Alternative splicing matters: N-type calcium channels in nociceptors.

How many different calcium channels does it take to make a nervous system? The answer: more than any of us predicted. In 1975 Hagiwara and colleagues published the first evidence that functionally different calcium channels are expressed in cells. By 1999, the calcium channel family could boast ten members, each member defined by a unique set of attributes to support their cellular functions and by unique amino acid sequences. Although nine of these genes are expressed in the nervous system, that number still seemed insufficient to support the wide spectrum of neuronal functions controlled by voltage-gated calcium channels. This discrepancy is probably explained by alternative pre-messenger RNA splicing which substantially expands the number of protein activities available from a limited number of genes. Like many other ion channel genes, each Ca(V)alpha(1) gene has the capacity to generate perhaps thousands of unique splice isoforms with unique functional properties. The high level of conservation among alternatively spliced exons in Ca(V)2.2 genes of different species and in some cases closely related genes implies biological importance. A number of Ca(V)alpha(1) isoforms have been identified from neural tissue but until recently we lacked direct evidence linking a specific splice site in a calcium channel gene to a specific function in an identified neuron population. Our recent studies show that alternative pre-mRNA splicing of a pair of 32 amino acid encoding exons in the C-terminus of Ca(V)2.2, e37a and e37b, underlie the expression of two mutually exclusive N-type channel isoforms. The inclusion of e37a creates a module that couples the N-type channel to a powerful form of G protein-dependent inhibition. The inhibitory pathway that works through e37a is voltage-independent, requires G(i/o) and tyrosine kinase activation, and is used by mu opioid and GABA(B) receptors to downregulate N-type channel activity. Combined with our previous studies that show enrichment of e37a in nociceptors, our data suggest a molecular basis for the high susceptibility of N-type currents in sensory neurons to voltage-independent inhibition following G protein activation.