Shootin1 interacts with actin retrograde flow and L1-CAM to promote axon outgrowth

doi:10.1083/jcb.200712138

Published online June 2, 2008
doi:10.1083/jcb.200712138
The Journal of Cell Biology, Vol. 181, No. 5, 817-829
The Rockefeller University Press, 0021-9525 $30.00
© 2008 Shimada et al.

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Shootin1 interacts with actin retrograde flow and L1-CAM to promote axon outgrowth

Tadayuki Shimada¹, Michinori Toriyama¹, Kaori Uemura¹, Hiroyuki Kamiguchi³, Tadao Sugiura², Naoki Watanabe⁴, and Naoyuki Inagaki¹

¹ Division of Signal Transduction and ² Biomedical Imaging and Informatics, Nara Institute of Science and Technology, Ikoma 630-0192, Japan
³ Laboratory for Neuronal Growth Mechanisms, Brain Science Institute, Institute of Physical and Chemical Research (RIKEN), Saitama 351-0198, Japan
⁴ Department of Pharmacology, Kyoto University Faculty of Medicine, Kyoto 606-8501, Japan

Correspondence to N. Inagaki: ninagaki{at}bs.naist.jp

Actin polymerizes near the leading edge of nerve growth cones,and actin filaments show retrograde movement in filopodia andlamellipodia. Linkage between actin filament retrograde flowand cell adhesion molecules (CAMs) in growth cones is thoughtto be one of the mechanisms for axon outgrowth and guidance.However, the molecular basis for this linkage remains elusive.Here, we show that shootin1 interacts with both actin filamentretrograde flow and L1-CAM in axonal growth cones of culturedrat hippocampal neurons, thereby mediating the linkage betweenthem. Impairing this linkage, either by shootin1 RNA interferenceor disturbing the interaction between shootin1 and actin filamentflow, inhibited L1-dependent axon outgrowth, whereas enhancingthe linkage by shootin1 overexpression promoted neurite outgrowth.These results strengthen the actin flow–CAM linkage model("clutch" model) for axon outgrowth and suggest that shootin1is a key molecule involved in this mechanism.

Abbreviations used in this paper: CAM, cell adhesion molecule;DIC, differential interference contrast; NES, nuclear exportsignal; PI 3-kinase, phosphoinositide-3-kinase; shRNA, shorthairpin RNA.

© 2008 Shimada et al. This article is distributed underthe terms of an Attribution–Noncommercial–ShareAlike–No Mirror Sites license for the first six monthsafter the publication date (see http://www.jcb.org/misc/terms.shtml).After six months it is available under a Creative Commons License(Attribution–Noncommercial–Share Alike 3.0 Unportedlicense, as described at http://creativecommons.org/licenses/by-nc-sa/3.0/).

Introduction

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Abstract
Introduction
Results
Discussion
Materials and methods
References

The nerve growth cone is the migrating tip of growing neuritesand plays a central role in axon outgrowth and guidance (Ramon y Cajal, 1890;Bray and Hollenbeck, 1988). Actin polymerizes near the leadingedge of growth cones, and actin filaments show remarkable retrogrademovement in filopodia and lamellipodia (Forscher and Smith, 1988;Katoh et al., 1999; Mallavarapu and Mitchison, 1999). Myosin1c and myosin II have been implicated in actin filament retrogradeflow in growth cones (Diefenbach et al., 2002; Medeiros et al., 2006).Linkage between the actin filament retrograde flow and celladhesion molecules (CAMs) is thought to transmit the force ofactin filament movement to extracellular substrates via CAMs(Mitchison and Kirschner, 1988; Jay, 2000; Suter and Forscher, 2000),thereby providing mechanical tension (Bray, 1979; Lamoureux et al., 1989)and protrusion of the leading edge (Lin and Forscher, 1995)for axon outgrowth and steering. Previous studies demonstratedthat CAMs such as apCAM (Suter et al., 1998), Nr-CAM (Faivre-Sarrailh et al., 1999),integrin (Grabham et al., 2000), and L1-CAM (Kamiguchi and Yoshihara, 2001)are coupled with actin filament retrograde flow in growth cones.Consistently, coupling between apCAM and actin filament retrogradeflow produced mechanical tension and induced protrusion of growthcones (Suter et al., 1998).

L1 is a single-pass transmembrane protein expressed predominantlyin developing neurons and involved in axon outgrowth and guidance(Lemmon et al., 1989; Dahme et al., 1997; Kamiguchi et al., 1998).A recent study showed that ankyrin_B promotes neurite initiationby coupling F-actin flow to L1 (Nishimura et al., 2003). However,ankyrin_B was involved neither in their coupling in growth conesnor in L1-mediated neurite elongation, and the molecular basisfor the actin flow–CAM linkage in growth cones remainselusive (Suter et al., 1998; Gil et al., 2003; Nishimura et al., 2003).It is also unanswered whether coupling of this linkage is involvedin the regulation of axon outgrowth. Recently we described anovel brain-specific intracellular protein, shootin1, whichis involved in axon formation and polarization of cultured hippocampalneurons (Toriyama et al., 2006). Shootin1 accumulates in axonalgrowth cones, and its accumulation in growth cones dynamicallyenhances neurite elongation. Shootin1 was shown to act upstreamof phosphoinositide-3-kinase (PI 3-kinase). However, shootin1-inducedaxon formation was not fully suppressed by a PI 3-kinase inhibitor(Toriyama et al., 2006), which suggests the existence of anadditional mechanism for axon outgrowth. Here, we show thatshootin1 interacts with both actin filament retrograde flowand L1-CAM in growth cones. Our data suggest that shootin1 mediatesthe linkage between actin retrograde flow and L1-CAM to promoteaxon outgrowth.

