Project description:Early passages (< 10) of frequently used GBM cell lines A172, LN18, LN229, T98G, U87-MG, U138-MG and U251-MG were characterised for global DNA methylation patterns.

Project description:Genomic copy number number characterisation of glioblastoma (GBM) cell lines.

Project description:Gene expression analysis of glioblastoma (GBM) cell lines.

Project description:Early passages (< 10) of frequently used GBM cell lines A172, LN18, LN229, T98G, U87-MG, U138-MG and U251-MG were characterised for genomic copy number by array CGH.

Project description:Characterization of gene expression for a panel of 50 in vitro and in vivo models of glioblastoma (GBM). Models include subcutaneously established xenograft lines, orthotopically grown subcutaneously established xenograft lines, serum derived cell lines and stem cell media derived cell lines. Multiple replicates of each line were run on different dates to determine the effect of batch and processing date on reproducibility of gene expression profiles 117 samples analyzed from 50 distinct GBM xenografts or cell lines. Biological replicates from the same passage number were included for many, but not all, of the lines.

Project description:Our main objective was to study genome-wide differential methylation in de novo glioblastoma multiforme (GBM, grade IV glioma). We evaluated CpG sites in gene promoters of 26,000+ genes using an array-based chip. We retrieved 54 GBM from biorepositories of two institutions(40 from Columbia University and 14 from Case Western Reserve University) and 24 control brain tissues from the New York Brain Bank, which collected control brain tissues from consented subjects without history of neurological diseases at autopsy. Bisulfite modified DNA was extracted from 54 GBM and 24 control brain tissue. The HumanMethylation27 Analysis Bead-Chips (Illumina) were used to interrogate 26,486 informative CpG sites in the autosomes.

Project description:The DNA methylation profiles of Glioma Stem Cell (GSC) lines were investigated in order to find the stem cell signature associated to glioblastoma (GBM). This goal was achieved through the comparison of GSC methylation data with FFPE-GBM biopsies and human foetal Neural Stem Cell (NSC) lines profiles.

Project description:Glioblastoma (GBM) derived sphere lines and adherent cell lines are an important tool for research in basic and translational neuro-oncology. Documentation of their genetic identity has become a requirement for scientific journals and grant applications to exclude cross-contamination and misidentification that lead to misinterpretation of results. Here, we report expression data for 26 samples including 4 GBM derived sphere lines (4 x 3 replicates), 2 GBM derived sphere lines passaged through intracranial transplantation (2x 1), 2 adherent GBM derived cell lines (2 + 2 x 3 replicates), 4 corresponding glioblastoma tumors and 2 non-tumor brain tissues.

Project description:The DNA methylation profiles of Glioma Stem Cell (GSC) lines were investigated in order to find the stem cell signature associated to glioblastoma (GBM). This goal was achieved through the comparison of GSC methylation data with FFPE-GBM biopsies and human foetal Neural Stem Cell (NSC) lines profiles. GSC lines: 3 (GBM2, G144, G166). FFPE-GBM biopsy pool: FFPE-GBM pool: 1 pool from 5 GBM biopsies. Human foetal NSC lines: 2 (CB660 from forebrain; CB660SP form spinal cord). Methylated DNA from each sample was enriched with the immunoprecipitation method using 5-methylcytosine antibody (Eurogentec). Immunoprecipitated DNA (IP-DNA) and total DNA were labeled and hybridized on Agilent Human CpG Island ChIP-on-Chip Microarray 244K. IP-DNA were labeled with Cy5 while the matching total DNA were labeled with Cy3.

Project description:Characterization of gene expression for a panel of 50 in vitro and in vivo models of glioblastoma (GBM). Models include subcutaneously established xenograft lines, orthotopically grown subcutaneously established xenograft lines, serum derived cell lines and stem cell media derived cell lines. Multiple replicates of each line were run on different dates to determine the effect of batch and processing date on reproducibility of gene expression profiles