An ether ‐à‐go‐go K+ current, Ih‐eag, contributes to the hyperpolarization of human fusion‐competent myoblasts

Abstract

1 Two early signs of human myoblast commitment to fusion are membrane potential hyperpolarization and concomitant expression of a non-inactivating delayed rectifier K⁺ current, I_K(NI). This current closely resembles the outward K⁺ current elicited by rat ether-à-go-go (r-eag) channels in its range of potential for activation and unitary conductance. 2 It is shown that activation kinetics of I_K(NI), like those of r-eag, depend on holding potential and on [Mg²⁺]_o, and that I_K(NI), like r-eag, is reversibly inhibited by a rise in [Ca²⁺]. 3 Forced expression of an isolated human ether-à-go-go K⁺ channel (h-eag) cDNA in undifferentiated myoblasts generates single-channel and whole-cell currents with remarkable similarity to I_K(NI). 4 h-eag current (I_h-eag) is reversibly inhibited by a rise in [Ca²⁺]_i, and the activation kinetics depend on holding potential and [Mg²⁺]_o. 5 Forced expression of h-eag hyperpolarizes undifferentiated myoblasts from −9 to −50 mV, the threshold for the activation of both I_h-eag and I_K(NI). Similarly, the higher the density of I_K(NI), the more hyperpolarized the resting potential of fusion-competent myoblasts. 6 It is concluded that h-eag constitutes the channel underlying I_K(NI) and that it contributes to the hyperpolarization of fusion-competent myoblasts. To our knowledge, this is the first demonstration of a physiological role for a mammalian eag K⁺ channel.