Role of the coagulation system in tumor-cell-induced platelet aggregation and metastasis

The ability of tumor cells to initiate coagulation and subsequent platelet aggregation is believed to facilitate the metastatic process. The mechanism by which tumor cells initiate thrombotic alterations is unclear. We have purified a plasma membrane protein platelet aggregating activity/procoagulant activity (PAA/PCA) from several rodent tumors which initiates the coagulation of homologous plasma and aggregation of homologous platelets by a mechanism independent of factor VII. This protein does not possess any proteinase activity; however, its activity is dependent upon the presence of factor X. In addition, PAA/PCA requires reconstitution with phospholipid for expression of activity. These results suggest that tumor cells express a unique protein which possesses procoagulant activity resulting in thrombin generation. Thrombin is responsible for subsequent tumor-cell-induced platelet aggregation.     

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.     

Adhesive receptor Mac-1 coordinates the activation of factor X on stimulated cells of monocytic and myeloid differentiation: an alternative initiation of the coagulation protease cascade.

Monocytes initiate coagulation through regulated surface expression of tissue factor and local assembly of a proteolytic enzymatic complex formed by tissue factor and factor VII/activated factor VII. We now show that, in the absence of these initiating molecules, monocytes and cell lines of monocytic/myeloid differentiation can alternatively initiate coagulation after exposure to ADP. The molecular basis for this procoagulant response consists of two distinct events. First, cell stimulation with ADP induces high-affinity binding of coagulation factor X to the surface-adhesive receptor Mac-1. Locally, Mac-1-concentrated factor X is then rapidly proteolytically cleaved to an active protease with size and activity characteristics of activated factor X, which supports the cell-associated formation of thrombin and the procoagulant response. We conclude that the monocytic/myeloid adhesive receptor Mac-1 has the unexpected, specifically inducible property to organize a molecular assembly culminating in rapid fibrin formation that is independently regulated from tissue factor and factor VII/activated factor VII.     

Characterization of the effects of cultured vascular cells on the activation of blood coagulation

The coagulant properties of intact bovine vascular cells (aortic endothelial and smooth muscle cells) and human vascular cells (cutaneous and foreskin microvascular cells, umbilical venous endothelium) grown in vitro were studied. Compared to nonvascular cells (fibroblasts, corneal endothelial cells, fetal lung or intestinal mucosal cells), vascular cells had little procoagulant activity. Radioimmunologic measurement of thrombin in recalcified plasma demonstrated markedly lower concentrations of thrombin in the presence of vascular endothelial and smooth muscle cells compared to corneal endothelial and fetal lung cells. The low thrombin concentrations were not a consequence of thrombin binding to the vascular cells nor were they due to accelerated thrombin inactivation by antithrombin-III or alpha 2-macroglobulin. Neither vascular cells nor the nonvascular cells promoted contact activation of plasma as measured by a sensitive specific assay for kallikrein. Studies with intact cell monolayers and purified factors VIIa and X indicated that while nonvascular cells express tissue factor activity, vascular cells do not exhibit this property. These data suggest that the nonthrombogenic nature of intact vascular cells is due to their failure to initiate contact activation and to express tissue factor activity. In addition, the primary difference in coagulant potential between vascular cells and nonvascular cells is the lack of tissue factor expression by the vascular cells.     

Incomplete gamma carboxylation of human coagulation factor VII: differential effects on tissue factor binding and enzymatic activity

The integrity of the γ-carboxylic glutamic acid (GLA) residues of coagulation factor VII are thought to be essential for both the interaction of factor VII with its cell-surface lipoprotein receptor tissue factor and for the activated protein to manifest its serine protease activity. During the course of transiently expressing recombinant human factor VII in monkey COS cells it was noted that the factor VII synthesized in the absence of added vitamin K had < 20% of expected procoagulant activity yet retained 65% of its binding activity to recombinant human tissue factor. Similar results were obtained when vitamin K was omitted from human 293 cell cultures permanently expressing recombinant factor VII. In contrast, both transient and permanent expression of factor VII in human 293 cell cultures containing physiological concentrations of vitamin K resulted in the synthesis of fully functional factor VII. Furthermore, factor VII in plasma samples from 24 patients undergoing warfarin therapy bound quantitatively to tissue factor whereas factor VII procoagulant activity averaged 65% of normal. Thus, data from both in vitro and in vivo situations indicated that factor VII molecules with suboptimal GLA content retained most of their ability to bind tissue factor but exhibited reduced procoagulant activity.     

