UMLS:C0017636 - FACTA Search

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Query: UMLS:C0017636 (glioblastoma)
18,345 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The Mxi1 protein functions in a regulatory network with members of the c-Myc family, in which c-Myc activates transcription and stimulates cell proliferation, and Mxi1 negatively regulates these actions. Inactivation of the MXI1 gene could, therefore, inhibit differentiation and enhance proliferation in the presence of normal levels of c-Myc, and thus MXI1 is a potential tumor suppressor gene. We and others have previously mapped the MXI1 gene to the distal portion of chromosome 10q, a region that is rearranged or affected by allelic loss in many astrocytic brain tumors. Using a newly described polymorphic CA microsatellite repeat in the third MXI1 intron, we show that 7 of 11 informative glioblastomas demonstrated MXI1 allelic loss. Sequence analysis revealed no somatic mutations in any of the six MXI1 coding exons, similar to findings in prostate tumors with MXI1 allelic loss. To determine whether MXI1 can indeed function as a suppressor of growth, we have introduced a steroid-inducible MXI1 expression vector into the U87MG cell line, a glioblastoma cell line lacking endogenous MXI1 expression. Induction of MXI1 expression resulted in a decreased growth rate and distinct morphological changes. Furthermore, cell cycle analysis demonstrated that induction of MXI1 results in accumulation of cells in the G2-M phase. Thus, these studies support the notion that MXI1 normally functions to suppress cell growth and suggest that loss of MXI1 function may play a role in human glioblastoma development.
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PMID:MXI1, a putative tumor suppressor gene, suppresses growth of human glioblastoma cells. 935 56

We present our experience with a combination chemotherapy regimen consisting of ranimustine (MCNU) and recombinant human mutant tumor necrosis factor-alpha (TNF-SAM2) for malignant astrocytomas. We also investigated the expression of nuclear factor-kappa B (NF-kappa B), tumor necrosis factor receptor type 1 (TNFR1), and c-Myc in human astrocytoma tissues in vivo in patients treated with TNF-SAM2 by RT-PCR and immunohistochemical analysis to examine whether there is any correlation between the prognosis of these patients after TNF-SAM2 treatment and the expression of these factors. The initial regimens were prescribed as adjuvant therapy in conjunction with radiotherapy following standard surgical treatment. Newly diagnosed patients were treated with up to four cycles of this regimen (TNF-SAM2, MCNU, and radiotherapy: TMR group). Four patients with anaplastic astrocytomas and 13 patients with glioblastomas (11 men and 6 women) aged 24 to 68 years (median 55.7 years) were eligible and evaluated for response and toxicity. The estimated median survival time was 354 weeks with anaplastic astrocytomas, and 79 +/- 10.8 weeks with glioblastomas. One- and 2-year survival rates were 100% and 100% with anaplastic astrocytomas, and 69.2% and 30.8% with glioblastomas. Grade 3 and 4 hematological toxicities were not experienced. None of the patients experienced a treatment delay due to toxicity. All other acute toxicities were anticipated and manageable. Two of the 4 patients with anaplastic astrocytomas were positive for the expression of NF-kappa B, TNFRl and c-Myc. The expression of NF-kappa B, TNFR1 and c-Myc was investigated in 10 of the 13 patients with glioblastoma, and c-Myc, TNFRl and NF-kappa B were detected in 9, 7, and 8 of these 10 patients' surgical specimens, respectively. Despite the small number of patients, these clinical results suggest that combined chemotherapy with mutant TNF-alpha (TNF-SAM2) was safe and well tolerated, and may confer a survival benefit for patients with malignant astrocytomas in comparison to our historical controls. Its effectiveness as an adjuvant therapy deserves a properly stratified randomized trial. Although there was no significant correlation between the efficacy of TNF-SAM2 treatment and the expression of NF-kappa B, our results suggest that the constitutive activation of NF-kappa B subunits in malignant astrocytomas, especially in glioblastoma, could be associated with resistance to TNF-alpha immunotherapy. These results could offer new insight to help establish a new chemotherapeutic strategy for malignant astrocytomas.
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PMID:Correlation of the expression of nuclear factor-kappa B, tumor necrosis factor receptor type 1 (TNFR 1) and c-Myc with the clinical course in the treatment of malignant astrocytomas with recombinant mutant human tumor necrosis factor-alpha (TNF-SAM2). 1076 4

