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Parallel evolution of a splicing program controlling neuronal excitability in flies and mammals

Antonio Torres-Méndez, Sînziana Pop, Sophie Bonnal, Isabel Almudí, Alida Avola, Ruairí J.V. Roberts, Chiara Paolantoni, Ana Alcaina‐Caro, Ane Martín Anduaga, Irmgard U. Haussmann, Violeta Morı́n, Fernando Casares, Matthias Soller, Sebastián Kadener, Jean‐Yves Roignant, Lucia L. Prieto-Godino, Manuel Irimia

2022Science Advances42 citationsDOIOpen Access PDF

Abstract

Alternative splicing increases neuronal transcriptomic complexity throughout animal phylogeny. To delve into the mechanisms controlling the assembly and evolution of this regulatory layer, we characterized the neuronal microexon program in Drosophila and compared it with that of mammals. In nonvertebrate bilaterians, this splicing program is restricted to neurons by the posttranscriptional processing of the enhancer of microexons (eMIC) domain in Srrm234 . In Drosophila , this processing is dependent on regulation by Elav/Fne. eMIC deficiency or misexpression leads to widespread neurological alterations largely emerging from impaired neuronal activity, as revealed by a combination of neuronal imaging experiments and cell type–specific rescues. These defects are associated with the genome-wide skipping of short neural exons, which are strongly enriched in ion channels. We found no overlap of eMIC-regulated exons between flies and mice, illustrating how ancient posttranscriptional programs can evolve independently in different phyla to affect distinct cellular modules while maintaining cell-type specificity.

Topics & Concepts

BiologyAlternative splicingExonRNA splicingEnhancerTranscriptomeDrosophila (subgenus)GenomeEvolutionary biologyGeneticsNeuroscienceGeneGene expressionRNARNA Research and SplicingRNA modifications and cancerRNA and protein synthesis mechanisms
Parallel evolution of a splicing program controlling neuronal excitability in flies and mammals | Litcius