Bronchoalveolar lavage procoagulant activity in bleomycin-induced lung injury in marmosets. Characterization and relationship to fibrin deposition and fibrosis

Although pulmonary fibrin deposition and coagulation abnormalities have been observed in acute lung injury in humans, their role in the pathogenesis of pulmonary disorders is unclear. In order to gain further insights into the role of the coagulation in lung injury, we examined the relationship between procoagulant activity in bronchoalveolar lavage (BAL) fluids and the evolution of bleomycin-induced lung injury in marmosets. The BAL procoagulant activity was increased at 1, 2, and 4 wk after bleomycin challenge compared with that in control subjects, and it was capable of shortening the recalcification times of plasmas deficient in factor VII and factor VIII but not in factor X. This profile suggested the presence in BAL of an activator of factor X. Activation of purified human factor X by BAL was demonstrated by measuring the amidolytic activity of the generated factor Xa on its N-benzoyl-L-isoleucyl L-glutamyl-glycyl-L-argenine-p-nitroanilide substrate. Factor X activating activity was increased in BAL at 2 wk after bleomycin challenge. Cleavage of 125I-labeled human factor X by BAL from bleomycin-challenged marmosets yielded a 55,500 Mr product that comigrated with factor Xa, the appearance of which correlated strongly with amidolytic evidence of factor Xa activity. Electron microscopy of the lungs of animals from all groups revealed pulmonary fibrin deposition at 2 wk after bleomycin challenge, at the time of increased BAL procoagulant and factor X activating activity. The BAL procoagulant activity was completely sedimentable by ultracentrifugation and was inhibited by concanavalin A and phospholipase C. Activation of purified factor X by BAL was inhibited by monospecific polyclonal goat and rabbit antibodies to human factor VII as well as antibody to bovine tissue factor, demonstrating that factor X activating activity in BAL was attributable to tissue factor associated with material similar to factors VII or VIIa. We conclude that procoagulant activity in BAL increases after bleomycin challenge in marmosets and is attributable to activation of factor X by tissue factor associated with factors VII or VIIa-like material. Increased BAL procoagulant activity is temporally associated with pulmonary fibrin deposition and pulmonary fibrosis during bleomycin-induced pulmonary injury in the marmoset.     

Procoagulant activity of the MC28 fibrosarcoma cell line in vitro and in vivo

Summary Experimental evidence suggests that many tumours can activate blood coagulation and that such interaction is part of the pathology of metastatic tumour growth. This study aimed to study the procoagulant activity of the methylcholanthrene-induced (MC28) fibrosarcoma to determine whether coagulation activation by these cells could explain the previously reported effects of oral anticoagulants on lung seeding in this model. MC28 cells shortened the recalcification times of normal and factor VII-deficient plasma and directly activated factor X in a chromogenic assay, but did not aggregate platelets iri vitro in either whole blood or platelet-rich plasma. Cellular coagulant activity was calcium-dependent, blocked by DFP and concanavalin A but not inhibited by iodoacetamide, E-64 or antibodies to human tissue factor or factor VII. Injection of viable MC28 cells into hooded Lister rats induced a decrease in platelet count ( P <0.001), plasma factor X ( P <0.001) and fibrinogen ( P <0.05) and a marked increase in plasma haemoglobin ( P < 0.001). These effects were either not observed or were considerably less marked in heparinized or warfarinized animals. Injection of MC28 cells treated with concanavalin A in vitro completely abolished the clotting changes observed with untreated cells. In conclusion, MC28 cells possessed a potent factor X-activating serine proteinase procoagulant in vitro , which had some of the characteristics of a tissue factor/ factor VIIa complex. In vivo , MC28 cells caused clotting activation and intravascular fibrin generation. Since thrombocytopenia was abolished by heparin and the cells lacked platelet aggregating activity in vitro , thrombocytopenia was probably secondary to intravascular coagulation and thrombin generation. The trigger for intravascular clotting activation appeared to be the cellular procoagulant activity since it was abolished by prior in vitro blockade of the latter with concanavalin A.     