Results

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Shootin1 interacts with both actin filament retrograde flow and L1-CAM in growth cones
Fig. 1 A shows shootin1 immunoreactivity in a cultured rat hippocampalneuron. Shootin1 accumulated to a high level in axonal growthcones (Fig. 1 A, arrows), where it localized in filopodia andlamellipodia in close apposition with actin filaments (Fig. 1 B,arrowheads). To elucidate the association of shootin1 with cytoskeletaldynamics in growth cones, we performed fluorescent speckle microscopy(Waterman-Storer and Salmon, 1997; Watanabe and Mitchison, 2002).We performed live imaging of EGFP-shootin1 expressed at a lowlevel in cultured hippocampal neurons. EGFP-shootin1 appearedas discrete speckle signals that serve as fiduciary marks, allowingmeasurement of molecular movement of shootin1. Shootin1 specklesdisplayed retrograde movement in filopodia and lamellipodiaof axonal growth cones (Fig. 1 C, arrowheads; and Video 1, availableat http://www.jcb.org/cgi/content/full/jcb.200712138/DC1). Themean speed of shootin1 speckles was 4.5 ± 0.4 µm/min(mean ± SD, n = 60), which is similar to that of actinfilament retrograde flow in axonal growth cones (Katoh et al., 1999;Mallavarapu and Mitchison, 1999) and fibroblast lamellipodia(Watanabe and Mitchison, 2002).

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Figure 1. Shootin1 and actin filaments in axonal growth cones and XTC fibroblasts. (A) Immunofluorescent localization of shootin1 in a cultured hippocampal neuron. Arrows and arrowheads denote an axonal growth cone and minor process growth cones, respectively. (B) Deconvolved images of an axonal growth cone stained by anti-shootin1 antibody and rhodamine phalloidin. (inset) An enlarged view of the filopodium in the rectangle. Arrowheads indicate shootin1 accumulation in a filopodium. (C) A fluorescent speckle image of EGFP-shootin1 in an axonal growth cone (left) and time series of the indicated area at 5-s intervals (right). See Video 1 (available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1). (D) A fluorescent speckle image of EGFP-shootin1 expressed in an XTC fibroblast (left) and a time series of the indicated area at 10-s intervals (right). See Video 2. Yellow arrowheads denote a speckle of EGFP-shootin1 moving retrogradely. (E) A fluorescent speckle image of mCherry-β-actin (red) and EGFP-shootin1 (green) coexpressed in an XTC fibroblast (left). See Video 3. The kymographs (right) of the peripheral region indicated by the rectangle in the left panel show that the speckles of shootin1 and those of actin retrograde flow moved at similar speeds (lines). Bar: (A) 50 µm; (B–E) 5 µm.

To compare the movement of shootin1 speckles directly with thatof actin filament retrograde flow, we coexpressed EGFP-shootin1and β-actin fused to mCherry (Shaner et al., 2004) in XTCfibroblasts, which are suitable for speckle imaging of actinretrograde flow in lamellipodia (Watanabe and Mitchison, 2002).EGFP-shootin1 signals also showed retrograde movement in lamellipodiaof XTC fibroblasts (Fig. 1 D, arrowheads; and Video 2, availableat http://www.jcb.org/cgi/content/full/jcb.200712138/DC1). Specklesof EGFP-shootin1 and those of mCherry-actin retrograde flowmoved at similar speeds (EGFP-shootin1: 2.6 ± 0.9 µm/min,n = 20; mCherry-actin: 2.7 ± 0.5 µm/min, n = 20;Fig. 1 E and Video 3), which suggests that shootin1 interactswith actin filament retrograde flow. To confirm this, we inhibitedactin polymerization near the leading edge of lamellipodia withcytochalasin. As previously described (Forscher and Smith, 1988;Medeiros et al., 2006), treatment of XTC fibroblasts with 1µM cytochalasin D led to disruption of the peripheralregions of actin filament networks in lamellipodia. The boundaryof the mCherry-actin speckles moved from the leading edge oflamellipodia at 1.3 ± 0.3 µm/min (n = 10), andthe flow speed of actin speckles was reduced to 0.9 ±0.1 µm/min (n = 10; Fig. 2 A and Video 4). Concurrently,the boundary of EGFP-shootin1 speckles moved rearward at thesame rate (1.2 ± 0.4 µm/min, n = 10) and the speedof shootin1 speckles was also reduced to 1.0 ± 0.1 µm/min(n = 10), thereby indicating that the signals of shootin1 coincidewith the redistribution of actin filament networks. Similarrearward movement of the boundary of EGFP-shootin1 specklesand a reduction of the speed of shootin1 speckles were alsoinduced by cytochalasin D in filopodia and lamellipodia of axonalgrowth cones (Fig. 2 B and Video 5). We conclude from theseobservations that shootin1 interacts dynamically with actinfilaments, which move retrogradely in axonal growth cones.

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Figure 2. Effect of cytochalasin D on retrograde movement of EGFP-shootin1 speckles in XTC fibroblasts and axonal growth cones. (A) Time-lapse speckle images of mCherry–β-actin (red) and EGFP-shootin1 (green) coexpressed in XTC fibroblasts treated with 1 µM cytochalasin D at 0 min. See Video 4 (available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1). (B) Time-lapse speckle images of EGFP-shootin1 in an axonal growth cone treated with 1 µM cytochalasin D at 0 min. See Video 5. Dotted lines indicate the leading edge and boundary of speckles. Bars, 5 µm.

L1 is a single-pass transmembrane protein expressed predominantlyin developing neurons and involved in axon outgrowth and guidance(Lemmon et al., 1989; Dahme et al., 1997; Kamiguchi et al., 1998).L1 immunoreactivity localized in axonal growth cones of hippocampalneurons, in close apposition with shootin1 (Fig. 3 A, arrowheads). We examined the physiological association between shootin1 andL1 by coimmunoprecipitation assay. When shootin1 was immunoprecipitatedfrom P5 rat brain lysates, coprecipitation of L1 was detected;shootin1 was also reciprocally coimmunoprecipitated with L1(Fig. 3 B). We also coexpressed exogenous shootin1 and L1 inHEK293T cells but could not detect coimmunoprecipitation betweenshootin1 and L1 (unpublished data). These results indicate thatshootin1 associates with L1 in vivo, probably through unidentifiedneuron-specific proteins.

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Figure 3. Shootin1 associates with L1. (A) Deconvolved images of an axonal growth cone stained by anti-shootin1 and anti-L1 antibodies. (inset) An enlarged view of the rectangle. Arrowheads indicate shootin1 accumulation in a filopodium. Bar, 5 µm. (B) Coimmunoprecipitation of shootin1 and L1 from P5 rat brain lysates. Brain lysates were incubated with anti-shootin1 antibody, anti-L1 antibody, or control IgG. The immunoprecipitates were analyzed by immunoblotting with anti-shootin1 and anti-L1 antibodies.

