Shared role for differentially methylated domains of imprinted genes

For most imprinted genes, a difference in expression between the maternal and paternal alleles is associated with a corresponding difference in DNA methylation that is localized to a differentially methylated domain (DMD). Removal of a gene's DMD leads to a loss of imprinting. These observations suggest that DMDs have a determinative role in genomic imprinting. To examine this possibility, we introduced sequences from the DMDs of the imprinted Igf2r, H19, and Snrpn genes into a nonimprinted derivative of the normally imprinted RSVIgmyc transgene, created by excising its own DMD. Hybrid transgenes with sequences from the Igf2r DMD2 were consistently imprinted, with the maternal allele being more methylated than the paternal allele. Only the repeated sequences within DMD2 were required for imprinting these transgenes. Hybrid transgenes containing H19 and Snrpn DMD sequences and ones containing sequences from the long terminal repeat of a murine intracisternal A particle retrotransposon were not imprinted. The Igf2r hybrid transgenes are comprised entirely of mouse genomic DNA and behave as endogenous imprinted genes in inbred wild-type and mutant mouse strains. These types of hybrid transgenes can be used to elucidate the functions of DMD sequences in genomic imprinting.     

Unregulated expression of the imprinted genes H19 and Igf2r in mouse uniparental fetuses.

The present study shows that the H19 and Igf2r genes, which are imprinted and expressed solely from maternal alleles, are expressed in an unregulatable manner in mouse uniparental, androgenetic, and parthenogenetic fetuses at day 9.5 of gestation. In the androgenetic fetuses, the H19 and Igf2r genes were respectively expressed at 12 and 40% of the levels in biparental fetuses. In addition, the expression of both genes was excessive (1259 and 482%, respectively) in the parthenotes. These expressions of the imprinted genes were not regulated by methylation in the regulatory regions. Moreover, the expression of the antisense Igf2r RNA (Air) was also excessive and was not correlated with Igf2r gene expression in the uniparental fetuses. Taken together, these results indicate that the parental specific expression of imprinted genes is not maintained in particular genes in uniparental embryos, which in turn suggests that both parental genomes are required to establish maternal specific expression of the H19 and Igf2r genes by trans-acting mechanisms.     

Germ line-specific programming of parental genomes for development

Parental genomes have reciprocal phenotypic effects during development in the mouse because they are programmed (imprinted) with germ line-specific epigenetic modifications. These epigenetic modifications are inherited after fertilisation and they determine whether the maternal or the paternal allele of an 'imprinted' gene is expressed. Four such imprinted genes have so far been identified; the paternal genes of Igf2, and Snrpn, and the maternal genes of Igf2r and H19 are preferentially expressed during development. Igf2 and H19 are closely linked on chromosome 7 and show remarkably similar temporal and spatial patterns of expression. A mechanistic, and possibly a functional link may exist in the reciprocal imprinting of H19 and Igf2. The paternal H19 gene is apparently repressed by DNA methylation in the promoter region. This modification is not inherited from sperm but introduced after fertilisation. The nature of the primary germ line imprint therefore remains to be determined.     

Oppositely imprinted genes H19 and insulin-like growth factor 2 are coexpressed in human androgenetic trophoblast.

Human uniparental gestations such as gynogenetic ovarian teratomas and androgenetic complete hydatidiform moles provide a model to evaluate the integrity of parent-specific gene expression--i.e., imprinting--in the absence of a complementary parental genetic contribution. We studied expression, in these tissues, of the oppositely imprinted genes H19, which is an embryonic nontranslated RNA, and insulin-like growth factor type 2 (IGF2). Normal gestations only express H19 from the maternal allele and express IGF2 from the paternal allele, whereas neither is expressed from the maternal genome of gynogenetic gestations, and both are expressed from the paternal genome of androgenetic gestations. Coexpression of H19 and IGF2 in the androgenetic tissues was in a single population of cells, mononuclear trophoblast--the same cell type expressing these genes in biparental placentas. These results demonstrate that a biparental genome may be required for expression of the reciprocal IGF2/H19 imprint. Alternatively, biparental expression may be a normal feature of some imprinted genes in specific cell types. Additional experiments with other imprinted genes will clarify whether this reflects global failure of the imprinting process or a change specific to the IGF2/H19 locus.     

The imprinted mouse Igf2r/Air cluster--a model maternal imprinting system

Every diploid organism inherits a complete chromosome set from its father and mother in addition to the sex chromosomes, so that all autosomal genes are available in two copies. For most genes, both copies are expressed without preference. Imprinted genes, however, are expressed depending on their parental origin, being active on the paternal or maternal allele only. To date 73 imprinted genes are known in mouse (www.mgu.har.mrc.ac.uk/research/imprinting), 37 show paternal expression while 36 show maternal expression, indicating no bias for imprinting to occur in one sex or the other. Therefore, two different parental-specific imprinting systems may have evolved in mammals, acting specifically in the paternal or maternal gamete. Similarities and differences between the two imprinting systems will be reviewed, with specific reference to the role of non-coding RNAs and chromatin modifications. The mouse Igf2r/Air cluster is presented as a model of the maternal imprinting system.     

