Identification of an Invariant Response: Stable Contact with Schwann Cells Induces Veil Extension in Sensory Growth Cones

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The Journal of Neuroscience, February 1, 2000, 20(3):1044-1055

Identification of an Invariant Response: Stable Contact with Schwann Cells Induces Veil Extension in Sensory Growth Cones
Michael Polinsky¹, Kenneth Balazovich², and Kathryn W. Tosney²
Departments of ¹ Neurosurgery and ² Biology, The University of Michigan, Ann Arbor, Michigan 48109

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Growth cones sense cues by filopodial contact, but how their motility is altered by contact remains unclear. Although contactcould alter motile dynamics in complex ways, our analysis showsthat stable contact with Schwann cells induces motility changesthat are remarkably discrete and invariant. Filopodial contactinvariably induces local veil extension. Even when contacts arebrief, veils always extend before the filopodia retract. Contactat filopodial tips suffices for induction. Moreover, veils extendsignificantly sooner than on filopodia contacting laminin, whichoften detach without extending veils. The overall behavioral responsesof the growth cone, such as increased area and turning, resultfrom integrating multiple discrete responses. Cycles of veil inductionenlarge the growth cone and often lead it onto the cell. Invariantveil induction is abolished by blocking N-cadherin signaling.We propose an axonal guidance model in which different guidancecues act by inducing different but discrete and invariantresponses.

Key words: axonal guidance mechanisms; filopodia; G-proteins; growth cones; guidance cues; N-cadherin; pathfinding mechanisms; Schwann-neurite interactions; sensory neuron guidance; veils

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

To reach their targets, neurites trace out intricate paths by responding to environmental cues (Tosney, 1991; Goodman andShatz, 1993). The cues are detected by growth cones that dynamicallyextend actin-rich processes organized as cylinders (filopodia)or flat sheets (lamellipodia or "veils"). Extensions may retractor may fill with cytoplasm ("engorge") and thereby extend thegrowth cone (Goldberg and Burmeister, 1986). Extension is essentialfor pathfinding. When extension is experimentally prevented, growthcones still advance but lose pathfinding ability (Marsh and Letourneau,1984; Bentley and Toroion-Raymond, 1986). The filopodia detectenvironmental cues and somehow transmit information that can altergrowth cone direction. Stable filopodial adhesion is suspectedto modulate second messenger systems that alter cytoskeletal dynamicsand hence, trajectory (Marsh and Letourneau, 1984; Caudy and Bentley,1986; Gunderson, 1987; Aletta and Greene, 1988; Burmeister andGoldberg, 1988; Forscher, 1989; Goldberg and Burmeister, 1989;Schuch et al., 1989; Calof and Lander, 1991; Gomez and Letourneau,1994).

Contact could influence motility stochastically, by altering motile characteristics on a probability basis, or it could influencemotility selectively, by invariably altering a distinct characteristicsuch as the adhesion, lifetime, number, size, or stability ofprocesses. Such highly selective responses have been recentlyreported. Stable filopodial contact with two cell types inducesdiscrete and invariant motile changes (Oakley and Tosney, 1993;Steketee and Tosney, 1999). Stable contact with anterior sclerotomecells stimulates veil and filopodial extension throughout thegrowth cone and locally induces contacting processes to consolidate.Stable contact with posterior sclerotome cells locally prohibitsveil extension. Similarly discrete responses are seen in othersystems. Filopodia contacting guidepost cells in insects preferentiallyengorge (O'Connor et al., 1990; Myers and Bastiani, 1993). Somecues abolish the ability to extend locally ("local collapse":Fan and Raper, 1995); some cause selective pruning of filopodialextensions (Burmeister and Goldberg, 1988; Stretavan and Reichardt,1993); others locally alter how many filopodia extend (Myers andBastiani, 1993).

The present study asks if another physiologically relevant behavior, a growth cone enlargement and rapid spread onto Schwanncells (Letourneau et al., 1990), is mediated by an equally discreteand invariant response. Examining filopodial and veil dynamicsshows that stable contact with Schwann cells does invariably stimulatea discrete response, veil extension. This veil induction sufficesto alter growth cone size andtrajectory.

If truly physiological, these invariant responses should result from invariant molecular contacts that act through secondmessengers to alter the local cytoskeletal dynamics selectively.If so, disrupting the relevant signaling cascade may only diminishoverall behavioral responses like turning or spreading (productsof several forces) but should abolish the invariant response.Therefore, interventions were repeated that diminish the behavioralresponse to Schwann cells (Letourneau et al., 1990). The findingsestablish that blocking functions of N-cadherin or G-proteinsabolishes the invariant veil induction. The results reveal thatstable filopodial contact, mediated by N-cadherin and involvingG-proteins, induces a discrete and invariant response. The invariantresponse leads to growth cone enlargement and biases trajectorytoward advance onto Schwanncells.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cell culture. Chicken embryos (6.5-d-old, stage 28-30; Hamburger and Hamilton, 1951) were washed in Puck's saline G, decapitated,eviscerated, divested of their notochord, spinal cord, and meninges,and again thoroughly washed. Dorsal root ganglia (DRG) were isolatedfrom the hindlimb region and transferred into Ham's F-12 mediasupplemented with 10% heat-inactivated horse serum, antibiotics(Life Technologies, Gaithersburg, MD), 50 ng/ml nerve growth factor,20 mM HEPES buffer, and hormone additives (Bottenstein et al.,1980). DRG were divided extensively into small explants usingtungsten needles. Approximately 20-30 explants were transferredin 200 µl of medium into a 13 mm diameter center well of a 35mm glass-bottomed Petri dish. Acid-washed glass substrates wereprepared beforehand by coating them with polyornithine (Sigma,St. Louis, MO; 1 mg/ml in water) followed by laminin (Life Technologies;100 µl/ml in 250 mM Tris/HCl buffer, pH 7.4). Cultures were maintainedat 37°C in 5% CO₂ for at least 2 hr beforerecording.

To assess the role of selected cell surface molecules, the medium was exchanged 1 hr before recording with pre-equilibratedmedium containing a selected monoclonal antibody [HNK-1, whichrecognizes an epitope expressed on both DRG and Schwann cells;1E8 which recognizes Po, the earliest known marker for Schwanncells (Bhattachyaryya et al., 1991; a gift of Eric Frank, Universityof Pittsburgh, Pittsburgh, PA); anti-fibronectin (Sigma; catalog#F3648); or NCD-2 (200 µg/ml; a gift of G. B. Grunwald, JeffersonMedical College, Philadelphia, PA), which recognizes the N terminusof chick N-cadherin (Hatta and Takeichi, 1986)]. Cultures werealso labeled with appropriate secondary antibodies to confirmthat the primary antibody bound effectively at the concentrationsapplied (data not shown), using protocols as in Oakley and Tosney(1993).