L1 is linked to actin filament retrograde flow in growth cones of hippocampal neurons
By tracking the movement of microbeads coated with L1-Fc, whichbinds homophilically to L1, or anti-L1 antibody, a previousstudy showed that L1 is linked to actin filament retrogradeflow in growth cones of chick dorsal root ganglion neurons (Kamiguchi and Yoshihara, 2001).Microbeads coated with L1-Fc, anti-L1 antibody, or IgG (control)were placed on axonal growth cones of hippocampal neurons culturedon coverslips coated with N-cadherin–Fc using laser opticaltweezers. Similar to the case of dorsal root ganglion neurons(Kamiguchi and Yoshihara, 2001), 54% of the beads coated withL1-Fc showed retrograde directional movement (n = 24; Fig. S1,A and B, available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1),whereas the remaining 46% showed Brownian motion or no movement.The mean velocity of the moving beads was 1.1 ± 0.10µm/min (mean ± SEM). Similar results were obtainedwith beads coated with anti-L1 antibody (n = 25; Fig. S1 B).However, only 32% of the IgG-coated beads showed retrogrademovement (n = 25), and the velocity of the moving beads (0.64± 0.08 µm/min) was significantly slower than thatof beads coated with L1-Fc or anti-L1 antibody (P = 0.0030 comparedwith L1-Fc; P = 0.00012 compared with anti-L1 antibody; Fig.S1 B). In addition, none of the L1-Fc–coated beads showedretrograde movement in the presence of both 1 µM cytochalasinD and 50 µM blebbistatin (n = 23; unpublished data), whichblock actin filament retrograde movement (Medeiros et al., 2006).Together, these results indicate that L1 is linked to actinfilament retrograde flow in the axonal growth cones of hippocampalneurons.

Shootin1 mediates the linkage between actin filament retrograde flow and L1 in growth cones
To examine whether shootin1 mediates this linkage, we firstsuppressed shootin1 expression in hippocampal neurons usingshort hairpin RNA (shRNA). Neurons expressing shRNA againstshootin1 were immunostained by anti-shootin1 antibody afterthe observation of actin filament retrograde flow in growthcones (Fig. S2, A and B, available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1).The mean shootin1 immunoreactivity in growth cones of neuronsexpressing the shRNA (n = 6 growth cones) was 11% of that ingrowth cones expressing the control shRNA (n = 6 growth cones).The rates of EGFP-actin retrograde flow in growth cones expressingshootin1 shRNA and in those expressing control shRNA were 4.0± 0.9 µm/min (n = 60) and 4.1 ± 0.5 µm/min(n = 60), respectively; the difference between them was notsignificant (P = 0.91). In addition, there was no significantdifference in the levels and organization of actin filamentsin growth cones expressing shootin1 shRNA and those expressingcontrol shRNA (n = three independent cultures, 150 growth conesexamined; P = 0.27; Fig. S2 C).

However, suppression of shootin1 by shRNA significantly reducedthe flow velocity of L1-Fc–coated beads (n = 71, P = 0.0000035compared with control; Fig. 4, A, B, and E; and Videos 6 and7, available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1),although it did not affect the percentage of the beads thatshowed retrograde flow. The peak velocity of moving beadsdeclined substantially from 0.8–1.0 µm/min to 0.4–0.6µm/min. In addition, expression of an RNAi refractorymyc-shootin1 rescued the effect of shootin1 RNAi (n = 44; P= 0.85 compared with control; P = 0.00024 compared with RNAi;Fig. 4, C–E). Each L1-Fc–coated bead probably bindsto multiple L1 molecules in growth cones, thereby monitoringthe engagement of multiple L1 molecules with actin filamentretrograde flow. Thus, the reduction in the flow velocity ofL1-Fc–coated beads by RNAi without a change in the actinfilament retrograde flow rate suggests that suppression of shootin1in growth cones reduces the number of L1 molecules linked toactin flow. We do not rule out the alternative possibility thatL1 can bind to F-actin flow weakly even in the absence of shootin1.In such a case, shootin1 down-regulation would lead to a decreasein the number of L1 molecules strongly linked to F-actin flow.Concerning the percentage of the moving beads, Gil et al. (2003)found that the stationary behavior of beads bound to cell surfaceL1 is mediated by ankyrin. The percentage of moving L1-Fc–coatedbeads may therefore be mainly regulated by this molecule. Together,these results suggest that shootin1 mediates the linkage betweenactin filament retrograde flow and L1 in growth cones.

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Figure 4. Repression of shootin1 expression by RNAi weakens the actin flow–L1 linkage. (A, B, and D) DIC micrographs showing retrograde movement of L1-Fc–coated beads on axonal growth cones (two days in vitro) expressing a control shRNA (A), the shRNA designated against shootin1 (B), or the shRNA designated against shootin1 together with the mutant myc-shootin1 (D), which is refractory to the shRNA (left), and time series of the indicated areas at 30-s intervals (right). See Videos 6 and 7 (available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1). As previously described (Toriyama et al., 2006), about half of the RNAi-induced neurons polarized after 48 h in vitro. Therefore, we selected such neurons and performed the analysis on their axonal growth cones. (C) Hippocampal neurons transfected with shootin1 shRNA (left), or shootin1 shRNA together with the refractory myc-shootin1 (right) were cultured for 48 h. The vector to express the shRNAs is designed to coexpress EGFP (green). Shootin1 and myc-shootin1 were immunostained by anti-shootin1 (left) and anti-myc (right) antibodies, respectively (red). Arrows denote axonal growth cones. (E) The percentage of beads coated with L1-Fc that showed retrograde flow on growth cones expressing a control shRNA (n = 86), shootin1 shRNA (n = 71), or shootin1 shRNA and the refractory myc-shootin1 (n = 44); mean velocity of moving beads as means ± SEM (***, P < 0.0005 compared with control and RNAi + refractory shootin1); and the percentage of moving beads with indicated velocities. Bars: (B) 5 µm; (C) 50 µm.

