The structure of a gene co-expression network reveals biological functions underlying eQTLs.

The structure of a gene co-expression network reveals biological functions underlying eQTLs.

What are the commonalities between genes, whose expression level is partially controlled by eQTL, especially with regard to biological functions? Moreover, how are these genes related to a phenotype of interest? These issues are particularly difficult to address when the genome annotation is incompl...

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Main Authors: Nathalie Villa-Vialaneix, Laurence Liaubet, Thibault Laurent, Pierre Cherel, Adrien Gamot, Magali SanCristobal
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2013-01-01
Series:PLoS ONE
Online Access:https://www.ncbi.nlm.nih.gov/pmc/articles/pmid/23577081/?tool=EBI
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spelling doaj-ee6743e3d6ee4c59bee0e8e3409c590c2021-03-03T20:24:00ZengPublic Library of Science (PLoS)PLoS ONE1932-62032013-01-0184e6004510.1371/journal.pone.0060045The structure of a gene co-expression network reveals biological functions underlying eQTLs.Nathalie Villa-VialaneixLaurence LiaubetThibault LaurentPierre CherelAdrien GamotMagali SanCristobalWhat are the commonalities between genes, whose expression level is partially controlled by eQTL, especially with regard to biological functions? Moreover, how are these genes related to a phenotype of interest? These issues are particularly difficult to address when the genome annotation is incomplete, as is the case for mammalian species. Moreover, the direct link between gene expression and a phenotype of interest may be weak, and thus difficult to handle. In this framework, the use of a co-expression network has proven useful: it is a robust approach for modeling a complex system of genetic regulations, and to infer knowledge for yet unknown genes. In this article, a case study was conducted with a mammalian species. It showed that the use of a co-expression network based on partial correlation, combined with a relevant clustering of nodes, leads to an enrichment of biological functions of around 83%. Moreover, the use of a spatial statistics approach allowed us to superimpose additional information related to a phenotype; this lead to highlighting specific genes or gene clusters that are related to the network structure and the phenotype. Three main results are worth noting: first, key genes were highlighted as a potential focus for forthcoming biological experiments; second, a set of biological functions, which support a list of genes under partial eQTL control, was set up by an overview of the global structure of the gene expression network; third, pH was found correlated with gene clusters, and then with related biological functions, as a result of a spatial analysis of the network topology.https://www.ncbi.nlm.nih.gov/pmc/articles/pmid/23577081/?tool=EBI
collection DOAJ
language English
format Article
sources DOAJ
author Nathalie Villa-Vialaneix
Laurence Liaubet
Thibault Laurent
Pierre Cherel
Adrien Gamot
Magali SanCristobal
spellingShingle Nathalie Villa-Vialaneix
Laurence Liaubet
Thibault Laurent
Pierre Cherel
Adrien Gamot
Magali SanCristobal
The structure of a gene co-expression network reveals biological functions underlying eQTLs.
PLoS ONE
author_facet Nathalie Villa-Vialaneix
Laurence Liaubet
Thibault Laurent
Pierre Cherel
Adrien Gamot
Magali SanCristobal
author_sort Nathalie Villa-Vialaneix
title The structure of a gene co-expression network reveals biological functions underlying eQTLs.
title_short The structure of a gene co-expression network reveals biological functions underlying eQTLs.
title_full The structure of a gene co-expression network reveals biological functions underlying eQTLs.
title_fullStr The structure of a gene co-expression network reveals biological functions underlying eQTLs.
title_full_unstemmed The structure of a gene co-expression network reveals biological functions underlying eQTLs.
title_sort structure of a gene co-expression network reveals biological functions underlying eqtls.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2013-01-01
description What are the commonalities between genes, whose expression level is partially controlled by eQTL, especially with regard to biological functions? Moreover, how are these genes related to a phenotype of interest? These issues are particularly difficult to address when the genome annotation is incomplete, as is the case for mammalian species. Moreover, the direct link between gene expression and a phenotype of interest may be weak, and thus difficult to handle. In this framework, the use of a co-expression network has proven useful: it is a robust approach for modeling a complex system of genetic regulations, and to infer knowledge for yet unknown genes. In this article, a case study was conducted with a mammalian species. It showed that the use of a co-expression network based on partial correlation, combined with a relevant clustering of nodes, leads to an enrichment of biological functions of around 83%. Moreover, the use of a spatial statistics approach allowed us to superimpose additional information related to a phenotype; this lead to highlighting specific genes or gene clusters that are related to the network structure and the phenotype. Three main results are worth noting: first, key genes were highlighted as a potential focus for forthcoming biological experiments; second, a set of biological functions, which support a list of genes under partial eQTL control, was set up by an overview of the global structure of the gene expression network; third, pH was found correlated with gene clusters, and then with related biological functions, as a result of a spatial analysis of the network topology.
url https://www.ncbi.nlm.nih.gov/pmc/articles/pmid/23577081/?tool=EBI
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