Project description:In the last decade, an unexpectedly large number of translated regions (translons) have been discovered using ribosome profiling and proteomics. Translons can regulate mRNA translation and encode micropeptides that contribute to multiprotein complex formation, Ca2+ regulation in muscle, and signaling during embryonic development. However, identification of translons has been limited to cell lines or large organs due to high input requirements for conventional ribosome profiling and mass spectrometry. Here, we employed Ribo-ITP, a low input ribosome profiling technique on difficult to collect samples like microdissected hippocampal tissues and single pre-implantation embryos. We detected thousands of translons across these samples, most of which initiated at non-canonical start sites, were less than 100 amino long with significantly altered amino acid composition. Comparative analysis of more than a thousand ribosome profiling datasets across a wide range of cell types revealed pervasive expression of most of the detected translons. To test the translational capacity of the detected translons, we engineered a translon dependent GFP reporter system, and detected robust expression of translons initiating at near-cognate start codons in mouse embryonic stem cells (mESCs). Mutating the translons in mESCs identified a small proportion that negatively impacted growth. Taken together, we present a proof-of-concept study to identify non-canonical translation events from ultra-low input samples which can be applied to cell and tissue types inaccessible to conventional methods.

Project description:Ribo-ITP coupled ribosome profiling identifies non-canonical translational events in low input samples

Project description:Ribo-ITP coupled ribosome profiling identifies non-canonical translational events in low input samples [Ribo-seq]

Project description:A translating ribosome is typically thought to follow the reading frame defined by the selected start codon. Using super-resolution ribosome profiling, here we report pervasive out-of-frame translation from the start codon. Unlike programmable frameshifting during elongation, start codon-associated ribosome frameshifting (SCARF) stems from the slippage of the initiating ribosome. Using a massively paralleled reporter assay, we uncovered sequence elements acting as SCARF enhancers or repressors, implying that start codon recognition is coupled with reading frame fidelity. This finding explains thousands of mass spectrometry spectra unannotated from human proteome. Mechanistically, we find that the eukaryotic initiation factor 5B (eIF5B) maintains the reading frame fidelity during the transition from initiation to elongation. Intriguingly, amino acid starvation induces SCARF by proteasomal degradation of eIF5B. The stress-induced SCARF products provide a degradative source to mitigate amino acid scarcity during starvation. Our findings illustrate the beneficial effect of divergent translation in nutrient stress adaptation.

Project description:A rapid protocol for ribosome profiling of low input samples

Project description:Input mRNAs and ribosome protected fragments (RPFs) from Heterozygout (Control) and Dis3l2 knockout (KO) mESCs cultures were analyzed by TruSeq Ribo Profile (Illumina) library preparation and high throughput sequencing

Project description:Small proteins consisting of 50 or fewer amino acids have been identified as regulators of larger proteins in bacteria and eukaryotes. Despite the importance of these molecules, the true prevalence of these regulators remains unknown because conventional annotation pipelines usually exclude such small open reading frames (smORFs). We previously identified several dozen small proteins in the model organism Escherichia coli using theoretical bioinformatic approaches based on sequence conservation and matches to canonical ribosome binding sites. Here, we present an empirical approach for discovering new proteins, taking advantage of recent advances in ribosome profiling in which antibiotics are used to trap newly-initiated 70S ribosomes at start codons. This approach led to the identification of many novel initiation sites in intergenic regions in E. coli. We selected 41 smORFs for chromosomal tagging and detected small protein synthesis for all but 3. The corresponding genes are not only intergenic, but are also found antisense to other genes, in operons, and overlapping other open reading frames (ORFs), some impacting translation of larger downstream genes. These results demonstrate the utility of this method for identifying new genes, regardless of their genomic context.

Project description:Despite advancement of data-independent acquisition mass spectrometry (DIA-MS) to provide comprehensive and reproducible quantitative proteome profiling, its utility in very low-input samples is limited. For low-input samples at microscale, the proteome composition and overall peptide ion patterns are different from the conventional sample size. Thus, the conventional LC-MS/MS acquisition and widely used large proteome-scale DIA libraries may not be suitable for the microscale sample. In this study, we report a sample size-comparable library-based DIA approach for enhanced proteome coverage of low-input samples at nanoscale to near single-cell levels (i.e. nanogram cells,~5-50 cells). With these spectral libraries made freely available, we envision that such single-shot DIA strategy and the DIA digital map will advance quantitative proteomics applications by enabling improved deep proteome profiling for mass-limited samples.

Project description:iPS cells, produced in in presence of exogeneously expressed E-cadherin and abcence of viral Oct4 were compared with conventional produced OSKM-iPS cells and murine embryonic stem cells (mESCs) or MEFs Total RNA was isolated from iPSCs and mESCs grown in presence of LIF on gelatin-coated plates for 4 days and from murine embryonic fibroblasts grown in standard medium (DMEM-Glutamax, high-glucose, 10 % FBS, 1X non-essential amino acids, penicillin/ streptomycin

Project description:Translational control is a widespread mode of gene regulation in organisms ranging from bacteria to mammals. Computational models posit that translational control of protein expression during elongation is exerted through a traffic jam of multiple ribosomes at ribosome pause sites on mRNAs. Yet neither the in vivo frequency of ribosome traffic jams nor the contribution of such traffic jams to protein expression has been measured in any organism. Here we show that upon starvation for single amino acids in the bacterium Escherichia coli, ribosome traffic jams are pervasive across the transcriptome, but they occur at only a subset of codons cognate to the limiting amino acid, and their severity is determined by the translation efficiency of mRNAs. Surprisingly, a computational model based on the observed traffic jams at ribosome pause sites is quantitatively inconsistent with measured protein synthesis rates. By comparison, a model incorporating abortion of protein synthesis at ribosome pause sites in addition to ribosome traffic jams predicts protein synthesis rate with higher accuracy. Consistent with the latter model, a significant fraction of the nascent polypeptides at ribosome pause sites is degraded through the activity of the transfer-messenger RNA during amino acid starvation in E. coli. Our work provides a minimal, experimentally-constrained model for predicting protein expression from ribosome dynamics, and it suggests the existence of a trade-off between the cellular translational capacity and the processivity of protein synthesis in vivo. 6 samples for ribosome profiling and 5 samples for total mRNA profiling