DNA methylation, histone modifications, and nucleosomal occupancy collaborate to cause silencing of tumor-related genes in cancer. The development of drugs that target these processes is therefore important for cancer therapy. Inhibitors of DNA methylation and histone deacetylation have been approved by the Food and Drug Administration for treatment of hematologic malignancies. However, drugs that target other mechanisms still need to be developed. Recently, 3-deazaneplanocin A (DZNep) was reported to selectively inhibit trimethylation of lysine 27 on histone H3 (H3K27me3) and lysine 20 on histone H4 (H4K20me3) as well as reactivate silenced genes in cancer cells. This finding opens the door to the pharmacologic inhibition of histone methylation. We therefore wanted to further study the mechanism of action of DZNep in cancer cells. Western blot analysis shows that DZNep globally inhibits histone methylation and is not selective. Two other drugs, sinefungin and adenosine dialdehyde, have similar effects as DZNep on H3K27me3. Intriguingly, chromatin immunoprecipitation of various histone modifications and microarray analysis show that DZNep acts through a different pathway than 5-aza-2′-deoxycytidine, a DNA methyltransferase inhibitor. These observations give us interesting insight into how chromatin structure affects gene expression. We also determined the kinetics of gene activation to understand if the induced changes were somatically heritable. We found that upon removal of DZNep, gene expression is reduced to its original state. This suggests that there is a homeostatic mechanism that returns the histone modifications to their “ground state” after DZNep treatment. Our data show the strong need for further development of histone methylation inhibitors
Previous studies have shown that DNA methyltransferase (Dnmt) 1 is required for maintenance of bulk DNA methylation and is essential for mouse development. However, somatic disruption of DNMT1 in the human cancer cell line HCT116 was not lethal and caused only minor decreases in methylation. Here, we report the identification of a truncated DNMT1 protein, which was generated by the disruption of DNMT1 in HCT116 cells. The truncated protein, which had parts of the regulatory N-terminal domain deleted but preserved the catalytic C-terminal domain, was present at different levels in all DNMT1 single-knockout and DNMT1͞DNMT3b doubleknockout cell lines tested and retained hemimethylase activity. DNMT1 RNAi resulted in decreased cell viability in WT and knockout cells and further loss of DNA methylation in DNMT1 knockout cells. Furthermore, we observed a delay in methylation after replication and an increase in hemimethylation of specific CpG sites in cells expressing the truncated protein. Remethylation studies after drug-induced hypomethylation suggest a putative role of DNMT1 in the de novo methylation of a subtelomeric repeat, D4Z4, which is lost in cells lacking full-length DNMT1. Our data suggest that DNMT1 might be essential for maintenance of DNA methylation, proliferation, and survival of cancer cells. DNA methylation ͉ epigeneticT he biological roles of the major mammalian DNA methyltransferase (Dnmt), DNMT1, have been enigmatic. Although gene-targeting studies in mice have clearly demonstrated an essential function of Dnmt1 in embryonic development, cell survival, and tumorigenesis (1), there have been controversial reports regarding the function of this enzyme in human cancer cells. In mice, Dnmt1 has been implicated in maintaining the majority of bulk DNA methylation, differentiation of ES cells, and imprinting (2, 3). Furthermore, deletion of Dnmt1 in mouse embryonic fibroblasts caused a decrease in genomic methylation, p53-dependent apoptosis, and deregulation of transcription (4). Heterozygosity for Dnmt1 in combination with administration of the DNMT inhibitor 5-aza-2Јdeoxycytidine (5-aza-CdR) greatly reduced the number of polyps in a mouse model for intestinal neoplasia (5).A series of RNAi experiments for DNMT1 have been described for various human cancer cell lines, which have shown apparently inconsistent results in regard to DNA methylation of tumor suppressor genes (6-10). The differences might be attributed to the techniques used but also to distinct sensitivities of individual cell lines (10). Furthermore, RNAi may not cause a complete depletion of the protein, so residual protein might still be available and capable of maintaining DNA methylation. Rhee et al. (11,12) generated a widely used series of HCT116 colon cancer cells with homozygous deletions for DNMT1 (DNMT1 Ϫ/Ϫ ) (11), DNMT3b (DNMT3b Ϫ/Ϫ ) (12), or both DNMT1 and DNMT3b (12) [double knockout (DKO)]. Surprisingly, somatic disruption of DNMT1 resulted in only a 20% decrease in overall genomic methylation with no discernible changes i...
