Rbfox proteins regulate alternative splicing of neuronal sodium channel SCN8A.

The SCN8A gene encodes the voltage-gated sodium channel Na(v)1.6, a major channel in neurons of the CNS and PNS. SCN8A contains two alternative exons,18N and 18A, that exhibit tissue specific splicing. In brain, the major SCN8A transcript contains exon 18A and encodes the full-length sodium channel. In other tissues, the major transcript contains exon 18N and encodes a truncated protein, due to the presence of an in-frame stop codon. Selection of exon 18A is therefore essential for generation of a functional channel protein, but the proteins involved in this selection have not been identified. Using a 2.6 kb Scn8a minigene containing exons 18N and 18A, we demonstrate that co-transfection with Fox-1 or Fox-2 initiates inclusion of exon 18A. This effect is dependent on the consensus Fox binding site located 28 bp downstream of exon 18A. We examined the alternative splicing of human SCN8A and found that the postnatal switch to exon 18A is completed later than 10 months of age. In purified cell populations, transcripts containing exon 18A predominate in neurons but are not present in oligodendrocytes or astrocytes. Transcripts containing exon 18N appear to be degraded by nonsense-mediated decay in HEK cells. Our data indicate that RBFOX proteins contribute to the cell-specific expression of Na(v)1.6 channels in mature neurons.

Identification of evolutionarily conserved, functional noncoding elements in the promoter region of the sodium channel gene SCN8A.

SCN8A is a major neuronal sodium channel gene expressed throughout the central and peripheral nervous systems. Mutations of SCN8A result in movement disorders and impaired cognition. To investigate the basis for the tissue-specific expression of SCN8A, we located conserved, potentially regulatory sequences in the human, mouse, chicken, and fish genes by 5' RACE of brain RNA and genomic sequence comparison. A highly conserved 5' noncoding exon, exon 1c, is present in vertebrates from fish to mammals and appears to define the ancestral promoter region. The distance from exon 1c to the first coding exon increased tenfold during vertebrate evolution, largely by insertion of repetitive elements. The mammalian gene acquired three novel, mutually exclusive noncoding exons that are not represented in the lower vertebrates. Within the shared exon 1c, we identified four short sequence elements of 10-20 bp with an unusually high level of evolutionary conservation. The conserved elements are most similar to consensus sites for the transcription factors Pou6f1/Brn5, YY1, and REST/NRSF. Introduction of mutations into the predicted Pou6f1 and REST sites reduced promoter activity in transfected neuronal cells. A 470-bp promoter fragment containing all of the conserved elements directed brain-specific expression of the LacZ reporter in transgenic mice. Transgene expression was highest in hippocampal neurons and cerebellar Purkinje cells, consistent with the expression of the endogenous gene. The compact cluster of conserved regulatory elements in SCN8A provides a useful target for molecular analysis of neuronal gene expression.

Multiple transcripts of sodium channel SCN8A (Na(V)1.6) with alternative 5'- and 3'-untranslated regions and initial characterization of the SCN8A promoter.

To identify the transcriptional start sites of the neuronal channel SCN8A, we carried out 5'-RACE (rapid amplification of cDNA ends) with RNA from human and mouse brain. We recovered four mutually exclusive 5'-untranslated exons (exon 1a to exon 1d) that map to a 1.8-kb region of genomic DNA located approximately 70 kb upstream of the first coding exon. The same 5'-untranslated exons are expressed in central, peripheral and sympathetic nervous system and in embryonic and adult brain. A 4.8-kb genomic fragment containing these 5' exons demonstrated promoter activity in transfected MN-1 cells. In transgenic mice, transcription of the 4.8-kb promoter was restricted to brain and spinal cord. The 4.8-kb promoter contains eight consensus Sp1-binding sites and two Inr sites. A potential NRSE/RE-1 site is located nearby. Two active polyadenylation sites identified by 3'-RACE are conserved in human, mouse, and chicken SCN8A. Sequence comparison of human and mouse SCN8A identified 12 conserved noncoding elements whose effect on transcription was tested in transfected cells.