RHAMM Promotes Interphase Microtubule Instability and Mitotic Spindle Integrity through MEK1/ERK1/2 Activity*

An oncogenic form of RHAMM (receptor for hyaluronan-mediated motility, mouse, amino acids 163–794 termed RHAMMΔ163) is a cell surface hyaluronan receptor and mitotic spindle protein that is highly expressed in aggressive human cancers. Its regulation of mitotic spindle integrity is thought to contribute to tumor progression, but the molecular mechanisms underlying this function have not previously been defined. Here, we report that intracellular RHAMMΔ163 modifies the stability of interphase and mitotic spindle microtubules through ERK1/2 activity. RHAMM−/− mouse embryonic fibroblasts exhibit strongly acetylated interphase microtubules, multi-pole mitotic spindles, aberrant chromosome segregation, and inappropriate cytokinesis during mitosis. These defects are rescued by either expression of RHAMM or mutant active MEK1. Mutational analyses show that RHAMMΔ163 binds to α- and β-tubulin protein via a carboxyl-terminal leucine zipper, but in vitro analyses indicate this interaction does not directly contribute to tubulin polymerization/stability. Co-immunoprecipitation and pulldown assays reveal complexes of RHAMMΔ163, ERK1/2-MEK1, and α- and β-tubulin and demonstrate direct binding of RHAMMΔ163 to ERK1 via a D-site motif. In vitro kinase analyses, expression of mutant RHAMMΔ163 defective in ERK1 binding in mouse embryonic fibroblasts, and blocking MEK1 activity collectively confirm that the effect of RHAMMΔ163 on interphase and mitotic spindle microtubules is mediated by ERK1/2 activity. Our results suggest a model wherein intracellular RHAMMΔ163 functions as an adaptor protein to control microtubule polymerization during interphase and mitosis as a result of localizing ERK1/2-MEK1 complexes to their tubulin-associated substrates.

The interphase microtubule network is composed of ␣and ␤-tubulin heterodimers that form tubules, which are highly dynamic structures participating in cell morphology/ polarity, signaling, migration, proliferation, and protein trafficking (1)(2)(3). The effects of microtubules depend on their dynamic nature composed of polymerization and depolymerization cycles. These are primarily controlled by post-translational modification of microtubule-stabilizing (MAPs) 3 and -de-stabilizing proteins (e.g. Stathmin) (4 -6). The microtubules of mitotic spindles, which also contain heterodimers of ␣and ␤-tubulin, are particularly dynamic. This property is essential for appropriate chromosome segregation and, consequently, genomic stability (7)(8)(9)(10). The microtubule functions that depend upon dynamic cycles of polymerization/depolymerization are increasingly targeted as a means for controlling cancer growth and spread and the progression of other diseases in which microtubules play a role. For example taxanes, which promote microtubule stability, are widely used as an adjuvant treatment for cancer (11)(12)(13). However, an understanding of the molecular mechanisms controlling microtubule turnover in cancer cells is still incomplete.
RHAMM is an oncogenic protein that has been implicated in the progression of many human cancers, including breast, acute myeloid leukemia, multiple myeloma, gastric, and prostate cancers (14 -16). (RHAMM/HMMR is the human gene designation, and Rhamm is the mouse gene designation; RHAMM is used here to describe the protein product of both species.) Most studies to date suggest that RHAMM overexpression promotes tumor progression. Thus, high RHAMM expression in breast cancer is predictive of poor clinical outcome (17,18), and polymorphisms in this gene have been linked to breast cancer susceptibility in some human populations (18,19). SERA analyses have identified RHAMM as a tumor marker for acute myeloid leukemia, and clinical trials are ongoing to assess the use of RHAMM peptide vaccines for control of acute myeloid leukemia and multiple myeloma (20).
RHAMM expression in adult mammals is largely restricted to sites of tissue injury and to pathological processes involved in chronic inflammation and neoplasia (15,21). RHAMM is distributed within several intracellular compartments, and it is also localized to the surface of certain normal and transformed cells (21,22). Intracellular RHAMM proteins are found in the cell nucleus (15) on interphase microtubules (23), mitotic spindles, centrosomes (24), and within mitochondria (25). RHAMM is one of a number of proteins that can be exported to the cell surface by unconventional mechanisms (15,26). This structurally diverse group of proteins is characterized by the lack of an identifiable signal peptide for export through the Golgi/endoplasmic reticulum.
Extracellular RHAMM promotes cell motility and invasion through sustained stimulation of the activity of MEK1/ERK1/2 kinases (resulting from its association with integral receptors such as CD44 and platelet-derived growth factor receptor and with hyaluronan (15,22,27)). The gene designation for MEK1 is MAP2K1; for ERK1 is MAPK3, and for ERK2 is MAPK1. MEK1, ERK1, and ERK2 are used here for protein products of these genes. The functions of intracellular RHAMM are less well understood, but its association with mitotic spindles requires a leucine zipper located in the carboxyl terminus that facilitates RHAMM/tubulin interactions. These interactions are required for Ran-driven, acentrosomal mitotic spindle pole formation in Xenopus egg extracts (15,28,29). Forced high expression of RHAMM results in multi-pole spindles, and this effect has been linked to genomic instability in multiple myeloma (30). The pole-stimulating function of RHAMM is restricted in human cell lines by breast cancer gene 1 (BRCA1)-BRCA1 association ring domain 1 (BARD1) complexes, which safeguard the formation of focused bipolar mitotic spindles (28). Recently, intracellular RHAMM has also been implicated in abscission during cytokinesis as a result of its association with supervillin, a member of the gelsolin family of proteins (31). The molecular mechanisms underlying these two RHAMM functions in the cell cycle has not, to our knowledge, previously been reported.
Full-length RHAMM (RHAMM FL ) is expressed in cultured cells and contains two microtubule-binding regions (23,29). Injured, subconfluent, or neoplastic cultured cells express additional RHAMM protein isoforms resulting from alternative splicing and/or post-translational processing (32,33). Most of these are amino-terminal truncations of the full-length protein and therefore contain only the carboxyl-terminal tubulin binding sequence (27). At least one of the truncated forms (e.g. RHAMM ⌬163 ) is transforming when overexpressed in 10T1/2 MEF cell lines (32). Therefore, understanding the mechanisms by which RHAMM affects microtubule structures via its carboxyl-terminal sequence may help to clarify its role(s) in neoplastic diseases.
