Epigenetic analysis of the Dlk1-Gtl2 imprinted domain on mouse chromosome 12: implications for imprinting control from comparison with Igf2-H19.

Dlk1 and Gtl2 are reciprocally imprinted genes located 80 kb apart on mouse chromosome 12. Similarities between this domain and that of the well characterized Igf2-H19 locus have been previously noted. Comparative genomic and epigenetic analysis of these two domains might help identify allele-specific epigenetic regulatory elements and common features involved in aspects of imprinting control. Here we describe a detailed methylation analysis of the Dlk1-Gtl2 domain on both parental alleles in the mouse. Like the Igf2-H19 domain, areas of differential methylation are hypermethylated on the paternal allele and hypomethylated on the maternal allele. Three differentially methylated regions (DMRs), each with different epigenetic characteristics, have been identified. One DMR is intergenic, contains tandem repeats and is the only region that inherits a paternal methylation mark from the germline. An intronic DMR contains a conserved putative CTCF-binding domain. All three DMRs have both unique and common features compared to those identified in the Igf2-H19 domain.     

<Emphasis Type="Italic">Calcr</Emphasis>, a brain-specific imprinted mouse calcitonin receptor gene in the imprinted cluster of the proximal region of chromosome 6

Expressed sequence tags (ESTs) in the human chromosome 7q21-q31 region were recently used to screen for allelic expression bias in monochromosomal hybrids retaining a paternal or maternal human chromosome 7. Six candidate imprinted genes were identified. In this study, we investigated parent-of-origin-specific expression profiles of their mouse homologues in the proximal region of chromosome 6. An imprinting analysis, using F1 mice from reciprocal crosses between the B6 and JF strains, demonstrated that the mouse calcitonin receptor gene (Calcr) was expressed preferentially from the maternal allele in brain, whereas no allelic bias was detected in other tissues. Our results indicate that Calcr is imprinted in a tissue-specific manner, with a predominant expression from the maternal allele in the brain. Electronic Publication     

Evidence for uniparental, paternal expression of the human GABAA receptor subunit genes, using microcell-mediated chromosome transfer

We have constructed mouse A9 hybrids containing a single normal human chromosome 15, via microcell-mediated chromosome transfer. Cytogenetic and DNA-polymorphic analyses identified mouse A9 hybrids that contained either a paternal or maternal human chromosome 15. Paternal specific expression of the known imprinted genes SNRPN (small nuclear ribonucleoprotein-associated polypeptide N gene) and IPW (imprinted gene in the Prader-Willi syndrome region) was maintained in the A9 hybrids. Using this system, we first demonstrated that human GABAAreceptor subunit genes, GABRB3 , GABRA5 and GABRG3 , were expressed exclusively from the paternal allele and that E6-AP (E6- associated protein or UBE3A ) was biallelically expressed. Moreover, the 5' portion of the GABRB3 gene was found to be hypermethylated on the paternal allele. Our data imply that GABAAreceptor subunit genes are imprinted and are possible candidates for Prader-Willi syndrome, and that this human monochromosomal hybrid system enables the efficient analysis of imprinted loci.      

Methylation profiling in individuals with uniparental disomy identifies novel differentially methylated regions on chromosome 15

