Comparison of the sequence organization of related retrovirus-like multigene families in three evolutionarily distant rodent genomes.

Sequences related to mouse intracisternal A-particle (IAP) genes have been isolated from rat and Syrian hamster gene libraries as recombinants in lambda phage. The sequences are moderately reiterated in both these genomes but their sequence organization in the hamster genome is different from that in the rat genome. Restriction analysis and electron microscopy indicate that the Syrian hamster IAP sequences represent a family of relatively homogeneous well-conserved units; in this, they resemble the mouse IAP genes. The rat sequences, in contrast, are heterogeneous. Both the hamster and rat IAP sequences contain regions homologous to mouse IAP genes interspersed with regions of apparent non-homology. The interspersed regions range in size from 0.5-1.0 kilobases (Kb). The regions of homology among the mouse, rat and Syrian hamster IAP sequences have been mapped to a 5-6 Kb internal region on the mouse IAP genes. Mouse IAP long terminal repeat (LTR) sequences were not detected in the rat and Syrian hamster genomes. We used the thermal stability of hybrids between cloned and genomic IAP sequences to measure family homogeneity. Mouse and Syrian hamster IAP sequences are homogeneous by this criterion, but the rat IAP sequences are heterogeneous with a Tm 6 degrees C below the self-hybrid. The contrasting organization of IAP-related elements in the genomes of these rodents indicates that amplification or homogenization of this sequence family has occurred independently and at different periods of time during their evolution.     

Structural analysis of type II variants within the mouse intracisternal A-particle sequence family.

Intracisternal A-particle (IAP) elements are present in multiple copies in the mouse and other rodent genomes. The bulk of this sequence family in Mus musculus consists of 7 Kb long elements, but the majority of IAP sequences involved in known transpositions have been deleted forms. The present study describes a subset of deleted IAP sequences (type II IAP) characterized by insertion of a particular short sequence element (AIIins). AIIins are interspersed and the majority occur as part of the type II IAP elements in the mouse genome. AIIins sequences are absent or in low copy number outside Mus musculus. We have isolated clones containing AIIins from a mouse genomic DNA library and have sequenced three isolates of AIIins and their surrounding IAP sequences to define the detailed structure of type II elements. AIIins are 272, 268 and 264 bp long and 90% homologous in sequence. They are bracketed by 9 bp duplications, suggesting they may be inserted elements. A 75 bp region containing a core enhancer sequence is repeated at the 5' end in type II IAP elements. Insertion into the IAP genome, with potential to encode an integrase function, may have played a role in the amplification of AIIins.     

The heterochromatic copies of the LTR retrotransposons as a record of the genomic events that have shaped the Drosophila melanogaster genome

Transposable elements, which are major components of most genomes, are known to accumulate in heterochromatic regions in which they have progressively diverged in sequence by mutations and internal deletions and insertions (indels) during the course of evolution. They therefore provide a record of the genomic events that have shaped the genomes, some of which could correspond to speciation events. Using the sequence divergence between the long terminal repeats (LTRs), we estimated the date of the insertion events of the LTR retrotransposon copies embedded within the heterochromatin regions of the Drosophila melanogaster genome. We did not detect traces of any specific waves of mobilization of retrotransposons within heterochromatin, apart from a very recent wave, which corresponds to the numerous LTR retrotransposon copies found in euchromatin.     

Identification of novel LTR retrotransposons in the genome of Aedes aegypti

We have detected seventy-six novel LTR retrotransposons in the genome of the mosquito Aedes aegypti by a genome wide analysis using the LTR_STRUC program. We have performed a phylogenetic classification of these novel elements and a distribution analysis in the genome of A. aegypti. These mobile elements belong either to the Ty3/gypsy or to the Bel family of retrotransposons and were not annotated in the mosquito LTR retrotransposon database (TEfam). We have found that  1.8% of the genome is occupied by these newly detected retrotransposons that are distributed predominantly in intergenic genomic sequences and introns. The potential role of retrotransposon insertions linked to host genes is described and discussed. We show that a retrotransposon family belonging to the Osvaldo lineage has peculiar structural features, and its presence is likely to be restricted to the A. aegypti and to the Culex pipiens quinquefasciatus genomes. Furthermore we show that the ninja-like group of elements lacks the Primer Binding Site (PBS) sequence necessary for the replication of retrotransposons. These results integrate the knowledge on the complicate genomic structure of an important disease vector.     