We have shown that intracellular RHAMM proteins, in particular RHAMM ⌬163 , complex with MEK1 and ERK1/2 (33). We were prompted to investigate whether or not intracellular RHAMM protein controls interphase and mitotic microtubule stability/integrity through MEK1/ERK1/2 because we reported that ERK1/2 activity is necessary for dynamic instability of interphase microtubules in RAS-transformed fibroblasts (34), and others have shown that microtubule stability results in multi-pole spindles (35), and BRCA1-ERK1/2 form complexes during mitosis (36,37). Here, our results suggest that MEK1-ERK1/2 complexes mediate the effects of intracellular RHAMM ⌬163 on interphase and mitotic spindle structure and that RHAMM performs scaffolding functions to control both activity and targeting of MEK1-ERK1/2 complexes to tubulin.

EXPERIMENTAL PROCEDURES
Reagents-␣-and ␤-tubulin heterodimers and MAP-enriched tubulin were purchased from Cytoskeleton Inc. (Denver, CO). Mouse anti-tubulin monoclonal antibodies and antiphospho-ERK1/2 antibodies were purchased from Sigma and Santa Cruz Biotechnology (Santa Cruz, CA). An anti-pan-ERK1/2 polyclonal antibody was purchased from BD Transduction Laboratories. Alexa dye secondary antibodies were obtained from Invitrogen. Nocodazole and the MEK1 inhibitor (PD98059) were purchased from Sigma. The mutant active MEK1 expression vector was the kind gift of Natalie Ahn (University of Colorado, Boulder). Polyclonal anti-RHAMM antibodies were prepared against the peptide sequence (mouse RHAMM) 727 KLKDENSQLKSEVS 740 by ProSci (Poway, CA). Additional peptides, 715 HQNLKQKIKHVVKLKDENSQLKSE-VSKLRSQ 745 and 728 LKDENSQLKSEVSKL 742 , which contains the leucine zipper required for an association of RHAMM with the mitotic spindle (28), and control peptides 195 KLQATQKD-LTESKGKLVQLEGKL 217 and control peptide 2 ( 218 VSIEKEK-IDEK 228 ) were used in MAPK binding assays and were synthesized at the London Regional Cancer Program Proteomics Center. Biotinylated hyaluronan was purchased from Hyalose (Oklahoma City, OK).
Immunofluorescence-Cells were plated overnight on sterile glass coverslips at 50% subconfluence in DMEM supplemented with 10% FBS. Cells were fixed with buffered 3% paraformaldehyde and then permeabilized with 0.1% Triton X-100 in PBS. Nonspecific binding sites were blocked with 3% BSA in PBS for 1 h at 20°C. Anti-tubulin, anti-acetylated tubulin, and antiphospho-ERK1/2 antibodies were diluted 1:100; anti-RHAMM antibodies were diluted 1:1000. Fixed cultures were incubated with primary antibodies for 2 h at 20°C. Cultures were washed in 3% BSA in PBS and then incubated with Alexa dye-labeled secondary antibodies, which were diluted 1:150. Cultures were washed again in 3% BSA/PBS and then mounted in a Vectashield mountant containing DAPI (1.5 g/ml).
Western and Far Western Blots-Cell lysates were prepared using RIPA buffer as described previously (33). Equal amounts of cell lysate or GST-RHAMM recombinant protein were resolved by electrophoresis on a 10% SDS-polyacrylamide gel. Separated proteins were transferred to nitrocellulose membranes in a buffer containing 25 mM Tris-HCl, pH 8.3, 192 mM glycine, and 20% methanol using electrophoretic transfer cells (Bio-Rad) at 100 V for 1.5 h at 4°C. Membranes were incubated in TBST ϩ 5% defatted milk to block nonspecific protein-bind-ing sites, and then the membranes were incubated with primary antibodies at dilutions recommended by the manufacturer for 2 h at 4°C. Polyclonal anti-RHAMM antibodies were used at a dilution of 1:15,000. Membranes were washed, and immunodetection was then performed using secondary antibodies provided in an ECL kit (Invitrogen).
For far-Western analyses, recombinant GST-RHAMM was separated on SDS-PAGE and transferred to nitrocellulose membranes as above. Microtubule protein (Cytoskeleton Inc., 99% ␣and ␤-tubulin heterodimers) was incubated with the nitrocellulose membrane at 0.2 g/ml as described for primary antibodies, washed, and then incubated with an anti-␣-tubulin mouse monoclonal antibody (1:100 dilution). Bound tubulin antibodies were detected using goat anti-mouse-HRP secondary antibody. Bound antibody was detected with reagents in an ECL kit as above.
Pulldown Assays-Recombinant mouse GST-RHAMM proteins and GST protein by itself were produced in bacteria as described previously (22) and then subsequently purified using glutathione-Sepharose 4B beads (GE Healthcare). ERK1, ERK2, and MEK1 recombinant proteins (human) were purchased from Enzo Life Sciences, Inc. (Plymouth Meeting, PA). Based on a Coomassie Blue-stained SDS-polyacrylamide gel, 100 l of GST-RHAMM(706 -767) beads and 50 l of GST beads were used for this assay. The beads were washed with 1ϫ PBS before blocking with 100 mM lactose overnight at 4°C. Purified bovine ␣and ␤-heterodimeric tubulin (Cytoskeleton Inc.) was diluted in tubulin buffer to a concentration of 50 g/ml, and 500 l was mixed with lactose-blocked GST-RHAMM(706 -767) or GST beads alone at 4°C for 3 h. The beads were then washed with 1 ml of wash buffer (50 mM Tris, pH 8.0, with 0.1% Triton X-100) five times at 4°C. 100 l of 2ϫ SDS loading buffer was added to beads, which were boiled at 95°C for 10 min, and then 20 l of the supernatant were loaded on a 10% SDS-polyacrylamide gel. Separated proteins were transferred to a nitrocellulose membrane and incubated with anti-tubulin antibodies as described above for Western blots. To confirm binding of ␣and ␤-tubulin to RHAMM in cells, cell lysates were prepared from primary RHAMM Ϫ/Ϫ and wild type MEF as described above, and then pulldown assays were performed using recombinant RHAMM(706 -767) linked to Sepharose beads. Beads were washed, and associated proteins were separated on a gradient SDS-PAGE (5-12%) and lightly stained with silver, and clearly separated bands in the range of 45-65 kDa were cut out, protein-eluted, and identified with MALDI-TOF analysis (Emili and Greenblatt Proteomics Research Center, University of Toronto, Toronto, Canada).
