Project description:The link between DNA methylation and neurodevelopmental disorders is well established. However, how DNA methylation is fine-tuned – ensuring precise gene expression and developmental fidelity – remains poorly understood. PROSER1, a known TET2 interactor, was recently linked to a severe neurodevelopmental disorder. Here, we demonstrate that PROSER1 interacts with all TET enzymes and stabilizes chromatin-bound TET-OGT-PROSER1-DBHS (TOPD) complexes, which regulate DNA demethylation and developmental gene expression. Surprisingly, we find that PROSER1 also sequesters TET enzymes, preventing widespread demethylation and transposable element de-repression. Our findings identify PROSER1 as a key factor which both positively and negatively regulates DNA demethylation essential for mammalian neurodevelopment.

Project description:The link between DNA methylation and neurodevelopmental disorders is well established. However, how DNA methylation is fine-tuned – ensuring precise gene expression and developmental fidelity – remains poorly understood. PROSER1, a known TET2 interactor, was recently linked to a severe neurodevelopmental disorder. Here, we demonstrate that PROSER1 interacts with all TET enzymes and stabilizes chromatin-bound TET-OGT-PROSER1-DBHS (TOPD) complexes, which regulate DNA demethylation and developmental gene expression. Surprisingly, we find that PROSER1 also sequesters TET enzymes, preventing widespread demethylation and transposable element de-repression. Our findings identify PROSER1 as a key factor which both positively and negatively regulates DNA demethylation essential for mammalian neurodevelopment.

Project description:DNA methylation at enhancers and CpG islands usually leads to gene repression, which is counteracted by DNA demethylation through the TET protein family. However, how TET enzymes are recruited and regulated at these genomic loci is not fully understood. Here, we identify TET2 and a previously undescribed proline and serine rich protein, PROSER1 as interactors of UTX, a component of the enhancer-associated MLL3/4 complexes. Affinity purification of PROSER1 resulted in the identification of OGT and TET1-3. We find that PROSER1 mediates the interaction between OGT and TET2, thus promoting TET2 O-GlcNAcylation and protein stability. Additionally, PROSER1, UTX, OGT, and TET1/2 colocalize on many genomic elements genome-wide. Loss of PROSER1 results in lower enrichment of UTX, and TET1/2 at enhancers and CpG islands, with a concomitant increase in DNA methylation and transcriptional downregulation of associated target genes and increased DNA hypermethylation encroachment at H3K4me1-predisposed CpG islands. Taken together, this study describes for the first time a regulator of TET2 O-GlcNAcylation and its implications in mediating DNA demethylation at UTX-dependent enhancers and CpG islands.

Project description:DNA methylation at enhancers and CpG islands usually leads to gene repression, which is counteracted by DNA demethylation through the TET protein family. However, how TET enzymes are recruited and regulated at these genomic loci is not fully understood. Here, we identify TET2 and a previously undescribed proline and serine rich protein, PROSER1 as interactors of UTX, a component of the enhancer-associated MLL3/4 complexes. Affinity purification of PROSER1 resulted in the identification of OGT and TET1-3. We find that PROSER1 mediates the interaction between OGT and TET2, thus promoting TET2 O-GlcNAcylation and protein stability. Additionally, PROSER1, UTX, OGT, and TET1/2 colocalize on many genomic elements genome-wide. Loss of PROSER1 results in lower enrichment of UTX, and TET1/2 at enhancers and CpG islands, with a concomitant increase in DNA methylation and transcriptional downregulation of associated target genes and increased DNA hypermethylation encroachment at H3K4me1-predisposed CpG islands. Taken together, this study describes for the first time a regulator of TET2 O-GlcNAcylation and its implications in mediating DNA demethylation at UTX-dependent enhancers and CpG islands.

Project description:DNA methylation at enhancers and CpG islands usually leads to gene repression, which is counteracted by DNA demethylation through the TET protein family. However, how TET enzymes are recruited and regulated at these genomic loci is not fully understood. Here, we identify TET2 and a previously undescribed proline and serine rich protein, PROSER1 as interactors of UTX, a component of the enhancer-associated MLL3/4 complexes. Affinity purification of PROSER1 resulted in the identification of OGT and TET1-3. We find that PROSER1 mediates the interaction between OGT and TET2, thus promoting TET2 O-GlcNAcylation and protein stability. Additionally, PROSER1, UTX, OGT, and TET1/2 colocalize on many genomic elements genome-wide. Loss of PROSER1 results in lower enrichment of UTX, and TET1/2 at enhancers and CpG islands, with a concomitant increase in DNA methylation and transcriptional downregulation of associated target genes and increased DNA hypermethylation encroachment at H3K4me1-predisposed CpG islands. Taken together, this study describes for the first time a regulator of TET2 O-GlcNAcylation and its implications in mediating DNA demethylation at UTX-dependent enhancers and CpG islands.

