CD44 Interaction with c-Src Kinase Promotes Cortactin-mediated Cytoskeleton Function and Hyaluronic Acid-dependent Ovarian Tumor Cell Migration*

Lilly Y. W. BourguignonDagger, Hongbo Zhu, Lijune Shao, and Yue-Wei Chen

From the Department of Cell Biology and Anatomy, School of Medicine, University of Miami, Miami, Florida 33101

Received for publication, July 20, 2000, and in revised form, November 15, 2000



    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In this study we have demonstrated that both CD44 (the hyaluronan (HA) receptor) and c-Src kinase are expressed in human ovarian tumor cells (SK-OV-3.ipl cell line), and that these two proteins are physically associated as a complex in vivo. Using a recombinant cytoplasmic domain of CD44 and an in vitro binding assay, we have detected a specific interaction between CD44 and c-Src kinase. Furthermore, the binding of HA to SK-OV-3.ipl cells promotes c-Src kinase recruitment to CD44 and stimulates c-Src kinase activity, which, in turn, increases tyrosine phosphorylation of the cytoskeletal protein, cortactin. Subsequently, tyrosine phosphorylation of cortactin attenuates its ability to cross-link filamentous actin in vitro. In addition, transfection of SK-OV-3.ipl cells with a dominant active form of c-Src (Y527F)cDNA promotes CD44 and c-Src association with cortactin in membrane projections, and stimulates HA-dependent/CD44-specific ovarian tumor cell migration. Finally, overexpression of a dominant-negative mutant of c-Src kinase (K295R) in SK-OV-3.ipl cells impairs the tumor cell-specific phenotype. Taken together, these findings strongly suggest that CD44 interaction with c-Src kinase plays a pivotal role in initiating cortactin-regulated cytoskeleton function and HA-dependent tumor cell migration, which may be required for human ovarian cancer progression.



    INTRODUCTION
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The cell adhesion molecule, CD44, is one of the major hyaluronic acid (HA)1 receptors (1-3). It belongs to a family of transmembrane glycoproteins which contain a variable extracellular domain, a single spanning 23-amino acid transmembrane domain, and a 70-amino acid cytoplasmic domain (4). Nucleotide sequence analyses reveal that many CD44 isoforms (derived from alternative splicing mechanisms) are variants of the standard form, CD44s (4). CD44s (molecular mass ~85 kDa) is the most common isoform of CD44 found in many cell types including human ovarian carcinoma cells (5-9). The presence of high levels of CD44s (often together with CD44v) is emerging as an important metastatic tumor marker in a number of carcinomas, and is also implicated in the unfavorable prognosis of a variety of cancers including human ovarian cancers (5-9).

The invasive phenotype of CD44s-positive epithelial tumor cells has been linked to HA-mediated CD44 signaling and cytoskeletal activation. CD44s contains several HA-binding sites in their extracellular domain (1-3). The binding of HA to CD44s causes cells to adhere to the extracellular matrix (ECM) components (1-3), and has also been implicated in the stimulation of several different biological activities (10-16). The intracellular domain of CD44 binds to signaling proteins such as RhoGTPases (e.g. RhoA) (17); Tiam1, a guanine nucleotide exchange factor for Rac1 (18); and cytoskeletal proteins, including ankyrin (2, 3, 9, 17-21) and the ERM proteins (ezrin, radixin, and moesin) (23). Recent studies indicate that the binding of ECM components (e.g. HA) promote CD44-mediated Tiam1-Rac1 signaling and cytoskeleton function leading to specific structural changes in the plasma membrane and tumor cell migration in metastatic tumor cells (18). These findings strongly suggest that the CD44 molecule provides a direct linkage between the ECM and the cytoskeleton. In particular, the coordinated oncogenic signaling processes contributed by HA-dependent and CD44-mediated cytoskeleton activation is considered to be a possible mechanism underlying tumor cell motility and migration: an obvious prerequisite for metastasis.

The Src family kinases are classified as oncogenic proteins due to their ability to activate cell proliferation (24, 25), spreading (26, 27), and migration (27-30) in many cell types including epithelial tumor cells (30). The amino terminus of Src contains a myristoylation (or palmitoylation) site, which is important for membrane association (31, 32). Src also contains several functional domains including Src homology (SH) 3 and SH2 domains, the catalytic protein-tyrosine kinase core, and a conserved regulatory tyrosine phosphorylation site (31, 32). Certain amino acid residues in the c-Src molecule play an important role in modulating its kinase activity. Mutations of specific key amino acids result in either up-regulation or down-regulation of c-Src kinase activity. For example, replacement of tyrosine 527 with phenylalanine (e.g. Y527F, the dominant-active form of c-Src kinase) strongly activates c-Src kinase tranforming capability and enzyme activities (33). Mutation of lysine 295 to arginine (e.g. K295R, the dominant-negative form of c-Src kinase) renders c-Src kinase defective and reduces c-Src kinase-mediated biological activities (33, 34).

In addition, it has been observed that the interaction between Src kinase and membrane-linked molecules regulates receptor signaling and various cellular functions (31, 32). In fact, CD44s-mediated cellular signaling has been suggested to involve Src kinase family members (35). For example, Lck, one of the Src kinase family members, is found to be closely complexed with CD44s during T-cell activation (35). CD44 also selectively associates with active Src family tyrosine kinases (e.g. Lck and Fyn) in glycosphingolipid-rich plasma membrane domains of human peripheral blood lymphocytes (36). Moreover, the cytoplasmic domain of CD44s has been shown to be involved in the recruitment of the Src family (e.g. Src, Yes, and Fyn) in prostate tumor cells during anchorage-independent colony growth (20). Collectively, all these observations support the notion that c-Src kinases participate in CD44-mediated cellular signaling.

The questions of (i) whether CD44s-mediated c-Src kinase signaling plays a direct role in regulating ovarian tumor cell activation and (ii) which cytoskeletal protein(s) is (are) most likely involved in CD44-c-Src kinase-regulated downstream effector function leading to human ovarian cell migration are specifically addressed in this study. We have determined that CD44s (the standard form) and c-Src kinase are physically linked and functionally coupled in human ovarian tumor cells (SK-OV-3.ipl cell line). Furthermore, our data show that the cytoplasmic domain of CD44s is important for the association with c-Src kinase. HA treatment of ovarian tumor cells recruits c-Src kinase to CD44s and activates c-Src kinase activity. We have also demonstrated that c-Src kinase phosphorylates the cytoskeletal protein cortactin both in vivo and in vitro. Most importantly, cortactin phosphorylation by c-Src kinase attenuates its cross-linking ability of filamentous actin. Overexpression of a dominant-active form of c-Src kinase, by transfecting SK-OV-3.ipl cells with c-Src (Y527F)cDNA in these ovarian tumor cells, promotes the onset of CD44s/c-Src kinase-regulated cortactin function and tumor cell migration. Transfection of SK-OV-3.ipl cells with a dominant-negative mutant of c-Src kinase (K295R-kinase dead) effectively blocks the tumor cell-specific phenotype. Therefore, we believe that CD44-activated c-Src kinase signaling is directly involved in stimulating cortactin-cytoskeleton interaction and HA-mediated tumor cell migration during the progression of human ovarian cancer.


    MATERIALS AND METHODS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cell Lines and Culture-- The SK-OV-3.ipl cell line was established from ascites that developed in a nu/nu mouse given an intraperitoneal injection of SK-OV-3 human ovarian carcinoma cell line (obtained from the American Type Culture Collection) as described previously (37). Cells were grown in Dulbecco's modified Eagle's medium/F-12 medium supplement (Life Technologies, Inc.) supplemented with 10% fetal bovine serum.

