Project description:This project aims to identify novel RNA binding proteins in the nematode, Caenorhabditis elegans. Since interactions between RNAs and proteins may be transient, these animals were crosslinked with UV light at 254 nm which promotes the covalent link between proteins and RNAs. After this, polyadenylated mRNAs were purified via oligo(dT) coupled to magentic beads under stringent conditions. Finally, samples were subjected to mass spectrometry analysis. To rule out the possibility of RNA-independent binding we also analysed other samples: i) samples digested with RNase one; ii) samples where we performed competition assays with polyadenylic acid

Project description:This project aims to identify novel RNA binding proteins in the baker's yeast, Saccharomyces cerevisiae. Since interactions between RNAs and proteins may be transient, yeast cells were crosslinked with UV light at 254 nm which promotes the covalent link between proteins and RNAs. After this, polyadenylated mRNAs were purified via oligo(dT) coupled to magentic beads under stringet conditions. Finally, samples were subjected to mass spectrometry analysis. To rule out the possibility of RNA-independent binding we also analysed other samples: i) samples digested with RNase one; ii) samples where we performed competition assays with polyadenylic acid.

Project description:Here we show that biotin-labelled miR-34a can be loaded to AGO2, and AGO2 immunoprecipitation can pulldown biotinylated miR-34a (Bio-miR pulldown). RNA-sequencing (RNA-seq) of the Bio-miR pulldown RNAs efficiently identified miR-34a mRNA targets, which could be verified with luciferase assays. In contrast to the approach of Bio-miR pulldown, RNA-seq of miR-34a overexpression samples had limited value in identifying direct targets of miR-34a. It seems that pulldown of 30 -Biotin-tagged miRNA can identify bona fide microRNA targets at least for miR34a.

Project description:Total RNA was extracted from zebrafish embryos at different time points post pathogen infection. The RNA was DNase treated. Stranded RNAseq libraries were constructed using the Illumina TruSeq Stranded RNA protocol with oligo dT pulldown. This data is part of a pre-publication release. For information on the proper use of pre-publication data shared by the Wellcome Trust Sanger Institute (including details of any publication moratoria), please see http://www.sanger.ac.uk/datasharing/

Project description:In the current work, we present a comprehensive coverage of the RNA-binding protein (RBP) interactome of Drosophila at four levels of resolution. The highest level tackled in our study represents the RNA-protein complexes, which we address by combining formaldehyde crosslinking of Drosophila S2 cells followed by polyA+ pulldown using oligo-dT beads. On the second level of resolution we identified direct RBPs in the cell using UV crosslinking. Given the paucity of information available on the RNA-binding regions in the Drosophila RBPs that we uncovered, we developed the CAPRI methodology to dissect RNA binding domains (RBDs) on a systematic level. The CAPRI technique provided the final two levels of resolution of our study. The protocol utilised FASP to enable isolation of peptides crosslinked to RNA and peptides adjacent to these crosslinked sites. The CAPRI pipeline mapped both the peptides in proximity to RNA and the precise amino acids contacting RNA. The RNA crosslinked peptide analysis was made by de novo peptide analysis software, PEAKS (Bioinformatics Solutions Inc). In a separate analysis, we also applied FA crosslinking to RBD capture and showed it to be a viable complementary method to the CAPRI workflow. We next applied CAPRI interactome capture to human cells in order to analyse the evolutionary conservation of newly identified RNA binding domains between the two species. These interactome capture techniques and the datasets acquired using them are discussed in detail in the following sections. In summary, we present a comprehensive resource for the study of RNA-protein interactions at a high throughput scale.

Project description:To investigate the RNA binding proteins that change following mTOR inhibition, HeLa cells were treated with and without 200nM Torin1 for an hour. Cells were the UV254 cross-linked, lysed and large scale whole cell oligo(dT) based pulldowns were performed with identification and quantification of purified proteins by label free mass spectrometry.

Project description:The Bacillus subtilis genome encodes four 3’ exoribonucleases: polynucleotide phosphorylase (PNPase), RNase R, RNase PH, and YhaM. Previous work showed that PNPase, encoded by the pnpA gene, is the major 3’ exonuclease involved in mRNA turnover; in a pnpA deletion strain, numerous mRNA decay intermediates accumulate. Whether B. subtilis mRNA decay occurs in the context of a degradosome complex is controversial. In this study, global mapping of mRNA decay intermediate 3’ ends within coding sequences was performed in strains that were either deleted for, or had an inactivating point mutation in, the pnpA gene. The pattern of 3’ end accumulation in these strains was highly similar, suggesting that mRNA decay was not occurring in the context of a degradosome, whose structure would be affected by the absence of PNPase. A comparison with mapped 3’ ends in a strain lacking CshA, the major RNA helicase, indicated that different mRNAs may require both PNPase and CshA for efficient decay. RNA-seq analysis of strains lacking RNase R suggested that this enzyme did not play a major role in mRNA turnover in the wild-type strain. Strains were constructed that contained only one of the four known 3’ exoribonucleases. When RNase R was the only 3’ exonuclease present, it was able to degrade a model mRNA efficiently, showing processive decay even through a strong stem-loop structure that inhibits PNPase processivity. Strains containing only RNase PH or only YhaM were also insensitive to this RNA secondary structure, suggesting the existence of another, as-yet unidentified, 3’ exoribonuclease.

Project description:Bacteria depend on efficient RNA turnover to rapidly alter gene expression, essentially for responding to changing conditions. Nevertheless, remarkably few details are known about the rate-limiting steps in targeting and decay of RNA. The membrane-anchored endoribonuclease RNase Y is a virulence factor in Gram- positive pathogens. We have obtained a global picture of RNase Y sequence specificity using RNA-seq and the novel transcriptome-wide EMOTE method. Ninety- nine endoribonucleolytic sites produced in vivo were precisely mapped, notably inside six out of seven genes whose half-lives increase the most in an RNase Y deletion mutant, and additionally to three separate transcripts encoding degradation ribonucleases, including RNase Y itself, suggesting a regulatory network. We show that RNase Y is required to initiate the major degradation pathway of a defined sub-set of transcripts that are inaccessible to other ribonucleases, but is prevented from promiscuous activity by membrane confinement and sequence preference for guanosines. Rnase Y activity in S. aureus is analysed on a genome wide scale under two perspectives: a RNA decay timecourse with mRNA-seq; and exact position of cleavage with an EMOTE assay (Exact Mapping Of Trancripts Ends)

Project description:oligo-dT and random primed RNA-seq libraries were used to test an improved annotation of the zebrafish transcriptome

Project description:We performed Malat1 pulldown using biotin labeled Stellaris Oligo in 4T1-TGL WT cells.