Ca _V 2.1 α ₁ subunit motifs that control presynaptic Ca _V 2.1 subtype abundance are distinct from Ca _V 2.1 preference

Presynaptic voltage-gated Ca ²⁺ channels (Ca _V ) subtype abundance at mammalian synapses regulates synaptic transmission in health and disease. In the mammalian central nervous system, most presynaptic terminals are Ca _V 2.1 dominant with a developmental reduction in Ca _V 2.2 and Ca _V 2.3 levels, and Ca _V 2 subtype levels are altered in various diseases. However, the molecular mechanisms controlling presynaptic Ca _V 2 subtype levels are largely unsolved. Since the Ca _V 2 α ₁ subunit cytoplasmic regions contain varying levels of sequence conservation, these regions are proposed to control presynaptic Ca _V 2 subtype preference and abundance. To investigate the potential role of these regions, we expressed chimeric Ca _V 2.1 α ₁ subunits containing swapped motifs with the Ca _V 2.2 and Ca _V 2.3 α ₁ subunit on a Ca _V 2.1/Ca _V 2.2 null background at the calyx of Held presynaptic terminal. We found that expression of Ca _V 2.1 α ₁ subunit chimeras containing the Ca _V 2.3 loop II-III region or cytoplasmic C-terminus (CT) resulted in a large reduction of presynaptic Ca ²⁺ currents compared to the Ca _V 2.1 α ₁ subunit. However, the Ca ²⁺ current sensitivity to the Ca _V 2.1 blocker Agatoxin-IVA, was the same between the chimeras and the Ca _V 2.1 α ₁ subunit. Additionally, we found no reduction in presynaptic Ca ²⁺ currents with Ca _V 2.1/2.2 cytoplasmic CT chimeras. We conclude that the motifs in the Ca _V 2.1 loop II-III and CT do not individually regulate Ca _V 2.1 preference, but these motifs control Ca _V 2.1 levels and the Ca _V 2.3 CT contains motifs that negatively regulate presynaptic Ca _V 2.3 levels. We propose that the motifs controlling presynaptic Ca _V 2.1 preference are distinct from those regulating Ca _V 2.1 levels and may act synergistically to impact pathways regulating Ca _V 2.1 preference and abundance.