Retroviral elements and their hosts: insertional mutagenesis in the mouse germ line

The inbred mouse is an invaluable model for human biology and disease. Nevertheless, when considering genetic mechanisms of variation and disease, it is important to appreciate the significant differences in the spectra of spontaneous mutations that distinguish these species. While insertions of transposable elements are responsible for only ~0.1% of de novo mutations in humans, the figure is 100-fold higher in the laboratory mouse. This striking difference is largely due to the ongoing activity of mouse endogenous retroviral elements. Here we briefly review mouse endogenous retroviruses (ERVs) and their influence on gene expression, analyze mechanisms of interaction between ERVs and the host cell, and summarize the variety of mutations caused by ERV insertions. The prevalence of mouse ERV activity indicates that the genome of the laboratory mouse is presently behind in the “arms race” against invasion.     

Insertional polymorphisms of ETn retrotransposons include a disruption of the wiz gene in C57BL/6 mice

ETn (early transposon) elements are moderate repetitive sequences present in hundreds of copies in the mouse genome. Their length ranges from 4.4 to 7.1 kb, and, like transposons, they contain long terminal repeats (LTRs) on both sides and are flanked by target site duplications (Kaghad et al. 1985). ETn-related elements can be grouped into three distinct families. Members of the ETn I and ETn II families mainly contain sequences of unknown origin in their core region. Only very short stretches of retrovirus-like sequences are present, and there are no ORFs. ETn I and ETn II elements differ primarily in the 3- half of both the 5- and 3- LTR, and in the 5- end of the core region (see Fig. 1). As a consequence, only ETn II elements contain a primer binding site for tRNALys. In contrast to ETn I and ETn II, members of the recently described MusD family (Mager and Freeman 2000) contain ORFs for (at least parts of) D-type virus Gag, Pro, and Pol proteins. However, in other regions they are structurally similar to ETn II elements and contain an intact primer binding site. It has been shown that MusD sequences are evolutionarily older than ETn II elements, suggesting that the latter might have arisen by recombinatory replacement of the MusD gene-coding sequences with sequences of unknown origin (Mager and Freeman 2000). ETn elements are still active as retrotransposons. In the past years, several germ line and somatic mutations caused by fresh ETn integrations have been found (Table 1). From 19 mutations, sufficient sequence is available in seven cases to show that the insertion was an ETn II element. In eight cases, the sequence data available indicate either an ETn II or a MusD element. ETn I has not been found to be the cause of any mutations, prompting the suggestion that ETn II is the "mobile" family, whereas ETn I elements have lost the capacity to retrotranspose.     

Cross-Species Transmission and Differential Fate of an Endogenous Retrovirus in Three Mammal Lineages

Endogenous retroviruses (ERVs) arise from retroviruses chromosomally integrated in the host germline. ERVs are common in vertebrate genomes and provide a valuable fossil record of past retroviral infections to investigate the biology and evolution of retroviruses over a deep time scale, including cross-species transmission events. Here we took advantage of a catalog of ERVs we recently produced for the bat Myotis lucifugus to seek evidence for infiltration of these retroviruses in other mammalian species (>100) currently represented in the genome sequence database. We provide multiple lines of evidence for the cross-ordinal transmission of a gammaretrovirus endogenized independently in the lineages of vespertilionid bats, felid cats and pangolin ~13–25 million years ago. Following its initial introduction, the ERV amplified extensively in parallel in both bat and cat lineages, generating hundreds of species-specific insertions throughout evolution. However, despite being derived from the same viral species, phylogenetic and selection analyses suggest that the ERV experienced different amplification dynamics in the two mammalian lineages. In the cat lineage, the ERV appears to have expanded primarily by retrotransposition of a single proviral progenitor that lost infectious capacity shortly after endogenization. In the bat lineage, the ERV followed a more complex path of germline invasion characterized by both retrotransposition and multiple infection events. The results also suggest that some of the bat ERVs have maintained infectious capacity for extended period of time and may be still infectious today. This study provides one of the most rigorously documented cases of cross-ordinal transmission of a mammalian retrovirus. It also illustrates how the same retrovirus species has transitioned multiple times from an infectious pathogen to a genomic parasite (i.e. retrotransposon), yet experiencing different invasion dynamics in different mammalian hosts.     

Microarray-based global mapping of integration sites for the retrotransposon, intracisternal A-particle, in the mouse genome

Mammalian genomes contain numerous evolutionary harbored mobile elements, a part of which are still active and may cause genomic instability. Their movement and positional diversity occasionally result in phenotypic changes and variation by causing altered expression or disruption of neighboring host genes. Here, we describe a novel microarray-based method by which dispersed genomic locations of a type of retrotransposon in a mammalian genome can be identified. Using this method, we mapped the DNA elements for a mouse retrotransposon, intracisternal A-particle (IAP), within genomes of C3H/He and C57BL/6J inbred mouse strains; consequently we detected hundreds of probable IAP cDNA–integrated genomic regions, in which a considerable number of strain-specific putative insertions were included. In addition, by comparing genomic DNAs from radiation-induced myeloid leukemia cells and its reference normal tissue, we detected three genomic regions around which an IAP element was integrated. These results demonstrate the first successful genome-wide mapping of a retrotransposon type in a mammalian genome.     

