Novel ELISA for the specific detection of protease NEXIN-1 in human biological samples.

Introduction: Serpin E2 or protease nexin-1 (PN-1) is a glycoprotein belonging to the serpin superfamily, whose function is closely linked to its ability to inhibit thrombin and proteases of the plasminergic system. Objectives: In the absence of specific quantitative methods, an ELISA for the quantification of human PN-1 was characterized and used in biological fluids. Methods: The ELISA for human PN-1 was developed using two monoclonal antibodies raised against human recombinant PN-1. PN-1 was quantified in plasma, serum, platelet secretion from controls and patients with hemophilia A and in conditioned medium of aortic tissue. Results: A linear dose-response curve was observed between 2 and 35 ng/mL human PN-1. Intra- and interassay coefficients of variation were 6.2% and 11.1%, respectively. Assay recoveries of PN-1 added to biological samples were ≈95% in plasma, ≈97% in platelet reaction buffer, and ≈93% in RPMI cell culture medium. Levels of PN-1 secreted from activated human platelets from controls was similar to that of patients with hemophilia A. PN-1 could be detected in conditioned media of aneurysmal aorta but not in that of control aorta. Conclusion: This is the first fully characterized ELISA for human serpin E2 level in biological fluids. It may constitute a relevant novel tool for further investigations on the pathophysiological role of serpin E2 in a variety of clinical studies.

Development and characterization of single-domain antibodies neutralizing protease nexin-1 as tools to increase thrombin generation.

BACKGROUND: Protease nexin-1 (PN-1) is a member of the serine protease inhibitor (Serpin)-family, with thrombin as its main target. Current polyclonal and monoclonal antibodies against PN-1 frequently cross-react with plasminogen activator inhibitor-1 (PAI-1), a structurally and functionally homologous Serpin. OBJECTIVES: Here, we aimed to develop inhibitory single-domain antibodies (VHHs) that show specific binding to both human (hPN-1) and murine (mPN-1) PN-1. METHODS: PN-1-binding VHHs were isolated via phage-display using llama-derived or synthetic VHH-libraries. Following bacterial expression, purified VHHs were analyzed in binding and activity assays. RESULTS AND CONCLUSIONS: By using a llama-derived library, 2 PN-1 specific VHHs were obtained (KB-PN1-01 and KB-PN1-02). Despite their specificity, none displayed inhibitory activity toward hPN-1 or mPN-1. From the synthetic library, 4 VHHs (H12, B11, F06, A08) could be isolated that combined efficient binding to both hPN-1 and mPN-1 with negligible binding to PAI-1. Of these, B11, F06, and A08 were able to fully restore thrombin activity by blocking PN-1. As monovalent VHH, half-maximal inhibitory concentration values for hPN-1 were 50 ± 10, 290 ± 30, and 960 ± 390 nmol/L, for B11, F06, and A08, respectively, and 1580 ± 240, 560 ± 130, and 2880 ± 770 nmol/L for mPN-1. The inhibitory potential was improved 4- to 7-fold when bivalent VHHs were engineered. Importantly, all VHHs could block PN-1 activity in plasma as well as PN-1 released from activated platelets, one of the main sources of PN-1 during hemostasis. In conclusion, we report the generation of inhibitory anti-PN-1 antibodies using a specific approach to avoid cross-reactivity with the homologous Serpin PAI-1.

Targeting protease nexin-1, a natural anticoagulant serpin, to control bleeding and improve hemostasis in hemophilia.

