Project description:Proteostasis is a fundamental network of cellular pathways that ensures the optimal concentration and composition of correctly folded proteins within cells in normal and stress conditions. Among key components of this network are the molecular chaperones, which mediate protein folding but also act as modulators of protein synthesis. We have reported on a functional link between translation and de novo folding of proteins in the yeast Saccharomyces cerevisiae by uncovering a specific synthetic-lethal interaction between apparent unrelated mutant variants, the uL3[W255C] variant of the ribosomal protein uL3 and the null mutants of Zuo1 and Ssz1. Zuo1 and Ssz1 are components of the chaperone system named as ribosome-associated complex. Here, we performed a genome-wide analysis of ribosome dynamics by 5PSeq (Pelechano et al. 2015 PMID 26046441) in strains harbouring either wild-type uL3 or mutant uL3[W255C] in the presence or absence of Zuo1 or Ssz1. This method allows the study of ribosome dynamics, by sequencing 5’ phosphorylated mRNA co-translational degradation intermediates. Our results indicate that the rpl3[W255C] mutant is slightly impaired in translation elongation, defect that is significantly enhanced when combined with the deprivation of either Zuo1 or Ssz1.

Project description:Developmentally-regulated GTP-binding (Drg) proteins are important for embryonic development, cell growth, proliferation, and differentiation. Despite their highly conserved nature, the functions of Drg proteins in translation are unknown. Here, we performed a wide analysis of ribosome dynamic in S.cerevisiae Rbg1, Rbg2 and Slh1 depleted cells using 5Pseq (Pelechano et al. 2015 PMID 26046441), which allows the study of ribosome dynamics by sequencing the 5' phoshporylated mRNA co-translational degradation itermediates. We demonstrate the yeast Drg ortholog, Rbg1, alleviates ribosome pausing at Arginine/Lysine-rich regions in mRNAs, and mainly targets genes related to ribonucleoprotein complex biogenesis and non-coding RNA processing pathways.

Project description:eIF5A is an essential translation elongation factor present in all eukaryotes, and the only known protein to follow a post-translational modification called hypusination. Here, we performed a wide analysis of ribosome dynamics in S. cerevisiae eIF5A depleted cells using 5Pseq (Pelechano et al. 2015 PMID 26046441). This method allows the study of ribosome dynamics, by sequencing 5’ phosphorylated mRNA co-translational degradation intermediates. Since eIF5A is an essential protein in yeast, we used two eIF5A temperature-sensitive strains containing a single Pro83 to Ser mutation (tif51A-1) and double Cys39 to Tyr and Gly118 to Asp mutations (tif51A-3) in the highly expressed gene TIF51A (HYP2) that encodes eIF5A protein (Li et al. 2011 PMID: 24923804).

Project description:In addition to predominant protein methylation on lysine and arginine residues, histidine also serves as a substrate for the modification. However, a limited number of enzymes responsible for this modification has been reported. Moreover, the biological mission of the histidine methylation has remained poorly understood. Here, we reported that human METTL18 is a histidine methyltransferase for ribosomal protein RPL3 and that the modification specifically slows ribosome traverse on tyrosine codons, allowing proper folding of synthesized proteins. Harnessing in vitro methylation assay with methyl-donor analogue and quantitative mass spectrometry, we identified that His245 of RPL3 is methylated at τ-N position by METTL18. Structural comparison of the modified and unmodified ribosomes showed the stoichiometric modification and suggested its role in translation tuning. Indeed, genome-wide ribosome profiling revealed the suppressed ribosomal translocation at tyrosine codons by RPL3 methylation. Because the slower elongation provides enough time for nascent protein folding, RPL3 methylation protects cells from cellular aggregation of Tyr-rich proteins. Our results reveal histidine methylation as an example of “ribosome code”, which ensures proteome integrity in cells.

Project description:Protein methylation occurs predominantly on lysine and arginine residues, but histidine also serves as a substrate for the modification. However, a limited number of enzymes responsible for this modification have been reported. Moreover, the biological role of histidine methylation has remained poorly understood. Here, we report that human METTL18 is a histidine methyltransferase for the ribosomal protein RPL3 and that the modification specifically slows ribosome traverse on tyrosine codons, allowing the proper folding of synthesized proteins. By performing an in vitro methylation assay with a methyl donor analog and quantitative mass spectrometry, we found that His245 of RPL3 is methylated at the τ-N position by METTL18. Structural comparison of the modified and unmodified ribosomes showed stoichiometric modification and suggested a role in translation tuning. Indeed, genome-wide ribosome profiling revealed suppressed ribosomal translocation at tyrosine codons by RPL3 methylation. Because the slower elongation provides enough time for nascent protein folding, RPL3 methylation protects cells from the cellular aggregation of Tyr-rich proteins. Our results reveal histidine methylation as an example of a “ribosome code” that ensures proteome integrity in cells.

