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  • 1
    Online Resource
    Online Resource
    Next-generation tag sequencing for cancer gene expression profiling
    Cold Spring Harbor Laboratory ; 2009
    In:  Genome Research Vol. 19, No. 10 ( 2009-10), p. 1825-1835
    Details
    In: Genome Research, Cold Spring Harbor Laboratory, Vol. 19, No. 10 ( 2009-10), p. 1825-1835
    Abstract: We describe a new method, Tag-seq, which employs ultra high-throughput sequencing of 21 base pair cDNA tags for sensitive and cost-effective gene expression profiling. We compared Tag-seq data to LongSAGE data and observed improved representation of several classes of rare transcripts, including transcription factors, antisense transcripts, and intronic sequences, the latter possibly representing novel exons or genes. We observed increases in the diversity, abundance, and dynamic range of such rare transcripts and took advantage of the greater dynamic range of expression to identify, in cancers and normal libraries, altered expression ratios of alternative transcript isoforms. The strand-specific information of Tag-seq reads further allowed us to detect altered expression ratios of sense and antisense (S-AS) transcripts between cancer and normal libraries. S-AS transcripts were enriched in known cancer genes, while transcript isoforms were enriched in miRNA targeting sites. We found that transcript abundance had a stronger GC-bias in LongSAGE than Tag-seq, such that AT-rich tags were less abundant than GC-rich tags in LongSAGE. Tag-seq also performed better in gene discovery, identifying 〉 98% of genes detected by LongSAGE and profiling a distinct subset of the transcriptome characterized by AT-rich genes, which was expressed at levels below those detectable by LongSAGE. Overall, Tag-seq is sensitive to rare transcripts, has less sequence composition bias relative to LongSAGE, and allows differential expression analysis for a greater range of transcripts, including transcripts encoding important regulatory molecules.
    Type of Medium: Online Resource
    ISSN: 1088-9051
    URL: Article
    DOI: 10.1101/gr.094482.109
    RVK:
    XA 10000
    Language: English
    Publisher: Cold Spring Harbor Laboratory
    Publication Date: 2009
    detail.hit.zdb_id: 1483456-X
    SSG: 12
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  • 2
    Online Resource
    Online Resource
    Extensive relationship between antisense transcription and alternative splicing in the human genome
    Cold Spring Harbor Laboratory ; 2011
    In:  Genome Research Vol. 21, No. 8 ( 2011-08), p. 1203-1212
    Details
    In: Genome Research, Cold Spring Harbor Laboratory, Vol. 21, No. 8 ( 2011-08), p. 1203-1212
    Abstract: To analyze the relationship between antisense transcription and alternative splicing, we developed a computational approach for the detection of antisense-correlated exon splicing events using Affymetrix exon array data. Our analysis of expression data from 176 lymphoblastoid cell lines revealed that the majority of expressed sense–antisense genes exhibited alternative splicing events that were correlated to the expression of the antisense gene. Most of these events occurred in areas of sense–antisense (SAS) gene overlap, which were significantly enriched in both exons and nucleosome occupancy levels relative to nonoverlapping regions of the same genes. Nucleosome occupancy was highly correlated with Pol II abundance across overlapping regions and with concomitant increases in local alternative exon usage. These results are consistent with an antisense transcription-mediated mechanism of splicing regulation in normal human cells. A comparison of the prevalence of antisense-correlated splicing events between individuals of Mormon versus African descent revealed population-specific events that may indicate the continued evolution of new SAS loci. Furthermore, the presence of antisense transcription was correlated to alternative splicing across multiple metazoan species, suggesting that it may be a conserved mechanism contributing to splicing regulation.
    Type of Medium: Online Resource
    ISSN: 1088-9051
    URL: Article
    DOI: 10.1101/gr.113431.110
    RVK:
    XA 10000
    Language: English
    Publisher: Cold Spring Harbor Laboratory
    Publication Date: 2011
    detail.hit.zdb_id: 1483456-X
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  • 3
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    Online Resource
    High-resolution structural genomics reveals new therapeutic vulnerabilities in glioblastoma
    Cold Spring Harbor Laboratory ; 2019
    In:  Genome Research Vol. 29, No. 8 ( 2019-08), p. 1211-1222
    Details
    In: Genome Research, Cold Spring Harbor Laboratory, Vol. 29, No. 8 ( 2019-08), p. 1211-1222
    Abstract: We investigated the role of 3D genome architecture in instructing functional properties of glioblastoma stem cells (GSCs) by generating sub-5-kb resolution 3D genome maps by in situ Hi-C. Contact maps at sub-5-kb resolution allow identification of individual DNA loops, domain organization, and large-scale genome compartmentalization. We observed differences in looping architectures among GSCs from different patients, suggesting that 3D genome architecture is a further layer of inter-patient heterogeneity for glioblastoma. Integration of DNA contact maps with chromatin and transcriptional profiles identified specific mechanisms of gene regulation, including the convergence of multiple super enhancers to individual stemness genes within individual cells. We show that the number of loops contacting a gene correlates with elevated transcription. These results indicate that stemness genes are hubs of interaction between multiple regulatory regions, likely to ensure their sustained expression. Regions of open chromatin common among the GSCs tested were poised for expression of immune-related genes, including CD276 . We demonstrate that this gene is co-expressed with stemness genes in GSCs and that CD276 can be targeted with an antibody-drug conjugate to eliminate self-renewing cells. Our results demonstrate that integrated structural genomics data sets can be employed to rationally identify therapeutic vulnerabilities in self-renewing cells.
    Type of Medium: Online Resource
    ISSN: 1088-9051 , 1549-5469
    URL: Article
    DOI: 10.1101/gr.246520.118
    RVK:
    XA 10000
    Language: English
    Publisher: Cold Spring Harbor Laboratory
    Publication Date: 2019
    detail.hit.zdb_id: 1483456-X
    SSG: 12
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