Project description:mRNA translation decodes nucleotide into amino acid sequences. However, translation has also been shown to affect mRNA stability depending on codon composition in model organisms, although universality of this mechanism remains unclear. Here, using three independent approaches to measure exogenous and endogenous mRNA decay, we define which codons are associated with stable or unstable mRNAs in human cells. We demonstrate that the regulatory information affecting mRNA stability is encoded in codons and not in nucleotides. Stabilizing codons tend to be associated with higher tRNA levels and higher charged/total tRNA ratios. While mRNAs enriched in destabilizing codons tend to possess shorter poly(A)-tails, the poly(A)-tail is not required for the codon-mediated mRNA stability. This mechanism depends on translation; however, the number of ribosome loads into a mRNA modulates the codon-mediated effects on gene expression. This work provides definitive evidence that translation strongly affects mRNA stability in a codon-dependent manner in human cells. 293T cells and k562 cells were infected with ORFome library to decay exodogenous gene mRNA decay. Stable infected cells were treated with actinmycin D at 6 well plate and samples were collected in duplicate every hour 0-6h for RNA-seq

Project description:mRNA endogenous decay profiles approach in 293T, HeLa and RPE cells. mRNA translation decodes nucleotide into amino acid sequences. However, translation has also been shown to affect mRNA stability depending on codon composition in model organisms, although universality of this mechanism remains unclear. Here, using three independent approaches to measure exogenous and endogenous mRNA decay, we define which codons are associated with stable or unstable mRNAs in human cells. We demonstrate that the regulatory information affecting mRNA stability is encoded in codons and not in nucleotides. Stabilizing codons tend to be associated with higher tRNA levels and higher charged/total tRNA ratios. While mRNAs enriched in destabilizing codons tend to possess shorter poly(A)-tails, the poly(A)-tail is not required for the codon-mediated mRNA stability. This mechanism depends on translation; however, the number of ribosome loads into a mRNA modulates the codon-mediated effects on gene expression. This work provides definitive evidence that translation strongly affects mRNA stability in a codon-dependent manner in human cells.

Project description:mRNA translation decodes nucleotide into amino acid sequences. However, translation has also been shown to affect mRNA stability depending on codon composition in model organisms, although universality of this mechanism remains unclear. Here, using three independent approaches to measure exogenous and endogenous mRNA decay, we define which codons are associated with stable or unstable mRNAs in human cells. We demonstrate that the regulatory information affecting mRNA stability is encoded in codons and not in nucleotides. Stabilizing codons tend to be associated with higher tRNA levels and higher charged/total tRNA ratios. While mRNAs enriched in destabilizing codons tend to possess shorter poly(A)-tails, the poly(A)-tail is not required for the codon-mediated mRNA stability. This mechanism depends on translation; however, the number of ribosome loads into a mRNA modulates the codon-mediated effects on gene expression. This work provides definitive evidence that translation strongly affects mRNA stability in a codon-dependent manner in human cells.

Project description:The control of mRNA stability plays a central role in regulating gene expression patterns. While much is known about the roles of 5´ and 3´ untranslated regions in the mRNA stability control, the impact of protein-coding sequences on mRNA stability had been obscure. Recently, several groups reported that codon composition in the ORF affects mRNA deadenylation and degradation rates in a translation-dependent manner. Hence, codons define not only the amino acid sequences to be synthesized but also the stability of mRNAs. However, how 61 codons differently affect mRNA stability remains unclear. Besides, aberrant stalling of the ribosome induces ribosome quality control (RQC) and No-go decay. The relationship between the two co-translational mRNA decay pathways is not systematically analyzed. To precisely characterize the effects of 61 codons on mRNA stability, we developed a simplified reporter system that allows detection of the effect of every single codon on mRNA stability in zebrafish embryos. Using this system, we show that the effect of codons on mRNA stability is partially but significantly correlated with the translation elongation rate and tRNA abundance. Interestingly, the codon effect is still maintained in zebrafish embryos lacking Znf598, an essential mediator of RQC and NGD. Znf598-dependent NGD targets a particular type of ribosome stalling but has limited impact on endogenous mRNA stability. Our study thus defines two related co-translational mRNA decay pathways during animal development.

Project description:Amino acid misincorporation promotes mRNA instability

Project description:mRNA degradation is a critical aspect of gene expression which dictates mRNA steady-state levels in conjunction with transcription rate. Previous studies in other model organisms have demonstrated that enrichment of specific codons within the open reading frame (ORF) can influence mRNA stability, primarily by modulating translation elongation speed. Despite advancements in our understanding of mRNA stability regulation by microRNAs and 3'UTR-based factors in mammalian systems, the importance of other mRNA regions such as the ORF sequence on dictating cellular mRNA levels are incompletely understood. To characterize the effects of the coding sequence on mRNA decay in mammals, we analyzed mRNA stability in human and Chinese Hamster Ovary (Cricetulus griseus) cells by both global metabolic labeling and single-gene mRNA reporter transcription shutoffs. In agreement with previous studies, we observed that synonymous codon usage impacts mRNA stability in mammalian cells. Unexpectedly, we also found that amino acid content is a potent determinant of mRNA stability in humans and other mammalian species. Codon and amino acid effects on decay correlate with tRNA levels measured by tRNA-Seq or intracellular amino acid levels measured by HPLC, respectively. These results suggest that both tRNA and amino acid levels have complementary effects on regulation of mRNA stability in mammals, hinting at the possibility of dynamic control of mRNA levels via altered tRNA or amino acid levels.

Project description:In neurodegenerative diseases, including pathologies with well-known causative alleles, genetic factors that modify severity or age of onset are not entirely understood. We recently documented the unexpected prevalence of transfer RNA (tRNA) mutants in the human population, including variants that cause amino acid mis-incorporation. We hypothesized that a mistranslating tRNA will exacerbate toxicity and modify the molecular pathology of disease-causing alleles and investigated the combinatorial effects of tRNA variants in cellular models of Huntington’s disease. This dataset represents MS/MS data confirming Phenylaline to Serine amino acid misincorporation events caused by the tRNA-Ser G35A variant described in our study. The wildtype (WT) or mistranslating tRNA (VAR) were expressed in murine N2a cells along with mCherry protein. We affinity purified the mCherry protein to search for Ser misincorporation events at Phe codons.

Project description:To investigate the potential influence of transcription on mRNA stability in mammalian cells, we tested  the global relationship between rates of synthesis and decay of mRNAs. We estimated synthesis rates by flash 4sU labeling followed by RNA-seq, and decay rates by treating cells with Actinomycin D (ActD) for 0, 2, 4 and 6 hours and measuring half-lives of all expressed genes by MARS-seq analysis. As short-term perturbations of transcription elongation dynamics diminished mRNA stability, we next wished to examine the effect of extended transcription slowdown. To this end, we treated cells with CPT for 24 hours and profiled mRNA stability in a genome-wide manner using ActD time-course and MARS-seq.

Project description:In this work, we determine andenylated and total mRNA decay rates and correlate them with codon optimality. We conclude that optimality is a major contributor to mRNA stability in budding yeast.

Project description:We utilized oligonucleotide microarrays to measure cellular mRNA decay rates in mock- or reovirus-infected murine L929 cells to determine if changes in host mRNA expression are a consequence of reovirus-induced alterations in cellular mRNA stability.