Spatial Generalization of Learning in Smooth Pursuit Eye Movements: Implications for the Coordinate Frame and Sites of Learning

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The Journal of Neuroscience, June 1, 2002, 22(11):4728-4739

Spatial Generalization of Learning in Smooth Pursuit Eye Movements: Implications for the Coordinate Frame and Sites of Learning
I-han Chou and Stephen G. Lisberger
Howard Hughes Medical Institute, W. M. Keck Foundation Center for Integrative Neuroscience, and Department of Physiology, University of California, San Francisco, San Francisco, California 94143-0444

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have examined the underlying coordinate frame for pursuit learning by testing how broadly learning generalizes to differentretinal loci and directions of target motion. Learned changesin pursuit were induced using double steps of target speed. Monkeystracked a target that stepped obliquely away from the point offixation, then moved smoothly either leftward or rightward. Ineach experimental session, we adapted the response to targetsmoving in one direction across one locus of the visual field bychanging target speed during the initial catch-up saccade. Learningoccurred in both presaccadic and postsaccadic eye velocity. Thechanges were specific to the adapted direction and did not generalizeto the opposite direction of pursuit. To test the spatial scaleof learning, we examined the responses to targets that moved acrossdifferent parts of the visual field at the same velocity as thelearning targets. Learning generalized partially to motion presentedat untrained locations in the visual field, even those acrossthe vertical meridian. Experiments with two sets of learning trialsshowed interference between learning at different sites in thevisual field, suggesting that pursuit learning is not capableof spatial specificity. Our findings are consistent with the previoussuggestions that pursuit learning is encoded in an intermediaterepresentation that is neither strictly sensory nor strictly motor.Our data add the constraint that the site or sites of pursuitlearning must process visual information on a fairly large spatialscale that extends across the horizontal and verticalmeridians.

Key words: motor learning; frontal eye fields; arcuate pursuit area; sensory-motor interaction; MST; gain control

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Motor responses must adapt to changing sensory conditions on a daily basis. One form of motor learning can be observed insmooth pursuit eye movements, which are used by primates to trackmoving targets (for review, see Lisberger et al., 1987; Kellerand Heinen, 1991). Normally, the initial 100 msec of target motioncauses brisk eye acceleration in a direction and at a rate determinedprecisely by the target motion (Lisberger et al., 1981). Learningoccurs if targets move at an initial velocity for 100 msec andthen step to a different velocity. The visual input from the initialtarget motion is unchanged, yet the eye acceleration responseto this input gradually becomes more appropriate for the final,rather than the initial, target velocity (Carl and Gellman, 1987;Kahlon and Lisberger, 1996, 1999; Ogawa and Fujita, 1997).

We have been narrowing possible physiological sites for learning within the known circuitry for pursuit. Signals that guidepursuit eye movements arise in the middle temporal (MT) visualarea and pass through a number of cortical and subcortical areasto the cerebellum, which relays them to the final oculomotor pathwaysin the brainstem. Our previous papers (Kahlon and Lisberger, 1996,1999) implied that learning is in a coordinate system that isneither purely visual nor purely eye movement. They suggesteda locus of learning downstream from MT and upstream from cerebellaroutputs. Possible sites include the medial superior temporal area(MST), frontal pursuit area (FPA), dorsolateral and dorsomedialpontine nuclei (DLPN), the nucleus reticularis tegmenti pontis(NRTP), and the cerebellarcortex.

In the current study, we investigate the spatial scale of information processing at the site or sites of learning by askinghow broadly pursuit learning generalizes across the visual field.Our experimental design was based on the fact that neurons inMT have small receptive fields primarily confined to the contralateralvisual field (Van Essen et al., 1981; Desimone and Ungerleider,1986), whereas MST neurons have a range of receptive field sizes,including large receptive fields that can extend far into theipsilateral visual field (Komatsu and Wurtz, 1988). If learningwere specific to a narrow region of visual field around the siteof the adapting stimulus, for example, we would conclude thatlearning is induced at a site where visual space is representedin small receptive fields, such as the synapses from MT onto targetssuch as MST or FPA. Such a finding would call into serious doubtthe common belief that motor learning for pursuit occurs in thecerebellum, as it seems to for other motor systems (Ito, 1976;Raymond et al., 1996).

Our approach was to induce learning with target motion across a given position in the visual field and test for generalizationto targets that moved across other regions of the visual field.The data revealed that generalization was incomplete, but oftenextended to positions in the visual field across the verticalmeridian. Our data support the conclusion that the site or sitesof learning are downstream from MT, in areas that process informationon a spatial scale including both visualhemifields.

Part of this work has been presented in a preliminary report (Chou and Lisberger, 2000).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Five rhesus monkeys (Macaca mulatta) served as subjects. Three of the monkeys had participated in previous studies of pursuitlearning. The remaining two were naive to pursuit learning paradigms.Monkeys were first trained to sit in a primate chair and to attendto spots of light. After training, head restraints and scleralsearch coils were implanted surgically (c.f. Judge et al., 1980).All surgeries were performed using sterile procedure with isofluoraneanesthesia. Appropriate analgesic and antibiotic treatments wereadministered postoperatively. After recovery from surgery, themonkeys were trained to sit with their heads restrained facinga display screen and to fixate and track spots of light that steppedaway from the point of fixation and/or moved across the visualfield. Each experimental session lasted ~2 hr, during which theanimals worked for fluid reinforcement to satiation. All proceduresconformed to the National Institutes of Health Guide for the Careand Use of Laboratory Animals and had been approved in advanceby the Institutional Animal Care and Use Committee at Universityof California SanFrancisco.

Moving and stationary visual targets were presented either on an analog oscilloscope or using a mirror-galvanometer projectionsystem, with the same results. Targets presented on an analogoscilloscope (Hewlett Packard 1304a) appeared as bright 0.4° squareson a dark background. The nominal spatial resolution of the display,defined by the resolution of the 16-bit digital-to-analog convertersthat drove it, was 65,536 × 65,536 pixels. The display was positioned35 cm in front of the monkey and subtended 36 × 30° of visualangle. Because the display was rectangular and the number of pixelsused to create the output signals was the same in each dimension,the spatial increment of each pixel was slightly different inthe horizontal and vertical dimensions. Targets presented withthe mirror galvanometer system subtended ~0.5°. They were createdby imaging the light beam from a fiber optic light source ontoa pair of mirrors and projecting the beam onto the back of a largetangent screen placed 114 cm from the monkeys' eyes, subtending~50 × 40°. Target position was controlled by setting the positionof the mirrors with a pair of galvanometers (General Scanning).The movement of one eye was monitored using a scleral search coilsystem from CNC Engineering. All experiments were performed indim ambientlighting.