${Delta}$ N-shootin1 and NES- ${Delta}$ N-shootin1 disturb the interaction between shootin1 and actin filament retrograde flow
Next, we designed a shootin1 deletion mutant that disturbs theinteraction between shootin1 and actin filament flow. Becauseshootin1 does not have well-characterized functional domains(Toriyama et al., 2006), we could not design mutants based ondomain structure. ${Delta}$ N-shootin1 was produced by deleting the N-terminal216 amino acids from the wild type (Fig. 5 A). We fused thenuclear export signal (NES) LSLKLAGLDL (Fukuda et al., 1996)to the N terminus of ${Delta}$ N-shootin1, as ${Delta}$ N-shootin1 unexpectedlyaccumulated in the neuronal nucleus. Myc-NES- ${Delta}$ N-shootin1 waslocalized in the cytoplasm of hippocampal neurons and accumulatedin growth cones (unpublished data). When EGFP- ${Delta}$ N-shootin1 orEGFP-NES- ${Delta}$ N-shootin1 were expressed in XTC fibroblasts, theirspeckles showed retrograde movement similar to that of EGFP-shootin1(Fig. 5 B and Video 8, available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1;and data not shown), which suggests that these mutants alsointeract with actin filament retrograde flow. Overexpressionof myc-NES- ${Delta}$ N-shootin1 in XTC cells decreased the number of EGFP-shootin1speckles that displayed retrograde movement without affectingthe retrograde flow of mCherry-actin speckles (Fig. 5 C andVideo 9). Similar results were obtained for myc- ${Delta}$ N-shootin1 (unpublisheddata). We also produced ${Delta}$ C-shootin1, in which the C-terminal79 amino acids of the wild type were deleted (Fig. 5 A). Incontrast to ${Delta}$ N-shootin1, EGFP- ${Delta}$ C-shootin1 did not interact withactin retrograde filament flow in XTC cells (Fig. 5 A), andmyc- ${Delta}$ C-shootin1 did not accumulate in neuronal growth cones (notdepicted). In addition, overexpression of myc-shootin1 or myc- ${Delta}$ C-shootin1in XTC cells did not decrease substantially the number of EGFP-shootin1speckles that displayed retrograde movement (Fig. 5, D and E).These results suggest that ${Delta}$ N-shootin1 and NES- ${Delta}$ N-shootin1 disturbthe interaction between shootin1 and actin filament retrogradeflow.

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Figure 5. NES- ${Delta}$ N-shootin1 disturbs the linkage between shootin1 and actin filament retrograde flow. (A) Schematic representation of the wild-type (WT) and ${Delta}$ N- and ${Delta}$ C-shootin1, and their abilities to interact with actin filament flow and inhibit the interaction between EGFP-shootin1 and actin filament flow. Numbers indicate amino acid numbers. (B and C) Fluorescent speckle images of EGFP- ${Delta}$ N-shootin1 (B, left), and EGFP-shootin1 and mCherry-actin coexpressed in the same XTC fibroblast (C, left), with a time series of the indicated area of the cells at 10-s intervals (right). Myc-NES- ${Delta}$ N-shootin1 was also overexpressed in the cell in C under the β-actin promoter. See Videos 8 and 9 (available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1). (D and E) Fluorescent speckle images of EGFP-shootin1 (left) in XTC fibroblasts and a time series of the indicated area of the cells at 10-s intervals (right). Myc-shootin1 (D) and myc- ${Delta}$ C-shootin1 (E) were also overexpressed in the cells under the β-actin promoter. Arrowheads indicate speckles of EGFP- ${Delta}$ N-shootin1 (B), mCherry-actin (C), and EGFP-shootin1 (D and E) moving retrogradely. Bar, 5 µm.

Myc-NES- ${Delta}$ N-shootin1 was overexpressed in hippocampal neuronsto disturb this interaction. The rates of EGFP-actin retrogradeflow in growth cones overexpressing myc-NES- ${Delta}$ N-shootin1 and inthose overexpressing the control protein myc-GST were 3.6 ±0.4 µm/min (n = 60) and 3.9 ± 0.4 µm/min(n = 60), respectively (Fig. S2, D and E); the difference betweenthem was not significant (P = 0.12). In addition, there wasno significant difference between the levels and organizationof actin filaments in growth cones expressing these proteins(n = three independent cultures, 150 growth cones examined;P = 0.48; Fig. S2 F). However, overexpression of myc-NES- ${Delta}$ N-shootin1decreased the percentage of L1-Fc–coated beads that showedretrograde flow on axonal growth cones and significantly reducedthe velocity of the retrograde flow (n = 41, P = 0.011 comparedwith myc-GST; Fig. 6, A–C). The peak velocity of movingbeads declined substantially from 0.8–1.0 µm/minto 0.4–0.6 µm/min, which suggests that disturbingthe shootin1-actin flow interaction also weakens the actin flow–L1linkage. These results suggest that disturbing the interactionbetween shootin1 and actin filament flow by NES- ${Delta}$ N-shootin1 alsoimpairs the actin flow–L1 linkage, and strengthen thenotion that shootin1 mediates the linkage between actin filamentretrograde flow and L1 in growth cones.

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Figure 6. Disturbing the linkage between shootin1 and actin filament retrograde flow by NES- ${Delta}$ N-shootin1 weakens the actin flow–L1 linkage. (A and B) DIC micrographs showing retrograde movement of L1-Fc–coated beads on axonal growth cones (two days in vitro) overexpressing myc-GST (A, left) or myc-NES- ${Delta}$ N-shootin1 (B, left), and a time series of the indicated areas at 30-s intervals (A and B, right). (C) The percentage of beads coated with L1-Fc that showed retrograde flow on growth cones expressing myc-GST (n = 41) or myc-NES- ${Delta}$ N-shootin1 (n = 41), mean velocity of moving beads as means ± SEM (**, P < 0.02), and the percentage of moving beads with indicated velocities. (D) A fluorescent speckle image of EGFP-NES- ${Delta}$ N-shootin1 in an axonal growth cone (left) and a time series of the indicated area at 5-s intervals (right). Arrowheads indicate a speckle of EGFP-NES- ${Delta}$ N-shootin1 moving retrogradely. Bars, 5 µm.

To examine whether NES- ${Delta}$ N-shootin1 retains the ability to associatewith L1, we compared the flow speeds of EGFP-NES- ${Delta}$ N-shootin1(Fig. 6 D) and EGFP-shootin1 (Fig. 1 C) in growth cones: theywere 4.2 ± 0.5 µm/min (mean ± SD, n = 60)and 4.5 ± 0.4 µm/min (mean ± SD, n = 60),respectively, and not significantly different (P = 0.37). Togetherwith the finding that overexpression of myc-NES- ${Delta}$ N-shootin1 reducedthe velocity of the L1-Fc-coated beads, these observations suggestedthat ${Delta}$ N-shootin1 has a reduced ability to associate with L1.

