The influenza A virus M2 channel: A molecular modeling and simulation study

Abstract

The M2 protein of influenza virus forms ion channels activated by low pH which are proton permeable and play a key role in the life cycle of the virus M2 is a 97-residue integral membrane protein containing a single transmembrane (TM) helix M2 is present as disulfide-linked homotetramers. The TM domain of M2 has been modeled as a bundle of four parallel M2 helices The helix bundle forms a left-handed supercoil surrounding a central pore. Residue H37 has been implicated in the mechanism of low-pH activation of the channel. Models generated with H37 in a fully deprotonated state exhibit a pore occluded by a ring of H37 side chains oriented toward the lumen of the pore. Models with H37 in a fully protonated state no longer exhibit such occlusion of the pore, as the H37 side chains adopt a more interfacial location. Extended molecular dynamics simulations with water molecules within and at the mouths of the pores support this distinction between the H37- deprotonated and H37-protonated models. These simulations suggest that only in the H37-protonated model is there a continuous column of water extending the entire length of the central pore A mechanism for activation of M2 by low pH is presented in which the H37-deprotonated model corresponds to the 'closed' form of the channel, while the H37-protonated model corresponds to the 'open' form A switch from the closed to the open form of the channel occurs if H37 is protonated midway through a simulation. The open channel is suggested to contain a wire of H-bonded water molecules which enables proton permeability.