Project description:Targeting Innate Immune Signaling in Glioma-Initiating Cells Impairs Self-Renewal and Radiation-Induced Cellular Plasticity

Project description:Glioma initiating cells (GICs) are considered responsible for the therapeutic resistance and recurrence of malignant glioma. To clarify the molecular mechanism of GIC maintenance/differentiation, we established GIC clones from GBM patient tumors having the potential to differentiate into malignant gliomas in mouse intracranial xenograft, and established an in vitro glioma induction system by using serum stimulation. Upon the serum stimulation, the GIC spheres showed increased cellular proliferation, motility, filopodia/lameripodia formation and adhesion to the culture dishes. Simultaneously, the NSC marker proteins such as CD133 and Sox2 were down-regulated, and the astrocyte/glioma marker GFAP and the malignancy marker CD44 dramatically up-regulated. To identify genes/proteins whose expression changes dynamically during the differentiation of GICs into glioma cells, these GICs were subjected to DNA microarray/iTRAQ based integrated proteomics.

Project description:Glioma initiating cells (GICs) are considered responsible for the therapeutic resistance and recurrence of malignant glioma. To clarify the molecular mechanism of GIC maintenance/differentiation, we established GIC clones from GBM patient tumors having the potential to differentiate into malignant gliomas in mouse intracranial xenograft, and established an in vitro glioma induction system by using serum stimulation. Upon the serum stimulation, the GIC spheres showed increased cellular proliferation, motility, filopodia/lameripodia formation and adhesion to the culture dishes. Simultaneously, the NSC marker proteins such as CD133 and Sox2 were down-regulated, and the astrocyte/glioma marker GFAP and the malignancy marker CD44 dramatically up-regulated. To identify genes/proteins whose expression changes dynamically during the differentiation of GICs into glioma cells, these GICs were subjected to DNA microarray/iTRAQ based integrated proteomics. Within 4 hours of tumor removal from GBM patients, tissues were subjected to GIC preparation. After successive cloning, total RNA from GIC clones (GIC03A and GIC03U) on day 2 or 7 of subculture in NSC medium with or without 10% FCS was subjected to the analysis with Affymetrix microarrays. Simultaneously, the proteins extracted from the same set of cells were subjected to LC-shot gun analyses using the 8-plex iTRAQ method. We sought to obtain the information of the common molecules that were up- or down-regulated during the GSC differentiation process, and functional targets for the early onset of GIC-associated glioma.

Project description:Glioblastoma is the deadliest adult brain cancer and all patients ultimately succumb to the disease. Radiation therapy (RT) provides survival benefit of 6 months over surgery alone but these results have not improved in decades. We report that radiation induces a glioma-initiating cell phenotype and identified trifluoperazine (TFP) as a compound that interferes with this phenotype conversion. TFP caused loss of radiation-induced Nanog mRNA expression, activation of GSK3 with consecutive post-translational reduction in p-Akt, Sox2 and -catenin protein levels. TFP did not alter the intrinsic radiation sensitivity of glioma-initiating cells (GICs). Continuous treatment with TFP and a single dose of radiation reduced the number of GICs in vivo and prolonged survival in syngeneic and patient-derived orthotopic xenograft (PDOX) mouse models of glioblastoma. Our findings suggest that combination of a dopamine receptor antagonist with radiation enhances the efficacy of RT in glioblastoma by preventing radiation-induced phenotype conversion of radiosensitive non-GICs into treatment resistant, induced GICs.

Project description:SUMMARY Despite numerous genome-wide association studies involving glioblastoma (GBM), few therapeutic targets have been identified for this disease. Using patient derived glioma sphere cultures (GSCs), we have found that a subset of the proneural (PN) GSCs undergo transition to a mesenchymal (MES) state in a TNFa/NFkB dependent manner with an associated enrichment of CD44 sub-populations and radio-resistant phenotypes. To the contrary, MES GSCs exhibit constitutive NFkB activation, CD44 enrichment and radio-resistance. Patients whose tumors exhibit a higher MES metagene, increased expression of CD44, or activated NFkB were associated with poor radiation response and shorter survival. Our results indicate that NFkB activation mediated MES differentiation and radiation resistance presents an attractive therapeutic target for GBM. SIGNIFICANCE In this study, we show plasticity between the proneural (PN) and mesenchymal (MES) transcriptome signatures observed in glioblastoma (GBM). Specifically, we show that PN glioma sphere cultures (GSCs) can be induced to a MES state with an associated enrichment of CD44 expressing cells and a gain of radio-resistance, which we implicate as NFkB- dependent. Newly diagnosed GBM samples show a direct correlation between radiation response, higher MES metagene, CD44 expression, and NFkB activation. This correlation is also observed in the subset of GBM samples that do not exhibit IDH1 mutation, a favorable prognostic marker. Our results uncover a previously unknown link between subtype plasticity that is regulated by NFkB. Inhibition of NFkB activation can directly impact radio-resistance and presents an attractive therapeutic target for GBM. Gene expression data for 17 isolated Glioma Stem Cells

Project description:Glioblastoma (GBM) is the most common and aggressive primary brain tumor in adults, with glioma initiating cells (GICs) implicated to be critical for tumor progression and resistance to therapy. The hypoxic tumor microenvironment has been shown to play an important role to maintain the GICs; however, the mechanisms regulating responses of GICs to hypoxia remain poorly understood.

