| 1. |
- Barrio, Alvaro Martinez, et al.
(author)
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The First Sequenced Carnivore Genome Shows Complex Host-Endogenous Retrovirus Relationships
- 2011
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In: PLOS ONE. - : Public Library of Science (PLoS). - 1932-6203. ; 6:5, s. e19832-
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Journal article (peer-reviewed)abstract
- Host-retrovirus interactions influence the genomic landscape and have contributed substantially to mammalian genome evolution. To gain further insights, we analyzed a female boxer (Canis familiaris) genome for complexity and integration pattern of canine endogenous retroviruses (CfERV). Intriguingly, the first such in-depth analysis of a carnivore species identified 407 CfERV proviruses that represent only 0.15% of the dog genome. In comparison, the same detection criteria identified about six times more HERV proviruses in the human genome that has been estimated to contain a total of 8% retroviral DNA including solitary LTRs. These observed differences in man and dog are likely due to different mechanisms to purge, restrict and protect their genomes against retroviruses. A novel group of gammaretrovirus-like CfERV with high similarity to HERV-Fc1 was found to have potential for active retrotransposition and possibly lateral transmissions between dog and human as a result of close interactions during at least 10.000 years. The CfERV integration landscape showed a non-uniform intra-and inter-chromosomal distribution. Like in other species, different densities of ERVs were observed. Some chromosomal regions were essentially devoid of CfERVs whereas other regions had large numbers of integrations in agreement with distinct selective pressures at different loci. Most CfERVs were integrated in antisense orientation within 100 kb from annotated protein-coding genes. This integration pattern provides evidence for selection against CfERVs in sense orientation relative to chromosomal genes. In conclusion, this ERV analysis of the first carnivorous species supports the notion that different mammals interact distinctively with endogenous retroviruses and suggests that retroviral lateral transmissions between dog and human may have occurred.
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| 2. |
- Benachenhou, Farid, et al.
(author)
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Conserved structure and inferred evolutionary history of long terminal repeats (LTRs)
- 2013
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In: Mobile DNA. - : Springer Science and Business Media LLC. - 1759-8753. ; 4, s. 5-
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Journal article (peer-reviewed)abstract
- Background: Long terminal repeats (LTRs, consisting of U3-R-U5 portions) are important elements of retroviruses and related retrotransposons. They are difficult to analyse due to their variability. The aim was to obtain a more comprehensive view of structure, diversity and phylogeny of LTRs than hitherto possible. Results: Hidden Markov models (HMM) were created for 11 clades of LTRs belonging to Retroviridae (class III retroviruses), animal Metaviridae (Gypsy/Ty3) elements and plant Pseudoviridae (Copia/Ty1) elements, complementing our work with Orthoretrovirus HMMs. The great variation in LTR length of plant Metaviridae and the few divergent animal Pseudoviridae prevented building HMMs from both of these groups. Animal Metaviridae LTRs had the same conserved motifs as retroviral LTRs, confirming that the two groups are closely related. The conserved motifs were the short inverted repeats (SIRs), integrase recognition signals (5' TGTTRNR ... YNYAACA 3'); the polyadenylation signal or AATAAA motif; a GT-rich stretch downstream of the polyadenylation signal; and a less conserved AT-rich stretch corresponding to the core promoter element, the TATA box. Plant Pseudoviridae LTRs differed slightly in having a conserved TATA-box, TATATA, but no conserved polyadenylation signal, plus a much shorter R region. The sensitivity of the HMMs for detection in genomic sequences was around 50% for most models, at a relatively high specificity, suitable for genome screening. The HMMs yielded consensus sequences, which were aligned by creating an HMM model (a 'Superviterbi' alignment). This yielded a phylogenetic tree that was compared with a Pol-based tree. Both LTR and Pol trees supported monophyly of retroviruses. In both, Pseudoviridae was ancestral to all other LTR retrotransposons. However, the LTR trees showed the chromovirus portion of Metaviridae clustering together with Pseudoviridae, dividing Metaviridae into two portions with distinct phylogeny. Conclusion: The HMMs clearly demonstrated a unitary conserved structure of LTRs, supporting that they arose once during evolution. We attempted to follow the evolution of LTRs by tracing their functional foundations, that is, acquisition of RNAse H, a combined promoter/polyadenylation site, integrase, hairpin priming and the primer binding site (PBS). Available information did not support a simple evolutionary chain of events.