Immunoreagents-- Monoclonal rat anti-CD44 antibody (clone 020; isotype IgG2b; obtained from CMB-TECH, Inc., Miami, FL) used in this study recognizes the standard form of CD44 (CD44s). Monoclonal mouse anti-phosphotyrosine antibody (PY-plusTM; clone PY20; IgG2b) was purchased from Zymed Laboratories Inc. (South San Francisco, CA). Rabbit polyclonal antibody against human c-Src kinase (recognizing a peptide sequence corresponding to amino acids 509-533 at the carboxyl terminus of human c-Src p60) and rabbit anti-Src (Tyr(P)418) phosphospecific antibody were obtained from Santa Cruz Biotechnology (Santa Cruz, CA) and BIOSOURCE International (Camarillo, CA), respectively. Mouse monoclonal anti-green fluorescent protein (GFP) antibody and mouse monoclonal anti-cortactin antibody (clone 4F11) were purchased from PharMingen (San Diego, CA) and Upstate Biotechnology Inc. (Lake Placid, NY), respectively.

Cloning, Expression, and Purification of CD44 Cytoplasmic Domain (CD44cyt) from Escherichia coli-- The procedure for preparing the fusion protein of CD44's cytoplasmic domain was the same as described previously (9, 17).

Expression Constructs-- The c-Src (Y527F) mutant or the c-Src (K295R) mutant cDNAs (kindly provided by Dr. David Shalloway (Cornell University, Ithaca, NY) was cloned into pEGFPN1 vector (CLONTECH) using PCR-based cloning strategy. Specifically, c-Src (Y527F) mutant cDNA or c-Src (K295R) mutant cDNA was amplified by PCR with two specific primers (left, 5'-GCCTCGAGATGGGGAGCAGCAAGAGCAAG-3'; right, 5'-GCAAGCTTTAGGTTCTCTCCAGGCTGGTA-3') linked with a specific enzyme digestion site (XhoI or HindIII). PCR product digested with XhoI and HindIII was purified with QIAquick PCR purification kit (Quagen). The cDNA was cloned into pEGFPN1 vector digested with XhoI and HindIII. Subsequently, both c-Src (Y527F) mutant cDNA and c-Src (K295R) mutant cDNA sequences were confirmed by nucleotide sequencing analyses.

Cell Transfection-- To establish a transient expression system, SK-OV-3.ipl cells were transfected with various plasmid DNAs (e.g. GFP-tagged c-Src (Y527F) or GFP-c-Src (K295R) or vector alone) using electroporation methods according to those procedures described previously (38). Various transfectants were then analyzed for their protein expression (e.g. c-Src-related proteins) by immunoblot, c-Src kinase activity, and tumor cell migration assays as described below.

In Vitro Binding of c-Src Recombinant Protein to CD44-- Purified constitutively activated c-Src kinase recombinant protein (39) was first bound to anti-c-Src kinase-conjugated immunoaffinity beads. Subsequently, aliquots (10-20 ng of proteins) of these beads were incubated with 0.5 ml of a binding buffer (20 mM Tris-HCl (pH 7.4), 150 mM NaCl, 0.1% bovine serum albumin, and 0.05% Triton X-100) in the presence of various concentrations (10-400 ng/ml) of 125I-labeled FLAG-CD44cyt fusion protein (5,000 cpm/ng protein) at 4 °C for 5 h. Specifically, equilibrium binding conditions were determined by performing a time course (1-10 h) of 125I-labeled FLAG-CD44cyt binding to c-Src kinase at 4 °C. The binding equilibrium was found to be established when the in vitro CD44-c-Src kinase binding assay was conducted at 4 °C after 4 h. Following binding, beads were washed extensively in the binding buffer and the bead-bound radioactivity was counted.

As a control, 125I-labeled FLAG-CD44cyt fusion protein was also incubated with uncoated beads to determine the binding observed due to the nonspecific binding of the ligand. Nonspecific binding, which represented ~15-20% of the total binding, was always subtracted from the total binding. The values expressed under "Results" represent an average of triplicate determinations of three to five experiments with S.D. less than ±5%.

Immunoprecipitation and Immunoblotting Techniques-- SK-OV-3.ipl cells were solubilized in 50 mM Tris-HCl (pH 7.4), 150 mM NaCl, 1% Triton X-100 buffer and immunoprecipitated using rat anti-CD44s antibody or rabbit anti-c-Src kinase antibody followed by goat anti- rat IgG or goat anti-rabbit IgG, respectively. The immunoprecipitated material was solubilized in SDS sample buffer, electrophoresed, and immunoblotted with rabbit anti-c-Src kinase antibody (5 µg/ml) or rat anti-CD44s antibody (5 µg/ml), followed by incubation with horseradish peroxidase-conjugated goat anti-rabbit IgG or goat anti-rat IgG (1:10,000 dilution) at room temperature for 1 h. The blots were developed using ECL chemiluminescence reagent (Amersham Pharmacia Biotech) according to the manufacturer's instructions.

Cell lysates were also prepared from SK-OV-3.ipl cells treated with HA at various concentrations (e.g. 0, 5, 10, 25, 50, and 100 µg/ml) for various time intervals (e.g. 0, 2, 5, 10, 15, 20, 30, and 60 min) and immunoprecipitated with anti-CD44s IgG to isolate CD44s-c-Src kinase complex (as described above). Immunoprecipitates were immunoblotted with either anti-Src (Tyr(P)418) (5 µg/ml) or anti-c-Src kinase (5 µg/ml). In some cases, SK-OV-3.ipl cells (treated with HA (50 µg/ml) for 10-60 min in the absence or the presence of PP2, an inhibitor for c-Src family kinases (purchased form Calbiochem-Novabiochem, San Diego, CA); or untreated) were solubilized in 50 mM Tris-HCl (pH 7.4), 150 mM NaCl, 1% Triton X-100 buffer. These materials were then immunoprecipitated by mouse anti-cortactin, followed by immunoblotting with mouse anti-phosphotyrosine antibody/or reblotting with mouse anti-cortactin plus peroxidase-conjugated goat anti-mouse IgG and ECL chemiluminescence reagent.

In some experiments, SK-OV-3.ipl cells (e.g. untransfected or transfected by GFP-tagged c-Src (Y527F)cDNA or GFP-tagged c-Src (K295R)cDNA or vector alone) were treated with HA (50 µg/ml) for 10-60 min. Cell lysates of these transfectants were immunoprecipitated by rat anti-CD44s antibody (5 µg/ml). The anti-CD44s-mediated immunoprecipitated material was then immunoblotted with mouse anti-GFP antibody (5 µg/ml) for 1 h at room temperature. Some cell lysate was either immunoblotted with mouse anti-GFP antibody (5 µg/ml) or immunoprecipitated with mouse anti-GFP antibody (5 µg/ml), followed by immunoblotting with rabbit anti-c-Src antibody (5 µg/ml). In some cases, the cell lysate of these cells was immunoprecipitated by mouse anti-cortactin (5 µg/ml), followed by immunoblotting with mouse anti-phosphotyrosine antibody/reblotting with mouse anti-cortactin antibody plus horseradish peroxidase-conjugated goat anti-mouse IgG (1:10,000 dilution) and ECL chemiluminescence reagent.