Impairing the actin flow–L1 linkage by shootin1 RNAi inhibits L1-dependent axon outgrowth
Next, we analyzed the effects of impairing the actin flow–L1linkage on axon outgrowth. Hippocampal neurons were transfectedwith shRNA against shootin1 and cultured for 48 h on coverslipscoated with L1-Fc or a control substrate, polylysine. As hasbeen described (Oliva et al., 2003), control neurons developedlonger axons on L1-Fc than on polylysine (Fig. 7, A and B),which suggests that homophilic binding between L1 in growthcones and L1-Fc on culture plates is important for axon outgrowth. Suppression of shootin1 expression by RNAi resulted in a significantdecrease in axonal length on L1-Fc (n = three independent cultures,160 neurons examined; P = 0.0086 compared with control; Fig. 7 B),whereas shootin1 RNAi on polylysine caused only a marginal reductionof axonal length (n = three independent cultures, 174 neuronsexamined; P = 0.22 compared with control). The decrease in axonallength by RNAi was significantly smaller on polylysine thanon L1-Fc (P = 0.032; Fig. 7 C). This is consistent with theobservation that shootin1 RNAi reduced the velocity of retrogrademovement of L1-Fc–coated beads on axonal growth cones(Fig. 4) but did not affect the movement of polylysine-coatedbeads (n = 49; P = 0.58 compared with control; Fig. 8, A–C). The inhibition of axon elongation on L1-Fc by RNAi was rescuedby expression of the RNAi refractory myc-shootin1 (n = threeindependent cultures, 270 neurons examined; P = 0.60 comparedwith control; P = 0.00068 compared with RNAi; Fig. S3 A, availableat http://www.jcb.org/cgi/content/full/jcb.200712138/DC1).

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Figure 7. Impairing the actin flow–L1 linkage by RNAi inhibits L1-dependent axon outgrowth. Hippocampal neurons were transfected with shRNA against shootin1 or with control shRNA, and cultured on L1-Fc– or polylysine-coated coverslips for 48 h. Some were also cotransfected with shRNA against L1. Neuronal morphology was visualized by EGFP fluorescence. (A) Vectors expressing shRNAs coexpress EGFP. (B) Length of axons or the longest neurites. (C) The percentage reduction in axons by shootin1 RNAi (mean ± SEM; *, P < 0.05, ***, P < 0.01; n = 3 independent cultures; 512 neurons were examined). Bar, 50 µm.

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Figure 8. Shootin1 RNAi does not affect the movement of polylysine-coated beads on axonal growth cones. (A and B) DIC micrographs showing retrograde movement of polylysine-coated beads on axonal growth cones (two days in vitro) expressing a control shRNA (A, left) or a shRNA against shootin1 (B, left), and a time series of the indicated areas at 30-s intervals (A and B, right). (C) The percentage of polylysine-coated beads that showed retrograde flow on axonal growth cones expressing the control (n = 46) or shootin1 shRNA (n = 49), mean velocity of moving beads as means ± SEM, and the percentage of moving beads with indicated velocities. Bar, 5 µm.

To further confirm that these RNAi effects are L1 dependent,neurons were cotransfected with shRNA against L1 and culturedon L1-Fc. Consistent with the notion that homophilic bindingbetween L1 in growth cones and L1-Fc on culture plates is importantfor axon outgrowth, neurons transfected with control shRNA andcultured on L1-Fc developed longer axons than those transfectedwith L1 shRNA and cultured on L1-Fc (Fig. 7, A and B). Shootin1RNAi reduced axonal length of neurons transfected with L1 shRNAand cultured on L1-Fc (n = three independent cultures, 178 neuronsexamined; P = 0.0022 compared with control; Fig. 7, A and B),though to a significantly lesser degree than the reduction seenin neurons without L1 RNAi (P = 0.00063; Fig. 7 C), therebyconfirming the L1-dependency of the RNAi effects. We previouslyfound that shootin1-induced axon formation was inhibited bythe PI-3 kinase inhibitor LY294002 (Toriyama et al., 2006).However, it was not fully suppressed, which suggests the existenceof an additional PI-3 kinase–independent mechanism forshootin1-induced axon outgrowth. Therefore, we also examinedwhether the effects of shootin1 RNAi on L1-dependent axon outgrowthare affected by PI 3-kinase activity. In the presence of 20µM LY294002, shootin1 RNAi resulted in a significant decreasein axon outgrowth on L1-Fc (n = three independent cultures,226 neurons examined; P = 0.00015 compared with control) butnot on polylysine (n = three independent cultures, 213 neuronsexamined; P = 0.52 compared with control; Fig. S3 B). The decreasein axon outgrowth by shootin1 RNAi on L1-Fc in the presenceor absence of LY294002 was similar (P = 0.73; Fig. S3C), therebysuggesting that the effects of shootin1 RNAi on L1-dependentaxon outgrowth are not influenced by PI 3-kinase activity. Together,these results suggest that impairing the actin flow–L1linkage by shootin1 RNAi inhibits L1-dependent axon outgrowth.

Impairing the actin flow–L1 linkage by NES- ${Delta}$ N-shootin1 inhibits L1-dependent axon outgrowth
Next, we examined the effects of disturbing the actin flow–shootin1linkage by NES- ${Delta}$ N-shootin1 on axon outgrowth. As in the caseof shootin1 RNAi, overexpression of myc-NES- ${Delta}$ N-shootin1 in hippocampalneurons also reduced axon outgrowth significantly on L1-Fc (n= three independent cultures, 623 neurons examined; P = 0.00083compared with GST; Fig. 9, A and B). We noted that cell bodiesof some neurons overexpressing myc-NES- ${Delta}$ N-shootin1 showed a ratherflattened morphology (unpublished data). Overexpressing myc-NES- ${Delta}$ N-shootin1in neurons cultured on polylysine or in neurons expressing L1shRNA also inhibited axon outgrowth (for neurons on polylysine:n = three independent cultures, 565 neurons examined, P = 0.0062compared with GST; for neurons expressing L1 shRNA: n = threeindependent cultures, 182 neurons examined, P = 0.00088 comparedwith GST; Fig. 9, A and B); however, the effects were significantlyweaker than those in neurons cultured on L1-Fc without L1 RNAi(for neurons on polylysine: P = 0.0014; for neurons expressingL1 shRNA: P = 0.034; Fig. 9 C). Thus, although these data suggestan additional L1-independent effect of myc-NES- ${Delta}$ N-shootin1, italso inhibited L1-dependent axon outgrowth.

