Project description:So far, the annotation of translation initiation sites (TISs) has been based mostly upon bioinformatics rather than experimental evidence. We adapted ribosomal footprinting to puromycin-treated cells to generate a transcriptome-wide map of TISs in a human monocytic cell line. A neural network was trained on the ribosomal footprints at previously annotated AUG translation initiation codons (TICs), and used for the ab initio prediction of TISs in 5062 transcripts with sufficient sequence coverage. Functional interpretation suggested 2994 novel upstream open reading frames (uORFs) in the 5´ UTR (924 AUG, 2070 near-cognate codons), 1406 uORFs overlapping with the coding sequence (116 AUG, 1290 near-cognate) and 546 N-terminal protein extensions (6 AUG, 540 near-cognate). The TIS detection method was validated on the basis of previously published alternative TISs and uORFs. On average, TICs in newly annotated TISs were significantly more conserved among primates than control codons, both for AUGs (p<10-10) and near-cognate codons (p=3.8×10-3). The derived transcriptome-wide map of novel candidate TISs will help to explain how human proteome diversity is influenced by alternative translation initiation and regulation. Examination of translational initiation in human cell lines using ribosomal footprinting

Project description:To understand the impact of alternative translation initiation on a proteome, we performed the first study on protein turnover using positional proteomics and ribosome profiling to distinguish between N-terminal proteoforms of individual genes. Overall, we monitored the stability of 1,941 human N-terminal proteoforms, including 147 N-terminal proteoform pairs that originate from alternative translation initiation, alternative splicing or incomplete processing of the initiator methionine. Ribosome profiling of lactimidomycin and cycloheximide treated human Jurkat T-lymphocytes

Project description:To understand the impact of alternative translation initiation on a proteome, we performed the first study on protein turnover using positional proteomics and ribosome profiling to distinguish between N-terminal proteoforms of individual genes. Overall, we monitored the stability of 1,941 human N-terminal proteoforms, including 147 N-terminal proteoform pairs that originate from alternative translation initiation, alternative splicing or incomplete processing of the initiator methionine.

Project description:So far, the annotation of translation initiation sites (TISs) has been based mostly upon bioinformatics rather than experimental evidence. We adapted ribosomal footprinting to puromycin-treated cells to generate a transcriptome-wide map of TISs in a human monocytic cell line. A neural network was trained on the ribosomal footprints at previously annotated AUG translation initiation codons (TICs), and used for the ab initio prediction of TISs in 5062 transcripts with sufficient sequence coverage. Functional interpretation suggested 2994 novel upstream open reading frames (uORFs) in the 5´ UTR (924 AUG, 2070 near-cognate codons), 1406 uORFs overlapping with the coding sequence (116 AUG, 1290 near-cognate) and 546 N-terminal protein extensions (6 AUG, 540 near-cognate). The TIS detection method was validated on the basis of previously published alternative TISs and uORFs. On average, TICs in newly annotated TISs were significantly more conserved among primates than control codons, both for AUGs (p<10-10) and near-cognate codons (p=3.8×10-3). The derived transcriptome-wide map of novel candidate TISs will help to explain how human proteome diversity is influenced by alternative translation initiation and regulation.

Project description:Translation initiation generally occurs at AUG codons in eukaryotes although it has been shown that non-AUG or non-canonical translation initiation can also occur. However, the evidence for non-canonical translation initiation sites (TISs) is largely indirect and based on ribosome profiling studies. Here, using a strategy specifically designed to enrich N-termini of proteins, we demonstrate that many human proteins are translated at non-canonical TISs. The large majority of TISs that mapped to 5’ untranslated regions were non-canonical and led to N-terminal extension of annotated proteins or translation of upstream small open reading frames (uORF). There has been little controversy on whether the corresponding amino acid to the start codon is incorporated at TIS or methionine is still incorporated. Notably, methionine was incorporated at almost all non-canonical TISs identified in this study. Comparison of the TISs determined through mass spectrometry with ribosome profiling data revealed that about two-thirds of the novel annotations were indeed supported by ribosome profiling data. The sequence orthology analysis and relative translation frequency analysis of non-canonical TISs over canonical ones suggests that those non-canonical TISs are not leaky but they can have certain biological functions. Overall, this study provides evidence of protein translation initiation at non-canonical TISs and indicates that further studies are required for elucidation of functional implications of such non-canonical translation initiation.

