High-Resolution Ribosome Profiling Reveals Gene-Specific Details of UGA Re-Coding in Selenoprotein Biosynthesis.
Simon BohleberNoelia Fradejas-VillarWenchao ZhaoUschi ReuterUlrich SchweizerPublished in: Biomolecules (2022)
Co-translational incorporation of selenocysteine (Sec) into selenoproteins occurs at UGA codons in a process in which translational elongation competes with translational termination. Selenocysteine insertion sequence-binding protein 2 (<i>SECISBP2</i>) greatly enhances Sec incorporation into selenoproteins by interacting with the mRNA, ribosome, and elongation factor Sec (EFSEC). Ribosomal profiling allows to study the process of UGA re-coding in the physiological context of the cell and at the same time for all individual selenoproteins expressed in that cell. Using HAP1 cells expressing a mutant <i>SECISBP2</i>, we show here that high-resolution ribosomal profiling can be used to assess read-through efficiency at the UGA in all selenoproteins, including those with Sec close to the C-terminus. Analysis of ribosomes with UGA either at the A-site or the P-site revealed, in a transcript-specific manner, that <i>SECISBP2</i> helps to recruit tRNA<sup>Sec</sup> and stabilize the mRNA. We propose to assess the effect of any perturbation of UGA read-through by determining the proportion of ribosomes carrying UGA in the P-site, pUGA. An additional, new observation is frameshifting that occurred 3' of the UGA/Sec codon in <i>SELENOF</i> and <i>SELENOW</i> in <i>SECISBP2</i>-mutant HAP1 cells, a finding corroborated by reanalysis of neuron-specific <i>Secisbp2<sup>R543Q</sup></i>-mutant brains.