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A hierarchy of coupling free energies underlie the thermodynamic and functional architecture of protein structures

Athi N. Naganathan, Adithi Kannan

2021Current Research in Structural Biology25 citationsDOIOpen Access PDF

Abstract

Protein sequences and structures evolve by satisfying varied physical and biochemical constraints. This multi-level selection is enabled not just by the patterning of amino acids on the sequence, but also via coupling between residues in the native structure. Here, we employ an energetically detailed statistical mechanical model with millions of microstates to extract such long-range structural correlations, i.e. thermodynamic coupling free energies, from a diverse family of protein structures. We find that despite the intricate and anisotropic distribution of coupling patterns, the majority of residues (>70%) are only marginally coupled contributing to functional motions and catalysis. Physical origins of ‘sectors’, determinants of native ensemble heterogeneity in extant, ancient and designed proteins, and the basis for allostery emerge naturally from coupling free energies. The statistical framework highlights how evolutionary selection and optimization occur at the level of global interaction network for a given protein fold impacting folding, function, and allosteric outputs.

Topics & Concepts

Allosteric regulationHierarchyCoupling (piping)Protein foldingStatistical physicsExtant taxonBasis (linear algebra)Protein evolutionProtein designProtein structureSelection (genetic algorithm)Computational biologyBiological systemComputer scienceEvolutionary biologyChemistryPhysicsBiologyArtificial intelligenceMathematicsMaterials scienceBiochemistryEnzymeGeneEconomicsMetallurgyGeometryMarket economyProtein Structure and DynamicsEnzyme Structure and FunctionOrigins and Evolution of Life