,whereas direct inactivation of the contralateral N.Acc. blocksthe integration of this information into accurate goal-directedresponses, thereby leading to random responding and impaired foragingbehavior (Fig. 6D).

Disconnections between the N.Acc. and the vSub before the test phase of the delayed SWSh did not disrupt foraging behavior,suggesting that direct inputs from the hippocampus to the N.Acc.are not essential for efficient performance on this delayed responsetask. This result may seem paradoxical, considering that bilateralinactivation of either the vSub (present study) or the N.Acc.(Seamans and Phillips, 1994) severely disrupted test phase performanceon this task. However, given that an intact PL is also crucialfor efficient delayed SWSh behavior (Seamans et al., 1995), itappears that efferents from the PL to the N.Acc. play a criticalrole when foraging is guided by previous knowledge of the probablelocation of food in the test environment. Moreover, the presentdata demonstrate that inputs from the vSub to the PL are alsoessential for delayed SWSh performance. Given these results, itcan be inferred that after a vSub-N.Acc disconnection, unimpairedtransmission of information between the intact hippocampus andthe PFC would still occur, thereby enabling the relevant spatialinformation to be transferred serially first from the vSub tothe PL and then to the unanesthetized N.Acc. via either ipsilateralor contralateral cortico-striatal connections (Sesack et al.,1989; Brog et al., 1993; Conde et al., 1995) [see Fig. 6E (also6A)].

Conclusions
Goldman-Rakic has posited that "the hippocampus and PFC are functionally as well as anatomically related and, in general,that the PFC regulates behavior in collaboration with a largeset of other cortical and subcortical structures, which togetherconstitute the brain's machinery for spatial cognition" (Goldman-Rakic,1994, p. 352). The present series of experiments provides directconfirmation of this hypothesis by demonstrating that performanceof a delayed spatial task that requires an animal to use previouslyacquired trial-unique information is dependent on a network comprisingthe vSub and the PL. Furthermore, our data expand on this ideaby showing that exploratory goal-directed locomotion that is notdependent on previously acquired knowledge about the locationof food is subserved by a separate subcortical network linkingof the hippocampus to the ventral striatum. Finally, with respectto delayed spatial tasks, these results suggest that interactionsbetween the PFC and the ventral striatum are involved in the transformationof spatial memory, processed by hippocampal-cortical circuits,into an efficient sequence of goal-directed motor responses (Robbins,1990, 1991; Goldman-Rakic et al., 1992). Further investigationof this hypothesis is the subject of ongoing research in our laboratory.

FOOTNOTES

Received Oct. 10, 1996; revised Dec. 17, 1996; accepted Dec. 18, 1996.

This research was supported by a grant from the Natural Sciences and Engineering Research Council (NSERC) of Canada to A.G.P.S.B.F. is a recipient of an NSERC scholarship, and J.K.S. holdsa University of British Columbia Graduate Fellowship. We thankMs. Penny Lam and Mr. Tony Drew for their assistance with behavioraltesting, Dr. Charles D. Blaha and Mr. Jason Carr for helpful discussions,and Ms. Susanna K. Kovacs for editorial comments.

Correspondence should be addressed to Anthony G. Phillips, Department of Psychology, University of British Columbia, 2136West Mall, Vancouver, British Columbia, Canada V6T 1Z4.

