Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0004153 (atherosclerosis)
 77,401 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

There is compelling experimental evidence that tissue factor pathway inhibitor (TFPI) exerts important role(s) as a natural anticoagulant. Immunodepletion of TFPI lowers the treshold by which tissue factor (TF) can induce disseminated intravascular coagulation. Conversely, infusion of recombinant TFPI protects against thrombosis and disseminated intravascular coagulation in numerous experimental models. Since TFPI mutants associated with thrombosis have not yet been identified, a definite role of TFPI in coagulation is yet to be assigned. Current research on TFPI is mainly focused on the cell biology of TFPI, on the contribution of TFPI to the anticoagulant action of heparins, and on the role of lipoprotein-associated TFPI. TFPI is produced constitutively in endothelial cells, and is to a great extent bound to its surface. The binding molecule(s) have not yet been characterized, but TFPI is rapidly released by heparin and other negatively charged ions. In other cell lines degradation of TFPI is mediated by the low density lipoprotein receptor-related protein, which may be important for its clearance. In plasma, TFPI contributes strongly to the postheparin anticoagulant effect seen in dilute prothrombin time assays. The effect is probably mediated by redistribution of TFPI. Moreover, in the presence of heparin, antithrombin and TFPI cooperate to inhibit activation of coagulation. Antithrombin abrogates activation of factor VII bound to TF, whereas TFPI inhibits factor VIIa/TF complexes formed. The role of lipoprotein associated TFPI is still essentially unknown, but may play an important role in atherosclerosis.
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PMID:Tissue factor pathway inhibitor (TFPI)--an update. 897 19

Whereas unperturbed endothelial cells provide potent anticoagulant properties, exposure to inflammatory and atherogenic stimuli can rapidly lead to a procoagulant behavior. Because recent studies provide evidence that apoptosis of vascular cells may occur under conditions such as atherosclerosis and inflammation, we investigated whether apoptotic endothelial cells may contribute to the development of a prothrombotic state. In this report, it is shown that both adherent and detached apoptotic human umbilical vein endothelial cells (HUVECs) become procoagulant. Apoptosis was induced by staurosporine, a nonspecific protein kinase inhibitor, or by culture in suspension with serum deprivation. Both methods resulted in similar findings. As assessed by flow cytometric determination of annexin V binding, HUVECs undergoing cell death exhibited typically a more rapid exposure of membrane phosphatidylserine (PS) than DNA fragmentation. Depending on the stage of apoptosis, this redistribution of phospholipids was found to induce an increase of the activity of the intrinsic tenase complex by 25% to 60%. Although apoptotic cells did not show antigenic or functional tissue factor (TF) activity, when preactivated with lipopolysaccharide, TF procoagulant activity increased by 50% to 70%. At 8 hours after apoptosis induction, antigenic thrombomodulin, heparan sulfates, and TF pathway inhibitor decreased by about 83%, 80%, and 59%, respectively. The functional activity of these components was reduced by about 36%, 52%, and 39%, respectively. Moreover, the presence of apoptotic HUVECs led to a significant increase of thrombin formation in recalcified citrated plasma. In conclusion, apoptotic HUVECs, either adherent or in suspension, become procoagulant by increased expression of PS and the loss of anticoagulant membrane components.
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PMID:Apoptotic vascular endothelial cells become procoagulant. 911 87

Folic acid deficiency represents a vitamin deficiency that may be due either to an inadequacy of the dietary supply or to an increased requirement. It leads to a number of abnormalities including hematological, neurological and cardiovascular disorders. In this study, we investigated whether folic acid deficiency would influence platelet and macrophage activities. For 6 weeks, rats were fed a test diet containing a low amount of folic acid (250 mu g/kg) by comparison with a control diet (750 mu g/kg). We found 40 and 32 percent reductions (P < 0.05) of plasma and erythrocyte folates, respectively in the tested group. Peritoneal macrophages of the folic acid deficient animals exhibited greater (20 x) tissue factor (TF) activity than in the controls. We also found that folate depletion significantly enhanced the thrombin- and ADP-induced platelet aggregation (+64 and + 13 percent, respectively). Moreover, the results of incubations with radiolabeled arachidonic acid indicated that platelets of folic acid deficient animals incorporated more labeling than controls did. When stimulated with thrombin, the mobilization of arachidonate from platelet phospholipids and its subsequent formation of cyclooxygenase and lipoxygenase metabolites were enhanced in the deficient animals. In particular, thromboxane biosynthesis was markedly increased. The analysis of the plasma fatty acid composition showed a decrease in the plasma unsaturation index related to a marked fall of long chain (n-3) fatty acids which was also observed in platelets. These data suggested the occurrence of an oxidative stress in folic acid deficient animals which was confirmed by increases in plasma lipid peroxidation products (more than +20 percent) and an enhanced susceptibility of erythrocytes to free radicals (+23 percent). Altogether these data suggested that folic acid deficiency altered the circulating and cellular fatty acid composition and thus influenced the balance of the platelet eicosanoid synthesis. In addition, total homocysteine and glutathione concentrations were highly increased in plasma from folate-depleted rats. From these results, we conclude that folate deficiency can potentiate the coagulation pathway mediated by the macrophage TF as well as the platelet activation process. It is suggested that these dysfunctions might be related to the loss of (n-3) polyunsaturated fatty acids. The latter could result from an increased lipid peroxidation triggered by the folic acid deficiency-induced hyperhomocysteinemia.
Atherosclerosis 1996 Apr 05
PMID:Pro-thrombotic effects of a folic acid deficient diet in rat platelets and macrophages related to elevated homocysteine and decreased n-3 polyunsaturated fatty acids. 912 97

