The Development of Abnormal Axon Trajectories after Rotation of One Eye in Xenopus

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (5)

Citing Articles via Google Scholar

Google Scholar

Articles by Guo, Y.

Articles by Udin, S. B.

Search for Related Content

PubMed

PubMed Citation

Articles by Guo, Y.

Articles by Udin, S. B.

Pubmed/NCBI databases
Substance via MeSH

Previous Article  |  Next Article

The Journal of Neuroscience, June 1, 2000, 20(11):4189-4197

The Development of Abnormal Axon Trajectories after Rotation of One Eye in Xenopus
Yujin Guo and Susan B. Udin
Department of Physiology and Biophysics, State University of New York, Buffalo, New York 14214

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The targeting of isthmotectal axons in the Xenopus binocular pathway is guided by both activity-dependent cues and activity-independentcues. Abnormal visual activity induced by unilateral eye rotationoverrides activity-independent cues and causes isthmotectal axonsto arborize at new locations during a critical period of developmentthat ends ~3 months postmetamorphosis (PM). Horseradish peroxidasestaining of isthmotectal axons reveals that they normally runrostrocaudally in the tectum; in contrast, those axons in animalswith early eye rotation have circuitous trajectories. In thispaper, by studying the trajectories and branching patterns ofisthmotectal axons at different times after eye rotation, we aimedto investigate when and how activity cues determine the projectionpattern of isthmotectal axons. As suggested by electrophysiologicalrecording, isthmotectal axons initially grow normally and makearbors according to activity-independent cues despite the presenceof abnormal visual input. Our findings demonstrate that the developmentof abnormal trajectories starts by 2 weeks PM in response to eyerotation and is a protracted process. It begins in the tectalregions in which the initial connections of isthmotectal axonsare first formed according to activity-independent cues. At transitionalstages (5 and 10 weeks), axons with arbors at two different locationsare observed, with locations corresponding to the old and newtermination sites, respectively. Later, at 10 weeks of age, thefainter horseradish peroxidase staining in arbors at old terminationsites suggests that the older arbors are undergoingwithdrawal.

Key words: optic tectum; Xenopus; activity-dependent synaptic modification; unilateral eye rotation; axon trajectories; arbors; development; nucleus isthmi

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The formation of precise neuronal connections depends on activity-independent (chemoaffinity) cues and activity-dependentcues. During normal development, endogenous activity-independentcues enable axons carrying sensory inputs to form crude topographicmaps (Sperry, 1963; Udin and Fawcett, 1988; Goodman and Shatz,1993; O'Leary and Wilkinson, 1999). The further refinement ofthese maps requires patterned sensory activity (Schmidt and Edwards,1983; Cline and Constantine-Paton, 1989; Scherer and Udin, 1989).The arborizations of afferent axons can be modified by activity(Udin, 1983; Antonini and Stryker, 1993b; Schmidt and Buzzard,1993; Katz and Shatz, 1996). Normally, chemoaffinity and activity-dependentcues work in harmony, but abnormal eye position in Xenopus duringdevelopment can set up a conflict whereby visual input inducesaxons to shift their arbors away from the sites specified by chemoaffinitymarkers. In this study, we examined the process of reorganizationof axons in the Xenopus visual system that results from a mismatchof activity-dependent and chemoaffinitycues.

The topographic representations of the binocular visual field in Xenopus optic tectum have been studied by electrophysiologicalmapping (Gaze et al., 1979). The contralateral and ipsilateralmaps are in spatial registration during normal development. Theformation of the contralateral map begins within a few days offertilization and is independent of visual experience (Gaze etal., 1979; Keating et al., 1986). In contrast, the ipsilateralmap develops much later, at the end of metamorphosis. An initiallycoarse ipsilateral map forms regardless of the presence or absenceof proper visual cues (Grant and Keating, 1989b). However, themaintenance and refinement of the ipsilateral map is mediatedby correlated activity between the two eyes during the criticalperiod (Keating and Feldman, 1975; Brickley et al., 1998). Whenone eye is surgically rotated, resulting in a rotated contralateralmap, the initially normal ipsilateral map is topographically mismatchedbut later reorganizes and conforms to the rotated contralateralmap (Fig. 1) (Udin and Keating, 1981). Electrophysiological studiesshow that, although the eye rotation is performed before the formationof the ipsilateral map, the first sign of modification of theipsilateral map is not detected until ~3-4 weeks postmetamorphosis(PM) (Grant and Keating, 1992; Bandarchi et al., 1994).

View larger version (24K):
[in this window]
[in a new window]
Figure 1. A, Schematic diagram showing binocular visual input to one locus on the right tectal lobe in a normal adult Xenopus. Visual input via the left eye is relayed directly via retinotectal axons. The input from the right eye is carried indirectly via isthmotectal axons. The input at each position in the binocular field activates a single locus on the right tectum via both pathways. B, After the rotation of the left eye, stimulation at the same position in the visual field now activates different retinal ganglion cells in the left eye, which project to another locus on the right tectum. Therefore, isthmotectal axons must shift their connections to restore topographic registration with retinotectal axons.

The ipsilateral visual information is relayed through the nucleus isthmi (NI) (Glasser and Ingle, 1978; Gruberg and Udin,1978). The isthmotectal projection is the plastic component inthe ipsilateral pathway (Udin and Keating, 1981). In normal animals,the majority of the isthmotectal axons run in a straight rostrocaudaldirection in the tectum. However, eye rotation induces isthmotectalaxons to take abnormal routes (Udin, 1983). The anomalous trajectoriesare the anatomical basis for the rearrangement of the ipsilateralmap in response to early eyerotation.