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| 3. |
- Benachenhou, Farid, et al.
(author)
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Evolutionary Conservation of Orthoretroviral Long Terminal Repeats (LTRs) and ab initio Detection of Single LTRs in Genomic Data
- 2009
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In: PLos ONE. - : Public Library of Science (PLoS). - 1932-6203. ; 4:4, s. e5179-
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Journal article (peer-reviewed)abstract
- BACKGROUND: Retroviral LTRs, paired or single, influence the transcription of both retroviral and non-retroviral genomic sequences. Vertebrate genomes contain many thousand endogenous retroviruses (ERVs) and their LTRs. Single LTRs are difficult to detect from genomic sequences without recourse to repetitiveness or presence in a proviral structure. Understanding of LTR structure increases understanding of LTR function, and of functional genomics. Here we develop models of orthoretroviral LTRs useful for detection in genomes and for structural analysis. PRINCIPAL FINDINGS: Although mutated, ERV LTRs are more numerous and diverse than exogenous retroviral (XRV) LTRs. Hidden Markov models (HMMs), and alignments based on them, were created for HML- (human MMTV-like), general-beta-, gamma- and lentiretroviruslike LTRs, plus a general-vertebrate LTR model. Training sets were XRV LTRs and RepBase LTR consensuses. The HML HMM was most sensitive and detected 87% of the HML LTRs in human chromosome 19 at 96% specificity. By combining all HMMs with a low cutoff, for screening, 71% of all LTRs found by RepeatMasker in chromosome 19 were found. HMM consensus sequences had a conserved modular LTR structure. Target site duplications (TG-CA), TATA (occasionally absent), an AATAAA box and a T-rich region were prominent features. Most of the conservation was located in, or adjacent to, R and U5, with evidence for stem loops. Several of the long HML LTRs contained long ORFs inserted after the second A rich module. HMM consensus alignment allowed comparison of functional features like transcriptional start sites (sense and antisense) between XRVs and ERVs. CONCLUSION: The modular conserved and redundant orthoretroviral LTR structure with three A-rich regions is reminiscent of structurally relaxed Giardia promoters. The five HMMs provided a novel broad range, repeat-independent, ab initio LTR detection, with prospects for greater generalisation, and insight into LTR structure, which may aid development of LTR-targeted pharmaceuticals.
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| 4. |
- Benachenhou, Farid, 1966-
(author)
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Retroviral long Terminal Repeats; Structure, Detection and Phylogeny
- 2010
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Doctoral thesis (other academic/artistic)abstract
- Long terminal repeats (LTRs) are non-coding repeats flanking the protein-coding genes of LTR retrotransposons. The variability of LTRs poses a challenge in studying them. Hidden Markov models (HMMs), probabilistic models widely used in pattern recognition, are useful in dealing with this variability. The aim of this work was mainly to study LTRs of retroviruses and LTR retrotransposons using HMMs. Paper I describes the methodology of HMM modelling applied to different groups of LTRs from exogenous retroviruses (XRVs) and endogenous retroviruses (ERVs). The detection capabilities of HMMs were assessed and were found to be high for homogeneous groups of LTRs. The alignments generated by the HMMs displayed conserved motifs some of which could be related to known functions of XRVs. The common features of the different groups of retroviral LTRs were investigated by combining them into a single alignment. They were the short inverted terminal repeats TG and CA and three AT-rich stretches which provide retroviruses with TATA boxes and AATAAA polyadenylation signals. In Paper II, phylogenetic trees of three groups of retroviral LTRs were constructed by using HMM-based alignments. The LTR trees were consistent with trees based on other retroviral genes suggesting co-evolution between LTRs and these genes. In Paper III, the methods in Paper I and II were extended to LTRs from other retrotransposon groups, covering much of the diversity of all known LTRs. For the first time an LTR phylogeny could be achieved. There were no major disagreement between the LTR tree and trees based on three different domains of the Pol gene. The conserved LTR structure of paper I was found to apply to all LTRs. Putative Integrase recognition motifs extended up to 12 bp beyond the short inverted repeats TG/CA. Paper IV is a review article describing the use of sequence similarity and structural markers for the taxonomy of ERVs. ERVs were originally classified into three classes according to the length of the target site duplication. While this classification is useful it does not include all ERVs. A naming convention based on previous ERV and XRV nomenclature but taking into account newer information is advocated in order to provide a practical yet coherent scheme in dealing with new unclassified ERV sequences. Paper V gives an overview of bioinformatics tools for studies of ERVs and of retroviral evolution before and after endogenization. It gives some examples of recent integrations in vertebrate genomes and discusses pathogenicity of human ERVs including their possible relation to cancers. In conclusion, HMMs were able to successfully detect and align LTRs. Progress was made in understanding their conserved structure and phylogeny. The methods developed in this thesis could be applied to different kinds of non-coding DNA sequence element.
