Gene connectivity and enzyme evolution in the human metabolic network

Abstract Background Determining the factors involved in the likelihood of a gene being under adaptive selection is still a challenging goal in Evolutionary Biology. Here, we perform an evolutionary analysis of the human metabolic genes to explore the associations between network structure and the pr...

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Main Authors: Begoña Dobon, Ludovica Montanucci, Juli Peretó, Jaume Bertranpetit, Hafid Laayouni
Format: Article
Language:English
Published: BMC 2019-09-01
Series:Biology Direct
Subjects:
Online Access:http://link.springer.com/article/10.1186/s13062-019-0248-7
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spelling doaj-0b6dcfd5c8e742efb1c7d84085e634992020-11-25T01:56:48ZengBMCBiology Direct1745-61502019-09-0114111410.1186/s13062-019-0248-7Gene connectivity and enzyme evolution in the human metabolic networkBegoña Dobon0Ludovica Montanucci1Juli Peretó2Jaume Bertranpetit3Hafid Laayouni4Institut de Biologia Evolutiva (UPF-CSIC), Universitat Pompeu FabraDipartimento di Biomedicina Comparata e Alimentazione, Università degli Studi di PadovaInstitute for Integrative Systems Biology I2SysBio (University of Valencia-CSIC) and Department of Biochemistry and Molecular Biology, University of ValenciaInstitut de Biologia Evolutiva (UPF-CSIC), Universitat Pompeu FabraInstitut de Biologia Evolutiva (UPF-CSIC), Universitat Pompeu FabraAbstract Background Determining the factors involved in the likelihood of a gene being under adaptive selection is still a challenging goal in Evolutionary Biology. Here, we perform an evolutionary analysis of the human metabolic genes to explore the associations between network structure and the presence and strength of natural selection in the genes whose products are involved in metabolism. Purifying and positive selection are estimated at interspecific (among mammals) and intraspecific (among human populations) levels, and the connections between enzymatic reactions are differentiated between incoming (in-degree) and outgoing (out-degree) links. Results We confirm that purifying selection has been stronger in highly connected genes. Long-term positive selection has targeted poorly connected enzymes, whereas short-term positive selection has targeted different enzymes depending on whether the selective sweep has reached fixation in the population: genes under a complete selective sweep are poorly connected, whereas those under an incomplete selective sweep have high out-degree connectivity. The last steps of pathways are more conserved due to stronger purifying selection, with long-term positive selection targeting preferentially enzymes that catalyze the first steps. However, short-term positive selection has targeted enzymes that catalyze the last steps in the metabolic network. Strong signals of positive selection have been found for metabolic processes involved in lipid transport and membrane fluidity and permeability. Conclusions Our analysis highlights the importance of analyzing the same biological system at different evolutionary timescales to understand the evolution of metabolic genes and of distinguishing between incoming and outgoing links in a metabolic network. Short-term positive selection has targeted enzymes with a different connectivity profile depending on the completeness of the selective sweep, while long-term positive selection has targeted genes with fewer connections that code for enzymes that catalyze the first steps in the network. Reviewers This article was reviewed by Diamantis Sellis and Brandon Invergo.http://link.springer.com/article/10.1186/s13062-019-0248-7Network topologyDegreeConnectivityMetabolismEnzymesPositive selection
collection DOAJ
language English
format Article
sources DOAJ
author Begoña Dobon
Ludovica Montanucci
Juli Peretó
Jaume Bertranpetit
Hafid Laayouni
spellingShingle Begoña Dobon
Ludovica Montanucci
Juli Peretó
Jaume Bertranpetit
Hafid Laayouni
Gene connectivity and enzyme evolution in the human metabolic network
Biology Direct
Network topology
Degree
Connectivity
Metabolism
Enzymes
Positive selection
author_facet Begoña Dobon
Ludovica Montanucci
Juli Peretó
Jaume Bertranpetit
Hafid Laayouni
author_sort Begoña Dobon
title Gene connectivity and enzyme evolution in the human metabolic network
title_short Gene connectivity and enzyme evolution in the human metabolic network
title_full Gene connectivity and enzyme evolution in the human metabolic network
title_fullStr Gene connectivity and enzyme evolution in the human metabolic network
title_full_unstemmed Gene connectivity and enzyme evolution in the human metabolic network
title_sort gene connectivity and enzyme evolution in the human metabolic network
publisher BMC
series Biology Direct
issn 1745-6150
publishDate 2019-09-01
description Abstract Background Determining the factors involved in the likelihood of a gene being under adaptive selection is still a challenging goal in Evolutionary Biology. Here, we perform an evolutionary analysis of the human metabolic genes to explore the associations between network structure and the presence and strength of natural selection in the genes whose products are involved in metabolism. Purifying and positive selection are estimated at interspecific (among mammals) and intraspecific (among human populations) levels, and the connections between enzymatic reactions are differentiated between incoming (in-degree) and outgoing (out-degree) links. Results We confirm that purifying selection has been stronger in highly connected genes. Long-term positive selection has targeted poorly connected enzymes, whereas short-term positive selection has targeted different enzymes depending on whether the selective sweep has reached fixation in the population: genes under a complete selective sweep are poorly connected, whereas those under an incomplete selective sweep have high out-degree connectivity. The last steps of pathways are more conserved due to stronger purifying selection, with long-term positive selection targeting preferentially enzymes that catalyze the first steps. However, short-term positive selection has targeted enzymes that catalyze the last steps in the metabolic network. Strong signals of positive selection have been found for metabolic processes involved in lipid transport and membrane fluidity and permeability. Conclusions Our analysis highlights the importance of analyzing the same biological system at different evolutionary timescales to understand the evolution of metabolic genes and of distinguishing between incoming and outgoing links in a metabolic network. Short-term positive selection has targeted enzymes with a different connectivity profile depending on the completeness of the selective sweep, while long-term positive selection has targeted genes with fewer connections that code for enzymes that catalyze the first steps in the network. Reviewers This article was reviewed by Diamantis Sellis and Brandon Invergo.
topic Network topology
Degree
Connectivity
Metabolism
Enzymes
Positive selection
url http://link.springer.com/article/10.1186/s13062-019-0248-7
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