In-Cell Western assay: a new approach to visualize tissue factor in human monocytes

BACKGROUND: Tissue factor (TF) is an integral membrane protein essential for the initiation of the extrinsic pathway of hemostasis. A precise understanding of the TF regulation is still limited and dependent on the availability of methodological tools. Here, we describe a new approach for assessing TF amounts in human mononuclear cells (MNCs) by using the whole blood experimental conditions. AIM: In order to study TF antigen levels in human MNCs, we applied a quantitative immunostaining technique-- in-cell Western (ICW) assay using an Odyssey Infrared Imaging System. METHODS AND RESULTS: The ICW assay of TF in resting or lipopolysaccharide (LPS)-stimulated human MNCs was performed. Several sample preparation conditions were tested, namely the plating of MNCs prior to immunostaining, paraformaldehyde fixation, and an adequate cell number was used in the assay. By the use of recombinant human TF standards, it was possible, for the first time, to measure TF amounts in LPS-stimulated MNCs as 0.09 +/- 0.02 ng and 0.43 +/- 0.15 ng 10(-6) cells of surface and total TF, respectively. The concentrations of TF in resting MNCs, however, were below the detection limit. CONCLUSIONS: A novel TF ICW assay is a reproducible, time- and cost-saving method, which could become useful for studies in the fields of physiology and pathophysiology of human hemostasis.     

High tissue factor-expressing human monocytes carry low surface CD36: application to intersubject variability

BACKGROUND: The 'high and low responder' phenomenon describes an intersubject variability in mononuclear cell (MNC) prothrombotic reactivity to lipopolysaccharide (LPS) stimulation. Because alterations in surface CD36 expression in monocytes were associated with impaired monocyte function, we studied the relationship between the levels of surface CD36 presentation and the prothrombotic reactivity of monocytes from high-responder (HR) and low-responder (LR) individuals. METHODS AND RESULTS: The relationship between levels of tissue factor (TF) expression and surface CD36 presentation in MNCs from HR individuals (n = 7) and LR individuals (n = 8) was investigated. Resting MNCs from HR individuals contained significantly more TF mRNA but levels of TF antigen and procoagulant activity similar to MNCs from LR individuals. Resting CD14+ MNCs from HR individuals expressed significantly lower surface CD36, as mean fluorescence intensities (MFIs) were 70.4 +/- 6.3 vs. 132.0 +/- 14.5 arbitrary units (AU) in HR and LR individuals, respectively. MFI from surface TF negatively correlated with surface CD36 in the population of resting (r = -0.598, P = 0.031) and LPS-stimulated (r = -0.672, P = 0.009) CD14+ cells. LPS-stimulated MNCs from HR individuals contained significantly more TF in a surface pool (2079 +/- 199 vs. 786 +/- 57 AU) along with higher TF procoagulant activity (57.3 +/- 15.2 vs. 21.1 +/- 4.5 mU 10(6) cells(-1)) as compared with LR individuals. CD14+ MNCs from HR individuals expressed less surface CD36 during a 2-h LPS challenge. CONCLUSIONS: A novel phenotype of monocytes characterized by high TF and low CD36 presentation could be further developed for use as a marker for detection of HR individuals prone to developing prothrombotic conditions.     

弥散性血管内凝血患者全血细胞组织因子活性改变的意义

目的 应用脂多糖(LPS,内毒素)刺激全血细胞组织因子(TF)的表达及促凝活性(TF-PCA)增强程度.观察弥散性血管内凝血(DIC)时TF-PCA的改变及在诊断DIC中的意义.方法 病例资料来源:华中科技大学同济医学院附属协和医院2005年1月至2007年1月住院急性粒细胞白血病患者,正常对照组(A组)38例,疾病组中相关凝血检查lF常病例(B组)8例,1～2项凝血检查异常组(C组)21例,疑似DIC组(D组,凝血检查3项或以上,但未达到DIC诊断标准者)12例,符合DIC诊断病例(E组)23例.采用用LPS刺激的全血复钙时间检测全血细胞TF活性(Tssue Factor Clotting Time,TiFaCr),即在抗凝全血中加入或不加IPS于370℃温育一定时间,然后复钙检查全血凝固时间,根据全血凝固时间缩短的程度(△s)来判断TF-PCA的强弱.应用SPSS 13.0软件进行成LSD-t检验及双变量相关性处理,以P<0.05为差异具有统计学意义.结果 对受检病例进行回顾性、描述性分析显示DIC、疑似DIC患者TF-PCA分别是(95.2±68.6)、(85.8±16.9)As与正常组(30.4±25.1)△s比较差异具有统计学意义(P<0.01),TF mRNA检测、TF-PCA抑制实验结果 提示TiFaCT.测定TF-PCA有较高的敏感性和特异性.结论 DIC和疑似DIC患者在LPS刺激后TF-PCA明显增强,TiFaCT 对于DIC的诊断及预后评价有重要临床参考价值.     

