Dnmt1 binds and represses genomic retroelements via DNA methylation in mouse early embryos.

Genome-wide passive DNA demethylation in cleavage-stage mouse embryos is related to the cytoplasmic localization of the maintenance methyltransferase DNMT1. However, recent studies provided evidences of the nuclear localization of DNMT1 and its contribution to the maintenance of methylation levels of imprinted regions and other genomic loci in early embryos. Using the DNA adenine methylase identification method, we identified Dnmt1-binding regions in four- and eight-cell embryos. The unbiased distribution of Dnmt1 peaks in the genic regions (promoters and CpG islands) as well as the absence of a correlation between the Dnmt1 peaks and the expression levels of the peak-associated genes refutes the active participation of Dnmt1 in the transcriptional regulation of genes in the early developmental period. Instead, Dnmt1 was found to associate with genomic retroelements in a greatly biased fashion, particularly with the LINE1 (long interspersed nuclear elements) and ERVK (endogenous retrovirus type K) sequences. Transcriptomic analysis revealed that the transcripts of the Dnmt1-enriched retroelements were overrepresented in Dnmt1 knockdown embryos. Finally, methyl-CpG-binding domain sequencing proved that the Dnmt1-enriched retroelements, which were densely methylated in wild-type embryos, became demethylated in the Dnmt1-depleted embryos. Our results indicate that Dnmt1 is involved in the repression of retroelements through DNA methylation in early mouse development.

JHDM3A module as an effector molecule in guide-directed modification of target chromatin.

With the objective of returning cells to their undifferentiated state through alteration of epigenetic states, small molecules have been used that specifically inhibit proteins involved in sustaining the epigenetic system. However, this chemical-based approach can cause chaotic epigenomic states due to random actions of the inhibitors. We investigated whether JHDM3A/JMJD2A, a trimethylated histone H3-lysine 9 (H3K9me3)-specific demethylase, could function as an effector molecule to selectively demethylate target chromatin, with the aid of a guide protein to serve as a delivery vehicle. JHDM3A, which normally locates in euchromatin, spread out to heterochromatin when it was fused to heterochromatin protein-1α (HP1α) or HP1ß; in these cells, demethylation efficiency was also markedly increased. Two truncated modules, JHDM3A(GFP)(406) and JHDM3A(GFP)(701), had contrasting modes and efficiencies of H3K9me3 demethylation; JHDM3A(GFP)(406) showed a very uniform rate (∼80%) of demethylation, whereas JHDM3A(GFP)(701) had a broad methylation range of 4-80%. The methylation values were highly dependent on the presence of the guide proteins OCT4, CTCF, and HP1. Chromatin immunoprecipitation detected reduced H3K9me3 levels at OCT4 regulatory loci in the cells expressing OCT4-tagged JHDM3A(GFP)(701). Derepression of the Sox2 gene was observed in JHDM3A(GFP)(701)OCT4-expressing cells, but not in cells that expressed the JHDM3A(GFP)(701) module alone. JHDM3A(GFP)(701)-assisted OCT4 more efficiently turned on stem cell-related microRNAs than GFP-OCT4 itself. These results suggest that JHDM3A(GFP)(701) is a suitable catalytic module that can be targeted, under the control of a guide protein, to specific loci where the chromatin H3K9me3 status and the milieu of gene expression are to be modified.

Phosphorylation of serine-10 of histone H3 shields modified lysine-9 selectively during mitosis.

Post-translational modifications of histones play important roles in regulating chromatin dynamics and epigenetic inheritance during mitosis. The epigenetic significance and stability of histone H3-lysine 9 (H3K9) modifications have been well studied in interphase cells, whereas not as much in mitotic cells. Here, we inspected mitosis-coupled alterations in the global modifications of H3K9. Signals for H3K9 mono-, di-methylation and acetylation became invisible as cells entered mitosis in contrast to the pattern observed for H3-serine 10 phosphorylation (H3S10ph). Treatment with the aurora-B inhibitor ZM447439 or expression of the dominant negative mutant Aur-B(K106R) resulted in prometaphase chromosomes that lacked signals for H3S10ph but were positive for H3K9 modifications. Trimethylation was the sole K9 modification that remained consistently detectable throughout the cell cycle. This phenomenon was specific for H3K9-S10, as this pattern was not observed at H3K27-S28. Methylated H3K27 remained detectable throughout the cell cycle, despite phosphorylation of the adjacent H3S28. Contrastingly, our dot-blot experiment using synthetic peptides showed that phosphorylation of serine residue basically kept adjacent lysine from antibody access. Together, these results suggest that phosphorylation of serine residue occurs in a selective manner, being influenced by the types of modifications and the nature of neighboring lysine residues.

DNA methylation state is preserved in the sperm-derived pronucleus of the pig zygote.

