Abstract
Select proteins involved in electrical and chemical neurotransmission are re-coded at the RNA level via the deamination of particular adenosines to inosine by adenosine deaminases acting on RNA (ADARs). It has been hypothesized that this process, termed RNA editing, acts to "fine-tune" neurophysiological properties in animals and potentially downstream behavioral outputs. However, the extreme phenotypes resulting from deletions of adar loci have precluded investigations into the relationship between ADAR levels, target transcripts, and complex behaviors. Here, we engineer Drosophila hypomorphic for ADAR expression using homologous recombination. A substantial reduction in ADAR activity (>80%) leads to altered circadian motor patterns and abnormal male courtship, although surprisingly, general locomotor coordination is spared. The altered phenotypic landscape in our adar hypomorph is paralleled by an unexpected dichotomous response of ADAR target transcripts, i.e. certain adenosines are minimally affected by dramatic ADAR reduction, whereas editing of others is severely curtailed. Furthermore, we use a novel reporter to map RNA editing activity across the nervous system, and we demonstrate that knockdown of editing in fruitless-expressing neurons is sufficient to modify the male courtship song. Our data demonstrate that network-wide temporal and spatial regulation of ADAR activity can tune the complex system of RNA-editing sites and modulate multiple ethologically relevant behavioral modalities.
Highlights
Informational recoding of RNA by the catalytic deamination of adenosine to inosine proceeds through the action of ADARs3 [1]
Previous studies have focused on the relationship between dADAR activity and motor control, it is unclear whether complex behaviors require regulated editing and, if so, whether subpopulations of edited proteins contribute to distinct behavioral outputs
During homologous recombination, screening for recombinant flies is facilitated by the insertion of an ϳ5-kb whiteϩ mini-gene eye color selection cassette within an intron of the Drosophila adar locus (dAdar) locus, subsequently removed via a Cre-recombinase step [17, 18]
Summary
Previous studies have focused on the relationship between dADAR activity and motor control, it is unclear whether complex behaviors require regulated editing and, if so, whether subpopulations of edited proteins contribute to distinct behavioral outputs. We investigate these issues using homologous recombination and a molecular reporter for RNA editing activity. Through the generation of a novel hypomorphic dAdar allele, we demonstrate an unexpectedly complex relationship between in vivo dADAR levels and deamination of specific RNA editing targets These data, combined with neuron-specific dADAR knockdown, demonstrate that correct regulation of editing activity at both cell-autonomous and network levels is required for behavioral outputs in Drosophila and provide. RNA Editing Affects Complex Behavior in Drosophila mechanistic insight into the complex landscape of proteomic diversity generated by RNA editing
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