Project description:To understand how cell physiological state affects mRNA translation, we used the bacterium Shewanella oneidensis MR-1 grown under steady state conditions at either 20% or 8.5% O2. Using a combination of quantitative proteomics and RNA-Seq, we generated high-confidence data on >1000 mRNA and protein pairs. By using a steady state model, we found that differences in protein–mRNA ratios were primarily due to differences in the translational efficiency of specific genes. When oxygen levels were lowered, 28% of the proteins showed at least a 2-fold change in expression. Transcription levels were significantly altered for 26% of the protein changes; translational efficiency was significantly altered for 46% and a combination of both was responsible for the remaining 28%. Changes in translational efficiency were significantly correlated with the codon usage pattern of the genes and measurable tRNA pools changed in response to altered O2 levels. Our results suggest that changes in the translational efficiency of proteins, in part due to altered tRNA pools, is a major determinant of regulated alterations in protein expression levels in bacteria. For further details, see the resulting publication and its supplemental material: Taylor, R. C. et al., "Changes in translational efficiency is a dominant regulatory mechanism in the environmental response of bacteria", Integrative Biology, 2013, 5, 1393. DOI: 10.1039/c3ib40120k mRNA profiles of Shewanella MR-1 were generated by sequencing on SOLID sequencers under high (20%) or low (8.5%) oxygen, with primary sample comparison pair in triplicate, other samples in duplicate.

Project description:Ribosome profiling data reports on the distribution of translating ribosomes, at steady-state, with codon-level resolution. We present a robust method to extract codon translation rates and protein synthesis rates from these data, and identify causal features associated with elongation and translation efficiency in physiological conditions in yeast. We show that neither elongation rate nor translational efficiency is improved by experimental manipulation of the abundance or body sequence of the rare AGG tRNA. Deletion of three of the four copies of the heavily used ACA tRNA shows a modest efficiency decrease that could be explained by other rate-reducing signals at gene start. This suggests that correlation between codon bias and efficiency arises as selection for codons to utilize translation machinery efficiently in highly translated genes. We also show a correlation between efficiency and RNA structure calculated both computationally and from recent structure probing data, as well as the Kozak initiation motif, which may comprise a mechanism to regulate initiation. We test whether tRNA abundance affects elongation or translation efficiency by changing the tRNA levels through deletion or over expression and measuring the ribosomal dwell time at each codon using a robust statistical method that accounts for flow conservation.

Project description:Ribosome profiling data reports on the distribution of translating ribosomes, at steady-state, with codon-level resolution. We present a robust method to extract codon translation rates and protein synthesis rates from these data, and identify causal features associated with elongation and translation efficiency in physiological conditions in yeast. We show that neither elongation rate nor translational efficiency is improved by experimental manipulation of the abundance or body sequence of the rare AGG tRNA. Deletion of three of the four copies of the heavily used ACA tRNA shows a modest efficiency decrease that could be explained by other rate-reducing signals at gene start. This suggests that correlation between codon bias and efficiency arises as selection for codons to utilize translation machinery efficiently in highly translated genes. We also show a correlation between efficiency and RNA structure calculated both computationally and from recent structure probing data, as well as the Kozak initiation motif, which may comprise a mechanism to regulate initiation.

Project description:We investigated the changes in the abundance of reads across the entire mitochondrial transcriptome, we found an increase in the regions that span gene boundaries, where RNA processing is required to release individual mitochondrial RNAs from the precursor transcripts. These data confirm an impairment of mt-tRNA processing efficiency without severe effects on mature mt-mRNA or mt-tRNA steady-state levels. Strand-specific coverage profiles were generated in bedGraph format and normalised to library size (RPM; reads per million mapped).

Project description:Given the overall steady-state mRNA abundance between these two groups displayed negligible differences, these data implied an increased translational efficiency in cells bearing K177Q mutation.

Project description:Embryogenesis entails dramatic shifts in mRNA translation and turnover to account for gene expression differences during proliferation and cellular differentiation. Codon identity modulates mRNA stability during early vertebrate embryogenesis, but how the composition of tRNA pools adapts to the embryo s translational demand is unknown. By quantitatively profiling the tRNA repertoires of zebrafish embryos during the maternal-to-zygotic transition, here we find that maternal and zygotic tRNA pools are distinct. We show that translational activation during embryogenesis and tRNA gene derepression are temporally coordinated by TORC1 activity, which increases at gastrulation and inactivates the RNA polymerase III repressor Maf1a/b in vivo. Reshaping of tRNA pools results in differential tRNA anticodon supply, but these changes do not alter decoding rates in zebrafish embryos. Instead, our data indicate that tRNA repertoires reflect the inherent codon bias of the zebrafish mRNA transcriptome, and tRNA levels are boosted at gastrulation to ensure efficient translation as embryos enter differentiation.

Project description:Here, we employed ribosome profiling to explore global changes in mRNA translational status in neuronally differentiated neuroblast cultures at several time-points after whole cell depolarisation, and compared this to steady-state mRNA levels. Immediately after depolarisation, genes with known function at the synapse were subjected to a surge of translational activity without corresponding changes in mRNA levels. At later time-points, however, these changes became synchronised, suggesting there are different layers of post-transcriptional regulation which are temporally separated but become coordinated over time. Sequencing of small RNAs additionally revealed that changes in microRNA (miRNA) and tRNA-derived small RNA fragments (tRFs) coincided with this early post-transcriptional disparity, however these molecules exhibited strongest association with the remodelling of mRNA steady-state levels. Transcripts displaying high levels of translational dynamics relative to underlying mRNA levels were characterised by more intrinsic features, including mRNA length, GC content, secondary structure and motifs for RNA binding proteins. These data suggest that activity-associated neuronal translation is initially regulated independently of mRNA levels, wherein transcript features contribute to modulation of mRNA translatability, while miRNA and tRFs fine-tune mRNA levels.

Project description:mRNA TE and steady-state levels were measured in hypoxic U87MG cells treated with non-silencing control or HuR-specific siRNA pools followed by ribosome density fractionation.

Project description:mRNA TE and steady-state levels were measured in hypoxic U87MG cells treated with non-silencing control or HIF-2α-specific or HIF-1α-specific siRNA pools followed by ribosome density fractionation.

Project description:Protein concentrations evolve under greater evolutionary constraint than mRNA levels. In addition, translation efficiency of mRNA populations represents the chief determinant of basal protein concentrations. This raises a fundamental question as to how mRNA and protein levels are actively coordinated in dynamic systems responding to acute physiological stimuli. This report examines the contributions of mRNA abundance and translation efficiency to protein output in cells responding to oxygen stimulus. We show that alternative translation efficiencies, not mRNA levels, represent the major adaptive mechanism that governs the cellular response to perturbations in [O2]. This phenomenon is coordinated by eIF4F under atmospheric [O2] and the previously uncharacterized hypoxic eIF4F (eIF4FH) under low [O2]. The oxygen-regulated remodeling of translation efficiency enables oxygenated and hypoxic cells to produce surprisingly divergent translatomes of similar complexity, with minimal dependence on mRNA levels. Changes in mRNA concentrations observed between normoxic and hypoxic cells are likely neutral, as they are during evolution. We propose that mRNAs contain hard-wired translation efficiency determinants for their triage by the translation apparatus on [O2] stimulus.