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Regulation of 5?1 integrin conformation and function by urokinase rece
http://www.100md.com 《细胞学杂志》
     1 Department of Medicine and Pulmonary and Critical Care Division, University of California, San Francisco, San Francisco, CA 94143

    2 Department of Cell Biology, The Scripps Research Institute, La Jolla, CA 92037

    3 Structural Biology Program, Massachusetts General Hospital, Charlestown, MA 02129

    4 Wellcome Trust Centre for Cell-Matrix Research, School of Biological Sciences, University of Manchester, Manchester M13 9PT, England, UK

    Correspondence to Harold A. Chapman: halchap@itsa.ucsf.edu; or Ying Wei: yingwei@itsa.ucsf.edu

    Urokinase-type plasminogen activator receptors (uPARs), up-regulated during tumor progression, associate with ?1 integrins, localizing urokinase to sites of cell attachment. Binding of uPAR to the ?-propeller of 3?1 empowers vitronectin adhesion by this integrin. How uPAR modifies other ?1 integrins remains unknown. Using recombinant proteins, we found uPAR directly binds 5?1 and rather than blocking, renders fibronectin (Fn) binding by 5?1 Arg-Gly-Asp (RGD) resistant. This resulted from RGD-independent binding of 5?1–uPAR to Fn type III repeats 12–15 in addition to type III repeats 9–11 bound by 5?1. Suppression of endogenous uPAR by small interfering RNA in tumor cells promoted weaker, RGD-sensitive Fn adhesion and altered overall 5?1 conformation. A ?1 peptide (res 224NLDSPEGGF232) that models near the known -chain uPAR-binding region, or a ?1-chain Ser227Ala point mutation, abrogated effects of uPAR on 5?1. Direct binding and regulation of 5?1 by uPAR implies a modified "bent" integrin conformation can function in an alternative activation state with this and possibly other cis-acting membrane ligands.

    Abbreviations used in this paper: ERK, extracellular signal–regulated kinase; Fn, fibronectin; LIBS, ligand-induced binding site; Ln-5, laminin-5; PAI-1, plasminogen activator inhibitor-1; RGD, Arg-Gly-Asp; siRNA, small interfering RNA; suPAR, soluble uPAR; Tet, tetracycline; uPA, urokinase-type plasminogen activator; uPAR, uPA receptor; Vn, vitronectin.

    Introduction

    The urokinase-type plasminogen activator receptor (uPAR) plays important roles in cell adhesion and migration and chemotaxis, as well as tumor metastasis, by virtue of its interactions with the urokinase-type plasminogen activator (uPA), vitronectin (Vn), and integrins (Degryse et al., 2001; Ahmed et al., 2003; Sturge et al., 2003). Because of the capacity of uPAR to bind both integrins and uPA, this receptor contributes to matrix remodeling and cell migration in part by focusing plasmin activation to sites of cell attachment (Chapman and Wei, 2001). It has also become clear that uPAR–integrin complexes can transduce intracellular signals. Several groups have reported that the binding of uPA to uPAR stimulates intracellular signaling (Aguirre-Ghiso et al., 2003; Tarui et al., 2003; Sitrin et al., 2004), and much of this signaling is consistent with an integrin-mediated pathway. In addition, uPAR expression by itself, independently of uPA, has been reported to mediate extracellular signal–regulated kinase (ERK) activation. Recently, Czekay et al. (2003) showed that plasminogen activator inhibitor-1 (PAI-1) can detach cells by binding to the uPA present in uPA–uPAR–integrin complexes on the cell surface. Although the mechanism remains uncertain, these investigators found that PAI-1 not only detached cells from Vn, but also from fibronectin (Fn) and type-1 collagen. This influence of PAI-1 on integrin function, via uPAR, may be related to the consistent findings that high PAI-1 is an independent risk factor for tumor metastasis (Andreasen et al., 1997). Together, this body of evidence indicates uPAR–integrin interactions likely have physiological and pathobiological importance.

    Previous reports have indicated that uPAR can physically interact with multiple integrins including ?1 and ?2 integrins (Xue et al., 1997; Pluskota et al., 2003). We previously identified uPAR as an integrin ligand because a binding site for uPAR on the integrin M?2 mapped to the ligand-binding region of its ?-propeller (Simon et al., 2000). Among ?1 integrins, uPAR directly associates with 3?1 via a surface loop within the ?-propeller (W4 BC loop), but outside the laminin-5 (Ln-5) binding region. uPAR is also able to associate with 5?1 (Aguirre-Ghiso et al., 1999; Wei et al., 2001) and to regulate 5?1-mediated cell migration to Fn (Yebra et al., 1999), 5?1 signaling (Aguirre-Ghiso et al., 2003; Tarui et al., 2003), and Fn matrix assembly (Monaghan et al., 2004).

    Integrin 5?1 is among many members of the integrin family that recognize an Arg-Gly-Asp (RGD) motif within their ligands (Takagi et al., 2003). Peptides containing this motif can efficiently block these integrin–ligand interactions (Arnaout et al., 2002). 5?1 integrin and Fn form a prototypic integrin/ligand pair (Takagi et al., 2003), functionally important because it mediates Fn adhesion and Fn matrix assembly, which is vital to many cell functions in vivo (Cukierman et al., 2001). This integrin is also shown to play a key role in promoting tumor angiogenesis and tumor metastasis (Jin and Varner, 2004). In addition to the RGD sequence present in Fn type III module 10, a set of residues present in the Fn type III module 9 (synergy site) contribute to high affinity recognition by 5?1 (Redick et al., 2000). The COOH-terminal heparin-binding site (HepII) of Fn also plays an important role in regulating cell adhesion, migration, Fn fibrillogenesis, signal transduction, and organization of focal adhesions and cytoskeleton (Huang et al., 2001; Kim et al., 2001). The interaction of cells to the HepII domain is currently thought to operate through proteoglycans such as syndecan 4 (Kim et al., 2001) and integrin 4?1 (Mould and Humphries, 1991).

    To date, little is known of the molecular mechanism by which uPAR regulates 5?1-mediated function. In this report, the effect of uPAR on 5?1-mediated adhesion, migration, and Fn matrix assembly was investigated. Surprisingly, using recombinant proteins, we found that direct binding of uPAR to 5?1 does not change overall integrin binding to Fn, but changes integrin conformation, subsequently forming an additional binding site on Fn, which is RGD independent. In the course of this work a ?1 peptide sequence was discovered that blocks all uPAR/?1 function. Mapping of this peptide near the known -chain site of uPAR–?1 interaction confirms this region of ?1 integrins as an important regulatory site and suggests a molecular basis for PAI-1–mediated cell detachment. Positioning of the uPAR-binding site near the Fn-binding site of 5?1 not only promotes 5?1 interactions with Fn, but allows PAI-1 to reverse Fn binding, empowering a mechanism of cell migration on Fn in either a protease-rich or protease inhibitor–rich milieu.