To assess direct binding of RHAMM to ERK1, ERK2, and MEK1, purified GST-RHAMM recombinant protein (mouse, amino acids 164 -794) was immobilized on glutathione-Sepharose as a GST fusion protein or covalently linked to SulfoLink gel as per the manufacturer's instructions (Pierce). Recombinant MAPKs were incubated with GST-RHAMM beads in binding buffer (25 mM HEPES, pH 7.2, 50 mM NaCl; 10 mM MgCl 2 ) for 1 h at 4°C on a nutator. Beads were sedimented by centrifugation, washed 10 times with 1 ml of cold binding buffer/wash, then boiled in SDS-PAGE loading buffer before electrophoresis on 10% SDS-PAGE, and transferred to a nitrocellu-lose membrane for Western blot analysis. For competition analyses, 1 g of MAPK recombinant protein was incubated with 10 g of peptide or soluble recombinant wild type or mutant RHAMM protein at 4°C on a nutator for 1 h, and GST-RHAMM beads were then added, and the mixture was incubated an additional 1 h. GST-RHAMM beads were captured by centrifugation and analyzed as above for bound MAPKs.
Microtubule Pelleting Assays-Pelleting assays were performed using GST-RHAMM ⌬373 and GST-RHAMM ⌬163 recombinant proteins or GST alone used as a control. These proteins were incubated with taxol-stabilized porcine microtubules, prepared according to manufacturer's instructions (MAP spin-down assay kit, Cytoskeleton Inc.). 1-2 g/ml recombinant RHAMM proteins were dissolved in microtubule cushion buffer (PEM) supplemented with 2 mM DTT and 20 M taxol. The solution was pre-cleared by centrifugation at 80,000 ϫ g for 45 min at 4°C. The supernatant was decanted and incubated with either 50 M of taxol-polymerized microtubules or buffer alone. Samples were layered over 350 l of 10% glycerol in PEM, and microtubules were sedimented from soluble protein by centrifugation at 80,000 ϫ g for 40 min at room temperature. Equal amounts of the supernatant and pellet were separated on 10% SDS-polyacrylamide gels, and tubulin was detected by Western blot analysis as described above.
Immunoprecipitation Assays-Immunoprecipitations were performed using 500 g of protein from cell lysates pre-cleared with 10 l of protein A/G-Sepharose beads (Invitrogen). The pre-cleared lysate was incubated with primary antibodies for 12 h at 4°C on a nutator at concentrations recommended by the manufacturer. Anti-RHAMM polyclonal antibodies were used at 5/400 g of cell lysate. The protein-antibody complexes were captured with protein A/G-Sepharose beads, which were pelleted and washed. Bound protein was released by boiling in 25 l of Laemmli buffer. Released proteins were separated on a 10% SDS-PAGE as described above, and Western blots were conducted as described above.
Analysis of Acetylated Tubulin Levels in Soluble and Insoluble Fractions-1 ϫ 10 5 cells were plated on fibronectin-coated (10 g/ml) cell culture dishes in DMEM, 10% FCS containing antibiotics/antimycotics. 24 h later, cells were washed with PBS. The soluble fraction was isolated by treating cells with 300 l of microtubule stabilizing buffer (0.1 M Pipes, pH 6.9, 1 mM EGTA, 2.5 mM GTP, 4% PEG 6000, 0.2% Triton X-100) plus proteinase and phosphatase inhibitor on ice. Following removal of the soluble fraction, the insoluble fraction was isolated by treating cells with 300 l of RIPA lysis buffer (50 mM Tris-HCl, pH 7.4, 150 mM NaCl, 2 mM EDTA, 1% Nonidet P-40, 0.1% SDS) on ice and scraping the plate with a cell scraper. Soluble and insoluble fractions were stored at 4°C (short term) or Ϫ80°C (long term) prior to quantifying the protein concentration using an Advanced Protein Assay (Cytoskeleton, Inc.). Equal amounts of protein were loaded on an SDS-polyacrylamide gel and separated by electrophoresis as described above. Western analyses were performed using 1:1000 anti-acetylated and 1:1000 total (␣ and ␤) tubulin antibodies (Sigma).
Resistance of Interphase Microtubules to Nocodazole-Cells were plated at 50% confluence on fibronectin-coated coverslips as above. 24 h later, cells were treated with culture medium containing different concentrations of either nocodazole or DMSO for 30 min. After treatment, cells were washed with PBS and incubated with microtubule stabilizing buffer for 10 min on ice. Cell monolayers were washed again with PBS and then fixed in 4% paraformaldehyde in PBS for 10 min on ice. After fixation, cells were washed for 5 min with PBS and then blocked with 3% BSA/PBS for 1 h at room temperature. Cells were incubated overnight at 4°C with either 1:200 diluted (1% BSA/PBS) anti-␣-tubulin antibody or isotypematched nonimmune IgG (Cytoskeleton Inc.). Monolayers were washed three times at 5-min intervals with PBS followed by 30 min of incubation with 1:200 diluted (1% BSA/PBS) secondary antimouse or anti-rabbit secondary antibody (labeled with Alexa Fluor 647). Monolayers were washed three times at 5-min intervals with PBS to remove unbound secondary antibody and then incubated with a 1:20,000 dilution (PBS) of DAPI for 10 min to detect nuclei. Monolayers were washed three times in PBS at 5-min intervals and then mounted in Dako fluorescent mounting medium and examined with an Olympus confocal microscope.
Nocodazole-induced Cell Cycle Block-Cells were plated at 50% confluence on sterile coverslips in DMEM, 10% FCS plus antibiotic/ anti-mycotic, incubated at 37°C, 5% CO 2 humidified atmosphere, allowed to adhere for 5-6 h, and then incubated for 24 h in 60 ng/ml of nocodazole. Cells were released from the nocodazole block by washing monolayers three times with DMEM ϩ 10% FCS. Monolayers were fixed in 3% paraformaldehyde at 2, 4, and 6 h following the removal of nocodazole and were stained for ␣-tubulin using anti-tubulin antibodies as described above. Cells were photographed with an Olympus confocal microscope.
