Project description:Silencing of young retrotransposons by Cytosine DNA methylation is essential for spermatogenesis. Failure to methylate retrotransposon promoters leads to their reactivation, meiotic catastrophe and infertility. How transposons become reactivated and why their reactivation follows spermatogenic developmental patterns remains unclear. Here, we show that specific retrotransposon families exhibit distinct expression patterns and chromatin landscapes throughout spermatogenesis when DNA methylation is absent from their promoters. We find a strong correlation between the loss of bivalent H3K4me3-H3K27me3 chromatin modifications and the transition from low retrotransposon expression in spermatogonia to reactivation in meiotic spermatocytes. Using a combination of DNA pulldowns, mass spectrometry and chromatin profiling by CUT&Tag, we identify the DNA methylation-sensitive transcription factor NRF1 as a potential regulator of unmethylated retrotransposons in spermatogenesis. Germline conditional ablation of Nrf1 reduced the upregulation of IAPs in the absence of DNA methylation and rescued the accumulation of IAP-derived Pol protein to wild type germ cell levels. Our study demonstrates that a combination of chromatin modifications and a DNA methylation-sensitive TF regulates young retrotransposons upon loss of repressive DNA methylation in germ cells, suggesting these interactions may be a core strategy used by retrotransposons to proliferate in the germline after evading silencing by DNA methylation.

Project description:Silencing of young retrotransposons by Cytosine DNA methylation is essential for spermatogenesis. Failure to methylate retrotransposon promoters leads to their reactivation, meiotic catastrophe and infertility. How transposons become reactivated and why their reactivation follows spermatogenic developmental patterns remains unclear. Here, we show that specific retrotransposon families exhibit distinct expression patterns and chromatin landscapes throughout spermatogenesis when DNA methylation is absent from their promoters. We find a strong correlation between the loss of bivalent H3K4me3-H3K27me3 chromatin modifications and the transition from low retrotransposon expression in spermatogonia to reactivation in meiotic spermatocytes. Using a combination of DNA pulldowns, mass spectrometry and chromatin profiling by CUT&Tag, we identify the DNA methylation-sensitive transcription factor NRF1 as a potential regulator of unmethylated retrotransposons in spermatogenesis. Germline conditional ablation of Nrf1 reduced the upregulation of IAPs in the absence of DNA methylation and rescued the accumulation of IAP-derived Pol protein to wild type germ cell levels. Our study demonstrates that a combination of chromatin modifications and a DNA methylation-sensitive TF regulates young retrotransposons upon loss of repressive DNA methylation in germ cells, suggesting these interactions may be a core strategy used by retrotransposons to proliferate in the germline after evading silencing by DNA methylation.

Project description:Silencing of young retrotransposons by Cytosine DNA methylation is essential for spermatogenesis. Failure to methylate retrotransposon promoters leads to their reactivation, meiotic catastrophe and infertility. How transposons become reactivated and why their reactivation follows spermatogenic developmental patterns remains unclear. Here, we show that specific retrotransposon families exhibit distinct expression patterns and chromatin landscapes throughout spermatogenesis when DNA methylation is absent from their promoters. We find a strong correlation between the loss of bivalent H3K4me3-H3K27me3 chromatin modifications and the transition from low retrotransposon expression in spermatogonia to reactivation in meiotic spermatocytes. Using a combination of DNA pulldowns, mass spectrometry and chromatin profiling by CUT&Tag, we identify the DNA methylation-sensitive transcription factor NRF1 as a potential regulator of unmethylated retrotransposons in spermatogenesis. Germline conditional ablation of Nrf1 reduced the upregulation of IAPs in the absence of DNA methylation and rescued the accumulation of IAP-derived Pol protein to wild type germ cell levels. Our study demonstrates that a combination of chromatin modifications and a DNA methylation-sensitive TF regulates young retrotransposons upon loss of repressive DNA methylation in germ cells, suggesting these interactions may be a core strategy used by retrotransposons to proliferate in the germline after evading silencing by DNA methylation.

Project description:In mammals, primordial germ cells (PGCs) undergo global erasure of DNA methylation with delayed demethylation of germline genes and selective retention of DNA methylation at young retrotransposons. However, the molecular mechanisms of persistent DNA methylation in PGCs remain unclear. Here we report that resistance to DNA methylation reprogramming in PGCs requires UHRF2, the paralog of the DNMT1 cofactor UHRF1. PGCs from Uhrf2 knock-out mice show loss of retrotransposon DNA methylation, while DNA methylation is unaffected in somatic cells of Uhrf2-/- mice. Furthermore, Uhrf2-deficient PGCs show precocious demethylation of germline genes and overexpress meiotic genes in females.

Project description:In mammals, primordial germ cells (PGCs) undergo global erasure of DNA methylation with delayed demethylation of germline genes and selective retention of DNA methylation at young retrotransposons. However, the molecular mechanisms of persistent DNA methylation in PGCs remain unclear. Here we report that resistance to DNA methylation reprogramming in PGCs requires UHRF2, the paralog of the DNMT1 cofactor UHRF1. PGCs from Uhrf2 knock-out mice show loss of retrotransposon DNA methylation, while DNA methylation is unaffected in somatic cells of Uhrf2-/- mice. Furthermore, Uhrf2-deficient PGCs show precocious demethylation of germline genes and overexpress meiotic genes in females.

