Patterns of coevolving amino acids unveil structural and dynamical domains
Author(s) -
Daniele Granata,
Luca Ponzoni,
Cristian Micheletti,
Vincenzo Carnevale
Publication year - 2017
Publication title -
proceedings of the national academy of sciences
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 5.011
H-Index - 771
eISSN - 1091-6490
pISSN - 0027-8424
DOI - 10.1073/pnas.1712021114
Subject(s) - pairwise comparison , encode , protein evolution , curse of dimensionality , dimensionality reduction , multiple sequence alignment , phylogenetic tree , biological system , statistical physics , computer science , protein structure , computational biology , evolutionary biology , sequence alignment , physics , biology , artificial intelligence , peptide sequence , genetics , gene , nuclear magnetic resonance
Patterns of interacting amino acids are so preserved within protein families that the sole analysis of evolutionary comutations can identify pairs of contacting residues. It is also known that evolution conserves functional dynamics, i.e., the concerted motion or displacement of large protein regions or domains. Is it, therefore, possible to use a pure sequence-based analysis to identify these dynamical domains? To address this question, we introduce here a general coevolutionary coupling analysis strategy and apply it to a curated sequence database of hundreds of protein families. For most families, the sequence-based method partitions amino acids into a few clusters. When viewed in the context of the native structure, these clusters have the signature characteristics of viable protein domains: They are spatially separated but individually compact. They have a direct functional bearing too, as shown for various reference cases. We conclude that even large-scale structural and functionally related properties can be recovered from inference methods applied to evolutionary-related sequences. The method introduced here is available as a software package and web server (spectrus.sissa.it/spectrus-evo_webserver).
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