Molecular determinants of inactivation in voltage‐gated Ca2+ channels

Abstract

Evolution has created a large family of different classes of voltage‐gated Ca²⁺ channels and a variety of additional splice variants with different inactivation properties. Inactivation controls the amount of Ca²⁺ entry during an action potential and is, therefore, believed to play an important role in tissue‐specific Ca²⁺ signalling. Furthermore, mutations in a neuronal Ca²⁺ channel (Ca_v2.1) that are associated with the aetiology of neurological disorders such as familial hemiplegic migraine and ataxia cause significant changes in the process of channel inactivation. Ca²⁺ channels of a given subtype may inactivate by three different conformational changes: a fast and a slow voltage‐dependent inactivation process and in some channel types by an additional Ca²⁺‐dependent inactivation mechanism. Inactivation kinetics of Ca²⁺ channels are determined by the intrinsic properties of their pore‐forming α₁‐subunits and by interactions with other channel subunits. This review focuses on structural determinants of Ca²⁺ channel inactivation in different parts of Ca²⁺ channel α₁‐subunits, including pore‐forming transmembrane segments and loops, intracellular domain linkers and the carboxyl terminus. Inactivation is also affected by the interaction of the α₁‐subunits with auxiliary β‐subunits and intracellular regulator proteins. The evidence shows that pore‐forming S6 segments and conformational changes in extra‐ (pore loop) and intracellular linkers connected to pore‐forming segments may play a principal role in the modulation of Ca²⁺ channel inactivation. Structural concepts of Ca²⁺ channel inactivation are discussed.