Structural Models for a Series of Allosteric Inhibitors of IGF1R Kinase.

Academic Article

Abstract

  • The allosteric inhibition of insulin-like growth factor receptor 1 kinase (IGF1RK) is a potential strategy to overcome selectivity barriers for targeting receptor tyrosine kinases. We constructed structural models of a series of 12 indole-butyl-amine derivatives that have been reported as allosteric inhibitors of IGF1RK. We further studied the dynamics and interactions of each inhibitor in the allosteric pocket via all-atom explicit-solvent molecular dynamics (MD) simulations. We discovered that a bulky carbonyl substitution at the R1 indole ring is structurally unfavorable for inhibitor binding in the IGF1RK allosteric pocket. Moreover, we found that the most potent derivative (termed C11) acquires a distinct conformation: forming an allosteric pocket channel with better shape complementarity and interactions with the receptor. In addition to a hydrogen-bonding interaction with V1063, the cyano derivative C11 forms a stable hydrogen bond with M1156, which is responsible for its unique binding conformation in the allosteric pocket. Our findings show that the positioning of chemical substituents with different pharmacophore features at the R1 indole ring influences molecular interactions and binding conformations of indole-butyl-amine derivatives and, hence, dramatically affects their potencies. Our results provide a structural framework for the design of allosteric inhibitors with improved affinities and specificities against IGF1RK.
  • Authors

  • Verma, Jyoti
  • Vashisth, Harish
  • Publication Date

  • May 14, 2024
  • Keywords

  • Allosteric Regulation
  • Allosteric Site
  • Humans
  • Hydrogen Bonding
  • Indoles
  • Models, Molecular
  • Molecular Dynamics Simulation
  • Protein Binding
  • Protein Kinase Inhibitors
  • Receptor, IGF Type 1
  • Structure-Activity Relationship
  • allosteric inhibitors
  • insulin-like growth factor receptor 1 kinase
  • molecular docking
  • molecular dynamics
  • pharmacophore modeling
  • Digital Object Identifier (doi)

    Start Page

  • 5368
  • Volume

  • 25
  • Issue

  • 10