Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0017636 (glioblastoma)
 18,345 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Cultured SK-OS-10 cells (human osteogenic sarcoma metastatic to lung) shed microvesicles (dia. 300-1000 nm) that contained procoagulant and proaggregatory activities inhibitable by hirudin, by anti-tissue factor antibody and by phospholipase A2. These results show that SK-OS-10 cells belong to a group including U87MG human glioblastoma and HL-60 promyelocytic leukemia in which these activities are due to a thrombin-dependent mechanism arising from the presence of tissue factor on the surface of the tumor cells and their shed microvesicles.
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PMID:Tissue factor-dependent activation of platelets by cells and microvesicles of SK-OS-10 human osteogenic sarcoma cell line. 303 40

Microvesicles (diameter ca 200 nm) from the cell-free supernatant of U87MG human glioblastoma cell caused platelet aggregation and coagulation in a manner identical with that previously shown for the intact cells. Both activities were inhibited by dansylarginine -N-(3-ethyl-1,5-pentanediyl) amide (DAPA), confirming the thrombin-dependent nature of both activities. The specific activities per microgram of protein were 2-10 times greater in the microvesicles than in the plasma membrane fraction, suggesting localization in specific membrane domains. Sucrose density centrifugation gave a single protein peak (density 1.14) with congruent procoagulant and platelet aggregating activities. Both activities required the extrinsic pathway, as shown by studies with factor-deficient plasmas, and both were inhibited by heating (60 min/100 degrees C), by reduction and alkylation, and by incubation of the microvesicles with rabbit anti-bovine brain tissue factor antibody. These observations were confirmed using microvesicles from the HL-60 human promyelocytic leukemia cells, which are known to contain tissue factor activity. The results suggest that both procoagulant and proaggregating activities are causally related through the presence of tissue factor in the microvesicles. Studies with the Baumgartner perfusion apparatus showed that U87MG microvesicles increased the size of adherent thrombi nearly tenfold and that these thrombi were associated with nucleated cells from the blood. The increase in adherent thrombi did not occur if perfusion was carried out in the presence of DAPA, confirming the role of thrombin in their formation.
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PMID:Tissue factor in microvesicles shed from U87MG human glioblastoma cells induces coagulation, platelet aggregation, and thrombogenesis. 673 71

U87MG cells (human glioblastoma) express tissue factor and shed membrane-derived vesicles enriched in procoagulant activity. Tissue factor antigen has been studied by flow cytometry, immunofluorescent microscopy and Western blotting. Flow cytometric analysis utilized monoclonal antibodies recognizing the tissue factor extracellular domain and the carboxyl-terminal nine amino acids. Studies with intact and permeabilized cells support the location of the carboxyl-terminal domain in the cytoplasm, as previously predicted from the protein sequence. Immunofluorescent microscopy revealed a heterogeneous staining pattern, indicating that tissue factor antigen may be clustered on the cell surface. Intense staining was occasionally observed in cytoplasmic extensions and membrane regions that appeared to be extruding from the cells. Western blot analysis of vesicles shed into the culture medium revealed a principal tissue factor band with mobility marginally slower than that of placental tissue factor. Both extracellular and cytoplasmic epitopes were present in this vesicular tissue factor.
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PMID:Immunofluorescent studies of tissue factor on U87MG cells: evidence for non-uniform distribution. 814 84

Tissue factor is heterogeneously distributed within and among cells in cultures of U87-MG, a glioblastoma-derived line. The heterogeneity among cells may reflect the presence of distinct populations within the U87-MG cultures. This hypothesis has been confirmed by cloning of five distinct sublines from the parent population. These subpopulations have remained distinct through 4 months of growth in culture and one cycle of cryogenic preservation and thawing. The cultures differ in growth rates, amounts of tissue factor activity expressed, tissue factor antigen measured by flow cytometry, and patterns of tissue factor distribution studied by immunofluorescence microscopy. Characterization of these sublines allowed us to recognize that the tissue factor distribution on polarized cells (e.g. spindle-shaped) differed from that on cells with less polar morphologies. Finely speckled tissue factor staining tended to be localized to polarized aspects of the cell body where actin stress fibers are commonly present, whereas larger distinct foci of tissue factor were present in regions of membrane spreading. These results show that tissue factor is distributed differently in distinct regions of plasma membrane differentiation. Furthermore, the isolation of distinct stable subpopulations by dilutional cloning of U87-MG cultures serves as a reminder that cell culture heterogeneity can complicate experiments using molecular genetic manipulation of cultured cells which require clonal isolation of genetically altered lines.
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PMID:Tissue factor and cell morphology variations in cell lines subcloned from U87-MG. 981 5

