Phosphorylation of p53 by TAF1 inactivates p53-dependent transcription in the DNA damage response.

While p53 activation has long been studied, the mechanisms by which its targets genes are restored to their preactivation state are less clear. We report here that TAF1 phosphorylates p53 at Thr55, leading to dissociation of p53 from the p21 promoter and inactivation of transcription late in the DNA damage response. We further show that cellular ATP level might act as a molecular switch for Thr55 phosphorylation on the p21 promoter, indicating that TAF1 is a cellular ATP sensor. Upon DNA damage, cells undergo PARP-1-dependent ATP depletion, which is correlated with reduced TAF1 kinase activity and Thr55 phosphorylation, resulting in p21 activation. As cellular ATP levels recover, TAF1 is able to phosphorylate p53 on Thr55, which leads to dissociation of p53 from the p21 promoter. ChIP-sequencing analysis reveals p53 dissociates from promoters genome wide as cells recover from DNA damage, suggesting the general nature of this mechanism.

H2A.Z maintenance during mitosis reveals nucleosome shifting on mitotically silenced genes.

Profound chromatin changes occur during mitosis to allow for gene silencing and chromosome segregation followed by reactivation of memorized transcription states in daughter cells. Using genome-wide sequencing, we found H2A.Z-containing +1 nucleosomes of active genes shift upstream to occupy TSSs during mitosis, significantly reducing nucleosome-depleted regions. Single-molecule analysis confirmed nucleosome shifting and demonstrated that mitotic shifting is specific to active genes that are silenced during mitosis and, thus, is not seen on promoters, which are silenced by methylation or mitotically expressed genes. Using the GRP78 promoter as a model, we found H3K4 trimethylation is also maintained while other indicators of active chromatin are lost and expression is decreased. These key changes provide a potential mechanism for rapid silencing and reactivation of genes during the cell cycle.

Role of nucleosomal occupancy in the epigenetic silencing of the MLH1 CpG island.

Epigenetic silencing of tumor suppressor genes is generally thought to involve DNA cytosine methylation, covalent modifications of histones, and chromatin compaction. Here, we show that silencing of the three transcription start sites in the bidirectional MLH1 promoter CpG island in cancer cells involves distinct changes in nucleosomal occupancy. Three nucleosomes, almost completely absent from the start sites in normal cells, are present on the methylated and silenced promoter, suggesting that epigenetic silencing may be accomplished by the stable placement of nucleosomes into previously vacant positions. Activation of the promoter by demethylation with 5-aza-2'-deoxycytidine involves nucleosome eviction. Epigenetic silencing of tumor suppressor genes may involve heritable changes in nucleosome occupancy enabled by cytosine methylation.

Frequent switching of Polycomb repressive marks and DNA hypermethylation in the PC3 prostate cancer cell line.

Epigenetic reprogramming is commonly observed in cancer, and is hypothesized to involve multiple mechanisms, including DNA methylation and Polycomb repressive complexes (PRCs). Here we devise a new experimental and analytical strategy using customized high-density tiling arrays to investigate coordinated patterns of gene expression, DNA methylation, and Polycomb marks which differentiate prostate cancer cells from their normal counterparts. Three major changes in the epigenomic landscape distinguish the two cell types. Developmentally significant genes containing CpG islands which are silenced by PRCs in the normal cells acquire DNA methylation silencing and lose their PRC marks (epigenetic switching). Because these genes are normally silent this switch does not cause de novo repression but might significantly reduce epigenetic plasticity. Two other groups of genes are silenced by either de novo DNA methylation without PRC occupancy (5mC reprogramming) or by de novo PRC occupancy without DNA methylation (PRC reprogramming). Our data suggest that the two silencing mechanisms act in parallel to reprogram the cancer epigenome and that DNA hypermethylation may replace Polycomb-based repression near key regulatory genes, possibly reducing their regulatory plasticity.

