Protein S is a cofactor for tissue factor pathway inhibitor

Protein S is a vitamin K-dependent protein that acts as a cofactor of the anticoagulant protein APC. However, protein S also exhibits anticoagulant activity in the absence of APC. Thrombin generation experiments in normal plasma and in plasma deficient in tissue factor pathway inhibitor (TFPI) and/or protein S demonstrated that protein S stimulates the inhibition of TF by TFPI. Kinetic analysis in model systems containing purified proteins showed that protein S enhances the formation of the binary FXa:TFPI complex by reducing the Ki of TFPI from approximately 4 nM to approximately 0.5 nM. Enhancement of inhibitory activity of TFPI by protein S is only observed with full-length TFPI and in the presence of a negatively charged phospholipid surface. The Ki decrease brings the TFPI concentration necessary for FXa:TFPI complex formation within range of the plasma TFPI concentration which increases FXa:TFPI complex formation and accelerates feedback inhibition of the TF pathway by enhancing the formation of the quaternary TFPI:FXa:TF:FVIIa complex. Thus, protein S is not only a cofactor of APC, but also of TFPI. A reduced TFPI cofactor activity may contribute to the increased risk of venous thrombosis in protein-S deficient individuals. Using calibrated automated thrombography we have developed two assays that enable quantification of the functional activity of the TFPI/protein S system in plasma. These assays show that the activity of the TFPI/protein S system is greatly impaired in oral contraceptive users.     

Monocyte tissue factor response is decreased in patients with hyperlipidemia

Monocytes are potent regulators of blood coagulation through the expression of tissue factor (TF) on stimulation and of tissue factor pathway inhibitor (TFPI), a selective inhibitor of TF pathway. As hyperlipidemia can modify some monocyte functions, we compared the TF and TFPI expression by circulating monocytes and the plasma TFPI levels between 65 healthy normolipemic controls and 38 nontreated hyperlipemic patients. TF and TFPI relationships with plasma lipoproteins are also examined. TF and TFPI expression were evaluated in peripheral mononuclear cells after isolation from blood by density gradient centrifugation and after short culture with or without lipopolysaccharide (LPS). TF and TFPI activity and antigen were measured in mononuclear cell lysates using amidolytic assay and enzyme-linked immunosorbent assay, respectively. TFPI activity and antigen were measured in plasma using the same methods. Plasma factor VII (FVII) activity and antigen were also determined. LPS-stimulated monocyte TF activity and antigen were lower in hyperlipidemic patients than in controls (0.0001相似文献   

Platelet tissue factor pathway inhibitor modulates intravascular coagulation

Tissue factor pathway inhibitor (TFPI) is produced by megakaryocytes and is found internally within quiescent platelets but is not in α-granules. It is released in soluble form and expressed on the surface of platelets that are dual activated with thrombin plus collagen. Platelet TFPI is exclusively TFPIα, the most evolutionarily conserved TFPI isoform. It appears to be physiologically active as an inhibitor of tissue factor (TF) initiated FXa generation in vitro, and acts locally to dampen clot growth in a murine vascular injury model. These data suggest that platelet TFPI plays an important role in modulating TF activity within a growing clot thereby preventing formation of an occlusive clot.     

Structure and biology of tissue factor pathway inhibitor.

Human tissue factor pathway inhibitor (TFPI) is a modular protein comprised of three Kunitz type domains flanked by peptide segments that are less structured. The sequential order of the elements are: an N-terminal acidic region followed by the first Kunitz domain (K1), a linker region, a second Kunitz domain (K2), a second linker region, the third Kunitz domain (K3), and the C-terminal basic region. The K1 domain inhibits factor VIIa complexed to tissue factor (TF) while the K2 domain inhibits factor Xa. No direct protease inhibiting functions have been demonstrated for the K3 domain. Importantly, the Xa-TFPI complex is a much more potent inhibitor of the VIIa-TF than TFPI by itself. Furthermore, the C-terminal basic region of TFPI is required for rapid physiologic inhibition of coagulation and is needed for the inhibition of smooth muscle cell proliferation. Although a number of additional targets for attachment have been reported, the C-terminal basic region appears to play an important role in binding of TFPI to cell surfaces. A primary site of TFPI synthesis is endothelium and the endothelium-bound TFPI contributes to the antithrombotic potential of the vascular endothelium. Further, increased levels of plasma TFPI under septic conditions may represent endothelial dysfunction. We have proposed that the extravascular cells that synthesize TF also synthesize TFPI providing dual components necessary for the regulation of clotting in their microenvironment. Like the TF synthesis in these cells is augmented by serum, so is the case with the TFPI gene expression. TFPI gene knock out mice reveal embryonic lethality suggesting a possible role of this protein in early development. Since TF-induced coagulation is thought to play a significant role in many disease states, including disseminated intravascular clotting, sepsis, acute lung injury and cancer, recombinant TFPI may be a beneficial therapeutic agent in these disease states to attenuate pathologic clotting. The purpose of this review is to outline recent developments in the field related to the structural specificity and biology of TFPI.     