DNA methylation reprogramming (DMR) during preimplantation development erases differentiation-associated, unessential epigenetic information accumulated during gametogenesis, and ultimately brings pluripotency to the resulting embryo. Two patterns of DMR of sperm-derived pronucleus have been reported in mammals. In the first, the male pronucleus is actively demethylated whereas in the second, the methylation state seems to be maintained. The maintenance-type DMR has been seen only through immunocytochemical observations, and waits to be proven by additional molecular-level evidence. We demonstrate that, in pig, paternally derived DNA methylation is preserved during pronucleus development, based on the following observations. First, immunostaining of pig zygotes at different time points showed the DNA methylation state to be balanced between parental pronuclei throughout pronucleus development. Second, bisulfite analysis of PRE-1 repetitive sequences found mono- and polyspermic eggs to have similar methylation states. Third, the methylation state of a human erythropoietin gene delivered by transgenic pig spermatozoa was maintained in the male pronucleus. Finally, 5-aza-2'-deoxycytidine treatment, which blocks re-methylation, did not show the male pronucleus to be stalled in a demethylated state. In pig zygotes, paternally derived cytosine methylation was preserved throughout pronucleus development. These findings from multilateral DMR analyses provide further support to the view that DMR occurs in a non-conserved manner during early mammalian development.

Assessment of difference in gene expression profile between embryos of different derivations.

Researchers have exerted sustained efforts to improve the viability of somatic cell nuclear transfer (SCNT) embryos, testing their experimental designs and probing the resultant embryos. However, the lack of a reliable method to estimate the efficacy of these experimental attempts is a chief hindrance to tackling the low-viability problem in SCNT. Here, we introduce a procedure that assesses the degree of difference in gene expression profiles (GEPs) of blastocysts from each other as a representative control of good quality. We first adapted a multiplex reverse transcription-polymerase chain reaction strategy to obtain GEPs for 15 reprogramming-related genes from single mouse blastocysts. GEPs of individual blastocysts displayed a broad range of variations, the extent of which was calculated using a weighted root mean square deviation (wRMSD). wRMSD-based quantitation of GEP difference (qGEP) found that GEP difference between in vivo-derived blastocysts (in vivo) and SCNT blastocysts was greater than the difference between in vivo blastocysts and in vitro-produced (IVP) blastocysts, demonstrating that the SCNT group was more distantly related to the in vivo group than the IVP group. Our qGEP approach for grading individual blastocysts would be useful for selecting a better protocol to derive embryos of better quality prior to field applications.

Cytoplasmic localization of oocyte-specific variant of porcine DNA methyltransferase-1 during early development.

DNA methyltransferase-1 (Dnmt1) is involved in the maintenance of genomic methylation patterns. Rather than full-length Dnmt1, mouse oocytes have a truncated variant called Dnmt1o. Immunofluorescence data showed that Dnmt1o localized to the cytoplasm, but this has not been confirmed using more direct methods. The cytoplasmic localization of Dnmt1o has been assigned to the main cause of global DNA demethylation in early mouse embryos. We studied localization of Dnmt1o in mouse and pig embryos. We identified pig Dnmt1o protein and its transcript with unique 5'-end sequence. Physically separating mouse and pig 2-cell embryos into their nuclear and cytoplasmic components demonstrated that Dnmt1o of both species localized to the cytoplasm. Cloned pig embryos had Dnmt1o as the main form, with no indication of somatic Dnmt1. These findings indicate that Dnmt1o is cytoplasmic during early development; its presence in both pig and mouse embryos further suggests that Dnmt1o is conserved in mammals.

Dynamic DNA methylation reprogramming: active demethylation and immediate remethylation in the male pronucleus of bovine zygotes.

DNA methylation reprogramming (DMR) is believed to be a key process by which mammalian zygotes gain nuclear totipotency through erasing epigenetic modifications acquired during gametogenesis. Nonetheless, DMR patterns do not seem to be conserved among mammals. To identify uniform rules underlying mammalian DMRs, we explored DMRs of diverse mammalian zygotes. Of the zygotes studied, of particular interest was the bovine zygote; the paternal DNA methylation first decreased and was then rapidly restored almost to the maternal methylation level even before the two-cell stage. The 5-azadeoxycytidine treatment led to complete demethylation of the male pronucleus. The unusually dramatic changes in DNA methylation levels indicate that the bovine male pronucleus undergoes active demethylation, which is followed by de novo methylation. Our results show that, in bovine, the compound processes of active DNA demethylation and de novo DNA methylation, along with de novo H3-K9 trimethylation also, take place altogether within this very narrow window of pronucleus development.

Gradual development of a genome-wide H3-K9 trimethylation pattern in paternally derived pig pronucleus.

The cytoplasm of a mature oocyte contains many protein complexes that are programmed to restructure incoming sperm chromatins on fertilization. Of the complicated biochemical events that these functional machineries control, the most impressive and important is epigenetic reprogramming. Despite its importance in epigenetic resetting, or "de-differentiation," of gamete genomes back to an incipient status, the mechanisms of epigenetic reprogramming do not seem to be conserved among mammals. Here, we report that, unlike in the mouse, the pig sperm-derived pronucleus is markedly trimethylated at lysine 9 of histone H3 (H3-m(3)K9), which might be associated with preservation of paternally derived cytosine methylation in pig zygotes. The male H3-m(3)K9 pattern is gradually established during pronucleus development, and this process occurs independently of DNA replication. Considering these unique epigenetic features, the pig zygote is, we believe, suited to serve as another model of epigenetic reprogramming that is antithetical to the well-characterized mouse model.