NSUN6 is a human RNA methyltransferase that catalyzes formation of m5C72 in specific tRNAs

Many cellular RNAs require modification of specific residues for their biogenesis, structure, and function. 5-methylcytosine (m⁵C) is a common chemical modification in DNA and RNA but in contrast to the DNA modifying enzymes, only little is known about the methyltransferases that establish m⁵C modifications in RNA. The putative RNA methyltransferase NSUN6 belongs to the family of Nol1/Nop2/SUN domain (NSUN) proteins, but so far its cellular function has remained unknown. To reveal the target spectrum of human NSUN6, we applied UV crosslinking and analysis of cDNA (CRAC) as well as chemical crosslinking with 5-azacytidine. We found that human NSUN6 is associated with tRNAs and acts as a tRNA methyltransferase. Furthermore, we uncovered tRNA^Cys and tRNA^Thr as RNA substrates of NSUN6 and identified the cytosine C72 at the 3′ end of the tRNA acceptor stem as the target nucleoside. Interestingly, target recognition in vitro depends on the presence of the 3′-CCA tail. Together with the finding that NSUN6 localizes to the cytoplasm and largely colocalizes with marker proteins for the Golgi apparatus and pericentriolar matrix, our data suggest that NSUN6 modifies tRNAs in a late step in their biogenesis.     

Increased activity of rat liver N2-guanine tRNA methyltransferase II in response to liver damage

Alterations in rat liver transfer RNA (tRNA) methyltransferase activities have been observed after liver damage by various chemicals or by partial hepatectomy. The qualitative and quantitative nature of these activity changes and the time course for their induction have been studied. Since homologous tRNAs are essentially fully modified in vivo, E. coli tRNAs were used as in vitro substrates for the rat liver enzymes in these studies. Each of the liver-damaging agents tested rapidly caused increases in activities of the enzyme(s) catalyzing methyl group transfer to tRNAs that have an unmodified guanine at position 26 from the 5′ end of the molecule. This group of tRNAs includes E. coli tRNA^Nfmet, tRNA^Ala₁, tRNA^Leu₁, or ^Leu₂, and tRNA^Ser₃ (Group 1). In each case N²-methylguanine and N²,N²-dimethylguanine represented 90% or more of the products of these in vitro methylations. The product and substrate specificity observed are characteristic of N²-guanine methyltransferase II ($\text{S-}\text{adenosyl}\text{-}\text{L}\text{-}\text{methionine:tRNA}$ (guanine-2)-methyltransferase, EC 2.1.1.32). In crude and partially purified preparations derived from livers of both control and treated animals this enzyme activity was not diminished significantly by exposure to 50°C for 10 min. The same liver-damaging agents induced little or no change in the activities of enzymes that catalyze methyl group transfer to various other E. coli tRNAs that do not have guanine at position 26 (Group 2). The results of mixing experiments appear to rule out the likelihood that the observed enzyme activity changes are due to stimulatory or inhibitory materials present in the enzyme preperations from control or treated animals. Thus, our experiments indicate that liver damage by each of several different methods, including surgery or administration of chemicals that are strong carcinogens, hepatotoxins, or cancer-promoting substances, all produce changes in liver tRNA methyltransferase activity that represent a selective increase in activity of N²-guanine tRNA methyltransferase II. It is proposed that the specificity of this change is not fortuitous, but is the manifestation of an as yet unidentified regulatory process.     

Overexpression of initiator methionine tRNA leads to global reprogramming of tRNA expression and increased proliferation in human epithelial cells

Transfer RNAs (tRNAs) are typically considered housekeeping products with little regulatory function. However, several studies over the past 10 years have linked tRNA misregulation to cancer. We have previously reported that tRNA levels are significantly elevated in breast cancer and multiple myeloma cells. To further investigate the cellular and physiological effects of tRNA overexpression, we overexpressed tRNA_i^Met in two human breast epithelial cell lines. We then determined tRNA abundance changes and performed phenotypic characterization. Overexpression of tRNA_i^Met significantly altered the global tRNA expression profile and resulted in increased cell metabolic activity and cell proliferation. Our results extend the relevance of tRNA overexpression in human cells and underscore the complexity of cellular regulation of tRNA expression.     