Synthesis of coagulation factor V by cultured aortic endothelium

Bovine aortic endothelium has been examined with respect to the synthesis of coagulation factor V. After cultured cells reached confluency, samples of supernatant culture media and solubilized cells were analyzed for factor V in a two-stage bioassay and in a double- antibody radioimmunoassay. In addition, preconfluent cells were pulsed for 4 days with 35S-methionine in methionine-free media. After the 4- day pulse, supernatant media were chromatographed on a factor V monoclonal antibody-Sepharose resin to isolate 35S-labeled factor V. The isolated material and 125I-factor V standards were analyzed by electrophoresis and autoradiography. The bioassay indicated an increase, with time, of unactivated factor V in the culture supernatant, whereas solubilized cells were negative for factor V. The radioimmunoassay indicated an increase, with time, of factor V antigen in the culture supernatants, and the solubilized cells yielded a constant level of antigen per cell. Autoradiograms of electrophoretograms of immunoadsorbed 35S-culture supernatant with 125I- factor V/Va standards revealed labeled proteins with electrophoretic mobilities compatible with 125I-factor V/Va standards. The data obtained from three different sources-bioassay, radioimmunoassay, and 35S-methionine incorporation-all indicate that factor V is synthesized by cultured bovine aortic endothelium.     

Regulation of the procoagulant activity within the bronchoalveolar compartment of normal human lung

The nature of the procoagulant activity of normal bronchoalveolar fluid was examined both qualitatively and quantitatively. Unconcentrated, cell-free lavage freshly obtained from normal volunteers clotted normal plasma in a mean of 84 +/- 20 s. The procoagulant activity was initiated by Factor VII-tissue factor complexes as judged by differential activity in various plasmas genetically deficient in single clotting factors, by neutralization of the procoagulant activity with antibodies to either Factor VII or tissue factor, and by a Factor X activation assay. Preincubation of the lavage with calcium was required to demonstrate Factor VII activity in unconcentrated samples. The cell-free fluid contained about 8,500 thromboplastin units/mg protein, equivalent to a third of the thromboplastin standard and indicating high amounts of cofactor. Quantitation of Factor VII was estimated by functional analysis in coagulation and amidolytic assays with reference to dilutions of normal plasma of known Factor VII concentration. When lavage and diluted plasma were adjusted to yield equivalent amidolytic activities, the average ratio of the Factor VII-clotting activity of the alveolar fluid relative to plasma Factor VII was 19 +/- 7, suggesting the presence of Factor VIIa in lavage. In contrast to previous reports with serum or activated plasma, immunoblots of concentrated lavage revealed only single-chain Factor VII, and 125I-Factor VII added to the fluid was not converted to 125I-Factor VIIa, suggesting a unique control mechanism in the lung compartment which differs from plasma. When equivalent Factor VII amidolytic activities in diluted plasma and cell-free lavage were compared, the rates of Factor Xa formation were very similar.(ABSTRACT TRUNCATED AT 250 WORDS)     

Enhancement by human umbilical vein endothelial cells of factor Xa- catalyzed activation of factor VII

