What good are transposable elements (TEs)? Although their activity can be harmful to host genomes and can cause disease, they nevertheless represent an important source of genetic variation that has helped shape genomes. In this review, we examine the impact of TEs, collectively referred to as the mobilome, on the transcriptome. We explore how TEs—particularly retrotransposons—contribute to transcript diversity and consider their potential significance as a source of small RNAs that regulate host gene transcription. We also discuss a critical role for the mobilome in engineering transcriptional networks, permitting coordinated gene expression, and facilitating the evolution of novel physiological processes.
The epigenetic events that occur during the development of the mammalian embryo are essential for correct gene expression and cell-lineage determination. Imprinted genes are expressed from only one parental allele due to differential epigenetic marks that are established during gametogenesis. Several theories have been proposed to explain the role that genomic imprinting has played over the course of mammalian evolution, but at present it is not clear if a single hypothesis can fully account for the diversity of roles that imprinted genes play. In this review, we discuss efforts to define the extent of imprinting in the mouse genome, and suggest that different imprinted loci may have been wrought by distinct evolutionary forces. We focus on a group of small imprinted domains, which consist of paternally expressed genes embedded within introns of multiexonic transcripts, to discuss the evolution of imprinting at these loci.
Maternally and paternally derived alleles can utilize different promoters, but allele-specific differences in cotranscriptional processes have not been reported. We show that alternative polyadenylation sites at a novel murine imprinted gene (H13) are utilized in an allele-specific manner. A differentially methylated CpG island separates polyA sites utilized on maternal and paternal alleles, and contains an internal promoter. Two genetic systems show that alleles lacking methylation generate truncated H13 transcripts that undergo internal polyadenylation. On methylated alleles, the internal promoter is inactive and elongation proceeds to downstream polyadenylation sites. This demonstrates that epigenetic modifications can influence utilization of alternative polyadenylation sites.Supplemental material is available at http://www.genesdev.org.Received January 28, 2008; revised version accepted March 10, 2008. Transcription by RNA polymerase II (Pol II) requires multiple linked steps, including the assembly of an initiation complex, promoter release, elongation followed by splicing, polyadenylation (polyA), and dissociation of the polymerase complex from the template DNA. Each step provides an opportunity for the cell to regulate gene expression, either by changing the abundance or availability of mRNAs or by generating variant gene products. Epigenetic modifications to DNA and histones can influence transcription at the initiation stage by altering the accessibility of promoter sequences to initiation complex components (Kass et al. 1997a,b). Following initiation, regions of heterochromatin can subtly impede the progress of an elongating polymerase complex, reducing transcriptional output (Lorincz et al. 2004). However, it is not clear whether epigenetic modifications downstream from a promoter can lead to variant gene products through alternative polyadenylation or splicing.Polyadenylation, the addition of multiple adenyl residues to the 3Ј end of a newly synthesized transcript, confers stability and is required for nuclear export (Huang and Carmichael 1996;Jacobson and Peltz 1996). This occurs following cleavage of the newly synthesized pre-mRNA, typically 15-30 nucleotides downstream from a conserved hexamer motif (usually AAUAAA or AUUAAA) (Proudfoot and Brownlee 1976;Zhao et al. 1999). A large proportion of human genes utilize more than one polyadenylation (polyA) site (Tian et al. 2005), making alternative polyadenylation a major source of transcriptional diversity. The mechanisms governing alternative polyA site selection in mammalian cells have been studied in detail at only a small number of loci; notably the immunoglobulin heavy chain (Takagaki and Manley 1998) and calcitonin/CGRP genes (Lou et al. 1998). In both cases, polyA site selection is cell typespecific and is regulated by changes in the concentration of diffusible RNA processing factors (Lou et al. 1998;Takagaki and Manley 1998).Imprinted genes are differentially expressed on maternally and paternally derived alleles and are estimated to com...
G9a Histone Methyltransferase Contributes to Imprinting in the Mouse Placenta
Whereas DNA methylation is essential for genomic imprinting, the importance of histone methylation in the allelic expression of imprinted genes is unclear. Imprinting control regions (ICRs), however, are marked by histone H3-K9 methylation on their DNA-methylated allele. In the placenta, the paternal silencing along the Kcnq1 domain on distal chromosome 7 also correlates with the presence of H3-K9 methylation, but imprinted repression at these genes is maintained independently of DNA methylation. To explore which histone methyltransferase (HMT) could mediate the allelic H3-K9 methylation on distal chromosome 7, and at ICRs, we generated mouse conceptuses deficient for the SET domain protein G9a. We found that in the embryo and placenta, the differential DNA methylation at ICRs and imprinted genes is maintained in the absence of G9a. Accordingly, in embryos, imprinted gene expression was unchanged at the domains analyzed, in spite of a global loss of H3-K9 dimethylation (H3K9me2). In contrast, the placenta-specific imprinting of genes on distal chromosome 7 is impaired in the absence of G9a, and this correlates with reduced levels of H3K9me2 and H3K9me3. These findings provide the first evidence for the involvement of an HMT and suggest that histone methylation contributes to imprinted gene repression in the trophoblast.
