Impaired Recognition of the Goal Location during Spatial Navigation in Rats with Hippocampal Lesions

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The Journal of Neuroscience, June 15, 2001, 21(12):4505-4513

Impaired Recognition of the Goal Location during Spatial Navigation in Rats with Hippocampal Lesions
Stig A. Hollup, Kirsten G. Kjelstrup, Joakim Hoff, May-Britt Moser, and Edvard I. Moser
Department of Psychology, Norwegian University of Science and Technology, 7491 Trondheim, Norway

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Converging evidence suggests that the hippocampus is essential for goal-directed spatial navigation. Successful navigationrequires not only the ability to compute an appropriate path towardthe target but is also guided by recognition of places along thetrajectory between start and goal. To determine whether the hippocampuscontributes to place recognition, we trained rats with hippocampallesions in an annular water maze with a remotely controlled escapeplatform at a constant location in the corridor. The platformremained submerged and unavailable until the rat had swum at leastone full lap. Probe trials with the platform unavailable for 60sec were inserted at regular intervals. In these trials, the ratwould swim over the platform several times, regardless of itsnavigational abilities. After a few training sessions, all sham-operatedcontrol animals reduced their swim velocity when they approachedthe platform, indicating that they recognized the target location.Rats with hippocampal lesions, in contrast, swam at the same velocityas elsewhere in the corridor. Preoperative training or prolongedpostoperative training did not alleviate the deficit. Rats withhippocampal lesions were able to learn a cued version of the task,which implies that the failure to slow down was not attributableto motor inflexibility. Thus, hippocampal lesions caused a severebut selective deficit in the identification of a location, suggestingthat the hippocampus may be essential for image recognition duringspatialnavigation.

Key words: hippocampus; learning; memory; recognition; spatial; navigation; trajectory; plasticity; rat

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Although the hippocampus is involved in a broad range of memory types (Squire, 1992), it appears to have a particular functionin spatial navigation and memory (O'Keefe and Nadel, 1978; Nadel,1991; Steckler et al., 1998). First, there is a strong activationof the hippocampus during memory-guided spatial navigation (Maguireet al., 1997, 1998; Bontempi et al., 1999). Second, activity inhippocampal pyramidal neurons is location-specific (O'Keefe andDostrovsky, 1971; Wilson and McNaughton, 1993), depends on theconfiguration of distal landmarks (Muller et al., 1987; O'Keefeand Speakman, 1987; O'Keefe and Burgess, 1996), and may outlastremoval or concealment of the controlling cues (O'Keefe and Speakman,1987; Quirk et al., 1990). Finally, animals with hippocampal lesionsfail to learn the location of a hidden goal whose position isdefined by the arrangement of distal landmarks (Jarrard, 1978;Olton et al., 1978; Morris et al., 1982, 1990; Sutherland et al.,1983).

However, not all features of spatial navigation and memory depend on the hippocampus. Rats with hippocampal lesions can solvelandmark-based navigation tasks under certain conditions, suchas when training is prolonged (Morris et al., 1990) or when taskdifficulty is increased progressively (Whishaw et al., 1995; Whishawand Jarrard, 1996). To identify the exact function of the hippocampusin spatial navigation, it would be helpful to isolate navigationaloperationsexperimentally.

Goal-directed navigation may involve several different algorithms in succession (Cheng, 2000), and each algorithm may involveseveral successive operations. Recognition of the current locationis one such operation, but it plays different roles in differentproposed algorithms. In some models, recognition of the currentlocation is a first and necessary step in deciding what to donext (Benhamou et al., 1995; Brown and Sharp, 1995; Reid and Staddon,1998). What these models have in common is that recognition orrecall of a location is a separate step from choosing where togo next, and these operations could therefore be mediated by differentneuronalcircuits.

Because some types of recognition memory are likely to be independent of the hippocampus (Murray and Mishkin, 1998; Brownand Aggleton, 2001), we examined whether the integrity of thisstructure is necessary for image recognition during navigationwhen the goal can be reached without the use of a geometric algorithmfor path calculation. Annular place navigation tasks (O'Keefeet al., 1975) can be used for this purpose. Rats with or withouthippocampal lesions were trained to swim in laps in an annularcorridor in a water maze with a hidden escape platform at a fixedlocation in the corridor. On probe trials without the platform,normal rats exhibited reduced speed each time they passed thetarget position, indicating that they recognized the place. Thecorridor walls guided all animals to the goal, so a failure toslow down at the target after a lesion of the hippocampus mightimply a specific deficit in recognition oflocations.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects. Fifty-seven male Long-Evans rats (350-500 gm) were housed in groups of four to six in large transparent polycarbonatecages (59 × 38 × 20 cm). The animals were kept on a 12 hr light/darkschedule and tested in their dark phase. Animals with lesionsreceived food and water ad libitum.