Genome-wide assessments reveal extremely high levels of polymorphism of two active families of mouse endogenous retroviral elements

Endogenous retroviral elements (ERVs) in mice are significant genomic mutagens, causing ~10% of all reported spontaneous germ line mutations in laboratory strains. The majority of these mutations are due to insertions of two high copy ERV families, the IAP and ETn/MusD elements. This significant level of ongoing retrotranspositional activity suggests that inbred mice are highly variable in content of these two ERV groups. However, no comprehensive genome-wide studies have been performed to assess their level of polymorphism. Here we compared three test strains, for which sufficient genomic sequence is available, to each other and to the reference C57BL/6J genome and detected very high levels of insertional polymorphism for both ERV families, with an estimated false discovery rate of only 0.4%. Specifically, we found that at least 60% of IAP and 25% of ETn/MusD elements detected in any strain are absent in one or more of the other three strains. The polymorphic nature of a set of 40 ETn/MusD elements found within gene introns was confirmed using genomic PCR on DNA from a panel of mouse strains. For some cases, we detected gene-splicing abnormalities involving the ERV and obtained additional evidence for decreased gene expression in strains carrying the insertion. In total, we identified nearly 700 polymorphic IAP or ETn/MusD ERVs or solitary LTRs that reside in gene introns, providing potential candidates that may contribute to gene expression differences among strains. These extreme levels of polymorphism suggest that ERV insertions play a significant role in genetic drift of mouse lines.     

Natural selection maintains the transcribed LTR retrotransposons in Nosema bombycis

Eight intact LTR retrotransposons (Nbrl-Nbr8) have been previously characterized from the genome of Nosema bombycis, a eu-karyotic parasite with a compact and reduced genome. Here we describe six novel transcribed Nbr elements (Nbr9-Nbrl4) identified through either cDNA library or RT-PCR. Like previously determined ones, all of them belong to the Ty3/Gypsy superfamily. Retro-transposon diversity and incomplete domains with insertions {Nbrll), deletions (Nbrll) and in-frame stop codons in coding regions (Nbr9) were detected, suggesting that both defective and loss events of LTR retrotransposon have happened in N. bombycis genome.Analysis of selection showed that strong purifying selection acts on all elements except Nbrll. This implies that selective pressure keeps both these Nbrs and their functions in genome. Interestingly, Nbrll is under positive selection and some positively selected codons were identified, indicating that new functionality might have evolved in the Nbrll retrotransposon. Unlike other transposable elements, Nbrll has integrated into a conserved syntenic block and probably resulted in the inversion of both flanking regions. This demonstrates that transposable element is an important factor for the reshuffling and evolution of their host genomes, and may be maintained under natural selection.     

Characterization of amplified intracisternal A-particle elements encoding integrase.

Type IIB intracisternal A-particle (IAP) elements have undergone marked amplification and transposition in the genomic DNA of some mouse myelomas. We have made a cDNA library from one such myeloma, MOPC 315, to determine whether some property of the elements themselves has a role in this process. Sequencing of several type IIB cDNAs and one genomic type IIB IAP element has shown that they are nearly identical (greater than 99%) and contain 2 open reading frames (ORFs). ORF2 is capable of encoding the IAP integrase, an enzyme which catalyzes integration of proviral DNA into the genome. An antiserum to a synthetic peptide based on the IAP integrase gene sequence reacted with ORF2 product expressed in bacteria as a fusion protein, and detected a 47 kDa protein, predicted from the size of ORF2, in myeloma cell fractions by Western blotting.     

Microarray analysis of LTR retrotransposon silencing identifies Hdac1 as a regulator of retrotransposon expression in mouse embryonic stem cells

Retrotransposons are highly prevalent in mammalian genomes due to their ability to amplify in pluripotent cells or developing germ cells. Host mechanisms that silence retrotransposons in germ cells and pluripotent cells are important for limiting the accumulation of the repetitive elements in the genome during evolution. However, although silencing of selected individual retrotransposons can be relatively well-studied, many mammalian retrotransposons are seldom analysed and their silencing in germ cells, pluripotent cells or somatic cells remains poorly understood. Here we show, and experimentally verify, that cryptic repetitive element probes present in Illumina and Affymetrix gene expression microarray platforms can accurately and sensitively monitor repetitive element expression data. This computational approach to genome-wide retrotransposon expression has allowed us to identify the histone deacetylase Hdac1 as a component of the retrotransposon silencing machinery in mouse embryonic stem cells, and to determine the retrotransposon targets of Hdac1 in these cells. We also identify retrotransposons that are targets of other retrotransposon silencing mechanisms such as DNA methylation, Eset-mediated histone modification, and Ring1B/Eed-containing polycomb repressive complexes in mouse embryonic stem cells. Furthermore, our computational analysis of retrotransposon silencing suggests that multiple silencing mechanisms are independently targeted to retrotransposons in embryonic stem cells, that different genomic copies of the same retrotransposon can be differentially sensitive to these silencing mechanisms, and helps define retrotransposon sequence elements that are targeted by silencing machineries. Thus repeat annotation of gene expression microarray data suggests that a complex interplay between silencing mechanisms represses retrotransposon loci in germ cells and embryonic stem cells.     

