5hey Citations

Origins of Allostery and Evolvability in Proteins: A Case Study.

Raman AS, White KI, Ranganathan R
Cell 166 468-480 (2016)
Related entries: 5heb, 5hed, 5het, 5hf1, 5hfb, 5hfc, 5hff

Cited: 59 times
EuropePMC logo PMID: 27321669

Abstract

Proteins display the capacity for adaptation to new functions, a property critical for evolvability. But what structural principles underlie the capacity for adaptation? Here, we show that adaptation to a physiologically distinct class of ligand specificity in a PSD95, DLG1, ZO-1 (PDZ) domain preferentially occurs through class-bridging intermediate mutations located distant from the ligand-binding site. These mutations provide a functional link between ligand classes and demonstrate the principle of "conditional neutrality" in mediating evolutionary adaptation. Structures show that class-bridging mutations work allosterically to open up conformational plasticity at the active site, permitting novel functions while retaining existing function. More generally, the class-bridging phenotype arises from mutations in an evolutionarily conserved network of coevolving amino acids in the PDZ family (the sector) that connects the active site to distant surface sites. These findings introduce the concept that allostery in proteins could have its origins not in protein function but in the capacity to adapt.

Articles - 5hey mentioned but not cited (2)

  1. "Infostery" analysis of short molecular dynamics simulations identifies highly sensitive residues and predicts deleterious mutations. Karami Y, Bitard-Feildel T, Laine E, Carbone A. Sci Rep 8 16126 (2018)
  2. Autoregulation of the LIM kinases by their PDZ domain. Casanova-Sepúlveda G, Sexton JA, Turk BE, Boggon TJ. Nat Commun 14 8441 (2023)


Reviews citing this publication (10)

  1. The causes of evolvability and their evolution. Payne JL, Wagner A. Nat Rev Genet 20 24-38 (2019)
  2. Emerging Themes in PDZ Domain Signaling: Structure, Function, and Inhibition. Liu X, Fuentes EJ. Int Rev Cell Mol Biol 343 129-218 (2019)
  3. Specificity in PDZ-peptide interaction networks: Computational analysis and review. Amacher JF, Brooks L, Hampton TH, Madden DR. J Struct Biol X 4 100022 (2020)
  4. Recent advances suggest increased influence of selective pressure in allostery. Bhat AS, Dustin Schaeffer R, Kinch L, Medvedev KE, Grishin NV. Curr Opin Struct Biol 62 183-188 (2020)
  5. Roadmap on biology in time varying environments. Murugan A, Husain K, Rust MJ, Hepler C, Bass J, Pietsch JMJ, Swain PS, Jena SG, Toettcher JE, Chakraborty AK, Sprenger KG, Mora T, Walczak AM, Rivoire O, Wang S, Wood KB, Skanata A, Kussell E, Ranganathan R, Shih HY, Goldenfeld N. Phys Biol 18 (2021)
  6. Correlated positions in protein evolution and engineering. Franceus J, Verhaeghe T, Desmet T. J Ind Microbiol Biotechnol 44 687-695 (2017)
  7. Improvements in the Resistance of the Banana Species to Fusarium Wilt: A Systematic Review of Methods and Perspectives. Rocha AJ, Soares JMDS, Nascimento FDS, Santos AS, Amorim VBO, Ferreira CF, Haddad F, Santos-Serejo JAD, Amorim EP. J Fungi (Basel) 7 249 (2021)
  8. The Conformational Plasticity Vista of PDZ Domains. Murciano-Calles J. Life (Basel) 10 E123 (2020)
  9. Functional assays for transcription mechanisms in high-throughput. Qiu C, Kaplan CD. Methods 159-160 115-123 (2019)
  10. Step-by-step design of proteins for small molecule interaction: A review on recent milestones. Pereira JM, Vieira M, Santos SM. Protein Sci 30 1502-1520 (2021)

Articles citing this publication (47)



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