Human Tyrosine tRNA Is Also Internally Cleavable by E. coli Ribonuclease P RNA Ribozyme in Vitro

Transfer RNA is an essential molecule for biological system, and each tRNA molecule commonly has a cloverleaf structure. Previously, we experimentally showed that some Drosophila tRNA (tRNA^Ala, tRNA^His, and tRNA_i ^Met) molecules fit to form another, non-cloverleaf, structure in which the 3'-half of the tRNA molecules forms an alternative hairpin, and that the tRNA molecules are internally cleaved by the catalytic RNA of bacterial ribonuclease P (RNase P). Until now, the hyperprocessing reaction of tRNA has only been reported with Drosophila tRNAs. This time, we applied the hyperprocessing reaction to one of human tRNAs, human tyrosine tRNA, and we showed that this tRNA was also hyperprocessed by E. coli RNase P RNA. This tRNA is the first example for hyperprocessed non-Drosophila tRNAs. The results suggest that the hyperprocessing reaction can be a useful tool to detect destablized tRNA molecules from any species.     

Genome-wide analysis revealed novel molecular features and evolution of Anti-codons in cyanobacterial tRNAs

Transfer RNAs (tRNAs) play important roles to decode the genetic information contained in mRNA in the process of translation. The tRNA molecules possess conserved nucleotides at specific position to regulate the unique function. However, several nucleotides at different position of the tRNA undergo modification to maintain proper stability and function. The major modifications include the presence of pseudouridine (Ψ) residue instead of uridine and the presence of m⁵-methylation sites. We found that, Ψ13 is conserved in D-stem, whereas Ψ38 & Ψ39 were conserved in the anti-codon loop (AL) and anti-codon arm (ACA), respectively. Furthermore, Ψ55 found to be conserved in the Ψ loop. Although, fourteen possible methylation sites can be found in the tRNA, cyanobacterial tRNAs were found to possess conserved G9, m³C₃₂, C₃₆, A₃₇, m⁵C₃₈ and U₅₄ methylation sites. The presence of multiple conserved methylation sites might be responsible for providing necessary stability to the tRNA. The evolutionary study revealed, tRNA^Met and tRNA^Ile were evolved earlier than other tRNA isotypes and their evolution is date back to at least 4000 million years ago. The presence of novel pseudouridination and m⁵-methylation sites in the cyanobacterial tRNAs are of particular interest for basic biology. Further experimental study can delineate their functional significance in protein translation.     

Specific binding of bovine immunoglobulins to Sepharose and Sephadex

Bacteriophage T5 BglII/HindIII DNA fragment (803 basepairs), containing the genes for 2 tRNAs and 2 RNAs with unknown functions, was cloned in the plasmid pBR322. The analysis of DNA sequence indicates that tRNA genes code isoacceptor tRNAs^Ser (tRNA^Ser₁ and tRNA^Ser₂) with anticodons UGA and GGA, respectively. The main unusual structural feature of these tRNAs is the presence of extra non-basepaired nucleotides in the joinings of stem ‘b’ with stems ‘a’ and ‘c’.     

Escherichia coli formylmethionine tRNA: methylation of specific guanine and adenine residues catalyzed by HeLa cells tRNA methylases and the effect of these methylations on its biological properties

Purified HeLa cell tRNA methylases have been used for site-specific methylations of Escherichia coli formylmethionine transfer ribonucleic acid (tRNA^fMet). Guanine-N²-methylase catalyzed the methylation of a specific guanine residue (G₂₇) and adenine-1-methylase that of a specific adenine residue (A₅₉). The combined action of both of these enzymes leads to a total incorporation of two methyl groups and results in the methylation of both G₂₇ and A₅₉.The effect of introducing additional methyl groups on the function of tRNA has been studied by a comparison in vitro of the biological properties of tRNA^fMet and enzymically methylated tRNA^fMet. It was found that none of the following properties of E. coli tRNA^fMet are altered to any significant extent by methylation: (a) rate, extent, and specificity of aminoacylation, (b) ability of methionyl-tRNA to be enzymically formylated, and (c) ability of formylmethionyl-tRNA to initiate protein synthesis in cell-free extracts of E. coli in the presence of f2 RNA as messenger. Also, the temperature versus absorbance profile of the doubly methylated tRNA^fmet was virtually identical to that of the E. coli tRNA^fMet, and enzymically methylated tRNA^fmet resembled tRNA^fMet in that both were resistant to deacylation by E. coli, N-acylaminoacyl-tRNA hydrolase.     

