Excitation–Contraction Coupling: Calcium current modulation by the γ1 subunit depends on alternative splicing of CaV1.1

The skeletal muscle voltage-gated calcium channel (Ca_V1.1) primarily functions as a voltage sensor for excitation–contraction coupling. Conversely, its ion-conducting function is modulated by multiple mechanisms within the pore-forming α_1S subunit and the auxiliary α₂δ-1 and γ₁ subunits. In particular, developmentally regulated alternative splicing of exon 29, which inserts 19 amino acids in the extracellular IVS3-S4 loop of Ca_V1.1a, greatly reduces the current density and shifts the voltage dependence of activation to positive potentials outside the physiological range. We generated new HEK293 cell lines stably expressing α₂δ-1, β₃, and STAC3. When the adult (Ca_V1.1a) and embryonic (Ca_V1.1e) splice variants were expressed in these cells, the difference in the voltage dependence of activation observed in muscle cells was reproduced, but not the reduced current density of Ca_V1.1a. Only when we further coexpressed the γ₁ subunit was the current density of Ca_V1.1a, but not that of Ca_V1.1e, reduced by >50%. In addition, γ₁ caused a shift of the voltage dependence of inactivation to negative voltages in both variants. Thus, the current-reducing effect of γ₁, unlike its effect on inactivation, is specifically dependent on the inclusion of exon 29 in Ca_V1.1a. Molecular structure modeling revealed several direct ionic interactions between residues in the IVS3-S4 loop and the γ₁ subunit. However, substitution of these residues by alanine, individually or in combination, did not abolish the γ₁-dependent reduction of current density, suggesting that structural rearrangements in Ca_V1.1a induced by inclusion of exon 29 may allosterically empower the γ₁ subunit to exert its inhibitory action on Ca_V1.1 calcium currents.