In the experiments described in this paper, we report that abnormal activity starts to affect the isthmotectal axons by 2weeks PM. Moreover, during transitional stages when the guidingforces for isthmotectal axon arborizations are shifting from chemoaffinitycues to activity-dependent cues, some axons exhibit arbors attwolocations.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Eye rotation. Tadpoles of stage 55-58 (Nieuwkoop and Faber, 1967), bred in our laboratory, were anesthetized by immersionin 1:2000 MS-222 (3-aminobenzoic acid ethyl ester; Sigma, St.Louis, MO). All of the extraocular muscles in the left eye werecut, and the left eye was rotated 180° about its axis. The eyewas held at the rotated position for 30 sec to allow the periorbitaltissue to adhere. In many cases, various degrees of derotationsoccurred. Only animals with final rotations of 90-180° wereused.

Axon labeling. Horseradish peroxidase (HRP) was injected into the NI at 2 weeks, 5-6 weeks, 9-10 weeks, or 4+ months PM. Thefrog was anesthetized, and the tectum was exposed. The frog waspositioned with the upper jaw horizontal. Glass filament micropipetteswith tip diameters of 20-40 µm were filled with a mixture of 4.0%HRP (Type VI; Sigma) and 1.0% lysolecithin (Sigma). Six to 12pressure injections were made in the left NI at 500-700 µm fromthe midline, 50-200 µm from the caudal tectal border, and 800-1050µm deep. The number and sites of injections varied with the sizeof the animal. After 3 d survival, animals were reanesthetized.The right tectal lobe was excised, flattened, fixed in 2.5% glutaraldehyde,and reacted for visualization of HRP (Udin and Fisher, 1983).

Data analysis: overall axon orientation. A method was devised to measure the orientation of isthmotectal axon trajectoriesusing the MicroBrightField (Colchester, VT) Neurolucida system(Udin, 1983): Using a 40× objective, a pair of 50 µm orthogonallines was superimposed on the image of the isthmotectal axonsbeing studied, with one line being oriented along the axis normally,followed by isthmotectal axons (see Fig. 3). We referred to thisline as "RC" to indicate that it was parallel to the normal trajectoryof the isthmotectal axons, which generally run rostrocaudally,with some deviation at the tectal edges; the other line was referredto as "ML" to indicate its mediolateral orientation. The numbersof crossings of isthmotectal axons with the ML and RC segmentswere counted for each field, and the value of the crossing index[(ML $-$ RC)/(ML + RC)] was calculated. Perfect rostrocaudal alignmentwould produce a value of 1, and completely random trajectorieswould yield a value of 0. Predominance of mediolateral trajectorieswould produce negativevalues.

The number and location of HRP-labeled axons in the whole mounts varied depending on the location of the injection sites inthe NI. To study the labeled axons with minimal bias, the followingprocedure was adopted. Under a 40× objective, a field with stainedaxons was chosen. Using the Neurolucida program, a 50 µm gridwas superimposed on the axon image and was oriented as describedabove. Crossings of axons with the RC or/and ML lines were marked.Then the stage was moved one screen frame (100 µm). Unless thenew field was empty or contained broken axons, crossings of axonsin this field with the grid were marked as described above. Usually,the pair of orthogonal lines with the intersection closest tothe center of the image was chosen. Only the crossings of theorthogonal lines with the "stem" axons were counted. If a profilebranched more than five times in the image field, it was consideredto be a terminal arbor and was not counted. This procedure wasrepeated until all the available fields had been surveyed. Theoutline of the tectum was then traced using a 10×objective.

The regions with labeling on the medial, rostral, and lateral borders were not used in the pooled data. The orientation ofthe axons on the very edge of the whole mounts was not well preserved;for the axons on the very rostral side of the tectum, it was difficultto study the changes in their trajectories because they had veryshort stems. The whole mounts with fewer than five axons werenotused.

Data analysis: individual axon trajectories. Some HRP-labeled axons in the whole mounts were well separated from the otheraxons and were intact from their point of entry to tectum to theterminal arborizations. In those cases, those axons were tracedfrom their point of entry to the end of every terminal using a100× objective. When this was done, the outline of the tectumwas traced under a 10×objective.

In some cases, the borders of the tecta in whole mounts were not clear. Some landmarks used to estimate the boundaries includedthe optic tract, the axons on the very medial edge and lateraledge, and the rostral border of the tecta in which the incomingisthmotectal axons changed their trajectories sharply and spreadout.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

After eye rotation, isthmotectal axons shift their terminal arbors from one location to another to reestablish topographicregistration with retinotectal projections (Fig. 2). Rotationsof the contralateral eyes (90 and 180°) cause the topographicmaps of retinotectal projections on the right tectum to rotateaccordingly (Grant and Keating, 1992; Keating and Grant, 1992).To restore registration with retinotectal axons, the topographicmaps of isthmotectal axons also rotate to similar degrees. Asdeduced from the normal map and that after 90° rotation, in ananimal with 90° eye rotation, isthmotectal axons that used toterminate in areas a, b, c, and d now terminate in new areas A,B, C, and D, respectively. Note that the shift is minimal in axonsin area d, which receives inputs from the central part of thevisual field.