Tumor necrosis factor receptor type 1 (TNFR1) and c-Myc are important in signal transduction in tumor necrosis factor-alpha (TNF-alpha)-induced cytotoxicity, whereas activation of nuclear factor-kappa B (NF-kappa B) protects against TNF-alpha-induced apoptosis. This study investigated the expression of NF-kappa B, TNFR1, and c-Myc in human astrocytoma tissues by reverse transcriptase-polymerase chain reaction (PCR) and immunohistochemical analysis. TNFR1 messenger ribonucleic acid (mRNA) and c-Myc mRNA were frequently expressed in malignant astrocytomas, especially in glioblastomas, compared with low-grade astrocytomas by PCR analysis. TNFR1 and c-Myc mRNAs were barely detectable in normal brain tissues. NF-kappa B p50 and p65 subunit mRNAs were detected in various grades of astrocytomas, with frequent expression in malignant astrocytomas. The presence of activated NF-kappa B was confirmed by nuclear localization in neoplastic astrocytes as determined by immunohistochemistry. Both p50 and p65 subunits were inhomogeneously expressed in neoplastic astrocytes of glioblastoma, but only in a few scattered tumor cells in low-grade astrocytoma, and almost undetectable in normal brain tissues. These results indicate that TNFR1 and c-Myc are overexpressed in malignant astrocytomas, and this may increase the cellular sensitivity to the cytotoxic action of TNF-alpha. NF-kappa B p50 and p65 were simultaneously induced and activated in malignant astrocytomas. Our results suggest that the constitutive activation of NF-kappa B subunits in malignant astrocytoma, especially in glioblastoma, could be associated with the resistance to TNF-alpha immunotherapy, and indicates new therapeutic strategies for malignant astrocytomas.
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PMID:Expression of nuclear factor-kappa B, tumor necrosis factor receptor type 1, and c-Myc in human astrocytomas. 1138 77

Aberrations of genes/proteins regulating cell cycle and growth, increased proliferation and telomerase activity (TA) are documentable in glioblastoma multiforme. TA is more frequently detectable in secondary glioblastoma, which is also characterized by p53 mutation/overexpression. Discordant telomere (Te) length values have been reported in glioblastomas with and without TA. In 31 glioblastomas, in which pre-existing astrocytoma was not documented, we compared cases with and without TA for the expression of p53, EGFR, c-Myc, MIB-1 and Topoisomerase IIalpha; p53 mutations were also investigated by SSCP-PCR. Correlations were made with Te parameters [TePs: number (TeNo), length and area] as evaluated by image analysis in interphase nuclei of fluorescence in situ hybridization (FISH)-processed sections. We found no differences in the expression of the proteins evaluated and in TePs, except Te/nuclear area %, which was significantly lower in TA+ cases (p=0.02). TePs were, instead, inversely correlated with TA (p=0.0001). TA was positively correlated with MIB1 staining index in the TA+ cases (p=0.033), which also showed a positive correlation between TeNo and EGFR expression (p=0.042), and a trend towards a negative correlation between TeNo and p53 expression (p=0.05). Tumors overexpressing EGFR had a significantly shorter lifetime (p=0.0001). TeNo seems to be inversely correlated to tumor proliferation and lifetime in glioblastoma multiforme.
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PMID:In situ detection of telomeres by fluorescence in situ hybridization and telomerase activity in glioblastoma multiforme: correlation with p53 status, EGFR, c-myc, MIB1, and Topoisomerase IIalpha protein expression. 1461 23

