Molecular motions within the pore of voltage-dependent sodium channels.

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Molecular motions within the pore of voltage-dependent sodium channels.

J P Bénitah, R Ranjan, T Yamagishi, M Janecki, G F Tomaselli and E Marban

Department of Medicine, Johns Hopkins University School of Medicine, Baltimore, Maryland 21205, USA.

ABSTRACT

The pores of ion channel proteins are often modeled as staticstructures. In this view, selectivity reflects rigidly constrainedbackbone orientations. Such a picture is at variance with thegeneralization that biological proteins are flexible, capableof major internal motions on biologically relevant time scales.We tested for motions in the sodium channel pore by systematicallyintroducing pairs of cysteine residues throughout the pore-liningsegments. Two distinct pairs of residues spontaneously formeddisulfide bonds bridging domains I and II. Nine other permutations,involving all four domains, were capable of disulfide bondingin the presence of a redox catalyst. The results are inconsistentwith a single fixed backbone structure for the pore; instead,the segments that line the permeation pathway appear capableof sizable motions.

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