![[Feedback]](/icons/banner/feedbackACT.gif){kind=icon}
![[For Subscribers]](/icons/banner/subscriberACT.gif){kind=icon}
![[Archive]](/icons/banner/archiveACT.gif){kind=icon}
![[Search]](/icons/banner/searchACT.gif){kind=icon}
![[Contents]](/icons/banner/tocACT.gif){kind=icon}
|
|
|
|
|
||
Vol. 18, Issue 11, 4591-4602, November 2007
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
*Department of Cell Biology, Lerner Research Institute, and Department of Molecular Medicine, Cleveland Clinic Lerner College of Medicine, The Cleveland Clinic, Cleveland, OH 44195; and Randall Division of Cell and Molecular Biophysics, King's College London, Guy's Campus, London SE1 1UL, United Kingdom
Submitted February 21, 2007;
Revised August 29, 2007;
Accepted August 31, 2007
Monitoring Editor: Yu-li Wang
 |
ABSTRACT |
|---|
 TOP ABSTRACT INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
|
INTRODUCTION |
|---|
|
TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
). Understanding the early events that enable carcinoma cell migration and invasion is thus an important research goal that has potential to improve early diagnosis of aggressive tumors and to stimulate new approaches toward molecularly based adjuvant therapies.
Migration and invasion of carcinoma cells are highly coordinated processes that depend in large part on alterations to cell–cell and cell–extracellular matrix (ECM) adhesion properties and the molecular composition and organization of the actin cytoskeleton (for review, see Guo and Giancotti, 2004; Carragher and Frame, 2004). Direct imaging of carcinoma cell migration in ECM layers and in living primary tumors has revealed that carcinoma cells migrate singly or as collective groups, often undergoing directed movement along collagen fibers. Within the local stroma, this mode of migration involves extensive assembly of cell protrusions, whereas specialized, ECM-degrading adhesions termed invadopodia or podosomes may mediate intravasation (for review, see Friedl and Wolf, 2003; Condeelis et al., 2005). Several approaches have identified gene expression profiles that distinguish invading cells from cells that remain within the primary tumor. Micropipet collection of cells chemotaxing toward epidermal growth factor in rat and mouse carcinoma models identified a gene expression signature in which transcripts for multiple actin-binding and regulatory proteins were up-regulated (Wyckoff et al., 2000; Condeelis et al., 2005). Comparative gene expression profiling of primary and metastatic tumors has begun to address the issue of metastasis to specific organs and to demonstrate significant alterations in the expression of cytoskeletal components (van't Veer et al., 2002; Minn et al., 2005).
Other candidate markers of migratory carcinoma cells have been identified at protein level by immunohistochemical analyses of clinical specimens. With regard to cytoskeletal reorganizations in carcinoma cells, the actin-bundling protein fascin has emerged as a very interesting candidate biomarker because its expression is low or absent in the majority of normal adult epithelia, yet up-regulation of the protein has been reported in all forms of human carcinoma studied to date. Consistently, irrespective of the tissue source of the tumor, primary carcinomas with high levels of fascin correlate with a clinically aggressive phenotype and poor prognosis (Maitra et al., 2002; Pelosi et al., 2003; Hashimoto et al., 2004, 2005a,b, 2006; Yoder et al., 2005; Zigeuner et al., 2006). Whether fascin contributes functionally to metastasis is largely unknown; however, high fascin protein in the primary carcinoma has been correlated with local lymph node or distant metastases (Hashimoto et al., 2004; Puppa et al., 2007) or with an increased frequency of metastastic disease (Zigeuner et al., 2006). The fascin transcript is a component of a gene signature that correlates with breast cancer metastasis to the lung (Minn et al., 2005).
To date, the cellular and molecular properties of fascin have been mostly studied in normal mesenchymal and neuronal cells. In vitro, fascin cross-links filamentous actin (F-actin) into tightly packed, parallel bundles in cooperation with Arp2/3 complex and Wiskott-Aldrich syndrome protein (Vignjevic et al., 2003; Haviv et al., 2006). In intact cells, fascin-and-actin bundles support cortical cell protrusions and growth cone filopodia (Yamashiro et al., 1998; Adams et al., 1999; Cohan et al., 2001, Adams and Schwartz, 2000; Anilkumar et al., 2003; Svitkina et al., 2003; Vignjevic et al., 2006). Fascin contains N- and C-terminal actin-binding sites and the actin cross-linking activity of fascin is negatively regulated by a protein kinase C (PKC) phosphorylation site (serine-39 in human fascin) that lies within the amino-terminal actin-binding site (Ono et al., 1997). The balance between nonphosphorylated and phosphorylated fascin in cells is governed by ECM components and other extracellular cues (for review, see Adams, 2004). The expression of fascin in carcinoma cells represents an aberrant situation for which the regulatory mechanisms and specific functional consequences are largely unknown (for review, see Hashimoto et al., 2005a). Fascin overexpression or depletion were reported to result in altered carcinoma cell migration, but the mechanisms of how fascin affects this endpoint remain unclear (Jawhari et al., 2003; Hashimoto et al., 2005b; Xie et al., 2005). Here, we have developed inducible knockdown of fascin in human colon carcinoma cells to establish the functional contribution of fascin in carcinoma cells and in vivo.
|
MATERIALS AND METHODS |
|---|
|
TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
; Adams and Schwartz, 2000). A GFP-Xenopus tropicalis fascin-1 expression plasmid was prepared by subcloning X. tropicalis fascin-1 cDNA (clone Thda 017B16; obtained from Cambridge University and The Wellcome Trust Sanger Institute and Wellcome Trust/Cancer Research UK Institute X. tropicalis EST project; Gilchrist et al., 2004) into pEGFP-C (Clontech, Mountain View, CA) by using the polymerase chain reaction (PCR) primers listed in Table 2. The cDNA clone was sequenced in it entirety, and it is deposited as GenBank DQ374150. S33A and S33D mutations of X. tropicalis fascin-1 were prepared by PCR-based mutagenesis of green fluorescent protein (GFP)-Xtfascin, by using the oligonucleotides listed in Table 2 and the QuikChange II site-directed mutagenesis kit (Stratagene, La Jolla, CA).
