Developmental temperature selectively regulates a voltage‐activated potassium current in Drosophila

Abstract

Ionic currents are regulated by many conditions including disease states, ageing, learning and memory, and chronic drug treatment. Here we describe a novel phenomenon of regulation of ionic currents by developmental temperature. Raising Drosophila larvae at 28°C instead of 18°C increased one of the two voltage‐activated K⁺‐ currents, the delayed sustained I_K, in their muscles by up to 3.5‐fold, with little effect on the early transient current, I_A. Consistent with this increase in I_K, the amplitude and the duration of the action potentials were reduced. The major increase in I_K occurred between a rather abrupt interval from 25° to 28°C. The activation curve of the increased current was shifted towards hyperpolarizing potentials. There was no change in activation kinetics. This phenomenon has mechanistic implications for activity‐dependent neuronal plasticity, expression of ion channels in cultured cells and heterologus systems, phototransduction, and behavior. The specificity of the regulation suggests a discrete mechanism geared to affect excitability such that it can respond to altered external stimuli such as temperature. 1994 John Wiley & Sons, Inc.