Modeling and gene knockdown to assess the contribution of nonsense-mediated decay, premature termination, and selenocysteine insertion to the selenoprotein hierarchy.

Anze Zupanic,Catherine Meplan,Daryl P Shanley,John E Hesketh,Grazielle V.B Huguenin

doi:10.1261/rna.055749.115

Anze Zupanic, Catherine Meplan + Show 3 more

Open Access

https://doi.org/10.1261/rna.055749.115

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Abstract

The expression of selenoproteins, a specific group of proteins that incorporates selenocysteine, is hierarchically regulated by the availability of Se, with some, but not all selenoprotein mRNA transcripts decreasing in abundance with decreasing Se. Selenocysteine insertion into the peptide chain occurs during translation following recoding of an internal UGA stop codon. There is increasing evidence that this UGA recoding competes with premature translation termination, which is followed by nonsense-mediated decay (NMD) of the transcript. In this study, we tested the hypothesis that the susceptibility of different selenoprotein mRNAs to premature termination during translation and differential sensitivity of selenoprotein transcripts to NMD are major factors in the selenoprotein hierarchy. Selenoprotein transcript abundance was measured in Caco-2 cells using real-time PCR under different Se conditions and the data obtained fitted to mathematical models of selenoprotein translation. A calibrated model that included a combination of differential sensitivity of selenoprotein transcripts to NMD and different frequency of non-NMD related premature translation termination was able to fit all the measurements. The model predictions were tested using SiRNA to knock down expression of the crucial NMD factor UPF1 (up-frameshift protein 1) and selenoprotein mRNA expression. The calibrated model was able to predict the effect of UPF1 knockdown on gene expression for all tested selenoproteins, except SPS2 (selenophosphate synthetase), which itself is essential for selenoprotein synthesis. These results indicate an important role for NMD in the hierarchical regulation of selenoprotein mRNAs, with the exception of SPS2 whose expression is likely regulated by a different mechanism.

Highlights

The micronutrient selenium (Se) is essential for health (Rayman 2012) and its biological functions are brought about through selenoproteins, a specific group of proteins that incorporate selenocysteine, the 21st amino acid (Labunskyy et al 2014)
We show that a single model, which includes competition among selenocysteine insertion, premature termination, and nonsense-mediated decay (NMD), and deadenylation-dependent mRNA turnover can explain the observed variations in mRNA levels for all selenoprotein mRNAs studied with the exception of SPS2, which is likely regulated by a different mechanism
To investigate the effects of Se status on selenoprotein mRNA levels in Caco-2 cells, RNA was extracted from cells grown either in media deficient in Se (NoSe) or in media supplemented with different concentrations of sodium selenite, ranging from 5 nM to 40 nM

Summary

Introduction

The micronutrient selenium (Se) is essential for health (Rayman 2012) and its biological functions are brought about through selenoproteins, a specific group of proteins that incorporate selenocysteine, the 21st amino acid (Labunskyy et al 2014). A currently accepted mechanism/hypothesis proposes that only transcripts featuring a PTC of at least 50–55 nucleotides (nt) upstream of an exon junction are vulnerable to NMD (Popp and Maquat 2013). On this basis, SELK should not be a target of NMD, while TXNRD2 should be. It has been suggested that other factors, such as differential regulation of selenoprotein expression by EIF4A3 (Budiman et al 2009) or dependence of selenocysteine insertion on two different Sec-tRNA isoforms (Jameson and Diamond 2004), could explain the apparent resistance of GPX4 to NMD under low Se; neither of these two mechanisms can explain the observed increased abundance of GPX2 mRNA

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