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 IX by factor XIa

Blood coagulation factor IX is activated during hemostasis by two distinct mechanisms. Activation through factor VIIa/tissue factor occurs early in the course of fibrin clot formation. Activation by factor XIa appears to be important for maintaining the integrity of the clot over time. In general, coagulation proteases are activated on a phospholipid surface in the presence of a protein cofactor. Until recently, activation of factor IX by factor XIa was thought to be the exception to this rule, as phospholipid has no effect on the reaction and no cofactor had been identified. These curious observations suggest that factor IX is activated by factor XIa in the fluid phase. A large amount of new evidence now indicates that factor IX activation by factor XIa occurs on the surface of activated platelets. The data suggest, however, that this reaction differs significantly from other protease-substrate interactions on the platelet surface. This is likely to be due, in part, to the unusual structure of the factor XI molecule.     

Heparanase enhances the generation of activated factor X in the presence of tissue factor and activated factor VII

Background

Heparanase is an endo-β-D-glucuronidase dominantly involved in tumor metastasis and angiogenesis. Recently, we demonstrated that heparanase is involved in the regulation of the hemostatic system. Our hypothesis was that heparanase is directly involved in activation of the coagulation cascade.

Design and Methods

Activated factor X and thrombin were studied using chromogenic assays, immunoblotting and thromboelastography. Heparanase levels were measured by enzyme-linked immunosorbent assay. A potential direct interaction between tissue factor and heparanase was studied by co-immunoprecipitation and far-western assays.

Results

Interestingly, addition of heparanase to tissue factor and activated factor VII resulted in a 3- to 4-fold increase in activation of the coagulation cascade as shown by increased activated factor X and thrombin production. Culture medium of human embryonic kidney 293 cells over-expressing heparanase and its derivatives increased activated factor X levels in a non-enzymatic manner. When heparanase was added to pooled normal plasma, a 7- to 8-fold increase in activated factor X level was observed. Subsequently, we searched for clinical data supporting this newly identified role of heparanase. Plasma samples from 35 patients with acute leukemia at presentation and 20 healthy donors were studied for heparanase and activated factor X levels. A strong positive correlation was found between plasma heparanase and activated factor X levels (r=0.735, P=0.001). Unfractionated heparin and an inhibitor of activated factor X abolished the effect of heparanase, while tissue factor pathway inhibitor and tissue factor pathway inhibitor-2 only attenuated the procoagulant effect. Using co-immunoprecipitation and far-western analyses it was shown that heparanase interacts directly with tissue factor.

Conclusions

Overall, our results support the notion that heparanase is a potential modulator of blood hemostasis, and suggest a novel mechanism by which heparanase increases the generation of activated factor X in the presence of tissue factor and activated factor VII.     

Plasma tissue factor plus activated peripheral mononuclear cells activate factors VII and X in cardiac surgical wounds

OBJECTIVES: The purpose of this study was to test the hypothesis that activated monocytes with soluble plasma tissue factor (pTF) activate factors VII and X to generate thrombin. BACKGROUND: Despite heparin, thrombin is progressively generated during cardiac surgery with cardiopulmonary bypass (CPB), produces intravascular fibrin and fibrinolysis, and causes serious thromboembolic and nonsurgical bleeding complications. Thrombin is primarily produced in the surgical wound, but mechanisms are unclear. METHODS: In 13 patients, interactions of mononuclear cells, platelets, pTF, and pTF fractions to activate factors VII and X were evaluated in pre-bypass, perfusate, and pericardial wound blood before and during CPB. RESULTS: Monocytes are activated in wound, but not in pre-bypass or perfusate plasma (monocyte chemotactic protein-1 = 29.5 +/- 2.1 pmoles/l vs. 2.8 +/- 1.2 pmoles/l and 3.3 +/-1.4 pmoles/l, respectively). Wound pTF is substantially elevated compared to other locations (3.64 +/- 0.45 pmoles/l vs. 0.71 +/- 0.65 pmoles/l and 1.31 +/- 1.4 pmoles/l). Supernatant wound pTF contains 81.7% of TF antigen; wound microparticle pTF contains 18.3%. Wound monocytes and all C5a-stimulated monocytes (but not activated platelets) completely convert factor VII to factor VIIa with wound pTF. Activated monocytes more efficiently activate factor X with wound supernatant TF/factor VII(VIIa) complex than with wound microparticle TF/factor VII(fVIIa). The correlation coefficient (r) between wound thrombin generation (F1.2) and wound pTF concentration is 0.944 (p = 0.0004). CONCLUSIONS: During cardiac surgery with CPB, wound monocytes plus wound pTF or wound microparticle-free supernatant pTF preferentially accelerate activation of factor VII and factor X. This system represents a novel mechanism for thrombin generation via the TF coagulation pathway.     

