Role of Nucleosomal Occupancy in the Epigenetic Silencing of the MLH1 CpG Island

Lin, Joy; Jeong, Shinwu; Liang, Gangning; Takai, Daiya; Fatemi, M.; Tsai, Yvonne; Egger, Gerda; Gal‐Yam, Einav Nili; Jones, Peter A.

doi:10.1016/j.ccr.2007.10.014

Cited by 196 publications

(175 citation statements)

References 45 publications

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“…The other three genes, miR-137, miR-193a and miR-127, were expressed even in cell lines with complete methylation, and were unlikely to be silenced by promoter methylation in gastric cancers. Since methylation of putative promoter regions consistently represses transcription of their downstream genes, 29,30 the presence of the expression of the three genes in gastric cancer cell lines with complete methylation of their ''promoter'' CGI indicated that the three genes had additional or alternative promoters.…”

Section: Discussionmentioning

confidence: 99%

“…1a), whose methylation statuses are now known to be critical for induction of gene silencing. 29,30 qMSP was performed by real-time PCR using SYBR 1 Green I (BioWhittaker Molecular Applications, Rockland, ME) and an iCycler Thermal Cycler (Bio-Rad Laboratories, Hercules, CA). Although the same primer set was used for qMSP, a specific annealing temperature in the presence of SYBR 1 Green I was redetermined using the fully methylated and unmethylated DNA.…”

Section: Cell Lines and Tissue Samplesmentioning

confidence: 99%

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DNA methylation of microRNA genes in gastric mucosae of gastric cancer patients: Its possible involvement in the formation of epigenetic field defect

Ando

Yoshida

Enomoto

et al. 2009

Intl Journal of Cancer

258

207

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Accumulation of aberrant DNA methylation in normal-appearing gastric mucosae, mostly induced by H. pylori infection, is now known to be deeply involved in predisposition to gastric cancers (epigenetic field defect), and silencing of protein-coding genes has been analyzed so far. In this study, we aimed to clarify the involvement of microRNA (miRNA) gene silencing in the field defect. First, we selected three miRNA genes as methylation-silenced after analysis of six candidate ''methylation-silenced'' tumor-suppressor miRNA genes. Methylation levels of the three genes (miR124a-1, miR-124a-2 and miR-124a-3) were quantified in 56 normal gastric mucosae of healthy volunteers (28 volunteers with H. pylori and 28 without), 45 noncancerous gastric mucosae of gastric cancer patients (29 patients with H. pylori and 16 without), and 28 gastric cancer tissues (13 intestinal and 15 diffuse types). Among the healthy volunteers, individuals with H. pylori had 7.8-13.1-fold higher methylation levels than those without (p < 0.001). Among individuals without H. pylori, noncancerous gastric mucosae of gastric cancer patients had 7.2-15.5-fold higher methylation levels than gastric mucosae of healthy volunteers (p < 0.005). Different from protein-coding genes, individuals with past H. pylori infection retained similar methylation levels to those with current infection. In cancer tissues, methylation levels were highly variable, and no difference was observed between intestinal and diffuse histological types. This strongly indicated that methylationsilencing of miRNA genes, in addition to that of protein-coding genes, contributed to the formation of a field defect for gastric cancers. ' 2008 Wiley-Liss, Inc.Key words: field for cancerization; microRNA; methylation; gastric cancer; Helicobacter pylori Metachronous occurrence of gastric cancers is becoming an important issue as localized resection of early gastric cancers by endoscopic submucosal dissection (ESD) has become common. 1 The incidence of secondary primary gastric cancers after ESD reaches as high as 2.0% per year 2 whereas the incidence of gastric cancer in the general Japanese population is 0.14% per year. 3 This indicates that noncancerous gastric mucosae are already predisposed to developing gastric cancers, forming a field defect (field for cancerization). High incidences of metachronous cancers have been known not only for gastric cancers but also for bladder, liver, and esophageal cancers 4-6 and are becoming recognized for lung, breast and colorectal cancers. [7][8][9] A molecular basis for the field defect has been considered as an accumulation of genetic and epigenetic alterations in normalappearing tissues. Traditionally, cells with a genetic alteration were considered to form a physically continuous patch, producing a genetically altered field. 10 Recently, we found that aberrant DNA methylation of specific genes can be induced in as high as several percentage of cells in noncancerous gastric mucosae (thus in multiple independent gastric glands), and the degre...