血管紧张素Ⅱ对单核细胞组织因子表达的影响及调控机制

目的　观察血管紧张素Ⅱ (AngⅡ )对人单核细胞组织因子 (TF)表达的影响及机制。方法　人外周血单核细胞的分离采用淋巴细胞分离液及Percoll。细胞促凝活性 (PCA)的检测采用一期凝固法。细胞TF抗原测定采用ELISA法 ;TFmRNA检测采用RT PCR的方法 ;IκBα水平分析采用Westernblot方法 ;NF κB的变化分析用凝胶电泳迁移率实验。结果　AngⅡ (10 - 9～ 10 - 7mol L)可剂量依赖性诱导单核细胞PCA、TF抗原及mRNA的增加 ,并有明显的时效关系。洛沙坦 (losartan)浓度在 10 - 6 ～10 - 5mol L可不同程度地阻断AngⅡ的作用。Staurosporine(2 .5× 10 - 7mol L)以及金雀异黄素 (4× 10 - 5mol L)可显著抑制AngⅡ (10 - 7mol L)诱导的单核细胞PCA、TF抗原增加及TFmRNA的表达 ;AngⅡ(10 - 7mol L)作用 15min可引起单核细胞IκBα水平下降 (P <0 .0 5 ) ,6 0min时IκBα水平降至最低水平 ,180min时恢复至正常水平 ;凝胶电泳迁移率显示AngⅡ (10 - 7mol L)诱导单核细胞NF κB的作用在 15min起效 ,6 0min时核内NF κB的水平最高 ,180min恢复正常 ;洛沙坦 (10 - 5mol L)或PDTC(10 - 4mol L)均可抑制NF κB的活化。结论　AngⅡ可诱导单核细胞TF的表达 ,该作用是通过AngⅡ 1型受体实现的。胞内PKC发挥较强的作用。NF κB的     

Plasmin‐dependent proteolysis of tissue factor pathway inhibitor in a mouse model of endotoxemia

Summary. Background: The development of a procoagulant state in sepsis, owing to aberrant expression of tissue factor (TF) and a sharp decrease in the level of its major inhibitor, TF pathway inhibitor (TFPI), could lead to microthrombotic organ failure. The mechanism for the decline in TFPI activity in the lung could involve plasmin‐mediated cleavage of the inhibitor. Objective: To investigate the effect of plasmin generation on lung‐associated TFPI activity, in normal conditions and during infusion of endotoxin (lipopolysaccharide [LPS]) in mice. Methods: Plasmin generation and TFPI activity were assayed in the lungs of mice deficient in tissue‐type plasminogen (Plg) activator (t‐PA) or Plg, at 2 h after LPS or saline injection. Results: The sharp loss of lung‐associated TFPI activity at 2 h after LPS challenge paralleled the abrupt increase in plasmin generation. TFPI activity was significantly retained in both t‐PA^?/? and Plg^?/? mice, which are unable to generate plasmin. Conclusion: The increased plasmin generation during the early stages of sepsis could cleave/inactivate TFPI and thus lead to thrombotic complications.     

