Cryptic prokaryotic promoters explain instability of recombinant neuronal sodium channels in bacteria

Mutations in genes encoding the human-brain-expressed voltage-gated sodium (Na(V)) channels Na(V)1.1, Na(V)1.2, and Na(V)1.6 are associated with a variety of human diseases including epilepsy, autism spectrum disorder, familial migraine, and other neurodevelopmental disorders. A major obstacle hindering investigations of the functional consequences of brain Na(V) channel mutations is an unexplained instability of the corresponding recombinant complementary DNA (cDNA) when propagated in commonly used bacterial strains manifested by high spontaneous rates of mutation. Here, using a combination of in silico analysis, random and site-directed mutagenesis, we investigated the cause for instability of human Na(V)1.1 cDNA. We identified nucleotide sequences within the Na(V)1.1 coding region that resemble prokaryotic promoter-like elements, which are presumed to drive transcription of translationally toxic mRNAs in bacteria as the cause of the instability. We further demonstrated that mutations disrupting these elements mitigate the instability. Extending these observations, we generated full-length human Na(V)1.1, Na(V)1.2, and Na(V)1.6 plasmids using one or two introns that interrupt the latent reading frames along with a minimum number of silent nucleotide changes that achieved stable propagation in bacteria. Expression of the stabilized sequences in cultured mammalian cells resulted in functional Na(V) channels with properties that matched their parental constructs. Our findings explain a widely observed instability of recombinant neuronal human Na(V) channels, and we describe re-engineered plasmids that attenuate this problem.