Path Integration Absent in Scent-Tracking Fimbria-Fornix Rats: Evidence for Hippocampal Involvement in "Sense of Direction" and "Sense of Distance" Using Self-Movement Cues

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The Journal of Neuroscience, June 1, 1999, 19(11):4662-4673

Path Integration Absent in Scent-Tracking Fimbria-Fornix Rats: Evidence for Hippocampal Involvement in "Sense of Direction" and "Sense of Distance" Using Self-Movement Cues
Ian Q. Whishaw and Bogdan Gorny
Department of Psychology and Neuroscience, University of Lethbridge, Lethbridge, Alberta, Canada T1K 3M4

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Allothetic and idiothetic navigation strategies use very different cue constellations and computational processes. Allotheticnavigation requires the use of the relationships between relativelystable external (visual, olfactory, auditory) cues, whereas idiotheticnavigation requires the integration of cues generated by self-movementand/or efferent copy of movement commands. The flexibility withwhich animals can switch between these strategies and the neuralstructures that support these strategies are not well understood.By capitalizing on the proclivity of foraging rats to carry largefood pellets back to a refuge for eating, the present study examinedthe contribution of the hippocampus to the use of allothetic versusidiothetic navigation strategies. Control rats and fimbria-fornix-ablatedrats were trained to follow linear, polygonal, and octagonal scenttrails that led to a piece of food. The ability of the rats toreturn to the refuge with the food via the shortest route usingallothetic cues (visual cues and/or the odor trail available)or using ideothetic cues (the odor trail removed and the ratsblindfolded or tested in infrared light) was examined. Controlrats "closed the polygon" by returning directly home in all cueconditions. Fimbria-fornix rats successfully used allothetic cues(closed the polygon using visual cues or tracked back on the string)but were insensitive to the direction and distance of the refugeand were lost when restricted to idiothetic cues. The resultssupport the hypothesis that the hippocampal formation is necessaryfor navigation requiring the integration of idiotheticcues.

Key words: allothetic cue; dead reckoning; idiothetic cue; fimbria-fornix; hippocampus; hippocampal lesions; odor tracking; path integration; piloting; spatial learning; spatial navigation

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Allothetic and idiothetic navigation strategies use very different cue constellations and computational processes (Darwin,1873; Barlow, 1964; O'Keefe and Nadel, 1978; Mittelstaedt andMittelstaedt, 1980; Landeau et al., 1984; Etienne, 1987; Gallistel,1990; Maurer and Séguinot, 1995). Allothetic navigation requiresthe use of the relationships between relatively stable external(visual, olfactory, auditory) cues, whereas idiothetic navigationrequires the integration of cues generated by self-movement. Ananimal can obtain self-movement information from vestibular receptors,muscle and joint receptors, and efference copy of commands thatgenerate movement. An animal may also use flows in visual, auditory,and olfactory stimuli caused by its movements. Using an allotheticstrategy an animal can use geometrical calculations to determinedirections and distances to places in its environment, whereasusing an idiothetic strategy it can integrate and double-integratecues generated by its movements to make the same determinations.The ability to estimate direction and distance are colloquiallycalled "sense of direction" and "sense ofdistance."

