Urokinase regulates vitronectin binding by controlling urokinase receptor oligomerization

The urokinase plasminogen activator system: a rich source of tumour markers for the individualised management of patients with cancer

The urokinase plasminogen activator (uPA) system consists of the serine protease uPA, the glycolipid-anchored receptor, uPAR, and the 2 serpin inhibitors, plasminogen activator inhibitor-1 (PAI-1) and plasminogen activator inhibitor-2 (PAI-2). Recent findings suggest that uPA, uPAR and PAI-1 play a critical role in cancer invasion and metastasis. Consistent with their role in cancer dissemination, high levels of uPA, PAI-1 and uPAR in multiple cancer types correlate with adverse patient outcome. The prognostic value of uPA/PAI-1 in axillary node-negative breast cancer patients was recently validated using both a prospective randomised trial and a pooled analysis. Assay of uPA and PAI-1 may thus help identify low-risk node-negative patients for whom adjuvant chemotherapy is unnecessary. Finally, emerging data suggest that high levels of uPA and PAI-1 in breast cancer are associated with a preferential response to adjuvant chemotherapy but relative resistance to hormone therapy. The measurement of uPA components, especially in breast cancer, thus has the potential to help with individualised patient management.

The urokinase receptor (uPAR) and the uPAR-associated protein (uPARAP/Endo180): membrane proteins engaged in matrix turnover during tissue remodeling

The breakdown of the barriers formed by extracellular matrix proteins is a pre-requisite for all processes of tissue remodeling. Matrix degradation reactions take part in specific physiological events in the healthy organism but also represent a crucial step in cancer invasion. These degradation processes involve a highly organized interplay between proteases and their cellular binding sites as well as specific substrates and internalization receptors. This review article is focused on two components, the urokinase plasminogen activator receptor (uPAR) and the uPAR-associated protein (uPARAP, also designated Endo180), that are considered crucially engaged in matrix degradation. uPAR and uPARAP have highly diverse functions, but on certain cell types they interact with each other in a process that is still incompletely understood. uPAR is a glycosyl-phosphatidylinositol-anchored glycoprotein on the surface of various cell types that serves to bind the urokinase plasminogen activator and localize the activation reactions in the proteolytic cascade system of plasminogen activation. uPARAP is an integral membrane protein with a pronounced role in the internalization of collagen for intracellular degradation. Both receptors have additional functions that are currently being unraveled. The present discussion of uPAR and uPARAP is centered on their protein structure and molecular and cellular function.

Mapping the Interaction between High Molecular Mass Kininogen and the Urokinase Plasminogen Activator Receptor

The urokinase plasminogen activator receptor (uPAR) is a multifunctional, GPI-linked receptor that modulates cell adhesion/migration and fibrinolysis. We mapped the interaction sites between soluble uPAR (suPAR) and high molecular mass kininogen (HK). Binding of biotin-HK to suPAR was inhibited by HK, 56HKa, and 46HKa with an IC50 of 60, 110, and 8 nm, respectively. We identified two suPAR-binding sites, a higher affinity site in the light chain of HK and 46HKa (His477-Gly496) and a lower affinity site within the heavy chain (Cys333-Lys345). HK predominantly bound to suPAR fragments containing domains 2 and 3 (S-D2D3). Binding of HK to domain 1 (S-D1) was also detected, and the addition of S-D1 to S-D2D3 completely inhibited biotin-HK or -46HKa binding to suPAR. Using sequential and overlapping 20-amino acid peptides prepared from suPAR, two regions for HK binding were identified. One on the carboxyl-terminal end of D2 (Leu166-Thr195) blocked HK binding to suPAR and to human umbilical vein endothelial cells (HUVEC). This site overlapped with the urokinase-binding region, and urokinase inhibited the binding of HK to suPAR. A second region on the amino-terminal portion of D3 (Gln215-Asn255) also blocked HK binding to HUVEC. Peptides that blocked HK binding to uPAR also inhibited prekallikrein activation on HUVEC. Therefore, HK interacts with suPAR at several sites. HK binds to uPAR as part of its interaction with its multiprotein receptor complex on HUVEC, and the biological functions that depend upon this binding are modulated by urokinase.

