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.     

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     

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.     

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.     

Human Cells Have a Limited Set of tRNA Anticodon Loop Substrates of the tRNA Isopentenyltransferase TRIT1 Tumor Suppressor

Human TRIT1 is a tRNA isopentenyltransferase (IPTase) homologue of Escherichia coli MiaA, Saccharomyces cerevisiae Mod5, Schizosaccharomyces pombe Tit1, and Caenorhabditis elegans GRO-1 that adds isopentenyl groups to adenosine 37 (i6A37) of substrate tRNAs. Prior studies indicate that i6A37 increases translation fidelity and efficiency in codon-specific ways. TRIT1 is a tumor suppressor whose mutant alleles are associated with cancer progression. We report the systematic identification of i6A37-containing tRNAs in a higher eukaryote, performed using small interfering RNA knockdown and other methods to examine TRIT1 activity in HeLa cells. Although several potential substrates contained the IPTase recognition sequence A36A37A38 in the anticodon loop, only tRNA^SerAGA, tRNA^SerCGA, tRNA^SerUGA, and selenocysteine tRNA with UCA (tRNA^[Ser]SecUCA) contained i6A37. This subset is a significantly more restricted than that for two distant yeasts (S. cerevisiae and S. pombe), the only other organisms comprehensively examined. Unlike the fully i6A37-modified tRNAs for Ser, tRNA^[Ser]SecUCA is partially (∼40%) modified. Exogenous selenium and other treatments that decreased the i6A37 content of tRNA^[Ser]SecUCA led to increased levels of the tRNA^[Ser]SecUCA. Of the human mitochondrion (mt)-encoded tRNAs with A36A37A38, only mt tRNAs tRNA^SerUGA and tRNA^TrpUCA contained detectable i6A37. Moreover, while tRNA^Ser levels were unaffected by TRIT1 knockdown, the tRNA^[Ser]SecUCA level was increased and the mt tRNA^SerUGA level was decreased, suggesting that TRIT1 may control the levels of some tRNAs as well as their specific activity.     

The 1.2 Å crystal structure of an E. coli tRNA acceptor stem microhelix reveals two magnesium binding sites

tRNA identity elements assure the correct aminoacylation of tRNAs by the cognate aminoacyl-tRNA synthetases. tRNA^Ser belongs to the so-called class II system, in which the identity elements are rather simple and are mostly located in the acceptor stem region, in contrast to ‘class I’, where tRNA determinants are more complex and are located within different regions of the tRNA.The structure of an Escherichia coli tRNA^Ser acceptor stem microhelix was solved by high resolution X-ray structure analysis. The RNA crystallizes in the space group C2, with one molecule per asymmetric unit and with the cell constants a = 35.79, b = 39.13, c = 31.37 Å, and β = 111.1°. A defined hydration pattern of 97 water molecules surrounds the tRNA^Ser acceptor stem microhelix. Additionally, two magnesium binding sites were detected in the tRNA^Ser aminoacyl stem.     

Superposition of two tRNA acceptor stem crystal structures: Comparison of structure, ligands and hydration

We solved the X-ray structures of two Escherichia coli tRNA^Ser acceptor stem microhelices. As both tRNAs are aminoacylated by the same seryl-tRNA-synthetase, we performed a comparative structure analysis of both duplexes to investigate the helical conformation, the hydration patterns and magnesium binding sites. It is well accepted, that the hydration of RNA plays an important role in RNA-protein interactions and that the extensive solvent content of the minor groove has a special function in RNA. The detailed comparison of both tRNA^Ser microhelices provides insights into the structural arrangement of the isoacceptor tRNA aminoacyl stems with respect to the surrounding water molecules and may eventually help us to understand their biological function at atomic resolution.     

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.     

