Gametes are highly specialised cells that can give rise to the next generation through their ability to generate a totipotent zygote. In mouse, germ cells are first specified in the developing embryo as primordial germ cells (PGCs) starting around embryonic day (E) 6.251 (Fig. 1a). Following subsequent migration into the developing gonad, PGCs undergo a wave of extensive epigenetic reprogramming at E10.5/E11.52–11, including genome-wide loss of 5-methylcytosine (5mC)2–5,7–11 (Fig. 1a). The underlying molecular mechanisms of this process have remained enigmatic leading to our inability to recapitulate this step of germline development in vitro12–14. Using an integrative approach, we show that this complex reprogramming process involves the coordinated interplay between promoter sequence characteristics, DNA (de)methylation, Polycomb (PRC1) complex and both DNA demethylation-dependent and -independent functions of Tet1 to enable the activation of a critical set of germline reprogramming responsive (GRR) genes involved in gamete generation and meiosis. Our results also unexpectedly reveal a role for Tet1 in safeguarding but not driving DNA demethylation in gonadal PGCs. Collectively, our work uncovers a fundamental biological role for gonadal germline reprogramming and identifies the epigenetic principles of the PGC-to-gonocyte transition that will be instructive towards recapitulating complete gametogenesis in vitro.
Methylation at the 5 position of cytosine in DNA (5meC), is a key epigenetic mark in eukaryotes. Once introduced, 5meC can be maintained through DNA replication due to the activity of “maintenance” DNA methyltransferases.. Despite their ancient origin, DNA methylation pathways differ widely across metazoans, such that 5meC is either confined to transcribed genes or lost altogether in several lineages. Here we use comparative epigenomics to investigate the evolution of DNA methylation. Although the model nematode C. elegans has lost DNA methylation, more basal nematodes retain cytosine DNA methylation, targeted to repeat loci. Unexpectedly, we find that DNA methylation coevolves with the DNA alkylation repair enzyme ALKB2 across eukaryotes. We further show that DNA methyltransferases introduce the toxic lesion 3meC into DNA both in vitro and in vivo. Alkylation damage is thus intrinsically associated with DNA methyltransferase activity, and this may promote the loss of DNA methylation in many species.
BackgroundReactive oxygen species (ROS)-induced oxidative stress is well known to play a major role in male infertility. Sperm are sensitive to ROS damaging effects because as male germ cells form mature sperm they progressively lose the ability to repair DNA damage. However, how oxidative DNA lesions in sperm affect early embryonic development remains elusive.ResultsUsing cattle as model, we show that fertilization using sperm exposed to oxidative stress caused a major developmental arrest at the time of embryonic genome activation. The levels of DNA damage response did not directly correlate with the degree of developmental defects. The early cellular response for DNA damage, γH2AX, is already present at high levels in zygotes that progress normally in development and did not significantly increase at the paternal genome containing oxidative DNA lesions. Moreover, XRCC1, a factor implicated in the last step of base excision repair (BER) pathway, was recruited to the damaged paternal genome, indicating that the maternal BER machinery can repair these DNA lesions induced in sperm. Remarkably, the paternal genome with oxidative DNA lesions showed an impairment of zygotic active DNA demethylation, a process that previous studies linked to BER. Quantitative immunofluorescence analysis and ultrasensitive LC–MS-based measurements revealed that oxidative DNA lesions in sperm impair active DNA demethylation at paternal pronuclei, without affecting 5-hydroxymethylcytosine (5hmC), a 5-methylcytosine modification that has been implicated in paternal active DNA demethylation in mouse zygotes. Thus, other 5hmC-independent processes are implicated in active DNA demethylation in bovine embryos. The recruitment of XRCC1 to damaged paternal pronuclei indicates that oxidative DNA lesions drive BER to repair DNA at the expense of DNA demethylation. Finally, this study highlighted striking differences in DNA methylation dynamics between bovine and mouse zygotes that will facilitate the understanding of the dynamics of DNA methylation in early development.ConclusionsThe data demonstrate that oxidative stress in sperm has an impact not only on DNA integrity but also on the dynamics of epigenetic reprogramming, which may harm the paternal genetic and epigenetic contribution to the developing embryo and affect embryo development and embryo quality.Electronic supplementary materialThe online version of this article (10.1186/s13072-018-0224-y) contains supplementary material, which is available to authorized users.
