Proposed structural models of human factor Va and prothrombinase.

BACKGROUND: The prothrombinase complex consists of factor Xa, FVa, calcium ions, and phospholipid membrane. The prothrombinase complex plays a key role in the blood coagulation process. OBJECTIVE: To derive solvent-equilibrated models of human FVa and the prothrombinase complex. METHODS: Several modeling techniques have been employed, including homology modeling, protein-protein docking, and molecular dynamics simulation methods, to build the structural models. RESULTS AND CONCLUSIONS: We found, upon simulation, a possibly significant shift towards planarity of the five FVa domains. To estimate a prothrombinase structure, we docked an FXa model to the equilibrated FVa model using experimental data as docking filters. We found that simulation of the docked complex led to some changes in the protein-protein contacts, but not buried surface area, as compared to the initial docking model. Possible locations of prothrombin binding to prothrombinase are indicated.     

Assembly of the prothrombin activator complex on rabbit alveolar macrophage high-affinity factor Xa receptors. A kinetic study

Efficient prothrombin activation occurs after assembly of factors Va, Xa, and phospholipid surface cofactor as a multimolecular complex. These components are provided by platelets and plasma within the vascular space, but molecules and membranes for prothrombin activator assembly in extravascular spaces have not been identified. In the present study, purified alveolar macrophages were found to produce high-affinity factor Xa receptors that mediate formation of enzymatic prothrombinase complexes and rapid prothrombin to thrombin conversion in the absence of exogenous factor V/Va or platelets. Thus, in reaction mixtures with alveolar macrophages cultured for 20 h in serum-free medium, the thrombin formation rate was 152 nM/min/0.66 X 10(6) cells, after adding prothrombin (1.5 microM), Ca2+ (5 mM), and factor Xa (3.7 nM). The observed Kd of factor Xa interaction with macrophage receptors is 2.1 +/- 0.94 X 10(-10) M. Kinetic analysis and inhibition studies using isolated factor V and anti-factor V antibody show that macrophage Xa receptors are functionally and antigenically similar to plasma factor V. By contrast, freshly isolated cells lacked receptors promoting prothrombin conversion at high rates. Inhibitors of protein synthesis and glycosylation, puromycin and monensin, respectively, abrogated production of Xa receptors in culture. Additionally, subcellular fractionation and enzyme-marker studies (alkaline phosphodiesterase I) indicate that internal and external membranes of alveolar macrophages have phospholipid surface cofactor activity required for prothrombinase complexes. Pulmonary surfactant is also shown to express this cofactor activity. Alveolar macrophages and surfactant comprise an efficient prothrombin activator system that is independent of plasma factor V. This system may facilitate rapid extravascular alveolar thrombin formation even at very low concentrations of factor Xa during lung defense reactions to inflammation or edema.     

Defining the structure of membrane-bound human blood coagulation factor Va.

BACKGROUND: Blood coagulation factor (F) Va is the essential protein cofactor to the serine protease FXa. Factor Va stimulates the thrombin-to-prothrombin conversion by the prothrombinase complex, by at least five orders of magnitude. Factor Va binds with very high affinity to phosphatidylserine containing phospholipid membranes, which allows the visualization of its membrane-bound state by transmission electron microscopy (EM). METHODS: In this paper we present an averaged three-dimensional structure of FVa molecules attached to phosphatidylserine containing lipid tubes, as determined by EM and single particle analysis. The low-resolution FVa three-dimensional structure is compared with the available atomic models for FVa. RESULTS: The experimental data are combined with the most suitable atomic model and a membrane-bound FVaEM model is proposed that best fits the protein density defined by EM. In the FVaEM model, the C1 and C2 membrane-binding domains are juxtaposed onto the membrane surface and the model geometries indicate a deeper insertion of both C domains into the lipid bilayer than has been previously suggested. CONCLUSION: The present structure is a first step towards a higher-resolution experimental structure of a human FVa molecule in its membrane-bound conformation, allowing the visualization of individual domains within FVa and its association with the membrane.     

