Factor IXa-factor VIIIa-cell surface complex does not contribute to the basal activation of the coagulation mechanism in vivo.

We have infused recombinant factor VIIa into patients with hereditary factor VII deficiency with marked reductions in plasma concentrations of factor IX activation peptide (FIXP), factor X activation peptide (FXP), and prothrombin activation fragment F1+2. These investigations show substantial elevations in these markers of coagulation activation and thereby demonstrate that the factor VII-tissue factor pathway is largely responsible for the activation of factor IX as well as factor X in the basal state (ie, the absence of thrombosis or provocative stimuli). We have administered a monoclonal antibody purified factor IX concentrate to individuals with hemophilia B. These studies show an increase in the plasma levels of FIXP that were initially greatly decreased, but no change in FXP or F1+2. We have also infused highly purified factor VIII concentrate into patients with hemophilia A. The data demonstrate no significant changes in the plasma concentrations of FXP and F1+2. The above observations indicate that factor IXa generated by the factor VII-tissue factor pathway is unable to activate factor X under basal conditions. Based upon the above findings, we outline a model of blood coagulation system function under basal conditions, and suggest a process by which the generation of factor Xa and thrombin might be accelerated during normal hemostasis and in the setting of thrombotic disorders.     

Detection of factor X activation in humans

A sensitive radioimmunoassay (RIA) for the fragment that is liberated from factor X when this zymogen is activated by factor VII/VIIa-tissue factor or factor IXa was developed. Antisera were raised in rabbits to a synthetic 15 amino acid peptide containing the COOH-terminal sequence of the activation fragment coupled to bovine serum albumin with glutaraldehyde. The reactivity of the antibody population obtained toward the factor X zymogen was negligible (less than 1/36,000 that of the activation peptide on a molar basis). However, because other plasma constituents contributed to a nonspecific basal signal in the RIA, a procedure by which the peptide could be reproducibly extracted from plasma was developed. The mean level of this species in normal individuals younger than the age of 40 was 66.4 pmol/L, and elevations up to 550 pmol/L were observed in patients with evidence of disseminated intravascular coagulation. The validity of these measurements of factor X activation is supported by the fact that the RIA signal migrates on reverse-phase high pressure liquid chromatography in a manner identical to that of the native peptide and can be quantitatively recovered. The mean concentration of the activation fragment was markedly decreased to 25.7 pmol/L in patients with hereditary factor VII deficiency (P = .0001 v normal controls), whereas the mean level in subjects with factor VIII deficiency was 61.1 pmol/L (P greater than .1 v normal controls). These data indicate that the basal (ie, in the absence of thrombosis or provocative stimuli) levels of FXP under in vivo conditions result mainly from the activity of the extrinsic pathway.     

Tissue factor-dependent activation of tritium-labeled factor IX and factor X in human plasma

Recent investigations have suggested that the activation of factor IX by factor VII/tissue factor may be an important alternative route to the generation of factor Xa. Accordingly, we have compared the tissue factor-dependent activation of tritium-labeled factor IX and factor X in a human plasma system and have studied the role of proteases known to stimulate factor VII activity. Plasma was defibrinated by heating and depleted of its factors IX and X by passing it through antibody columns. Addition of human brain thromboplastin, Ca2+, and purified 3H- labeled factor X to the plasma resulted, after a short lag, in burst- like activation of the factor X, measured as the release of radiolabeled activation peptide. The progress of activation was slowed by both heparin and a specific inhibitor of factor Xa, suggesting a feedback role for this enzyme, but factor X activation could not be completely abolished by such inhibitors. In the case of 3H-factor IX activation, the rate also increased for approximately 3 min after addition of thromboplastin, but was not subsequently curtailed. A survey of proteases implicated as activators of factor VII in other settings showed that both factor Xa and (to a much smaller extent) factor IXa could accelerate the activation of factor IX. However, factor Xa was unique in obliterating activation when present at concentrations greater than approximately 1 nM. Heparin inhibited the tissue factor-dependent activation of factor IX almost completely, apparently through the effect of antithrombin on the feedback reactions of factors Xa and IXa on factor VII. These results suggest that a very tight, biphasic control of factor VII activity exists in human plasma, which is modulated mainly by factor Xa. Variation of the factor IX or factor X concentrations permitted kinetic parameters for each activation to be derived. At saturation of factor VIIa/tissue factor, factor IX activation was significantly more rapid than was previously found in bovine plasma under similar conditions. The activation of factor X at saturation was slightly more rapid than in bovine plasma, despite the presence of heparin.     