Dimerization controls the lipid raft partitioning of uPAR/CD87 and regulates its biological functions

The urokinase-type plasminogen activator receptor (uPAR/CD87) is a glycosylphosphatidylinositol-anchored membrane protein with multiple functions in extracellular proteolysis, cell adhesion, cell migration and proliferation. We now report that cell surface uPAR dimerizes and that dimeric uPAR partitions preferentially to detergent-resistant lipid rafts. Dimerization of uPAR did not require raft partitioning as the lowering of membrane cholesterol failed to reduce dimerization and as a transmembrane uPAR chimera, which does not partition to lipid rafts, also dimerized efficiently. While uPA bound to uPAR independently of its membrane localization and dimerization status, uPA-induced uPAR cleavage was strongly accelerated in lipid rafts. In contrast to uPA, the binding of Vn occurred preferentially to raft- associated dimeric uPAR and was completely blocked by cholesterol depletion.

The role of urokinase-type plasminogen activator (uPA)/uPA receptor in HIV-1 infection

The binding of urokinase-type plasminogen activator (uPA) to its glycosyl-phosphatidyl-inositol (GPI) anchored receptor (uPAR) mediates a variety of functions in terms of vascular homeostasis, inflammation and tissue repair. Both uPA and uPAR, as well as their soluble forms detectable in plasma and other body fluids, represent markers of cancer development and metastasis, and they have been recently described as predictors of human immunodeficiency virus (HIV) disease progression, independent of CD4+ T cell counts and viremia. A direct link between the uPA/uPAR system and HIV infection was earlier proposed in terms of cleavage of gp120 envelope by uPA. More recently, a negative regulatory effect on both acutely and chronically infected cells has been linked to the noncatalytic portion of uPA, also referred to as the amino-terminal fragment (ATF). ATF has also been described as a major CD8+ T cell soluble HIV suppressor factor. In chronically infected promonocytic U1 cells this inhibitory effect is exerted at the very late stages of the virus life cycle, involving virion budding and entrapment in intracytoplasmic vacuoles, whereas its mechanism of action in acutely infected cells remains to be defined. Since uPAR is a GPI-anchored receptor it requires association with a signaling-transducing component and different partners, which include CD11b/CD18 integrin and a G-protein coupled receptor homologous to that for the bacterial chemotactic peptide formyl-methionyl-leucyl-phenylalanine. Which signaling coreceptor(s) is(are) responsible for uPA-dependent anti-HIV effect remains currently undefined.

Sequences within domain II of the urokinase receptor critical for differential ligand recognition

The receptor for urokinase-type plasminogen activator (uPAR) plays important roles in a number of physiological and pathological processes by virtue of its interactions with urokinase-type plasminogen activator (uPA), vitronectin (Vn), and several other proteins. The uPA binding site spans all three domains (D1 to D3) of uPAR. However, the nature of the Vn binding site within uPAR is still not clear. In this study, we conducted homolog-scanning mutagenesis on uPAR by switching 14 individual segments of 4-8 residues to their counterpart sequences of a uPAR homolog CD59. All 14 mutants were well expressed, reacted with a panel of monoclonal antibodies, and exhibited correct molecular weights. Of these 14 mutants, six mutants were defective in both uPA and Vn binding. Most importantly, we found two unique mutants uPAR(Asn172-Lys175) and uPAR(Glu183-Asn186) within the D2 domain, which displayed differential ligand binding activity: both had high affinity uPA binding, but completely lost Vn binding, indicating that these two sequences constitute a novel Vn binding site. Indeed, two peptides, P1 (153CPGSNGFHNNDTFHFLKC) and P2 (171CNTTKCNEGPILELENLPQ), derived from the sequences of the identified uPA and Vn binding pockets within D2, respectively, behaved like bona fide ligand binding sites: peptide P1 bound uPA but not Vn, whereas peptide P2 bound Vn and inhibited uPAR-mediated cell adhesion, but did not interact with uPA. Altogether, our data demonstrated that uPAR D2 contains two distinct ligand binding sites for uPA and Vn. Such information will help us better understand the complex roles of uPAR in cell adhesion, migration, and tumor metastasis.

