The lipoprotein-associated coagulation inhibitor that inhibits the factor VII-tissue factor complex also inhibits factor Xa: insight into its possible mechanism of action

Blood coagulation is initiated when plasma factor VII(a) binds to its essential cofactor tissue factor (TF) and proteolytically activates factors X and IX. Progressive inhibition of TF activity occurs upon its addition to plasma. This process is reversible and requires the presence of VII(a), catalytically active Xa, Ca2+, and another component that appears to be associated with the lipoproteins in plasma, a lipoprotein-associated coagulation inhibitor (LACI). A protein, LACI(HG2), possessing the same inhibitory properties as LACI, has recently been isolated from the conditioned media of cultured human liver cells (HepG2). Rabbit antisera raised against a synthetic peptide based on the N-terminal sequence of LACI(HG2) and purified IgG from a rabbit immunized with intact LACI(HG2) inhibit the LACI activity in human serum. In a reaction mixture containing VIIa, Xa, Ca2+, and purified LACI(HG2), the apparent half-life (t1/2) for TF activity was 20 seconds. The presence of heparin accelerated the initial rate of inhibition threefold. Antithrombin III alpha alone had no effect, but antithrombin III alpha with heparin abrogated the TF inhibition. LACI(HG2) also inhibited Xa with an apparent t1/2 of 50 seconds. Heparin enhanced the rate of Xa inhibition 2.5-fold, whereas phospholipids and Ca2+ slowed the reaction 2.5-fold. Xa inhibition was demonstrable with both chromogenic substrate (S-2222) and bioassays, but no complex between Xa and LACI(HG2) could be visualized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Nondenaturing PAGE, however, showed that LACI(HG2) bound to Xa but not to X or Xa inactivated by diisopropyl fluorophosphate. Thus, LACI(HG2) appears to bind to Xa at or near its active site. Bovine factor Xa lacking its gamma-carboxyglutamic acid-containing domain, BXa(-GD), through treatment with alpha-chymotrypsin, was used to further investigate the Xa requirement for VIIa/TF inhibition by LACI(HG2). LACI(HG2) bound to BXa(-GD) and inhibited its catalytic activity against a small molecular substrate (Spectrozyme Xa), though at a rate approximately sevenfold slower than native BXa. Preincubation of LACI(HG2) with saturating concentrations of BXa(-GD) markedly retarded the subsequent inhibition of BXa. The VII(a)/TF complex was not inhibited by LACI(HG2) in the presence of BXa(-GD), and further, preincubation of LACI(HG2) with BXa(-GD) slowed the inhibition of VIIa/TF after the addition of native Xa. The results are consistent with the hypothesis that inhibition of VII(a)/TF involves the formation of a VIIa-TF-XA-LACI complex that requires the GD of XA.(ABSTRACT TRUNCATED AT 400 WORDS)     

Studies of a mechanism inhibiting the initiation of the extrinsic pathway of coagulation

We have extended earlier studies (Blood 66:204, 1985) of a mechanism of inhibition of factor VIIa/tissue factor activity that requires a plasma component (called herein extrinsic pathway inhibitor or EPI) and factor Xa. An activated peptide release assay using 3H-factor IX as a substrate was used to evaluate inhibition. Increasing the tissue factor concentration from 20% to 40% (vol/vol) overcame the inhibitory mechanism in normal plasma but not in factor VII-deficient plasma supplemented with a low concentration of factor VII. A second wave of factor IX activation obtained by a second addition of tissue factor to plasma with a normal factor VII concentration was almost abolished by supplementing the reaction mixture with additional EPI and factor X. Factor Xa's active site was necessary for factor Xa's contribution to inhibition, but preliminary incubation of factor Xa with EPI in the absence of factor VIIa/tissue factor complex or of factor VIIa/tissue factor complex in the absence of EPI did not replace the need for the simultaneous presence of factor Xa, factor VIIa/tissue factor, calcium, and EPI in an inhibitory reaction mixture. Inhibition of factor VIIa/tissue factor was reversible; both tissue factor and factor VIIa activity could be recovered from a dissociated, inhibited factor VIIa/tissue factor complex. EPI appeared to bind to a factor VIIa/tissue factor complex formed in the presence of factor Xa but not to a factor VIIa/tissue factor complex formed in the absence of factor Xa.     