In blood coagulation on endothelium, an unperturbed vascular endothelial cell surface apparently provides activity equivalent to the phospholipid needed for generation of factor Xa and thrombin in soluble systems. Phospholipid in soluble systems also markedly enhances the ability of factor Xa to activate factor VII; therefore we investigated the influence of an unperturbed monolayer of human umbilical vein endothelial cells (HUVEC) upon factor VII activation. HUVEC were found to augment factor Xa-catalyzed activation of factor VII. This appeared to result from the binding of trace amounts of factor Xa to the cells. Adding active site-inhibited factor Xa to reaction mixtures, but not factor X, abolished the enhanced activation. Adding either anti-factor V antibodies or exogenous factor Va had no effect upon reaction rates. Thus factor Va does not function as a cofactor for the reaction. In further experiments the effect upon activation of factor VII and prothrombin was studied by varying the order of addition of factor Xa and factor Va to supernatants of HUVEC monolayers. Evidence was obtained that HUVEC, unlike platelets, possess a functional factor Xa binding site that is independent of factor Va. Since phospholipid is the only known cofactor for factor Xa/Ca2+-induced activation of factor VII, the demonstration of enhanced activation of factor VII in the presence of unperturbed cultured HUVEC supports a hypothesis that the functional equivalent of procoagulant phospholipid is available on the luminal surface of vascular endothelium in vivo.     

The role of endothelial cells and subendothelial components in the initiation of blood coagulation

The effect of collagen on isolated platelets, platelet-rich plasma and whole blood has been studied. Collagen failed to generate factor XIa-like activity in mixtures of isolated platelets, collagen and Ca++. Moreover, collagen added to whole blood or platelet-rich plasma containing 125I-factor IX and Ca++, also failed to form cleaved (activated) factor IX. In preliminary studies, lysed endothelial cells were found to enhance the formation of factor Xa and thrombin and to induce cleavage of 125I-factor IX in normal plasma, factor XII and factor-XI-deficient plasma even in the presence of antibody to tissue factor.     

Estrogen regulation of a tissue factor-like procoagulant in the immature rat uterus

An estrogen-responsive procoagulant activity is present in the plasma membrane fraction of immature rat uterus. This procoagulant has many of the properties of tissue factor, a widely occurring, integral membrane protein which initiates the intrinsic pathway of coagulation. Procoagulant activity was demonstrated to activate prothrombin in rat uterus, to activate human coagulation factor X, and to cause clot formation by human plasma. Procoagulant activity could be solubilized from the plasma membrane by the detergent octyl glucoside and had an apparent mol wt of 20,000-40,000 by gel filtration. Procoagulant activity was increased 4-fold within 3 h after immature rats were injected with estradiol. The increase was tissue- and hormone specific and was not affected by a warfarin-induced vitamin K deficiency. Coagulation factor VII was required for clot formation by the procoagulant. These properties are consistent with identification of the procoagulant as tissue factor. mRNA for tissue factor was increased in the uterus 3 h after estrogen stimulation. In the preceding paper we showed that prothrombin is increased in the immature uterus within 3 h of estrogen stimulation. The presence of increased amounts of a tissue factor-like procoagulant in the same time period suggests a functional relationship between these two proteins and a possible role for both in uterine development. Thrombin is a growth factor in fibroblasts and endothelial cells. We propose that after estrogen stimulation, prothrombin enters the uterus with the influx of plasma proteins and is activated by the procoagulant to thrombin. We suggest that thrombin might act as a paracrine factor early in the estrogen-stimulated development of the uterus.     

Abnormalities in pathways of alveolar fibrin turnover among patients with interstitial lung disease

Fibrin deposition is prominent in the histopathologic features of chronic interstitial lung disease. Human alveolar macrophages can potentially modulate this process because normal macrophages synthesize and express the initial enzymes of both coagulation and fibrinolytic pathways. In the present study, we examined the cell-associated procoagulant activity of macrophages lavaged from patients with sarcoidosis (n = 14) or idiopathic pulmonary fibrosis (n = 13) and compared the enzyme activities with that of a group of normal volunteers (n = 16). Cells from sarcoid patients had a mean (+/- 1 SD) tissue factor activity of 1,491 +/- 2,160 units/5 X 10(5) cells, as compared with a mean of 480 units (range, 140 to 1,000 units) for normal control subjects. The same cells had a mean plasma Factor VII equivalent of 4.7 ng/10(6) cells, as compared with 0.81 ng/10(6) cells (range, 0.2 to 2.0 ng) for the normal control subjects. The enhanced activity correlated with disease activity as judged by radiographic stage: only patients with Stage II or Stage III disease had consistently elevated procoagulant activity. There was no correlation of procoagulant activity with the percentage of lymphocytes in the alveolar fluid. Cells from patients with idiopathic pulmonary fibrosis also had increased tissue factor (mean, 2,980 +/- 2,619 units) but less consistently elevated Factor VII. There was considerable variation in both procoagulant activity and cell differentials between lavage sites in 10 patients in whom 2 separate lobes were studied concurrently. In addition, we examined the plasminogen activator (PA) activities of lavaged cells and concentrated alveolar fluids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding and Release of Factor VIII/von Willebrand''s Factor by Human Endothelial Cells