Insulin inhibits tissue factor expression in monocytes

Summary.  Objectives:  Platelets from healthy subjects are inhibited by insulin but type 2 diabetes mellitus (T2DM) platelets have become insulin-resistant, which might explain their hyperactivity. In the present study we investigated whether monocytes are responsive to insulin. Methods and results:  LPS-induced tissue factor (TF) upregulation was measured in human monocytes and monocytic THP-1 cells in a factor Xa generation assay. Insulin (0.1–100 nmol L⁻¹) induced a dose-dependent inhibition in both cell types and in monocytes 100 nmol L⁻¹ insulin inhibited cytosolic, membrane-bound and microparticle TF by 32 ± 2, 27 ± 3 and 52 ± 4% ( n  = 3). Insulin induced Tyr phosphorylation of the insulin receptor (INS-R) and formation of an INS-R – G_iα₂ complex, suggesting interference with LPS-induced cAMP control. Indeed, insulin interfered with LPS-induced cAMP decrease and TF upregulation in a manner similar to an inhibitor of G_i (pertussis toxin) and agents that raise cAMP (iloprost, forskolin, IBMX) reduced TF upregulation. Although LPS failed to raise cytosolic Ca²⁺, quenching of Ca²⁺ increases (BAPTA-AM) reduced and induction of Ca²⁺ entry (ionophore, P2X7 activation) enhanced upregulation of TF mRNA and procoagulant activity. Insulin interfered with MCP-1-induced Ca²⁺ mobilization but not with ATP-induced Ca²⁺ rises. Conclusions:  Insulin inhibits TF expression in monocytes and monocyte-derived microparticles through interference with G_iα₂-mediated cAMP suppression, which attenuates Ca²⁺-mediated TF synthesis.     

Identification and characterization of murine alternatively spliced tissue factor

Tissue factor (TF) is a transmembrane glycoprotein that initiates coagulation and plays a critical role in regulating hemostasis and thrombosis. We have recently reported a naturally occurring, soluble form of human tissue factor (asTF) generated by alternative splicing. This splice variant has a novel C-terminus with no homology to that of the full-length TF (flTF), lacks a transmembrane domain, and is active in the presence of phospholipids. Mouse models offer unique opportunities to examine the relative importance of flTF and asTF in mediating thrombosis, the response to arterial injury, and ischemic damage. To that end, we have identified and characterized murine asTF (masTF). Like the human splice variant, masTF lacks a transmembrane domain and has a unique C-terminus. We have generated antibodies specific to masTF and murine flTF (mflTF) to examine the expression of both forms of TF. masTF antigen is widely and abundantly expressed, with a pattern similar to that of mflTF, in adult tissues, in experimentally induced thrombi, and during development. These studies demonstrate that masTF contributes to the pool of total TF and may thus play an important role in mediating TF-dependent processes.     

No evidence for the presence of tissue factor in high‐purity preparations of immunologically isolated eosinophils

Summary. Background: To date, there is no unequivocal opinion on whether human eosinophils express tissue factor (TF). Therefore, we studied the expression of TF protein and activity in resting or stimulated immunologically purified human eosinophils. Methods and results: By use of immunologic isolation, we achieved over 96% purity of eosinophil preparations, and contamination by CD14‐positive cells was below 0.3%. Flow cytometric [fluorescence‐activated cell sorting (FACS)] analysis of eosinophils revealed no surface expression of TF antigen in resting or stimulated eosinophils. Immunoblotting of eosinophil lysates did not show any TF protein under resting or stimulated conditions. The lysates of resting or stimulated eosinophils contained no detectable levels of TF procoagulant activity. In contrast, monocytes, stimulated in plasma or medium, possessed readily detectable TF levels on the cell surface and in cell lysates as detected by FACS and immunoblotting. This was active TF antigen, as confirmed by TF activity assay (19.2 ± 4.2 and 28.6 ± 3.1 mU per 10⁶ cells, stimulated in medium or plasma, respectively). We found no detectable TF mRNA levels in resting or stimulated eosinophils by real‐time polymerase chain reaction (PCR), whereas in monocytes TF mRNA levels were significantly increased after stimulation. Conclusions: Our data indicate that there is no evidence for TF expression in high‐purity preparations of immunologically isolated eosinophils.     

The role of platelets in decrypting monocyte tissue factor

Although about 80% of tissue factor (TF) extracellular domain antigen present in lipopolysaccharide (LPS)-stimulated monocytes is available at the cell surface, only 10% to 20% of the total extractable TF activity is expressed on the surface of intact monocytes. Thus, most of the TF activity is latent or encrypted in the cell membrane. When coincubated, leukocytes and platelets generate more TF activity than either cell type alone. We have shown that such platelet-promoted enhancement of LPS-induced TF activity in monocytes in whole blood depends on neutrophil involvement in a P-selectin/CD15 (a leukocyte membrane-bound carbohydrate)-dependent reaction. The effect was even more pronounced when both the phorbol ester, phorbol 12-myristate 13-acetate (PMA), and LPS were present during monocyte stimulation. We currently envisage that decryption is mediated through the secretion of TF-rich particles by monocytes. These particles express CD15 and bind P-selectin exposed on either activated platelets or platelet-derived microparticles. Interactions and fusion events, that typically occur between monocytes and platelets, would facilitate the generation of monocytes/monocyte microparticle and platelets/platelet microparticle hybrids, leading to particles rich in decrypted TF activity. In conclusion, platelets play a pivotal role in decrypting TF activity of monocytes, generating a hybrid TF terrain, which both triggers and favors thrombogenesis.     