Factor Va - factor Xa interactions: molecular sites involved in enzyme:cofactor assembly

The generation of thrombin by the prothrombinase complex is a key event in coagulation. In this complex, the activated form of coagulation factor V (FVa) serves as an essential cofactor to factor Xa (FXa) in the activation of prothrombin to thrombin. The enzyme FXa is virtually ineffective in the absence of its cofactor. The assembly of FXa with its cofactor FVa on negatively charged phospholipid membranes enhances its catalytic efficiency by several orders of magnitude. The non-activated procofactor factor V (FV) circulates in plasma with a domain organization of A1-A2-B-A3-C1-C2 expressing little procoagulant activity. Upon activation through limited proteolysis by either thrombin or FXa, the B-domain dissociates from FVa. After activation, the procoagulant activity of FVa is greatly enhanced. This report provides insight into the interaction of FV and FXa and the molecular events important in enzyme:cofactor assembly of the FXa:FVa complex. Furthermore, light is shed on the molecular events associated with the activation process, i.e. the release of the B-domain and exposure of binding sites for FXa. The assembly of FVa and FXa was studied using a set of recombinant FV mutants. The interaction between FVa and FXa on phospholipid was investigated with a functional prothrombin activation assay as well as in a novel direct binding assay in the absence of prothrombin. We found that all three thrombin cleavages in FV contribute to increasing the FXa affinity and that the B-domain in intact FV has an inhibitory effect on the FV-FXa interaction, which is important in prohibiting premature coagulation.     

The assembly of the factor X-activating complex on activated human platelets

Summary.  Platelet membranes provide procoagulant surfaces for the assembly and expression of the factor X-activating complex and promote the proteolytic activation and assembly of the prothrombinase complex resulting in normal hemostasis. Recent studies from our laboratory and others indicate that platelets possess specific, high-affinity, saturable, receptors for factors XI, XIa, IX, IXa, X, VIII, VIIIa, V, Va and Xa, prothrombin, and thrombin. Studies described in this review support the hypothesis that the factor X-activating complex on the platelet surface consists of three receptors (for the enzyme, factor IXa; the substrate, factor X; and the cofactor, factor VIIIa), the colocalization of which results in a 24 million-fold acceleration of the rate of factor X activation. Whether the procoagulant surface of platelets is defined exclusively by procoagulant phospholipids, or whether specific protein receptors exist for the coagulant factors and proteases, is currently unresolved. The interaction between coagulation proteins and platelets is critical to the maintenance of normal hemostasis and is pathogenetically important in human disease.     

Exosites in the substrate specificity of blood coagulation reactions

Summary.  The specificity of blood coagulation proteinases for substrate, inhibitor, and effector recognition is mediated by exosites on the surfaces of the catalytic domains, physically separated from the catalytic site. Some thrombin ligands bind specifically to either exosite I or II, while others engage both exosites. The involvement of different, overlapping constellations of exosite residues enables binding of structurally diverse ligands. The flexibility of the thrombin structure is central to the mechanism of complex formation and the specificity of exosite interactions. Encounter complex formation is driven by electrostatic ligand–exosite interactions, followed by conformational rearrangement to a stable complex. Exosites on some zymogens are in low affinity proexosite states and are expressed concomitant with catalytic site activation. The requirement for exosite expression controls the specificity of assembly of catalytic complexes on the coagulation pathway, such as the membrane-bound factor Xa•factor Va (prothrombinase) complex, and prevents premature assembly. Substrate recognition by prothrombinase involves a two-step mechanism with initial docking of prothrombin to exosites, followed by a conformational change to engage the FXa catalytic site. Prothrombin and its activation intermediates bind prothrombinase in two alternative conformations determined by the zymogen to proteinase transition that are hypothesized to involve prothrombin (pro)exosite I interactions with FVa, which underpin the sequential activation pathway. The role of exosites as the major source of substrate specificity has stimulated development of exosite-targeted anticoagulants for treatment of thrombosis.     