To assess the role of G-proteins, pertussis toxin (PTX; 200 ng/ml; Sigma) was added after cells had incubated for 1-2 hr.Cultures were incubated an additional 3 hr, and the medium wasexchanged with fresh, pre-equilibrated, PTX-containing medium15 min before recording. As negative controls, the ceramidaseinhibitor oleoylethanolamine (100 or 50 nM) or the phosphatidycholine-specificphospholipase C inhibitor tricyclodecan-9-yl-xantogenate potassium(25 µg/ml) were added; neither altered nor diminished the invariantresponse to contact with Schwann cells (data not shown). As apositive control, the PTX used was tested in an established assaywhere PTX reversed growth cone-neurite inhibition (C. Walker andR. Hume, unpublishedobservations).

Optical recording. Cultures were recorded on optical laser disk at 15 frames per minute as in Steketee and Tosney (1999).Potential interactions between sensory growth cones and non-neuronalcells from ganglia ("Schwann cells") were selected based on trajectory,morphology, and absence of interference from debris or other cells.Schwann cells were morphologically recognizable as highly motileand distinctive cells with large, rounded lamella at the leadingedge, one or two consolidated cytoplasmic extensions at the trailingpole, and nuclei eccentric to the trailing edge. These morphologicalfeatures predicted the direction of migration and facilitatedselection of potential interactions. Schwann cells isolated fromsciatic nerves or from dorsal or ventral roots elicited identicalresponses (data not shown). Growth cones were selected that madesteady progress overall (albeit at different rates), without showingspontaneous collapse. No attempt was made to select growth conesof a particular size or rate of advance. For instance, growthcones were recorded that, before contact, ranged in surface areafrom 2.1 to 11.1 µm², in complexity from 4 to 23 filopodia, and in speed from a slightwithdrawal ( $-$ 2.2 µm/min) to 4.3 µm/min. Despite their diversity,all growth cones showed the same, invariant response to Schwanncell contact. To confirm purity, cultures were labeled with HNK-1monoclonal antibody as in Oakley and Tosney (1993). HNK-1 brightlylabels neural crest-derived sensory neurons and Schwann cells,but not potential contaminating populations such as sclerotomecells, vascular endothelia, or fibroblasts. A recording sessionended when the growth cone ceased to contact the cell or after35min.

Image analysis. To detect any invariant response to contact, stringent criteria are needed to distinguish contacting fromnoncontacting filopodia and to exclude ambiguous cases in whichtechnical limitations would not allow clear determination as towhether or not contact has been made. Except for data in Table1, the established concept of a "stable contact" was used, withtwofold criteria that rested on retrospective analysis of recordings:filopodia were considered to be stably contacting the substrateor cell only if they straightened as though under tension andremained motionless and rigid for at least 1 min. Stable filopodialcontacts were analyzed during two time periods. "Precontact periods"were defined as periods before stable filopodial contact withthe Schwann cell. During this period, all filopodia stably contactedlaminin alone. "Postcontact periods" were defined as periods withstable filopodial contact, cells were considered to be interactingactively. During postcontact periods, filopodia were classifiedas "noncontacting" if they adhered to laminin and "contacting"if they adhered to Schwann cells. Veils were defined as lamellarprojections that extended at least 2 µm from the filopodial base(Steketee and Tosney, 1999). The time of veil initiation was definedas the time when such a veil is first detectable. The recordedsession of each growth cone was considered to be one interaction,during which many individual filopodial contacts were made, bothwith the laminin substrate and the Schwann cell.


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Table 1. The invariant veil extension on contact with Schwann cells is not a function of the type on duration of filopodial contact

To determine if more transient or less stable contacts also induced veils on contact with Schwann cells (Table 1), veil extensionand the duration of contact were assessed in various types offilopodial contact, based on two criteria: (1) whether the filopodialtips were moving or stationary; stationary tips may, with someambiguity, be inferred to be contacting the substrate; or (2)whether the filopodial shafts remained flexible or became rigidon contact. The types of contact were: (1) noncontacting, in whichfilopodial tips moved constantly, without hesitation, showinga lack of adhesion, (2) "hesitating", in which filopodial tipsappeared to remain stationary for 0.1-0.9 min, suggesting adhesion,but the shaft failed to straighten, (3) "transient" contacts inwhich the filopodial tip was static for 0.1-0.9 min and the shaftstraightened on contact, and (4) stable contacts, in which thetip was unmoving for $>=$ 1.0 min and the shaft straightened on contact.We also searched for contacts $>=$ 1.0 min in which the shaft didnot straighten on contact, but found none. Filopodia (n = 456)were analyzed on contacting (Schwann cell substrate) and noncontacting(laminin substrate) sides of 43 growth cones during the first15 min of postcontactinteractions.

To determine if contact-induced changes in growth cone area, growth cone speed, or filopodial number could account for thelocal change in veil dynamics on contact with Schwann cells, thesecharacteristics were measured in 18 growth cones 5 min beforeand 5 and 10 min after the initial stable contact (Table 2).Interactions were selected in which growth cones made only 1-4stable contacts with Schwann cells during the first 10 min afterinitial contact, to let us distinguish the effects of single contactsfrom the possible additive effects of multiple contacts. For areameasurements, the phase-light central portions of growth coneswith the peripheral spread regions and the veils, but excludingfilopodia and phase-dark consolidated portions, were traced onscreenand the area was calculated using functions of the Image-1/Metamorphprogram (Universal Imaging). Speeds of advance were calculatedover a 5 min period centered on each time point. Filopodia werecounted manually at each time point and examined to determineif they did or did not extend veils within 3.5 min of stable contact.To determine if veil activity increases systematically with growthcone area, the extension of veils on filopodia contacting lamininduring the initial 15 min postcontact interval was assessed (seeFig. 5). To examine integration of responses, this populationwas also analyzed to determine if an overall behavioral responseto contact, an increase in growth cone area, correlated with thenumber of stably contacting filopodia (Table 3).