Although there is considerable evidence that the hippocampus is involved in allothetic navigation (O'Keefe and Nadel, 1978;O'Keefe and Speakman, 1987), there is also evidence from behavioral(Whishaw et al., 1997; Whishaw and Maaswinkel, 1998; Maaswinkeland Whishaw, 1999), modeling (Samsonovich and McNaughton, 1997),and electrophysiological (O'Mare et al., 1994;; Sharp et al.,1995; Taube and Burton, 1995; Blair and Sharp, 1996; McNaughtonet al., 1996; Wiener, 1996; Golob and Taube, 1997) studies thatthe hippocampal formation is involved in idiothetic navigation.The relative contribution of the hippocampus to the two formsof navigation is still uncertain, however. Ordinarily, it is difficultto be certain that an animal is using an allothetic versus anidiothetic strategy because animals are very flexible in theiruse of strategies and cues (Etienne et al., 1996; Dudchenko etal., 1997; Martin et al., 1997; Maaswinkel and Whishaw, 1999).The objective of the present study was to solve the problem ofcue specification in order to examine the relative contributionof the hippocampus in the use of these strategies. The rats weretrained in a new task in which they followed linear or polygonscented trails to obtain a large food pellet hidden on an openfield. Because rats have a proclivity to carry the food back tothe refuge, accuracy and the cues used to return to the home basewere dependent variables (Whishaw and Tomie, 1997). To force ananimal to use an idiothetic strategy to reach its refuge withthe food, the rats were tested when blindfolded or under infraredlight, a spectral wavelength in which they cannot see, and insome experiments the scent trail was additionally removed oncean animal reached the food. To examine the relative contributionof the hippocampus, fimbria-fornix (FF) lesions, which disruptinformation flow in the hippocampal formation (Bland, 1986), impairmemory (Gaffan and Gaffan, 1991), and produce spatial deficits(Whishaw and Jarrard, 1995), wereused.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals
Twelve adult female Long-Evans rats (University of Lethbridge vivarium), weighing 250-300 gm, were housed in groups in wiremesh cages in a laboratory with room temperature maintained at20-21°C and lighted on a 12 hr light/dark cycle (8 A.M. to 8 P.M.).Six rats received sham operations and six received fimbria-fornixlesions beforetesting.
Surgery. For surgery, the rats were anesthetized with sodium pentobarbital (40 mg/kg, i.p.) and atropine methyl nitrate (5mg/kg, i.p.). To make fimbria-fornix lesions, 1.5 mA cathodalcurrent was passed for 40 sec through 00 stainless steel insectpins, insulated with epoxylite except at the surface of theirtips. Lesions were made at two sites in each hemisphere usingcoordinates in reference to bregma and the surface of the dura:1.3 mm posterior, 1.5 mm lateral, and 3.6 mm ventral, and 1.5mm posterior, 0.5 mm lateral, and 3.3 mm ventral (Whishaw andJarrard, 1996). The control rats received anesthesiaonly.

Feeding
Feeding was restricted to maintain the rats at 90% of their expected body weights. Large (750 mg) rodent pellets (Bio-Serv,Frenchtown, NJ) were used for reward during behavioral testing.Rats reliably carry these pellets to a refuge for eating (Whishawet al., 1995a,b). After testing each day, the rats were supplementallyfed with LabDiet Laboratory Rodent Pellets in their homecage.

Apparatus
The open field consisted of a 204-cm-diameter circular wooden table, similar to a Barnes's spatial testing apparatus (Barnes,1979), that was painted white and elevated 64 cm above the floor(Whishaw and Maaswinkel, 1998). Eight 11.5-cm-diameter holes werecut in the table, spaced equidistant around its perimeter andcentered 13.5 cm from the table's edge (Fig. 1A). A cage, similarto a rat's home cage, could be inserted beneath a hole to serveas a refuge. The apparatus was located in a test room in whichmany cues, including windows covered by blinds, counters, a refrigerator,cupboards, a desk with computers, etc., were present. A camerawas located above the center of the table so that the behaviorof the animals could be videorecorded (Whishaw and Tomie, 1997).

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Figure 1. A, The foraging table showing the location of the refuge hole () and a string in one of its configurations with a food pellet located at its end. B, An example of the string that the rats tracked and food pellets that they carried back to the refuge. C, An example of a rat tracking along the string to the food pellet.

Strings and scent
The rats were trained to follow a scented string to the food pellet. The string was ~2 mm diameter, but pieces were of variablelength and were placed on the table to form varying patterns onthe table (Fig. 1A,B). The strings were scented with almond extract.The odor remained on the string for ~20 min after it was wipedonto the string with a soaked piece of cotton gauze. Preliminaryexperiments indicated that rats trained to follow the scentedstring (Fig. 1C) did not follow an odor tract left by a pieceof string that had just beenremoved.

Masks and blindfolds
Masks and blindfolds, used to control the rats use of visual cues, were constructed of felt and attached by a Velcro collarfixed around a rat's neck [see Whishaw and Maaswinkel (1998),their Fig. 2]. They were fastened across a rat's face by an elasticchin strap that was attached to the neck collar. The elastic strapwas flexible so that a rat could grasp food pellets with its mouthand chew and swallow them. A mask allowed the rats to see, whereasa blindfold occluded vision. The effectiveness of the blindfoldswas tested on rats trained to swim to a visible platform locatedin a swimming pool. Well trained rats wearing a mask swam directlyto the platform from any starting point on the periphery of thepool, whereas rats wearing the blindfold swam around the edgeof the pool or swam in a haphazard manner. The rats were adaptedto masks and blindfolds by having them wear the apparel for atleast 30 min/d for 5 d before testing. Before the formal tests,a mask or blindfold was placed on the animals for 30 min beforethetest.

