Lateral gene transfer as a support for the tree of life

Lateral gene transfer (LGT), the acquisition of genes from other species, is a major evolutionary force. However, its success as an adaptive process makes the reconstruction of the history of life an intricate puzzle: If no gene has remained unaffected during the course of life's evolution, how...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 109; no. 13; pp. 4962 - 4967
Main Authors Abby, Sophie S., Tannier, Eric, Gouy, Manolo, Daubin, Vincent
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 27.03.2012
National Acad Sciences
Subjects
Actinobacteria
Archaea - genetics
Bacteria - genetics
Biodiversity
Biological Sciences
Biological taxonomies
Biomarkers
Datasets
Evolution
Evolution, Molecular
Evolutionary genetics
Gene families
Gene transfer
Gene Transfer, Horizontal - genetics
Genomes
Horizontal gene transfer
Life Sciences
Macromolecules
Microorganisms
Models, Genetic
Phylogenetics
Phylogeny
Plant roots
Proteins
Roots
Signal transduction
Species Specificity
Systematics, Phylogenetics and taxonomy
We they distinction
genome evolution
phylogeny
bacteria
archaea
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Summary:Lateral gene transfer (LGT), the acquisition of genes from other species, is a major evolutionary force. However, its success as an adaptive process makes the reconstruction of the history of life an intricate puzzle: If no gene has remained unaffected during the course of life's evolution, how can one rely on molecular markers to reconstruct the relationships among species? Here, we take a completely different look at LGT and its impact for the reconstruction of the history of life. Rather than trying to remove the effect of LGT in phytogenies, and ignoring as a result most of the information of gene histories, we use an explicit phylogenetic model of gene transfer to reconcile gene histories with the tree of species. We studied 16 bacterial and archaeal phyla, representing a dataset of 12,000 gene families distributed in 336 genomes. Our results show that, in most phyla, LGT provides an abundant phylogenetic signal on the pattern of species diversification and that this signal is robust to the choice of gene families under study. We also find that LGT brings an abundant signal on the location of the root of species trees, which has been previously overlooked. Our results quantify the great variety of gene transfer rates among lineages of the tree of life and provide strong support for the "complexity hypothesis," which states that genes whose products participate to macromolecular protein complexes are relatively resistant to transfer.
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Author contributions: S.S.A., E.T., M.G., and V.D. designed research; S.S.A. and V.D. performed research; S.S.A., E.T., M.G., and V.D. analyzed data; and S.S.A., E.T., M.G., and V.D. wrote the paper.
Edited* by Nancy A. Moran, Yale University, West Haven, CT, and approved February 10, 2012 (received for review October 14, 2011)
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1116871109