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Title: Hierarchical Organization Endows the Kinase Domain with Regulatory Plasticity.

Authors: Creixell, Pau; Pandey, Jai P; Palmeri, Antonio; Bhattacharyya, Moitrayee; Creixell, Marc; Ranganathan, Rama; Pincus, David; Yaffe, Michael B

Published In Cell Syst, (2018 10 24)

Abstract: The functional diversity of kinases enables specificity in cellular signal transduction. Yet how more than 500 members of the human kinome specifically receive regulatory inputs and convey information to appropriate substrates-all while using the common signaling output of phosphorylation-remains enigmatic. Here, we perform statistical co-evolution analysis, mutational scanning, and quantitative live-cell assays to reveal a hierarchical organization of the kinase domain that facilitates the orthogonal evolution of regulatory inputs and substrate outputs while maintaining catalytic function. We find that three quasi-independent "sectors"-groups of evolutionarily coupled residues-represent functional units in the kinase domain that encode for catalytic activity, substrate specificity, and regulation. Sector positions impact both disease and pharmacology: the catalytic sector is significantly enriched for somatic cancer mutations, and residues in the regulatory sector interact with allosteric kinase inhibitors. We propose that this functional architecture endows the kinase domain with inherent regulatory plasticity.

PubMed ID: 30243563 Exiting the NIEHS site

MeSH Terms: Allosteric Regulation; Allosteric Site; Catalytic Domain*; Evolution, Molecular*; Humans; Mutation; Neoplasms/genetics; Protein Kinases/chemistry*; Protein Kinases/genetics; Protein Kinases/metabolism; Substrate Specificity

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