The dihydropyridine receptor (DHPR) β 1a subunit is crucial for enhancement of DHPR triad expression, assembly of DHPRs in tetrads, and elicitation of DHPRα 1S charge movement-the three prerequisites of skeletal muscle excitation-contraction coupling. Despite the ability to fully target α 1S into triadic junctions and tetradic arrays, the neuronal isoform β 3 was unable to restore considerable charge movement (measure of α 1S voltage sensing) upon expression in β 1 -null zebrafish relaxed myotubes, unlike the other three vertebrate β-isoforms (β 1a , β 2a , and β 4 ). Thus, we used β 3 for chimerization with β 1a to investigate whether any of the five distinct molecular regions of β 1a is dominantly involved in inducing the voltage-sensing function of α 1S . Surprisingly, systematic domain swapping between β 1a and β 3 revealed a pivotal role of the src homology 3 (SH3) domain and C terminus of β 1a in charge movement restoration. More interestingly, β 1a SH3 domain and C terminus, when simultaneously engineered into β 3 sequence background, were able to fully restore charge movement together with proper intracellular Ca 2+ release, suggesting cooperativity of these two domains in induction of the α 1S voltage-sensing function in skeletal muscle excitation-contraction coupling. Furthermore, substitution of a proline by alanine in the putative SH3-binding polyproline motif in the proximal C terminus of β 1a (also of β 2a and β 4 ) fully obstructed α 1S charge movement. Consequently, we postulate a model according to which β subunits, probably via the SH3-C-terminal polyproline interaction, adapt a discrete conformation required to modify the α 1S conformation apt for voltage sensing in skeletal muscle.