LAUSR

Significance Association of the adaptor protein STAC3 to the calcium channel was recently identified as essential for skeletal muscle contraction. While STAC3 is expressed exclusively in skeletal muscle, the other two isoforms, STAC1 and STAC2, are found in the brain, but their function has not yet been investigated. Recently we identified the C1 domain of STAC as crucial for its association with calcium channels. However, the corresponding binding domain remained unknown. Here, we demonstrate that STAC proteins associate with the C terminus of CaV1.2 at the IQ domain, and that this interaction results in the inhibition of calcium-dependent inactivation. Taken together, our data identify a functionally important STAC interaction domain and suggest that STAC proteins modulate calcium entry through CaV1 channels. The adaptor proteins STAC1, STAC2, and STAC3 represent a newly identified family of regulators of voltage-gated calcium channel (CaV) trafficking and function. The skeletal muscle isoform STAC3 is essential for excitation–contraction coupling and its mutation causes severe muscle disease. Recently, two distinct molecular domains in STAC3 were identified, necessary for its functional interaction with CaV1.1: the C1 domain, which recruits STAC proteins to the calcium channel complex in skeletal muscle triads, and the SH3-1 domain, involved in excitation–contraction coupling. These interaction sites are conserved in the three STAC proteins. However, the molecular domain in CaV1 channels interacting with the STAC C1 domain and the possible role of this interaction in neuronal CaV1 channels remained unknown. Using CaV1.2/2.1 chimeras expressed in dysgenic (CaV1.1−/−) myotubes, we identified the amino acids 1,641–1,668 in the C terminus of CaV1.2 as necessary for association of STAC proteins. This sequence contains the IQ domain and alanine mutagenesis revealed that the amino acids important for STAC association overlap with those making contacts with the C-lobe of calcium-calmodulin (Ca/CaM) and mediating calcium-dependent inactivation of CaV1.2. Indeed, patch-clamp analysis demonstrated that coexpression of either one of the three STAC proteins with CaV1.2 opposed calcium-dependent inactivation, although to different degrees, and that substitution of the CaV1.2 IQ domain with that of CaV2.1, which does not interact with STAC, abolished this effect. These results suggest that STAC proteins associate with the CaV1.2 C terminus at the IQ domain and thus inhibit calcium-dependent feedback regulation of CaV1.2 currents.