C-reactive protein contributes to the hypercoagulable state in coronary artery disease

OBJECTIVES: Elevated plasma C-reactive protein (CRP) levels predict coronary events, but it is unclear whether CRP plays a role in thrombosis associated with these events. We investigated tissue factor (TF) induction by CRP on peripheral blood mononuclear cells (PBMC) from patients with coronary disease. PATIENTS AND METHODS: PBMC from 35 patients with stable angina (SA) in study 1, 10 male patients with SA, 10 with unstable angina (UA) and 10 matched controls in study 2, and 25 patients with inflammatory disorders (ID) and 24 normal controls in study 3 were stimulated with CRP, interferon-gamma (IFN) or lipopolysaccharide (LPS), or their combination. PBMC from additional normal donors were also stimulated with CRP in adherent and non-adherent conditions, and TF activity, antigen and mRNA expression detected. RESULTS: CRP (5-25 microg mL(-1)) dose dependently induced more TF on PBMC from SA patients than 42 contemporary controls (P = 0.001, study 1). Compared with controls, patients with SA or UA had higher basal, and much higher CRP- or CRP/LPS-induced monocyte TF activity although serum CRP levels were similar (study 2). IFN induced monocyte TF activity in patients with angina, but not in controls. Basal or CRP-induced TF levels did not differ between controls and ID, even though ID patients had much higher serum CRP levels (study 3). CRP-induced monocyte TF activity correlated with serum CRP levels in controls (P = 0.005) and ID (P = 0.007) in study 3, but not in patients with angina (P =0.84) in study 2. CRP induced more TF activity, protein and mRNA under adherent than non-adherent conditions implying that it may mainly target macrophages in lymphocyte-rich lesions. CONCLUSIONS: Our results indicate that monocytes from patients with angina are preactivated and express TF but CRP is unlikely to be a major priming factor in vivo. IFN and CRP further increase TF levels that may contribute to the hypercoagulable state in coronary disease.     

Separation of dendritic cells from highly purified human monocytes by counterflow centrifugation induces tissue factor expression

BACKGROUND: In vitro generation of dendritic cells (DCs) from human monocytes represents a promising tool in immunotherapy. However, it is not known whether the separation of DCs from monocytes induces tissue factor expression and therefore may trigger coagulation in patients receiving these DC preparations. The aim of this study is thus to analyze tissue factor expression on monocyte-derived DCs and to compare their ability to trigger thrombin generation to that of macrophages obtained from the same monocytes. STUDY DESIGN AND METHODS: Human monocytes are separated by leukapheresis and washed by using counterflow centrifugation in sterile, endotoxin-free conditions. Macrophages are grown from human monocytes in the presence of GM-CSF alone and immature DCs are grown in the presence of GM-CSF plus IL-4 for 5 days with fetal calf serum (IDC-FCS). Immature DCs are also grown from human monocytes for 7 days in the presence of GM-CSF plus IL-4 with human group AB serum (IDC-HS). The addition of prostaglandin E(2) and TNFalpha in this culture medium at Day 5 leads to mature DCs (MDC-HS). Tissue factor mRNA expression is studied by RT-PCR analysis. Tissue factor antigen is measured by ELISA in cell lysates and by direct flow cytometry. The procoagulant activity of intact cells is assessed by using an amidolytic assay or a chronometric assay. RESULTS: IDC-FCS express tissue factor mRNA and antigen and trigger thrombin generation. Procoagulant activity of IDC-FCS is dependent on both tissue factor expression and exposure to anionic phospholipid. Monocyte-derived macrophages cultured for 5 days with GM-CSF alone express lower levels of tissue factor mRNA, tissue factor antigen, and procoagulant activity than IDC-FCS. IDC-HS and MDC-HS also express high levels of tissue factor mRNA and antigen and support procoagulant activity. CONCLUSION: Monocyte-derived DCs express a high level of functional tissue factor and support procoagulant activity. This finding should be taken into account in clinical trials.     