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Figure 9. Impairing the actin flow–L1 linkage by myc-NES- ${Delta}$ N-shootin1 inhibits L1-dependent axon outgrowth. Neurons overexpressing myc-NES- ${Delta}$ N-shootin1 or myc-GST were cultured on L1-Fc– or polylysine-coated coverslips for 48 h and stained by anti-myc antibody (A). Some were cotransfected with shRNA against L1. (B) The lengths of axons or the longest neuritis. (C) The percentage reduction in axons by expressing myc-NES- ${Delta}$ N-shootin1 (mean ± SEM; *, P < 0.05, ***, P < 0.01; n = 3 independent cultures, 1,370 neurons were examined). Bar, 50 µm.

Enhancing the actin flow–L1 linkage by shootin1 overexpression promotes L1-dependent neurite outgrowth
Finally, we examined whether increased levels of shootin1 alterthe linkage between actin flow and L1. To do so, because shootin1accumulates strongly in axonal growth cones (Fig. 1 A, arrows;Toriyama et al., 2006), we monitored the movement of actin retrogradeflow and L1-Fc–coated beads on minor process growth cones,where shootin1 levels are low (Fig. 1 A, arrowheads). The ratesof EGFP-actin retrograde flow in growth cones overexpressingmyc-shootin1 and in those overexpressing myc-GST were 4.6 ±0.8 µm/min (n = 60) and 4.3 ± 0.5 µm/min(n = 60), respectively (Fig. S4, A and B, available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1);the difference between them was not significant (P = 0.25).In addition, there was no significant difference between thelevels and organization of actin filaments in growth cones expressingthese proteins (n = three independent cultures, 150 growth conesexamined; P = 0.42; Fig. S4 C).

In contrast to shootin1 RNAi and myc-NES- ${Delta}$ N-shootin1 overexpression,myc-shootin1 overexpression significantly increased the velocityof those beads that showed retrograde movement on minor processgrowth cones (n = 35, P = 0.045 compared with GST; Fig. 10, A–C),which suggests that it enhanced the actin flow–L1 linkage. These results further strengthen the notion that shootin1 mediatesthe linkage between actin filament retrograde flow and L1 ingrowth cones. Concurrently, myc-shootin1 overexpression in hippocampalneurons promoted outgrowth of total minor processes on L1-Fc(n = four independent cultures, 276 neurons examined; P = 0.039compared with GST; Fig. 10, D and E) but not in neurons expressingshRNA against L1 (n = four independent cultures, 278 neuronsexamined; P = 0.47 compared with GST; Fig. 10, D–F). Wealso examined whether the effects of shootin1 overexpressionon L1-dependent neurite outgrowth are affected by PI 3-kinaseactivity. In the presence of LY294002, shootin1 overexpressionresulted in a significant increase in axonal length on L1-Fc(n = 3 independent cultures, 244 neurons examined; P = 0.050compared with control; Fig. S4 D). A similar increase was observedin the absence of LY294002 (P = 0.84; Fig. S4 D), which indicatesthat the effects of shootin1 overexpression on L1-dependentaxon outgrowth are not affected by PI 3-kinase activity, asin the case of shootin1 RNAi. Thus, we considered that L1-dependentaxon outgrowth induced by shootin1 was mediated mainly througha PI 3-kinase–independent mechanism. Together, these resultssuggest that enhancing the actin flow–L1 linkage by shootin1overexpression promotes L1-dependent neurite outgrowth.

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Figure 10. Enhancing the actin flow–L1 linkage by shootin1 overexpression promotes L1-dependent neurite outgrowth. (A and B) DIC micrographs showing retrograde movement of L1-Fc–coated beads on minor process growth cones (one day in vitro) overexpressing myc-GST (A, left) or myc-shootin1 (B, left), and a time series of the indicated areas at 30-s intervals (A and B, right). (C) The percentage of beads coated with L1-Fc that showed retrograde flow on minor process growth cones expressing myc-GST (n = 28) or myc-shootin1 (n = 35), mean velocity of moving beads as means ± SEM (*, P < 0.05), and the percentage of moving beads with indicated velocities. (D–F) Neurons overexpressing myc-shootin1 or myc-GST were cultured on L1-Fc–coated coverslips for 24 h (D). They were also cotransfected with control shRNA or shRNA against L1. (E) The lengths of total minor processes (lengths of all neurites except the longest one) relative to that of the control neurons expressing myc-GST and control shRNA. (F) The percentage increase in total minor processes upon expression of myc-shootin1 (mean ± SEM; *, P < 0.05; n = 4 independent cultures, 554 neurons were examined). Bars: (B), 5 µm; (D) 50 µm.

	Discussion

Top Abstract Introduction Results Discussion Materials and methods References

Linkage between actin filament retrograde flow and CAMs in growthcones is thought to transmit the force of actin filament movementto extracellular substrates via CAMs, thereby providing mechanicaltension for axonal outgrowth and guidance. Actin flow–CAMlinkage has also been found to produce mechanical tension innonneuronal cells (Felsenfeld et al., 1996) and has been implicatedin cell migration (Felsenfeld et al., 1996) and the relocationof cell–cell contacts (Kametani and Takeichi, 2007). Concerningthe actin flow–CAM linkage in growth cones, a criticalquestion that remains to be addressed is the molecular basisfor the linkage. It is also unknown whether coupling of thislinkage induces axon outgrowth. Here, we have shown that shootin1interacts with both actin filament retrograde flow and L1 inaxonal growth cones and provided evidence that shootin1 mediatesthe linkage between them. When this linkage was impaired byshootin1 RNAi or NES- ${Delta}$ N-shootin1, axon outgrowth was inhibitedin an L1-dependent manner. However, enhancing the linkage byshootin1 overexpression promoted L1-dependent neurite outgrowth.We previously found that shoootin1 overexpression induced formationof multiple axons on coverslips coated with polylysine and laminin(Toriyama et al., 2006). As laminin binds to multiple CAMs,including L1 and its chicken relative NgCAM (Grumet et al., 1993;Brummendorf and Rathjen, 1996; Hall et al., 1997), we consideredthe fact that the coverslips coated with polylysine and laminincould monitor L1-dependent neurite outgrowth by shootin1. Collectively,the present results suggest that shootin1 is a key moleculeinvolved in the actin flow–CAM linkage for axon outgrowth.