Quantitative PCR-RNA was isolated from 50% confluent cells using TRIzol (Invitrogen) following the manufacturer's instructions. 1 g of RNA was reverse-transcribed using SuperScriptII (Invitrogen) following the manufacturer's instructions. Oligo(dT) (Invitrogen) was used as primer for cDNA synthesis. CYBR Green PCR master mix was pur-  72°C. Relative expression levels were calculated as ⌬Ct. Amplification of ␤-actin was used for standardization.

RHAMM ⌬163 Decorates Both Interphase and Mitotic Spindle
Microtubules-RHAMM FL was previously shown to decorate both interphase and mitotic spindles of epithelial and immune cells (23,30). We wanted to confirm the co-localization of RHAMM proteins with microtubule structures in 10T1/2 fibroblasts, which express both endogenous RHAMM FL and truncated RHAMM forms, including small amounts of RHAMM ⌬163 (Fig. 1, A and B). In the mouse, these RHAMM proteins are 95 and 70 kDa, respectively. As noted previously for the other cell types (23,29), these endogenous RHAMM proteins decorated the poles of mitotic spindles in 10T1/2 fibroblasts as well as the length of interphase microtubules ( Fig.  2A). Primary wild type MEF expressed lower levels of RHAMM protein than 10T1/2 fibroblasts, and expression was most easily detected in these primary cells by mRNA analysis (Fig. 1B,  graph). Analysis showed that the predominant RHAMM protein was full length. Therefore, immortalized RHAMM Ϫ/Ϫ MEF lines (22) were transfected with either RHAMM FL or RHAMM ⌬163 to compare the tubulin binding properties of both RHAMM protein forms. Expression of these two RHAMM forms in transfected cells was confirmed with quantitative PCR and immunohistochemistry (Fig. 1, B, graph, and  C). When photographed at the same laser intensity, primary RHAMM Ϫ/Ϫ MEF as well as immortalized RHAMM Ϫ/Ϫ MEF lines exhibited large bundles of brightly staining interphase microtubules in contrast to the interphase microtubules of either immortalized RHAMM-rescued lines or primary wild type MEF, which stained less brightly (Fig. 2B). Primary and immortalized RHAMM Ϫ/Ϫ MEF exhibited a high frequency of multi-pole mitotic spindles ( Fig. 2B and supplemental Fig. 1A) and chromosome misalignment on these aberrant spindles. Expression of RHAMM FL rescued both interphase microtubule abnormalities and mitotic spindle/chromosome segregation defects (Fig. 2B). These results suggested that, in addition to decorating microtubule structures, RHAMM plays an essential and nonredundant role in microtubule integrity.
RHAMM Associates with Both Interphase and Mitotic Spindle Microtubules-Previous studies identified microtubule-binding sequences in both exon 4 and 16 of RHAMM FL (Fig. 1A) (23,29). In these studies, deletion of amino acids 1-103 resulted in loss of RHAMM on interphase microtubules and its accumulation in the nucleus (23). An additional microtubule-binding site was identified in the carboxyl terminus of RHAMM that co-immunoprecipitated with ␥-tubulin (29) and mediated an association with centrosomes and mitotic spindles (24,29). This second binding site contained a leucine zipper (mouse, 728 L-KDENSQLKSEVSKL 742 ), which was required for decoration of RHAMM on mitotic spindles (28,29). These collective results were interpreted as evidence that the two tubulin-binding sequences of RHAMM FL performed separate functions; the amino-terminal sequence was proposed to regulate interphase microtubules, and the carboxyl-terminal sequence was proposed to regulate mitotic spindle/centrosome integrity.
To confirm this separation of tubulin-binding sites, we first prepared Myc-tagged amino-terminal truncations of RHAMM FL that lacked the tubulin-binding site in exon 4 (e.g. RHAMM ⌬373 , Fig. 3A, and RHAMM ⌬163 , data not shown). These constructs were expressed in 10T1/2 fibroblasts, and their ability to decorate interphase and mitotic spindle microtubules was assessed with immunofluorescence assays (Fig. 3A, interphase microtubules shown). Results unexpectedly showed that the carboxyl-terminal tubulin-binding region alone was sufficient to locate RHAMM to both interphase and mitotic spindle microtubules. The Myc tag did not modify the association of RHAMM with microtubules because untagged truncated RHAMM cDNAs expressed in RHAMM Ϫ/Ϫ MEF also decorated interphase microtubules (data not shown). These results predicted that the leucine zipper bound to both interphase and spindle microtubules, raising the possibility that short RHAMM forms such as RHAMM ⌬163 affect interphase and mitotic spindle microtubules by a common mechanism. FIGURE 2. RHAMM decorates microtubules and its expression affects microtubule structures. A, RHAMM decorates interphase microtubules and mitotic spindles. Immunofluorescence staining with anti-RHAMM exon 8-specific polyclonal antibodies was used to analyze RHAMM expression and distribution in 10T1/2 cells. Tubulin was detected by staining with an anti-␣tubulin antibody. RHAMM co-distributes with tubulin in interphase microtubules of 10T1/2 fibroblasts. RHAMM also co-localizes with tubulin in mitotic spindle microtubules (lower three panels) of 10T1/2 cells and is particularly concentrated at the spindle apex. Images were taken on a Zeiss confocal microscope. B, immunofluorescence staining of RHAMM Ϫ/Ϫ , RHAMM FL -rescued and wild type MEF shows that microtubules stain more brightly in RHAMM Ϫ/Ϫ MEF than in either RHAMM-rescued or wild type MEF (images were taken at the same laser setting). Small inset in image of RHAMM-rescued MEF shows tubulin staining taken at higher laser setting. Nuclei of RHAMM Ϫ/Ϫ MEF are often larger and cells more highly spread than RHAMMrescued cells. RHAMM loss also results in aberrant mitotic spindle formation and defective chromosome alignment/segregation compared with RHAMMrescued or wild type MEFs. Arrows indicate poles of mitotic spindles. Images were taken with an Olympus confocal microscope at ϫ40 magnification.