|
|
Flow Cytometry
Cells were trypsinized and resuspended at 2 x 107 cells/ml in phosphate-buffered saline (PBS). Then, they were incubated on ice with antibodies to integrin subunits (Table 1) at established appropriate dilutions, or isotype-matched controls, washed, incubated for 30 min with fluorescein isothiocyanate (FITC)-conjugated secondary antibodies, and washed again. Cells were passed through a BD Biosciences FACScan using FlowJo software (Tree Star, Ashland, OR) with fluorescent excitation with an Argon laser (excitation at 488 nm). Ten thousand events were acquired per sample.
Soft Agar Growth Assay
We seeded 35-mm dishes in triplicate with 5 x 102, 5 x 103, or 5 x 104 cells in 1 ml of DMEM containing 10% FCS and 0.35% Noble agar (BD Biosciences) over a base of DMEM containing 10% FCS and 0.5% Noble agar. Dishes were refed with 1 ml of DMEM containing 10% FCS and 0.35% Noble agar each week. Colony formation was scored by microscopical examination after 4 wk.
Tumor Xenografts in Nude Mice
Experiments were carried out by Cleveland Clinic Foundation (CCF) Animal Tumor Core in accordance with institutional guidelines. For subcutaneous injection, eight 5-wk-old female NCr athymic nude (nu/nu) mice were injected in the right and left flanks with 106 SW480-Pa cells or IKD-F11 cells in 50 µl of PBS, respectively. Mice were randomly assigned into two groups of four. One group received doxycycline ad libitum at 2 mg/ml in the drinking water. Mice were inspected every 3–4 d and tumors measured with calipers over a 32-d period. Volumes were calculated using the formula for a prolate spheroid: (4/3)
ab2 (a is major axis and b is minor axis of the tumor). For metastasis experiments, groups of 12 mice were injected intrasplenically with either 5 x 106 SW480-Pa or IKD-F11 cells in 50 µl of PBS. Mice in each group were randomly assigned into two sets of six. One set of each cell line received doxycycline as described above. In total, six mice were removed from the experiment because they died the day after inoculation. Other mice were inspected every 3–4 d for 7 wk. For analysis of metastatic behavior of GFP-Xtfascin subclones, groups of six mice were injected intrasplenically with 2 x 106 IKD-F11 cells stably expressing either GFP, GFP-Xtfascin, GFP-XtfascinS33A, or GFP-XtfascinS33D, in 50 µl of PBS. All mice were maintained on doxycycline and inspected every 3–4 d for 8 wk. At the end of each experiment, all mice were killed by CO2 inhalation and necropsied. Primary spleen tumors and macroscopic metastatic tumors in the abdomen, liver, or ovary were recorded. Tumors were resected and either fixed in 10% formaldehyde/PBS or snap-frozen in liquid nitrogen and stored at –80°C for immunoblotting. Fixed tumors were paraffin-embedded, sectioned, and stained with hematoxylin and eosin or immunostained for human fascin as described previously (Yoder et al., 2005).
Scanning Electron Microscopy
Cells plated on 15 nM laminin (LN) for 2 h were fixed in 1.6% paraformaldehye/2.5% glutaraldehyde and postfixed with 1% osmium tetroxide and 0.5% uranyl acetate. Samples were dehydrated through a series of graded ethyl alcohols (70–100%), followed by chemical drying in hexamethyldisilazane. Cells were coated with gold and examined under a JEOL JSM-5310 microscope by using JUS DSG1 Digital Imaging Console version 2.30C (JEOL USA, Peabody, MA).
Fluorescence Microscopy
Experiments were carried out with cells plated for 2 h on 15 nM LN; in some experiments, cells were pretreated with inhibitors. Indirect immunofluorescent stainings for fascin, 
-actinin, phosphotyrosine, and vinculin were carried out as described previously (Adams, 1997; Anilkumar et al., 2003). Samples labeled with FITC, tetramethylrhodamine B isothiocyanate, or Alexa 568 fluorochromes were examined at room temperature under a Leica DM RXE(TCS-SP/SP-AOSB) confocal laser scanning microscope with HCX Plan Apo 63x numerical aperture 1.4 oil immersion objective lens, using Leica confocal software version 2.5 (Leica, Wetzler, Germany). Confocal images were acquired as Z stacks or single XY sections at room temperature. In some experiments, projections of image stacks were prepared in Volocity version 3.7.0 (Improvision, Coventry, United Kingdom).
Transfilter Migration Assay
We seeded 2.5 x 104 cells/well into the top chambers of a 24-well, 8-µm pore-size micropore polycarbonate membrane filter (BD Biosciences), and the lower chambers were filled with DMEM containing 10% FCS as a chemoattractant and incubated for 24 h at 37°C. Cells remaining on the upper surface were carefully removed with a cotton swab, and the membranes were fixed and stained with Diff-Quik stain (Dade Behring, Deerfield, IL). Migration was quantified by counting the migrated cells in five random 20x magnification fields per filter. At least three independent experiments were carried out.
