Project description:Pseudouridine (Ψ) is the most abundant RNA modification, yet little is known about its content, dynamics and function in mRNA and ncRNA. Here, we perform quantitative MS analysis and develop CAP-seq for transcriptome-wide Ψ profiling. The unexpected high Ψ content (Ψ/U ratio: ~ 0.2% to 0.6%) indicates that pseudouridylation in mammalian mRNA is much more prevalent and comprehensive than previously believed. In concordance, CAP-seq identified 2,084 Ψ sites within 1,929 human transcripts. We prove four previously unknown Ψ sites in rRNA and EEF1A1 mRNA. Genetic and biochemical analysis uncover PUS1 as a major human mRNA Ψ synthase. In response to stimuli, Ψ level and sites are dynamically modulated in stimulus-specific manners. Comparisons between human and mouse pseudouridylation reveal conserved and unique sites across tissue and species. We observe stop codon pseudouridylation and readthrough events simultaneously for HSPB1 mRNA, indicating a role in nonsense suppression. Together, these approaches allow in-depth analysis of transcriptome-wide pseudouridylation events and our comprehensive study provides a resource for functional studies of Ψ-mediated epigenetic regulation. Here we report a transcriptome-wide profiling method that utilizes a chemically synthesized N3-CMC, which pre-enriches the Ψ-containing RNAs and blocks the reverse transcription.Mapping the Ψ sites in human transcriptome was performed using HEK293T and PUS1 dependent Ψ sites were identified by comparing PUS1 knock out cells with wildtype cells. Stress inducible or suppressed Ψ sites were identified by comparing stress treated cells with untreated cells. And mouse brain and liver were used to map Ψ sites in mouse transcriptome.

Project description:We have engineered an RT-active DNA polymerase variant called RT-KTq I614Y that produces error RT‑signatures specific for pseudouridine (Ψ) without prior chemical treatment of the RNA samples. These signatures are amplified during DNA amplicon library preparation and are detected by NGS. This method was applied to distinguish U from Ψ in RNA oligonucleotides (modified or unmodified) used in the previous polymerase screening and oligonucleotides which are designed from the human 18S rRNA at the position around 1445. Finally, RT-KTq I614Y was used to detect Ψ55 in tRNAGly(GCC) from Saccharomyces cerevisiae wildtype compared to data from tRNAGly(GCC) from S. cerevisiae pus4Δ.

Project description:Here, we developed a Ψ RNA immunoprecipitation sequencing method (Ψ-RIP-seq) combined with direct RNA sequencing by Oxford Nanopore Technologies to detect mRNA Ψ transcriptome-wide. We identified a large number of novel Ψs in mRNA, revealing a conserved enrichment of Ψ in mRNA 3′ UTR. We further showed that a genome-wide association of Ψ with mRNA polyadenylation, and uncovered that cleavage factor complex I (CFI) regulated Ψ generation in mRNA 3′ UTR. We finally demonstrated that Ψ in mRNA 3′ UTR promoted mRNA stability in a CFI-dependent manner.

Project description:Pseudouridine (Y) is an abundant chemical modification that plays critical roles in cellular RNA metabolism and functions, and in RNA therapeutic applications. Transcriptome-wide mapping technologies present major advantages in discovering the functional contexts and crucial effector proteins of Y. Current mapping strategies for Ys are limited in identifying Ys at base-resolution within consecutive uridine sequence contexts where Y occurs frequently. Here we report “Mut-Y-seq” that utilities a recently evolved reverse transcriptase (“RT-1306”) coupled with the selective labeling of Y by the CMC treatment to identify Ys in mRNAs and non-coding RNAs from human cells. We showed that RT-1306 showed significantly promoted read-through and mutation signatures against the CMC-Y adduct; the mutation signatures generated by RT-1306 can discern the position of Y in consecutive uridine sequence contexts. We quantitatively characterized the Y-identification efficiencies by Mut-Y-seq under variable chemical treatment conditions by the receiver operating characteristic curve analysis and revealed the presence of potential false positive discoveries generated by side-reactions on unmodified uridines. Finally, the intersection of sites identified by orthogonal chemical treatments (i.e. CMC and bisulfite) produced a high-confidence list of Y sites in mRNAs and non-ribosomal long non-coding RNAs from HEK-293T cells. This report presents datasets for biological functional studies of endogenous Y sites, and sheds light on the combination of the reverse transcriptase engineering and selective chemical reactions for further expanding the toolkit for studying RNA chemical modifications.