Project description:Various forms of the protein, called proteoform, are generated by co- or post-translational modification, alternative splicing and alternative translation initiation site, resulting in interactions between ribosomes, mRNAs, tRNAs, and various enzymes. Here, we introduce a N-terminal peptide enrichment method (Nrich) using a negative selection on filter for the N-terminal peptides with two chemical reagents for labeling free amine and two endoproteases. We identified 6,525 acetylated (or partially acetylated) and 6,570 free protein N-termini from 5,727 proteins. The protein N-termini can be classified into nine groups, such as initial methionine removed or retained, non-terminal residue, signal/transit/pro-peptide removal, putative alternative translational initiation site (methionine removed or retained) and unknown processing, suggesting various proteoform in vivo. In addition, novel protein N-termini was identified in 5`-UTR sequence with pseudo start codon using customized database. Nrich can obtain information about protein stability, localization and function through the observation of finished N-terminal sequence of mature protein.

Project description:To understand the impact of alternative translation initiation on a proteome, we performed the first large-scale study of protein turnover rates in which we distinguish between N-terminal proteoforms pointing to translation initiation events. Using pulsed SILAC combined with N-terminal COFRADIC we monitored the stability of 1,941human N-terminal proteoforms, including 147 proteoform pairs with heterogeneous N-termini originating from the same gene that result from alternative translation initiation and incomplete processing of the initiator methionine. N-terminally truncated proteoforms were on average less abundant than canonical proteoforms, many had different stabilities and exhibited both faster and slower turnover rates compared to their canonical counterparts. These differences in stability did not depend on the length of truncation but on individual protein characteristics. In silico simulation of N-terminal proteoforms in macromolecular complexes revealed possible consequences for complex integrity such as replacement of unstable canonical subunits. The extent of intrinsic disorder in N-terminal protein structures correlated with turnover times, indicating that a change in the structural flexibility of protein N-termini in truncated proteoforms might impact proteoform stability. Interestingly, removal of the initiator methionine by methionine aminopeptidases reduced the stability of processed proteoforms while susceptibility for N-terminal acetylation, another common co-translational modification, did not seem to impact on turnover rates. Taken together, our findings reveal differences in protein stability between N-terminal proteoforms and point to a role for alternative translation initiation and co-translational initiator methionine removal in the overall regulation of proteome homeostasis.

Project description:Purpose: To uncover immune genes and pathways that are modulated by the GPCR/NPR-15 Methods: RNA was extracted from synchronized L4 stage npr-15(tm12539) and WT animals grown at 20 C using Qiagen extraction kits and following standard methods Results: RNA seq analyses shows enriched and signficant upregulated immune, neuropeptide, synaptic signaling and metabolism genes and pathways that are dependent on NPR-15 Conclusions: Our study uncovered NPR-15 to be modulator of the innate immunity in C. elegans

Project description:This dataset contains spectral information of protein N-terminal peptides isolated from Listeria monocytogenes EGD-e, a bacterial model organism and human pathogen. When mapped onto the Listeria genome these peptides indicate the exact location of translation initiation sites (TIS). The large majority of the identified TIS corresponded to start sites of predicted open reading frames (ORFs), however, a significant fraction of the identified TIS indicated deviations from the current genome annotation. The latter include primarily TIS inside the sequence of predicted ORFs or TIS that delineate the start position of novel ORFs.

Project description:To understand the impact of alternative translation initiation on a proteome, we performed the first large-scale study of protein turnover rates in which we distinguish between N-terminal proteoforms pointing to translation initiation events. Using pulsed SILAC combined with N-terminal COFRADIC we monitored the stability of 1,941human N-terminal proteoforms, including 147 proteoform pairs with heterogeneous N-termini originating from the same gene that result from alternative translation initiation and incomplete processing of the initiator methionine. N-terminally truncated proteoforms were on average less abundant than canonical proteoforms, many had different stabilities and exhibited both faster and slower turnover rates compared to their canonical counterparts. These differences in stability did not depend on the length of truncation but on individual protein characteristics. In silico simulation of N-terminal proteoforms in macromolecular complexes revealed possible consequences for complex integrity such as replacement of unstable canonical subunits. The extent of intrinsic disorder in N-terminal protein structures correlated with turnover times, indicating that a change in the structural flexibility of protein N-termini in truncated proteoforms might impact proteoform stability. Interestingly, removal of the initiator methionine by methionine aminopeptidases reduced the stability of processed proteoforms while susceptibility for N-terminal acetylation, another common co-translational modification, did not seem to impact on turnover rates. Taken together, our findings reveal differences in protein stability between N-terminal proteoforms and point to a role for alternative translation initiation and co-translational initiator methionine removal in the overall regulation of proteome homeostasis.