Hemophilia A and B, diseases caused by the lack of factor VIII (FVIII) and factor IX (FIX) respectively, lead to insufficient thrombin production, and therefore to bleeding. New therapeutic strategies for hemophilia treatment that do not rely on clotting factor replacement, but imply the neutralization of natural anticoagulant proteins, have recently emerged. We propose an innovative approach consisting of targeting a natural and potent thrombin inhibitor, expressed by platelets, called protease nexin-1 (PN-1). By using the calibrated automated thrombin generation assay, we showed that a PN-1-neutralizing antibody could significantly shorten the thrombin burst in response to tissue factor in platelet-rich plasma (PRP) from patients with mild or moderate hemophilia. In contrast, in PRP from patients with severe hemophilia, PN-1 neutralization did not improve thrombin generation. However, after collagen-induced platelet activation, PN-1 deficiency in F8-/-mice or PN-1 blocking in patients with severe disease led to a significantly improved thrombin production in PRP, underlining the regulatory role of PN-1 released from platelet granules. In various bleeding models, F8-/-/PN-1-/- mice displayed significantly reduced blood loss and bleeding time compared with F8-/-mice. Moreover, platelet recruitment and fibrin(ogen) accumulation were significantly higher in F8-/-/PN-1-/- mice than in F8-/-mice in the ferric chloride-induced mesenteric vessel injury model. Thromboelastometry studies showed enhanced clot stability and lengthened clot lysis time in blood from F8-/-/PN-1-/- and from patients with hemophilia A incubated with a PN-1-neutralizing antibody compared with their respective controls. Our study thus provides proof of concept that PN-1 neutralization can be a novel approach for future clinical care in hemophilia.

Hematopoietic protease nexin-1 protects against lung injury by preventing thrombin signaling in mice.

Coagulation and fibrinolytic system deregulation has been implicated in the development of idiopathic pulmonary fibrosis, a devastating form of interstitial lung disease. We used intratracheal instillation of bleomycin to induce pulmonary fibrosis in mice and analyzed the role of serine protease inhibitor E2 (serpinE2)/protease nexin-1 (PN-1), a tissue serpin that exhibits anticoagulant and antifibrinolytic properties. PN-1 deficiency was associated, after bleomycin challenge, with a significant increase in mortality, as well as a marked increase in active thrombin in bronchoalveolar lavage fluids, an overexpression of extracellular matrix proteins, and an accumulation of inflammatory cells in the lungs. Bone marrow transplantation experiments showed that protective PN-1 was derived from hematopoietic cell compartment. A pharmacological strategy using the direct thrombin inhibitor argatroban reversed the deleterious effects of PN-1 deficiency. Concomitant deficiency of the thrombin receptor protease-activated receptor 4 (PAR4) abolished the deleterious effects of PN-1 deficiency in hematopoietic cells. These data demonstrate that prevention of thrombin signaling by PN-1 constitutes an important endogenous mechanism of protection against lung fibrosis and associated mortality. Our findings suggest that appropriate doses of thrombin inhibitors or PAR4 antagonists may provide benefit against progressive lung fibrosis with evidence of deregulated thrombin activity.

Clearance of plasmin-PN-1 complexes by vascular smooth muscle cells in human aneurysm of the ascending aorta.

Plasminogen is a circulating zymogen which enters the arterial wall by radial, transmural hydraulic conductance, where it is converted to plasmin by tissue plasminogen activator t-PA on an activation platform involving S100A4 on the vascular smooth muscle cell (vSMC) membrane. Plasmin is involved in the progression of human thoracic aneurysm of the ascending aorta (TAA). vSMCs protect the TAA wall from plasmin-induced proteolytic injury by expressing high levels of antiproteases. Protease nexin-1 (PN-1) is a tissue antiprotease belonging to the serpin superfamily, expressed in the vascular wall, and is able to form a covalent complex with plasmin. LDL receptor-related protein-1 (LRP-1) is a scavenger receptor implicated in protease-antiprotease complex internalization. In this study, we investigated whether PN-1 and LRP-1 are involved in the inhibition and clearance of plasminogen by the SMCs of human TAA. We demonstrated an overexpression of S100A4, PN-1, and LRP-1 in the medial layer of human TAA. Plasminogen activation taking place in the media of TAA was revealed by immunohistochemical staining and plasmin activity analyses. We showed by cell biology studies that plasmin-PN-1 complexes are internalized via LRP-1 in vSMCs from healthy and TAA media. Thus, two complementary mechanisms are involved in the protective role of PN-1 in human TAA: one involving plasmin inhibition and the other involving tissue clearance of plasmin-PN1 complexes via the scavenger receptor LRP-1.