The uptake and release of factor VIII/von Willebrand's protein by cultured human umbilical vein endothelial cells have been examined using highly purified 125I-factor VIII possessing von Willebrand's factor activity. 125I-factor VIII/vWF was taken up by the cells, reaching maximum binding within 4 h with a t1-2 of binding of 15 min. Endothelial cell binding of 125I-factor VIII/vWF reached saturation at a concentration of 1.5 mg/l. Binding was inhibited by coincubation of excess unlabelled factor VIII/vWF. Most of the cell-associated radioactivity was released by treatment of the cells with trypsin. Internalization of bound protein was evidenced by the incorporation into the cells of radioactivity which could not be released by trypsin. Human vascular smooth muscle cells did not bind 125I-factor VIII/vWF. Addition of 0.1 microM epinephrine to the 125I-factor VIII/vWF labelled endothelial cultures induced the release of cell bound, protein-associated radioactivity into the medium. Propranolol inhibited completely epinephrine-induced release, whereas phenylephrine had no effect. Endothelial cells maintained in medium partially depleted of factor VIII/vWF by tricalcium citrate cellulose treatment of plasma did not release factor VIII antigen into the culture medium during subsequent incubation. Although [3H]proline was incorporated into proteins released by endothelial cells under these experimental conditions, specific incorporation of label into factor VIII/vWF antigen was not detectable by a sensitive solid-phase immunoradiometric assay. We conclude that factor VIII/vWF binds to endothelial cells and that this cell-bound protein is mobilized by epinephrine through beta-adrenergic stimulation.     

Association of smooth muscle cell tissue factor with caveolae

There is still no satisfactory explanation for the low catalytic activity of tissue factor (TF)/factor VII(a) complexes towards coagulation factor X, as found on the apical surface side of cell layers. It has been hypothesized that TF exists in a latent form. Layers of cultured human smooth muscle cells, constitutively expressing TF, were immunogold-labeled for TF in situ and processed for electron microscopy. We showed that, besides internalization and accumulation in lysosomal-like structures, TF remained associated with noncoated, flask- shaped microinvaginations of the plasma membrane. These invaginations were identified as caveolae. In regions in which intercellular contacts were interrupted, more TF-positive caveolae were observed. Enzymatically detached smooth muscle cells exhibited a similar enlargement of caveolar structures. Concomitantly, an increase of catalytic activity of apically formed TF/VIIa complexes towards factor X was found on the suspended cells. We speculate that caveolae- associated TF may function as a latent pool of procoagulant activity, which can rapidly be activated at sites in which vessel wall integrity is lost.     

Characterization of the thrombin generation potential of leukemic and solid tumor cells by calibrated automated thrombography

Background

Thrombin, the final enzyme of blood coagulation, is a multifunctional serine protease also involved in the progression of cancer. Tumor cells may activate blood coagulation proteases through the expression of procoagulant activities. However, specific information about the thrombin generation potential of malignant tissues is lacking. In this study we applied a single global coagulation test, the calibrated automated thrombogram assay, to characterize the specific procoagulant phenotypes of different tumor cells.

Design and Methods

Malignant hematologic cells (i.e. NB4, HEL, and K562) or solid tumor cells (i.e. MCF-7 breast cancer and H69 small cell lung cells) were selected for the study. The calibrated automated thrombo-gram assay was performed in normal plasma and in plasma samples selectively deficient in factor VII, XII, IX or X, in the absence or presence of a specific anti-tissue factor antibody. Furthermore, cell tissue factor levels were characterized by measuring antigen, activity and mRNA expression.