Infrared testing
In addition to testing the rats while their vision was occluded by blindfolds, some of the experiments were performed underinfrared light. The test room was light proof, and the room lightswere turned off. Under infrared light, the animals' movementswere recorded with a Sony infrared camera. The experimenter usedan infrared spotter to orient in the testroom.

Training
All of the training was conducted with straight scented trails. A piece of string of variable length, scented with almondextract, was stretched from the edge of the refuge hole and ledto the food pellet (Fig. 1). Initially, the string was quite short(<10 cm) and led in different directions, but as the animals becameproficient in following the string, its length was increased toup to >150 cm. Training lasted ~14 d, by which time the rats wereproficient in following the string to retrieve food under bothmask and blindfoldedconditions.

Analysis
The behavior of the rats was filmed on all of the tests. From the ongoing trials and the video recordings the following behavioralmeasures weremade.
Correct trial. A correct trial was a trial during which a rat found a food pellet and returned directly to the starting holewithout stopping at any other potential exithole.
Retrieval. A retrieval was defined as an exit from the home cage and a return with a foodpellet.
Error. An incorrect trial was one during which a rat found a food pellet but stopped at one of the other potential exits beforereturning to the exit from which its excursion began. A rat wasdeemed to have stopped at an exit if its snout was brought towithin ~2 cm of a hole (errors were usually unambiguous becausethe rats stopped and inserted their heads into the holes). Insome experiments, if the rat followed the string home, ratherthan taking a more direct route, that was classified as aerror.
Travel distance. The outward and homeward distances were analyzed with a movement-tracking device to compute distancetraveled.
Response times. Using a stop watch, an observer recorded separately the time taken to find a food pellet and the time takento return to the home cage with thefood.
Heading angles. Measures of heading angles were made after a rat retrieved a food pellet and began its homeward trip. Oncethe rat had moved one body length with the food, the angle thatit was pointing, measured through the long axis of the animal'sbody relative to the most direct line to the refuge, wasmeasured.

Statistical analysis
Group comparisons were made using ANOVA's and t tests (Winer, 1962).

Histology
At the completion of the experiments, the rats were deeply anesthetized and perfused with saline and saline-formalin, andthe brains were removed and stored in a 30% sucrose-formalin solution.The brains were cut in 40 µm sections on a cryostat, and alternatesections were stained with cresyl violet and foracetylcholinesterase.

Procedure
Testing began once the rats were reliably following the string to retrieve the food. The following four tests wereadministered.
Return accuracy on a linear scent track. A scented string 125 cm long and an unscented string of the same length were bothstretched in a straight line on the table. The location of thestrings varied from trial to trial, and trials were given in apseudo-random order, with one trial given each day. Each rat receivedthree trials while wearing a mask and three trials while wearingablindfold.
Return accuracy on a linear track with scent removed. The rats were tested with strings of length 20, 30, 50, 100, and 150cm. Strings were placed on the table so that one end was at thetarget distance and the other led into the rats' refuge and thento the experimenter. Once a rat reached the food pellet, the stringwas gently pulled from the table. All of the rats received threetrials wearing masks and three trials wearing blindfolds at eachof the distances. Order of distance presentation varied from trialto trial as did stringdirection.
Return accuracy from a polygon scent track. The rats received four tests with the scented track positioned on the table ina polygon pattern (curved or angular). The length, direction,and pattern of the string arrangement were different for eachtest, but in all cases the distance home from the food locationwas much shorter than the string distance. For three tests, therats performed once with masks and once with blindfolds. For thefourth test, the rats wore no head gear, and one trial was givenin normal light and one trial was given in infraredlight.
Travel distance on an octagonal scent track. The string led from the refuge cage and then formed an octagon (75 cm diameter)in the center of the table. No food pellet was present. Each ratreceived one trial under room lights on 1 d and another trialunder infrared light on a second day. Once a rat reached the octagon,the string connecting the refuge with the octagon was removed.If a rat left the octagon and entered the refuge the trial wascomplete. If a rat completed four complete rotations around theoctagon, the trial was ended by removing therat.
Test from a novel location, with and without vision. Each rat completed two trials following the scented string from a novellocation. On one trial the rats wore a mask, and on the secondtrial they woreblindfolds.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Histological results

The dorsal fornix and the fimbria were completely sectioned in all of the rats that were given lesions (Fig. 2, top left vsright). The lesions were selective and did not damage the septum,the septal portions of the hippocampus, or the hippocampal commissure.The tract made by the electrodes and the lesion did a small amountof damage to the supracollasal septohippocampal pathways justabove the lesion and along the path made by the penetration. Previouswork has shown that supracallosal damage does not produce additionalimpairments on spatial tasks (Sutherland and Rodriguez, 1989;Jeltsch et al., 1994). Stains for acetylcholinesterase (AChE)revealed extensive depletion of AChE throughout the hippocampus(Fig. 2, bottom left vs right), a marker that serves to confirmthe completeness of the lesion. From previous work it is knownthat the lesion used in the present experiment reduces cholinergicmarkers by ~70% in the dorsal hippocampus (Cassel et al., 1991;Jeltsch et al., 1994), in addition to damaging many other afferentand efferent pathways.