Hemophilia as a defect of the tissue factor pathway of blood coagulation: effect of factors VIII and IX on factor X activation in a continuous-flow reactor.

The effect of factors VIII and IX on the ability of the tissue factor-factor VIIa complex to activate factor X was studied in a continuous-flow tubular enzyme reactor. Tissue factor immobilized in a phospholipid bilayer on the inner surface of the tube was exposed to a perfusate containing factors VIIa, VIII, IX, and X flowing at a shear rate of 57, 300, or 1130 sec-1. Factor Xa in the effluent was determined by chromogenic assay. The flux of factor Xa (moles formed per unit surface area per unit time) was strongly dependent on wall shear rate, increasing about 3-fold as wall shear rate increased from 57 to 1130 sec-1. The addition of factors VIII and IX at their respective plasma concentrations resulted in a further 2- to 3-fold increase. The direct activation of factor X by tissue factor-factor VIIa could be virtually eliminated by the lipoprotein-associated coagulation inhibitor; however, when factors VIII and IX were present at their approximate plasma concentrations, factor Xa production rates were enhanced 15- to 20-fold. These results suggest that the tissue factor pathway, mediated through factors VIII and IX, produces significant levels of factor Xa even in the presence of an inhibitor of the tissue factor-factor VIIa complex; moreover, the activation is dependent on local shear conditions. These findings are consistent both with a model of blood coagulation in which initiation of the system results from tissue factor and with the bleeding observed in hemophilia.     

Studies of the activation of factor VII bound to tissue factor [see comments]

Experiments were performed to evaluate activation of factor VII bound to relipidated tissue factor (TF) in suspension and to TF constitutively expressed on the surface of an ovarian carcinoma cell line (OC-2008). Activation was assessed by measuring cleavage of 125I- factor VII and by the ability of unlabeled factor VII to catalyze activation of a variant factor IX molecule that, after activation, cannot back-activate factor VII. Factor Xa was found to effectively activate factor VII bound to TF relipidated in either acidic or neutral phospholipid vesicles. Autoactivation of factor VII bound to TF in suspension was dependent on the preparation of TF apoprotein used and the technique of its relipidation. This highlights the need for caution in extrapolating data from TF in suspension to the activation of factor VII bound to cell surfaces during hemostasis. A relatively slow activation of factor VII bound to OC-2008 monolayers in the absence of added protease was observed consistently. Antithrombin in the presence or absence of heparin prevented this basal activation, whereas TF pathway inhibitor (TFPI/factor Xa complexes had only a limited inhibitory effect. Adding a substrate concentration of factor X markedly enhanced basal activation of factor VII, but both TFPI/factor Xa and antithrombin/heparin abolished this enhancement. Overall, our data are compatible with the hypothesis that not all factor VII/TF complexes formed at a site of tissue injury are readily activated to factor VIIa (VIIa)/TF complexes during hemostasis. The clinical significance of this is discussed.     