Time-Lapse Imaging of Migrating Cells
Cells were plated for 1 h at 37°C in serum-free DMEM on glass-bottomed dishes (MatTek, Ashland, MA) coated with 15 nM LN and blocked with 1 mg/ml heat-denatured bovine serum albumin. Pilot experiments established this concentration to be optimal for haptokinetic (i.e., random migration on uniform ECM) cell migration. Nonattached cells were rinsed off, and the remaining cells, in serum-free DMEM, were placed into a temperature- and CO2-controlled incubator (at 37°C, 5% CO2) on the stage of a Leica DMIRE2 inverted microscope (Leica), equipped with electronically controlled shutters and filter wheel. Phase contrast images were captured under a 20x objective with a camera controller C4742_95 (Hamamatsu, Bridgewater, NJ), run by Improvision Openlab software, version 3.1.5, every 4 min for 50 frames (in total, 200 min). In some experiments, cells were pre-treated with pharmacological agents as described in the text. All reagents were maintained throughout the experiments at the same concentrations as used for pretreatment. Mean cell speed (defined as length of the migration trajectory divided by time) and net migration (defined as straight-line distance between the starting and ending points) were calculated from traces of the displacement of each cell centroid prepared in Improvision Openlab 3.1.5 and analyzed in Excel (Microsoft, Redmond, WA). At least three independent experiments were carried out for each experimental condition.
Analysis of Focal Adhesion Disassembly
Cells were transfected with monomeric red fluorescent protein (mRFP)-paxillin (gift of Martin Humphries, University of Manchester, Manchester, United Kingdom) and 36 h later plated onto glass-bottom dishes coated with 15 nM LN. After 2 h of adhesion, cells were imaged using a CARV spinning disk head attached to a Leica DMIRB widefield microscope. All images were acquired using a 40x/1.3 oil immersion objective at 37°C. Images were acquired using separate Cy3 excitation and emission filter sets (Ludl, Hawthorne, NY) controlled by automatic excitation and emission wheels (Ludl) on an Orca ER charge-coupled device camera (Hammamatsu). Acquisition was performed using Andor IQ software (Andor, Belfast, Northern Ireland). Frames were acquired every 20 s over 20 min. Analysis of focal adhesion disassembly kinetics was performed in NIH ImageJ (http://rsb.info.nih.gov/ij/index.html). A background correction mask was applied to all frames within a single movie to highlight the RFP-positive structures. Adhesions either present at the beginning of filming period, or appearing during filming, were manually tracked through the entire time-lapse series until the time when they dissolved, i.e., when fluorescence intensity was no longer visible. The percentage of all adhesions that dissolved over time was calculated from tracking 12 cells in each population in three independent experiments. The mean time taken for adhesions to disappear in each cell line, in the absence or presence of doxycycline, was calculated from measuring the time to dissolution for adhesions from multiple cells. For each cell line, measurements were taken from 12 to 15 adhesions from five cells from three independent experiments.
Rac Activity Assay
Rac-GTP was quantified using the G-LISA Rac activation assay kit according to manufacturer's procedure (Cytoskeleton, Denver, CO). Lysates were prepared from IKD-F11 Fas+ and Fas– cells plated on 15 nM LN for 2 h, and from IKD-F11 Fas+ cells treated with 100 µM NSC23766 overnight. C2C12 cells in suspension or plated on 50 nM fibronectin (FN) for 15 min were used as controls for the method (Adams and Schwartz, 2000). Experiments were done in triplicate.
Gel Electrophoresis and Immunoblotting
Whole cell lysates were prepared in SDS-polyacrylamide gel electrophoresis sample buffer buffer (2% SDS, 10% glycerol, and 50 mM Tris-HCl, pH 6.8). Tumor extracts were prepared from frozen samples that were powdered with a pestle and mortar in liquid nitrogen, extracted in radioimmunoprecipitation assay buffer containing protease inhibitor cocktail, sonicated, and centrifuged. All samples were electrophoresed on 10% or 12.5% polyacrylamide gels under reducing conditions and transferred to polyvinylidene difluoride membranes (Millipore, Billerica, MA) by using a semidry transfer blot system. After blocking with Tris-buffered saline containing 1% Tween 20, 2% skim milk, and 0.5% bovine serum albumin for 1 h, the membranes were incubated with the primary antibodies (Table 1) and developed with alkaline phosphatase-conjugated secondary antibodies (Table 1) and enhanced chemiluminescence as described previously (Anilkumar et al., 2003). Quantitative analysis was performed using NIH ImageJ, version 1.38.
|
RESULTS |
|---|
|
TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
), and that have high endogenous fascin (Figure 1A), as suitable for fascin-knockdown experiments. To enable inducible knockdown of fascin transcripts, clonal derivatives of SW480 with stable expression of the TetR protein were developed (designated "parental", Pa or PaA; Figure 1B). Stable transfection of these lines with pSUPERIOR plasmid then provided tetracycline-inducible expression of a previously validated shRNA against human fascin-1 (Hashimoto et al., 2005b). Individual clones were tested for continued expression of fascin in the absence of the shRNA (Fascin+ condition) or with doxycycline induction of shRNA expression (Fascin– condition). Whereas SW480 and SW480-PaA cells maintained the same level of fascin protein irrespective of the addition of doxycycline, the inducible knockdown (IKD) subclones showed substantial and specific reduction of fascin. Several IKD subclones with >80% knockdown of fascin in the presence of doxycycline were chosen for further experiments (IKD-F11 and IKD-F12 in Figure 1B). Treatment with 0.1 µg/ml doxycycline for 48 h was sufficient to decrease fascin levels by 90% in IKD-F11 cells (Figure 1C). Inspection by indirect immunofluorescent staining for fascin demonstrated that fascin was present in the cell bodies, protrusions, and filopodial tips of IKD-F11 Fas+ cells and that the level of knockdown in IKD-F11 Fas– cells was uniform across the cell population (Figure 1D). After application of 1 µg/ml doxycycline for 48 h, knockdown of fascin was maintained for at least 120 h (Figure 1E).
