Programmed stop codon readthrough (SCR) is a form of genetic re-coding, in which a near-cognate tRNA base-pairs with a stop codon, leading to the translation of a C-terminally extended protein. Recent studies revealed that SCR represents an evolutionarily conserved, spatio-temporally controlled mechanism of posttranscriptional gene regulation that requires cis-regulatory elements as well as trans-acting factors. In this study, we characterized cis-regulatory elements controlling programmed SCR of the Drosophila POU3-family member drifter/ventral veins lacking (dfr/vvl). Using S2 cell-based luciferase assays, we show that stop codon identity and the +4 to + 9 nucleotide sequence are required but not sufficient for dfr SCR regulation. Phylogenetic prediction identified an mRNA stem-loop in the 3' UTR, proximal to the readthrough UAG codon. Mutational analysis revealed that the distance from the stop codon as well as stem-loop stability, but not the underlying sequence identity, critically impact dfr SCR. Similarly, the mRNA stem-loop promoted SCR in an in vivo Drosophila model. We applied this information to refine computational prediction of SCR-associated mRNA stem-loops and show that these elements effectively promote SCR of heterologous mRNAs. These findings increase our understanding of SCR and the underlying regulatory mechanisms. Stop codon readthrough is regulated both by mRNA sequence identity and mRNA structure elements.A 3' mRNA stem-loop and its thermodynamic stability determine stop codon readthrough efficiency.Computational analyses identified 3 UTR mRNA stem-loops in previously predicted SCR genes. eng
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