    Results

    PAI-1 mediates cell detachment by reversing ligand binding to ?1 integrins

    PAI-1 can detach cells from Vn and Fn by binding to uPA present in uPA–uPAR–integrin complexes on the cell surface (Czekay et al., 2003). However, the mechanism of detachment is uncertain. To explore a possible mechanism, we took advantage of a recently described point mutant of the Ln-5 receptor, 3?1, incapable of uPAR interaction but fully capable of Ln-5 adhesion and signaling (Zhang et al., 2003). This mutation, His245Ala, allowed us to test the hypothesis that PAI-1 acts directly on matrix-engaged 3?1 by binding to uPA–uPAR complexes bound to 3?1 and not through indirect effects mediated by another integrin. Mouse kidney epithelial cells expressing wt 3?1 (wt 3) attach to Ln-5– or Fn-coated surfaces, and this attachment is not reversed by the presence of uPA or uPA–PAI-1 complexes (Fig. 1 A). Co-expression of human uPAR in these cells (wt 3/U) resulted in marked sensitivity of matrix attachment to the presence of uPA–PAI-1, as predicted by prior studies of Czekay et al. (2003). However, epithelial cells bearing the H245A 3 mutation (mut 3), although attaching normally to Ln-5, failed to detach from Ln-5 in the presence of uPA–PAI-1 complexes whether or not there was coexpression of uPAR. In contrast, mut 3 cells expressing uPAR (mut 3/U) adhered to Fn and detached >80% in the presence of uPA–PAI-1. Similar results were obtained in at least three separate experiments. These data indicate that matrix detachment initiated by uPA–PAI-1 requires uPAR interaction with the specific integrin that is matrix engaged. If so, this finding raises the possibility that uPA–PAI-1 directly affects matrix ligand binding to uPAR–integrin complexes, resulting in cellular detachment. This possibility was tested in HT1080 fibrosarcoma cells, cells known to express uPAR and bind Fn through 5?1 (Xue et al., 1997). The binding of biotinylated, soluble III 9-11 (Fn type III repeats 9–11, containing the RGD integrin-binding site) to HT1080 cells was almost completely blocked when cells were pretreated with active uPA and PAI-1 during the 4°C binding assay (Fig. 1 B). These results indicate that uPA–PAI-1 complexes interfere with ?1 integrin ligand binding in a uPAR-dependent manner.

    Figure 1. uPAR and ligand-engaged integrin are required for uPA–PAI-1 mediated matrix detachment. (A) Cell detachment from Ln-5 and Fn. 96-well plates were coated with Fn or Ln-5 and blocked with BSA. Wt 3, wt 3/U, mut 3, or mut 3/U cells were allowed to attach for 1.5 h, were acid washed, and then were incubated with uPA, PAI-1, or PAI-1 followed by uPA. The wells were washed as described in Materials and methods, and the number of remaining attached cells was determined. Each column is expressed as a percentage of the control (acid washed only; 100%). n = 3. (B) Biotin-III 9-11 Fn fragment binding to HT1080 cells. HT1080 cells were acid washed and incubated with or without uPA, or with uPA followed by PAI-1. The cells were then incubated with biotinylated III 9-11. After washing, the cells were lysed and the bound biotin III 9-11 was detected by avidin-HRP. The densitometry of the bands was quantified and graphed. All the steps were done at 4°C. Each column is expressed as a percentage of the control (100%). Data shown are representative from three independent experiments with similar results. (C) Effect of uPA–PAI-1 on purified 5?1 binding to Fn. Recombinant 5?1-Fc integrin was analyzed by Western blotting with peroxidase-conjugated anti–human Fc antibody. The 5-Fc and ?1-Fc proteins are shown as an inset. Nunc high binding plates precoated with Fn were incubated with 5?1-Fc with or without suPAR in the presence of 1 mM Mn2+. Increasing amounts of uPA–PAI-1 mixture were then added. Bound 5?1-Fc was detected by protein A–HRP and quantified by OD at 490 nm. Data are expressed as specific binding (total binding subtract the binding to BSA-coated wells). n = 3. Each experiment was done with triplicate determinations.

    To explore this finding further, we performed Fn-binding assays using recombinant purified soluble 5?1 and uPAR. Recombinant 5?1-Fc fusion protein was expressed in HEK 293 cells and purified using protein A–agarose beads (Coe et al., 2001). The 5?1-Fc fusion was found to bind to Fn-coated surfaces (Fig. 1 C) and the binding is Mn2+-dependent (unpublished data). Integrin 5?1 binding to Fn was not affected by the presence of either uPA–PAI-1 complexes or soluble uPAR (suPAR). However, in the presence of suPAR, increasing amounts of uPA–PAI-1 complexes progressively blocked 5?1 binding to Fn (Fig. 1 C). Addition of uPA or PAI-1 separately had no effect on Fn binding. In additional experiments, biotinylated suPAR could also be shown to bind to immobilized 5?1-Fc, as expected (unpublished data). Together, these data indicate that uPAR binds 5?1, and such binding modifies 5?1 integrin binding to Fn and enables PAI-1 to release Fn from 5?1 through uPAR-bound uPA. All of these events can happen on the extracellular domains of the integrin independent of cell signaling.

    These observations imply that uPAR can interact with at least two and possibly multiple ?1 integrins, suggesting the involvement of the common ?1-chain itself in uPAR binding. Moreover, the direct effect of uPA–PAI-1 on Fn binding to uPAR–5?1 suggests the uPAR-binding site may be positioned close to the Fn-binding site. As demonstrated in Fig. 2 A, an energy-minimized model of integrin 5?1 structure was generated based on the atomic coordinates of the v?3 crystal structure (Xiong et al., 2001). Recently, we have found that the blade 4 BC loop of the proposed ?-propeller structure of integrin 3 is important for uPAR association (Wei et al., 2001). The corresponding BC loop in the 5?1 model is highlighted in red. Inspection of the model reveals two loops on the ?1-chain (224NLDSPEGGF232 in yellow, 262FHFAGDGKL270 in purple) that are very close to the blade 4 BC loop of the ?-propeller (in red). We hypothesized that the two ?1-chain loops may also be involved in integrin–uPAR association. The alignment of these ?1-chain sequences with that of other integrin ?-chains is shown in Fig. 2 B. Interestingly, the NH2-terminal Asn 224 in ?1P1 has been implicated in bonding to the Asp (D) of RGD in the v?3 crystal, placing these loops very close to the putative RGD-binding pocket of 5?1. This could potentially explain the direct effect of uPA–PAI-1 on Fn binding to uPAR–5?1.

    Figure 2. Model of 5?1 structure and homologous sequence alignment. (A) An energy-minimized model of integrin 5?1 structure was developed based on the atomic coordinates of v?3 crystal structure (Xiong et al., 2001). The putative W4 BC loop (NLTY) of the predicted ?-propeller structure of the 5-chain (blue) is marked in red. The two ?1 peptides ?1P1 and ?1P2 from ?1-chain (gray) are indicated in yellow and purple, respectively. Both side and top view of the model are shown. (B) The sequence alignment of the two ?1 peptide regions in ?1-chain shows homologies among different ?-chains. ?1P1 peptide is underlined yellow and ?1P2 purple. In the 3?1 model, these are the two ?1 sequences closest to the reported 3 interaction site with uPAR (W4 BC loop of the ?-propeller structure). Asterisk highlights Ser227 within the ?1P1 sequence because only the ?1-chain contains this Ser and a SerAla point mutation in the ?1P1 peptide was made and used in some experiments.

    uPAR associates with 5?1 and changes Fn adhesion properties

    To explore whether the ?1 loops discussed above are involved in uPAR and 5?1 interactions, a series of Fn adhesion experiments were performed. Kidney epithelial cells used in Fig. 1 and their uPAR cotransfectants were again used. The adhesion of these cells to Fn is mediated to a large extent by the 5?1 integrin because the adhesion can be completely blocked by an 5?1-blocking antibody 5H10-27 (unpublished data). The observation that uPAR associates with 3?1 integrin (Wei et al., 2001) and the complex mediates RGD-independent cell adhesion to Vn (unpublished data) prompted us to test whether adhesion of uPAR-expressing cells to Fn can be inhibited by RGD peptides. Surprisingly, overexpression of uPAR strikingly increased cell adhesion to Fn in the presence of RGD-containing peptides (Fig. 3 A). Indeed up to 1 mM RGD had no discernible affect on adhesion of uPAR-expressing cells to Fn. By contrast, the adhesion of non-uPAR–expressing cells to Fn was totally abolished by 500 μM RGD peptides. The RGD-resistant adhesion of uPAR-expressing cells was observed at all Fn concentrations supporting adhesion (0.5–5 μg/ml; Fig. S3, available at http://www.jcb.org/cgi/content/full/jcb.200404112/DC1). The ?1 peptides had no effect on Fn adhesion of non-uPAR–expressing cells at any concentration tested, but 400 μM of either of the two ?1 peptides completely inhibited cell adhesion to Fn in uPAR-expressing cells. The scrambled peptides had no effect (Fig. 3 A). The dose inhibition effect of one of the two ?1 peptides (?1P1) on adhesion to Fn is shown in Fig. 3 B.