Tissue factor pathway inhibitor reduces experimental lung metastasis of B16 melanoma

The importance of tissue factor (TF) in tumor biology has been highlighted by studies suggesting its involvement in cell signaling, metastasis and angiogenesis. Since many animal studies have shown that anticoagulant therapy can reduce experimental metastasis, we studied whether the natural inhibitor of TF-mediated blood coagulation, Tissue Factor Pathway Inhibitor (TFPI), might be similarly effective. Using a murine experimental model, we found that intravenous injection of recombinant murine TFPI immediately before introduction of tumor cells reduced metastasis by 83% (P < 0.001). B16 murine melanoma cells stably transfected with a TFPI expression vector exhibited reduced lung seeding following intravenous injection by 81% (P < 0.001) compared with controls. No difference in primary tumor growth was observed between TFPI+ and control cells. Mice receiving intravenous somatic gene transfer of sense TFPI expression vector developed 78% fewer lung nodules than controls (P < 0.05). We conclude that TFPI has significant anti-metastatic activity in this experimental model.     

Tissue factor pathway inhibitor on circulating microparticles in acute myocardial infarction

In acute myocardial infarction (AMI), increased Tissue Factor (TF) expression on circulating monocytes and microparticles (MP) may contribute to thrombotic events. Because surfacebound Tissue Factor Pathway Inhibitor-1 (TFPI) inhibits TF activity on monocytes and endothelial cells decreased TFPI expression may reinforce the procoagulant activity of circulating MP. Aim of the study was to analyze TFPI expression and TF activity after stenting and thrombolysis inAMI. Thirty-nine patients of a randomized study comparing intravenous thrombolysis (n=19) and stenting (n=20) were included. Before and after therapy blood samples for analysis of MPs, TF antigen and activity, prothrombin fragment F1+2 and D-dimer were obtained. TFPI expression on TF positive MPs was decreased after thrombolysis but not after stenting. In contrast, TF plasma levels and TF positive MP remained unchanged in both treatment groups. After thrombolysis increased D-dimer and F1+2 plasma concentrations indicated activation of fibrinolysis and coagulation. Significance of MPTFPI for inhibition of TF activity was measured using inhibitory TFPI antibodies. Membrane-associated TFPI inhibited TF activity on circulating MPs. After thrombolysis inhibition of TF activity by TFPI was decreased as compared to stenting. Correlation of circulating TF with F1+2 only after thrombolysis, suggests a role for TF-induced activation of coagulation after thrombolysis. Enhanced TF activity on circulating MPs in AMI is inhibited by endogenous surface-boundTFPI. After thrombolysis but not after stenting MPTFPI is degraded and may induce thrombin generation due to unopposed tissue factor activity. Anti-TF therapies during thrombolysis may reduce thrombin generation in AMI.     

Relevance of tissue factor and tissue factor pathway inhibitor for hypercoagulable state in the lungs of patients with idiopathic pulmonary fibrosis

We investigated the role of tissue factor (TF) and tissue factor pathway inhibitor (TFPI) in the lungs of patients with idiopathic pulmonary fibrosis (IPF). Bronchoalveolar lavage (BAL) fluid was obtained from 22 patients with IPF, and the levels of TF and TFPI antigen were measured by ELISA. The TF and TFPI levels in BAL fluid supernatant were significantly higher in IPF patients than in normal controls. In addition, both levels were significantly higher in advanced cases than in nonadvanced cases. There was a significant correlation between the TF and TFPI levels. Localization of TF and TFPI antigens was investigated by immunohistochemical staining. Both antigens were mainly localized in hyperplastic cuboidal epithelial cells, suggesting that the widespread distribution of these cells contributed to the increase of TF and TFPI antigen levels in the lungs of IPF patients. To assess whether TF activity is counterbalanced by TFPI in the lungs of IPF patients, we examined procoagulant activity and TF activity. It was found, however, that both procoagulant and TF activities were significantly higher in the BAL fluid supernatant of IPF patients than in that of normal controls, which suggested that TFPI was actually increased, but the increase was insufficient to counterbalance TF, leading to the development of a hypercoagulable state in the lungs of IPF patients.     