REFERENCES

Albert DJ, Madryga FJ (1980) An examination of the functional spread of 4 µl of slowly infused lidocaine. Behav Neural Biol 29:378-384 . [Web of Science][Medline]
Amaral DG, Witter MP (1994) Hippocampal formation. In: The rat nervous system, 2nd Ed (Paxinos G, ed), pp 443-494. San Diego: Academic.
Barnes CA, McNaughton BL, Mizumori SJ, Leonard BW, Lin LH (1990) Comparison of spatial and temporal characteristics of neuronal activity in sequential stages of hippocampal processing. Prog Brain Res 83:287-300 . [Web of Science][Medline]
Brog JS, Salyapongse A, Deutch A, Zahm DS (1993) The pattern of afferent innervation of the core and shell in the "accumbens" part of the ventral striatum: immunohistochemical detection of retrogradely transported fluoro-gold. J Comp Neurol 338:255-278 . [Web of Science][Medline]
Conde F, Maire-Lepoivre E, Audinat E, Crepel F (1995) Afferent connections of the medial frontal cortex of the rat. II. Cortical and subcortical afferents. J Comp Neurol 325:567-593.
Cook RG, Brown RF, Riley DA (1985) Flexible memory processing by rats: use of prospective and retrospective information in the radial arm maze. Anim Behav Proc 11:453-469.
Devenport LD, Devenport JA, Halloway FA (1981) Reward-induced stereotypy: modulation by the hippocampus. Science 212:1288-1289 . [Abstract/Free Full Text]
Doyère V, Burette F, Negro CR, Laroche S (1993) Long-term potentiation of hippocampal afferents and efferents to prefrontal cortex: implications for associative learning. Neuropsychologia 31:1031-1053 . [Web of Science][Medline]
Dunnett SB (1990) Role of the prefrontal cortex and striatal output systems in short-term memory deficits associated with aging, basal forebrain lesions, and cholinergic-rich grafts. Can J Psychol 44:210-232 . [Web of Science][Medline]
Everitt BJ, Morris KA, O'Brien A, Burns L, Robbins TW (1991) The basolateral amygdala-ventral striatal systems and conditioned place preference: further evidence of limbic-striatal interactions underlying reward-related processes. Neuroscience 41:1-18. [Web of Science][Medline]
Floresco SB, Seamans JK, Phillips AG (1996) Differential effects of lidocaine infusions into the ventral CA1/subiculum or the nucleus accumbens on the acquisition and retention of spatial information. Behav Brain Res 81:163-172 . [Web of Science][Medline]
Fuster JM (1991) The prefrontal cortex and its relation to behavior. Prog Brain Res 87:201-211 . [Web of Science][Medline]
Fuster JM (1995) Memory and planning: two temporal perspectives of frontal lobe function. Adv Neurol 66:9-19 . [Medline]
Fuster JM, Bauer RH, Jervey JP (1985) Functional interactions between inferotemporal and prefrontal cortex in a cognitive task. Brain Res 330:299-307 . [Web of Science][Medline]
Gaffan D, Harrison S (1987) Amygdalectomy and disconnection in visual learning for auditory secondary reinforcement by monkeys. J Neurosci 7:2285-2292 . [Abstract]
Gaffan D, Gaffan EA, Harrison S (1988) Disconnection of the amygdala from visual association cortex impairs visual reward-association learning in monkeys. J Neurosci 8:3144-3150. [Abstract]
Gaffan D, Gaffan EA, Harrison S (1989) Visual-visual associative learning and reward-association learning in monkeys: the role of the amygdala. J Neurosci 9:558-564 . [Abstract]
Goldman-Rakic PS (1987) Circuitry of the prefrontal cortex and its regulation of behavior by representational knowledge. In: Handbook of physiology, Vol 5 (Mountcastle PF, ed), pp 373-417. Bethesda, MD: American Physiological Association.
Goldman-Rakic PS (1990) Cellular and circuit basis of working memory in prefrontal cortex of nonhuman primates. Prog Brain Res 85:325-335 . [Medline]
Goldman-Rakic PS (1994) Working memory dysfuntion in schizophrenia. J Neuropsychol Clin Neurosci 6:348-357 . [Abstract/Free Full Text]
Goldman-Rakic PS, Bates JF, Chafee MW (1992) The prefrontal cortex and internally generated motor acts. Curr Opin Neurobiol 2:803-835.
Granon S, Poucet B (1995) Medial prefrontal lesions in the rat and spatial navigation: evidence for impaired planning. Behav Neurosci 109:474-484 . [Web of Science][Medline]
Groenewegen HJ, Vermeulen-Van der Zee E, Te Kortschot A, Witter MP (1987) Organization of the projections from the subiculum to the ventral striatum in the rat: a study using anterograde transport of Phaseolus vulgarus leucoagglutinin. Neuroscience 23:103-120 . [Web of Science][Medline]
Isaacson RL (1982) The hippocampus. In: The limbic system, 2nd Ed. New York: Plenum.
Jarrard LE (1993) On the role of the hippocampus in learning and memory in the rat. Behav Neural Biol 60:9-26 . [Web of Science][Medline]
