Retinoids play crucial roles in various biological processes by interacting with their carrier proteins such as cellular retinol-binding protein (CRBP). Understanding the molecular interactions between retinoids and CRBP enables their pharmacological and biomedical applications. Experimentally, CRBP(I) does not bind to retinoic acid, but when arginine is introduced into 108th residue instead of glutamine (Q108R), it binds to retinoic acid. Here, molecular dynamics simulations were performed to understand the differences in the microscopic and dynamic behaviors of the non-binding wild-type CRBP(I)-retinoic acid and binding Q108R variant-retinoic acid complexes. The ligand RMSD and RMSF, the binding poses of binding motif amino acids, and the number of hydrogen bonds and salt-bridges revealed the relative instability of the non-binding complex. In particular, the ligand's terminal group showed very different dynamics and interactions. So far, most studies have focused on the binding characteristics of retinoids, but the features of their non-binding modes have not been studied well. This study provides some structural insights into the non-binding modes of a retinoid in CRBP, which may be applicable in retinoid-based drug discovery and protein engineering through computational modeling.
Keywords: Cellular retinol-binding protein; Molecular dynamics simulation; Protein-ligand interaction; Retinoic acid; Site-directed mutagenesis.
Copyright © 2023 Elsevier Inc. All rights reserved.