Project description:Among all mammalian cell types, sperm exhibit the highest level of DNA methylation, with approximately 70–80% of CpG sites being methylated. The role of this paternal hypermethylation in embryonic developmental competence, aside from the well-characterized H19-DMR and Dlk1-Dio3 intergenic germline DMR (IG-DMR) loci, remains largely unexplored. In mouse male germ cells, the lack of DNA methyltransferase (Dnmt) causes a loss of methylation, leading to meiotic catastrophe and infertility. To circumvent this limitation, we used sperm-like androgenetic haploid embryonic stem cells (AG-haESCs) for oocyte injection to produce offspring. Using CRISPR/Cas9, we effectively inactivated Dnmt1, Dnmt3a and Dnmt3b in AG-haESCs and later reactivated them in the resulting embryos, overcoming Dnmt haploinsufficiency and enabling the generation of viable offspring from methylation-deficient haploid cells. In the offspring embryos, the paternal genome derived from Dnmt-inactivated AG-haESCs rapidly reacquired methylation and restored a methylome in post-implantation embryos comparable to that of wild-type AG-haESC counterparts. These semi-cloned embryos could develop to term and survived to adulthood, exhibiting near-normal morphological and physiological parameters. These findings indicate that the functional significance of paternal genome methylation is mainly restricted to the imprinted loci Igf2-H19 and Dlk1-Dio3, while methylation of the paternal genome elsewhere appears dispensable for normal development.

Project description:Among all mammalian cell types, sperm exhibit the highest level of DNA methylation, with approximately 70–80% of CpG sites being methylated. The role of this paternal hypermethylation in embryonic developmental competence, aside from the well-characterized H19-DMR and Dlk1-Dio3 intergenic germline DMR (IG-DMR) loci, remains largely unexplored. In mouse male germ cells, the lack of DNA methyltransferase (Dnmt) causes a loss of methylation, leading to meiotic catastrophe and infertility. To circumvent this limitation, we used sperm-like androgenetic haploid embryonic stem cells (AG-haESCs) for oocyte injection to produce offspring. Using CRISPR/Cas9, we effectively inactivated Dnmt1, Dnmt3a and Dnmt3b in AG-haESCs and later reactivated them in the resulting embryos, overcoming Dnmt haploinsufficiency and enabling the generation of viable offspring from methylation-deficient haploid cells. In the offspring embryos, the paternal genome derived from Dnmt-inactivated AG-haESCs rapidly reacquired methylation and restored a methylome in post-implantation embryos comparable to that of wild-type AG-haESC counterparts. These semi-cloned embryos could develop to term and survived to adulthood, exhibiting near-normal morphological and physiological parameters. These findings indicate that the functional significance of paternal genome methylation is mainly restricted to the imprinted loci Igf2-H19 and Dlk1-Dio3, while methylation of the paternal genome elsewhere appears dispensable for normal development.

Project description:This SuperSeries is composed of the SubSeries listed below. Abstract Among all mammalian cell types, sperm cells exhibit one of the highest levels of DNA methylation, with ~80% of CpG sites being methylated. The role of this sperm hypermethylation in offspring development, aside from the methylation at the well-characterized H19-DMR and Dlk1-Dio3 intergenic germline DMR (IG-DMR) loci, remains largely unexplored. In mouse germ cells, removal of DNA methylation by deleting methyltransferase (Dnmt) genes causes meiotic catastrophe and infertility. To circumvent this limitation, we inactivated them instead in androgenetic haploid embryonic stem cells (AG-haESCs) lacking H19-DMR and IG-DMR to remove methylation prior to oocyte injection, and subsequently reactivated them in the resulting embryos during cleavage, to ensure Dnmt sufficiency. This strategy enabled the generation of viable offspring from unmethylated paternally-derived haploid cells. In the resulting embryos, the paternal genome rapidly reacquired methylation and was comparable to wild-type in post-implantation embryos. These semi-cloned embryos could develop to term and survived to adulthood, exhibiting near-normal morphological and physiological parameters. These findings indicate that the essential hereditary function of the paternal genome methylation is mainly restricted to the imprinted loci Igf2-H19 and Dlk1-Dio3, while methylation elsewhere appears dispensable for subsequent development, as de novo methylation activity intrinsic to the early embryo ensures epigenetic reprogramming for offspring development.