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Figure 2. Photomicrographs of a control and lesion brain. Top, Cresyl violet sections shows the intact fimbria-fornix (FF) at the septal tip of the hippocampus (left) and an illustration of the absent fimbria-fornix (right). Bottom, Acetylcholinesterase sections through the hippocampus illustrating dense acetylcholinesterase staining in CA1 and dentate gyrus (left) and absence of staining in the FF lesion section (right). The slight cut in the left top of the cresyl violet section is an electrode tract.

General behavioral observations

After a rat in a refuge cage was placed beneath a hole, the rat typically poked its head out of the hole a number of timesbefore it exited. It exited by pulling itself up with its forepawsand pushing with its hind paws. Once on the table, it paused andscanned the table in search of the scented string. On its outwardjourneys it walked along the string, which it sniffed with lateralscanning motions of the head. If a rat deviated away from thestring, it quickly circled to relocate the string. Once a ratfound a piece of food, it grasped it in its mouth and set offfor the refuge. Once it arrived at the refuge, it inserted itshead into the hole and adjusted the position of its feet so thatit could drop down into the cage beneath the hole. In general,travel speed home was faster than travel speed out. If the ratwas wearing a mask its travel speed was slightly slower than whenit was sighted, both when tracking and returning to the refuge.Travel speed under infrared light was typically faster than travelspeed under masked conditions. In all of the experiments, themajor group differences were caused by the very poor performanceof the fimbria-fornix rats when they could not use vision or olfaction.Although the fimbria-fornix rats were able to return home quicklyin the light and to follow the string to the refuge in the absenceof vision, they became lost and frequently ate their food on thetable in the absence of thesecues.

Return accuracy on a linear scent track

To evaluate tracking accuracy, a straight scented string and a straight nonscented string were placed on the table. On alltrials, when masked and blindfolded, both the control and thefimbria-fornix rats followed the scented string to the food andignored the nonscented string. They also returned directly backto the refuge, along the path of the scented string. Figure 3illustrates the return paths of the control and fimbria-fornixrats on one tracking problem. Although there were no group differences,there were significant differences in response times. The ratswere faster in the mask than in the blindfolded condition (F_(1,10)= 10.4; p < 0.01), and they were faster in returning to the homecage with the food than they were in traveling out to the food(F_(1,10) = 2.7; p < 0.05).

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Figure 3. Illustrations of the homeward trajectories (solid lines) of the control (top) and fimbria-fornix (FF) rats along a scented string in the blindfold condition. The dotted line is a nonscented string.

Return accuracy on a linear track with scent removed

The rats were presented with strings of different length (Fig. 4A), and the strings were removed just as the rats graspedthe food, thus requiring that the rats return home without thescented track, either with vision or when blindfolded. The mainfindings were that the control rats were equally accurate in sightedand blindfolded conditions. When sighted, the fimbria-fornix ratsperformed almost as well as the control rats; when blindfolded,they made more errors, had longer return times, and had more deviantheading directions than they did when sighted and than did thecontrol rats.

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Figure 4. A, The rats traveled one of five linear distances to find a food pellet. The scent string was removed when they reached the food pellet. B, Errors as a function of distance on the return trip (mean and SE) consisted of a visit to an incorrect hole. C, Latencies to return home as a function of distance (mean and SE). FFB, Fimbria-fornix blindfold; FFV, fimbria-fornix vision; CV, control vision; CB, control blindfold.

Errors
A measure of errors, visits to incorrect holes on the return trip, gave significant effects of group (F_(1,10) = 26.1; p =0.005), visual condition (F_(1,10) = 23.8; p = 0.006), and visualcondition by group (F_(1,10) = 23.8; p = 0.006). All of these effectswere attributable to errors made by the fimbria-fornix rats (Fig.4B). There were also significant effects of distance traveledout versus back (F_(4,40) = 3.81; p = 0.01) and distance by group(F_(4,40) = 3.8; p = 0.01). The interaction effect was attributablemainly to the much poorer performance of the fimbria-fornix groupin the blindfolded condition than in the sighted condition. Thefimbria-fornix rats did make errors in the light, but these errorsoccurred mainly when the strings were adjacent to other holes,rather than when they occupied the center of the board. Sightedfimbria-fornix rats had a strong tendency to stop at incorrectholes if they were adjacent to their routehome.

