Project description:The progression and transition between the naïve, formative, and primed pluripotent states are accompanied by a sharp activation of the de novo DNA methyltransferases and the reorganization of transcriptional and epigenetic landscapes. Here we identified Zinc Finger Protein 281 (ZFP281) as an essential factor in the formative-to-primed pluripotent state transition. Using a knockout mouse model and a knockin degron cell system, we revealed that transcription of Dnmt3a/3b depends on the activity of ZFP281 in embryonic stem cells, epiblast-like cells, and epiblast stem cells. Mechanically, chromatin-bound ZFP281 and DNA hydroxylase TET1 are decreased in the formative state but recovered in the primed state to compete with DNMT3A/3B for establishing the DNA methylation and gene expression programs of primed pluripotency. In addition, chromatin occupancy of ZFP281 and TET1 depend on the R-loop structures formed at the ZFP281 target gene promoters devoid of DNA methylation. Our study demonstrates a comprehensive role of ZFP281 in modulating DNA methylation and demethylation for the establishment and maintenance of primed pluripotency.

Project description:The progression and transition between the naïve, formative, and primed pluripotent states are accompanied by a sharp activation of the de novo DNA methyltransferases and the reorganization of transcriptional and epigenetic landscapes. Here we identified Zinc Finger Protein 281 (ZFP281) as an essential factor in the formative-to-primed pluripotent state transition. Using a knockout mouse model and a knockin degron cell system, we revealed that transcription of Dnmt3a/3b depends on the activity of ZFP281 in embryonic stem cells, epiblast-like cells, and epiblast stem cells. Mechanically, chromatin-bound ZFP281 and DNA hydroxylase TET1 are decreased in the formative state but recovered in the primed state to compete with DNMT3A/3B for establishing the DNA methylation and gene expression programs of primed pluripotency. In addition, chromatin occupancy of ZFP281 and TET1 depend on the R-loop structures formed at the ZFP281 target gene promoters devoid of DNA methylation. Our study demonstrates a comprehensive role of ZFP281 in modulating DNA methylation and demethylation for the establishment and maintenance of primed pluripotency.

Project description:The progression and transition between the naïve, formative, and primed pluripotent states are accompanied by a sharp activation of the de novo DNA methyltransferases and the reorganization of transcriptional and epigenetic landscapes. Here we identified Zinc Finger Protein 281 (ZFP281) as an essential factor in the formative-to-primed pluripotent state transition. Using a knockout mouse model and a knockin degron cell system, we revealed that transcription of Dnmt3a/3b depends on the activity of ZFP281 in embryonic stem cells, epiblast-like cells, and epiblast stem cells. Mechanically, chromatin-bound ZFP281 and DNA hydroxylase TET1 are decreased in the formative state but recovered in the primed state to compete with DNMT3A/3B for establishing the DNA methylation and gene expression programs of primed pluripotency. In addition, chromatin occupancy of ZFP281 and TET1 depend on the R-loop structures formed at the ZFP281 target gene promoters devoid of DNA methylation. Our study demonstrates a comprehensive role of ZFP281 in modulating DNA methylation and demethylation for the establishment and maintenance of primed pluripotency.

Project description:The mammalian TET dioxygenases contribute to global waves of DNA demethylation in the zygote and in primordial germ cells, but their involvement during de novo DNA methylation at peri/post-implantation development is unknown. Here, we show novel physiological functions of Tet1 in the pre-primitive streak stage mouse embryo, where it is expressed not only in the primed-state epiblast, but also in the extra-embryonic ectoderm. In the epiblast, Tet1 contributes to DNA methylation patterning, which indirectly results in dominant transcriptional repression involving a Jumonji-family gene Jmjd8. In the extra-embryonic ectoderm, Tet1 suppresses expression of metabolic genes involved in oxidative phosphorylation. These lineage-specific gene repressive functions, involving distinct modes of regulation by DNA methylation, counteract precocious differentiation of the embryo prior to the onset of gastrulation. Such dysregulation in the absence of Tet1 are surprisingly tolerated in an inbred strain but results in full embryonic lethality in non-inbred mice, thus implicating a complex but essential role of Tet1 in normal gestational development.

Project description:The mammalian TET dioxygenases contribute to global waves of DNA demethylation in the zygote and in primordial germ cells, but their involvement during de novo DNA methylation at peri/post-implantation development is unknown. Here, we show novel physiological functions of Tet1 in the pre-primitive streak stage mouse embryo, where it is expressed not only in the primed-state epiblast, but also in the extra-embryonic ectoderm. In the epiblast, Tet1 contributes to DNA methylation patterning, which indirectly results in dominant transcriptional repression involving a Jumonji-family gene Jmjd8. In the extra-embryonic ectoderm, Tet1 suppresses expression of metabolic genes involved in oxidative phosphorylation. These lineage-specific gene repressive functions, involving distinct modes of regulation by DNA methylation, counteract precocious differentiation of the embryo prior to the onset of gastrulation. Such dysregulation in the absence of Tet1 are surprisingly tolerated in an inbred strain but results in full embryonic lethality in non-inbred mice, thus implicating a complex but essential role of Tet1 in normal gestational development.