Project description:Our lab first derived mouse androgenetic haploid embryonic stem cells (AG-haESCs) and demonstrated that AG-haESCs can be used as an “artificial spermatids” to generate gene-edited semi-cloned (SC) mice through intracytoplasmic injection (ICAHCI) into mature oocyte, even though the birth efficiency is very low. Further we proved that H19-DMR and IG-DMR were the main barrier to generate viable mice through androgenetic and parthenogenetic haESCs. More importantly, AG-haESCs mediated SC technology combined with CRISPR-Cas9 is a powerful tool to generate gene-modified mouse models and carry out genetic screening at organismal level. However, it is still not clear how the H19-DMR and IG-DMR coordinately regulate SC embryo development. Here, we found that the H19-DMR and IG-DMR regulate the development of SC embryos in spatio-temporal scales. Firstly, we found that the H19-DMR and IG-DMR are not indispensable for the development of preimplantation of SC embryos. Secondly, H19-DMR is essential for the development of SC embryos in mid-gestation and IG-DMR takes effect in late-gestation. Further, the maintenance of paternal H19-DMR methylation status and deletion of paternal H19 transcription unit play a key role in the structures and transport functions of SC embryo placenta. Importantly, AG-haESCs carrying triple deletions, including H19, H19-DMR and IG-DMR, can further improve the efficiency in generation of viable, normal-size, and fertile mice.

Project description:The use of two inhibitors of Mek1/2 and Gsk3β (2i) promotes the generation of mouse diploid and haploid embryonic stem cells (ESCs) from the inner cell mass of biparental and uniparental blastocysts, respectively. However, a system enabling long-term maintenance of imprints in ESCs has proven challenging. Here, we report that usage of a two-step a2i (alternative two inhibitors of Src and Gsk3β, TSa2i) derivation/culture protocol results in the establishment of androgenetic haploid ESCs (AG-haESCs) with stable DNA methylation at paternal DMRs (differentially DNA methylated regions) up to passage 60 that can efficiently support generating mice upon oocyte injection. We also show coexistence of H3K9me3 marks and ZFP57 bindings with intact DMR methylations. Furthermore, we demonstrate that TSa2i-treated AG-haESCs are a heterogeneous cell population regarding paternal DMR methylation. Strikingly, AG-haESCs with late passages display increased paternal-DMR methylations and improved developmental potential compared to early-passage cells, in part through the enhanced proliferation of H19-DMR hypermethylated cells. Together, we establish AG-haESCs that can long-term maintain paternal imprints.

Project description:Imprinting at the Dlk1-Dio3 cluster is controlled by the IG-DMR, an imprinting control region differentially methylated between maternal and paternal chromosomes. The maternal IG-DMR is essential for imprinting control, functioning as a cis enhancer element. Meanwhile, DNA methylation at the paternal IG-DMR is thought to prevent enhancer activity. To explore whether suppression of enhancer activity at the methylated IG-DMR requires the transcriptional repressor TRIM28, we analyzed Trim28chatwo embryos and performed epistatic experiments with IG-DMR deletion mutants. We found that while TRIM28 regulates the enhancer properties of the paternal IG-DMR, it also controls imprinting through other mechanisms. Additionally, we found that the paternal IG-DMR, previously deemed dispensable for imprinting, is required in certain tissues, demonstrating that imprinting is regulated in a tissue-specific manner. Using ChRO-seq to analyze nascent transcription, we show that different tissues have a distinctive regulatory landscape at the Dlk1-Dio3 cluster, providing insight into potential mechanisms of tissue-specific imprinting control. ChRO-seq identified 30 novel transcribed regulatory elements, including a candidate regulatory region that depends on the paternal IG-DMR. Together, our findings challenge the model that Dlk1-Dio3 imprinting is regulated through a single mechanism and demonstrate that different tissues use distinct strategies for imprinting control.