Time
A measure of time taken to return to the refuge with the food gave a significant effect of group (F_(1,10) = 15.171; p = 0.003),visual condition (F_(1,10) = 15.5; p = 0.028), and visual conditionby group (F_(1,10) = 15.1; p = 0.003). All of the significant effectsof time were attributable to the slow returns of the fimbria-fornixrats when they were blindfolded (Fig. 4C). On many trials theylost their way, ate their food, and only reached the refuge afterhaphazard walks around the foraging table. Although the fimbria-fornixrats returned more quickly at the shortest distance, the effectof distance did not quite reach significance (F_(4,40) = 2.49;p = 0.058).

Heading angle
Heading angles, consisting of the direction the rat pointed after traveling one body length with the food relative to thestraight line direction to the food, are summarized by group,condition, and distance in Figure 5. There were significant effectsof group (F_(1,10) = 14.9; p = 0.003), visual condition (F_(1,10)= 13.8; p = 0.004), and visual condition by group (F_(1,10) = 13.1;p = 0.05). These effects were caused by the more deviant anglesof the rats with FF lesions. There were also significant effectsof distance traveled to reach the food (F_(4,40) = 4.44; p = 0.04)and distance traveled by group (F_(4,40) = 2.94; p = 0.03). Theseeffects were attributable to the more deviant heading angles ofthe blindfolded fimbria-fornix rats at longer distances.

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Figure 5. Turning angles of rats after food retrieval as a function of distance traveled to reach the food. Note that the fimbria-fornix rats were inaccurate at all distances when blindfolded.

Behavioral analysis
When the way in which the rats retrieved the food and turned toward home was examined, differences were observed between theturning movements made by control and fimbria-fornix rats (Fig.6). The control rats typically stretched forward to retrieve thefood and then recoiled along the main axis of their body so thatthey faced in the direction from which they had come. Forwardstretching was much less obvious in the fimbria-fornix rats, whichdid not recoil and turn but simply pivoted as they walked. Inblindfolded conditions, the first response of the fimbria-fornixrats with the food was often to begin to eat before attemptingto return home. Counts on whether the rats recoiled along theiroutward path or moved in some other direction gave a significantgroup effect (F_(1,10) = 39.2; p < 0.001).

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Figure 6. Turning strategies of control and fimbria-fornix rats on retrieving a food pellet when the scent string was removed. The control rat stretches forward to retrieve the food and then recoils backward and pivots to face the refuge. The fimbria-fornix rat walks over to the food and fails to pivot back to the return path.

Return accuracy from polygon scent tracks

The rats were tested on three polygons under masked and blindfolded conditions (Fig. 7A). Response times and distances outand back were averaged for the three problems. The main findingswere that the control rats took the most direct route home underboth masked and blindfolded conditions, whereas the fimbria-fornixrats took the direct route home only while they were sighted.An examination of the behavior of the rats showed that both controland fimbria-fornix rats tracked the string on the outward tripin both mask and blindfolded conditions. The control rats alwaysreturned directly to the starting hole via the shortest routeunder both visual and blindfolded conditions. The fimbria-fornixgroup returned directly home when sighted, but when blindfoldedthey followed the scent track home. Accordingly, the outward distancefor both groups of rats in both conditions was very similar tothe outward string length. The homeward distance for the controland sighted fimbria-fornix rats was very close to the shortestdistance back to the starting hole. The travel distance of theblindfolded fimbria-fornix rats was much longer than the stringdistance back. This was because many of the rats walked off courseand had to find their way back to the string, or else they circled,as if searching for the refuge, before they reached it.

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Figure 7. A, Three polygon string tracks that the rats were required to follow. B, Time (mean and SEs on the three problems) taken to travel to the food (Out) and return (Back) in control and fimbria-fornix (FF) rats in mask and blindfold conditions. C, Distance traveled to reach the food by control and fimbria-fornix rats in masked and blindfolded conditions. The top portion of the gray bars (Out) represents the distance to the food along the string. The bottom portion of the gray bars (Back) represents the shortest distance from the food to the home refuge. Note that the performance of the groups is quite similar and approximates the string out and shortest back distance, with the exceptions of the return back performance of the fimbria-fornix rats when blindfolded.