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.     

Functional characterization of platelet-bound factor XIa: retention of factor XIa activity on the platelet surface

Previously we have shown that both factor XI and factor XIa are bound specifically to distinct, high-affinity sites on the surface of activated platelets in the presence of high Mr kininogen. To determine the functional significance of factor XIa binding to platelets, bound factor XIa has now been compared with the unbound enzyme. Platelets incubated with thrombin, high Mr kininogen, and 125I-labeled factor XIa bound 130 to 500 molecules of factor XIa per platelet. Scatchard analysis of binding data give a dissociation constant (Kd) of 822 pmol/L +/- 140 (SEM). Rates of factor IX activation, assayed by release of trichloroacetic acid-soluble 3H-labeled activation peptide from purified [3H]-factor IX, were similar when factor XIa was bound to platelets and when it was free in solution. The platelet-bound factor XIa was isolated by centrifugation through 20% sucrose and was functionally characterized both in a factor XIa coagulation assay and in the factor IX activation peptide release assay in comparison with unbound factor XIa in the presence of treated platelets. The functional activity of platelet-bound factor XIa as a factor IX activator as well as its structural integrity were shown to be fully retained on the platelet surface. Since platelets bind factor XI and promote its proteolytic activation to factor XIa, factor XIa binding to platelets may serve to localize factor IX activation to the hemostatic plug, where factor XIa is protected from inactivation by plasma protease inhibitors and where acceleration of subsequent coagulation reactions can occur.     

Phospholipids accelerate factor IX activation by surface bound factor XIa

Activation of bovine factor IX by surface bound factor XIa which was generated either by activation of human citrated factor IX deficient plasma or a mixture of purified human factors XII, high molecular weight kininogen (HMWK) and XI in glass tubes, is accelerated by cephalin. Human brain cephalin in dilutions ranging from 1:5 to 1:500 was studied for its effect on the activation of factor IX in concentrations of 1.0 u/ml and 16 u/ml. Cephalin dilutions from 1:5 to 1:30 accelerated the activation of the concentrated factor IX sample two- to threefold. Protein cleavage of this factor IX sample in the presence of 1:30 cephalin occurred twice as fast as in the absence of cephalin. Activation of the dilute factor IX sample (1.0 u/ml) was most effectively accelerated by cephalin in dilutions from 1:30 to 1:250. In all experiments the presence of phospholipid led to an increased factor IX cleavage concomitantly with faster generation of factor IXa activity. The results demonstrate that phospholipids actively participate in blood coagulation at an earlier stage than previously described.     

Inhibition of platelet prothrombinase activity by a lupus anticoagulant

Lupus anticoagulants are spontaneously occurring antibodies with specificity for negatively charged phospholipids. The plasma of a patient with such a polyclonal antibody of IgM type demonstrated low levels of factor VIII coagulant activity (VIII:C) and factors IX, XI and XII when analyzed by biologic clotting assays, whereas in immunochemical assays, normal levels of VIII coagulant antigen and factor IX were obtained. After immunoadsorption of patient plasma with anti-IgM Sepharose, normal biologic activities were demonstrated in clotting assays for VIII:C, factors IX, XI, and XII. The addition of the patient's isolated IgM to normal plasma resulted in grossly abnormal results in these coagulation assays, and a pattern similar to that of the patient's plasma was obtained. The inhibitory effect of the patient's lupus anticoagulant on blood coagulation was demonstrated also in platelet-rich plasma. The results of the clotting assays indicated that the anticoagulant inhibited several of the reactions in the blood coagulation cascade. The availability of purified components made it possible to demonstrate an inhibiting effect on the activation of prothrombin by factor Xa in the presence of isolated platelets, as well as in a system where purified factor V and well defined phospholipid vesicles were substituted for the platelets.     