The size and composition of dNTP (deoxyribonucleoside triphosphate) pools influence the accuracy of DNA synthesis and consequently the genetic stability of nuclear and mitochondrial genomes. In order to keep the dNTP pool in balance, the synthesis and degradation of DNA precursors must be precisely regulated. One such mechanism involves catabolic activities that convert deoxynucleoside triphosphates into their monophosphate form. Human cells possess an all-α NTP (nucleoside triphosphate) pyrophosphatase named DCTPP1 [dCTP pyrophosphatase 1; also known as XTP3-TPA (XTP3-transactivated protein A)]. In the present study, we provide an extensive characterization of this enzyme which is ubiquitously distributed in the nucleus, cytosol and mitochondria. Interestingly, we found that in addition to dCTP, methyl-dCTP and 5-halogenated nucleotides, DCTPP1 hydrolyses 5-formyl-dCTP very efficiently and with the lowest Km value described so far. Because the biological function of mammalian all-α NTP pyrophosphatases remains uncertain, we examined the role of DCTPP1 in the maintenance of pyrimidine nucleotide pools and cellular sensitivity to pyrimidine analogues. DCTPP1-deficient cells accumulate high levels of dCTP and are hypersensitive to exposure to the nucleoside analogues 5-iodo-2'-deoxycytidine and 5-methyl-2'-deoxycytidine. The results of the present study indicate that DCTPP1 has a central role in the balance of dCTP and the metabolism of deoxycytidine analogues, thus contributing to the preservation of genome integrity.
Summary Investigations of the human germline and programming are challenging because of limited access to embryonic material. However, the pig as a model may provide insights into transcriptional network and epigenetic reprogramming applicable to both species. Here we show that, during the pre- and early migratory stages, pig primordial germ cells (PGCs) initiate large-scale epigenomic reprogramming, including DNA demethylation involving TET-mediated hydroxylation and, potentially, base excision repair (BER). There is also macroH2A1 depletion and increased H3K27me3 as well as X chromosome reactivation (XCR) in females. Concomitantly, there is dampening of glycolytic metabolism genes and re-expression of some pluripotency genes like those in preimplantation embryos. We identified evolutionarily young transposable elements and gene coding regions resistant to DNA demethylation in acutely hypomethylated gonadal PGCs, with potential for transgenerational epigenetic inheritance. Detailed insights into the pig germline will likely contribute significantly to advances in human germline biology, including in vitro gametogenesis.
Decitabine (5-aza-2′-deoxycytidine, aza-dCyd) is an anti-cancer drug used clinically for the treatment of myelodysplastic syndromes and acute myeloid leukaemia that can act as a DNA-demethylating or genotoxic agent in a dose-dependent manner. On the other hand, DCTPP1 (dCTP pyrophosphatase 1) and dUTPase are two ‘house-cleaning’ nucleotidohydrolases involved in the elimination of non-canonical nucleotides. In the present study, we show that exposure of HeLa cells to decitabine up-regulates the expression of several pyrimidine metabolic enzymes including DCTPP1, dUTPase, dCMP deaminase and thymidylate synthase, thus suggesting their contribution to the cellular response to this anti-cancer nucleoside. We present several lines of evidence supporting that, in addition to the formation of aza-dCTP (5-aza-2′-deoxycytidine-5′-triphosphate), an alternative cytotoxic mechanism for decitabine may involve the formation of aza-dUMP, a potential thymidylate synthase inhibitor. Indeed, dUTPase or DCTPP1 down-regulation enhanced the cytotoxic effect of decitabine producing an accumulation of nucleoside triphosphates containing uracil as well as uracil misincorporation and double-strand breaks in genomic DNA. Moreover, DCTPP1 hydrolyses the triphosphate form of decitabine with similar kinetic efficiency to its natural substrate dCTP and prevents decitabine-induced global DNA demethylation. The data suggest that the nucleotidohydrolases DCTPP1 and dUTPase are factors involved in the mode of action of decitabine with potential value as enzymatic targets to improve decitabine-based chemotherapy.
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