Elimination of the Slow Gating of Clc-0 Chloride Channel by a Point Mutation

The inactivation of the ClC-0 chloride channel is very temperature sensitive and is greatly facilitated by the binding of a zinc ion (Zn(2+)) from the extracellular side, leading to a Zn(2+)-induced current inhibition. To further explore the relation of Zn(2+) inhibition and the ClC-0 inactivation, we mutated all 12 cysteine amino acids in the channel and assayed the effect of Zn(2+) on these mutants. With this approach, we found that C212 appears to be important for the sensitivity of the Zn(2+) inhibition. Upon mutating C212 to serine or alanine, the inactivation of the channel in macroscopic current recordings disappears and the channel does not show detectable inactivation events at the single-channel level. At the same time, the channel's sensitivity to Zn(2+) inhibition is also greatly reduced. The other two cysteine mutants, C213G and C480S, as well as a previously identified mutant, S123T, also affect the inactivation of the channel to some degree, but the temperature-dependent inactivation process is still present, likewise the high sensitivity of the Zn(2+) inhibition. These results further support the assertion that the inhibition of Zn(2+) on ClC-0 is indeed due to an effect on the inactivation of the channel. The absence of inactivation in C212S mutants may provide a better defined system to study the fast gating and the ion permeation of ClC-0.