On the molecular mechanisms for the highly procoagulant pattern of C6 glioma cells

BACKGROUND: That there is a correlation between cancer and procoagulant states is well-known. C6 glioma cell line was originally induced in random-bred Wistar-Furth rats and is morphologically similar to glioblastoma multiforme, the most common aggressive glioma resistant to therapeutic interventions. OBJECTIVES: In this study we analyzed the molecular mechanisms responsible for the highly procoagulant properties of C6 glioma cells. METHODS: The presence of tissue factor (TF) and phosphatidylserine (PS) in C6 cells was investigated by flow-cytometric and functional analyses. The assembly of extrinsic tenase, intrinsic tenase and prothrombinase complexes on these cells was studied using enzymatic assays employing plasma or purified proteins. RESULTS: TF was identified by flow-cytometric and functional [factor (F) Xa formation in the presence of cells and FVIIa] assays. Alternatively, conversion of FX into FXa was also observed in the presence of C6 cells, FIXa and FVIIIa. This effect was both cell- and FVIIIa-dependent, being consistent with formation of the intrinsic tenase complex. C6 cells were also able to activate prothrombin in the presence of FXa and FVa, thus supporting formation of the prothrombinase complex. This ability was similar to positive controls performed with PS-containing vesicles. Accordingly, exposure of PS on C6 cells was demonstrated by flow cytometry employing specific anti-PS antibodies. In addition, annexin V, which blocks PS binding sites, inhibited FX and prothrombin conversion by their respective C6-assembled activating complexes. CONCLUSION: C6 glioma cells support all procoagulant reactions leading to robust thrombin formation. This ability results from concomitant TF exposure and from the presence of the anionic lipid PS at the outer leaflet of cell membrane. Therefore, this animal cell line may be used to explore new aspects concerning the role of blood coagulation proteins in tumor biology, especially those affecting the central nervous system.     

Proteolytic cleavage of protein S during the hemostatic response

BACKGROUND: Protein S is a vitamin K-dependent protein with anticoagulant properties. It contains a so-called thrombin-sensitive region (TSR), which is susceptible to cleavage by coagulation factor Xa (FXa) and thrombin. Upon cleavage, the anticoagulant activity of protein S is abolished. OBJECTIVE: The aim of the present study was to determine whether protein S is cleaved within the TSR during activation of the coagulation system under near physiological conditions. RESULTS: In a reconstituted coagulation system containing apart from protein S only procoagulant constituents and synthetic phospholipid vesicles, protein S was cleaved at Arg60 by the FXa generated (3 mol min(-1) mol(-1) enzyme). FXa-catalyzed cleavage of protein S, however, was inhibited by factor Va and prothrombin by more than 70%. During clotting of recalcified citrated plasma in the presence of a synthetic lipid membrane, no FXa-catalyzed proteolysis of protein S was observed. Substituting platelets for phospholipid vesicles resulted both in the reconstituted system and in plasma in cleavage of the TSR. Cleavage was at Arg60 and was observed upon platelet activation, irrespective of the presence of FXa (13 pmol min(-1) 10(-8) platelets). No cleavage by thrombin was observed in either the reconstituted coagulation system or clotting plasma. CONCLUSION: These findings suggest that in vivo the anticoagulant activity of protein S is not down-regulated by FXa or thrombin during activation of coagulation. Our results rather suggest a role for a platelet protease in down-regulating the anticoagulant activity of protein S during the hemostatic response.     

Inhibition by human thrombomodulin of factor Xa-mediated cleavage of prothrombin.