RHAMM ⌬163 Promotes Microtubule Instability-Because loss of RHAMM expression resulted in the appearance of brightly staining, large microtubule networks (e.g. Fig. 2B), we assessed the possibility that RHAMM expression affects microtubule stability. Stability was compared in primary RHAMM Ϫ/Ϫ and wild type MEF by quantifying resistance of interphase microtubules to disruption by nocodazole and by measuring ␣-tubulin acetylation levels, the latter used as a marker for stable microtubules. Interphase microtubules of primary RHAMM Ϫ/Ϫ MEF were more resistant to disruption by nocodazole than wild type MEF (Fig. 3B and supplemental Fig. 2). ␣-Tubulin was also significantly more acetylated in primary and immortalized RHAMM Ϫ/Ϫ MEF compared with immortalized RHAMM-rescued MEF (Fig. 4A) and primary wild type MEF (Fig. 4B). The expression of RHAMM containing either one (RHAMM ⌬163 ) or two (RHAMM FL ) microtubule-binding sites rescued this RHAMM Ϫ/Ϫ microtubule phenotype equally well (Fig. 4, A and B), predicting that the carboxyl-terminal mitotic spindle/tubulin-binding site was able to mediate interphase microtubule interactions.
Spindle microtubules resemble their interphase counterparts in that they are dynamically regulated, at least in part, by similar mechanisms. To further characterize the mitotic functions of RHAMM ⌬163 and to assess if RHAMM expression affected mitotic spindle stability, we quantified mitotic processes that reflect the dynamic nature of mitotic microtubules such as spindle integrity (10,35,36), chromosome segregation (37), and abscission during cytokinesis (38) in immortalized RHAMM Ϫ/Ϫ , RHAMM ⌬163 , and RHAMM FL -rescued MEF (Figs. 5 and 6 and supplemental Fig. 3). The occurrence of bipole versus multi-pole spindles and abnormal chromosome alignment on the mitotic spindle were used as indicators of aberrant spindle formation (35). Abnormal cytokinesis was detected by time-lapse analysis of mitotic cells (31) and by the presence of multinucleated cells.
Immortalized RHAMM Ϫ/Ϫ MEF exhibited a high percentage (almost 40% of mitotic cells) of multi-pole spindles, and this defect was most strongly reduced by the expression of RHAMM FL (Fig. 5) and, interestingly, to a lesser extent by expression of RHAMM ⌬163 (data not shown). Chromosome segregation was aberrant on multiple pole spindles, and this defect was also rescued by expression of RHAMM FL (e.g. Fig. 5). A similar finding was observed when primary RHAMM Ϫ/Ϫ MEF were compared with primary wild type MEF (supplemental Fig. 1B). Large multinucle-FIGURE 3. Myc-RHAMM ⌬373 binds to interphase microtubules, and loss of RHAMM expression increases interphase microtubule resistance to nocodazole. A, 10T1/2 cells were transfected with a RHAMM expression construct lacking the first amino-terminal 373 amino acids (aa) (RHAMM ⌬373 ). To distinguish between expression of the transfected construct from endogenous RHAMM, RHAMM ⌬373 included an amino-terminal Myc epitope tag. RHAMM ⌬373 -transfected 10T1/2 cells were stained with Myc tag (green) and anti-␣-tubulin (red) antibodies. RHAMM ⌬373 and ␣tubulin co-localize on interphase microtubules (yellow). Images were taken with a Zeiss confocal at ϫ40 magnification. B, nocodazole resistance of interphase microtubules is increased in RHAMM Ϫ/Ϫ MEF. Primary wild type and RHAMM Ϫ/Ϫ MEF were exposed to 3 ng/ml nocodazole or buffer containing DMSO alone. Soluble and insoluble protein fractions were isolated and separated on a 10% SDSpolyacrylamide gel. The amount of ␣-tubulin in both fractions was quantified by Western analysis using an ␣-tubulin antibody. Values represent the mean Ϯ S.E. of n ϭ 6 samples Statistical significance was assessed by a Student's t test, and significant results (p Ͻ 0.01) are marked by asterisks.

FIGURE 4. Stability of interphase microtubules is modified by RHAMM expression and by activated MEK1.
A, acetylated and total tubulin levels in 50% confluent RHAMM Ϫ/Ϫ , RHAMM ⌬163 -rescued, and RHAMM MEK1 -rescued MEF were detected by Western analysis using anti-␣-acetylated tubulin and ␣-tubulin antibodies. Graph shows the ratio of acetylated tubulin to total tubulin. B, comparison of microtubule stability between primary RHAMM Ϫ/Ϫ and wild type MEF. 50% confluent wild type and RHAMM Ϫ/Ϫ MEF were serum-starved overnight in defined medium. 30 min after stimulation with 10% FBS, total protein was isolated, and levels of acetylated and total ␣-tubulin levels were determined by Western analysis. Values in both A and B are the mean Ϯ S.E. of n ϭ 3 replicates. Statistical significance was assessed by a Student's t test, and significant results (p Ͻ 0.01) are marked by asterisks. ated cells were common in RHAMM Ϫ/Ϫ MEF populations, and their presence was reduced by either RHAMM FL or RHAMM ⌬163 expression ( Fig. 6 and supplemental Fig. 3B). Timelapse analysis of RHAMM Ϫ/Ϫ MEF revealed a high percentage of cells with aberrant abscission during cytokinesis (supplemental Fig. 3). Abscission defects ranged from failure of the cleavage furrow to form in mitotic cells, resulting in giant multinuclear cells, to formation of multiple cleavage furrows, resulting in many small daughter cells, most of which lacked nuclei. These defects were equally rescued by the expression of RHAMM FL or RHAMM ⌬163 . Collectively, data suggested that RHAMM was required for regulating stability of interphase and mitotic microtubules and that this function resided in the carboxylterminal 728 LKDENSQLKSEVSKL 742 microtubule-binding site.