    Figure 3. uPAR binding to 5?1 changes the Fn-binding mechanism. (A) Adhesion to Fn. mut 3 (–uPAR), or mut 3/U (+uPAR) cells pretreated with different peptides were plated on Fn and cell adhesion was measured as described in Materials and methods. RGD and RAD: 500 μM; ?1 peptides: 400 μM. A representative of three independent experiments with triplicate wells is shown. (B) Dose effect of ?1P1 peptide on Fn adhesion. Wt 3/U cells were seeded on Fn-coated wells with ?1P1 peptide (50–400 μM) and the adhesion was assessed as above. Data are expressed as percentage of control (no peptide added). n = 3. (C) Effect of ?1P1 peptide on uPAR–5?1 complex formation. HT1080 cells were lysed in 1% Triton X-100 lysis buffer and the lysates were incubated with peptide ?1P1, its scrambled control (sc?1p1), or left untreated. Lysates were immunoprecipitated (P1D6) and the lysates and immunoprecipitates separated by SDS-PAGE and blotted for uPAR (R2) and integrin 5. Data shown are representative of three independent experiments. White lines indicate that intervening lanes have been spliced out. (D) Biotin-suPAR binding to 5?1–Fn complex. 20 nM biotinylated suPAR was added to Fn-coated wells and incubated with or without 5?1-Fc or 5?1SA-Fc (20 μg/ml). The bound biotin-suPAR was detected by avidin-HRP and Fn-bound integrin was detected by Protein A–HRP. "–" represents the background binding on Fn or BSA. Both are quantified by measuring OD at 490 nm. n = 3.

    Because the ?1 peptide sequence contains a natural Ser227Ala polymorphism, inviting a mutational analysis, we explored the functional properties of this peptide in more detail. We tested the effect of the ?1P1 peptide on the biochemical association of 5?1 and uPAR. HT1080 cell lysates were immunoprecipitated with 5 antibodies in the presence of ?1P1 or its scrambled control, and the presence of uPAR was determined by immunoblotting. As indicated in Fig. 3 C, uPAR could be reliably coprecipitated with 5?1 and this association was completely blocked by the functionally active peptide, suggesting residues 224–232 in the ?1-chain are involved in uPAR–5?1 physical association. To test this point further, a 5?1-Fc fusion protein containing the entire extracellular domains of 5?1 was expressed in which Ser227 was mutated to Ala (5?1SA-Fc). As shown in Fig. 3 D, the 5?1SA-Fc fusion was found to bind Fn identically to wt. We verified that recombinant biotinylated suPAR bound to 5?1-Fc/Fn, but not appreciably to Fn alone. However, the Ser227 to Ala mutant integrin (5?1SA-Fc) totally lost interaction with uPAR, indicating that Ser227 on the integrin ?1-chain, and by inference the 224–232 ?1 peptide loop, is critical for uPAR association.

    uPAR binding to 5?1 induces an additional binding site for Fn

    Next, we examined whether the apparent switch in the mechanism of 5?1 adhesion to Fn initiated by the presence of uPAR (Fig. 3 A) was evident with purified proteins. Fn was immobilized and 5?1-Fc binding to Fn was measured by protein A–HRP as before. Fn–5?1 binding in the presence or absence of suPAR is similar (Fig. 4 A), and both can be blocked by an 5-blocking antibody (unpublished data). The binding of 5?1 to Fn in the absence of suPAR was abolished by RGD peptides, as expected, whereas binding in the presence of suPAR was vice versa. Interestingly, the binding of mutant integrin (5?1SA) to Fn remained RGD sensitive in the presence of suPAR (Fig. 4 A). These findings completely recapitulate the pattern seen with live cells and indicate that the presence of uPAR markedly changes the matrix-binding properties of 5?1. This raises two possibilities: uPAR binding switches the integrin-binding site from the central RGD binding domain (III 10) to a different site on Fn. Or, uPAR binding to 5?1 creates an additional binding site for Fn. To determine which possibility is more likely, we made biotinylated RGD peptides and performed binding assays with purified proteins. Binding of biotin-RGD (closed bars) and 5?1-Fc (open bars) to Fn were measured separately and graphed together (Fig. 4 B). In the absence of uPAR, biotin-RGD (0.5 mM) competed with the RGD-binding site on immobilized Fn, blocking 5?1 binding to the plate. However, in the presence of suPAR, biotin-RGD robustly bound to uPAR–5?1–Fn unless 10-fold excess unlabeled RGD was added (Fig. 4 B), strongly suggesting the existence of an additional RGD-independent binding site for Fn. Nevertheless, the RGD-binding site on 5?1 must still be intact in the presence of suPAR, otherwise biotin-RGD would not be able to bind 5?1.

    Figure 4. uPAR–5?1 binds to heparin-binding domain II of Fn. (A) Effect of RGD peptides on wt or mutant 5?1 binding to Fn. Purified 5?1-Fc or mutant 5?1SA-Fc (20 μg/ml) was added to Fn-coated wells in the presence or absence of suPAR and incubated with RGD peptides. The bound 5?1 was detected by protein A–HRP. n = 3. (B) Binding of biotin-RGD to uPAR–5?1–Fn complexes. 20 μg/ml purified 5?1 was allowed to bind immobilized Fn in the presence or absence of 20 nM suPAR. 0.5 mM biotinylated RGD peptides or buffer were then added and incubated without or with excess unlabeled peptides (5 mM). The bound biotin was detected by avidin-HRP and bound 5?1 in parallel plates was detected by protein A–HRP. The data are expressed as absorbance at 490 nm. n = 3. (C) Cell adhesion to Fn fragments. Mut 3 (–uPAR) and mut 3/U (+uPAR) cells were plated in Fn or Fn fragment (III 9-11 or III 12-15)–coated wells and incubated without or with different peptides: RGD or control RAD peptides (500 μM); ?1P1 or control sc?1P1 peptide (400 μM). The attached cells were quantified and the data from a representative experiment are shown. n = 3.