The effects of shear rate on the enzymatic activity of the tissue factor-factor VIIa complex

A novel enzyme reactor for studying phospholipid-dependent reactions was used to explore the effects of flow on tissue factor (TF)-initiated coagulation. Capillary tubes (0.27 mm i.d.) were coated with a phospholipid bilayer containing TF, a transmembrane protein that is an essential cofactor for factor VII. Production of factor Xa exiting the tube was monitored with time during perfusion of the capillary with factor X (50 to 1500 nM) in the presence of factor VIIa (10 nM). Steady-state production of factor Xa as a function of [FX] was determined by chromogenic assay (Spectrozyme Xa) for a range of wall shear rates (25 to 3000 sec-1). Diffusion was found to play a major limiting role in FXa production for TF:30% phosphatidylserine (PS)/70% phosphatidylcholine (PC) surfaces. In contrast, TF/PC surfaces slowed the reaction sufficiently to enter a kinetically controlled regime where shear fluid had little effect on Km. In contrast with classical enzyme kinetic theory there was a three-fold increase in Vmax as shear increased from 25 to 300 sec-1. This finding implies a direct effect of shear on the kinetics of factor X activation by TF/FVIIa. The perfusion system is simple to use and offers the potential for studying the role of flow on a wide variety of enzymatic reactions related to coagulation.     

Factors IXa and Xa play distinct roles in tissue factor-dependent initiation of coagulation

Tissue factor is the major initiator of coagulation. Both factor IX and factor X are activated by the complex of factor VIIa and tissue factor (VIIa/TF). The goal of this study was to determine the specific roles of factors IXa and Xa in initiating coagulation. We used a model system of in vitro coagulation initiated by VIIa/TF and that included unactivated platelets and plasma concentrations of factors II, V, VIII, IX, and X, tissue factor pathway inhibitor, and antithrombin III. In some cases, factor IX and/or factor X were activated by tissue factor- bearing monocytes, but in some experiments, picomolar concentrations of preactivated factor IX or factor X were used to initiate the reactions. Timed samples were assayed for both platelet activation and thrombin activity. Factor Xa was 10 times more potent than factor IXa in initiating platelet activation, but factor IXa was much more effective in promoting thrombin generation than was factor Xa. In the presence of VIIa/TF, factor X was required for both platelet activation and thrombin generation, while factor IX was only required for thrombin generation. We conclude that VIIa/TF-activated factors IXa and Xa have distinct physiologic roles. The main role of factor Xa that is initially activated by VIIa/TF is to activate platelets by generating an initial, small amount of thrombin in the vicinity of platelets. Factor IXa, on the other hand, enhances thrombin generation by providing factor Xa on the platelet surface, leading to prothrombinase formation. Only tiny amounts of factors IX and X need to be activated by VIIa/TF to perform these distinct functions. Our experiments show that initiation of coagulation is highly dependent on activation of small amounts of factors IXa and Xa in proximity to platelet surfaces and that these factors play distinct roles in subsequent events, leading to an explosion of thrombin generation. Furthermore, the specific roles of factors IXa and Xa generated by VIIa/TF are not necessarily reflected by the kinetics of factor IXa and Xa generation.     

Activation of factor X and its regulation by tissue factor pathway inhibitor in small-diameter capillaries lined with human endothelial cells.

The activation of factor X at the surface of endothelial cells was investigated under controlled flow conditions. A method is described for preparing polyethylene capillaries whose inner walls are covered with a confluent layer of human umbilical vein endothelial cells. To obtain a stable and unperturbed layer of endothelial cells it was essential to pre-perfuse the endothelialized capillaries with medium for about 18 hours. At this stage no tissue factor activity could be detected, but when the seeded cells were perfused with medium containing tumor necrosis factor (TNF) a maximum steady-state rate of factor Xa production (16 fmol factor Xa/min/cm2) was observed within 8 hours. Further experiments were performed with endothelial cells incubated for 4 hours with TNF. Factor Xa was produced at a rate of 7 fmol factor Xa/min/cm2 on perfusion of the capillaries with factor X (100 nmol/L) and factor VII (0.1 U/mL) at a shear rate of 34 s-1. The extracellular matrix preparations of these cells produced factor Xa at a 20-fold higher rate (150 fmol factor Xa/min/cm2). In both cases factor Xa formation was dependent on the presence of factor VII and was completely inhibited when the perfusate also contained 5 nmol/L recombinant tissue factor pathway inhibitor (rTFPI). Pre-perfusion with factor Xa-TFPI complex in the absence of factor VIIa caused a much lesser inhibitory effect, suggesting that TFPI-mediated neutralization of endothelial cell and matrix tissue factor activity requires the presence of factor VIIa in addition to the presence of factor Xa.     

