Project description:Background: Cytosine hydroxymethylation (5hmC) was recently identified in mammalian DNA as the product of oxidation of methylated cytosines (5mC) by Ten-Eleven-Translocation (TET) enzymes. The TETs have been shown to influence 5mC metabolism, pluripotency and differentiation during early embryonic development. However, a functional relationship between gene expression and 5hmC in adult (somatic) stem cell differentiation is however mainly unknown. To explore the role of this novel DNA modification in adult stem cell differentiation we profiled 5hmC and gene activity in purified mouse intestinal progenitors and differentiated progeny. Results: We show that the hydroxymethylome is highly dynamic with tens of thousands of differentially hydroxymethylated regions between progenitors and differentiated progeny. In progenitors 5hmC does not correlate with gene expression levels, however, upon differentiation a global increase in 5hmC is observed with an overall positive correlation between 5hmC and gene expression together with prominent associations with histone modifications that typify active genes and enhancer elements. Conclusions: In the context of recent evidence of near identical methylomes between mouse intestinal stem and differentiated cells, our data imply that a gene regulatory role for 5hmC is predominant over its role in controlling DNA methylation states. Our study provides an insight into the dynamics of 5hmC and of epigenetic machineries in differentiation of the mouse intestine.

Project description:Background: Cytosine hydroxymethylation (5hmC) was recently identified in mammalian DNA as the product of oxidation of methylated cytosines (5mC) by Ten-Eleven-Translocation (TET) enzymes. The TETs have been shown to influence 5mC metabolism, pluripotency and differentiation during early embryonic development. However, a functional relationship between gene expression and 5hmC in adult (somatic) stem cell differentiation is however mainly unknown. To explore the role of this novel DNA modification in adult stem cell differentiation we profiled 5hmC and gene activity in purified mouse intestinal progenitors and differentiated progeny. Results: We show that the hydroxymethylome is highly dynamic with tens of thousands of differentially hydroxymethylated regions between progenitors and differentiated progeny. In progenitors 5hmC does not correlate with gene expression levels, however, upon differentiation a global increase in 5hmC is observed with an overall positive correlation between 5hmC and gene expression together with prominent associations with histone modifications that typify active genes and enhancer elements. Conclusions: In the context of recent evidence of near identical methylomes between mouse intestinal stem and differentiated cells, our data imply that a gene regulatory role for 5hmC is predominant over its role in controlling DNA methylation states. Our study provides an insight into the dynamics of 5hmC and of epigenetic machineries in differentiation of the mouse intestine.

Project description:5-hydroxymethylcytosine and gene activity in mouse intestinal differentiation (hmeDIP-seq).

Project description:5-hydroxymethylcytosine and gene activity in mouse intestinal differentiation (RNA-Seq).

Project description:The discovery of cytosine hydroxymethylation (5-hmC) as a mechanism that potentially controls DNA methylation changes typical of neoplasia prompted us to investigate its behavior in colon cancer. 5-hmC is globally reduced in proliferating cells such as colon tumors and the gut crypt progenitors, from which tumors can arise. Here, we show that colorectal tumors and cancer cells express Ten-Eleven Translocation (TET) transcripts at levels similar to normal tissues. Genome-wide analyses show that promoters marked by 5-hmC in normal tissue, and those identified as TET2 targets in colorectal cancer cells, are resistant to methylation gain in cancer. In vitro studies of TET2 in cancer cells confirm that these promoters are resistant to methylation gain independently of sustained TET2 expression. We also find that a considerable number of the methylation gain-resistant promoters marked by 5-hmC in normal colon overlap with those that are marked with poised bivalent histone modifications in embryonic stem cells. Together our results indicate that promoters that acquire 5-hmC upon normal colon differentiation are innately resistant to neoplastic hypermethylation by mechanisms that do not require high levels of 5-hmC in tumors. Our study highlights the potential of cytosine modifications as biomarkers of cancerous cell proliferation.

Project description:Regulation of gene expression changes during chondrogenic differentiation by DNA methylation and demethylation is little understood. Methylated cytosines (5mC) are oxidized by the ten-eleven-translocation (TET) proteins to 5-hydroxymethylcytosines (5hmC), 5-formylcytosines (5fC), and 5-carboxylcytosines (5caC), eventually leading to a replacement by unmethylated cytosines (C), ie, DNA demethylation. Additionally, 5hmC is stable and acts as an epigenetic mark by itself. Here, we report that global changes in 5hmC mark chondrogenic differentiation in vivo and in vitro. Tibia anlagen and growth plate analyses during limb development at mouse embryonic days E 11.5, 13.5, and 17.5 showed dynamic changes in 5hmC levels in the differentiating chondrocytes. A similar increase in 5hmC levels was observed in the ATDC5 chondroprogenitor cell line accompanied by increased expression of the TET proteins during in vitro differentiation. Loss of TET1 in ATDC5 decreased 5hmC levels and impaired differentiation, demonstrating a functional role for TET1-mediated 5hmC dynamics in chondrogenic differentiation. Global analyses of the 5hmC-enriched sequences during early and late chondrogenic differentiation identified 5hmC distribution to be enriched in the regulatory regions of genes preceding the transcription start site (TSS), as well as in the gene bodies. Stable gains in 5hmC were observed in specific subsets of genes, including genes associated with cartilage development and in chondrogenic lineage-specific genes. 5hmC gains in regulatory promoter and enhancer regions as well as in gene bodies were strongly associated with activated but not repressed genes, indicating a potential regulatory role for DNA hydroxymethylation in chondrogenic gene expression.