Increased expression of protease nexin-1 in fibroblasts during idiopathic pulmonary fibrosis regulates thrombin activity and fibronectin expression.

Idiopathic pulmonary fibrosis (IPF) is a chronic diffuse lung disease characterized by an accumulation of excess fibrous material in the lung. Protease nexin-1 (PN-1) is a tissue serpin produced by many cell types, including lung fibroblasts. PN-1 is capable of regulating proteases of both coagulation and fibrinolysis systems, by inhibiting, respectively, thrombin and plasminergic enzymes. PN-1 is thus a good candidate for regulating tissue remodeling occurring during IPF. We demonstrated a significant increase of PN-1 expression in lung tissue extracts, lung fibroblasts and bronchoalveolar lavage fluids of patients with IPF. The increase of PN-1 expression was reproduced after stimulation of control lung fibroblasts by transforming growth factor-ß, a major pro-fibrotic cytokine involved in IPF. Another serpin, plasminogen activator inhibitor-1 (PAI-1) is also overexpressed in fibrotic fibroblasts. Unlike PAI-1, cell-bound PN-1 as well as secreted PN-1 from IPF and stimulated fibroblasts were shown to inhibit efficiently thrombin activity, indicating that both serpins should exhibit complementary roles in IPF pathogenesis, via their different preferential antiprotease activities. Moreover, we observed that overexpression of PN-1 induced by transfection of control fibroblasts led to increased fibronectin expression, whereas PN-1 silencing induced in fibrotic fibroblasts led to decreased fibronectin expression. Overexpression of PN-1 lacking either its antiprotease activity or its binding capacity to glycosaminoglycans had no effect on fibronectin expression. These novel findings suggest that modulation of PN-1 expression in lung fibroblasts may also have a role in the development of IPF by directly influencing the expression of extracellular matrix proteins. Our data provide new insights into the role of PN-1 in the poorly understood pathological processes involved in IPF and could therefore give rise to new therapeutic approaches.

Endothelial protease nexin-1 is a novel regulator of A disintegrin and metalloproteinase 17 maturation and endothelial protein C receptor shedding via furin inhibition.

OBJECTIVE: Human protein C is a plasma serine protease that plays a key role in hemostasis, and activated protein C (aPC) is known to elicit protective responses in vascular endothelial cells. This cytoprotective activity requires the interaction of the protease with its cell membrane receptor, endothelial protein C receptor. However, the mechanisms regulating the beneficial cellular effects of aPC are not well known. We aimed to determine whether a serine protease inhibitor called protease nexin-1 (PN-1) or serpinE2, expressed by vascular cells, can modulate the effect of aPC on endothelial cells. APPROACH AND RESULTS: We found that vascular barrier protective and antiapoptotic activities of aPC were reduced both in endothelial cells underexpressing PN-1 and in endothelial cells whose PN-1 function was blocked by a neutralizing antibody. Our in vitro data were further confirmed in vivo. Indeed, we found that vascular endothelial growth factor-mediated hyperpermeability in the skin of mice was markedly reduced by local intradermal injection of aPC in wild-type mice but not in PN-1-deficient mice. Furthermore, we demonstrated a previously unknown protective role of endothelial PN-1 on endothelial protein C receptor shedding. We provided evidence that PN-1 inhibits furin, a serine protease that activates a disintegrin and metalloproteinase 17 involved in the shedding of endothelial protein C receptor. We indeed evidenced a direct interaction between PN-1 and furin in endothelial cells. CONCLUSIONS: Our results thus demonstrate an original role of PN-1 as a furin convertase inhibitor, providing new insights for understanding the regulation of endothelial protein C receptor-dependent aPC endothelial protective effects.

