Litcius/Paper detail

Differential adaptive RNA editing signals between insects and plants revealed by a new measurement termed haplotype diversity

Yuange Duan, Ye Xu, Fan Song, Li Tian, Wanzhi Cai, Hu Li

2023Biology Direct28 citationsDOIOpen Access PDF

Abstract

BACKGROUND: C-to-U RNA editing in plants is believed to confer its evolutionary adaptiveness by reversing unfavorable DNA mutations. This "restorative hypothesis" has not yet been tested genome-wide. In contrast, A-to-I RNA editing in insects like Drosophila and honeybee is already known to benefit the host by increasing proteomic diversity in a spatial-temporal manner (namely "diversifying hypothesis"). METHODS: We profiled the RNA editomes of multiple tissues of Arabidopsis thaliana, Drosophila melanogaster, and Apis melifera. We unprecedentedly defined the haplotype diversity (HD) of RNA molecules based on nonsynonymous editing events (recoding sites). RESULTS: Signals of adaptation is confirmed in Arabidopsis by observing higher frequencies and levels at nonsynonymous editing sites over synonymous sites. Compared to A-to-I recoding sites in Drosophila, the C-to-U recoding sites in Arabidopsis show significantly lower HD, presumably due to the stronger linkage between C-to-U events. CONCLUSIONS: C-to-U RNA editing in Arabidopsis is adaptive but it is not designed for diversifying the proteome like A-to-I editing in Drosophila. Instead, C-to-U recoding sites resemble DNA mutations. Our observation supports the restorative hypothesis of plant C-to-U editing which claims that editing is used for fixing unfavorable genomic sequences.

Topics & Concepts

BiologyArabidopsisRNA editingDrosophila melanogasterNonsynonymous substitutionRNAGeneticsAdaptation (eye)Drosophila (subgenus)Arabidopsis thalianaComputational biologyEvolutionary biologyGenomeGeneMutantNeuroscienceRNA regulation and diseasePhotosynthetic Processes and MechanismsCRISPR and Genetic Engineering