VEGF has been proposed to participate in normal and pathological vessel formation. Surprisingly, lack of only a single VEGF allele resulted in embryonic lethality due to abnormal formation of intra- and extra-embryonic vessels. Homozygous VEGF-deficient embryos, generated by tetraploid aggregation, revealed an even more severe defect in vessel formation. These results (1) suggest a tight regulation of early vessel development by VEGF and, indirectly, the presence of other VEGF-like molecules; (2) reveal an unprecedented lethal phenotype associated with heterozygous deficiency of an autosomal gene, and (3) demonstrate that tetraploid aggregation was a valid and the only method to study the phenotype of the homozyogous VEGF-deficient embryos. The dominant and strict dose-dependent role of VEGF in vivo renders this molecule a desirable therapeutic target for promoting or preventing angiogenesis. Tissue factor (TF) is the principal cellular initiator of coagulation and its deregulated expression has been related to thrombogenesis in sepsis, cancer, and inflammation. However, TF appears to be also involved in a variety of non-hemostatic functions including inflammation, cancer, brain function, immune response, and tumor-associated angiogenesis. Surprisingly, TF deficiency resulted in embryonic lethality due to abnormal extra-embryonic vessel development and defective vitelloembryonic circulation. The abnormal yolk sac vasculature is reminiscent of that observed in embryos lacking VEGF, possibly suggesting that both gene functions are interconnected. These targeting studies extend the recently documented role of TF in tumor-associated angiogenesis and warrant further study of its role in angiogenesis during other pathological disorders. The plasminogen system, via its triggers, tissue-type plasminogen activator (t-PA) and urokinase-type plasminogen activator (u-PA) and its inhibitor, plasminogen activator inhibitor-1 (PAI-1), has been implicated in thrombosis, arterial neointima formation, and atherosclerosis. Studies in mice with targeted gene inactivation of t-PA, u-PA, PAI-1, the urokinase receptor (u-PAR), and plasminogen (Plg) revealed (1) that deficiency of t-PA or u-PA increase the susceptibility to thrombosis associated with inflammation and that combined deficiency of t-PA:u-PA or deficiency of Plg induces severe spontaneous thrombosis; (2) that vascular injury-induced neointima formation is reduced in mice lacking u-PA-mediated plasmin proteolysis, unaltered in t-PA- or u-PAR-deficient mice and accelerated in PAI-1-deficient mice, but that it can be reverted by adenoviral PAI-1 gene transfer; and (3) that atherosclerosis in mice doubly deficient in apolipoprotein E (apoE) and PAI-1 is reduced after 10 weeks of cholesterol-rich diet. Thus, the plasminogen system significantly affects thrombosis, restenosis, and atherosclerosis.
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PMID:Insights in vessel development and vascular disorders using targeted inactivation and transfer of vascular endothelial growth factor, the tissue factor receptor, and the plasminogen system. 918 98

