Structural and functional basis of plasminogen activation by staphylokinase.

Staphylokinase (Sak), a 15.5-kDa bacterial protein, forms a complex with human plasmin, which in turn activates other plasminogen molecules to plasmin. Three recombinant DNA-based approaches, (i) site directed substitution with alanine, (ii) search for proximity relationships at the complex interface, and (iii) active-site accessibility to protease inhibitors have been used to deduce a coherent docking model of the crystal structure of Sak on the homology-based model of microplasmin (microPli), the serine protease domain of plasmin.

Arginine 719 in human plasminogen mediates formation of the staphylokinase:plasmin activator complex.

Staphylokinase (Sak), a 16-kDa bacterial protein, forms a 1:1 stoichiometric complex with the serine proteinase domain of human plasmin, which in turn converts other plasminogen molecules into plasmin. To identify amino acid residues critical for generating the Sak:plasmin activator complex, alanine-scanning mutagenesis was performed on phage-displayed micro-plasminogen (microPlg). Substitution of Arg719 with Ala [microPlg(R719A)] disrupted complex formation, although the sensitivity of phage-displayed microPlg(R719A) to activation by urokinase and the amidolytic activity of the micro-plasmin derivative [microPli(R719A)] remained unaffected.

Enzymatic properties of phage-displayed fragments of human plasminogen.

Two low-molecular-mass forms of human plasminogen, plasminogen-(543-791)-peptide (micro-plasminogen), comprising the serine protease domain, and plasminogen-(444-791)-peptide (mini-plasminogen), which in addition contains kringle 5, were displayed on filamentous phage by fusion to the N-terminus of the minor coat protein pIII, to levels of 0.5 molecules micro-plasminogen-pIII/phage particle and 0.1 molecules mini-plasminogen-pIII/phage particle.