Platelet membrane-mediated coagulation protease complex assembly

Platelet membranes provide procoagulant surfaces for the assembly and expression of a variety of coagulation protease complexes. These assembled complexes promote the proteolytic activation of various coagulation proteins resulting in normal hemostasis. Recent studies from our laboratory and others indicate that platelets possess specific, high-affinity, saturable receptors for factor (F) XI, FXIa, FIX, FIXa, FX, FXa, FV, FVa, prothrombin, and thrombin. The molecular mechanisms involved in the assembly of the intrinsic tenase and prothrombinase enzyme-cofactor complexes on platelet membranes are the subject of intense investigation. Whether the procoagulant surface of platelets is defined exclusively by procoagulant phospholipids, or whether specific protein receptors exist for the coagulant cofactors and proteases, is currently unresolved. In this article, we review some of these platelet receptor-mediated coagulation protein interactions and discuss platelet receptor-mediated F-X activation as a point of attack for the development of antithrombotic agents.     

Factor XII-independent activation of factor XI in plasma: effects of sulfatides on tissue factor-induced coagulation

Factor XI (FXI) may be activated in a purified system by thrombin and by autoactivation in the presence of negatively charged substances such as dextran sulfate or sulfatides. The current studies were performed to determine if these processes occur during the coagulation of plasma. FXII--deficient plasma was supplemented with 125I-FXI and clot formation was induced with tissue factor and/or sulfatides. Cleavage of FXI was studied by standard polyacrylamide gel electrophoresis and autoradiography. Activated FXI (FXIa) was detected after 20 minutes of incubation with sulfatides alone and this process was markedly accelerated by the addition of tissue factor (TF). The enhancing effect of TF was blocked by hirudin, which indicated thrombin involvement in FXI activation. The contribution of FXIa to FIX activation in this system was studied using a 3H-FIX activation peptide release assay. Sulfatides increased FIX activation about twofold in plasma induced to clot with TF but had no effect if the plasma was immunodepleted of FXI. FIX activation was also increased in plasma induced to clot with FXa if sulfatides were present. The enhanced generation of FIXa was dependent on FXI and was blocked by hirudin. Some activation was seen in the reactions with sulfatides and hirudin and is likely solely caused by FXI autoactivation. The data indicate that during the coagulation of plasma in the presence of sulfatides, FXI is activated by a mechanism that is thrombin dependent and does not require FXII.     

Activated factor X and thrombin formation triggered by tissue factor on endothelial cell matrix in a flow model: effect of the tissue factor pathway inhibitor

The procoagulant subcellular matrix of stimulated endothelial cells that contains tissue factor (TF) was used to investigate the mechanism by which TF pathway inhibitor (TFPI) inhibits thrombin formation initiated by TF/factor VIIa (FVIIa) under flow conditions. Purified coagulation factors VII, X, and V and prothrombin were perfused at a wall shear rate of 100 s-1 through a flow chamber containing a coverslip covered with matrix of cultured human umbilical vein endothelial cells. This resulted in a TF- and FVII-dependent FXa and thrombin generation as measured in the effluent at the outlet of the system. Inhibition of this TF/FVIIa-triggered thrombin formation by TFPI purified from plasma was dependent on the amount of TF present on the endothelial cell matrix. The rate of prothrombinase assembly and steady-state levels of thrombin formation were decreased by TFPI. Because persistent albeit decreased steady-state levels of thrombin formation occurred in the presence of TFPI, we conclude that plasma- TFPI does not inhibit FXa present in the prothrombinase complex. The addition of FIX and FVIII to perfusates containing FVII and FX increased the FXa generation on endothelial matrices, and counteracted the inhibition of thrombin formation on endothelial cell matrices by TFPI. Our data provide further evidence for the hypothesis that the rapid inactivation of TF/FVIIa by TFPI in combination with the absence of either FVIII or FIX causes the bleeding tendency of patients with hemophilia A or B.     