Circulating monocytes mirror the imbalance in TF and TFPI expression in carotid atherosclerotic plaques with lipid-rich and calcified morphology

Background

Thrombogenicity of atherosclerotic plaque largely depends on plaque morphology and their content of tissue factor (TF) and tissue factor pathway inhibitor (TFPI). The relationship between morphological composition of plaque (lipid-rich or calcified) and expression of TF and TFPI in circulating blood monocytes and within the plaques is not characterized.

Objective

To investigate whether lipid-rich (echolucent) or calcified (echogenic) morphology of carotid atherosclerotic plaques is associated with differences in TF and TFPI expression in circulating blood monocytes and within carotid atherosclerotic plaques.

Methods

We studied levels of monocyte TF and TFPI mRNA and protein expression and association with traditional risk factors for atherosclerosis in asymptomatic subjects with echolucent (n = 20) or echogenic (n = 20) carotid plaques, or controls without carotid atherosclerosis (n = 20) determined by ultrasonography. Sections of calcified or lipid-rich carotid plaques obtained from symptomatic patients were assessed for TF and TFPI antigen expression.

Results

TF and TFPI surface presentation, surface TF/TFPI ratio, and TF activity were higher in monocytes obtained from subjects with echolucent than with echogenic plaques or controls without carotid atherosclerosis. Multiple regression analyses revealed inverse association between serum apoA1 and monocyte surface TF antigen expression (p = 0.007), and positive association between serum apoB and monocyte surface TFPI expression (p = 0.028). Sections from lipid-rich carotid plaques contained 2.5-fold more TF and 1.5-fold more TFPI antigens relative to calcified lesions, also yielding a higher TF/TFPI ratio.

Conclusions

Our findings indicate that circulating monocytes of asymptomatic individuals with echolucent lipid-rich carotid atherosclerosis express an imbalance between TF and TFPI expression cohering with changes found within advanced carotid atherosclerotic plaques obtained from symptomatic patients.     

Alternatively spliced isoforms of tissue factor pathway inhibitor

Tissue factor pathway inhibitor (TFPI) is the major regulator of tissue factor (TF)-induced coagulation. It down regulates coagulation by binding to the TF/fVIIa complex in a fXa dependent manner. It is predominantly produced by microvascular endothelial cells, though it is also found in platelets, monocytes, smooth muscle cells, and plasma. Its physiological importance is demonstrated by the embryonic lethality observed in TFPI knockout mice and by the increase in thrombotic burden that occurs when heterozygous TFPI mice are bred with mice carrying genetic risk factors for thrombotic disease, such as factor V Leiden. Multiple TFPI isoforms, termed TFPIα, TFPIβ, and TFPIδ in humans and TFPIα, TFPIβ, and TFPIγ in mice, have been described, which differ in their domain structure and method for cell surface attachment. A significant functional difference between these isoforms has yet to be described in vivo. Both human and mouse tissues produce, on average, approximately 10 times more TFPIα message when compared to that of TFPIβ. Consistent with this finding, several lines of evidence suggest that TFPIα is the predominant protein isoform in humans. In contrast, recent work from our laboratory demonstrates that TFPIβ is the major protein isoform produced in adult mice, suggesting that TFPI isoform production is translationally regulated.     

The expression of tissue factor and tissue factor pathway inhibitor in aortic smooth muscle cells is up-regulated in synthetic compared to contractile phenotype

Tissue factor (TF) and its specific inhibitor TF pathway inhibitor (TFPI) are produced by vascular smooth muscle cells (SMCs) in vitro and are increased in vivo in atherosclerotic compared to normal vessels. Besides local regulation of the hemostatic balance, this may be related to non-hemostatic TF/protease dependent functions such as SMC proliferation, adhesion and migration. The aim of the study was to compare the expression of both proteins between the contractile (normal adult) and synthetic (neo-intimal) SMC phenotypes. Primary cultures of SMCs isolated from rat thoracic aorta before and 10 days after balloon injury displayed stable characteristics of the contractile and synthetic phenotype, respectively. Synthetic SMCs expressed more TF mRNA than contractile SMCs, but released excess TF in the conditioned medium, so that the cell-associated TF activity measured by a factor Xa generating assay remained similar in the two subtypes. Accordingly, cell surface thrombogenicity measured under blood flow conditions was also similar. The production and release of functional TFPI was enhanced by a factor 3 to 6 (p < 0.01) in synthetic SMCs. A difference in the quantitative expression of TF and TFPI is a new distinctive feature of SMC phenotypes. Matrix-associated TFPI derived from synthetic SMCs may serve as an anchorage for their migration and regulate protease-activated processes during neo-intima formation.     