Human thrombomodulin significantly inhibited the rate of prothrombin conversion to thrombin by Factor Xa in the presence of phospholipid or platelets, calcium, and Factor Va. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of 125I-prothrombin activation revealed that thrombomodulin reduced the rate of prothrombin activation but did not alter the cleavage pattern. The inhibition was reversed by the inclusion of a highly specific rabbit antithrombomodulin antibody. If thrombomodulin was replaced by hirudin, the rate of thrombin generation was not decreased excluding the possibility that the inhibition by thrombomodulin was secondary to the binding of small amounts of thrombin formed early in the reaction and the prevention of feedback breakdown of prothrombin by thrombin. The inhibitory activity of thrombomodulin was overcome by increasing the concentration of Factor Xa and specific, saturable binding of thrombomodulin to Factor Xa was demonstrated. These results indicate that thrombomodulin binds to Factor Xa and thereby inhibits the activity of the prothrombinase complex.     

An all-atom solution-equilibrated model for human extrinsic blood coagulation complex (sTF–VIIa–Xa): a protein–protein docking and molecular dynamics refinement study

Summary. Tissue factor (TF)‐bound factor (F)VIIa plays a critical role in activating FX, an event that rapidly results in blood coagulation. Despite recent advances in the structural information about soluble TF (sTF)‐bound VIIa and Xa individually, the atomic details of the ternary complex are not known. As part of our long‐term goal to provide a structural understanding of the extrinsic blood coagulation pathway, we built an all atom solution‐equilibrated model of the human sTF–VIIa–Xa ternary complex using protein–protein docking and molecular dynamics (MD) simulations. The starting structural coordinates of sTF–VIIa and Xa were derived from dynamically equilibrated solution structures. Due to the flexible nature of the light‐chain of the Xa molecule, a three‐stage docking approach was employed in which SP (Arg195‐Lys448)/EGF2 (Arg86‐Arg139), EGF1 (Asp46‐Thr85) and GLA (Ala1‐Lys45) domains were docked in a sequential manner. The rigid‐body docking approach of the FTDOCK method in conjunction with filtering based on biochemical knowledge from experimental site‐specific mutagenesis studies provided the strategy. The best complex obtained from the docking experiments was further refined using MD simulations for 3 ns in explicit water. In addition to explaining most of the known experimental site‐specific mutagenesis data pertaining to sTF–VIIa, our model also characterizes likely enzyme‐binding exosites on FVIIa and Xa that may be involved in the ternary complex formation. According to the equilibrated model, the 140s loop of VIIa serves as the key recognition motif for complex formation. Stable interactions occur between the FVIIa 140s loop and the FXa β‐strand B2 region near the sodium‐binding domain, the 160 s loop and the N‐terminal activation loop regions. The helical‐hydrophobic stack region that connects the GLA and EGF1 domains of VIIa and Xa appears to play a potential role in the membrane binding region of the ternary complex. The proposed model may serve as a reasonable structural basis for understanding the exosite‐mediated substrate recognition of sTF–VIIa and to advance understanding of the TFPI‐mediated regulatory pathway of the extrinsic blood coagulation cascade.     

Cholesterol enhances phospholipid-dependent activated protein C anticoagulant activity

The influence of cholesterol on activated protein C (APC) anticoagulant activity in plasma and on factor Va inactivation was investigated. Anticoagulant and procoagulant activities of phosphatidylcholine/phosphatidylserine (PC/PS) vesicles containing cholesterol were assessed in the presence and absence of APC using factor Xa-1-stage clotting and factor Va inactivation assays. Cholesterol at approximate physiological membrane levels (30%) in PC/PS (60%/10% w/w) vesicles prolonged the factor Xa-1-stage clotting time dose-dependently in the presence of APC but not in the absence of APC. APC-mediated cleavage of purified recombinant factor Va variants that were modified at specific APC cleavage sites (Q306/Q679-factor Va; Q506/Q679-factor Va) was studied to define the effects of cholesterol on APC cleavage at R506 and R306. When compared to control PC/PS vesicles, cholesterol in PC/PS vesicles enhanced factor Va inactivation and the rate of APC cleavage at both R506 and R306. Cholesterol also enhanced APC cleavage rates at R306 in the presence of the APC cofactor, protein S. In summary, APC anticoagulant activity in plasma and factor Va inactivation as a result of cleavages at R506 and R306 by APC is markedly enhanced by cholesterol in phospholipid vesicles. These results suggest that cholesterol in a membrane surface may selectively enhance APC activities.     