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Table 2. The invariant veil extension on contact with Schwann cells is not a function of contact-induced changes in growth cone area, growth cone speed, or filopodial number


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Table 3. Invariant responses integrate to alter an overall growth cone behavior; increasing numbers of filopodial contacts correlate with increasing surface area

To examine the temporal metrics of veil extension on filopodia making stable contacts, the time from initial stable contactto either veil initiation or to filopodial detachment withoutveil initiation was determined on laminin and Schwann cell substratesfor all filopodia that were present during the first 15 min afterinitial contact with Schwann cells (see Fig. 3).

To compare normal and treated cultures, veil extension, veil stabilization, growth cone area, and filopodia number were measuredin both precontact and postcontact intervals in untreated andin NCD-2-treated and PTX-treated cultures (see Figs. 2, 4, 6).In HNK-1, 1E8, and fibronectin-treated cultures, veil inductionand stabilization were analyzed, and in oleoylethanolamine andtricyclodecan-9-yl-xantogenate-treated cultures, veil inductionwas analyzed. To detect changes in veil extension on contact,all veils were counted during entire precontact and postcontactperiods. In all untreated interactions, we noticed that 100% offilopodia stably contacting Schwann cells extended veils within3.5 min of contact. We therefore calculated the percentage ofprecontact, postcontact, and noncontacting filopodia that extendedveils within the same period. To determine the stability of veils,the history of every veil was noted as either a "retract" (veilretracted and disappeared) or a "fill" (veil was stable and laterengorged). To determine whether veil stabilization after contactwas general (throughout the growth cone) or focal (restrictedto contacting filopodia alone), each veil was also classifiedas extending along either "contacting" or "noncontacting" filopodia.To measure an overall consequence of veil activities, growth conesurface area was measured as above once per minute, and valueswere normalized for comparisons. To detect contact-dependent changesin filopodial extension, filopodia were counted once per minutethroughout eachinteraction.

For statistical comparisons, repeated measures ANOVAs were used to first determine that the contact state of the growth coneaffected veil induction or stabilization within each treatmentgroup. Repeated measures ANOVAs also showed whether the type oftreatment had a significant effect on veil induction and stabilization.It was then possible to make statistical comparisons within andbetween individual groups using paired t tests. For example, the"postcontact-contacting" group was compared to the "precontact"group in the untreated condition. Paired t tests were also usedto compare precontact to postcontact growth cone area, growthrate, and filopodia number. To present data from growth conesof variable sizes and shapes, the quantitative measurements ofgrowth cone area and filopodia number were normalized by expressingvalues as a percentage of the maximum value. On graphs, errorbars represent SEM; in tables and text, means and SD arereported.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Growth cone response to Schwann cells

As easily seen in recordings, growth cone contact with a Schwann cell robustly stimulated veil extension (Fig. 1). Duringthe precontact period, a filopodium often waved over the Schwanncell, but eventually its tip would adhere to the cell, and thefilopodium would stop moving and straighten as if under tension(Fig. 1, 0 min); such filopodia were considered to be making stablecontacts. The stable contact of just one filopodial tip, for remarkablybrief periods of time, initiated a sequence of distinctive events:an induction of veil extension, a stabilization of veils, anda consequent growth cone enlargement and advance onto the Schwanncell.

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Figure 1. Stable filopodial contact with a Schwann cell stimulates an invariant response. Frames shown in this and subsequent micrographs indicate elapsed time since initial stable contact in minutes at top right. Note the rapid formation of a veil (arrow) within 3 min of initial contact. As more filopodia contact, they too induce local veil extension. Veils are relatively stable and accumulate to enlarge the growth cone even before it moves onto the cell (see also Fig. 6A). The growth cone advances along the regions of greatest protrusive activity, as veils fill with cytoplasm and then consolidate to form neurite. This Schwann cell also responded to contact by extending a veil (3 min), which later spread under the growth cone (18 min).

The first event is discrete and invariant: a veil always extended along a contacting filopodium (Fig. 1, 3 min). This initialresponse to stable contact was rapid, reproducible, and confinedsolely to contacting filopodia. The veils extended swiftly aftercontact. Remarkably, in many cases the response was essentiallyimmediate, and veils extended within the sampling interval of4 sec; we saw contact in one frame and a veil in the next. Minimalcontact, for a minimal duration, was required to elicit veil extension.A single filopodium sufficed, even though veils are commonly envisionedas extending between two filopodia. Moreover, this veil extensionis not a mere spreading onto a more adhesive substratum, but aresponse to some signal from the filopodial tip. Veil extensionwas induced even when the entire growth cone lay on laminin andthe filopodium contacted the cell only at its tip (Fig. 1). Theresponse cannot be attributable to a simple maximizing of directadhesion.

The veil extension stimulated by stable contact was confined to those filopodia that actually contacted the Schwann cell andwas impressively invariant (Fig. 2A). Every filopodium contactinga Schwann cell extended a veil within 3.5 min, whereas filopodiastably contacting laminin, before or after the Schwann cell interactioncommenced, extended veils randomly and much less frequently. Duringtheir first 3.5 min of contacting the laminin substratum, 37%of filopodia extended veils, and although many filopodia adheredfor longer periods, many detached without extending veils at all(Figs. 2A, 3). Against this modest baseline of veil extension,it is impressive that veils extended on every filopodium thatcontacted a Schwann cell. Indeed, >400 additional filopodial contactsobserved by four independent observers have failed to reveal asingle contrary case (M. Polinsky, K. Balazovich, M. Steketee,and L. Foa, unpublished observations).

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Figure 2. Responses to stable contact. Veil extension (A) and stabilization (B) are both significantly stimulated by stable contact in untreated cells. In A, the entries for filopodia contacting Schwann cells in untreated, 1E8, HNK-1, or anti-fibronectin conditions lack error bars because every single filopodium stably contacting Schwann cells showed veil induction, without exception. In the untreated conditions, veil extension on filopodia contacting Schwann cells differs from both the precontacting and the noncontacting values at **p < 0.0001. This response is invariant. During postcontact periods, comparing activities on contacting and noncontacting filopodia in untreated cells documents that the stimulation is local, confined to filopodia contacting Schwann cells. The effects on veil tension and stabilization are both abolished with either a blocking antibody to N-cadherin (NCD-2) or pertussis toxin (PTX). The PTX elimination of the contact-induced veil extension was detectable and significant despite the PTX stimulation of veil stability on laminin before contact. Likewise, veil induction is unaltered by 1E8, HNK-1, and anti-fibronectin antibodies, despite their differential effects on other motile activities: the anti-fibronectin alters veil extension on laminin before contact, 1E8 alters stabilization before cell contact, and HNK-1 alters stabilization after contact but only on noncontacting filopodia. Error bars indicate SEM. *p < 0.05; **p < 0.01 compared to the corresponding untreated values.