Activation of factor IX by the reaction product of tissue factor and factor VII: additional pathway for initiating blood coagulation.

A study was carried out on mechanisms, independent of activated Factor XI, capable of activating Factor IX. The reaction product of tissue factor and Factor VII functioned as a potent Factor IX activator in the assay system used. Activated Factor IX itself activated Factor X; thrombin failed to activate Factor IX. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis confirmed that the reaction product of tissue factor and Factor VII activated Factor IX, with replacement of the band corresponding to native factor IX [molecular weight (Mr) 55,000] by bands corresponding to the heavy chain (Mr 27,000) and light chain (Mr 17,000) of activated Factor IX. When either Factor VII or calcium ions were left out of incubation mixtures, the band of native Factor IX persisted unchanged. Contact of blood with tissue factor represents a second mechanism, bypassing activated Factor XI, for the activation of Factor IX during hemostasis. It may help to explain the discrepancy between the mild bleeding of hereditary Factor XI deficiency and the severe bleeding of hereditary Factor IX deficiency.     

Activation of bovine factor VII by hageman factor fragments

During the early events of coagulation of human blood by the intrinsic pathway, factor XII is activated to a form which can activate factor XI, and is proteolytically fragmented to smaller species (30,000 daltons and 70,000 daltons) which have lost most of the ability to activate factor XI but which can activate prekallikrein rapidly. The effect of these fragments on factor VII was studied. It was found that these Hageman factor fragments promoted rapid proteolysis of one-chain factor VII to a more active two-chain form. The amino-terminal sequences of the chains of activated factor VII were found to be Ala- Asx-Gly- and Ile-Val-Gly-, the same as were earlier observed after activation of factor VII by activated factor X. This finding indicates that initiation of coagulation by the intrinsic pathway also primes the extrinsic pathway.     

Activation of human factor VII during clotting in vitro

We have studied factor VII activation by measuring the ratio of factor VII clotting to coupled amidolytic activity (VIIc/VIIam) and cleavage of 125I-factor VII. In purified systems, a low concentration of Xa or a higher concentration of IXa rapidly activated 125I-factor VII, yielding a VIIc/VIIam ratio of 25 and similar gel profiles of heavy and light chain peaks of VIIa. On further incubation, VIIa activity diminished and a third 125I-peak appeared. When normal blood containing added 125I- factor VII was clotted in a glass tube, the VIIc/VIIam ratio rose fivefold, and 20% of the 125I-factor VII was cleaved. Clotting normal plasma in an activated partial thromboplastin time (APTT) system yielded a VIIc/VIIam ratio of 25 and over 90% cleavage of 125I-factor VII. Clotting factor XII-deficient plasma preincubated with antibodies to factor X in an APTT system with added XIa yielded a VIIc/VIIam ratio of 19 and about 60% cleavage, which indicates that IXa, at a concentration achievable in plasma, can effectively activate factor VII. Clotting normal plasma with undiluted tissue factor yielded a VIIc/VIIam ratio of 15 to 20 and 60% cleavage of 125I-factor VII, whereas clotting plasma with diluted tissue factor activated factor VII only minimally. We conclude that both Xa and IXa can function as significant activators of factor VII in in vitro clotting mixtures but believe that only small amounts of factor VII may be activated in vivo during hemostasis.     

Congenital deficiency of blood clotting factors II, VII, IX, and X.