Platelet protease nexin-1, a serpin that strongly influences fibrinolysis and thrombolysis.

BACKGROUND: Protease nexin-1 (PN-1) is a serpin that inhibits plasminogen activators, plasmin, and thrombin. PN-1 is barely detectable in plasma, but we have shown recently that PN-1 is present within the α-granules of platelets. METHODS AND RESULTS: In this study, the role of platelet PN-1 in fibrinolysis was investigated with the use of human platelets incubated with a blocking antibody and platelets from PN-1-deficient mice. We showed by using fibrin-agar zymography and fibrin matrix that platelet PN-1 inhibited both the generation of plasmin by fibrin-bound tissue plasminogen activator and the activity of fibrin-bound plasmin itself. Rotational thromboelastometry and laser scanning confocal microscopy were used to demonstrate that PN-1 blockade or deficiency resulted in increased clot lysis and in an acceleration of the lysis front. Protease nexin-1 is thus a major determinant of the lysis resistance of platelet-rich clots. Moreover, in an original murine model in which thrombolysis induced by tissue plasminogen activator can be measured directly in situ, we observed that vascular recanalization was significantly increased in PN-1-deficient mice. Surprisingly, general physical health, after tissue plasminogen activator-induced thrombolysis, was much better in PN-1-deficient than in wild-type mice. CONCLUSIONS: Our results reveal that platelet PN-1 can be considered as a new important regulator of thrombolysis in vivo. Inhibition of PN-1 is thus predicted to promote endogenous and exogenous tissue plasminogen activator-mediated fibrinolysis and may enhance the therapeutic efficacy of thrombolytic agents.

Highly sulfated dermatan sulfate from the skin of the ray Raja montagui: anticoagulant activity and mechanism of action.

The dermatan sulfate (DS) isolated from the ray skin Raja montagui was identified and characterized. Its average molecular weight (Mw) and sulfate content were 39 kDa and 25% w/w, respectively. This DS prolonged thrombin time and activated partial thromboplastin time and inhibited the thrombin generation in a concentration-dependent manner whereas it had no effect on the anti-Xa assay and on platelet function. Data from the anti-IIa assay allowed the assessment of the specific anticoagulant activity which was 40 units/mg. The kinetics of the thrombin inhibition by heparin cofactor II (HCII) has been studied as a function of DS concentration according to a kinetic model in which the polysaccharide binds quickly to the inhibitor and forms a complex more reactive than the free inhibitor towards thrombin. This DS accelerated thrombin inhibition exclusively by HCII. The dissociation constant of the DS-HCII complex, K(DSHCII), and the rate constant of the thrombin inhibition by this complex, k, were (2.93+/-0.25)x10(-6)M and (2.2+/-0.35)x10(9)M(-1)min(-1), respectively. Our findings indicated that the major polysaccharide in the skin of the ray Raja montagui was a DS endowed with a high anticoagulant effect mediated by HCII and which may constitute an anticoagulant drug of interest in anticoagulant therapy.

Anticoagulant and antithrombotic properties of platelet protease nexin-1.

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 alpha-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 FeCl(3)-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.

Mechanism of thrombin inhibition by heparin cofactor II and antithrombin in the presence of the ray (Raja radula) skin dermatan sulfate.

