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On the nature of fur evolution: A phylogenetic approach in Actinobacteria

BACKGROUND: An understanding of the evolution of global transcription regulators is essential for comprehending the complex networks of cellular metabolism that have developed among related organisms. The fur gene encodes one of those regulators – the ferric uptake regulator Fur – widely distributed...

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Autores principales: Santos, Catarina L, Vieira, João, Tavares, Fernando, Benson, David R, Tisa, Louis S, Berry, Alison M, Moradas-Ferreira, Pedro, Normand, Philippe
Formato: Texto
Lenguaje:English
Publicado: BioMed Central 2008
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2464607/
https://www.ncbi.nlm.nih.gov/pubmed/18578876
http://dx.doi.org/10.1186/1471-2148-8-185
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author Santos, Catarina L
Vieira, João
Tavares, Fernando
Benson, David R
Tisa, Louis S
Berry, Alison M
Moradas-Ferreira, Pedro
Normand, Philippe
author_facet Santos, Catarina L
Vieira, João
Tavares, Fernando
Benson, David R
Tisa, Louis S
Berry, Alison M
Moradas-Ferreira, Pedro
Normand, Philippe
author_sort Santos, Catarina L
collection PubMed
description BACKGROUND: An understanding of the evolution of global transcription regulators is essential for comprehending the complex networks of cellular metabolism that have developed among related organisms. The fur gene encodes one of those regulators – the ferric uptake regulator Fur – widely distributed among bacteria and known to regulate different genes committed to varied metabolic pathways. On the other hand, members of the Actinobacteria comprise an ecologically diverse group of bacteria able to inhabit various natural environments, and for which relatively little is currently understood concerning transcriptional regulation. RESULTS: BLAST analyses revealed the presence of more than one fur homologue in most members of the Actinobacteria whose genomes have been fully sequenced. We propose a model to explain the evolutionary history of fur within this well-known bacterial phylum: the postulated scenario includes one duplication event from a primitive regulator, which probably had a broad range of co-factors and DNA-binding sites. This duplication predated the appearance of the last common ancestor of the Actinobacteria, while six other duplications occurred later within specific groups of organisms, particularly in two genera: Frankia and Streptomyces. The resulting paralogues maintained main biochemical properties, but became specialised for regulating specific functions, coordinating different metal ions and binding to unique DNA sequences. The presence of syntenic regions surrounding the different fur orthologues supports the proposed model, as do the evolutionary distances and topology of phylogenetic trees built using both Neighbor-Joining and Maximum-Likelihood methods. CONCLUSION: The proposed fur evolutionary model, which includes one general duplication and two in-genus duplications followed by divergence and specialization, explains the presence and diversity of fur genes within the Actinobacteria. Although a few rare horizontal gene transfer events have been reported, the model is consistent with the view of gene duplication as a main force of microbial genomes evolution. The parallel study of Fur phylogeny across diverse organisms offers a solid base to guide functional studies and allows the comparison between response mechanisms in relation with the surrounding environment. The survey of regulators among related genomes provides a relevant tool for understanding the evolution of one of the first lines of cellular adaptability, control of DNA transcription.
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spelling pubmed-24646072008-07-15 On the nature of fur evolution: A phylogenetic approach in Actinobacteria Santos, Catarina L Vieira, João Tavares, Fernando Benson, David R Tisa, Louis S Berry, Alison M Moradas-Ferreira, Pedro Normand, Philippe BMC Evol Biol Research Article BACKGROUND: An understanding of the evolution of global transcription regulators is essential for comprehending the complex networks of cellular metabolism that have developed among related organisms. The fur gene encodes one of those regulators – the ferric uptake regulator Fur – widely distributed among bacteria and known to regulate different genes committed to varied metabolic pathways. On the other hand, members of the Actinobacteria comprise an ecologically diverse group of bacteria able to inhabit various natural environments, and for which relatively little is currently understood concerning transcriptional regulation. RESULTS: BLAST analyses revealed the presence of more than one fur homologue in most members of the Actinobacteria whose genomes have been fully sequenced. We propose a model to explain the evolutionary history of fur within this well-known bacterial phylum: the postulated scenario includes one duplication event from a primitive regulator, which probably had a broad range of co-factors and DNA-binding sites. This duplication predated the appearance of the last common ancestor of the Actinobacteria, while six other duplications occurred later within specific groups of organisms, particularly in two genera: Frankia and Streptomyces. The resulting paralogues maintained main biochemical properties, but became specialised for regulating specific functions, coordinating different metal ions and binding to unique DNA sequences. The presence of syntenic regions surrounding the different fur orthologues supports the proposed model, as do the evolutionary distances and topology of phylogenetic trees built using both Neighbor-Joining and Maximum-Likelihood methods. CONCLUSION: The proposed fur evolutionary model, which includes one general duplication and two in-genus duplications followed by divergence and specialization, explains the presence and diversity of fur genes within the Actinobacteria. Although a few rare horizontal gene transfer events have been reported, the model is consistent with the view of gene duplication as a main force of microbial genomes evolution. The parallel study of Fur phylogeny across diverse organisms offers a solid base to guide functional studies and allows the comparison between response mechanisms in relation with the surrounding environment. The survey of regulators among related genomes provides a relevant tool for understanding the evolution of one of the first lines of cellular adaptability, control of DNA transcription. BioMed Central 2008-06-25 /pmc/articles/PMC2464607/ /pubmed/18578876 http://dx.doi.org/10.1186/1471-2148-8-185 Text en Copyright ©2008 Santos et al; licensee BioMed Central Ltd. http://creativecommons.org/licenses/by/2.0 This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
spellingShingle Research Article
Santos, Catarina L
Vieira, João
Tavares, Fernando
Benson, David R
Tisa, Louis S
Berry, Alison M
Moradas-Ferreira, Pedro
Normand, Philippe
On the nature of fur evolution: A phylogenetic approach in Actinobacteria
title On the nature of fur evolution: A phylogenetic approach in Actinobacteria
title_full On the nature of fur evolution: A phylogenetic approach in Actinobacteria
title_fullStr On the nature of fur evolution: A phylogenetic approach in Actinobacteria
title_full_unstemmed On the nature of fur evolution: A phylogenetic approach in Actinobacteria
title_short On the nature of fur evolution: A phylogenetic approach in Actinobacteria
title_sort on the nature of fur evolution: a phylogenetic approach in actinobacteria
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2464607/
https://www.ncbi.nlm.nih.gov/pubmed/18578876
http://dx.doi.org/10.1186/1471-2148-8-185
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