Structural requirements for TFPI-mediated inhibition of neointimal thickening after balloon injury in the rat.

The intimal thickening that follows vascular injury is inhibited by periprocedural tissue factor pathway inhibitor (TFPI) treatment in animal models. TFPI is a multivalent Kunitz-type protease inhibitor that inhibits factor Xa via its second Kunitz domain and the factor VIIa/tissue factor (TF) complex via its first Kunitz domain. The basic C-terminus of TFPI is required for the binding of TFPI to cell surfaces and cell-bound TFPI mediates the internalization and degradation of factor X and the down regulation of surface factor VIIa/TF activity. The C-terminus of TFPI is also required for its reported direct inhibition of smooth muscle cell proliferation in vitro. To examine the structural requirements for the inhibition of neointimal formation by TFPI, several TFPI-related proteins were tested in the rat carotid angioplasty model: 1) XK(1), a hybrid protein containing the N-terminal portion of factor X and the first Kunitz domain of TFPI that directly inhibits factor VIIa/TF; 2) TFPI(WT), the full-length TFPI molecule that inhibits factor Xa and factor VIIa/TF and binds cell surfaces; 3) TFPI(K36I), an altered form of TFPI that inhibits factor Xa, but not factor VIIa/TF, and binds cell surfaces; 4) TFPI(13-161), a truncated form of TFPI that inhibits factor VIIa/TF but interacts with factor Xa poorly and does not bind to cell surfaces. Seven day infusions of XK(1), TFPI(WT), and high levels of TFPI(K36I) begun the day before balloon-induced vascular injury produced a significant reduction in the intimal hyperplasia measured 28 days after angioplasty. The infusion of high concentrations of TFPI(13-161) was ineffective in this model. These in vivo results directly mirror the ability of each TFPI-related protein to inhibit tissue thromboplastin-induced coagulation in rat plasma: XK(1) approximately TFPI(WT)>TFPI(K36I)>TFPI(13-161). The studies confirm the important role of TF-mediated coagulation in the smooth muscle proliferation and neointimal thickening that follows vascular injury and suggest that the anticoagulant effect alone of TFPI and TFPI-related proteins is sufficient to explain their therapeutic action.     

Mechanism of antithrombin III inhibition of factor VIIa/tissue factor activity on cell surfaces. Comparison with tissue factor pathway inhibitor/factor Xa-induced inhibition of factor VIIa/tissue factor activity

Recent studies have shown that antithrombin III (AT III)/heparin is capable of inhibiting the catalytic activity of factor VIIa bound either to relipidated tissue factor (TF) in suspension or to TF expressed on cell surfaces. We report studies of the mechanism of which by AT III inhibits factor VIIa bound to cell surface TF and compare this inhibitory mechanism with that of tissue factor pathway inhibitor (TFPI)-induced inhibition of factor VIIa/TF. AT III alone and AT III/heparin to a greater extent reduced factor VIIa bound to cell surface TF. Our data show that the decrease in the amount of factor VIIa associated with cell surface TF in the presence of AT III was the result of (1) accelerated dissociation of factor VIIa from cell surface TF after the binding of AT III to factor VIIa/TF complexes and (2) the inability of the resultant free factor VIIa-AT III complexes to bind effectively to a new cell surface TF site. Binding of TFPI/factor Xa to cell surface factor VIIa/TF complexes markedly decreased the dissociation of factor VIIa from the resultant quaternary complex of factor VIIa/TF/TFPI/factor Xa. Addition of high concentrations of factor VIIa could reverse the AT III-induced inhibition of cell surface factor VIIa/TF activity but not TFPI/factor Xa-induced inhibition of factor VIIa/TF activity.     