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Figure 3. Temporal metrics of veil extension. A, On filopodia making stable contact with Schwann cells, veil initiation is skewed toward early times. All veils extend rapidly, within 3.5 min of contact (mean, 0.81 ± 0.69; range, 0.1-2.7 min), and before the filopodium detaches. B, In contrast, on filopodia from the same growth cones that are stably contacting laminin, veil initiation is not so temporally skewed. Many veils initiate within the first 3.5 min, but in a more even distribution, and the first veil may not extend for many minutes (mean, 2.48 ± 2.37; range, 0.1-19.8 min). C, Moreover, many filopodia stably contacting laminin detach without having extended veils, despite long durations of contact (range, 1.0-21.5 min). Data reflect analysis of 80 stable contacts with laminin and 100 stable contacts with Schwann cells that were present during the first 15 min of contact, on 34 growth cones. Mean values for initiation in A and B are significantly different (p < 0.0001), using the two-tailed unpaired nonparametric Student's t test.

The temporal metrics of veil extension also indicates that veils on filopodia contacting Schwann cells are actively induced.On stable contact with Schwann cells, all veils initiated rapidly(mean, 0.81 min ± 0.69), within a restricted temporal period (range,0.1-2.7 min), and the distribution of initiations was skewed towardearly values (Fig. 3A). All filopodia extended veils before detaching.In contrast, on filopodia stably contacting laminin, veils initiatedsignificantly later (mean, 2.48 ± 2.37; p < 0.0001), over a largertemporal period (range, 0.1-19.8 min), and initiations were moreevenly distributed (Fig. 3B). Moreover, many filopodia stablycontacting laminin detached without having extended veils, eventhose that had remained attached for long periods (range, 0.1-21.5min; Fig. 3C).

The invariant veil extension on contact with Schwann cells is not simply a function of the type or duration of contact (Table1). The duration of stable contacts (defined as those >1.0 minwith the shaft straightening on contact) did not differ with substrate.Likewise, the duration of transient contacts (<1.0 min with shaftstraightening) did not differ with substrate. Therefore, a longerduration of contact with Schwann cells cannot explain the higherincidence of veil extension. Moreover, although the n is small,filopodia making even very brief contacts (<1.0 min) with Schwanncells all extended veils before detaching. The small number ofsuch brief contacts seen could be attributable to difficultiesin detecting them on Schwann cells. The difficulty is particularlyacute when using only a single criterion, tip-stasis, which isvery difficult to discern against the background of the phase-darkSchwann cell. Indeed, in "hesitating contacts" (<1.0 min withoutshaft-straightening) Schwann cell contacts of <0.8 min were notdetected. However, relatively few contacts were detected on Schwanncells even when using shaft straightening as a criterion as well,in "transient contacts". Another possible explanation for thesmall number of brief contacts detected and the significant differencein the duration of Schwann cell contacts in the hesitating classis that many initial contacts with Schwann cells may transforminto longer-lived stable contacts. Schwann cell contact may stimulateshaft straightening and stability. Shaft straightening does appearto be a general concomitant of all longer-lived contacts, eventhose on laminin, because the "hesitating" contacts in which shaftsfail to straighten were generally very brief on laminin (mean,0.21 ± 0.12 min) and were not detected at >0.6 min. Furthermore,contacts longer than 1.0 min without shaft straightening wereso rare that they are absent from this data set. Clearly however,stable contacts are a significant proportion of all contacts madewith the Schwann cell. Veil extension on contacting filopodiais not, therefore, some irrelevant side effect pertinent onlyto a minor class ofcontacts.

The rapid veil response is also clearly not a consequence of changes in other growth cone metrics or some biased selectionfor growth cones with particular features. Every filopodial contactwith Schwann cells induced veil extension, regardless of the factthat the range of sizes, complexity, and rates of advance amonggrowth cones were quite diverse (Table 2). The invariant veilextension is not attributable simply to an increased protrusionof all processes, because the extension of filopodia was essentiallyunchanged (Fig. 4A, Table 2). Growth cone size does increaseafter stable contact (below), but the increase is gradual, variable,and later than the first invariant responses. In addition, contactdoes not stimulate veils simply because the contact enlarged thegrowth cone, and larger growth cones tend to extend more veils.Even on large growth cones, the veiling activity on individualfilopodia remains a local function of the substrate contacted.Veil extension is unrelated to growth cone area. Each growth conecontacting a Schwann cell, regardless of its size, makes stablecontacts with laminin that both do, and do not, extend veils (Fig.5). Increases in growth cone area are therefore insufficient toaccount for the dramatically increased local veil extension onfilopodia contacting the Schwann cell.

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Figure 4. Filopodial extension. Contact (time 0) does not alter the numbers of filopodia extended in untreated or treated cells. (A, n = 18 interactions; B, C, n = 7 for each treatment.) In B, interactions were followed for a shorter period.

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Figure 5. Veil activity fails to correlate with growth cone area. Ten minutes after the initial stable contact with a Schwann cell, the areas of growth cones were measured, and those filopodia making stable contacts with laminin were recorded as extending or failing to extend a veil within 3.5 min of contact. Each horizontal line portrays activity on a single growth cone (n = 18 growth cones, 85 filopodia). In individual growth cones, filopodia were in both classes, extending and failing to extend veils, unlike those filopodia on the same growth cones that were directly contacting the cell (45 filopodia), which always extended veils. Thus, veil extension does not vary systematically with growth cone area, but is a property of the substrate contacted.

Because rapid veil extension characterizes every filopodial contact with Schwann cells, we consider the veils to be invariablyinduced by contact, and therefore call the veil induction the"invariantresponse."

In addition to inducing veil extension, stable contact also locally increases the probability that the site of induced veilextension will engorge with cytoplasm, a quality we termed "veilstabilization." Stabilization was assessed by following the fulllifetime of veils. After protrusion, a veil either retracted anddisappeared or it stabilized and subsequently "filled" with cytoplasm,thereby advancing the growth cone. Stability was markedly enhancedby stable filopodial contact with a Schwann cell. In repeatingcycles, veils extended, remained in an extended state, and theneventually filled (Fig. 1); 78% of veils that had extended alongcontacting filopodia filled (Fig. 2B). In marked contrast, veilsextending along those filopodia in precontact intervals had justthe opposite tendency and generally retracted. The stabilizationwas local rather than attributable to an overall change in growthcone dynamics on contact because the low fill rate at noncontactsites was comparable to the precontactrate.

