Voltage-gated calcium channels function as Ca super(2+)-activated signaling receptors

Voltage-gated calcium channels (VGCCs) are transmembrane cell surface proteins responsible for multifunctional signals. In response to voltage, VGCCs trigger synaptic transmission, drive muscle contraction, and regulate gene expression. Voltage perturbations open VGCCs enabling Ca super(2+) binding to the low affinity Ca super(2+) binding site of the channel pore. Subsequent to permeation, Ca super(2+) targets selective proteins to activate diverse signaling pathways. It is becoming apparent that the Ca super(2+)-bound channel triggers secretion in excitable cells and drives contraction in cardiomyocytes prior to Ca super(2+) permeation. Here, I highlight recent data implicating receptor-like function of the Ca super(2+)-bound channel in converting external Ca super(2+) into an intracellular signal. The two sequential mechanistic perspectives of VGCC function are discussed in the context of the prevailing and longstanding current models of depolarization-evoked secretion and cardiac contraction.