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Licensed Unlicensed Requires Authentication Published by De Gruyter June 1, 2005

Activation of proPHBSP, the Zymogen of a Plasma Hyaluronan Binding Serine Protease, by an Intermolecular Autocatalytic Mechanism

  • Michael Etscheid , Andreas Hunfeld , Herbert König , Rainer Seitz and Johannes Dodt
From the journal Biological Chemistry

Abstract

The hyaluronic acid binding serine protease (PHBSP), an enzyme with the ability to activate the coagulation factor FVII and the plasminogen activator precursors and to inactivate factor VIII and factor V, could be isolated from human plasma in the presence of 6m urea as a single-chain zymogen, whereas under native conditions only its activated two-chain form was obtained. The total yield of proenzyme (proPHBSP) was 5–6 mg/l, corresponding to a concentration of at least 80–100nm in plasma. Upon removal of urea, even in the absence of charged surfaces a rapid development of amidolytic activity was observed that correlated with the appearance of the two-chain enzyme. The highest activation rate was observed at pH 6. ProPHBSP processing was concentration-dependent following a second order kinetic and was accelerated by catalytic amounts of active PHBSP, indicating an intermolecular autocatalytic activation. Charged macromolecules like poly-L-lysine, heparin, and dextran sulfate strongly accelerated the autoactivation, suggesting that in vivo proPHBSP activation might be a surface-bound process. The intrinsic activity of the proenzyme was determined to be 0.25–0.3%, most likely due to traces of PHBSP. The presence of physiological concentrations of known plasma inhibitors of PHBSP, like α2 antiplasmin and C1 esterase inhibitor, but not antithrombin III/heparin, slowed down zymogen processing. Our in vitro data suggest that the autoactivation of proPHBSP during plasma fractionation is induced by the removal of inhibitors of PHBSP and is accelerated by charged surfaces of the chromatographic resins.

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Published Online: 2005-06-01
Published in Print: 2000-12-18

Copyright © 2000 by Walter de Gruyter GmbH & Co. KG

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