    To determine where the additional binding site interacts on Fn, we examined the effect of uPAR on cell adhesion to Fn fragments in the presence or absence of RGD peptides. Our initial experiments show that adhesion to NH2-terminal 70-kD Fn was RGD-resistant, but unaffected by the presence of uPAR and not blocked by 5 integrin blocking antibodies (unpublished data). Thus, we focused on the Fn type III repeats. Cells with or without uPAR were allowed to attach to immobilized Fn fragments containing type III repeats 9–11 (III 9-11) or type III repeats 12–15 (III 12-15). Cells without or with uPAR expression adhered strongly to the RGD-containing III 9-11 and the adhesion of both cells was blocked by RGD peptides, confirming that the uPAR-expressing cells maintained an RGD-binding site on Fn for 5?1. As expected, ?1P1 had no effect on this adhesion. However, only uPAR-expressing cells attached to III 12-15, and this adhesion was resistant to RGD peptides and now sensitive to the ?1 peptide (?1P1), indicating uPAR induces at least one 5?1-binding site within the COOH-terminal heparin-binding domain of Fn. This additional site conveys RGD resistance to binding of cells to the whole Fn molecule (Fig. 4 C). As expected, the Ser227Ala point mutant peptide (?1P1SA), like scrambled ?1P1, had no effect.

    uPAR alters 5?1 conformation and changes 5?1 integrin–dependent adhesion and detachment in tumor cells

    The above data indicate that binding of uPAR to 5?1 alters integrin conformation and changes its matrix ligand binding properties. To probe this idea further and determine whether uPAR-mediated changes in 5?1 function are observable in nontransfected cells, several tumor cell lines expressing various amounts of uPAR were evaluated. HT1080 (fibrosarcoma), MDA-MB-231 (breast carcinoma), and Skov-3 (ovarian carcinoma) cells were transfected with a small interfering RNA (siRNA) previously shown to suppress uPAR mRNA (Vial et al., 2003) or control and suppression of surface uPAR expression verified 48 h later by FACS analysis (Fig. 5 A). Suppression of surface uPAR had no effect on total ?1 integrin expression (JB1A). However, suppression of uPAR had clear effects on integrin conformation as judged by altered binding of the conformation-sensitive mAbs, HUTS-21, and 9EG7, in all of the cell lines examined. Suppression of surface uPAR was accompanied by increased binding of both HUTS-21 and 9EG7 antibodies (Fig. 5 A), confirming that endogenous uPAR expression modifies integrin ?1-chain conformation.

    Figure 5. Suppression of uPAR expression induces LIBS epitope and changes 5?1-mediated Fn binding in tumor cells. (A) FACS analysis of HT1080, MDA-MB-231, and Skov-3 cells with uPAR (siRNA uPAR) or control siRNA (control) transfection. Cells were harvested 48 h after transfection and incubated with antibodies against uPAR (uPAR), total ?1 (JB1A), or conformation-sensitive ?1 integrin antibodies (HUTS-21, 9EG7), followed by FITC-conjugated secondary antibodies. (B) HT1080 adhesion to Fn. siRNA uPAR or control cells were seeded to Fn-coated wells and incubated with different peptides. All the above experiments were performed at least three times with similar results.

    Are the changes in 5?1 conformation in tumor cells induced by knockdown of uPAR accompanied by changes in mechanism of adhesion? Previous studies show that these cell lines express substantial levels of uPAR and 5?1 integrin (Xue et al., 1997; van der Pluijm et al., 2001). Indeed, we confirmed that Fn adhesion was mainly mediated by 5?1 as the 5-blocking antibody (P1D6) totally blocked the Fn adhesion (unpublished data). To investigate whether increased RGD resistance of Fn adhesion by uPAR expression also exists in nontransfected cells, we tested the relation between uPAR level and Fn adhesion in HT1080, MDA-MB-231, and Skov-3 cells. Because the data from these cell lines are all very similar, we only show results with HT1080 cells (Fig. 5 B). Expression of high levels of endogenous uPAR leads to the expected phenotype when cells are plated on Fn: RGD resistance and ?1 peptide susceptibility. siRNA suppression of uPAR in HT1080 cells, like prior studies with transfected epithelial cells, switched the Fn phenotype to RGD sensitive and ?1 peptide resistant (Fig. 5 B). Furthermore, the noninvasive breast cancer cells MCF-7 and T47D, expressing little uPAR, showed only RGD-sensitive Fn adhesion (Fig. S2, available at http://www.jcb.org/cgi/content/full/jcb.200404112/DC1). These data support the conclusion that the mechanism of Fn adhesion among tumor cells depends upon uPAR expression level.

    uPAR expression promotes 5?1-mediated cell adhesion, migration, and Fn matrix assembly

    When cells are plated on an Fn-coated surface (5 μg/ml) for 1 h, the difference in Fn adhesion between cells with and without surface uPAR is marginal (Fig. 3 A, Fig. 4 C, Fig. 5 B). However, when cells are seeded onto lower amounts of Fn (0.2–5 μg/ml) for shorter periods of time (20 min), adhesion of uPAR-expressing HT1080 cells to Fn was obviously more robust (Fig. 6 A). We repeated similar experiments using MDA-MB-231 (Fig. S1, available at http://www.jcb.org/cgi/content/full/jcb.200404112/DC1) and Skov-3 cells with or without uPAR suppression and found similar results. These findings indicate that uPAR expression not only changes the conformation of 5?1 and how it engages Fn, but together these changes might promote cell adhesion and migration.

    Figure 6. uPAR overexpression enhances Fn fibril formation. (A) HT1080 adhesion to low concentration of Fn. siRNA uPAR or control cells were seeded to Fn (0.2–5 μg/ml)-coated wells and incubated for 20 min. The adhesion was quantified as described in Materials and methods. (B) Top: FACS analysis of uPAR inducible clone Tet-uPAR cells. Both Tet-treated (2 μg/ml; +Tet) and nontreated cells (–Tet) were stained with FITC-conjugated uPAR antibody. n = 8. Bottom: Fn in Tet-uPAR cells. Cells without (–Tet) or with (+Tet) tetracycline induction were lysed with 3% Triton X-100 and centrifuged. Triton-insoluble pellets were then extracted with 2% deoxycholate (DOC) and centrifuged. The insoluble and soluble fractions on different membranes were analyzed by Western blotting using anti–human Fn antibodies. The same samples were blotted for ?-actin to normalize the loading. n = 3. White line indicates that intervening lanes have been spliced out.

    To explore activation of 5?1 by uPAR further, kidney epithelial cells expressing uPAR under a tetracycline (Tet)-inducible promoter were established. In the absence of Tet (–Tet) the cells had little uPAR surface expression, whereas Tet-induced cells (+Tet) showed robust surface uPAR (Fig. 6 B). Initial experiments verified that induction of uPAR produced the same switch in Fn adhesion phenotype observed for stable clones and tumor cells examined above. Although the mechanism of 5?1-mediated Fn attachment changed in the presence of uPAR, immunofluoresence of fixed cells plated on Fn did not reveal discernible changes in the distribution of 5?1 by uPAR induction alone (unpublished data). Nonetheless, +Tet cells produced more cell-associated and deoxycholate-insoluble Fn (Fig. 6 B), indicating that this pool of Fn is much more organized into matrix fibrils in the presence of uPAR.

    To test whether uPAR association with 5?1 affects cell migration, we performed wound assays on tumor cells (HT1080 and MDA-MB-231) and the Tet-responsive cells with or without uPAR induction using RGD and ?1 peptides (?1P1). The cells were seeded onto Fn-coated wells and allowed to form a monolayer before wounding. Preliminary experiments indicated that as little as 20 μM of either the RGD-containing or the ?1P1 peptide suppressed migration. As shown in Fig. 7, both RGD and ?1P1 alone blocked wound closure of HT1080 cells, and the combination of both peptides had a statistically significant greater effect. Similar results were obtained from MDA-MB-231 cells. More importantly, Tet-inducible cells with uPAR expression (+Tet) migrated faster in this assay and the migration was blocked by both RGD and ?1 peptides, whereas cells without uPAR (–Tet) had little migration (unpublished data). Together, these data confirm our findings that uPAR, through its interaction with ?1 integrin(s), promotes cell motility and that this function can be specifically blocked by the ?1-chain peptides identified here.