Factor Xa is highly protected from antithrombin–fondaparinux and antithrombin–enoxaparin when incorporated into the prothrombinase complex

Summary.  Antithrombin and its cofactor, heparin, target both the product of prothrombin activation by prothrombinase, thrombin, as well as the enzyme responsible for the reaction, factor (F)Xa. These studies were carried out to quantify the effects of each of the prothrombinase components on the half-life of FXa in the presence of antithrombin and the low-molecular-weight heparins (enoxaparin, Aventis, Laval, Quebec, Canada) or the heparin pentasaccharide (fondaparinux, Organon Sanofi-Synthelabo, Cypress, TX, USA). Experiments were carried out using a recombinant form of prothrombin in which the active site serine has been mutated to cysteine and subsequently labeled with fluorescein. This mutant allowed calculation of the second order rate constant for inhibition of FXa by antithrombin in such a way that competition for antithrombin by thrombin is eliminated and competition for FXa by prothrombin is accounted for. Intrinsic rate constants for the inhibition of FXa by antithrombin–enoxaparin and antithrombin–fondaparinux, in the presence of the various prothrombinase components, were calculated. Addition of phospholipid had no significant effect on the second order rate constant for inhibition of FXa by antithrombin, while addition of FVa appeared to be mildly protective. Further addition of prothrombin however, caused profound protection of FXa, increasing its half-life from 1.1 to 353 s in the case of fondaparinux, and from 0.4 to 42 s in the case of enoxaparin. Similar results were reported for unfractionated heparin previously [ 1 ]. Therefore, in the presence of unfractionated heparin, fondaparinux, or enoxaparin, prothrombinase is profoundly protected from antithrombin.     

Isolation and study of an acquired inhibitor of human coagulation factor V.

A coagulation Factor V inhibitor developed in a man 75 yr of age in association with an anaplastic malignancy and drug treatment (including the aminoglycoside antibiotic, gentamicin). The patient did not bleed abnormally, despite both surgical challenge and plasma Factor V activity of less than 1%. The inhibited plasma had grossly prolonged prothrombin and activated partial thromboplastin times, but a normal thrombin time. Mixing studies indicated progressive coagulation inhibition with normal plasma, but not with Factor V-deficient plasma, and reversal of coagulation inhibition by the addition of bovine Factor V to the patient's plasma. 1 ml of patient plasma inhibited the Factor V activity of 90 ml of normal human plasma. The inhibitor was isolated by sequential affinity chromatography on protein A-Sepharose and Factor V-Sepharose. The IgG isolate markedly inhibits the activity of prothrombinase assembled from purified Factors Xa and Va, calcium ion, and phospholipid vesicles, and partially inhibits prothrombinase assembled from purified Factor Xa, calcium ion, and normal platelets. The Factor V of platelets, however, appears relatively inaccessible to the antibody, inasmuch as platelets isolated from whole blood supplemented for 8 h with the antibody functioned normally with respect to platelet Factor V-mediated prothrombinase function. The absence of obvious hemorrhagic difficulties in the patient, the total inhibition of plasma Factor V by the inhibitor, and the apparent inaccessibility of platelet Factor V to the inhibitor specifically implicate platelet Factor V in the maintenance of hemostasis.     