Masks or blindfolds

Travel times
Although there was no group effect for time (F_(1,20) = 3.39; p = 0.09, the effects of visual condition (F_(1,10) = 40; p =0.001) and direction traveled (F_(1,20) = 5.0; p = 0.49) were significant.The fimbria-fornix rats were faster on their outward trips thanwere the control rats, especially in the mask condition, and therewere no effects of blindfolding within the groups. What is perhapsmore important, the interactions between group and visual condition(F_(1,10) = 20.5; p = 0.001) and group by direction traveled (F_(1,10)= 10.8; p = 0.008) were significant. The interactions were attributableto slower returns in both control and fimbria-fornix rats in theblindfold condition and the especially slow return times for thefimbria-fornix rats in the blindfolded condition (Fig. 7B).

Travel distance
Analysis of the travel distance gave significant effects for all of the main effects, groups (F_(1,20) = 13.8; p = 0.004),visual condition (F_(1,10) = 24; p = 0.001), and direction (F_(1,20)= 16.3; p < 0.002). Outward travel distances in both groups inboth visual conditions were similar and approximated the stringdistance, but there were group differences in homeward distance,as indicated by the significant interactions between group byvisual condition (F_(1,10) = 14.92; p = 0.003), group by direction(F_(1,10) = 7.52; p = 0.001), and vision by direction (F_(1,10)= 5.9; p = 0.03). There was no effect of blindfolding on the homewardtrips of the control group, whose return trip approximated thedistance of the shortest route home, but the fimbria-fornix grouptook long routes when blindfolded (Fig. 7C).

Room or infrared light

The rats were given one polygon problem under room light and another under infrared light, and their return paths are illustratedin Figure 8. All six control rats returned directly to the homeunder light and dark conditions, whereas five of the fimbria-fornixrats returned directly home under light conditions. All of thefimbria-fornix rats returned home along the track in the dark(Fig. 8A). As occurred in the blindfold conditions, return latenciesfor the fimbria-fornix rats in the dark were significantly higherthan latencies for the fimbria-fornix rats in the light or forthe control group in either the light or dark (p < 0.01) (Fig.8B).

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Figure 8. A, Homeward trajectories for control and fimbria-fornix (FF) rats under room light and infrared light on one polygon string problem. Returns of fimbria-fornix rats were inaccurate in the dark, because they were largely following the scent string back to the refuge. Return latencies were mean and SEs. Note the significantly longer latencies of the fimbria-fornix rats under infrared light.

Travel distance on an octagonal track
The rats were allowed access to an octagonal tract via a string bridge. Once they were on the octagonal track, the connectingbridge to their home was removed (Fig. 9A). The control rats eachmade a single trip around the track, and when they arrived backat the starting location without finding food, they went to therefuge hole and entered the refuge cage. The fimbria-fornix ratsmade many trips around the octagon (Fig. 9B), and most were removedat the end of their fourth circuitry. Thus, the control rats madefewer circles around the octagon (control mean = 1 vs FF mean= 3.83) and spent much less time tracking the string (F_(1,10)= 15.3; p = 0.003) than did the fimbria-fornix rats (Fig. 9C).

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Figure 9. A, A string led from the refuge hole to an octagonal circuit on which there was no food. Once the rat was on the octagon, the string connecting it to the home cage was removed. B, Travel paths made by control and fimbria-fornix rats. Note that the control rats averaged one circle on the octagon before returning to the home cage, whereas the fimbria-fornix rats made many turns around the octagon. C, Time (mean and SE) spent traveling on the octagon for control and fimbria-fornix rats.

Test from a novel location, with and without vision
The return routes and choices made by control and fimbria-fornix rats in tests in which their refuge cage was moved to a newlocation are shown in Figure 10. When masked, all of the rats,with the exception of two control rats, returned to the familiarhome location (Fig. 10A). The two control rats returned directlyto the new home location. When blindfolded, all of the controlrats returned by fairly direct paths to the new location. Thefimbria-fornix rats were inaccurate and encountered incorrectlocations or returned to the new location by following the string(Fig. 10B).

