A critical GxxxA motif in the gamma6 calcium channel subunit mediates its inhibitory effect on Cav3.1 calcium current.

The eight members of the calcium channel gamma subunit family are integral membrane proteins that regulate the expression and behaviour of voltage and ligand gated ion channels. While a subgroup consisting of gamma(2), gamma(3), gamma(4) and gamma(8) (the TARPs) modulate AMPA receptor localization and function, the gamma(1) and gamma(6) subunits conform to the original description of these proteins as regulators of voltage gated calcium channels. We have previously shown that the gamma(6) subunit is highly expressed in atrial myocytes and that it is capable of acting as a negative modulator of low voltage activated calcium current. In this study we extend our understanding of gamma(6) subunit modulation of low voltage activated calcium current. Using engineered chimeric constructs, we demonstrate that the first transmembrane domain (TM1) of gamma(6) is necessary for its inhibitory effect on Cav3.1 current. Mutational analysis is then used to identify a unique GxxxA motif within TM1 that is required for the function of the subunit strongly suggesting the involvement of helix-helix interactions in its effects. Results from co-immunoprecipitation experiments confirm a physical association of gamma(6) with the Cav3.1 channel in both HEK cells and atrial myocytes. Single channel analysis reveals that binding of gamma(6) reduces channel availability for activation. Taken together, the results of this study provide both a molecular and a mechanistic framework for understanding the unique ability of the gamma(6) calcium channel subunit to modulate low voltage activated (Cav3.1) calcium current density.

Calcium channel gamma6 subunits are unique modulators of low voltage-activated (Cav3.1) calcium current.

The calcium channel gamma (gamma) subunit family consists of eight members whose functions include modulation of high voltage-activated (HVA) calcium currents in skeletal muscle and neurons, and regulation of alpha-amino-3-hydroxy-5-methylisoxazole-4-propanoic acid (AMPA) receptor targeting. Cardiac myocytes express at least three gamma subunits, gamma(4), gamma(6) and gamma(7), whose function(s) in the heart are unknown. Here we compare the effects of the previously uncharacterized gamma(6) subunit with that of gamma(4) and gamma(7) on a low voltage-activated calcium channel (Cav3.1) that is expressed in cardiac myocytes. Co-expression of both the long and short gamma(6) subunit isoforms, gamma(6L) and gamma(6S), with Cav3.1 in HEK-293 cells significantly decreases current density by 49% and 69%, respectively. Two other gamma subunits expressed in cardiac myocytes, gamma(4) and gamma(7), have no significant effect on Cav3.1 current. Neither gamma(6L), gamma(6S), gamma(4) nor gamma(7) significantly affect the voltage dependency of activation or inactivation or the kinetics of Cav3.1 current. Transient expression of gamma(6L) in an immortalized atrial cell line (HL-1) significantly reduces the endogenous low voltage-activated current in these cells by 63%. Green fluorescent protein tagged gamma(6L) is localized primarily in HEK-293 cell surface membranes where it is evenly distributed. Expression of gamma(6L) does not affect the level of Cav3.1 mRNA or the amount of total Cav3.1 protein in transfected HEK-293 cells. These results demonstrate that the gamma(6) subunit has a unique ability to inhibit Cav3.1 dependent calcium current that is not shared with the gamma(4) and gamma(7) isoforms and is thus a potential regulator of cardiac low voltage-activated calcium current.