Project description:In mammals, DNA methylation is rapidly re-established after implantation following global erasure in pre-implantation embryos, the regulation of which, however, is not completely understood. Here, by mapping H3K36me2 in pre- and post-implantation mouse embryos, we unravel the dynamic reprogramming of H3K36me2 in mouse early development and its role in post-implantation de novo DNA methylation. Parental H3K36me2 was progressively lost by the 8-cell stage, while de novo H3K36me2 was established at putative enhancers after ZGA mediated by histone acetylation, followed by genome-wide deposition after implantation. H3K36me2 was however excluded from the inactive X chromosome. Catalytic mutation of NSD1, the major H3K36me2 methyltransferase, compromised post-implantation development and DNA methylation re-establishment, with extra-embryonic lineages more severely affected than embryonic lineages. De novo DNA methylation establishment in embryonic lineages partially bypassed H3K36me2/3 through elevated DNMT3B expression. Mechanistically, the PWWP domain of DNMT3A, but not that of DNMT3B, confers strict requirement of H3K36me2/3 for DNA methylation, while DNMT3B is a “leaky” reader of H3K36 methylation. Nevertheless, germline-specific genes, including those contain CpG islands at promoters, still require H3K36me2 to be efficiently methylated and silenced. Amid global remethylation, DNA methylation valleys (DMVs) escape de novo DNA methylation, where PRC1 and H2AK119ub1 antagonize H3K36me2 invasion. Thus, reprogramming of H3K36me2 is required for early embryogenesis and regulates lineage- and locus-specific post-implantation DNA methylation establishment.

Project description:In mammals, DNA methylation is rapidly re-established after implantation following global erasure in pre-implantation embryos, the regulation of which, however, is not completely understood. Here, by mapping H3K36me2 in pre- and post-implantation mouse embryos, we unravel the dynamic reprogramming of H3K36me2 in mouse early development and its role in post-implantation de novo DNA methylation. Parental H3K36me2 was progressively lost by the 8-cell stage, while de novo H3K36me2 was established at putative enhancers after ZGA mediated by histone acetylation, followed by genome-wide deposition after implantation. H3K36me2 was however excluded from the inactive X chromosome. Catalytic mutation of NSD1, the major H3K36me2 methyltransferase, compromised post-implantation development and DNA methylation re-establishment, with extra-embryonic lineages more severely affected than embryonic lineages. De novo DNA methylation establishment in embryonic lineages partially bypassed H3K36me2/3 through elevated DNMT3B expression. Mechanistically, the PWWP domain of DNMT3A, but not that of DNMT3B, confers strict requirement of H3K36me2/3 for DNA methylation, while DNMT3B is a “leaky” reader of H3K36 methylation. Nevertheless, germline-specific genes, including those contain CpG islands at promoters, still require H3K36me2 to be efficiently methylated and silenced. Amid global remethylation, DNA methylation valleys (DMVs) escape de novo DNA methylation, where PRC1 and H2AK119ub1 antagonize H3K36me2 invasion. Thus, reprogramming of H3K36me2 is required for early embryogenesis and regulates lineage- and locus-specific post-implantation DNA methylation establishment.

Project description:DNA methylation plays essential roles in mammalian development. During post-implantation development, de novo establishment of DNA methylation is accomplished by DNA methyltransferases, in particular DNMT3A and DNMT3B. At present, the distinct functions of these two enzymes remain largely elusive. To comprehensively identify the target sites for de novo DNA methylation by the DNMT3 enzymes, we took advantage of female mouse ES cells established in the presence of MEK and Gsk3 inhibitors, which lack most DNA methylation (2i/L ES cells), in combination with genetic ablation of Dnmt3a or Dnmt3b. We analyzed de novo DNA methylation in mouse embryonic fibroblasts (2i-MEFs) derived from Dnmt3 knockout (KO) 2i/L ES cells. Both Dnmt3a and Dnmt3b KO 2i-MEFs exhibited a modest but global reduction in CpG methylation, which was particularly notable on the X chromosome in Dnmt3b KO cells. Although most genes were methylated similarly in both knockouts, we identified 355 and 333 uniquely unmethylated genes in Dnmt3a and Dnmt3b KO 2i-MEFs, respectively. Notably, Dnmt3a was exclusively required for de novo methylation at both TSS regions and gene bodies of Polycomb group (PcG) target developmental genes. Consistent with this, tissue-specific DNA methylation at PcG target developmental genes was substantially reduced in Dnmt3a KO embryos. Finally, we found that human patients with DNMT3A mutant acute myeloid leukemia (AML) or harboring DNMT3B mutation associated with immunodeficiency, centromere, and facial anomalies (ICF) syndrome exhibited reduced CpG methylation at regions that were hypomethylated in Dnmt3a or Dnmt3b KO 2i-MEFs, respectively. Collectively, our findings in DNA-hypomethylated 2i/L ES cells revealed a set of unique de novo DNA methylation target sites for both DNMT3 enzymes during mammalian development that overlap with hypomethylated sites in human patients.

