Histone H3 lysine 9 trimethylation (H3K9Me3) has been associated with transcriptional repression, but recent findings implicate this chromatin modification in transcriptional activation and mRNA elongation by RNA polymerase II. Here, we applied immunoprecipitation (IP) with a custom DNA tiling microarray containing many transcription factors important in development and cancer (for example homeotic genes; N ¼ 683 total genes) to explore the relationship between H3K9Me3 and other histone modifications with the differential expression of genes. Cancer cell lines derived from different tissues (2 leukemia, 2 medulloblastoma) were characterized with IP antibodies to H3K9Me3, H3K4 dimethylation (H3K4Me2) and H3K9 acetylation (H3K9Ac). MV4-11 is known to overexpress the HOXA9 and MEIS1 genes, whereas D283 overexpresses the OTX2 homeobox gene. Gene expression was assessed by Affymetrix U133 array. Mapping the number and size of histone markings demonstrated significant colocalization of H3K9Ac and H3K4Me2 with H3K9Me3, indicating a pattern of putative 'activating' and 'repressive' markings. The median site size was 600-821 bp and 72-95% or 53-80% of chromatin signal sites were located within 1 kb or 500 bp of transcription start sites (TSS), respectively. A relatively small number of genes displayed additional H3K9Me3 sites in the 5 0 -region distant from the TSS. Comparing genes with modification sites to those without sites in their promoters confirmed the positive associations of H3K9Ac and H3K4Me2 with gene expression and revealed that H3K9Me3 is associated with active genes rather than being a repressive marking as previously thought. The positive regulatory effect of all three types of modifications were quantitatively correlated with site size, and applied to absolute gene expression within a single cell line as well as relative expression among pairs of cell lines. Extended patterns of H3K9Me3 upstream of some genes (for example HOXA9 and OTX2) may result from the action of multiple promoter elements. We found an inverse relationship between promoter DNA hypermethylation and H3K9Me3 in three studied genes (HOXA9, TMS1, RASSF1A). The localization of H3K9Me3 downstream of the TSSs of expressed genes and not within promoter regions of hypermethylated and silenced genes is consistent with the proposed coupling of H3K9Me3 with RNA polymerase II. Our results indicate a need for revising aspects of the histone code involving H3 lysine methylation. Awareness of H3K9Me3 as a mark of gene activity, not repression, is especially important for the classification of human cancer using chromatin and histone profiles.
We explored the associations of aberrant DNA methylation patterns in 12 candidate genes with adult glioma subtype, patient survival, and gene expression of enhancer of zeste human homolog 2 (EZH2) and insulin-like growth factor-binding protein 2 (IGFBP2). We analyzed 154 primary glioma tumors (37 astrocytoma II and III, 52 primary glioblastoma multiforme (GBM), 11 secondary GBM, 54 oligodendroglioma/oligoastrocytoma II and III) and 13 nonmalignant brain tissues for aberrant methylation with quantitative methylation-specific PCR (qMS-PCR) and for EZH2 and IGFBP2 expression with quantitative reverse transcription PCR (qRT-PCR). Global methylation was assessed by measuring long interspersed nuclear element-1 (LINE1) methylation. Unsupervised clustering analyses yielded 3 methylation patterns (classes). Class 1 (MGMT, PTEN, RASSF1A, TMS1, ZNF342, EMP3, SOCS1, RFX1) was highly methylated in 82% (75/91) of lower-grade astrocytic and oligodendroglial tumors, 73% (8/11) of secondary GBMs, and 12% (6/52) of primary GBMs. The primary GBMs in this class were early onset (median age 37 years). Class 2 (HOXA9 and SLIT2) was highly methylated in 37% (19/52) of primary GBMs. None of the 10 genes for class 3 that were differentially methylated in classes 1 and 2 were hypermethylated in 92% (12/13) of nonmalignant brain tissues and 52% (27/52) of primary GBMs. Class 1 tumors had elevated EZH2 expression but not elevated IGFBP2; class 2 tumors had both high IGFBP2 and high EZH2 expressions. The gene-specific hypermethylation class correlated with higher levels of global LINE1 methylation and longer patient survival times. These findings indicate a generalized hypermethylation phenotype in glioma linked to improved survival and low IGFBP2. DNA methylation markers are useful in characterizing distinct glioma subtypes and may hold promise for clinical applications.
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