Mechanisms of Cs+ blockade in a Ca2+-activated K+ channel from smooth muscle.

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Mechanisms of Cs+ blockade in a Ca2+-activated K+ channel from smooth muscle.

X Cecchi, D Wolff, O Alvarez and R Latorre

Departmento de Biologia, Universidad de Chile, Santiago.

ABSTRACT

Large unitary conductance Ca2+-activated K+ channels from smoothmuscle membrane were incorporated into phospholipid planar bilayers,and the blockade induced by internally and externally appliedCs+ was characterized. Internal Cs+ blockade is voltage dependentand can be explained on the basis of a Cs+ binding to a sitethat senses 54% of the applied voltage, with an apparent dissociationconstant, Kd(0), of 70 mM. On the other hand, external Cs+ blocksthe channel in micromolar amounts, and the voltage dependenceof blockade is a function of Cs+ concentration. The fractionalelectrical distance can be as large as 1.4 at 10 mM Cs+. Thislast result suggests that the channel behaves as a multi-ionpore. At large negative voltages the I-V relationships in thepresence of external Cs+ show an upturn, indicating relief ofCs+ block. External Cs+ blockade is relieved by increasing theinternal K+ concentration, but can be enhanced by increasingthe external K+. All the characteristics of external Cs+ blockcan be explained by a model that incorporates a "knock-on" ofCs+ by K+.

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