Project description:Regulation of the translatome is essential during stress. However, the precise sets of translational targets regulated by the key translational stress responses –integrated stress response (ISR) and mTORC1 – remain elusive. We developed multiplexed enhanced protein dynamics (mePROD) proteomics, combining dynamic SILAC, multiplexing, and signal amplification, to enable measuring acute changes in protein synthesis. Treating cells with ISR/mTORC1-modulating stressors, we showed extensive translatome modulation and ~20% of proteins synthesized at highly reduced rates. Comparing translation-deficient sub-proteomes revealed an extensive overlap demonstrating that target specificity is achieved on protein level and not by pathway activation. Titrating inhibition of cap-dependent translation confirmed that synthesis of individual proteins is controlled by intrinsic properties responsive to global translation inhibition. This study reports a method to measure translation rates at the nascent chain level and provides insight into how the ISR and mTORC1, two key cellular pathways, regulate the translatome to guide cellular survival upon stress.

Project description:In response to starvation, cells undergo a metabolic shift to ensure their survival by shutting down protein synthesis and activating catabolic processes, including autophagy, to degrade proteins and recycle nutrients. These processes, however, do require protein synthesis. We asked how this fundamental conflict is resolved. Upon starvation, cells activate the Integrated Stress Response (ISR) and inhibit mammalian target of rapamycin complex 1 (mTORC1). The ISR inhibits protein translation through the phosphorylation of the alpha subunit of eukaryotic translation initiation factor 2 (eIF2), whereas mTORC1 inhibition induces activation of the transcription factors TFEB/TFE3. We discovered that PPP1R15A (aka GADD34), a member of the protein phosphatase 1 complex (PP1) is a direct and early target of TFEB. GADD34 recruits PP1 to dephosphorylate eIF2 and thus fine-tunes protein synthesis to enable translation of the transcriptional program induced by starvation leading to a sustained autophagic flux.

Project description:In times of cellular stress, such as during virus infections, the integrated stress response (ISR) blocks translation initiation through phosphorylation of the essential translation initiation factor eIF2. Phosphorylated eIF2 (p-eIF2) sequesters the eIF2-specific guanidine exchange factor (GEF) eIF2B, thereby preventing eIF2 recycling. Here we describe the first example of a viral ISR antagonist that inhibits the ISR at its most central step: the interplay between p-eIF2 and eIF2B. Using AP-MS, we determine that BW10 binds eIF2B. There, it selectively displaces eIF2B’s inhibitor p-eIF2 without affecting the association of its substrate eIF2. By this mechanism, BW10 renders cellular translation immune to regulation by eIF2 phosphorylation. Thus, under stress conditions BW10 creates the unprecedented situation of high levels of p-eIF2 coinciding with unimpaired translation.

Project description:Metabolic flexibility is a common hallmark of aggressive and metastatic cancers. Here, we reveal that dynamic changes in mitochondrial translation rates drive the switch between glycolytic and mitochondrial energy production required for metastasis. We find that loss of 5-methylcytosine (m5C) in mitochondrial tRNAMet is sufficient to repress mitochondrial translation and trigger the switch from oxidative phosphorylation (OXPHOS) to glycolysis. Glycolytic tumour cells form primary tumours but fail to metastasize in an orthotopic mouse model of human oral cancer. Instead, a small subpopulation of non-dividing tumour cells requires high OXPHOS levels for invasion and metastasis. Although this metastasis-initiating metabolic switch is highly dynamic and reversible, we identify a mitochondria-driven gene signature predictive for lymph node metastasis and disease progression. Finally, we demonstrate that pharmacological inhibition of mitochondrial translation blocks metastasis in orthotopic transplants. Together, our results indicate that metastasis-initiating cells can be eradicated by blocking mitochondrial translation.

Project description:Ribosome-associated quality control pathways respond to defects in translational elongation to recycle arrested ribosomes and degrade aberrant polypeptides and mRNAs. Loss of an individual tRNA gene leads to ribosomal pausing that is resolved by the translational GTPase GTPBP2, and in its absence causes neuron death. Here we show that loss of the homologous protein GTPBP1 during tRNA deficiency in the mouse brain also leads to codon-specific ribosome pausing and neurodegeneration, suggesting that these non-redundant translational GTPases function in the same pathway to mitigate ribosome pausing. Ribosome stalling in the mutant brain led to activation of the integrated stress response (ISR) mediated by GCN2 and decreased mTORC1 signaling. However, in contrast to the ISR, which enhanced neuron survival, reduced mTORC1 signaling increased neuronal death. Our data demonstrate that GTPBP1 functions as an important quality control mechanism during translation elongation and suggest that translational signaling pathways intricately interact to regulate neuronal homeostasis during defective translation elongation.

