Project description:Pseudouridine (Ψ) is known for decades, but its flexibility in base-pairing remains unclear. This study engineers artificial box H/ACA guide RNAs to direct pseudouridylation at the uridine of a premature termination codon (PTC; UAA, UAG, or UGA) within an intron-less mRNA and U36 of the anticodon of a matching tRNA in yeast and human cells. Targeted pseudouridylation leads to the formation of a Ψ-Ψ codon-anticodon pair, which, together with the other two Watson-Crick base pairs in the codon-anticodon duplex, significantly improves codon-anticodon recognition, robustly promoting PTC read-through. The intron-less mRNA level remains unchanged with or without guide RNAs. Additionally, pseudouridylation does not impact tRNA stability or charging. Our results show that nonsense suppression is promoted by the high affinity of the Ψ-Ψ pair, which is verified by melting curve analysis. This work has identified an unusual Ψ-Ψ base pair, which contributes significantly to codon-anticodon recognition and translational recoding.

Project description:When eukaryotic cells are deprived of amino acids, uncharged tRNAs accumulate and activate the conserved GCN2 protein kinase. We examine how yeast growth and tRNA charging or aminoacylation is affected during amino acid depletion in the presence and absence of GCN2. tRNA charging is measured using a microarray technique which allows for simultaneous measurement of all cytosolic tRNAs. A fully prototrophic and its isogenic GCN2 deletion strain were used. We measured relative tRNA charging levels in yeast strains with an intact and deleted GCN2.

Project description:Pseudouridine (Psi) is one of the most frequent post-transcriptional modification of RNA. Enzymatic Psi modification occurs on rRNA, snRNA, snoRNA, tRNA, non-coding RNA and has recently been discovered on mRNA. Transcriptome-wide detection of Psi (Psi-seq) has yet to be performed for the widely studied model organism Dro­­­­sophila melanogaster. Here, we optimized Psi-seq analysis for this species and have identified thousands of Psi modifications throughout the female fly head transcriptome. We find that Psi is widespread on both cellular and mitochondrial rRNAs. In addition, more than a thousand Psi sites were found on mRNAs. When pseudouridinylated, mRNAs frequently had many Psi sites. Many mRNA Psi sites are present in genes encoding for ribosomal proteins, and many are found in mitochondrial encoded RNAs, further implicating the importance of pseudouridinylation for ribosome and mitochondrial function. The 7SLRNA of the signal recognition particle is the non-coding RNA most enriched for Psi. The three mRNAs most enriched for Psi encode highly-expressed yolk proteins (YP1, YP2, YP3). By comparing the pseudouridine profiles in the RluA-2 mutant and the w1118 control genotype, we identified Psi sites that were missing in the mutant RNA as potential RluA-2 targets. Finally, differential gene expression analysis of the mutant transcriptome indicates a major impact of loss of RluA-2 on the ribosome and translational machinery.

Project description:Pseudouridine (Ψ) is an abundant modification in small RNA and is catalyzed by multiple pseudouridine synthases (PUSs). However, the substrate specificity of human PUSs are not fully understood. In this study, we adopted PRAISE, a quantitative Ψ detection method, to profile pseudouridylation in small RNA, including cytosolic and mitochondrial tRNAs, snRNA, and snoRNA. We found that pseudouridylation of snoRNAs can be mediated not only by RNA-guided DKC1, but also stand-alone enzyme PUS7. Interestingly, we found that several PUS enzymes, which install nearby Ψ sites within tRNA anticodon stem-loop, can influence pseudouridylation level catalyzed by other PUSs. Typical examples include PUS1, RPUSD1, and PUS7, revealing a novel interplay among human PUSs during Ψ formation. For the three RluA family enzymes, we found that in addition to the canonical substrate Ψ30, RPUSD1 also catalyzes Ψ72 of tRNA-Arg isoacceptors. RPUSD2 pseudouridylates Ψ31 of mt-tRNALeu(CUN), and Ψ32 of mt-tRNAPro and mt-tRNACys, and hence is functionally similar to yeast Pus9. RPUSD3 does not modify tRNA at all, consistent with its lack of a catalytic residue. Together, using quantitative Ψ profiling, our study characterized the tRNA substrates of PUS enzymes and revealed unexpected interplay among human PUSs in tRNA pseudouridylation.

Project description:Pseudouridine (Ψ), the isomer of uridine, is ubiquitous in most RNA families, including tRNA, rRNA and mRNA. Pseudouridine synthase 3 (PUS3) catalyzes pseudouridylation of position 38/39 in tRNAs, but whether it can modify other RNA types, including mRNA, remains elusive. Here, we determine the single particle cryo-EM structure of apo and tRNA-bound human PUS3, showing how it forms a symmetric homodimer that recognizes the characteristic L-shape of tRNA across two distinct interaction interfaces. Structure-guided and patient-derived mutations validate our structural findings in complementary biochemical assays. Furthermore, we deleted PUS1 and PUS3 in HEK293 cells and used Pseudo-seq to detect Ψ sites in the transcriptome. Although PUS1-dependent sites were detectable in tRNA and mRNA, we did not find any evidence for PUS3 modifying other RNA classes than tRNA. In summary, our work provides the molecular basis for PUS3-mediated tRNA modification in humans and aids in understanding how impairments in its activity lead to intellectual disabilities through defects in tRNA modifications.

Project description:Pseudouridine synthases (PUSs) are responsible for the installation of pseudouridine (Ψ) modification in RNA. However, the activity and function of the PUS enzymes remain largely unexplored. Here we focus on human PUS10 and find that it co-expresses with the microprocessor (DROSHA–DGCR8 complex). Depletion of PUS10 results in a marked reduction of the expression level of a large number of mature miRNAs and concomitant accumulation of unprocessed primary microRNAs (pri-miRNAs) in multiple human cells. Mechanistically, PUS10 directly binds to pri-miRNAs and interacts with the microprocessor to promote miRNA biogenesis. Unexpectedly, this process is independent of the catalytic activity of PUS10. Additionally, we develop a sequencing method to profile Ψ in the tRNAome and report PUS10-dependent Ψ sites in tRNA. Collectively, our findings reveal differential functions of PUS10 in nuclear miRNA processing and in cytoplasmic tRNA pseudouridylation.

Project description:We profiled the cellular tRNA charging landscape using next-generation sequencing and identified a subset of tRNA that sense nutrients. The charging levels of tRNAGln were exclusively and significantly decreased in response to amino acid starvation.

Project description:We profiled the cellular tRNA charging landscape using next-generation sequencing and identified a subset of tRNA that sense nutrients. The charging levels of tRNAGln were exclusively and significantly decreased in response to amino acid starvation.

Project description:We profiled the cellular tRNA charging landscape using next-generation sequencing and identified a subset of tRNA that sense nutrients. The charging levels of tRNAGln were exclusively and significantly decreased in response to amino acid starvation.

Project description:We profiled the cellular tRNA charging landscape using next-generation sequencing and identified a subset of tRNA that sense nutrients. The charging levels of tRNAGln were exclusively and significantly decreased in response to amino acid starvation.