Project description:The participation of transfer RNAs (tRNAs) in fundamental aspects of biology and disease necessitates an accurate, experimentally confirmed annotation of tRNA genes, and curation of precursor and mature tRNA sequences. This has been challenging, mainly because RNA secondary structure and nucleotide modifications, together with tRNA gene multiplicity, complicate sequencing and sequencing read mapping efforts. To address these issues, we developed hydro-tRNAseq, a method based on partial alkaline RNA hydrolysis that generates fragments amenable for sequencing. To identify transcribed tRNA genes, we further complemented this approach with Photoactivatable Crosslinking and Immunoprecipitation (PAR-CLIP) of SSB/La, a conserved protein involved in pre-tRNA processing. Our results show that approximately half of all predicted tRNA genes are transcribed in human cells. We also report predominant nucleotide modification sites, their order of introduction, and identify tRNA leader, trailer and intron sequences. By using complementary sequencing-based methodologies, we present a human tRNA atlas, and determine expression levels of mature and processing intermediates of tRNAs in human cells.

Project description:We analyze whether tRNA quantifications based on small RNA-seq data are informative enough to distinguish between different human cell lines covering multiple tissue types. We therefore apply both small RNA-seq and Hydro-tRNAseq to HEK293 (kidney), HCT116 (colon), HeLa (cervix), MDA-MB-231 (breast), and BJ fibroblasts. First, the correlations between the two methods of identical samples and computational mapping pipeline range between 0.93 and 0.96 for all cell lines. tRNA quantifications from both protocols are compared and significantly higher Spearman correlations are obtained within matching samples versus mismatching cell lines. In consequence, we demonstrate that small RNA-seq quantifications of sample-specific tRNA profiles show a good agreement with conventional tRNA-seq.

Project description:Measurements of cellular tRNA abundance are hampered by pervasive blocks to cDNA synthesis at modified nucleosides and the extensive similarity among tRNA genes. We overcome these limitations with modification-induced misincorporation tRNA sequencing (mim-tRNAseq), which combines a workflow for full-length cDNA library construction from mature tRNA with a simple-to-use computational analysis toolkit. Our method accurately captures tRNA abundance and modification status in multiple eukaryotes and is applicable to any organism with a known genome.

Project description:To investigate differential mitochondrial tRNA gene expression in wild type (WT) and mutant (E423P) mitochondrial RNA polymerase (POLRMT) overexpression flies, we performed Drsophila mitochondrial tRNA-seq according to the Hydro-tRNAseq method. tRNA-seq reads were subjected to 3' - adapter filtering , 3' - adapter trimming and quality control. The tRNAs expression levels were measured by tag count. For each tRNA sequence-based profile, the mapped reads number used to estimate the expression level of each tRNA. The tRNAs expression profiling was calculated based on uniquely mapped reads and including mapped reads, respectively. We found no difference in the relative abundance of mitochondrial individual tRNAs between WT and E423P overexpression flies.

Project description:Specific environmental insults cause the limited fragmentation of transfer RNAs (tRNAs) into tRNA-derived small RNAs (tsRNAs), which have been implicated in a wide range of biological processes. tRNA fragmentation results from endonucleolytic activities targeting single-stranded tRNA regions. However, how a tRNA with a single hydrolyzed phosphodiester bond in the anticodon loop (‘nicked’ tRNA) gives rise to distinct tsRNAs remains poorly understood. After identifying RNA helicases that were able to unwind ‘nicked’ tRNAs in vitro, the specificity of one of those enzymes, DDX3X, was determined by RNA helicase assays on tRNAs, which had been subjected to recombinant Angiogenin. Both in vivo ‘nicked’ tRNAs, DDX3X-unwound ‘nicked’ tRNAs as well as heat-denatured ‘nicked’ tRNAs were subjected to small RNA sequencing.