The maternal and paternal genomes possess distinct epigenetic marks that distinguish them at imprinted loci. In order to identify imprinted loci, we used a novel method, taking advantage of the fact that uniparental disomy (UPD) provides a system that allows the two parental chromosomes to be studied independently. We profiled the paternal and maternal methylation on chromosome 15 using immunoprecipitation of methylated DNA and hybridization to tiling oligonucleotide arrays. Comparison of six individuals with maternal versus paternal UPD15 revealed 12 differentially methylated regions (DMRs). Putative DMRs were validated by bisulfite sequencing, confirming the presence of parent-of-origin-specific methylation marks. We detected DMRs associated with known imprinted genes within the Prader-Willi/Angelman syndrome region, such as SNRPN and MAGEL2, validating this as a method of detecting imprinted loci. Of the 12 DMRs identified, eight were novel, some of which are associated with genes not previously thought to be imprinted. These include a site within intron 2 of IGF1R at 15q26.3, a gene that plays a fundamental role in growth, and an intergenic site upstream of GABRG3 that lies within a previously defined candidate region conferring an increased maternal risk of psychosis. These data provide a map of parent-of-origin-specific epigenetic modifications on chromosome 15, identifying DNA elements that may play a functional role in the imprinting process. Application of this methodology to other chromosomes for which UPD has been reported will allow the systematic identification of imprinted sites throughout the genome.Imprinting is a phenomenon in which the expression status of a gene is dependent on the sex of the parent from which it is inherited. Imprinted genes generally exhibit monoallelic expression accompanied by parent-of-origin-specific epigenetic marks such as differential DNA methylation and histone modifications that distinguish the maternal and paternal genomes at these loci (Reik and Walter 2001; Dindot et al. 2009). More than 60 imprinted genes have been identified in humans (http://www.geneimprint.com/), and their clustered nature suggests that many are regulated by regional control mechanisms.To date, the discovery of imprinted sites in both mouse and human has largely been driven through the use of phenotype-based approaches. The vast majority of loci subject to parent-of-origin effects were first recognized through the observation that maternal and paternal transmission of the same genetic mutation results in different phenotypes (Nicholls et al. 1989). For example, the identification of imprinted gene clusters in 15q11-q13 associated with Prader-Willi/Angelman syndrome, 11p11.5 associated with Beckwith-Wiedemann syndrome, and imprinted loci at 14q32, 6q24, and 20q13.2 were all catalyzed by the initial observation that genetic disease occurred specifically in patients with either uniparental disomy (UPD) or deletions of these regions of specific parental origin. In combination with chromosomal engineering techniques that can systematically generate defined aneuploidies, this notion has been applied to screen the mouse genome for imprinting with great success, resulting in the identification of more than 130 murine imprinted genes (Williamson et al. 2009). However, because this methodology relies on the recognition of overt phenotypic differences between individuals to detect imprinting, it is likely to miss imprinting that may cause subtle phenotype differences or those that manifest in ways that are not easily recognized by typical methods of phenotypic characterization. Further, imprinted genes will also be missed or masked by phenotypes that are lethal.In order to circumvent this limitation, a variety of genomic techniques have been developed to identify parent-of-origin effects. Several previous studies have attempted to detect imprinting based on the differential expression of parental alleles at imprinted loci. Studies using subtractive cDNA hybridization (Kaneko-Ishino et al. 1995) and high-throughput cDNA sequencing in hybrid mouse strains (Wang et al. 2008) have been used to detect imprinted expression with some success. However, these approaches are limited in that they can only assay the subset of genes expressed in the tissue(s) under investigation, and for some genes, imprinted expression is only observed in specific tissues or at certain developmental stages (Deltour et al. 1995; Rougeulle et al. 1997; Zhou et al. 2006). Furthermore, sequencing-based approaches are only able to assay allelic bias in genes containing transcribed polymorphisms (Daelemans et al. 2010).Alternative approaches to detect imprinting have used the fact that the maternal and paternal genomes have differential epigenetic marks at most imprinted loci. This approach has the advantage over expression-based methods, in that these differential methylation marks are generally conserved, even in tissues that lack imprinted expression (Dockery et al. 2009). The presence of overlapping euchromatin and heterochromatin marks has been used to highlight imprinted domains in human (Wen et al. 2008), and restriction landmark genome scanning (Hayashizaki et al. 1994) and methylation-sensitive representational difference analysis (Kelsey et al. 1999; Smith et al. 2003) have been applied as methods to detect differentially methylated regions in the mouse genome. However, the reliance of these latter techniques on restriction enzyme digestion means that they can only assay a small subset of CpGs that overlap the enzyme recognition site, and if used in outbred genomes, are liable to artifacts generated by the presence of single nucleotide variants that alter restriction patterns.Because one of the key features of imprinted genes is the presence of parent-of-origin-specific methylation, we hypothesized that the systematic comparison of DNA methylation patterns in maternal versus paternal chromosomes should represent an optimal method for the detection of imprinted loci. Based on this hypothesis, we have taken advantage of the fact that uniparental disomy provides a unique system that allows the separate study of chromosomes derived from a single parent and combined this with a methodology in which the methylation of entire chromosomes can be analyzed in an unbiased fashion. By analyzing methylation patterns in cases of maternal UPD15 (matUPD15) and paternal UPD15 (patUPD15) using immunoprecipitation of methylated DNA and high-density tiling arrays with complete coverage of human chromosome 15, we generated separate methylation profiles of the maternally and paternally derived alleles. Comparison of the two parental epigenotypes identifies numerous loci on chromosome 15 that show parent-of-origin-specific methylation differences, defining a set of DNA elements that are likely responsible for the establishment and/or maintenance of imprinting on this chromosome. We identify novel imprinted loci both within and outside of the known PWS/AS imprinted domain, suggesting candidate loci that may exert parent-of-origin effects in several human phenotypes.     