We do not rule out the involvement of other molecules in thelinkage between actin filament flow and L1, or the possibilitythat shootin1 may couple actin flow to other CAMs. Unknown moleculesmay mediate the interaction between shootin1 and L1, as we couldnot obtain evidence that shootin1 directly interacts with L1.At present, it is also unknown whether shootin1 interacts directlywith actin filaments or through association with other molecules.The velocity of L1-Fc–coated microbeads on growth coneswas slower than those of shootin1 and actin filament retrogradeflows. Therefore, the couplings between shootin1 and L1 mayincorporate "clutchlike" slippages as previously proposed (Mitchison and Kirschner, 1988),or this may simply be reflective of the fact that the retrogradeflow has to move a heavy bead. Recently, we detected phosphorylatedforms of shootin1 in cultured hippocampal neurons (unpublisheddata). It will be intriguing to learn whether phosphorylationof shootin1 is involved in modulation of actin flow–CAMlinkage, which has been implicated in regulation of axon outgrowthand guidance (Suter et al., 1998; Suter and Forscher, 2000).Detailed molecular mechanisms involved in actin filament–shootin1linkage and shootin1-L1 linkage remain important issues forfuture analysis.

In conclusion, this study has shown that shootin1 mediates thelinkage between actin filament retrograde flow and L1 in growthcones. Formation of this linkage together with multiple mechanismsinvolving actin polymerization near the leading edge (Mallavarapu and Mitchison, 1999),microtubule dynamics (Tanaka and Sabry, 1995; Dent and Gertler, 2003),axonal transport (Brown, 2003), and plasma membrane expansion(Lockerbie et al., 1991) may coordinately contribute to axonoutgrowth.

Materials and methods

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Cultures and transfection
Hippocampal neurons prepared from embryonic day 18 rat embryoswere cultured on coverslips coated with L1-Fc, N-cadherin–Fc,or polylysine as described previously (Inagaki et al., 2001).They were transfected with vectors using Nucleofector (Amaxa)before plating. XTC cells were cultured as described previously(Higashida et al., 2004) and transfected with vectors usingSuperFect (QIAGEN). Coverslips coated with polylysine, L1-Fc,or N-cadherin–Fc were prepared as described previously(Inagaki et al., 2001; Kamiguchi and Yoshihara, 2001).

DNA constructs
cDNA fragments of the shootin1 deletion mutants ${Delta}$ N-shootin1 and ${Delta}$ C-shootin1 were amplified by PCR and subcloned into pCAGGS-myc(Niwa et al., 1991) or pEGFP (Clontech Laboratories, Inc.) vectors.pCAGGS-myc was used to overexpress proteins under the β-actinpromoter as described previously (Toriyama et al., 2006). Unexpectedly,myc- ${Delta}$ N-shootin1 preferentially accumulated in the neuronal nucleus,whereas it was mainly localized in the cytoplasm of XTC cells.To express myc- ${Delta}$ N-shootin1 in the cytoplasm of neurons, we fusedthe NES LSLKLAGLDL (Fukuda et al., 1996) to the N terminus of ${Delta}$ N-shootin1. The RNAi refractory shootin1 mutant was generatedby using QuikChange II site-directed mutagenesis kit (Stratagene).Four silent mutations (underlined) in 5'-TGAAGCTGTTAAAAAGTTAGA-3'were induced in the target sequence of shootin1 shRNA (Toriyama et al., 2006).

RNAi
Expression of shootin1 was suppressed using shRNA designatedagainst shootin1 as described previously (Toriyama et al., 2006).The original vector to express shRNAs was designed to coexpressEGFP. We also constructed a vector that does not coexpress EGFPby deleting the coding sequence of EGFP. For vector-based RNAiof L1, we also used the BLOCK-iT Pol II miR RNAi ExpressionVector kit (Invitrogen). The targeting mRNA sequence 5'-ATCATTCAGACTACATCTGCA-3'corresponds to nucleotides 605–625 in the coding regionof rat L1, whereas the control vector pcDNA 6.2-GW/EmGFP-miR-negencodes an mRNA not to target any known vertebrate gene. Toensure a high-level expression of shRNA before neurite elongation,hippocampal neurons prepared from embryonic day 18 rat embryoand transfected with the expression vector shRNA were platedon uncoated polystyrene plates. After a 20-h incubation to induceshRNA expression, the cells were collected and cultured on coverslipscoated with polylysine, L1-Fc, or N-cadherin–Fc. Reductionof shootin1 and L1 levels in neurons was confirmed immunocytochemicallyusing anti-shoootin1 (Toriyama et al., 2006) and anti-L1 antibodies(Fig. S5, available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1).

Immunocytochemistry and immunoprecipitation
Immunocytochemistry and immunoprecipitation were performed asdescribed previously (Toriyama et al., 2006). Secondary antibodiesand phalloidin were conjugated with Alexa 488 (Invitrogen),Alexa 594 (Invitrogen), or rhodamine (Invitrogen). We used 50%glycerol and 50% PBS as the mounting medium.

Microscopy
Fluorescence and phase-contrast images of fixed neurons wereacquired at room temperature using a fluorescence microscope(Axioplan2; Carl Zeiss, Inc.) equipped with a plan-Neofluar40x 0.75 NA or 20x 0.50 NA objective (Carl Zeiss, Inc.), a charge-coupleddevice camera (AxioCam MRm; Carl Zeiss, Inc.), and imaging software(Axiovision 3; Carl Zeiss, Inc.). The original images of shootin1immunoreactivity and Alexa 594 phalloidin staining were quantifiedusing Multi Gauge software (Fujifilm). Adjustments of imagesize, brightness, and contrast were performed on Photoshop Element5.0 (Adobe). For the deconvolution analysis shown in Fig. 1 Band Fig. 3 A, z series of focal planes were digitally imagedat room temperature using a fluorescence microscope (AxiovertS100; Carl Zeiss, Inc.) equipped with a plan-Apochromat 63xoil 1.40 NA objective (Carl Zeiss, Inc.) and CSNAP and Deltavision2(Applied Precision, LLC) software, and deconvolved with theDeltavision constrained iterative algorithm to generate high-resolutionimages.