Hemostatic properties of a TFPI antibody

Bleeds in hemophilia are treated either on demand or prophylactically by intravenous replacement therapy with FVIII or FIX. However, there is a call for subcutaneous and less frequent drug administration, and this need may be met by administration of a suitable antibody. Pioneering studies in vitro] and in a rabbit hemophilia model suggest that blockage of tissue factor pathway inhibitor (TFPI) provides a potential alternative approach to current therapy of hemophilia patients. TFPI down-regulates the initiation of coagulation by inhibition of FVIIa/TF/FXa and blockage of TFPI enhances FXa and thrombin generation. In line with these discoveries, TFPI targeting reagents with different potential benefits are currently evaluated as possible novel therapeutic agents. The development and testing of these agents in in vitro and in vivo hemophilia models provide new information about the mode of action of TFPI and its role in hemostasis. Blockage of TFPI with various antagonists has been shown to effectively enhance FX activation by TF/FVIIa and improve clot formation in hemophilia blood and plasma. The monoclonal antibody, mAb 2021, is one such antagonist directed towards the Kunitz-type protease inhibitor (KPI) 2 domain of TFPI which is now being tested in preclinical and clinical trials. Using mAb 2021, we have confirmed the original findings, and further characterized the pro-haemostatic effect of this specific anti-KPI-2 mAb in preclinical studies.     

Tissue factor reduction and tissue factor pathway inhibitor release after heparin administration

Elevated plasma levels of tissue factor (TF) and tissue factor pathway inhibitor (TFPI) and large amounts of monocyte procoagulant activity (PCA) have been documented in unstable angina (UA) patients. In in vitro experiments heparin is able to blunt monocyte TF production by inhibiting TF and cytokine gene expression by stimulated cells and after in vivo administration it reduces adverse ischemic outcomes in UA patients. TF and TFPI plasma levels and monocyte PCA have been investigated in 28 refractory UA patients before and during anticoagulant subcutaneous heparin administration (thrice daily weight- and PTT-adjusted for 3 days) followed by 5000 IU X 3 for 5 days. After 2-day treatment, immediately prior to the heparin injection, TF and TFPI plasma levels [(median and range): 239 pg/ml, 130-385 pg/ ml and 120 ng/ml, 80-287 ng/ml] were lower in comparison to baseline samples (254.5 pg/ml, 134.6-380 pg/ml and 135.5 ng/ml, 74-306 ng/ml). Four h after the heparin injection TF furtherly decreased (176.5 pg/ml, 87.5-321 pg/ml; -32.5%. p<0.001) and TFPI increased (240.5 ng/ml, 140-450 ng/ml; +67%, p<0.0001). After 7-day treatment, before the injection of heparin, TF and TFPI plasma levels (200 pg/ml, 128-325 pg/ml and 115 ng/ml, 70-252 ng/ml) significantly decreased (p<0.05) in comparison to the pre-treatment values. On the morning of the 8th day, 4 h after the injection of heparin TF plasma levels and monocytes PCA significantly decreased (156.5 pg/ml, 74-259 pg/ml and from 180 U/105 monocytes, 109-582 U/10(5) monocytes to 86.1 U/10(5) monocytes, 28-320 U/10(5) monocytes; - 38% and -55% respectively) and TFPI increased (235.6 ng/ml, 152-423 ng/ ml; +70%, p<0.001). In conclusion, heparin treatment is associated with a decrease of high TF plasma levels and monocyte procoagulant activity in UA patients. These actions of heparin may play a role in determining the antithrombotic and antiinflammatory properties of this drug.     

Shedding of active tissue factor by aortic smooth muscle cells (SMCs) undergoing apoptosis

As apoptosis of neo-intimal SMCs is a feature of advanced atherosclerotic plaques, the procoagulant properties of SMCs of synthetic phenotype undergoing apoptosis were investigated. SMCs isolated from rat aorta obtained 10 days after balloon injury, previously found to up-regulate Tissue Factor (TF) and Tissue Factor Inhibitor (TFPI) and to release large amounts of TFPI (Ghrib et al. Thromb Haemost 2002;87:1043-50), were sensitive to the apoptosis induced by Fas-ligand. During this process, surface TF activity rose by a factor 10 over 6 hours, in parallel with a proportional increase in prothrombinase, while TF protein expressed at the membrane significantly decreased. The microparticles (MPs) produced during SMC death bore intact and functional TF, but the release of TFPI did not change, so that the balance shifted to a procoagulant state during apoptosis. Shed MPs enhanced thrombus formation in flowing whole blood over collagen coated-glass slides. Apoptotic SMCs in atherosclerotic plaques represent a reservoir of highly thrombogenic material, released into the blood stream in case of spontaneous or mechanical plaque disruption.     