A patient congenitally deficient in factors II, VII, IX, and X has been further investigated after a follow-up of 15 yr. At birth, these factors, when determined by clotting assays, were undetectable. Following therapy with vitamin K1, the clotting activity of these factors rose but never exceeded 18% of normal. Immunologic assays revealed much higher levels of these factors than did clotting assays, thus suggesting that the vitamin-K-dependent factors were present in abnormal forms. Two-dimensional crossed immunoelectrophoresis showed that at least two forms of prothrombin were present in the patient's plasma. One form was similar to normal prothrombin; the other had the same mobility as acarboxyprothrombin. In addition, the majority of this fast-migrating peak was not adsorbable onto insoluble barium salts. These observations suggested that some molecules of the patient's prothrombin lacked the normal complement of gamma-carboxyglutamic acid residues. This observation was confirmed by a specific assay for gamma-carboxyglutamate. Since malabsorption of vitamin K, warfarin intoxication, and hepatic dysfunction were excluded as causes of this patient's syndrome, this rare congenital abnormality could represent either a defective gamma-carboxylation mechanism within the hepatocyte or faulty vitamin K transport.     

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.     

Standardization of factor VII/activated factor VII measurement in plasma of patients treated with recombinant factor activated VII.

To improve the standardization of the factor VII clotting activity (FVII:C) assay in patients treated with recombinant activated factor VII (rFVIIa), we conducted a multicentre study on plasma samples from four patients with haemophilia A, before and at various times after injection of a single dose of rFVIIa. FVII:C and prothrombin time were measured with the methods and reagents routinely used in each laboratory. Strong inter-laboratory variability of FVII:C values was found. The main source of variability was the type of thromboplastin. FVII:C values measured using rabbit thromboplastin were very close to activated factor VII clotting activity values (FVIIa:C) measured with a commercial assay (Staclot VIIa-TF). FVII:C values obtained with human placental thromboplastin were about three times lower than those obtained with rabbit and recombinant thromboplastins, and with the FVIIa:C assay. There was a good relationship between FVIIa:C and activated factor VII antigen values measured using a commercial immunoassay (Imubind FVIIa ELISA). In conclusion, rFVIIa at pharmacological concentrations can be easily monitored on the basis of FVII:C, using rabbit and probably also recombinant thromboplastin; equivalent results are obtained with a specific activated factor VII bioassay.     

Activation and inactivation of human factor X by proteases derived from Ficus carica

We investigated the effect of proteases derived from Ficus carica (common fig) on human blood coagulation. The milky sap (latex) of several Ficus (F.) species contain ficin, which is a mixture of proteases. Ficin derived from Ficus carica shortened the activated partial thromboplastin time and the prothrombin time of normal plasmas and plasmas deficient in coagulation factors, except plasma deficient in factor X (FX) and generated activated FX (FXa) in defibrinated plasma. Chromatographic separation of ficin from Ficus carica yielded six proteolytic fractions with a different specificity towards FX. We isolated two factor X activators with molecular masses of 23.2 and 23.5 kDa, and studied their action on purified human FX. Factor X was converted to activated FXbeta by consecutive proteolytic cleavage in the heavy chain between Leu178 and Asp179, Arg187 and Gly188, and Arg194and Ile195 (FX numbering system) with concomitant release of a carboxy-terminal peptide. The cleavage pattern of FXa degradation products in the light chain was influenced by Ca2+ and Mn2+. These data suggest the haemostatic potency of Ficus proteases is based on activation of human coagulation factor X.     

Activation peptides prolong the murine plasma half-life of human factor VII

Coagulation factors VII (FVII), IX (FIX), X (FX), and protein C share the same domain organization but display very different plasma half-lives. It is plausible that the half-life is influenced by the activation peptide, differing in length and glycosylation and missing in FVII. To test this hypothesis, the influence of activation peptides on the plasma half-life of human FVII was studied by administering human FVII variants containing activation peptide motifs to mice. Insertion of the activation peptide from FX gave 4-fold longer terminal half-life (5.5 hours vs 1.4 hours for FVII), whereas the activation peptide from FIX and protein C resulted in half-lives of 4.3 and 1.7 hours, respectively. Using FX's activation peptide we identified the N-linked glycans as structural features important for the half-life. The peptide location within the FVII molecule appeared not to be critical because similar prolongation was obtained with the activation peptide inserted immediately before the normal site of activation and at the C-terminus. However, only the latter variant was activatable, yielding full amidolytic activity and reduced proteolytic activity with preserved long half-life. Our data support that activation peptides function as plasma retention signals and constitute a new manner to extend the half-life of FVII(a).     