Project description:Most mitochondrial proteins are encoded in the nucleus and require mitochondrial import after translation in the cytosol. A number of mutations in the mitochondrial protein import machinery have been shown to lead to human pathologies. However, a lack suitable tools to measure mitochondrial protein uptake has prevented determination of import rates across the mitochondrial proteome and identification of specific proteins affected by perturbation. Here, we introduce a pulsed-SILAC based proteomics approach that includes a booster signal to selectively increase the sensitivity for mitochondrial proteins, enabling dynamic analysis of mitochondrial protein uptake at the global scale. We applied this method to determine protein uptake kinetics and examined how inhibitors of different mitochondrial import machineries affect protein uptake in sub-mitochondrial compartments. Monitoring changes in translation and protein uptake upon mitochondrial membrane depolarization revealed that protein uptake was extensively modulated the import- and translation machineries, via activation of the integrated stress response. Strikingly, uptake changes were not uniform with three groups of protein identified that showed no changes in uptake, or changes driven by reduced translation or import capacity. This study provides with a quantitative proteomics method to monitor mitochondrial protein uptake at a global scale to provide with insight into uptake rearrangements upon perturbation.

Project description:Most mitochondrial proteins are encoded in the nucleus and require mitochondrial import after translation in the cytosol. A number of mutations in the mitochondrial protein import machinery have been shown to lead to human pathologies. However, a lack suitable tools to measure mitochondrial protein uptake has prevented determination of import rates across the mitochondrial proteome and identification of specific proteins affected by perturbation. Here, we introduce a pulsed-SILAC based proteomics approach that includes a booster signal to selectively increase the sensitivity for mitochondrial proteins, enabling dynamic analysis of mitochondrial protein uptake at the global scale. We applied this method to determine protein uptake kinetics and examined how inhibitors of different mitochondrial import machineries affect protein uptake in sub-mitochondrial compartments. Monitoring changes in translation and protein uptake upon mitochondrial membrane depolarization revealed that protein uptake was extensively modulated the import- and translation machineries, via activation of the integrated stress response. Strikingly, uptake changes were not uniform with three groups of protein identified that showed no changes in uptake, or changes driven by reduced translation or import capacity. This study provides with a quantitative proteomics method to monitor mitochondrial protein uptake at a global scale to provide with insight into uptake rearrangements upon perturbation.

Project description:IFN-g primes macrophages for enhanced inflammatory activation by TLRs and microbial killing, but little is known about the regulation of cell metabolism or mRNA translation during priming. We found that IFN-g regulates macrophage metabolism and translation in an integrated manner by targeting mTORC1 and MNK pathways that converge on the selective regulator of translation initiation eIF4E. Physiological downregulation of the central metabolic regulator mTORC1 by IFN-g was associated with autophagy and translational suppression of repressors of inflammation such as HES1. Genome-wide ribosome profiling in TLR2-stimulated macrophages revealed that IFN-g selectively modulates the macrophage translatome to promote inflammation, further reprogram metabolic pathways, and modulate protein synthesis. These results add IFN-g-mediated metabolic reprogramming and translational regulation as key components of classical inflammatory macrophage activation. RPF and RNAseq libraries were generated from mock or IFN-g-primed human macrophages. Cells were stimulated with Pam3Cys and harvested at 4 hours. Libraries were generated using protocol modified from Illumina Truseq technology.

Project description:IFN-g primes macrophages for enhanced inflammatory activation by TLRs and microbial killing, but little is known about the regulation of cell metabolism or mRNA translation during priming. We found that IFN-g regulates macrophage metabolism and translation in an integrated manner by targeting mTORC1 and MNK pathways that converge on the selective regulator of translation initiation eIF4E. Physiological downregulation of the central metabolic regulator mTORC1 by IFN-g was associated with autophagy and translational suppression of repressors of inflammation such as HES1. Genome-wide ribosome profiling in TLR2-stimulated macrophages revealed that IFN-g selectively modulates the macrophage translatome to promote inflammation, further reprogram metabolic pathways, and modulate protein synthesis. These results add IFN-g-mediated metabolic reprogramming and translational regulation as key components of classical inflammatory macrophage activation. microRNA-seq libraries were generated from mock or IFN-g-primed human macrophages. Cells were stimulated with or without Pam3Cys and harvested at 4 hours Libraries were generated using Illumina Truseq small RNA technology.

Project description:Integrated Stress Response (ISR) is a homeostatic mechanism induced by endoplasmic reticulum (ER) stress. With acute/transient ER stress, decreased global protein synthesis and increased uORF mRNA translation are followed by translation normalization. Here, we report a dramatically different response during more physiologically relevant chronic ER stress. This unique ISR program is characterized by persistently elevated uORF mRNA translation and concurrent gene expression reprogramming, which permits simultaneous stress sensing and proteostasis. PERK-dependent switching from eIF4F/eIF2B- to eIF3D/GADD34-regulated translation initiation results in partial but not complete translation recovery, and together with transcriptional reprogramming, selectively bolsters expression of proteins with ER functions. Coordination of these transcriptional and translational changes prevents ER dysfunction and inhibits “foamy cell” development, thus establishing a molecular basis for understanding human diseases associated with ER dysfunction.