Tissue factor and tissue factor pathway inhibitor levels in trophoblast cells: implications for placental hemostasis

The placenta is a highly vascularized organ with fetal and maternal blood supply. Syncytiotrophoblasts (STB), which line the placenta villous are possibly involved in local hemostatic mechanisms. The aim of this study was to evaluate the levels of tissue factor (TF) and its inhibitors, tissue factor pathway inhibitor (TFPI, TFPI-2), in STB model within hemostatic and inflammatory environments. Human primary STB cell cultures were characterized by vascular and hormonal markers. TF and TFPI mRNA expression, protein levels and activity were determined and compared to human umbilical vein endothelial cells (HUVEC). High levels of TF were demonstrated in STB cells compared to low levels in HUVEC. In contrast, STB expressed lower TFPI levels than HUVEC. LPS and TNFalpha increased the high constitutive TF in STB, whereas LPS and IL-1alpha further reduced TFPI levels. The procoagulant tendency of STB identified by us may reflect the physiological need for immediate inhibition of hemorrhage in the placental inter-villous spaces in basal and inflammatory conditions. This hemostatic balance may be critical for normal placental function and pregnancy outcome.     

Inhibition of endothelial cell tube formation by the low molecular weight heparin, tinzaparin, is mediated by tissue factor pathway inhibitor

Heparin and low molecular weight heparins (LMWHs) have both antithrombotic and anti-angiogenic activities. The anti-angiogenic activity of LMWH may be associated with the release of endothelial tissue factor pathway inhibitor (TFPI), an important endogenous inhibitor of tissue factor/Factor VIIa (TF/fVIIa). To evaluate the effects of LMWH, tinzaparin, and TFPI in a model of angiogenesis-mediated processes, we compared the effects of tinzaparin, and recombinant TFPI in inhibiting either basic fibroblast growth factor-2 (FGF2)- or TF/fVIIa-induced endothelial cell tube formation in human umbilical vein endothelial cells (HUVEC). Our results show that tinzaparin and recombinant TFPI both blocked endothelial tube formation induced by either FGF2 or TF/fVIIa, in a concentration-dependent manner. Endothelial tube formation was only marginally inhibited by a potent and specific anti-Factor Xa, recombinant tick anticoagulant protein (rTAP). A monoclonal anti-TFPI anti-body reversed the inhibitory effects of either tinzaparin or recombinant-TFPI on HUVEC tube formation. Tinzaparin fractions in the range of 8,000 to 12,600 Da were most effective in stimulating the release of TFPI from HUVEC. These results suggest that the inhibitory effect of the LMWH tinzaparin on endothelial tube formation is associated with stimulation of the release of TFPI, but not to anti-Factor Xa activity.     

Tissue factor activity is upregulated in human endothelial cells exposed to oscillatory shear stress

Hemodynamic forces play a critical role in the pathogenesis of atherosclerosis as evidenced by the focal nature of the disease. Oscillatory shear stress characterizes the hemodynamic environment of plaque-prone areas as opposed to unidirectional shear stress typical of plaque-free areas. These particular flow conditions modulate atherosclerosis-related genes. Tissue factor (TF) initiates blood coagulation, contributes to vascular remodeling, and is therefore a potential contributor in the development/progression of atherosclerosis. We investigated the effect of oscillatory and unidirectional flows on TF using an in vitro perfusion system. Human endothelial cells exposed for 24 h to oscillatory shear stress, significantly increased TF mRNA, and TF protein expression (1.5- and 1.75-fold, respectively, p < 0.01), and surface TF activity (twofolds-increase). Expression of TF inhibitor (TFPI), mRNA and protein, remained unchanged as compared to static conditions. Conversely, cells exposed to unidirectional shear, showed a decrease in TF activity with a significant increase in TFPI mRNA and protein expression (1.5- and 1.8-fold, respectively, p < 0.01). These results show for the first time that pulsatile oscillatory shear stress induces a pro-coagulant phenotype of endothelial cells which may favor formation/progression of atherothrombotic lesions.