Establishment of paternal allele-specific DNA methylation at the imprinted mouse Gtl2 locus

The monoallelic expression of imprinted genes is controlled by epigenetic factors including DNA methylation and histone modifications. In mouse, the imprinted gene Gtl2 is associated with two differentially methylated regions: the IG-DMR, which serves as a gametic imprinting mark at which paternal allele-specific DNA methylation is inherited from sperm, and the Gtl2-DMR, which acquires DNA methylation on the paternal allele after fertilization. The timeframe during which DNA methylation is acquired at secondary DMRs during post-fertilization development and the relationship between secondary DMRs and imprinted expression have not been well established. In order to better understand the role of secondary DMRs in imprinting, we examined the methylation status of the Gtl2-DMR in pre- and post-implantation embryos. Paternal allele-specific DNA methylation of this region correlates with imprinted expression of Gtl2 during post-implantation development but is not required to implement imprinted expression during pre-implantation development, suggesting that this secondary DMR may play a role in maintaining imprinted expression. Furthermore, our developmental profile of DNA methylation patterns at the Cdkn1c- and Gtl2-DMRs illustrates that the temporal acquisition of DNA methylation at imprinted genes during post-fertilization development is not universally controlled.     

CTCF elements direct allele-specific undermethylation at the imprinted H19 locus

The H19 imprinted gene locus is regulated by an upstream 2 kb imprinting control region (ICR) that influences allele-specific expression, DNA methylation, and replication timing. This ICR becomes de novo methylated during late spermatogenesis in the male but emerges from oogenesis in an unmethylated form, and this allele-specific pattern is then maintained throughout early development and in all tissues of the mouse. We have used a genetic approach involving transfection into embryonic stem (ES) cells in order to decipher how the maternal allele is protected from de novo methylation at the time of implantation. Our studies show that CCCTC binding factor (CTCF) boundary elements within the ICR have the ability to prevent de novo methylation on the maternal allele. Since CTCF does not recognize its binding sequence when methylated, this reaction does not occur on the paternal allele, thus preserving the gamete-derived, allele-specific pattern. These results suggest that CTCF may play a general role in the maintenance of differential methylation patterns in vivo.     

The ontogeny of allele-specific methylation associated with imprinted genes in the mouse.

We have investigated the DNA methylation patterns in genomically imprinted genes of the mouse. Both Igf2 and H19 are associated with clear-cut regions of allele-specific paternal modification in late embryonic and adult tissues. By using a sensitive PCR assay, it was possible to follow the methylation state of individual HpaII sites in these genes through gametogenesis and embryogenesis. Most of these CpG moieties are not differentially modified in the mature gametes and also become totally demethylated in the early embryo in a manner similar to non-imprinted endogenous genes. Thus, the overall allele-specific methylation pattern at these sites must be established later during embryogenesis after the blastula stage. In contrast, sites in an Igf2r gene intron and one CpG residue in the Igf2 upstream region have allele-specific modification patterns which are established either in the gametes or shortly after fertilization and are preserved throughout pre-implantation embryogenesis. These studies suggest that only a few DNA modifications at selective positions in imprinted genes may be candidates for playing a role in the maintenance of parental identity during development.     

Antagonism between DNA and H3K27 methylation at the imprinted Rasgrf1 locus

At the imprinted Rasgrf1 locus in mouse, a cis-acting sequence controls DNA methylation at a differentially methylated domain (DMD). While characterizing epigenetic marks over the DMD, we observed that DNA and H3K27 trimethylation are mutually exclusive, with DNA and H3K27 methylation limited to the paternal and maternal sequences, respectively. The mutual exclusion arises because one mark prevents placement of the other. We demonstrated this in five ways: using 5-azacytidine treatments and mutations at the endogenous locus that disrupt DNA methylation; using a transgenic model in which the maternal DMD inappropriately acquired DNA methylation; and by analyzing materials from cells and embryos lacking SUZ12 and YY1. SUZ12 is part of the PRC2 complex, which is needed for placing H3K27me3, and YY1 recruits PRC2 to sites of action. Results from each experimental system consistently demonstrated antagonism between H3K27me3 and DNA methylation. When DNA methylation was lost, H3K27me3 encroached into sites where it had not been before; inappropriate acquisition of DNA methylation excluded normal placement of H3K27me3, and loss of factors needed for H3K27 methylation enabled DNA methylation to appear where it had been excluded. These data reveal the previously unknown antagonism between H3K27 and DNA methylation and identify a means by which epigenetic states may change during disease and development.     

