Project description:Deregulated mRNA translation in cancer is a source of aberrant protein production when tryptophan shortage is induced by anti-tumor immunity (refs). Tryptophan is decoded by only one codon, and currently the consequences of aberrant protein production in conditions of a shortage of amino acids decoded by multiple codons are unknown. Leucine is decoded by six codons, and its levels influence a variety of key processes in cancer, including the control of mTOR signaling (ref) and epithelial to mesenchymal transition (PMID: 28274951). Here, we show that both leucine deprivation and DNA damage elicit ribosomal stalling and subsequent aberrant protein production predominantly at one codon for leucine, UUA. Mechanistically, we found that the leucine tRNA lowest in abundance is causative for ribosomal stalling and aberrant protein production. In addition, UUA-induced aberrant protein production impacts the landscape of neoepitopes presented at the surface of cancer cells, which can elicit T-cell recognition and killing. Altogether, codon-specific induction of neoepitopes by chemotherapy and leucine diet opens up new avenues for the development of adoptive T cell therapies.

Project description:U87MG is a commonly studied grade IV glioma cell line that has been analyzed in at least 1,700 publications over four decades. In order to comprehensively characterize the genome of this cell line and to serve as a model of broad cancer genome sequencing, we have generated greater than 30x genomic sequence coverage using a novel 50-base mate paired strategy with a 1.4kb mean insert library. A total of 1,014,984,286 mate-end and 120,691,623 single-end two-base encoded reads were generated from five slides. All data were aligned using a custom designed tool called BFAST, allowing optimal color space read alignment and accurate identification of DNA variants. The aligned sequence reads and mate pair information identified 35 interchromosomal translocation events, 1,315 structural variations (>100bp), 191,743 small (<21bp) insertions and deletions (indels), and 2,384,470 single nucleotide variations (SNVs). Among these observations, the known homozygous mutation in PTEN was robustly identified, and genes involved in cell adhesion were overrepresented in the mutated gene list. Data were compared to 219,187 heterozygous single nucleotide polymorphisms assayed by Illumina 1M Duo genotyping array to assess accuracy: 93.83% of all SNPs were reliably detected at filtering thresholds that yield greater than 99.99% sequence accuracy. Protein coding sequences were disrupted predominantly in this cancer cell line due to small indels, large deletions and translocations. In total, 512 genes were homozygously mutated, including 154 by SNVs, 178 by small indels, 145 by large microdeletions and 35 by interchromosomal translocations to reveal a highly mutated cell line genome. Of the small homozygously mutated variants, 8 SNVs and 99 indels were novel events not present in dbSNP. These data demonstrate that routine generation of broad cancer genome sequence is possible outside of genome centers. The sequence analysis of U87MG provides an unparalleled level of mutational resolution compared to any cell line to date. Whole genome sequencing of the U87MG brain cancer cell line using the AB SOLiD3 sequencer and genotyping using the Illumina Human1M-Duov3 DNA Analysis BeadChip

Project description:U87MG is a commonly studied grade IV glioma cell line that has been analyzed in at least 1,700 publications over four decades. In order to comprehensively characterize the genome of this cell line and to serve as a model of broad cancer genome sequencing, we have generated greater than 30x genomic sequence coverage using a novel 50-base mate paired strategy with a 1.4kb mean insert library. A total of 1,014,984,286 mate-end and 120,691,623 single-end two-base encoded reads were generated from five slides. All data were aligned using a custom designed tool called BFAST, allowing optimal color space read alignment and accurate identification of DNA variants. The aligned sequence reads and mate pair information identified 35 interchromosomal translocation events, 1,315 structural variations (>100bp), 191,743 small (<21bp) insertions and deletions (indels), and 2,384,470 single nucleotide variations (SNVs). Among these observations, the known homozygous mutation in PTEN was robustly identified, and genes involved in cell adhesion were overrepresented in the mutated gene list. Data were compared to 219,187 heterozygous single nucleotide polymorphisms assayed by Illumina 1M Duo genotyping array to assess accuracy: 93.83% of all SNPs were reliably detected at filtering thresholds that yield greater than 99.99% sequence accuracy. Protein coding sequences were disrupted predominantly in this cancer cell line due to small indels, large deletions and translocations. In total, 512 genes were homozygously mutated, including 154 by SNVs, 178 by small indels, 145 by large microdeletions and 35 by interchromosomal translocations to reveal a highly mutated cell line genome. Of the small homozygously mutated variants, 8 SNVs and 99 indels were novel events not present in dbSNP. These data demonstrate that routine generation of broad cancer genome sequence is possible outside of genome centers. The sequence analysis of U87MG provides an unparalleled level of mutational resolution compared to any cell line to date.