Activation of coagulation factor VII by tissue-type plasminogen activator.

To investigate the effect of tissue-type plasminogen activator (t-PA) on blood coagulation, we examined the effects of the addition of t-PA to normal pool plasma (NPP) on clotting times such as diluted prothrombin time (PT) and kaolin clotting time (KCT). The diluted PT but not the KCT was significantly shortened by the addition of t-PA to NPP compared with the normal controls, suggesting a t-PA-induced activation of blood coagulation through factor VII (FVII) activation. The activated factor VII (FVIIa) concentration in the NPP was significantly increased by the addition of t-PA. Although the FVIIa formation was not observed following the incubation of purified FVII with only t-PA or plasminogen, an increase in the FVIIa level was observed after the incubation of purified FVII with t-PA together with plasminogen, or only plasmin. This plasmin-mediated FVIIa formation was also confirmed by Western blotting. These findings suggest that t-PA enhances the activation of the coagulation system through FVII activation.     

Comparison of coagulant activity of factor VII and activated factor VII activity assays when used for determination of recombinant activated factor VII levels in plasma.

Two assays [coagulant activity of factor VII (FVII:C) and activated factor VII (FVIIa) activity] are currently available for the assessment of factor VII and FVIIa pharmacokinetics. This article presents the results of a comparison of the two assays when applied both in vitro as well as during clinical pharmacokinetic trials of recombinant FVIIa (rFVIIa) administered to healthy individuals and haemophilia patients. The in-vitro data showed that, for the FVII:C assay, plasma samples do not dilute in parallel. For the FVIIa activity assay, dilutions of samples are both parallel and linear with different dilutions of the calibrator. Moreover, intra-assay variation was found to be smaller for the FVIIa activity assay than for the FVII:C assay. When adding different amounts of rFVIIa (0-6 microg/ml) to normal plasma, a mean specific activity of rFVIIa of 48.6 U/mug was observed on applying the FVII:C assay; however, the specific activity decreased with increasing levels of rFVIIa. For the FVIIa activity assay, the mean specific activity was 45.4 IU/mug. Direct comparison of the two activity assays showed that no simple conversion between FVII:C and FVIIa activity measurements are possible. When applying the two assays for pharmacokinetic assessments in two clinical trials, statistically significant different estimates for the area under the curve, half-life, clearance and volume of distribution were obtained. In conclusion, for evaluation of rFVIIa pharmacokinetic properties, activity should be measured with the FVIIa activity assay - which is a more specific and reliable assay of the two available factor VII activity assays, especially when assessing low activity levels.     

Activation of factor IX by erythrocyte membranes causes intrinsic coagulation.

As an extension of our earlier work, procoagulant activity of erythrocyte [red blood cell (RBC)] membrane was examined using biochemical and rheological techniques. Western blot analysis of coagulation factors incubated with erythrocytes (RBCs) showed that only factor IX (FIX) was activated by RBC membranes in the presence of calcium ions. A fluorogenic assay suggested that activated FIX is capable of activating factor X. A preliminary crude extraction of the substance from RBC membranes suggested that a FIX-activating enzyme may be located on the RBC membrane. The initiation of FIX activation by RBCs was enhanced by an elevation in hematocrit. Moreover, the rate of FIX activation by RBCs from normal pregnant women and diabetic patients was much faster than that from normal subjects. In addition, glucose treatment of normal RBCs resulted in the increase in procoagulant activity. It is suggested that FIX activation by RBC membranes may serve as a triggering mechanism for blood coagulation, although further study will be required to clarify the putative FIX activating enzyme on the RBC membrane and to permit more extensive physiological experiments to be performed.