Newer concepts of blood coagulation

Summary. In this report we describe an in vitro model of blood coagulation reactions that mimics as closely as possible the in vivo condition. Our model indicates that the tissue factor—factor VIIa complex initiates coagulation by activating small amounts of both factor IX and factor X in the environment of the tissue factor bearing cell. Factor Xa and factor IXa formed in the initial reaction then play very distinct roles in the subsequent interactions of the clotting mechanism leading to a burst of thrombin generation on the platelet surface. Our results also indicate that factor XI can be activated by thrombin in the absence of factor XII and that the function of factor XI is simply to enhance conversion of factor IX to factor IXa resulting in enhanced thrombin generation on the platelet surface.     

Activation of human factor VII by activated factors IX and X

Factor VII clotting activity increases about five-fold when blood is clotted in glass. Prior studies suggested that this results from activation induced by activated factor IX (IXa). However, in purified systems containing phospholipid and calcium, activated factor X (Xa) is known to activate factor VII rapidly. Therefore, we studied activation of factor VII by IXa and X, in systems using purified human factors. Concentrations of IXa and Xa were calculated from total activated protein concentrations rather than from active site concentrations. In the presence of phospolipid and calcium, both IXa and Xa activated factor VII 25-fold; however, Xa was roughly 800 times more efficient than IXa. Without added phospholipid, activation of factor VII by both Xa and IXa was markedly slowed, and Xa was roughly 20 times more efficient than IXa. When both phospholipid and calcium were omitted, activation of factor VII by either enzyme was negligible. Adding normal prothrombin, but not decarboxylated prothrombin, substantially slowed activation of factor VII by both Xa and IXa. Adding thrombin-activated factor VIII and antithrombin-III did not change rates of factor VII activation by either enzyme. These results from purified systems do not provide an explanation for the prior data from plasma systems.     

Factor IX Bm Kiryu: a Val-313-to-Asp substitution in the catalytic domain results in loss of function due to a conformational change of the surface loop: evidence obtained by chimaeric modelling

Summary. Factor IX Kiryu is a naturally occurring mutant of factor IX that has 2.5% coagulant activity, even though normal plasma levels of factor IX antigen are detected. Factor IX Kiryu was purified from a patient's plasma by immunoaffinity chromatography with a calcium-dependent anti-factor IX monoclonal antibody column. It was cleaved normally by factor XIa in the presence of Ca²⁺, yielding a two-chain factor IXa. However, the resulting factor IXa showed only 1.5% of the normal factor IXa in terms of factor X activation in the presence of factor VIII, phospholipids, and Ca²⁺, and had 20% of the normal esterase activity for Z-Arg- p -nitrobenzyl ester. Therefore factor IXa Kiryu showed the defect of the catalytic triad or primary substrate binding site as well as defective interaction with factors VIII/X. Single-strand conformational polymorphism analysis and DNA sequencing of the amplified DNA revealed a missense point mutation, a T-to-A substitution at nucleotide number 31 059 of the factor IX Kiryu gene. This mutation resulted in the amino acid substitution of Val-313 by Asp in the catalytic domain. Restriction enzyme analysis of the amplified DNA showed that the mutation was inherited from the patient's mother. The chimaeric method was employed to construct a model of the serine protease domain of factor IXa, and the resultant model suggested that the Val-313 to Asp substitution altered the conformation of the substrate-binding site. These data combined with our previous findings on a Gly-311-to-Glu mutant of factor IX suggest that the loop conformation from Gly-311 to Arg-318 is important for the expression of coagulant activity.     

Effect of DDAVP on plasma level of factor XII

The effect of DDAVP on blood coagulation factors was investigated after its intravenous infusion into normal subjects. A marked increase in factor XII was observed in addition to the expected rise of factor VIII coagulant activity (VIII:C), factor VIII related antigen (VIIIR:Ag) and plasminogen activator, DDAVP also produced a concomitant but less pronounced rise of factor VII, but there was no change in factors V, IX, X and XI.     

