Cross-Modal Reorganization of Horizontal Connectivity in Auditory Cortex without Altering Thalamocortical Projections

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 (25)

Citing Articles via Google Scholar

Google Scholar

Articles by Gao, W.-J.

Articles by Pallas, S. L.

Search for Related Content

PubMed

PubMed Citation

Articles by Gao, W.-J.

Articles by Pallas, S. L.

Previous Article  |  Next Article

The Journal of Neuroscience, September 15, 1999, 19(18):7940-7950

Cross-Modal Reorganization of Horizontal Connectivity in Auditory Cortex without Altering Thalamocortical Projections
W.-J. Gao and S. L. Pallas
Department of Biology, Georgia State University, Atlanta, Georgia 30302

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The development of the different, highly specialized regions of the mammalian cerebral cortex depends in part on neural activity,either intrinsic spontaneous activity or externally driven sensoryactivity. To determine whether patterned sensory activity instructsthe development of intrinsic cortical circuitry, we have experimentallyaltered the modality of sensory inputs to cerebral cortex. Neonataldiversion of retinal axons to the auditory thalamus (cross-modalrewiring) results in a primary auditory cortex (AI) that resemblesvisual cortex in its response properties and topography (Roe etal., 1990, 1992). To test the hypothesis that the visual responseproperties are created by a visually driven reorganization ofauditory cortical circuitry, we investigated the effect of earlyvisual experience on the development of intrinsic, horizontalconnections within AI. Horizontal connections are likely to playan important role in the construction of visual response propertiesin AI as they do in visual cortex. Here we show that early visualinputs to auditory thalamus can reorganize horizontal connectionsin AI, causing both an increase in their extent and a change inpattern, so that projections are not restricted to the isofrequencyaxis, but extend in a more isotropic pattern around the injectionsite. Thus, changing afferent modality, without altering the sourceof the thalamocortical axons, can profoundly alter cortical circuitry.Similar changes may underlie cortical compensatory processes indeaf or blind humans and may also have played a role in the parcellationof neocortex during mammalianevolution.

Key words: cortical development; sensory cortex; cross-modal plasticity; retinal axons; activity; biotinylated dextran amine; visual development; cortical circuitry; ferret

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The role of sensory inputs in specifying the regional characteristics of cerebral cortex has been a matter of considerabledebate among developmental neuroscientists (Rakic, 1988; O'Leary,1989; Pallas, 1990; Sur et al., 1990; Levitt et al., 1997). Theidentity and pattern of activity within the thalamocortical inputsmay play an important role in cortical regionalization (Katz andShatz, 1996; Catalano and Shatz, 1998). To test the hypothesisthat certain aspects of cortical regional identity are instructedby thalamic activity patterns, independent of molecular cues onthalamocortical axons, we investigated whether the intrinsic circuitryof sensory cortex can be altered by changing the modality butnot the source of thalamocortical inputs during development. Bydiverting the retina to the auditory thalamus (MGN) early in development,the modality and thus activity pattern of the inputs to auditorycortex can be altered without manipulating the thalamocorticalpathway that carries the novel information. This "cross-modalrewiring" paradigm also allows us to ask whether different corticalareas are functionally interchangeable if they are driven by thesame sensory epithelium. Previous results have shown that auditorycortex that has received visual input during postnatal developmentresembles primary visual cortex in its topography and receptivefield properties (Sur et al., 1988; Roe et al., 1990, 1992). Ourgoal was to determine whether this similarity is caused by a modificationof the intrinsic circuitry of the AI by the visual inputs duringdevelopment, or alternatively, whether the visual afferents makeuse of pre-existing similarities in processing circuitry betweenvisual and auditorycortex.

Each sensory cortical area has a number of unique structural and functional attributes. The pattern of horizontal connectionsbetween neurons within a cortical area is one striking example.These connections may be important in constructing the characteristicreceptive field properties seen in each region of sensory cortex.In mammalian visual cortex, horizontal projections are arrangedin a roughly circular pattern, depending on the species (Rocklandand Lund, 1982; Gilbert and Wiesel, 1983; Matsubara et al., 1985,1987; Callaway and Katz, 1990; Weliky and Katz, 1994; Durack andKatz, 1996; Ruthazer and Stryker, 1996; Bosking et al., 1997),and connect neurons with similar orientation tuning (Gilbert andWiesel, 1979; T'so et al., 1986; Gilbert and Wiesel, 1989; Malachet al., 1993). In auditory cortex, neurons within an isofrequencydomain are interconnected, forming an elongated strip of horizontallyprojecting axons (Reale et al., 1983; Imig et al., 1986; Matsubaraand Phillips, 1988; Ojima et al., 1991; Wallace and Bajwa, 1991).Early in development, horizontal projections are widespread, butbecome progressively more restricted under the influence of neuralactivity (Callaway and Katz, 1990, 1991; Weliky and Katz, 1994;Ruthazer and Stryker, 1996). This study addresses whether theorganization of specific horizontal connections can be alteredby changing the modality and thus the patterned activity of thalamocorticalinputs during development. Alterations in horizontal connectionsmay play an important role in organizing the visual receptivefield properties and retinotopy that have been reported in cross-modalAI (Roe et al., 1990, 1992).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The effect of early visual inputs on the pattern of horizontal connectivity in auditory cortex was investigated by makingsmall injections of biotinylated dextran amine (BDA) in AI ofadult cross-modal and normal ferrets. Specific procedures aredetailedbelow.

Animals. Timed pregnant ferrets were purchased from Marshall Farms (North Rose, NY), and their kits were used in the cross-modalgroup. Normal animals were purchased as adults. All animals werekept on a 16/8 light/dark cycle and fed ferret chow and waterad libitum. The animals were treated in accordance with all institutional(Institutional Animal Care and Use Committee), Society for Neuroscience,and National Institutes of Health guidelines for Animal Care andLaboratory Use. Fifteen control and twelve experimental ferretswere used in this study. Seven representative cases from eachgroup were analyzed quantitatively. Excluded cases had poor injections,insufficient transport, or smalllesions.

Neonatal induction of cross-modal projections. To route retinal axons to the auditory thalamus and thus alter the modalityof thalamocortical input, specific lesions were made in ferretkits (Sur et al., 1988; Angelucci et al., 1998). The aim was toreduce normal targets of the retina and to deafferent the medialgeniculate nucleus (MGN; auditory thalamus), thus inducing theretinal axons to innervate MGN and provide the auditory pathwaywith visual information. Within 24 hr after birth, neonates wereplaced on a heating pad and anesthetized with isoflurane. A smallincision was made along the midline of the scalp, and the midbrainwas exposed by removing a flap of bone. A heat cautery was usedto ablate the inferior colliculus (IC) bilaterally, the superficialpart of the left superior colliculus (SC), and the left visualcortex (V1). In addition, the brachium of the inferior colliculus(BIC) was severed. After recovery from the surgery, the kits werereturned to the animal colony. Supportive care and analgesicswere given as necessary throughout the recoveryperiod.