We describe recent information on the atherothrombotic processes leading to the acute coronary syndromes (ACS) in humans. Then, we outline the mechanism of action and impact of lipid-lowering therapy in stabilization and secondary prevention of such processes. We start with (1) definitions of atherosclerotic lesions. In the progression of coronary atherosclerosis, eight morphologically different lesions are defined (Type I to VI) in various phases of disease. (2) Then we discuss vulnerable lipid-rich plaques and ACS. The type IV and Va lesions tend to be relatively small in size, but soft or vulnerable to disruption (with subsequent thrombosis) because of high lipid content (cholesterol esters rather than free cholesterol monohydrate crystals). The above process represents a "passive" phenomenon of plaque disruption. In addition to this "passive" phenomenon, an "active," macrophage-dependent, phenomenon of plaque disruption is evolving. (3) We then show the role of thrombosis in ACS. Monocytes/macrophages in lipid-rich plaques may play a detrimental role after plaque disruption, promoting thrombin generation and thrombosis through the tissue factor pathway, which can be prevented by tissue factor pathway inhibitor. Such thrombotic phenomena are critical in the development of ACS. (4) Finally, we discuss the effect of lipid-modifying strategies on the vulnerable lipid-rich plaques. When high LDL-cholesterol is reduced therapeutically, efflux from the plaques of the liquid or sterified cholesterol, and also its hydrolysis into cholesterol crystals depositing in the vessel wall, predominate over the influx of LDL-cholesterol. Consequently, there is a decrease in the softness of the plaque and so, presumably in the "passive" phenomenon of plaque disruption. When low HDL-cholesterol is increased experimentally, there is a partial decrease in the number and activity of the macrophages and so, presumably in the "active" phenomenon of plaque disruption.
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PMID:Human lesion studies. 918 99

Blood platelets are capable of interacting with monocytes and macrophages and of enhancing various functions of these cells, which are believed to play a role in thrombosis and inflammation. An increase in the uptake of oxidised low density lipoprotein (LDL), in the synthesis of procoagulant tissue factor, thrombospondin and leukotrienes, as well as stimulation of oxygen radical production by platelets has been described (1-5). In circulating blood, a substantial proportion of monocytes was found to be associated with platelets, but the pathophysiological significance of such platelet-monocyte conjugates is not yet clear (6,7). Immigration of monocytes into the arterial intima and their differentiation into macrophages are initial steps in the development of an atherosclerotic lesion (8). During differentiation, there is a tremendous increase in the activity and secretion of the enzyme PAF acetylhydrolase (PAF = platelet-activating factor = 1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine) (9,10), and there is some evidence that this enzyme may contribute to the development of atherosclerosis. It cleaves PAF, and the remaining lyso-PAF is chemotactic for monocytes (11). Furthermore it also acts on oxidised low density lipoproteins and enhances their uptake into macrophages (12,13). We were therefore interested in investigating whether platelets may modulate the differentiation of monocytes into macrophages and the activity of PAF acetylhydrolase.
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PMID:Platelets inhibit the activity of platelet-activating factor acetylhydrolase in monocyte-derived macrophages. 921 35

Human atherosclerotic plaques are heterogeneous tissues containing a number of different cell types, including macrophages, smooth muscle, endothelial and other undefined mesenchymal-appearing cells. Significant numbers of macrophages are found in human atherosclerotic plaques and have been postulated to be a major source of growth factor production during atherogenesis. In vitro evidence suggested that macrophages synthesize PDGF and might therefore contribute to the growth of the vessel wall in atherosclerosis. However, examination of PDGF synthesis in human atheroma by in situ hybridization revealed that while smooth muscle, mesenchymal, and endothelial cells synthesize this growth factor macrophages did not. Our inability to detect PDGF mRNA in macrophages was not due to any problems with hybridization to this cell type. In situ hybridization studies on human atherosclerotic plaques have demonstrated that plaque macrophages contain many different mRNAs other than PDGF including tissue factor, factor XIII, apoprotein E, transforming growth factor beta, and tumor necrosis factor. Recent studies have indicated that macrophages may be a major source as well of another group of inflammatory cytokines which are members of the RANTES/SIS cytokine family. In situ hybridization studies on human carotid endarterectomy specimens using probes specific for the inflammatory cytokines RANTES, LD78, HIMAP, and MCP-1 revealed numerous cells containing the mRNAs encoding for these proteins (5%, 13%, 8%, and 16% of plaque cells respectively). This is in contrast to generally low level expression found in normal human arteries (< 1% of normal medial cells contain these mRNAs). Cells expressing these cytokines were often found associated with inflammatory zones in human atherosclerotic plaques. Serial section immunohistochemistry suggests that macrophages and/or T cells may synthesize these proteins. In addition to localization to macrophages MCP-1 expression was also detected in smooth muscle cells and mesenchymal-appearing cells with many of the morphological characteristics of cells previously seen to express PDGF. In vitro evidence suggests that these proteins may be chemotactic to monocytes and lymphocytes. The finding of increased expression of these mRNAs in human atheroma suggests they may play a role in monocyte trafficking into the atherosclerotic plaque.
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PMID:Local expression of inflammatory cytokines in human atherosclerotic plaques. 922 84