View larger version (18K):
[in this window]
[in a new window]
Figure 2. The changes in visual topography on the right tectal lobe after eye rotation in an adult Xenopus at 1 year PM. A, The visual field through the left eye. The topographic maps on the right tectum in animals with no eye rotation (B), 90° clockwise rotation of the left eye (C), and 180° rotation of the left eye (D), inferred from the electrophysiological recording of retinotectal maps. Numbers and circles represent the locations of stimuli in the visual field and the sites that those stimuli activate in the tectum. For example, site 4 in the tectum in B is activated by a stimulus at position 4 in the visual field. After eye rotation, the stimulus at the same position in the visual field will activate a different location in the tectum. The new location is given the same number, e.g., 4, and represented by an open circle. The isthmotectal axons that normally project to the old location of site 4 in the normal animal will project to the new location 4 after eye rotation. The dotted line represents the caudal border of isthmotectal projections in normal animals. E, After 90° rotation, the isthmotectal axons that project to areas a, b, c, and d in normal animals terminate in areas A, B, C, and D. Axons that project to the middle part of the tectum (area d) change their termination sites very little because they activate the part of the eye near its axis of rotation. [Adapted from Grant (1982).]

The trajectories and arborizations of isthmotectal axons in the tectum were visualized by injecting the NI with HRP (Fig.3A,B). In normal animals, isthmotectal axons entered the tectumfrom the rostral side and grew caudally, rarely changing theirpositions along the mediolateral axis. The great majority wereparallel to one another and had a high level of order. However,eye rotation induced isthmotectal axons to take abnormal routesto reach new termination sites; many ran in medial and lateraldirections, and some made U-turns. The likelihood that these axonscrossed one another was large. As a result, the degree of therearrangement of isthmotectal axons can be assessed by their lackof order.

View larger version (90K):
[in this window]
[in a new window]
Figure 3. A, B, Photomicrographs depicting HRP-stained isthmotectal axons in flat-mounted tecta in adults. A, Normal. In normal adults, isthmotectal axons run straight from rostral to caudal and are parallel to one another. B, Eye-rotated adults. Adult isthmotectal axons in eye-rotated animals show a low degree of order. Scale bar, 100 µm. Rostral is up, and medial is left. C, D, A schematic drawing showing the measurement of crossing index (c. i.). A pair of orthogonal lines is superimposed on the axons (dashed lines) being measured. Crossings of axons with RC and ML lines are counted.

The rearrangement of isthmotectal axons in response to unilateral eye rotation starts by 2 weeks PM and continues well into 10 weeks PM

The orderliness of the isthmotectal axons was reflected by the values of the crossing indices (Fig. 3C,D). Briefly, a pairof orthogonal lines was superimposed on the image of the isthmotectalaxons at different tectal positions, with one line (RC) beingoriented along the axis normally, followed by isthmotectal axons,and the other line (ML) running orthogonally. The numbers of crossingsof isthmotectal axons with the ML and RC segments were countedfor 50 × 50 µm segments, and the value of the crossing index [(ML $-$ RC)/(ML + RC)] was calculated. Perfect rostrocaudal alignmentwould produce a value of 1, and completely random trajectorieswould yield a value of0.

The sample included 1409 axon crossings in 33 eye-rotated animals and 372 crossings in 31 controls. The crossing indices fromall ages are charted in Figure 4. In normal animals, the crossingindices did not change significantly with age. However, therewere marked differences between the eye-rotated group and thenormal group. The rearrangement of isthmotectal axons in the eyerotation group started by 2 weeks PM, at which time isthmotectalaxons already displayed considerable disorder. With increasingage, the degree of rearrangement became progressively larger.The development of this disorder was a gradual process. Differencesin crossing indices reached statistical significance when pairsof groups separated by >7 weeks were compared. Crossing indicesin successive eye-rotation groups did not differ significantlyfrom one another.

View larger version (22K):
[in this window]
[in a new window]
Figure 4. Analysis of isthmotectal axon trajectories. Each dot represents the total crossing index of one tectum. Bars represent the median. A, Crossing indices in normal animals. The isthmotectal axons in normal animals display orderly trajectories at all age groups. B, Crossing indices in eye-rotated animals. The isthmotectal axons in eye-rotated animals exhibit abnormal trajectories starting at 2 weeks PM, and the degree of rearrangement increases with the age of the animals. Differences in crossing indices reached statistical significance between 2 and 9-10 weeks (Mann-Whitney test, p = 0.0244), 5 and >16 weeks (Mann-Whitney test, p = 0.0280), and 2 and >16 weeks (Mann-Whitney test, p = 0.002).

At transitional stages, isthmotectal axons form two arbors, with one consistent with activity-independent cues and the other consistent with abnormal activity cues

Electrophysiological studies have demonstrated that eye-rotated animals have essentially normal ipsilateral maps for the firstfew weeks after metamorphosis (Grant and Keating, 1992), suggestingthat the isthmotectal axons initially make functional arbors inthe normal locations. Ultimately, when the reorganization wascomplete, the isthmotectal axons arborized at different locations,and the vast majority of them (34 of 35) had only one arbor (Fig.5D). To understand how the isthmotectal axons arrive at the locationsspecified by eye rotation, we studied the branching patterns ofisthmotectal axons at transitional stages. Our studies revealedthat eye rotation induced isthmotectal axons that initially hadone arbor to sprout new branches and form new arbors; the oldarbors were subsequently withdrawn.

View larger version (22K):
[in this window]
[in a new window]
Figure 5. Tracings of HRP-stained isthmotectal axons. A, Two weeks PM. Both normal animals and eye-rotated animals at this age have some axons with dense arbors (a1 and a2), as well as axons with scattered branches (a3). Note that the axons with dense arbors in eye-rotated animals extend branchlets outside their arbors (a1 and a2). B, Five weeks PM. Each axon in normal animals has one arbor. In eye-rotated animals, some axons extend branchlets outside their arbors (b1), and others have arbors at two locations (b2 and b3). C, Nine to 10 weeks PM. Some axons in eye-rotated animals have two arbors (c2 and c3), whereas others have abnormal trajectories and one arbor (c1). D, More than 16 weeks. In normal animals, axons each have one arbor and rostrocaudally oriented trajectories. In eye-rotated animals, the majority have circuitous trajectories and one arbor (d1 and d3). The single observed case of an axon with two arbors at this age group is shown in the drawing (d2). Also shown is an axon that makes a lateral turn and retains remnant branches outside the main arbor (d4). Scale bar, 100 µm.