The c-Myc transcription factor regulates expression of genes related to cell growth, division, and apoptosis. Mxi1, a member of the Mad family, represses transcription of c-Myc-regulated genes by mediating chromatin condensation via histone deacetylase and the Sin3 corepressor. Mxi1 is a c-Myc antagonist and suppresses cell proliferation in vitro. Here, we describe the identification of Mxi1-0, a novel Mxi1 isoform that is alternatively transcribed from an upstream exon. Mxi1-0 and Mxi1 have different amino-terminal sequences, but share identical Max- and DNA-binding domains. Both isoforms are able to bind Max, to recognize E-box binding sites, and to interact with Sin3. Despite these similarities and in contrast to Mxi1, Mxi1-0 is predominantly localized to the cytoplasm and fails to repress c-Myc-dependent transcription. Although Mxi1-0 and Mxi1 are coexpressed in both human and mouse cells, the relative levels of Mxi1-0 are higher in primary glioblastoma tumors than in normal brain tissue. This variation in the levels of Mxi1-0 and Mxi1 suggests that Mxi1-0 may modulate the Myc-inhibitory activity of Mxi1. The identification of Mxi1-0 as an alternatively transcribed Mxi1 isoform has significant implications for the interpretation of previous Mxi1 studies, particularly those related to the phenotype of the mxi1 knockout mouse.
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PMID:Mxi1-0, an alternatively transcribed Mxi1 isoform, is overexpressed in glioblastomas. 1554 75

Myc is a ubiquitous mediator of cell proliferation that transactivates the expression of various genes through E-box sites. Here we report a novel gene, mimitin (Myc-induced mitochondrial protein), that encodes a mitochondrial protein with a molecular mass of 20 kDa. We demonstrated that the transcription of mimitin is directly stimulated by c-Myc. To investigate the role of Mimitin, its expression was suppressed by the RNA interference (RNAi) technique. Whereas specific inhibition of mimitin expression did not affect cell proliferation in human cervical carcinoma, colon adenocarcinoma, and hepatocarcinoma cell lines, it did suppress cell proliferation in human glioblastoma, esophageal squamous cell carcinoma (ESCC), and embryonic lung fibroblastic cells, with the greatest suppression efficiency in ESCC cells. To investigate whether mimitin is related to tumorigenesis in ESCC in vivo, the expression of Mimitin protein in ESCC tissues was studied. Mimitin was highly expressed in 80% (28 of 35) of ESCC tumors, suggesting that high expression of Mimitin is a characteristic feature of ESCC. The expression level of Mimitin was found to be correlated with that of c-Myc and cell proliferation, but not with the histopathological grade, stage of cancer, or age of patients. Taken together, these results suggest that the novel gene mimitin is a direct transcriptional target of c-Myc, and is involved in Myc-dependent cell proliferation at least in ESCC cells.
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PMID:A novel Myc-target gene, mimitin, that is involved in cell proliferation of esophageal squamous cell carcinoma. 1577 66

The product of the MYC oncogene is widely deregulated in cancer and functions as a regulator of gene transcription. Despite an extensive profile of regulated genes, the transcriptional targets of c-Myc essential for transformation remain unclear. In this study, we show that c-Myc significantly induces the expression of the H19 noncoding RNA in diverse cell types, including breast epithelial, glioblastoma, and fibroblast cells. c-Myc binds to evolutionarily conserved E-boxes near the imprinting control region to facilitate histone acetylation and transcriptional initiation of the H19 promoter. In addition, c-Myc down-regulates the expression of insulin-like growth factor 2 (IGF2), the reciprocally imprinted gene at the H19/IGF2 locus. We show that c-Myc regulates these two genes independently and does not affect H19 imprinting. Indeed, allele-specific chromatin immunoprecipitation and expression analyses indicate that c-Myc binds and drives the expression of only the maternal H19 allele. The role of H19 in transformation is addressed using a knockdown approach and shows that down-regulation of H19 significantly decreases breast and lung cancer cell clonogenicity and anchorage-independent growth. In addition, c-Myc and H19 expression shows strong association in primary breast and lung carcinomas. This work indicates that c-Myc induction of the H19 gene product holds an important role in transformation.
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PMID:The c-Myc oncogene directly induces the H19 noncoding RNA by allele-specific binding to potentiate tumorigenesis. 1670 59

