Project description:Methionine adenosyltransferase (MAT) catalyzes the synthesis of S-adenosylmethionine (SAM). As the sole methyl-donor of methylation of DNA, RNA and proteins, SAM amount affects gene expression by changing their methylation. Expression of MAT2A, the catalytic subunit of isozyme MAT2, is positively correlated with proliferation of cancer cells. However, how MAT2A promotes cell proliferation is largely unknown. Given that the protein synthesis is induced in proliferating cells and that RNA and protein components of translation machinery are methylated, we tested whether MAT2 and SAM are coupled with protein synthesis. By measuring ongoing protein translation with puromycin labeling in HeLa and Hepa1 cells, we revealed that MAT2A depletion by siRNA or chemical inhibition by cycloleucine reduced protein synthesis in mammalian cells. Overexpression of MAT2A enhanced protein synthesis, indicating that SAM is limiting under normal culture conditions. MAT2 inhibition did not accompany a reduction in the mTORC1 activity but reduced polysome formation. Polysome-bound RNA sequencing revealed that MAT2 inhibition decreased translation efficiency of a fraction of mRNAs. MAT2A was also found to interact with the proteins involved in rRNA processing and ribosome biogenesis. Depletion or inhibition of MAT2 reduced 18S rRNA processing. In addition, by quantitative mass spectrometry, we observed that some translation factors were dynamically methylated in response to the activity of MAT2A or the availability of SAM. These observations suggest that cells possess an mTOR-independent regulatory mechanism that tunes translation in response to the amount of SAM. Such a system may acclimate cells for survival when SAM synthesis is reduced whereas it may support proliferation when SAM is sufficient.

Project description:In eukaryotic cells, the spatial regulation of protein expression is frequently conferred through the coupling of mRNA localization and the local control of translation. mRNA localization to the endoplasmic reticulum (ER) is a prominent example of such regulation and serves a ubiquitous role in segregating the synthesis of secretory and integral membrane proteins to the ER. Recent genomic and biochemical studies have now expanded this view to suggest a role for the ER in global protein synthesis. We have utilized cell fractionation and ribosome profiling to obtain a genomic survey of the subcellular organization of mRNA translation and report that ribosomal loading of mRNAs, a proxy for mRNA translation, is biased to the ER. Notably, ER-associated mRNAs encoding both cytosolic and topogenic signal-encoding proteins display similar ribosome loading densities, suggesting that ER-associated ribosomes serve a global role in mRNA translation. We propose that the partitioning of mRNAs and their translation between the cytosol and ER compartments may represent a novel mechanism for the post-transcriptional regulation of gene expression. HEK293 cells were fractionated between the cytosol and endoplasmic reticulum. Within each fraction, ribosome footprints were generated and sequenced. In parallel, total mRNA was sequenced.

Project description:Transfer RNA (tRNA) plays a central role in translation. Simultaneously synthesizing the minimal yet sufficient number of tRNA species (at least 21) in vitro poses a challenge to constructing a self-reproducible artificial cell. In this study, we developed a simplified processing method that enables the simultaneous expression of all 21 tRNAs in a reconstituted transcription/translation system (PURE system). By combining direct tRNA linkage and HDVR attachment methods, termed the tRNA array method, we achieved simultaneous expression of all 21 tRNAs from a single polycistronic DNA template in the PURE system. This method allows for the easy customization of the genetic code by introducing additional tRNAs. To demonstrate genetic code reassignment, we replaced five Leu residues (CUU) in Nanoluc with ACG, which is assigned to Thr in the native codon table. To confirm amino acid reassignment, we performed LC-MS/MS analysis of translated Nanoluc proteins. The results confirmed the incorporation of threonine at the reassigned ACG codon in the presence of tRNA^Thr_CGU, and leucine incorporation when using tRNA^Leu_CGU.

Project description:The polyglutamine expansion of huntingtin (mHtt) causes Huntington disease (HD) and neurodegeneration, but the mechanisms remain unclear. Here, we found that mHtt promotes ribosome stalling and suppresses protein synthesis. Depletion of mHtt enhances protein synthesis and increases the speed of ribosome translocation, while mHtt directly inhibits protein synthesis in vitro. We found interactions of ribosomal proteins and translating ribosomes with mHtt. High-resolution global ribosome footprint profiling (Ribo-Seq) and mRNA-Seq indicated a widespread shift in ribosome occupancy toward the 5’ and 3’ end and unique single-codon pauses on selected mRNA targets in HD cells, compared to controls. Thus, mHtt impedes ribosomal translocation during translation by promoting ribosome stalling, a novel mechanistic defect that can be exploited for HD therapeutics.

