Abstract
Neuraminidase (NA) of influenza is a key target for virus infection control and the recently discovered open 150-cavity in group-1 NA provides new opportunity for novel inhibitors design. In this study, we used a combination of theoretical methods including fragment docking, molecular linking and molecular dynamics simulations to design ligands that specifically target at the 150-cavity. Through in silico screening of a fragment compound library on the open 150-cavity of NA, a few best scored fragment compounds were selected to link with Zanamivir, one NA-targeting drug. The resultant new ligands may bind both the active site and the 150-cavity of NA simultaneously. Extensive molecular dynamics simulations in explicit solvent were applied to validate the binding between NA and the designed ligands. Moreover, two control systems, a positive control using Zanamivir and a negative control using a low-affinity ligand 3-(p-tolyl) allyl-Neu5Ac2en (ETT, abbreviation reported in the PDB) found in a recent experimental work, were employed to calibrate the simulation method. During the simulations, ETT was observed to detach from NA, on the contrary, both Zanamivir and our designed ligand bind NA firmly. Our study provides a prospective way to design novel inhibitors for controlling the spread of influenza virus.
Highlights
Introduction cases toM2 inhibitors have been reported, so application of theM2 inhibitors was limited during some epidemics [8,9]
Extensive molecular dynamics simulations in explicit solvent were applied to validate the binding between NA and the designed ligands
Our study provides a prospective way to design novel inhibitors for controlling the spread of influenza virus
Summary
Introduction cases toM2 inhibitors have been reported, so application of theM2 inhibitors was limited during some epidemics [8,9]. The NA inhibitors were developed by structure-based drug design, exclusively based on group-2 NAs [15]. The conformational change of the 150-loop in group-1 NAs suggests new opportunities for antiviral drug design. Vaccines and antiviral drugs are two available strategies in preventing and controlling influenza virus infections. It takes three to six months to create a vaccine for a newly emerged virus strain [2]. Under this circumstance, antiviral drug for controlling virus infection is of great importance and necessity in the lag phase of the vaccine manufacturing [4]
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