|
|
), and direct counting of attached cells was not altered relative to IKD-F11 Fas+ cells or SW480 cells (data not shown). SW480 cells express multiple 
1 integrins and neither the cell-surface expression of integrin 1, 2, 3, or 6 subunits, nor the levels of -catenin and E-cadherin were changed upon fascin depletion (data not shown). Some, but not all, clinical studies have correlated fascin expression with the proliferative status of carcinomas (for review, see Hashimoto et al., 2005a). However, in soft agar growth assays, IKD-F11 and IKD-F12 Fas– cells proliferated indistinguishably from their Fas+ counterparts and SW480-Pa cells (Supplemental Table 1). Previously, fascin overexpression in fascin-negative SW1222 colon carcinoma cells was reported to increase cell proliferation. However, this result was obtained in a different experimental system of three-dimensional collagen gels that promote integrin-mediated glandular differentiation: these gels do not provide conditions for anchorage-independent growth (Jawhari et al., 2003). Because a major role of cell protrusions and filopodia is in cell migration, our subsequent analyses focused on cell migration properties. IKD-F11 Fas– cells had reduced transfilter migration activity (Figure 3A). Time-lapse imaging also revealed a significant decrease in haptokinetic migration on LN, both in terms of mean speed and the net migration (Figure 3, B and C). Migration of SW480-Pa cells was not altered in the absence or presence of doxycycline (data not shown). The mode of migration of Fas+ cells was complex in all lines, with cells becoming extended and spindly through extension of dynamic protrusions with filopodia and elongation of the tail region, followed by rapid rounding due to tail retraction, and then extension of new filopodia and protrusions in the direction of migration (Supplemental Movie 1). In contrast, Fas– cells either extended without release of the tail region, or extended and then retracted at the front edge, followed by extension at another point on the cell surface, such that the net displacement of cell bodies was decreased (Figure 3C and Supplemental Movie 2).
|
-actinin in the cell body cytoskeleton or vinculin in focal adhesions were not obviously altered (Supplemental Figure 1A). In contrast, the ventral surfaces of IKD-F11 Fas– cells contained denser areas of phosphotyrosine-containing adhesions (Supplemental Figure 1A). Immunoblotting of the profile of phosphotyrosine-containing proteins in LN-adherent SW480-Pa, IKD-F11, and IKD-F12 cells established that, in each line, the content of phosphotyrosine-containing proteins was unchanged in the absence or presence of doxycycline (Supplemental Figure 1B). Whereas levels of -actinin and vinculin were not altered in fascin IKD clones compared with SW480-Pa cells, the phosphotyrosine-containing protein paxillin was consistently elevated (Supplemental Figure 1C). However, paxillin levels were not altered in any cells upon fascin depletion (Supplemental Figure 1C), and we did not observe definite alterations in the paxillin staining of focal adhesions (data not shown). We conclude that the observed alterations in patterning of phosphotyrosine-containing adhesions under Fas– conditions relate to protein relocalization rather than a change in the abundance of phosphotyrosine-containing proteins.
Focal adhesions are transient structures that dynamically assemble and disassemble as cells migrate (Webb et al., 2003). To directly measure kinetic aspects of focal adhesions under control and fascin-depleted conditions, IKD-F11 cells maintained in the presence or absence of doxycycline were transfected with mRFP-paxillin. Cells were plated onto LN, and paxillin-containing focal adhesions were analyzed by fluorescence time-lapse microscopy (Figure 3D). IKD-F11 Fas– cells showed a significant reduction in focal adhesion disassembly. Only 5 ± 2% of the total focal adhesions per cell were disassembled during the 20-min filming period, compared with 52 ± 6% disassembled in Fas+ counterparts (Figure 3E and Supplemental Movies 3 and 4). This change in behavior was specific to fascin-depleted cells because SW480 and SW480Pa cells, which had lower endogenous paxillin than F11 cells, had near-identical percentages of focal adhesions disassembled to IKD-F11 Fas+ cells. Furthermore, the percentage of focal adhesions disassembling in SW480Pa cells was not significantly altered in the presence of doxycycline (Figure 3E). To measure rates of disassembly, the mean time taken for adhesions to disappear in each cell line, in the absence or presence of doxycycline, was calculated from measuring the time to dissolution for a number of adhesions from multiple cells. The mean time to dissolution was not significantly different between SW480Pa cells, in the absence or presence of doxycycline, or IKD-F11 Fas+ cells. However, it was significantly longer (mean of 18. 6 min vs. 9.2 min) in IKD-F11 Fas– cells (Figure 3F). These data identify a role for fascin in the control of focal adhesion disassembly dynamics.
Fascin Functions in a Rac-dependent Pathway in Colon Carcinoma Cell Migration
To gain insight into the molecular pathways by which fascin participates in carcinoma cell migration, we tested the effects of pharmacological inhibitors of signaling molecules that have generally significant roles in cytoskeletal reorganisations during cell migration. We reasoned that fascin-depleted cells would respond differently to inhibition of mediators that function upstream of fascin. Treatment of cells with bisindolylmalemide I (BIM), an inhibitor of conventional PKC isoforms, or Y27632, an inhibitor of Rho kinase, significantly inhibited migration speed to a similar extent in both IKD-F11 Fas+ and Fas– cells (Figure 4A). In contrast, the Rac inhibitor NSC23766 (Gao et al., 2004), significantly decreased the migration of IKD-F11 Fas+ cells yet did not inhibit migration of IKD-F11 Fas– cells (Figure 4A and Supplemental Movies 5 and 6). The migration of NSC23766-treated IKD-F11 Fas– cells was not significantly different from that of NSC23766-treated IKD-F11 Fas+ cells (Figure 4A, lane 4 vs. 8).
|
). Levels of Rac-GTP were equivalent in LN-adherent IKF-F11 Fas+ and Fas– cells. As expected, cells treated with NSC23766 had lower Rac activity (Figure 4C). Thus, the Rac independence of migration of IKD-F11 Fas– cells is not due to reduced levels of either Rac protein or Rac activity.