Data acquisition and sequences of target motion were controlled by software running on a combination of a DEC Alpha UNIX workstationand a 500 MHz Pentium-based PC running Windows NT and VenturComRTX. The PC performed all real-time operations and controlledthe visual displays, whereas the UNIX workstation provided a userinterface for easy programming and modification of the experiment.Analog signals proportional to horizontal and vertical eye positionwere differentiated by an analog circuit that provided differentiationfor signals up to 25 Hz and rejected signals of higher frequencies( $-$ 20 db/decade). Position and velocity signals and other codesrelated to the timing of trial events were digitized at 1000 samples/secon each channel and stored for lateranalysis.

Experimental design
Previous studies in monkeys have examined learning in the initiation phase of pursuit and used targets that appeared a fewdegrees eccentric to the position of fixation and moved towardthe position of fixation (Kahlon and Lisberger, 1996, 2000). Suchtarget configurations are not optimal for studying spatial generalizationof learning because they require a strict relationship betweenthe initial location of the target and the direction of targetmotion. Therefore, the first goal of the current study was touse targets that moved in a variety of directions relative tothe position of fixation and to characterize the effects of learningon presaccadic and postsaccadic eye velocity. Experiments consistedof a series of trials, each of which lasted ~2 sec. At the startof each trial, a stationary target appeared on the display, andmonkeys were required to fixate within a 2 × 2° window for aninterval that was randomized between 800 and 1000 msec. The targetthen underwent an oblique position step and began moving horizontallyeither toward or away from the vertical meridian. These step-rampstimuli always required both saccadic and smooth tracking. Themonkeys were allowed 350 msec to acquire the target and then hadto maintain gaze within a 2 × 2° window centered on the target.If the monkeys kept their gaze within the window around the targetthroughout the duration of target motion, they received a fluidreinforcement.
Each experiment comprised three blocks of trials (Fig. 1). The initial, "baseline" block delivered ~200 trials designed toprovide a prelearning assessment of pursuit by having the targetmove in the basic step-ramp manner described above for both rightwardand leftward target motion. The second "learning" block consistedof 600-800 trials. For each experiment, 50% of the trials were"learning trials" that provided double steps of target velocityin a single direction chosen as the "learning direction." We controlledthe time of the second step of target velocity by having the computersense the rapid deflection of eye velocity associated with thesaccade as the time when eye velocity exceeded 50°/sec and invokethe change in target velocity at that time. The remaining trialsin the learning block were "control trials" that provided singlesteps of target velocity in the nonadapted direction (25% of trials),and "probe trials" in which the target moved in the learning direction(25% of trials) without the intrasaccadic velocity step. The thirdand final "recovery" block provided control and probe trials torecord the recovery from any learning. Experiments were designedto either increase or decrease the eye velocity at the initiationof pursuit. For increase-velocity experiments, the target hadan initial velocity of 10°/sec, and the intrasaccadic step increasedvelocity to 30°/sec. For decrease-velocity experiments, the targethad an initial velocity of 25°/sec, and the intrasaccadic stepdecreased velocity to 5°/sec.

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Figure 1. Schematic representation of the basic learning paradigm. This example experiment was designed to increase rightward eye velocity. Trials began by having the monkey fixate a peripheral spot at the location indicated by the plus signs for 800-1200 msec. A target then appeared in the center of the screen, at the location indicated by the circles, and immediately began to move smoothly to the right or the left. Baseline block: trials present target motion at a single speed to the left or the right. Learning block: 50% of the trials are "learning trials" in which the target moved at one speed before the first saccade and a second speed after the saccade. The remaining trials in the learning block were "probe trials," in which the target moved in the learning direction but did not change speeds during the saccade and "control trials," in which the target moved in the opposite direction. Recovery block: same blend of trials as in the baseline block. In all velocity traces, upward and downward deflections represent rightward and leftward target velocities, respectively.

Each daily experiment used one of several different learning paradigms, each customized to answer a specific question aboutthe spatial generalization oflearning.
Paradigm 1. The fixation target appeared at straight-ahead gaze. The target step was always 5° right and 5° up, and the targetcould then move to either the left or the right, toward or awayfrom the vertical meridian. Learning trials provided an intrasaccadicchange in target velocity for only one of the two directions.The configuration of trials for this paradigm is shown in Figure1.
Paradigm 2. The fixation target appeared in one of four possible positions, located at the corners of a 10 × 10° square thatwas centered in front of the monkey. The target then underwenta position step to the center of the screen and began to moveto the right or left. As a result, targets moved to the rightor left across positions that were just over 7° eccentric in thefour quadrants of the visual field. In the learning block, intrasaccadicchanges in target velocity were provided for only one combinationof position in the visual field and direction of target motion.Over the course of experiments on each monkey, however, all combinationsof initial target position and direction of target motion weretested for effects oflearning.
Paradigm 3. The fixation target appeared in one of 10 possible positions, located along a diagonal line passing through thecenter of the screen. As in paradigm two, the target stepped tothe center and began to move to the left or right. Fixation positionswere chosen so that pursuit targets moved across positions thatwere 3-11° eccentric in the visual field. In one set of experiments,there was only one learning block, in which an intrasaccadic changein target velocity occurred for targets at one position that was5 or 7° eccentric in the visual field. In another set of experiments,two learning blocks were run. In the first, learning trials werepresented at a single location 5° eccentric. In the second learningblock, two types of learning trials presented targets at two differentlocations: for the learning trials, the moving stimulus started5° in either the right/up or left/down quadrant of the visualfield.

