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The Importance of Detail: How Differences in Ligand Structures Determine Distinct Functional Responses in Integrin αv β3.

Antonella PaladinoMonica CiveraFlavio CurnisMayra PaolilloCesare GennariUmberto PiarulliAngelo CortiLaura BelvisiGiorgio Colombo
Published in: Chemistry (Weinheim an der Bergstrasse, Germany) (2019)
Ligand-based control of protein functional motions can provide novel opportunities in the study of fundamental biological mechanisms and in the development of novel therapeutics. In this work we addressed the ligand-based modulation of integrin functions. Inhibitors of integrin αv β3 are interesting anticancer agents but their molecular mechanisms are still unclear: Peptides and peptidomimetics characterized by the Arg-Gly-Asp (RGD) or isoAsp-Gly-Arg (isoDGR) binding motifs have shown controversial agonist/antagonist effects. We have investigated the differential mechanisms of integrin activation/deactivation by three distinct ligands (cyclo-RGDf(NMe)V (Cilengitide), cyclo[DKP3-RGD], cyclo[DKP3-isoDGR]; DKP=diketopiperazine) through a comparative analysis of ligand-controlled protein internal dynamics: Although RGD facilitates the onset of dynamic states leading to activation, isoDGR induces a diffuse rigidification of the complex consistent with antagonist activities. Computational predictions have been experimentally probed by showing that the antibody AP5, which is capable of recognizing the active form of integrin, binds specifically to the RGD complexes and not to the isoDGR complex, which supports opposite functional roles of the two motifs targeting the same binding site.
Keyphrases
  • cell adhesion
  • cell migration
  • amino acid
  • binding protein
  • protein protein
  • high resolution
  • transcription factor
  • cancer therapy
  • molecular dynamics simulations
  • low grade
  • drug delivery
  • dna binding