Project description:In mammals, primordial germ cells (PGCs) undergo global erasure of DNA methylation with delayed demethylation of germline genes and selective retention of DNA methylation at young retrotransposons. However, the molecular mechanisms of persistent DNA methylation in PGCs remain unclear. Here we report that resistance to DNA methylation reprogramming in PGCs requires UHRF2, the paralog of the DNMT1 cofactor UHRF1. PGCs from Uhrf2 knock-out mice show loss of retrotransposon DNA methylation, while DNA methylation is unaffected in somatic cells of Uhrf2-/- mice. Furthermore, Uhrf2-deficient PGCs show precocious demethylation of germline genes and overexpress meiotic genes in females.

Project description:Mammalian genomes harbor millions of retrotransposon copies, some of which are transpositionally active. In mouse prospermatogonia, PIWI-interacting small RNAs called piRNAs combat retrotransposon activity. The piRNA system guides de novo DNA methylation at retrotransposon promoters, but it remains unclear whether DNA methylation is involved in retrotransposon silencing in prospermatogonia. We performed a genome-wide study of DNA methylation and RNA abundance for retrotransposons in developing mouse male germ cells, using Pld6/Mitopld and Dnmt3l knockout (KO) mice deficient in piRNA biogenesis and de novo DNA methylation, respectively. The Dnmt3l mutation greatly reduced DNA methylation at most retrotransposons but its effect on their RNA abundance was low in prospermatogonia. In the Pld6 mutants, only few retrotransposons exhibited reduced DNA methylation but many were more upregulated at the RNA level than in the Dnmt3l mutants. Moreover, the retrotransposon upregulation by the Pld6 mutation was observed even in the Dnmt3l KO background. Thus, in prospermatogonia, post-transcriptional RNA digestion by the piRNA system plays a more important role in retrotransposon regulation than transcriptional silencing by DNA methylation. However, their relative importance was changed in meiotic spermatocytes where hypomethylation of retrotransposons increased their expression by up to 100-fold in both mutants. Interestingly, retrotransposon activation disrupted the transcriptome integrity because intergenic and intronic retrotransposon sequences, in particular, the antisense promoter of LINE-1, drive expression of nearby genes.

Project description:Patterns of DNA methylation are established during gametogenesis. The catalytically-inactive adaptor Dnmt3L is crucial to ensure this occurs correctly. In vitro, Dnmt3L binds to the N terminal tail of histone H3 but the function of this interaction during development is unknown. Here we show that Dnmt3L-histone H3 interaction is necessary for spermatogenesis. Mutant animals exhibit reduced fertility, defective methylation establishment at retrotransposons coupled with their reactivation and meiotic catastrophe. The spermatogonial stem cell pool is also defective, with mutant cells displaying marked changes in gene expression. Genome-wide methylation analysis reveals reductions in CG methylation as well as severe loss of non-CG methylation suggesting that non-CG methylation is specifically sensitive to the ability of Dnmt3L to bind histone H3. MethylC-Seq of wild-type and Dnmt3LA/A 1dpp prospermatagonia

Project description:PIWI-associated RNAs (piRNAs) support germline by suppressing retrotransposons and genes. In mice, piRNAs are essential for spermatogenesis but not oogenesis. To test how this applies to other mammals, we deleted Mov10l1 helicase in golden hamsters whose piRNA pathway configuration is closer to other mammals than that of mice. Mov10l1–/– male hamsters showed impaired establishment of spermatogonia accompanied by transcriptome dysregulation and surge of MYSERV retrotransposon expression. The rare viable spermatogenic cells showed meiotic failure phenotype like Mov10l1–/– mice. Female Mov10l1–/–hamsters were sterile due to post-meiotic loss of developmental competence in zygotes. Unique phenotypes of Mov10l1–/– hamsters demonstrate adaptive nature of piRNA-mediated control of genes and retrotransposons, which enables confronting emerging genomic threats or acquiring new physiological roles.

Project description:PIWI-associated RNAs (piRNAs) support germline by suppressing retrotransposons and genes. In mice, piRNAs are essential for spermatogenesis but not oogenesis. To test how this applies to other mammals, we deleted Mov10l1 helicase in golden hamsters whose piRNA pathway configuration is closer to other mammals than that of mice. Mov10l1–/– male hamsters showed impaired establishment of spermatogonia accompanied by transcriptome dysregulation and surge of MYSERV retrotransposon expression. The rare viable spermatogenic cells showed meiotic failure phenotype like Mov10l1–/– mice. Female Mov10l1–/–hamsters were sterile due to post-meiotic loss of developmental competence in zygotes. Unique phenotypes of Mov10l1–/– hamsters demonstrate adaptive nature of piRNA-mediated control of genes and retrotransposons, which enables confronting emerging genomic threats or acquiring new physiological roles.