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Section: Discussionmentioning

confidence: 99%

Section: Cell Lines and Tissue Samplesmentioning

confidence: 99%

DNA methylation of microRNA genes in gastric mucosae of gastric cancer patients: Its possible involvement in the formation of epigenetic field defect

Ando

Yoshida

Enomoto

et al. 2009

Intl Journal of Cancer

258

207

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“…4B, middle). MLH1 is a target gene activated by p53, but it is unmethylated (25,35), and its expression is not significantly affected by 5aza-dC treatment of HCT116 cells (microarray signals: HCT116 and HCT116 ϩ 5aza-dC, 189 and 152 arbitrary units, respectively).…”

Section: Nek2 Repression By Exogenously Expressed P53mentioning

confidence: 99%

“…Both doxo and 5aza-dC have been shown to alter chromatin structure, including causing eviction or turnover of nucleosomes (35,38). To determine whether drug treatment causes changes in nucleosome occupancy at the NEK2 promoter, nuclei from HCT116 cells treated with or without 5aza-dC or doxo were digested with MNase and analyzed by qPCR using convergent primers spanning the p53-binding region (Fig.…”

Section: Modulation Of P53 or Treatment With 5aza-dc Leads To Local Cmentioning

confidence: 99%

Local Depletion of DNA Methylation Identifies a Repressive p53 Regulatory Region in the NEK2 Promoter

Nabilsi

Ryder

Peraza-Penton

et al. 2013

Journal of Biological Chemistry

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Background: NEK2 is a mammalian kinase that promotes centrosome separation during the cell cycle. Results: Agents that demethylate the NEK2 promoter or induce DNA damage repress NEK2 expression in a p53-dependent manner. Conclusion: p53 represses NEK2 expression and protects its binding region from accumulating DNA methylation. Significance: Knowledge regarding novel mechanisms of NEK2 regulation may help inform clinical application of NEK2-based anticancer therapeutics.

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“…10,[15][16][17] These studies implicated several factors in the propensity of given CpG sites to remethylate, including proximity to a transcription start site (TSS), occupancy of RNA Polymerase II (RNAP II), and the presence of certain histone modifications. 10,16 Given the widespread use of these agents and the promising clinical trials underway utilizing DAC or related compounds as a synergistic or sensitizing agents, [4][5][6] it is vital to understand both the extent and stability of DACinduced demethylation given its immediate potential to improve cancer treatment.…”

Section: Introductionmentioning

confidence: 99%

Factors affecting the persistence of drug-induced reprogramming of the cancer methylome

et al. 2016

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Aberrant DNA methylation is a critical feature of cancer. Epigenetic therapy seeks to reverse these changes to restore normal gene expression. DNA demethylating agents, including 5-aza-2 0 -deoxycytidine (DAC), are currently used to treat certain leukemias, and can sensitize solid tumors to chemotherapy and immunotherapy. However, it has been difficult to pin the clinical efficacy of these agents to specific demethylation events, and the factors that contribute to the durability of response remain largely unknown. Here we examined the genome-wide kinetics of DAC-induced DNA demethylation and subsequent remethylation after drug withdrawal in breast cancer cells. We find that CpGs differ in both their susceptibility to demethylation and propensity for remethylation after drug removal. DAC-induced demethylation was most apparent at CpGs with higher initial methylation levels and further from CpG islands. Once demethylated, such sites exhibited varied remethylation potentials. The most rapidly remethylating CpGs regained >75% of their starting methylation within a month of drug withdrawal. These sites had higher pretreatment methylation levels, were enriched in gene bodies, marked by H3K36me3, and tended to be methylated in normal breast cells. In contrast, a more resistant class of CpG sites failed to regain even 20% of their initial methylation after 3 months. These sites had lower pretreatment methylation levels, were within or near CpG islands, marked by H3K79me2 or H3K4me2/3, and were overrepresented in sites that become aberrantly hypermethylated in breast cancers. Thus, whereas DAC-induced demethylation affects both endogenous and aberrantly methylated sites, tumorspecific hypermethylation is more slowly regained, even as normal methylation promptly recovers. Taken together, these data suggest that the durability of DAC response is linked to its selective ability to stably reset at least a portion of the cancer methylome.

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Role of Nucleosomal Occupancy in the Epigenetic Silencing of the MLH1 CpG Island

Cited by 196 publications

References 45 publications

DNA methylation of microRNA genes in gastric mucosae of gastric cancer patients: Its possible involvement in the formation of epigenetic field defect

DNA methylation of microRNA genes in gastric mucosae of gastric cancer patients: Its possible involvement in the formation of epigenetic field defect

Local Depletion of DNA Methylation Identifies a Repressive p53 Regulatory Region in the NEK2 Promoter

Factors affecting the persistence of drug-induced reprogramming of the cancer methylome

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