Alternative polyadenylation alters protein dosage by switching between intronic and 3'UTR sites.

Alternative polyadenylation (APA) creates distinct transcripts from the same gene by cleaving the pre-mRNA at poly(A) sites that can lie within the 3' untranslated region (3'UTR), introns, or exons. Most studies focus on APA within the 3'UTR; however, here, we show that CPSF6 insufficiency alters protein levels and causes a developmental syndrome by deregulating APA throughout the transcript. In neonatal humans and zebrafish larvae, CPSF6 insufficiency shifts poly(A) site usage between the 3'UTR and internal sites in a pathway-specific manner. Genes associated with neuronal function undergo mostly intronic APA, reducing their expression, while genes associated with heart and skeletal function mostly undergo 3'UTR APA and are up-regulated. This suggests that, under healthy conditions, cells toggle between internal and 3'UTR APA to modulate protein expression.

Citation

Nicola de Prisco, Caitlin Ford, Nathan D Elrod, Winston Lee, Lauren C Tang, Kai-Lieh Huang, Ai Lin, Ping Ji, Venkata S Jonnakuti, Lia Boyle, Maximilian Cabaj, Salvatore Botta, Katrin Õunap, Karit Reinson, Monica H Wojcik, Jill A Rosenfeld, Weimin Bi, Kristian Tveten, Trine Prescott, Thorsten Gerstner, Audrey Schroeder, Chin-To Fong, Jaya K George-Abraham, Catherine A Buchanan, Andrea Hanson-Khan, Jonathan A Bernstein, Aikaterini A Nella, Wendy K Chung, Vicky Brandt, Marko Jovanovic, Kimara L Targoff, Hari Krishna Yalamanchili, Eric J Wagner, Vincenzo A Gennarino. Alternative polyadenylation alters protein dosage by switching between intronic and 3'UTR sites. Science advances. 2023 Feb 17;9(7):eade4814

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PMID: 36800428

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