Jay TM, Witter MP (1991) Distribution of hippocampal CA1 and subicular efferents in the prefrontal cortex of the rat studied by means of anterograde transport of Phaseolus vulgaris leucoagglutinin. J Comp Neurol 313:574-586 . [Web of Science][Medline]
Jung MW, Wiener SI, McNaughton BL (1994) Comparison of spatial firing characteristics of units in dorsal and ventral hippocampus of the rat. J Neurosci 14:7347-7356 . [Abstract]
Kelley AE, Stinus L (1985) Disappearance of hoarding behavior after 6-hydroxydopamine lesions of the mesolimbic dopamine neurons and its reinstatement with L-dopa. Behav Neurosci 99:531-545 . [Web of Science][Medline]
Kesner RP (1989) Retrospective and prospective coding of information: role of the medial prefrontal cortex. Exp Brain Res 74:163-167 . [Web of Science][Medline]
Kesner RP, DiMattia BV (1987) Neurobiology of an attribute model of memory. In: Progress in psychobiology and physiological psychology (Morrison AR, Epstein AN, eds), pp 207-277. New York: Academic.
Lavoie AM, Mizumori SJ (1994) Spatial movement- and reward-sensitive discharge by medial ventral striatum neurons in rats. Brain Res 638:157-68 . [Web of Science][Medline]
Mogenson GJ, Brudzynski SM, Wu M, Yang CR, Yim CY (1993) From motivation to action: a review of dopaminergic regulation of limbic $right-arrow$ nucleus accumbens $right-arrow$ ventral pallidum $right-arrow$ pedunculopontine nucleus circuitries involved with limbic-motor integration. In: Limbic-motor circuits and neuropsychiatry (Kalivas PW, Barnes CD, eds), pp 193-263. Boca Raton, FL: CRC.
Morris RGM, Schenk F, Tweedie F, Jarrard LE (1991) Ibotenate lesions of the hippocampus and/or subiculum: dissociating components of allocentric spatial learning. Eur J Neurosci 2:1016-1028.
O'Keefe J, Nadel L (1978) In: The hippocampus as a cognitive map. Oxford: Oxford UP.
Olton DS, Papas BC (1979) Spatial memory and hippocampal function. Neuropsychologia 17:669-682 . [Web of Science][Medline]
Olton DS, Samuelson RJ (1976) Remembrance of places past: spatial memory in rats. Anim Behav Proc 2:97-116.
Packard MG, Hirsh R, White NM (1989) Differential effects of fornix and caudate nucleus lesions on two radial arm maze tasks: evidence for multiple memory systems. J Neurosci 9:465-1472.
Packard MG, Regenold W, Quirion R, White NM (1990) Post-training injection of the acetylcholine M2 receptor antagonist AF-DX 116 improves memory. Brain Res 524:72-76 . [Web of Science][Medline]
Paxinos G, Watson C (1986) In: The rat brain in stereotaxic coordinates, 2nd Ed. New York: Academic.
Poucet B, Herrmann T, Buhot MC (1991) Effects of short lasting inactivations of the ventral hippocampus and medial septum on long term and short term acquisition of spatial information in rats. Behav Brain Res 4:453-65.
Poucet B, Thinus-Blanc C, Muller RU (1994) Place cells in the ventral hippocampus of rats. NeuroReport 5:2045-2048 . [Web of Science][Medline]
Robbins TW (1990) The case for frontalstriatal dysfunction in schizophrenia. Schizophrenia Bull 16:391-402 .
Robbins TW (1991) Cognitive deficits in schizophrenia and Parkinson's disease: neural basis and the role of dopamine. In: The mesolimbic dopamine system: from motivation to action (Willner P, Scheel-Kruger J, eds), pp 497-528. New York: Wiley.
Roberts WA, Smythe WE (1979) Memory for list of spatial events in the rat. Learn Motiv 8:341-351.
Seamans JK, Phillips AG (1994) Selective memory impairments produced by transient lidocaine-induced lesions of the nucleus accumbens in rats. Behav Neurosci 108:456-468 . [Web of Science][Medline]
Seamans JK, Floresco SB, Phillips AG (1995) Functional differences between the prelimbic and anterior cingulate regions of rat prefrontal cortex. Behav Neurosci 109:1063-1073 . [Web of Science][Medline]
Sharp PE, Green C (1994) Spatial correlates of firing patterns of single cells in the subiculum of freely moving animals. J Neurosci 14:2239-2356.
Sesack SR, Deutch AY, Roth RH, Bunney BS (1989) Topographical organization of the efferent projections of the medial prefrontal cortex in the rat: an anterograde tract-tracing study with Phaseolus vulgaris leucoagglutinin. J Comp Neurol 290:213-242 . [Web of Science][Medline]
Swanson LW (1992) In: Structure of the rat brain. Amsterdam: Elsevier.
Welsh JP, Harvey JA (1991) Pavlovian conditioning in the rabbit during inactivation of the interpositus nucleus. J Physiol (Lond) 444:459-480 . [Abstract/Free Full Text]
Yang CR, Mogenson GJ (1987) Hippocampal signal transmission to the mesencephalic locomotor regions and its regulation by dopamine D-2 receptors in the nucleus accumbens: an electrophysiological and behavioral study. Neuroscience 23:1041-1055 . [Web of Science][Medline]