BDA tracer injections. Biotinylated dextran amine was chosen as a tracer to reveal horizontal projections because of its easeof use, its ability to travel anterogradely, and its stability.After administration of atropine (0.04 mg/kg) and doxapram (2mg/kg), adult ferrets (120 d or older) were preanesthetized withketamine (40 mg/kg) combined with xylazine (1-2 mg/kg) or diazepam(2 mg/kg). Amoxicillin (30 mg/kg) was then injected as a prophylacticagainst infection, followed by dexamethasone (40 mg/kg) to preventbrain edema. An endotracheal tube was placed to deliver isofluraneanesthesia and oxygen, and the cephalic vein was cannulated forfluid therapy during the surgery. The head was fixed in a stereotaxicdevice, and electrodes were placed for monitoring of heart rateand respiration. A deep state of anesthesia was maintained with1.25-2% isoflurane. The surgery was then performed under strictaseptic conditions. A flap of skin and muscle was removed fromabove the lateral cortex. A hole was drilled in the skull to exposethe primary auditory cortex (AI), and the dura was retracted.A volume of 50-150 nl of 10% BDA in sterile saline was injectedthrough a micropipette (tip diameter, 15-25 µm) with the aid ofa Picospritzer II (General Valve, Fairfield, NJ). One injectionper hemisphere was made 300-500 µm below the pia, into the superficiallayer 2/3 of AI, approximately in the center of the ectosylviangyrus where AI is located (Fig. 1A) (Kelly et al., 1986). TheBDA was injected slowly over 15-20 min. The opening in the skullwas then covered by a piece of sterile plastic film attached withdental cement. The muscle was sutured, and the incision was closed.The ferret was supervised closely until it recovered from theanesthesia, and was given supportive care and analgesics as necessarythroughout the recovery period.

View larger version (23K):
[in this window]
[in a new window]
Figure 1. A, Drawing of the left side of a ferret brain, with the location of the sulci surrounding AI noted. The arrow shows the approximate location of the tracer injections. aes, Anterior ectosylvian sulcus; pes, posterior ectosylvian sulcus; sss, suprasylvian sulcus; pss, pseudosylvian sulcus. B, Illustration of methods used for making polar plots of bouton distribution. The arrow shows the tracer injection site, and the camera lucida drawing of the resulting label is superimposed on the polar plot. With the injection site as the origin, the polar coordinates of the center of each bouton cluster were recorded. Lines were drawn through the center of each bouton cluster to arrive at the plots shown in Figures 6 and 7. The dashed lines indicate the sulci surrounding AI and show how the plots were oriented.

Tracing of retinal projections. To ensure that the visual inputs were successfully routed into the MGN in cross-modal animals,cholera toxin (B subunit, 1%, 6 µl; List Biological Labs, Campbell,CA) was injected into the posterior chamber of each eye at theend of the BDA injection surgery. Several normal animals werealso given eye injections as a control (Pallas and Moore, 1997).Animals were monitored postsurgically and given topical ophthalmicantibiotics and anti-inflammatory drugs (dexamethasone, 40 mg/kg)ifnecessary.

Histology and immunocytochemistry. After 4-5 d survival, animals were overdosed with sodium pentobarbital (65 mg/kg) and perfusedthrough the heart with 0.1 M PBS followed by 2% paraformaldehydefor 10 min. The brains were quickly extracted from the skull,and the thalamus and midbrain were separated from each hemisphere.The cortical hemispheres were then gently flattened between twoweighted glass plates. After flattening, the tissues were post-fixedwith 4% paraformaldehyde in 30% sucrose/0.1 M phosphate buffer(PB) at 4°C for 24 hr. The brain tissue was then sectioned frozenat 50 µm in a tangential (cortical hemispheres) or coronal (midbrainand thalamus) plane. The sections were collected in 0.1 M PB.One set of sections at 200 µm intervals was mounted onto gelatin-subbedslides for Nissl staining with cresylecht violet. The other sectionswere used forimmunocytochemistry.

To visualize the anterograde labeling resulting from the BDA injections, the cortical sections were rinsed with 0.1 M PBSplus 0.3% Triton X-100 three times for 15 min, then left in samesolution for 1 hr. They were then reacted with ABC complex (VectastainElite; Vector Laboratories, Burlingame, CA) for 1-1.5 hr at adilution of 1:500 in 0.1 M PBS containing 0.3% Triton X-100. Afterthoroughly rinsing in buffer, a diaminobenzidine (DAB) reactionwith 0.02% DAB and 0.008% hydrogen peroxide was performed. Thereactions were intensified by adding 2% nickel ammonium sulfateand 0.68% imidazole (Tago et al., 1989). The sections were thenmounted onto gelatin-subbed slides, dehydrated, cleared in xylene,and coverslipped with Permount (Fisher, Pittsburgh,PA).

The cholera toxin labeling of thalamus was visualized with an antibody to the toxin. The sections were rinsed with 0.1 M PBSwith 0.3% Triton X-100 and 0.34% sodium azide and treated with0.1 M glycine for 1 hr. The nonspecific binding was blocked with3% normal rabbit serum (Vector Laboratories, Burlingame, CA) for1 hr. The sections were then transferred into the primary antibody(goat anti-cholera toxin, 1:2000; List Biological Labs) with 3%normal rabbit serum at 4°C for 3 d. The sections were rinsed againand placed in Cy-2-conjugated rabbit anti-goat secondary antibody(Jackson ImmunoResearch, West Grove, PA) with 3% normal rabbitserum for 4 hr in the dark. The sections were mounted, dried,cleared in xylene, and coverslipped with Krystalon (DiagnosticSystems, Gibbstown,NJ).

Bouton plotting and data analysis. Based on our own and others' studies of the location of normal ferret AI (Kelly et al.,1986; Phillips et al., 1988) and on our own anatomical and physiologicalstudies on cross-modal ferrets (Pallas et al., 1990; Roe et al.,1990, 1992; Pallas and Sur, 1993), AI was defined as the regionon the ectosylvian gyrus bounded by the anterior and posteriorectosylvian sulci, medial to the pseudosylvian sulcus (Fig. 1A).In each case, sections at a depth of 300-500 µm under the pia(layer 2/3) were selected for three-dimensional plotting of boutonsusing a camera lucida and Neurolucida software (Microbrightfield,Burlington, VT) under a Zeiss Axiophot microscope at a magnificationof 400×. The location and size of clusters of boutons were alsorecorded. Clusters were drawn by a blind observer and definedaccording to the presence of concentrated boutons and the relativelyclear-cut borders of each cluster. The isolated axons and radiatingfibers around the injection site were excluded from measures ofcluster area. Boutons were sometimes found lateral to the AI borderin the region known as AII, but these were excluded from theanalysis.