Glycogen synthase kinase‐3 negatively regulates tissue factor expression in monocytes interacting with activated platelets

Summary. Background: At the site of vascular injury, monocytes (MN) interacting with activated platelets (PLT) synthesize tissue factor (TF) and promote thrombus formation. Intracellular signals necessary for the expression of TF in MN, in the context of a developing thrombus, remain unknown. Objective: The study was designed to investigate the role of the glycogen synthase kinase 3 (GSK3, a serine‐threonine kinase) downstream insulin receptor pathway, in PLT‐induced TF expression in MN. Methods: To this purpose we used a well‐characterized in vitro model of human MN‐PLT interactions that allows detailed analysis of TF activity, TF protein and gene expression.Results: The results demonstrated that, in MN interacting with activated PLT: (i) TF activity, antigen and mRNA were low until 8–10 h and dramatically increased thereafter, up to 24 h; (ii) according to the kinetics of TF expression in MN, GSK3β undergoes phosphorylation on serine 9, a process associated with down‐regulation of enzyme activity; (iii) pharmacological blockade of GSK3 further increased TF expression and was accompanied by increased accumulation of NF‐kB, in the nucleus; (iv) blockade of phosphoinositide‐3 kinase (PI(3)K) by wortmannin inhibited PLT‐induced TF expression; and (v) according to the established role of the GSK3 downstream insulin receptor, insulin increased PLT‐induced TF expression in a PI(3)K‐dependent manner. Conclusion: GSK3 acts as a molecular brake on the signaling pathway, leading to TF expression in MN interacting with activated PLT. PI(3)K, through Akt‐dependent phosphorylation of GSK3, relieves this brake and allows TF gene expression. This study identifies a novel molecular link between thrombotic risk and metabolic disorders.     

Tissue factor and monocyte chemoattractant protein-1 expression in hypertensive individuals with normal or increased carotid intima-media wall thickness

BACKGROUND: People with hypertension display an inflammatory pattern that includes increased plasma concentrations of monocyte chemoattractant protein 1 (MCP-1) and C-reactive protein (CRP) and enhanced expression of tissue factor (TF) mRNA in blood monocytes. METHODS: In this study, we investigated the relationship between CRP concentrations and TF and MCP-1 mRNA expression in unstimulated and lipopolysaccharide (LPS)-stimulated monocytes isolated from hypertensives with or without an increase in carotid intima-media thickness (IMT). We also investigated the expression of TF and MCP-1 mRNA and MCP-1 protein after in vitro addition of CRP to monocytes. We measured CRP (by immunonephelometry) and monocyte expression of TF and MCP-1 (by real-time PCR) in 80 untreated hypertensive patients without clinical cardiovascular disease (CVD) or additional risk factors for CVD compared with 41 controls. Based on IMT measured by carotid Doppler ultrasonography, patients were classified into the categories of normal (< or =1 mm) or abnormal (>1 mm). TF and MCP-1 mRNA and MCP-1 protein (by Western blotting) were measured after in vitro addition of CRP to monocytes from 10 randomized controls as well as 10 hypertensives with IMT < or =1 mm and 10 with IMT >1 mm. RESULTS: CRP and TF and MCP-1 mRNA concentrations were significantly higher in IMT >1 mm hypertensives vs those with IMT < or =1 mm and controls. CRP had no effect on monocyte TF mRNA from either hypertensives or controls. CRP-stimulated monocytes from hypertensives, however, showed increased MCP-1 mRNA and protein expression compared with controls and LPS-stimulated cells. CONCLUSIONS: Our findings suggest that the inflammatory response of blood monocytes plays an important role in the development of atherosclerosis and hypertension.     

A novel anticoagulant activity assay of tissue factor pathway inhibitor I (TFPI).