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A mutation in mouse Disc1 that models a schizophrenia risk allele leads to specific alterations in neuronal architecture and cognition
PNAS, May 13, 2008; 105(19): 7076 - 7081.
[Abstract] [Full Text] [PDF]

I. Lee and F. Solivan
The roles of the medial prefrontal cortex and hippocampus in a spatial paired-association task
Learn. Mem., May 5, 2008; 15(5): 357 - 367.
[Abstract] [Full Text] [PDF]

T. Yoon, J. Okada, M. W. Jung, and J. J. Kim
Prefrontal cortex and hippocampus subserve different components of working memory in rats
Learn. Mem., February 19, 2008; 15(3): 97 - 105.
[Abstract] [Full Text] [PDF]

Y. Zhou, E. Takahashi, W. Li, A. Halt, B. Wiltgen, D. Ehninger, G.-D. Li, J. W. Hell, M. B. Kennedy, and A. J. Silva
Interactions between the NR2B Receptor and CaMKII Modulate Synaptic Plasticity and Spatial Learning
J. Neurosci., December 12, 2007; 27(50): 13843 - 13853.
[Abstract] [Full Text] [PDF]

Y. S. Jo, E. H. Park, I. H. Kim, S. K. Park, H. Kim, H. T. Kim, and J.-S. Choi
The Medial Prefrontal Cortex Is Involved in Spatial Memory Retrieval under Partial-Cue Conditions
J. Neurosci., December 5, 2007; 27(49): 13567 - 13578.
[Abstract] [Full Text] [PDF]

A. E. Block, H. Dhanji, S. F. Thompson-Tardif, and S. B. Floresco
Thalamic-Prefrontal Cortical-Ventral Striatal Circuitry Mediates Dissociable Components of Strategy Set Shifting
Cereb Cortex, July 1, 2007; 17(7): 1625 - 1636.
[Abstract] [Full Text] [PDF]