To quantitatively describe the bouton distributions of each animal, polar plots of bouton distribution were constructed (Fig.1B). The location of the injection site was defined as the plotorigin. The angle and distance of individual bouton clusters relativeto the injection site (polar coordinates) and their width andheight were measured using Microbrightfield software. The horizontalaxis (0-180°) was not corrected for section tilt on each slidein plots of individual cases, but was normalized for interanimalcomparisons. In that case, a straight line was drawn from thetop of the pseudosylvian sulcus (pss) extending to the top centerof the suprasylvian sulcus to normalize the angular orientationof sections. This allowed direct, location-matched comparisonof the bouton cluster distributions in AI of both normal and cross-modalanimals. Other quantitative measures taken were bouton density(number of boutons per cluster area), the SD in the location ofeach bouton cluster compared with the location of all clusters(eccentricity, or how scattered the clusters were), the percentcoverage or zone of influence of all boutons together [obtainedby drawing a perimeter through the center of the outermost boutonclusters (Fig. 1B) and dividing that area by the area of AI],and the proportion of AI occupied by the clusters themselves (obtainedby determining the area covered by each cluster, adding all clusterareas in each case, and calculating a percentage of the totalarea of AI). To compare cluster eccentricity between animals,polar plots from different cases were aligned by rotating they-axis of each plot by the number of degrees necessary to matchthe orientation of the cluster vector closest to horizontal. Comparisonswere made in each 90° sector of the map to analyze spatial differencesacross the extent of AI. Statistical comparisons were done usinga Pearson's correlation coefficient analysis or t test as indicated,and all measurements were quoted as means ±SE.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In the following, we report on how the qualitative features (laminar and tangential) of the horizontal connections revealedby the BDA injections differ in normal compared with cross-modalAI, followed by an account of the quantitative differences betweenthe two groups. The BDA injections labeled numerous clusters ofboutons within AI. In general, we found that the horizontal connectivitypatterns in normal ferret AI are organized as they are in cats,in a strip corresponding to the isofrequency axis [which runsanteroposteriorly in ferrets (Kelly et al., 1986; Phillips etal., 1988), perpendicular to its orientation in cats]. However,the bouton clusters in the cross-modal cases were more uniformlyarranged and were not confined to an anteroposterior strip, suggestingthat the early visual inputs directed a reorganization of thenormalpattern.

Methodological considerations

A potential source of artifact with any tracer injection is variability in the size and the depth of the tracer uptake zone.To overcome this drawback, we marked the tip of the injectionmicropipette at 500 µm intervals so that depth of the pipetteplacement could be measured and thus controlled. The injectionswere also done slowly (over 15-20 min) to prevent brain injuriescaused by pressure buildup. We did note that when the injectionamount of BDA was >200 nl or when the depth of the injection pipettewas close to layer 6 and the white matter, the anterograde labelingwas very variable, and thus those cases were excluded from thisstudy.

We did not attempt to analyze labeled terminals that were within 500 µm of the injection site. There were two reasons forthis: the high density of labeled processes and terminals closeto the halo from the injection made it difficult to obtain anaccurate impression of them, and also the local axonal projectionsmay arise from a different class of axon collaterals (Ojima etal., 1991; Dalva and Katz, 1994), including inhibitoryinterneurons.

Injection size and location

The BDA injections were located approximately in the center of AI to facilitate comparison across animals. They consistentlyproduced good anterograde label in AI. Labeled axons were readilyrecognized even in the close vicinity of the injection site. Ineach case, there was necrosis at the core region of the injectionsite and a halo zone a short distance around it. Only in the coreregion was the labeling obscured by the dark reaction product.In Figure 2A a typical injection site is shown, and neuronal fiberscan be seen streaming in an anterograde direction away from thesite. These BDA injections produced label in a series of patchesor clusters at a distance from the injection site (Fig. 2B). Theclusters varied in the density of their neuronal processes aswell as their bouton density (Fig. 2C). Clusters were more densenear the sulcal borders. In addition to the labeled axonal terminals,a few retrogradely labeled somata were also seen (Fig. 2B), althoughthey tended to lie outside of the bouton clusters.

View larger version (96K):
[in this window]
[in a new window]
Figure 2. BDA injections were made into layer 2/3 of AI in adult ferrets. A, An example of an injection site in a tangential section through AI. Note the relatively small and densely packed appearance of the halo and the fibers exiting the center. B, The BDA injections resulted in the labeling of several clusters of axon terminals in AI. This micrograph shows two such clusters, one very dense (arrowhead) and the other more sparse. C, At higher magnification, individual boutons within a patch can be seen. The locations of these boutons were mapped at high magnification and used for data analysis. Scale bar: A, 300 µm; B, 150 µm; C, 40 µm.

Care was taken to make comparably sized BDA injections in all animals to ensure that any differences seen between normal andcross-modal cases were not caused by this variable. To ensurethat the variation was similar in normal and cross-modal groups,the core of the injection as well as the diameter of the haloof label surrounding the injection site were measured (Table 1).The injection sites were small (mean core diameter of 417 ± 30.6µm in normal animals and 366 ± 33.7 µm in cross-modal animals,and a mean halo diameter of 565 ± 60.1 µm in normal animals comparedwith 507 ± 34.7 µm in cross-modal animals), and did not differsignificantly between normal and experimental animals (for coresize, p = 0.27; for halo size, p = 0.420). Furthermore, injectionsize was not significantly correlated with the number of labeledbouton clusters within each group (see below) (r = 0.089 for normaland 0.268 for cross-modal cases). Thus, injection size was unlikelyto be a factor in the differences seen between normal and cross-modalcases. We did note that with very large injections (>200 nl ofBDA and 1000 µm diameter injection sites), the anterograde labelwas distributed more widely, as would be expected in normal animalsif the injection crossed many isofrequency lines (Wallace andBajwa, 1991). Such cases were not included in this study.


View this table:
[in this window]
[in a new window]
Table 1. Tracer injection and patch distribution^a

Relationship between lesion size and retinal axon rerouting

A second technical variable that required consideration was the fact that the amount of retinal axon rerouting into the MGNdepends on the size of the neonatal lesions (Angelucci et al.,1997, 1998). For this reason, lesions were reconstructed and rankedas large (>75% of the midbrain absent), medium (50-75% of themidbrain absent), or small (<50% missing). Of the seven cross-modalferrets used in this study, two had a large lesion (9836 and 9869),four had a medium lesion (9834, 9837, 9865, and 9823), and onehad a small lesion (9819). When the pattern of anterograde retino-MGNlabel from eye injections was analyzed, we found that 100% ofthe cross-modal ferrets had retino-MGN axons, and four of sevenhad numerous such axons. Retinal axons were very rarely seen inMGN of normal animals; in the course of several investigationsusing intraocular cholera toxin injections, we have seen retino-MGNaxons in <10% of animals (n = 57), and then only one axon wasobserved that appeared to have strayed slightly from the medialborder of the LGN (Pallas and Moore, 1997).