Lesions. The rats were anesthetized with Equithesin (pentobarbital and chloral hydrate; 1.0 ml/250 gm body weight, i.p.).Hippocampal lesions were made by bilateral injection of ibotenicacid (Biosearch Technologies, San Rafael, CA) at 28 sites (Jarrard,1989). Ibotenic acid was dissolved in PBS, pH 7.4, at 10 mg/mland injected with a 1 µl Hamilton syringe mounted to the stereotaxicframe. Injections of 0.05-0.10 µl were made over 10-20 sec ateach site. The syringe was retracted 2 min after the injection.In sham-operated rats, the syringe was lowered through the neocortex,but no drug wasinfused.

Annular water maze task. The animals were trained to search for a hidden platform in an annular corridor in a white circularpolyvinyl chloride tank (198 cm diameter and 50 cm deep) filledto a depth of 40 cm with water at 25 ± 2°C (Fig. 1). The waterwas made opaque with latex liquid. The corridor was defined bytwo circular, transparent Perspex walls of 75 and 95 cm diameter,respectively, placed around the center of the water-filled tank.The tank contained four pneumatically controlled 10-cm-diameterescape platforms, one in the center of each pool quadrant andall within the corridor. Each platform could be regulated betweenan available and an unavailable level (1.5 and 22 cm below thesurface, respectively). Only one platform was used at a time;the other three remained submerged at the bottom of the tank.For each rat, the location of the active platform was constantthroughout the experiment. The apparatus was located in a room(4 × 7 m) with multiple cues on all sides. A wall (2 × 2 m) separatedthe pool from the experimenter during thetrials.

All training sessions consisted of four consecutive trials. In each trial, the rats were released from one of four equallyspaced start positions along the perimeter of the corridor ina predetermined and pseudorandom order. Trials in the corridoralways started with the platform in the submerged (unavailable)position. The platform was not raised until the rat had swum atleast one full lap in the corridor. In this way, the rats learnedto circle through the corridor rather than floating at the expectedplatform location. If the rats had not entered the platform after120 sec, they were guided onto it. Every fourth trial was a probetrial. In these trials, the platform was kept in its lower positionfor the first 60 sec of the test, and the search pattern was recorded.The platform was subsequently raised to its upper, accessibleposition, after which the rat found the platform. The rats werereleased from the quadrant opposite to the platform on the probetrials. The position of the rat was revealed by a video trackingsystem (Axona Ltd., St. Albans, UK) that extracted and storedthe x--y coordinates of the rat's black head on the white poolsurface (in the water maze) at 50 Hz. After swimming, the ratwas placed under an infrared heatinglamp.

New learning in pretrained animals. There were three training conditions in the annular task. First, 10 rats with hippocampallesions and 10 with sham lesions received 40 trials of pretrainingwith a constant platform location in a different water tank. Therewas no corridor during this pretraining. New learning in theseanimals was tested on a single day consisting of 13 trials. Thesetrials were given as three blocks of four trials, each startingwith a probe trial, plus a final probe trial at the end. The intervalbetween successive blocks of trials was 30 min. During the probetrials, the platform was raised at 60sec.

Learning in naïve animals. A second group of animals (six with intended hippocampal lesions and 6 with sham lesions) receivedno pretraining. Training in the corridor was conducted over aperiod of 8 d. On each of days 1-3 and 6-8, the animals receivedfour blocks of training with the hidden platform in a constantposition, according to the same protocol as in the pretrainedrats (13 trials). On days 4 and 5, the platform was made visible.The pneumatically controlled platforms were all submerged. A 10-cm-longsplit was made in the inner corridor wall, and a new, elevatedplatform was placed 10 cm behind the split. The platform diskwas marked with colored tape and reached 1.5 cm above the watersurface. Each day, the animals received two blocks of four trials,and the latency to swim through the split and climb the platformwas recorded. On days 6-8, the inner corridor wall was replaced,and the original training procedure wasresumed.

Retention. Finally, a third group of animals was trained for 5 d in the corridor before surgery. All animals received 10 blocksof four trials, with two blocks of training each day. A probetest was conducted on the sixth day. The platform was raised atthe end of this trial, as above. The animals were ranked, matched,and assigned to surgery groups according to the proportion oftime they spent around the platform. Surgery (nine hippocampallesions and eight sham lesions) was conducted after the probetrial. Six days later, a single retention test was conducted.Again, the platform was kept in its lower position for the first60 sec, and the animal's position wastracked.