Protection against De Novo Methylation Is Instrumental in Maintaining Parent-of-Origin Methylation Inherited from the Gametes
SummaryIdentifying loci with parental differences in DNA methylation is key to unraveling parent-of-origin phenotypes. By conducting a MeDIP-Seq screen in maternal-methylation free postimplantation mouse embryos (Dnmt3L-/+), we demonstrate that maternal-specific methylation exists very scarcely at midgestation. We reveal two forms of oocyte-specific methylation inheritance: limited to preimplantation, or with longer duration, i.e. maternally imprinted loci. Transient and imprinted maternal germline DMRs (gDMRs) are indistinguishable in gametes and preimplantation embryos, however, de novo methylation of paternal alleles at implantation delineates their fates and acts as a major leveling factor of parent-inherited differences. We characterize two new imprinted gDMRs, at the Cdh15 and AK008011 loci, with tissue-specific imprinting loss, again by paternal methylation gain. Protection against demethylation after fertilization has been emphasized as instrumental in maintaining parent-of-origin methylation inherited from the gametes. Here we provide evidence that protection against de novo methylation acts as an equal major pivot, at implantation and throughout life.
Imprinted genes undergo epigenetic modifications during gametogenesis, which lead to transcriptional silencing of either the maternally or the paternally derived allele in the subsequent generation. Previous work has suggested an association between imprinting and the products of retrotransposition, but the nature of this link is not well defined. In the mouse, three imprinted genes have been described that originated by retrotransposition and overlap CpG islands which undergo methylation during oogenesis. Nap1l5, U2af1-rs1, and Inpp5f_v2 are likely to encode proteins and share two additional genetic properties: they are located within introns of host transcripts and are derived from parental genes on the X chromosome. Using these sequence features alone, we identified Mcts2, a novel candidate imprinted retrogene on mouse Chromosome 2. Mcts2 has been validated as imprinted by demonstrating that it is paternally expressed and undergoes promoter methylation during oogenesis. The orthologous human retrogenes NAP1L5, INPP5F_V2, and MCTS2 are also shown to be paternally expressed, thus delineating novel imprinted loci on human Chromosomes 4, 10, and 20. The striking correlation between imprinting and X chromosome provenance suggests that retrotransposed elements with homology to the X chromosome can be selectively targeted for methylation during mammalian oogenesis.
Parental imprinting is important for seed development, but few imprinted genes have been identified in plants. The four known imprinted genes in Arabidopsis thaliana encode transcriptional regulators. Here, we describe a novel imprinted gene, MATERNALLY EXPRESSED PAB C-TERMINAL (MPC), which encodes the C-terminal domain of poly(A) binding proteins (PABPs). PABPs play roles in mRNA stability and translation. MPC interacts with proteins that also interact with the C-terminal domain of typical PABPs, suggesting that MPC may regulate translation by modulating PABP activity. In the endosperm, MPC is expressed only from the maternal allele. Reduction of MPC expression affects seed development. In dna methyltransferase1 (met1) mutants, MPC is ectopically expressed, and the paternal allele is active in the endosperm. CGs in the 5′ flanking region and gene body of MPC lose methylation in a met1 background. Both regions are required to confer imprinted reporter expression, suggesting that the gene body contains imprinting control region elements. In Arabidopsis, DEMETER (DME) activates expression of maternal alleles. MPC expression is reduced in flowers and seeds in a dme-4 mutant but only after fertilization in dme-1. We conclude that other factors along with DME promote MPC expression and that DME has indirect effects on imprinted gene expression in endosperm.
Alagille syndrome (AGS) is an autosomal dominant disorder characterized by bile duct paucity along with cardiovascular, skeletal, and ophthalmologic defects. The identification of JAG1 as the AGS disease gene revealed the crucial role of the Notch signaling pathway in the development of multiple organ systems in humans. Patients with identical mutations in JAG1 demonstrate extreme clinical variability, suggesting that other factors may influence the severity of the developmental defects in this disorder. We have defined the temporal and spatial expression patterns of the Notch receptor genes in the developing mammalian heart and liver in order to identify potential ligand/receptor interactions during embryogenesis. In the developing heart, both Notch1 and Notch2 are expressed in the outflow tracts and the epicardium, in specific cell populations previously shown to express JAG1. These cells are destined to undergo epithelial‐to‐mesenchymal transformation. In the newborn mouse liver, Notch2 and Notch3 are expressed in opposing cell populations, suggesting they play different roles in cell fate determination during bile duct development. JAG1 is also expressed in cells adjacent to those expressing Notch2, suggesting a possible ligand receptor relationship. The Notch receptors have distinct roles in cell fate determination in different organ systems. © 2002 Wiley‐Liss, Inc.
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