Phospholipid surfaces regulate the delivery of substrate to tissue factor:VIIa and the removal of product

For many years, the essential role of tissue factor (TF) in coagulation and thrombogenesis has been recognized. The catalytic complex of TF and VIIa (TF:VIIa) is membrane-bound whereas its substrate, factor X (FX), is distributed between a phospholipid-bound fraction and one that is in true solution in 3-dimensional space. This complicates analytical solutions for the kinetic mechanisms describing this reaction because dimensionality must be preserved. We believe that, at the time of activation, FX is simultaneously bound to TF:VIIa and the phospholipid surface. The hydrolysis of a peptide bond activates FX and the product, Xa, is yet bound to the catalytic complex in a manner such that it must leave before a new molecule of X encounters the complex. This means that, in principle, the classically defined Vmax does not apply because on a surface, infinite substrate and its attendant infinite collision frequency do not apply. We show that increasing the lipid surface area available to each TF:VIIa increases the apparent k(cat) and that it approaches a maximum asymptotically, exhibiting a K(1/2) at a 40 nm lipid radius. Notably, this is of the same order as transient confinement zones that have been identified on the surface of living cells. We believe the increased lipid surface area allows the Xa to easily diffuse away from the enzyme complex along the 2D lipid surface, thereby allowing new substrate to approach the enzyme and minimizing collisions between the product and the enzyme complex (product inhibition). Thus, after Xa leaves the vicinity of the enzyme, a new FX molecule is able to bind TF:VIIa and the rate at which this complex forms cannot exceed the leaving rate of Xa from the TF:VIIa and phospholipid sites. Thus, this parameter is of critical interest. Starting with the off-rate of Xa from appropriate phospholipid surfaces, we note that the literature values differ by a factor of approximately 500. Using energy transfer techniques between 30% phosphatidylserine/70% phosphatidylcholine vesicles and human F.Xa, we measured this off rate and found it agrees closely with the Biacore generated data. We have determined the binding parameters of Xa to vesicles and a continuous supported bilayer. Our data are in excellent agreement with the data derived using a lipid coated Biacore chip.     

The effect of leukocyte elastase on tissue factor pathway inhibitor.

Tissue factor pathway inhibitor (TFPI) is a multivalent Kunitz-type inhibitor that directly inhibits factor Xa and, in a factor Xa-dependent fashion, also inhibits the factor VIIa/tissue factor (TF) catalytic complex. The Kunitz-2 domain in TFPI is needed for the binding and inhibition of factor Xa, while the Kunitz-1 domain appears to be responsible for binding factor VIIa in a quaternary factor Xa-TFPI-factor VIIa/TF inhibitory complex. Human leukocyte elastase (HLE) proteolytically cleaves TFPI between threonine-87 and threonine-88 within the polypeptide that links the Kunitz-1 and Kunitz-2 domains in the TFPI molecule. HLE treatment not only affects the ability of TFPI to inhibit factor VIIa/TF, but also dramatically reduces its inhibition of factor Xa. Both purified HLE and stimulated neutrophils regenerate TF activity from a preformed factor Xa-TFPI-factor VIIa/TF inhibitory complex. Kinetic analysis suggests that HLE cleavage does not effect the affinity of the initial encounter interaction between factor Xa and TFPI, whereas it markedly reduces the affinity of the final factor Xa:TFPI complex with Ki (final) values for untreated and HLE-treated TFPI of 58 pmol/L and 4.4 nmol/L, respectively. Thus, an epitope in the amino-terminal region of TFPI or a conformation of the TFPI molecule that requires the presence of this region is needed in concert with the Kunitz-2 domain to produce optimal inhibition of factor Xa by TFPI.     