Two overall growth cone behaviors commonly alter as a consequence of the locally enhanced veil extension and stability thatwas reiterated with each stable contact, producing an additiveeffect. First, when multiple filopodia contacted the Schwann cell,growth cone area progressively increased, beginning within thefirst minute after contact (Fig. 6A). The increase in area correlatedtemporally with the cumulative enhancement of veil extension andstabilization, which was typically obvious within the first 1.5min of contact. After 10-15 min of contact, growth cone areashad approximately doubled. Importantly, the enlargement of growthcones was not attributable to direct spreading along the surfaceof the cell, because it was visible when the only contact withthe cell was via filopodia; instead, the growth cone enlargementwas mediated by an accumulated effect of locally altered protrusiveactivity. Repeated cycles of veil extension and stabilizationcause the growth cone to extend and retain more veils and thusto enlarge and become much more lamellar. Enlargement was usuallyobvious even before the growth cone body had advanced onto thecell (Fig. 1).

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Figure 6. Growth cone area. Area increases after stable contact (at time 0) with untreated cells (A, n = 18 interactions), but fails to change in treated cultures (B, C, n = 7 for each treatment). In B interactions were followed for a shorter period. All growth cones analyzed here ultimately contacted the Schwann cell with multiple filopodia during the recorded interaction.

The increase in growth cone size appears to be a consequence of integrating individual discrete responses. Integration wasassessed by analyzing interactions in which growth cones madeonly one to four stable filopodial contacts with a Schwann cellduring the first 10 min of contact. The numbers of total contactsduring this period increase in rough concert with the averagemaximum increases in surface area, doubling when four contactswere established (Table 3). These observations are in accordwith the notion that overall growth cone behaviors result fromintegration of multiple signals (McCobb et al., 1988; Strittmatterand Fishman, 1991; Erskine and McCaig, 1997; Ming et al., 1997;Song et al., 1997; Wang and Zheng, 1998). They extend this ideaby suggesting that integration might emerge from an addition ofvery discreteresponses.

A second consequence of reiterated veil induction and stabilization is directional growth cone migration. Trajectory, an overallbehavioral response, is determined by regional differences inprotrusive activity; a prerequisite for turning is a local changein motile activities. Growth cones advance preferentially in regionswhere veils extend and engorge most vigorously. Because stablecontact dramatically enhanced these components of motility, growthcones preferentially advanced at contact sites and consequentlyonto the Schwann cell. The spatial containment of the responseto contact sites was necessary for turning behavior and, by implication,fornavigation.

Schwann cell response to growth cones

Stable filopodial contact sometimes stimulated a focal extension from the Schwann cell, a small rounded lamella that extendedfrom the contacted site and progressively enlarged with persistentcontact (Fig. 1). In these cases, growth cones and Schwann cellsmutually stimulated each other's protrusive activity. However,the Schwann cell response was relatively rare (~20% responded)and seldom as rapid as the growth cone response. Despite theircommon origin in the neural crest, the sensory neuron and Schwanncell show diverse responses to contact, even at this early developmentalstage.

Interactions during N-cadherin blockade

Blocking the function of N-cadherin abolished the invariant response to stable contact with Schwann cells. Treatment withNCD-2 eliminated the local, contact-mediated induction of veilextension. Filopodia still adhered to the cell, and filopodialcontact even when multiple and prolonged, failed to stimulateveil extension (Fig. 7). Despite protracted contact (>20 min),veils extended on contacting filopodia at a rate comparable tothat in the precontact period and significantly less than thatin untreated cells (Fig. 2A). In NCD-2-treated cells, those veilsthat did form generally took longer to form and required moreextensive contact with the Schwann cell. The absence of inductioncontrasted markedly with the untreated cells, in which even singlecontacts briskly enhanced veil extension. Blocking N-cadherinalso abolished veil stabilization on contact, reducing it to belowthe baseline value on laminin (Fig. 2B). Veils extending alongcontacting filopodia were relatively unstable and retracted 90%of the time, contrasting with the stability of veils in the untreatedcondition. Contact under N-cadherin blockade was insufficientto stimulate preferential engorgement.

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Figure 7. Blocking N-cadherin function blocks the invariant response. In the presence of blocking antibody NCD-2, stable contact fails to stimulate veil extension. Veils seldom form on contacting filopodia, and when they do form they are short-lived (arrows at 5 and 8 min). Note that multiple stable contacts fail to stimulate veil extension. The growth cone advances in the direction of its most robust protrusive activity. This Schwann cell retains some spreading response to contact: its leading edge initially faces perpendicular to the oncoming growth cone but reorients toward the contact site.

In the absence of the invariant response, stable contact seldom altered growth cone behavior. First, growth cones did notenlarge after contact, even when multiple filopodia made prolongedcontact with a Schwann cell, contrasting with the doubling ofarea in untreated cells (Fig. 6A,B). As in untreated conditions,the number of filopodia extended was unaffected (Fig. 4B). Second,as veils extended and stabilized randomly, the growth cones tendedto migrate along their precontact trajectory rather than preferentiallyadvancing toward contact sites. Some even turned away from thecell.

Observations of precontact motility served as an internal control. NCD-2 had no effect on precontact morphology or motility.Growth cones were similar in size and shape and possessed similarnumbers of filopodia (Figs. 4, 7). Likewise, Schwann cells remainedhighly motile and retained normal morphologicalfeatures.

In contrast, antibodies that bound to other epitopes on the surface of the Schwann cell and or/growth cone failed to evendiminish veil induction (Fig. 2A). Veils extended on 100% of thefilopodia stably contacting Schwann cells treated with antibodiesto fibronectin, Po (antibody 1E8), or the HNK-1 epitope. Neitherthe antibody presence on the cell surface, nor disrupting adhesionthrough such molecules, sufficed to alter the invariant response.The retained induction of veils is the more striking in that eachantibody did affect motile behavior in other respects (Fig. 2A,B).1E8 diminished veil stability in precontact periods; HNK-1 diminishedveil stability in postcontact periods but only on laminin; anti-fibronectinincreased veil extension in precontact periods. Such effects canbe discriminated from those relevant to the guidance interactionby focusing on the invariant response itself. Inhibiting a signalingfunction essential to the invariant response returns veil extensionto baseline, so that the invariant response is abolished. Inhibitingother signaling systems may alter other aspects of motility, butfailed to even modify the invariant response. Signaling systemslikely play more than one role in motility, so that dissectingout discrete and relevant effects has been problematic. However,focusing on a local, invariant response can allow discriminationof causalrelations.

