Simultaneous identification of specifically interacting paralogs and inter-protein contacts by Direct-Coupling Analysis

TL;DR

This paper extends direct-coupling analysis to simultaneously identify interacting paralogs, predict inter-protein contacts, and distinguish interacting protein families, thereby broadening the application of coevolutionary methods in complex biological systems.

Contribution

It introduces a novel approach that integrates multiple scales of protein interaction analysis, including paralog matching and contact prediction, using coevolutionary modeling.

Findings

Successfully matched interacting paralogs within species.

Accurately predicted inter-protein residue contacts.

Discriminated between interacting and noninteracting protein families.

Abstract

Understanding protein-protein interactions is central to our understanding of almost all complex biological processes. Computational tools exploiting rapidly growing genomic databases to characterize protein-protein interactions are urgently needed. Such methods should connect multiple scales from evolutionary conserved interactions between families of homologous proteins, over the identification of specifically interacting proteins in the case of multiple paralogs inside a species, down to the prediction of residues being in physical contact across interaction interfaces. Statistical inference methods detecting residue-residue coevolution have recently triggered considerable progress in using sequence data for quaternary protein structure prediction; they require, however, large joint alignments of homologous protein pairs known to interact. The generation of such alignments is a complex computational task on its own; application of coevolutionary modeling has in turn been restricted to proteins without paralogs, or to bacterial systems with the corresponding coding genes being co-localized in operons. Here we show that the Direct-Coupling Analysis of residue coevolution can be extended to connect the different scales, and simultaneously to match interacting paralogs, to identify inter-protein residue-residue contacts and to discriminate interacting from noninteracting families in a multiprotein system. Our results extend the potential applications of coevolutionary analysis far beyond cases treatable so far.