M. D. Saxe, G. Malleret, S. Vronskaya, I. Mendez, A. D. Garcia, M. V. Sofroniew, E. R. Kandel, and R. Hen
Paradoxical influence of hippocampal neurogenesis on working memory
PNAS, March 13, 2007; 104(11): 4642 - 4646.
[Abstract] [Full Text] [PDF]

P. W. German and H. L. Fields
Rat Nucleus Accumbens Neurons Persistently Encode Locations Associated With Morphine Reward
J Neurophysiol, March 1, 2007; 97(3): 2094 - 2106.
[Abstract] [Full Text] [PDF]

S. B. Floresco and S. Ghods-Sharifi
Amygdala-Prefrontal Cortical Circuitry Regulates Effort-Based Decision Making
Cereb Cortex, February 1, 2007; 17(2): 251 - 260.
[Abstract] [Full Text] [PDF]

A. Ishikawa and S. Nakamura
Ventral Hippocampal Neurons Project Axons Simultaneously to the Medial Prefrontal Cortex and Amygdala in the Rat
J Neurophysiol, October 1, 2006; 96(4): 2134 - 2138.
[Abstract] [Full Text] [PDF]

L. Alvarez-Jaimes, M. Feliciano-Rivera, M. Centeno-Gonzalez, and C. S. Maldonado-Vlaar
Contributions of the Mitogen-Activated Protein Kinase and Protein Kinase C Cascades in Spatial Learning and Memory Mediated by the Nucleus Accumbens
J. Pharmacol. Exp. Ther., September 1, 2005; 314(3): 1144 - 1157.
[Abstract] [Full Text] [PDF]

T. Bast, B. M. da Silva, and R. G. M. Morris
Distinct Contributions of Hippocampal NMDA and AMPA Receptors to Encoding and Retrieval of One-Trial Place Memory
J. Neurosci., June 22, 2005; 25(25): 5845 - 5856.
[Abstract] [Full Text] [PDF]

K.R. Bailey and R.G. Mair
Dissociable Effects of Frontal Cortical Lesions on Measures of Visuospatial Attention and Spatial Working Memory in the Rat
Cereb Cortex, September 1, 2004; 14(9): 974 - 985.
[Abstract] [Full Text] [PDF]

D. K. Hannesson, J. G. Howland, and A. G. Phillips
Interaction between Perirhinal and Medial Prefrontal Cortex Is Required for Temporal Order But Not Recognition Memory for Objects in Rats
J. Neurosci., May 12, 2004; 24(19): 4596 - 4604.
[Abstract] [Full Text] [PDF]

C. Rocher, M. Spedding, C. Munoz, and T. M. Jay
Acute Stress-induced Changes in Hippocampal/Prefrontal Circuits in Rats: Effects of Antidepressants
Cereb Cortex, February 1, 2004; 14(2): 224 - 229.
[Abstract] [Full Text] [PDF]

A. G. Phillips, S. Ahn, and S. B. Floresco
Magnitude of Dopamine Release in Medial Prefrontal Cortex Predicts Accuracy of Memory on a Delayed Response Task
J. Neurosci., January 14, 2004; 24(2): 547 - 553.
[Abstract] [Full Text] [PDF]

A. Ishikawa and S. Nakamura
Convergence and Interaction of Hippocampal and Amygdalar Projections within the Prefrontal Cortex in the Rat
J. Neurosci., November 5, 2003; 23(31): 9987 - 9995.
[Abstract] [Full Text] [PDF]

S. Otani, H. Daniel, M.-P. Roisin, and F. Crepel
Dopaminergic Modulation of Long-term Synaptic Plasticity in Rat Prefrontal Neurons
Cereb Cortex, November 1, 2003; 13(11): 1251 - 1256.
[Abstract] [Full Text] [PDF]

M.-C. Buhot, M. Wolff, N. Benhassine, P. Costet, R. Hen, and L. Segu
Spatial Learning in the 5-HT1B Receptor Knockout Mouse: Selective Facilitation/Impairment Depending on the Cognitive Demand
Learn. Mem., November 1, 2003; 10(6): 466 - 477.
[Abstract] [Full Text] [PDF]