Project description:We quantified the targets and kinetics of DNA methylation acquisition in mouse embryos, and determined the contribution of the de novo methyltransferases DNMT3A and DNMT3B to this process. We provide single-base maps of cytosine methylation by RRBS from the blastocysts to post-implantation stages and in embryos lacking DNMT3A or DNMT3B activity, and performed RNA-Seq in embryos lacking DNMT3B activity.

Project description:The correct establishment of DNA methylation patterns during mouse early development is essential for cell fate specification. However, the molecular targets as well as the mechanisms that determine the specificity of the de novo methylation machinery during differentiation are not completely elucidated. Here we show that the DNMT3B-dependent DNA methylation in epiblasts of key developmental regulatory regions provides an epigenetic priming that ensures flawless commitment at later stages. Using in vitro stem cell differentiation and loss of function experiments combined with high-throughput genome-wide bisulfite-, bulk-, and single cell RNA-sequencing, we dissected the specific role of DNMT3B in cell specification, we identified the DNMT3B-dependent regulatory elements on the genome which, in Dnmt3b knockout (3BKO), impair the differentiation into meso-endodermal (ME) progenitors and redirect epiblast-like cells (EpiLCs) towards the neuro-ectodermal lineages. Moreover, ectopic expression of DNMT3B in 3BKO re-establishes the DNA methylation of the master regulator Sox2 super-enhancer, down-modulates its expression, and restores the expression of ME markers. Taken together, our data reveal that DNMT3B-dependent methylation at the epiblast stage is essential for the priming of the meso-endodermal lineages and provide functional characterization of the de novo DNMTs during EpiLCs lineage determination.

Project description:The correct establishment of DNA methylation patterns during mouse early development is essential for cell fate specification. However, the molecular targets as well as the mechanisms that determine the specificity of the de novo methylation machinery during differentiation are not completely elucidated. Here we show that the DNMT3B-dependent DNA methylation in epiblasts of key developmental regulatory regions provides an epigenetic priming that ensures flawless commitment at later stages. Using in vitro stem cell differentiation and loss of function experiments combined with high-throughput genome-wide bisulfite-, bulk-, and single cell RNA-sequencing, we dissected the specific role of DNMT3B in cell specification, we identified the DNMT3B-dependent regulatory elements on the genome which, in Dnmt3b knockout (3BKO), impair the differentiation into meso-endodermal (ME) progenitors and redirect epiblast-like cells (EpiLCs) towards the neuro-ectodermal lineages. Moreover, ectopic expression of DNMT3B in 3BKO re-establishes the DNA methylation of the master regulator Sox2 super-enhancer, down-modulates its expression, and restores the expression of ME markers. Taken together, our data reveal that DNMT3B-dependent methylation at the epiblast stage is essential for the priming of the meso-endodermal lineages and provide functional characterization of the de novo DNMTs during EpiLCs lineage determination.

Project description:The correct establishment of DNA methylation patterns during mouse early development is essential for cell fate specification. However, the molecular targets as well as the mechanisms that determine the specificity of the de novo methylation machinery during differentiation are not completely elucidated. Here we show that the DNMT3B-dependent DNA methylation in epiblasts of key developmental regulatory regions provides an epigenetic priming that ensures flawless commitment at later stages. Using in vitro stem cell differentiation and loss of function experiments combined with high-throughput genome-wide bisulfite-, bulk-, and single cell RNA-sequencing, we dissected the specific role of DNMT3B in cell specification, we identified the DNMT3B-dependent regulatory elements on the genome which, in Dnmt3b knockout (3BKO), impair the differentiation into meso-endodermal (ME) progenitors and redirect epiblast-like cells (EpiLCs) towards the neuro-ectodermal lineages. Moreover, ectopic expression of DNMT3B in 3BKO re-establishes the DNA methylation of the master regulator Sox2 super-enhancer, down-modulates its expression, and restores the expression of ME markers. Taken together, our data reveal that DNMT3B-dependent methylation at the epiblast stage is essential for the priming of the meso-endodermal lineages and provide functional characterization of the de novo DNMTs during EpiLCs lineage determination.