Although the cases used in this study varied in lesion size and extent of cross-modal rewiring, the lack of multiple casesat each lesion size prevented us from firmly relating any observeddifferences in horizontal connectivity patterns to this variable.It is possible that with a larger study involving a wider varietyof lesion sizes an effect could be seen, and this would be aninteresting avenue for furtherinvestigation.

Tangential distribution of horizontal connections

The observed differences in the tangential distribution of bouton clusters between normal and cross-modal cases were analyzedqualitatively with respect to their number and mediolateral oranteroposterior location. The distribution of clusters in thetangential plane was clearly different in normal animals as comparedwith cross-modal animals. The clusters in normal animals weredistributed mainly in strips extending anteriorly and posteriorlyaway from the injection site up to the anterior ectosylvian andposterior ectosylvian sulci (Fig. 3A). The anteroposterior axiscorresponds to the isofrequency axis of the tonotopic map in theseanimals (Kelly et al., 1986; Kelly and Judge, 1994). However,in cross-modal animals, in addition to those axons extending alongthe isofrequency axis, the injections also labeled axons thatextended medially, forming bouton clusters in medial AI (Fig.3B). Along with bouton clusters located outside of anteroposteriorstrips, we noted that there were more clusters in cross-modalthan normal AI, and they were noticeably more widespread in theirdistribution pattern when compared with the bouton clusters innormal AI.

View larger version (97K):
[in this window]
[in a new window]
Figure 3. Digitized micrograph of a tangential section through layer 2/3 of AI, showing the pattern of bouton clusters arising from long range horizontally projecting axons in representative normal (A) and cross-modal (B) animals. The arrows indicate the injection sites. Anterior is to the left, and medial is up in this and the other figures. Scale bar, 1 mm.

To illustrate cluster distribution and confirm our light microscopic observations, the locations of all labeled boutons withinlayer 2/3 were mapped at high magnification (400×). In Figure4, bouton distributions in one representative tangential sectionare shown for four normal and four cross-modal cases. In the reconstructionsfrom normal animals (Fig. 4, top), it can be seen that the BDA-labeledaxonal arbors extended mainly anteriorly and posteriorly fromthe injection site and formed patches distributed along the anteroposterioraxis. Clusters could be identified and followed through severalserial tangential sections.

View larger version (22K):
[in this window]
[in a new window]
Figure 4. Reconstruction of the bouton distributions in a representative tangential section through layer 2/3 from four normal (top) and four cross-modal (bottom) cases after BDA injections in AI. Each dot represents a single bouton. The BDA-labeled axonal arbors in normal ferrets were distributed mainly in an anteroposterior direction, along the same axis as the isofrequency domains. The case shown in the bottom right was the most atypical in that the boutons were arranged more medially than in the other cases. In cross-modal AI, the axonal projections and thus the bouton clusters were more widely distributed than in normal AI and were more likely to be found in the medial part of AI. In one case, there are two clusters ventral to the pseudosylvian sulcus which are likely located in AII rather than AI. Scale bar, 1 mm.

In contrast to normal cases, in cross-modal cases the bouton clusters were arranged in a semicircular pattern around the injectionsite (Fig. 4, bottom). In all seven of the cross-modal animalsused in this experiment, the clusters were distributed in thissemicircular pattern, whereas in normal animals the pattern waselongated. The presence of bouton clusters at the medial crownof the ectosylvian gyrus was in striking contrast to what wasseen in normal AI, and in addition to being distributed more widely,the clusters also appeared more numerous. Some clusters in bothgroups extended lateral to the top of the pseudosylvian sulcusinto what was probably the secondary auditory area AII (Fig. 4bottom, top left) (Pallas et al., 1990; Pallas and Sur, 1993),but these were not included in furtheranalyses.

Figure 5 shows polar plots of the three-dimensional extent of the bouton distributions of the labeled clusters in normal (Fig.5, top) and cross-modal (Fig. 5, bottom) cases, correspondingto the reconstructions shown in Figure 4. These plots were madeby drawing a perimeter around the centers of the outermost boutonclusters (Fig. 1), and they illustrate the overall extent of coverageof auditory cortex by horizontal connections; i.e., their zoneof influence or coverage area. The polar plots of the coverageareas in normal animals were stripe-like and elongated anteroposteriorlyalong the isofrequency axis of the tonotopic map. In contrast,in cross-modal animals the coverage areas extended over a largerarea of AI and were not strip-like, but were more circular orisotropic, with a rosette or fan shape.

View larger version (25K):
[in this window]
[in a new window]
Figure 5. Polar plots showing the coverage area of the labeled boutons from four normal (top) and four cross-modal (bottom) cases, corresponding to those in Figure 4. The bouton clusters covered an elongated strip extending anteroposteriorly in normal animals, but in cross-modal cases covered a wider, more circular area and extended mediolaterally as well as anteroposteriorly, often resembling a rosette-like pattern.

The cluster distributions from all seven normal and seven cross-modal animals are summarized in Figure 6. The labeled boutonclusters in normal AI were arranged in an elongated fashion oneither side of the injection site in all cases. Within the anteriorhalf of AI, the population of clusters was centered on a vectorof 163° ± 6.6, and in the posterior half it was centered at 14.8°± 7.5. Most bouton clusters in normal AI were located within thesemore anterior and posterior sectors of the polar plot, ratherthan in the medial (centered on 90°) and lateral (centered on270°) sectors. There were no clusters in the sectors at 60-90°or 300-330° and very few at 180-300°. However, in the cross-modalcases all of these regions contained several clusters.

View larger version (25K):
[in this window]
[in a new window]
Figure 6. Combined polar plots showing the locations of the centers of all bouton clusters from seven normal cases (left) and seven cross-modal cases (right). To align the plots from different animals, the horizontal axis of the plot (0-180°) was aligned with the axis of the pseudosylvian sulcus in each case (Fig. 1), and the polar coordinates of the center of each bouton cluster were recorded. Each case is represented by its own symbol. The clusters in normal animals were anisotropically arranged and were preferentially located within anterior and posterior sectors. In contrast, the labeled bouton clusters in cross-modal ferrets were arranged more isotropically and were located in all sectors.

Quantitative analysis of bouton clusters

To characterize the distributions of labeled bouton clusters in both groups quantitatively, several measures were taken. Toanalyze the individual clusters, cluster size (diameter = meanof height and width) and shape (elongation factor, as determinedby the ratio of height to width) were measured. There were nosignificant differences between the normal and cross-modal groupsin either cluster size (Table 1, Fig. 7A; mean of normals, 790.4± 30.89 µm and mean of cross-modals, 812.1 ± 26.80 µm; p = 0.6)or shape (Fig. 7B; 1.6 ± 0.05 in normal and 1.5 ± 0.04 in cross-modal;p = 0.4), suggesting that the early visual inputs have no effecton the general morphology of bouton clusters. However, the visualinput did have a significant effect on the number of bouton clusterscontained within AI (Table 1, Fig. 7C; normal mean, 10.3 ± 1.43;cross-modal mean, 16.7 ± 0.61; p = 0.001).

