Mutations stabilizing an open conformation within the external region of the permeation pathway of the potassium channel KcsA.

Four subunits of the bacterial Streptomyces lividans protein KcsA form a K+ channel which can be functionally reconstituted in vitro. Here we show that substitution of the tyrosine residue 82 by cysteine, valine or threonine, but not by glycine, led to functional channel types. Like the wild-type (WT) and an L81C channel, the mutant channels exhibit an internal pH-sensitive side and are cation selective. Based on the relative positions of the blocker tetraethylammonium within the electric field, the external entryways of the channels are concluded to have similar dimensions. For inward currents, the WT and the mutant channels vary in the occupancy of their subconductance states and concomitantly in their mean currents. Rectification properties are scarcely (L81C), little (Y82C) or considerably (Y82T and Y82V) altered. The data suggest that the amino acid type in position 82 stabilizes to varying degrees an open conformation within the external region of the permeation pathway.

Pore mutations affecting tetrameric assembly and functioning of the potassium channel KcsA from Streptomyces lividans.

Designed mutations within the Streptomyces lividans kcsA gene resulted in a set of mutant proteins, which were characterized in respect to their assembly and channel activities. (i) The amino acid residue leucine 81 located at the external side of KcsA was found to be exchangeable by a cysteine residue without affecting the channel characteristics. (ii) Substitution of the first glycine (G77) residue within the GYG motif by an alanine or substitution of the tyrosine (Y) residue 78 by a phenylalanine (F) led to mutant proteins which form tetramers of reduced stability. In contrast to the AYG mutant protein, GFG functions as an active K(+) channel whose characteristics correspond to those of the wild-type KcsA channel. (iii) The investigated mutant proteins, which carry different mutations (T72A, T72C, V76A, V76E, G77E, Y78A, G79A, G79D, G79E) within the signature sequence of the pore region, do not at all or only to a very small degree assemble as tetramers and lack channel activity.

Exploring the open pore of the potassium channel from Streptomyces lividans.

The tetrameric potassium channel from Streptomyces lividans (KcsA) embedded in planar bilayers exhibits the following electrophysiological characteristics: (i) K+ ions can cross the pore in a highly hydrated state (nH2O > or = 6), (ii) the selectivity for K+ exceeds that for Na+ ions by 11 times, and both Ca2+ and Mg2+ are permeant, (iii) the internal side is blocked by Ba2+ ions in a voltage-dependent manner, (iv) intrinsic rectification is due to gating, depending on the direction of the electric field, (v) the internal side is pH-sensitive, and (vi) the open pore has a diameter of approximately 5.8 A. In conclusion, our results show that ion conduction and selectivity of KcsA cannot easily be reconciled with the properties deduced from the rigid crystal structure [Doyle et al., Science 280 (1998) 69-77], which must be concluded to have the pore trapped in its closed state.