Discovery of novel genes derived from transposable elements using integrative genomic analysis

Complex eukaryotes contain millions of transposable elements (TEs), comprising large fractions of their nuclear genomes. TEs consist of structural, regulatory, and coding sequences that are ordinarily associated with transposition, but that occasionally confer on the organism a selective advantage a...

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Bibliographic Details
Published inMolecular biology and evolution Vol. 32; no. 6; pp. 1487 - 1506
Main Authors Hoen, Douglas R, Bureau, Thomas E
Format Journal Article
LanguageEnglish
Published United States Oxford University Press 01.06.2015
Subjects
Arabidopsis - genetics
Arabidopsis thaliana
Chromosomes, Plant - genetics
DNA Transposable Elements
Eukaryotes
Evolution, Molecular
Exons
Flowers & plants
Genes
Genetic Variation
Genome, Plant
Genomes
Genomics
Genomics - methods
Multigene Family
Phylogeny
Sequence Alignment
exaptation
Brassicaceae
transposable elements
Arabidopsis
tandem arrays of genes
molecular domestication
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Summary:Complex eukaryotes contain millions of transposable elements (TEs), comprising large fractions of their nuclear genomes. TEs consist of structural, regulatory, and coding sequences that are ordinarily associated with transposition, but that occasionally confer on the organism a selective advantage and may thereby become exapted. Exapted transposable element genes (ETEs) are known to play critical roles in diverse systems, from vertebrate adaptive immunity to plant development. Yet despite their evident importance, most ETEs have been identified fortuitously and few systematic searches have been conducted, suggesting that additional ETEs may await discovery. To explore this possibility, we develop a comprehensive systematic approach to searching for ETEs. We use TE-specific conserved domains to identify with high precision genes derived from TEs and screen them for signatures of exaptation based on their similarities to reference sets of known ETEs, conventional (non-TE) genes, and TE genes across diverse genetic attributes including repetitiveness, conservation of genomic location and sequence, and levels of expression and repressive small RNAs. Applying this approach in the model plant Arabidopsis thaliana, we discover a surprisingly large number of novel high confidence ETEs. Intriguingly, unlike known plant ETEs, several of the novel ETE families form tandemly arrayed gene clusters, whereas others are relatively young. Our results not only identify novel TE-derived genes that may have practical applications but also challenge the notion that TE exaptation is merely a relic of ancient life, instead suggesting that it may continue to fundamentally drive evolution.
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ISSN:0737-4038
1537-1719
DOI:10.1093/molbev/msv042