Novel insights into the regulation of coagulation by factor V isoforms,tissue factor pathway inhibitorα, and protein S

Factor V (FV) is a regulator of both pro‐ and anticoagulant pathways. It circulates as a single‐chain procofactor, which is activated by thrombin or FXa to FVa that serves as cofactor for FXa in prothrombin activation. The cofactor function of FVa is regulated by activated protein C (APC) and protein S. FV can also function as an anticoagulant APC cofactor in the inhibition of FVIIIa in the membrane‐bound tenase complex (FIXa/FVIIIa). In recent years, it has become clear that FV also functions in multiple ways in the tissue factor pathway inhibitor (TFPI) anticoagulant pathway. Of particular importance is a FV splice variant (FV‐Short) that serves as a carrier and cofactor to TFPIα in the inhibition of FXa. FV‐Short is generated through alternative splicing of exon 13 that encodes the large activation B domain. A highly negatively charged binding site for TFPIα is exposed in the C‐terminus of the FV‐Short B domain, which binds the positively charged C‐terminus of TFPIα, thus keeping TFPIα in circulation. The binding of TFPIα to FV‐Short is also instrumental in localizing the inhibitor to the surface of negatively charged phospholipids, where TFPIα inhibits FXa in process that is stimulated by protein S. Plasma FV activation intermediates and partially proteolyzed platelet FV similarly bind TFPIα with high affinity and regulate formation of prothrombinase. The novel insights gained into the interaction between FV isoforms, TFPIα, and protein S have opened a new avenue for research about the mechanisms of coagulation regulation and also for future development of therapeutics aimed at modulating coagulation.     

Characterization of an acquired inhibitor to coagulation factor V. Antibody binding to the second C-type domain of factor V inhibits the binding of factor V to phosphatidylserine and neutralizes procoagulant activity.

Coagulation Factor V is an essential component of the prothrombinase complex, which activates the zymogen prothrombin to thrombin. A patient was described who developed a Factor V inhibitor that neutralized the procoagulant activity of Factor V and resulted in a fatal hemorrhagic diathesis (Coots, M. C., A. F. Muhleman, and H. I. Glueck. 1978. Am. J. Hematol. 4:193-206). This inhibitor was shown to be an IgG antibody that bound to the light chain of Factor V. Using a series of light chain deletion mutants, we have found that this antibody binds to the second C-type domain of the light chain. Both inhibitor IgG and Fab fragments rapidly neutralized the procoagulant activity of Factor Va, implying that the neutralization resulted from specific binding to the C2 domain. We have previously demonstrated that deletion of the C2 domain results in loss of procoagulant activity, as well as loss of phosphatidylserine-specific binding. Confirming these results, both inhibitor IgG and Fab fragments interfered with phosphatidylserine-specific binding of Factor V. Conversely, preincubation of Factor Va with procoagulant phospholipids protected the cofactor from inactivation by the inhibitor. Our results suggest that this inhibitor neutralizes the procoagulant activity of Factor Va by interfering with the C2-mediated interaction with phospholipid surfaces, thereby disrupting formation of the prothrombinase complex.     

Antiphospholipid antibody syndrome: rapid, sensitive, and specific flow cytometric assay for determination of anti-platelet phospholipid autoantibodies

A rapid, sensitive and specific flow cytometric assay has been developed for the determination of autoantibodies directed against platelet anionic phospholipids in antiphospholipid antibody syndrome (APLAS). The method is based on demonstrable competition between the placental anticoagulant protein I, annexin V, and the patients' autoantibodies on the platelet anionic phospholipids (the binding site for the prothrombinase complex; prothrombin and factors Va and Xa). The method is practical and rapid, uses readily available reagents, and involves standard equipment. The assay is inexpensive and cost-effective for both single and multiple samples. Results are provided within 2 hours from obtaining blood samples, thereby supporting clinical decision-making and management. Ten serum samples from patients with the clinical diagnosis of APLAS (48 tests), 10 from normal individuals (35 tests), and 10 from patients with immune thrombocytopenia (33 tests) were tested. Platelet preparations preincubated with normal sera showed high binding of fluorescein-labeled annexin V with an average fluorescence of 202.9 +/- 22.0 (arbitrary units). Patients with immune thrombocytopenia exhibited similar results, with an average fluorescence of 192.5 +/- 32.1 (P >.05). In contrast, incubation with sera from patients with APLAS resulted in a marked decline in the binding of annexin V to an average fluorescence of only 14.6 +/- 7.4 (P <.001). Preincubation with annexin V followed by the addition of patients' sera showed displacement of annexin V to a similar degree. Because annexin V attenuates procoagulant activity by competing with factors Va and Xa on the platelet anionic phospholipids, its displacement by patients' antibodies may result in the acceleration of procoagulant activity, thereby promoting thrombogenesis in APLAS.     