Factor Xa binding to annexin 2 mediates signal transduction via protease-activated receptor 1

The serine protease zymogen factor X is converted to its catalytically active form factor Xa by the binary complex of factor VIIa bound to its cell surface receptor tissue factor (TF) or by the intrinsic Xase complex, which consists of active factors VIII (VIIIa), IX (IXa), factor X, and Ca2+. Factor Xa has procoagulant activity by conversion of prothrombin to thrombin and also induces signal transduction, either alone or in the ternary TF:VIIa:factor Xa coagulation initiation complex. Factor Xa cleaves and activates protease activated receptor (PAR)1 or -2, but factor Xa signaling efficiency varies among cell types. We show here that annexin 2 acts as a receptor for factor Xa on the surface of human umbilical vein endothelial cells and that annexin 2 facilitates factor Xa activation of PAR-1 but does not enhance coagulant function of factor Xa. Overexpression of TF abolishes annexin 2 dependence on factor Xa signaling and diminishes binding to cell surface annexin 2, whereas selectively abolishing TF promotes the annexin 2/factor Xa interaction. We propose that annexin 2 serves to regulate factor Xa signaling specifically in the absence of cell surface TF and may thus play physiological or pathological roles when factor Xa is generated in a TF-depleted environment.     

The regulation of the factor VII-dependent coagulation pathway: rationale for the effectiveness of recombinant factor VIIa in refractory bleeding disorders

We have explored the molecular basis of the clinical therapeutic effect of factor VIIa in hemophilia A using empirical reconstituted in vitro thrombin generation models. Tissue factor acts as a receptor and activator of preexistent but virtually inactive two-chain plasma factor VIIa. However, most of the factor VII circulates as a single-chain inactive zymogen (10 nM) and a trace (approximately 10-100 pM) circulates in the active two-chain form. Empirical reconstitution (purified factors VIIa, X, IX, VIII, V, prothrombin, and relipidated tissue factor) showed that plasma concentrations of factor VII (10 nM) prolong the initiation phase of thrombin generation significantly at low concentrations of tissue factor and 100 pM factor VIIa. Thus, we show for the first time that the zymogen factor VII may have a very significant inhibitory action on thrombin generation at physiologic ratios of factor VII to factor VIIa. The inhibition kinetics of factor Xa generation by low concentrations of tissue factor indicate that factor VII inhibits the reaction by competition for the initial binding of factor VIIa to tissue factor. Physiological concentrations of factor VII also inhibit the maximal rate of thrombin generation by 100 pM factor VIIa in the absence of factor VIII. Increasing the concentration of factor VIIa to 2 nM in this hemophilia A model overcame the inhibition of thrombin generation by 10 nM factor VII. Increasing the concentration up to 10 nM factor VIIa in the absence of factor VIII completely normalized the thrombin generation profile to that observed in the presence of factor VIII and 10 nM factor VII/100 pM factor VIIa. The levels of factor VIIa that overcome the inhibitory effect of factor VII and that normalize thrombin generation in our model are consistent with the observed plasma levels of factor VIIa needed to manage hemophilia A. Our data strongly indicate that the therapeutic mechanism of factor VIIa in the medical treatment of hemophiliacs with inhibitors is in large part based on overcoming the inhibitory effect of factor VII on thrombin generation.     

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.     

Aptamer ARC19499 mediates a procoagulant hemostatic effect by inhibiting tissue factor pathway inhibitor