Coinheritance of Factor V (FV) Leiden enhances thrombin formation and is associated with a mild bleeding phenotype in patients homozygous for the FVII 9726+5G>A (FVII Lazio) mutation

We investigated the role of thrombophilic mutations as possible modifiers of the clinical phenotype in severe factor VII (FVII) deficiency. Among 7 patients homozygous for a cross-reacting material-negative (CRM-) FVII defect (9726+5G>A, FVII Lazio), the only asymptomatic individual carried FV Leiden. Differential modulation of FVII levels by intragenic polymorphisms was excluded by a FVII to factor X (FX) gene haplotype analysis. The coagulation efficiency in the FV Leiden carrier and a noncarrier was evaluated by measuring FXa, FVa, and thrombin generation after extrinsic activation of plasma in the absence and presence of activated protein C (APC). In both patients coagulation factor activation was much slower and resulted in significantly lower amounts of FXa and thrombin than in a normal control. However, more FXa and thrombin were formed in the plasma of the patient carrying FV Leiden than in the noncarrier, especially in the presence of APC. These results were confirmed in FV-FVII doubly deficient plasma reconstituted with purified normal FV or FV Leiden. The difference in thrombin generation between plasmas reconstituted with normal FV or FV Leiden gradually decreased at increasing FVII concentration. We conclude that coinheritance of FV Leiden increases thrombin formation and can improve the clinical phenotype in patients with severe FVII deficiency.     

New insights into how blood clots: implications for the use of APTT and PT as coagulation screening tests and in monitoring of anticoagulant therapy.

Blood coagulation occurs efficiently on cell surfaces such as activated platelets and monocytes, and fibroblasts. It is initiated by limited amounts of tissue factor (TF) exposed at the sites of vascular injury that complexes with trace amounts of circulating factor VIIa (FVIIa). Additional FVIIa-TF complexes are formed from FVII-TF involving positive feedback loops, including FVIIa-TF as well as factors Xa and IXa as they are formed in subsequent steps. For sustained normal coagulation to proceed, effective in vivo activation of factor X requires the participation of factor IXa generated via the FVIIa-TF complex. This may, in part, be due to effective inhibition of factor Xa and FVIIa-TF complex by tissue factor pathway inhibitor that results in blockage of direct activation of factor X by the FVIIa-TF complex. Additional generation of factor Xa at injury sites may then proceed via the FIXa-VIIIa pathway. Thrombin generated from prothrombin via complex formation of prothrombin with FXa and FVa on phospholipid surfaces (prothrombinase complex) powerfully accelerates coagulation by activation of FVIII and FV, and sustains coagulation through activation of FXI. Thus, in light of our current understanding of how blood clots in vivo, it is clear that both prothrombin time (PT) and activated partial thromboplastin time (APTT) are highly artificial in vitro systems with major limitations. Nevertheless, these tests are quite useful as global screening tests for abnormalities in the intrinsic or extrinsic, as well as common, pathways of coagulation and for monitoring of anticoagulant therapy.     

Tissue factor- and factor X-dependent activation of protease-activated receptor 2 by factor VIIa

Protease-activated receptor 2 (PAR2) is expressed by vascular endothelial cells and other cells in which its function and physiological activator(s) are unknown. Unlike PAR1, PAR3, and PAR4, PAR2 is not activatable by thrombin. Coagulation factors VIIa (FVIIa) and Xa (FXa) are proteases that act upstream of thrombin in the coagulation cascade and require cofactors to interact with their substrates. These proteases elicit cellular responses, but their receptor(s) have not been identified. We asked whether FVIIa and FXa might activate PARs if presented by their cofactors. Co-expression of tissue factor (TF), the cellular cofactor for FVIIa, together with PAR1, PAR2, PAR3, or PAR4 conferred TF-dependent FVIIa activation of PAR2 and, to lesser degree, PAR1. Responses to FXa were also observed but were independent of exogenous cofactor. The TF/FVIIa complex converts the inactive zymogen Factor X (FX) to FXa. Strikingly, when FX was present, low picomolar concentrations of FVIIa caused robust signaling in cells expressing TF and PAR2. Responses in keratinocytes and cytokine-treated endothelial cells suggested that PAR2 may be activated directly by TF/FVIIa and indirectly by TF/FVIIa-generated FXa at naturally occurring expression levels of TF and PAR2. These results suggest that PAR2, although not activatable by thrombin, may nonetheless function as a sensor for coagulation proteases and contribute to endothelial activation in the setting of injury and inflammation. More generally, these findings highlight the potential importance of cofactors in regulating PAR function and specificity.     