Project description:Dnmt2 genes are highly conserved tRNA methyltransferases with biological roles in cellular stress responses. The absence of obvious mutant phenotypes under laboratory conditions suggested a function for Dnmt2 under non-physiological conditions. Indeed, Dnmt2 has recently been implicated in various aspects of the cellular stress response and the tRNA methyltransferase activity of Dnmt2 has been shown to interfere with stress-induced fragmentation of various tRNAs. We used adult animals and small RNA sequencing during a heat stress experiment to determine the tRNA fragment abundance and identities in wild-type and Dnmt2 mutant somatic tissues. Dnmt2 mutants produced tRNA fragments with different identities when compared to wild-type controls, indicating the accumulation of non-physiological tRNA-derived molecules in tissues without Dnmt2. 6 samples examined: heterozygous and Dnmt2 mutant under control, heat shock and recovery conditions

Project description:To quantify tRNA expression, we perform hydro-tRNA sequencing (Gogakos et al. 2017) in HACAT (keratinoytes) and HepG2 (liver) human cell lines. This study contains 6 samples. Three replicates for each of the five cell lines. This data complements our previously published data (GEO: GSE137834), which contained five additional cell lines from different tissues: HEK293 (kidney), HCT116 (colon), HeLa (cervix), MDA-MB-231 (breast), and BJ fibroblasts. Therefore, with these extra two cell lines, this constitutes a tissue-wide dataset of tRNA sequencing covering a total of seven human cell lines.

Project description:Increased proliferation and elevated levels of protein synthesis are characteristic of transformed and tumor cells. Though components of the translation machinery are often misregulated in cancers, how tRNA plays a role in cancer cells has not been explored. We compare genome-wide tRNA expression in tumorigenic versus non-tumorigenic breast cell lines, as well as tRNA expression in breast tumors versus normal breast tissues. In tumorigenic versus non-tumorigenic cell lines, nuclear-encoded tRNAs increase by up to 3-fold and mitochondrial-encoded tRNAs increase by up to 5-fold. In tumors versus normal breast tissues, both nuclear and mitochondrial-encoded tRNAs increase by up to 10-fold. This tRNA over-expression is selective and coordinates with the properties of cognate amino acids. Nuclear- and mitochondrial-encoded tRNAs exhibit distinct expression patterns, indicating that tRNAs can be used as biomarkers for breast cancer. We analyzed tRNA expression levels in 2 non-tumorigenic breast cell lines, 6 tumorigenic breast cancer cell lines, 3 normal breast tissue samples, and 9 breast tumor samples. We used a non-tumorigenic breast cell line (MCF10A) as a reference sample in all hybridizations. All data is dye-swapped.

Project description:RNase P is essential to perform the 5’ maturation of tRNA precursors. Beyond the ancestral form of RNase P containing a ribozyme, protein-only RNase P enzymes termed PRORP were identified in eukaryotes. In human mitochondria, PRORP forms a complex with two protein partners to become functional. In plants, although PRORP enzymes are active alone, we investigate their interaction network to understand their integration with gene expression pathways. Here we investigate functional interactions involving the Arabidopsis nuclear RNase P PRORP2. We show, using an immuno-affinity strategy, that PRORP2 makes a complex with the tRNA methyl transferases TRM1A and B in vivo. Beyond RNase P, these enzymes can also interact with RNase Z. We show that TRM1A/B localize in the nucleus and find that their double knock out mutation results in a severe macroscopic phenotype. Using a combination of immuno-detections, mass spectrometry and a transcriptome wide tRNAseq approach, we observe that TRM1A/B are responsible for the m2,2G26 modification of 70% of cytosolic tRNAs in vivo. We use the transcriptome wide tRNAseq approach as well as RNA blot hybridizations to show that RNase P activity is impaired in TRM1A/B mutants for specific tRNAs, in particular, tRNAs containing a m2,2G modification at position 26 that are strongly down-regulated in TRM1A/B mutants. Altogether, results indicate that the m2,2G adding enzymes TRM1A/B functionally cooperate with nuclear RNase P in vivo for the early steps of cytosolic tRNAs biogenesis.

Project description:Dnmt2 genes are highly conserved tRNA methyltransferases with biological roles in cellular stress responses. The absence of obvious mutant phenotypes under laboratory conditions suggested a function for Dnmt2 under non-physiological conditions. Indeed, Dnmt2 has recently been implicated in various aspects of the cellular stress response and the tRNA methyltransferase activity of Dnmt2 has been shown to interfere with stress-induced fragmentation of various tRNAs. We used adult animals and small RNA sequencing during a heat stress experiment to determine the tRNA fragment abundance and identities in wild-type and Dnmt2 mutant somatic tissues. Dnmt2 mutants produced tRNA fragments with different identities when compared to wild-type controls, indicating the accumulation of non-physiological tRNA-derived molecules in tissues without Dnmt2.