Immunofluorescence Staining-- SK-OV-3.ipl cells (untransfected or transfected with various plasmid DNAs such as GFP-tagged c-Src (Y527F)cDNA or GFP-tagged c-Src (K295R)cDNA or vector alone) were first washed with PBS (0.1 M phosphate buffer (pH 7.5) and 150 mM NaCl) buffer and fixed by 2% paraformaldehyde. Subsequently, untransfected/vector-transfected cells or GFP-tagged SK-OV-3.ipl transfectants were stained with Texas Red-labeled or cyanine (Cy5)-labeled rat anti-CD44s antibody. In some cases, GFP-tagged and cyanine-labeled cells were then rendered permeable by ethanol treatment, followed by incubating with Texas Red-conjugated mouse anti-cortactin IgG. To detect nonspecific antibody binding, cyanine-CD44s labeled cells were incubated with Texas Red-conjugated normal mouse IgG. No labeling was observed in such control samples. These labeled samples were examined with a confocal laser scanning microscope (MultiProbe 2001 Inverted CLSM system, Molecular Dynamics, Sunnyvale, CA). Cells displaying membrane projections were counted under the microscope. Specifically, every cell in the field was examined for the occurrence of the cell phenotypes (e.g. with or without membrane projections). At least 200-300 cells (in 12 different fields) were examined in each sample. Quantitative values describing the percentage of cells displaying membrane projections in each sample were expressed as "percentage of total cells."

Tumor Cell Migration Assays-- Twenty-four transwell units were used for monitoring in vitro cell migration as described previously (9, 17, 18, 21). Specifically, the 5-µm porosity polycarbonate filters (CoStar Corp., Cambridge, MA) were used for the cell migration assay. SK-OV-3.ipl cells (untransfected or transfected with GFP-tagged c-Src (Y527F)cDNA or GFP-tagged c-Src (K295R)cDNA or vector alone) (~1 × 104 cells/well) were placed in the upper chamber of the transwell unit. The growth medium containing high glucose DMEM supplemented with 200 µg/ml hyaluronic acid was placed in the lower chamber of the transwell unit. After 18 h of incubation at 37 °C in a humidified 95% air, 5% CO2 atmosphere, vital stain MTT (Sigma) was added at a final concentration of 0.2 mg/ml to both the upper and the lower chambers and incubated for additional 4 h at 37 °C. Migrative cells at the lower part of the filter were removed by swabbing with small pieces of Whatman filter paper. Both the polycarbonate filter and the Whatman paper were placed in dimethyl sulfoxide to solubilize the crystal. Color intensity was measured in 450 nm.

Cell migration processes were determined by measuring the cells that migrate from then upper chambers to the lower side of the polycarbonate filters by standard cell number counting methods as described previously (9, 17, 18, 21). The CD44-specific cell migration was determined by subtracting nonspecific cell migration (i.e. cells migrate to the lower chamber in the presence of anti-CD44s antibody treatment) from the total migrative cells in the lower chamber. The CD44-specific cell migration in vector-transfected cells (control) is designated as 100%. Each assay was set up in triplicate and repeated at least three times. All data were analyzed statistically using Student's t test, and statistical significance was set at p < 0.01.

In Vitro c-Src Kinase Assay-- An in vitro c-Src kinase assay using enolase as a substrate was performed as described previously (40). Briefly, lysates from SK-OV-3.ipl cells (treated with HA (50 µg/ml) for 10-60 min; or pretreated with anti-CD44 followed by HA (50 µg/ml) treatment for 10-60 min; or untreated) were prepared and processed for anti-CD44-mediated or anti-c-Src kinase-mediated immunoprecipitation to obtain the CD44s-c-Src kinase complexes. For assaying c-Src kinase activity, CD44s-c-Src kinase complexes were incubated with 10 µl of reaction buffer (20 mM PIPES (pH 7.0), 10 mM MnCl2, 10 µM Na3VO4)), 1 µl of freshly prepared acid-denatured enolase (Sigma) (5 µg of enolase plus 1 µl of 50 mM HCl incubated at 30 °C for 10 min and then neutralized with 1 µl of 1 M PIPES (pH 7.0)), and 20 mM ATP. After 10 min of incubation at 30 °C, reactions were terminated by adding 2× SDS sample buffer. Samples were then electrophoresed and immunoblotted with mouse anti-phosphotyrosine antibody plus horseradish peroxidase-conjugated goat anti-mouse IgG and ECL chemiluminescence reagent.

Phosphorylation of Cortactin by Endogenous c-Src, c-Src (Y527F)/c-Src (K295R) in Vitro-- Untransfected SK-OV-3.ipl cells and various transfectants were treated with HA (50 µg/ml) for various time intervals (0, 2, 5, 10, 15, 20, 30, and 60 min). At each time point, 100 mM c-Src-related proteins (isolated from HA-treated untransfected cells using anti-c-Src-conjugated immunoaffinity beads, or SK-OV-3.ipl cells transfected with either c-Src (Y527F) or c-Src (K295R) or vector alone using anti-GFP-conjugated Sepharose beads) were incubated with 20 µl of the reaction buffer (20 mM PIPES (pH 7.0), 10 mM MnCl2, 10 µM Na3VO4)), 1 µl of recombinant cortactin (a gift from Dr. Alan Mak, Queen's University, Kingston, Ontario, Canada) (5 µg of cortactin dissolved in 2 µl of 1 M PIPES (pH 7.0)), and 10 µCi of [gamma -32P]ATP (5000 Ci/mmol) at 30 °C for 1 h. To quantitate phosphorylated cortactin, aliquots of the reactions were analyzed by SDS-PAGE. The radioactivity associated with GFP-tagged cortactin band was analyzed by autoradiograms quantitated by a PhosphorImager (Molecular Dynamics, Sunnyvale, CA) or scintillating counting methods.

F-actin Cross-linking Assay-- The procedures for conducting F-actin cross-linking experiments were the same as those described previously (41, 42) with some modifications. Unphosphorylated or c-Src kinase phosphorylated recombinant cortactin (as described above) (50-100 nM) in 50 µl of TKM buffer (50 mM Tris-HCl (pH7.4), 134 mM KCl, and 1 mM MgCl2) was mixed with an equal volume of 8 µM 125I-labeled F-actin followed by a 30-min incubation at room temperature. Subsequently, the mixture was centrifuged at 25,000 × g for 10 min at room temperature. The supernatant was then collected, and the radioactivity in this fraction was counted. The decrease (or loss) of radioactivity in the supernatant fraction reflects F-actin precipitation due to the cross-linking reaction (41, 42). The F-actin cross-linking reaction in the presence of unphosphorylated cortactin (treated with a control protein isolated from untransfected cells using anti-GFP conjugated Sepharose beads) (control) is designated as 100%. Each assay was set up in triplicate and repeated at least three times. All data were analyzed statistically using Student's t test, and statistical significance was set at p < 0.01.


    RESULTS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Physical Association between CD44s (the Standard Form) and c-Src Kinase in Human Ovarian Tumor Cells-- CD44 family of transmembrane glycoproteins have been implicated in multiple oncogenic signaling pathways during tumor progression of various human cancers (2, 3, 9, 17, 18, 20). One of the CD44 signaling-related regulatory molecules is the Src family kinases (20, 35, 36). The question of whether the Src family kinases also participate in CD44-linked ovarian tumor cell-specific function is addressed in this study.

