Project description:Purpose:Pseudouridine (Ψ) is the most abundant RNA epigenetic modification and plays vital roles in various biological processes. However, its biogenesis and functions in mRNAs remain elusive. Method:Here, we developed an approach for enriching Ψ sites with deep sequencing (edu-Ψ-seq), which utilizes both exoribonuclease and restriction endonuclease activity to eliminate other nucleosides or reads without Ψ modifications. Results:Using edu-Ψ-seq approach in the dyskerin pseudouridine synthase 1 (DKC1) knockdown cells, we identified that more than 100 pseudouridines could be catalyzed by DKC1 in human mRNAs and non-coding RNAs (ncRNAs). Surprisingly, we discovered, for the first time, 10 pseudouridines in mRNAs might be guided by 11 small nucleolar ncRNAs (snoRNAs). Interestingly, we found that SNORA10 could guide DKC1 protein to induce the pseudouridylation of RPL15 mRNA. Importantly, loss of SNORA10 impaired the protein synthesis of RPL15 and inhibited cell proliferation. Conclusion:Overall, our study not only developed a powerful method for detecting Ψ sites but also uncovered another layer of gene expression regulation that involves crosstalk among snoRNAs, mRNA pseudouridylation and protein synthesis.

Project description:Pseudouridine is the most abundant modification occurring on RNA, yet with the exception of a few well-studied RNA molecules little is known about the modified positions and their function(s). Here, we develop Ψ-seq, a method for transcriptome-wide quantitative mapping of pseudouridine. We validate Ψ-seq with synthetic spike-ins and de novo identification of the vast majority of previously reported pseudouridylated positions. Ψ-seq permits discovery of hundreds of novel pseudouridine modifications in human and yeast mRNAs and snoRNAs. Knockdown and knockout of pseudouridine synthases uncovers the cognate PUSs mediating pseudouridine catalysis at these individual novel sites and their target sequence features. In both human and yeast pseudouridine formation on mRNA depends on both site-specific PUSs – often guided by a specific sequence motif - and snoRNA-guided PUSs. Importantly, upon heat shock in yeast, Pus7-mediated pseudouridylation is induced at >200 sites in diverse mRNAs. Pus7 deletion in yeast leads to decreased recovery from heat shock and decreased RNA levels at otherwise pseudouridylated messages, suggesting a role for pseudouridine in enhancing transcript stability. Pseudouridine stoichiometries in rRNA are highly conserved from yeast to mammals, but are reduced in cells derived from dyskeratosis congenita patients, where the pseudouridine synthase DKC1 is mutated, compared to age matched controls. Our results establish pseudouridine as a ubiquitous and dynamic modification in mRNA, and provide a sensitive, quantitative and transcriptome-wide methodology to address its underlying mechanisms and function.

Project description:Pseudouridine is the most abundant modification occurring on RNA, yet with the exception of a few well-studied RNA molecules little is known about the modified positions and their function(s). Here, we develop M-NM-(-seq, a method for transcriptome-wide quantitative mapping of pseudouridine. We validate M-NM-(-seq with synthetic spike-ins and de novo identification of the vast majority of previously reported pseudouridylated positions. M-NM-(-seq permits discovery of hundreds of novel pseudouridine modifications in human and yeast mRNAs and snoRNAs. Knockdown and knockout of pseudouridine synthases uncovers the cognate PUSs mediating pseudouridine catalysis at these individual novel sites and their target sequence features. In both human and yeast pseudouridine formation on mRNA depends on both site-specific PUSs M-bM-^@M-^S often guided by a specific sequence motif - and snoRNA-guided PUSs. Importantly, upon heat shock in yeast, Pus7-mediated pseudouridylation is induced at >200 sites in diverse mRNAs. Pus7 deletion in yeast leads to decreased recovery from heat shock and decreased RNA levels at otherwise pseudouridylated messages, suggesting a role for pseudouridine in enhancing transcript stability. Pseudouridine stoichiometries in rRNA are highly conserved from yeast to mammals, but are reduced in cells derived from dyskeratosis congenita patients, where the pseudouridine synthase DKC1 is mutated, compared to age matched controls. Our results establish pseudouridine as a ubiquitous and dynamic modification in mRNA, and provide a sensitive, quantitative and transcriptome-wide methodology to address its underlying mechanisms and function. Examination of m6A methylation in human Hek293 and A549 cell lines, in human embryonic stem cells (ESCs) undergoing differentiation to neural progenitor cells (NPCs), in OKMS inducible fibroblasts reprogrammed into iPSC, and upon knockdown of factors using siRNAs or shRNAs.

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:Pseudouridine (Ψ) is an ubiquitous RNA modification, present in the tRNAs and rRNAs of species across all domains of life. Conserved pseudouridine synthases modify the mRNAs of diverse eukaryotes, but the modification has yet to be identified in bacterial mRNAs. Here, we report the discovery of pseudouridines in mRNA from E. coli. By testing the mRNA modification capacity of all 11 known pseudouridine synthases, we identify RluA as the predominant mRNA-modifying enzyme, modifying the majority of high-confidence sites.

