Recently we reported on the dynamic properties of the cellular retinol binding protein, a member of the fatty acid binding protein family. A few conserved glycines were identified as important for producing the conformational changes necessary for the uptake and release of retinol. Here, we describe a multidisciplinary analysis of a genetically engineered mutation of one of these glycines (Gly67), designed to inhibit an observed hinge bending motion. The correctly folded mutant protein is unable to bind retinol. Analysis of the molecular dynamics simulations of the mutant and wild type protein using the essential dynamics method shows that the mutation indeed inhibits the hinge bending motions which are important for retinol binding.