M. Wolff, N. Benhassine, P. Costet, R. Hen, L. Segu, and M.-C. Buhot
Delay-Dependent Working Memory Impairment in Young-Adult and Aged 5-HT1BKO Mice as Assessed in a Radial-Arm Water Maze
Learn. Mem., September 1, 2003; 10(5): 401 - 409.
[Abstract] [Full Text] [PDF]

E. Degenetais, A.-M. Thierry, J. Glowinski, and Y. Gioanni
Synaptic Influence of Hippocampus on Pyramidal Cells of the Rat Prefrontal Cortex: An In Vivo Intracellular Recording Study
Cereb Cortex, July 1, 2003; 13(7): 782 - 792.
[Abstract] [Full Text] [PDF]

F. Sargolini, C. Florian, A. Oliverio, A. Mele, and P. Roullet
Differential Involvement of NMDA and AMPA Receptors Within the Nucleus Accumbens in Consolidation of Information Necessary for Place Navigation and Guidance Strategy of Mice
Learn. Mem., July 1, 2003; 10(4): 285 - 292.
[Abstract] [Full Text] [PDF]

S. B. Floresco and A. A. Grace
Gating of Hippocampal-Evoked Activity in Prefrontal Cortical Neurons by Inputs from the Mediodorsal Thalamus and Ventral Tegmental Area
J. Neurosci., May 1, 2003; 23(9): 3930 - 3943.
[Abstract] [Full Text] [PDF]

J. R. Sage, S. G. Anagnostaras, S. Mitchell, J. M. Bronstein, A. De Salles, D. Masterman, and B. J. Knowlton
Analysis of Probabilistic Classification Learning in Patients With Parkinson's Disease Before and After Pallidotomy Surgery
Learn. Mem., May 1, 2003; 10(3): 226 - 236.
[Abstract] [Full Text] [PDF]

I. Lee and R. P. Kesner
Time-Dependent Relationship between the Dorsal Hippocampus and the Prefrontal Cortex in Spatial Memory
J. Neurosci., February 15, 2003; 23(4): 1517 - 1523.
[Abstract] [Full Text] [PDF]

F. Passetti, Y. Chudasama, and T. W. Robbins
The Frontal Cortex of the Rat and Visual Attentional Performance: Dissociable Functions of Distinct Medial Prefrontal Subregions
Cereb Cortex, December 1, 2002; 12(12): 1254 - 1268.
[Abstract] [Full Text] [PDF]

R. G. Mair, J. K. Koch, J. B. Newman, J. R. Howard, and J. A. Burk
A Double Dissociation within Striatum between Serial Reaction Time and Radial Maze Delayed Nonmatching Performance in Rats
J. Neurosci., August 1, 2002; 22(15): 6756 - 6765.
[Abstract] [Full Text] [PDF]

A. E. Baldwin, K. Sadeghian, and A. E. Kelley
Appetitive Instrumental Learning Requires Coincident Activation of NMDA and Dopamine D1 Receptors within the Medial Prefrontal Cortex
J. Neurosci., February 1, 2002; 22(3): 1063 - 1071.
[Abstract] [Full Text] [PDF]

E. Degenetais, A.-M. Thierry, J. Glowinski, and Y. Gioanni
Electrophysiological Properties of Pyramidal Neurons in the Rat Prefrontal Cortex: An In Vivo Intracellular Recording Study
Cereb Cortex, January 1, 2002; 12(1): 1 - 16.
[Abstract] [Full Text] [PDF]

B. Roozendaal, D. J.-F. de Quervain, B. Ferry, B. Setlow, and J. L. McGaugh
Basolateral Amygdala-Nucleus Accumbens Interactions in Mediating Glucocorticoid Enhancement of Memory Consolidation
J. Neurosci., April 1, 2001; 21(7): 2518 - 2525.
[Abstract] [Full Text] [PDF]

