The Influence of 150-Cavity Binders on the Dynamics of Influenza A Neuraminidases as Revealed by Molecular Dynamics Simulations and Combined Clustering

Kyle T Greenway,Eric B Legresley,B Mario Pinto,Pratul K Agarwal

doi:10.1371/journal.pone.0059873

Kyle T Greenway, Eric B Legresley + Show 2 more

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https://doi.org/10.1371/journal.pone.0059873

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Journal: PloS one	Publication Date: Mar 27, 2013
Citations: 21	License type: CC BY 4.0

Affiliation: Simon Fraser University

Abstract

Neuraminidase inhibitors are the main pharmaceutical agents employed for treatments of influenza infections. The neuraminidase structures typically exhibit a 150-cavity, an exposed pocket that is adjacent to the catalytic site. This site offers promising additional contact points for improving potency of existing pharmaceuticals, as well as generating entirely new candidate inhibitors. Several inhibitors based on known compounds and designed to interact with 150-cavity residues have been reported. However, the dynamics of any of these inhibitors remains unstudied and their viability remains unknown. This work reports the outcome of long-term, all-atom molecular dynamics simulations of four such inhibitors, along with three standard inhibitors for comparison. Each is studied in complex with four representative neuraminidase structures, which are also simulated in the absence of ligands for comparison, resulting in a total simulation time of 9.6µs. Our results demonstrate that standard inhibitors characteristically reduce the mobility of these dynamic proteins, while the 150-binders do not, instead giving rise to many unique conformations. We further describe an improved RMSD-based clustering technique that isolates these conformations – the structures of which are provided to facilitate future molecular docking studies – and reveals their interdependence. We find that this approach confers many advantages over previously described techniques, and the implications for rational drug design are discussed.

Highlights

Influenza A and B viruses are responsible for the respiratory disease commonly referred to as ‘the flu’, with infections ranging from epidemics to pandemics and symptoms ranging from mild to life-threatening
All known NA possess highly conserved active site residues and conformations, crystallography has demonstrated that group-1 NA generally exhibit a cavity adjacent to the main sialic-acid-binding site that is not apparent in group-2 NA crystal structures (CS)
N109 is more dynamic, it exhibits a closed-cavity for 70% of all simulations and only slightly more in the apo simulation

Summary

Introduction

Influenza A and B viruses are responsible for the respiratory disease commonly referred to as ‘the flu’, with infections ranging from epidemics to pandemics and symptoms ranging from mild to life-threatening. There are nine known serotypes of NA (N1–N9) found in influenza A. All known NA possess highly conserved active site residues and conformations, crystallography has demonstrated that group-1 NA generally exhibit a cavity adjacent to the main sialic-acid-binding site that is not apparent in group-2 NA crystal structures (CS). This cavity is known as the 150-cavity as its accessibility is limited by a mobile loop composed of residues 147– 152, known as the 150-loop. The 150-loop has been crystallized in ‘open’ and ‘closed’ conformations [2,3], which provide snapshots along a conformational itinerary

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