Project description:Pseudouridine (Ψ) is the most abundant RNA modification, yet little is known about its content, dynamics and function in mRNA and ncRNA. Here, we perform quantitative MS analysis and develop CAP-seq for transcriptome-wide Ψ profiling. The unexpected high Ψ content (Ψ/U ratio: ~ 0.2% to 0.6%) indicates that pseudouridylation in mammalian mRNA is much more prevalent and comprehensive than previously believed. In concordance, CAP-seq identified 2,084 Ψ sites within 1,929 human transcripts. We prove four previously unknown Ψ sites in rRNA and EEF1A1 mRNA. Genetic and biochemical analysis uncover PUS1 as a major human mRNA Ψ synthase. In response to stimuli, Ψ level and sites are dynamically modulated in stimulus-specific manners. Comparisons between human and mouse pseudouridylation reveal conserved and unique sites across tissue and species. We observe stop codon pseudouridylation and readthrough events simultaneously for HSPB1 mRNA, indicating a role in nonsense suppression. Together, these approaches allow in-depth analysis of transcriptome-wide pseudouridylation events and our comprehensive study provides a resource for functional studies of Ψ-mediated epigenetic regulation.

Project description:Leishmania are unicellular parasites that cycle between the insect and mammalian host and is the causative agent of Leishmaniasis. Previous studies from our lab suggested that individual rRNA modification such as pseudouridine (Psi) and 2-O-methylation are developmentally regulated during the complex life cycle of these parasites. Ablation of a single snoRNA guiding Psi in the inter-subunit bridge, helix69 of the ribosome affects its affinity to translate specific mRNA. Mutational analysis in the pseudouridylation pocket of this snoRNA supports the notion that the guided modification and not the chaperone activity, is essential for the observed phenotype. Structural studies using CryoEM suggested that a single Psi modification can affect the rRNA structure. We propose that alteration in rRNA modifications could generate ribosomes preferentially translating state-beneficial proteins.

Project description:Pseudouridine (Ψ) is an abundant RNA modification that is present in and impacts the functions of diverse non-coding RNA species, including rRNA, tRNA, snRNA, etc. Pseudouridine also exists in mammalian mRNA and likely exhibits functional roles; however, functional investigations of pseudouridine in mammalian mRNA have been hampered by the lack of a quantitative method that detects Ψ at base precision. We have recently developed Bisulfite-Induced Deletion sequencing (BID-seq), which provides the community with a quantitative method to map RNA Ψ distribution transcriptome-wide at single-base resolution. Here, we describe an optimized BID-seq protocol to generate highly reproducible results, displaying nearly zero background deletions at unmodified uridines after bisulfite treatment and uncovering 8,407 Ψ sites starting from as little as 10 ng mouse embryonic stem cell (mESC) polyA+ RNA, with the steps that are fast in both library preparation and data analysis. This optimized BID-seq workflow takes 5 days to complete and includes four main sections: RNA preparation, library construction, next-generation sequencing (NGS), and data analysis. The library construction can be completed by researchers who have basic knowledge and skills in molecular biology and genetics. In addition to the experimental protocol, we provide BID-pipe (https://github.com/y9c/pseudoU-BIDseq), a user-friendly data analysis pipeline for BID-seq, requiring only basic bioinformatic and computational skills to uncover Ψ signatures from NGS data.

Project description:Functional characterization of pseudouridine (Ψ) in mammalian messenger RNA (mRNA) has been hampered by the lack of a quantitative method that maps pseudouridine in the whole transcriptome. We report bisulfite-induced deletion sequencing (BID-seq) that utilizes a bisulfite-mediated reaction to stoichiometrically convert pseudouridine into deletion upon reverse transcription. BID-seq enabled detection of abundant pseudouridine sites with stoichiometry information in several human cell lines and 12 different mouse tissues using 10-20 ng input RNA. We uncovered consensus sequences for pseudouridine in mammalian mRNA and assigned different ‘writer’ proteins to individual pseudouridine deposition. Our results reveal a transcript stabilization role of Ψ sites installed by TRUB1 in human cancer cells. We also detected presence of Ψ within stop codons of mammalian mRNA, and confirmed the role of Ψ in promoting stop codon read-through in vivo. This new method for sensitive and comprehensive detection of Ψ sets the stage for future investigations of the roles of Ψ in diverse biological processes.

Project description:Pseudouridine (Ψ) is an abundant post-transcriptional RNA modification in ncRNA and mRNA. However, transcriptome-wide measurement of individual Ψ sites remains unaddressed. Here, we develop “PRAISE”, via selective chemical labeling of Ψ by bisulfite to induce nucleotide deletion signature during reverse transcription, to realize quantitative assessment of the Ψ landscape in the human transcriptome. Unlike traditional RNA/DNA bisulfite treatment, our approach is based on quaternary base mapping and identifies 2,209 confident Ψ sites in HEK293T cells. By perturbing pseudouridine synthases, we obtained differential mRNA targets of PUS1, PUS7, TRUB1 and DKC1. In addition, we identified known and novel Ψ sites in mitochondrial mRNA, which are catalyzed by a mitochondria-localized isoform of PUS1. Collectively, we provide a reliable, sensitive and convenient method to quantify transcriptome-wide Ψ; we envision this approach would facilitate emerging efforts to elucidate the function and mechanism of mRNA pseudouridylation.

Project description:RT-qPCR of mice brains