View larger version (38K):
[in this window]
[in a new window]
Figure 7. Quantitative comparison of the bouton clusters in both normal (dark bars) and cross-modal (striped bars) animals. Asterisks indicate significant differences. A, B, Comparisons at the level of individual clusters. A, Cluster size (average of height and width) was similar in both groups. B, Cluster shape as measured by elongation factor (major axis of patch divided by minor axis) was also not significantly different between the two groups. C-F, Comparisons at the level of bouton cluster patterns. C, The number of clusters was significantly greater in cross-modal than normal AI. D, Cluster distance distribution. The distance of bouton clusters from the center of the injection site in both normal and cross-modal animals was similar. E, The area which was covered by bouton clusters (zone of influence) was also significantly larger in the cross-modal cases. F, Amount of scatter (SD) of bouton clusters away from the horizontal, isofrequency axis of the polar plots. This was a measure of the tendency of clusters to be more widely distributed in cross-modal than normal animals. There was a significant difference between the two groups.

To analyze this difference further, a comparison of the distribution of bouton clusters was made between normal and cross-modalcases. Bouton density within the clusters was averaged and foundto be similar in the two groups (3.26 ± 0.91 boutons/1000 µm² in normals and 3.72 ± 0.63 in cross-modal cases; p = 0.7). Wefound that the distribution of the distances of individual clustersto the center of the injection site was also similar in both groups(Fig. 7D, Table 1; p = 0.5), demonstrating that although theclusters are more numerous in cross-modal than in normal AI, theymaintain a similar lateral extent. However, this is not true whenthe entire zone of influence is considered. Because of the widespreadnature of the clusters in the cross-modal cases, they have a muchgreater zone of influence (Fig. 7E; normal, 27.2 ± 4.51%; cross-modal,52.9 ± 6.22%; p = 0.001) compared with normal AI. Consistent withthis, a measure of the proportion of AI occupied by the clustersthemselves shows that they occupied significantly less of AI innormal than in cross-modal cases (7.2 ± 1.36% in normals vs 14.8± 2.60% in cross-modals; p = 0.02). Thus, the horizontal projectionsfrom a given locus in AI can influence a larger extent of AI incross-modal animals, even though the radius of influence (clusterdistance from the injection site) does notchange.

It is clear from the camera lucida reconstructions of labeled boutons that the bouton clusters are less likely to lie on theanteroposterior, isofrequency axis in cross-modal animals. Toquantify the degree to which bouton clusters varied away fromthe anteroposterior axis, a cluster eccentricity from this axiswas calculated. This calculation of how far the labeled boutonclusters scattered from the axis was made by measuring the SDof clusters from their anteroposterior axis (eccentricity). Themean scatter was 884.5 ± 61.87 µm in cross-modal animals, whichwas significantly greater than the 619.1 ± 60.82 µm extent ofscatter in normal animals (p = 0.005; Fig. 7F).

In sum, these quantitative measures confirm the qualitative impressions presented above. The labeled clusters of boutons incross-modal AI, although of similar size and shape, and comparabledistance from the injection site, were more widely distributedthan in normal animals, and were scattered further from the isofrequencyaxis, where they were in a position to influence a larger proportionof the cortical circuitry withinAI.

Laminar distribution of horizontal connections

The pattern of horizontal connectivity in AI was analyzed in both the laminar and tangential planes. Although all brains usedin this study were sectioned in the tangential plane, the correspondingNissl-stained sections allowed determination of the approximatelaminar location of neuronal fibers and boutons by calculatingtheir position in relation to the granule cell layer. BDA injectionswere targeted on layer 2/3 in AI, at a depth of 300-500 µm fromthe cortical surface, and thus the neuronal processes leavingthe injection site originated primarily from those layers. However,in three normal and four cross-modal cases, a few clusters ofhorizontal connections could also be observed in the deeper layers.Bouton clusters also sometimes appeared in the secondary auditorycortical area, AII. In this study only boutons in layers 2/3 ofarea AI were analyzed. Occasionally, some of the labeled axonsentered the white matter, but were never observed extending intothe contralateral hemisphere. No apparent differences in the laminarextent of BDA-labeled fibers were consistently observed betweennormal and cross-modal cases, within the limitations presentedby tangential reconstructions. Further information could be gatheredon this topic by repeating this study and sectioning the tissuein the coronalplane.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The results of this study show that the characteristic horizontal connections between auditory cortical neurons can be alteredby early anomalous visual input, and become less elongated thannormal, deviating substantially from the isofrequency axis. Inaddition to the change in the pattern of horizontal connections,their number and zone of influence were increased. Therefore,our results support the hypothesis that local horizontal connectionsin cross-modal AI are susceptible to instruction from the visuallydriven pattern of activity in thalamocortical inputs during postnataldevelopment. Because we have not altered the thalamocortical pathwayin this paradigm, we suggest that the identity of the thalamicnucleus carrying the visual information does not influence thisprocess, or at least that it cannot override the sensory modality-basedinstructions for constructing intrinsic corticalcircuits.

Horizontal connections in normal AI are oriented along the anteroposterior axis

In primary visual cortex, long distance intracortical collaterals of pyramidal neurons link together neurons responding tosimilar stimulus features in a manner independent of their location(for review, see Rockland, 1998). This general organizationalfeature has also been seen in primary auditory cortex of catsand ferrets, where horizontal connections link neurons along anisofrequency domain (Reale et al., 1983; Matsubara and Phillips,1988; Ojima et al., 1991; Wallace et al., 1991; Clarke et al.,1993).

Our results show that the pattern of horizontal connections in normal ferrets is similar to that in cats, except that thetrajectory of bouton clusters was oriented anteroposteriorly,roughly perpendicular to its orientation in cats (Reale et al.,1983). However, the tonotopic map in ferrets is also perpendicularto that in cats, with high frequencies represented medially andlow frequencies laterally (Kelly et al., 1986; Phillips et al.,1988). Thus, the horizontal connections are oriented as wouldbe expected if their function in ferrets and cats is to link neuronswith similar sound frequency tuning. In the context of this study,we did not determine whether there was any restriction of connectionsaccording to binaural properties; this would be an interestingquestion for a combined anatomical/physiologicalstudy.

A previous report on horizontal connectivity patterns in normal ferret AI (Wallace and Bajwa, 1991) proposed that horizontalcollaterals link neurons with both similar and different frequencytuning, unlike in cats. These results raised the interesting possibilitythat a species difference exists and that auditory stimulus featuresother than frequency are linked in an organized fashion in ferretsbut not cats. However, our data on horizontal connectivity innormal ferret AI differ with this interpretation, because we foundbouton clusters to be very strongly biased along the anteroposterior,isofrequency axis, and almost completely excluded from other regions.This difference is probably the result of a difference in methodology,because the injections in this study were smaller and perhapsmore superficial than those in the other study. Larger injectionswould be expected to label more isofrequencylaminae.