Project description:We investigated the association of cryptic unstable transcripts (CUTs) to ribosomes in Saccharomyces cerevisiae. We used 5’cap-sequence followed by sucrose gradient fractionation of polyribosome fractions after ultracentrifugation to assess the relative association of transcripts to the ribosomes. We used 5PSeq approach, which measures ribosome dynamics by sequencing the presence of co-translation mRNA degradation intermediates, to assess if cryptic transcripts are engaged in active translation. We performed 5PSeq after glucose depletion to increase the number of ribosomes stop at the 5’UTR and start codon.

Project description:It is generally assumed that mRNAs undergoing translation are protected from decay. Here, we show that mRNAs are, in fact, co-translationally degraded. This is a widespread and conserved process affecting most genes, where 5′–3′ transcript degradation follows the last translating ribosome, producing an in vivo ribosomal footprint. By sequencing the ends of 5′ phosphorylated mRNA degradation intermediates, we obtain a genome-wide drug-free measurement of ribosome dynamics. We identify general translation termination pauses in both normal and stress conditions. In addition, we describe novel codon-specific ribosomal pausing sites in response to oxidative stress that are dependent on the RNase Rny1. Our approach is simple and straightforward and does not require the use of translational inhibitors or in vitro RNA footprinting that can alter ribosome protection patterns. RNA samples were quantified according to their 5’modification. Samples were quantified using 2 alternative methods. 5PSeq (measures 5’P RNAs) and 5PSeq-fragmented (measures the sequencing bias present in any sample by randomly fragmenting RNA, re-phosphorilating the 5’ends and subjecting the sample to 5PSeq; it is used as a negative control). Different strains of S. cerevisiae and S. pombe samples were analyzed. Cells were grown both in rich media (YPD or YES) and synthetic defined media (SD). Cells were subjected to different treatments such as inhibition of translation elongation with cyclohexamide (CHX), oxidative stress (0.2 mM H2O2) or inhibition of histidine biosyntesys (3-AT; 100mM 3-amino-1,2,4-triazole). S. cerevisiae samples grown in rich media were also analyzed after CHX treatment and sucrose fractionation into monosome and polyribosome fractionation. All samples were analyzed in biological duplicates.

Project description:Although several ribosomal protein (RP) paralogs are expressed in a tissue-specific manner, how these proteins affect translation and why they are required only in certain tissues have remained unclear. Here we show that RPL3L, a paralog of RPL3 specifically expressed in heart and skeletal muscle, influences translation elongation dynamics. Deficiency of RPL3L-containing ribosomes (RPL3L-ribosomes) in RPL3L knockout male mice resulted in impaired cardiac contractility. Ribosome occupancy at mRNA codons was found to be altered in the RPL3L-deficient heart, and the changes were negatively correlated with those observed in myoblasts overexpressing RPL3L. RPL3L-ribosomes were less prone to collisions compared with RPL3-containing canonical ribosomes. Although the loss of RPL3L-ribosomes altered translation elongation dynamics for the entire transcriptome, its effects were most pronounced for transcripts related to cardiac muscle contraction and dilated cardiomyopathy, with the abundance of the encoded proteins being correspondingly decreased. Our results provide new insight into the mechanisms and physiological relevance of tissue-specific translational regulation.

Project description:We investigated cryptic transcription start site usage, chromatin organization and post-transcriptional consequences in Saccharomyces cerevisiae. We used 5PSeq approach, which measures ribosome dynamics by sequencing the presence of co-translation mRNA degradation intermediates, to assess if cryptic transcripts are engaged in active translation. Here we assay the effect of Cycloheximide treatment (CHX) in the co-translational degradation profile of using strains where cryptic transcription is enhanced. We study the profiles in set2D and rrp6D, enhanced for the presence of chromatin-sensitive and RNA degradation-sensitive cryptic transcripts respectively.

Project description:We investigated cryptic transcription start site usage, chromatin organization and post-transcriptional consequences in Saccharomyces cerevisiae. We used 5PSeq approach, which measures ribosome dynamics by sequencing the presence of co-translation mRNA degradation intermediates, to assess if cryptic transcripts are engaged in active translation. We show that chromatin-dependent cryptic transcripts can be recognized by ribosomes and have the potential to produce truncated polypeptides by using downs-stream, in-frame start codons. Our work suggests that a significant fraction of chromatin-dependent internal cryptic promoters are in fact alternative truncated mRNA isoforms.