Immunoblotting with anti-CD44 antibody (recognizing an epitope located at the NH2-terminal region of CD44s (the standard form)) indicates that a single CD44s protein (mass ~ 85 kDa) is expressed in the human ovarian tumor cell line, SK-OV-3.ipl (Fig. 1, lane 1). In addition, we have used anti-c-Src kinase antibody-mediated immunoblot to detect the expression of c-Src kinase as a single polypeptide (mass ~ 60 kDa) (Fig. 1, lane 2) in SK-OV-3.ipl cells (Fig. 1, lane 2). Both CD44s and c-Src kinase detected in SK-OV-3.ipl cells by anti-CD44s and anti-c-Src kinase-mediated immunoblot is specific since no protein is detected in these cells using preimmune rat IgG or rabbit IgG, respectively (Fig. 1, lanes 5 and 6).



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Fig. 1.   Detection of CD44s and c-Src kinase complex in SK-OV-3.ipl cells. SK-OV-3.ipl cells (5 × 105 cells) were solubilized by 1% Nonidet P-40 buffer followed by immunoprecipitation and/or immunoblot by anti-CD44s antibody or anti-c-Src kinase antibody, respectively as described under "Experimental Procedures." Lane 1, detection of CD44s with rat anti-CD44s-mediated immunoblot of SK-OV-3.ipl cells. Lane 2, detection of c-Src kinase with rabbit anti-c-Src kinase-mediated immunoblot of SK-OV-3.ipl cells. Lane 3, detection of c-Src kinase in the complex by anti-CD44s-immunoprecipitation followed by immunoblotting with anti-c-Src kinase antibody. Lane 4, detection of CD44s in the complex by anti-c-Src kinase-mediated immunoprecipitation followed by immunoblotting with anti-CD44s antibody. Lane 5, immunoblot of SK-OV-3.ipl cells with preimmune rat IgG. Lane 6, immunoblot of SK-OV-3.ipl cells with preimmune rabbit IgG.

We then addressed the question of whether there is a physical linkage between CD44s and c-Src kinase in human ovarian tumor cells. First, we carried out anti-CD44s-mediated and anti-c-Src kinase-mediated precipitation followed by anti-c-Src kinase immunoblot (Fig. 1, lane 3) or anti-anti-CD44s immunoblot (Fig. 1, lane 4), respectively. Our results indicate that the c-Src kinase band is revealed in anti-CD44s-immunoprecipitated materials (Fig. 1, lane 3), and the CD44s band is detected in the anti-c-Src kinase-immunoprecipitated materials (Fig. 1, lane 4). These findings establish the fact that CD44s and c-Src kinase are closely associated with each other in ovarian tumor cells.

We have also used purified, FLAG-tagged cytoplasmic domain of CD44 fusion protein (FLAG-CD44cyt) and a constitutively activated c-Src kinase recombinant protein to conduct in vitro binding assays. Specifically, the binding of 125I-labeled FLAG-CD44cyt to c-Src kinase under equilibrium binding conditions was tested. Scatchard plot analyses presented in Fig. 2 indicate that c-Src kinase binds to the cytoplasmic domain of CD44 (CD44cyt) at a single site with high affinity (an apparent dissociation constant (Kd) of ~2.0 nM). These findings clearly indicate that the cytoplasmic domain of CD44 interacts directly with c-Src kinase.



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Fig. 2.   Binding of 124I-labeled FLAG-CD44cyt to c-Src recombinant protein. Various concentrations of 125I-labeled FLAG-CD44cyt were incubated with c-Src recombinant protein-coupled beads at 4 °C for 4 h. Following binding, beads were washed extensively in binding buffer and the bead-bound radioactivity was counted. As a control, 125I-labeled FLAG-CD44cyt was also incubated with uncoated beads to determine the binding observed due to the nonspecific binding of the ligand. Nonspecific binding, which represented ~20% of the total binding, was always subtracted from the total binding. Our binding data are highly reproducible. The values expressed under "Results" represent an average of triplicate determinations of three to five experiments with S.D. less than ±5%. The data represent Scatchard plot analysis of the equilibrium binding data between 125I-labeled FLAG-CD44cyt and c-Src kinase.

Stimulation of CD44s-associated c-Src Kinase Activity by HA in SK-OV-3.ipl Cells-- Previous studies show that full catalytic activity of c-Src kinase requires phosphorylation of tyrosine 418 (43). Using specific anti-phospho-Src antibody (i.e. anti-Src(Tyr(P)418), designed to detect the activated form of c-Src kinase), we have found that c-Src kinase activation (detected in the CD44s-c-Src kinase complex) is HA-dependent (Fig. 3A). A relatively low level of c-Src kinase activation is detected when SKOV-3.ipl cells were treated with either a low HA concentration (~5-10 µg/ml) or a high HA concentration (100 µg/ml) (Fig. 3A). If the concentration of HA increases to 25-50 µg/ml, c-Src kinase activation becomes significantly elevated (Fig. 3A).



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Fig. 3.   Detection of c-Src kinase activity in CD44s-c-Src complex. Cell lysates were prepared from SK-OV-3.ipl cells treated with HA at various concentrations (e.g. 0, 5, 10, 25, 50, and 100 µg/ml) for 10 min and immunoprecipitated with anti-CD44s antibody (to isolate CD44s-c-Src kinase complex) followed by immunoblotting with various antibodies (e.g. anti-phospho-Src (Tyr(P)418) antibody, anti-Src antibody or anti-phosphotyrosine antibody. A, detection of the activated form of c-Src kinase by anti-phospho-Src (Tyr(P)418)-mediated immuno blot using anti-CD44s-mediated immunoprecipitated materials prepared from SK-OV-3 cells treated with HA at various concentrations (e.g. 0, 5, 10, 25, 50, and 100 µg/ml). B, tyrosine phosphorylation of enolase by c-Src kinase in the CD44s complex detected by anti-phosphotyrosine antibody (panel a). (Note that an equal amount of c-Src kinase (revealed by anti-Src-mediated immunoblot) was used in this kinase assay (panel b).) C, recruitment of c-Src kinase into CD44s complex detected by anti-CD44s-mediated immunoprecipation followed by anti-c-Src kinase-mediated immunoblot using SK-OV-3.ipl cells treated with 50 µg/ml HA (right lane) or without any HA (left lane).

The kinase activity was also measured by the ability of c-Src kinase (using an equal amount of c-Src kinase protein) (Fig. 3B, panel b, right and left lanes) to tyrosine-phosphorylate the substrate, enolase, in vitro (Fig. 3B). Our results indicate that CD44s-associated c-Src kinase isolated from HA-treated cells shows a significantly higher level of kinase activity (Fig. 3B, panel a, right lane) than that obtained from untreated cells (Fig. 3B, panel a, left lane) or HA-treated cells in the presence of anti-CD44s antibody (data not shown). Furthermore, we have observed that HA treatment recruits a significant amount of c-Src kinase (Fig. 3C, right lane) into the CD44s-c-Src kinase complex (Fig. 3C, left lanes). Since CD44 does not contain intrinsic catalytic properties, HA must activate and recruit cellular tyrosine protein kinases such as c-Src kinase to regulate tyrosine protein phosphorylation.