Proteolytic processing of human coagulation factor IX by plasmin

Previous studies have shown that thrombin generation in vivo caused a 92% decrease in factor IX (F.IX) activity and the appearance of a cleavage product after immunoblotting that comigrated with activated F.IX (F.IXa). Under these conditions, the fibrinolytic system was clearly activated, suggesting plasmin may have altered F.IX. Thus, the effect(s) of plasmin on human F.IX was determined in vitro. Plasmin (50 nM) decreased the 1-stage clotting activity of F.IX (4 microM) by 80% and the activity of F.IXa (4 microM) by 50% after 30 minutes at 37 degrees C. Plasmin hydrolysis of F.IX yields products of 45, 30, 20, and 14 kd on reducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and 2 products of 52 and 14 kd under nonreducing conditions. Plasmin-treated F.IX did not bind the active site probe, p-aminobenzamidine, or form an SDS-stable complex with antithrombin. It only marginally activated human factor X in the presence of phospholipid and activated factor VIII. Although dansyl-Glu-Gly-Arg-chloromethyl ketone inactivated-F. IXa inhibited the clotting activity of F.IXa, plasmin-treated F.IX did not. Plasmin cleaves F.IX after Lys43, Arg145, Arg180, Lys316, and Arg318, but F.IXa is not appreciably generated despite cleavage at the 2 normal activation sites (Arg145 and Arg180). Tissue plasminogen activator-catalyzed lysis of fibrin formed in human plasma results in generation of the 45- and 30-kd fragments of F.IX and decreased F.IX clotting activity. Collectively, the results suggest that plasmin is able to down-regulate coagulation by inactivating F.IX.     

Atherosclerosis and coronary bypass surgery in hereditary factor VII deficiency

A 66-year-old man with homozygous deficiency of factor VII (less activity than 4 percent of normal) had a minimal hemorrhagic tendency and severe coronary atherosclerosis, and underwent aortocoronary saphenous vein bypass surgery. Although plasma factor VII coagulant activity and cross-reacting material were markedly reduced, comparable amounts of factor VII antigen were detected in peripheral blood mononuclear cells of both the patient and of a normal subject by Western blotting techniques. Accelerated coagulation was observed following brief exposure of the patient's phytohemagglutinin-stimulated peripheral blood mononuclear cells to low concentrations of ambient factor VII in vitro. Evidence indicates that factor VII plays a role in vivo in both hemostasis and atherogenesis and it might be assumed that factor VII deficiency would both predispose to excessive bleeding and forestall atherosclerosis. However, these observations suggest that factor VII-mediated thrombin generation may proceed by partitioning of small amounts of factor VII on tissue factor-expressing cells and that factor VII contained within monocytes may facilitate tissue factor-induced coagulation by these cells. These features may provide efficient coagulation activation despite a deficiency of the plasma coagulant protein. The current results may explain, at least in part, the minimal bleeding tendency, and also the occurrence of thrombosis and atherosclerosis in certain persons with factor VII deficiency.     

On the mechanism of inhibition of tissue factor pathway by the synthetic pentasaccharide during coagulation of human plasma.

The tissue factor (TF) pathway is preponderant in the initiation of blood coagulation in normal haemostasis and in thrombotic states. In the present study we investigated the mechanisms by which the synthetic pentasaccharide may influence the regulation of the TF pathway during clotting of human platelet poor plasma (PPP). Clotting of normal PPP or plasmas immuno-depleted of a single clotting factor (factor VII, factor XII, factor XI, factor IX, factor VIII, factor X, factor V, factor II) was initiated by triggering the TF pathway in the presence of fondaparinux (0.5 microg/ml). Activated factor VII (FVIIa) levels were measured in serum obtained at several time intervals after re-calcification of PPP. A clotting assay highly specific for FVIIa was used. The synthetic pentasaccharide inhibited the generation of FVIIa by 66%. The inhibitory effect of fondaparinux on FVIIa was completely abolished when antithrombin activity of plasma was inhibited by a specific antibody. Following the activation of TF pathway in plasmas depleted of factor X or factor IX, the inhibitory effect of fondaparinux on FVIIa generation was completely abolished, whereas it was not significantly modified when the other clotting factor-depleted plasmas were clotted. When fondaparinux was added in the serum, after the maximal generation of FVIIa, it inhibited by 20-30% the activity of the FVIIa-TF complex. These data suggest that fondaparinux enhances the antithrombin-dependent downregulation of the TF pathway by decreasing the generation of FVIIa via the inhibition of the generation and the activity of activated factor IX and activated factor X, and by inhibiting the activity of the FVIIa-TF complex.     