Data analysis
For each successfully completed trial, eye position and velocity traces were displayed on a computer screen, and the startand ending times of the first saccade after target motion onsetwere marked using a combination of software and visual inspection.We used a computer algorithm to detect two time points, firstwhere eye velocity rose above and second where it fell below 50°/sec.We then defined the saccade onset and offset times as 15 msecbefore the first and 15 msec after the second time point. To confirmthat the saccade onset and offset times determined by this automatedalgorithm corresponded closely to those defined by human users,the traces for each trial were checked individually by visualinspection and corrected if necessary. Trials were discarded ifthe saccade was initiated with a latency of <80 msec after theonset of target motion, because these were deemed to be anticipatoryrather than responses to the motion of the tracking target. Trialscontaining anticipatory saccades were rare, constituting <1% ofthe sample. All analyses of eye velocity and statistics were performedusing Matlab (The MathworksInc).
To analyze learning, presaccadic and postsaccadic horizontal eye velocity were estimated by calculating the average eye velocityover the 10 msec immediately before and after the saccade, respectively.Lisberger (1998) provided a detailed analysis of the filteringissues associated with making a measurement in the immediate wakeof a saccade and verified that the techniques we used are appropriateand would be difficult to improve on. For each experimental session,both the significance and magnitude of learning were assessedin presaccadic and postsaccadic eye velocity. Two-tailed Student'st tests were used to compare the responses in probe trials inthe baseline block and near the end of the learning blocks (criterion,p < 0.05). To assess the magnitude of changes in each experiment,we computed the "learning ratio," defined as mean eye velocityin the last 20 probe trials of the learning block divided by themean eye velocity in the baseline block. In analyses in whichwe compared the learning ratios for different conditions, we reportgeometric means and performed statistics on the logarithms ofthe learningratios.
To analyze the latency of pursuit, we computed average eye velocity traces for responses to identical target motions, alignedon the onset of target motion. Data from intervals that containeda saccade were omitted from the average. Thus, there could bea different number of samples in each bin of the average, andsome bins might contain very few samples: we did not compute anaverage eye velocity unless a bin included data from at leasteight trials. We then used the technique of Carl and Gellman (1987)to estimate the latency of pursuit. Regression lines were fitto two segments taken from the mean eye velocity traces. The firstsegment comprised the 40 msec surrounding the onset of targetmotion, when the eyes are essentially stationary; the second segmentcomprised the 40 msec after eye velocity rose 3 SD above the meanvelocity in the first segment. The time of pursuit onset was takento be the point where the two regression linesintersected.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Postsaccadic pursuit learning in a task designed for studying spatial generalization

Earlier work from our laboratory has studied pursuit learning only for targets that moved from eccentric positions towardthe position of fixation (Kahlon and Lisberger, 1996). This conditionproduces saccade-free initial pursuit and allows easy analysisof the presaccadic initiation of pursuit. However, it has thedrawbacks that it requires an unnatural combination of initialtarget position and motion and that it precludes analysis of thespatial generalization of learning for targets moving with a givenspeed and direction across different parts of the visual field.Therefore, we start by analyzing pursuit learning for targetswith initial positions and motions that required combinationsof saccades and smooth pursuit to achieve accurate tracking. Theseexperiments were done with paradigm 1, as described in MaterialsandMethods.

Figure 2 shows example eye position and velocity traces from single trials recorded early (black traces) and late (gray traces)in the learning block of an increase-velocity experiment: targetvelocity increased from 10 to 30°/sec during the first trackingsaccade for rightward target motion. During the first few learningtrials (Fig. 2A, black trace), post-saccadic eye velocity matchedor exceeded only slightly the target velocity present before thesaccade, although target velocity had stepped from 10 to 30°/secduring the saccade. At the time indicated by the vertical arrowon the eye velocity trace, ~60 msec after the end of the firstsaccade, a rapid eye acceleration corrected the mismatch betweeneye and target velocity introduced by the velocity step. The visibilityof this transition provides an example of a point that will beaddressed quantitatively below: the first 60 msec of the post-saccadicresponse is driven by the target motion present before the saccade.In spite of the brisk correction of smooth eye velocity, therewas still a residual position error that was then corrected bya small saccade (oblique arrow on position traces). After >100repetitions of the learning stimulus (gray trace), postsaccadiceye velocity had grown and was closer to the final target velocitythan in the first few learning trials. Because the smooth eyemovements were larger than at the outset of learning, the catch-upsaccade in the eye position record was later and smaller thanin the earlier trial. We did not observe the appearance of anticipatorypursuit, probably because both the direction and onset time ofthe target were randomized.

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Figure 2. Examples of eye movements in learning and probe trials before and after learning. A, Increase-velocity learning trials. The target (dashed lines) stepped obliquely away from the fixation point and began moving at 10°/sec. When the computer detected the onset of the first tracking saccade, the target velocity was stepped up to 30°/sec. B, Probe trials from the same experiment as the learning trial. The target moved at a constant 10°/sec. From top to bottom, the traces are as follows: superimposed eye and target velocity and superimposed eye and target position in the bottom figures. Black and gray traces show data from one trial before and after learning, respectively. The pairs of vertical lines on the velocity traces in B show the interval over which we measured postsaccadic eye velocity. T and E represent target and eye data, respectively.

Adaptive changes generalized to both presaccadic and postsaccadic eye velocity in the probe trials (Fig. 2B), which did notcontain an intrasaccadic step of target velocity and continuedto move at 10°/sec after the first tracking saccade. Postsaccadicvelocity matched target velocity almost perfectly in the firstfew probe trials in the learning block (black trace). At the endof the learning block, however, postsaccadic eye velocity hadincreased and was almost twice target velocity. As a result ofthe large smooth eye velocity, eye position passed the target,and a backwards corrective saccade was needed to achieve accuratetracking (Fig. 2B, downward arrow on positiontraces).

Throughout the paper, we examine how learning affects eye velocity in the 10 msec immediately after the end of the catch-upsaccade. The analyses we have used are based on the assumptionthat postsaccadic eye velocity is driven by presaccadic visualsignals. For each of 16 experiments, we tested this assumptionby asking when postsaccadic visual stimuli have their first effecton eye velocity. This time was assessed by comparing the averageeye velocity from probe trials with that from interleaved learningtrials. These trials provide identical stimuli until the targetchanges velocity during the saccade; the time when the responsesseparate should indicate when postsaccadic visual stimuli firstaffect eye velocity. Figure 3A shows an example from a singleexperiment. Data were analyzed by making separate averages ofthe last 200 msec of eye velocity before saccade onset and thefirst 200 msec of eye velocity after saccade end, for all trialsin the learning block of each experiment. Inspection of Figure3A gives the impression that the averages for trials with andwithout an intrasaccadic change in target velocity (gray vs blacktraces) diverged at the time shown by the upward arrow, 56 msecafter the end of the saccades. We verified this estimate by performinga running t test on each pair of averaged traces to determinethe time point at which they diverged significantly. Across all16 experiments, the mean time of divergence was 55 ± 9 msec. Thisconfirms that the eye velocity in the first 10 msec after theend of the saccade is appropriate for assaying the pursuit responseto visual inputs present before the saccade.