Flow cytometric analysis of agonist-induced annexin V, factor Va and factor Xa binding to human platelets

Activated platelets provide a procoagulant surface for the assembly and expression of prothrombinase complex. Expression of activity is associated with the binding of the protease factor Xa (FXa) and the co-factor Va (FVa) to the procoagulant surface. A flow cytometric methodology to measure annexin V-FITC as well as FVa and FXa binding to ionophore A 23187 activated platelets is described. Annexin V-FITC was used to determine platelet exposure of phosphatidylserine. The binding was calcium-dependent and excess of unlabelled annexin V (10-fold) prevented the binding of the labelled protein. The binding of FVa and FXa to platelets was measured using specific FITC-labelled monoclonal antibodies. The FITC labelled antibodies were displaced by 10-to 20-fold excess of unlabelled antibodies. Binding was strictly Ca2+-dependent. Fixation of platelets by formaldehyde caused artificial binding of annexin V, FVa and FXa as well, irrespective of the platelet activation status. Using gel-filtered platelets, the binding of FVa increased with alpha -granule secretion but the amount of stored FVa was not sufficient to saturate the available platelet binding sites. Exogenous FVa was needed for maximal FVa binding to occur. No binding of FXa from internal platelet stores was observed. Addition of exogenous FVa and FXa resulted in FXa binding to the platelet surface. The methodology might be of use for the study of platelets from patients with bleeding disorders.     

Structure-function relationships in factor IX and factor IXa

Factor IX (FIX) consists of an N-terminal gamma-carboxyglutamic acid (Gla) domain followed by two epidermal growth factor (EGF)-like domains, and the C-terminal serine protease domain. During physiologic coagulation, one of the activators of FIX is the FVIIa/tissue factor (TF) complex. In this reaction, the Gla and EGF1 domains of FIX are thought to interact with TF. The FIXa that is generated then combines with FVIIIa on the platelet surface to activate FX in the coagulation cascade. In this assembly, the protease domain and possibly the EGF2 domain of FIXa are thought to provide the primary specificity in binding to FVIIIa. Disruption of the interaction of FIX/FX with TF and of the FIXa:FVIIIa interface may provide a pharmacologic target as an alternative strategy for the development of antithrombotic agents.     

Tissue factor pathway.

Blood coagulation is initiated in response to vessel damage in order to preserve the integrity of the mammalian vascular system. The coagulation cascade can also be initiated by mediators of the inflammatory response, and fibrin deposition has been noted in a variety of pathological states. The cascade of coagulation zymogen activations which leads to clot formation is initiated by exposure of flowing blood to Tissue Factor (TF), the cellular receptor and cofactor for Factor VII (FVII). FVII binds to the receptor in a I:I stoichiometric complex and is rapidly activated. FVIIa undergoes an active site transition upon binding TF in the presence of calcium which enhances the fundamental properties of the enzyme. This results in rapid autocatalytic activation of FVII to FVIIa, thereby amplifying the response by generating more TF-FVIIa complexes. The TF-FVIIa activates both FIX and FX. Further FXa generation by the FIXa-FVIIIa-Ca2+-phospholipid complex is required to sustain the coagulation mechanism, since the TF-FVIIa complex is rapidly inactivated by Tissue Factor pathway inhibitor (TFPI). TFPI circulates in plasma, is associated with vascular cell surface and is released from platelets following stimulation by thrombin. TFPI requires the formation of an active TF-FVIIa complex and FXa generation before inhibition can occur. TFPI prevents further participation of TF in the coagulation process by forming a stable quaternary complex, TF-FVIIa-FXa-TFPI.     

