Tissue factor in acute coronary syndromes

Rupture of an atherosclerotic plaque with subsequent thrombosis and myocardial ischemia is the patho-physiological mechanism in acute coronary syndromes. Tissue factor (TF) as the main initiator of the extrinsic coagulation cascade plays a central role in the pathogenesis of acute coronary syndromes. The extent of the thrombotic process is modulated by local vascular TF of the ruptured plaque as well as by circulating TF. In addition, TF alters signaling pathways and, thereby, contributes to inflammatory reactions and vascular remodeling. This review addresses current concepts of the role of TF in acute coronary syndromes and discusses potential consequences and therapeutic approaches.     

Tissue factor: a critical role in inflammation and cancer

A series of coordinated enzymatic reactions takes place in the body whenever blood clots. The major physiological initiator of these reactions is a membrane-bound glycoprotein known as tissue factor (TF), which is normally separated from the bloodstream by the vascular endothelium. Bleeding, caused by injury or tissue damage, activates a complex enzyme cascade as TF becomes exposed to the bloodstream. In disease states, leukocytes or the vascular endothelium may abnormally express TF to cause intravascular coagulation. The blood-coagulation cascade is also relevant to diseases such as hemophilia, in which patients are deficient in blood proteins necessary for clotting, and is linked to vascular diseases such as heart attack and stroke, in which clotting can lead to the occlusion of blood vessels. Coagulation is also activated in inflammation and cancer. In this article, we discuss characteristics of TF and review its role in inflammation and cancer.     

Tissue factor and tumor: clinical and laboratory aspects

This review summarizes data demonstrating the role of TF in tumor development, metastasis and angiogenesis. TF is a transmembrane protein that is expressed constitutively in some kinds of extravascular cells and transiently in intravascular cells after stimulation with cytokines and growth factors. Originally TF was considered to have a function in the initiation of coagulation. In the last years it became evident that TF plays a role in physiological and pathological processes outside the hemostasis. Up-regulation of TF expression appears to be characteristic of tumor tissue. In a variety of human tumors it was shown by immunohistochemistry, that TF can be expressed in malignant cells as well as in tumor-infiltrating macrophages or endothelial cells. Such abnormal TF expression contributes to the angiogenic process by a shift in the balance between endogenous proangiogenic and antiangiogenic factors. Observations of a significant correlation between elevated TF expression with increased microvessel density and VEGF expression underline the TF involvement in tumor angiogenesis. Furthermore, TF expression influences also metastasis. The effect of TF on metastasis may result from its angiogenic effect, but also from the production of growth factors or adhesion proteins.     

Tissue factor in human coronary atherosclerotic plaques

The rupture or fissuring of a coronary atherosclerotic plaque and subsequent thrombosis is considered the key event in the pathogenesis of unstable angina and myocardial infarction. Although plaque disruption frequently occurs during the evolution of atherosclerosis, only a minority of ruptured plaques develop thrombosis. The content and procoagulant activity of tissue factor in human coronary atherosclerotic plaques varies widely, and different studies confirm that it is higher in the plaques extracted from patients with unstable angina, myocardial infarction or histologic/angiographic evidence of coronary thrombosis than in those taken from patients with stable angina or uncomplicated coronary lesions. Variations in tissue factor content and activity may be responsible for the different thrombotic responses to human coronary atherosclerotic plaque rupture.