Binding properties and evolution of homodimers in protein-protein interaction networks

doi:10.1093/nar/gki678

Nucleic Acids Research 2005 33(11):3629-3635; doi:10.1093/nar/gki678

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Published online 27 June 2005

© The Author 2005. Published by Oxford University Press. All rights reserved
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Article

Binding properties and evolution of homodimers in protein–protein interaction networks

Iaroslav Ispolatov^*, Anton Yuryev, Ilya Mazo and Sergei Maslov¹

Ariadne Genomics Inc. 9700 Great Seneca Highway, Suite 113, Rockville, MD 20850, USA ¹Department of Physics, Brookhaven National Laboratory Upton, NY 11973, USA

^*To whom correspondence should be addressed. Fax: +1 240 453 6208; Email: slava{at}ariadnegenomics.com

Received January 3, 2005. Revised June 9, 2005. Accepted June 9, 2005.

We demonstrate that protein–protein interaction networksin several eukaryotic organisms contain significantly more self-interactingproteins than expected if such homodimers randomly appearedin the course of the evolution. We also show that on averagehomodimers have twice as many interaction partners than non-self-interactingproteins. More specifically, the likelihood of a protein tophysically interact with itself was found to be proportionalto the total number of its binding partners. These propertiesof dimers are in agreement with a phenomenological model, inwhich individual proteins differ from each other by the degreeof their ‘stickiness’ or general propensity towardinteraction with other proteins including oneself. A duplicationof self-interacting proteins creates a pair of paralogous proteinsinteracting with each other. We show that such pairs occur morefrequently than could be explained by pure chance alone. Similarto homodimers, proteins involved in heterodimers with theirparalogs on average have twice as many interacting partnersthan the rest of the network. The likelihood of a pair of paralogousproteins to interact with each other was also shown to decreasewith their sequence similarity. This points to the conclusionthat most of interactions between paralogs are inherited fromancestral homodimeric proteins, rather than established de novoafter duplication. We finally discuss possible implicationsof our empirical observations from functional and evolutionarystandpoints.

Correspondence may also be addressed to Sergei Maslov. Fax:+1 631 344 2918; Email: maslov{at}bnl.gov

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