Project description:The mammalian TET dioxygenases contribute to global waves of DNA demethylation in the zygote and in primordial germ cells, but their involvement during de novo DNA methylation at peri/post-implantation development is unknown. Here, we show novel physiological functions of Tet1 in the pre-primitive streak stage mouse embryo, where it is expressed not only in the primed-state epiblast, but also in the extra-embryonic ectoderm. In the epiblast, Tet1 contributes to DNA methylation patterning, which indirectly results in dominant transcriptional repression involving a Jumonji-family gene Jmjd8. In the extra-embryonic ectoderm, Tet1 suppresses expression of metabolic genes involved in oxidative phosphorylation. These lineage-specific gene repressive functions, involving distinct modes of regulation by DNA methylation, counteract precocious differentiation of the embryo prior to the onset of gastrulation. Such dysregulation in the absence of Tet1 are surprisingly tolerated in an inbred strain but results in full embryonic lethality in non-inbred mice, thus implicating a complex but essential role of Tet1 in normal gestational development. This dataset includes the WGBS/oxWGBS: Methylation and hydroxymethylation profiling of epiblast-like cells (EpiLCs) in presence or absence of TET1. Whole genome bisulfite sequencing and oxidative whole genome bisulfite sequencing were performed on two wt EpiLCs (male) and two TET1 knock-out EpiLCs (one male and one female).

Project description:DNA methylation is the net result of deposition by DNA methyltransferases (DNMT1, 3A and 3B) and removal by the Ten-Eleven Translocation 1-3 (TET1-3) family of proteins and/or passive loss by replication. The relative contribution of the individual enzymes and pathways is only partially understood. Here we comprehensively analyzed and mathematically simulated the dynamics of DNA de-methylation during the reprogramming of the hypermethylated serum-cultured mouse embryonic stem cells (ESCs) to the hypomethylated 2i-cultured ground state of mESC. We show that DNA demethylation readily occurs in TET[1-/-, 2-/-] ESCs with similar kinetics as their WT littermates. Vitamin C activation of TET causes accelerated and more profound DNA demethylation without markedly affecting reprogramming kinetics. We developed a mathematical model that highly accurately predicts the global level of 5methyl- and 5hydroxymethylcytosine during the transition. Modeling and experimental validation show that the concentration of DNMT3A and DNMT3B determines the steady state level of global DNA methylation and absence of DNMT3A/B even in continued presence of DNMT1 results in gradual loss of 5mC. Taken together, DNMT1 alone is insufficient to maintain DNA methylation but requires the action of DNMT3A/3B that act as a “dimmer switches”.

Project description:DNA methylation is the net result of deposition by DNA methyltransferases (DNMT1, 3A and 3B) and removal by the Ten-Eleven Translocation 1-3 (TET1-3) family of proteins and/or passive loss by replication. The relative contribution of the individual enzymes and pathways is only partially understood. Here we comprehensively analyzed and mathematically simulated the dynamics of DNA de-methylation during the reprogramming of the hypermethylated serum-cultured mouse embryonic stem cells (ESCs) to the hypomethylated 2i-cultured ground state of mESC. We show that DNA demethylation readily occurs in TET[1-/-, 2-/-] ESCs with similar kinetics as their WT littermates. Vitamin C activation of TET causes accelerated and more profound DNA demethylation without markedly affecting reprogramming kinetics. We developed a mathematical model that highly accurately predicts the global level of 5methyl- and 5hydroxymethylcytosine during the transition. Modeling and experimental validation show that the concentration of DNMT3A and DNMT3B determines the steady state level of global DNA methylation and absence of DNMT3A/B even in continued presence of DNMT1 results in gradual loss of 5mC. Taken together, DNMT1 alone is insufficient to maintain DNA methylation but requires the action of DNMT3A/3B that act as a “dimmer switches”.

Project description:DNA methylation is the net result of deposition by DNA methyltransferases (DNMT1, 3A and 3B) and removal by the Ten-Eleven Translocation 1-3 (TET1-3) family of proteins and/or passive loss by replication. The relative contribution of the individual enzymes and pathways is only partially understood. Here we comprehensively analyzed and mathematically simulated the dynamics of DNA de-methylation during the reprogramming of the hypermethylated serum-cultured mouse embryonic stem cells (ESCs) to the hypomethylated 2i-cultured ground state of mESC. We show that DNA demethylation readily occurs in TET[1-/-, 2-/-] ESCs with similar kinetics as their WT littermates. Vitamin C activation of TET causes accelerated and more profound DNA demethylation without markedly affecting reprogramming kinetics. We developed a mathematical model that highly accurately predicts the global level of 5methyl- and 5hydroxymethylcytosine during the transition. Modeling and experimental validation show that the concentration of DNMT3A and DNMT3B determines the steady state level of global DNA methylation and absence of DNMT3A/B even in continued presence of DNMT1 results in gradual loss of 5mC. Taken together, DNMT1 alone is insufficient to maintain DNA methylation but requires the action of DNMT3A/3B that act as a “dimmer switches”.

Project description:Pluripotent cell identity comprises a spectrum of cell states including naive and primed states, which are typified by mouse embryonic stem cells (ESCs) and epiblast-derived stem cells (EpiSCs), respectively. Here we define a pluripotent cell fate (PCF) gene signature based on RNA-seq analysis associated with naive and primed pluripotency acquisition, and identify Zfp281 as a key transcriptional regulator for primed pluripotency and also as a barrier to achieve the naive pluripotency of both mouse and human ESCs. RNA sequencing analysis was performed in WT and Zfp281 null mouse embryonic stem cells under different pluripotent culture conditions. RNA-seq Experiments were carry out in two biological replciates. Genome binding/occupancy profiling of Zfp281 was performed in mouse embryonic stem cells by ChIP sequencing.