Axons in normal animals
Normal developing axons are shown in Figure 5. At 2 weeks PM, there coexisted mature-looking axons with arbors and immature-lookingaxons with only scattered branches, indicating that not all axonswere at the same developmental stages. Both types of axons tendedto grow straight in a rostrocaudal direction and did not extendbranches mediolaterally. At 5 and 9-10 weeks PM, axons in normalanimals had single, focused arbors and straight rostrocaudal trajectories.Similar results have been reported by Udin (1989).

Axons in eye-rotated animals
Two weeks PM. In animals with a rotated eye, both mature-looking axons with arbors and immature-looking axons with only scatteredbranches were observed (Fig. 5A). No apparent difference was seenin immature-looking axons between eye-rotated (a3) and normalanimals. In contrast, among four mature-looking axons with arborsin eye-rotated animals, three of them extended long branchletsoutside their arbors, one caudally (a1) and the other two mediolaterally(a2). These patterns were not observed in normalanimals.
Five weeks PM. Fourteen axons that were well separated from the neighboring axons were traced (Fig. 5B). Of these, six axonshad single focused arbors. In contrast, the rest had branchingpatterns that were not present in normal animals; three axonsextended branchlets away from their arbors (b1), and five madedense arbors at two different locations. The tecta of three ofthe "two-headed" axons had clearly identified borders that allowedus to identify the locations of the arbors; two had one set ofarbors caudal and slightly medial to the other set of arbors (b3),and one axon made two arbors along the mediolateral axis (b2).
Nine to 10 weeks PM. Of eight clearly identified axons, three axons had normal trajectories and single arbors (Fig. 5C). Therest had abnormal appearances. Three axons had abnormal trajectoriesand single arbors, as observed in eye-rotated adults (c1); twoaxons had two sets of arbors (c2 and c3).
More than 16 weeks PM. The majority of 35 traced axons had abnormal trajectories and single arbors (Fig. 5D, d1, d4); onehad two arbors (d2), and one had branches outside the main arbor(d4).

The locations of arbors in two-headed axons
In animals with early eye rotation, two distinct morphologies of axons in transitional stages were the extension of ectopicbranches from main arbors at 2 and 5 weeks PM and the presenceof axons with two separated arbors at 5 and 10 weeks PM. If theformation of two arbors is a step that leads to the final developmentof arbors at the location specified by the activity-dependentcues resulting from eye rotation, one would expect that the locationof one arbor in each such two-headed axon would correspond tothe normal termination site and the other arbor to the reorganizedsite.
To investigate the locations of arbors in each two-headed axon, the topographic maps of isthmotectal axons after differentdegrees of eye rotation were examined. All three two-headed axonsin 5 week PM tecta with identifiable locations and two two-headedaxons in 10 week PM tecta had one set of arbors, correspondingto the old site and another set corresponding to the new terminationsite. Figure 6A shows the predicted locations of new arbors inseveral axons after 90 or 180° eye rotation. After 90° rotation,axons that used to project to positions a and b terminated atpositions A and B; 180° rotation induced axons to shift theirconnections from original sites c and d to new sites C and D.

View larger version (23K):
[in this window]
[in a new window]
Figure 6. In two-headed axons, one arbor is located in the normal site, and the other is found at a site appropriate for the rotated map. A, Prediction of new termination sites of axons after eye rotations. The top panel shows the termination sites of four axons in normal animals, represented by a, b, c, and d. The middle panel shows the new termination sites (A and B) of axons a and b after 90° eye rotation. The old termination sites are also marked. The bottom panel shows the new terminations sites (C and D) of axons c and d after 180° eye rotation. The dotted line represents the caudal border of isthmotectal projections in normal animals, which also corresponds to the caudal margin of our whole mounts. B, Tracings of two-headed axons 1, 2, 3 and 4. Axons 1 and 2 are from animals at 10 weeks PM with 90° rotation and have one set of arbors at a and b and the other set at A and B, respectively. Axons 3 and 4 are from animals at 5 weeks PM with 180° rotation and have one set of arbors at c and d and the other set at C and D. Scale bar, 100 µm.

Examples of axons with two arbors at the predicted old and new sites are shown in Figure 6B. Axons 1 and 2 came from a 10week PM animal with 90° rotation; one set of their arbors waslocalized at original termination sites a and b, and another setof arbors was found in the postulated new sites A and B. Axons3 and 4, in 5 week PM animals with 180° rotation, had arbors atputative old termination sites c and d and another set of arborsat probable new termination sites C and D,respectively.

Changes in intensity of HRP staining in axons with two arbors
Interestingly, in both axons from a 10-week-old animal, arbors found at the old termination were thinner and more lightlystained than the arbors at the new sites (Fig. 7A,B). On the otherhand, both sets of arbors in the two-headed axons from the 5-week-oldanimals showed similar intensity of HRP staining (Fig. 7C). Thisfinding suggests that, at 10 weeks PM, some isthmotectal axonswere withdrawing the old arbors. Also at this age, some axonshad abnormal trajectories and single arbors, indicating that theseaxons had already completed the process of withdrawing old arbors(Fig. 7C). In fact, among 35 isthmotectal axons in adult animalswith early eye rotation (Fig. 7D), although the majority of themhad abnormal trajectories and one arbor, one axon had remnantbranches at positions other than main arbor (d4) and another axonhad two arbors, which may represent a failure of the completewithdrawal of old arbor (d2).