P. Roullet, F. Sargolini, A. Oliverio, and A. Mele
NMDA and AMPA Antagonist Infusions into the Ventral Striatum Impair Different Steps of Spatial Information Processing in a Nonassociative Task in Mice
J. Neurosci., March 15, 2001; 21(6): 2143 - 2149.
[Abstract] [Full Text] [PDF]

S. B. Floresco, D. N. Braaksma, and A. G. Phillips
Thalamic-Cortical-Striatal Circuitry Subserves Working Memory during Delayed Responding on a Radial Arm Maze
J. Neurosci., December 15, 1999; 19(24): 11061 - 11071.
[Abstract] [Full Text] [PDF]

S. H. Morris, S. Knevett, E. G. Lerner, and L. J. Bindman
Group I mGluR Agonist DHPG Facilitates the Induction of LTP in Rat Prelimbic Cortex In Vitro
J Neurophysiol, October 1, 1999; 82(4): 1927 - 1933.
[Abstract] [Full Text] [PDF]

A. Sebret, I. Lena, D. Crete, T. Matsui, B. P. Roques, and V. Dauge
Rat Hippocampal Neurons Are Critically Involved in Physiological Improvement of Memory Processes Induced by Cholecystokinin-B Receptor Stimulation
J. Neurosci., August 15, 1999; 19(16): 7230 - 7237.
[Abstract] [Full Text] [PDF]

B. D. Devan and N. M. White
Parallel Information Processing in the Dorsal Striatum: Relation to Hippocampal Function
J. Neurosci., April 1, 1999; 19(7): 2789 - 2798.
[Abstract] [Full Text] [PDF]

J. A. Parkinson, M. C. Olmstead, L. H. Burns, T. W. Robbins, and B. J. Everitt
Dissociation in Effects of Lesions of the Nucleus Accumbens Core and Shell on Appetitive Pavlovian Approach Behavior and the Potentiation of Conditioned Reinforcement and Locomotor Activity by D-Amphetamine
J. Neurosci., March 15, 1999; 19(6): 2401 - 2411.
[Abstract] [Full Text] [PDF]

R. Pussinen and J. Sirvio
Effects of D-cycloserine, a positive modulator of N-methyl-D-aspartate receptors, and ST 587, a putative alpha-1 adrenergic agonist, individually and in combination, on the non-delayed and delayed foraging behaviour of rats assessed in the radial arm maze
J Psychopharmacol, March 1, 1999; 13(2): 171 - 179.
[Abstract] [PDF]

L. L. Peoples, F. Gee, R. Bibi, and M. O. West
Phasic Firing Time Locked to Cocaine Self-Infusion and Locomotion: Dissociable Firing Patterns of Single Nucleus Accumbens Neurons in the Rat
J. Neurosci., September 15, 1998; 18(18): 7588 - 7598.
[Abstract] [Full Text] [PDF]

J. K. Seamans, S. B. Floresco, and A. G. Phillips
D1 Receptor Modulation of Hippocampal-Prefrontal Cortical Circuits Integrating Spatial Memory with Executive Functions in the Rat
J. Neurosci., February 15, 1998; 18(4): 1613 - 1621.
[Abstract] [Full Text] [PDF]

R. M. Vickery, S. H. Morris, and L. J. Bindman
Metabotropic Glutamate Receptors Are Involved in Long-Term Potentiation in Isolated Slices of Rat Medial Frontal Cortex
J Neurophysiol, December 1, 1997; 78(6): 3039 - 3046.
[Abstract] [Full Text] [PDF]

H. Gurden, M. Takita, and T. M. Jay
Essential Role of D1 But Not D2 Receptors in the NMDA Receptor-Dependent Long-Term Potentiation at Hippocampal-Prefrontal Cortex Synapses In Vivo
J. Neurosci., November 15, 2000; 20(22): RC106 - RC106.
[Abstract] [Full Text] [PDF]

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