Dynamic readjustment of parental methylation patterns of the 5'-flank of the mouse H19 gene during in vitro organogenesis

Gametic marks are stably propagated in order to manifest parent of origin-specific expression patterns of imprinted genes in the developing conceptus. Although the character of the imprint has not yet been fully elucidated, there is compelling evidence that it involves a methylation mark. This is exemplified by a region upstream of the H19 gene, which is not only methylated in a parent of origin-specific manner, but also regulates the silencing of the maternal Igf2 and paternal H19 alleles, respectively. We show here that the parental-specific methylation patterns within the differentially methylated domain (DMD) are perturbed in the soma during in vitro organogenesis. Under these conditions, the paternal DMD allele becomes partially demethylated, whereas the maternal DMD allele gains methylation. Despite these effects, there were no changes in allelic Igf2 or H19 expression patterns in the embryo. Finally, we show that although TSA derepresses the paternal H19 allele in ectoplacental cone when in vitro developed, there is no discernible effect on the methylation status of the paternally inherited 5'-flank in comparison to control samples. Collectively, this data demonstrates that the parental mark is sensitive to a subset of environmental cues and that a certain degree of plasticity of the gametic mark is tolerated without affecting the manifestation of the imprinted state.     

Relationship between DNA methylation, histone H4 acetylation and gene expression in the mouse imprinted Igf2-H19 domain

DNA methylation and histone H4 acetylation play a role in gene regulation by modulating the structure of the chromatin. Recently, these two epigenetic modifications have dynamically and physically been linked. Evidence suggests that both modifications are involved in regulating imprinted genes - a subset of genes whose expression depends on their parental origin. Using immunoprecipitation assays, we investigate the relationship between DNA methylation, histone H4 acetylation and gene expression in the well-characterised imprinted Igf2-H19 domain on mouse chromosome 7. A systematic regional analysis of the acetylation status of the domain shows that parental-specific differences in acetylation of the core histone H4 are present in the promoter regions of both Igf2 and H19 genes, with the expressed alleles being more acetylated than the silent alleles. A correlation between DNA methylation, histone hypoacetylation and gene repression is evident only at the promoter region of the H19 gene. Treatment with trichostatin A, a specific inhibitor of histone deacetylase, reduces the expression of the active maternal H19 allele and this can be correlated with regional changes in acetylation within the upstream regulatory domain. The data suggest that histone H4 acetylation and DNA methylation have distinct functions on the maternal and paternal Igf2-H19 domains.     

Polycomb group proteins Ezh2 and Rnf2 direct genomic contraction and imprinted repression in early mouse embryos

Genomic imprinting regulates parental-specific expression of particular genes and is required for normal mammalian development. How imprinting is established during development is, however, largely unknown. To address this question, we studied the mouse Kcnq1 imprinted cluster at which paternal-specific silencing depends on expression of the noncoding RNA Kcnq1ot1. We show that Kcnq1ot1 is expressed from the zygote stage onward and rapidly associates with chromatin marked by Polycomb group (PcG) proteins and repressive histone modifications, forming a discrete repressive nuclear compartment devoid of RNA polymerase II, a configuration also observed at the Igf2r imprinted cluster. In this compartment, the paternal Kcnq1 cluster exists in a three-dimensionally contracted state. In vivo the PcG proteins Ezh2 and Rnf2 are independently required for genomic contraction and imprinted silencing. We propose that the formation of a parental-specific higher-order chromatin organization renders imprint clusters competent for monoallelic silencing and assign a central role to PcG proteins in this process.     

The use of chimeric mice in studying the effects of genomic imprinting

This is a review of the data of clonal analysis of developing tissues in parthenogenetic and androgenetic chimeric mice. The time and causes of death of the parthenogenetic and androgenetic cell clones in chimeras are considered. The data obtained suggest that the development of cell clones, derivatives of the mesoderm and endoderm, is determined by the expression of alleles of the imprinted loci of paternal chromosomes, while the formation of cell clones, derivatives of the ectoderm, depends on the expression of other imprinted loci of maternal chromosomes. The death of androgenetic and parthenogenetic (gynogenetic) mammalian embryos is due to the lack of the expression of certain imprinted loci of the maternal and paternal genome, respectively.     

Asb4, Ata3, and Dcn are novel imprinted genes identified by high-throughput screening using RIKEN cDNA microarray

Genes differentially expressed between parthenogenetic and androgenetic embryos are candidates for the identification of imprinted genes, which are expressed specifically from the maternal or paternal allele. To search for genes differentially expressed between parthenogenetic and androgenetic embryos, we used the RIKEN full-length enriched mouse cDNA microarray. The 25 candidates obtained included 8 known imprinted genes (such as IgfII, Snrpn, and Neuronatin) and 3 new ones--Asb4 (ankyrin repeat and SOCS box-containing protein 4), Ata3 (amino acid transport system A3), and Decorin--which were confirmed by using normal diploid embryos from the reciprocal F1 crosses of B6 and JF1 mice. The 25 candidates also included genes that showed no imprinting-associated expression in normal diploid embryos. We describe a feasible high-throughput method of screening for novel imprinted genes by using the RIKEN cDNA microarray.     

