Project description:To study the role of tet3 and 5-hydroxymethylation in mouse intestine homeostasis our objectives are: To determine the cell types that show a 5hmC reduction level in the absence of Tet3. Identify the role of Tet3 on transcriptional regulation in the small intestinal epithelium. Define the physiological functions impaired in Tet3 -/- small intestine epithelium.

Project description:The methylcytosine dioxygenase Tet3 is highly expressed as a specific isoform in oocytes and zygotes but essentially absent from later stages of mouse preimplantation development. Here, we show that Tet3 expression promotes transdifferentiation of embryonic stem cells to trophoblast-like stem cells. By genome-wide analyses we demonstrate that TET3 associates with and co-occupies chromatin with RNA Polymerase II. Tet3 expression induces a global increase of transcription and total RNA levels, and its presence further enhances chromatin accessibility in regions open for transcription. This novel function of TET3 is not specific to the oocyte isoform, independent of its catalytic activity, the CXXC domain, or its interaction with OGT, and is localised in its highly conserved exon 4. We propose a more general role for TET3 promoting open chromatin and enhancing global transcription during changes of cellular identity, separate from its catalytic function.

Project description:Ten-eleven translocation (Tet) hydroxylases (Tet1-3) oxidize 5-methylcytosine (5mC) to 5-hydroxymethylcytosine (5hmC). In neurons increased 5hmC levels within gene bodies correlate positively with gene expression. The mechanisms controlling Tet activity and 5hmC levels are poorly understood. In particular, it is not known how the neuronal Tet3 isoform lacking a DNA binding domain is targeted to the DNA. To identify factors binding to Tet3 we screened for proteins that co-precipitate with Tet3 from mouse retina and identified the transcriptional repressor Rest as a highly enriched Tet3-specific interactor. Rest was able to enhance Tet3 hydroxylase activity after co-expression and overexpression of Tet3 activated transcription of Rest-target genes. Moreover, we found that Tet3 also interacts with Nsd3 and two other H3K36 methyltransferases and is able to induce H3K36 trimethylation. We propose a mechanism for transcriptional activation in neurons that involves Rest-guided targeting of Tet3 to the DNA for directed 5hmC-generation and Nsd3-mediated H3K36 trimethylation.

Project description:Tet3 is an Fe2+-dependent enzyme that oxidizes genomic 5-methylcytosine to 5-hydroxymethylcytosine with the help of alpha-ketoglutarate and oxygen. It is the most abundant Tet enzyme in differentiated tissues including brain. Adult brain contains the highest 5-hydroxymethylcytosine levels. How alpha-ketoglutarate is made available for the oxidation of mC in brain cells and how the Tet activity is linked to neural activity are unsolved questions. Our experiments with full mouse brains show that Tet3 interacts in the nucleus directly with selected enzymes of the mitochondrial citric acid cycle. This leads to the formation of isocitrate. Tet3 also interacts with aspartate aminotransferase, which produces oxaloacetate. Although oxaloacetate and isocitrate are biosynthetic alpha-ketoglutarate precursors, they function as inhibitors of Tet3 and are needed to protect the reactive Fe2+ center from degrading DNA. The supply of Tet3 with alpha-ketoglutarate is established by a direct interaction of Tet3 with glutamate dehydrogenase (Glud1), which converts the neurotransmitter glutamate directly into alpha-ketoglutarate. This links Tet3 function to neural activity.

Project description:Counter to the long-held belief that DNA methylation of terminally differentiated cells is permanent and essentially immutable, post-mitotic neurons exhibit extensive DNA demethylation. The causal role of active DNA demethylation in neurons, however, is not known. Tet family proteins oxidize 5-methylcytosine to initiate active DNA demethylation through the base-excision repair pathway. Here, we show that synaptic activity bi-directionally regulates neuronal Tet3 expression. Functionally, knockdown of Tet or inhibition of base-excision repair in hippocampal neurons elevates excitatory glutamatergic synaptic transmission, whereas overexpressing Tet3 or Tet1 catalytic domain decreases it. Furthermore, dysregulation of Tet3 signalling prevents homeostatic synaptic plasticity. Mechanistically, Tet3 dictates neuronal surface GluR1 levels. RNA-seq analyses further revealed a pivotal role of Tet3 in regulating gene expression in response to global synaptic activity changes. Thus, Tet3 serves as a synaptic activity sensor to epigenetically regulate basic properties and meta-plasticity of neurons via active DNA demethylation.