Assessing the role of tandem repeats in shaping the genomic architecture of great apes

Background

Ancestral reconstructions of mammalian genomes have revealed that evolutionary breakpoint regions are clustered in regions that are more prone to break and reorganize. What is still unclear to evolutionary biologists is whether these regions are physically unstable due solely to sequence composition and/or genome organization, or do they represent genomic areas where the selection against breakpoints is minimal.

Methodology and Principal Findings

Here we present a comprehensive study of the distribution of tandem repeats in great apes. We analyzed the distribution of tandem repeats in relation to the localization of evolutionary breakpoint regions in the human, chimpanzee, orangutan and macaque genomes. We observed an accumulation of tandem repeats in the genomic regions implicated in chromosomal reorganizations. In the case of the human genome our analyses revealed that evolutionary breakpoint regions contained more base pairs implicated in tandem repeats compared to synteny blocks, being the AAAT motif the most frequently involved in evolutionary regions. We found that those AAAT repeats located in evolutionary regions were preferentially associated with Alu elements.

Significance

Our observations provide evidence for the role of tandem repeats in shaping mammalian genome architecture. We hypothesize that an accumulation of specific tandem repeats in evolutionary regions can promote genome instability by altering the state of the chromatin conformation or by promoting the insertion of transposable elements.     

Maintenance of the copy number of retrotransposon MDG3 in the Drosophila melanogaster genome]

The genomes of laboratory stocks and natural population of Drosophila melanogaster contain 8-12 copies of retrotransposon MDG3 detected by in situ hybridization. Construction of genotypes with decreased MDG3 copy number using X-chromosome and chromosome 3 free of MDG3 copies results in appearance of hybrid genomes carrying up to 7-10 copies, instead of 2-4 copies expected. New MDG3 copies are detected in different genome regions, including the 42B hot spot of their location. The chromosomes, where new clusters of MDG3 were observed, carry conserved "parental pattern" of MDG1 arrangement. The data obtained suggest the existence of genomic mechanism for maintenance of retrotransposon copy number on a definite level.     

Targeted plasmid integration into the human genome by an engineered zinc-finger recombinase

The development of new methods for gene addition to mammalian genomes is necessary to overcome the limitations of conventional genetic engineering strategies. Although a variety of DNA-modifying enzymes have been used to directly catalyze the integration of plasmid DNA into mammalian genomes, there is still an unmet need for enzymes that target a single specific chromosomal site. We recently engineered zinc-finger recombinase (ZFR) fusion proteins that integrate plasmid DNA into a synthetic target site in the human genome with exceptional specificity. In this study, we present a two-step method for utilizing these enzymes in any cell type at randomly-distributed target site locations. The piggyBac transposase was used to insert recombinase target sites throughout the genomes of human and mouse cell lines. The ZFR efficiently and specifically integrated a transfected plasmid into these genomic target sites and into multiple transposons within a single cell. Plasmid integration was dependent on recombinase activity and the presence of recombinase target sites. This work demonstrates the potential for broad applicability of the ZFR technology in genome engineering, synthetic biology and gene therapy.     

Patterns of transitional mutation biases within and among mammalian genomes

Significant transition/transversion mutation bias is a well-appreciated aspect of mammalian nuclear genomes; however, patterns of bias among genes within a genome and among species remain largely uncharacterized. Understanding these patterns is important for understanding similarities and differences in mutational patterns among genomes and genomic regions. Therefore, we have conducted an analysis of 7,587 pairs of sequences of 4,347 mammalian protein-coding genes from seven species (human, mouse, rat, cow, sheep, pig, and macaque) and from the introns of 51 gene pairs and multiple intergenic regions (37 kbp, 52 kbp and 65 kbp) from the human, chimpanzee, and baboon genomes. Our analyses show that genes and regions with widely varying base composition exhibit uniformity of transition mutation rate both within and among mammalian lineages, as long as the transitional mutations caused by CpG hypermutability are excluded. The estimates show no relationship to potential intrachromosomal or interchromosomal effects. This uniformity points to similarity in point mutation processes in genomic regions with substantially different GC-content biases.