Pore mutations in Shaker K+ channels distinguish between the sites of tetraethylammonium blockade and C-type inactivation.

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J Physiol Vol 499, Issue Pt 2 pp 361-367
Copyright © 1997 by The Physiological Society

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Pore mutations in Shaker K+ channels distinguish between the sites of tetraethylammonium blockade and C-type inactivation.

A Molina, A G Castellano and J López-Barneo

Departamento de Fisiología Médica y Biofísica, Facultad de Medicina, Universidad de Sevilla, Spain.

1. We have studied the effect of external K+ and tetraethylammonium(TEA) on several mutants of Shaker B K+ channels with aminoacid substitutions in the pore which alter TEA affinity andthe rate of C-type inactivation. In all channels studied highexternal K+ makes C-type inactivation slower. 2. In the wild-typechannel, TEA blockade is voltage dependent and produces slowingof the inactivation time course. However, in the double mutantchannel (T449Y, D447E) TEA blockade, although of higher affinity,is voltage independent and does not affect the rate of C-typeinactivation. 3. Mutants with a charged amino acid at position449 (T449K and T449E) are resistant to TEA block. In these channels,C-type inactivation is also unaffected by TEA. 4. These resultsindicate that the sites where TEA blocks and competes with C-typeinactivation can be segregated. To modulate inactivation, TEAmust enter deeply into the channel mouth. These results suggestthat C-type inactivation is not due to a large molecular rearrangementin the outer channel vestibule, but it is essentially producedby a conformational change restricted to a local site in thepore.

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