A cell-based model of coagulation and the role of factor VIIa

Our cell-based model of haemostasis replaces the traditional 'cascade' hypothesis, and proposes that coagulation takes place on different cell surfaces in three overlapping steps: initiation, amplification, and propagation. In highlighting the importance of cellular control during coagulation, the cell-based model allows a more thorough understanding of how haemostasis works in vivo, and sheds light on the pathophysiological mechanisms behind certain coagulation disorders. For instance, this model proposes that haemophilia involves a failure of platelet-surface FXa generation, leading to a lack of platelet-surface thrombin production. Our data suggest that high-dose FVIIa is able to bind weakly to activated platelets, independently of tissue factor, in order to generate sufficient amounts of FXa to support a burst bf thrombin generation in the absence of FIXa/FVIIIa. The considerable success of high-dose recombinant FVIIa (rFVIIa; NovoSeven, Novo Nordisk, Copenhagen, Denmark) as a therapy for patients with haemophilia and inhibitors has led to its use in a growing number of alternative indications. We believe that even in the presence of the FIXa/FVIIIa complex, rFVIIa may be able to enhance both FXa and FIXa levels on the surface of activated platelets, thus increasing the production of thrombin.     

Effects of storage-induced platelet microparticles on the initiation and propagation phase of blood coagulation

Platelets shed microparticles, which support haemostasis via adherence to the damaged vasculature and by promoting blood coagulation. We investigated mechanisms through which storage-induced microparticles might support blood coagulation. Flow cytometry was used to determine microparticle number, cellular origin and surface expression of tissue factor (TF), procoagulant phosphatidylserine (PtdSer) and glycoprotein (GP) Ib-alpha. The influence of microparticles on initiation and propagation of coagulation were examined in activated factor X (factor Xa; FXa) and thrombin generation assays and compared with that of synthetic phospholipids. About 75% of microparticles were platelet derived and their number significantly increased during storage of platelet concentrates. About 10% of the microparticles expressed functionally active TF, as measured in a FXa generation assay. However, TF-driven thrombin generation was only found in plasma in which tissue factor pathway inhibitor (TFPI) was neutralised, suggesting that microparticle-associated TF in platelet concentrates is of minor importance. Furthermore, 60% of all microparticles expressed PtdSer. In comparison with synthetic procoagulant phospholipids, the maximal rate of thrombin formation in TF-activated plasma was 15-fold higher when platelet-free plasma was titrated with microparticles. This difference could be attributed to the ability of microparticles to propagate thrombin generation by thrombin-activated FXI. Collectively, our findings indicate a role of microparticles in supporting haemostasis by enhancement of the propagation phase of blood coagulation.     

Activation of factor XI by products of prothrombin activation

The prothrombinase complex converts prothrombin to α-thrombin through the intermediate meizothrombin (Mz-IIa). Both α-thrombin and Mz-IIa catalyze factor (F) XI activation to FXIa, which sustains α-thrombin production through activation of FIX. The interaction with FXI is thought to involve thrombin anion binding exosite (ABE) I. α-Thrombin can undergo additional proteolysis to β-thrombin and γ-thrombin, neither of which have an intact ABE I. In a purified protein system, FXI is activated by β-thrombin or γ-thrombin, and by α-thrombin in the presence of the ABE I-blocking peptide hirugen, indicating that a fully formed ABE I is not absolutely required for FXI activation. In a FXI-dependent plasma thrombin generation assay, β-thrombin, γ-thrombin, and α-thrombins with mutations in ABE I are approximately 2-fold more potent initiators of thrombin generation than α-thrombin or Mz-IIa, possibly because fibrinogen, which binds to ABE I, competes poorly with FXI for forms of thrombin lacking ABE I. In addition, FXIa can activate factor FXII, which could contribute to thrombin generation through FXIIa-mediated FXI activation. The data indicate that forms of thrombin other than α-thrombin contribute directly to feedback activation of FXI in plasma and suggest that FXIa may provide a link between tissue factor-initiated coagulation and the proteases of the contact system.     