Tissue factor (TF) pathway inhibitor I (TFPI) is the physiological inhibitor of TF-induced blood coagulation. Circulating blood contains full-length TFPI and TFPI truncated at the C-terminal end. Previous studies have shown that full-length TFPI exerts a stronger anticoagulant effect on diluted prothrombin time (DPT) than truncated TFPI, and it has been suggested that full-length TFPI is biologically more important in vivo. The objective of this study was to develop and validate an assay of TFPI anticoagulant activity. TFPI anticoagulant activity was assayed using a modified DPT assay. Plasmas were incubated in the absence and the presence of TFPI-blocking antibodies. Results were expressed as a ratio with the clotting time in the presence of anti-TFPI as the denominator. The ratio was normalized against a ratio obtained with a reference plasma. The assay was compared with assays of TFPI free antigen, total antigen, and bound TFPI, and TFPI chromogenic substrate activity. We performed all tests in 436 healthy individuals. The normalized TFPI anticoagulant ratio was strongly associated with TFPI free antigen (r = 0.73) but was weakly associated with TFPI chromogenic substrate activity (r = 0.46), TFPI total antigen (r = 0.48), and bound TFPI (r = 0.30). TFPI chromogenic substrate activity was strongly associated with TFPI total antigen (r = 0.73). We have developed a novel assay of TFPI anticoagulant activity in plasma, which may be considered a functional assay of full-length TFPI. Further studies are needed to establish the role of TFPI anticoagulant activity for thrombotic disorders.     

Procoagulant and inflammatory response of virus-infected monocytes

BACKGROUND: Monocytes play a prominent role in inflammation, coagulation and atherosclerosis by their ability to produce tissue factor (TF) and cytokines. The aim of the present study was to establish whether virus-infected monocytes initiate coagulation. In addition, the production of cytokines by monocytes may accelerate the chronic process of atherosclerosis and may contribute to coronary syndromes by eliciting plaque instability. MATERIALS AND METHODS: Monocytes were isolated by Vacutainer(R), BD Biosciences, Alphen aan den Rijn, Netherlands and subsequent magnetic cell sorting (MACS(R), Milteny Biotec, Bergish Gladbach, Germany). Coagulation times in normal pooled plasma and Factor VII-deficient plasma were measured after infection with cytomegalovirus (CMV), Chlamydia pneumoniae (Cp) and influenza A\H1N1. Anti-TF antibodies were added to neutralize TF expressed on monocytes. Interleukins (IL) 6, 8 and 10 were measured in the supernatants. RESULTS: Chlamydia pneumoniae- and CMV-infected monocytes decreased the clotting time by 60%, and influenza-infected monocytes by 19%, as compared to uninfected monocytes. Procoagulant activity was absent when Factor VII-deficient plasma or anti-TF antibodies were used. Monocytes produced both IL-6 and IL-8 after infection with CMV (317 pg mL-1 and 250 pg mL-1) or Cp (733 pg mL-1 and 268 pg mL-1). Similar results were obtained for influenza virus-infected monocytes, but the levels of both cytokines were 3-5-fold higher (1797 pg mL-1 and 725 pg mL-1). Interleukin-10 was not produced by infected monocytes. CONCLUSION: The procoagulant activity of virus-infected monocytes is TF-dependent. Although influenza infection did not generate a significant reduction in clotting time, the pronounced expression of IL-6 and IL-8 may induce local and/or systemic inflammatory reactions, which may be associated with plaque rupture and atherosclerosis. The lack of production of the anti-inflammatory cytokine IL-10 may even accelerate these processes.     

Splice variants of tissue factor promote monocyte‐endothelial interactions by triggering the expression of cell adhesion molecules via integrin‐mediated signaling

Summary. Background: TF is highly expressed in cancerous and atherosclerotic lesions. Monocyte recruitment is a hallmark of disease progression in these pathological states. Objective: To examine the role of integrin signaling in TF‐dependent recruitment of monocytes by endothelial cells. Methods: The expression of flTF and asTF in cervical cancer and atherosclerotic lesions was examined. Biologic effects of the exposure of primary microvascular endothelial cells (MVEC) to truncated flTF ectodomain (LZ‐TF) and recombinant asTF were assessed. Results: flTF and asTF exhibited nearly identical expression patterns in cancer lesions and lipid‐rich plaques. Tumor lesions, as well as stromal CD68⁺ monocytes/macrophages, expressed both TF forms. Primary MVEC rapidly adhered to asTF and LZ‐TF, and this was completely blocked by anti‐β1 integrin antibody. asTF‐ and LZ‐TF‐treatment of MVEC promoted adhesion of peripheral blood mononuclear cells (PBMCs) under orbital shear conditions and under laminar flow; asTF‐elicited adhesion was more pronounced than that elicited by LZ‐TF. Expression profiling and western blotting revealed a broad activation of cell adhesion molecules (CAMs) in MVEC following asTF treatment including E‐selectin, ICAM‐1 and VCAM‐1. In transwell assays, asTF potentiated PMBC migration through MVEC monolayers by ～3‐fold under MCP‐1 gradient. Conclusions: TF splice variants ligate β1 integrins on MVEC, which induces the expression of CAMs in MVEC and leads to monocyte adhesion and transendothelial migration. asTF appears more potent than flTF in eliciting these effects. Our findings underscore the pathophysiologic significance of non‐proteolytic, integrin‐mediated signaling by the two naturally occurring TF variants in cancer and atherosclerosis.     