Despite the fact that 45% of all human gene promoters do not contain CpG islands, the role of DNA methylation in control of non-CpG island promoters is controversial and its relevance in normal and pathological processes is poorly understood. Among the few studies which investigate the correlation between DNA methylation and expression of genes with non-CpG island promoters, the majority do not support the view that DNA methylation directly leads to transcription silencing of these genes. Our reporter assays and gene reactivation by 5-aza-2'-deoxycytidine, a DNA demethylating agent, show that DNA methylation occurring at CpG poor LAMB3 promoter and RUNX3 promoter 1(RUNX3 P1) can directly lead to transcriptional silencing in cells competent to express these genes in vitro. Using Nucleosome Occupancy Methylome- Sequencing, NOMe-Seq, a single-molecule, high-resolution nucleosome positioning assay, we demonstrate that active, but not inactive, non-CpG island promoters display a nucleosome-depleted region (NDR) immediately upstream of the transcription start site (TSS). Furthermore, using NOMe-Seq and clonal analysis, we show that in RUNX3 expressing 623 melanoma cells, RUNX3 P1 has two distinct chromatin configurations: one is unmethylated with an NDR upstream of the TSS; another is methylated and nucleosome occupied, indicating that RUNX3 P1 is monoallelically methylated. Together, these results demonstrate that the epigenetic signatures comprising DNA methylation, histone marks and nucleosome occupancy of non-CpG island promoters are almost identical to CpG island promoters, suggesting that aberrant methylation patterns of non-CpG island promoters may also contribute to tumorigenesis and should therefore be included in analyses of cancer epigenetics.
Exposure to tobacco smoke is associated with increased DNA methylation at certain genes in both lung and bladder tumors. We sought to identify interactions in bladder cancer between DNA methylation and a history of smoking, along with any possible effect of aging. We measured DNA methylation in 342 transitional cell carcinoma tumors at BCL2, PTGS2 (COX2), DAPK, CDH1 (ECAD), EDNRB, RASSF1A, RUNX3, TERT, and TIMP3. The prevalence of methylation at RUNX3, a polycomb target gene, increased as a function of age at diagnosis (P = 0.031) and a history of smoking (P = 0.015). RUNX3 methylation also preceded methylation at the other eight genes (P < 0.001). It has been proposed that DNA methylation patterns constitute a ''molecular clock'' and can be used to determine the ''age'' of normal tissues (i.e., the number of times the cells have divided). Because RUNX3 methylation increases with age, is not present in normal urothelium, and occurs early in tumorigenesis, it can be used for the first time as a molecular clock to determine the age of a bladder tumor. Doing so reveals that tumors from smokers are ''older'' than tumors from nonsmokers (P = 0.009) due to tumors in smokers either initiating earlier or undergoing more rapid cell divisions. Because RUNX3 methylation is acquired early on in tumorigenesis, then its detection in biopsy or urine specimens could provide a marker to screen cigarette smokers long before any symptoms of bladder cancer are present. [Cancer Res 2008;68(15):6208-14]
Identification of new molecular markers has led to the molecular classification of prostate cancer based on driving genetic lesions. The translation of these discoveries for clinical use necessitates the development of simple, reliable and rapid detection systems to screen patients for specific molecular aberrations. We developed two dual color immunohistochemistry-based assays for the simultaneous assessment of ERG-PTEN and ERG-SPINK1 in prostate cancer. A total of 232 cases from 184 localized and 48 metastatic prostate cancers were evaluated for ERG-PTEN and 284 cases from 228 localized and 56 metastatic prostate cancers were evaluated for ERG-SPINK1. Of the 232 cases evaluated for ERG-PTEN, 81 (35%) ERG positive and 77 (33%) PTEN deleted cases were identified. Of the 81 ERG