Tissue factor (TF) is a transmembrane protein that serves as the major initiator of the blood coagulation cascade. The overexpression of TF antigen and mRNA has previously been reported in advanced atherosclerotic lesions. Recently TF procoagulant activity has also been identified in these lesions. However, localization and activity of TF in various stages of atherosclerosis have not yet been reported. We studied TF localization and its activity in three stages of the human atherosclerotic lesions (diffuse intimal thickening, fatty streak, and atheromatous plaque). The thoracic aortas were obtained from 23 autopsy cases and were examined immunohistochemically using an anti-human TF polyclonal antibody and biotinylated factor VIIa (FVIIa) as a probe to test the FVIIa-binding ability of TF. In addition, the TF-mediated activation of factor X (FX) was quantitatively assessed using a chromogenic assay. In lesions of the diffuse intimal thickening and the fatty streak, almost all of intimal smooth muscle cells (SMCs), macrophages, and endothelial cells were positive for TF. In the atheromatous plaques, TF antigen was detected extensively in the extracellular matrix as well as in the intimal cells. TF in all stages of atherosclerotic lesions had the ability to bind biotinylated FVIIa. TF activity was detected in each lesion and was more prominent in fatty streaks and atheromatous plaques than in the diffuse intimal thickening. These results indicate that active TF is expressed in the early stage of atherosclerotic lesions as well as in the advanced stage, and it contributes to the thrombotic property of human atherosclerotic lesions.
Atherosclerosis 1997 Sep
PMID:Localization and activity of tissue factor in human aortic atherosclerotic lesions. 929 81

The initial step in atherosclerosis is the rapid targeting of monocytes to the sites of inflammation and endothelial injury. Serum levels of intercellular adhesion molecule-1 were found to be increased in ischaemic heart disease patients and polymorphisms in the E-selectin gene were associated with accelerated atherosclerosis in young (age < 40 years) patients, further suggesting a role of inflammation in atherosclerosis. Cholesterol loading in macrophages was found to induce interleukin-8 expression, suggesting an association between foam cell formation and beta 2-integrin-dependent adhesion of leukocytes. Enhanced endothelium-platelet interaction induced by hypercholesterolaemia is mediated by von Willebrand factor, whereas platelet adhesion to subendothelial matrix is mediated by fibulin-fibrinogen complexes. Activated platelets mediate the homing of leukocytes by interaction with the subendothelial matrix under shear stresses that do not allow neutrophil adhesion. They may also contribute to the oxidative modification of LDL, provide a source of lipids for foam cell generation and contribute to smooth muscle cell proliferation. Oxidized LDL induces tissue factor in macrophages that also provide sites for fibrin polymerization and decreases the anticoagulant activity of endothelium by interfering with thrombomodulin expression and inactivating tissue factor pathway inhibitor. Intravascular fibrinolysis induced by tissue-type plasminogen activator or urokinase may contribute to the initiation of atherosclerosis by inducing P-selectin and platelet activating factor as well as to plaque rupture, either directly or indirectly, by activating metalloproteinases. Plasminogen activator inhibitor-1 inhibits smooth muscle cell migration and, in the presence of vitronectin, promotes the clearance of thrombin by LDL receptor-related protein at sites of endothelial injury.
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PMID:Thrombosis and atherosclerosis. 933 57

Tissue factor pathway inhibitor (TFPI) is a potent inhibitor of tissue factor (TF) -initiated coagulation and may play a role in regulating coagulation in atherosclerotic plaques. The expression of TFPI protein and mRNA was examined by immunohistology and in situ hybridization in normal human and rabbit arteries, in human carotid arteries with advanced atherosclerosis, and in atherosclerotic aortas from cholesterol-fed rabbits. In normal human and rabbit arteries, TFPI protein and mRNA were detected in the adventitial layer but were undetectable in the luminal endothelium. In the medial smooth muscle layer of rabbits, weak expression of TFPI mRNA, but not protein, was detected; in that of humans, neither TFPI mRNA nor protein was detectable. In atherosclerotic arteries, TFPI protein and mRNA were detected in three of six internal carotid plaques from patients undergoing endarterectomy, and mRNA alone was detected in one further specimen. TFPI protein was found in areas of the plaque where TF was abundant and colocalized with macrophages, suggesting that these cells are responsible for TFPI synthesis. TFPI protein and mRNA were also detected in fatty-streak lesions in 18 of 19 rabbits fed a high-cholesterol diet for periods between 4 and 16 weeks. In these macrophage-rich lesions, expression of TFPI protein and mRNA was most intense at the base of the plaques. These studies suggest that TFPI is expressed in the adventitial layer of large arteries and that in atherosclerotic vessels, TFPI is expressed by macrophages in focal areas throughout the plaque. Local production of TFPI may regulate procoagulant activity and thrombotic events within atherosclerotic plaques.
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PMID:Tissue factor pathway inhibitor expression in atherosclerosis. 935 63


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