    Figure 7. RGD and ?1P1 peptides inhibit HT1080 cell wound healing. Serum-starved HT1080 monolayers were wounded and incubated with different peptides (RAD, RGD, sc?1P1, and ?1P1; 20 μM) in DME/0.1% BSA. The wounded areas were imaged at 0 and 24 h using a bright-field imaging system (Spot camera). The migration of HT1080 cells was quantified using SimplePCI software. The percent wound closure of each peptide-treated cell is shown on the right. n = 3. Marked pair (*) shows significant difference by t test (P < 0.006).

    Discussion

    Here, we report evidence that uPAR directly associates with the head domains of integrin 5?1, modifies 5?1 conformation, and creates an additional binding site for Fn, likely within the second Fn heparin-binding domain. Complexes of uPAR and 5?1 are functionally relevant because uPAR binding promotes 5?1-dependent Fn matrix assembly and migration. Importantly, our observations are not based strictly on transfected cells because these features of uPAR–5?1 interaction could be demonstrated in several tumor cell lines expressing endogenous uPAR. Collectively, these functional changes imply 5?1 activation by uPAR binding, as suggested previously by Aguirre-Ghiso et al. (1999). Our studies solidify 5?1 as a binding partner of uPAR and further define the uPAR-binding region on the integrin. The positioning of the uPAR-binding site near the integrin RGD-binding site also reveals a potential mechanism whereby uPAR–5?1 complex formation empowers PAI-1–dependent cell detachment from Fn: while the integrin RGD-binding site remains intact in uPAR–5?1 (Fig. 4), concurrent binding of urokinase and PAI-1 to uPAR now displaces intact Fn or the Fn cell–binding domain (containing RGD) from the integrin (Fig. 1), presumably by steric hindrance.

    The consequences of uPAR–5?1 complex formation contrast with that of other pathways of integrin activation. Available evidence indicates that integrin activation involves a global change in integrin conformation, at least part of which is a change in the orientation of the and ? head domains to better accommodate ligand binding. Several lines of evidence also support a model in which the very "bent" integrin conformation found in the V?3 crystal structure extends to point the head domains away from the cell under activating conditions (Takagi et al., 2002). However, the full range of conformational changes a ligand-bound integrin may assume is uncertain (Mould and Humphries, 2004). It is especially difficult to envision a fully extended conformation of activated integrins acting in cis to engage the much smaller GPI-anchored uPAR at the integrin upper surface. Rather, our findings suggest uPAR–5?1 complexes exhibit an activation state involving a modified bent integrin with distinct functional properties. Similarities and differences between models of "extended" integrin activation and a model consistent with results reported here are summarized in Fig. 8. The model raises the more general possibility that some version of an angled integrin configuration, rather than being inactive, actually functions to promote integrin binding to cis-acting membrane ligands, such as uPAR, which coordinate integrin function with specific cellular needs.

    Figure 8. Model for regulation of 5?1 integrin conformation and function by uPAR binding. Model proposes three basic forms of 5?1 exist on the cell surface: (1) A bent inactive form in the absence of integrin ligand; (2) an extended, active form induced by Fn binding in the absence of uPAR; and (3) a modified bent active form stabilized by uPAR binding, and potentially other cis-acting membrane proteins. In the case of uPAR, the modified bent form engages Fn differently as judged by Fn fragment III 9-11 and III 12-15 binding, altered ?1P1 peptide sensitivity, the reversal of Fn binding by the presence of uPA–PAI-1 complexes, and enhanced Fn matrix assembly.

    The notion that uPAR activates and stabilizes 5?1 has been previously proposed by Ossowski and colleagues based on their studies of human epidermoid carcinoma cell lines. Enhanced adhesion to Fn of tumorigenic (T-HEp-3) over dormant (D-HEp-3) epidermoid cells was directly related to uPAR levels (Aguirre-Ghiso et al., 1999). The high levels of uPAR in human epidermoid carcinoma cells (Hep-3) resulted in increased 5?1-dependent signaling to ERK as well as increased formation of Fn fibrils (Aguirre-Ghiso et al., 2001). Both 5?1-dependent ERK signaling and Fn matrix assembly were decreased in the presence of a uPAR-binding peptide, P25, which blocks uPAR–integrin association, indicating that in these cells ligation of uPAR with P25 inhibited 5?1 function. Similar to these findings, we observed that induction of uPAR expression with Tet in an epithelial cell line increased Fn fibril formation (Fig. 6 B). Conversely, suppression of uPAR expression by RNA interference in many tumor cell lines decreased adhesion (Fig. 6 A, Fig. S1). Additional observations reported here help provide a physical rationale for these and prior functional studies. The current data indicate that uPAR directly binds and changes the conformation and matrix-binding properties of 5?1. The capacity of short ?1-chain peptides to block uPAR–5?1 functions without affecting 5?1-mediated Fn binding itself point to important conformational differences between free and uPAR-bound 5?1. The finding that ?1P1 does not simply convert the function of uPAR–5?1 to that of free 5?1 by dissociating uPAR also suggests that the conformational change incurred by complex formation with uPAR is distinct and perhaps not readily reversible. This is consistent with the hypothesis that bent and extended conformations of 5?1 can function as distinct activation states (Fig. 8).

    This hypothesis is supported by our results, which reveal that suppressing uPAR expression induces ligand-induced binding site (LIBS) epitopes in HT1080, MDA-MB-231, and Skov-3 cells (Fig. 5 A). A recent report also documented increased ?1-chain LIBS epitopes on human skin fibroblasts exposed to a peptide that disrupts uPAR–integrin interactions (Wei et al., 1996; Monaghan et al., 2004). The LIBS antibodies (HUTS-21, 9EG7) used here map to sites near the hinge region of the integrin but far away from the uPAR interaction site. Although these LIBS antibodies are thought to recognize the "active" conformational state of the ?1 subunit that can be induced by ligand binding (e.g., Fn, RGD peptides, by activating antibody TS2/16, or Mn2+), their binding is more sensitive to conformational changes in the hinge, knee, or leg domains than changes near the ligand-binding pocket (Bazzoni et al., 1995; Luque et al., 1996; Mould and Humphries, 2004). We postulate that in uPAR-expressing cells the lower LIBS antibody binding reflects integrin angulation resulting from uPAR–5?1 complex formation. This occurs in spite of "activation" of the integrin as judged by enhanced adhesion and Fn matrix assembly, further supporting the idea that activated integrins could exist in grossly different conformational states depending on the nature of the ligand (Fig. 8).

    Previous studies have shown that initial cell attachment and spreading on Fn is mediated by the interaction of the RGD-containing Fn cell-binding domain (type III repeats 9–10) with 5?1 (Mould et al., 2000; Redick et al., 2000; Takagi et al., 2003), but that further progression of the cytoskeletal response requires additional signals (Hocking et al., 1998; Tarui et al., 2003). Additional binding sites for cells on Fn provide the necessary signals. For example, interaction of cells with the Fn NH2-terminal region can trigger integrin-mediated intracellular signals that are distinct from those generated in response to ligation with the RGD sequence (Forsyth et al., 2002). However, in our assays, adhesion of epithelial cells to this 70-kD fragment was not influenced by uPAR expression and not inhibited by 5?1 blocking antibodies (unpublished data). Signals for cytoskeletal reorganization may also be provided by the interaction of Fn fragments containing the heparin-binding domain (Hep II) (type III repeats 12–14) with cell surface proteoglycans (Huang et al., 2001). In fibroblasts, this response requires two cooperative signals provided by interactions of the RGD sequence with 5?1 integrin and the heparin-binding domain with syndecan-4 (Kim et al., 2001). Our data show that both cells with uPAR or without uPAR adhere to Fn III 9-11 in an RGD-dependent manner, whereas only cells bearing uPAR adhere to Fn III 12-15. The latter cannot be blocked by RGD peptides, but can be blocked by ?1 peptides that disrupt uPAR–?1 integrin interaction (Fig. 4 C). In most uPAR-expressing cells there are likely to be pools of 5?1 both free and bound to uPAR, suggesting that the incorporation of the heparin binding domain into the uPAR–5?1 complex results in distinct signals that lead to enhanced integrin function, as our data show (Fig. 6). We cannot be sure whether uPAR–5?1 complexes possess both Fn-binding sites or binding to both sites in Fn requires free and uPAR-complexed integrin. Future studies may distinguish between these possibilities.

