Litcius/Paper detail

CFIm-mediated alternative polyadenylation remodels cellular signaling and miRNA biogenesis

Souvik Ghosh, Meriç Ataman, Maciej Bąk, Anastasiya Börsch, Alexander Schmidt, Katarzyna Buczak, Georges Martín, Beatrice Dimitriades, Christina Herrmann, Alexander Kanitz, Mihaela Zavolan

2022Nucleic Acids Research34 citationsDOIOpen Access PDF

Abstract

The mammalian cleavage factor I (CFIm) has been implicated in alternative polyadenylation (APA) in a broad range of contexts, from cancers to learning deficits and parasite infections. To determine how the CFIm expression levels are translated into these diverse phenotypes, we carried out a multi-omics analysis of cell lines in which the CFIm25 (NUDT21) or CFIm68 (CPSF6) subunits were either repressed by siRNA-mediated knockdown or over-expressed from stably integrated constructs. We established that >800 genes undergo coherent APA in response to changes in CFIm levels, and they cluster in distinct functional classes related to protein metabolism. The activity of the ERK pathway traces the CFIm concentration, and explains some of the fluctuations in cell growth and metabolism that are observed upon CFIm perturbations. Furthermore, multiple transcripts encoding proteins from the miRNA pathway are targets of CFIm-dependent APA. This leads to an increased biogenesis and repressive activity of miRNAs at the same time as some 3' UTRs become shorter and presumably less sensitive to miRNA-mediated repression. Our study provides a first systematic assessment of a core set of APA targets that respond coherently to changes in CFIm protein subunit levels (CFIm25/CFIm68). We describe the elicited signaling pathways downstream of CFIm, which improve our understanding of the key role of CFIm in integrating RNA processing with other cellular activities.

Topics & Concepts

BiologyPolyadenylationBiogenesismicroRNAGene knockdownCell biologyPsychological repressionRNA interferencePhenotypeSignal transductionRNAGeneticsComputational biologyGene expressionGeneRNA Research and SplicingRNA modifications and cancerCancer-related gene regulation