Horizontal connections in cross-modal AI are arranged in a semicircular pattern

We found that the pattern of long distance, horizontal projections in AI with early visual input was distinctly differentfrom that in normal AI. Bouton clusters were arranged in a semicirclearound injection sites, rather than being arranged anisotropicallyalong the anteroposterior axis. The clusters were also greaterin number and thus in the proportion of AI that they occupied.Despite these differences in number and pattern, the shape andsize of the clusters was unaffected by visual input, and thesecharacteristics are perhaps outside of afferent activity-basedcontrol. Our interpretation of these data are that the visuallydriven activity of thalamic inputs, and not their anatomical source,controls the organization of intracortical circuitry. This couldoccur via Hebbian mechanisms, based on correlated activation ofneighboring retinal neurons or neurons with similar visual responseproperties.

In cat and ferret visual cortex, long distance axon collaterals are initially widespread, and bouton clusters only begin todevelop postnatally (Rockland and Lund, 1982; Callaway and Katz,1990; Dalva and Katz, 1994; Durack and Katz, 1996). Spontaneousactivity is required for early cluster formation, whereas laterstages of refinement are dependent on visually driven activity(Callaway and Katz, 1991; Löwel and Singer, 1992; Ruthazer andStryker, 1996). The development of horizontal connectivity inferret or cat auditory cortex has not been studied, although callosalconnections in cat auditory cortex show a similar, early diffusedevelopmental pattern as in cat V1 (Feng and Brugge, 1983). Thereare several reasons to conclude that the circular arrangementof bouton clusters that we observed is driven by the visual inputs,and not by a lack of normal auditory input to AI in cross-modalanimals. One is that our studies of callosal connections in deafenedand cross-modal ferrets (Pallas et al., 1999) show that the cross-modalcallosal connectivity pattern is distinct from the pattern inboth the normal and deaf groups. Second, if the location of clustersoutside of the isofrequency axis resulted from a lack of correlatedinput activity, it might be expected that they would remain onlypartially refined, as in deprived visual cortex. Instead, theclusters in the cross-modal animals actually looked more denseand compact than in normal animals. Furthermore, the number ofclusters was greater than normal in the cross-modal cases. Itis difficult to envision how a relaxation of cluster refinementmechanisms would result in an increased number of more refinedclusters. Finally, our preliminary studies indicate that horizontalconnections in deafened animals are diffuse and unorganized, suggestingthat in the cross-modal animals the early anomalous visual inputsare driving the formation of specific projections from intracorticallyprojecting pyramidal neurons (Gao et al., 1999; Pallas and Gao,1999).

The functional role of the long distance projections in cross-modal AI cannot be determined from our anatomical data. Thereis a retinotopic map in cross-modal AI, and neurons tuned to visualstimulus orientation are also found there (Roe et al., 1990, 1992).The altered horizontal connectivity pattern may be responsiblein part for the creation of these visual response properties inauditory cortex. An intriguing possibility is that the boutonclusters in cross-modal AI are organized as in visual cortex,where neurons with similar response properties, such as orientationtuning, are connected in an isotropic pattern across the retinotopicmap. Although there is some suggestion that neurons in cross-modalAI with similar orientation tuning are clustered (Sharma et al.,1996), it is unknown whether they are arranged in pinwheel fashionas in visual cortex. The resemblance seen between the arrangementof bouton clusters in AI and those found in normal ferret visualcortex (Weliky and Katz, 1994; Durack and Katz, 1996; Ruthazerand Stryker, 1996) is suggestive of a similar function. Alternatively,there may be a different substrate for bouton cluster organizationin cross-modal AI that is also roughly isotropic in pattern. Ourfuture efforts will be directed at answering thisquestion.

Implications for cortical specification

Cortical areal specification refers to a stepwise process whereby the fate ("identity") of a cortical region is progressivelyrestricted. Different steps are likely to be controlled by differentfactors. There is substantial evidence that thalamocortical afferentsplay a role in establishing some aspects of regional identity.Several molecular markers are found only in certain cortical regions(Levitt, 1984; Arimatsu et al., 1992; Cohen-Tannoudji et al.,1994; Paysan et al., 1994), and in at least one case marker expressionseems to be triggered by thalamic input (Levitt et al., 1997),but a causal relationship between marker expression and arealspecification is difficult to establish. It is clear that thereare detailed recognition mechanisms guiding thalamic axons tothe proper cortical region (Ghosh et al., 1990; Suzuki et al.,1997; Castellani et al., 1998; Inoue et al., 1998; Mann et al.,1998), suggesting that thalamocortical axons may instruct regionalidentity. This instruction could depend on the source of the thalamocorticalaxons, their activity pattern, or both. The results of this study,by showing that auditory thalamic axons carrying visual informationcan reorganize horizontal projections, strongly suggest that theorganization of intrinsic cortical connections depends not onthe source of thalamic inputs but on their modality-dependentactivity patterns. The results further suggest that activity inthis case is not merely permissive but instructive (Crair, 1999).

Clinical evidence relevant to this issue includes the observation that in blind and deaf patients, the "unused" cortical areacan be taken over and used by a different sensory modality (Nevilleet al., 1983; Sadato et al., 1996; Cohen et al., 1997; Kujalaet al., 1997; Lessard et al., 1998). Cross-modal plasticity hasalso been demonstrated in other animal models (Rebillard et al.,1977; Heil et al., 1991; Rauschecker, 1995), but it has not beenclear in each case whether the novel inputs reorganize corticalcircuitry during development or whether they simply take advantageof existing circuits. Furthermore, it is not known whether theinvasion and reorganization process is dependent on the patternof activity or the identity of the thalamocortical afferents.Our results suggest that activity-dependent control over corticalcircuit formation by thalamocortical afferents, based on correlatedactivity within neighboring regions of the retina, may explaina number of these observations. Furthermore, it may provide ageneral mechanism for cortical regionalization at the circuitlevel of organization. Such an afferent-driven organization rulewould have broad implications for both the development and theevolution of mammalian sensorycortex.

  FOOTNOTES

Received Feb. 5, 1999; revised June 18, 1999; accepted June 30, 1999.

This work was supported by grants to S.L.P. from the National Science Foundation, the Whitehall Foundation, the Fight forSight Inc. Research Division of Prevent Blindness America, andthe Georgia Research Alliance. We thank Astou Coly and Karen Pagefor their technical expertise, and Reha Erzurumlu, Barbara Finlay,Paul Katz, and Joanne Matsubara for their helpful criticisms ofthismanuscript.
Correspondence should be addressed to S. L. Pallas, Department of Biology, Georgia State University, P.O. Box 4010, Atlanta,GA30302.