Interactions during G-protein blockade

Similarly, the influence of PTX on the contact-mediated induction could be easily discriminated from its effects on the baselinemotile behavior, using the spatiotemporal criterion of stablecell contact. PTX did not grossly alter motility in that growthcones and Schwann cells were indistinguishable morphologicallyfrom untreated cells (compare Figs. 1, 7), but it did have onenotable effect on motility on laminin: it increased veil stabilizationin precontact periods (Fig. 2B). However, because the invariantresponse is directly associated with stable contact, the effectthat was directly relevant to the guiding interaction could bediscriminated by examining the invariant response itself. Thediscreteness of the invariant response can be used as a discriminatorytool to distinguish how experimental treatments affect specificresponses, even when the treatment alters some aspects of baselinemotility.

PTX eliminated the contact-mediated induction of veil extension (Fig. 8); after initial contact, veil extension on stablycontacting filopodia was reduced to baseline levels (Fig. 2A).Despite contact that was prolonged (>25 min) and extensive (asmuch as the entire leading edge of the growth cone), contactingfilopodia failed to extend veils any more efficiently than noncontactingor precontact filopodia. In addition, PTX significantly diminishedthe contact-mediated veil stabilization (Fig. 2B), but did notreduce it to a baseline value, suggesting that veil inductionand veil stabilization may be separable consequences of stablecontact. In the absence of specific induction on contact, thecontact-associated changes in overall growth cone behavior werealso greatly diminished. After contact, growth cones did not enlarge(Fig. 6C) and usually failed to advance onto the cell (Fig. 8).As in untreated conditions, the number of filopodia extended wasunaffected (Fig. 4C).

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Figure 8. Pertussis toxin blocks the invariant response. In the presence of pertussis toxin, stable contact fails to induce veil extension. The growth cone proceeds along its previous course, parallel to the cell. The cell fails to spread toward the site of contact and instead becomes quiescent at the initial contact site.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This study identifies an invariant response, a stereotyped and reproducible consequence of stable filopodial contact thatalters a highly discrete element of motility. Stable contact ofsensory growth cone filopodia with Schwann cells invariably inducesrapid veil extension. The invariant response is confined to thecontacting filopodia. Even brief contacts and contacts confinedto filopodial tips suffice forinduction.

Invariant responses may be the common and most direct response to specific molecular interactions with the surfaces of guidingcells. Two other cell types have also been shown to induce discreteand invariant responses in both motor (Oakley and Tosney, 1993)and sensory (Steketee and Tosney, 1999) growth cones (Fig. 9):posterior sclerotome inhibits veil extension on stably contactingfilopodia; anterior sclerotome stimulates protrusive activitythroughout the growth cone and locally stimulates consolidation.All three invariant responses are relevant physiologically, becausethese cells guide axons in the embryo and/or during regeneration(Keynes and Stern, 1984; Carpenter and Holiday, 1986; Son andThompson, 1995a,b). The filopodia likely act as long-distancesensors by ligand-receptor binding that modulates specific secondmessengers to alter cytoskeletal dynamics selectively. In accordwith this posited relationship, the invariant response to Schwanncells is eliminated by blocking N-cadherin or inhibiting G-proteinfunction.

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Figure 9. Schematic diagram of invariant responses. Motile activities are diagrammed for a growth cone on a homogeneous substratum (top left) or after stable filopodial contact with specific cell types (in clockwise order). Activity unbiased by contact is shown as symmetrical, with veils extending on both sides. Contact with a posterior sclerotome cell locally inhibits veil extension. The inhibition is a constant response; veils invariably fail to extend between contacting filopodia, even with repeated contacts, and extend again only when filopodial contact is lost. Contact with an anterior sclerotome cell stimulates extensions throughout the growth cone and then locally enhances consolidation of contacting processes in a manner overtly different than the veil stabilization by Schwann cells. The processes become motility-quiescent, thicken, and form a phase-dark region that rounds up to become neuritic. Contact with a Schwann cell locally induces veil extension. These veils are considered more stable because they seldom retract and they eventually engorge preferentially. Also see Oakley and Tosney (1993); Steketee and Tosney (1999).

These invariant responses are more typical sequela of contact than is the gross behavior, and reiterated cycles of each invariantresponse are needed to mediate a given gross behavior. In Schwanncell interactions, repeated cycles of veil induction can causea growth cone to enlarge and turn. Likewise in posterior sclerotomeinteractions, repeated cycles of local inhibition are requiredto cause growth cones to stop or turn, and interactions with anteriorsclerotome are often a protracted series of invariant responses(Oakley and Tosney, 1993).

Invariant responses must result from signaling rather than from adhesion alone. In Schwann cell interactions, a veil originatesfrom the distant filopodial base and does not spread directlyupon the cell. Even a consequence of repeated veil induction,growth cone enlargement, takes place while the contact is solelyfilopodial. Moreover, functionally blocking the homophilic bindingmolecule N-cadherin abolished the invariant response, but failedto abolish filopodial adhesion. The filopodia still adhered tothe Schwann cell, which possesses many other adhesive molecules(Bixby et al., 1988; Seilheimer and Schachner, 1988; Bhattachyaryyaet al., 1991). In contrast, antibodies to other surface molecules,fibronectin, Po, and the HNK-1 epitope, failed to modify the invariantresponse, despite their alteration of responses tolaminin.

In this study we did not intend to characterize a signaling cascade fully, but rather to determine if blocking a likely signalcould eliminate an invariant response. Results with PTX implicatea second messenger system involving G-proteins (Gilman, 1987;Strittmatter et al., 1990), but, more pertinent, they show thatinhibiting specific signaling cascades can eliminate invariantresponses. Such treatments discriminate direct effects on themost relevant guidance response, even when the treatment has indirector nonspecific effects. Thus, for testing putative signaling moleculesin guidance interactions, invariant responses can serve as a finediscriminating tool. An effect that is directly relevant to theguiding interaction can be identified by focusing on an invariantresponsedirectly.