Project description:Gene expression analysis of the human glioma cell line U87MG

Project description:miR-490 is robustly downregulated in GBM tumour samples. This study identifies the genes differentially expressed upon miR-490 overexpression in U87MG glioblastoma cell line. GeneChip PrimeView Human Gene Expression Array was used to assess mRNA expression profile in response to miR-490 overexpression in U87MG cell line.

Project description:Genome wide methylation profiling of gliomas is likely to provide important clues to improving treatment outcomes. Restriction enzyme based approaches have been widely utilized for methylation profiling of cancer genomes and will continue to have importance in combination with higher density microarrays. With the availability of the human genome sequence and microarray probe sequences, these approaches can be readily characterized and optimized via in silico modeling. We adapted the previously described HpaII/MspI based Methylation Sensitive Restriction Enzyme (MSRE) assay for use with two-color Agilent 244K CpG island microarrays. In this assay, fragmented genomic DNA is digested in separate reactions with isoschizomeric HpaII (methylation-sensitive) and MspI (methylation-insensitive) restriction enzymes. Using in silico hybridization, we found that genomic fragmentation with BfaI was superior to MseI, providing a maximum effective coverage of 22,362 CpG islands in the human genome. In addition, we confirmed the presence of an internal control group of fragments lacking HpaII/MspI sites which enable separation of methylated and unmethylated fragments. We used this method on genomic DNA isolated from normal brain, U87MG cells, and a glioblastoma patient tumor sample and confirmed selected differentially methylated CpG islands using bisulfite sequencing. Along with additional validation points, we performed a receiver operating characteristics (ROC) analysis to determine the optimal threshold (p ≤ 0.001). Based on this threshold, we identified ~2400 CpG islands common to all three samples and 145 CpG islands unique to glioblastoma. These data provide general guidance to individuals seeking to maximize effective coverage using restriction enzyme based methylation profiling approaches. Five samples: normal human brain DNA, U87MG cell line, glioblastoma tumor, human DNA treated with SssI enzyme used as positive control, and Genomiphied human DNA used as negative control. Two technical replicates were performed on all samples except the negative control.

Project description:To explore factors contributing to radioresistance in GBM, we established GBM radioresistant cell line using U87MG human GBM cells.

Project description:This SuperSeries is composed of the following subset Series: GSE39579: Proteo-Genomic Characterization and Mapping of Nucleosomes Decoded by Brd and HP1 Proteins (Chip-Seq data) GSE39580: Proteo-Genomic Characterization and Mapping of Nucleosomes Decoded by Brd and HP1 Proteins (expression data) Refer to individual Series

Project description:Next-generation sequencing (NGS) has significantly advanced the elucidation of developmental signaling mechanisms that are important for U87MG cells under differente treatment. We report here the application of RNA-sequencing technology for transcriptome profile of U87MG cells treated with CAR neutrophils, nanodrugs, and CAR neutrophils loaded nanodrugs. Six U87MG samples were performed in IIIumina HiSeq2500. The resulting sequence reads were mapped to human genome (hg19) using HISAT, and the RefSeq transcript levels (RPKMs) were quantified using the python script rpkmforgenes.py. Our RNA-seq data analyzed different cellular signal pathways under treatment. This study shows a detailed analysis of U87MG transcriptomes generated by RNA-seq technology, providing insight into the mechanisms underlying CAR neutrophils lysis the tumor cells.

Project description:human prostate cancer cell line LNCaP Raw sequence reads