Molecular and functional interdependence of the urokinase-type plasminogen activator system with integrins

The serine protease urokinase-type plasminogen activator (uPA), its inhibitor PAI-1, and its cellular receptor uPA-R (CD87) are of crucial importance during cellular invasion and migration, required for a variety of physio- and pathophysiological processes. It has become increasingly evident in recent years that the uPA/uPA-R-system has far more functional properties than plasminogen activation alone. This is reflected by its involvement in cellular events such as proliferation, adhesion, migration, and chemotaxis. Since uPA-R lacks a transmembrane domain and thus on its own is not capable of transmitting signals into cells, association and functional cooperation with other signaling molecules/receptors is needed. In this respect, one group of adhesion and signaling receptors, the integrins, have been identified which constitute, together with the uPA/uPA-R-system, an interdependent biological network by which the uPA/uPA-R-system broadly affects integrin functions and vice versa. Moreover, there is a growing body of evidence that cellular uPA, uPA-R, and PAI-1 expression is under control of specific ECM/integrin interactions and also that integrins are regulated by components of the uPA/uPA-R-system. By this multifaceted crosstalk, cells may modulate their proteolytic, adhesive, and migratory activities and monitor ECM integrity in their microenvironment.

Molecular mechanisms of glioma invasiveness: the role of proteases

The invasive nature of brain-tumour cells makes an important contribution to the ineffectiveness of current treatment modalities, as the remaining tumour cells inevitably infiltrate the surrounding normal brain tissue, which leads to tumour recurrence. Such local invasion remains an important cause of mortality and underscores the need to understand in more detail the mechanisms of tumour invasiveness. Several proteases influence the malignant characteristics of gliomas--could their inhibition prove to be a useful therapeutic strategy?

Induction of plasminogen activator inhibitor-1 by urokinase in lung epithelial cells

The plasminogen/plasmin system, urokinase-type plasminogen activator (uPA), its receptor (uPAR), and its inhibitor (PAI-1), influence extracellular proteolysis and cell migration in lung injury or neoplasia. In this study, we sought to determine whether tcuPA (two chain uPA) alters expression of its major inhibitor PAI-1 in lung epithelial cells. The expression of PAI-1 was evaluated at the protein and mRNA level by Western blot, immunoprecipitation, and Northern blot analyses. We found that tcuPA treatment enhanced PAI-1 protein and mRNA expression in Beas2B lung epithelial cells in a time- and concentration-dependent manner. The tcuPA-mediated induction of PAI-1 involves post-transcriptional control involving stabilization of PAI-1 mRNA. Inactivation of the catalytic activity of tcuPA had little effect on PAI-1 induction and the activity of the isolated amino-terminal fragment was comparable with full-length single- or two-chain uPA. In contrast, deletion of either the uPA receptor binding growth factor domain or kringle domain (kringle) from full-length single chain uPA markedly attenuated the induction of PAI-1. Induction of PAI-1 by exposure of lung epithelial cells to uPA is a newly recognized pathway by which PAI-1 could regulate local fibrinolysis and urokinase-dependent cellular responses in the setting of lung inflammation or neoplasia.

uPAR: a versatile signalling orchestrator

The plasminogen system has been implicated in clot lysis, wound healing, tissue regeneration, cancer and many other processes that affect health and disease. The urokinase receptor uPAR was originally thought to assist the directional invasion of migrating cells, but it is now becoming increasingly evident that this proteinase receptor elicits a plethora of cellular responses that include cellular adhesion, differentiation, proliferation and migration in a non-proteolytic fashion.