The epsilon-sarcoglycan gene (SGCE), mutated in myoclonus-dystonia syndrome,is maternally imprinted

Myoclonus-dystonia syndrome (MDS) is a non-degenerative neurological disorder that has been described to be inherited in an autosomal dominant mode with incomplete penetrance. MDS is caused by loss of function mutations in the epsilon-sarcoglycan gene. Reinvestigation of MDS pedigrees provided evidence for a maternal imprinting mechanism. As differential methylated regions (DMRs) are a characteristic feature of imprinted genes, we studied the methylation pattern of CpG dinucleotides within the CpG island containing the promoter region and the first exon of the SGCE gene by bisulphite genomic sequencing. Our findings revealed that in peripheral blood leukocytes the maternal allele is methylated, while the paternal allele is unmethylated. We also showed that most likely the maternal allele is completely methylated in brain tissue. Furthermore, CpG dinucleotides in maternal and paternal uniparental disomy 7 (UPD7) lymphoblastoid cell lines show a corresponding parent-of-origin specific methylation pattern. The effect of differential methylation on the expression of the SGCE gene was tested in UPD7 cell lines with only a weak RT-PCR signal observed in matUPD7 and a strong signal in patUPD7. These results provide strong evidence for a maternal imprinting of the SGCE gene. The inheritance pattern in MDS families is in agreement with such an imprinting mechanism with the exception of a few cases. We investigated one affected female that inherited the mutated allele from her mother. Surprisingly, we found the paternal wild type allele expressed whereas the mutated maternal allele was not detectable in peripheral blood cDNA.     

Stochastic imprinting in the progeny of Dnmt3L-/- females

The cis-acting regulatory sequences of imprinted genes are subject to germline-specific epigenetic modifications, the imprints, so that this class of genes is exclusively expressed from either the paternal or maternal allele in offspring. How genes are differentially marked in the germlines remains largely to be elucidated. Although the exact nature of the mark is not fully known, DNA methylation [at differentially methylated regions (DMRs)] appears to be a major, functional component. Recent data in mice indicate that Dnmt3a, an enzyme with de novo DNA methyltransferase activity, and the related protein Dnmt3L are required for methylation of imprinted loci in germ cells. Maternal methylation imprints, in particular, are strictly dependent on the presence of Dnmt3L. Here, we show that, unexpectedly, methylation imprints can be present in some progeny of Dnmt3L(-/-) females. This incomplete penetrance of the effect of Dnmt3L deficiency in oocytes is neither embryo nor locus specific, but stochastic. We establish that, when it occurs, methylation is present in both embryo and extra-embryonic tissues and results in a functional imprint. This suggests that this maternal methylation is inherited, directly or indirectly, from the gamete. Our results indicate that in the absence of Dnmt3L, factors such as Dnmt3a and possibly others can act alone to mark individual DMRs. However, establishment of appropriate maternal imprints at all loci does require a combination of all factors. This observation can provide a basis to understand mechanisms involved in some sporadic cases of imprinting-related diseases and polymorphic imprinting in human.     

