Presynaptic Ca(v)2 channels are essential for Ca2+-triggered exocytosis. In addition, there are two competing models for their roles in synapse structure. First, Ca2+ channels or Ca2+ entry may... Show morePresynaptic Ca(v)2 channels are essential for Ca2+-triggered exocytosis. In addition, there are two competing models for their roles in synapse structure. First, Ca2+ channels or Ca2+ entry may control synapse assembly. Second, active zone proteins may scaffold Ca(v)2s to presynaptic release sites, and synapse structure is Ca(v)2 independent. Here, we ablated all three Ca(v)2s using conditional knockout in cultured hippocampal neurons or at the calyx of Held, which abolished evoked exocytosis. Compellingly, synapse and active zone structure, vesicle docking, and transsynaptic nano-organization were unimpaired. Similarly, long-term blockade of action potentials and Ca2+ entry did not disrupt active zone assembly. Although Ca(v)2 knockout impaired the localization of beta subunits, alpha 2 delta-1 localized normally. Rescue with Ca(v)2 restored exocytosis, and Ca(v)2 active zone targeting depended on the intracellular C-terminus. We conclude that synapse assembly is independent of Ca(v)2s or Ca2+ entry through them. Instead, active zone proteins recruit and anchor Ca(v)2s via Ca(v)2 C-termini. Show less