Results

In normal plasma, NB4 induced the highest thrombin generation, followed by MCF-7, H69, HEL, and K562 cells. The anti-tissue factor antibody, as well as deficiencies of factors VII, IX and XII affected the thrombin generation potential of malignant cells to different degrees, allowing differentiation of the two different pathways of blood clotting activation – by tissue factor or contact activation. The thrombin generation capacity of NB4 and MCF-7 cells was tissue factor-dependent, as it was highly sensitive to inhibition by anti-tissue factor antibody and factor VII deficiency, while the thrombin generation capacity of H69, HEL and K562 was contact activation-dependent, as no thrombin was generated by these cells in factor XII-deficient plasma.

Conclusions

This study demonstrates that the calibrated automated thrombogram assay is capable of quantifying, characterizing, and comparing the thrombin generation capacity of different tumor cells. This provides a useful tool for understanding the key factors determining the global pro-coagulant profile of tumors, which is important for addressing specific targeted therapy for the prevention of thrombosis and for cancer.     

Cysteine proteinase procoagulant from amnion-chorion

Various coagulation abnormalities are associated with pregnancy. Several investigators have suggested that there may be a unique procoagulant associated with amniotic tissue and fluid. We identified a cysteine proteinase from malignant tissue, cancer procoagulant, and had reason to believe a similar proteinase may be present in amniotic tissue. Amniotic fluid and extracts of amnion-chorion were purified by immunoaffinity chromatography with an antibody that was developed to cancer procoagulant antigen. The purified amnion-chorion procoagulant initiated clotting in normal and factor VII-deficient citrated human plasma and directly activated pure human factor X in a two-stage clotting assay. It was inhibited by 1 mmol/L of iodoacetamide and 0.1 mmol/L of HgCl2, and the procoagulant activity was activated by 10 mmol/L of KCN; these are classic properties of cysteine proteinases. The pure amnion-chorion procoagulant had the same mol wt and immunologic determinants as cancer procoagulant from rabbit V2 carcinoma, as determined by crossed immunodiffusion, suggesting that the same or very similar proteins were associated with both tissues. Thus, this procoagulant may be derived from both undifferentiated and dedifferentiated cells.     

Procoagulant (thromboplastin) activity in human bronchoalveolar lavage fluids is derived from alveolar macrophages

Fibrin deposition in the alveolar space and the lung interstitium is a prominent feature of many types of inflammatory pulmonary diseases. Cells of the monocyte/macrophage line are the primary cells supplying procoagulant activity in inflammatory lesions. In the present study we found that both lung alveolar macrophages (LAM) and bronchoalveolar lavage fluids (BALF) from humans contained procoagulant activities. The procoagulant in BALF was associated with membrane vesicles which sedimented at 100,000 g for 1 h. By electron microscopy the BALF ultrasediment was seen to consist almost exclusively of membrane material and this was confirmed by monitoring the content of different marker enzymes for specific subcellular structures. Using macrophage membrane markers, at least part of the BALF-ultrasediment was shown to be derived from LAM. On the basis of phospholipase C sensitivity, antibody neutralization and the site of action of the procoagulant in the sequential activation of coagulation factors, both the LAM-associated and the BALF-associated procoagulant activity was identified as thromboplastin (tissue factor) or thromboplastin-factor VII complexes. This suggests that alveolar macrophages and the LAM-derived thromboplastin-containing microvesicles may contribute to intraalveolar and interstitial fibrin deposition in vivo and probably also have consequences for the development of pulmonary fibrosis.     

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.     

Flow as a regulator of the activation of factor X by tissue factor

A novel enzyme reactor for phospholipid-dependent reactions was used to study the effects of flow on tissue factor-initiated coagulation. Microcapillaries were coated with a phospholipid bilayer containing tissue factor, a transmembrane protein that is an essential cofactor for a plasma procoagulant enzyme, factor VII. We show that, in contrast to static, closed systems, the steady-state catalytic activity is independent of enzyme concentration and the time to steady state becomes a function of the enzyme concentration.