Selectivity filter mutations shift ion permeation mechanism in potassium channels

Author:

Mironenko Andrei1,de Groot Bert L1ORCID,Kopec Wojciech12ORCID

Affiliation:

1. Computational Biomolecular Dynamics Group, Max Planck Institute for Multidisciplinary Sciences , Am Fassberg 11, Göttingen 37077 , Germany

2. Department of Chemistry, Queen Mary University of London , 327 Mile End Road, London E1 4NS , UK

Abstract

Abstract Potassium (K+) channels combine high conductance with high ion selectivity. To explain this efficiency, two molecular mechanisms have been proposed. The “direct knock-on” mechanism is defined by water-free K+ permeation and formation of direct ion–ion contacts in the highly conserved selectivity filter (SF). The “soft knock-on” mechanism involves co-permeation of water and separation of K+ by water molecules. With the aim to distinguish between these mechanisms, crystal structures of the KcsA channel with mutations in two SF residues—G77 and T75—were published, where the arrangements of K+ ions and water display canonical soft knock-on configurations. These data were interpreted as evidence of the soft knock-on mechanism in wild-type channels. Here, we test this interpretation using molecular dynamics simulations of KcsA and its mutants. We show that while a strictly water-free direct knock-on permeation is observed in the wild type, conformational changes induced by these mutations lead to distinct ion permeation mechanisms, characterized by co-permeation of K+ and water. These mechanisms are characterized by reduced conductance and impaired potassium selectivity, supporting the importance of full dehydration of potassium ions for the hallmark high conductance and selectivity of K+ channels. In general, we present a case where mutations introduced at the critical points of the permeation pathway in an ion channel drastically change its permeation mechanism in a nonintuitive manner.

Funder

Deutsche Forschungsgemeinschaft

Publisher

Oxford University Press (OUP)

Reference70 articles.

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