Cyclo19,31[D-Cys19]-uPA19-31 is a potent competitive antagonist of the interaction of urokinase-type plasminogen activator with its receptor (CD87).

Urokinase-type plasminogen activator (uPA) represents a central molecule in pericellular proteolysis and is implicated in a variety of physiological and pathophysiological processes such as tissue remodelling, wound healing, tumor invasion, and metastasis. uPA binds with high affinity to a specific cell surface receptor, uPAR (CD87), via a well defined sequence within the N-terminal region of uPA (uPA19-31). This interaction directs the proteolytic activity of uPA to the cell surface which represents an important step in tumor cell proliferation, invasion, and metastasis. Due to its fundamental role in these processes, the uPA/uPAR-system has emerged as a novel target for tumor therapy. Previously, we have identified a synthetic, cyclic, uPA-derived peptide, cyclo19,31uPA19-31, as a lead structure for the development of low molecular weight uPA-analogues, capable of blocking uPA/uPAR-interaction [Burgle et al., Biol. Chem. 378 (1997), 231-237]. We now searched for peptide variants of cyclo19,31uPA19-31 with elevated affinities for uPAR binding. Among other tasks, we performed a systematic D-amino acid scan of uPA19-31, in which each of the 13 L-amino acids was individually substituted by the corresponding D-amino acid. This led to the identification of cyclo19,31[D-Cys19]-uPA19-31 as a potent inhibitor of uPA/uPAR-interaction, displaying only a 20 to 40-fold lower binding capacity as compared to the naturally occurring uPAR-ligands uPA and its amino-terminal fragment. Cyclo19,31[D-Cys19]-uPA19-31 not only blocks binding of uPA to uPAR but is also capable of efficiently displacing uPAR-bound uPA from the cell surface and to inhibit uPA-mediated, tumor cell-associated plasminogen activation and fibrin degradation. Thus, cyclo19,31[D-Cys19]-uPA19-31 represents a promising therapeutic agent to significantly affect the tumor-associated uPA/uPAR-system.

A novel type of bifunctional inhibitor directed against proteolytic activity and receptor/ligand interaction. Cystatin with a urokinase receptor binding site.

Cancer invasion and metastasis is a process requiring a coordinated series of (anti-)adhesive, migratory, and pericellular proteolytic events involving various proteases such as urokinase-type plasminogen activator (uPA)/plasmin, cathepsins B and L, and matrix metalloproteases. Novel types of double-headed inhibitors directed to different tumor-associated proteolytic systems were generated by substitution of a loop in chicken cystatin, which is nonessential for cysteine protease inhibition, with uPA-derived peptides covering the human uPA receptor binding sequence uPA-(19-31). The inhibition constants of these hybrids toward cysteine proteases are similar to those of wild-type cystatin (K(i), papain (pm), 1.9-2.4; K(i), cathepsin B (nm), 1.0-1.7; K(i), cathepsin L (pm), 0.12-0.61). FACS analyses revealed that the hybrids compete for binding of uPA to the cell surface-associated uPA receptor (uPAR) expressed on human U937 cells. The simultaneous interaction of the hybrid molecules with papain and uPAR was analyzed by surface plasmon resonance. The measured K(D) value of a papain-bound cystatin variant harboring the uPAR binding sequence of uPA (chCys-uPA-(19-31)) and soluble uPAR was 17 nm (K(D) value for uPA/uPAR interaction, 5 nm). These results indicate that cystatins with a uPAR binding site are efficient inhibitors of cysteine proteases and uPA/uPAR interaction at the same time. Therefore, these compact and small bifunctional inhibitors may represent promising agents for the therapy of solid tumors.

Immunological and functional analyses of the extracellular domain of human tissue factor.

Tissue factor (TF) initiates the extrinsic pathway of blood coagulation via formation of an enzymatic complex with coagulation factor VII/VIIa (FVII/VIIa). Although FVII is the only known ligand for TF, several reports in recent years have shown that the function of TF may not be limited to serving as a trigger of coagulation but that TF could also play a role in cellular signaling, metastasis, adhesion and embryogenesis. To explore the loci of the extracellular domain of TF important for its function, we analyzed the functional and immunological epitopes of TF1-219 by the use of both E. coli expressed TF variants encompassing various portions of the extracellular domain of TF and different anti-TF monoclonal antibodies (mAbs). N- and C-terminally truncated TF variants were analyzed for their VIIa-dependent procoagulant activity (PCA). The results obtained are in agreement with previously performed mutant and structural analyses of the interaction of FVII/FVIIa with the extracellular domain of TF. In addition, we observed that combination of two TF variants, Ec-TF1-122 and Ec-TF120-219, yields a soluble and active two-chain TF molecule with remarkable PCA. The reaction patterns of anti-TF mAbs with truncated TF variants and synthetic TF-derived peptides demonstrated that at least three distinct conformation-dependent epitope areas of TF (residues 1-25, 175-202, and 181 -214, respectively) are detected by these mAbs raised against native TF. In fact, mAbs, which are directed to the same epitope area of TF, behave very similar in various applications including immunohistochemistry and clotting tests. Since mAbs directed to the C-terminal epitope area of TF (residues 181-214) influence TF activity independent of FVIIa-binding, this region may be involved in functions of TF distinct from haemostasis.

Inhibition of the interaction of urokinase-type plasminogen activator (uPA) with its receptor (uPAR) by synthetic peptides.

Focusing of the serine protease urokinase-type plasminogen activator (uPA) to the cell surface via interaction with its specific receptor (uPAR, CD87) is an important step for tumor cell invasion and metastasis. The ability of a synthetic peptide derived from the uPAR-binding region of uPA (comprising amino acids 16-32 of uPA; uPA(16-32)) to inhibit binding of fluorescently labeled uPA to uPAR on human promyeloid U937 cells was assessed by quantitative flow cytofluorometric analysis (FACS) and compared to the inhibitory capacities of other synthetic peptides known to interfere with uPA/uPAR-interaction. An about 3000-fold molar excess of uPA(16-32) resulted in 50% inhibition of pro-uPA binding to cell surface-associated uPAR. Using a solid-phase uPA-ligand binding assay employing recombinant soluble uPAR coated to microtiter plates, the minimal binding region of wild-type uPA was determined. The linear peptide uPA(19-31) and its more stable disulfide-bridged cyclic form (cyclo(19,31)uPA(19-31)) displayed uPAR-binding activity whereas other peptides such as uPA(18-30), uPA(20-32) or uPA(20-30) did not react with uPAR. Cyclic peptide derivatives of cyclo(19,31)uPA(19-31) in which certain amino acids were deleted and/or replaced by other amino acids as well as uPAR-derived wild-type peptides did also not inhibit uPA/uPAR-interaction. Therefore, the present investigations identified cyclo(19,31)uPA(19-31) as a potential lead structure for the development of uPA-peptide analogues to block uPA/uPAR-interaction.