Glioblastoma (GBM) is a highly lethal primary brain cancer with hallmark features of diffuse invasion, intense apoptosis resistance and florid necrosis, robust angiogenesis, and an immature profile with developmental plasticity. In the course of assessing the developmental consequences of central nervous system (CNS)-specific deletion of p53 and Pten, we observed a penetrant acute-onset malignant glioma phenotype with striking clinical, pathological, and molecular resemblance to primary GBM in humans. This primary, as opposed to secondary, GBM presentation in the mouse prompted genetic analysis of human primary GBM samples that revealed combined p53 and Pten mutations as the most common tumor suppressor defects in primary GBM. On the mechanistic level, the "multiforme" histopathological presentation and immature differentiation marker profile of the murine tumors motivated transcriptomic promoter-binding element and functional studies of neural stem cells (NSCs), which revealed that dual, but not singular, inactivation of p53 and Pten promotes cellular c-Myc activation. This increased c-Myc activity is associated not only with impaired differentiation, enhanced self-renewal capacity of NSCs, and tumor-initiating cells (TICs), but also with maintenance of TIC tumorigenic potential. Together, these murine studies have provided a highly faithful model of primary GBM, revealed a common tumor suppressor mutational pattern in human disease, and established c-Myc as a key component of p53 and Pten cooperative actions in the regulation of normal and malignant stem/progenitor cell differentiation, self-renewal, and tumorigenic potential.
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PMID:Pten and p53 converge on c-Myc to control differentiation, self-renewal, and transformation of normal and neoplastic stem cells in glioblastoma. 1915 Sep 64

NF-kappaB activity is tightly regulated by IkappaB class of proteins. IkappaB proteins possess ankyrin repeats for binding to and inhibiting NF-kappaB. The regulatory protein, NPR1 from Brassica juncea possesses ankyrin repeats with sequence similarity to IkappaBalpha subgroup. Therefore, we examined whether stably expressed BjNPR1 could function as IkappaB in inhibiting NF-kappaB in human glioblastoma cell lines. We observed that BjNPR1 bound to NF-kappaB and inhibited its nuclear translocation. Further, BjNPR1 expression down-regulated the NF-kappaB target genes iNOS, Cox-2, c-Myc and cyclin D1 and reduced the proliferation rate of U373 cells. Finally, BjNPR1 decreased the levels of pERK, pJNK and PKCalpha and increased the Caspase-3 and Caspase-8 activities. These results suggested that inhibition of NF-kappaB activation by BjNPR1 can be a promising therapy in NF-kappaB dependent pathologies.
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PMID:Mustard NPR1, a mammalian IkappaB homologue inhibits NF-kappaB activation in human GBM cell lines. 1976 95

Oncogenes influence nutrient metabolism and nutrient dependence. The oncogene c-Myc stimulates glutamine metabolism and renders cells dependent on glutamine to sustain viability ("glutamine addiction"), suggesting that treatments targeting glutamine metabolism might selectively kill c-Myc-transformed tumor cells. However, many current or proposed cancer therapies interfere with the metabolism of glucose, not glutamine. Here, we studied how c-Myc-transformed cells maintained viability when glucose metabolism was impaired. In SF188 glioblastoma cells, glucose deprivation did not affect net glutamine utilization but elicited a switch in the pathways used to deliver glutamine carbon to the tricarboxylic acid cycle, with a large increase in the activity of glutamate dehydrogenase (GDH). The effect on GDH resulted from the loss of glycolysis because it could be mimicked with the glycolytic inhibitor 2-deoxyglucose and reversed with a pyruvate analogue. Furthermore, inhibition of Akt signaling, which facilitates glycolysis, increased GDH activity whereas overexpression of Akt suppressed it, suggesting that Akt indirectly regulates GDH through its effects on glucose metabolism. Suppression of GDH activity with RNA interference or an inhibitor showed that the enzyme is dispensable in cells able to metabolize glucose but is required for cells to survive impairments of glycolysis brought about by glucose deprivation, 2-deoxyglucose, or Akt inhibition. Thus, inhibition of GDH converted these glutamine-addicted cells to glucose-addicted cells. The findings emphasize the integration of glucose metabolism, glutamine metabolism, and oncogenic signaling in glioblastoma cells and suggest that exploiting compensatory pathways of glutamine metabolism can improve the efficacy of cancer treatments that impair glucose utilization.
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PMID:Glioblastoma cells require glutamate dehydrogenase to survive impairments of glucose metabolism or Akt signaling. 1982 36

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