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Figure 3. Summary of effects of learning in postsaccadic eye velocity. A, Demonstration that the postsaccadic analysis interval is driven by visual inputs from before the saccade. The solid traces show the mean eye velocity from learning trials (gray line) and probe trials (black line) from a single experiment. Dashed traces represent SD. Traces to the left and right of the vertical lines show eye velocity aligned to the start and end of the saccade, respectively. B, Postsaccadic eye velocity after learning is plotted as a function of eye velocity at the same time before learning. Each point shows data from one experiment. The y-axis plots the mean eye velocity in the last 20 probe trials in the adaptation block. The x-axis plots the mean eye velocity in the same type of trials in the baseline block. The diagonal line has a slope of one and would obtain if learning caused no change in eye velocity. Squares and triangles show results of increase-velocity and decrease-velocity experiments, respectively. Filled symbols indicate experiments in which learning caused statistically significant changes in eye velocity (t test; p < 0.05), and open symbols show experiments in which changes were not significant.

We studied learning in 18 experiments designed to increase eye velocity (Fig. 3B, squares) and 14 designed to decrease eyevelocity (Fig. 3B, triangles) in five animals. Plotting mean postsaccadiceye velocity for the last 20 probe trials of the learning blockas a function of that in the baseline block revealed that allexperiments caused learning in the appropriate direction. Eyevelocity was larger after than before the learning for increase-velocitylearning trials (squares) and was smaller after the learning fordecrease-velocity learning trials (triangles). The changes inpostsaccadic eye velocity were statistically significant in almostall experiments (30 of 32) (Fig. 3B, filled symbols). In differentexperiments in this series, learning was induced for horizontaltarget motion that started either above or below the horizontalmeridian and moved either toward or away from the vertical meridian.The magnitude and statistical significance of learning in postsaccadiceye velocity was not dependent on these parameters of the learningtargetmotion.

Spatial generalization of learning

We next tested the generalization of learning to target motion in the same direction as the adapting stimulus, but startingin different visual quadrants. Paradigm 2, described in Materialsand Methods, was used. As shown by the insets in the four panelsof Figure 4, the tracking target moved across the same eccentricityin the four quadrants of the visual field. Learning trials werepresented for only one direction of target motion (rightward orleftward) at only one visual field position. Probe and controltrials were presented in all four quadrants of the visual fieldand provided motion in either the learning or control direction,respectively.

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Figure 4. Examples of responses to probe target motion presented in different retinal locations after learning at one location. Each panel superimposes examples of horizontal eye velocity traces from single probe trials before learning (black traces) and after learning (gray traces). The dashed trace shows target velocity in the probe trials. The inset in each graph shows the relative position in the visual field of the probe target, shown by the arrow, and fixation point, shown by the plus sign. A, Probe target is in the same visual field location of the learning stimulus. B, Probe target is in the same vertical visual hemifield as the adapted location. C, Probe target is in the same horizontal visual hemifield as the adapted location. D, Probe target is in opposite visual quadrant to the adapted location. In each trial, the probe target was 7° eccentric in the visual field.

The traces in Figure 4 are examples of responses in single trials, chosen to illustrate the results of an increase-velocityexperiment for targets starting in the top right quadrant of thevisual field. The eye velocity traces in Figure 4A show examplesof the response in probe trials presenting rightward target motionfrom the adapting position in the visual field before (black traces)and after (gray traces) learning. Figure 4B-D shows examples ofthe eye velocity responses to rightward probe trials for the threeother target positions in the visual field, where the learningstimulus was not shown. For these examples, the effect of learningon the postsaccadic eye velocity was greatest when the probe trialprovided target motion in the visual field position of the learningstimulus (Fig. 4A), but was also present when the probe trialprovided target motion in the other three quadrants of the visualfield (Fig. 4B-D).

Learning generalized to targets presented in all of the test quadrants, but generalization was more nearly complete for increase-velocitythan for decrease-velocity experiments. For each experiment, wequantified the generalization of learning across the visual fieldby computing the learning ratio for probe trials with targetsstarting in each of the four visual quadrants. In Figure 5, eachgraph shows the distribution of learning ratios for probe trialsin each quadrant, where the quadrants of the visual field fromeach experiment have been rearranged so that results from theadapting quadrant are shown in the top left graph (Fig. 5A). Eachhistogram shows the results from increase-velocity and decrease-velocityexperiments as upward and downward histogram bars, respectively.Of the 23 experiments, two have been omitted from this analysisbecause they did not provide statistically significant changesin postsaccadic eye velocity even with the target in the adaptingquadrant.

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Figure 5. Generalization of learning to unadapted retinal locations. Each set of histograms shows the distribution of the learning ratio for probe trials in a particular retinal location. Upward black bars and downward gray bars show results for increase and decrease velocity experiments, respectively. For each distribution, the location of the dashed line and its label give the geometric mean of the learning ratio. The distributions with asterisks after the mean were significantly greater or smaller than 1 (one-sided t test against 1; p < 0.01). A, Distributions of learning ratio for probe targets at the adapted location. B, Probe targets in the same vertical hemifield but opposite horizontal hemifield to adapted location. C, Probe targets in the same horizontal hemifield but opposite vertical hemifield. D, Probe targets in opposite visual quadrant to adapted stimulus.

For increase-velocity experiments, changes in postsaccadic velocity occurred in all quadrants, as can be seen from the distributionsof learning ratios. The upward histograms in Figure 5 show geometric-meanlearning ratios of 1.78 in the adapting quadrant (Fig. 5A) andof 1.52, 1.58, and 1.48 in the other three quadrants. All of thesevalues were significantly >1.0 (t test; p < 0.01). ANOVA revealedthat there was no statistically significant effect of quadranton the magnitude oflearning.

For decrease-velocity experiments, learning did not generalize completely to all test quadrants. The downward histograms inFigure 5 reveal a learning ratio that averaged 0.65 for the adaptingquadrant (Fig. 5A), but ratios of 0.88, 0.87, and 0.95 in thetest quadrants. In the three test quadrants, the learning wassignificant in Figure 5, B and C (t test; p < 0.01), but not inFigure 5D, when the probe targets appeared in the opposite verticaland horizontal visual hemifield relative to the learning target.ANOVA revealed a significant effect (p < 0.01) of quadrant onthe learning ratio when all quadrants were examined (adaptingplus all test), because learning was attenuated in all of thetest quadrants, relative to the adapting quadrant. When the analysiswas repeated on just the test quadrants (i.e., compare Fig. 5B-D),there was no significant effect (p > 0.05).