Hemophilia A and B are caused by deficiencies in coagulation factor VIII (FVIII) and factor IX, respectively, resulting in deficient blood coagulation via the intrinsic pathway. The extrinsic coagulation pathway, mediated by factor VIIa and tissue factor (TF), remains intact but is negatively regulated by tissue factor pathway inhibitor (TFPI), which inhibits both factor VIIa and its product, factor Xa. This inhibition limits clot initiation via the extrinsic pathway, whereas factor deficiency in hemophilia limits clot propagation via the intrinsic pathway. ARC19499 is an aptamer that inhibits TFPI, thereby enabling clot initiation and propagation via the extrinsic pathway. The core aptamer binds tightly and specifically to TFPI. ARC19499 blocks TFPI inhibition of both factor Xa and the TF/factor VIIa complex. ARC19499 corrects thrombin generation in hemophilia A and B plasma and restores clotting in FVIII-neutralized whole blood. In the present study, using a monkey model of hemophilia, FVIII neutralization resulted in prolonged clotting times as measured by thromboelastography and prolonged saphenous-vein bleeding times, which are consistent with FVIII deficiency. ARC19499 restored thromboelastography clotting times to baseline levels and corrected bleeding times. These results demonstrate that ARC19499 inhibition of TFPI may be an effective alternative to current treatments of bleeding associated with hemophilia.     

Activation of human factor VII by factors IXa and Xa on human bladder carcinoma cells

Single chain factor VII is converted by limited proteolysis to its activated form, factor VIIa, by a number of blood coagulation proteases including factor IXa and factor Xa. We have determined the relative rate of human factor VII activation by human factors IXa and Xa in two different systems: one containing Ca++ and human bladder carcinoma (J82) cells, and the other containing Ca++ and mixed brain phospholipids. The rate of factor VII activation was determined by a one stage coagulation assay, and proteolytic cleavage of factor VII was assessed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and Western blotting techniques. On a molar basis, factor Xa was sixfold more efficient than factor IXa beta in activating factor VII when the activation reaction occurs on J82 cell surfaces. In contrast, when incubation takes place in a suspension of mixed phospholipids, factor Xa was 18-fold more efficient in activating factor VII than factor IXa beta. In addition, factor IXa alpha activated factor VII at a rate approximately one-half that observed using factor IXa beta. In the absence of cells or phospholipids, no activation of factor VII by either factors IXa or Xa was observed. The addition of stoichiometric amounts of either recombinant human factor VIII (des B-domain) or plasma-derived factor VIIIa failed to augment the rate of factor VII activation by either factors IXa alpha or IXa beta. Likewise, purified human factor Va failed to influence the rate of factor VII activation by factor Xa in either system. Collectively, our studies reveal that J82 cells possess procoagulant phospholipid capable of readily supporting the activation of factor VII by either factors IXa beta or Xa. Our data also demonstrate that the relative ability of factor IXa beta and Xa to activate factor VII is significantly different when these reactions occur on tumor cell surfaces as compared with suspensions of mixed phospholipids.     

Inhibition of thrombin generation by the zymogen factor VII: implications for the treatment of hemophilia A by factor VIIa

Factor VII circulates as a single chain inactive zymogen (10 nmol/L) and a trace ( approximately 10-100 pmol/L) circulates as the 2-chain form, factor VIIa. Factor VII and factor VIIa were studied in a coagulation model using plasma concentrations of purified coagulation factors with reactions initiated with relipidated tissue factor (TF). Factor VII (10 nmol/L) extended the lag phase of thrombin generation initiated by 100 pmol/L factor VIIa and low TF. With the coagulation inhibitors TFPI and AT-III present, factor VII both extended the lag phase of the reaction and depressed the rate of thrombin generation. The inhibition of factor Xa generation by factor VII is consistent with its competition with factor VIIa for TF. Thrombin generation with TF concentrations >100 pmol/L was not inhibited by factor VII. At low tissue factor concentrations (<25 pmol/L) thrombin generation becomes sensitive to the absence of factor VIII. In the absence of factor VIII, factor VII significantly inhibits TF-initiated thrombin generation by 100 pmol/L factor VIIa. In this hemophilia A model, approximately 2 nmol/L factor VIIa is needed to overcome the inhibition of physiologic (10 nmol/L) factor VII. At 10 nmol/L, factor VIIa provided a thrombin generation response in the hemophilia model (0% factor VIII, 10 nmol/L factor VII) equivalent to that observed with normal plasma, (100% factor VIII, 10 nmol/L factor VII, 100 pmol/L factor VIIa). These results suggest that the therapeutic efficacy of factor VIIa in the medical treatment of hemophiliacs with inhibitors is, in part, based on overcoming the factor VII inhibitory effect. (Blood. 2000;95:1330-1335)     

Tissue factor pathway inhibitor: the carboxy-terminus is required for optimal inhibition of factor Xa.

