Postnatal Survival of Mice with Maternal Duplication of Distal Chromosome 7 Induced by a Igf2/H19 Imprinting Control Region Lacking Insulator Function

The misexpressed imprinted genes causing developmental failure of mouse parthenogenones are poorly defined. To obtain further insight, we investigated misexpressions that could cause the pronounced growth deficiency and death of fetuses with maternal duplication of distal chromosome (Chr) 7 (MatDup.dist7). Their small size could involve inactivity of Igf2, encoding a growth factor, with some contribution by over-expression of Cdkn1c, encoding a negative growth regulator. Mice lacking Igf2 expression are usually viable, and MatDup.dist7 death has been attributed to the misexpression of Cdkn1c or other imprinted genes. To examine the role of misexpressions determined by two maternal copies of the Igf2/H19 imprinting control region (ICR)—a chromatin insulator, we introduced a mutant ICR (ICRΔ) into MatDup.dist7 fetuses. This activated Igf2, with correction of H19 expression and other imprinted transcripts expected. Substantial growth enhancement and full postnatal viability was obtained, demonstrating that the aberrant MatDup.dist7 phenotype is highly dependent on the presence of two unmethylated maternal Igf2/H19 ICRs. Activation of Igf2 is likely the predominant correction that rescued growth and viability. Further experiments involved the introduction of a null allele of Cdkn1c to alleviate its over-expression. Results were not consistent with the possibility that this misexpression alone, or in combination with Igf2 inactivity, mediates MatDup.dist7 death. Rather, a network of misexpressions derived from dist7 is probably involved. Our results are consistent with the idea that reduced expression of IGF2 plays a role in the aetiology of the human imprinting-related growth-deficit disorder, Silver-Russell syndrome

Coordinated allele-specific histone acetylation at the differentially methylated regions of imprinted genes

Genomic imprinting is an epigenetic inheritance system characterized by parental allele-specific gene expression. Allele-specific DNA methylation and chromatin composition are two epigenetic modification systems that control imprinted gene expression. To get a general assessment of histone lysine acetylation at imprinted genes we measured allele-specific acetylation of a wide range of lysine residues, H3K4, H3K18, H3K27, H3K36, H3K79, H3K64, H4K5, H4K8, H4K12, H2AK5, H2BK12, H2BK16 and H2BK46 at 11 differentially methylated regions (DMRs) in reciprocal mouse crosses using multiplex chromatin immunoprecipitation SNuPE assays. Histone acetylation marks generally distinguished the methylation-free alleles from methylated alleles at DMRs in mouse embryo fibroblasts and embryos. Acetylated lysines that are typically found at transcription start sites exhibited stronger allelic bias than acetylated histone residues in general. Maternally methylated DMRs, that usually overlap with promoters exhibited higher levels of acetylation and a 10% stronger allele-specific bias than paternally methylated DMRs that reside in intergenic regions. Along the H19/Igf2 imprinted domain, allele-specific acetylation at each lysine residue depended on functional CTCF binding sites in the imprinting control region. Our results suggest that many different histone acetyltransferase and histone deacetylase enzymes must act in concert in setting up and maintaining reciprocal parental allelic histone acetylation at DMRs

Protein Interactions at Oxidized 5-Methylcytosine Bases

5-Methylcytosine (5mC), the major modified DNA base in mammalian cells, can be oxidized enzymatically to 5-hydroxymethylcytosine (5hmC), 5-formylcytosine (5fC), and 5-carboxylcytosine (5caC) by the Ten-Eleven-Translocation (TET) family of proteins. Whereas 5fC and 5caC are recognized and removed by base excision repair proteins, the 5hmC base accumulates to substantial levels in certain cell types such as brain-derived neurons and is viewed as a relatively stable DNA base. As such, the existence of "reader" proteins that recognize 5hmC would be a logical assumption, and various searches have been undertaken to identify proteins that specifically bind to 5hmC and the other oxidized 5mC bases. However, the existence of definitive 5hmC "readers" has remained unclear and proteins interacting specifically with 5fC or 5caC are also very few. On the other hand, 5hmC is incapable of interacting with a number of proteins that recognize 5mC at CpG sequences, suggesting that 5hmC is an anti-reader modification that may serve to displace 5mC readers from DNA. In this review article, we discuss candidate proteins that may interact with oxidized 5mC bases

Parent-of-Origin-Specific Binding of Nuclear Hormone Receptor Complexes in the H19-Igf2 Imprinting Control Region

Parent-of-origin-specific expression of the mouse insulin-like growth factor 2 gene (Igf2) and the closely linked H19 gene located on distal chromosome 7 is regulated by a 2.4-kb imprinting control region (ICR) located upstream of the H19 gene. In somatic cells, the maternally and paternally derived ICRs are hypo- and hypermethylated, respectively, with the former binding the insulator protein CCCTC-binding factor (CTCF) and acting to block access of enhancers to the Igf2 promoter. Here we report on a detailed in vivo footprinting analysis—using ligation-mediated PCR combined with in vivo dimethyl sulfate, DNase I, or UV treatment—of ICR sequences located outside of the CTCF binding domains. In mouse primary embryo fibroblasts carrying only maternal or paternal copies of distal chromosome 7, we have identified five prominent footprints specific to the maternal ICR. Each of the five footprinted areas contains at least two nuclear hormone receptor hexad binding sites arranged with irregular spacing. When combined with fibroblast nuclear extracts, these sequences interact with complexes containing retinoic X receptor alpha and estrogen receptor beta. More significantly, the footprint sequences bind nuclear hormone receptor complexes in male, but not female, germ cell extracts purified from fetuses at a developmental stage corresponding to the time of establishment of differential ICR methylation. These data are consistent with the possibility that nuclear hormone receptor complexes participate in the establishment of differential ICR methylation imprinting in the germ line