Activation of the coagulation cascade after infusion of a factor XI concentrate in congenitally deficient patients

Virally inactivated, high-purity factor XI concentrates are available for treatment of patients with factor XI deficiency. However, preliminary experience indicates that some preparations may be thrombogenic. We evaluated whether a highly purified concentrate produced signs of activation of the coagulation cascade in two patients with severe factor XI deficiency infused before and after surgery. Signs of heightened enzymatic activity of the common pathway of coagulation (elevated plasma levels of prothrombin fragment 1 + 2 and fibrinopeptide A) developed in the early post-infusion period, accompanied by more delayed signs of fibrin formation with secondary hyperfibrinolysis (elevated D-dimer and plasmin-antiplasmin complex). These changes occurred in both patients, but were more severe in the older patient with breast cancer when she underwent surgery, being accompanied by fibrinogen and platelet consumption. There were no concomitant signs of heightened activity of the factor VII-tissue factor mechanism on the factor Xase complex (plasma levels of activated factor VII and of factor IX and X activation peptides did not increase). The observed changes in biochemical markers of coagulation activation indicate that concentrate infusions increased thrombin generation and activity and that such changes were magnified by malignancy and surgery. Because some factor XI concentrates may be thrombogenic, they should be used with caution, especially in patients with other risk factors for thrombosis.     

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.     

Activation of factor VIII by factor IXa

Thrombin causes an increase in factor VIII coagulant (VIII:C) activity, which is followed by a decay of VIII:C activity to below baseline levels. It has been suggested that a similar interaction of trace amounts of thrombin and factor VIII is a necessary prerequisite before factor VIII can participate in the coagulation cascade. In the current study, factor IXa, a serine protease with structural similarities to thrombin, is shown to cause an increase and subsequent fall in VIII:C in a manner qualitatively similar to the reaction with thrombin. The reaction is inhibited by a human inhibitor to factor IX and the interaction appears to involve only VIII:C, since factor-VIII-related protein (VIII:RP) is not changed on polyacrylamide gel electrophoresis (PAGE) or radioimmunoassay during the reaction. Phospholipid increases the activation of factor VIII by factor IXa, and high concentrations of diisopropylfluorophosphate and hirudin inhibit the reaction. The physiologic significance of the interaction of factor IXa with factor VIII is not entirely clear since the concentration of factor IXa needed for activation is much greater than the concentration of thrombin required for similar activation of factor VIII. Factor IXa is most likely to play a role in the intrinsic cascade acting as an initial activator of factor VIII, since factor IXa precedes thrombin in this clotting sequence. In addition, factor IXa may be important wherever relatively high local concentrations of factor IXa and factor VIII occur, particularly in the presence of phospholipid, which may serve to localize the coagulation factors.     

Platelet procoagulant complex assembly in a tissue factor-initiated system

Summary. The aim of this study was to examine the assembly of the factor IXa/VIIIa (Xase) and factor Xa/Va (IIase) complexes on the platelet surface in a system designed to mimic tissue factor-initiated coagulation. The experimental system contained tissue factor-bearing monocytes, unactivated platelets, and plasma concentrations of factors V, VIII, IX, X, prothrombin, tissue factor pathway inhibitor (TFPI), antithrombin III (ATIII), and small amounts of factor VIIa. The time courses of platelet activation, coagulation factor binding and thrombin generation were compared. In this system, thrombin generation by the combination of monocytes and platelets was synergistic compared to each cell type alone. Platelet activation and thrombin generation were minimal in the absence of prothrombin or factor X. After a lag period, platelet activation began, followed by progressive binding of factors Va and VIIIa. This was followed by factor IXa and Xa binding and the onset of thrombin generation. Unexpectedly, a transient early increase in platelet-associated factor IX and X was also seen, that was due to release from platelets. The amount of factor IX bound to isolated activated platelets was increased by addition of factor VIIIa, or by activation of factor IX to IXa. In contrast, factor VIIIa binding was not altered by the presence of factor IX or IXa. We conclude that in a tissue factor-initiated system, assembly of the procoagulant complexes on the platelet surface begins after platelet activation occurs. Platelet activation requires thrombin generation in the vicinity of the tissue factor bearing cells. The cofactors Va and VIIIa bind to the platelets and facilitate subsequent binding of factors IXa and Xa to form functional procoagulant complexes.     

