Conserved conformational hierarchy across functionally divergent glycosyltransferases of the GT-B structural superfamily as determined from microsecond molecular dynamics

Abstract

It has long been understood that some proteins to undergo conformational transitions enroute to the Michaelis Complex to allow chemistry. Examination of crystal structures of glycosyltransferase enzymes in the GT-B structural class reveals that the presence of ligand in the active site is necessary for the protein to crystalize in the closed conformation. Herein we describe microsecond molecular dynamics simulations of two evolutionarily unrelated glycosytransferases, HepI and GtfA. Simulations were performed using these proteins in the open and closed conformations, (respectively,) and we sought to identify the major dynamical modes and communication networks which allow conformational transition between the open and closed structures. We provide the first reported evidence (within the scope of our experimental parameters) that conformational hierarchy/directionality of the interconversion between open and closed conformations is a conserved feature of enzymes of the same structural superfamily. Additionally, residues previously identified to be important for substrate binding in HepI were shown to have strong negative correlations with non-ionizable residues distal to the active site. Mutagenesis of these residues produced mutants with altered enzymatic efficiency exhibiting lower K_m values, while the k_cat is effectively unchanged. The negatively correlated motions of these residues are important for substrate binding and forming the Michaelis complex, without impacting the activation barrier for catalysis. This suggests that in the bi-domain HepI, the enzyme dynamics did not impact the transition state stabilization or chemistry, but rather earlier steps along the reaction coordinate, leading to the reorganization of the active site electrostatic environment required for catalysis.