The cytoskeletal protein, cortactin, is a known c-Src kinase substrate, which is composed of six and a half 37-amino acid tandem repeats and an SH3 domain at the carboxyl terminus (41, 42). Between the SH3 and the repeat domains, there is an alpha -helical structure plus a sequence rich in proline residues (41, 42). Tyrosine phosphorylation of cortactin by c-Src kinase occurs in the region between the proline-rich sequence and the SH3 domain (41, 42, 44). In this study, we have found that HA treatment of ovarian tumor cells (SK-OV-3.ipl cells) stimulates tyrosine phosphorylation of the 85-kDa protein, cortactin, in vivo (Fig. 4, lane 3, a and b). In contrast, the level of cortactin tyrosine phosphorylation appears to be very low in those cells without any HA treatment (Fig. 4, lane 1, a and b) or treated with HA in the presence of PP2 (an inhibitor for the Src family kinases) (Fig. 4, lane 2, a and b). Kinetic analyses show that c-Src kinase activation (measured by c-Src-mediated cortactin phosphorylation) occurs as early as 2-5 min and reaches the maximal level ~30-60 min after the addition of HA to SKOV-3.ipl cells (Fig. 5). These findings clearly indicate that the binding of HA to these CD44s containing SK-OV-3.ipl cells promotes c-Src kinase activation leading to cortactin phosphorylation.



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Fig. 4.   Detection of cortactin tyrosine phosphorylation in HA-treated SK-OV-3.ipl cells. SK-OV-3.ipl cells (treated with HA (50 µg/ml) for 10 min in the absence or the presence of PP2 (an inhibitor for c-Src family kinases) or untreated) were solubilized in 50 mM Tris-HCl (pH 7.4), 150 mM NaCl, 1% Triton X-100 buffer. Cell lysates were then immunoprecipitated by anti-cortactin antibody followed by immunoblotting with mouse anti-phosphotyrosine antibody or reblotting with anti-cortactin plus peroxidase-conjugated goat anti-mouse IgG (1:10,000 dilution) as described under "Experimental Procedures." Lane 1, anti-cortactin-mediated immunoprecipitated materials (isolated from untreated SK-OV-3.ipl cells) were immunoblotted with anti-phosphotyrosine antibody (panel a) or reblotted with anti-cortactin (panel b). Lane 2, anti-cortactin-mediated immunoprecipitated materials (isolated from SK-OV-3.ipl cells treated with HA in the presence of PP2 (an inhibitor for the Src family kinases)) were immunoblotted with anti-phosphotyrosine antibody (panel a) or reblotted with anti-cortactin (panel b). Lane 3, anti-cortactin-mediated immunoprecipitated materials (isolated from SK-OV-3.ipl cells treated with HA) were immunoblotted with anti-phosphotyrosine antibody (panel a) or reblotted with anti-cortactin (panel b).



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Fig. 5.   Kinectic analysis of cortactin phosphorylation by c-Src kinase in SK-OV-3.ipl cells treated with HA. SK-OV-3.ipl cells were treated with HA (50 µg/ml) for various time intervals (0, 2, 5, 10, 15, 20, 30, and 60 min). At each time point, c-Src kinase (isolated from anti-c-Src-conjugated immunoaffinity beads) were assayed for its activity, by incubating with 10 µl of the reaction buffer (20 mM PIPES (pH 7.0), 10 mM MnCl2, 10 µM Na3VO4)), 1 µl of recombinant cortactin (5 µg of cortactin dissolved in 2 µl of 1 M PIPES (pH 7.0)), and 10 µCi of [gamma -32P]ATP at 30 °C for 1 h. To quantitate phosphorylated cortactin, aliquots of the reactions were analyzed by SDS-PAGE. The radioactivity associated with recombinant cortactin band was analyzed by autoradiograms quantitated by a PhosphorImager or scintillating counting methods as described under "Experimental Procedures."

Our preliminary data indicate that both Yes and Fyn are at least 5-fold less than c-Src kinase in SK-OV-3.ipl cells. Using specific anti-Fyn or anti-Yes-mediated immunoblot on anti-CD44s-precipitated material, we are unable to detect the association of these kinase molecules with CD44s or phosphorylation of cortactin (data not shown). Therefore, c-Src appears to be the major Src kinase family member (not Fyn or Yes) that is associated with CD44s and thus solely responsible for cortactin phosphorylation.

Effects of CD44s-c-Src Kinase Signaling on Cortactin Function and Ovarian Tumor Cell Migration-- The invasive phenotype of tumor cells (characterized by membranous projections and tumor cell migration) is closely associated with CD44s-mediated membrane motility and cytoskeleton function (9, 18, 21). To correlate CD44s-c-Src kinase signaling with ovarian tumor cell-specific behaviors, we have transiently transfected the ovarian tumor cells (SK-OV-3.ipl cells) with a dominant active form of GFP-tagged c-Src (Y527F)cDNA or a dominant-negative mutant of GFP-tagged c-Src kinase (K295R)cDNA (lacking kinase activity), respectively. Our results indicate that both GFP-tagged c-Src (Y527F) (Fig. 6A, lane 2) and GFP-tagged c-Src (K295R) (Fig. 6A, lane 3) are expressed as a 80-kDa protein detected by anti-GFP-mediated immunoprecipitation followed by anti-c-Src immunoblot (Fig. 6A). No detectable endogenous c-Src is detected in the anti-GFP-mediated immunoprecipitation followed by anti-c-Src-mediated immunoblot (Fig. 6A, lanes 1-3). The expression of these two GFP-tagged c-Src mutant proteins can also be detected by anti-GFP-mediated immunoblot (Fig. 7A, lanes 3 and 4). No protein band was detected in untransfected (Fig. 7A, lane 1) or vector-transfected SK-OV-3.ipl cells by anti-GFP-mediated immunoblotting (Fig. 7A, lane 2) or by anti-GFP-mediated immunoprecipitation followed by anti-c-Src immunoblot (Fig. 6A, lane 1).



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Fig. 6.   Detection of c-Src kinase mutant proteins and CD44s complex in SK-OV-3.ipl cells transfected with c-Src (Y527F)cDNA or c-Src (K295R)cDNA. A, SK-OV-3.ipl transfected with GFP-tagged c-Src (Y527F)cDNA or GFP-tagged c-Src (K295R)cDNA or vector alone were immunoprecipitated with mouse anti-GFP antibody followed by immunoblotting with anti-c-Src antibody. Lane 1, detection of cellular protein(s) associated with mouse anti-GFP-mediated immunoprecipitation and anti-c-Src kinase-mediated immunoblot in vector-transfected cells. Lane 2, detection of GFP-c-Src expression by mouse anti-GFP-mediated immunoprecipitation followed by anti-c-Src kinase-mediated immunoblot of c-Src (Y527F)cDNA-transfected cells. Lane 3, detection of GFP-c-Src expression by mouse anti-GFP-mediated immunoprecipitation followed by anti-c-Src kinase-mediated immunoblot of c-Src (K295R)cDNA-transfected cells. B, SK-OV-3.ipl transfected with GFP-tagged c-Src (Y527F)cDNA or GFP-tagged c-Src (K295R)cDNA or vector alone were immunoprecipitated with rat anti-CD44s-mediated immunoprecipitation followed by immunoblotting with anti-GFP antibody. Lane 1, detection of GFP-c-Src association with CD44s isolated from vector-transfected cells treated with (lane 2) or without HA (lane 1). Lane 2, detection of GFP-c-Src association with CD44s isolated from c-Src (Y527F)cDNA-transfected cells treated with (lane 4) or without HA (lane 3). Lane 3, detection of GFP-c-Src association with CD44s isolated from c-Src (K295R)cDNA-transfected cells treated with (lane 6) or without HA (lane 5).