A model of growth cone guidance

The most interesting feature of invariant responses to contact may be that they are indeed invariant. Every filopodium stablycontacting a given cell type elicits the identical response. Theresponses do not quench: repeated contacts also stimulate theidentical response. In contrast, overall behavior varies as theinvariant response is integrated with other factors, such as theangle or extent of contact, responses to additional cues, or theset-point for extension. For example, the invariant prohibitionof veil extension by posterior sclerotome can beget three avoidancebehaviors: a growth cone turns when only one side contacts, stopsif all filopodia contact, or branches by forming veils at opposite,noncontacting sides. Because the invariant responses themselvesare highly repeatable, they are likely to be direct physiologicalconsequences of filopodial contact and major components of guidancemechanisms.

The invariant responses have another property, discreteness, which may make them particularly valuable as guidance mechanisms.Each invariant response is impressively discrete. It does notaffect extension or engorgement or consolidation generally: itaffects a very precise subset of one activity. The Schwann cellresponse invariably affects veil extension without altering filopodialextension. Another response alters only the consolidation of acontacting filopodium without changing its lifetime or initialengorgement; a third alters the extension of veils down a filopodiumwithout changing initiation of veils on the same filopodium (Steketeeand Tosney, 1999). The effect is that cues have a constant, andvery discrete, readout in terms of motile activity. Cues elicitdiscrete changes in overt motile behaviors, and often do so locally.The discrete response is vital for navigation; local prohibitionor stimulation or consolidation causes turns in particulardirections.

This discreteness may facilitate signal integration. The final trajectory of a growth cone depends on integrating the manypositive and negative signals impinging on it simultaneously (McCobbet al., 1988; Strittmatter and Fishman, 1991; Erskine and McCaig,1997; Ming et al., 1997; Song et al., 1997; Wang and Zheng, 1998).If cues elicit discrete and invariant responses, signals couldbe integrated more easily. Our work suggests how invariant responsescan integrate to alter growth cone behavior (Steketee and Tosney,1999). As the number of stable contacts with Schwann cells increases,so does the growth cone area. Likewise, unitary responses to theinhibitory cue are added across the growth cone according to thenumber and site of stable contacts to produce turning, stopping,or branching. A local invariant response can integrate even withan aspect of motility that characterizes the entire growth cone.Growth cones on laminin regulate their general level of extensionabout a set-point, but when stable contact with posterior sclerotomeprohibits veil extension locally, they compensate by increasingextension at distant sites, thereby both maintaining their set-pointand amplifyingavoidance.

The discreteness of an invariant response does not limit its implications for guidance. Indeed, the very discreteness helpsto explain complex behaviors such as why growth cones track alongsidebarriers of inhibitory cues instead of turning away from thementirely. Because only veil extension (not duration of adhesion)is altered by stable contact with posterior sclerotome, contactingfilopodia both tether growth cones to the cell and simultaneouslyprevent travel onto it. Noncontacting filopodia still extend veilsand impel the growth cone forward, in parallel with the sclerotomeborder.

Because they would offer discrete effects that can be integrated, invariant responses may be a common guidance feature. Ifcues usually act by eliciting such discrete responses, then thereare a wealth of fine ways in which different cues could altertrajectories. Many discrete changes could take place in veil extensionalone: a cue could cause a growth cone to turn right by invariablyinhibiting veil extension, veil initiation, or veil stabilityon its left side, or by stimulating these features on the right.Similar scenarios can be built for filopodial extension, or engorgementor consolidation. Different mechanisms can underlie even changesin growth cone size. Growth cones enlarge on contacting both positivecellular cues but by different means: anterior sclerotome contactsincrease the frequency of both veil and filopodial initiationacross the growth cone; Schwann cell contacts increase the initiationand stability of veils locally. Different cues can operate byinducing different and very discrete changes in motility. Conversely,other neuronal types may respond to the same molecular signalwith an identical, invariant response. For instance, retinal growthcones assume an enlarged, lamellar morphology on filopodial contactwith N-cadherin substrata (Burden-Gulley et al., 1995), a grossbehavior consistent with the invariant response shownhere.

Invariant responses may be prevalent, but they are detectable only when motile histories are analyzed in detail. In the fewother cases where detailed motility (rather than just turningbehavior per se) has been analyzed, responses were found thatmeet half of our definition, by showing a discrete change in motility.Filopodia contacting guidepost cells preferentially engorge (O'Connoret al., 1990; Myers and Bastiani, 1993). Some cues abolish theability to extend locally (Fan and Raper, 1995); some cause selectivepruning of filopodia (Burmeister and Goldberg, 1988; Stretavanand Reichardt, 1993); others locally alter how many filopodiaextend (Myers and Bastiani, 1993). However, whether these responsesare invariant has yet to betested.

Finding discrete, invariant responses to three different cellular cues suggested this model for growth cone guidance. We proposethat many guidance cues induce discrete and invariant alterationsin motility. In other words, cues do not act simply to controlwhether actin polymerizes at the leading edge in some either-orfashion. Instead, the response is richer and more nuanced: eachcue generates a constant read-out on a discrete element of motilityitself. Different cues induce different discrete changes. Becausethey are discrete, these responses can integrate in a straightforwardmanner. We are testing this model by examining the detailed motilityof growth cones as they contact other cellular guidance cues anddefined molecularsubstrates.

  FOOTNOTES

Received May 19, 1999; revised Oct. 8, 1999; accepted Nov. 8, 1999.