Analysis of corridor behavior. For analysis of behavior in the corridor task, the water maze was divided into 12 segmentsof 30° arc with fixed segment borders. The platform was in thecenter of one of the segments. Memory was expressed as a consistentreduction of swim velocity within the segment that contained theplatform compared with the other sectors, as well as a correspondingincrease in time spent in this segment and an increase in thetortuosity of the swim trajectory at this location. To estimatetortuosity, we divided the swim path into segments of 0.5 secand expressed the length of each path segment as a percentageof the shortest possible path between the start and the end pointof the segment. The average value was referred to as "pathefficiency."

Delayed-nonmatching-to-sample task. Eight animals (four hippocampal and four sham) were trained in a nonspatial delayed-nonmatching-to-sampletask in the same water maze as above. The whole water maze arenawas used for this purpose. White curtains were drawn around therim of the pool to mask external landmarks, and the cues wereobjects hanging in thin, white string 10-15 cm over the watersurface. Training consisted of 107 sessions, distributed over11 d (seven on day 1 and then 10 per day). Each session consistedof a sample trial and a test trial 1 min later. On the sampletrial, a distinct cue was hanging over the pool. The rat swamfreely and was picked up after 30 sec. On the subsequent testtrial, two platforms were made available. The cue from the sampletrial was attached above one of the platforms, whereas a differentand new cue signaled the other platform. The rat was releasedfrom the rim of the pool opposite to the platforms. If the ratentered the platform beneath the familiar cue, both platformswere immersed and the animal was left in the water for another30 sec. If the rat swam to the new cue, the platform remainedelevated. We used a collection of 214 cue objects with distinctshape, brightness, and color (5-10 cm large, e.g., a coil of wire,a cup, a plate, a thermometer, a balloon, a can, and a bottle).The cue locations were always different in sample and test trialand were varied according to a pseudorandom schedule. New pairswere used in each trial. For each pair, the designation of sampleand novel object was random. The rats had been used in a contextualconditioning experiment during the precedingweek.

Histology. The rats received an overdose of Equithesin and were perfused transcardially with saline, followed by 4% formaldehyde.The brains were extracted and stored in 4% formaldehyde. At least1 week later, the brains were quickly frozen, cut in coronal sections(30 µm), mounted, and stained with cresyl violet. Every 10th sectionin the area of the hippocampus and the subiculum was retained.The volume of residual hippocampal tissue in the lesioned animalswas determined by placing each section under a microscope attachedto a digital camera (Olympus DP10; Olympus Optical, Tokyo, Japan)and a personal computer, taking the images into Canvas 7.0 (DenebaSystems, Miami, FL), tracing an outline of remaining hippocampaltissue, and determining the area of the outlined region for eachsection (Moser and Moser, 1998). The volume of the hippocampalremnant was expressed as the percentage of the mean volume ofhippocampal tissue in the sham-operatedgroup.

Approvals. The experiments were approved by the National Animal Research Authority ofNorway.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Hippocampal lesions

The hippocampal damage was nearly complete in all animals that received ibotenic acid injections (Fig. 1), except in one ratthat had no damage in the hippocampus beyond the cannula tracks.The latter animal was assigned to the sham group. The volume ofthe tissue remnants in the remaining hippocampal animals rangedfrom 0.9 to 46.0% of total hippocampal volume, with a mean ± SEMof 10.6 ± 2.5%. The remnants were mainly located in the ventralhippocampus. The lesions extended into the adjacent subiculumin most rats in the hippocampal group. Subicular damage was mainlyseen on sections close to the hippocampus and mainly in the ventralpart of the structure. No animals were excluded.

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Figure 1. Coronal sections showing cresyl violet stains of neuronal cell bodies in the dorsal (A, B) and intermediate-to-ventral (C, D) hippocampus of a sham-operated rat (A, C) and a rat with a complete hippocampal lesion (B, D). In the latter animal, 2.5% of hippocampal volume was spared.

Experiment 1: learning in pretrained animals

Recognition of the goal location was examined in pretrained animals that received new training in an unfamiliar environment.At the start of the new training, neither the lesion group northe sham group showed any preference for the platform segmentof the water maze corridor. As training continued, the sham-operatedanimals frequently speeded up when approaching the platform andthen always slowed down as they passed over the target on theprobe trials (Fig. 2). The time spent at the expected target locationincreased gradually (Figs. 3, 4), indicating that these animalsrecognized the place as the goal location. They showed no changein behavior outside the platform region. Rats with hippocampallesions, in contrast, failed to spend any more time at the platformposition than in other segments (Figs. 3, 4). Occasionally, someof them increased their speed 1-2 sec before reaching the targetposition, but they nonetheless failed to slow down when they arrivedat the destination (Fig. 2C).