Figure 6 provides a quantitative summary of the generalization of learning across quadrants within each experiment. Becausethe analyses described above showed no significant differencesbetween the three individual test quadrants, the data from thethree test quadrants were averaged for each daily experiment.Each point plots data from a single experiment and shows the arithmetic-meanlearning ratio in the test quadrants as a function of the learningratio in the adapting quadrant. If learning were independent ofthe quadrant in which the target was presented, then the learningratios should be the same for all target motions in the learningdirection, and the data from all our experiments should fall onthe line of slope 1 (Fig. 6, "complete generalization"). If, onthe other hand, learning were specific to the adapting quadrant,then learning should have been present only when the probe targetswere presented in that quadrant and the learning ratio shouldbe one in the test quadrants: all the data should fall along thehorizontal line (Fig. 6, "no generalization").

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Figure 6. Summary of generalization of learning across quadrants. The learning ratio averaged over all probe trials at unadapted locations in the visual field is plotted against learning ratio of the adapted step. Each symbol shows data for one experiment. Black square and gray triangles plot data for increase-velocity and decrease-velocity experiments, respectively. The two solid lines have slopes of 0 and 1 and would obtain if generalization were absent or complete, respectively.

The actual data are not consistent with the predictions of either "complete generalization" or "no generalization." For decrease-velocityexperiments (gray triangles), the data fall somewhere betweenthese two predictions. For increase-velocity experiments (darksquares), most of the data fall between the two lines, but intwo experiments, the learning ratios were higher in the test quadrantsthan in the adapting quadrant, suggesting that in those experiments,generalization of learning was complete. Separate regression analyseswere performed to find the best slope fit for increase and decrease-velocityexperiments. For decrease experiments, the slope of the regressionwas 0.41, which was significantly different from both 0 and 1.For increase experiments, the data were not well described bya linear relationship, so the regression did not yield a meaningfuldescription of thedata.

Probe of spatial generalization on a finer scale

To examine whether learning declined smoothly or abruptly as a function of the distance between the starting retinal positionsof the learning and test motions, we used paradigm 3 (see Materialsand Methods) to induce learning at a single location in the visualfield and probe learning with target motions at multiple locations.The trial configuration for these experiments is shown in Figure7A. As before, the target moved either leftward or rightward fromthe center of the screen, and its location in the visual fieldwas varied by using different positions for the fixation spot(Fig. 7A, open circles).

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Figure 7. Evaluation of the spatial generalization of learning on a finer grid. A, Target configuration for learning generalization experiments. The circles show the different fixation points, and the cross shows the initial position and possible motion of the tracking targets. B, Learning ratio is plotted as a function of the spatial separation between the learning stimulus and the test stimulus. Black and gray symbols show data for increase-velocity and decrease-velocity learning paradigms. Small filled symbols show the learning ratios from each individual experiment. Open symbols connected by lines show the geometric mean of the learning ratios across experiments. The learning stimulus was presented at zero on the x-axis, with represents a position either 5 or 7° eccentric in the visual field in different experiments. Learning ratios generated to increase learning (black squares) and decrease learning (gray triangles). The results have been arranged such that 0 represents the location of the learning stimulus. In some experiments, the learning stimulus was presented when the fixation point was placed 5° from the center, and in others, the fixation point was 7° from center.

The results from 10 velocity-increase and 10 velocity-decrease experiments were more consistent with a smooth change in spatialgeneralization as a function of the position of the target inthe visual field. In Figure 7B, the abscissa represents the spatialseparation between the location of the test stimulus and the learningstimulus, in degrees of visual angle. The ordinate plots the learningratio for probe trials presented at each location. Unconnectedpoints summarize individual experiments, whereas symbols connectedby lines present grand averages accumulated across experimentsthat used identical stimuli. For both increase-velocity (blacksymbols) and decrease-velocity (gray symbols) experiments, thelargest learning effects were observed at the location of thelearning target motion (zero on the x-axis). There was considerablevariability in the exact values of the learning ratios from day-to-day,but the averages show that learning declined gradually as a functionof the separation of learning and test targets. As we also demonstratedin Figure 5, learning generalized more completely to the oppositequadrant (points plotting to the left of the vertical dashed line)for increase-velocity learning than for decrease-velocity learning.Nonetheless, across all experiments, we observed some generalizationto targets as far as 18° from the adapting location. The reliabilityof the impressions gained from the averaged data are supportedby the separation in the distributions of learning ratios forincrease-velocity and decrease-velocity learning at everylocation.

Interference of two learning stimuli at different visual field locations

To ask whether pursuit learning could be more specific spatially when given appropriate stimulus conditions, we next createda set of experiments that mixed learning trials designed to causeincrease-velocity learning for targets at one location and decrease-velocitylearning for targets at another location. We probed the generalizationof learning with paradigm 3 (see Materials and Methods), whichpresented test target motions at 2° spatial intervals in the vicinityof the learning stimuli. To compare directly the spatial extentof generalization for one versus two learning stimuli, each experimentconsisted of two learning blocks. As illustrated in the top diagramin Figure 8A, the first learning block contained a single learningstimulus in a single location 5° eccentric in the visual quadrant,as in previous experiments. The second block added a second learningstimulus at location that was 5° eccentric in the opposite visualquadrant. Thus, this block contained trials that presented learningstimuli at two target locations separated by 10° (Fig. 8A, bottomdiagram). Trials containing the two learning stimuli were presentedwith equal frequency during the second learning block, and thesecond learning block was twice as long as the first, so thatthe number of presentations of the second learning stimulus wouldmatch that of the first stimulus in the first block. The secondlearning stimulus always required the opposite change in velocityas the first. For example, if we provided an increase-velocitylearning stimulus in the first learning block, then we added adecrease-velocity learning stimulus in the second learning block.We termed each experiment "increase-first" or "decrease-first"depending on the direction of the change in eye velocity producedby the first learning stimulus.

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Figure 8. Interference of learning when increase-velocity and decrease-velocity trials were presented at different visual field locations. A, Schematic diagram showing the target velocity (solid traces on the left) and position (schematic on right) for the learning trials presented during increase-first learning experiments. B, Summary of six increase-first experiments. The first learning block contained increase-velocity learning trials at one location. The second learning block contained increase- velocity trials at the original visual field location and decrease-velocity trials in the opposite quadrant of the visual field. C, Summary of seven decrease-first experiments. The first learning block contained decrease-velocity learning trials at one location. The second learning block contained decrease-velocity trials at the original visual field location and increase-velocity trials in the opposite quadrant of the visual field. In the graphs in B and C, learning ratio is plotted as a function of the position of the test stimulus in the visual field, relative to the location of the learning trials in the first learning block. Thus, the first learning stimulus was located at zero on the x-axis and the second learning stimulus at $-$ 10. Black and gray symbols show the generalization of learning after the first and second learning blocks. Small filled symbols show the learning ratios from each individual experiment. Open symbols connected by lines show the geometric mean of the learning ratios across experiments.