Project description:The polyglutamine expansion of huntingtin (mHtt) causes Huntington disease (HD) and neurodegeneration, but the mechanisms remain unclear. Here, we found that mHtt promotes ribosome stalling and suppresses protein synthesis. Depletion of mHtt enhances protein synthesis and increases the speed of ribosome translocation, while mHtt directly inhibits protein synthesis in vitro. We found interactions of ribosomal proteins and translating ribosomes with mHtt. High-resolution global ribosome footprint profiling (Ribo-Seq) and mRNA-Seq indicated a widespread shift in ribosome occupancy toward the 5’ and 3’ end and unique single-codon pauses on selected mRNA targets in HD cells, compared to controls. Thus, mHtt impedes ribosomal translocation during translation by promoting ribosome stalling, a novel mechanistic defect that can be exploited for HD therapeutics.

Project description:The polyglutamine expansion of huntingtin (mHtt) causes Huntington disease (HD) and neurodegeneration, but the mechanisms remain unclear. Here, we found that mHtt promotes ribosome stalling and suppresses protein synthesis. Depletion of mHtt enhances protein synthesis and increases the speed of ribosome translocation, while mHtt directly inhibits protein synthesis in vitro. We found interactions of ribosomal proteins and translating ribosomes with mHtt. High-resolution global ribosome footprint profiling (Ribo-Seq) and mRNA-Seq indicated a widespread shift in ribosome occupancy toward the 5’ and 3’ end and unique single-codon pauses on selected mRNA targets in HD cells, compared to controls. Thus, mHtt impedes ribosomal translocation during translation by promoting ribosome stalling, a novel mechanistic defect that can be exploited for HD therapeutics.

Project description:In ribosome biogenesis, a large fraction of ribosomes is used for producing ribosomal proteins. Here, we deal with the question what fraction of ribosomes should be allocated for synthesis of ribosomal proteins to optimize the cellular economy for growth. We define the "r-fraction" as the fraction of mRNA of the ribosomal protein genes out of the total mRNA and simulated how the amount of the total protein is affected by the r-fraction. Then, we empirically measured the amount of protein and RNA in fission yeast cells cultured at a high or low nitrogen source. In the cells cultured at a low nitrogen source, the r-fraction decreased from 0.46 to 0.42 with a 40% reduction of rRNA, but the reduction of the total protein was smaller at 30%. These results indicate that the r-fraction is internally controlled to optimize the efficiency of protein synthesis at a limited cellular cost.

Project description:Precise control of protein synthesis by engineering sequence elements in 5’ untranslated region (5’UTR) remains a fundamental challenge. To accelerate our understanding of cis-regulatory code embedded in 5’UTR, we devised massively parallel reporter assays from a synthetic mRNA library composed of over one million 5’UTR variants. A completely randomized 10-nucleotide sequence preceding an upstream open reading frame (uORF) and downstream GFP leads to a broad range of mRNA translatability and stability in mammalian cells. While efficient translation protects mRNA from degradation, uORF translation triggers mRNA decay in a UPF1-dependent manner. We also identified translational inhibitory elements in 5’UTR with G-quadruplex as a mark for mRNA decay in the P-body. Unexpectedly, an unstructured A-rich element in 5’UTR, while enabling cap-independent translation, destabilizes mRNAs in the absence of translation. Our results not only expose diverse sequence features of 5’UTR in controlling mRNA translatability, but also reveal ribosome-dependent and -independent mRNA surveillance pathways.

Project description:Ribosomopathies constitute a range of disorders associated with defective protein synthesis mainly affecting hematopoietic stem cells (HSCs) and erythroid development. Here we demonstrate that deletion of Polypyrimidine Tract Binding Protein 1 (PTBP1) in the hematopoietic compartment led to the development of a ribosomopathy-like condition. Specifically, loss of PTBP1 was associated with decreases in HSC self-renewal, erythroid differentiation and protein synthesis. Consistent with its function as a splicing regulator, PTBP1 deficiency led to splicing defects in hundreds of genes, and we demonstrate that the up-regulation of a specific isoform of CDC42 could partly mimic the protein synthesis defect associated with loss of PTBP1. Furthermore, PTBP1 deficiency was associated with a marked defect in ribosome biogenesis and a selective reduction in the translation of mRNAs encoding ribosomal proteins. Collectively, this work identifies PTBP1 as a key integrator of ribosomal functions and highlights the broad functional repertoire of RNA binding proteins.

Project description:Life is resilient because living systems are able to respond to elevated temperatures with an ancient gene expression program called the heat shock response (HSR). Our global analysis revealed a modular HSR dependent on the severity of the stress in yeast. Interestingly, at all temperatures analyzed, the transcription of hundreds of genes is upregulated among them the molecular chaperones, which protect proteins from aggregation. However, for approximately 90% of the regulated genes, the function under stress remained enigmatic. Surprisingly, the majority of these upregulated genes is translated but only for a small fraction this results in raised proteins levels. In this context, increased translation is required to counter-balance elevated protein turnover at elevated temperatures. This anaplerotic reaction together with the molecular chaperone system allows yeast to buffer proteotoxic stress. When the capacity of this system is exhausted at extreme temperatures, translation is stopped via phase transition and growth stops.