The diversity of class II transposable elements in mammalian genomes has arisen from ancestral phylogenetic splits during ancient waves of proliferation through the genome

DNA transposons make up 3% of the human genome, approximately the same percentage as genes. However, because of their inactivity, they are often ignored in favor of the more abundant, active, retroelements. Despite this relative ignominy, there are a number of interesting questions to be asked of th...

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Veröffentlicht in:	Molecular biology and evolution 2013-01, Vol.30 (1), p.100-108
Hauptverfasser:	Hellen, Elizabeth H B, Brookfield, John F Y
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Sprache:	eng
Schlagworte:	Animals Cats Cattle Discoveries DNA Transposable Elements - genetics Dogs Evolution, Molecular Genetic Variation Genome Genome, Human Humans Mammals - genetics Pan troglodytes Phylogeny Pongo Primates Recombination, Genetic Retroelements - genetics Rodentia Swine Ursidae
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creator	Hellen, Elizabeth H B Brookfield, John F Y
description	DNA transposons make up 3% of the human genome, approximately the same percentage as genes. However, because of their inactivity, they are often ignored in favor of the more abundant, active, retroelements. Despite this relative ignominy, there are a number of interesting questions to be asked of these transposon families. One particular question relates to the timing of proliferation and inactivation of elements in a family. Does an ongoing process of turnover occur, or is the process more akin to a life cycle for the family, with elements proliferating rapidly before deactivation at a later date? We answer this question by tracing back to the most recent common ancestor (MRCA) of each modern transposon family, using two different methods. The first method identifies the MRCA of the species in which a family of transposon fossils can still be found, which we assume will have existed soon after the true origin date of the transposon family. The second method uses molecular dating techniques to predict the age of the MRCA element from which all elements found in a modern genome are descended. Independent data from five pairs of species are used in the molecular dating analysis: human-chimpanzee, human-orangutan, dog-panda, dog-cat, and cow-pig. Orthologous pairs of elements from host species pairs are included, and the divergence dates of these species are used to constrain the analysis. We discover that, in general, the times to element common ancestry for a given family are the same for the different species pairs, suggesting that there has been no order-specific process of turnover. Furthermore, for most families, the ages of the common ancestor of the host species and of that of the elements are similar, suggesting a life cycle model for the proliferation of transposons. Where these two ages differ, in families found only in Primates and Rodentia, for example, we find that the host species date is later than that of the common ancestor of the elements, implying that there may be large deletions of elements from host species, examples of which were found in their ancestors.
doi_str_mv	10.1093/molbev/mss206
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The second method uses molecular dating techniques to predict the age of the MRCA element from which all elements found in a modern genome are descended. Independent data from five pairs of species are used in the molecular dating analysis: human-chimpanzee, human-orangutan, dog-panda, dog-cat, and cow-pig. Orthologous pairs of elements from host species pairs are included, and the divergence dates of these species are used to constrain the analysis. We discover that, in general, the times to element common ancestry for a given family are the same for the different species pairs, suggesting that there has been no order-specific process of turnover. Furthermore, for most families, the ages of the common ancestor of the host species and of that of the elements are similar, suggesting a life cycle model for the proliferation of transposons. 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However, because of their inactivity, they are often ignored in favor of the more abundant, active, retroelements. Despite this relative ignominy, there are a number of interesting questions to be asked of these transposon families. One particular question relates to the timing of proliferation and inactivation of elements in a family. Does an ongoing process of turnover occur, or is the process more akin to a life cycle for the family, with elements proliferating rapidly before deactivation at a later date? We answer this question by tracing back to the most recent common ancestor (MRCA) of each modern transposon family, using two different methods. The first method identifies the MRCA of the species in which a family of transposon fossils can still be found, which we assume will have existed soon after the true origin date of the transposon family. The second method uses molecular dating techniques to predict the age of the MRCA element from which all elements found in a modern genome are descended. Independent data from five pairs of species are used in the molecular dating analysis: human-chimpanzee, human-orangutan, dog-panda, dog-cat, and cow-pig. Orthologous pairs of elements from host species pairs are included, and the divergence dates of these species are used to constrain the analysis. We discover that, in general, the times to element common ancestry for a given family are the same for the different species pairs, suggesting that there has been no order-specific process of turnover. Furthermore, for most families, the ages of the common ancestor of the host species and of that of the elements are similar, suggesting a life cycle model for the proliferation of transposons. Where these two ages differ, in families found only in Primates and Rodentia, for example, we find that the host species date is later than that of the common ancestor of the elements, implying that there may be large deletions of elements from host species, examples of which were found in their ancestors.