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Figure 2. Swim pattern at the goal position on the final probe trial. A, Trajectory of a sham-operated rat (top) and a rat with a complete hippocampal lesion (HPC; bottom). Arrows indicate platform position on preceding training trials. B, Swim velocity during every single passage over the platform in all 10 sham-operated control animals (total of 30 passages; each curve corresponds to 1 passage). The crossing of the center of the platform segment was defined as t = 0 sec (stippled vertical line). The horizontal line indicates the average swim velocity of the group outside the platform segment (330° of arc). The sham-operated animals consistently slowed down when they approached the platform area. C, Swim velocity for every single passage over the platform in all 10 hippocampal-lesioned animals (total of 39 passages; horizontal line indicates average swim velocity outside the platform segment). The swim velocity over the platform was not lower than in other parts of the corridor.

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Figure 3. Dwell time (means ± SEM) in each of 12 30° segments of the annular corridor (inset) in the final probe trial in the pretrained animals. The platform segment is defined as 0°. Sham-operated rats, but not rats with hippocampal lesions (HPC), spent more time in the platform segment than in other segments.

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Figure 4. Development of swim speed (A), dwell time (B), and path efficiency (C) inside the platform segment (30°; left column) and outside this segment (remaining 330°; right column) across four probe tests (means ± SEM; pretrained animals). Rats with hippocampal lesions (HPC) failed to slow down (A), spend more time (B), or make more circuitous swim paths (C) in the platform segment.

We compared performance in two segments of the corridor, one consisting of the 30° of arc around the platform and the otherconsisting of the remaining 330°. A repeated-measures ANOVA ofbehavior in these segments showed significant effects of groups× segments (speed, F_(1,54) = 6.6, p < 0.05; dwell time, F_(1,54)= 29.0, p < 0.001) and groups × segments × trials (speed, F_(3,54)= 3.4, p < 0.05; dwell time, F_(3,54) = 5.8, p < 0.005). A separateanalysis dealing with all 12 30° segments on the final probe testrevealed significant groups × segments effects on speed (F_(11,198)= 2.3, p = 0.01) and time (F_(11,198) = 6.3, p < 0.001), with asignificant group difference in the target segment (speed, t₍₁₈₎= 4.7, p < 0.001; time, t₍₁₈₎ = 3.7, p = 0.001; one-tailed Student'st tests). There was no significant main effect of groups on speed(F_(1,18) = 2.8, p > 0.10). On the final probe test, the averagespeed of swimming outside the target segment was 20.2 ± 1.4 cm/secin the hippocampal group and 18.1 ± 0.6 cm/sec in the sham group(Fig. 4).

Recognition of the goal location was also expressed as an increase in the deviation of the swim path from the shortest possibletrajectory through the segment (path efficiency). Path lengthsin the target segment increased with training in the sham-operatedgroup but not in animals with hippocampal lesions (groups × trials,F_(3,54) = 4.6, p < 0.005; groups × segments × trials, F_(3,42)= 4.2, p = 0.01) (Fig. 4C).

There was no significant correlation between the volume of residual hippocampal tissue and performance on the final probetest (dwell time, r = 0.22; speed, r = $-$ 0.08; path efficiency,r = 0.08; all p > 0.50).

Experiment 2: learning in naïve animals

We subsequently trained a group of naïve rats with hippocampal lesions or sham lesions in the annular water maze. Neitherthe sham group nor the hippocampal group exhibited any preferencefor the platform region on the initial trial (swim velocity inthe platform segment, 20.4 ± 2.4 and 17.4 ± 0.9 cm/sec, respectively)(Fig. 5). As early as the second probe test, however, the shamanimals began to reduce the speed as they passed over the platformand spent more time at this location. Rats with hippocampal lesionsshowed no change in speed at the target position, and at the endof the training (trial 39), there was a clear group difference(sham, 12.5 ± 0.7 cm/sec; hippocampal, 20.1 ± 2.0 cm/sec; t₍₁₀₎= 4.0; p < 0.005). As in the pretrained animals, there was nosystematic change in speed outside the platform segment. In thesham group, the average velocity in the nontarget regions increasedfrom 18.9 ± 0.5 to 20.0 ± 0.9 cm/sec; in the hippocampal group,it increased from 18.9 ± 1.4 to 21.6 ± 1.1 cm/sec. A repeated-measuresANOVA of swim velocity in the target (30°) and nontarget (330°)segments showed a significant groups effect (F_(1,10) = 16.6, p< 0.005), but this was accompanied by significant effects of groups× segments (F_(1,110) = 10.2, p < 0.01) and groups × segments ×trials (F_(11,110) = 2.6, p < 0.01). Thus, the rats swam slowerin the target than the nontarget segments, but the differencewas expressed only in the control animals (Fig. 5).