Characterization of Factor VIII Inhibitors

Factor VIII (FVIII) inhibitors develop as either alloantibodies against exogenous FVIII in patients with congenital hemophilia A after FVIII-replacement therapy or as autoantibodies against endogenous FVIII in previously healthy, nonhemophilic individuals. The predominant immunoglobulin G (IgG) subclass of FVIII inhibitors is IgG(4). The main epitopic regions are known to be located, however, in the A2, A3, and C2 domains. The A2 and A3 epitopes have been identified between amino acid residues 484 and 509 and residues 558 and 565, respectively. Both of these regions are close to the binding sites for activated FIX (FIXa). Two regions have been identified in the C2 domain, one in the amino-terminal portion of the domain (residues 2181-2243) and the other in the carboxy-terminal portion of the domain (residues 2248-2312 and residues 2315-2330). In addition, a crystallographic analysis of a complex of the C2 domain and a human monoclonal IgG(4)(K) Fab revealed that this type of antibody is in direct contact with hydrophobic and basic residues of the membrane-binding surface. Inactivated FVIII is rapidly cleared from the circulation in the presence of inhibitors. The inhibitors also bind to essential FVIII ligand proteins, including von Willebrand factor, FIXa, FXa, and thrombin, and to surface membrane phospholipid. Some type 2 inhibitors interfere with binding to activated protein C.     

The fraction of recombinant factor VIII:Ag unable to bind von Willebrand factor has no FVIII coagulant activity: studies in vitro

A fraction of FVIII:Ag in commercial recombinant FVIII (rFVIII) cannot bind VWF whereas all the FVIII:Ag in plasma‐derived FVIII (pd‐FVIII) concentrates does. To compare the FVIII:C activities of the fractions of rFVIII:Ag that can and cannot bind VWF. The FVIII:Ag contents of the rFVIII Kogenate, and Advate and a pd‐FVIII‐pd‐VWF (Fanhdi) were measured by ELISA. The FX activation was initiated by adding 1.0 IU of FVIII:C of each FVIII‐containing product to a coagulant phospholipids suspension containing 1.0 nm FIXa, 100 nm FX, 1 μm hirudin and 2 mm calcium chloride and measured after 1, 5 and 10 min. The same approach was followed after adding 2.0 IU of pd‐VWF to1.0 IU of FVIII:C of Kogenate or Advate. The FVIII:Ag content/IU of FVIII:C of Kogenate, Advate and Fanhdi were 1.80 ± 0.05, 1.31 ± 0.9 and 0.84 ± 1.5 IU respectively. Only Kogenate and Advate effectively enhanced FX activation 1 min after adding each FVIII:C to the coagulant suspension containing FIXa and FX. Thus, the FXa initially generated by FIXa readily activated FVIII:C in control Kogenate and Advate to thereby effectively enhance FX activation while the VWF in Fanhdi continued to suppress FX activation for up to 10 min. Addition of pd‐VWF to Kogenate or Advate effectively decreased their enhancements of FX activation to the same level as Fanhdi over 10 min. The FVIII:Ag fraction in Kogenate and Advate that cannot bind VWF appears to be inactive as it has no measureable FVIII:C activity in the presence of added VWF in vitro.     