Vascular endothelial growth factor (VEGF) is a potent angiogenic factor in human gliomas. VEGF-induced proteins in endothelial cells, tissue factor (TF), osteopontin (OPN) and alphavbeta3 integrin have been implicated as important molecules by which VEGF promotes angiogenesis in vivo. Sixty-eight gliomas were immunohistochemically stained with TF, VEGF, OPN and alphavbeta3 integrin antibody. Twenty-three tumours, six normal brains and nine glioma cell lines were evaluated for their mRNA expression of VEGF and TF by reverse transcription polymerase chain reaction analysis. The data indicated that TF as well as VEGF was a strong regulator of human glioma angiogenesis. First, TF expression in endothelial cells which was observed in 74% of glioblastomas, 54% of anaplastic astrocytomas and none of low-grade astrocytomas, correlated with the microvascular density of the tumours. Double staining for VEGF and TF demonstrated co-localization of these two proteins in the glioblastoma tissues. Second, there was a correlation between TF and VEGF mRNA expression in the glioma tissues. Third, glioma cell conditioned medium containing a large amount of VEGF up-regulated the TF mRNA expression in human umbilical vein endothelial cells. OPN and alphavbeta3 integrin, were also predominantly observed in the microvasculature of glioblastomas associated with VEGF expression. Microvascular expression of these molecules could be an effective antiangiogenesis target for human gliomas.
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PMID:Tissue factor, osteopontin, alphavbeta3 integrin expression in microvasculature of gliomas associated with vascular endothelial growth factor expression. 1086 5

Glioblastoma (GBM) has explosive biologic properties with rapid clinical progression leading to death. Its distinguishing pathologic features, necrosis with surrounding pseudopalisades and microvascular hyperplasia, are believed to be instrumental to its accelerated growth. Microvascular hyperplasia arises in response to the secretion of proangiogenic factors by hypoxic pseudopalisades and allows for peripheral neoplastic expansion. Mechanisms underlying necrosis and hypoxia remain obscure, but vaso-occlusive and prothrombotic contributions could be substantial. Recent investigations on the origin of pseudopalisades suggest that this morphologic phenomenon is created by a tumor cell population actively migrating away from a central hypoxic region and that, in at least a significant subset, hypoxia-induced migration appears due to vaso-occlusion caused by intravascular thrombosis. Both vascular endothelial growth factor induced vascular permeability to plasma coagulation factors and the increased neoplastic expression of tissue factor likely contribute to a prothrombotic state favoring intravascular thrombosis. In addition to prothrombotic mechanisms, vaso-occlusion could also result from angiopoietin-2-mediated endothelial cell apoptosis and vascular regression, which follows neoplastic co-option of native vessels in animal models of gliomas. Vaso-occlusive and prothrombotic mechanisms in GBM could readily explain the presence of pseudopalisades and coagulative necrosis in tissue sections, the emergence of central contrast enhancement and its rapid peripheral expansion on neuroimaging, and the dramatic shift to an accelerated rate of clinical progression. Since the hypoxic induction of angiogenesis appears to support further neoplastic growth, therapeutic targeting of the underlying vascular pathology and thrombosis could provide a new means to prolong time to progression.
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PMID:Vaso-occlusive and prothrombotic mechanisms associated with tumor hypoxia, necrosis, and accelerated growth in glioblastoma. 1499 Sep 81

We have previously proposed that intravascular thrombosis and subsequent vasoocclusion contribute to the development of pseudopalisading necrosis, a pathologic hallmark that distinguishes glioblastoma (WHO grade 4) from lower grade astrocytomas. To better understand the potential prothrombotic mechanisms underlying the formation of these structures that drive tumor angiogenesis, we investigated tissue factor (TF), a potent procoagulant protein known to be overexpressed in astrocytomas. We hypothesized that PTEN loss and tumor hypoxia, which characterize glioblastoma but not lower grade astrocytomas, could up-regulate TF expression and cause intravascular thrombotic occlusion. We examined the effect of PTEN restoration and hypoxia on TF expression and plasma coagulation using a human glioma cell line containing an inducible wt-PTEN cDNA. Cell exposure to hypoxia (1% O(2)) markedly increased TF expression, whereas restoration of wt-PTEN caused decreased cellular TF. The latter effect was at least partially dependent on PTEN's protein phosphatase activity. Hypoxic cells accelerated plasma clotting in tilt tube assays and this effect was prevented by both inhibitory antibodies to TF and plasma lacking factor VII, implicating TF-dependent mechanisms. To further examine the genetic events leading to TF up-regulation during progression of astrocytomas, we investigated its expression in a series of human astrocytes sequentially infected with E6/E7/human telomerase, Ras, and Akt. Cells transformed with Akt showed the greatest incremental increase in hypoxia-induced TF expression and secretion. Together, our results show that PTEN loss and hypoxia up-regulate TF expression and promote plasma clotting by glioma cells, suggesting that these mechanisms may underlie intravascular thrombosis and pseudopalisading necrosis in glioblastoma.
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PMID:PTEN and hypoxia regulate tissue factor expression and plasma coagulation by glioblastoma. 1573 28

