Project description:Nonsense-mediated mRNA decay (NMD) pathway promotes the degradation of several mRNA species, including transcripts containing a premature termination codon. Here,we measured global mRNA half-lives in NMD deficient and wild-type (WT) embryonic stem cells (ESCs). This allowed us to discriminate which transcripts are affected by NMD. Several transcripts had an impaired half-life in Smg5 and Smg6 KO ESCs compared to WT. They belong to different pathways and cellular processing indicating that NMD regulates multiple processes in the cells. Finally, majority of the transcripts had an impairment on the half-life in both Smg5 and Smg6 KO ESCs indicating that endo- and exonucleolityc branches of the NMD pathway target the same mRNAs.

Project description:We calculated half-life values of mRNAs quantified by RNA-Seq by a suitable method of normalization. We determined the half-lives of more than 2200 mRNAs in the Stenotrophomonas maltophilia D457 wild-type strain and in an isogenic RNase G deficient mutant. Median half-lives were 2,74 and 3 min in the wild-type and the rng-deficient mutant respectively. We found an overall enhancement of half-life times of mRNAs when the gene encoding RNase G is lacking, showing that many RNAs are targets of RNase G in S. maltophilia. For achieving such goal, we propose a method for the normalization of RNA-Seq based studies on global bacterial mRNA decay.

Project description:Global RNA half lives in cyanobacteria

Project description:We have identified NANOS2 bound targets transcriptome wide by employing CRAC and RNA-seq in mouse SSCs. We have determined the average mRNA half-life in SSCs by SLAM-seq. By comparing CRAC and SLAM-seq datasets, we have demonstrated that NANOS2 binding reduces mRNA stability in SSCs.

Project description:Global SLAM-Seq for accurate mRNA decay determination and identification of NMD targets

Project description:uantitative proteomics studies of yeast that use metabolic labeling with amino acids rely on auxotrophic mutations of one or more genes on the amino acid biosynthesis pathways. These mutations affect yeast metabolism, and preclude the study of some biological processes. Overcoming this limitation, it has recently been described that proteins in a yeast prototrophic strain can also be metabolically labeled with heavy amino acids. However, the temporal profiles of label incorporation under the different phases of the prototroph’s growth have not been examined. Labeling trajectories are important in the study of protein turnover and dynamics, in which label incorporation into proteins is monitored across many timepoints. Here we monitored protein labeling trajectories for 48 h after a pulse with heavy lysine in a yeast prototrophic strain and compared them with those of a lysine auxotrophic yeast. Labeling was successful in prototroph yeast during exponential growth phase but not in stationary phase. Furthermore, we were able to determine the half lives of more than 1,700 proteins during exponential phase of growth with high accuracy and reproducibility. We found a median half life of 2 h in both strains which corresponds with the cellular doubling time. Nucleolar and ribosomal proteins showed short half-lives whereas mitochondrial proteins and other energy production enzymes presented longer half-lives. Except for some proteins involved in lysine biosynthesis, we observed a high correlation in protein half lives between prototroph and auxotroph strains. Overall, our results demonstrate the feasibility of using prototrophs for proteomic turnover studies and provide a reliable dataset of protein half lives in exponentially growing yeast.

Project description:Quantitative proteomics studies of yeast that use metabolic labeling with amino acids rely on auxotrophic mutations of one or more genes on the amino acid biosynthesis pathways. These mutations affect yeast metabolism, and preclude the study of some biological processes. Overcoming this limitation, it has recently been described that proteins in a yeast prototrophic strain can also be metabolically labeled with heavy amino acids. However, the temporal profiles of label incorporation under the different phases of the prototroph’s growth have not been examined. Labeling trajectories are important in the study of protein turnover and dynamics, in which label incorporation into proteins is monitored across many timepoints. Here we monitored protein labeling trajectories for 48 h after a pulse with heavy lysine in a yeast prototrophic strain and compared them with those of a lysine auxotrophic yeast. Labeling was successful in prototroph yeast during exponential growth phase but not in stationary phase. Furthermore, we were able to determine the half lives of more than 1,700 proteins during exponential phase of growth with high accuracy and reproducibility. We found a median half life of 2 h in both strains which corresponds with the cellular doubling time. Nucleolar and ribosomal proteins showed short half-lives whereas mitochondrial proteins and other energy production enzymes presented longer half-lives. Except for some proteins involved in lysine biosynthesis, we observed a high correlation in protein half lives between prototroph and auxotroph strains. Overall, our results demonstrate the feasibility of using prototrophs for proteomic turnover studies and provide a reliable dataset of protein half lives in exponentially growing yeast.

Project description:To investigate the changes in mRNA stablity upon loss of LARP1, we performed SLAM-seq and half-life measurements on WT and derived LARP1 KO cells. The canonical and 5′TOP mRNA cell lines used for single-molecule imaging were treated as biological replicates for the SLAM-seq analysis.

Project description:Global analysis of mRNA isoform half-lives: identification of stabilizing and destabilizing elements in yeast

Project description:We measured half-lives of 21,248 mRNA 3’ isoforms in yeast by rapidly depleting RNA polymerase II from the nucleus and performing direct RNA sequencing throughout the decay process. Interestingly, the half-lives of mRNA isoforms from the same gene, including nearly identical isoforms, often vary widely. Based on clusters of isoforms with different half-lives, we identify hundreds of sequences conferring stabilization or destabilization upon mRNAs terminating downstream. One class of stabilizing element is a polyU sequence that can interact with poly(A) tails, inhibit the association of poly(A) binding protein, and confer increased stability upon introduction into ectopic transcripts. More generally, destabilization and stabilization elements are linked to the degree to which the poly(A) tail can engage in double-stranded structures. Isoforms engineered to fold into 3’ stem-loop structures not involving the poly(A) tail exhibit even longer half-lives. We suggest that double-stranded structures at the 3’ ends are a major determinant of mRNA stability. Half-lives of 21,248 mRNA 3’ isoforms in yeast were measured by rapidly depleting RNA polymerase II from the nucleus and performing direct RNA sequencing throughout the decay process.