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Co-regulation of histone-modifying enzymes in cancer

PLoS ONE (2011) 6(8)
DOI: 10.1371/journal.pone.0024023
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Abstract

Cancer is characterized by aberrant patterns of expression of multiple genes. These major shifts in gene expression are believed to be due to not only genetic but also epigenetic changes. The epigenetic changes are communicated through chemical modifications, including histone modifications. However, it is unclear whether the binding of histone-modifying proteins to genomic regions and the placing of histone modifications efficiently discriminates corresponding genes from the rest of the genes in the human genome. We performed gene expression analysis of histone demethylases (HDMs) and histone methyltransferases (HMTs), their target genes and genes with relevant histone modifications in normal and tumor tissues. Surprisingly, this analysis revealed the existence of correlations in the expression levels of different HDMs and HMTs. The observed HDM/HMT gene expression signature was specific to particular normal and cancer cell types and highly correlated with target gene expression and the expression of genes with histone modifications. Notably, we observed that trimethylation at lysine 4 and lysine 27 separated preferentially expressed and underexpressed genes, which was strikingly different in cancer cells compared to normal cells. We conclude that changes in coordinated regulation of enzymes executing histone modifications may underlie global epigenetic changes occurring in cancer. © 2011 Islam et al.

Figures

  • Figure 1. Expression and correlation of H3K4 modifying enzymes and their targets in normal human tissues. (A) The absolute (log2) expression values of H3K4-specific HDM KDM5A, and H3K4-specific HMTs in 73 different normal human tissues (BioGPS database) are delineated in a color-coded heatmap, where red indicates higher expression of a gene and green indicates lower expression. The expression values and sample
  • Figure 2. Expression of HDMs and HMTs in normal human tissues and human cancer cell lines. (A) Expression of HDMs and HMTs in normal human tissues. Gene-normalized expression values (log2) of 26 HDMs and 11 HMTs are presented for eleven tissues (BioGPS database). (B) Expression of HDMs and HMTs in cancer cell lines. Gene-normalized (log2) expression values were generated for eleven cell lines from GSK dataset. Expression level for each gene was described in terms of preferential expression and underexpression, which showed relative higher expression of multiple HDM and HMT genes in cancer cells compared to normal cells. doi:10.1371/journal.pone.0024023.g002
  • Figure 4. Correlation between HDM and HMT gene expression. The PCC values of any gene pair’s expression profile in hematopoietic, lung and colon cell lines are depicted in a color-coded heatmap. The legend and scale are as in Figure 1. doi:10.1371/journal.pone.0024023.g004
  • Figure 5. Expression levels of KDM5A, KDM5B and a KDM5A target gene in human tumors. (A) KDM5A and KDM5B display highly tissue-specific expression patterns. The figure shows a heatmap of quantitative real-time PCR experiments in a panel of human tumor samples. Samples were arranged according to tumor grade, when information was available. Expression was normalized to the reference
  • Figure 6. Epigenetic landscape is defined by HDM/HMT gene expression signature. The status of HDM and HMT gene expression is presented in red (higher expression) and green (lower expression) colors. The KDM5A, EZH2, H3K4me3 and H3K27me3 modules are shown as large circles, either preferentially expressed (in red color) or underexpressed (in blue color). The expression of KDM5A targets and genes with H3K4me3 is determined by the levels of HDM1 and HMT1, which are relatively high in blood cells. In leukemia cells, the level of HMT1 becomes lower, the level of HDM2 becomes higher and as a result, the responsive H3K4me3 module is not preferentially expressed anymore. Some of the H3K4 and H3K27 trimethylated regions overlap as bivalent marks and remain poised for expression (shown as a grey area in the overlap). doi:10.1371/journal.pone.0024023.g006

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CITATION STYLE

APA

Islam, A. B. M. M. K., Richter, W. F., Jacobs, L. A., Lopez-Bigas, N., & Benevolenskaya, E. V. (2011). Co-regulation of histone-modifying enzymes in cancer. PLoS ONE, 6(8). https://doi.org/10.1371/journal.pone.0024023

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