Project description:The oocyte epigenome plays critical roles in mammalian gametogenesis and embryogenesis. Yet, how it is established remains elusive. Here, we report that histone-lysine N-methyltransferase SETD2, an H3K36me3 methyltransferase, is a crucial regulator of the mouse oocyte epigenome. Deficiency in Setd2 leads to extensive alterations of the oocyte epigenome, including the loss of H3K36me3, failure in establishing the correct DNA methylome, invasion of H3K4me3 and H3K27me3 into former H3K36me3 territories and aberrant acquisition of H3K4me3 at imprinting control regions instead of DNA methylation. Importantly, maternal depletion of SETD2 results in oocyte maturation defects and subsequent one-cell arrest after fertilization. The preimplantation arrest is mainly due to a maternal cytosolic defect, since it can be largely rescued by normal oocyte cytosol. However, chromatin defects, including aberrant imprinting, persist in these embryos, leading to embryonic lethality after implantation. Thus, these data identify SETD2 as a crucial player in establishing the maternal epigenome that in turn controls embryonic development.

Project description:The oocyte epigenome plays critical roles in mammalian gametogenesis and embryogenesis. Yet, how it is established remains elusive. Here, we report that histone-lysine N-methyltransferase SETD2, an H3K36me3 methyltransferase, is a crucial regulator of the mouse oocyte epigenome. Deficiency in Setd2 leads to extensive alterations of the oocyte epigenome, including the loss of H3K36me3, failure in establishing the correct DNA methylome, invasion of H3K4me3 and H3K27me3 into former H3K36me3 territories and aberrant acquisition of H3K4me3 at imprinting control regions instead of DNA methylation. Importantly, maternal depletion of SETD2 results in oocyte maturation defects and subsequent one-cell arrest after fertilization. The preimplantation arrest is mainly due to a maternal cytosolic defect, since it can be largely rescued by normal oocyte cytosol. However, chromatin defects, including aberrant imprinting, persist in these embryos, leading to embryonic lethality after implantation. Thus, these data identify SETD2 as a crucial player in establishing the maternal epigenome that in turn controls embryonic development.

Project description:This SuperSeries is composed of the following subset Series: GSE24646: h3k36me3-Establishing a reference epigenome in arabidopsis seedlings GSE24647: h3k9me2-Establishing a reference epigenome in arabidopsis seedlings GSE24648: h3k4me2-Establishing a reference epigenome in arabidopsis seedlings GSE24649: h3k4me3-Establishing a reference epigenome in arabidopsis seedlings GSE24650: h3k9me3-Establishing a reference epigenome in arabidopsis seedlings GSE24651: h3k27me3-Establishing a reference epigenome in arabidopsis seedlings GSE24652: h3k27me2-Establishing a reference epigenome in arabidopsis seedlings GSE24653: h3k56ac-Establishing a reference epigenome in arabidopsis seedlings GSE24654: h4k20me1-Establishing a reference epigenome in arabidopsis seedlings GSE24655: h3-Establishing a reference epigenome in arabidopsis seedlings GSE24656: h2bub-Establishing a reference epigenome in arabidopsis seedlings GSE24657: h3k27me3_gw-Establishing a reference epigenome in arabidopsis seedlings GSE24658: h3k4me3_gw-Establishing a reference epigenome in arabidopsis seedlings GSE24659: h3k4me2_gw-Establishing a reference epigenome in arabidopsis seedlings GSE24660: 5mc_gw-Establishing a reference epigenome in arabidopsis seedlings GSE24661: h3k36me3_gw-Establishing a reference epigenome in arabidopsis seedlings GSE24662: h3k27me1_gw-Establishing a reference epigenome in arabidopsis seedlings GSE24663: h3_gw-Establishing a reference epigenome in arabidopsis seedlings GSE24664: h3k27me3_roots_gw-Establishing a reference epigenome in arabidopsis seedlings GSE24665: h3k4me3_roots_gw-Establishing a reference epigenome in arabidopsis seedlings Refer to individual Series

Project description:SETD2 is the specific methyltransferase of H3K36me3. To obtain SETD2-dependent landscape of H3K36me3 in human genome, we performed ChIP sequencing in SETD2 silenced and control HepG2 cells.

Project description:SETD2 regulates the maternal epigenome, genomic imprinting and embryonic development

Project description:SETD2 is the specific methyltransferase of H3K36me3, while METTL3, METTL14 and WTAP are the components of m6A methyltransferase complex. To understand the global effect of H3K36me3 on m6A modification, we compared the m6A profiling in SETD2 and METTL3, METTL14 or WTAP knockdown HepG2 cells, and found depletion of H3K36me3 by SETD2 silencing globally reduced m6A in human transcriptome. What’s more, most of the SETD2-dependent hypomethylation sites also responded to knockdown of METTL3, METTL14, or WTAP.

Project description:Faithful maintenance of genomic imprinting is essential for mammalian development. While germline DNA methylation-dependent (canonical) imprinting is relatively stable during development, the recently discovered oocyte-derived H3K27me3-mediated noncanonical imprinting is mostly transient in early embryos with only a few genes maintain imprinted expression in the extraembryonic lineage. How these few noncanonical imprinted genes maintain their extraembryonic-specific imprinting is unknown. Here we report that maintenance of extraembryonic-specific noncanonical imprinting requires maternal allele-specific de novo DNA methylation (secondary differentially methylation regions; DMRs) at implantation. The secondary DMRs are located at the gene promoters with paternal allele-specific H3K4me3 preformed during preimplantation development. Importantly, genetic ablation of Eed and DNA methyltransferases revealed that both maternal H3K27me3 and zygotic Dnmt3a/3b are required for establishing secondary DMRs and for maintaining noncanonical imprinting. Thus, our study not only reveals the mechanism underlying maintenance of noncanonical imprinting, but also sheds light on how histone modifications in oocytes and preimplantation embryos may shape the secondary DMRs in post-implantation embryos.

Project description:Eggs contain about 200,000 mitochondria that generate ATP and metabolites essential for oocyte and embryo development. In addition to this energetic role, mitochondria also integrate the cellular metabolic and transcriptional state via metabolites which regulate epigenetic modifiers. The maternal epigenome is established during oogenesis, but there is no direct evidence linking oocyte mitochondrial function to the maternal epigenome and embryo development. The DRP1 protein is required for mitochondrial fission. Here, we demonstrate a dramatic maternal effect in that DRP1-deficient oocytes fertilized by wild-type sperm exhibit a high frequency of failure in peri- and post-implantation development. This failure is associated with altered oocyte mitochondrial function, changes in the oocyte transcriptome and proteome, and a decrease in oocyte DNA methylation and H3K27me3. Transplanting the pronuclei of these fertilized oocytes to normal ooplasm fails to rescue embryonic lethality. We conclude that mitochondrial function plays a role in establishing the maternal epigenome, with serious consequences for embryo development.

Project description:Setd2 is the specific methyltransferase of H3K36me3. To obtain Setd2-dependent landscape of H3K36me3 in mouse genome, we used mouse embryonic stem cells (mESCs) model with doxycycline (Dox)-induced Setd2 knockdown, and performed ChIP sequencing in mESCs with or without Dox treatment.

Project description:Setd2 is the specific methyltransferase of H3K36me3. To understand the global effect of H3K36me3 on m6A modification, we used mouse embryonic stem cells (mESCs) model with doxycycline (Dox)-induced Setd2 knockdown, and performed m6A-IP followed by sequencing in mESCs with or without Dox treatment. We found that depletion of H3K36me3 by Setd2 silencing globally reduced m6A in mouse transcriptome.