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Fig. 7.   Characterization of c-Src mutant proteins in SK-OV-3.ipl cells transfected with c-Src (Y527F)cDNA or c-Src (K295R)cDNA, and measurement of the F-actin cross-linking activity of cortactin (phosphorylated by c-Src (Y527F) or c-Src (K295R)). SK-OV-3.ipl cells (e.g. untransfected or transfected by GFP-tagged c-Src (Y527F)cDNA or GFP-tagged c-Src (K295R)cDNA or vector alone) were immunoblotted with mouse anti-GFP antibody, or immunoprecipitated with mouse anti-cortactin followed by immunoblotting with mouse anti-phosphotyrosine antibody/reblotting with mouse anti-cortactin antibody as described under "Experimental Procedures." A, detection of GFP protein expression in untransfected cells (lane 1), vector-transfected cells (lane 2), GFP-tagged c-Src (Y527F)cDNA-transfected cells (lane 3), or GFP-tagged c-Src (K295R)cDNA-transfected cells (lane 4) by immunoblotting with mouse anti-GFP antibody. B, panel a, detection of cortactin tyrosine phosphorylation in untransfected cells (lane 1), vector-transfected cells (lane 2), GFP-tagged c-Src (Y527F)cDNA-transfected cells (lane 3), or GFP-tagged c-Src (K295R)cDNA-transfected cells (lane 4) by immunoprecipitating various cell lysates with mouse anti-cortactin followed by immunoblotting with mouse anti-phosphotyrosine antibody. B, panel b, detection of cortactin expression in untransfected cells (lane 1), vector-transfected cells (lane 2), GFP-tagged c-Src (Y527F)cDNA-transfected cells (lane 3), or GFP-tagged c-Src (K295R)cDNA-transfected cells (lane 4) by immunoprecipitating cell lysates with mouse anti-cortactin followed by reblotting with mouse anti-cortactin antibody. C, analysis of cortactin phosphorylation by c-Src-related proteins. Purified cortactin recombinant protein was incubated with c-Src-related proteins isolated from untransfected cells (a) or SK-OV-3.ipl cells (transfected with either GFP-tagged c-Src (Y527F) (c) or GFP-tagged c-Src (K295R) (d) or vector alone (b) using anti-GFP-Sepahrose beads) in the kinase reaction buffer at 30 °C for 1 h as described under "Experimental Procedures." To quantitate phosphorylated cortactin, aliquots of the reactions were analyzed by SDS-PAGE. The radioactivity associated with cortactin band were analyzed by Scintillating counting. D, measurement of the F-actin cross-linking activity of cortactin. Purified cortactin recombinant protein treated with c-Src-related proteins was subjected to F-actin cross-linking analysis. Specifically, unphosphorylated cortactin (treated with c-Src-related proteins isolated from untransfected cells (a) or vector-transfected cells (b) or SK-OV-3.ipl cells transfected with c-Src (K295R)cDNA (d) using anti-GFP-conjugated beads); or phosphorylated cortactin (isolated from SK-OV-3.ipl cells transfected with c-Src (Y527F)cDNA using anti-GFP-conjugated beads (c)) was incubated with a TKM buffer (50 mM Tris-HCl (pH7.4), 134 mM KCl, and 1 mM MgCl2). Unphosphorylated or phosphorylated cortactin was then mixed with 125I-labeled F-actin followed by a 30-min incubation at room temperature. Subsequently, the mixture was centrifuged at 25,000 × g for 10 min at room temperature. The supernatant was then collected, and the radioactivity in this fraction was counted. The decrease (or loss) of radioactivity in the supernatant fraction reflects F-actin precipitation due to the cross-linking reaction (41, 42). The F-actin cross-linking reaction in the presence of unphosphorylated cortactin (treated by anti-GFP-conjugated beads prepared from untransfected cells) (control) is designated as 100%. Each assay was set up in triplicate and repeated at least three times. All data were analyzed statistically using the Student's t test, and statistical significance was set at p < 0.01.

Transfected GFP-c-Src forms (e.g. GFP-c-Src (Y527F) or GFP-c-Src (K295R)) are also associated with CD44s (Fig. 6B). HA treatment promotes an accumulation of the dominant active form of c-Src (GFP-c-Src (Y527F)) (Fig., 6B, lanes 3 and 4) (but not the dominant-negative form of c-Src (GFP-c-Src (K295R)) (Fig. 6C, lanes 5 and 6) into anti-CD44s-mediated immunoprecipitated materials. No GFP-related protein was observed in anti-CD44s immunoprecipitates blotted with anti-GFP antibody using vector-transfected cells treated with (lane 2) or without HA (lane 1). These results suggest that the activated c-Src kinase (but not the inactivated c-Src kinase) is involved in the recruitment of c-Src kinase to CD44s during HA-mediated cellular signaling.

In addition, we have demonstrated that transfection of SK-OV-3.ipl cells with c-Src (Y527F)cDNA stimulates cortactin tyrosine phosphorylation in vivo (Fig. 7B, lane 3, a and b), as compared with cortactin in untransfected (Fig. 7B, lane 1, a and b) or vector-transfected cells (Fig. 7B, lane 2, a and b). Our results also demonstrate that overexpression of c-Src (K295R) does not induce cortactin tyrosine phosphorylation (Fig. 7B, lane 4, a and b). These data support the conclusion that cortactin serves as one of the cellular substrates for c-Src kinase in vivo.

To determine whether there is any kinase activity associated with GFP-tagged c-Src (Y527F) or GFP-tagged c-Src (K295R), we have incubated these c-Src (Y527F)/(K295R) proteins with purified recombinant cortactin in the presence of [gamma -32P]ATP. As shown in Fig. 7C, a significant amount of cortactin phosphorylation occurs in the presence of c-Src (Y527F) (Fig. 7C, c), but not c-Src (K295R) (Fig. 7C, d). In contrast, very little tyrosine phosphorylation of cortactin is detected in control proteins using anti-GFP-conjugated beads prepared from untransfected/vector-transfected cells (Fig. 7C, a and b). Apparently, tyrosine phosphorylation of cortactin activated by c-Src (Y527F) (but not by c-Src (K295R)) can also occur in vitro.

Tyrosine phosphorylation of cortactin by c-Src kinase has been shown to down-regulate its cross-linking with filamentous actin (F-actin) in vitro (41, 42). Here, we have shown that unphosphorylated cortactin (treated by anti-GFP-conjugated beads isolated from untranfected cells (Fig. 7C, a) or vector-transfected cells (Fig. 7C, b) or c-Src (K295R)cDNA-transfected cells (Fig. 7C, d)) promotes F-actin cross-linking activity in vitro (Fig. 7D, a, b, and d). In contrast, c-Src (Y527F)-phosphorylated cortactin (Fig. 7C, c) significantly reduces its ability to cross-link F-actin (Fig. 7D, c). These results support the notion that tyrosine phosphorylation of cortactin by c-Src kinase inhibits its interaction with F-actin, which may be required for cytoskeleton-mediated function. Using double immunolabel staining, we have observed that both c-Src kinase (Fig. 8A) and CD44s (Fig. 8B) are colocalized at the cellular membranes of untransfected SK-OV-3.ipl cells (Fig. 8C). In c-Src (Y527F)cDNA-transfected cells, both GFP-tagged c-Src kinase (Y527F) (Fig. 8D) and CD44s (Fig. 8E) are closely colocalized in the plasma membranes and long membrane projections (Fig. 8F). In contrast, vector-transfected cells expressing CD44s on their surface (Fig. 8, inset b) (with no detectable GFP label (Fig. 8, inset a)) are not able to induce long membrane projections (Fig. 8, inset c). It is also noted that overexpression of GFP-tagged c-Src (K295R) significantly reduces c-Src kinase (Fig. 8G) colocalization (Fig. 8I) with CD44s (Fig. 8H) and the formation of membrane projections (Fig. 8, G-I).



