Regulation of cardiomyocyte full-length tissue factor expression and microparticle release under inflammatory conditions in vitro.

SUMMARY BACKGROUND: Myocardial inflammation is associated with an increase in circulating microparticles (MPs) and procoagulability. OBJECTIVES: We determined whether acute inflammation was associated with altered full-length tissue factor (flTF) expression and increased procoagulability in cardiomyocytic cells. METHODS: This study examined the transcriptional regulation of flTF expression in murine cardiomyocytic (HL-1) cells. Also, the generation of MPs by HL-1 cells and their ability to diffuse through an artificial endothelium was evaluated. RESULTS: Constitutive and tumor necrosis factor-alpha (TNF-alpha)-induced flTF expression of HL-1 was reduced when c-Jun N-terminal kinase (JNK) was inhibited. Tissue factor (TF)-positive procoagulant MPs were released from HL-1 cells in response to TNF-alpha. JNK inhibition potentiated the release of MPs from HL-1 cells without affecting MP-associated TF activity. MP generation was dependent on RhoA activation and associated with a reorganization of the actin cytoskeleton. Increased diffusion of HL-1-derived MPs through an endothelial monolayer was found after TNF-alpha treatment. The increased diffusion was dependent not only on TNF-alpha but also on HL-1-released mediators. CONCLUSIONS: Full-length TF expression in HL-1 cells was regulated through JNK. The TNF-alpha-induced increase in procoagulability was mediated through RhoA-dependent release of flTF-bearing MPs. These MPs were able to diffuse through an endothelial barrier adjacent to HL-1 cells and increased the procoagulability of the extracellular endothelial space. Cardiomyocytes seem to be a likely source of flTF-bearing procoagulant MPs.

Clopidogrel-mediated reduction of circulating tissue factor in patients with stable coronary artery disease.

BACKGROUND: Tissue factor (TF), the initiator of coagulation, circulates in blood and contributes to thrombosis in patients with coronary artery disease (CAD). TF is present in the alpha-granules of platelets. Therapy with clopidogrel results in inhibition of platelet degranulation. Whether clopidogrel affects circulating TF is unknown. This study examined the effect of clopidogrel on TF level in the blood of patients with stable CAD and ST-elevation myocardial infarction (STEMI) as well as healthy controls. METHODS: Thirty-three patients with CAD and twenty with STEMI were studied pre and post clopidogrel therapy (loading dose 300 mg, then 75 mg daily). All were treated with aspirin 100 mg/d. The control groups consisted of thirty healthy male volunteers also treated with clopidogrel and ten patients with CAD treated with aspirin only. TF concentration in blood drawn pre and 96 h post clopidogrel administration was measured by enzyme-linked immunosorbent assay. RESULTS: Patients with CAD and STEMI had significantly more TF in blood than healthy controls. Clopidogrel reduced TF in stable CAD patients to levels seen in healthy controls. No alterations in TF were found in controls and patients with STEMI post clopidogrel therapy. Clopidogrel reduced sCD40L level in stable CAD patients, but not in STEMI patients. A correlation between TF and sCD40L was found for the combined CAD and control, but not STEMI group. CONCLUSION: Clopidogrel leads to a reduction of not only sCD40L but also TF in stable CAD. The reduction of TF may lead to a reduced thrombogenicity, contributing to the benefits of clopidogrel therapy.