We observed interference between learning at visual field locations separated by 10°, at least when the two locations werein opposite quadrants of the visual field. Consider the "increase-first"experiment summarized in Figure 8B. The results of the first learningblock, with increase-velocity learning trials (black symbols),were compatible with earlier graphs (Fig. 7B, black symbols).Learning was excellent. It caused a large increase in postsaccadiceye velocity when tested at the location of the learning stimulus(downward arrow labeled "increase"), generalized well to nearbylocations, and generalized more weakly when tested in the oppositevisual quadrant (points plotted to the left of the vertical dashedline). In the second learning block, the competition caused bya decrease-velocity learning stimulus in the opposite visual quadrantcaused a decrease in postsaccadic eye velocity in that quadrant(gray symbols to the left of the vertical dashed line). It reduced,but did not eliminate the pre-existing learning in the quadrantthat was the site of the increase-velocity learning stimuli inboth learning blocks (symbols plotted to the right of the verticaldashed line).

Comparison of probe trials from learning blocks with two opposing stimuli versus learning blocks with just one learning stimulusreveals that learning was stronger when learning stimuli wereapplied at only one location. For example, the mean learning ratiofor decrease-velocity learning applied after increase learningwas 0.9 (Fig. 8B, gray symbol at upward vertical arrow labeled"decrease"), compared with 0.72 when decrease-velocity trialswere presented without increase-velocity trials (Fig. 8C, blacksymbol at upward vertical arrow labeled "decrease"). In the companiondecrease-first experiments (Fig. 8C), the mean learning ratiowas 1.40 after the second learning block (Fig. 8C, gray symbolat downward arrow labeled "increase") compared with 1.56 afterincrease-velocity learning trials alone in the same quadrant ofthe visual field (Fig. 8B, black symbol at downward arrow labeled"increase"). Furthermore, for both increase-first and decrease-firstexperiments, the competition from the second set of learning trialsattenuated the learning at the location of the first set of learningtrials. The latter attenuation can be appreciated by comparingthe gray and black symbols at the downward arrow labeled "increase"in Figure 8B and the upward arrow labeled decrease in Figure 8C.

These experiments provide several general observations. (1) For both types of experiment, the largest effect of the secondlearning block was at or near the location of the second learningstimulus (Fig. 8B,C, vertical arrows in left-hand side). (2) Thesecond learning block affected the pre-existing learning at thevisual field location of the first learning stimulus (positivevalues on the x-axis) in the right direction. (3) The effect wasconsistently smaller at the location of the first learning stimulus,because each learning stimulus predominated in the visual quadrantwhere it was presented. Thus, the spatial extent of the competitionbetween two learning stimuli shows broad agreement with the spatialextent of generalization to the opposite quadrant, which is incompletewhen learning stimuli are presented at a single location in thevisual field (Fig. 5).

Generalization of learning to presaccadic eye velocity

Our experiments were designed to cause learning in postsaccadic pursuit eye velocity by providing a visual stimulus indicatingthe need for learning only after the saccade. We found that thelearning also generalized to presaccadic eye velocity in manyexperiments. We studied learning in 18 experiments designed toincrease eye velocity (Fig. 9A, squares) and 14 designed to decreaseeye velocity (Fig. 9A, triangles) in five animals. Plotting meanpre-saccadic eye velocity for the last probe 20 trials of thelearning block as a function of that in the baseline block revealedthat many experiments caused learning in the appropriate direction.For 20 of 32 (63%) experiments, there were statistically significantchanges in presaccadic eye velocity (p < 0.05; filled symbols).All but one of the significant changes were in the direction expectedfor the learning conditions. Significant presaccadic changes wereobserved more often in experiments that provide learning trialswith target motion toward (12 of 15; 80%) versus away from (8of 17; 47%) the vertical meridian. Although presaccadic learningwas less likely to be statistically significant, statistical comparisonwith t tests of the learning ratios for presaccadic and postsaccadiceye velocity failed to revealed significant differences (increase-velocityexperiments: 1.37 and 1.66 for presaccadic and postsaccadic eyevelocity, p > 0.05; decrease-velocity experiments: 0.72 and 0.68for presaccadic and postsaccadic eye velocity, p > 0.05).

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Figure 9. Summary of effects of learning in presaccadic eye velocity. A, Presaccadic eye velocity after learning is plotted as a function of eye velocity at the same time before learning. Each point shows data from one experiment. The y-axis plots the mean eye velocity in the last 20 probe trials in the adaptation block. The x-axis plots the mean eye velocity in the same type of trials in the baseline block. The diagonal line has a slope of one and would obtain if learning caused no change in eye velocity. Squares and triangles show results of increase-velocity and decrease-velocity experiments, respectively. Filled symbols indicate experiments in which learning caused statistically significant changes in eye velocity (t test; p < 0.05), and open symbols show experiments in which changes were not significant. B, Example of the time course of acquisition of presaccadic and postsaccadic pursuit learning from a single increase-velocity experiment. The x-axis plots the number of times the learning stimulus was presented, and the y-axis plots eye velocity. Each data point shows eye velocity from one single learning trial. Filled and open symbols show average eye velocity across the 10 msec immediately before or after the saccade. The two single symbols with error bars on the left side of the graph show the mean and SDs of presaccadic and postsaccadic velocity taken from probe trials in the baseline block.

There were differences in the time course of presaccadic and postsaccadic learning. We assessed the time course by makinggraphs like Figure 9B, which shows presaccadic and postsaccadiceye velocity as a function of trial number for each learning trialdelivered in the experiment shown in Figure 1. We quantified thetime course of learning separately for presaccadic and postsaccadiceye velocity by using a least-squares procedure to fit a functionthat contained weighted exponential and linear components. Asshown in the example in Figure 9, postsaccadic velocity tendedto be described by exponential functions, and presaccadic by linearfunctions. Furthermore, learning occurred more rapidly in postsaccadicthan in presaccadic eyevelocity.