RHAMM Directly Binds to ␣and ␤-Tubulin-To begin to identify the mechanisms by which the carboxyl terminus of RHAMM affected interphase and mitotic spindles, we identified binding partners for 728 LKDENSQLKSEVSKL 742 . We first determined that recombinant RHAMM fragments containing this sequence (supplemental Fig. 4A) bound equally well to both soluble tubulin and pelleted, taxol-stabilized microtubules (supplemental Fig. 4B). We subsequently used soluble tubulin extracts for our assays. ␣and ␤-tubulins are common to both mitotic spindle and interphase microtubules, whereas ␥-tubulin is uniquely present in centrosomes and mitotic spindles (5, 6). We therefore first performed pulldown assays using recombinant carboxyl-terminal RHAMM fragments (supplemental Fig. 4A) and 10T1/2 fibroblast lysates. MALDI-TOF analysis was performed on isolated proteins that were separated on SDS-PAGE. Analysis showed that RHAMM ⌬163 bound to ␣and ␤-tubulin (data not shown). ␥-Tubulin was not detected in these assays, although this may have been due to limiting amounts in 10T1/2 cell lysates relative to the other tubulin isoforms. To assess if interactions were direct or indirect, pulldown assays were performed using purified ␣and ␤-tubulin heterodimers and a recombinant RHAMM(706 -767) fragment linked to Sepharose beads (Fig. 7A). Bound proteins were separated on SDS-PAGE and identified using anti-␣ or ␤-tubulin antibodies with Western blots. Sepharose-GST served as a negative control. RHAMM(706 -767) bound to tubulin heterodimers (Fig. 7A), whereas GST alone did not. The ability of truncated RHAMM forms that are represented in cells (e.g.  RHAMM ⌬163 and RHAMM ⌬373 ) to bind directly to these tubulin isoforms was confirmed with a far-Western assay using soluble ␣and ␤-tubulin heterodimers as probes (supplemental Fig. 4C). The laddering of recombinant RHAMM proteins in the assay shown in supplemental Fig. 4C was due to protease activity. The interaction between recombinant RHAMM(706 -767) and tubulin heterodimers was strongly reduced by the presence of a synthetic peptide (LKDENSQLKSEVSKL) mimicking the RHAMM carboxyl-terminal leucine zipper (Fig. 7B).
Collectively, these results indicated that the interaction between the carboxyl-terminal binding site in RHAMM and tubulin was direct and mediated by the highly conserved mitotic spindle binding 728 LKDENSQLKSEVSKL 742 sequence (28,29).

MEK1/ERK1/2 Mediate the Effects of RHAMM on Interphase and Mitotic
Microtubules-We next investigated how RHAMM ⌬163 affected microtubule stability. Previous studies had suggested RHAMM FL directly modified tubulin stability by promoting polymerization, similar to many other MAPs (23). To assess this possibility, the ability of GST-RHAMM to modify formation of taxol-stabilized tubulin polymers was assessed in vitro (supplemental Fig. 5). Recombinant RHAMM ⌬163 and RHAMM ⌬373 fragments did not significantly increase or decrease the amount of pelleted microtubules. These results suggested that RHAMM fragments such as RHAMM ⌬163 indirectly affected microtubule stability.
Although a direct role for ERK1/2 in somatic cell centrosome-driven mitosis is still controversial (40 -42), the above results and evidence that ERK1/2 phosphorylate protein substrates during G 2 /M (43) prompted us to examine the role of these kinases in RHAMM-mediated events of mitosis. Mitotic spindle integrity, chromosome segregation, and cytokinesis fidelity were compared in immortalized RHAMM Ϫ/Ϫ MEF following stable expression of either RHAMM FL or mutant active MEK1. Mutant MEK1 increased ERK1/2 activity as expected (data not shown) (22), reduced the frequency of cells with multi-pole mitotic spindles, and restored bi-pole spindles similar to that observed with RHAMM-rescue (Fig. 5). Activated MEK1 also restored the fidelity of cytokinesis in immortalized RHAMM Ϫ/Ϫ MEF to the same degree as RHAMM-rescue, as detected by time-lapse analyses and quantification of multinucleated cells (Fig. 6 and supplemental Fig. 3). However, despite promoting normal mitotic spindle morphology, activated MEK1 did not restore normal chromosome alignment and seg- FIGURE 7. RHAMM binds directly to heterodimeric ␣-, ␤-tubulin. A, pulldown assays were performed using Sepharose-GST-RHAMM(706 -767) and purified ␣-, ␤-tubulin heterodimers. Tubulin that bound to RHAMM was identified with Western blots using an anti-pan-tubulin antibody. IB, immunoblot. B, binding of GST-RHAMM(706 -767) to tubulin heterodimers is blocked by a synthetic peptide mimicking the leucine zipper (mouse, Leu 728 -Leu 742 ), which is required for an association of RHAMM with the mitotic spindle. Pulldown assays using Sepharose-GST-RHAMM(706 -767) and tubulin heterodimers were performed in the presence of varying amounts of synthetic peptide. Values in the graph are the mean Ϯ S.E. of n ϭ 3 separate experiments. Asterisks denote statistical significance (Student's t test, p Ͻ 0.01).
regation on the mitotic plate to the extent of RHAMM-rescue (e.g. Fig. 5).
RHAMM Binds Directly to ERK1 and Mutation of Its ERK Docking Sequence Phenocopies RHAMM Loss-Our previous work showed that cell surface RHAMM regulated ERK1/2 activation through an association with the integral hyaluronan receptor, CD44 (22,27). To exclude a possible involvement of cell surface RHAMM-activated ERK1/2 in controlling microtubule dynamics, we added recombinant RHAMM ⌬163 beads to RHAMM Ϫ/Ϫ MEF and quantified their effect on mito-sis using time-lapse analysis (22). Extracellular RHAMM ⌬163 did not rescue the mitotic defects of immortalized RHAMM Ϫ/Ϫ MEF (data not shown) indicating that cell surface activation of ERK1/2 through RHAMM was not sufficient for driving alterations in microtubule dynamics. These and data described above raised the possibility that intracellular RHAMM proteins, in particular RHAMM ⌬163 , scaffolded MEK1/ERK1/2 to tubulin.
Protein kinase-anchoring proteins generally bind directly to their target kinase (44). We therefore determined if GST-RHAMM bound directly or indirectly to MEK1, ERK1, and ERK2 recombinant proteins using pulldown assays. Surprisingly, only ERK1 bound directly to recombinant RHAMM ⌬163 (Fig. 8B) suggesting that previously noted interactions of RHAMM with MEK1 and ERK2 were indirect (e.g. Fig. 9C). Binding to ERK1 was specific in that soluble GST-RHAMM competed with ERK1/RHAMM bead interactions (Fig. 8B). Examination of the RHAMM ⌬163 sequence revealed a highly conserved MAPK "D" docking site (Fig. 8A). These sites are composed of positively charged and hydrophobic clusters of amino acids separated by 2-6 amino acids and are common to many of ERK1/2 scaffolds and substrates (45). To determine whether the sequence Lys 721 -Leu 728 acted as a docking site for ERK1, we used two experimental approaches. In the first approach, both Lys 721 and Lys 727 were mutated to Glu 721 and Glu 728 , and recombinant mutant GST-RHAMM was assayed for binding to ERK1 in pulldown assays; binding was reduced by ϳ50% (Fig. 8C). In the second approach, a synthetic peptide containing the putative D-site sequence (His 715 -Gln 745 , Fig. 8A) was used to compete for RHAMM ⌬163 /ERK1 interactions (Fig. 8B). This peptide reduced binding of ERK1 to RHAMM ⌬163 by ϳ90% (Fig. 8C). Unrelated synthetic RHAMM peptides (Fig. 8A) had no effect on binding (Fig. 8C) and served as controls.