Glioblastoma (GBM) is a highly malignant, rapidly progressive astrocytoma that is distinguished pathologically from lower grade tumors by necrosis and microvascular hyperplasia. Necrotic foci are typically surrounded by "pseudopalisading" cells-a configuration that is relatively unique to malignant gliomas and has long been recognized as an ominous prognostic feature. Precise mechanisms that relate morphology to biologic behavior have not been described. Recent investigations have demonstrated that pseudopalisades are severely hypoxic, overexpress hypoxia-inducible factor (HIF-1), and secrete proangiogenic factors such as VEGF and IL-8. Thus, the microvascular hyperplasia in GBM that provides a new vasculature and promotes peripheral tumor expansion is tightly linked with the emergence of pseudopalisades. Both pathologic observations and experimental evidence have indicated that the development of hypoxia and necrosis within astrocytomas could arise secondary to vaso-occlusion and intravascular thrombosis. This emerging model suggests that pseudopalisades represent a wave of tumor cells actively migrating away from central hypoxia that arises after a vascular insult. Experimental glioma models have shown that endothelial apoptosis, perhaps resulting from angiopoetin-2, initiates vascular pathology, whereas observations in human tumors have clearly demonstrated that intravascular thrombosis develops with high frequency in the transition to GBM. Tissue factor, the main cellular initiator of thrombosis, is dramatically upregulated in response to PTEN loss and hypoxia in human GBM and could promote a prothrombotic environment that precipitates these events. A prothrombotic environment also activates the family of protease activated receptors (PARs) on tumor cells, which are G-protein-coupled and enhance invasive and proangiogenic properties. Vaso-occlusive and prothrombotic mechanisms in GBM could readily explain the presence of pseudopalisading necrosis in tissue sections, the rapid peripheral expansion on neuroimaging, and the dramatic shift to an accelerated rate of clinical progression resulting from hypoxia-induced angiogenesis.
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PMID:'Pseudopalisading' necrosis in glioblastoma: a familiar morphologic feature that links vascular pathology, hypoxia, and angiogenesis. 1678 63

Tissue factor pathway inhibitor (TFPI) is a plasma Kunitz-type serine protease inhibitor that is mainly known for its inhibition of tissue factor-mediated coagulation. In addition to its anticoagulant properties, emerging data show that TFPI may also regulate endothelial cell functions via a non-haemostatic pathway. In this work we demonstrate that at concentrations within the physiological range, TFPI inhibits both endothelial cell migration and their differentiation into capillary-like structures in vitro. These effects were specific to endothelial cells since no inhibitory effect was observed on the migration of tumor (glioblastoma) cells. Inhibition of endothelial cell migration was correlated with a concomitant loss in cell adhesion, suggesting an alteration of focal adhesion complex integrity. Accordingly, we observed that TFPI inhibited the phosphorylation of focal adhesion kinase and paxillin, two key proteins involved in the scaffolding of these complexes, and that this effect was specific to endothelial cells. These results suggest that TFPI influences the angiogenic process via a non-haemostatic pathway, by downregulating the migratory mechanisms of endothelial cells.
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PMID:Tissue factor pathway inhibitor (TFPI) interferes with endothelial cell migration by inhibition of both the Erk pathway and focal adhesion proteins. 1832 7

Focal necrosis is a key pathologic feature that distinguishes glioblastoma from lower grade glioma. The presence of necrosis in a glioblastoma could promote its rapid growth and clinical progression. Focal necrosis of glioblastoma seems to be associated with thrombosis that result from hyper-coagulability. In the present study, we found that glioblastoma cells had a high level of constitutive nuclear factor (NF)-kappaB activity, which was directly correlated with necrosis in glioblastomas. We also found a direct correlation between NF-kappaB activity and the expression of tissue factor (TF), a potent procoagulant factor in gliomas. Inhibition of TF by an inhibitory antibody prevented the procoagulant activity of glioblastoma cells, indicating a TF-dependent mechanism. Blockade of NF-kappaB activation significantly inhibited TF expression and the procoagulant activity of glioblastoma cells in vitro. Blockade of NF-kappaB activation also significantly inhibited in vivo expression of TF, which was directly correlated with decreased necrosis formation and tumor growth of glioblastoma cells in nude mice. Collectively, these results suggest that elevated NF-kappaB activity in glioblastomas cells plays a critical role in necrosis formation of glioblastoma and that inhibition of NF-kappaB activity in glioblastoma can suppress necrosis formation and progressive growth.
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PMID:Aberrant NF-kappaB activity is critical in focal necrosis formation of human glioblastoma by regulation of the expression of tissue factor. 1857 45


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