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Fig. 8.   Immunofluorescence staining of c-Src kinase and CD44s in untransfected SK-OV-3.ipl cells or SK-OV-3.ipl transfectants. SK-OV-3.ipl cells (untransfected or transfected with GFP-tagged c-Src (Y527F)cDNA or GFP-tagged c-Src (K295R)cDNA or vector alone) were fixed by 2% paraformaldehyde. Subsequently, cells were rendered permeable by ethanol treatment and stained with various immunoreagents as described under "Experimental Procedures." A-C, FITC-labeled anti-c-Src kinase staining (A), Texas Red-labeled anti-CD44s staining (B), and colocalization of c-Src kinase and CD44s (C) in untransfected SK-OV-3.ipl cells. D-F, GFP-tagged c-Src (Y527F) (D), Texas Red-labeled anti-CD44s staining (E), and colocalization of GFP-tagged c-Src (Y527F) and CD44s (F) in GFP-tagged c-Src (Y527F)cDNA-transfected SK-OV-3.ipl cells. G-I, GFP-tagged c-Src (K295R) (G), Texas Red-labeled anti-CD44s staining (H), and colocalization of GFP-tagged c-Src (K295R) and CD44s (I) in GFP-tagged c-Src (K295R)cDNA-transfected SK-OV-3.ipl cells. Insets a-c, No detectable staining of GFP (a), Texas Red-labeled anti-CD44s (b), and a merged image (c) of a and b in vector-transfected SK-OV-3.ipl cells.

Further analyses indicate that transfection of SK-OV-3.ipl cells with GFP-tagged c-Src kinase (Y527F)cDNA induces a recruitment of cortactin (Fig. 9C) to c-Src kinase (Fig. 9A) and CD44s (Fig. 9B)-linked membrane projections. Our results also indicate that these c-Src (Y527F) transfectants display a significant increase in HA-dependent and a CD44s-specific ovarian tumor cell migration (Table I) as compared with untransfected/vector-transfected tumor cells (Table I). In contrast, overexpression of the dominant-negative form of c-Src (K295R) in SK-OV-3.ipl cells not only blocks the membrane localization of c-Src kinase (Fig. 9D) to CD44s (Fig. 9E) but also inhibits cortactin membrane association (Fig. 9F) with CD44s (Fig. 9E) and the formation of membrane projections (Fig. 9, D-F). Consequently, HA and CD44s-specific tumor cell migration is also inhibited in these c-Src mutant (K295R) transfectants (Table I). These findings suggest that CD44s-mediated c-Src kinase signaling plays a pivotal role in regulating cortactin-cytoskeleton function and HA-mediated tumor cell migration during human ovarian cancer progression.



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Fig. 9.   Immunofluorescence staining of c-Src kinase, CD44s and cortactin in SK-OV-3.ipl transfectants. SK-OV-3.ipl cells transfected with GFP-tagged c-Src (Y527F)cDNA or GFP-tagged c-Src (K295R)cDNA were fixed by 2% paraformaldehyde. Subsequently, cells were rendered permeable by ethanol treatment and stained with various immunoreagents as described under "Experimental Procedures." A-C, GFP-tagged c-Src kinase staining (A, green color), cyanine (Cy5)-labeled anti-CD44s staining (B, blue color), and Texas Red-labeled anti-cortactin staining (C, red color) in SK-OV-3.ipl cells transfected with c-Src (Y527F)cDNA. D-F, GFP-tagged c-Src kinase staining (D, green color), Cyanine (Cy5)-labeled anti-CD44s staining (E, blue color), and Texas Red-labeled anti-cortactin staining (F, red color) in SK-OV-3.ipl cells transfected with c-Src (K295R)cDNA.


                              
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Table I
Measurement of membrane motility and HA-mediated and CD44s-specific tumor cell migration



    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

HA is the major glycosaminoglycan of the ECM. It is known to cause cell aggregation of a number of different cell types and has been implicated in the stimulation of cell proliferation, cell migration, cell adhesion, and angiogenesis (9-21, 29). Overexpression of HA often occurs at sites of tumor attachment and invasion (45). The adhesion molecule, CD44 is one of the major HA receptors on the surface of a number of different cell types including human ovarian tumor cells (5-9). In the ovary, HA is present in large amounts in the mesothelial lining (7). In fact, it has been postulated that CD44 interaction with HA may be one of the important requirement for the spread of ovarian cancer. Nevertheless, the cellular and molecular mechanisms affecting the ability of CD44-positive ovarian tumor cells to spread and implant at HA-enriched locations within the peritoneal cavity remain unclear.

A number of studies indicate that transmembrane interaction between the cytoplasmic domain of CD44 and cytoskeletal proteins (in particular, ankyrin) plays an important role in CD44-mediated oncogenic signaling (2, 3). In particular, a 15-amino acid sequence located in the cytoplasmic domain of CD44 appears to be required for high affinity ankyrin binding (19-21). Several factors, including protein kinase C (46, 47) and Rho kinase-mediated phosphorylation (17), palmitoylation (48), and GTP binding (49), are required for the up-regulation of CD44-ankyrin interaction. Furthermore, we have found that the S2 subdomain (but not other subdomains) of the ankyrin repeat domain binds to CD44 directly (9); and overexpression of the S2 subdomain of ankyrin repeat domain promotes CD44-mediated human ovarian tumor cell migration (9). Most recently, Tiam1 (T lymphoma invasion and metastasis), one of the guanine nucleotide (GDP/GTP) exchange factors for RhoGTPases (e.g. Rac1) has also been found to bind CD44 (18) and to be regulated by the cytoskeletal proteins (e.g. ankyrin) (50) during metastatic tumor cell migration. Therefore, the selective interaction of CD44 with various oncogenic signaling molecules and/or cytoskeletal proteins could be one of the critical steps in promoting abnormal tumor cell motility.

A number of nonreceptor cytoplasmic tyrosine kinases (e.g. Src, Abl, Fps, Syk/ZAP70, Jak subfamilies, and several unclassified kinases) are involved in signal transduction pathways by coupling with surface receptors during cellular responses (51). In this study we have found that c-Src kinase and the cell surface adhesion molecule, CD44s are closely associated as a complex in human ovarian tumor cells (Figs. 1, 8, and 9). Abnormal regulation of Src-related enzymes is known to lead to oncogenic cellular transformation. This was first demonstrated by the identification of three Src family members (e.g. c-Src, c-Yes, and c-Fgr) as the transforming elements of acutely transforming retroviruses (52). Several tyrosine phosphorylation substrates (e.g. PLCgamma (53), Vav (54, 55), phosphatidylinositol 3-kinase (56), etc.) have been detected in activated cells. In most cases, the kinase(s) directly phosphorylating these polypeptides is (are) not known. It is assumed that c-Src kinase or tyrosine protein kinases activated by Src-like enzymes (e.g. Syk/ZAP70) (57, 58) is responsible for the tyrosine phosphorylation of these cellular proteins. In addition, some cytoplasmic tyrosine kinases, such as Csk, are considered to serve important regulatory functions by modulating the activity of Src subfamily kinases (59, 60).