    We have previously reported that uPAR expression in kidney embryonic 293 cells both promotes Vn adhesion through association of uPAR with 3?1 and impairs Fn adhesion mediated by 5?1 (Wei et al., 1996, 2001). Impairment of Fn adhesion in 293 cells appears anomalous with respect to all other cells expressing uPAR examined here and by others (Aguirre-Ghiso et al., 1999). Consistent with this difference, expression of uPAR in 293 cells did not decrease binding of HUTS-21 and 9EG7 antibodies (unpublished data), implying that for some reason uPAR interacts, but not in the same manner, with 5?1 in 293 cells as that seen in other transformed cells. The molecular basis for the anomalous behavior of 293 cells remains to be defined.

    The discovery of the capacity of 5?1 to undergo a phenotypic switch (i.e., RGD vs. ?1P1 dependent; Fig. 8), in Fn attachment may be relevant to attempts to regulate inflammation or tumor progression through integrin inhibition in vivo. uPAR is up-regulated in both inflammatory cells and many tumor cells with a metastatic phenotype. Indeed, uPAR expression is an independent risk factor for tumor metastasis in several clinical studies. RGD-based compounds or peptides have been shown to inhibit integrin function in vivo, but our data imply that one limitation in their use is the complete resistance of ?1 integrins complexed with uPAR from RGD-dependent ligand binding. Vn adhesion mediated by uPAR–3?1 complexes is also RGD-resistant (Wei et al., 1994). Instead, uPAR-bound ?1 integrins are sensitive to ?1 peptides that map to the region of uPAR–integrin interaction. As these ?1 peptides block cell adhesion (Fig. 5 B) and migration of various tumor cells (Fig. 7), it is possible that these reagents, perhaps coupled with RGD-based compounds, have therapeutic potential for suppression of tumor progression.

    Materials and methods

    Reagents and antibodies

    Active human uPA and uPAR mAbs were purchased from American Diagnostica. Active PAI-1 was a gift from Dr. Dan Lawrence (American Red Cross, Rockville, MD). suPAR was supplied by Dr. Gary Deng (Berlex Biosciences). Fn, Vn, and peptides GRGDSPK and GRADSPK were purchased from Sigma-Aldrich. Fn fragment III 9-11 was provided by Dr. Mark H. Ginsberg (The Scripps Research Institute, San Diego, CA). 804G supernatant rich in Ln-5 was a gift from J.C. Jones (Northwestern University Medical School, Chicago, IL). Peptides ?1P1 (NLDSPEGGF), sc?1P1 (EDGLFNPSG), ?1P2 (FHFAGDGKL), sc?1P2 (KDGLFAHFG), and ?1P1SA (NLDAPEGGF) were synthesized at University of California, San Francisco Biomolecular Resources Center and purified by HPLC. The antibodies against active conformation of the ?1 integrins (HUTS-21 and 9EG7), mouse 5-blocking antibody 5H10-27, and Fn mAb were purchased from BD Biosciences. Integrin ?1 mAb (JB1A) was a gift from Dr. John Wilkins (University of Manitoba, Winnipeg, Manitoba, Canada). Blocking antibodies to human integrin 3 (P1B5) and 5 (P1D6) and 5 pAb were purchased from CHEMICON International. HRP-conjugated anti–human Fc antibody was purchased from Jackson ImmunoResearch Laboratories, Inc. uPAR mAb for blotting (R2) was a gift from G. Hoyer-Hansen (Finsen Lab, Copenhagen, Denmark).

    Cell culture

    Mouse kidney epithelial cells expressing wt 3 (a gift from Dr. Jordan A. Kreidberg, Harvard Medical School, Boston, MA) or mut 3 and their uPAR cotransfected cells were cultured in DME as described previously (Wang et al., 1999; Zhang et al., 2003). HEK293, human fibrosarcoma HT1080, breast cancer MCF-7, T47D, and MDA-MB-231 Skov-3 cell lines were obtained from American Type Culture Collection (Rockville, MD) and grown in DME. The Tet-inducible uPAR cells (Tet-uPAR) were maintained in DME supplemented with zeocin, hygromycin, and blasticidin (5 μg/ml). Additional Tet (2 μg/ml) was added to induce uPAR expression. Modified Skov-3 cell line was a gift from Dr. Ernest Lengyel (University of Chicago, Chicago, IL).

    Cell detachment assay

    Microtiter plates were coated with 5 μg/ml Fn or Ln-5 supernatant (1:100) for 18 h at 4°C. The cell detachment assay was performed as described previously (Czekay et al., 2003). In brief, cells attached were acid washed, resuspended in incubation buffer (RPMI, 20 mM Hepes, and 0.02% BSA), and then incubated in the absence or presence of active uPA followed by PAI-1. After wash, the remaining adherent cells were fixed and stained. The amount of extracted stain was quantified by absorbance at 590 nm.

    Cell adhesion assay

    The cell adhesion assay was performed as described previously (Wei et al., 2001). In brief, cells were seeded onto Fn (5 μg/ml) or Fn fragment (10 μg/ml)–coated plates and incubated in DME/0.1% BSA with or without RGD or ?1 peptides for 1 h at 37°C. After washing, attached cells were fixed and stained with Giemsa. The data were quantified by measuring absorbance at 550 nm.

    Biotinylation of suPAR, III 9-11, and RGD peptides

    Human suPAR, Fn fragment III 9-11, or RGD peptides were biotinylated at 0.25 mg/ml using FluoReporter Biotin-XX Protein Labeling Kit (Molecular Probes, Inc.) following the manufacturer's instructions.

    Purification of 5?1-Fc and 5?1SA-Fc integrins

    Integrin 5-Fc and ?1-Fc or Ser227 to Ala mutant ?1SA-Fc constructs (5/pEE12.2hFc and ?1/pV.16hFc or ?1SA/pV.16hFc; Coe et al., 2001) were transfected into 293 cells. Culture supernatant was harvested after 48–72 h and passed through a Protein A–agarose column. Soluble integrin was eluted using 0.1 M glycine, pH 3.0, and neutralized in 1 M Tris-HCl, pH 8.0. Protein-containing fractions were dialyzed, concentrated, and identified by SDS-PAGE.

    Purified protein binding assay

    Nunc high binding microtiter plates were coated with 20 μg/ml Fn and blocked with 1% BSA. 20 μg/ml purified recombinant 5?1-Fc with or without 20 nM purified suPAR was added to each well in PBS with 1 mM MnCl2, and the plates were incubated for 1 h at 25°C. For different purposes, RGD peptides or uPA–PAI-1 mixture may be added together with suPAR. After washing, bound 5?1-Fc was detected by protein A–HRP and quantified by measuring absorbance at 490 nm. Data were expressed as specific binding (i.e., total binding minus the binding to wells coated with BSA alone).