View larger version (68K):
[in this window]
[in a new window]
Figure 7. Photomicrographic montages showing HRP labeling in two-headed axons at 5 and 10 weeks PM. A, Axon 1 is from an animal at 10 weeks PM. The arbor at old site a and the stem leading to it are much thinner than the arbor at new site A. The contrast in this photomicrograph is adjusted to emphasize the connection between two arbors. Only a lightly stained portion of the arbor at A is shown to demonstrate the faintly stained branches at a. Arrowheads point to the beginning part of the old arbor. B, The same axon is presented to show better the difference in intensity of HRP staining in two arbors, with the whole arbor at site A being shown. The HRP labeling in its arbor at old site a is substantially lighter than that in its arbor at new site A. C, Axon 3 is from an animal at 5 weeks PM. The HRP labeling in its arbors at both old site c and new site C are similar. Insets are high-magnification views of branches from the two arbors (under a 100× objective). Scale bar, 50 µm. Photomicrographs were taken using a 100× objective in A and a 25× objective in B and C.

There could be several reasons why we observed a population of "normal-looking" axons with straight trajectories and singlearbors in eye-rotated animals (data not shown). (1) The axonsmay not have started to change. (2) Some axons were in the middleof the tectum, corresponding to the optic axis of the rotatedeye, where minimal changes are expected because new terminationsites are very close to the old sites. (3) Some axons shiftedconnections from a rostral to a caudal location or vice versa,at the same mediolateral position (for example, see Fig. 7B, b3).(4) Not all axons responded to eyerotation.

Isthmotectal axons with younger arbors are the last group of axons to undergo rearrangement

NI cells are born over a period of 1-2 months, and most of their axons have arrived at the tectum at the time of eye rotation.However, they make only scattered branches until ~1 week beforemetamorphosis, when the oldest axons start to form arbors in rostromedialregions (Udin and Fisher, 1985; Udin, 1989). As development proceeds,relatively younger axons form arbors in the rostromedial regionand displace older axons and their arbors to the caudolateralpart of the tectum (Grant and Keating, 1986, 1989a). Because ofthe pattern of tectal growth (Udin and Fisher 1985), axons retainan overall rostrocaudal orientation, albeit with a small lateralbias in the lateralmost tectum. Thus, NI cells that ultimatelyproject to the caudolateral part of the tectum are the oldestand also have the oldest arbors induced by activity-independentcues. At 2 weeks PM, we observed that some isthmotectal axonshad arbors and others only had scattered branches. This resultindicates that arbors induced by activity-independent cues arestill forming and that isthmotectal axons are at different developmentalstages at theseages.

Do all isthmotectal axons respond to eye rotation at the same time, independent of their individual stages of development?To answer this question, we investigated the distribution of thecrossing indices across the tectum in different age groups. InFigure 8, the large black circles represent sites with the greatestdisorder of trajectories (smallest crossing index). In the 2 weekPM group, the most prominent rearrangements were found in thecaudolateral part of the tectum. In the 5 week PM group, the zoneof reorganization had spread medially, leaving primarily rostromedialaxons still in their normal positions. In animals of 10 weeksPM, only axons within a narrow medial band still had normal trajectories.In animals older than 16 weeks, the reorganization had been completedin virtually every region. This result shows that isthmotectalaxons reorganized following the order of caudolateral to rostromedial.Thus, younger axons with newly formed activity-independent arborswere the last group to be affected by eye rotation.

View larger version (19K):
[in this window]
[in a new window]
Figure 8. The rearrangement of isthmotectal axons takes place in the sequence of caudolateral to rostromedial. The distributions of the crossing indices of different ranges at 2, 5, 10, and >16 weeks PM. Large black circles, dark gray circles, light gray circles, and white circles represent high to low degrees of rearrangement (crossing indices of <0.1, 0.1-0.4, 0.4-0.7, and 0.7-1.0, respectively).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The present study demonstrates that eye rotation starts to affect isthmotectal axon trajectories by 2 weeks postmetamorphosisand that individual axons transiently sustain two distinct arborizationsduring the critical period. Further analysis of the locationsof paired arbors shows that they represent the normal and reorganizedtermination sites, suggesting that abnormal visual activity caninduce sprouting of new arbors and subsequent withdrawal of theoldarbors.

Unilateral eye rotation at tadpole stages leads to the reorganization of the ipsilateral map (Udin and Keating, 1981). However,electrophysiological mapping methods do not reveal rotated ipsilateralmaps until 3-4 weeks postmetamorphosis (Udin and Keating, 1981).Thus, a normal map forms and persists for at least another month,although abnormal visual input is present throughout the wholeperiod. By staining isthmotectal axons with HRP to characterizewhen and how isthmotectal axons are guided by activity cues, wecould examine subtle changes in branching patterns of isthmotectalaxons in response to abnormal visual activity that are difficultto detect by extracellular electrophysiological mapping (Georgeand Marks, 1974).

Our results show that isthmotectal axons start to extend ectopic branches in the earliest age group we studied: 2 weeks PM.Thus, isthmotectal axons respond to abnormal activity before changesare detected by electrophysiological mapping because no densearbors at rotated positions have formedyet.

Given that activity-independent cues instruct isthmotectal axons to arborize at one location and activity-dependent cues tellthe same set of axons to go elsewhere, how do axons respond tothese two conflicting forces? We observe axons with two distinctarbors, at locations corresponding to normal and reorganized sites.The existence of two-headed axons in eye-rotated animals at 5weeks PM suggests that abnormal activity cues trigger isthmotectalaxons to form new arbors, although they have already arborizedat other locations on the basis of activity-independentcues.