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Figure 5. Effect of extended training with the hidden platform in naïve rats with hippocampal lesions or sham surgery. The diagrams show the development of swimming speed (means ± SEM) in the platform segment (30° of arc; inset) and the nontarget segments (330° of arc). A, Sham-operated rats. B, Rats with hippocampal lesions (HPC). Note that the hippocampal group failed to slow down in the platform segment and that prolonged training did not improve performance in these animals. The training was interrupted by two cued training sessions (trials 40-55).

The distribution of dwell time changed in a similar manner. On the initial trial, neither the sham group nor the hippocampalgroup spent more time in the platform segment than expected bychance (4.4 ± 0.5 and 5.4 ± 1.0 sec, respectively; chance level,5.0 sec). On the final trial, the sham group spent 10.5 ± 0.8sec in the target segment, whereas the hippocampal group stillperformed at chance (6.3 ± 1.4 sec; t₍₁₀₎ = 2.9; p < 0.01). AnANOVA of dwell time in the goal segment (30°) and in the othersegments (330°) showed significant effects of groups × segments(F_(1,110) = 18.3, p < 0.005) and groups × segments × trials (F_(11,110)= 1.9, p = 0.05).

Finally, the hippocampal lesions affected the tortuosity of the swim trajectories. As training proceeded, paths in the goalsegment became increasingly less direct in the sham group butexhibited no change in the hippocampal group. On the first probetrial, there was no significant group difference (path efficiencyof 86.2 ± 2.3 and 89.0 ± 1.0%, respectively). On the final probetest (trial 39), the path efficiency in the sham group was 79.8± 1.0% in the target segment compared with 89.1 ± 1.0% in thenontarget segments (t₍₆₎ = 6.1, p < 0.001). There was no differencebetween target and nontarget segments in the hippocampal group(89.8 ± 2.5 and 91.4 ± 1.1%, respectively). An overall analysison the entire set of probe trials showed significant effects ofgroups (F_(1,10) = 40.1, p < 0.001), groups × segments (F_(1,110)= 6.1, p < 0.05), and groups × segments × trials (F_{(11, 110)} =2.7, p < 0.005).

Cued navigation

It is conceivable that hippocampal-lesioned animals failed to slow down over the platform because of general hyperactivityor an inability to change between motor programs. On the fourthand fifth days of training, we therefore tested the above animalsin a cued version of the corridor task. No platforms were availableinside the corridor in this condition. Instead, a 10-cm-long splitwas made in the inner corridor wall, and a new, clearly visibleplatform was placed 10 cm behind the split (Fig. 6). Both sham-operatedand hippocampal-lesioned animals learned to escape onto the visibleplatform. The hippocampal group was slower to climb the platformon the first session, but the escape latencies were soon below10 sec in both groups. On the final (fourth) session, the latencieswere 6.7 ± 0.6 (hippocampal) and 4.3 ± 0.2 (sham) sec. Althoughthe group difference was small, it was significant (F_(1,10) =7.8, p < 0.05). The difference was attributable to a few trialsin which the hippocampal animals ignored the split in the innercorridor wall. During these trials, the rats were always swimmingalong the outer corridor wall when they passed. Trajectories inthe middle or inner part of the corridor were followed by turningand subsequent escape. These observations exclude motivationaland motor explanations of why hippocampal-lesioned animals failedto slow down in the platform segment.

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Figure 6. Latency to climb the platform in a cued version of the task (means ± SEM). A clearly marked platform was elevated above the water surface but was placed behind the inner corridor wall (inset). A 10-cm-long split in the inner corridor wall allowed the rat to access the platform. Both sham-operated and hippocampal-lesioned (HPC) animals learned to find and enter the visible platform within a few seconds after they were released into the corridor.

Extended training

To determine whether rats with hippocampal lesions are able to overcome their recognition deficit with extended training,we trained the above animals for another 3 d (39 trials). Theoriginal inner corridor wall was reintroduced, and four blocksof trials were run eachday.

There was no significant improvement in the performance of the hippocampal group (Fig. 5). The average swim velocity in thisgroup was not lower in the platform segment (20.6 ± 2.4 cm/sec)than in other segments (21.7 ± 1.2 cm/sec), nor was there anyincrease in dwell time in the target zone (6.3 ± 0.9 sec; chancelevel, 5.0 sec). The mean path efficiency in the target segmentwas 87.3 ± 1.7% compared with 89.7 ± 1.4% in the nontarget segments.The sham-operated animals maintained their strong preference forthe platform segment, as demonstrated by slower swimming, longerdwell time, and more circuitous swim paths in the platform segment(average speed, 13.2 ± 0.7 cm/sec; average dwell time, 9.3 ± 0.7sec; average path efficiency, 80.2 ± 1.3%).