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| 5. |
- Benachenhou, Farid, et al.
(author)
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The phylogeny of orthoretroviral long terminal repeats (LTRs)
- 2009
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In: Gene. - Amsterdam : Elsevier. - 0378-1119 .- 1879-0038. ; 448:2, s. 134-138
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Journal article (peer-reviewed)abstract
- LTRs are sequence elements in retroviruses and retrotransposons which are difficult to align due to their variability. One way of handling such cases is to use Hidden Markov Models (HMMs). In this work HMMs of LTRs were constructed for three groups of orthoretroviruses: the betaretroviruslike human MMTV-like (HML) endogenous retroviruses, the lentiviruses, including HIV, and gammaretroviruslike human endogenous retroviruses (HERVs). The HMM-generated LTR alignments and the phylogenetic trees constructed from them were compared with trees based on alignments of the pol gene at the nucleic acid level. The majority of branches in the LTR and pol based trees had the same order for the three retroviral genera, showing that HMM methods are successful in aligning and constructing phylogenies of LTRs. The HML LTR tree deviated somewhat from the pol tree for the groups HML3, HML7 and HML6. Among the gammaretroviruslike proviruses, the exogenous Mouse Leukemia Virus (MLV) was highly related to HERV-T in the pol based tree, but not in the LTR based tree. Aside from these differences, the similarity between the trees indicates that LTRs and pol coevolved in a largely monophyletic way.
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| 6. |
- Benachenhou, Farid, et al.
(author)
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Universal structure and phylogeny of Long Terminal Repeats (LTRs)
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Other publication (other academic/artistic)abstract
- Long terminal repeats (LTRs) are important sequence elements of retroviruses and related retrotransposons. They are however difficult to analyse due to their variability. The aim of this work was to construct models of LTRs from all known groups of LTR retrotransposons and retroviruses, representative of the entire LTR diversity, making it possible for the first time to comprehensively study their phylogeny and to compare it to phylogenies of other retrotransposon genes. A general HMM describing all LTRs was built. Its associated Viterbi alignment showed a consistent basic structure with inverted repeats starting with TGTT at the 5´end, ending with AACA at the 3´ end, plus two conserved AT-rich areas, the first one often containing the TATA box and the second one containing the polyadenylation signal AATAAA. A less conserved AT-rich stretch was apparent in the likely U3 portion. R was harder to delineate. The polyadenylation signal was followed by a T rich area characteristic of U5. The modular LTR structure previously reported by us, with modules separated by clusters of insert states, was also observed in this pan-LTR setting The result attests to the highly conserved basic structure of LTRs, which must date over a billion years back. Hidden Markov models (HMM) were also created for 14 subgroups of LTRs. The HMMs yielded consensus sequences which were aligned to a "Superviterbi" alignment. The Superviterbi alignment yielded a phylogenetic tree which was consistent with a tree based on an alignment of concatenated RT, RNAse H and INT proteins. In particular it gave further support for the monophyly of retroviral LTRs. The phylogenetic reconstruction now allows inferences regarding the origin of LTR retrotransposons.
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| 7. |
- Blikstad, Vidar, et al.