Isthmotectal axons in adults with a rotated eye have only single arbors and these are found at the visuotopically correctlocations, so the arbors at the old termination sites in 5-week-oldanimals are probably resorbed at later stages. As expected, inanimals of 10 weeks PM, we observed two two-headed axons thatseem to be withdrawing the old arbors. Of the two arbors, onewith much lighter HRP staining occupies the old termination sites.Scattered branches or sparse arbors are observed at earlier ages,but the density of staining in them is nevertheless as robustas that in the sibling arbors. We speculate that faint stainingreflects a process of atrophy in the oldarbors.

Do all the axons shift their arbors in response to eye rotation? One line of evidence that they do not is a study in whichenucleation was performed in adult animals with early eye rotation(Brickley et al., 1994). After the contralateral eye was removed,both modified and unmodified ipsilateral maps were recorded insome animals. The growth patterns of isthmotectal axons may beheterogeneous, with some of them being affected by abnormal visualactivity and others not. This result could explain why we observedsome axons with normal trajectories in eye-rotated animals, althoughsome of these are located in regions, such as the optical centerof rotation at which no changes in trajectories areneeded.

Our data suggest that, when isthmotectal axons first grow into the tectum, their guiding factor is chemoaffinity cues (andperhaps correlation of firing patterns of isthmotectal axons withone another). Only during second phase do isthmotectal axons startto respond to binocular visual activity cues. Some threshold densityof synaptic connections may be required to trigger thisbehavior.

This two-stage hypothesis can be tested by taking advantage of the fact that isthmotectal axons mature at different rates.At the time of eye rotation, the majority of isthmotectal axonshave arrived in the tectum. However, isthmotectal axons only startto form arbors weeks later (Udin and Fisher, 1985). NI cells projectingto the caudolateral region form arbors earlier than those to therostromedial border (Grant and Keating, 1989a). If the abilityof isthmotectal axons to respond to activity cues is related totheir developmental stages, isthmotectal axons should reorganizeat the different speeds throughout the tectum. Indeed, our resultssuggest that reorganization of each isthmotectal axon begins afterit has made an arbor in the location defined by chemoaffinitycues. The reorganization starts in the caudolateral region, whichcontains the oldest arbors, and ends in the rostromedial area,which has the newest arbors. Similar results have been reportedwith electrophysiological mapping (Grant and Keating, 1992).

Activity can fine-tune the topographic maps that are established by chemoaffinity cues. In Xenopus, rearing animals in thedark during the critical period results in a coarse ipsilateralmap that becomes refined after the animals are returned to normallighting (Grant and Keating, 1989b; Keating et al., 1992). Inmammals, blocking binocular visual activity by intraocular infusionof TTX during a critical period leads to the formation of abnormallylarge and diffuse arbors in both LGN and visual cortex (Sretavanand Shatz, 1986; Sretavan et al., 1988; Antonini and Stryker,1993b). Monocular deprivation during the critical period resultsin a reduction of axon branches in geniculocortical afferentsserving the occluded eye and the expansion of afferents servingthe normal eye (Antonini and Stryker, 1993a). In the regenerationof the goldfish retinotectal projection, both strobe light andblocking of activity induces retinal ganglion cells to grow abnormallyenlarged arbors (Schmidt and Buzzard, 1990, 1993).

What are the cellular events that are triggered by activity that affect the arborizations of isthmotectal axons? One scenariois that correlated activity between isthmotectal axons and retinotectalaxons activates NMDA receptors in postsynaptic tectal cells, stabilizestheir dendrites (Cline, 1998; Wu and Cline, 1998), and promotesthe release from dendrites of signals that stabilize active terminals(Constantine-Paton and Cline, 1998). Several lines of evidencesupport the role of NMDA receptors in activity-dependent reorganizationof isthmotectal axons. During the critical period, NMDA applicationaccelerates the reorganization of isthmotectal axons in responseto eye rotation (Bandarchi et al., 1994); conversely, NMDA antagonistsblock this process (Scherer and Udin, 1989). Isthmotectal axonsrelease acetylcholine rather than glutamate; the ability of AChto increase glutamate release from retinotectal terminals is likelyto increase the impact of retinotectal activity on tectal cells(King and Schmidt, 1991; Titmus et al., 1999).

We propose that retrograde signals promote the growth and stabilization of branches at the site of release, without affectingthe total branch number and the length of an axon. This modelis supported by the results of studies of retinotectal axons inXenopus (Rajan et al., 1999) showing that blocking NMDA receptoractivity increases the rates of branch retractions and additionsin retinotectal axons, but that the branch number and axonal lengthstay unchanged over a 24 hr period. Studies done on cultured tectalcells also have shown that blocking NMDA receptors increases neuritemotility and sprouting (Lin and Constantine-Paton, 1998).

How does activity prompt isthmotectal axons to stay or reorganize? If the chemoaffinity-specified arbor is formed at a sitewith correlated activity, local release of retrograde signalspromotes the growth and stabilization of the arbors. Isthmotectalaxons form small branches outside the arbor (Udin, 1989); however,without stabilization signals, they disappear eventually becausethey are at a competitive disadvantage. If the arbor is firstformed in a region without correlated activity, the axon willextend and retract branches outside the arbor at a increasingrate. By trial and error, some branches extend to areas with correlatedactivity and receive the signals for growth and elaboration, anda new arbor forms. In the meantime, because an axon can only sustaina certain number of branches, the old arbor will lose the competitionandretract.