Functional assembly of intrinsic coagulation proteases on monocytes and platelets. Comparison between cofactor activities induced by thrombin and factor Xa

Generation of coagulation factor Xa by the intrinsic pathway protease complex is essential for normal activation of the coagulation cascade in vivo. Monocytes and platelets provide membrane sites for assembly of components of this protease complex, factors IXa and VIII. Under biologically relevant conditions, expression of functional activity by this complex is associated with activation of factor VIII to VIIIa. In the present studies, autocatalytic regulatory pathways operating on monocyte and platelet membranes were investigated by comparing the cofactor function of thrombin-activated factor VIII to that of factor Xa-activated factor VIII. Reciprocal functional titrations with purified human factor VIII and factor IXa were performed at fixed concentrations of human monocytes, CaCl2, factor X, and either factor IXa or factor VIII. Factor VIII was preactivated with either thrombin or factor Xa, and reactions were initiated by addition of factor X. Rates of factor X activation were measured using chromogenic substrate specific for factor Xa. The K1/2 values, i.e., concentration of factor VIIIa at which rates were half maximal, were 0.96 nM with thrombin-activated factor VIII and 1.1 nM with factor Xa-activated factor VIII. These values are close to factor VIII concentration in plasma. The Vsat, i.e., rates at saturating concentrations of factor VIII, were 33.3 and 13.6 nM factor Xa/min, respectively. The K1/2 and Vsat values obtained in titrations with factor IXa were not significantly different from those obtained with factor VIII. In titrations with factor X, the values of Michaelis-Menten coefficients (Km) were 31.7 nM with thrombin-activated factor VIII, and 14.2 nM with factor Xa-activated factor VIII. Maximal rates were 23.4 and 4.9 nM factor Xa/min, respectively. The apparent catalytic efficiency was similar with either form of factor VIIIa. Kinetic profiles obtained with platelets as a source of membrane were comparable to those obtained with monocytes. These kinetic profiles are consistent with a 1:1 stoichiometry for the functional interaction between cofactor and enzyme on the surface of monocytes and platelets. Taken together, these results indicate that autocatalytic pathways connecting the extrinsic, intrinsic, and common coagulation pathways can operate efficiently on the monocyte membrane.     

Occurrence of O-linked Xyl-GlcNAc and Xyl-Glc disaccharides in trocarin, a factor Xa homolog from snake venom

Summary.  Trocarin is a 46515-Da group D prothrombin-activating glycoprotein from the venom of the Australian elapid, Tropidechis carinatus . Amino acid sequencing and functional characterization of trocarin demonstrated that it is a structural and functional homolog of mammalian blood coagulation factor (F)Xa. In this study we show that, in contrast to mammalian Xa, which is not glycosylated, trocarin contains an O-linked carbohydrate moiety in its light chain and an N-linked carbohydrate oligosaccharide in its heavy chain. Mass spectrometry and sugar compositional analysis indicate that the O-linked carbohydrate moiety is a mixture of Xyl-GlcNAc-, GlcNAc-, Xyl-Glc- and Glc- structures linked to Ser 52. The N-linked carbohydrate on Asn 45 of the heavy chain is a sialylated, diantennary oligosaccharide that is located at the lip of the active site of the prothrombin activator.