The Actin-bundling and PKC-binding Activities of Fascin Both Contribute to Its Role in Rac-dependent Carcinoma Cell Migration
To establish whether the known actin-bundling and active PKC-binding activities of fascin both contribute to its role in carcinoma cell protrusions and migration, we set up cDNA rescue expression of fascin with X. tropicalis fascin-1, that is not targeted by the shRNA. IKD-F11 cells were prepared that stably expressed either GFP, GFP-Xtfascin, GFP-XtfascinS33A, or GFP-XtfascinS33D. (The PKC phosphorylation motif is 100% conserved between human and Xenopus fascin-1, with the substrate serine at position 33 in Xenopus). On a cell population basis, the Xtfascin proteins were all expressed at similar levels that represented 35–42% of the content of endogenous fascin (Supplemental Figure 2). On induction of shRNA expression by doxycycline, the endogenous fascin protein level decreased to 
30% of control levels in all lines, whereas the Xtfascin proteins remained at 80–85% of their levels in control cells and thus constituted the major form of fascin in the cells (Supplemental Figure 2B). Whereas GFP-, GFP-Xtfascin–, or GFP-XtfascinS33A–expressing cells cultured in the absence of doxycycline and then adhered to LN had similar morphologies to each other and to SW480-Pa cells, many of the GFP-Xtfascin-S33D–expressing cells were rounded (Figure 5A, top row).
|
The distinctive morphologies of cells expressing either GFP-XtfascinS33A or GFP-XtfascinS33D as their major form of fascin suggested that both activities of fascin are normally required for carcinoma cell migration. Indeed, whereas GFP-Xtfascin–expressing cells migrated in a similar manner to cells containing endogenous fascin, GFP-XtfascinS33A–expressing cells tended to extend without retraction, forming very long, thin cell protrusions with tiny, dynamic lamellipodia at their tips (Supplemental Movie 7). GFP-XtfascinS33D–expressing cells remained attached and rounded over time, undergoing small, oscillatory movements (Supplemental Movie 8). Kymographic analysis also demonstrated that these cells formed very few membrane extensions (data not shown). In comparison to IKD-F11 Fas+ cells (Figure 3C), the net migration of GFP-XtfascinS33D cells was decreased and that of GFP-XtfascinS33A cells was somewhat increased (Figure 5C). The latter result was probably due to the increased overall length of the cells and their protrusions and did not reach statistical significance versus IKD-F11 Fas+ cells.
To investigate the requirement for active Rac in both activities of fascin, we examined the effect of pre-treatment with NSC23766 on GFP-XtfascinS33A or GFP-Xtfascin-S33D cells. Under these conditions, GFP-Xtfascin-S33A cells became even more extended and the actin organization in protrusive tips resembled that of IKD-F11 Fas+ cells. The majority of GFP-XtfascinS33D cells remained round (Figure 5A, bottom row). The residual net motility of both cell types was inhibited by NSC23766 (Figure 5C). Thus, both the actin-bundling and PKC-binding activities of fascin are on Rac-dependent pathways.
Wild-Type Fascin Contributes to Tumor Development and Metastasis
To investigate whether depletion of fascin alters tumor cell behavior in vivo, we compared the growth of subcutaneous xenografts of SW480-Pa and IKD-F11 cells in nude mice, in the absence or presence of doxycycline delivered in the drinking water. Whereas the growth of SW480-Pa tumors was not altered in the presence of doxycycline, the development of IKD-F11 tumors was strongly reduced in the presence of doxycycline, such that tumors had only reached a small volume after 32 d (Table 3a). Immunoblot analysis of tumor extracts demonstrated that fascin was effectively and specifically knocked down in the IKD-F11 tumors of mice that had received doxycycline (Figure 6A). Immunohistochemical staining confirmed that fascin protein was uniformly decreased throughout these tumors (Figure 6B). To examine the influence of fascin on metastatic capacity, we compared the development of liver and abdominal metastases from intrasplenically injected SW480Pa or IKD-F11 cells, in nude mice provided without or with doxycycline in their drinking water. The incidence of primary spleen tumors and metastatic tumors was specifically decreased for IKD-F11 cells in the doxycycline-treated mice (Table 3b) and the number of metastatic tumors per mouse was also significantly decreased (Figure 6C).
|
|
|
DISCUSSION |
|---|
|
TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
; Hashimoto et al., 2005b; Xie et al., 2005). Through shRNA depletion of fascin in colon carcinoma cells, and rescue with wild-type and mutant cDNAs, we have established that fascin contributes to the migration of human colon carcinoma cells in vitro and tumor development and metastasis in vivo. Mechanistically, we demonstrate that 1) fascin makes multiple specific contributions to carcinoma migration by impacting on the assembly of filopodia and associated protrusions and the disassembly of focal adhesions, 2) Rac acts as an upstream regulator of the activities of fascin in cell migration, and 3) both the actin-bundling and active PKC-binding activities of fascin are needed for fascin to promote tumor metastasis.