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Figure 10. Paths and destinations of control and fimbria-fornix rats when the home cage was moved to a new location (shaded refuge). Note that in the mask condition in which the rats could see, most control rats and all fimbria-fornix rats carried the food to the old home location. In the blindfold condition in which the rats could not see, all control rats carried food to the new home location via a direct route, whereas fimbria-fornix rats reached other nearby holes or followed the string back to the new home location.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The experiments examined the contribution of the hippocampus to allothetic versus idiothetic navigation by exploiting a noveltask in which rats attempted to return home after following ascented string from their refuge to a food pellet located at theend of the string. Control rats navigated efficiently using bothallothetic and idiothetic cues. The rats with fimbria-fornix lesionssuccessfully navigated using allothetic cues but were impairedwhen forced to use idiothetic cues. These results are consistentwith the hypothesis that the integrity of the hippocampal formationis essential for idiothetic navigation.This may also be the firstdemonstration in tracking in an animal other than thedog.

Task demands

The novel feature of this study was the use of a scented string that allowed the subjects to track an odor trail to a foodpellet. The use of tracking facilitates an analysis of the rats'homing behavior in a number of ways. First, the rats' outwardpath and the cue are specified. Rats are very capable of usingsurface olfactory cues (Maaswinkel and Whishaw, 1999), and sothe use of a scented string forces them to focus on a particularcue. Second, all of the rats could be presented with exactly thesame outward journey. This removes the variability that occurswhen they take haphazard and individual outward routes in searchof randomly located food. The third, and perhaps the most important,feature of the procedure is that it was possible to determinewhen the rats switched cues and navigation strategies betweenthe outward and homewardtrip.

In the course of the study, the rats received a large number of tracking problems, which included linear tracks, polygon tracks,and an octagonal track. What was similar in all of the problems,however, was the comparison that was made between the rats' abilityto navigate home when they could use allothetic cues (vision orolfaction) and their ability to return home using idiothetic cues(when blindfolded or tested in infraredlight).

Cue use

When they were sighted, both the control and the fimbria-fornix rats traveled relatively directly home after a circuitousoutward trip. In doing so, they likely used stable visual roomcues to return to their home base. When blindfolded and presentedwith a polygon track, the control rats still took a relativelydirect route home, ignoring the scent track and thus "closingthe polygon." In doing so they were likely integrating the self-movementcues generated on the outwardtrip.

In contrast to the ability of the control rats to switch from an allothetic to an idiothetic navigation strategy, the fimbria-fornixrats' impairment in idiothetic navigation was starkly revealedwhen they wore blindfolds or were tested in infrared light. Ratherthan taking a direct route home after following a polygon track,they relocated the scent track and retraced its route back tothe starting location. Consequently, their homebound route wasas circuitous as their outbound route. This was not simply a matterof conveniently "taking an easy route home." When the scent trackwas removed, the fimbria-fornix rats became disoriented, ate theirfood on the table, and then walked around almost haphazardly untilthey regained the refuge. Thus, in a situation in which they wereforced to use idiothetic strategy, they were unable to do so.This result fails to confirm the suggestion that hippocampal ratspreferentially use idiothetic navigation strategies (Pearce etal., 1998).

The comparative behavior of the control and fimbria-fornix rats suggested that control rats may be prepared, and the fimbria-fornixrats may be unprepared, for making a direct homeward trip. Thefimbria-fornix rats' inability to reach home via a direct routewas apparent at all but the shortest outward trips. Nevertheless,after a trip of 20 cm (one body length), the fimbria-fornix ratscircled after finding the food pellet, so it was not possibleto demonstrate that they used an idiothetic strategy after eventhe shortest trip. The control rats also typically stretched forwardas they tracked and then recoiled after grasping the food pelletand so turned back along the axis of their body, thus reversingtheir trajectory. Their behavior seemed to suggest that they werealways anchored to the home base (Dudchenko et al., 1997; Martinet al., 1997). The fimbria-fornix rats walked over the food "asif they were going to pick it up and eat it on the spot" and thenturned in an almost haphazard direction once they grasped it,suggesting that they did not have a similar "homeanchor."

That both control and fimbria-fornix rats used visual cues was confirmed by a probe test in which the animals were startedfrom a novel location. Most of the control rats and all of thefimbria-fornix rats returned to the familiar location, thus signifyingthat they had previously learned that location in relation tovisual room cues. That the control rats could switch to an idiotheticstrategy was confirmed in a second probe trial in which the ratsstarted from a novel location when blindfolded. All of the controlrats returned to the novel location, whereas the fimbria-fornixrats tracked back along the string. The only strategy that wouldhave allowed the control rats to take a direct route home to anovel location isidiothetic.