Absence of directional generalization of pursuit learning

Previous studies have shown that learning of presaccadic pursuit in one direction did not generalize to pursuit in the oppositedirection (Kahlon and Lisberger, 1996, 1999). In those studies,however, target motion was always toward the position of fixationso that changes in direction required changes in the initial positionof the tracking target in the visual field. Because we have shownthat pursuit learning generalizes incompletely to different locationsin the visual field, it was important to retest direction generalizationwith our paradigm, which allowed us to use target motion in alldirections from a single initial position in the visualfield.

We tested direction generalization by comparing the effects of pursuit learning in one direction on pursuit of control targetmotions in the opposite direction, where the two target motionsstarted from the same location in the visual field. Each symbolin Figure 10 shows the results of a single experiment and plotslearning ratio in the control direction as a function of thatin the learning direction. Each point was obtained by measuringthe mean postsaccadic eye velocity from probe trials in the learningand baseline blocks in both the adapting and control directionsfor each experiment. Along the abscissa, which shows data forthe adapting direction, the symbols form a distinct bimodal distribution,with learning ratios centered above and below one for increase-velocityand decrease-velocity experiments, respectively. The geometricmeans of the learning ratios in increase-velocity and decrease-velocityexperiments were 1.66 and 0.68, and both were significantly differentfrom 1 (one-sided t test; p < 0.01). Along the ordinate, whichshows the learning ratios in the control direction, the symbolsfor different experiments are tightly distributed around 1 forboth increase-velocity and decrease-velocity experiments. Thegeometric means of the learning ratios in the control directionwere 1.05 for increase experiments and 1.06 for decrease experiments,and neither was significantly different from 1 (one-sided t test;p > 0.05).

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Figure 10. Lack of generalization of learning to target motion in the control direction. Each point represents data from one learning experiment, either designed to increase (squares) or decrease eye velocity (triangles). The axes shows the ratio of mean post-saccadic eye velocity after learning divided by mean eye velocity before learning. The x-axis shows the ratio for the adapted direction, and the y-axis shows the ratio for the opposite, unadapted direction.

We also conducted two experiments in each of two animals to assess the bandwidth of the directional generalization. Learningprocedures were the same as in the previous experiments, but nowthe probe trials started from the same position in the visualfield and moved in 12 different directions at 30° intervals relativeto the adapted direction. We found that postsaccadic learninggeneralized only partially to nearby directions. To quantify thedirection generalization, we fit a Gaussian function using theLevenberg-Marquardt method (Press et al., 1988) to the learningratios for all 12 directions. Across all experiments, the meanbandwidth at half-height of the Gaussian fits was 62°. Similarresults were obtained in two additional experiments on a thirdmonkey; however, we suspected the accuracy of vertical velocityrecordings in this animal so the data were not included in themean. These findings are consistent with previous findings showingthat learned changes generalized to motions within 60° of thetrained motion (Kahlon and Lisberger, 1999), but add the importantfeature that all directions of target motion were delivered atthe same location in the visualfield.

Absence of generalization of pursuit learning to saccades

Comparison of prelearning and postlearning saccades during probe trials did not reveal any significant changes in mean saccadeamplitude, direction, or latency in our experiments (t test; p> 0.05). This is consistent with one (Ogawa and Fujita, 1997)but not another (Nagao and Kitazawa, 1998) previous study. Thosetwo studies used different target conditions from each other andfrom this current study: saccadic adaptation seems dependent onthe exact target configuration selected for the pursuit learning.The lack of saccadic adaptation in our paradigm may seem surprising,given that the saccadic system takes target velocity into accountwhen programming a saccade to a moving target (Keller and Heinen,1991). However, the drive for saccadic learning is a positionerror (Wallman and Fuchs, 1998). For our learning paradigm, wecalculated the position error resulting from the change in targetvelocity by comparing the difference between the distance traveledby the target during the saccade at the first target velocityversus the distance traveled at the second velocity. The positionerrors present during learning trials averaged 1°, and thereforewere small in comparison with target step sizes typically usedto evoke saccadic adaptation (Straube et al., 1997). Thus, ourparadigm may not be effective in evoking saccadic adaptation orthe changes may be too small to detect given the variability ofsaccades evoked to movingtargets.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The central goal of our study was to constrain the possible sites of learning in pursuit eye movements by understanding howpursuit learning generalizes for the visual field location anddirection of moving targets. Generalization for the directionof target motion at a given retinal locus was quite restrictedand did not extend to the opposite direction. Generalization forinitial target position was partial, but often included targetsthat were in the opposite visual hemifield and as far as 18° ofvisual angle from the position of the adapting stimulus. The largespatial spread of learning effects seems to be an obligate featureof the neural circuits that produce pursuit learning, becausegreater spatial specificity did not emerge when two opposing learningstimuli were presented in different retinallocations.

Relationship to previous pursuit learning data

Our data provide an important extension to previous studies on pursuit learning (Nagao and Kitazawa, 1998; Ogawa and Fujita,1997), which have shown that learning to a particular directionof target motion can generalize to nearby target positions tosome degree. First, we have shown that learning can generalizeto spatial locations as far as 18° away, including sites in theopposite hemifield and that learning cannot be forced to be spatiallymore specific. This means that the expression of learning formotion in a particular direction must be described as somewherebetween position-specific and position-independent. Thus, ourdata support and extend the previous conclusion of Kahlon andLisberger (1996): learning occurs in a intermediate referenceframe that integrates signals related to multiple aspects of boththe visual stimulus and the evoked eye motion, and may involvemultiplesites.

Comparison of learning for presaccadic and postsaccadic eye velocity

Our learning paradigm was carefully contrived so that the signals that guide learning were available only after the saccade.Yet, learning caused changes in the component of postsaccadiceye velocity that is driven by visual inputs present before thesaccade. For learning to work correctly, the system must workthis way. Visual inputs present after the saccade constitute anerror signal that reports the failure to pursue correctly basedon visual inputs present 100 msec earlier. The error signals presentednear the fovea after the saccade therefore cause learning in theresponse to earlier visual signals presented in peripheral vision.This idea has been treated in the analysis of learning in thevestibulo-ocular reflex (Raymond and Lisberger, 1996), and appearsas well in other examples of visual-motor learning, such as insaccades (Shafer et al., 2000) or post-saccadic fixations (Opticanand Miles, 1985).