Glycine and asparagme tRNA sequences from the archaebacteriuin,Methanobacterium thermoautotrophicum

Two tRNA sequences from Methanobacterium thermoautotrophium are reported. Both tRNA^Gly_GCC and tRNA_NUU^Asn, the first tRNA sequences from methanogens, were determined by partial hydrolyses (both chemical and enzymatic) and analyzed by gel electrophoresis. The two tRNAs contain the unusual T-loop modifications, Cm and m¹I, which are present in other archaebacterial tRNAs. Finally the presence of an unknown modification in the D-loop has been inferred by a large jump in the sequence ladder. These tRNAs are approximately equidistant from eubacterial or eukaryotic tRNAs.     

Filtering of deep sequencing data reveals the existence of abundant Dicer-dependent small RNAs derived from tRNAs

Deep sequencing technologies such as Illumina, SOLiD, and 454 platforms have become very powerful tools in discovering and quantifying small RNAs in diverse organisms. Sequencing small RNA fractions always identifies RNAs derived from abundant RNA species such as rRNAs, tRNAs, snRNA, and snoRNA, and they are widely considered to be random degradation products. We carried out bioinformatic analysis of deep sequenced HeLa RNA and after quality filtering, identified highly abundant small RNA fragments, derived from mature tRNAs that are likely produced by specific processing rather than from random degradation. Moreover, we showed that the processing of small RNAs derived from tRNA^Gln is dependent on Dicer in vivo and that Dicer cleaves the tRNA in vitro.     

Processing of plant mitochondrial tRNAGly and tRNASer(GCU) is independent of RNA editing

The genes encoding pea and potato mitochondrial tRNA^Gly and pea mitochondrial tRNA^Ser(GCU) were analyzed with particular respect to their expression. Secondary-structure models deduced from the identical potato and pea tRNA^Gly gene sequences revealed A₇:C₆₆ mismatches in the seventh base pair at the base of the acceptor stems of both tRNAs. Sequence analyses of tRNA^Gly cDNA clones showed that these mispairings are not corrected by C₆₆ to U₆₆ conversions, as observed in plant mitochondrial tRNA^Phe. Likewise, a U₆:C₆₇ mismatch identified in the acceptor stem of the pea tRNA^Ser(GCU) is not altered by RNA editing to a mismatched U:U pair, which is created by RNA editing in Oenothera mitochondrial tRNA^Cys. In vitro processing reactions with the respective tRNA^Gly and tRNA^Ser(GCU) precursors show that such conversions are not necessary for 5′ and 3′ end maturation of these tRNAs. These results demonstrate that not all C:A (A:C) or U:C (C:U) mismatches in double-stranded regions of tRNAs are altered by RNA editing. An RNA editing event in plant mitochondrial tRNAs is thus not generally indicated by the presence of a mismatch but may depend on additional parameters. Received: 18 July 1997 / Accepted: 3 November 1997     

Transfer RNA gene mapping studies on chloroplast DNA from Chlamydomonas reinhardii

Total tRNA of Chlamydomonas reinhardii was fractionated by 2-dimensional gel electrophoresis. Sixteen tRNAs specific for eleven amino acids could be identified by aminoacylation with Escherichia coli tRNA synthetases. Hybridization of these tRNAs with chloroplast restriction fragments allowed for the localization of the genes of tRNA^Tyr, tRNA^Pro, tRNA^Phe (2 genes), tRNA^Ile (2 genes) and tRNA^His (2 genes) on the chloroplast genome of C. reinhardii. The genes for tRNA^Ala (2 genes), tRNA^Asn and tRNA^Leu were mapped by using individual chloroplast tRNAs from higher plants as probes.     

Conformational peculiarities of rRNA inff supMet from E. coli as revealed by fluorescent methods

Conformational transitions in several individual tRNAs (tRNA _inff ^supMet , tRNA^Phe from E. coli, tRNA _inf1 ^supVal , tRNA^Ser, tRNA^Phe from yeast) have been studied under various environmental conditions. The binding isotherms studies for dyes-tRNA complexes exhibited similarities in conformational states of all tRNAs investigated at low ionic strength (0.01 M NaCl). By contrast, at high ionic strength (0.4 M NaCl or 2×10^-4 M Mg²⁺) a marked difference is found in structural features of tRNA _inff ^supMet as compared with other tRNAs used. The tRNA _inff ^supMet is the only tRNA species that does not reveal the strong type of complexes with ethidium bromide, acriflavine and acridine orange.     

