Alternative splicing generates a smaller assortment of CaV2.1 transcripts in cerebellar Purkinje cells than in the cerebellum

P/Q-type calcium channels control many calcium- driven functions in the brain. The CACNA1A gene encoding the pore- forming Ca(V)2.1 (alpha(1A)) subunit of P/Q-type channels undergoes alternative splicing at multiple loci. This results in channel variants with different phenotypes. However, the combinatorial patterns of alternative splice events at two or more loci, and hence the diversity of Ca(V)2.1 transcripts, are incompletely defined for specific brain regions and types of brain neurons. Using RT-PCR and splice variant- specific primers, we have identified multiple Ca(V)2.1 transcript variants defined by different pairs of splice events in the cerebellum of adult rat. We have uncovered new splice variations between exons 28 and 34 (some of which predict a premature stop codon) and a new variation in exon 47 (which predicts a novel extended COOH- terminus). Single cell RTPCR reveals that each individual cerebellar Purkinje neuron also expresses multiple alternative Ca(V)2.1 transcripts, but the assortment is smaller than in the cerebellum. Two of these variants encode different extended COOH- termini which are not the same as those previously reported in Purkinje cells of the mouse. Our patch-clamp recordings show that calcium channel currents in the soma and dendrites of Purkinje cells are largely inhibited by a concentration of w-agatoxin IVA selective for P-type over Q-type channels, suggesting that the different transcripts may form phenotypic variants of P-type calcium channels in Purkinje cells. These results expand the known diversity of Ca(V)2.1 transcripts in cerebellar Purkinje cells, and propose the selective expression of distinct assortments of Ca(V)2.1 transcripts in different brain neurons and species.