A bipartite element with allele-specific functions safeguards DNA methylation imprints at the Dlk1-Dio3 locus

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Regulation of imprinted DNA methylation

DNA methylation is an essential enzymatic modification in mammals. This common epigenetic mark occurs predominantly at the fifth carbon of cytosines within the palindromic dinucleotide 5'-CpG-3'. The majority of methylated CpGs are located within repetitive elements including centromeric repeats, satellite sequences and gene repeats encoding ribosomal RNAs. CpG islands, frequently located at the 5' end of genes, are typically unmethylated. DNA methylation also occurs at imprinted genes which exhibit parent-of-origin-specific patterns of methylation and expression. Imprinted methylation at differentially methylated domains (DMDs) is one of the regulatory mechanisms controlling the allele-specific expression of imprinted genes. Proper control of DNA methylation is needed for normal development and loss of methylation control can contribute to initiation and progression of tumorigenesis (reviewed in Plass and Soloway, 2002). Because patterns of imprinted DNA methylation are highly reproducible, imprinted loci make useful models for studying regulation of DNA methylation and may provide insights into how this regulation goes awry in cancer. Here, we review what is currently known about the mechanisms regulating imprinted DNA methylation. We will focus on cis-acting DNA sequences, trans-acting protein factors and the possible involvement of RNAs in control of imprinted DNA methylation.     

ZFP57: KAPturing DNA methylation at imprinted loci

In this issue of Molecular Cell, Quenneville et al. (2011) characterize the role of ZFP57 in the maintenance of DNA methylation at imprinting control regions (ICRs), revealing an allele-specific binding pattern, binding motif, and interactions with other epigenetic regulators.     

Maternal and paternal alleles exhibit differential histone methylation and acetylation at maize imprinted genes

Imprinting is an epigenetically controlled form of gene regulation in which the expression of a gene is based on its parent of origin. This epigenetic regulation is likely to involve allele-specific DNA or histone modifications. The relative abundance of eight different histone modifications was tested at various regions in several imprinted maize (Zea mays) genes using a chromatin immunoprecipitation protocol coupled with quantitative allele-specific single nucleotide polymorphism assays. Histone H3 lysine-27 di- and tri-methylation are paternally enriched at the imprinted loci Mez1, ZmFie1 and Nrp1. In contrast, acetylation of histones H3 and H4 and H3K4 dimethylation are enriched at the maternal alleles of these genes. Di- and tri-methylation of H3 lysine-9, which is generally associated with constitutively silenced chromatin, was not enriched at either allele of imprinted loci. These patterns of enrichment were specific to tissues that exhibit imprinting. In addition, the enrichment of these modifications was dependent upon the parental origin of an allele and not sequence differences between the alleles, as demonstrated by reciprocal crosses. This study presents a detailed view of the chromatin modifications that are associated with the maternal and paternal alleles at imprinted loci and provides evidence for common histone modifications at multiple imprinted loci.     

Non-imprinted allele-specific DNA methylation on human autosomes

Background  

Differential DNA methylation between alleles is well established in imprinted genes and the X chromosomes in females but has rarely been reported at non-imprinted loci on autosomes.     

Aberrant regulation of imprinted gene expression in Gtl2lacZ mice

The imprinted region on mouse distal chromosome 12 covers about 1 Mb and contains at least three paternally expressed genes (Pegs: Peg9/Dlk1, Peg11/Rtl1, and Dio3) and four maternally expressed genes (Megs: Meg3/Gtl2, antiPeg11/antiRlt1, Meg8/Rian, and Meg9/Mirg). Gtl2(lacZ) (Gene trap locus 2) mice have a transgene (TG) insertion 2.3 kb upstream from the Meg3/Gtl2 promoter and show about 40% growth retardation when the TG-inserted allele is paternally derived. Quantitative RT-PCR experiments showed that the expression levels of Pegs in this region were reduced below 50%. These results are consistent with the observed phenotype in Gtl2lacZ mice, because at least two Pegs(Peg9/Dlk1 and Dio3) have growth-promoting effects. The aberrant induction of Megs from silent paternal alleles was also observed in association with changes in the DNA methylation level of a differentially methylated region (DMR) located around Meg3/Gtl2 exon 1. Interestingly, a 60 approximately 80% reduction in all Megs was observed when the TG was maternally derived, although the pups showed no apparent growth or morphological abnormalities. Therefore, the paternal or maternal inheritance of the TG results in the down-regulation in cis of either Pegs or Megs, respectively, suggesting that the TG insertion influences the mechanism regulating the entire imprinted region.     