INTRODUCTION: The kinetics of the thrombin inhibition by heparin cofactor II (HCII) and antithrombin (AT) have been studied as a function of the concentration of a dermatan sulfate (DS) from the skin of the ray Raja radula. MATERIALS AND METHODS: The initial concentrations of inhibitor (I), HCII or AT, and thrombin (E) were set at equimolecular levels (3.10(-9) M). Analysis of the experimental data obtained for DS concentrations ranging from 10(-8) to 10(-4) M was performed according to a previously described model in which DS binds quickly to the inhibitor and forms a complex more reactive than the free inhibitor towards thrombin. RESULTS: The apparent rate constant of the thrombin inhibition, k(app), by either HCII or AT, increased in a concentration-dependent manner for DS concentrations up to 10(-5) M or 10(-6) M, respectively. At higher DS concentrations, k(app) remained unchanged for thrombin inhibition by HCII whereas a decrease in k(app) was observed for the thrombin-AT reaction. The dissociation constant of the polysaccharide-inhibitor complex, K(DSI), and the rate constant of the thrombin inhibition by this complex, k, were (7.81+/-0.75).10(-7) M and (2.84+/-0.42).10(9) M(-1).min(-1), whereas they were (4.93+/-0.31).10(-7) M and (2.47+/-0.28).10(8) M(-1).min(-1), when the inhibitor was either HCII or AT, respectively. CONCLUSION: DS from ray skin catalyzes the thrombin inhibition by HCII or AT primarily by forming a DS-inhibitor complex more reactive than the free inhibitor towards the protease. The affinity of DS for HCII was approximately 2-fold higher whereas the catalyzed reaction rate constant was approximately 20-fold higher when compared to AT.

Macrophages and platelets are the major source of protease nexin-1 in human atherosclerotic plaque.

OBJECTIVE: Protease nexin-1 (PN-1), a serpin constitutively expressed by vascular smooth muscle cells and endothelial cells, inhibits thrombin, plasminogen activators, and plasmin and can thus be expected to play a role in vascular biology. The present study addressed the question of PN-1 expression in human atherothrombosis. METHODS AND RESULTS: Immunohistochemistry and biochemical studies confirmed that PN-1 was expressed at a moderate level in the medial layer of normal human arteries and showed that PN-1 expression was increased in atherothrombotic lesions. In early noncomplicated plaques, PN-1 was associated with infiltrating mononuclear cells. A strong PN-1 signal was observed in advanced lesions, principally in intraplaque hemorrhage-related structures. Monocytes/macrophages and platelets were identified as the main sources of PN-1 within atherothrombotic material. Isolated human monocytes and platelets both expressed high levels of active PN-1, and monocyte PN-1 expression was upregulated, at both messenger and protein levels, in response to stimulation by lipopolysaccharides. In contrast, PN-1 expression was downregulated during their differentiation into macrophages which were shown to produce degraded forms of PN-1. CONCLUSIONS: Platelets and monocytes/macrophages are a major source of PN-1 in human atherothrombotic plaques. PN-1 could thus represent a new actor in the evolution of atherosclerotic lesions.

Hypercoagulability after partial liver resection.

One concern of living donor liver transplantation remains the risk of morbidity and/or mortality for the donors, including the risk of postoperative thrombosis. We studied the coagulation changes after partial liver resection in l2 living donors and eight patients with non-malignant hepatic tumors (controls) and searched for potential predictive markers of thrombotic complications. Thrombosis (pulmonary embolism and portal vein thrombosis) developed in two donors and two controls. In donors and controls, we observed an early postoperative decrease in coagulation inhibitors protein C and antithrombin together with an increase in factor VIII and von Willebrand factor, which both persisted when prothrombin time had returned to normal. Dysregulation in the haemostatic system was confirmed by increased prothrombotic markers, with a 10- to 30-fold increase in thrombin-antithrombin complexes and moderate increase(1.5- to 2.0-fold) in sP-Selectin. No difference between donors and controls was observed and the data were pooled for comparison of patients with (n = 4) versus without (n = 16) thrombosis. Thrombin-antithrombin complexes were significantly higher in the thrombosis group, on day 1 (28.8 vs. 13.5 microg/l, p = 0.027) and day 2 (52.3 vs. 9.3 microg/l, p = 0.013). sP-selectin was also significantly higher in the thrombosis group on day 2 (103 vs. 53 ng/ml, p = 0.044) and day 4 (116 vs. 58 ng/ml, p = 0.026) after surgery. Our study indicates that improvement of thromboprophylaxis in partial liver resection is needed. It also suggests that thrombin-antithrombin complexes and sP-selectin could serve as early biological predictors of thrombotic complications in the post-operative period.

