Voltage-gated calcium channels mediate excitationcontraction coupling in the skeletal muscle. Their molecular composition, similar to neuronal channels, includes the pore-forming ␣ 1 and auxiliary ␣ 2 ␦, , and ␥ subunits. The ␥ subunits are the least characterized, and their subunit interactions are unclear. The physiological importance of the neuronal ␥ is emphasized by epileptic stargazer mice that lack ␥ 2 . In this study, we examined the molecular basis of interaction between skeletal ␥ 1 and the calcium channel. Our data show that the ␣ 1 1.1,  1a , and ␣ 2 ␦ subunits are still associated in ␥ 1 null mice. Reexpression of ␥ 1 and ␥ 2 showed that ␥ 1 , but not ␥ 2 , incorporates into ␥ 1 null channels. By using chimeric constructs, we demonstrate that the first half of the ␥ 1 subunit, including the first two transmembrane domains, is important for subunit interaction. Interestingly, this chimera also restores calcium conductance in ␥ 1 null myotubes, indicating that the domain mediates both subunit interaction and current modulation. To determine the subunit of the channel that interacts with ␥ 1 , we examined the channel in muscular dysgenesis mice. Cosedimentation experiments showed that ␥ 1 and ␣ 2 ␦ are not associated. Moreover, ␣ 1 1.1 and ␥ 1 subunits form a complex in transiently transfected cells, indicating direct interaction between the ␥ 1 and ␣ 1 1.1 subunits. Our data demonstrate that the first half of ␥ 1 subunit is required for association with the channel through ␣ 1 1.1. Because subunit interactions are conserved, these studies have broad implications for ␥ heterogeneity, function and subunit association with voltage-gated calcium channels.The L-type voltage-gated calcium channels of the skeletal muscle serve both as a voltage-gated calcium channel and as a voltage sensor for excitation-contraction (EC) 1 coupling (1, 2). These channels serve to couple depolarization to intracellular calcium release via the ryanodine receptor. The sites of EC coupling in the skeletal muscle are the triads, which are highly organized junctions comprising the t-tubules and the underlying sarcoplasmic reticulum (3). The voltage-gated calcium channels are localized predominantly in the t-tubules in close association with the ryanodine receptor in the sarcoplasmic reticulum (4, 5).At the molecular level, the calcium channel is composed of the pore-forming ␣ 1 1.1 subunit and auxiliary ␣ 2 ␦,  1 , and ␥ 1 subunits (6). This four-subunit composition of the channels is similar to that of the neuronal voltage-gated channels (7, 8). The auxiliary ␣ 2 ␦ and  subunits enhance membrane trafficking of the ␣ 1 1.1 subunit and modulate the voltage-dependent kinetics of the channel (9). In addition to the role of the  1 subunit in the trafficking of the channel, it also has a crucial role in EC coupling as emphasized by the absence of EC coupling and early lethality in mice that lack the skeletal  1 subunit (10). The subunit interactions of the ␣ 2 ␦ and  subunits have been relatively well defined.The ␥ 1 subunit is ...