Nucleotide sequences of yeast genes for tRNA(2), tRNA(2) and tRNA(1): homology blocks occur in the vicinity of different tRNA genes

Three members of a collection of pBR322-yeast DNA recombinant plasmids containing yeast tRNA genes have been analyzed and sequenced. Each plasmid carries a single tRNA gene: pY44, tRNA^Ser₂; pY41, tRNA^Arg₂; pY7, tRNA^Val₁. All three genes are intronless and terminate in a cluster of Ts in the non-coding strand. The sequence information here and previously determined sequences allow an extensive comparison of the regions flanking several yeast tRNA genes. This analysis has revealed novel features in tRNA gene arrangement. Blocks of homology in the flanking regions were found between the tRNA genes of an isoacceptor family but, more interestingly, also between genes coding for tRNAs of different amino-acid specificities. Particularly, three examples are discussed in which sequence elements in the neighborhood of different tRNA genes have been conserved to a high degree and over long distances.     

Mature methyl-deficient tRNA isolated from a mammary adenocarcinoma

A transplantable rat tumor, mammary adenocarcinoma 13762, accumulates tRNA which can be methylated in vitro by mammalian tRNA (adenine-1) methyltransferase. This unusual ability of the tumor RNA to serve as substrate for a homologous tRNA methylating enzyme is correlated with unusually low levels of the A₅₈-specific adenine-1 methyltransferase. The nature of the methyl-accepting RNA has been examined by separating tumor tRNA on two-dimensional polyacrylamide gels. Comparisons of ethidium bromide-stained gels of tumor vs. liver tRNA show no significant quantitative differences and no accumulation of novel tRNAs or precursor tRNAs in adenocarcinoma RNA. Two-dimensional separations of tumor RNA after in vitro [¹⁴C]methylation using purified adenine-1 methyltransferase indicate that about 25% of the tRNA species are strongly methyl-accepting RNAs. Identification of six of the tRNAs separated on two-dimensional gels has been carried out by hybridization of cloned tRNA genes to Northern blots. Three of these, tRNA^Lys3, tRNA^Gln and tRNA^Met_i, are among the adenocarcinoma methyl-accepting RNAs. The other three RNAs, all of which are leucine-specific tRNAs, show no methyl-accepting properties. Our results suggest that low levels of a tRNA methyltransferase in the adenocarcinoma cause selected species of tRNA to escape the normal A₅₈ methylation, resulting in the appearance of several mature tRNAs which are deficient in 1-methyladenine. The methyl-accepting tRNAs from the tumor appear as ethidium bromide-stained spots of similar intensity to those seen for RNA from rat liver; therefore, methyladenine deficiency does not seem to impair processing of these tRNAs.     

Increased tRNA level in yeast cells with mutant translation termination factors eRF1 and eRF3

We have earlier characterized Saccharomyces cerevisiae strains with mutations of essential SUP45 and SUP35, which code for translation termination factors eRF1 and eRF3, respectively. In this work, the sup45 and sup35 nonsense mutants were compared with respect to the levels of eight tRNAs: tRNA^Tyr, tRNA^Gln, tRNA^Trp, tRNA^Leu, tRNA^Arg (described as potential suppressor tRNAs), tRNA^Pro, tRNA^His, and tRNA^Gly. The mutants did not display a selective increase in tRNAs, capable of a noncanonical read-through at stop codons. Most of the mutations increased the level of all tRNAs under study. The mechanisms providing for the viability of the sup45 and sup35 nonsense mutants are discussed.     