Use of chimeric mice for studying the effects of genomic imprinting

This is a review of the data of clonal analysis of developing tissues in parthenogenetic and androgenetic chimeric mice. The time and causes of death of the parthenogenetic and androgenetic cell clones in chimeras are considered. The data obtained suggest that the development of cell clones, derivatives of the mesoderm and endoderm, is determined by the expression of alleles of the imprinted loci of paternal chromosomes, while the formation of cell clones, derivatives of the ectoderm, depends on the expression of other imprinted loci of maternal chromosomes. The death of androgenetic and parthenogenetic (gynogenetic) mammalian embryos is due to the lack of the expression of certain imprinted loci of the maternal and paternal genome, respectively.     

Epigenetic regulation of Igf2/H19 imprinting at CTCF insulator binding sites

The mouse insulin-like growth factor II (Igf2) and H19 genes are located adjacent to each other on chromosome 7q11-13 and are reciprocally imprinted. It is believed that the allelic expression of these two genes is regulated by the binding of CTCF insulators to four parent-specific DNA methylation sites in an imprinting control center (ICR) located between these two genes. Although monoallelically expressed in peripheral tissues, Igf2 is biallelically transcribed in the CNS. In this study, we examined the allelic DNA methylation and CTCF binding in the Igf2/H19 imprinting center in CNS, hypothesizing that the aberrant CTCF binding as one of the mechanisms leads to biallelic expression of Igf2 in CNS. Using hybrid F1 mice (M. spretus males x C57BL/6 females), we showed that in CNS, CTCF binding sites in the ICR were methylated exclusively on the paternal allele, and CTCF bound only to the unmethylated maternal allele, showing no differences from the imprinted peripheral tissues. Among three other epigenetic modifications examined, histone H3 lysine 9 methylation correlated well with Igf2 allelic expression in CNS. These results suggest that CTCF binding to the ICR alone is not sufficient to insulate the Igf2 maternal promoter and to regulate the allelic expression of the gene in the CNS, thus challenging the aberrant CTCF binding as a common mechanism for lack of Igf2 imprinting in CNS. Further studies should be focused on the identification of factors that are involved in histone methylation and CTCF-associated factors that may be needed to coordinate Igf2 imprinting.     

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.     

Dnmt1 overexpression causes genomic hypermethylation, loss of imprinting, and embryonic lethality

Biallelic expression of Igf2 is frequently seen in cancers because Igf2 functions as a survival factor. In many tumors the activation of Igf2 expression has been correlated with de novo methylation of the imprinted region. We have compared the intrinsic susceptibilities of the imprinted region of Igf2 and H19, other imprinted genes, bulk genomic DNA, and repetitive retroviral sequences to Dnmt1 overexpression. At low Dnmt1 methyltransferase levels repetitive retroviral elements were methylated and silenced. The nonmethylated imprinted region of Igf2 and H19 was resistant to methylation at low Dnmt1 levels but became fully methylated when Dnmt1 was overexpressed from a bacterial artificial chromosome transgene. Methylation caused the activation of the silent Igf2 allele in wild-type and Dnmt1 knockout cells, leading to biallelic Igf2 expression. In contrast, the imprinted genes Igf2r, Peg3, Snrpn, and Grf1 were completely resistant to de novo methylation, even when Dnmt1 was overexpressed. Therefore, the intrinsic difference between the imprinted region of Igf2 and H19 and of other imprinted genes to postzygotic de novo methylation may be the molecular basis for the frequently observed de novo methylation and upregulation of Igf2 in neoplastic cells and tumors. Injection of Dnmt1-overexpressing embryonic stem cells in diploid or tetraploid blastocysts resulted in lethality of the embryo, which resembled embryonic lethality caused by Dnmt1 deficiency.     

Mechanisms of Igf2/H19 imprinting: DNA methylation, chromatin and long-distance gene regulation

The mouse Igf2 and H19 genes lie 70-kb apart on chromosome 7 and are reciprocally imprinted. Two regulatory regions are important for their parental allele-specific expression: a differentially methylated region (DMR) upstream of H19 and a set of tissue-specific enhancers downstream of H19. The enhancers specifically activate Igf2 on the paternal chromosome and H19 on the maternal chromosome. The interactions between the enhancers and the genes are regulated by the DMR, which works as a selector by exerting dual functions: a methylated DMR on the paternal chromosome inactivates adjacent H19 and an unmethylated DMR on the maternal chromosome insulates Igf2 from the enhancers. These processes appear to involve methyl-CpG-binding proteins, histone deacetylases and the formation of chromatin insulator complexes. The Igf2/H19 region provides a unique model in which to study the roles of DNA methylation and chromatin structure in the regulation of chromosome domains.