Project description:Dysregulation of imprinted gene loci also referred to as loss of imprinting (LOI) can result in severe developmental defects and other diseases, but the molecular mechanisms that ensure imprint stability remain incompletely understood. Here, we dissect the functional components of the imprinting control region of the essential Dlk1-Dio3 locus (called IG-DMR) and the mechanism by which they ensure imprinting maintenance. Using pluripotent stem cells carrying an allele-specific reporter system, we demonstrate that the IG-DMR consists of two antagonistic regulatory elements: a paternally methylated CpG-island that prevents the activity of Tet dioxygenases and a maternally unmethylated regulatory element, which serves as a non-canonical enhancer and maintains expression of the maternal Gtl2 lncRNA by precluding de novo DNA methyltransferase function. Targeted genetic or epigenetic editing of these elements leads to LOI with either bi-paternal or bi-maternal expression patterns and respective allelic changes in DNA methylation and 3D chromatin topology of the entire Dlk1-Dio3 locus. Although the targeted repression of either IG-DMR or Gtl2 promoter is sufficient to cause LOI, the stability of LOI phenotype depends on the IG-DMR status, suggesting a functional hierarchy. These findings establish the IG-DMR as a novel type of bipartite control element and provide mechanistic insights into the control of Dlk1-Dio3 imprinting by allele-specific restriction of the active DNA (de)methylation machinery.

Project description:We report the DNA-methylation profiling of 10 regions selected from the DLK1-DIO3 domain on chromosome 14q32 in BM/PB samples from patients with acute promyelocytic leukaemia (APL), other subclasses of acute myeloid leukaemia and healthy donors, using high-throughput amplicon bisulfite sequencing with Roche 454 technology. We identify monoallelic-hypermethylation in APL only at the differentially methylated region (DMR) located upstream from the MEG3 gene (MEG3-DMR), whereas no changes in the DNA methylation profile were detected at the imprinting control region of the domain (IG-DMR) among the samples analysed. We show that the expression profile of 6 miRNAs clustered downstream from the MEG3-DMR correlates with the methylation profile at both DMRs. We demonstrate that miRNAs expression negatively correlates with DNA-methylation at the IG-DMR and MEG3 gene-body, whereas the correlation was positive for the CpGs located in the promoter of MEG3, including the binding sites for the insulator CTCF. We propose a loss of imprinting at the CTCF binding sites in patients with APL. These results are consistent with the previously reported DLK1-DIO3 miRNAs overexpression in APL, indicating a possible involvement of these ncRNAs in the pathogenesis of the disease. Investigation of the epigenetic regulation of the miRNAs clustered in 14q32 by next-generation sequencing

Project description:IG-DMR hypomethylation in Dlk1-Dio3 imprint locus mediates offspring hippocampal neurogenesis

Project description:Here, we establish a system to simultaneously inactivate Dnmts in one step through screening for base editors that can efficiently introduce a stop codon endogenously. Dnmt-null embryos display primitive streak elongation failure at E7.5. Interestingly, although DNA methylation is absent, gastrulation-related pathways are down-regulated in Dnmt-null embryos. Moreover, DNMT1 or DNMT3A/3B are indispensable for gastrulation and their functions are independent of TET proteins. Hypermethylation can be sustained by either DNMT1 or DNMT3A/3B at some promoters, which are mainly related to miRNAs. Strikingly, majority of hypermethylated promoter-related miRNAs are overexpressed and located at the Dlk1-Dio3 imprinted region. The predicted targets of these miRNAs tend to be down-regulated and enriched in the gastrulation-related pathways in Dnmt-null embryos. Finally, introduction of a single mutant allele of six miRNAs partially restores primitive streak elongation in Dnmt-null embryos.