Allele-specific histone lysine methylation marks regulatory regions at imprinted mouse genes

In different eukaryotic model systems, chromatin and gene expression are modulated by post-translational modification of histone tails. In this in vivo study, histone methylation and acetylation are investigated along the imprinted mouse genes Snrpn, Igf2r and U2af1-rs1. These imprinted genes all have a CpG-rich regulatory element at which methylation is present on the maternal allele, and originates from the female germ line. At these 'differentially methylated regions' (DMRs), histone H3 on the paternal allele has lysine-4 methylation and is acetylated. On the maternally inherited allele, in contrast, chromatin is marked by hypermethylation on lysine-9 of H3. Allele-specific patterns of lysine-4 and lysine-9 methylation are also detected at other regions of the imprinted loci. For the DMR at the U2af1-rs1 gene, we establish that the methyl-CpG-binding-domain (MBD) proteins MeCP2, MBD1 and MBD3 are associated with the maternal allele. These data support the hypothesis that MBD protein-associated histone deacetylase/chromatin-remodelling complexes are recruited to the parental allele that has methylated DNA and H3-K9 methylation, and are prevented from binding to the opposite allele by H3 lysine-4 methylation.     

Alternative splicing and imprinting control of the Meg3/Gtl2-Dlk1 locus in mouse embryos

The distal part of the mouse Chr 12 contains a cluster of reciprocally imprinted genes. Recently we found a grandparental origin-dependent, transmission-ratio distortion (TRD) in this region. The TRD resulted from postimplantation loss of embryos that inherited the distal Chr 12 alleles from the maternal grandfather. These data suggested that imprinting of one or more genes in this region was not uniformly well established or maintained in all the embryos. To elucidate the mechanism underlying such a variation, we examined the expression of two genes from the distal Chr 12 imprinted region, the maternally expressed gene 3/gene-trap locus 2 ( Meg3/ Gtl2), and the delta-like homolog 1 ( Dlk1) gene. We demonstrated that the Meg3/ Gtl2 gene had two major mRNA forms. One form, Meg3-proximal ( Meg3p), contained exons 1-3. The second form, Meg3-distal ( Meg3d) did not contain exons 1-3 and was present in oocytes and in 1- and 2-cell embryos. We observed cross-dependent and splice form-specific relaxation of imprinting of the Dlk1 and Meg3d, but not Meg3p. Expression patterns of Dlk1 and Meg3/ Gtl2 in embryos from crosses between different mouse strains suggest that 1). imprinting of the Dlk1 and Meg3/ Gtl2 genes is not strictly coordi- nated; 2). parental origin-dependent expression of these genes is under control of a strain-specific, cis-acting modifier located in a 1.5-Mb region that includes the Meg3/ Gtl2-Dlk1 locus. Biallelic expression of Dlk1 and Meg3d did not affect embryo viability and, therefore, cannot be responsible for the lethal phenotypes in UPD12 embryos or for the transmission-ratio distortion.     

Timing of establishment of paternal methylation imprints in the mouse

Imprinted genes are characterized by predominant expression from one parental allele and differential DNA methylation. Few imprinted genes have been found to acquire a methylation mark in the male germ line, however, and only one of these, H19, has been studied in detail. We examined methylation of the Rasgrf1 and Gtl2 differentially methylated regions (DMR) to determine whether methylation is erased in male germ cells at e12.5 and when the paternal allele acquires methylation. We also compared their methylation dynamics with those of H19 and the maternally methylated gene Snrpn. Our results show that methylation is erased on Rasgrf1, H19, and Snrpn at e12.5, but that Gtl2 retains substantial methylation at this stage. Erasure of methylation marks on Gtl2 appears to occur later in female germ cells to give the unmethylated profile seen in mature MII oocytes. In the male germ line, de novo methylation of Rasgrf1, Gtl2, and H19 occurs in parallel between e12.5 and e17.5, but the DMR are not completely methylated until the mature sperm stage, suggesting a methylation dynamic different from that of IAP, L1, and minor satellite sequences, which have been shown to become fully methylated by e17.5 in male germ cells. This study also indicates important differences between different imprinted DMR in timing and extent of methylation in the germ cells.