A genome-wide screen for normally methylated human CpG islands that can identify novel imprinted genes

DNA methylation is a covalent modification of the nucleotide cytosine that is stably inherited at the dinucleotide CpG by somatic cells, and 70% of CpG dinucleotides in the genome are methylated. The exception to this pattern of methylation are CpG islands, CpG-rich sequences that are protected from methylation, and generally are thought to be methylated only on the inactive X-chromosome and in tumors, as well as differentially methylated regions (DMRs) in the vicinity of imprinted genes. To identify chromosomal regions that might harbor imprinted genes, we devised a strategy for isolating a library of normally methylated CpG islands. Most of the methylated CpG islands represented high copy number dispersed repeats. However, 62 unique clones in the library were characterized, all of which were methylated and GC-rich, with a GC content >50%. Of these, 43 clones also showed a CpG(obs)/CpG(exp) >0.6, of which 30 were studied in detail. These unique methylated CpG islands mapped to 23 chromosomal regions, and 12 were differentially methylated regions in uniparental tissues of germline origin, i.e., hydatidiform moles (paternal origin) and complete ovarian teratomas (maternal origin), even though many apparently were methylated in somatic tissues. We term these sequences gDMRs, for germline differentially methylated regions. At least two gDMRs mapped near imprinted genes, HYMA1 and a novel homolog of Elongin A and Elongin A2, which we term Elongin A3. Surprisingly, 18 of the methylated CpG islands were methylated in germline tissues of both parental origins, representing a previously uncharacterized class of normally methylated CpG islands in the genome, and which we term similarly methylated regions (SMRs). These SMRs, in contrast to the gDMRs, were significantly associated with telomeric band locations (P =.0008), suggesting a potential role for SMRs in chromosome organization. At least 10 of the methylated CpG islands were on average 85% conserved between mouse and human. These sequences will provide a valuable resource in the search for novel imprinted genes, for defining the molecular substrates of the normal methylome, and for identifying novel targets for mammalian chromatin formation.     

Novel deletions affecting the MEG3-DMR provide further evidence for a hierarchical regulation of imprinting in 14q32

The imprinted region on chromosome 14q32 harbors several maternally or paternally expressed genes as well as two DMRs (differentially methylated regions), the IG-DMR and the MEG3-DMR, which both act as imprinting control centers. Genetic aberrations affecting the imprinted gene cluster in 14q32 result in distinct phenotypes, known as maternal or paternal uniparental disomy 14 phenotypes (upd(14)mat, upd(14)pat). In both syndromes, three types of molecular alterations have been reported: uniparental disomy 14, deletions and epimutations. In contrast to uniparental disomy and epimutations, deletions affecting regulatory elements in 14q32 are associated with a high-recurrence risk. Based on two single deletion cases a functional hierarchy of the IG-DMR as a regulator for the methylation of the MEG3-DMR has been proposed. We have identified two novel deletions of maternal origin spanning the MEG3-DMR, but not the IG-DMR in patients with upd(14)pat syndrome, one de novo deletion of 165 kb and another deletion of 5.8 kb in two siblings. The 5.8 kb deletion was inherited from the phenotypically normal mother, who carries the deletion in a mosaic state on her paternal chromosome 14. The methylation at both DMRs was investigated by quantitative next generation bisulfite sequencing and revealed normal methylation patterns at the IG-DMR in all patients with the exception of certain CpG dinucleotides. Thus, we could confirm that deletions of the MEG3-DMR does not generally influence the methylation pattern of the IG-DMR, which strengthens the hypothesis of a hierarchical structure and distinct functional properties of the two DMRs.     

Developmentally regulated functions of the H19 differentially methylated domain

Igf2 and H19 are physically linked imprinted genes. In embryonic liver, their reciprocal expression (paternal for Igf2 and maternal for H19) is controlled by a paternally methylated region (H19 DMD) located 5' of H19. This region contains a methylation-sensitive insulator that prevents the Igf2 promoters being activated by downstream enhancers on the maternal chromosome. In adult liver, Igf2 is normally not expressed but is reactivated upon tumour formation. By analysing three deletions of the H19 locus, we investigated the mechanism regulating the imprinted expression of the Igf2 gene in the course of liver tumourigenesis. We observed that the role of the H19 DMD in the control of Igf2 expression changes during tumourigenesis. The H19 DMD is required on the paternal chromosome for Igf2 activation in the early stages while its maternal allele is necessary for maintaining Igf2 imprinting only in the late stages. A positive regulatory function of the paternal H19 DMD is also evident in normal neonatal liver, but its relevance for Igf2 expression becomes higher in the second post-natal week. Our results support a model in which both methylated and non-methylated parental copies of the H19 DMD have active roles in the regulation of Igf2 expression in the liver and these activities are under developmental control.     

