A Study of RNA-editing in Nuclei Revealed Acquisition of RNA-editing on the Endosymbiont-derived Genes, and a Preference for Intracellular Remodeling Genes in Adaptation to Endosymbiosis

Overview

Journal For Res (Fayettev)

Date 2024 Nov 11

PMID 39524518

Authors

Yiran Wang

Lihu Wang

Su Chen

Song Chen

Affiliations

Soon will be listed here.

Abstract

RNA-editing is a post-transcriptional modification that can diversify genome-encoded information by modifying individual RNA bases. In contrast to the well-studied RNA-editing in organelles, little is known about nuclear RNA-editing in higher plants. We performed a genome-wide study of RNA-editing in nuclei using the RNA-seq data generated from the sequenced poplar genotype, 'Nisqually-1'. A total of 24,653 nuclear RNA-editing sites present in 8,603 transcripts were identified. Notably, RNA-editing in nuclei tended to occur on endosymbiont-derived genes. We then scrutinized RNA-editing in a cyanobacterial strain closely related to chloroplast. No RNA-editing sites were identified therein, implying that RNA-editing of these endosymbiont-derived genes was acquired after endosymbiosis. Gene ontology enrichment analysis of all the edited genes in nuclei demonstrated that nuclear RNA-editing was primarily focused on genes involved in intracellular remodeling processes, which suggests that RNA-editing plays contributing roles in organellar establishment during endosymbiosis. We built a coexpression network using all C-to-U edited genes and then decomposed it to obtain 18 clusters, six of which contained a conserved core motif, A/G-C-A/G. Such a short core motif not only attracted the RNA-editing machinery but also enabled large numbers of sites to be targeted though further study is necessary to verify this finding.

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