The axons at transitional stages in eye-rotated animals displayed relatively few side branches, which is unexpected if theaxons extend branches randomly to search for the locations withcorrelated activity by trial and error. Our staining method mayhave failed to catch very transient branches. Alternatively, thesearching process may not be completely by chance; perhaps someof the visuotopic organization within the isthmotectal populationis preserved during the reorganization process. Connections madeby a given isthmotectal axon may help to stabilize branches madeby neighboring isthmotectal axons with similar receptivefields.

The two-headed axons call to mind the dual projections in the inferior colliculus of barn owls reared with prisms that createa mismatch between visual and auditory tectal maps (Feldman andKnudsen, 1997). In those animals, connections mediating the normalauditory topographic map coexist with connections mediating amap that matches the shifted visual map. In contrast with Xenopusisthmotectal projections, the owls' dual projections persist anatomicallyinto adulthood, with the influence of the normal connections beingsuppressed by inhibitory interneurons (Zheng and Knudsen, 1999).

In summary, the above results suggest that, in animals with early eye rotation, isthmotectal axons are initially guided byactivity-independent cues and establish connections at locationsthat have been rendered "incongruent" by the eye rotation. Thesearbors allow the axons to detect the activity mismatch, promptingthem to search other tectal areas for correlated activity andto make arbors there; in the meantime, the old, incorrect arborsarewithdrawn.

  FOOTNOTES

Received Nov. 10, 1999; revised Feb. 16, 2000; accepted March 21, 2000.

This work was supported by United States Public Health Service Grant EY-03470 to S.B.U. We thank Drs. Simon Grant, Vicky Stirling,and Wenbiao Gan for their helpful comments on this manuscriptand Dr. Diana Williams for use of Fig. 3B.
Correspondence should be addressed to Dr. Susan B. Udin, 313 Cary Hall, Department of Physiology, State University of NewYork, Buffalo, NY 14214. E-mail: sudin{at}buffalo.edu.