Project description:The correct establishment of DNA methylation patterns during mouse early development is essential for cell fate specification. However, the molecular targets as well as the mechanisms that determine the specificity of the de novo methylation machinery during differentiation are not completely elucidated. Here we show that the DNMT3B-dependent DNA methylation in epiblasts of key developmental regulatory regions provides an epigenetic priming that ensures flawless commitment at later stages. Using in vitro stem cell differentiation and loss of function experiments combined with high-throughput genome-wide bisulfite-, bulk-, and single cell RNA-sequencing, we dissected the specific role of DNMT3B in cell specification, we identified the DNMT3B-dependent regulatory elements on the genome which, in Dnmt3b knockout (3BKO), impair the differentiation into meso-endodermal (ME) progenitors and redirect epiblast-like cells (EpiLCs) towards the neuro-ectodermal lineages. Moreover, ectopic expression of DNMT3B in 3BKO re-establishes the DNA methylation of the master regulator Sox2 super-enhancer, down-modulates its expression, and restores the expression of ME markers. Taken together, our data reveal that DNMT3B-dependent methylation at the epiblast stage is essential for the priming of the meso-endodermal lineages and provide functional characterization of the de novo DNMTs during EpiLCs lineage determination.

Project description:The correct establishment of DNA methylation patterns during mouse early development is essential for cell fate specification. However, the molecular targets as well as the mechanisms that determine the specificity of the de novo methylation machinery during differentiation are not completely elucidated. Here we show that the DNMT3B-dependent DNA methylation in epiblasts of key developmental regulatory regions provides an epigenetic priming that ensures flawless commitment at later stages. Using in vitro stem cell differentiation and loss of function experiments combined with high-throughput genome-wide bisulfite-, bulk-, and single cell RNA-sequencing, we dissected the specific role of DNMT3B in cell specification, we identified the DNMT3B-dependent regulatory elements on the genome which, in Dnmt3b knockout (3BKO), impair the differentiation into meso-endodermal (ME) progenitors and redirect epiblast-like cells (EpiLCs) towards the neuro-ectodermal lineages. Moreover, ectopic expression of DNMT3B in 3BKO re-establishes the DNA methylation of the master regulator Sox2 super-enhancer, down-modulates its expression, and restores the expression of ME markers. Taken together, our data reveal that DNMT3B-dependent methylation at the epiblast stage is essential for the priming of the meso-endodermal lineages and provide functional characterization of the de novo DNMTs during EpiLCs lineage determination.

Project description:The correct establishment of DNA methylation patterns during mouse early development is essential for cell fate specification. However, the molecular targets as well as the mechanisms that determine the specificity of the de novo methylation machinery during differentiation are not completely elucidated. Here we show that the DNMT3B-dependent DNA methylation in epiblasts of key developmental regulatory regions provides an epigenetic priming that ensures flawless commitment at later stages. Using in vitro stem cell differentiation and loss of function experiments combined with high-throughput genome-wide bisulfite-, bulk-, and single cell RNA-sequencing, we dissected the specific role of DNMT3B in cell specification, we identified the DNMT3B-dependent regulatory elements on the genome which, in Dnmt3b knockout (3BKO), impair the differentiation into meso-endodermal (ME) progenitors and redirect epiblast-like cells (EpiLCs) towards the neuro-ectodermal lineages. Moreover, ectopic expression of DNMT3B in 3BKO re-establishes the DNA methylation of the master regulator Sox2 super-enhancer, down-modulates its expression, and restores the expression of ME markers. Taken together, our data reveal that DNMT3B-dependent methylation at the epiblast stage is essential for the priming of the meso-endodermal lineages and provide functional characterization of the de novo DNMTs during EpiLCs lineage determination.