Tissue factor pathway inhibitor (TFPI) is a multivalent Kunitz-type protease inhibitor that binds to and inactivates factor Xa directly, and in a factor Xa-dependent fashion inhibits the factor VIIa/tissue factor catalytic complex. TFPI is a slow, tight-binding, competitive, and reversible inhibitor of factor Xa, in which the formation of an initial encounter complex between TFPI and factor Xa is followed by slow isomerization to a final, tightened complex. Wild-type recombinant TFPI (rTFPI), expressed in mouse C127 cells, separates into two forms on heparin-agarose chromatography that elute at 0.3 mol/L and 0.6 mol/L NaCl. Western blot analysis shows that both forms contain the N-terminus of full-length TFPI, but only rTFPI(0.6) is recognized by an antibody directed against the C-terminus. rTFPI(0.3) and rTFPI(0.6) inhibit factor Xa with 1:1 stoichiometry and inhibit factor VIIa/tissue factor equally in an endpoint-type assay. However, rTFPI(0.6) is a more potent inhibitor than rTFPI(0.3) of coagulation in normal plasma induced by either factor Xa or tissue factor. The initial inhibition of factor Xa (less than 5 seconds) produced by rTFPI(0.6) is several-fold greater than that produced by rTFPI(0.3), presumably reflecting a lower Ki of the immediate encounter complex between factor Xa and TFPI. The differential effect of these forms of TFPI on tissue factor-induced coagulation in normal plasma appears to be directly related to their ability to inhibit factor Xa. To confirm the role of the C-terminal region of TFPI in optimal factor Xa inhibition, a carboxy-terminal mutant of rTFPI, which is truncated after leucine 252 and thus lacks the basic sequence K T K R K R K K Q R V K (residues 254-265), was expressed in C127 cells. This form of rTFPI elutes from heparin-agarose at 0.28 mol/L NaCl and inhibits factor Xa at a rate that is slower than rTFPI(0.3). The Ki(final)s for factor Xa inhibition by rTFPI(0.6), rTFPI(0.3), and rTFPI1-252 are 3.1 +/- 0.6, 19.6 +/- 0.8, and 19.6 +/- 3.0 pmol/L, respectively.     

Physiological concentrations of tissue factor pathway inhibitor do not inhibit prothrombinase

Tissue factor pathway inhibitor (TFPI) is a Kunitz-type serine proteinase inhibitor that directly inhibits factor Xa and, in a factor Xa dependent manner, inhibits the factor VIIa/tissue factor catalytic complex. The inhibitory effect of TFPI in prothrombin activation assays using purified components of the prothrombinase complex was examined. When factor Xa is added to mixtures containing TFPI, prothrombin, calcium ions, and nonactivated platelets or factor V and phospholipids, TFPI significantly reduces subsequent thrombin generation, and the inhibitory effect is enhanced by heparin. If factor Xa is preincubated with calcium ions and thrombin-activated platelets or factor Va and phospholipids to permit formation of prothrombinase before the addition of prothrombin and physiologic concentrations of TFPI (< 8 nmol/L), minimal inhibition of thrombin generation occurs, even in the presence of heparin. Thus, contrary to results in amidolytic assays with chromogenic substrates, prothrombinase is resistant to inhibition by TFPI in the presence of its physiological substrate, prothrombin. Higher concentrations of TFPI (approximately 100 nmol/L), similar to those used in animal studies testing for therapeutic actions of TFPI, do effectively block prothrombinase activity.