Because intracellular hyaluronan/RHAMM interactions have been suggested to play a role in mitosis (46), the above mutant RHAMM ⌬163 protein was assessed for its hyaluronan binding ability. Mutant RHAMM ⌬163 retained an ability to bind to biotinyl- ated hyaluronan consistent with evidence that Val 747 -Lys 750 are essential for this interaction (47,48), and peptide His 715 -Gln 745 did not block binding of biotinylated hyaluronan to recombinant RHAMM ⌬163 (data not shown). These results allowed us to clearly interpret a role of direct RHAMM ⌬163 /ERK1 interactions in microtubule dynamics in cells. We therefore next assessed if the D-site also mediated binding of ERK1 to RHAMM in cells. The association of ERK1 and MEK1 with RHAMM ⌬163 and the ERK1 docking mutant RHAMM ⌬163 (Fig.  8A) was compared by immunoprecipitation assays following transient expression of these RHAMM constructs in 10T1/2 cells (Fig. 1B) (33). ERK1/MEK1 co-associated with RHAMM ⌬163 but not with the mutant RHAMM ⌬163 (Fig. 9A) confirming that the D-site was necessary for ERK1/MEK1/ RHAMM interactions in cells.
We then assessed if RHAMM ⌬163 anchored ERK1/2 to microtubules, providing these MAPKs with access to their microtubule MAPs, which then directly modified microtubule dynamics. To begin to assess this possibility, mutant RHAMM ⌬163 was expressed in H-RAS-transformed 10T1/2 cells, which exhibited high levels of microtubule-associated, active ERK1/2 (34). We expected that mutant RHAMM ⌬163 would behave as a dominant negative suppressor of endogenous RHAMM proteins because RHAMM proteins dimerize and trimerize (data not shown) and because we successfully blocked the hyaluronan binding function of cell surface RHAMM with this approach (32,33). ␣and ␤-tubulin heterodimers were immunoprecipitated, and associated active ERK1/2 (p-ERK1/2) were detected with Western blots. Expression of mutant RHAMM ⌬163 in H-RAS-transformed 10T1/2 fibroblasts resulted in loss of detectable phospho-ERK1/2 from tubulin (Fig. 9B). Total cellular levels of p-ERK1/2 were also reduced in mutant RHAMM ⌬163 -transfected cells, and therefore values were normalized by calculating the percent of tubulin-associated p-ERK1/2 to total cellular p-ERK in both cell lines (Fig. 9B, graph). Expression of mutant RHAMM ⌬163 thus reduced the percentage of tubulin-associated p-ERK1/2 by ϳ2.5-fold. We next assessed if mutant RHAMM ⌬163 also affected acetylated tubulin levels. Although acetylated tubulin levels were low in H-RAS or RHAMM ⌬163 10T1/2 fibroblasts, the expression of mutant RHAMM ⌬163 in H-RAS 10T1/2 fibroblasts strongly increased levels of ␣-tubulin acetylation (Fig. 10,  A and B). These results were consistent with a model in which intracellular RHAMM ⌬163 functioned as an adaptor protein that bound directly to ERK1 and to tubulin but indirectly to MEK1/ERK2, thus targeting this activated kinase complex to microtubules, which phosphorylated MAPs to modify microtubule stability (Fig. 9C).

DISCUSSION
Our data suggest that RHAMM proteins control the structure of interphase and mitotic spindle microtubules and that these effects are driven by MEK1/ERK1/2 kinase activity. Previous reports had established an involvement of ERK1/2 in interphase microtubule dynamics resulting from their ability to phosphorylate both microtubule-stabilizing and -destabilizing proteins such as MAP and stathmin (49,50). Our results additionally and unexpectedly reveal a role for MEK1 in restricting multi-pole mitotic spindles and promoting normal cytokinesis during mitosis. Evidence presented in this study further suggests that RHAMM/MEK1-ERK1/2 complexes affect microtubule function by promoting their dynamic instability. We therefore propose that RHAMM targets and anchors MEK1/ERK1/2 to tubulin, where these MAPKs phosphorylate the tubulin-associated proteins that regulate microtubule dynamics (5). Because the dynamic nature of microtubules has been linked to functions associated with cancer progression, including cell cycle progression and motility/invasion, our results raise the possibility that microtubules are an important oncogenic target of transforming RHAMM protein forms such as RHAMM ⌬163 .
The ERK1/2 MAPKs decorate both interphase microtubules and poles of mitotic spindles (50 -53) and modify interphase microtubule stability (34). Although ERK1/2 kinase activity is clearly required for progression through G 1 /S, the direct versus indirect role of these kinases in somatic cell mitosis (G 2 /M) is still controversial (40,41,51). On the one hand, proteomic analyses have identified G 2 /M targets for ERK1/2 kinases (43), and blocking MEK1 with kinase inhibitors can result in aberrant mitotic spindles and a G 2 /M block (50,51,53). On the other hand, acute blocking of MEK1 activity during mitosis to prevent the direct substrate effects of this kinase pathway resulted in very minor consequences to mitosis and in particular did not influence mitotic spindle integrity of treated cells (41). The authors of this last study (41) concluded that the MEK1/ERK1/2 kinase pathway controls expression of genes necessary for progression through G 2 /M (e.g. cdc25C (42) and cyclinB1/cdc-2 (54)) but does not play a major role in normal G 2 /M by directly phosphorylating substrates. Although RHAMM may affect events in mitosis by MEK1/ERK1/2-regulated gene expression, it also appears to have direct effects on mitotic spindles because its addition to Xenopus egg extracts controls mitotic spindle pole formation and number (28). Further studies will be required to dissect the roles of direct versus indirect effects of RHAMM- FIGURE 9. Mutation of RHAMM ⌬163 D-site reduces RHAMM/ERK1 interactions and association of p-ERK1/2 with tubulin. A, native and mutant (loss of ERK docking) RHAMM ⌬163 were expressed in 10T1/2 fibroblasts, and the association of RHAMM with ERK1 and MEK1 was assessed by immunoprecipitation (IP) using anti-RHAMM antibodies. Although native RHAMM ⌬163 immunoprecipitates with ERK1, ERK2 (data not shown), and MEK1, mutant RHAMM ⌬163 does not. Immunoprecipitations using anti-ERK1 and nonimmune IgG were used as positive and negative controls, respectively. B, H-RAS-transformed cells express high levels of endogenous RHAMM ⌬163 and display abundant tubulin-associated p-ERK1/2, as detected by immunoprecipitation assays using anti ␣-tubulin antibodies. Expression of mutant RHAMM ⌬163 , which acts as a dominant negative suppressor of endogenous RHAMM ⌬163 function, ablates the association of p-ERK1/2 with tubulin. Densitometry values represent the mean Ϯ S.E. of n ϭ 4 samples. Asterisks denote statistical significance (Student's t test, p Ͻ 0.01). C, diagram of proposed interactions among RHAMM, MEK1, ERK1/2 and tubulin. RHAMM is predicted to scaffold MEK1/ERK1/2 to tubulin in mitotic spindle and interphase microtubules. RHAMM binds directly to ERK1 through its D-site and to tubulin through its carboxyl-terminal leucine zipper but indirectly complexes with MEK1 and ERK2 via as yet unidentified proteins or as a result of a direct association of ERK1 with both MEK1 and ERK2.

