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ABSTRACT: The generation of plasmin by plasminogen (Pg) activators (PAs) is a physiologic process in animals that dissolves blood clots and promotes wound healing, blood vessel growth, and the migration of normal and cancerous cells. Pathogenic bacteria have evolved PAs [e.g., streptokinase (SK) and staphylokinase] that exploit the Pg system to infect animals. Animal PAs have a conserved ability to cleave a wide spectrum of animal Pgs, but the ability of bacterial PAs to cleave different animal Pgs is surprisingly restricted. We show that the spectrum of activity of an archetypal bacterial PA (SK) with animal Pgs can be profoundly altered by mutations that affect intermolecular complementarity at sites that participate in complex formation or substrate binding. Comparative sequence analysis of animal plasmins vs. close structural homologues (trypsin and chymotrypsin) that are not molecular targets for invading bacteria indicates that the sites in plasmin that interact with SK are preferentially targeted for mutation. Conversely, intermolecular contact sites in SKs that activate human Pg are more highly conserved than other loci in the molecule or than the same sites in other SKs that activate non-human Pgs. We propose that active modulation of intermolecular complementarity at sites of contact between SK and Pg may represent a competitive evolutionary strategy in a survival battle, whereby animals seek to evade bacterial invasion, and bacteria endeavor to invade their animal hosts.
Proceedings of the National Academy of Sciences 09/2003; 100(16):9168-72. · 9.68 Impact Factor
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ABSTRACT: There is remarkable homology between the core structures of plasmin, a fibrin clot-degrading enzyme, and factor D, a complement-activating enzyme, despite markedly different biological functions. We postulated that sequence divergence in the loop structures between these two enzymes mediated the unique substrate and inhibitor interactions of plasmin. Recombinant microplasminogens chimerized with factor D sequences at loops 3, 5, and 7 were cleaved by the plasminogen activator urokinase and developed titratable active sites. Chimerization abolished functional interactions with the plasminogen activator streptokinase but did not block complex formation. The microplasmin chimeras showed enhanced resistance (k(i) decreased up to two to three times) to inactivation of microplasmin by alpha(2)-antiplasmin. Microplasmin chimerization had minimal ( approximately 2 fold) effects on the catalytic efficiency for cleavage of small substrates and did not alter the cleavage of fibrin. However, microplasmin and the microplasmin chimeras showed enhanced abilities to degrade fibrin in plasma clots suspended in human plasma. These studies indicate that loop regions of the protease domain of plasmin are important for interactions with substrates, regulatory molecules, and inhibitors. Because modification of these regions affected substrate and inhibitor interactions, loop chimerization may hold promise for improving the clot dissolving properties of this enzyme.
Journal of Biological Chemistry 10/2002; 277(36):33068-74. · 4.77 Impact Factor
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ABSTRACT: Streptokinase (SK) and staphylokinase form cofactor-enzyme complexes that promote the degradation of fibrin thrombi by activating human plasminogen. The unique abilities of streptokinase to nonproteolytically activate plasminogen or to alter the interactions of plasmin with substrates and inhibitors may be the result of high affinity binding mediated by the streptokinase beta-domain. To examine this hypothesis, a chimeric streptokinase, SKbetaswap, was created by swapping the SK beta-domain with the homologous beta-domain of Streptococcus uberis Pg activator (SUPA or PauA, SK uberis), a streptokinase that cannot activate human plasminogen. SKbetaswap formed a tight complex with microplasminogen with an affinity comparable with streptokinase. The SKbetaswap-plasmin complex also activated human plasminogen with catalytic efficiencies (k(cat)/K(m) = 16.8 versus 15.2 microm(-1) min(-1)) comparable with streptokinase. However, SKbetaswap was incapable of nonproteolytic active site generation and activated plasminogen by a staphylokinase mechanism. When compared with streptokinase complexes, SKbetaswap-plasmin and SKbetaswap-microplasmin complexes had altered affinities for low molecular weight substrates. The SKbetaswap-plasmin complex also was less resistant than the streptokinase-plasmin complex to inhibition by alpha(2)-antiplasmin and was readily inhibited by soybean trypsin inhibitor. Thus, in addition to mediating high affinity binding to plasmin(ogen), the streptokinase beta-domain is required for nonproteolytic active site generation and specifically modulates the interactions of the complex with substrates and inhibitors.
Journal of Biological Chemistry 08/2002; 277(30):26846-51. · 4.77 Impact Factor