(author)
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Evolution of human endogenous retroviral sequences : a conceptual account
- 2008
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In: Cellular and Molecular Life Sciences (CMLS). - : Springer Science and Business Media LLC. - 1420-682X .- 1420-9071. ; 65:21, s. 3348-3365
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Research review (peer-reviewed)abstract
- Endogenous retroviruses (ERVs) most likely are remnants of ancient retroviral infections. ERVs preserve functions of exogenous retroviruses to a varying extent, and can be parasites, symbionts or more or less neutral genetic 'junk'.Their evolution has two facets, pre- and post-endogenization. Although the two are not clearly separated, the first pertains to retroviral evolution in general and the second to the fate of repetitive DNA and the evolution of the host organism and its genome. The study of ERVs provides much material for the understanding of retroviral evolution. This sequence archive reflects the history of successes and shortcomings of antiviral resistance, but also of strategic evolutionary decisions regarding genome organization and new gene acquisition. This review discusses retroviral evolution illustrated through HERVs, bioinformatic prerequisites for ERV studies, the endogenization process and HERV evolution post-endogenization, including relation to disease. (Part of a multi-author review).
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| 8. |
- Blomberg, Jonas, et al.
(author)
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Classification and nomenclature of endogenous retroviral sequences (ERVs) : problems and recommendations
- 2009
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In: Gene. - Amsterdam : Elsevier. - 0378-1119 .- 1879-0038. ; 448:2, s. 115-123
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Research review (peer-reviewed)abstract
- The genomes of many species are crowded with repetitive mobile sequences. In the case of endogenous retroviruses (ERVs) there is, for various reasons, considerable confusion regarding names assigned to families/groups of ERVs as well as individual ERV loci. Human ERVs have been studied in greater detail, and naming of HERVs in the scientific literature is somewhat confusing not just to the outsider. Without guidelines, confusion for ERVs in other species will also probably increase if those ERVs are studied in greater detail. Based on previous experience, this review highlights some of the problems when naming and classifying ERVs, and provides some guidance for detecting and characterizing ERV sequences. Because of the close relationship between ERVs and exogenous retroviruses (XRVs) it is reasonable to reconcile their classification with that of XRVs. We here argue that classification should be based on a combination of similarity, structural features, (inferred) function, and previous nomenclature. Because the RepBase system is widely employed in genome annotation, RepBase designations should be considered in further taxonomic efforts. To lay a foundation for a phylogenetically based taxonomy, further analyses of ERVs in many hosts are needed. A dedicated, permanent, international consortium would best be suited to integrate and communicate our current and future knowledge on repetitive, mobile elements in general to the scientific community.
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| 9. |
- Blomberg, Jonas, et al.
(author)
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Towards a retrovirus database, RetroBank
- 2010
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In: Centennial Retrovirus Meeting. - Bologna, Italy : Medimond. - 9788875875862 ; , s. 19-22
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Conference paper (other academic/artistic)
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| 10. |
- Bolisetty, M., et al.
(author)
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Unexpected diversity and expression of avian endogenous retroviruses
- 2012
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In: mBio. - 2161-2129. ; 3:5, s. e00344-12
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Journal article (peer-reviewed)abstract
- Endogenous retroviruses (ERVs) were identified and characterized in three avian genomes to gain insight into early retroviral evolution. Using the computer program RetroTector to detect relatively intact ERVs, we identified 500 ERVs in the chicken genome, 150 in the turkey genome, and 1,200 in the zebra finch genome. Previous studies suggested that endogenous alpharetroviruses were present in chicken genomes. In this analysis, a small number of alpharetroviruses were seen in the chicken and turkey genomes; however, these were greatly outnumbered by beta-like, gamma-like, and alphabeta proviruses. While the avian ERVs belonged to the same major groups as mammalian ERVs, they were more heterogeneous. In particular, the beta-like viruses revealed an evolutionary continuum with the gradual acquisition and loss of betaretroviral markers and a transition from beta to alphabeta and then to alpharetroviruses. Thus, it appears that birds may resemble a melting pot for early ERV evolution. Many of the ERVs were integrated in clusters on chromosomes, often near centromeres. About 25% of the chicken ERVs were in or near cellular transcription units; this is nearly random. The majority of these integrations were in the sense orientation in introns. A higher-than-random number of integrations were >100 kb from the nearest gene. Deep-sequencing studies of chicken embryo fibroblasts revealed that about 20% of the 500 ERVs were transcribed and translated. A subset of these were also transcribed in vivo in chickens, showing tissue-specific patterns of expression.
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