The observation that fascin-depletion leads to a stronger phenotype in transfilter chemotactic migration than in haptokinetic migration (Figure 3) is consistent with the hypothesis that fascin is required in localized spatial signaling for filopodia formation and directional migration. Previous experiments placed Rac as an upstream regulator of fascin-containing protrusions in skeletal myoblasts, but these experiments focused on the endpoint of lamellipodial assembly; also the active PKC-binding activity of fascin was not appreciated at this time (Adams and Schwartz, 2000). Rac is a well-established regulator of actin polymerization, and, via its substrate p21-activated kinase, activates Lim kinase to inactivate cofilin (Machesky and Hall, 1997; Hartwig et al., 1995; Yang et al., 1998). These mechanisms impact on the availability of F-actin, which is a prerequisite for F-actin bundling by fascin. More recent studies of normal skeletal myoblasts uncovered that phosphorylated fascin interacts with active PKC (Anilkumar et al., 2003). We demonstrate here that residual net migration in fascin-knockdown cells specifically rescued by expression of a phosphomimetic fascin mutant, GFP-XtfascinS33D, remained susceptible to Rac inhibition. This finding points to unsuspected complexity in the mechanisms by which Rac regulates fascin. The Rac pathway may be particularly suitable as a target to block fascin-dependent cell migration, because it regulates both activities of fascin.
Tractional forces exerted by integrin-based focal adhesions on the local ECM environment are important for the development of lamellipodial protrusions (Wang et al., 2001; Parker et al., 2002). At the molecular level, substratum adhesion is required for coupling of Rac to its effector p21-activated kinase, and, in cells lacking the focal adhesion protein vinculin, constitutively active Rac is not sufficient to rescue lamellipodia formation (del Pozo et al., 2000; Goldmann and Ingber, 2002). We uncovered here that fascin depletion resulted not only in alterations to cell protrusions and loss of filopodia but also in a slower rate of disassembly of focal adhesions. Fascin does not localize to focal adhesions; therefore, we propose that the slower disassembly of focal adhesions upon depletion of fascin is secondarily linked to the loss of filopodia through effects on the actin network in lamellipodia. It is well known that dynamic focal adhesion assembly and disassembly are needed for migration (Webb et al., 2003).
The complex phenotype of fascin-depleted cells suggests that coupling between focal adhesions and protrusions is a two-way process. Indeed, several molecular processes including the balance between Rac and Rho activities and microtubule targeting coordinately regulate protrusions and focal adhesions (Sander et al., 1999; Wittmann et al., 2003; Goldberg and Kloog, 2006). Although we did not observe alterations of the cell body actin cytoskeleton upon fascin depletion, effects on focal adhesions and thereby cell migration could also be a consequence of a lack of competition between fascin and tropomyosin for binding to contractile actomysin filaments (Ishikawa et al.,1998). It is highly likely that disruption of a key intracellular mechanical link would alter the forces exerted on focal adhesions by the actin cytoskeleton.
As discussed above, our data establish that reduced assembly of filopodia and protrusions, decreased focal adhesion disassembly, and decreased directional cell migration are all consequences of the acute depletion of fascin. The specificity of these effects was established by normalization of phenotype upon cDNA-based expression of GFP-Xtfascin in the knockdown cells (Figure 5). Furthermore, the strikingly different morphologies and migration behavior of cells reconstituted with either nonPKC-binding (GFP-XtfasS33A) or nonactin-bundling (GFP-XtfasS33D) fascin mutants clearly define that both forms of fascin are needed for its function in carcinoma cell protrusions and migration. Our novel data also indicate complexity in the underlying mechanisms: both the phosphorylated and nonphosphorylated forms of fascin act in Rac-dependent pathways.
Importantly, the xenograft tumor experiments revealed that fascin contributes both in the development of primary tumors and in their metastatic spread. The apparent discrepancy between the lack of effect of fascin-depletion on anchorage-independent growth and the clear effect on primary tumor development is not surprising in view that anchorage-independent growth is a good, but not perfect, model for tumorigenicity. In the context of a tumor, stromal-derived or vascular-derived factors provide additional contributions to regulate tumor cell proliferation, tumor vascularization, and the expansion and growth of the tumor. The in vitro anchorage independence colony growth assay does not recapitulate these features. Differing results for soft agar growth and tumor development in vivo have previously been reported for certain oncogenes (e.g., Kim et al., 2006). Thrombospondin-1 and -2 do not affect anchorage-independent growth yet strongly inhibit tumor development due to their antiangiogenic activities (Streit et al., 1999a,b).
We suggest that the reduced development of primary tumors by fascin-depleted cells could result from a reduced ability of the tumor to expand because of the reduced migratory capacity of the cells. Cell migration is of established significance in metastasis, and we demonstrated here that fascin-depleted cells gave rise to fewer metastases. In accordance with the cell culture migration data, neither GFP-XtfasS33D nor GFP-XtfasS33A fascin mutants rescued metastastic behavior of fascin-depleted cells to the extent that wild-type GFP-Xtfascin did. These data demonstrate the biological relevance of the mechanisms identified in cell culture and provide a rationale for considering fascin as a potential therapeutic target as well as a carcinoma biomarker. Putting together our findings with the previously published clinical correlations, the basis for the correlation between high fascin expression and poor prognosis of human carcinomas resides in a contribution of fascin in one or more steps of metastasis. Metastasis is a complex, multistage process in which cell migration is involved at many steps and different steps present greater or lesser obstacles to tumor cell dissemination (Steeg, 2006). It will be of future importance to identify the exact steps at which phosphorylated and nonphosphorylated fascin contributes to metastasis.
|
ACKNOWLEDGMENTS |
|---|
|
Footnotes |
|---|
The online version of this article contains supplemental material at MBC Online (http://www.molbiolcell.org). 