Distance

The experiments also suggested that the fimbria-fornix rats did not know the homeward distance, confirming a result of a previousstudy that described impaired homing on a linear track of variabledistance (Whishaw, 1993). When blindfolded, the fimbria-fornixrats frequently picked up the food and circled as if looking forthe home base at that location. If they tracked home, they frequentlystopped and circled on the way, as if again looking for the home.To confirm they they displayed an impairment in distance estimates,the rats were given an octagonal track to follow on which therewas no food. It was hypothesized that once the rats had completeda tour around the octagon, they would realize that they had returnedto the proximity of the refuge and so would leave the track toreturn to the refuge. Although the control rats did return tothe refuge after a single turn on the track, the fimbria-fornixrats remained on the octagonal track and continued to circle untilthey wereremoved.

Allothetic versus idiothetic strategies

In a number of previous studies it has been demonstrated that rats with hippocampal damage can form place responses usingvisual cues (Whishaw and Jarrard, 1995, 1996; Whishaw et al.,1995b; Whishaw and Maaswinkel, 1998; L. D. Day, M. Weisend, R.J. Sutherland, T. Schallert, unpublished observation). This wasconfirmed in the present study. In fact, the ability of the fimbria-fornixrats to return to the home base using visual cues was essentialto the demonstration that they are impaired in idiothetic navigation.Nevertheless, it was interesting that even when they were sighted,the return routes of the fimbria-fornix rats were recognizablyless direct than those of the control rats. Possibly, the controlrats use allothetic and idiothetic strategies concurrently (Whishawand Mittleman, 1986; Dudchenko et al., 1997; Martin et al., 1997),whereas the fimbria-fornix rats are able to use only allotheticcues. The fimbria-fornix rats' dependence on allothetic cues wasmanifest in another way. They had a strong tendency to stop atincorrect refuge holes when the holes were adjacent to a homewardroute. It is well known that hippocampal rats are more stronglyresponsive to local cues than are control rats (O'Keefe and Nadel,1978), so that is likely that in learning to enter their homerefuge they developed strong tendencies to approach similar stimuliencounteredelsewhere.

Anatomical localization

The hippocampal formation is a complex of nuclei and pathways (Amaral and Witter, 1995), and there is behavioral evidencefor heterogeneity in its function (Grey and McNaughton, 1983;Jarrard, 1993; Sharp et al., 1995; Whishaw and Jarrard, 1995).Because fimbria-fornix lesions disconnect a number of hippocampalstructures, it is not possible to specify the structures thatare involved in idiothetic navigation. Cells that code head directionare found in subicular complex (Taube, 1990, 1995; Sharp, 1997),parietal and posterior cingulate cortex (Chen et al., 1994), thalamus(Mizumori and Williams, 1993; Taube, 1995), and striatum (Wiener,1996), suggesting a role for these structures in idiothetic navigation.On logical grounds, others have concluded that the behavior ofplace cells in the hippocampus proper suggests that they may alsoplay a role in idiothetic navigation (McNaughton et al., 1996).Future studies will have to separately assess the roles of differentanatomical structures on dissociative tasks such as the one usedin the presentstudy.

Conclusion

Contemporary research suggests that the hippocampus plays some central role in spatial navigation [but see Squire (1992)],but there are divergent views concerning this role (O'Keefe andNadel, 1978; Worden, 1992; Muller et al., 1996; Whishaw and Maaswinkel,1998). The present finding supports the idea that the hippocampusplays a role in idiothetic navigation. This conclusion is consistentwith previous suggestions that the hippocampus contains an innatespatial framework within which it can generate vectors betweenpoints (Whishaw et al., 1995a,b, 1997; McNaughton et al., 1996;Samsonovich and McNaughton, 1997). Although the present resultssupport a role for the hippocampus in idiothetic navigation, theyare not definitive in assigning this as an exclusive function.Hippocampal animals are also impaired in learning new allotheticspatial problems in which the demands of working memory are high(Shapiro and O'Connor, 1992; Angeli et al., 1993; Whishaw andJarrard, 1995, 1996). This may mean that idiothetic informationaids in the transition between one problem and the next (Whishawet al., 1997), or it may indicated that the impairment in idiotheticnavigation is but one aspect of a general hippocampal functionin spatial behavior and memory (O'Keefe and Nadel, 1978). Theresolution of this question must await more definitivestudies.

  FOOTNOTES

Received Nov. 11, 1998; revised March 10, 1999; accepted March 19, 1999.

This work was supported by the Medical Research Council ofCanada.
Correspondence should be addressed to Ian Q. Whishaw, Department of Psychology, University of Lethbridge, Lethbridge, Alberta,T1K 3M4,Canada.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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