Mechanism of the inhibitory effect of protease inhibitor on tumor necrosis factor alpha production of monocytes

If the inflammatory response becomes excessive or uncontrolled by some stimuli, inappropriate inflammatory responses occur. Monocytes are extremely important cells for regulating the cytokine network and tumor necrosis factor alpha (TNFalpha) and interleukin- (IL) 10, which are mainly synthesized by monocytes, are representative cytokines that play a central role in the cytokine network. Protease inhibitors such as gabexate mesilate (GM) and ulinastatin (UTI) have been shown to have various beneficial effects by inhibiting the activation of leukocytes, but the mechanism for this has yet to be fully elucidated. In this study we investigated the mechanism of the inhibitory effect of protease inhibitors on the proinflammatory cytokine production of lipopolysaccharide- (LPS) stimulated monocytes. LPS-stimulated monocytes were treated with GM or UTI. The value of TNFalpha and IL-10 in the culture medium of monocytes was measured and each mRNA expression was assayed. The inhibitory effect of protease inhibitors on the activity of intracellular signal transduction pathways such as protein kinase C (PKC) and nuclear factor kappa B (NFkappaB) were also evaluated. GM decreased the TNFalpha production of LPS-stimulated monocytes as shown by the inhibition of mRNA expression and increased the IL-10 production of LPS-stimulated monocytes. GM also suppressed the NFkappaB activity of LPS-stimulated monocytes. UTI decreased the TNFalpha production of LPS-stimulated monocytes, but did not inhibit the TNFalpha mRNA expression. The present study shows that the inhibitory effect of GM on the TNFalpha production of activated human monocytes is mediated by the suppression of NFkappaB activation, while the mechanism of UTI inhibiting TNFalpha production of human monocytes may be due to the inhibition of either the translation or secretion of TNFalpha.     

Monocyte adhesion and transmigration induce tissue factor expression: role of the mitogen-activated protein kinases

The expression of tissue factor (TF) by monocytes that have transmigrated across the endothelium to sites of extravascular inflammation acts both to focus and amplify the inflammatory response. Because clustering of the integrins responsible for endothelial adhesion and transmigration induces tyrosine phosphorylation and activation of the mitogen-activated protein (MAP) kinases, we postulated that transmigration might lead to monocyte activation and TF production. Monocytes were migrated across TNFalpha-primed ECV304 cells grown on fibronectin-coated Transwell chambers in response to FMLP (10(-8) M). After transmigration, monocytes showed a time-dependent increase in surface TF expression and biological procoagulant activity. TF expression was dependent on monocyte adhesion to ECV304 cells. Specifically, TF was not induced by FMLP treatment of suspended monocytes, by migration across fibronectin alone, or by soluble factors induced during migration, whereas monocyte-ECV304 adhesion was sufficient to stimulate TF. Antibodies against CD29 (beta1 integrin), but not against CD18 (beta2 integrin) or CD31 (PECAM-1), inhibited TF expression. Monocyte adhesion to ECV304 cells induced tyrosine phosphorylation of cellular proteins and specifically of the ERK and p38 MAP kinases. Tyrosine kinase inhibition with genistein (10 microg/mL) blocked transmigration, whereas selective ERK inhibition with PD98059 (50 microM) or p38 inhibition with SB203580 (20 microM) did not. However, both ERK and p38 inhibition dose dependently abolished TF expression. These studies suggest that an extravascular focus of infection or inflammation can promote both intravascular thrombosis and extravascular fibrin deposition during the process of adhesion and transmigration across the endothelial barrier. The selective inhibition of the mitogen-activated protein kinases may offer a novel therapeutic means of modulating this inflammatory sequence.