Project description:Transfer RNAs (tRNAs) play an essential role in protein synthesis by linking the nucleic acid sequences of gene products to the amino acid sequences of proteins. Although only 32 tRNAs are needed to decode all 61 sense codons in the genetic code, there are > 400 functional tRNA genes in the humans. Adding to this diversity, there are many single nucleotide polymorphisms in tRNAs across our population, including anticodon variants that mistranslate the genetic code. In human genomes, we identified three alanine tRNA (tRNAAla) variants with non-synonymous anticodon mutations: tRNAAlaCGC G35T, tRNAAlaUGC G35A, and tRNAAlaAGC C36T. Since alanyl-tRNA synthetase (AlaRS) does not recognize the anticodon, we hypothesized that these human tRNAAla variants will mis-incorporate Ala at glutamate (Glu), valine (Val), and threonine (Thr) codons. We found that human cells expressing the naturally occurring tRNAAla variants were characterized by defects in protein production and cell growth. Using mass spectrometry, we confirmed and estimated Ala mis-incorporation levels at Glu (0.7%), Val (5%) and Thr (0.1%) codons. Although Ala mis-incorporation was higher at Val codons, cells mis-incorporating Ala at Glu codons had the most severe defect in protein production. Significant growth defects were observed in cells mistranslating Glu and Val codons, while the low level of mis-incorporation at Thr codons was well-tolerated in human cells. The data demonstrate the ability of natural human tRNAAla variants to generate mistranslation leading to a phenotypic response that depends on the nature of the amino acid replacement and the level of mis-incorporation.

Project description:Pulmonary veno-occlusive disease (PVOD) is a rare and severe form of pulmonary arterial hypertension, characterized by progressive obstruction of small pulmonary vessels and a lack of effective therapeutic options. Our previous research, utilizing a mitomycin C (MMC)-induced rat model, demonstrated that activation of the integrated stress response (ISR) via protein kinase R (PKR) is a critical driver of endothelial dysfunction and pulmonary vascular remodeling. However, it remains unclear whether PKR is the sole mediator of ISR activation and the pathogenesis of PVOD under the MMC treatment. In this study, we administered the same dose of MMC used in rats to control (Ctrl) and PKR knockout (KO) mice. Consistent with observations in rats, Ctrl mice exhibited ISR activation in the vascular endothelium and rapidly developed vascular remodeling in both arteries and veins following MMC treatment. In contrast, KO mice showed no evidence of ISR activation or vascular remodeling under same conditions. Proteomic analysis revealed that the PKR-ISR axis perturbs proteostasis in Ctrl mice but not in KO mice. These findings highlight the essential role of PKR-mediated ISR activation and the disruption of proteostasis in the pathogenesis of PVOD, placing PKR as a promising therapeutic target for this disease.

Project description:In neurodegenerative diseases, including pathologies with well-known causative alleles, genetic factors that modify severity or age of onset are not entirely understood. We recently documented the unexpected prevalence of transfer RNA (tRNA) mutants in the human population, including variants that cause amino acid mis-incorporation. We hypothesized that a mistranslating tRNA will exacerbate toxicity and modify the molecular pathology of disease-causing alleles and investigated the combinatorial effects of tRNA variants in cellular models of Huntington’s disease. This dataset represents MS/MS data confirming Phenylaline to Serine amino acid misincorporation events caused by the tRNA-Ser G35A variant described in our study. The wildtype (WT) or mistranslating tRNA (VAR) were expressed in murine N2a cells along with mCherry protein. We affinity purified the mCherry protein to search for Ser misincorporation events at Phe codons.

Project description:Mature tRNA pools were measured using an adaptation of Y-shaped Adapter-ligated MAture tRNA sequencing (YAMAT-seq) (Shigematsu et al., 2017) in nine strains derived from the model bacterium, Pseudomonas fluorescens SBW25. The aim of the experiment was to determine the effect on the mature tRNA pool of (i) removing the single-copy serCGA gene by genetic engineering, and (ii) duplicating the serTGA gene during a subsequent, compensatory evolution experiment. We found that (i) results in the loss of tRNA-Ser(CGA) from the mature tRNA pool, and (ii) results in a 2-fold higher expression of tRNA-Ser(UGA). tRNA-Ser(UGA) presumably substitutes for tRNA-Ser(CGA) by wobble base pairing to translate codon 5'-UCG-3'.

Project description:Understanding the interplay of the proteome and the metabolome aids in understanding cellular phenotypes. To enable more robust inferences from such multi-omics analyses, combining proteomic and metabolomic datasets from the same sample provides major benefits by reducing technical variation between extracts during the pre-analytical phase, decreasing sample variation due to varying cellular content between aliquots, and limiting the required sample amount. We evaluated the advantages, practicality and feasibility of a single-sample workflow for combined proteome and metabolome analysis. In the workflow, termed MTBE-SP3, we combined a fully automated protein lysis and extraction protocol (autoSP3) with a semi-automated biphasic 75% EtOH/MTBE extraction for quantification of polar/non-polar metabolites. Additionally, we compared the resulting proteome of various biological matrices (FFPE tissue, fresh-frozen tissue, plasma, serum and cells) between autoSP3 and MTBE-SP3. Our analysis revealed that the single-sample workflow provided similar results to those obtained from autoSP3 alone, with an 85-98% overlap of proteins detected across the different biological matrices. Additionally, it provides distinct advantages by decreasing (tissue) heterogeneity by retrieving metabolomics and proteomic data from the identical biological material, and limiting the total amount of required material. Lastly, we applied MTBE-SP3 to a lung adenocarcinoma cohort of 10 patients. Integrating the metabolic and proteomic alterations between tumour and non-tumour adjacent tissue yielded consistent data independent of the method used. This revealed mitochondrial dysfunction in tumor tissue through deregulation of OGDH, SDH family enzymes and PKM. In summary, MTBE-SP3 enables the facile and confident parallel measurement of proteins and metabolites obtained from the same sample. This workflow is particularly applicable for studies with limited sample availability and offers the potential to enhance the integration of metabolomic and proteomic datasets.