Crystal structure of a transfer‐ribonucleoprotein particle that promotes asparagine formation

Four out of the 22 aminoacyl‐tRNAs (aa‐tRNAs) are systematically or alternatively synthesized by an indirect, two‐step route requiring an initial mischarging of the tRNA followed by tRNA‐dependent conversion of the non‐cognate amino acid. During tRNA‐dependent asparagine formation, tRNA^Asn promotes assembly of a ribonucleoprotein particle called transamidosome that allows channelling of the aa‐tRNA from non‐discriminating aspartyl‐tRNA synthetase active site to the GatCAB amidotransferase site. The crystal structure of the Thermus thermophilus transamidosome determined at 3 Å resolution reveals a particle formed by two GatCABs, two dimeric ND‐AspRSs and four tRNAs^Asn molecules. In the complex, only two tRNAs are bound in a functional state, whereas the two other ones act as an RNA scaffold enabling release of the asparaginyl‐tRNA^Asn without dissociation of the complex. We propose that the crystal structure represents a transient state of the transamidation reaction. The transamidosome constitutes a transfer‐ribonucleoprotein particle in which tRNAs serve the function of both substrate and structural foundation for a large molecular machine.     

Unexpected expansion of tRNA substrate recognition by the yeast m1G9 methyltransferase Trm10

N-1 Methylation of the nearly invariant purine residue found at position 9 of tRNA is a nucleotide modification found in multiple tRNA species throughout Eukarya and Archaea. First discovered in Saccharomyces cerevisiae, the tRNA methyltransferase Trm10 is a highly conserved protein both necessary and sufficient to catalyze all known instances of m¹G₉ modification in yeast. Although there are 19 unique tRNA species that contain a G at position 9 in yeast, and whose fully modified sequence is known, only 9 of these tRNA species are modified with m¹G₉ in wild-type cells. The elements that allow Trm10 to distinguish between structurally similar tRNA species are not known, and sequences that are shared between all substrate or all nonsubstrate tRNAs have not been identified. Here, we demonstrate that the in vitro methylation activity of yeast Trm10 is not sufficient to explain the observed pattern of modification in vivo, as additional tRNA species are substrates for Trm10 m¹G₉ methyltransferase activity. Similarly, overexpression of Trm10 in yeast yields m¹G₉ containing tRNA species that are ordinarily unmodified in vivo. Thus, yeast Trm10 has a significantly broader tRNA substrate specificity than is suggested by the observed pattern of modification in wild-type yeast. These results may shed light onto the suggested involvement of Trm10 in other pathways in other organisms, particularly in higher eukaryotes that contain up to three different genes with sequence similarity to the single TRM10 gene in yeast, and where these other enzymes have been implicated in pathways beyond tRNA processing.     

Transfer RNA Identity Change in Anticodon Variants of E. coli tRNAPhe in Vivo

The anticodon sequence is a major recognition element for most aminoacyl-tRNA synthetases. We investigated the in vivo effects of changing the anticodon on the aminoacylation specificity in the example of E. coli tRNA^Phe. Constructing different anticodon mutants of E. coli tRNA^Phe by site-directed mutagenesis, we isolated 22 anticodon mutant tRNA^Phe; the anticodons corresponded to 16 amino acids and an opal stop codon. To examine whether the mutant tRNAs had changed their amino acid acceptor specificity in vivo, we tested the viability of E. coli strains containing these tRNA^Phe genes in a medium which permitted tRNA induction. Fourteen mutant tRNA genes did not affect host viability. However, eight mutant tRNA genes were toxic to the host and prevented growth, presumably because the anticodon mutants led to translational errors. Many mutant tRNAs which did not affect host viability were not aminoacylated in vivo. Three mutant tRNAs containing anticodon sequences corresponding to lysine (UUU), methionine (CAU) and threonine (UGU) were charged with the amino acid corresponding to their anticodon, but not with phenylalanine. These three tRNAs and tRNA^Phe are located in the same cluster in a sequence similarity dendrogram of total E. coli tRNAs. The results support the idea that such tRNAs arising from in vivo evolution are derived by anticodon change from the same ancestor tRNA.