K(+) channels of squid giant axons open by an osmotic stress in hypertonic solutions containing nonelectrolytes.

In hypertonic solutions made by adding nonelectrolytes, K(+) channels of squid giant axons opened at usual asymmetrical K(+) concentrations in two different time courses; an initial instantaneous activation (I (IN)) and a sigmoidal activation typical of a delayed rectifier K(+) channel (I (D)). The current-voltage relation curve for I (IN) was fitted well with Goldman equation described with a periaxonal K(+) concentration at the membrane potential above -10 mV. Using the activation-voltage curve obtained from tail currents, K(+) channels for I (IN) are confirmed to activate at the membrane potential that is lower by 50 mV than those for I (D). Both I (IN) and I (D) closed similarly at the holding potential below -100 mV. The logarithm of I (IN)/I (D) was linearly related with the osmolarity for various nonelectrolytes. Solute inaccessible volumes obtained from the slope increased with the nonelectrolyte size from 15 to 85 water molecules. K(+) channels representing I (D) were blocked by open channel blocker tetra-butyl ammonium (TBA) more efficiently than in the absence of I (IN), which was explained by the mechanism that K(+) channels for I (D) were first converted to those for I (IN) by the osmotic pressure and then blocked. So K(+) channels for I (IN) were suggested to be derived from the delayed rectifier K(+) channels. Therefore, the osmotic pressure is suggested to exert delayed-rectifier K(+) channels to open in shrinking rather hydrophilic flexible parts outside the pore than the pore itself, which is compatible with the recent structure of open K(+) channel pore.