Address correspondence to: Josephine C. Adams (adamsj{at}ccf.org)
Abbreviations used: BIM, bisindolylmaleimide I; IKD, inducible knockdown; LN, laminin; mRFP, monomer red fluorescent protein; shRNA, short hairpin RNA; TetR, tetracycline repressor.
|
REFERENCES |
|---|
|
TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
|---|
Adams, J. C. (2004). Roles of fascin in cell adhesion and motility. Curr. Opin. Cell Biol 16, 590–596.[CrossRef][Medline]
Adams, J. C., Clelland, J. D., Collett, G. D., Matsumura, F., Yamashiro, S., and Zhang, L. (1999). Cell-matrix adhesions differentially regulate fascin phosphorylation. Mol. Biol. Cell 10, 4177–4190.
Adams, J. C., and Schwartz, M. A. (2000). Stimulation of fascin spikes by thrombospondin-1 is mediated by the GTPases Rac and Cdc42. J. Cell Biol 150, 807–822.
Akiyama, S. K., Yamada, S. S., Chen, W. T., and Yamada, K. M. (1989). Analysis of fibronectin receptor function with monoclonal antibodies: roles in cell adhesion, migration, matrix assembly, and cytoskeletal organization. J. Cell Biol 109, 863–875.
Anilkumar, N., Annis, D. A., Mosher, D. F., and Adams, J. C. (2002). Trimeric assembly of the C-terminal region of thrombospondin-1 or thrombospondin-2 is necessary for cell spreading and fascin spike organisation. J. Cell Sci 115, 2357–2366.
Anilkumar, N., Parsons, M., Monk, R., Ng, T., and Adams, J. C. (2003). Interaction of fascin and protein kinase Calpha: a novel intersection in cell adhesion and motility. EMBO J 22, 5390–5402.[CrossRef][Medline]
Carragher, N. O., and Frame, M. C. (2004). Focal adhesion and actin dynamics: a place where kinases and proteases meet to promote invasion. Trends Cell Biol 14, 241–249.[CrossRef][Medline]
Christofori, G. (2006). New signals from the invasive front. Nature 441, 444–450.[CrossRef][Medline]
Cohan, C. S., Welnhofer, E. A., Zhao, L., Matsumura, F., and Yamashiro, S. (2001). Role of the actin bundling protein fascin in growth cone morphogenesis: localization in filopodia and lamellipodia. Cell Motil. Cytoskeleton 48, 109–120.[CrossRef][Medline]
Condeelis, J., Singer, R. H., and Segall, J. E. (2005). The great escape: when cancer cells hijack the genes for chemotaxis and motility. Annu. Rev. Cell. Dev. Biol 21, 695–718.[CrossRef][Medline]
Costantini, R. M., Falcioni, R., Battista, R., Zupi, G., Kennel, S. J., Colasante, A., Venturo, I., Curcio, C. G., and Sacchi, A. (1990). Integrin (6/4) expression in human lung cancer as monitored by specific monoclonal antibodies. Cancer Res 50, 6107–6112.
del Pozo, M. A., Price, L. S., Alderson, N. B., Ren, X. D., and Schwartz, M. A. (2000). Adhesion to the extracellular matrix regulates the coupling of the small GTPase Rac to its effector PAK. EMBO J 19, 2008–2014.[CrossRef][Medline]
Friedl, P., and Wolf, K. (2003). Tumour-cell invasion and migration: diversity and escape mechanisms. Nat. Rev. Cancer 3, 362–374.[CrossRef][Medline]
Gao, Y., Dickerson, J. B., Guo, F., Zheng, J., and Zheng, Y. (2004). Rational design and characterization of a Rac GTPase-specific small molecule inhibitor. Proc. Natl. Acad. Sci. USA 101, 7618–7623.
Gilchrist, M. J., Zorn, A. M., Voigt, J., Smith, J. C., Papalopulu, N., and Amaya, E. (2004). Defining a large set of full-length clones from a Xenopus tropicalis EST project. Dev. Biol 271, 498–516.[CrossRef][Medline]
Goldberg, L., and Kloog, Y. (2006). A Ras inhibitor tilts the balance between Rac and Rho and blocks phosphatidylinositol 3-kinase-dependent glioblastoma cell migration. Cancer Res 66, 11709–11717.
Goldmann, W. H., and Ingber, D. E. (2002). Intact vinculin protein is required for control of cell shape, cell mechanics, and rac-dependent lamellipodia formation. Biochem. Biophys. Res. Commun 290, 749–755.[CrossRef][Medline]
Guo, W., and Giancotti, F. G. (2004). Integrin signalling during tumour progression. Nat. Rev. Mol. Cell Biol 5, 816–826.[CrossRef][Medline]
Hartwig, J. H., Bokoch, G. M., Carpenter, C. L., Janmey, P. A., Taylor, A. L., Toker, A., and Stossel, T. P. (1995). Thrombin receptor ligation and activated Rac uncap actin filament barbed ends through phosphoinositide synthesis in permeabilised human platelets. Cell 82, 643–653.[CrossRef][Medline]
Hashimoto, Y., Shimada, Y., Kawamura, J., Yamasaki, S., and Imamura, M. (2004). The prognostic relevance of fascin expression in human gastric carcinoma. Oncology 67, 262–270.[CrossRef][Medline]
Hashimoto, Y., Skacel, M., and Adams, J. C. (2005a). Roles of fascin in human carcinoma motility and signaling: prospects for a novel biomarker? Int. J. Biochem. Cell Biol 37, 1787–1804.[CrossRef][Medline]
Hashimoto, Y., Ito, T., Inoue, H., Okumura, T., Tanaka, E., Tsunoda, S., Higashiyama, M., Watanabe, G., Imamura, M., and Shimada, Y. (2005b). Prognostic significance of fascin overexpression in human esophageal squamous cell carcinoma. Clin. Cancer Res 11, 2597–2605.