Project description:DNA methylation at enhancers and CpG islands usually leads to gene repression, which is counteracted by DNA demethylation through the TET protein family. However, how TET enzymes are recruited and regulated at these genomic loci is not fully understood. Here, we identify TET2 and a previously undescribed proline and serine rich protein, PROSER1 as interactors of UTX, a component of the enhancer-associated MLL3/4 complexes. Affinity purification of PROSER1 resulted in the identification of OGT and TET1-3. We find that PROSER1 mediates the interaction between OGT and TET2, thus promoting TET2 O-GlcNAcylation and protein stability. Additionally, PROSER1, UTX, OGT, and TET1/2 colocalize on many genomic elements genome-wide. Loss of PROSER1 results in lower enrichment of UTX, and TET1/2 at enhancers and CpG islands, with a concomitant increase in DNA methylation and transcriptional downregulation of associated target genes and increased DNA hypermethylation encroachment at H3K4me1-predisposed CpG islands. Taken together, this study describes for the first time a regulator of TET2 O-GlcNAcylation and its implications in mediating DNA demethylation at UTX-dependent enhancers and CpG islands.

Project description:Genome-wide DNA demethylation is a unique feature of mammalian development and naïve pluripotent stem cells. So far, it was unclear how mammals specifically achieve global DNA hypomethylation, given the high conservation of the DNA (de-)methylation machinery among vertebrates. We found that DNA demethylation requires TET activity but mostly occurs at sites where TET proteins are not bound suggesting a rather indirect mechanism. Among the few specific genes bound and activated by TET proteins was the naïve pluripotency and germline marker Dppa3 (Pgc7, Stella), which undergoes TDG dependent demethylation. The requirement of TET proteins for genome-wide DNA demethylation could be bypassed by ectopic expression of Dppa3. We show that DPPA3 binds and displaces UHRF1 from chromatin and thereby prevents the recruitment and activation of the maintenance DNA methyltransferase DNMT1. We demonstrate that DPPA3 alone can drive global DNA demethylation when transferred to amphibians (Xenopus) and fish (medaka), both species that naturally do not have a Dppa3 gene and exhibit no post-fertilization DNA demethylation. Our results show that TET proteins are responsible for active and - indirectly also for - passive DNA demethylation; while TET proteins initiate local and gene-specific demethylation in vertebrates, the recent emergence of DPPA3 introduced a unique means of genome-wide passive demethylation in mammals and contributed to the evolution of epigenetic regulation during early mammalian development.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:TET enzymes mediate DNA demethylation by oxidizing 5-methylcytosine (5mC) in DNA to 5-hydroxymethylcytosine (5hmC), 5-formylcytosine (5fC) and 5-carboxylcytosine (5caC). Because these oxidized methylcytosines (oxi-mC) are not recognized by the maintenance methyltransferase DNMT1, DNA demethylation can occur through “passive”, replication-dependent dilution as cells divide. A distinct, replication-independent (“active”) mechanism of DNA demethylation involves excision of 5fC and 5caC by the DNA repair enzyme thymine DNA glycosylase (TDG), followed by base excision repair. Here we used inducible gene-disrupted mice to show that TET enzymes influence both replication-dependent primary T cell differentiation and replication-independent macrophage differentiation, whereas TDG has no effect. Mice with long-term (1 year) deletion of Tdg are healthy and show normal survival and hematopoiesis. In summary, TET enzymes regulate differentiation and DNA demethylation primarily through passive dilution of oxidized methylcytosines in replicating T cells, and active, replication-independent DNA demethylation mediated by TDG does not appear to be essential for immune cell activation or differentiation.

Project description:TET enzymes mediate DNA demethylation by oxidizing 5-methylcytosine (5mC) in DNA to 5-hydroxymethylcytosine (5hmC), 5-formylcytosine (5fC) and 5-carboxylcytosine (5caC). Because these oxidized methylcytosines (oxi-mC) are not recognized by the maintenance methyltransferase DNMT1, DNA demethylation can occur through “passive”, replication-dependent dilution as cells divide. A distinct, replication-independent (“active”) mechanism of DNA demethylation involves excision of 5fC and 5caC by the DNA repair enzyme thymine DNA glycosylase (TDG), followed by base excision repair. Here we used inducible gene-disrupted mice to show that TET enzymes influence both replication-dependent primary T cell differentiation and replication-independent macrophage differentiation, whereas TDG has no effect. Mice with long-term (1 year) deletion of Tdg are healthy and show normal survival and hematopoiesis. In summary, TET enzymes regulate differentiation and DNA demethylation primarily through passive dilution of oxidized methylcytosines in replicating T cells, and active, replication-independent DNA demethylation mediated by TDG does not appear to be essential for immune cell activation or differentiation.