Patterns of Dynamics Comprise a Conserved Evolutionary Trait

The importance of protein dynamics in function may suggest an evolutionary selection on large-scale protein motions. Here we systematically studied the dynamic characteristics in 2221 protein domains (58477 sequences) of the Pfam database. We defined the patterns of dynamics (PODs) based on the estimated NMR order parameters and the predicted degree of disorder, and found a significant correlation between them in families of both structured and disordered protein domains. We demonstrate that conservation of dynamic patterns frequently exceeds conservation of sequence and is comparable to the patterns of hydropathy and nonspecific interaction potential. Similarity of dynamic patterns is weakly correlated to structure similarity and to the degree of disorder. We illustrate that POD alignments could be applied to sequentially divergent or intrinsically disordered regions. We propose that patterns of dynamics comprise a conserved evolutionary trait, which could be used to infer evolutionary relationships as an alternative to sequence and structure. Patterns of Dynamics (PODs) can be used to infer evolutionary relationships as an alternative to sequence or structure. [Display omitted] •Coarse-grained dynamic characteristics comprise a conserved trait in Pfam domains.•Divergent sequences show conserved flexibility and disorder patterns.•Similarities of structure and dynamic patterns are weakly correlated.•Patterns of dynamics can indicate evolutionary relationship in disordered proteins.