Project description:Targeted pseudouridylation identifies a novel Ψ-Ψ codon-anticodon pairing in nonsense suppression and translational recoding

Project description:Transfer RNAs (tRNAs) maintain translational fidelity through strict charging by their cognate aminoacyl-tRNA synthetase and codon:anticodon base pairing with the mRNA at the ribosome. Mistranslation occurs when an amino acid not specified by the genetic code is incorporated into a protein. Since alanyl-tRNA synthetase uniquely recognizes a G3:U70 base pair in alanine tRNAs and the anticodon plays no role in charging, alanine tRNA variants with anticodon mutations have the potential to mistranslate alanine. Our goal was to quantify mis-incorporation of alanine into proteins in Saccharomyces cerevisiae strains expressing one of 57 different alanine tRNA anticodon variants. Using mass spectrometry, we observed mistranslation for 45 of the variants when expressed on single-copy plasmids.

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: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: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 (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:Nonsense mutations, responsible for ~11% of genetic diseases, create premature stop codons (PTCs) and lead to truncated and often non-functional proteins. Recently, programmable RNA pseudouridylation has emerged as a new type of RNA base editor to suppress PTCs. However, current methods suffer from low efficiency and limited precision. Here, we develop RESTART v3, an updated version of RESTART, which utilizes near-cognate tRNAs to improve the readthrough efficiency of pseudouridine-modified PTCs. We show an average of ~5-fold higher editing efficiency than RESTART v2 in cultured cells, currently the most active RNA pseudouridylation tool to mediate PTC readthrough. Moreover, RESTART v3 achieves functional PTC readthrough in disease cell models of cystic fibrosis and Hurler syndrome. Furthermore, RESTART v3 enables accurate incorporation of the original amino acid for nearly half of the PTC sites, considering the naturally occurring frequencies of sense to nonsense codons. In line with the benign off-target effect of RESTART, RESTART v3 does not change the coding information nor the expression level of transcripts with off-target editing; except for the specifically overexpressed tRNA molecule, it does not alter the expression level of endogenous tRNA pool. Overall, RESTART v3 represents an enhanced RNA base editor with increased efficiency and accuracy.

Project description:Nonsense mutations, responsible for ~11% of genetic diseases, create premature stop codons (PTCs) and lead to truncated and often non-functional proteins. Recently, programmable RNA pseudouridylation has emerged as a new type of RNA base editor to suppress PTCs. However, current methods suffer from low efficiency and limited precision. Here, we develop RESTART v3, an updated version of RESTART, which utilizes near-cognate tRNAs to improve the readthrough efficiency of pseudouridine-modified PTCs. We show an average of ~5-fold higher editing efficiency than RESTART v2 in cultured cells, currently the most active RNA pseudouridylation tool to mediate PTC readthrough. Moreover, RESTART v3 achieves functional PTC readthrough in disease cell models of cystic fibrosis and Hurler syndrome. Furthermore, RESTART v3 enables accurate incorporation of the original amino acid for nearly half of the PTC sites, considering the naturally occurring frequencies of sense to nonsense codons. In line with the benign off-target effect of RESTART, RESTART v3 does not change the coding information nor the expression level of transcripts with off-target editing; except for the specifically overexpressed tRNA molecule, it does not alter the expression level of endogenous tRNA pool. Overall, RESTART v3 represents an enhanced RNA base editor with increased efficiency and accuracy.

Project description:Nonsense mutations, responsible for ~11% of genetic diseases, create premature stop codons (PTCs) and lead to truncated and often non-functional proteins. Recently, programmable RNA pseudouridylation has emerged as a new type of RNA base editor to suppress PTCs. However, current methods suffer from low efficiency and limited precision. Here, we develop RESTART v3, an updated version of RESTART, which utilizes near-cognate tRNAs to improve the readthrough efficiency of pseudouridine-modified PTCs. We show an average of ~5-fold higher editing efficiency than RESTART v2 in cultured cells, currently the most active RNA pseudouridylation tool to mediate PTC readthrough. Moreover, RESTART v3 achieves functional PTC readthrough in disease cell models of cystic fibrosis and Hurler syndrome. Furthermore, RESTART v3 enables accurate incorporation of the original amino acid for nearly half of the PTC sites, considering the naturally occurring frequencies of sense to nonsense codons. In line with the benign off-target effect of RESTART, RESTART v3 does not change the coding information nor the expression level of transcripts with off-target editing; except for the specifically overexpressed tRNA molecule, it does not alter the expression level of endogenous tRNA pool. Overall, RESTART v3 represents an enhanced RNA base editor with increased efficiency and accuracy.

Project description:Nonsense mutations, responsible for ~11% of genetic diseases, create premature stop codons (PTCs) and lead to truncated and often non-functional proteins. Recently, programmable RNA pseudouridylation has emerged as a new type of RNA base editor to suppress PTCs. However, current methods suffer from low efficiency and limited precision. Here, we develop RESTART v3, an updated version of RESTART, which utilizes near-cognate tRNAs to improve the readthrough efficiency of pseudouridine-modified PTCs. We show an average of ~5-fold higher editing efficiency than RESTART v2 in cultured cells, currently the most active RNA pseudouridylation tool to mediate PTC readthrough. Moreover, RESTART v3 achieves functional PTC readthrough in disease cell models of cystic fibrosis and Hurler syndrome. Furthermore, RESTART v3 enables accurate incorporation of the original amino acid for nearly half of the PTC sites, considering the naturally occurring frequencies of sense to nonsense codons. In line with the benign off-target effect of RESTART, RESTART v3 does not change the coding information nor the expression level of transcripts with off-target editing; except for the specifically overexpressed tRNA molecule, it does not alter the expression level of endogenous tRNA pool. Overall, RESTART v3 represents an enhanced RNA base editor with increased efficiency and accuracy.