Identification of Glycosylation Sites Essential for Surface Expression of the Ca_Vα2δ1 Subunit and Modulation of the Cardiac Ca_V1.2 Channel Activity*

Alteration in the L-type current density is one aspect of the electrical remodeling observed in patients suffering from cardiac arrhythmias. Changes in channel function could result from variations in the protein biogenesis, stability, post-translational modification, and/or trafficking in any of the regulatory subunits forming cardiac L-type Ca²⁺ channel complexes. Ca_Vα2δ1 is potentially the most heavily N-glycosylated subunit in the cardiac L-type Ca_V1.2 channel complex. Here, we show that enzymatic removal of N-glycans produced a 50-kDa shift in the mobility of cardiac and recombinant Ca_Vα2δ1 proteins. This change was also observed upon simultaneous mutation of the 16 Asn sites. Nonetheless, the mutation of only 6/16 sites was sufficient to significantly 1) reduce the steady-state cell surface fluorescence of Ca_Vα2δ1 as characterized by two-color flow cytometry assays and confocal imaging; 2) decrease protein stability estimated from cycloheximide chase assays; and 3) prevent the Ca_Vα2δ1-mediated increase in the peak current density and voltage-dependent gating of Ca_V1.2. Reversing the N348Q and N812Q mutations in the non-operational sextuplet Asn mutant protein partially restored Ca_Vα2δ1 function. Single mutation N663Q and double mutations N348Q/N468Q, N348Q/N812Q, and N468Q/N812Q decreased protein stability/synthesis and nearly abolished steady-state cell surface density of Ca_Vα2δ1 as well as the Ca_Vα2δ1-induced up-regulation of L-type currents. These results demonstrate that Asn-663 and to a lesser extent Asn-348, Asn-468, and Asn-812 contribute to protein stability/synthesis of Ca_Vα2δ1, and furthermore that N-glycosylation of Ca_Vα2δ1 is essential to produce functional L-type Ca²⁺ channels.