A protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.

A protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.

Protein Domain Co-occurrence Network (DCN) is a biological network that has not been fully-studied. We analyzed the properties of the DCNs of H. sapiens, S. cerevisiae, C. elegans, D. melanogaster, and 15 plant genomes. These DCNs have the hallmark features of scale-free networks. We investigated th...

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Main Authors: Zheng Wang, Xue-Cheng Zhang, Mi Ha Le, Dong Xu, Gary Stacey, Jianlin Cheng
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2011-03-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC3063783?pdf=render
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spelling doaj-9cc7dafdac8f4edc905d174bcd60bf702020-11-24T22:17:06ZengPublic Library of Science (PLoS)PLoS ONE1932-62032011-03-0163e1790610.1371/journal.pone.0017906A protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.Zheng WangXue-Cheng ZhangMi Ha LeDong XuGary StaceyJianlin ChengProtein Domain Co-occurrence Network (DCN) is a biological network that has not been fully-studied. We analyzed the properties of the DCNs of H. sapiens, S. cerevisiae, C. elegans, D. melanogaster, and 15 plant genomes. These DCNs have the hallmark features of scale-free networks. We investigated the possibility of using DCNs to predict protein and domain functions. Based on our experiment conducted on 66 randomly selected proteins, the best of top 3 predictions made by our DCN-based aggregated neighbor-counting method achieved a semantic similarity score of 0.81 to the actual Gene Ontology terms of the proteins. Moreover, the top 3 predictions using neighbor-counting, χ(2), and a SVM-based method achieved an accuracy of 66%, 59%, and 61%, respectively, when used to predict specific Gene Ontology terms of human target domains. These predictions on average had a semantic similarity score of 0.82, 0.80, and 0.79 to the actual Gene Ontology terms, respectively. We also used DCNs to predict whether a domain is an enzyme domain, and our SVM-based and neighbor-inference method correctly classified 79% and 77% of the target domains, respectively. When using DCNs to classify a target domain into one of the six enzyme classes, we found that, as long as there is one EC number available in the neighboring domains, our SVM-based and neighboring-counting method correctly classified 92.4% and 91.9% of the target domains, respectively. Furthermore, we benchmarked the performance of using DCNs to infer species phylogenies on six different combinations of 398 single-chromosome prokaryotic genomes. The phylogenetic tree of 54 prokaryotic taxa generated by our DCNs-alignment-based method achieved a 93.45% similarity score compared to the Bergey's taxonomy. In summary, our studies show that genome-wide DCNs contain rich information that can be effectively used to decipher protein function and reveal the evolutionary relationship among species.http://europepmc.org/articles/PMC3063783?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Zheng Wang
Xue-Cheng Zhang
Mi Ha Le
Dong Xu
Gary Stacey
Jianlin Cheng
spellingShingle Zheng Wang
Xue-Cheng Zhang
Mi Ha Le
Dong Xu
Gary Stacey
Jianlin Cheng
A protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.
PLoS ONE
author_facet Zheng Wang
Xue-Cheng Zhang
Mi Ha Le
Dong Xu
Gary Stacey
Jianlin Cheng
author_sort Zheng Wang
title A protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.
title_short A protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.
title_full A protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.
title_fullStr A protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.
title_full_unstemmed A protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.
title_sort protein domain co-occurrence network approach for predicting protein function and inferring species phylogeny.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2011-03-01
description Protein Domain Co-occurrence Network (DCN) is a biological network that has not been fully-studied. We analyzed the properties of the DCNs of H. sapiens, S. cerevisiae, C. elegans, D. melanogaster, and 15 plant genomes. These DCNs have the hallmark features of scale-free networks. We investigated the possibility of using DCNs to predict protein and domain functions. Based on our experiment conducted on 66 randomly selected proteins, the best of top 3 predictions made by our DCN-based aggregated neighbor-counting method achieved a semantic similarity score of 0.81 to the actual Gene Ontology terms of the proteins. Moreover, the top 3 predictions using neighbor-counting, χ(2), and a SVM-based method achieved an accuracy of 66%, 59%, and 61%, respectively, when used to predict specific Gene Ontology terms of human target domains. These predictions on average had a semantic similarity score of 0.82, 0.80, and 0.79 to the actual Gene Ontology terms, respectively. We also used DCNs to predict whether a domain is an enzyme domain, and our SVM-based and neighbor-inference method correctly classified 79% and 77% of the target domains, respectively. When using DCNs to classify a target domain into one of the six enzyme classes, we found that, as long as there is one EC number available in the neighboring domains, our SVM-based and neighboring-counting method correctly classified 92.4% and 91.9% of the target domains, respectively. Furthermore, we benchmarked the performance of using DCNs to infer species phylogenies on six different combinations of 398 single-chromosome prokaryotic genomes. The phylogenetic tree of 54 prokaryotic taxa generated by our DCNs-alignment-based method achieved a 93.45% similarity score compared to the Bergey's taxonomy. In summary, our studies show that genome-wide DCNs contain rich information that can be effectively used to decipher protein function and reveal the evolutionary relationship among species.
url http://europepmc.org/articles/PMC3063783?pdf=render
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