ADAR1- and ADAR2-mediated regulation of maturation and targeting of miR-376b to modulate GABA neurotransmitter catabolism.

miRNAs are short noncoding RNA molecules that regulate gene expression by inhibiting translation or inducing degradation of target mRNAs. miRNAs are often expressed as polycistronic transcripts, so-called miRNA clusters, containing several miRNA precursors. The largest mammalian miRNA cluster, the miR-379-410 cluster, is expressed primarily during embryonic development and in the adult brain; however, downstream regulation of this cluster is not well understood. Here, we investigated adenosine deamination to inosine (RNA editing) in the miR-379-410 cluster by adenosine deaminase acting on RNA (ADAR) enzymes as a possible mechanism modulating the expression and activity of these miRNAs in a brain-specific manner. We show that the levels of editing in the majority of mature miRNAs are lower than the editing levels of the corresponding site in primary miRNA precursors. However, for one miRNA, miR-376b-3p, editing was significantly higher in the mature form than in the primary precursor. We found miR-376b-3p maturation is negatively regulated by ADAR2 in an editing activity-independent manner, whereas ADAR1-mediated and ADAR2-mediated editing were observed to be competitive. In addition, the edited miR-376b-3p targets a different set of mRNAs than unedited miR-376b-3p, including 4-aminobutyrate aminotransferase, encoding the enzyme responsible for the catabolism of the neurotransmitter gamma aminobutyric acid (GABA). Expression of edited miR-376b-3p led to increased intracellular GABA levels as well as increased cell surface presentation of GABA type A receptors. Our results indicate that both editing and editing-independent effects modulate the expression of miR-376b-3p, with the potential to regulate GABAergic signaling in the brain.

Altered p53 and NOX1 activity cause bioenergetic defects in a SCA7 polyglutamine disease model.

Spinocerebellar ataxia type 7 (SCA7) is one of the nine neurodegenerative disorders caused by expanded polyglutamine (polyQ) domains. Common pathogenic mechanisms, including bioenergetics defects, have been suggested for these so called polyQ diseases. However, the exact molecular mechanism(s) behind the metabolic dysfunction is still unclear. In this study we identified a previously unreported mechanism, involving disruption of p53 and NADPH oxidase 1 (NOX1) activity, by which the expanded SCA7 disease protein ATXN7 causes metabolic dysregulation. The NOX1 protein is known to promote glycolytic activity, whereas the transcription factor p53 inhibits this process and instead promotes mitochondrial respiration. In a stable inducible PC12 model of SCA7, p53 and mutant ATXN7 co-aggregated and the transcriptional activity of p53 was reduced, resulting in a 50% decrease of key p53 target proteins, like AIF and TIGAR. In contrast, the expression of NOX1 was increased approximately 2 times in SCA7 cells. Together these alterations resulted in a decreased respiratory capacity, an increased reliance on glycolysis for energy production and a subsequent 20% reduction of ATP in SCA7 cells. Restoring p53 function, or suppressing NOX1 activity, both reversed the metabolic dysfunction and ameliorated mutant ATXN7 toxicity. These results hence not only enhance the understanding of the mechanisms causing metabolic dysfunction in SCA7 disease, but also identify NOX1 as a novel potential therapeutic target in SCA7 and possibly other polyQ diseases.