Project description:Limitation for amino acids is thought to regulate translation in mammalian cells primarily by signaling through the kinases mTORC1 and GCN2. We find that limitation for the amino acid arginine causes a selective loss of tRNA charging, which regulates translation through ribosome pausing at two of six arginine codons. Interestingly, limitation for leucine, an essential and abundant amino acid in protein, results in little or no ribosome pausing. Chemical and genetic perturbation of mTORC1 and GCN2 signaling revealed that their robust response to leucine limitation prevents ribosome pausing, while an insufficient response to arginine limitation led to loss of arginine tRNA charging and ribosome pausing. Codon-specific ribosome pausing decreased protein production and triggered premature ribosome termination without significantly reducing mRNA levels. Together, our results suggest that amino acids which are not optimally sensed by the mTORC1 and GCN2 pathways still regulate translation through an evolutionarily conserved mechanism based on synonymous codon usage.

Project description:Messenger RNA (mRNA) translation can lead to higher rates of mRNA decay, suggesting a role for the ribosome in mRNA destruction. Furthermore, features of an mRNA, such as codon identities, that are directly probed by the ribosome also correlate with mRNA decay rates. Specifically, many amino acids are encoded by synonymous codons, and some synonymous codons are decoded by more abundant tRNAs leading to more optimal translation and increased mRNA stability. In addition to different translation rates, the presence of individual codons can lead to higher or lower rates of amino acid misincorporation which could potentially lead to protein misfolding if an individual amino acid makes many critical contacts in a structure. Here, we directly test whether amino acid misincorporation affects mRNA stability, taking advantage of an aminoglycoside antibiotic (G418) which promotes higher error rates in the ribosome. We observe that G418 decreases firefly luciferase mRNA stability in an in vitro system, and we similarly observe that G418 reduces mRNA stability in mouse embryonic stem cells (mESCs). G418-sensitive mRNAs are enriched for suboptimal hydrophobic amino acid codons as well as other codons that are known to result in higher rates of amino acid misincorporation. Since protein folding is highly sensitive to the identity of hydrophobic amino acids, these results strongly suggest that defects in protein folding are linked to mRNA decay.

Project description:Amino acid availability regulates translation through the action of the GCN2 and mTORC1 pathways. Low amino acids activate the eIF2α kinase GCN2 through binding of uncharged tRNAs to a histidyl-tRNA synthetase−related regulatory domain. Once activated GCN2 phosphorylates eIF2α, inhibiting ternary complex formation and translation initiation. Recent studies show that mTORC1 is particularly sensitive to arginine and leucine status, with a deprivation of these amino acids leading to a strong inhibition of mTORC1 that prevents the phosphorylation and inactivation of the translational repressor 4EBP1. Though amino acids are known regulators of translation, the effects that deficiencies of specific amino acids have on translation have yet to be determined. We demonstrate that deprivation of leucine or methionine results in large inhibitory effects on translation initiation and on polysome formation that are not replicated by overexpressing non-phosphorylatable 4EBP1 or a phosphomimetic eIF2α. Our results demonstrate that a lack of either leucine or methionine has a major impact on mRNA translation, though they act by quite different mechanisms. Leucine deprivation appears to primarily inhibit ribosome loading, whereas methionine deprivation appears to primarily impair start site recognition. These data point to a unique regulatory effect that methionine status has on translation initiation.

Project description:GCN2 (General Control Nonderepressible 2) is a serine/threonine-protein kinase that controls mRNA translation in response to amino acid availability. Here we show that production and clearance of erythrocytes are controlled by GCN2. Our data highlight the importance of tissue-resident macrophages as the primary cell type mediating this effect. During different stress conditions, such as hemolysis, amino acid deficiency or hypoxia, GCN2 knockout (GCN2-/-) mice displayed resistance to anemia as compared to wild-type (GCN2+/+) mice. GCN2-/- liver macrophages display defective erythrophagocytosis and lysosome maturation. Molecular analysis of GCN2-/- cells indicates that the ATF4-NRF2 pathway is a critical downstream mediator of GCN2 in regulating RBC clearance and iron recycling. We performed NRF2 (Nfe2l2) ChIP-seq experiments in both WT and GCN2 KO MEFs with or without leucine deprivation.

Project description:Many tumors escape by activating multiple cellular pathways that induce immunosuppression. One pivotal immune-suppressive mechanism is the production of tryptophan metabolites along the kynurenine pathway by IFNγ-induced IDO1 enzyme production 4-8. Phase III clinical trials using chemical inhibition of IDO1 in combination with PD1 pathway blockade, however, failed to improve melanoma treatment 9-12. This points at an incomplete understanding of the role of IDO1 and the consequent tryptophan degradation on mRNA translation and cancer progression. Here, we investigated the effects of prolonged IFNγ treatment on mRNA translation in melanoma cells by ribosome profiling. Surprisingly, we observed a massive accumulation of ribosomes ~20 amino acids downstream of tryptophan codons (termed here as W-Bumps) along with their expected stalling at the tryptophan codon itself. This indicated ribosomal bypass of the tryptophan codons in the absence of tryptophan. Detailed examination of W-Bumps position and its corresponding peptide sequences pinpointed towards ribosomal frameshifting events and their effects in the ribosome exit tunnel. In particular, W-Bumps strength was associated with the disorderedness level of potential out-of-frame peptides predicted downstream of tryptophan codons. Indeed, reporter assays demonstrated the induction of ribosomal frameshifting, and the generation of trans-frame proteins and their presentation at the cell surface after IFNγ treatment. Proteomics and immunopeptidomics analyses verified the production of IFNγ-induced trans-frame and out-of-frame aberrant peptides and their presentation on HLA class I molecules. Priming of naïve T cells from healthy donors with aberrant peptides resulted in identification of reactive, peptide-specific T cells. Altogether, our results suggest that IFNγ-induced IDO1-mediated tryptophan depletion plays a role in the immune recognition of melanoma cells by contributing to the diversity of the peptidome landscape, and by inducing the presentation of aberrant peptides.