Fluorescent speckle imaging
Fluorescent speckle imaging was performed as described previously(Watanabe and Mitchison, 2002) using EGFP- or mCherry-taggedproteins, and cells were cultured in Leibovitz's L-15 medium(Invitrogen). Speckle images were acquired at room temperature(XTC cells) or 37°C (neurons) using a fluorescent microscope(BX52; Olympus) equipped with a cooled charge-coupled device(CCD) camera (Cool SNAP HQ; Roper Scientific), or an invertedmicroscope (IX71; Olympus) equipped with a cooled CCD camera(UIC-QE; MDS Analytical Technologies), using in both cases aplan-Apochromat 100x oil 1.40 NA objective (Olympus) and imagingsoftware (MetaMorph; MDS Analytical Technologies). Adjustmentsof image size, brightness, and contrast were performed on PhotoshopElement 5.0. Speckle speed was measured by the following procedure,using Multi Gauge software. First, a pair of moving specklesthat kept their relative position constant for at least 20 sduring each experiment (5 frames) were identified. We then manuallyoverlaid 300-nm-diameter circle scales on one of these speckles,and the translocation of the circles between the first and fifthframes was measured.

Bead tracking
1-µm-diameter polystyrene beads (Polysciences, Inc.) werecoated with L1-Fc or anti-L1 antibody (Kamiguchi and Yoshihara, 2001)as described previously (Nishimura et al., 2003). To preparepolylysine-coated beads, a 1% (wt/vol) aqueous suspension of1-µm-diameter polystyrene beads was mixed with an equalvolume of 20 mg/ml carbodiimide in sodium phosphate buffer for4 h at room temperature. After washes, the beads were incubatedwith 1 mg/ml polylysine in PBS, pH 7.4, overnight at room temperature.The beads were blocked with 7.5 mg/ml BSA in 50 mM Tris-HClbuffer, pH 8.0, and stored in PBS at 4°C. As described previously(Kamiguchi and Yoshihara, 2001), we used the laser optical trapsystem to place beads on growth cones cultured in Leibovitz'sL-15 medium (Invitrogen).

As vectors expressing shRNAs are designed to coexpress EGFP,we used the EGFP fluorescence to identify growth cones expressingshRNA during bead tracking experiments. Reduction of shootin1and L1 levels and expression of myc-tagged proteins in neuronswere confirmed immunocytochemically after the experiments. Differentialinterference contrast (DIC) images of beads were acquired atroom temperature using a fluorescence microscope (Eclipse TE2000-U;Nikon) equipped with a plan-Apochromat 60x WI 1.20 NA objective(Nikon) and a digital video camera (DCR-SR100; Sony). Videoswere acquired directly by the video camera without software.Extraction of still images from videos was performed by Premier6 (Adobe). Adjustments of image size, brightness, and contrastwere performed on Photoshop Element 5.0. Bead velocity was quantifiedusing Multi Gauge software. We manually overlaid 1-µm-diametercircle scales on the images of microbeads and then measuredtranslocation of the scales during a 2-min observation period(121 frames).

Statistics
In the statistical analysis, significance was determined bythe unpaired Student's t test.

Materials
Preparation of anti-shootin1 antibody has been described previously(Toriyama et al., 2006). Antibody against the L1 cytoplasmicdomain (Schaefer et al., 1999) was provided by V. Lemmon (Universityof Miami School of Medicine, Miami, FL). Antibodies againstmyc and L1 were obtained from MBL International and Santa CruzBiotechnology Inc., respectively. Blebbistatin, cytochalasinD, and poly-D-lysine were obtained from BIOMOL International,L.P., EMD, and Sigma-Aldrich, respectively. Rhodamine phalloidinand Alexa 594 phalloidin were obtained from Invitrogen. mCherry(Shaner et al., 2004) was provided by R. Tsien (University ofCalifornia, San Diego, San Diego, CA).

Online supplemental material
Fig. S1 shows linkage between L1 and actin filament retrogradeflow in axonal growth cones. Fig. S2 shows the effects of shootin1RNAi and NES- ${Delta}$ N-shootin1 overexpression on actin filament retrogradeflow in axonal growth cones. Fig. S3 shows the effects of RNAirefractory shootin1 and LY294002 on the shootin1 RNAi–inducedinhibition of axon outgrowth on L1-Fc. Fig. S4 shows the effectsof shootin1 overexpression on actin filament retrograde flowtogether with the effects of LY294002 on the shootin1-inducedpromotion of L1-dependent neurite outgrowth. Fig. S5 shows repressionof L1 by RNAi. Videos 1 and 5 are time-lapse videos of EGFP-shootin1speckles in the growth cone of hippocampal neurons as describedin Fig. 1 C and Fig. 2 B. Video 2 is a time-lapse video of EGFP-shootin1speckles in an XTC cell as described in Fig. 1 D. Video 3 and4 are time-lapse videos of EGFP-shootin1 and mCherry-actin specklesin XTC cells as described in Fig. 1 E and Fig. 2 A. Video 6and 7 are time-lapse videos of L1-Fc–coated beads on theaxonal growth cone of hippocampal neuron as described in Fig.4 (A and B). Video 8 is a time-lapse video of EGFP- ${Delta}$ N-shootin1speckles in an XTC cell as described in Fig. 5 B. Video 9 isa time-lapse video of EGFP-shootin1 and mCherry-actin specklesin the same XTC cell as described in Fig. 5 C. Online supplementalmaterial is available at http://www.jcb.org/cgi/content/full/jcb.200712138/DC1.

Acknowledgments

We thank V. Lemmon for providing anti-L1 antibody and L1 constructs,R. Tsien for providing mCherry, A. Konishi for discussion, andI. Smith for reviewing the manuscript.

This research was supported in part by the Ministry of Education,Culture, Sports, Science and Technology (MEXT; 20300111 and19700291) and the Japan Society for the Promotion of Science(20022029 and 20016017) Grant-in-Aid for Scientific Research,the Global Centers of Excellence Program at Nara Institute ofScience and Technology (MEXT), the Osaka Medical Research Foundationfor Incurable Diseases, and the Nara Institute of Science andTechnology Interdisciplinary Promotion Project.

Submitted: 21 December 2007

Accepted: 30 April 2008

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