An ANOVA of behavior in target and nontarget segments on trials 56-94 showed a significant effect of groups on speed (F_(1,10)= 14.0, p < 0.005) and path efficiency (F_(1,10) = 40.1, p < 0.001)but also a significant groups × segments interaction effect (speed,F_(1,110) = 5.1, p < 0.05; dwell time, F_(1,110) = 7.3, p < 0.05;path efficiency, F_(1,110) = 6.1, p < 0.05). There was no effectof segments × trials (F < 1) or groups × segments × trials (F_(11,110)= 1.3) on dwell time, but the effects on speed (segments × trials,F_(11,110) = 2.6, p < 0.005; groups × segments × trials, F_(11,110)= 2.6, p < 0.005) and path efficiency (segments × trials, F_(11,110)= 4.4, p < 0.001; groups × segments × trials, F_(11,110) = 2.7,p < 0.005) were significant. The latter effects did not reflecta systematic change toward low speed and circuitous paths in thegoal segment but could be caused by the less selective behaviorof the sham group on the first trial of each day (Fig. 5).

Experiment 3: retention

To determine whether the hippocampus is essential for goal recognition also when the task is acquired by an intact hippocampus,we examined the effect of hippocampal lesions on retention in17 rats that had been trained preoperatively for 5 d (40 trials)in the annular water maze. During pretraining, all of these ratssearched for the hidden platform in the correct segment. On thefinal probe test, the animals spent significantly more time inthe platform segment than elsewhere in the corridor (t₍₁₆₎ = 4.1,p < 0.001; one-tailed Student's t test) (Fig. 7A). They swam slowerand with less direct paths in the platform segment than in theother segments (speed, t₍₁₆₎ = 4.5, p < 0.001; path efficiency,t₍₁₆₎ = 2.7, p < 0.01). The animals were ranked according to timespent in the platform zone, matched, and assigned to two groups,which received hippocampal lesions and sham surgery, respectively.There was no group difference on any measure after the matching(group and group × segment, all F < 1). Surgery started 1 hr afterthe probe test.

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Figure 7. Effect of hippocampal lesions when the task was acquired before surgery. (A, B). Speed (A) and dwell time (B) in the goal segment (30°) and the other segments (remaining 30°) before surgery (Pre) and 6 d after surgery (Post). Values are means ± SEM. Only the sham-operated rats maintained their preference for the platform segment. Rats with lesions of the hippocampus (HPC) failed to differentiate between target and nontarget segments. C, Dwell time (means ± SEM) in each of 12 30° segments of the annular corridor (inset) on the postoperative retention test. The platform segment is defined as 0°.

Retrieval was measured on a second probe test 6 d later. Only the sham-operated group maintained its preference for the platformsegment (Fig. 7). The performance of the sham group was as accurateas on the preoperative test 1 week earlier. Rats with hippocampallesions, in contrast, failed to slow down at the platform andspent no more time there than elsewhere. A repeated-measures ANOVAof behavior in target and nontarget segments showed a significanteffect of groups on swim velocity (F_(1,15) = 20.1, p < 0.001)and path efficiency (F_(1,15) = 33.5, p < 0.001), indicating fasterswimming and less circuitous trajectories in the hippocampal group.There was also a significant groups × segments effect on time(F_(1,15) = 6.1, p < 0.05) and path efficiency (F_(1,15) = 5.4,p < 0.05). The groups × segments effect on speed was not significant(F_(1,15) = 1.6), possibly because of the large general increasein swim velocity in the hippocampal group in this specific experiment.The correlation between the volume of residual hippocampal tissueand behavior in the platform segment on the retention test wasnot significant (dwell time, r = $-$ 0.43; speed, r = 0.50; pathefficiency, r = $-$ 0.57; all p > 0.10).

Altogether, the data suggest that hippocampal lesions disrupted recognition of the goal location also when the task was acquiredwith an intact brain. Although retention was tested only 6 d aftersurgery, the deficit was probably specific. Previous researchhas shown that, 7 d after surgery, animals with partial hippocampallesions can acquire a new spatial task within one or a few trials,at the same rate as the control animals, even if their retentionof previous spatial memory is totally disrupted (Moser and Moser,1998).