Dr. Gao's present address: Section of Neurobiology, Yale University School of Medicine, 333 Cedar Street, New Haven, CT 06510.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Angelucci A, Clascá F, Bricolo E, Cramer KS, Sur M (1997) Experimentally induced retinal projections to the ferret auditory thalamus: development of clustered eye-specific patterns in a novel target. J Neurosci 17:2040-2055[Abstract/Free Full Text].
Angelucci A, Clascá F, Sur M (1998) Brainstem inputs to the ferret medial geniculate nucleus and the effect of early deafferentation on novel retinal projections to the auditory thalamus. J Comp Neurol 400:417-439[Web of Science][Medline].
Arimatsu Y, Miyamoto M, Nihonmatsu I, Hirata K, Uratani Y, Hatanaka Y, Takiguchi-Hayashi K (1992) Early regional specification for a molecular neuronal phenotype in the rat neocortex. Proc Natl Acad Sci USA 89:8879-8883[Abstract/Free Full Text].
Bosking WH, Zhang Y, Schofield B, Fitzpatrick D (1997) Orientation selectivity and the arrangement of horizontal connections in tree shrew striate cortex. J Neurosci 17:2112-2127[Abstract/Free Full Text].
Callaway EM, Katz LC (1990) Emergence and refinement of clustered horizontal connections in cat striate cortex. J Neurosci 10:1134-1153[Abstract].
Callaway EM, Katz LC (1991) Effects of binocular deprivation on the development of clustered horizontal connections in cat striate cortex. Proc Natl Acad Sci USA 88:745-749[Abstract/Free Full Text].
Castellani V, Yue Y, Bolz J (1998) Dual action of a ligand for eph receptor tyrosine kinases on specific populations of axons during the development of cortical circuits. J Neurosci 18:4663-4672[Abstract/Free Full Text].
Catalano SM, Shatz CJ (1998) Activity-dependent cortical target selection by thalamic axons. Science 281:559-562[Abstract/Free Full Text].
Clarke S, de Ribaupierre F, Rouiller EM, de Ribaupierre Y (1993) Several neuronal and axonal types form long intrinsic connections in the cat primary auditory cortical field (AI). Anat Embryol (Berl) 188:117-138[Medline].
Cohen LG, Celnik P, Pascual-Leone A, Cornwell B, Faiz L, Dambrosias J, Honda M, Sadato N, Gerloff C, Catala MD, Hallett M (1997) Functional relevance of cross-modal plasticity in blind humans. Nature 389:180-186[Medline].
Cohen-Tannoudji M, Babinet C, Wassef M (1994) Early determination of a mouse somatosensory cortex marker. Nature 368:460-463[Medline].
Crair MC (1999) Neuronal activity during development: permissive or instructive? Curr Opin Neurobiol 9:88-99[Web of Science][Medline].
Dalva MB, Katz LC (1994) Rearrangements of synaptic connections in visual cortex revealed by laser photostimulation. Science 265:255-258[Abstract/Free Full Text].
Durack JC, Katz LC (1996) Development of horizontal projections in layer 2/3 of ferret visual cortex. Cereb Cortex 6:178-183[Abstract/Free Full Text].
Feng JZ, Brugge JF (1983) Postnatal development of auditory callosal connections in the kitten. J Comp Neurol 214:416-426.
Gao W-J, Moore DR, Pallas SL (1999) Bilateral cochlear ablation in neonatal ferrets prevents refinement of horizontal connectivity in primary auditory cortex. Soc Neurosci Abstr 25, in press.
Ghosh A, Antonini A, McConnell SK, Shatz CJ (1990) Requirement for subplate neurons in the formation of thalamocortical connections. Nature 347:179-181[Medline].
Gilbert CD, Wiesel TN (1979) Morphology and intracortical projections of functionally characterised neurones in the cat visual cortex. Nature 280:120-125[Medline].
Gilbert CD, Wiesel TN (1983) Clustered intrinsic connections in cat visual cortex. J Neurosci 3:1116-1133[Abstract].
Gilbert CD, Wiesel TN (1989) Columnar specificity of intrinsic horizontal and corticocortical connections in cat visual cortex. J Neurosci 9:2432-2442[Abstract].
Heil P, Bronchti G, Wollberg Z, Scheich H (1991) Invasion of visual cortex by the auditory system in the naturally blind mole rat. NeuroReport 2:735-738[Web of Science][Medline].
Imig TJ, Reale RA, Brugge JF, Morel A, Adrian HO (1986) Topography of cortico-cortical connections related to tonotopic and binaural maps of cat auditory cortex. In: Two hemispheres-one brain: functions of the corpus callosum (Leporé F, Ptito M, Jasper HH, eds), pp 103-115. New York: Alan R. Liss.
Inoue T, Tanaka T, Suzuki SC, Takeichi M (1998) Cadherin-6 in the developing mouse brain: expression along restricted connection systems and synaptic localization suggest a potential role in neuronal circuitry. Dev Dyn 211:338-351[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].
Kelly JB, Judge PW (1994) Binaural organization of primary auditory cortex in the ferret (Mustela putorius). J Neurophysiol 71:904-913[Abstract/Free Full Text].
Kelly JB, Judge PW, Phillips DP (1986) Representation of the cochlea in primary auditory cortex of the ferret (Mustela putorius). Hear Res 24:111-115[Web of Science][Medline].
Kujala T, Alho K, Huotilainen M, Ilmoniemi RJ, Lehtokoski A, Leinonen A, Rinne T, Salonen O, Sinkkonen J, Standertskjöld-Nordenstam CG, Näätänen R (1997) Electrophysiological evidence for cross-modal plasticity in humans with early- and late-onset blindness. Psychophysiology 34:213-216[Web of Science][Medline].
Lessard N, Pare M, Lassonde M (1998) Early-blind human subjects localize sound sources better than sighted subjects. Nature 395:278[Medline].
Levitt P (1984) A monoclonal antibody to limbic system neurons. Science 223:229-301.
Levitt P, Barbe MF, Eagleson KL (1997) Patterning and specification of the cerebral cortex. Annu Rev Neurosci 20:1-24[Web of Science][Medline].
Löwel S, Singer W (1992) Selection of intrinsic horizontal connections in the visual cortex by correlated neuronal activity. Science 209-212.
Malach R, Amir Y, Harel M, Grinvald A (1993) Relationship between intrinsic connections and functional architecture revealed by optical imaging and in vivo targeted biocytin injections in primate striate cortex. Proc Natl Acad Sci USA 90:10469-10473[Abstract/Free Full Text].
Mann F, Zhukareva V, Pimenta A, Levitt P, Bolz J (1998) Membrane-associated molecules guide limbic and nonlimbic thalamocortical projections. J Neurosci 18:9409-9419[Abstract/Free Full Text].
Matsubara JA, Phillips DP (1988) Intracortical connections and their physiological correlates in the primary auditory cortex (AI) of the cat. J Comp Neurol 268:38-48[Web of Science][Medline].