The activity of c-Src kinase is required for epithelial cell scattering (29, 61, 62), migration (30), and organization of the cortical cytoskeleton (63). The cytoskeletal protein, cortactin (encoded by the EMS1 gene) is a prominent substrate for Src-related protein-tyrosine kinases (41, 42, 64). Overexpression of cortactin correlates with cancer progression and poor patient prognosis (65). A number of ligands (including fibroblast growth factor (66), epidermal growth factor (67), and thrombin (68)), integrin activation (69), phagocytosis (70), and mechanical strain (71) have all been shown to stimulate tyrosine phosphorylation of cortactin leading to cytoskeleton-regulated cell motility (42). Here, we have determined that cortactin is a cellular substrate for c-Src kinase in human ovarian tumor cells (SK-OV-3.ipl cell line) activated by HA binding to CD44 (Figs. 4 and 5). Two structural features of cortactin, a repeat domain and a COOH-terminal SH3 domain resemble neufectin, a F-actin-associated protein (45). In fact, cortactin is considered to be an actin binding protein (41, 42, 44). Our data indicate that the unphosphorylated form of cortactin (in the presence of the dominant-negative mutant protein of c-Src kinase (K295R)) is capable of cross-linking the actin filaments into bundles in vitro (Fig. 7). In contrast, tyrosine phosphorylation of cortactin by the dominant-active form of c-Src kinase (Y527F) down-regulates its ability to cross-link filamentous actin (Fig. 7). These results are consistent with previous findings suggesting cortactin plays an important role as an F-actin modulator in c-Src kinase-regulated cytoskeleton reorganization.

To further elucidate cortactin interaction with c-Src kinase and CD44s in vivo, we have used immunocytochemical staining and confocal microscopy to monitor morphological changes and the intracellular distribution of various proteins in SK-OV-3.ipl transfectants expressing GFP-tagged c-Src mutants (e.g. c-Src (Y527F) or c-Src (K295R)). We have observed that overexpression of the dominant-active form of GFP-tagged c-Src kinase (Y527F) (by transfecting SK-OV-3.ipl cells with c-Src (Y527F)cDNA) promotes colocalization of cortactin (Fig. 9C) with CD44s (Fig. 9B) and c-Src kinase (Fig. 9A) at membrane projections (Fig. 9, A-C). In contrast, transfection of SK-OV-3.ipl cells with the dominant-negative c-Src kinase mutant (K295R)cDNA effectively inhibits the recruitment of cortactin (Fig. 9F) or c-Src kinase (Fig. 9D) to CD44s (Fig. 9E) at the cellular membranes and impairs the formation membrane projections (Fig. 9, D-F) (Table I). These findings suggest that the ability of cortactin to remodel actin filaments (Fig. 9) or become recruited into CD44s-associated membrane projections is tightly regulated by c-Src kinase activity.

There is increasing evidence that the ability of CD44 to transmit information from the cell's exterior to its interior depends on HA-CD44 interaction and selective down-stream molecular switches (1-3). During ovarian tumor cell transformation and spreading, overexpressed CD44s is tightly coupled with at least two different tyrosine kinase-based oncogenic regulators such as p185HER2 (8) and c-Src kinase (20, 35, 36). In SK-OV-3.ipl cells, CD44s and the receptor tyrosine kinase, p185HER2, are physically linked to each other via interchain disulfide bonds, and HA is capable of stimulating CD44s-associated p185HER2 tyrosine kinase activity, causing an increase in the ovarian carcinoma cell growth (8). In this study we have described a CD44s-related nonreceptor c-Src tyrosine kinase signaling pathway in human ovarian tumor cells. Specifically, we have determined that CD44s binds to c-Src kinase both in vivo (Figs. 1, 6, 8, and 9) and in vitro (Fig. 2). In particular, the cytoplasmic domain of CD44s binds to c-Src kinase at a single site with high affinity (an apparent dissociation constant (Kd) of ~2.0 nM) (Fig. 2). Preliminary data indicate that the SH3 domain of c-Src kinase may be involved in the binding of a proline-containing sequence in the cytoplasmic domain of CD44s (data not shown).

Most Src family kinases are modified with specific lipids that direct them to subdomains of cell membrane that have high cholesterol and glycolipid content, called membrane "rafts" (31). In fact, the Src kinases, Lck and Fyn, have been shown to be associated with CD44s in glycosphingolipid-rich plasma membrane domains of human peripheral blood lymphocytes (36). Therefore, it is possible that the interaction between CD44 and c-Src kinase at the membrane rafts facilitates HA-mediated stimulation of the catalytic activity of c-Src kinase (Figs. 3-5). This, in turn, modifies cortactin structure/function (Figs. 4, 5, and 7-9) and induces membrane projections and tumor cell migration (Table I). Several lines of evidence also indicate that activation of c-Src activity was correlated with its ability to interact with tyrosine-phosphorylated p185HER2 both in vitro and in vivo in mammary tumors (72, 73). The questions of (i) whether "cross-talk" occurs between CD44s-c-Src kinase and CD44s-p185HER2 tyrosine kinase; and (ii) what other tyrosine-phosphorylated substrate(s) is(are) involved in ovarian tumor development are currently under investigation in our laboratory.

In normal cells, such as human endothelial cells, the level of CD44 expression is relatively low and HA does not bind CD44 very well. In fact, HA binds to RHAMM (another HA binding receptor) better than it does to CD44 in normal cells (75). Consequently, the c-Src kinase activity associated with CD44 in normal cells fails to be activated by HA. In the ovary, large amounts of HA accumulation in the mesothelial lining (7) are involved in tumor attachment/invasion (45). CD44 is overexpressed on the surface of ovarian tumor cells and mediates cell migration in response to HA (9). Therefore, CD44 interaction with HA has been postulated to be one of the important requirements for the spread of ovarian cancer. In this study we have provided new evidence that the binding of HA to CD44s on the surface of ovarian tumor cells not only promotes c-Src kinase recruitment to CD44s, but also activates c-Src kinase activity to phosphorylate the cytoskeletal protein, cortactin, leading to tumor cell migration. This new information may establish HA-inducible CD44s-c-Src kinase signaling as an important functional indicator to evaluate oncogenic potential, and allow the development of new drug targets to inhibit tumor cell motility during the progression of human ovarian cancer.


    ACKNOWLEDGEMENT

We gratefully acknowledge Dr. Gerard J. Bourguignon's assistance in the preparation of this paper.


    FOOTNOTES

* This work was supported by United States Public Health Grants CA66163 and CA78633 and Department of Defense Grants DAMD 17-97-1-7014 and DAMD 17-99-1-9291.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom reprint requests should be addressed: Dept. of Cell Biology and Anatomy, University of Miami Medical School, 1600 N.W. 10th Ave., Miami, FL 33101. Tel.: 305-243-6985; Fax: 305-545-7166; E-mail: lbourgui@med.miami.edu.

Published, JBC Papers in Press, November 17, 2000, DOI 10.1074/jbc.M006498200


    ABBREVIATIONS

The abbreviations used are: HA, hyaluronan; ECM, extracellular matrix; PIPES, 1,4-piperazinediethanesulfonic acid; SH, Src homology; PAGE, polyacrylamide gel electrophoresis; GFP, green fluorescent protein; PCr, polymerase chain reaction.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES


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