Project description:Chemotherapeutic agents and leucine deprivation induce codon-biased aberrant protein production in cancer

Project description:Protein synthesis is metabolically costly, and the level of translation must match nutrient availability and cellular needs. Overall protein synthesis levels are modulated by regulating translation initiation. The cap-binding protein eIF4E—the earliest contact between mRNAs and the translation machinery—serves as one point of control, but its contributions to mRNA-specific translation regulation remain poorly understood. We acutely depleted eIF4E, which is essential in budding yeast, and observed surprisingly modest effects on cell growth and protein synthesis. Long-lived transcripts were downregulated, likely reflecting accelerated turnover, and the strongest gene-specific effects arose as secondary effects of reduced protein biosynthesis on amino acid pools. Futile cycles of amino acid synthesis and degradation were accompanied by translational activation of GCN4, which is typically induced by amino acid starvation. We further identified translational tuning of PCL5, a negative regulator of Gcn4, that provides a consistent protein-to-mRNA ratio under varying translation environments. This translational control depended in part on a uniquely long poly-(A) tract in the PCL5 5’ UTR and on poly-(A) binding protein. These results highlight the intricate interplay between translation, amino acid homeostasis, and gene regulation and uncover new layers of feedback control in cellular response to stress and nutrient availability.

Project description:Protein synthesis is metabolically costly, and the level of translation must match nutrient availability and cellular needs. Overall protein synthesis levels are modulated by regulating translation initiation. The cap-binding protein eIF4E—the earliest contact between mRNAs and the translation machinery—serves as one point of control, but its contributions to mRNA-specific translation regulation remain poorly understood. We acutely depleted eIF4E, which is essential in budding yeast, and observed surprisingly modest effects on cell growth and protein synthesis. Long-lived transcripts were downregulated, likely reflecting accelerated turnover, and the strongest gene-specific effects arose as secondary effects of reduced protein biosynthesis on amino acid pools. Futile cycles of amino acid synthesis and degradation were accompanied by translational activation of GCN4, which is typically induced by amino acid starvation. We further identified translational tuning of PCL5, a negative regulator of Gcn4, that provides a consistent protein-to-mRNA ratio under varying translation environments. This translational control depended in part on a uniquely long poly-(A) tract in the PCL5 5’ UTR and on poly-(A) binding protein. These results highlight the intricate interplay between translation, amino acid homeostasis, and gene regulation and uncover new layers of feedback control in cellular response to stress and nutrient availability.

Project description:Protein synthesis is metabolically costly, and the level of translation must match nutrient availability and cellular needs. Overall protein synthesis levels are modulated by regulating translation initiation. The cap-binding protein eIF4E—the earliest contact between mRNAs and the translation machinery—serves as one point of control, but its contributions to mRNA-specific translation regulation remain poorly understood. We acutely depleted eIF4E, which is essential in budding yeast, and observed surprisingly modest effects on cell growth and protein synthesis. Long-lived transcripts were downregulated, likely reflecting accelerated turnover, and the strongest gene-specific effects arose as secondary effects of reduced protein biosynthesis on amino acid pools. Futile cycles of amino acid synthesis and degradation were accompanied by translational activation of GCN4, which is typically induced by amino acid starvation. We further identified translational tuning of PCL5, a negative regulator of Gcn4, that provides a consistent protein-to-mRNA ratio under varying translation environments. This translational control depended in part on a uniquely long poly-(A) tract in the PCL5 5’ UTR and on poly-(A) binding protein. These results highlight the intricate interplay between translation, amino acid homeostasis, and gene regulation and uncover new layers of feedback control in cellular response to stress and nutrient availability.

Project description:Removing cellular transfer RNAs (tRNAs), making their cognate codons unreadable, creates a genetic firewall that prevents viral replication and horizontal gene transfer. However, numerous viruses and mobile genetic elements encode parts of the translational apparatus, including tRNAs, potentially rendering a genetic-code-based firewall ineffective. In this paper, we show that such horizontally transferred tRNA genes can enable viral replication in Escherichia coli cells despite the genome-wide lack of three codons and the previously essential cognate tRNAs and release factor 1. By repurposing viral tRNAs, we then develop recoded cells bearing an amino-acid-swapped genetic code that reassigns two of the six serine codons to leucine during translation. This amino-acid-swapped genetic code renders cells completely resistant to viral infections by mistranslating viral proteomes and prevents the escape of synthetic genetic information by engineered reliance on serine codons to produce leucine-requiring proteins. Finally, we also repurpose the third free codon to biocontain this virus-resistant host via dependence on an amino acid not found in nature.