Experiment 4: single-item recognition

To examine the functional specificity of the recognition deficit in the spatial task, we tested nonspatial recognition ofsingle items in the water maze in eight rats with sham lesionsor hippocampal lesions. We used a nonspatial delayed nonmatchingprocedure and determined whether such animals could distinguishnonfamiliar items from items that had been presented on a sampletrial 1 min earlier. All animals swam directly to one of the cuesduring the choice trial. There was no initial preference for thenonfamiliar cue (sham group, 50.0 ± 4.1%; hippocampal group, 42.9± 14.3%). Both sham-operated and hippocampal-lesioned animalsgradually began to swim more often to the novel cue, althoughtheir preference for the new object was still only moderate atthe end of the training. On the last 2 d, 63.8 ± 2.4% of the sham-operatedanimals and 68.8 ± 7.2% of the hippocampal-lesioned animals preferredthe nonfamiliar cue, which was better than chance (t₍₇₎ = 4.5,p < 0.005). There were no group differences (effects of groupsand groups × sessions, F < 1). However, choices were slightlymore consistent in the sham group (9 of 10 last sessions abovechance) than in the hippocampal group (7 of 10 sessions abovechance). It is possible that we would have seen an impairmentin the hippocampal group with a larger sample, with longer delays,or with extended training, but the results of experiment 4, althoughpreliminary, suggest that such differences might besmall.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Rats with hippocampal lesions failed to search at the goal. Because all animals passed this area regardless of whether theywere able to compute an efficient trajectory, our findings suggestthat the hippocampus is necessary for an animal to recognize thegoal location and terminate its search uponarrival.

Did the animals have a memory deficit?

The undifferentiated behavior of the hippocampal group does not necessarily imply that spatial memory was disrupted. Impairedperformance after hippocampal ablation could reflect an inabilityto terminate thigmotactic behavior or, more generally, a failureto efficiently alter response strategies (Day et al., 1999). Hyperactivityand poor switching between motor programs could in principle accountfor the maintenance of high speed in the goal segment in ratswith hippocampal lesions. However, when a visible platform wasmade available behind a small hole in the inner corridor wall,both lesioned and unlesioned rats slowed down, turned, swam throughthe door, and climbed the platform. Thus, they could stop whenthey knew where the platform was, suggesting that the lesion disruptedgoal recognition rather than motorcontrol.

Hippocampal involvement in recognition of the goal location

Most previous experiments are neutral as to whether hippocampal lesions compromise the ability to use spatial informationto get to a goal, or the ability to recognize locations on arrival,or both. Rats with hippocampal lesions take indirect and apparentlyrandom routes toward the goal location (Morris et al., 1982, 1990;Eichenbaum et al., 1990), but if image recognition is a prerequisitefor computing trajectories (Benhamou et al., 1995; Brown and Sharp,1995; Reid and Staddon, 1998), this impairment could result frompoor place recognition rather than poor trajectory planning. Inthe present task, inability to select an appropriate directionwould not normally prevent the animals from entering the platformarea. Thus, the failure to slow down over the platform in thehippocampal group probably reflected a failure in identifyingthis place as the target site. Our results do not establish whetherthe hippocampus is necessary also for computing trajectories betweenplaces, but the fact that firing in many place cells is influencedby the past or future path of the animal (Frank et al., 2000;Wood et al., 2000) suggestsso.

A few previous studies have dissociated trajectory planning and goal recognition by simplified and extended training. Afterpretraining with a visible target in the water maze, rats withhippocampal lesions took circuitous routes to the platform butdid slow down once they reached the goal region, indicating thatthey recognized the area but did not know how to get there (Whishawet al., 1995; Whishaw and Jarrard, 1996). Similar results wereobtained in a spatial odor discrimination task, in which hippocampal-lesionedrats failed to learn which cups to approach, but nonetheless refrainedfrom digging for reward when they reached the wrong cup (Dudchenkoet al., 2000). A different pattern appeared when rats with hippocampaldamage started from a constant position in the water maze (Eichenbaumet al., 1990) or had an escape platform that initially occupiednearly the entire pool and then became progressively smaller (Dayet al., 1999). These animals headed correctly toward the hiddentarget but failed to slow down and turn when they missed the target.Their impairment at the goal location was similar to the one seenhere.

Why do these findings diverge? The earlier studies, unlike the present one, were characterized by explicit shaping of theescape behavior. Task demands were increased progressively, byeither starting with a visible platform or reducing its size.Under these conditions, all animals, including those with lesions,performed at a low error rate during the initial trials. Humanamnesics benefit substantially from such "errorless" trainingand are able to learn, as well as remember, some new semanticinformation when competing inappropriate responses are eliminated(Baddeley and Wilson, 1994). Such error prevention may accountfor the residual spatial learning capacity of hippocampal-lesionedanimals, too. Whether the rats improve most on trajectory planningor goal recognition might depend on the exact trainingprotocol.

The robustness of the recognition impairment in the present study may also reflect the fact that the rat had to choose betweentwo responses at the goal location, slowing down and swimmingon, with the appropriate decision depending on the animal's previousbehavior during the trial. A similar decision was not requiredin the cued task. The choice requirement may have added to theimpairment of the hippocampal group but was probably not the primarycause. If the rats knew the location of the goal but not whetherthey had already been there, they would likely have reduced theirspeed during each passage. However, animals with hippocampal lesionsnever slowed down, suggesting that recognition was disruptedspecifically.

