Find in Library

&#946;-<i>N</i>-Acetyl-<span style="font-variant: small-caps;">d</span>-hexosaminidase from <i>Ostrinia furnacalis</i> (O<i>f</i>Hex1) is a new target for the design of insecticides. Although some of its inhibitors have been found, there is still no commercial drug available at present. The residence time of the ligand may be important for its pharmacodynamic effect. However, the unbinding routes of ligands from O<i>f</i>Hex1 still remain largely unexplored. In the present study, we first simulated the six dissociation routes of <i>N,N,N</i>-trimethyl-<span style="font-variant: small-caps;">d</span>-glucosamine-chitotriomycin (TMG-chitotriomycin, a highly selective inhibitor of O<i>f</i>Hex1) from the active pocket of O<i>f</i>Hex1 by steered molecular dynamics simulations. By comparing the potential of mean forces (PMFs) of six routes, Route 1 was considered as the most possible route with the lowest energy barrier. Furthermore, the structures of six different states for Route 1 were snapshotted, and the key amino acid residues affecting the dissociated time were analyzed in the unbinding pathway. Moreover, we also analyzed the &#8220;open&#8211;close&#8222; mechanism of Glu368 and Trp448 and found that their conformational changes directly affected the dissociation of TMG-chitotriomycin. Our findings would be helpful to understanding and identifying novel inhibitors against O<i>f</i>Hex1 from virtual screening or lead-optimization.