Project description:tRNA-derived small RNAs (tsRNA) are a new type of noncoding RNAs that can be mainly classified into two groups: tRFs (tRNA-derived fragments) and tiRNAs (tRNA halves). The abnormal expression of tsRNAs is known to play an important role in the biological progression of breast cancer. However, it's still unclear about the mechanism of tsRNAs in cancer. tRF-1-Ser is a tRF that is high expression in breast cancer and negatively regulated by 25(OH)D. Our study aims to find out the effect of tRF-1-Ser on breast cancer and explore the change of RNA in tRF-1-Ser knock-down breast cancer cells.

Project description:The CCA-adding enzyme adds CCA to the 3' ends of transfer RNAs (tRNAs), a critical step in tRNA biogenesis that generates the amino acid attachment site. We found that the CCA-adding enzyme plays a key role in tRNA quality control by selectively marking unstable tRNAs and tRNA-like small RNAs for degradation. Instead of adding CCA to the 3' ends of these transcripts, CCA-adding enzymes from all three kingdoms of life add CCACCA. Here, we report deep sequencing analysis of the 3' ends of tRNA-Ser-CGA and tRNA-Ser-UGA from S. cerevisiae strains and show that hypomodified mature tRNAs are subjected to CCACCA (or poly(A) addition) as part of a rapid tRNA decay pathway in vivo. We conjecture that CCACCA addtion is a universal mechanism for controlling tRNA levels and preventing errors in translation. 121 samples analyzed in total, representing time courses of 10 different yeast strains; Biological replicates for each time point are included

Project description:The CCA-adding enzyme adds CCA to the 3' ends of transfer RNAs (tRNAs), a critical step in tRNA biogenesis that generates the amino acid attachment site. We found that the CCA-adding enzyme plays a key role in tRNA quality control by selectively marking unstable tRNAs and tRNA-like small RNAs for degradation. Instead of adding CCA to the 3' ends of these transcripts, CCA-adding enzymes from all three kingdoms of life add CCACCA. Here, we report deep sequencing analysis of the 3' ends of tRNA-Ser-CGA and tRNA-Ser-UGA from S. cerevisiae strains and show that hypomodified mature tRNAs are subjected to CCACCA (or poly(A) addition) as part of a rapid tRNA decay pathway in vivo. We conjecture that CCACCA addtion is a universal mechanism for controlling tRNA levels and preventing errors in translation.

Project description:Differential mRNA translation efficiency (mTE) of codons is important in regulating protein synthesis, cellular states, and can change in response to amino acid (AA) availability. While the mTE of codons is canonically associated with their corresponding transfer RNA (tRNA) isoacceptors, its regulation by AAs in mammalian cells remains unexplored. We found that ELAC2, a 3’ tRNA maturation endonuclease, decreases the mTE of UC[U/C] serine (Ser) codons in response to Ser-limitation. Ablation of ELAC2 restored UC[U/C] mTE but reduced the mTE of AG[U/C] Ser codons. Among the tRNASer isoacceptors, tRNASer(GCU) decreased the most in ELAC2-deficient cells. Surprisingly, tRNASer(GCU) delivery restored AG[U/C] mTE and reduced UC[C/U] mTE in ELAC2-deficient cells. Finally, we deciphered the effects of Ser-sensitive codons on mRNA translation and the human proteome. Our study revealed that in response to Ser-limitation, regulation of tRNASer(GCU) levels fine-tune the mTE of UC[C/U] or AG[U/C] Ser-sensitive codons and shapes the proteome.

Project description:In this study, a unique tea cultivar ‘Anxi kucha’ was discovered for the first time, which is rich in both secondary metabolites. In the targeted data, theacrine (17.44 mg/g) was detected only in the ‘Anxi kucha’ tea plant in the test materials. The content of EGCG3"Me in ‘Anxi kucha’ (11.25mg/g), ‘Tieguanyin’ (5.32mg/g) and ‘Fudingdabaicha’ (0.93mg/g) showed high, medium and low changes. Through proteomics and transcriptomics, it was identified that the key pathways for the synthesis of theacrine and EGCG3"Me were the purine metabolism pathway and the flavonoid biosynthesis pathway, respectively. Combined proteome-transcriptome-metabolome analysis showed that SAMS3, APRT1, IMPDH, and TCS1 were the main enzymes promoting theacrine synthesis; CHI1, CHI2, FLS2 and LAR1 were the main enzymes that promote the synthesis of EGCG3"Me. The results of transcription factor analysis showed that MYB4 and bHLH74 had positive regulatory effects on the synthesis of theacrine and EGCG3"Me. Theacrine and EGCG3"Me are both bitter compounds. This study provides a valuable material rich in theacrine and EGCG3"Me, which provides a material basis for further development and utilization in the field of tea health food and a theoretical basis for studying the functional components of tea.