</description><subject>Animals</subject><subject>Cats</subject><subject>Cattle</subject><subject>Discoveries</subject><subject>DNA Transposable Elements - genetics</subject><subject>Dogs</subject><subject>Evolution, Molecular</subject><subject>Genetic Variation</subject><subject>Genome</subject><subject>Genome, Human</subject><subject>Humans</subject><subject>Mammals - genetics</subject><subject>Pan troglodytes</subject><subject>Phylogeny</subject><subject>Pongo</subject><subject>Primates</subject><subject>Recombination, Genetic</subject><subject>Retroelements - genetics</subject><subject>Rodentia</subject><subject>Swine</subject><subject>Ursidae</subject><issn>0737-4038</issn><issn>1537-1719</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2013</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqFkkuLFDEUhYMoTju6dCtZuikn76reCDL4aBhwM65DKnXTFcmjTKpb-jf5J83Q7aArVzdwv5x7bnIQek3JO0q2_CbmMMLxJtbKiHqCNlTyvqM93T5FG9K3syB8uEIvav1OCBVCqefoirEt40LJDfp1PwOe_BFK9esJZ4dtMLXi3Q6vxaS65GrGABgCREhrxT7haGI0wZuE95ByhIpnU7EpvkLCruSITbJQ2_2Al_kUcsNg9RbXJfgmMR2KT_sHyDdJ_NMcm0SbvJQcvINiVp8TXueSD_u5VbjMeYmeORMqvLrUa_Tt08f72y_d3dfPu9sPd50VjKydYwPldFCTU6PoQVBuKNCBCbe11hEQ1pDB0tYhVgqpnGNWgiJETf0oJsav0fuz7nIYI0y2mWyr6KX4aMpJZ-P1v53kZ73PR80lk1TIJvD2IlDyj0N7CR19tRCCSZAPVTd7UhGpmPg_ynrOKBt60tDujNqSay3gHh1Roh-yoM9Z0OcsNP7N32s80n8-n_8GGjq34Q</recordid><startdate>20130101</startdate><enddate>20130101</enddate><creator>Hellen, Elizabeth H B</creator><creator>Brookfield, John F Y</creator><general>Oxford University Press</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope><scope>8FD</scope><scope>FR3</scope><scope>P64</scope><scope>RC3</scope><scope>5PM</scope></search><sort><creationdate>20130101</creationdate><title>The diversity of class II transposable elements in mammalian genomes has arisen from ancestral phylogenetic splits during ancient waves of proliferation through the genome</title><author>Hellen, Elizabeth H B ; Brookfield, John F Y</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c420t-f2813186df6b47e413a1e1824f9ccf0e4ca08c17e40c5456ff2c5e6006d7b4d23</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2013</creationdate><topic>Animals</topic><topic>Cats</topic><topic>Cattle</topic><topic>Discoveries</topic><topic>DNA Transposable Elements - genetics</topic><topic>Dogs</topic><topic>Evolution, Molecular</topic><topic>Genetic Variation</topic><topic>Genome</topic><topic>Genome, Human</topic><topic>Humans</topic><topic>Mammals - genetics</topic><topic>Pan troglodytes</topic><topic>Phylogeny</topic><topic>Pongo</topic><topic>Primates</topic><topic>Recombination, Genetic</topic><topic>Retroelements - genetics</topic><topic>Rodentia</topic><topic>Swine</topic><topic>Ursidae</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Hellen, Elizabeth H B</creatorcontrib><creatorcontrib>Brookfield, John F Y</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><collection>Technology Research Database</collection><collection>Engineering Research Database</collection><collection>Biotechnology and BioEngineering Abstracts</collection><collection>Genetics Abstracts</collection><collection>PubMed Central (Full Participant titles)</collection><jtitle>Molecular biology and evolution</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Hellen, Elizabeth H B</au><au>Brookfield, John F Y</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>The diversity of class II transposable elements in mammalian genomes has arisen from ancestral phylogenetic splits during ancient waves of proliferation through the genome</atitle><jtitle>Molecular biology and evolution</jtitle><addtitle>Mol Biol Evol</addtitle><date>2013-01-01</date><risdate>2013</risdate><volume>30</volume><issue>1</issue><spage>100</spage><epage>108</epage><pages>100-108</pages><issn>0737-4038</issn><eissn>1537-1719</eissn><abstract>DNA transposons make up 3% of the human genome, approximately the same percentage as genes. 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The second method uses molecular dating techniques to predict the age of the MRCA element from which all elements found in a modern genome are descended. Independent data from five pairs of species are used in the molecular dating analysis: human-chimpanzee, human-orangutan, dog-panda, dog-cat, and cow-pig. Orthologous pairs of elements from host species pairs are included, and the divergence dates of these species are used to constrain the analysis. We discover that, in general, the times to element common ancestry for a given family are the same for the different species pairs, suggesting that there has been no order-specific process of turnover. Furthermore, for most families, the ages of the common ancestor of the host species and of that of the elements are similar, suggesting a life cycle model for the proliferation of transposons. 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subjects	Animals Cats Cattle Discoveries DNA Transposable Elements - genetics Dogs Evolution, Molecular Genetic Variation Genome Genome, Human Humans Mammals - genetics Pan troglodytes Phylogeny Pongo Primates Recombination, Genetic Retroelements - genetics Rodentia Swine Ursidae
title	The diversity of class II transposable elements in mammalian genomes has arisen from ancestral phylogenetic splits during ancient waves of proliferation through the genome
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