Abstract
BackgroundStable evolutionary signal has been observed in a yeast protein-protein interaction (PPI) network. These finding suggests more connected regions of a PPI network to be potential mediators of evolutionary information. Because more connected regions of PPI networks contain functional complexes, we are motivated to exploit the orthology relation for identifying complexes that can be clearly attributed to such evolutionary signal.ResultsWe proposed a computational methodology for detecting the orthology signal present in a PPI network at a functional complex level. Specifically, we examined highly functionally coherent putative protein complexes as detected by a clustering technique in the complete yeast PPI network, in the yeast sub-network which spans only ortholog proteins as determined by a given second organism, and in yeast sub-networks induced by a set of proteins randomly selected. We proposed a filtering technique for extracting orthology-driven clusters with unique functionalities, that is, neither enriched by clusters identified using the complete yeast PPI network nor identified using random sampling. Moreover, we extracted functional categories that can be clearly attributed to the presence of evolutionary signal as described by these clusters.ConclusionsApplication of the proposed methodology to the yeast PPI network indicated that evolutionary information at a functional complex level can be retrieved from the structure of the network. In particular, we detected protein complexes whose functionality could be uniquely attributed to the evolutionary signal. Moreover, we identified functions that are over-represented in these complexes due the evolutionary signal.
Highlights
Stable evolutionary signal has been observed in a yeast protein-protein interaction (PPI) network
Motivated by the above observations, in this paper we focus on the explicit use of orthology for detecting evolutionary signal at a functional complex level, that is, functional complexes that can be clearly attributed to this evolutionary signal
Escherichia coli (E.coli), Caenorhabditis elegans, Drosophila melanogaster and Homo sapiens are standard organisms used in protein network and genome comparative studies (e.g [18,19]) and represent the diverse life-forms from a prokaryote (E.coli) to the highly complex eukaryote
Summary
Stable evolutionary signal has been observed in a yeast protein-protein interaction (PPI) network. Orthologous proteins have high amino acid sequence similarity and usually retain the same or very similar function, which allows one to infer biological information between the proteins Orthology as such is very important in studying. The authors observed that a high local clustering around protein-protein interactions correlates with evolutionary conservation of the participating proteins This means that highly connected proteins and protein pairs embedded in a well clustered neighbourhood tend to be evolutionary conserved and retain their evolutionary signal. These findings suggest that more connected regions of a PPI network are potential mediators of evolutionary information
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