Ankyrin-G isoform imbalance and interneuronopathy link epilepsy and bipolar disorder.

Abstract

ANK3, encoding the adaptor protein Ankyrin-G, has been implicated in bipolar disorder by genome wide association studies. ANK3 has multiple alternative first exons, and a bipolar disorder-associated ANK3 variant has been shown to reduce expression of exon 1b. Here we identify mechanisms through which reduced ANK3 exon 1b isoform expression disrupts neuronal excitation-inhibition balance. We find that parvalbumin interneurons and principal cells differentially express ANK3 first exon subtypes. Parvalbumin interneurons express only isoforms containing exon 1b, whereas excitatory principal cells express exon 1e alone, or both 1e and 1b. In transgenic mice deficient for exon 1b, parvalbumin interneurons lack voltage-gated sodium channels at their axonal initial segments and have increased firing thresholds and diminished action potential dynamic range. These mice exhibit an Ank3 gene dosage-dependent phenotype including behavior changes modeling bipolar disorder, epilepsy, and sudden death. Thus, ANK3’s important association with human bipolar susceptibility may arise from imbalance between ankyrin-G function in interneurons and principal cells and resultant excessive circuit sensitivity and output. Ankyrin-G isoform imbalance is a novel molecular endophenotype and potential therapeutic target.