Variants of recombinant factor VIIa with increased intrinsic activity

Following vascular damage, blood clotting is triggered when factor VIIa (FVIIa) forms a complex with tissue factor (TF). In hemophilia A and B, the propagation phase of blood coagulation is disrupted due to the lack of factors VIII (FVIII) and IX (FIX), leading to excessive bleeding. However, high doses of recombinant FVIIa (rFVIIa) can bypass the FVIII/FIX deficiency and ameliorate bleeding problems. Although the precise mechanism of action of rFVIIa at pharmacological doses remains a matter of debate, rFVIIa-catalyzed (TF-independent) activation of factor X (FX) on the surface of the activated platelet appears to be important. Variants of rFVIIa with increased intrinsic (TF-independent) activity have been developed, which may offer improved treatment of bleeding episodes, for example, in hemophiliacs with inhibitory antibodies to FVIII; they can also help us to understand how FVIIa works at the molecular level. This article reviews the properties of these molecules.     

Thrombin generation and platelet activation induced by rFVIIa (NovoSeven®) and NN1731 in a reconstituted cell-based model mimicking haemophilia conditions

Summary.  Replacement therapy with factor VIII (FVIII) and factor IX (FIX) is routinely used in haemophilia patients with haemophilia A and B, respectively, while recombinant activated FVII (rFVIIa) has proven to induce haemostasis in haemophilia patients with inhibitors. To evaluate the effect of therapeutic intervention in patients with residual factor activities, the effects of increasing concentrations of rFVIIa or NN1731 on thrombin generation and platelet activation were measured in a cell-based model system mimicking severe, moderate and mild haemophilia A or B. Purified monocytes stimulated to express tissue factor and non-activated platelets from peripheral blood of healthy donors were incubated with a mixture of purified human coagulation factors in the absence or presence of increasing concentrations of FVIII or FIX. Sub-samples were analysed for thrombin activity and platelet activation measured as exposure of P-selectin by flow cytometry. Dose-dependent increases in thrombin generation and platelet activation were observed following increasing concentrations of rFVIIa or NN1731 in both haemophilia A- and B-like conditions. At 25 n m rFVIIa, which nears the peak levels in patient plasma after 90 μg kg⁻¹ intravenous dosing, the effects on maximum thrombin generation rate (maxTG) at 1–10% FVIII were comparable to those at 100% and 200% FVIII in the absence of rFVIIa. Normalization of maxTG required 500 n m rFVIIa and 25 n m NN1731 or 25–100 n m rFVIIa and 5 n m NN1731 in severe or moderate/mild haemophilia A and haemophilia B, respectively. This suggests that NN1731 holds its promise as a future bypassing agent for haemophilia patients with and without inhibitors.     

Effect of anticoagulants and antiplatelet agents on platelet-mediated thrombin generation.

The present study was designed to determine the mechanism by which and extent to which antagonists of glycoprotein IIbIIIa (GPIIbIIIa or alpha beta ) or activated factor X (FXa) activity block tissue factor-initiated thrombin generation by prothrombinase complexes assembled on the surface of activated platelets. In the presence of high concentrations of GPIIbIIIa antagonists, which eliminate platelet aggregation but not activation, there is still a substantial amount of thrombin produced. In contrast, specific antagonists of the coagulation cascade lead to abolition of both thrombin generation and platelet aggregation. In addition, inhibitors with similar inhibitory activity (Ki) against purified human FXa require a much broader range of concentrations (a variation of 10 000-fold or more) to reduce the amount of thrombin produced in a platelet-rich plasma assay. At the doses tested, inhibitors with greater potency in prevention of thrombin production in the platelet-rich plasma assay were effective in vivo antithrombotics in an animal model system, whereas a lower potency compound did not reduce thrombus mass. Therefore, inhibition of FXa within platelet bound prothrombinase rather than inhibition of purified FXa in solution may be a better predictor of antithrombotic efficacy. In addition, all the studied anticoagulants fared better than the antiplatelet agents in reducing thrombin generation.