Dr. Guo's present address: Department of Psychiatry, Mount Sinai School of Medicine, New York, NY10029.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Antonini A, Stryker MP (1993a) Rapid remodeling of axonal arbors in the visual cortex. Science 260:1819-1821[Abstract/Free Full Text].
Antonini A, Stryker MP (1993b) Development of individual geniculocortical arbors in cat striate cortex and effects of binocular impulse blockade. J Neurosci 13:3549-3573[Abstract].
Bandarchi J, Scherer WJ, Udin SB (1994) Acceleration by NMDA treatment of visually induced map reorganization in juvenile Xenopus after larval eye rotation. J Neurobiol 25:451-460[Medline].
Brickley SG, Keating MJ, Grant S (1994) Experience-dependent mechanism of binocular map plasticity in Xenopus: incongruent connections are masked by retinal input. Neurosci Lett 182:13-16[Web of Science][Medline].
Brickley SG, Dawes EA, Keating MJ, Grant S (1998) Synchronizing retinal activity in both eyes disrupts binocular map development in the optic tectum. J Neurosci 18:1491-1504[Abstract/Free Full Text].
Cline HT (1998) Topographic maps: developing roles of synaptic plasticity. Curr Biol 8:R836-R839[Web of Science][Medline].
Cline HT, Constantine-Paton M (1989) NMDA receptor antagonists disrupt the retinotectal topographic map. Neuron 3:413-426[Web of Science][Medline].
Constantine-Paton M, Cline HT (1998) LTP and activity-dependent synaptogenesis: the more alike they are, the more different they become. Curr Opin Neurobiol 8:139-148[Web of Science][Medline].
Feldman DE, Knudsen EI (1997) An anatomical basis for visual calibration of the auditory space map in the barn owl's midbrain. J Neurosci 17:6820-6837[Abstract/Free Full Text].
Gaze RM, Keating MJ, Östberg A, Chung S-H (1979) The relationship between retinal and tectal growth in larval Xenopus: implications for the development of the retino-tectal projection. J Embryol Exp Morphol 53:103-143[Web of Science][Medline].
George SA, Marks WB (1974) Optic nerve terminal arborizations in the frog: shape and orientation inferred from electrophysiological measurements. Exp Neurol 42:467-482[Web of Science][Medline].
Glasser S, Ingle D (1978) The nucleus isthmus as a relay station in the ipsilateral visual projection to the frog's optic tectum. Brain Res 159:214-218[Medline].
Goodman CS, Shatz CJ (1993) Developmental mechanisms that generate precise patterns of neuronal connectivity. Neuron 10:77-98.
Grant S (1982) The development and modification of binocular neuronal connections in Xenopus laevis. In: PhD thesis University of London.
Grant S, Keating MJ (1986) Normal maturation involves systematic changes in binocular visual connections in Xenopus laevis. Nature 322:258-261.
Grant S, Keating MJ (1989a) Changing patterns of binocular visual connections in the intertectal system during development of the frog, Xenopus laevis. I. Normal maturational changes in response to changing binocular geometry. Exp Brain Res 75:99-116[Web of Science][Medline].
Grant S, Keating MJ (1989b) Changing patterns of binocular visual connections in the intertectal system during development of the frog, Xenopus laevis. II. Abnormalities following early visual deprivation. Exp Brain Res 75:117-132[Web of Science][Medline].
Grant S, Keating MJ (1992) Changing patterns of binocular visual connections in the intertectal system during development of the frog, Xenopus laevis. III. Modifications following early eye rotation. Exp Brain Res 89:383-396[Web of Science][Medline].
Gruberg ER, Udin SB (1978) Topographic projections between the nucleus isthmi and the tectum of the frog Rana pipiens. J Comp Neurol 179:487-500[Web of Science][Medline].
Katz LC, Shatz CJ (1996) Synaptic activity and the construction of cortical circuits. Science 274:1133-1138[Abstract/Free Full Text].
Keating MJ, Feldman JD (1975) Visual deprivation and intertectal neuronal connexions in Xenopus laevis. Proc R Soc Lond B Biol Sci 191:467-474[Medline].
Keating MJ, Grant S (1992) The critical period for experience-dependent plasticity in a system of binocular visual connections in Xenopus laevis: its temporal profile and relation to normal developmental requirement. Eur J Neurosci 4:27-36[Web of Science][Medline].
Keating MJ, Grant S, Dawes EA, Nanchahal K (1986) Visual deprivation and the maturation of the retinotectal projection in Xenopus laevis. J Embryol Exp Morphol 91:101-115[Web of Science][Medline].
Keating MJ, Dawes EA, Grant S (1992) Plasticity of binocular visual connections in the frog, Xenopus laevis: reversibility of effects of early visual deprivation. Exp Brain Res 90:121-128[Medline].
King WM, Schmidt JT (1991) The long latency component of retinotectal transmission: enhancement by stimulation of nucleus isthmi or tectobulbar tract and block by nicotinic cholinergic antagonists. Neurosci 40:701-712[Web of Science][Medline].
Lin S, Constantine-Paton M (1998) Suppression of sprouting: an early function of NMDA receptors in the absence of AMPA/Kainate receptor activity. J Neurosci 18:3725-3737[Abstract/Free Full Text].
Nieuwkoop PD, Faber J (1967) In: A normal table of Xenopus laevis (Daudin). Amsterdam: North Holland.
O'Leary DD, Wilkinson DG (1999) Eph receptors and ephrins in neural development. Curr Opin Neurobiol 9:65-73[Web of Science][Medline].
Rajan I, Witte S, Cline HT (1999) NMDA receptor activity stabilizes presynaptic retinotectal axons and postsynaptic optic tectal cell dendrite in vivo. J Neurobiol 38:357-368[Web of Science][Medline].
Scherer WJ, Udin SB (1989) N-Methyl-D-aspartate antagonists prevent interaction of binocular maps in Xenopus tectum. J Neurosci 9:3837-3843[Abstract].
Schmidt JT, Buzzard M (1990) Activity-driven sharpening of the regenerating retinotectal projection: effects of blocking or synchronizing activity on the morphology of individual regenerating arbors. J Neurobiol 21:900-917[Web of Science][Medline].
Schmidt JT, Buzzard M (1993) Activity-driven sharpening of the retinotectal projection in goldfish: development under stroboscopic illumination prevents sharpening. J Neurobiol 24:384-399[Web of Science][Medline].
Schmidt JT, Edwards DL (1983) Activity sharpens the map during the regeneration of the retinotectal projection in goldfish. Brain Res 269:29-39[Web of Science][Medline].
Sperry RW (1963) Chemoaffinity in the orderly growth of nerve fiber patterns and connections. Proc Natl Acad Sci USA 50:703-710[Free Full Text].
Sretavan DW, Shatz CJ (1986) Prenatal development of retinal ganglion cell axons: segregation into eye-specific layers within the cat's lateral geniculate nucleus. J Neurosci 6:234-251[Abstract].
Sretavan DW, Shatz CJ, Stryker MP (1988) Modification of retinal ganglion cell axon morphology by prenatal infusion of tetrodotoxin. Nature 336:468-471[Medline].
Titmus MJ, Tsai HJ, Lima R, Udin SB (1999) Effects of choline and other nicotinic agonists on the tectum of juvenile and adult Xenopus frogs: a patch-clamp study. Neuroscience 91:753-769[Medline].
Udin SB (1983) Abnormal visual input leads to development of abnormal axon trajectories in frogs. Nature 301:336-338[Medline].
Udin SB (1989) The development of the nucleus isthmi in Xenopus. II. Branching patterns of contralaterally projecting isthmotectal axons during maturation of binocular maps. Vis Neurosci 2:153-163[Web of Science][Medline].
Udin SB, Fawcett JW (1988) Formation of topographic maps. Annu Rev Neurosci 11:289-327[Web of Science][Medline].
Udin SB, Fisher MD (1983) Visualization of HRP-filled axons in unsectioned, flattened optic tectum. J Neurosci Methods 9:283-285[Medline].
Udin SB, Fisher MD (1985) The development of the nucleus isthmi in Xenopus laevis. I. Cell genesis and formation of connections with the tecta. J Comp Neurol 232:25-35[Web of Science][Medline].
Udin SB, Keating MJ (1981) Plasticity in a central nervous pathway in Xenopus: anatomical changes in the isthmotectal projection after larval eye rotation. J Comp Neurol 203:575-594[Web of Science][Medline].
Wu GY, Cline HT (1998) Stabilization of dendritic arbor structure in vivo by CaMKII. Science 279:222-226[Abstract/Free Full Text].
Zheng W, Knudsen EI (1999) Functional selection of adaptive auditory space map by GABAA-mediated inhibition. Science 284:962-965[Abstract/Free Full Text].

Copyright © 2000 Society for Neuroscience 0270-6474/00/20114189-09$05.00/0

This article has been cited by other articles:

W. M. DeBello, D. E. Feldman, and E. I. Knudsen
Adaptive Axonal Remodeling in the Midbrain Auditory Space Map
J. Neurosci., May 1, 2001; 21(9): 3161 - 3174.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (5)

Citing Articles via Google Scholar

Google Scholar

Articles by Guo, Y.

Articles by Udin, S. B.

Search for Related Content

PubMed

PubMed Citation

Articles by Guo, Y.

Articles by Udin, S. B.

Pubmed/NCBI databases
Substance via MeSH