    To test biotinylated RGD peptides binding to Fn–5?1–suPAR, Nunc microtiter plates were coated with Fn and incubated with 5?1-Fc with or without suPAR as above. 0.5 mM biotin-RGD was then added to each well for another hour. After washing, avidin peroxidase was added and the bound biotin-RGD was quantified as described above. To test specificity of binding, 10-fold molar excess nonbiotinylated RGD peptides were added. Biotinylated suPAR binding assay was performed similarly to confirm Fn–5?1–suPAR complex formation.

    uPAR RNA interference

    HT1080 cells were transfected with siRNAs that specifically target the uPAR gene or nonsilencing control and used within 48–72 h. siRNA duplexes were synthesized by in vitro transcription. The sequence of the DNA targeting uPAR is 5'-GGTGAAGAAGGGCGTCCAA-3'. A nonsilencing siRNA 5'-AACCTGCGGGAAGAAGTGG-3' was used as a control (Vial et al., 2003). Synthetic siRNA oligonucleotides were purified with Microspin G-25 columns from Amersham Biosciences.

    FACS analysis

    Cells with or without siRNA uPAR transfection were incubated with primary antibody to active form ?1 integrin (HUTS-21, 9EG7) or to total ?1 integrin (JB1A) and secondary FITC-conjugated anti–mouse IgG or anti–rat IgG (for 9EG7; Sigma-Aldrich) and analyzed on a flow cytometer (FACSCaliber; BD Biosciences). uPAR was detected by a mAb to uPAR.

    Biotin-III 9-11 binding assay

    All the procedures were done at 4°C. HT1080 cells were acid washed and incubated without or with uPA followed by PAI-1. The cells were then incubated with 50 nM biotinylated Fn fragment III 9-11 in RPMI/0.02% BSA for 1 h. After washing, the cells were lysed and the total protein separated by SDS-PAGE. The bound biotin-III 9-11 was detected by avidin-HRP. The bands were quantified and analyzed by densitometry.

    Generation of inducible uPAR clones (Tet-uPAR)

    Wt 3 epithelial cells were transfected with Tet repressor (pcDNA6/TR, blasticidin; Invitrogen) and Tet on an expression construct containing full-length uPAR (pcDNA5/TO, hygromycin; Invitrogen) with a ratio of 6:1. After antibiotic selection, 2 μg/ml Tet was added and uPAR-expressing clones were selected by cell sorting. Tet was removed and the cells resorted for nonexpressing clones. These cells were diluted to select single clones. The data presented in this paper were obtained from one of the representative clones.

    Detection of ECM-associated Fn

    Fn fibrils were detected as described previously (Aguirre-Ghiso et al., 2001). In brief, Tet-uPAR cells without or with Tet induction were lysed with 3% Triton X-100 buffer. Triton-insoluble pellets were treated with DNase and then extracted with 2% deoxycholate buffer. The insoluble and soluble fractions were mixed with sample buffer and analyzed by SDS-PAGE and Western blotting using anti–human Fn antibodies and an antibody to ?-actin.

    Wound healing

    HT1080 cells were grown to confluence on Fn-coated surface. Medium was replaced with DME/0.1% BSA 6 h before wounding. The wound was made using a 1-ml pipet tip. The detached cells were removed by washing and the wounded cells were incubated without or with RGD or ?1 peptides (20 μM) for 24 h. Cells were imaged at 0 and 24 h by phase-contrast videomicroscopy.

    Coimmunoprecipitation

    HT1080 cells were lysed in Triton lysis buffer (50 mM Hepes, pH 7.5, 150 mM NaCl, and 1% Triton X-100) supplemented with protease inhibitors and 1 mM PMSF. Clarified lysates were incubated with or without 400 μM peptide ?1P1 and immunoprecipitated with antibody to integrin 5 (P1D6). The immunoprecipitates were blotted for uPAR (R2) or integrin 5 (pAb).

    Online supplemental material

    The supplemental material (Figs. S1–S3) is available at http://www.jcb.org/cgi/content/full/jcb.200404112/DC1. Fig. S1 shows that suppression of uPAR expression by RNA interference induces LIBS epitope and changes 5?1-mediated Fn binding in MDA-MB-231 cells. Fig. S2 shows the effect of uPAR expression level on Fn adhesion of different breast cancer cell lines. Fig. S3 shows the RGD-resistant adhesion of uPAR-expressing cells on different concentrations of Fn.

    Acknowledgments

    We thank Dr. D. Lawrence for PAI-1, Dr. G. Deng for suPAR, Dr. M.H. Ginsberg for Fn fragment III 9-11, Dr. J.C. Jones for Ln-5, Dr. J.A. Wilkins for ?1 integrin antibody, Dr. G. Hoyer-Hansen for R2 antibody, Dr. E. Lengyel for Skov-3 cells, and Dr. J.A. Kreidberg for the murine epithelial cells.

    This work was supported by National Institutes of Health grants HL44712 (to H.A. Chapman) and HL 31950 (to D.J. Loskutoff).

    Submitted: 20 April 2004

    Accepted: 7 December 2004

    References

    Aguirre-Ghiso, J.A., K. Kovalski, and L. Ossowski. 1999. Tumor dormancy induced by downregulation of urokinase receptor in human carcinoma involves integrin and MAPK signaling. J. Cell Biol. 147:89–104.

    Aguirre-Ghiso, J.A., D. Liu, A. Mignatti, K. Kovalski, and L. Ossowski. 2001. Urokinase receptor and fibronectin regulate the ERKMAPK to p38MAPK activity ratios that determine carcinoma cell proliferation or dormancy in vivo. Mol. Biol. Cell. 12:863–879.

    Aguirre-Ghiso, J.A., Y. Estrada, D. Liu, and L. Ossowski. 2003. ERKMAPK activity as a determinant of tumor growth and dormancy; regulation by p38SAPK. Cancer Res. 63:1684–1695.

    Ahmed, N., K. Oliva, Y. Wang, M. Quinn, and G. Rice. 2003. Downregulation of urokinase plasminogen activator receptor expression inhibits Erk signalling with concomitant suppression of invasiveness due to loss of uPAR-?1 integrin complex in colon cancer cells. Br. J. Cancer. 89:374–384.

    Andreasen, P.A., L. Kjoller, L. Christensen, and M.J. Duffy. 1997. The urokinase-type plasminogen activator system in cancer metastasis: a review. Int. J. Cancer. 72:1–22.

    Arnaout, M.A., S.L. Goodman, and J.P. Xiong. 2002. Coming to grips with integrin binding to ligands. Curr. Opin. Cell Biol. 14:641–651.

    Bazzoni, G., D.T. Shih, C.A. Buck, and M.E. Hemler. 1995. Monoclonal antibody 9EG7 defines a novel ?1 integrin epitope induced by soluble ligand and manganese, but inhibited by calcium. J. Biol. Chem. 270:25570–25577.

    Chapman, H.A., and Y. Wei. 2001. Protease crosstalk with integrins: the urokinase receptor paradigm. Thromb. Haemost. 86:124–129.

    Coe, A.P., J.A. Askari, A.D. Kline, M.K. Robinson, H. Kirby, P.E. Stephens, and M.J. Humphries. 2001. Generation of a minimal 5?1 integrin-Fc fragment. J. Biol. Chem. 276:35854–35866.

    Cukierman, E., R. Pankov, D.R. Stevens, and K.M. Yamada. 2001. Taking cell-matrix adhesions to the third dimension. Science. 294:1708–1712.

    Czekay, R.P., K. Aertgeerts, S.A. Curriden, and D.J. Loskutoff. 2003. Plasminogen activator inhibitor-1 detaches cells from extracellular matrices by inactivating integrins. J. Cell Biol. 160:781–791.

