Difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotes

<p>Abstract</p> <p>Background</p> <p>A protein-protein interaction network (PIN) was suggested to be a disassortative network, in which interactions between high- and low-degree nodes are favored while hub-hub interactions are suppressed. It was postulated that a disass...

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Main Authors: Tanaka Hiroshi, Niimura Yoshihito, Hase Takeshi
Format: Article
Language:English
Published: BMC 2010-11-01
Series:BMC Evolutionary Biology
Online Access:http://www.biomedcentral.com/1471-2148/10/358
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spelling doaj-a38b0afa676d4964a7edd84a622986b32021-09-02T09:47:48ZengBMCBMC Evolutionary Biology1471-21482010-11-0110135810.1186/1471-2148-10-358Difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotesTanaka HiroshiNiimura YoshihitoHase Takeshi<p>Abstract</p> <p>Background</p> <p>A protein-protein interaction network (PIN) was suggested to be a disassortative network, in which interactions between high- and low-degree nodes are favored while hub-hub interactions are suppressed. It was postulated that a disassortative structure minimizes unfavorable cross-talks between different hub-centric functional modules and was positively selected in evolution. However, by re-examining yeast PIN data, several researchers reported that the disassortative structure observed in a PIN might be an experimental artifact. Therefore, the existence of a disassortative structure and its possible evolutionary mechanism remains unclear.</p> <p>Results</p> <p>In this study, we investigated PINs from the yeast, worm, fly, human, and malaria parasite including four different yeast PIN datasets. The analyses showed that the yeast, worm, fly, and human PINs are disassortative while the malaria parasite PIN is not. By conducting simulation studies on the basis of a duplication-divergence model, we demonstrated that a preferential duplication of low- and high-degree nodes can generate disassortative and non-disassortative networks, respectively. From this observation, we hypothesized that the difference in degree dependence on gene duplications accounts for the difference in assortativity of PINs among species. Comparison of 55 proteomes in eukaryotes revealed that genes with lower degrees showed higher gene duplicabilities in the yeast, worm, and fly, while high-degree genes tend to have high duplicabilities in the malaria parasite, supporting the above hypothesis.</p> <p>Conclusions</p> <p>These results suggest that disassortative structures observed in PINs are merely a byproduct of preferential duplications of low-degree genes, which might be caused by an organism's living environment.</p> http://www.biomedcentral.com/1471-2148/10/358
collection DOAJ
language English
format Article
sources DOAJ
author Tanaka Hiroshi
Niimura Yoshihito
Hase Takeshi
spellingShingle Tanaka Hiroshi
Niimura Yoshihito
Hase Takeshi
Difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotes
BMC Evolutionary Biology
author_facet Tanaka Hiroshi
Niimura Yoshihito
Hase Takeshi
author_sort Tanaka Hiroshi
title Difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotes
title_short Difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotes
title_full Difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotes
title_fullStr Difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotes
title_full_unstemmed Difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotes
title_sort difference in gene duplicability may explain the difference in overall structure of protein-protein interaction networks among eukaryotes
publisher BMC
series BMC Evolutionary Biology
issn 1471-2148
publishDate 2010-11-01
description <p>Abstract</p> <p>Background</p> <p>A protein-protein interaction network (PIN) was suggested to be a disassortative network, in which interactions between high- and low-degree nodes are favored while hub-hub interactions are suppressed. It was postulated that a disassortative structure minimizes unfavorable cross-talks between different hub-centric functional modules and was positively selected in evolution. However, by re-examining yeast PIN data, several researchers reported that the disassortative structure observed in a PIN might be an experimental artifact. Therefore, the existence of a disassortative structure and its possible evolutionary mechanism remains unclear.</p> <p>Results</p> <p>In this study, we investigated PINs from the yeast, worm, fly, human, and malaria parasite including four different yeast PIN datasets. The analyses showed that the yeast, worm, fly, and human PINs are disassortative while the malaria parasite PIN is not. By conducting simulation studies on the basis of a duplication-divergence model, we demonstrated that a preferential duplication of low- and high-degree nodes can generate disassortative and non-disassortative networks, respectively. From this observation, we hypothesized that the difference in degree dependence on gene duplications accounts for the difference in assortativity of PINs among species. Comparison of 55 proteomes in eukaryotes revealed that genes with lower degrees showed higher gene duplicabilities in the yeast, worm, and fly, while high-degree genes tend to have high duplicabilities in the malaria parasite, supporting the above hypothesis.</p> <p>Conclusions</p> <p>These results suggest that disassortative structures observed in PINs are merely a byproduct of preferential duplications of low-degree genes, which might be caused by an organism's living environment.</p>
url http://www.biomedcentral.com/1471-2148/10/358
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AT niimurayoshihito differenceingeneduplicabilitymayexplainthedifferenceinoverallstructureofproteinproteininteractionnetworksamongeukaryotes
AT hasetakeshi differenceingeneduplicabilitymayexplainthedifferenceinoverallstructureofproteinproteininteractionnetworksamongeukaryotes
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