What type of recognition memory was involved?

Did the annular task measure recognition memory? Because performance requires that stimuli around the platform be matchedagainst corresponding stimuli in the rat's memory, we tested aform of recognition. However, there are at least two types ofrecognition memory, a fast and familiarity-based recognition processthat is spared in amnesia, and a slower identification processthat is impaired in amnesia (Huppert and Piercy, 1976, 1978; Hintzmanand Curran, 1994). When an animal slowed down over the platformin the annular corridor, it could not do so only by judging thefamiliarity or recency of specific landmarks. Because the ratsswam in laps, they were exposed to all segments of the corridorseveral times in each trial during training, and the various regionsof the apparatus were probably soon indistinguishable in termsof familiarity. To be able to slow down over the platform, theyhad to know that they were about to hit the hidden target. Terminationof search behavior at the goal position therefore involves anelement of associative recollection or recall and may thus relyon different brain structures than pure familiarity or recencyjudgments (Eichenbaum et al., 1994; Steckler et al., 1998; Aggletonand Brown, 1999). Accordingly, although the hippocampus may beinstrumental in identifying the platform site as the goal, othercircuits may, in principle, be sufficient for non-navigationalspatial recognition, such as tested in spatial delayed comparisontests.

Is the hippocampus necessary only for spatial types of recognition memory? There is evidence suggesting that hippocampal regionsare active during discrimination between locations or arrangementsof items but not when single items are to be recognized (Mumbyet al., 1992; Gaffan, 1994; Ennaceur et al., 1996; Wan et al.,1999; Brown and Aggleton, 2001). The present results are consistentwith this distinction, showing that hippocampal lesions disruptrecognition of spatial location but not necessarily recognitionof single nonspatial items. However, single-item recognition issometimes attenuated, particularly at long sample-test delays(Alvarez et al., 1995; Reed and Squire, 1997; Beason-Held et al.,1999; Clark et al., 2000; Stark and Squire, 2000), and a majortask is to determine the exact conditions under which impairmentoccurs. One critical determinant may be whether recognition isaccompanied by recall of features of the original encoding context(Huppert and Piercy, 1976, 1978; Eldridge et al., 2000). Thisadditional element of associative recollection or cued recallmay be what distinguishes performance in the annular corridor,and possibly in some spatial delayed comparison tasks, from hippocampal-independenttasks that can be solved purely by a nonassociative familiarityjudgment.

Image recognition outside the goal area

Our results do not establish whether the hippocampus has a special function in recognition of goal locations or is necessaryfor image recognition also at earlier decision points along theanimal's trajectory. The task taxed recognition of the goal location,but it is certainly possible that the identification of otherlocations was equallydisrupted.

If the hippocampus contributes specifically to goal recognition, this might be expressed in the firing correlates of individualhippocampal neurons. It has been reported that some hippocampalneurons fire when animals approach or arrive at a goal, regardlessof the goal's location (Eichenbaum et al., 1987; Breese et al.,1989; Gothard et al., 1996), but it remains to be determined whatis signaled by such neurons. Hippocampal place fields can followlocal landmarks even when these are not goals (O'Keefe and Speakman,1987; Hetherington and Shapiro, 1997; Wood et al., 1999), suggestingthat it may be sensory characteristics of the goal that providethe relevant input to the "goal cells" rather than its incentivevalue (Gothard et al., 1996). Goal-related activity has so farnot been dissociated from sensory features (Speakman and O'Keefe,1990). Thus, either the number of hippocampal cells with specificgoal-recognition activity is small, or such activity is not expressedby a frequency code, or goal cells, if they exist, are locatedoutside the hippocampus. If the latter is true, the failure toslow down in the goal segment after lesions of the hippocampusmay perhaps represent a general impairment in recognition of spatialimages that impedes the animal along the entire trajectory fromstart togoal.

  FOOTNOTES

Received Dec. 13, 2000; revised Feb. 16, 2001; accepted April 3, 2001.

This work was supported by Norwegian Research Council Grants 122512/310 and 133958/420 and Fifth Framework Research, TechnologicalDevelopment, and Demonstration Programme of the European CommissionGrant QLG3-CT-1999-00192. We thank Dr. R. Biegler for helpfulcomments and discussion, and K. Barmen, R. Dahl, I. Hammer, andK. Haugen for technicalassistance.
Correspondence should be addressed to Edvard Moser, Department of Psychology, Norwegian University of Science and Technology,N-7491 Trondheim, Norway. E-mail: edvard.moser{at}svt.ntnu.no.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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