Histone H3-lysine 9 methylation is associated with aberrant gene silencing in cancer cells and is rapidly reversed by 5-aza-2'-deoxycytidine.

Epigenetic modifications of cytosine residues in DNA and the amino termini of histone proteins have emerged as key mechanisms in chromatin remodeling, impacting both the transcriptional regulation and the establishment of chromosomal domains. Using the chromatin immunoprecipitation (ChIP) assay, we demonstrate that aberrantly silenced genes in cancer cells exhibit a heterochromatic structure that is characterized by histone H3 lysine 9 (H3-K9) hypermethylation and histone H3 lysine 4 (H3-K4) hypomethylation. This aberrant heterochromatin is incompatible with transcriptional initiation but does not inhibit elongation by RNA polymerase II. H3-K9 methylation may, therefore, play a role in the silencing of tumor-suppressor genes in cancer. Treatment with 5-aza-2'-deoxycytidine (5-Aza-CdR), previously known for its ability to inhibit cytosine methylation, induced a rapid and substantial remodeling of the heterochromatic domains of the p14ARF/p16INK4a locus in T24 bladder cancer cells, reducing levels of dimethylated H3-K9 and increasing levels of dimethylated H3-K4 at this locus. In addition, 5-Aza-CdR increased acetylation and H3-K4 methylation at the unmethylated p14 promoter, suggesting it can induce chromatin remodeling independently of its effects on cytosine methylation.

Selective anchoring of DNA methyltransferases 3A and 3B to nucleosomes containing methylated DNA.

Proper DNA methylation patterns are essential for mammalian development and differentiation. DNA methyltransferases (DNMTs) primarily establish and maintain global DNA methylation patterns; however, the molecular mechanisms for the generation and inheritance of methylation patterns are still poorly understood. We used sucrose density gradients of nucleosomes prepared by partial and maximum micrococcal nuclease digestion, coupled with Western blot analysis to probe for the interactions between DNMTs and native nucleosomes. This method allows for analysis of the in vivo interactions between the chromatin modification enzymes and their actual nucleosomal substrates in the native state. We show that little free DNA methyltransferase 3A and 3B (DNMT3A/3B) exist in the nucleus and that almost all of the cellular contents of DNMT3A/3B, but not DNMT1, are strongly anchored to a subset of nucleosomes. This binding of DNMT3A/3B does not require the presence of other well-known chromatin-modifying enzymes or proteins, such as proliferating cell nuclear antigen, heterochromatin protein 1, methyl-CpG binding protein 2, Enhancer of Zeste homolog 2, histone deacetylase 1, and UHRF1, but it does require an intact nucleosomal structure. We also show that nucleosomes containing methylated SINE and LINE elements and CpG islands are the main sites of DNMT3A/3B binding. These data suggest that inheritance of DNA methylation requires cues from the chromatin component in addition to hemimethylation.

Distinct localization of histone H3 acetylation and H3-K4 methylation to the transcription start sites in the human genome.

Almost 1-2% of the human genome is located within 500 bp of either side of a transcription initiation site, whereas a far larger proportion (approximately 25%) is potentially transcribable by elongating RNA polymerases. This observation raises the question of how the genome is packaged into chromatin to allow start sites to be recognized by the regulatory machinery at the same time as transcription initiation, but not elongation, is blocked in the 25% of intragenic DNA. We developed a chromatin scanning technique called ChAP, coupling the chromatin immunoprecipitation assay with arbitrarily primed PCR, which allows for the rapid and unbiased comparison of histone modification patterns within the eukaryotic nucleus. Methylated lysine 4 (K4) and acetylated K9/14 of histone H3 were both highly localized to the 5' regions of transcriptionally active human genes but were greatly decreased downstream of the start sites. Our results suggest that the large transcribed regions of human genes are maintained in a deacetylated conformation in regions read by elongating polymerase. Common models depicting widespread histone acetylation and K4 methylation throughout the transcribed unit do not therefore apply to the majority of human genes.