In our paradigm, learning was induced with complete spatial and temporal separation between the presaccadic inputs that weresubject to learning and the postsaccadic signals that guided learning.In spite of this separation, learning could generalize to a largeregion of the visual field surrounding the presaccadic visualstimulus. Learning was also able to generalize to pursuit thatpreceded the saccade in approximately two-thirds of our experiments,but the time course of learning was slower for presaccadic thanpostsaccadic pursuit. This could imply that the systems responsiblefor these two components of pursuit are heavily shared and areboth subject to a single learning mechanism. Perhaps the neuralsystems that guide presaccadic and postsaccadic overlap only partially,but both are subject to learning. Alternatively, the interactionsthat drive learning with presaccadic and postsaccadic visual signalsmay access the same mechanisms with different efficacies. In thisregard, it is interesting that the postsaccadic learning is faster,because this is the situation that would obtain most often withnatural tracking using a combination of saccades and smoothpursuit.

Constraints on the neural site of pursuit learning

To shed light on the neural sites of pursuit learning, we now relate the properties of the generalization of learning to theproperties of signals processed at different stages of the neuralcircuit for pursuit. Suppose, for example, we had found that learningfor a target motion to the right at one position in the visualfield caused changes in pursuit only for probe target motionsthat took the target to the right starting within a few degreesof the position of the adapting stimulus. Then, we would concludethat the site of learning was early in the visual pathways, ata site where image motion was represented by cells with smallreceptive fields. Suppose, at the other extreme, that learningfor rightward target motion at one position in the visual fieldcaused the same changes in rightward pursuit to targets that appearedanywhere in the visual field. Then we would conclude that thesite of learning was probably deep in the motor system, at a sitewhere neural signals represented pursuit eye motion along thehorizontalaxis.

Our data fall intermediate between the predictions at the motor and sensory extremes, and so does our conclusion. When wetested the generalization of pursuit to target motion in the learningdirection across different parts of the visual field, we foundgeneralization that was incomplete, but significant, extendingin many cases to sites across the horizontal or vertical meridianfrom the visual field location of the targets used for learning.The fact that generalization occurs to retinal locations as muchas 18° away in the opposite visual quadrant makes it unlikelythat learning occurs at the level of areas V1 or MT, where thereceptive fields are small and are confined primarily to the contralateralvisual field. At <10°, which is where we placed our learning stimuli,V1 neurons have receptive fields of $<=$ 1° in diameter (Gattass etal., 1981; Van Essen et al., 1984). MT neurons with receptivefields at these eccentricities have been reported to have receptivefields ranging 5-10° in diameter (Gattass and Gross, 1981; VanEssen et al., 1984; Desimone and Ungerleider, 1986; Komatsu andWurtz, 1988; Ferrera and Lisberger, 1997). In MT, although thereis some ipsilateral visual representation, the majority of theneurons have receptive fields confined to the contralateral hemifield(Van Essen et al., 1981; Desimone and Ungerleider, 1986). Forboth V1 and MT, the size of the receptive fields is smaller thanthe spatial scale of thegeneralization.

Two cortical areas in the pursuit pathway operate on spatial scales that would make them good candidates for sites of learning.MST contains cells with large receptive fields, some extendingwell into the ipsilateral hemifield (Komatsu and Wurtz, 1988).At 7° eccentricity, some MST neurons have receptive fields >15°in diameter (Desimone and Ungerleider, 1986; Komatsu and Wurtz,1988; Ferrera and Lisberger, 1997). Furthermore, neurons in thedorsal region of MST integrate both retinal image motion and extraretinalinformation that may signal the direction of eye motion (Newsomeet al., 1988) and would satisfy the criterion previously establishedby (Kahlon and Lisberger, 1996) for a site of learning where thereis an interaction of signals related to image motion and eye motion.The arcuate FPA, which receives visual motion signals from bothMT and MST (Tian and Lynch, 1996), is also a plausible site forlearning. FPA has a spatial scale and an interaction of imagemotion and eye motion signals similar to area MST (MacAvoy etal., 1991; Gottlieb et al., 1993, 1994). Furthermore, FPA hasthe capacity to modulate the gain of the pursuit response to targetmotion (Tanaka and Lisberger, 2001), and could use this capacityduring pursuit learning. Another area that contains an appropriatemix of visual signals, large receptive fields, and eye motionsignals is the DLPN (Suzuki and Keller, 1984; Mustari et al.,1988).

Finally, the fact that learning generalizes incompletely for target position in the visual field raises an obstacle to theconclusion that pursuit learning occurs in the cerebellum. Severalforms of motor learning are thought to reside in the cerebellum:for example, learning the metrics of arm movements (Gilbert andThach, 1977; Ojakangas and Ebner, 1992), changing the gain ofthe vestibulo-ocular reflex, (Ito, 1982; Raymond et al., 1996),and changing the gain of saccades (Optican and Robinson, 1980).For pursuit, it is tempting to come to the same conclusion: lesionsof the vermis (Takagi et al., 2000) or the entire cerebellum (Nagaoand Kitazawa, 2000) may affect pursuit learning. Recordings fromPurkinje cells during pursuit learning are consistent with learningeither within or upstream from the floccular complex of the cerebellum(Kahlon and Lisberger, 2000). However, floccular firing duringpursuit generalizes fully across the visual field: Purkinje cellresponses show a single, unifying relationship to eye accelerationfor targets presented up to 20° eccentric in either visual hemifield(Krauzlis and Lisberger, 1991). Thus, the floccular complex ofthe cerebellum does not have discharge properties that would makeit appropriate as a sole site for pursuit learning. Further workwill be needed to determine whether the smooth eye movement partsof the cerebellar vermis play a special role in pursuit learning,or if pursuit learning resides in the pontine nuclei, the cerebralcortex, or hitherto unexplored regions such as the basal ganglia.Finally, the complex dependence of pursuit learning on many featuresof image, target, and eye motion raises the possibility that learningresults from multiple components of the pursuit circuit, eachwith different signaling properties, rather than from any singlearea encoding all thesignals.

  FOOTNOTES

Received Jan. 18, 2002; revised March 15, 2002; accepted March 18, 2002.

This work was supported by National Institutes of Health Grant NS34835 and the Howard Hughes Medical Institute. We thank membersof the Lisberger laboratory for helpful comments on this manuscript,Karen MacLeod, Elizabeth Montgomery, and Stefanie Tokiyama forexcellent technical assistance, and Scott Ruffner for computerprogramming.

Correspondence should be addressed to Dr. I-han Chou, Department of Physiology, Box 0444, University of California, San Francisco,513 Parnassus Avenue, Room 762-S, San Francisco, CA 94143-0444.E-mail: ihan{at}phy.ucsf.edu.

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