This Déjà vu feeling--analysis of multidomain protein evolution in eukaryotic genomes.

Evolutionary innovation in eukaryotes and especially animals is at least partially driven by genome rearrangements and the resulting emergence of proteins with new domain combinations, and thus potentially novel functionality. Given the random nature of such rearrangements, one could expect that pro...

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Main Authors: Christian M Zmasek, Adam Godzik
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2012-01-01
Series:PLoS Computational Biology
Online Access:http://europepmc.org/articles/PMC3499355?pdf=render
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spelling doaj-a119082930294b399d3f36463b0e4a762020-11-25T01:44:11ZengPublic Library of Science (PLoS)PLoS Computational Biology1553-734X1553-73582012-01-01811e100270110.1371/journal.pcbi.1002701This Déjà vu feeling--analysis of multidomain protein evolution in eukaryotic genomes.Christian M ZmasekAdam GodzikEvolutionary innovation in eukaryotes and especially animals is at least partially driven by genome rearrangements and the resulting emergence of proteins with new domain combinations, and thus potentially novel functionality. Given the random nature of such rearrangements, one could expect that proteins with particularly useful multidomain combinations may have been rediscovered multiple times by parallel evolution. However, existing reports suggest a minimal role of this phenomenon in the overall evolution of eukaryotic proteomes. We assembled a collection of 172 complete eukaryotic genomes that is not only the largest, but also the most phylogenetically complete set of genomes analyzed so far. By employing a maximum parsimony approach to compare repertoires of Pfam domains and their combinations, we show that independent evolution of domain combinations is significantly more prevalent than previously thought. Our results indicate that about 25% of all currently observed domain combinations have evolved multiple times. Interestingly, this percentage is even higher for sets of domain combinations in individual species, with, for instance, 70% of the domain combinations found in the human genome having evolved independently at least once in other species. We also show that previous, much lower estimates of this rate are most likely due to the small number and biased phylogenetic distribution of the genomes analyzed. The process of independent emergence of identical domain combination is widespread, not limited to domains with specific functional categories. Besides data from large-scale analyses, we also present individual examples of independent domain combination evolution. The surprisingly large contribution of parallel evolution to the development of the domain combination repertoire in extant genomes has profound consequences for our understanding of the evolution of pathways and cellular processes in eukaryotes and for comparative functional genomics.http://europepmc.org/articles/PMC3499355?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Christian M Zmasek
Adam Godzik
spellingShingle Christian M Zmasek
Adam Godzik
This Déjà vu feeling--analysis of multidomain protein evolution in eukaryotic genomes.
PLoS Computational Biology
author_facet Christian M Zmasek
Adam Godzik
author_sort Christian M Zmasek
title This Déjà vu feeling--analysis of multidomain protein evolution in eukaryotic genomes.
title_short This Déjà vu feeling--analysis of multidomain protein evolution in eukaryotic genomes.
title_full This Déjà vu feeling--analysis of multidomain protein evolution in eukaryotic genomes.
title_fullStr This Déjà vu feeling--analysis of multidomain protein evolution in eukaryotic genomes.
title_full_unstemmed This Déjà vu feeling--analysis of multidomain protein evolution in eukaryotic genomes.
title_sort this déjà vu feeling--analysis of multidomain protein evolution in eukaryotic genomes.
publisher Public Library of Science (PLoS)
series PLoS Computational Biology
issn 1553-734X
1553-7358
publishDate 2012-01-01
description Evolutionary innovation in eukaryotes and especially animals is at least partially driven by genome rearrangements and the resulting emergence of proteins with new domain combinations, and thus potentially novel functionality. Given the random nature of such rearrangements, one could expect that proteins with particularly useful multidomain combinations may have been rediscovered multiple times by parallel evolution. However, existing reports suggest a minimal role of this phenomenon in the overall evolution of eukaryotic proteomes. We assembled a collection of 172 complete eukaryotic genomes that is not only the largest, but also the most phylogenetically complete set of genomes analyzed so far. By employing a maximum parsimony approach to compare repertoires of Pfam domains and their combinations, we show that independent evolution of domain combinations is significantly more prevalent than previously thought. Our results indicate that about 25% of all currently observed domain combinations have evolved multiple times. Interestingly, this percentage is even higher for sets of domain combinations in individual species, with, for instance, 70% of the domain combinations found in the human genome having evolved independently at least once in other species. We also show that previous, much lower estimates of this rate are most likely due to the small number and biased phylogenetic distribution of the genomes analyzed. The process of independent emergence of identical domain combination is widespread, not limited to domains with specific functional categories. Besides data from large-scale analyses, we also present individual examples of independent domain combination evolution. The surprisingly large contribution of parallel evolution to the development of the domain combination repertoire in extant genomes has profound consequences for our understanding of the evolution of pathways and cellular processes in eukaryotes and for comparative functional genomics.
url http://europepmc.org/articles/PMC3499355?pdf=render
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