H-RAS
H-RAS/mutant RHAMM ∆163 FIGURE 10. Interactions of RHAMM ⌬163 with ERK1 are required for microtubule instability in H-RAS-transformed cells. A, immunofluorescence using acetylated tubulin-specific antibodies in parental 10T1/2 cells and in 10T1/2 cells transfected with either RHAMM ⌬163 or H-RAS shows that expression of these two proteins reduces microtubule stability. Expression of mutant RHAMM ⌬163 in H-RAS-transformed cells blocks the effect of RAS on microtubules. Images were taken with a Zeiss confocal microscope at ϫ40 magnification. B, acetylated ␣-tubulin is quantified by densitometry analysis of Western blots. As predicted from immunofluorescence images, expression of either H-RAS or oncogenic RHAMM ⌬163 significantly reduces acetylated ␣-tubulin levels relative to parental 10T1/2 cells, whereas conversely, expression of mutant RHAMM ⌬163 restores acetylated ␣-tubulin to parental 10T1/2 levels. Values represent the mean Ϯ S.E. of n ϭ 3 assays. Statistical significance was assessed using a Student's t test, and statistically significant results (p Ͻ 0.01) are marked by an asterisk. MEK1-ERK1/2 complexes in mitotic spindle integrity of somatic cells.
Mitotic spindle formation is driven by multiple, cooperative microtubule nucleation and capture sites. Centrosomes play a dominant role in microtubule capture in somatic cells but are absent from germ cells and plant cells. Cells lacking centrosomes form mitotic spindles in a chromatin-dependent manner, a process that requires formation of Ran-GTP gradients (36,55,56). However, Ran-GTP gradients are also thought to provide kinetic stimulus but not the driving force for mitotic spindle formation in somatic cells that contain centrosomes (55). Intracellular RHAMM proteins have, to date, been most strongly implicated in Ran-dependent spindle assembly (28). Intriguingly, Ran, like RHAMM, is overexpressed in human cancers in vivo, and a number of human cancer cell lines exhibit dependence on Ran-GTP for successful mitosis. Silencing Ran expression in tumor cells results in aberrant mitotic spindle formation and apoptosis, whereas mitosis and survival of normal cell lines are largely unaffected (57,58). Therefore, Randirected mitosis may predominate in diseased and/or stressed tissues, and RHAMM may also participate in spindle formation under these conditions. This possibility is consistent with evidence that RHAMM expression is primarily limited to tissue injury and neoplasia, that it associates with TPX2, a spindle pole protein required for Ran-driven mitosis (24), and that Ran-directed mitosis requires several ERK1/2 substrates, including Survivin (57) and Ran-binding protein (59 -61).
The physiological and pathological processes that require RHAMM for cell division in vivo are understudied. RHAMM Ϫ/Ϫ mice are fertile and adults do not have obvious defects that can be associated with aberrant cell proliferation during embryogenesis or adult homeostasis. Loss of RHAMM reduces desmoid tumor initiation and invasion in a mouse model of tumor susceptibility, but the consequences of RHAMM loss on tumor cell division was evident only when cell-cell contact was limited in culture (62). Furthermore, although cell division was not the major focus of the study, differences in mesenchymal cell proliferation during excisional skin wound repair of RHAMM Ϫ/Ϫ versus wild type siblings were not observed (22). Thus, a major challenge for future studies will be to define the conditions under which RHAMM plays a role in mitosis in vivo.
In this study, RHAMM loss resulted in a high percentage of multi-pole spindles in mitotic cells. These results are consistent with a previous study showing that microinjection of functionblocking RHAMM antibodies also promoted multi-pole spindles (24). However, an in vitro study utilizing Xenopus egg or HeLa cell extracts showed that excess carboxyl-terminal RHAMM protein fragments promoted multiple spindle poles, whereas anti-RHAMM antibodies focused spindle poles in Ran-driven spindle formation. These effects depended upon the presence of BRCA1-BARD1 complexes, which were proposed to block the pole-stimulating function of RHAMM protein (28). This apparent discrepancy (28) with both our present results and those of Maxwell et al. (24) predicts that the mitotic functions of RHAMM are complex and may depend upon cell background, RHAMM protein levels, and possibly RHAMM isoform expression. For example, our results showing that RHAMM controls several apparently mechanistically distinct processes during mitosis is consistent with functional complexity. Thus, RHAMM loss affects not only spindle integrity but also chromosome segregation and cytokinesis, whereas the effects of RHAMM on spindle integrity and cytokinesis are mediated by MEK1, chromosome segregation appears to be mediated through other mechanisms.
In conclusion, we show that RHAMM associates with both interphase and mitotic spindle microtubules by directly binding to ␣and ␤-tubulin through a highly conserved leucine zipper in its carboxyl terminus. This interaction promotes dynamic instability of interphase microtubules and is associated with mitotic spindle defects that can also arise from altered microtubule stability. These RHAMM-mediated effects require MEK1/ERK1/2 activity. Because RHAMM binds directly to both ␣/␤-tubulin and ERK1, and complexes with MEK1/ERK2, we propose that intracellular carboxyl-terminal fragments of RHAMM perform scaffolding functions linking active MEK1/ ERK1/2 to their microtubule substrates.