Project description:Glioblastoma multiforme (GBM) is a highly aggressive and malignant brain tumor that is refractory to existing therapeutic regimens due in part to the presence of stem-like cells, termed Glioma-Initiating Cells (GICs). The complex interactions between different signaling pathways and epigenetic regulation of key genes may be critical in the maintaining GICs in their stem-like state. Although several signaling pathways have been identified as being dysregulated in GBM, the prognosis of GBM patients remains miserable despite improvements in targeted therapies. In this report we identified that the BRG1 catalytic subunit of the SWI/SNF chromatin remodeling complex plays a fundamental role in the maintaining GICs in their stem-like state. In addition, we identified a novel mechanism by which BRG1 maintains glucose levels critical for GICs. BRG1 downregulates the expression of TXNIP, a negative regulator of glycolysis. BRG1 knockdown led to STAT3 upregulation, which in turn led to TXNIP activation. We further identified that TXNIP is a STAT3-regulated gene. Moreover, BRG1 suppressed the expression of interferon-stimulated genes, which regulate tumorigenesis. We also demonstrate that BRG1 plays a critical role in the drug resistance of GICs and in GIC-induced tumorigenesis. By genetic and pharmacological means, we found that inhibition of BRG1 can sensitize GICs to chemotherapeutic drugs, temozolomide and Carmustine. Our studies suggest that BRG1 may be a novel therapeutic target in GBM. The identification of the critical role that BRG1 plays GIC stemness and chemosensitivity in GICs will inform the development of better targeted therapies in GBM and possibly other cancers.

Project description:Glioblastoma (GBM) is the most common and aggressive primary brain tumor in adults, with glioma initiating cells (GICs) implicated to be critical for tumor progression and resistance to therapy. KDM1B is involved in regulating GICs' responses to hypoxia, since over-expression of KDM1B delays the cell growth under hypoxia while knocking-down of KDM1B in GICs promotes their survival and tumorigenic abilities.

Project description:Glioblastoma (GBM) is the most common and aggressive primary brain tumor in adults, with glioma initiating cells (GICs) implicated to be critical for tumor progression and resistance to therapy. The hypoxic tumor microenvironment has been shown to play an important role to maintain the GICs; however, the mechanisms regulating responses of GICs to hypoxia remain poorly understood. We used microarray to to detail the global change of gene expression in GICs cultured under hypoxia compared to normoxia and identified de-regulated genes during hypoxia. CD133+ D456MG GICs were cultured under 1% O2 or 20% O2 for 12 hours. Then RNA was extracted and gene expression was profiled by microarray.

Project description:SUMMARY Despite numerous genome-wide association studies involving glioblastoma (GBM), few therapeutic targets have been identified for this disease. Using patient derived glioma sphere cultures (GSCs), we have found that a subset of the proneural (PN) GSCs undergo transition to a mesenchymal (MES) state in a TNFa/NFkB dependent manner with an associated enrichment of CD44 sub-populations and radio-resistant phenotypes. To the contrary, MES GSCs exhibit constitutive NFkB activation, CD44 enrichment and radio-resistance. Patients whose tumors exhibit a higher MES metagene, increased expression of CD44, or activated NFkB were associated with poor radiation response and shorter survival. Our results indicate that NFkB activation mediated MES differentiation and radiation resistance presents an attractive therapeutic target for GBM. SIGNIFICANCE In this study, we show plasticity between the proneural (PN) and mesenchymal (MES) transcriptome signatures observed in glioblastoma (GBM). Specifically, we show that PN glioma sphere cultures (GSCs) can be induced to a MES state with an associated enrichment of CD44 expressing cells and a gain of radio-resistance, which we implicate as NFkB- dependent. Newly diagnosed GBM samples show a direct correlation between radiation response, higher MES metagene, CD44 expression, and NFkB activation. This correlation is also observed in the subset of GBM samples that do not exhibit IDH1 mutation, a favorable prognostic marker. Our results uncover a previously unknown link between subtype plasticity that is regulated by NFkB. Inhibition of NFkB activation can directly impact radio-resistance and presents an attractive therapeutic target for GBM. 4 treatments