Expression patterns of the novel imprinted genes Nap1l5 and Peg13 and their non-imprinted host genes in the adult mouse brain

Recent work has implicated imprinted gene functioning in neurodevelopment and behaviour and defining the expression patterns of these genes in brain tissue has become a key prerequisite to establishing function. In this work we report on the expression patterns of two novel imprinted loci, Nap1l5 and Peg13, in adult mouse brain using in situ hybridisation methods. Nap1l5 and Peg13 are located, respectively, within the introns of the non-imprinted genes Herc3 and the Tularik1 (T1)/KIAA1882 homologue in two separate microimprinted domains on mouse chromosomes 6 and 15. These 'host' genes are highly expressed in brain and consequently we were interested in assessing their expression patterns in parallel to the imprinted genes. The brain expression of all four genes appeared to be mainly neuronal. The detailed expression profiles of Nap1l5 and Peg13 were generally similar with widespread expression that was relatively high in the septal and hypothalamic regions, the hippocampus and the cerebral cortex. In contrast, there was some degree of dissociation between the imprinted genes and their non-imprinted hosts, in that, whilst there was again widespread expression of Herc3 and the T1/KIAA1882 homologue, these genes were also particularly highly expressed in Purkinje neurons and piriform cortex. We also examined expression of the novel imprinted genes in the adrenal glands. Nap1l5 expression was localised mainly to the adrenal medulla, whilst Peg13 expression was observed more generally throughout the adrenal medulla and the outer cortical layers.     

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.     

Biallelic expression of Tssc4, Nap1l4, Phlda2 and Osbpl5 in adult cattle

Journal of Genetics - Genomic imprinting of the Cdkn1c/Kcnq1ot1 region shows lack of conservation between human and mouse. This region has been reported to be associated with...     

Genome level analysis of rice mRNA 3'-end processing signals and alternative polyadenylation

The position of a poly(A) site of eukaryotic mRNA is determined by sequence signals in pre-mRNA and a group of polyadenylation factors. To reveal rice poly(A) signals at a genome level, we constructed a dataset of 55 742 authenticated poly(A) sites and characterized the poly(A) signals. This resulted in identifying the typical tripartite cis-elements, including FUE, NUE and CE, as previously observed in Arabidopsis. The average size of the 3′-UTR was 289 nucleotides. When mapped to the genome, however, 15% of these poly(A) sites were found to be located in the currently annotated intergenic regions. Moreover, an extensive alternative polyadenylation profile was evident where 50% of the genes analyzed had more than one unique poly(A) site (excluding microheterogeneity sites), and 13% had four or more poly(A) sites. About 4% of the analyzed genes possessed alternative poly(A) sites at their introns, 5′-UTRs, or protein coding regions. The authenticity of these alternative poly(A) sites was partially confirmed using MPSS data. Analysis of nucleotide profile and signal patterns indicated that there may be a different set of poly(A) signals for those poly(A) sites found in the coding regions. Based on the features of rice poly(A) signals, an updated algorithm termed PASS-Rice was designed to predict poly(A) sites.     

The role of the Brr5/Ysh1 C-terminal domain and its homolog Syc1 in mRNA 3'-end processing in Saccharomyces cerevisiae

The cleavage/polyadenylation factor (CPF) of Saccharomyces cerevisiae is thought to provide the catalytic activities of the mRNA 3'-end processing machinery, which include endonucleolytic cleavage at the poly(A) site, followed by synthesis of an adenosine polymer onto the new 3'-end by the CPF subunit Pap1. Because of similarity to other nucleases in the metallo-beta-lactamase family, the Brr5/Ysh1 subunit has been proposed to be the endonuclease. The C-terminal domain of Brr5 lies outside of beta-lactamase homology, and its function has not been elucidated. We show here that this region of Brr5 is necessary for cell viability and mRNA 3'-end processing. It is highly homologous to another CPF subunit, Syc1. Syc1 is not essential, but its removal improves the growth of other processing mutants at restrictive temperatures and restores in vitro processing activity to cleavage/ polyadenylation-defective brr5-1 extract. Our findings suggest that Syc1, by mimicking the essential Brr5 C-terminus, serves as a negative regulator of mRNA 3'-end formation.     

Epigenetic control of chromosome breakage at the 5' end of Paramecium tetraurelia gene A

Macronuclei and micronuclei of ciliates have related genomes, with macronuclei developing from zygotic micronuclei through programmed DNA rearrangements. While Paramecium tetraurelia wild-type strain 51 and mutant strain d48 have the same micronuclear genome, qualitative differences between their macronuclear genomes have been described, demonstrating that programmed DNA rearrangements could be epigenetically controlled in ciliates. Macronuclear chromosomes end downstream of gene A (A51 Mac ends) and at the 5' end of gene A (Ad48 Mac ends) in strains 51 and d48, respectively. To gain further insight into the process of chromosome end formation, we performed an extensive analysis of locus A rearrangement in strains d48 and 51, in strain d12, which harbors a gene A deletion, and in interstrain cross progeny. We show that (i) allele Ad12 harbors a deletion of >16 kb, (ii) A51 Mac ends distribute over four rather than three DNA regions, (iii) strains d48 and 51 display only quantitative differences (rare Ad48 and A51 Mac ends do form in strains 51 and d48, respectively), (iv) the level of A51 Mac ends is severalfold enhanced in d12- and d48-derived progeny, and (v) this level inversely correlates with the level of Ad48 Mac ends in the d48 parent. Together, these data lead to a model in which the formation of Ad48 Mac ends is epigenetically controlled by a d48 factor(s). We propose that the d48 factor(s) may be derived from RNA molecules transcribed from the Ad48 Mac ends and encompassing the truncated A gene and telomeric repeats.     

A reassessment of imprinting regions and phenotypes on mouse chromosome 6: Nap1l5 locates within the currently defined sub-proximal imprinting region

Previous studies (Beechey, 2000) have shown that mouse proximal chromosome (Chr) 6 has two imprinting regions. An early embryonic lethality is associated with two maternal copies of the more proximal imprinting region, while mice with two maternal copies of the sub-proximal imprinting region are growth retarded at birth, the weight reduction remaining similar to adulthood. No detectable postnatal imprinting phenotype was seen in these earlier studies with two paternal copies of either region. The sub-proximal imprinting region locates distal to the T77H reciprocal translocation breakpoint in G-band 6A3.2 and results reported here show that it does not extend beyond the breakpoint of the more distal T6Ad translocation in 6C2. It has been confirmed that the postnatal growth retardation observed with two maternal copies of the sub-proximal region is established in utero, although placental size was normal. A new finding is that 16.5-18.5-dpc embryos, with two paternal copies of the sub-proximal imprinting region, were larger than their normal sibs, although placental size was normal. As no postnatal growth differences have been observed in these mice, the fetal overgrowth must normalize by birth. The imprinted genes Peg1/Mest, Copg2, Copg2as and Mit1/Lb9 map to the sub-proximal imprinting region and are thus candidates for the observed imprinting phenotypes. Another candidate is the recently reported imprinted gene Nap1l5. Expression studies of Nap1l5 in mice with two maternal or two paternal copies of different regions of Chr 6 have demonstrated that the gene locates within the sub-proximal imprinting region. FISH has mapped Nap1l5 to G-band 6C1, within the sub-proximal imprinting region but several G-bands distal to the Peg1/Mest cluster. This location, and the 30-Mb separation of these loci on the sequence map, makes it probable that Nap1l5 defines a new imprinting domain within the currently defined sub-proximal imprinting region.