Genome-Wide Characterization of Endogenous Retroviruses in the Bat Myotis lucifugus Reveals Recent and Diverse Infections

Bats are increasingly recognized as reservoir species for a variety of zoonotic viruses that pose severe threats to human health. While many RNA viruses have been identified in bats, little is known about bat retroviruses. Endogenous retroviruses (ERVs) represent genomic fossils of past retroviral infections and, thus, can inform us on the diversity and history of retroviruses that have infected a species lineage. Here, we took advantage of the availability of a high-quality genome assembly for the little brown bat, Myotis lucifugus, to systematically identify and analyze ERVs in this species. We mined an initial set of 362 potentially complete proviruses from the three main classes of ERVs, which were further resolved into 13 major families and 86 subfamilies by phylogenetic analysis. Consensus or representative sequences for each of the 86 subfamilies were then merged to the Repbase collection of known ERV/long terminal repeat (LTR) elements to annotate the retroviral complement of the bat genome. The results show that nearly 5% of the genome assembly is occupied by ERV-derived sequences, a quantity comparable to findings for other eutherian mammals. About one-fourth of these sequences belong to subfamilies newly identified in this study. Using two independent methods, intraelement LTR divergence and analysis of orthologous loci in two other bat species, we found that the vast majority of the potentially complete proviruses identified in M. lucifugus were integrated in the last ∼25 million years. All three major ERV classes include recently integrated proviruses, suggesting that a wide diversity of retroviruses is still circulating in Myotis bats.     

Evolutionary history of the human endogenous retrovirus family ERV9

Several distinct families of endogenous retrovirus-like elements (ERVs) exist in the genomes of primates. Despite the important evolutionary consequences that carrying these intragenomic parasites may have for their hosts, our knowledge about their evolution is still scarce. A matter of particular interest is whether evolution of ERVs occurs via a master lineage or through several lineages coexisting over long periods of time. In this work, the paleogenomic approach has been applied to the study of the evolution of ERV9, one of the human endogenous retrovirus families mobilized during primate evolution. By searching the GenBank database with the first 676 bp of the ERV9 long terminal repeat, we identified 156 different element insertions into the human genome. These elements were grouped into 14 subfamilies based on several characteristic nucleotide differences. The age of each subfamily was roughly estimated based on the average sequence divergence of its members from the subfamily consensus sequence. Determination of the sequential order of diagnostic substitutions led to the identification of four distinct lineages, which retained their capacity of transposition over extended periods of evolution. Strong evidence for mosaic evolution of some of these lineages is presented. Taken altogether, the available data indicate that the possibility of ERV9 still being active in the human lineage can not be discarded.     

Integration and Fixation Preferences of Human and Mouse Endogenous Retroviruses Uncovered with Functional Data Analysis

Endogenous retroviruses (ERVs), the remnants of retroviral infections in the germ line, occupy ~8% and ~10% of the human and mouse genomes, respectively, and affect their structure, evolution, and function. Yet we still have a limited understanding of how the genomic landscape influences integration and fixation of ERVs. Here we conducted a genome-wide study of the most recently active ERVs in the human and mouse genome. We investigated 826 fixed and 1,065 in vitro HERV-Ks in human, and 1,624 fixed and 242 polymorphic ETns, as well as 3,964 fixed and 1,986 polymorphic IAPs, in mouse. We quantitated >40 human and mouse genomic features (e.g., non-B DNA structure, recombination rates, and histone modifications) in ±32 kb of these ERVs’ integration sites and in control regions, and analyzed them using Functional Data Analysis (FDA) methodology. In one of the first applications of FDA in genomics, we identified genomic scales and locations at which these features display their influence, and how they work in concert, to provide signals essential for integration and fixation of ERVs. The investigation of ERVs of different evolutionary ages (young in vitro and polymorphic ERVs, older fixed ERVs) allowed us to disentangle integration vs. fixation preferences. As a result of these analyses, we built a comprehensive model explaining the uneven distribution of ERVs along the genome. We found that ERVs integrate in late-replicating AT-rich regions with abundant microsatellites, mirror repeats, and repressive histone marks. Regions favoring fixation are depleted of genes and evolutionarily conserved elements, and have low recombination rates, reflecting the effects of purifying selection and ectopic recombination removing ERVs from the genome. In addition to providing these biological insights, our study demonstrates the power of exploiting multiple scales and localization with FDA. These powerful techniques are expected to be applicable to many other genomic investigations.