Protease nexin-1 interacts with thrombomodulin and modulates its anticoagulant effect.

The endothelial cell membrane glycoprotein thrombomodulin (TM) plays a critical role in the regulation of coagulation. TM is an essential cofactor in protein C activation by thrombin, and a direct inhibitor of thrombin-induced platelet activation and fibrinogen clotting. Protease nexin-1 (PN-1) is a serpin synthesized and secreted by a variety of cells including endothelial cells. PN-1 bound to the cell surface through interactions with glycosaminoglycans, is an efficient inhibitor of thrombin and controls thrombin-induced cell responses. An investigation of the interaction of PN-1 with TM using purified proteins and cultured human aortic endothelial cells was performed. Purified PN-1 was observed to bind to purified TM in a concentration-dependent manner. Double immunofluorescence studies indicated that PN-1 and TM were colocalized at the endothelial cell surface from which they were coprecipitated. Pretreatment of the cells with chondroitinase ABC greatly decreased the amount of the PN-1 associated to TM at the cell surface demonstrating the involvement of the TM chondroitin-sulfate chain in the formation of complexes. The inhibitory activity of the PN-1/TM complexes on the catalytic activity of thrombin, and on thrombin-induced fibrinogen clotting, was markedly enhanced when compared with the inhibitory activity of each partner. PN-1-overexpressing human aortic endothelial cells and PN-1-underexpressing human aortic endothelial cells exhibited respectively a significantly reduced ability and enhanced capacity to activate protein C. Furthermore, PN-1 decreased the cofactor activity of TM on thrombin activable fibrinolysis inhibitor activation by thrombin. These data show for the first time that PN-1 forms complexes with TM and modulates its anticoagulant activity.

Prothrombin Saint-Denis: a natural variant with a point mutation resulting in Asp to Glu substitution at position 552 in prothrombin.

A new prothrombin variant, with a point mutation at nucleotide 20 029 resulting in Asp 552 to Glu substitution (prothrombin numbering), has been identified in a male newborn. Plasma prothrombin level was <3%, 16% and 60% when measured by clotting, chromogenic and immunological assays respectively. The substitution did not affect the rate of prothrombin conversion to thrombin but altered thrombin activity. Amino acid 552 has been reported to be involved in the allosteric transition, which is induced by sodium binding to thrombin. This is the first known amino acid substitution at this site to result in dysprothrombinaemia.

Red blood cells from patients with homozygous sickle cell disease provide a catalytic surface for factor Va inactivation by activated protein C.

The structure of red blood cell (RBC) membranes in homozygous sickle cell disease (SCD) is significantly disturbed, with an increased exposure of aminophospholipids (phosphatidylserine and phosphatidylethanolamine) at the outer surface, responsible for a procoagulant activity of SS RBCs. Aminophospholipids are known not only to promote procoagulant reactions, but also to support inhibition of blood coagulation by the protein C system. The aim of the present study was to examine whether SS RBCs could serve as a catalytic surface for the inactivation of factor Va by activated protein C (APC). Venous blood was obtained from 19 consecutive SS patients and 13 controls (AA). In all SS patients, the amount of phosphatidylserine exposed at the outer surface of RBCs was increased compared with controls, as demonstrated by a prothrombinase assay. In addition, SS RBCs significantly (P < 0.0001) increased the rate of FVa inactivation by APC: the mean values (and ranges) of the factor Va inactivation rates were 30 (0-57) vs 9.5 (0-32) mmol Vai/min/mol APC for SS RBCs and normal RBCs respectively. Our results indicate that SS RBCs provide a catalytic surface for the negative control of blood coagulation, which may partially control the procoagulant activity of these cells.