Project description:The mechanism responsible for developmental stage-specific regulation of ?-globin gene expression involves DNA methylation. Previous results have shown that the ?-globin promoter is nearly fully demethylated during fetal liver erythroid differentiation and partially demethylated during adult bone marrow erythroid differentiation. The hypothesis that 5-hydroxymethylcytosine (5 hmC), a known intermediate in DNA demethylation pathways, is involved in demethylation of the ?-globin gene promoter during erythroid differentiation was investigated by analyzing levels of 5-methylcytosine (5 mC) and 5 hmC at a CCGG site within the 5' ?-globin gene promoter region in FACS-purified cells from baboon bone marrow and fetal liver enriched for different stages of erythroid differentiation. Our results show that 5 mC and 5 hmC levels at the ?-globin promoter are dynamically modulated during erythroid differentiation with peak levels of 5 hmC preceding and/or coinciding with demethylation. The Tet2 and Tet3 dioxygenases that catalyze formation of 5 hmC are expressed during early stages of erythroid differentiation and Tet3 expression increases as differentiation proceeds. In baboon CD34+ bone marrow-derived erythroid progenitor cell cultures, ?-globin expression was positively correlated with 5 hmC and negatively correlated with 5 mC at the ?-globin promoter. Supplementation of culture media with Vitamin C, a cofactor of the Tet dioxygenases, reduced ?-globin promoter DNA methylation and increased ?-globin expression when added alone and in an additive manner in combination with either DNA methyltransferase or LSD1 inhibitors. These results strongly support the hypothesis that the Tet-mediated 5 hmC pathway is involved in developmental stage-specific regulation of ?-globin expression by mediating demethylation of the ?-globin promoter.

Project description:Tet-enzyme-mediated 5-hydroxymethylation of cytosines in DNA plays a crucial role in mouse embryonic stem cells (ESCs). In RNA also, 5-hydroxymethylcytosine (5hmC) has recently been evidenced, but its physiological roles are still largely unknown. Here we show the contribution and function of this mark in mouse ESCs and differentiating embryoid bodies. Transcriptome-wide mapping in ESCs reveals hundreds of messenger RNAs marked by 5hmC at sites characterized by a defined unique consensus sequence and particular features. During differentiation a large number of transcripts, including many encoding key pluripotency-related factors (such as Eed and Jarid2), show decreased cytosine hydroxymethylation. Using Tet-knockout ESCs, we find Tet enzymes to be partly responsible for deposition of 5hmC in mRNA. A transcriptome-wide search further reveals mRNA targets to which Tet1 and Tet2 bind, at sites showing a topology similar to that of 5hmC sites. Tet-mediated RNA hydroxymethylation is found to reduce the stability of crucial pluripotency-promoting transcripts. We propose that RNA cytosine 5-hydroxymethylation by Tets is a mark of transcriptome flexibility, inextricably linked to the balance between pluripotency and lineage commitment.

Project description:BackgroundDNA methylation is an epigenetic mechanism essential for gene regulation and vital for mammalian development. 5-hydroxymethylcytosine (5hmC) is the first oxidative product of the TET-mediated 5-methylcytosine (5mC) demethylation pathway. Aside from being a key intermediate in cytosine demethylation, 5hmC may have potential regulatory functions with emerging importance in mammalian biology.MethodsHere, we investigate the global 5hmC enrichment in five brain structures, including cerebellum, cerebral cortex, hippocampus, hypothalamus and thalamus, as well as liver tissues from female and male adult mice by using chemical capture-based technique coupled with next-generation sequencing. At the same time, we carried out total RNA sequencing (RNA-seq) to analyze the transcriptomes of brain regions and liver tissues.ResultsOur results reveal preferential 5hmC enrichment in the gene bodies of expressed genes, and 5hmC levels of many protein-coding genes are positively correlated with RNA expression intensity. However, more than 75% of genes with low or no 5hmC enrichment are genes encode for mitochondrial proteins and ribosomal proteins despite being actively transcribed, implying different transcriptional regulation mechanisms of these housekeeping genes. Brain regions developed from the same embryonic structures have more similar 5hmC profiles. Also, the genic 5hmC enrichment pattern is highly tissue-specific, and 5hmC marks genes involving in tissue-specific biological processes. Sex chromosomes are mostly depleted of 5hmC, and the X inactive specific transcript (Xist) gene located on the X chromosome is the only gene to show sex-specific 5hmC enrichment.ConclusionsThis is the first report of the whole-genome 5hmC methylome of five major brain structures and liver tissues in mice of both sexes. This study offers a comprehensive resource for future work of mammalian cytosine methylation dynamics. Our findings offer additional evidence that suggests 5hmC is an active epigenetic mark stably maintained after the global reprogramming event during early embryonic development.

Project description:Although global erasure of DNA methylation has been observed in zygotes and primordial germ cells, the responsible enzyme(s) have been elusive. The demonstration that members of the Tet (ten eleven translocation) family of proteins are capable of catalyzing conversion of 5-methylcytosine (5mC) of DNA to 5-hydroxymethylcytosine (5hmC) raises the possibility that Tet proteins may participate in this process. Indeed, recent studies have implicated the involvement of Tet3 in the conversion of 5mC to 5hmC in zygotes. This result, combined with the demonstration that Tet proteins can further oxidize 5hmC to 5-carboxylcytosine followed by excision by thymine-DNA glycosylase, raises the possibility that active demethylation may take place in a process that involves Tet3-mediated oxidation followed by base excision repair. We demonstrated by immunostaining of mitotic chromosome spreads of preimplantation embryos that the 5hmC associated with the paternal genome in zygotes is gradually lost during preimplantation development. Our study suggests that, although the conversion of 5mC to 5hmC in zygotes is an enzyme-catalyzed process, loss of 5hmC during preimplantation appears to be a DNA replication-dependent passive process.