positive cases, PTEN loss was confirmed in 35 (15%) cases by fluorescence in situ hybridization. PTEN status was concordant in 203 cases (Sensitivity 90%; Specificity 87% (p<0.0001) by both immunohistochemisty and FISH, however, immunohistochemisty could not distinguish between heterozygous and homozygous deletion status of PTEN. Of the 284 cases evaluated for ERG-SPINK1, 111 (39%) cases were positive for ERG. In the remaining 173 ERG negative cases; SPINK1 was positive in 26 (9 %) cases. SPINK1 expression was found to be mutually exclusive with ERG expression; however, we identified two cases, of which, one showed concomitant expression of ERG and SPINK1 in the same tumor foci and in the second case ERG and SPINK1 was seen in two independent foci of the same tumor nodule. Unlike the homogenous ERG staining in cancer tissues, heterogeneous SPINK1 staining was observed in the majority of the cases. Further studies are required to understand the molecular heterogeneity of cases with concomitant ERG-SPINK1 expression. Automated dual ERG-PTEN and ERG-SPINK1 immunohistochemisty assays are simple, reliable and portable across study sites for the simultaneous assessment of these proteins in prostate cancer.
The structure and organization of chromatin have attracted a great deal of attention recently because of their implications for the field of epigenetics. DNA methylation and the post-translational modifications that occur on histones can specify transcriptional competency. During cancer development, tumor suppressor genes become silenced by DNA hypermethylation and chromatin modifiers no longer perform in their usual manner. Current epigenetic therapy has been able to take advantage of the reversibility of these epimutations. Progress has been made in the treatment of hematological malignancies and some solid tumors. As the knowledge of how chromatin regulates gene expression is enhanced, improvements in the treatment of cancer can be made.
Background This study examines the combined effect of two common genetic alterations, ERG and PTEN, in prostate carcinoma progression. Methods Prostate tissue from ninety patients having unilateral capsular penetrating lesions (CPL), and a contra-lateral organ confined (COC) second lesion, were examined by immunohistochemistry for the expression of the TMPRSS2:ERG transformation product ERG and the loss of expression of PTEN, a powerful phosphatase inhibiting the PI3 Kinase pathway. Multivariate logistic regression was carried out to analyze the data. Results After adjusting for Gleason score, the odds of having capsular penetration were 5.19 times higher (p=0.015) for ERG+/PTEN- group as compared to the wild type (ERG-/PTEN+). Conclusions This study presents the first evidence that ERG over expression and PTEN deletion is associated with greater risk of capsular penetration. Although further studies are needed, these results have the potential to change clinical assessment for prostate cancer.
Interleukin-1a (IL-1a) is secreted by a variety of cell types and is a major player in immune and inflammatory processes. Genes involved in immunological processes are known to be strictly regulated; however, how epigenetic mechanisms contribute to this regulation in not understood. To gain insight into the epigenetic regulation of the human TATA-less IL-1A gene, we show that active and silent chromatin modifications characterize the regulatory regions of IL-1a in expressing and non-expressing cells, respectively, and that the DNA methylation in the proximal promoter is associated with the expression status of the cells. Interestingly, although nucleosome depletion in active promoters is found in yeast and fly genes, now it has been reported in human promoters. We here show on the level of single DNA molecules that in expressing cells, a nucleosome is absent in about half of the proximal IL-1a promoters. This observation might reflect a more subtle regulation of nucleosome positioning in TATA-less genes or human genes in general.
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