Literature DB >> 16790583

The evolution of mobile DNAs: when will transposons create phylogenies that look as if there is a master gene?

John F Y Brookfield1, Louise J Johnson.   

Abstract

Some families of mammalian interspersed repetitive DNA, such as the Alu SINE sequence, appear to have evolved by the serial replacement of one active sequence with another, consistent with there being a single source of transposition: the "master gene." Alternative models, in which multiple source sequences are simultaneously active, have been called "transposon models." Transposon models differ in the proportion of elements that are active and in whether inactivation occurs at the moment of transposition or later. Here we examine the predictions of various types of transposon model regarding the patterns of sequence variation expected at an equilibrium between transposition, inactivation, and deletion. Under the master gene model, all bifurcations in the true tree of elements occur in a single lineage. We show that this property will also hold approximately for transposon models in which most elements are inactive and where at least some of the inactivation events occur after transposition. Such tree shapes are therefore not conclusive evidence for a single source of transposition.

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Year:  2006        PMID: 16790583      PMCID: PMC1526530          DOI: 10.1534/genetics.104.027219

Source DB:  PubMed          Journal:  Genetics        ISSN: 0016-6731            Impact factor:   4.562


  25 in total

1.  Selection on Alu sequences?

Authors:  J F Brookfield
Journal:  Curr Biol       Date:  2001-11-13       Impact factor: 10.834

2.  Adaptive evolution in LINE-1 retrotransposons.

Authors:  S Boissinot; A V Furano
Journal:  Mol Biol Evol       Date:  2001-12       Impact factor: 16.240

3.  L1 (LINE-1) retrotransposon evolution and amplification in recent human history.

Authors:  S Boissinot; P Chevret; A V Furano
Journal:  Mol Biol Evol       Date:  2000-06       Impact factor: 16.240

4.  Potential for retroposition by old Alu subfamilies.

Authors:  Karla Johanning; Claudina Alemán Stevenson; Oluwatosin O Oyeniran; Yair M Gozal; Astrid M Roy-Engel; Jerzy Jurka; Prescott L Deininger
Journal:  J Mol Evol       Date:  2003-06       Impact factor: 2.395

5.  Master genes in mammalian repetitive DNA amplification.

Authors:  P L Deininger; M A Batzer; C A Hutchison; M H Edgell
Journal:  Trends Genet       Date:  1992-09       Impact factor: 11.639

6.  Transposable elements in mendelian populations. I. A theory.

Authors:  C H Langley; J F Brookfield; N Kaplan
Journal:  Genetics       Date:  1983-07       Impact factor: 4.562

7.  Structure and variability of recently inserted Alu family members.

Authors:  M A Batzer; G E Kilroy; P E Richard; T H Shaikh; T D Desselle; C L Hoppens; P L Deininger
Journal:  Nucleic Acids Res       Date:  1990-12-11       Impact factor: 16.971

8.  A model for DNA sequence evolution within transposable element families.

Authors:  J F Brookfield
Journal:  Genetics       Date:  1986-02       Impact factor: 4.562

9.  Alu insertion polymorphisms and human evolution: evidence for a larger population size in Africa.

Authors:  M Stoneking; J J Fontius; S L Clifford; H Soodyall; S S Arcot; N Saha; T Jenkins; M A Tahir; P L Deininger; M A Batzer
Journal:  Genome Res       Date:  1997-11       Impact factor: 9.043

Review 10.  Alu repeats and human disease.

Authors:  P L Deininger; M A Batzer
Journal:  Mol Genet Metab       Date:  1999-07       Impact factor: 4.797
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  15 in total

1.  In search of lost trajectories: Recovering the diversification of transposable elements.

Authors:  Timothée Flutre; Emmanuelle Permal; Hadi Quesneville
Journal:  Mob Genet Elements       Date:  2011-07-01

2.  Analysis of genes associated with retrotransposons in the rice genome.

Authors:  Nicholas Krom; Jill Recla; Wusirika Ramakrishna
Journal:  Genetica       Date:  2007-12-09       Impact factor: 1.082

3.  Recent spread of a retrotransposon in the Silene latifolia genome, apart from the Y chromosome.

Authors:  Dmitry A Filatov; Elaine C Howell; Constantinos Groutides; Susan J Armstrong
Journal:  Genetics       Date:  2008-12-08       Impact factor: 4.562

4.  Families of transposable elements, population structure and the origin of species.

Authors:  Jerzy Jurka; Weidong Bao; Kenji K Kojima
Journal:  Biol Direct       Date:  2011-09-19       Impact factor: 4.540

5.  Estimating the age of retrotransposon subfamilies using maximum likelihood.

Authors:  Elizabeth E Marchani; Jinchuan Xing; David J Witherspoon; Lynn B Jorde; Alan R Rogers
Journal:  Genomics       Date:  2009-04-18       Impact factor: 5.736

6.  The tempo and mode of evolution of transposable elements as revealed by molecular phylogenies reconstructed from mosquito genomes.

Authors:  Claudio J Struchiner; Eduardo Massad; Zhijian Tu; José M C Ribeiro
Journal:  Evolution       Date:  2009-07-28       Impact factor: 3.694

7.  Reconstructing the evolutionary history of transposable elements.

Authors:  Arnaud Le Rouzic; Thibaut Payen; Aurélie Hua-Van
Journal:  Genome Biol Evol       Date:  2013       Impact factor: 3.416

8.  Inference of transposable element ancestry.

Authors:  Aaron C Wacholder; Corey Cox; Thomas J Meyer; Robert P Ruggiero; Vijetha Vemulapalli; Annette Damert; Lucia Carbone; David D Pollock
Journal:  PLoS Genet       Date:  2014-08-14       Impact factor: 5.917

9.  A snapshot of histone modifications within transposable elements in Drosophila wild type strains.

Authors:  Rita Rebollo; Béatrice Horard; Flora Begeot; Marion Delattre; Eric Gilson; Cristina Vieira
Journal:  PLoS One       Date:  2012-09-04       Impact factor: 3.240

10.  Transposable element invasions.

Authors:  Elizabeth H B Hellen; John F Y Brookfield
Journal:  Mob Genet Elements       Date:  2013-01-01
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