Hashimoto, Y., Skacel, M., Lavery, I. C., Mukherjee, A. L., Casey, G., and Adams, J. C. (2006). Prognostic significance of fascin expression in advanced colorectal cancer: an immunohistochemical study of colorectal adenomas and adenocarcinomas. BMC Cancer 6, 241.[CrossRef][Medline]
Haviv, L., Brill-Karniely, Y., Mahaffy, R., Backouche, F., Ben-Shaul, A., Pollard, T.D., and Bernheim-Groswasser, A. (2006). Reconstitution of the transition from lamellipodium to filopodium in a membrane-free system. Proc. Natl. Acad. Sci. USA 103, 4906–4911.
Ishikawa, R., Yamashiro, S., Kohama, K., and Matsumura, F. (1998). Regulation of actin binding and actin bundling activities of fascin by caldesmon coupled with tropomyosin. J. Biol. Chem 273, 26991–26997.
Jawhari, A. U., Buda, A., Jenkins, M., Shehzad, K., Sarraf, C., Noda, M., Farthing, M. J., Pignatelli, M., and Adams, J. C. (2003). Fascin, an actin-bundling protein, modulates colonic epithelial cell invasiveness and differentiation in vitro. Am. J. Pathol 162, 69–80.
Kim, S. H., Nakagawa, H., Navaraj, A., Naomoto, Y., Klein-Szanto, A. J., Rustgi, A. K., and El-Deiry, W. S. (2006). Tumorigenic conversion of primary human esophageal epithelial cells using oncogene combinations in the absence of exogenous Ras. Cancer Res 66, 10415–10424.
Kyriazis, A. P., DiPersio, L., Michael, G. J., Pesce, A. J., and Stinnett, J. D. (1978). Growth patterns and metastatic behavior of human tumors growing in athymic mice. Cancer. Res 38, 3186–3190.
Machesky, L. M., and Hall, A. (1997). Role of actin polymerization and adhesion to extracellular matrix in Rac- and Rho-induced cytoskeletal reorganization. J. Cell Biol 138, 913–926.
Maitra, A. et al. (2002). Immunohistochemical validation of a novel epithelial and a novel stromal marker of pancreatic ductal adenocarcinoma identified by global expression microarrays: sea urchin fascin homolog and heat shock protein 47. Am. J. Clin. Pathol 118, 52–59.[CrossRef][Medline]
Minn, A. J., Gupta, G. P., Siegel, P. M., Bos, P. D., Shu, W., Giri, D. D., Viale, A., Olshen, A. B., Gerald, W. L., and Massague, J. (2005). Genes that mediate breast cancer metastasis to lung. Nature 436, 518–524.[CrossRef][Medline]
Ono, S., Yamakita, Y., Yamashiro, S., Matsudaira, P. T., Gnarra, J. R., Obinata, T., and Matsumura, F. (1997). Identification of an actin binding region and a protein kinase C phosphorylation site on human fascin. J. Biol. Chem 272, 2527–2533.
Parker, K. K., Brock, A. L., Brangwynne, C., Mannix, R. J., Wang, N., Ostuni, E., Geisse, N. A., Adams, J. C., Whitesides, G. M., and Ingber, D. E. (2002). Directional control of lamellipodia extension by constraining cell shape and orienting cell tractional forces. FASEB J 16, 1195–1204.
Pelosi, G. et al. (2003). Independent prognostic value of fascin immunoreactivity in stage I nonsmall cell lung cancer. Br. J. Cancer 88, 537–547.[CrossRef][Medline]
Puppa, G. et al. (2007). Independent prognostic value of fascin immunoreactivity in stage III-IV colonic adenocarcinoma. Br J. Cancer 96, 1118–1126.[CrossRef][Medline]
Sander, E. E., ten Klooster, J. P., van Delft, S., van der Kammen, R. A., and Collard, J. G. (1999). Rac downregulates Rho activity: reciprocal balance between both GTPases determines cellular morphology and migratory behavior. J. Cell Biol 147, 1009–1022.
Staquet, M. J., Dezutter-Dambuyant, C., Schmitt, D., Amiot, M., Boumsell, L., and Thivolet, J. (1989). A surface glycoprotein complex related to the adhesive receptors of the VLA family, shared by epidermal Langerhans cells and basal keratinocytes. J. Invest. Dermatol 92, 739–745.[CrossRef][Medline]
Steeg, P. S. (2006). Tumor metastasis: mechanistic insights and clinical challenges. Nat. Med 12, 895–904.[CrossRef][Medline]
Streit, M., Velasco, P., Brown, L. F., Skobe, M., Richard, L., Riccardi, L., Lawler, J., and Detmar, M. (1999a). Overexpression of thrombospondin-1 decreases angiogenesis and inhibits the growth of human cutaneous squamous cell carcinoma. Am. J. Pathol 155, 441–452.
Streit, M., Riccardi, L., Velasco, P., Brown, L. F., Hawighorst, T., Bornstein, P., and Detmar, M. (1999b). Thrombospondin-2, a potent enogenous inhibitor of tumour growth and angiogenesis. Proc. Natl. Acad. Sci. USA 96, 14888–14893.
Svitkina, T. M., Bulanova, E. A., Chaga, O. Y., Vignjevic, D. M., Kojima, S., Vasiliev, J. M., and Borisy, G. G. (2003). Mechanism of filopodia initiation by reorganization of a dendritic network. J. Cell Biol 160, 409–421.
Tenchini, M. L., Adams, J.C., Gilberty, C., Steel, J., Hudson, D. L., Malcovati, M., and Watt, F. M. (1993). Evidence against a major role for integrins in calcium-dependent intercellular adhesion of epidermal keratinocytes. Cell Adhes. Commun 1, 55–66.[Medline]
van't Veer, L. J. et al. (2002). Gene expression profiling predicts clinical outcome of breast cancer. Nature 415, 530–536.