Project description:In this study: (1) we distinguished Tet3 target genes that are regulated by its catalytic vs. noncatalytic functions in neuroectoderm (NE) cells by transcriptomic profiling of Tet3 wildtype (WT), Tet3 catalytic mutant (Mut), and Tet3 knockout (KO) NE cells by RNA-seq. (2) We mapped genome-wide DNA methylation of Tet3-WT, Tet3-Mut, and Tet3-KO NE cells by WGBS. (3) We determined Tet3 genome-wide occupancy in Tet3-WT NE cells by CUT&Tag. (4) We mapped 5hmC rich regions in Tet3-WT, Tet3-Mut, and Tet3-KO NE cells by hmeDIP. (5) We overexpressed (OE) the Tet3 target gene Dnmt1 (D) or an empty vector (EV) in Tet3-WT, Tet3-Mut, and Tet3-KO NE cells and assessed gene expression by RNA-seq. (6) We overexpressed (OE) Tet3 (T) or an empty vector (EV) in Tet3-WT, Tet3-Mut, and Tet3-KO NE cells and examined gene expression changes in these cells by RNA-seq.

Project description:Dynamic DNA methylation and demethylation regulate gene expression during development. While DNA methyltransferases (DNMTs) establish and maintain cytosine methylation patterns, Ten-eleven translocation (Tet) dioxygenases catalyze sequential oxidation of 5-methylcytosine (5mC) to promote demethylation. Target-specific 5mC oxidation requires precise regulation of the Tet enzymatic activity. However, the mechanism underlying their activity control remains largely unexplored. Here we show a large low-complexity domain (LCD), present within the catalytic domain of Tet3, functions to repress the dioxygenase activity. Recombinant LCD-deleted Tet3 exhibits enhanced activity to convert 5mC into oxidized species. Deletion of the Tet3 LCD in mouse oocytes renders 5mC oxidation indiscriminately across the genome, leading to most prominently the derepression of ERVK retrotransposons and upregulation of adjacent genes. The extensive 5mC oxidation is associated with impairments in oocyte development. These findings suggest an intrinsic auto-regulatory mechanism of Tet3 dioxygenase operating to ensure a tight regulation of its enzymatic activity to achieve spatiotemporal specificity of methylome reprogramming during oocyte development.

Project description:Dynamic DNA methylation and demethylation regulate gene expression during development. While DNA methyltransferases (DNMTs) establish and maintain cytosine methylation patterns, Ten-eleven translocation (Tet) dioxygenases catalyze sequential oxidation of 5-methylcytosine (5mC) to promote demethylation. Target-specific 5mC oxidation requires precise regulation of the Tet enzymatic activity. However, the mechanism underlying their activity control remains largely unexplored. Here we show a large low-complexity domain (LCD), present within the catalytic domain of Tet3, functions to repress the dioxygenase activity. Recombinant LCD-deleted Tet3 exhibits enhanced activity to convert 5mC into oxidized species. Deletion of the Tet3 LCD in mouse oocytes renders 5mC oxidation indiscriminately across the genome, leading to most prominently the derepression of ERVK retrotransposons and upregulation of adjacent genes. The extensive 5mC oxidation is associated with impairments in oocyte development. These findings suggest an intrinsic auto-regulatory mechanism of Tet3 dioxygenase operating to ensure a tight regulation of its enzymatic activity to achieve spatiotemporal specificity of methylome reprogramming during oocyte development.

Project description:Dynamic DNA methylation and demethylation regulate gene expression during development. While DNA methyltransferases (DNMTs) establish and maintain cytosine methylation patterns, Ten-eleven translocation (Tet) dioxygenases catalyze sequential oxidation of 5-methylcytosine (5mC) to promote demethylation. Target-specific 5mC oxidation requires precise regulation of the Tet enzymatic activity. However, the mechanism underlying their activity control remains largely unexplored. Here we show a large low-complexity domain (LCD), present within the catalytic domain of Tet3, functions to repress the dioxygenase activity. Recombinant LCD-deleted Tet3 exhibits enhanced activity to convert 5mC into oxidized species. Deletion of the Tet3 LCD in mouse oocytes renders 5mC oxidation indiscriminately across the genome, leading to most prominently the derepression of ERVK retrotransposons and upregulation of adjacent genes. The extensive 5mC oxidation is associated with impairments in oocyte development. These findings suggest an intrinsic auto-regulatory mechanism of Tet3 dioxygenase operating to ensure a tight regulation of its enzymatic activity to achieve spatiotemporal specificity of methylome reprogramming during oocyte development.

Project description:TET proteins are tumor suppressors that through their catalytic activity oxidize 5-methylcytosine to 5-hydroxymethylcytosine, to promote DNA demethylation and to regulate gene expression. Notably, TET2 is the second most frequently mutated gene in hematological malignancies, including T cell lymphomas. However, murine models with deletion of TET2 do not exhibit T cell expansion, presumably due to redundancy with other members of the TET family of proteins. In order to gain insight on the TET mediated molecular events that safeguard T cells from aberrant proliferation we performed serial adoptive transfers of murine CD4 T cells that lack concomitantly TET2 and TET3 to fully immunocompetent congenic mice. Our data reveal a progressive acquisition of malignant traits upon loss of TET2 and TET3 that is characterized by loss of genomic integrity, acquisition of aneuploidy and upregulation of the protooncogene Myc.