Postprandial triglycerides and blood coagulation.

Most of our lifetime we spend in the postprandial state. Postprandial triglyceridemia may represent a procoagulant state involving disturbances of both blood coagulation and fibrinolysis, in particular due to elevation of the plasma levels of activated factor VII (VIIa) and plasminogen activator inhibitor (PAI-1). Therefore, disturbances of the hemostatic system might, at least partly, account for by the link between hypertriglyceridemia and coronary heart disease (CHD). Factor VIIa is the first enzyme of the blood coagulation system and serves a priming function for triggering of the clotting cascade. The coagulant activity of factor VII (VIIc, total activity of factor VII in plasma) was identified as an independent predictor of myocardial infarction in initially healthy middle-aged men, and particularly of fatal coronary events, and both serum cholesterol and triglyceride concentrations correlated positively with the VIIc level. Addition of fat to diet has been consistently shown to cause a rapid conversion of the factor VII zymogen into its active form (VIIa) whereas the concentration of total protein is unaffected. Postprandial activation of factor VII is dependent on lipolytic activity and it is mainly supported by large triglyceride-rich lipoprotein of the VLDL class. Studies in vivo with specific coagulation factor-deficient patients indicate that factor IX is essential for the postprandial activation of factor VII. The basal generation of thrombin seems to be unaffected by increased plasma levels of VIIa. However, since VIIa-tissue factor complex is responsible for the initiation of the coagulation cascade, increased generation of VIIa in the postprandial state would increase the potential for thrombin production in the event of plaque rupture. Plasminogen activator inhibitor-1 (PAI-1) is the major physiological inhibitor of the plasminogen activators in the circulation and thereby the principal inhibitor of the fibrinolytic system. Postprandial triglyceridemia has been observed in many, not all, studies to increase PAI-1 plasma levels, which would further strengthen the chances of thrombotic occlusion of a vessel after rupture of an atherosclerotic plaque.     

Characterization of the inhibition of tissue factor in serum

Tissue factor (TF) is a lipoprotein cofactor that markedly enhances the proteolytic activation of factors IX and X by factor VIIa. The functional activity of TF is inhibited by serum in a time- and temperature-dependent fashion. The inhibitory effect is also dependent on the presence of calcium ions and can be reversed by calcium chelation (EDTA) and dilution, thus excluding direct proteolytic destruction of TF as the mechanism for inhibition. Using crude TF, serum immunodepleted of factor VII, and serum depleted of the vitamin K- dependent coagulation factors by BaSO4 absorption, it is shown that TF factor inhibition requires the presence of VII(a), X(a), and an additional moiety contained in barium-absorbed serum. When each of the other required components were at saturating concentrations, half- maximal inhibition of TF occurred in reaction mixtures containing 2% (vol/vol) of TF at a factor VII(a) concentration of 4 ng/mL (80 pmol/L), a factor X concentration of 50 ng/mL (850 pmol/L), and a concentration of barium-absorbed serum of 2.5% (vol/vol). Catalytically active factor Xa appeared to be required for the generation of optimal TF inhibition. The results are consistent with the conclusions of Hjort that barium-absorbed serum contains a moiety that inhibits the VIIa- Ca2+-TF complex. The role of factor X(a) in the generation of the inhibitory phenomenon remains to be elucidated. The inhibitor present in serum (plasma) may in part be produced by the liver in vivo since cultured human hepatoma cells (HepG2) secrete this inhibitory activity in vitro.