EFFECTS OF [CA2+](I) AND TEMPERATURE ON MINK CHANNELS EXPRESSED IN XENOPUS-OOCYTES

Slowly activating, voltage-dependent minK channels cloned from rat kidney were expressed in Xenopus oocytes. Increase in the bath temperature from 22 to 32-degrees-C resulted in a dramatic acceleration of minK channel activation. The extraordinarily high Q10 of minK channel activation was voltage-dependent, being higher at more negative potentials (Q10 at -20 mV: 7.02; at 20 mV: 4.0). While activation of minK channels was highly voltage-dependent at 22-degrees-C, voltage had only little effect on minK channel activation at 32-degrees-C. Increase in [Ca2+]i, which has recently been shown to increase the maximal conductance g(max) at room temperature, did not affect g(max) at 32-degrees-C. However, increase of [Ca2+]i caused acceleration of minK channel activation at both temperatures. The interaction of [Ca2+]i and temperature on g(max) and activation rate of minK channels described here is very similar to recent findings on Ca- and temperature-effects on the slowly activating potassium conductance I(Ks) in guinea pig cardiac myocytes.