Matsubara JA, Cynader M, Swindale NV, Stryker MP (1985) Intrinsic projections within visual cortex: Evidence for orientation-specific local connections. Proc Natl Acad Sci USA 82:935-939[Abstract/Free Full Text].
Matsubara JA, Cynader MS, Swindale NV (1987) Anatomical properties and physiological correlates of the intrinsic connections in cat area 18. J Neurosci 7:1428-1446[Abstract].
Neville HJ, Schmidt A, Kutas M (1983) Altered visual-evoked potentials in congenitally deaf adults. Brain Res 266:127-132[Web of Science][Medline].
O'Leary DDM (1989) Do cortical areas emerge from a protocortex? Trends Neurosci 12:400-406[Web of Science][Medline].
Ojima H, Honda C, Jones EG (1991) Patterns of axon collateralization of identified supragranular pyramidal neurons in the cat auditory cortex. Cereb Cortex 1:80-94[Abstract/Free Full Text].
Pallas SL (1990) Cross-modal plasticity in sensory cortex: visual responses in primary auditory cortex in ferrets with induced retinal projections to the medial geniculate nucleus. In: The neocortex: ontogeny and phylogeny. NATO Advanced Research Workshop (Finlay BL, Innocenti G, Scheich H, eds), pp 205-218. New York: Plenum.
Pallas SL, Gao W-J (1999) Cross-modal reorganization of cortical connectivity. Invest Ophthalmol Vis Sci 40:S645.
Pallas SL, Moore DR (1997) Retinal axons arborize in the medial geniculate nucleus of neonatally-deafened ferrets. Soc Neurosci Abstr 23:1994.
Pallas SL, Sur M (1993) Visual projections induced into the auditory pathway of ferrets. II. Corticocortical connections of primary auditory cortex with visual input. J Comp Neurol 337:317-333[Web of Science][Medline].
Pallas SL, Roe AW, Sur M (1990) Visual projections induced into the auditory pathway of ferrets. I. Novel inputs to primary auditory cortex (AI) from the LP/Pulvinar complex and the topography of the MGN-AI projection. J Comp Neurol 298:50-68[Web of Science][Medline].
Pallas SL, Littman T, Moore DR (1999) Cross-modal reorganization of callosal connectivity in auditory cortex without altering thalamocortical input. Proc Natl Acad Sci USA 96:8751-8756[Abstract/Free Full Text].
Paysan J, Bolz J, Mohler H, Fritschy J-M (1994) GABA_A receptor a1 subunit, an early marker for area specification in developing rat cerebral cortex. J Comp Neurol 350:133-149[Web of Science][Medline].
Phillips DP, Judge PW, Kelly JB (1988) Primary auditory cortex in the ferret (Mustela putorius): neural response properties and topographic organization. Brain Res 443:281-294[Web of Science][Medline].
Rakic P (1988) Specification of cerebral cortical areas. Science 241:170-176[Abstract/Free Full Text].
Rauschecker JP (1995) Compensatory plasticity and sensory substitution in the cerebral cortex. Trends Neurosci 18:36-43[Web of Science][Medline].
Reale RA, Brugge JF, Feng JZ (1983) Geometry and orientation of neuronal processes in cat primary auditory cortex (AI) related to characteristic-frequency maps. Proc Natl Acad Sci USA 80:5449-5453[Abstract/Free Full Text].
Rebillard G, Carlier E, Rebillard M, Pujol R (1977) Enchancement of visual responses in the primary auditory cortex of the cat after an early destruction of cochlear receptors. Brain Res 129:162-164[Web of Science][Medline].
Rockland KS (1998) Complex microstructures of sensory cortical connections. Curr Opin Neurobiol 8:545-551[Web of Science][Medline].
Rockland KS, Lund JS (1982) Widespread intrinsic connections in the tree shrew visual cortex. Science 215:1532-1534[Abstract/Free Full Text].
Roe AW, Pallas SL, Hahm J, Sur M (1990) A map of visual space induced in primary auditory cortex. Science 250:818-820[Abstract/Free Full Text].
Roe AW, Pallas SL, Kwon Y, Sur M (1992) Visual projections routed to the auditory pathway in ferrets: receptive fields of visual neurons in primary auditory cortex. J Neurosci 12:3651-3664[Abstract].
Ruthazer ES, Stryker M (1996) The role of activity in the development of long-range horizontal connections in area 17 of the ferret. J Neurosci 16:7253-7269[Abstract/Free Full Text].
Sadato N, Pascual-Leone A, Grafman J, Ibañez V, Deiber MP, Dold G, Hallett M (1996) Activation of the primary visual cortex by Braille reading in blind subjects. Nature 380:526-528[Medline].
Sharma J, Angelucci A, Rao SC, Sheth BR, Sur M (1996) Auditory cortex with induced visual projections: horizontal connectivity and optical imaging of functional responses. Soc Neurosci Abstr 22:1730.
Sur M, Garraghty PE, Roe AW (1988) Experimentally induced visual projections into auditory thalamus and cortex. Science 242:1437-1441[Abstract/Free Full Text].
Sur M, Pallas SL, Roe AW (1990) Cross-modal plasticity in cortical development: differentiation and specification of sensory neocortex. Trends Neurosci 13:227-233[Web of Science][Medline].
Suzuki SC, Inoue T, Kimura Y, Tanaka T, Takeichi M (1997) Neuronal circuits are subdivided by differential expression of Type-II classic cadherins in postnatal mouse brains. Mol Cell Neurosci 9:433-447[Web of Science][Medline].
Tago H, McGeer P, McGeer E, Akiyama H, Hersh L (1989) Distribution of choline acetyltransferase immunopositive structures in the rat brainstem. Brain Res 495:271-297[Web of Science][Medline].
T'so DY, Gilbert CD, Wiesel TN (1986) Relationships between horizontal interactions and functional architecture in cat striate cortex as revealed by cross-correlation analysis. J Neurosci 6:1160-1170[Abstract].
Wallace MN, Bajwa S (1991) Patchy intrinsic connections of the ferret primary auditory cortex. NeuroReport 2:417-420[Web of Science][Medline].
Wallace MN, Kitzes LM, Jones EG (1991) Intrinsic inter- and intralaminar connections and their relationship to the tonotopic map in cat primary auditory cortex. Exp Brain Res 86:527-544[Web of Science][Medline].
Weliky M, Katz LC (1994) Functional mapping of horizontal connections in developing ferret visual cortex: experiments and modeling. J Neurosci 14:7291-7305[Abstract].

Copyright © 1999 Society for Neuroscience 0270-6474/99/19187940-11$05.00/0

This article has been cited by other articles:

J. Syka
Plastic Changes in the Central Auditory System After Hearing Loss, Restoration of Function, and During Learning
Physiol Rev, July 1, 2002; 82(3): 601 - 636.
[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 (25)

Citing Articles via Google Scholar

Google Scholar

Articles by Gao, W.-J.

Articles by Pallas, S. L.

Search for Related Content

PubMed

PubMed Citation

Articles by Gao, W.-J.

Articles by Pallas, S. L.