Project description:Pseudouridine (Ψ) is an ubiquitous RNA modification, present in the tRNAs and rRNAs of species across all domains of life. Conserved pseudouridine synthases modify the mRNAs of diverse eukaryotes, but the modification has yet to be identified in bacterial mRNAs. Here, we report the discovery of pseudouridines in mRNA from E. coli. By testing the mRNA modification capacity of all 11 known pseudouridine synthases, we identify RluA as the predominant mRNA-modifying enzyme, modifying the majority of high-confidence sites.

Project description:We present RESTART, a programmable approach employing engineered artificial guide snoRNA (gsnoRNA) to achieve precise and efficient site-directed pseudouridylation in mammalian cells without changing the coding information. We identified and optimized gsnoRNA scaffolds, which can mediate PTC-readthrough by recruiting endogenous DKC1 (pseudouridine synthase). We also found combining exogenous non-canonical DKC1-isoform3 with gsnoRNA can further improve the efficiency of PTC-readthrough. We applied such strategies to correct disease-relevant nonsense mutations, while maintaining the global Ψ abundance in cellular RNA and gene expression. Collectively, RESTART would become a powerful tool for therapeutics and basic research.

Project description:RNA can be extensively modified post-transcriptionally with >170 covalent modifications, expanding its functional and structural repertoire. Pseudouridine (Ψ), the most abundant modified nucleoside in rRNA and tRNA, has recently been found within mRNA molecules. Due to technical challenges, it remained unclear whether pseudouridylation of mRNA can be snoRNA-guided, which has important implications for understanding the physiological target spectrum of snoRNAs and for their potential therapeutic exploitation in genetic diseases. Here, using a massively parallel reporter based strategy we simultaneously interrogate Ψ levels across hundreds of synthetic constructs with predesigned complementarity against endogenous snoRNAs. Our results demonstrate that snoRNA-mediated pseudouridylation can occur on mRNA targets. However, this is typically achieved at low efficiencies, and is constrained by the localization of mRNA, by the expression levels of snoRNAs and by the length of the snoRNA:mRNA complementarity stretches. We exploited these insights for the design of snoRNAs targeting pseudouridylation at premature termination codons, which was previously suggested to suppress translational termination. However, in contrast to previous studies, in this and follow-up experiments we observe no evidence for readthrough of pseudouridylated stop codons. Our study enhances our understanding of the scope, ‘design rules’ and constraints of snoRNA-mediated pseudouridylation, and challenges a key functional outcome associated with this modification.

Project description:Post-transcriptional modifications of mRNA have emerged as novel regulators of gene expression. Pseudouridylation is the most abundant and widespread type of RNA modification in living organisms; however, the biological role of pseudouridine in mRNAs remains poorly understood. Here, we show that the pseudouridine synthase dyskerin associates with RNA polymerase II and is enriched at RNA polymerase II-transcribed genes genome-wide. As part of the H/ACA complex, dyskerin binds to thousands of mRNAs and is responsible for their pseudouridylation, an action that occurs in chromatin and does not appear to require a fully complementary guide RNA. In cells lacking dyskerin, pseudouridylation of mRNAs is reduced, while at the same time, de novo protein production is enhanced, indicating that pseudouridylation of mRNAs by dyskerin interferes with translation. Accordingly, pseudouridylation of an mRNA by dyskerin in vitro results in reduced translation of that mRNA. Moreover, in patients with dyskeratosis congenita caused by inherited mutations in the DKC1 gene, binding between mutated dyskerin and mRNAs is altered and pseudouridylation of mRNAs severely reduced. Our findings reveal a new critical function of the H/ACA complex in directing translation control with important implications for development and disease. 

Project description:Post-transcriptional modifications of mRNA have emerged as novel regulators of gene expression. Pseudouridylation is the most abundant and widespread type of RNA modification in living organisms; however, the biological role of pseudouridine in mRNAs remains poorly understood. Here, we show that the pseudouridine synthase dyskerin associates with RNA polymerase II and is enriched at RNA polymerase II-transcribed genes genome-wide. As part of the H/ACA complex, dyskerin binds to thousands of mRNAs and is responsible for their pseudouridylation, an action that occurs in chromatin and does not appear to require a fully complementary guide RNA. In cells lacking dyskerin, pseudouridylation of mRNAs is reduced, while at the same time, de novo protein production is enhanced, indicating that pseudouridylation of mRNAs by dyskerin interferes with translation. Accordingly, pseudouridylation of an mRNA by dyskerin in vitro results in reduced translation of that mRNA. Moreover, in patients with dyskeratosis congenita caused by inherited mutations in the DKC1 gene, binding between mutated dyskerin and mRNAs is altered and pseudouridylation of mRNAs severely reduced. Our findings reveal a new critical function of the H/ACA complex in directing translation control with important implications for development and disease.