Splicing-accessible coding 3′UTRs control protein stability and interaction networks

Background 3′-Untranslated regions (3′UTRs) play crucial roles in mRNA metabolism, such as by controlling mRNA stability, translation efficiency, and localization. Intriguingly, in some genes the 3′UTR is longer than their coding regions, pointing to additional, unknown functions. Here, we describe...

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Published in:Genome Biology 2020-07, Vol.21 (1), p.1-24, Article 186
Main Authors: Preussner, Marco, Gao, Qingsong, Morrison, Eliot, Herdt, Olga, Finkernagel, Florian, Schumann, Michael, Krause, Eberhard, Freund, Christian, Chen, Wei, Heyd, Florian
Format: Article
Language:English
Subjects:
3' Untranslated regions
3′UTR
Alternative open reading frame
Alternative splicing
Amino acids
Annotations
Exons
Gene expression
Genomes
Localization
Mammals
mRNA stability
Peptides
Proline
Protein disorder
Protein expression
Protein interaction
Protein stability
Protein-protein interaction
Proteins
Proteomes
Reading
Retinitis
Retinitis pigmentosa
Translation
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Summary:Background 3′-Untranslated regions (3′UTRs) play crucial roles in mRNA metabolism, such as by controlling mRNA stability, translation efficiency, and localization. Intriguingly, in some genes the 3′UTR is longer than their coding regions, pointing to additional, unknown functions. Here, we describe a protein-coding function of 3′UTRs upon frameshift-inducing alternative splicing in more than 10% of human and mouse protein-coding genes. Results 3′UTR-encoded amino acid sequences show an enrichment of PxxP motifs and lead to interactome rewiring. Furthermore, an elevated proline content increases protein disorder and reduces protein stability, thus allowing splicing-controlled regulation of protein half-life. This could also act as a surveillance mechanism for erroneous skipping of penultimate exons resulting in transcripts that escape nonsense mediated decay. The impact of frameshift-inducing alternative splicing on disease development is emphasized by a retinitis pigmentosa-causing mutation leading to translation of a 3′UTR-encoded, proline-rich, destabilized frameshift-protein with altered protein-protein interactions. Conclusions We describe a widespread, evolutionarily conserved mechanism that enriches the mammalian proteome, controls protein expression and protein-protein interactions, and has important implications for the discovery of novel, potentially disease-relevant protein variants.
ISSN:1474-760X
1474-7596
1474-760X
DOI:10.1186/s13059-020-02102-3