    Degryse, B., S. Orlando, M. Resnati, S.A. Rabbani, and F. Blasi. 2001. Urokinase/urokinase receptor and vitronectin/v?3 integrin induce chemotaxis and cytoskeleton reorganization through different signaling pathways. Oncogene. 20:2032–2043.

    Forsyth, C.B., J. Pulai, and R.F. Loeser. 2002. Fibronectin fragments and blocking antibodies to 2?1 and 5?1 integrins stimulate mitogen-activated protein kinase signaling and increase collagenase 3 (matrix metalloproteinase 13) production by human articular chondrocytes. Arthritis Rheum. 46:2368–2376.

    Hocking, D.C., J. Sottile, and P.J. McKeown-Longo. 1998. Activation of distinct 5?1-mediated signaling pathways by fibronectin's cell adhesion and matrix assembly domains. J. Cell Biol. 141:241–253.

    Huang, W., R. Chiquet-Ehrismann, J.V. Moyano, A. Garcia-Pardo, and G. Orend. 2001. Interference of tenascin-C with syndecan-4 binding to fibronectin blocks cell adhesion and stimulates tumor cell proliferation. Cancer Res. 61:8586–8594.

    Jin, H., and J. Varner. 2004. Integrins: roles in cancer development and as treatment targets. Br. J. Cancer. 90:561–565.

    Kim, J., I. Han, Y. Kim, S. Kim, and E.S. Oh. 2001. C-terminal heparin-binding domain of fibronectin regulates integrin-mediated cell spreading but not the activation of mitogen-activated protein kinase. Biochem. J. 360:239–245.

    Luque, A., M. Gomez, W. Puzon, Y. Takada, F. Sanchez-Madrid, and C. Cabanas. 1996. Activated conformations of very late activation integrins detected by a group of antibodies (HUTS) specific for a novel regulatory region (355-425) of the common ?1 chain. J. Biol. Chem. 271:11067–11075.

    Monaghan, E., V. Gueorguiev, C. Wilkins-Port, and P.J. McKeown-Longo. 2004. The receptor for urokinase-type plasminogen activator regulates fibronectin matrix assembly in human skin fibroblasts. J. Biol. Chem. 279:1400–1407.

    Mould, A.P., and M.J. Humphries. 1991. Identification of a novel recognition sequence for the integrin 4?1 in the COOH-terminal heparin-binding domain of fibronectin. EMBO J. 10:4089–4095.

    Mould, A.P., and M.J. Humphries. 2004. Regulation of integrin function through conformational complexity: not simply a knee-jerk reaction? Curr. Opin. Cell Biol. 16:544–551.

    Mould, A.P., J.A. Askari, and M.J. Humphries. 2000. Molecular basis of ligand recognition by integrin 5?1. I. Specificity of ligand binding is determined by amino acid sequences in the second and third NH2-terminal repeats of the subunit. J. Biol. Chem. 275:20324–20336.

    Pluskota, E., D.A. Soloviev, and E.F. Plow. 2003. Convergence of the adhesive and fibrinolytic systems: recognition of urokinase by integrin M?2 as well as by the urokinase receptor regulates cell adhesion and migration. Blood. 101:1582–1590.

    Redick, S.D., D.L. Settles, G. Briscoe, and H.P. Erickson. 2000. Defining fibronectin's cell adhesion synergy site by site-directed mutagenesis. J. Cell Biol. 149:521–527.

    Simon, D.I., Y. Wei, L. Zhang, N.K. Rao, H. Xu, Z. Chen, Q. Liu, S. Rosenberg, and H.A. Chapman. 2000. Identification of a urokinase receptor-integrin interaction site. Promiscuous regulator of integrin function. J. Biol. Chem. 275:10228–10234.

    Sitrin, R.G., D.R. Johnson, P.M. Pan, D.M. Harsh, J. Huang, H.R. Petty, and R.A. Blackwood. 2004. Lipid raft compartmentalization of urokinase receptor signaling in human neutrophils. Am. J. Respir. Cell Mol. Biol. 30:233–241.

    Sturge, J., D. Wienke, L. East, G.E. Jones, and C.M. Isacke. 2003. GPI-anchored uPAR requires Endo180 for rapid directional sensing during chemotaxis. J. Cell Biol. 162:789–794.

    Takagi, J., B.M. Petre, T. Walz, and T.A. Springer. 2002. Global conformational rearrangements in integrin extracellular domains in outside-in and inside-out signaling. Cell. 110:599–611.

    Takagi, J., K. Strokovich, T.A. Springer, and T. Walz. 2003. Structure of integrin 5?1 in complex with fibronectin. EMBO J. 22:4607–4615.

    Tarui, T., N. Andronicos, R.P. Czekay, A.P. Mazar, K. Bdeir, G.C. Parry, A. Kuo, D.J. Loskutoff, D.B. Cines, and Y. Takada. 2003. Critical role of integrin 5?1 in urokinase (uPA)/urokinase receptor (uPAR, CD87) signaling. J. Biol. Chem. 278:29863–29872.

    van der Pluijm, G., B. Sijmons, H. Vloedgraven, C. van der Bent, J.W. Drijfhout, J. Verheijen, P. Quax, M. Karperien, S. Papapoulos, and C. Lowik. 2001. Urokinase-receptor/integrin complexes are functionally involved in adhesion and progression of human breast cancer in vivo. Am. J. Pathol. 159:971–982.

    Vial, E., E. Sahai, and C.J. Marshall. 2003. ERK-MAPK signaling coordinately regulates activity of Rac1 and RhoA for tumor cell motility. Cancer Cell. 4:67–79.

    Wang, Z., J.M. Symons, S.L. Goldstein, A. McDonald, J.H. Miner, and J.A. Kreidberg. 1999. 3?1 integrin regulates epithelial cytoskeletal organization. J. Cell Sci. 112:2925–2935.

    Wei, Y., D.A. Waltz, N. Rao, R.J. Drummond, S. Rosenberg, and H.A. Chapman. 1994. Identification of the urokinase receptor as an adhesion receptor for vitronectin. J. Biol. Chem. 269:32380–32388.

    Wei, Y., M. Lukashev, D.I. Simon, S.C. Bodary, S. Rosenberg, M.V. Doyle, and H.A. Chapman. 1996. Regulation of integrin function by the urokinase receptor. Science. 273:1551–1555.

    Wei, Y., J.A. Eble, Z. Wang, J.A. Kreidberg, and H.A. Chapman. 2001. Urokinase receptors promote ?1 integrin function through interactions with integrin 3?1. Mol. Biol. Cell. 12:2975–2986.

    Xiong, J.P., T. Stehle, B. Diefenbach, R. Zhang, R. Dunker, D.L. Scott, A. Joachimiak, S.L. Goodman, and M.A. Arnaout. 2001. Crystal structure of the extracellular segment of integrin V?3. Science. 294:339–345.

    Xue, W., I. Mizukami, R.F. Todd III, and H.R. Petty. 1997. Urokinase-type plasminogen activator receptors associate with ?1 and ?3 integrins of fibrosarcoma cells: dependence on extracellular matrix components. Cancer Res. 57:1682–1689.

    Yebra, M., L. Goretzki, M. Pfeifer, and B.M. Mueller. 1999. Urokinase-type plasminogen activator binding to its receptor stimulates tumor cell migration by enhancing integrin-mediated signal transduction. Exp. Cell Res. 250:231–240.

    Zhang, F., C.C. Tom, M.C. Kugler, T.T. Ching, J.A. Kreidberg, Y. Wei, and H.A. Chapman. 2003. Distinct ligand binding sites in integrin 3?1 regulate matrix adhesion and cell–cell contact. J. Cell Biol. 163:177–188.(Ying Wei1, Ralf-Peter Czekay2, Liliane R)