This work was supported by National Institutes of Health Grant NS21308. We thank Mike Steketee forcomments.
Correspondence should be addressed to K. W. Tosney, The Department of Biology, Natural Science Building, 830 North University,The University of Michigan, Ann Arbor, MI 48109-1048. E-mail:ktosney{at}umich.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Aletta JM, Greene LA (1988) Growth cone configuration and advance: a time-lapse study using video-enhanced differential interference contrast microscopy. J Neurosci 8:1425-1435[Abstract].
Bentley D, Toroion-Raymond A (1986) Disoriented pathfinding by pioneer neurone growth cones deprived of filopodia by cytochalasin treatment. Nature 323:712-715[Medline].
Bhattachyaryya A, Frank E, Ratner N, Brackenbury R (1991) Po is an early marker of the Schwann cell lineage in chickens. Neuron 7:831-844[Web of Science][Medline].
Bixby JL, Lilien J, Reichardt LF (1988) Identification of the major proteins that promote neuronal process outgrowth on Schwann cells in vitro. J Cell Biol 107:353-361[Abstract/Free Full Text].
Bottenstein JE, Skaper SD, Varon SS, Sato GH (1980) Selective survival of neurons from chick embryo sensory ganglionic dissociates utilizing serum-free supplemented medium. Exp Cell Res 125:183-190[Web of Science][Medline].
Burden-Gulley SM, Payne HR, Lemmon V (1995) Growth cones are actively influenced by substrate-bound adhesion molecules. J Neurosci 15:4370-4381[Abstract].
Burmeister DW, Goldberg DJ (1988) Micropruning: the mechanism of turning of Aplysia growth cones at substrate borders in vitro. J Neurosci 8:3151-3159[Abstract].
Calof A, Lander AD (1991) Relationship between neuronal migration and cell-substratum adhesion: laminin and merosin promote olfactory neuronal migration but are anti-adhesive. Cell Biol 115:779-794.
Carpenter EM, Holiday M (1986) Defective innervation of chick limbs in the absence of presumptive Schwann cells. Dev Biol 150:144-159.
Caudy M, Bentley D (1986) Pioneer growth cone morphologies reveal proximal increases in substrate affinity within leg segments of grasshopper embryos. J Neurosci 6:264-279.
Erskine L, McCaig CD (1997) Integrated interactions between chondroitin sulfate proteoglycans and weak dc electric fields regulate nerve growth cone guidance in vitro. J Cell Sci 110:1957-65[Abstract].
Fan J, Raper J (1995) Localized collapsing cues can steer growth cones without inducing their full collapse. Neuron 14:263-274[Web of Science][Medline].
Forscher P (1989) Calcium and polyphosphoinositide control of cytoskeletal dynamics. Trends Neurosci 12:468-74[Web of Science][Medline].
Gilman AG (1987) G proteins: transducers of receptor-generated signals. Annu Rev Biochem 56:615-649[Web of Science][Medline].
Goldberg D, Burmeister D (1986) Stages in axon formation: observations of growth of Aplysia axons using video-enhanced contrast-differential interference contrast microscopy. J Cell Biol 103:1021-1031[Abstract/Free Full Text].
Goldberg DJ, Burmeister DW (1989) Looking into growth cones. Trends Neurosci 12:503-506[Web of Science][Medline].
Gomez TM, Letourneau P (1994) Filopodia initiate choices made by sensory neuron growth cones at laminin fibronectin borders in vitro. J Neurosci 14:5959-5972[Abstract].
Goodman CS, Shatz CJ (1993) Developmental mechanisms that generate precise patterns of neuronal connectivity. Cell 72 [Suppl]:77-98.
Gunderson RW (1987) Response of sensory neurites and growth cones to patterned substrata of laminin and fibronectin in vitro. Dev Biol 121:423-431[Web of Science][Medline].
Hamburger V, Hamilton HL (1951) A series of normal stages in the development of the chick embryo. J Morphol 88:49-92[Web of Science].
Hatta K, Takeichi M (1986) Expression of N-cadherin adhesion molecules associated with early morphogenetic events in chick development. Nature 320:447-449[Medline].
Keynes RJ, Stern CD (1984) Segmentation in the vertebrate nervous system. Nature 310:786-89[Medline].
Letourneau PC, Shattuck TA, Roche FK, Takeichi M, Lemmon V (1990) Nerve growth cone migration onto Schwann cells involves the calcium-dependent adhesion molecule, N-cadherin. Dev Biol 138:430-442[Web of Science][Medline].
Marsh L, Letourneau PC (1984) Growth of neurites without filopodial or lamellipodial activity in the presence of cytochalasin B. J Cell Biol 99:2041-2047[Abstract/Free Full Text].
McCobb DP, Cohan CS, Connor JA, Kater SB (1988) Interactive effects of serotonin and acetylcholine on neurite elongation. Neuron 1:377-385[Web of Science][Medline].
Ming G, Song H, Berninger B, Holt CE, Tessier-Lavigne M, Poo M (1997) cAMP-dependent growth cone guidance by netrin-1. Neuron 19:1225-1235[Web of Science][Medline].
Myers PZ, Bastiani MJ (1993) Growth cone dynamics during the migration of an identified commissural growth cone. J Neurosci 13:127-143[Abstract].
Oakley RA, Tosney KW (1993) Contact-mediated mechanisms of motor axon segmentation. J Neurosci 13:3773-3792[Abstract].
O'Connor TP, Duerr JS, Bentley D (1990) Pioneer growth cone steering decisions mediated by single filopodial contacts in situ. J Neurosci 10:3935-46[Abstract].
Schuch U, Lohse MJ, Schachner M (1989) Neural cell adhesion molecules influence second messenger systems. Neuron 3:13-20[Web of Science][Medline].
Seilheimer B, Schachner M (1988) Studies of adhesion molecules mediating interactions between cells of peripheral nervous system indicate a major role for L1 in mediating sensory neuron growth on Schwann cells in culture. J Cell Biol 107:341-51[Abstract/Free Full Text].
Son Y-J, Thompson WJ (1995a) Schwann cell processes guide regeneration of peripheral axons. Neuron 14:125-132[Web of Science][Medline].
Son Y-J, Thompson WJ (1995b) Nerve sprouting in muscle is induced and guided by processes extended by Schwann cells. Neuron 14:131-411.
Song HJ, Ming GL, Poo MM (1997) cAMP-induced switching in turning direction of nerve growth cones. Nature 388:275-9[Medline].
Steketee M, Tosney KW (1999) Contact with isolated sclerotome cells steers sensory growth cones by altering distinct elements of extension. J Neurosci 19:3495-3506[Abstract/Free Full Text].
Stretavan DW, Reichardt LF (1993) Time-lapse video analysis of retinal ganglion cell axon pathfinding at the mammalian optic chiasm: growth cone guidance using intrinsic chiasm cues. Neuron 10:761-77[Web of Science][Medline].
Strittmatter S, Fishman MC (1991) The neuronal growth cone as a specialized transduction system. BioEssays 13:127-134[Web of Science][Medline].
Strittmatter SM, Valenzuela D, Kennedy TE, Neer EJ, Fishman MC (1990) G_o is a major growth cone protein subject to regulation by GAP-43. Nature 344:836-481[Medline].
Tosney KW (1991) Cells and cell-interactions that guide motor axons in the developing chick embryo. BioEssays 13:1-7[Web of Science][Medline].
Wang Q, Zheng JQ (1998) cAMP-mediated regulation of neurotrophin-induced collapse of nerve growth cones. J Neurosci 18:4973-4984[Abstract/Free Full Text].

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