ALBERT

Description: Serine protease inhibitors, termed serpins, are key regulators in many biologic events. Protease nexin-1 (PN-1) is a serpin that is barely detectable in plasma but found in many organs and produced by most cell types, including monocytes, platelets, and vascular cells. It has a large inhibition spectrum because it is the most efficient tissue inhibitor of thrombin but also a powerful inhibitor of plasminogen activators and plasmin. It has a high affinity for glycosaminoglycans, such as heparan sulfates, which potentiate its activity toward thrombin and target it to the pericellular space. PN-1 has been previously largely described as a crucial regulator of the proteolytic activity in nerves and of central and peripheral nervous system function. In contrast, little was known about its involvement in hemostasis and vascular biology. This article reviews recent data underlining its emerging role as a key factor in the responses of vessels to injury. Indeed, studies of PN-1–deficient mice have established important antithrombotic and antifibrinolytic properties of this serpin that have heretofore gone unrecognized. The roles of PN-1 in the areas of hemostasis and thrombosis summarized here provide insights that may allow the development of drugs and treatment strategies to prevent or limit thrombotic disorders.

Description: Targeting natural anticoagulant proteins as a means to rebalance the hemostatic system is an emerging trend in the development of innovative therapeutic strategies for hemophilia. These 2 articles develop these concepts in the areas of hemostasis and contact activation. In the study by Aymonnier and colleagues, simple amino acid substitutions converted a serpin elastase inhibitor, α1-antitrypsin (α1AT), into a potent antithrombin, activated protein C inhibitor, or anti-PKa/FXIIa inhibitor. In the study by de Maat and colleagues, redesign of α1AT strongly altered its inhibitory behavior and enables it to be used for the treatment of contact system–mediated thrombosis and inflammation.

Description: Protease nexin–1 (PN-1) is a serpin that inhibits plasminogen activators, plasmin, and thrombin. PN-1 is barely detectable in plasma but is expressed by platelets. Here, we studied platelet PN-1 in resting and activated conditions and its function in thrombosis. Studies on human platelets from healthy donors and from patients with a Gray platelet syndrome demonstrate that PN-1 is present both at the platelet surface and in α-granules. The role of PN-1 was investigated in vitro using human platelets incubated with a blocking antibody and using platelets from PN-1–deficient mice. Both approaches indicate that platelet PN-1 is active on thrombin and urokinase-type plasminogen activator. Blockade and deficiency of platelet PN-1 result in accelerated and increased tissue factor-induced thrombin generation as indicated by calibrated automated thrombography. Moreover, platelets from PN-1–deficient mice respond to subthreshold doses of thrombin, as assessed by P-selectin expression and platelet aggregation. Thrombus formation, induced ex vivo by collagen in blood flow conditions and in vivo by FeCl3-induced injury, is significantly increased in PN-1–deficient mice, demonstrating the antithrombotic properties of platelet PN-1. Platelet PN-1 is thus a key player in the thrombotic process, whose negative regulatory role has been, up to now, markedly underestimated.

Description: Abstract 818 Fibrinolysis, a physiological process leading to clot resorbtion, is strictly controlled by fibrin-localized plasminogen activators (tPA and uPA) and by inhibitors like plasminogen activator type-1 (PAI-1). The serpin PAI-1 is a plasmatic serine protease inhibitor, that is also stored in platelets α-granules. PAI-1 inhibits both the action of urokinase- and tissue-type plasminogen activators (uPA and tPA respectively), and is up to now considered as the principal inhibitor of fibrinolysis in vivo. Interestingly, platelets are also known to inhibit fibrinolysis by both PAI-1-dependent and PAI-1-independent mechanisms. The individual role of other serpins, specifically protease nexin-1 (PN-1) in the thrombolytic process has not been investigated so far. Indeed, we recently demonstrated that a significant amount of PN-1 is stored within the α-granules of platelets and plays an antithrombotic function in vivo. PN-1, also known as SERPINE2, deserves a special interest since it also significantly inhibits in vitro uPA, tPA and plasmin. In this study, we explored the effect of PN-1 on fibrinolysis in vitro and in vivo. We evidenced the antifibrinolytic activity of platelet PN-1 in vitro using a specific PN-1-blocking antibody and PN-1 deficient platelets and, in vivo in PN-1−/− mice. Our data directly indicate that platelet PN-1 inhibits both tPA and plasmin activities in fibrin zymography. Remarkably, whereas fibrin-bound tPA or plasmin activity is not affected by PAI-1, we showed that PN-1 inhibits both plasmin generation induced by tPA-bound to fibrin and fibrin-bound plasmin. Moreover, PN-1 blockade or PN-1 deficiency result in an increased lysis of fibrin clots generated from platelet-rich plasma indicating that PN-1 regulates endogenous tPA-mediated lysis. Rotational thromboelastometry (ROTEM®) analysis shows that platelet PN-1 significantly decreases the rate of fibrinolysis ex vivo. Futhermore, blockade or deficiency of PN-1 provides direct evidence for an acceleration of the lysis-front velocity in platelet-rich clots. To challenge the role of PN-1 on fibrinolysis in vivo, we have developed an original murine model of thrombolysis. Using a dorsal skinfold chamber, thrombus formation induced by ferric chloride injury of venules and subsequent thrombolysis were visualized by microscopy on alive animals. This new approach allows a reproducible quantification of thrombus formation and of tPA- induced thrombus lysis. We observed that thrombi are more readily lysed in PN-1-deficient mice than in wild-type mice. Moreover, in PN-1 deficient mice, the rate and the extent of reperfusion were both increased (Figure A and B). These data demonstrate that platelet PN-1 is a new negative regulator of thrombolysis activity of plasmin, both in solution and within the clot. For the first time, this study shows that PN-1 protects towards thrombolysis and therefore could give rise to new approaches for therapeutic application. Indeed, PN-1 might be a promising target for optimizing thrombolytic therapy by tPA. Figure : Effect of PN-1 on thrombolysis. (A) Representative intravital images of vessels reperfusion after tPA treatment in dorsal skinfold chamber. (B) Quantification of the incidence of reperfused vessels within 1 hour post tPA treatment Figure :. Effect of PN-1 on thrombolysis. (A) Representative intravital images of vessels reperfusion after tPA treatment in dorsal skinfold chamber. (B) Quantification of the incidence of reperfused vessels within 1 hour post tPA treatment Disclosures: No relevant conflicts of interest to declare.