Long-range DNase I hypersensitivity mapping reveals the imprinted Igf2r and Air promoters share cis-regulatory elements

Epigenetic mechanisms restrict the expression of imprinted genes to one parental allele in diploid cells. At the Igf2r/Air imprinted cluster on mouse chromosome 17, paternal-specific expression of the Air noncoding RNA has been shown to silence three genes in cis: Igf2r, Slc22a2, and Slc22a3. By an unbiased mapping of DNase I hypersensitive sites (DHS) in a 192-kb region flanking Igf2r and Air, we identified 21 DHS, of which nine mapped to evolutionarily conserved sequences. Based on the hypothesis that silencing effects of Air would be directed towards cis regulatory elements used to activate genes, DHS are potential key players in the control of imprinted expression. However, in this 192-kb region only the two DHS mapping to the Igf2r and Air promoters show parental specificity. The remaining 19 DHS were present on both parental alleles and, thus, have the potential to activate Igf2r on the maternal allele and Air on the paternal allele. The possibility that the Igf2r and Air promoters share the same cis-acting regulatory elements, albeit on opposite parental chromosomes, was supported by the similar expression profiles of Igf2r and Air in vivo. These results refine our understanding of the onset of imprinted silencing at this cluster and indicate the Air noncoding RNA may specifically target silencing to the Igf2r promoter.     

The IPL gene on chromosome 11p15.5 is imprinted in humans and mice and is similar to TDAG51, implicated in Fas expression and apoptosis

We searched for novel imprinted genes in a region of human chromosome 11p15.5, which contains several known imprinted genes. Here we describe the cloning and characterization of the IPL ( I mprinted in P lacenta and L iver) gene, which shows tissue-specific expression and functional imprinting, with the maternal allele active and the paternal allele relatively inactive, in many human and mouse tissues. Human IPL is highly expressed in placenta and shows low but detectable expression in fetal and adult liver and lung. Mouse Ipl maps to the region of chromosome 7 which is syntenic with human 11p15.5 and this gene is expressed in placenta and at higher levels in extraembryonic membranes (yolk sac), fetal liver and adult kidney. Mouse and human IPL show sequence similarity to TDAG51 , a gene which was shown to be essential for Fas expression and susceptibility to apoptosis in a T lymphocyte cell line. Like several other imprinted genes, mouse and human IPL genes are small and contain small introns. These data expand the repertoire of known imprinted genes and will be helpful in testing the mechanism of genomic imprinting and the role of imprinted genes in growth regulation.      

IMPT1, an imprinted gene similar to polyspecific transporter and multi- drug resistance genes

Human chromosome 11p15.5 and distal mouse chromosome 7 include a megabase-scale chromosomal domain with multiple genes subject to parental imprinting. Here we describe mouse and human versions of a novel imprinted gene, IMPT1 , which lies between IPL and p57 KIP2 and which encodes a predicted multi-membrane-spanning protein similar to bacterial and eukaryotic polyspecific metabolite transporter and multi- drug resistance pumps. Mouse Impt1 and human IMPT1 mRNAs are highly expressed in tissues with metabolite transport functions, including liver, kidney, intestine, extra-embryonic membranes and placenta, and there is strongly preferential expression of the maternal allele in various mouse tissues at fetal stages. In post-natal tissues there is persistent expression, but the allelic bias attenuates. An allelic expression bias is also observed in human fetal and post-natal tissues, but there is significant interindividual variation and rare somatic allele switching. The fact that Impt1 is relatively repressed on the paternal allele, together with data from other imprinted genes, allows a statistical conclusion that the primary effect of human chromosome 11p15.5/mouse distal chromosome 7 imprinting is domain-wide relative repression of genes on the paternal homolog. Dosage regulation of the metabolite transporter gene(s) by imprinting might regulate placental and fetal growth.