Solution structure of the kringle domain from urokinase-type plasminogen activator.

The solution structure of the kringle domain from urokinase-type plasminogen activator (u-PA) has been determined using 1H nuclear magnetic resonance spectroscopy and dynamical simulated annealing calculations. A total of 35 structures, 20 generated using a distance geometry method prior to simulated annealing and 15 generated using initial random phi, psi values, have been calculated based on 946 experimental nuclear Overhauser effect distance constraints and 48 dihedral angle constraints. Excluding the N- and C-terminal residues (-1 to 12, 77 to 82) and a number of surface residues (M18, G19, S42, D55 to R60, G67) that are disordered or flexible, the root mean square deviation values from the mean structure are 0.49(+/- 0.14) A and 0.65(+/- 0.16) A for the backbone atoms, and 1.03(+/- 0.21) A and 1.39(+/- 0.24) A for all heavy atoms, for the two sets of structures, respectively. An extended binding site for anionic polysaccharides such as heparin has been located on a relatively flat facet of the molecule, involving three consecutive arginines, R57, R58 and R60 (there is a deletion at site 59 of the consensus sequence), which form a cationic triad facing the solvent, and two histidines, H37 and H40, at the opposite end of the molecule. Comparison between the u-PA kringle structure and the crystal and NMR solution structures of tissue-type plasminogen activator kringle 2 has shown that the two proteins have similar global folds but demonstrate a number of local differences.

1H NMR characterization of the urokinase kringle module. Structural, but not functional, relatedness to homologous domains.

The human urokinase (uPA) kringle (K) domain has been characterized via high resolution NMR spectroscopy. The 1H spectrum is analogous to that of the K2 domain of tissue-type plasminogen activator (tPA) and other homologous domains from the plasminogen (Pgn) heavy chain. This indicates a similar folding for the uPA/K. Comparisons of the high-field methyl and aromatic regions of the uPA/K and tPA/K2 spectra against those from the Pgn/K1 and K4 homologues afford the immediate assignment of signals stemming from conserved residues, such as the characteristic high-field shifted Leu46 delta, delta'-methyl doublets, and the aromatic side chains at the hydrophobic core, in particular those from Trp25, His48a, Tyr50, and Trp62. Resonances unresolved due to spectral overlaps in the 1H-1H correlated two-dimensional spectra were identified via a natural abundance 1H-13C single/multiple quantum correlated experiment. Spin systems unique to the uPA/K, such as His7, His37, His40, and His78, were assigned from Overhauser experiments and sequence information. Acid/base titrations of His imidazole signals in 2H2O yielded pKa* (pKa determined from acid/base titration in 2H2O, uncorrected for deuterium isotope effects) values of 6.2 for His7, 6.3 for His37, 6.4 for His40, 4.1 for His48a, and 6.2 for His78, which suggests a significant structural protection for His48a, consistent with a buried location within the hydrophobic core. Binding of low molecular weight heparin to the uPA/K in 2H2O affects mainly the His37, His40, His48a, and Tyr50 resonances, in a concerted and saturable fashion (association constant approximately 58 mM-1). The absence of perturbation of the His7 and His78 side chains indicates that segment 37-50 is selectively sensitive to heparin binding. Thus, the kringle outer B-loop is likely to be proximal to the basic residues responsible for the interaction with the polyanion ligand.

Heparin binding to the urokinase kringle domain.

The binding of urokinase to immobilized heparin and dextran sulfate was studied using activity assays of the bound urokinase. The markedly higher binding observed with high M(r) urokinase compared to low M(r) urokinase indicated a role for the amino-terminal fragment (ATF). This was confirmed by the use of inactive truncated urokinase and monoclonal antibodies specific for the ATF in competition assays of urokinase binding. Antibody competition assays suggested a site in the kringle domain, and a synthetic decapeptide Arg-52-Trp-62 from the kringle sequence (kringle numbering convention) was competitive in assays of urokinase binding to dextran sulfate and heparin. Heparin binding to the urokinase kringle was unambiguously demonstrated via 1H NMR spectroscopy at 500 MHz. Effective equilibrium association constants (K(a)*) were determined for the interaction of isolated kringle fragment and low M(r) heparin at pH 7.2. The binding was strong in salt-free 2H2O (K(a)* approximately 57 mM-1) and remained significant in 0.15 M NaCl (K(a)* approximately 12 mM-1), supporting a potential physiological role for the interaction. This is the first demonstration of a function for the kringle domain of urokinase, and it suggests that while the classical kringle structure has specificity for lysine binding, there may also exist a class of kringles with affinity for polyanion binding.