Whyte G. Owen

The elastase-mediated pathway of fibrinolysis

Plasmin and elastase degrade fibrin and inhibit the blood coagulation system by degrading key proteins. Elastase can facilitate plasmin expression via an alternative pathway of plasminogen activation. Elastase modifies plasminogen to yield a zymogen that is a better substrate for activators than native plasminogen. Furthermore, elastase inactivates the inhibitor system of plasmin and plasminogen activators without affecting plasmin and plasminogen activators. While plasmin activity develops from a blood zymogen as a consequence of activators synthesized and secreted by endothelium and possibly other cells, elastase is secreted in an active form primarily by polymorphonuclear leukocytes. Plasmin and elastase may play mutual roles in thrombolysis, inflammation, and tumour invasion and metastasis.

High Concentrations of Active Plasminogen Activator Inhibitor-1 in Porcine Coronary Artery Thrombi

Addition of exogenous plasminogen activator inhibitor-1 (PAI-1) to fibrin clots inhibits fibrinolysis in vivo. However, it is unknown whether the localized concentrations of active PAI-1 necessary to produce this antifibrinolytic effect can be recruited to acute arterial thrombi by endogenous mechanisms. We measured PAI-1 activity and antigen in porcine coronary artery thrombi that formed in response to acute vascular injury. Mean PAI-1 activity in thrombi (n = 5) was 36 +/- 5.1 micrograms/mL, which is > 2000 times its concentration in normal porcine plasma. The presence of markedly elevated concentrations of active PAI-1 in thrombi was confirmed by an immunoactivity assay and by demonstrating formation of sodium dodecyl sulfate-stable complexes after addition of 125I-urokinase to thrombus extracts. Comparative analysis of PAI-1 antigen by Western blotting and urokinase inhibition assay suggested that approximately one third of thrombus-associated PAI-1 was active. Histological examination of coronary thrombi revealed that they consisted predominantly of dense aggregates of platelets with interspersed islands of fibrin, which closely resemble the histological appearance of thrombi in patients with myocardial infarction and unstable angina pectoris. Washed porcine platelets prepared from peripheral blood contained sufficient PAI-1 antigen and activity to account for the concentrations observed in coronary artery thrombi. However, the specific activity of human platelet PAI-1 was lower than that of porcine platelet PAI-1 (2% versus 50% active, respectively), and human platelets inhibited in vitro fibrinolysis to a lesser extent than did porcine platelets. These results indicate that active PAI-1 accumulates in porcine coronary artery thrombi in concentrations markedly higher than those present in plasma and that PAI-1 may be an important determinant of the known resistance of platelet-rich thrombi to lysis by tissue-type plasminogen activator. These studies also underscore the importance of considering possible species differences in protein function when comparing animal models of thrombosis to acute coronary thrombosis in humans.

Platelet responses to compound interactions with thrombin.

Catalytic and noncatalytic interactions of thrombin with platelets are investigated with use of thrombin variants with altered specificities and with ligands of thrombin receptors on platelets. Both alpha-thrombin and weakly coagulant meizothrombin-des-fragment-1 (mu-thrombin) hydrolyze proteolytically activated receptor 1 for thrombin (rPAR1(T), recombinant) with catalytic efficiencies of >10(7) M(-)(1) s(-)(1), whereas rPAR1(T) is not a substrate for weakly coagulant beta-thrombin. In contrast, both mu-thrombin and beta-thrombin are weak agonists of platelet dense body (ATP) secretion. Antibodies that block rPAR1(T) cleavage strongly inhibit the secretory reaction to alpha- and mu-thrombins but not to beta-thrombin or to thrombin receptor activating peptide (TRAP). However, catalytically inactive FPR-thrombin, which binds glycoprotein Ib but does not inhibit rPAR1(T) cleavage, inhibits responses to TRAP as well as those to alpha- and mu-thrombins, which indicates that binding of the inactive enzyme to platelets influences the function of PAR1(T). An antibody that inhibits binding of thrombin to platelet glycoprotein Ib inhibits secretory responses to thrombin but not to TRAP, so occupancy of glycoprotein Ib per se accounts for only part of the attenuation. All three thrombins stimulate a rise in cytosolic Ca(II), and the dose response to beta-thrombin is congruent with that for ATP secretion. However, the response of cytosolic Ca(II) is 10-100 times more sensitive to mu-thrombin and alpha-thrombin than ATP secretion is, and is inhibited by neither anti-PAR1(T) Ig nor FPR-thrombin. Thus, alpha-thrombin appears to have an activity not shared by either mu- or beta-thrombins. This activity is owed to more than coupling of independent signals from cleavage of two proteolytically activated receptors, as there is no synergism when mu-thrombin and beta-thrombin costimulate secretion. It is concluded either that alpha-thrombin has a third interaction site on platelets with which neither mu-thrombin nor beta-thrombin interacts or that dual receptors are coordinately cleaved. In either case, the strong secretory response to thrombin appears to be moderated, independently of cytosolic Ca(II), by occupancy of a noncatalytic interaction site such as glycoprotein Ib.

A factor from endothelium facilitates activation of plasminogen by tissue plasminogen activator.

A component extracted from endothelium and partially purified has been found to have a capacity to enhance the rate of plasminogen activation by tissue-type plasminogen activator. The mechanism of action of this cofactor differs from that of others, such as fibrin.