Structures of tobacco chloroplast genes for tRNAIle (CAU), tRNALeu (CAA), tRNACys (GCA), tRNASer (UGA) and tRNAThr (GGU): a compilation of tRNA genes from tobacco chloroplasts

Summary The location and nucleotide sequences of tobacco chloroplast genes for tRNA^Ile (CAU), tRNA^Leu (CAA), tRNA^Cys (GCA), tRNA^Ser (UGA) and tRNA^Thr (GGU) (trnI-CAU, trnL-CAA, trnC-GCA, trnS-UGA and trnT-GGU, respectively) have been determined. The trnI and trnL are located in the inverted repeat region. The trnC, trnS and trnT are present in the large single copy region. These five tRNA genes together with the 25 different tRNA genes previously published have been compiled and compared. These 30 tRNA genes corresponding to 20 amino acids are most likely to be all of the tRNA genes encoded in tobacco chloroplast genome.This paper is dedicated to Professor Morio Ikehara on the occasion of his retirement from Osaka University in March 1986.     

tRNASer(CGA) differentially regulates expression of wild-type and codon-modified papillomavirus L1 genes

Exogenous transfer RNAs (tRNAs) favor translation of bovine papillomavirus 1 wild-type (wt) L1 mRNA in in vitro translation systems (Zhou et al. 1999, J. Virol., 73, 4972–4982). We, therefore, investigated whether papillomavirus (PV) wt L1 protein expression could be enhanced in eukaryotic cells following exogenous tRNA supplementation. Both Chinese hamster ovary (CHO) and Cos1 cells, transfected with PV1 wt L1 genes, effectively transcribed the genes but did not translate them. However, L1 protein translation was demonstrated following co-transfection with the L1 gene and a gene expressing tRNA^Ser(CGA). Cell lines, stably transfected with a bovine papillomavirus 1 (BPV1) wt L1 expression construct, produced L1 protein after the transfection of the tRNA^Ser(CGA) gene, but not following the transfection with basal vectors, suggesting that tRNA^Ser(CGA) gene enhanced wt L1 translation as a result of endogenous tRNA alterations and phosphorylation of translation initiation factors elF4E and elF2α in the tRNA^Ser(CGA) transfected L1 cell lines. The tRNA^Ser(CGA) gene expression significantly reduced translation of L1 proteins expressed from codon-modified (HB) PV L1 genes utilizing mammalian preferred codons, but had variable effects on translation of green fluorescent proteins (GFPs) expressed from six serine GFP variants. The changes of tRNA pools appear to match the codon composition of PV wt and HB L1 genes and serine GFP variants to regulate translation of their mRNAs. These findings demonstrate for the first time in eukaryotic cells that translation of the target genes can be differentially influenced by the provision of a single tRNA expression construct.     

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.     

DNA sequences of tobacco chloroplast genes for tRNASer (GGA), tRNAThr (UGU), tRNALeu (UAA), tRNAPhe (GAA): the tRNALeu gene contains a 503 bp intron

Summary The location and nucleotide sequence of tobacco chloroplast genes for tRNA^Ser (GGA), tRNA^Thr (UGU), tRNA^Leu (UAA) and tRNA^Phe (GAA) (trnS-GGA, trnT-UGU, trnL-UAA and trnF-GAA, respectively) have been determined. These genes are located in the 10 kbp BamHI fragment which lies in the middle of the large single-copy region of the chloroplast DNA. The gene order is trnS-trnT-trnL-trnF. The trnS, trnL and trnF are encoded on the same strand while the trnT on the opposite strand. The trnL contains a 503 bp intron like maize and broad bean trnL-UAAs.     

tRNAHis 5-methylcytidine levels increase in response to several growth arrest conditions in Saccharomyces cerevisiae

tRNAs are highly modified, each with a unique set of modifications. Several reports suggest that tRNAs are hypomodified or, in some cases, hypermodified under different growth conditions and in certain cancers. We previously demonstrated that yeast strains depleted of tRNA^His guanylyltransferase accumulate uncharged tRNA^His lacking the G₋₁ residue and subsequently accumulate additional 5-methylcytidine (m⁵C) at residues C₄₈ and C₅₀ of tRNA^His, due to the activity of the m⁵C-methyltransferase Trm4. We show here that the increase in tRNA^His m⁵C levels does not require loss of Thg1, loss of G₋₁ of tRNA^His, or cell death but is associated with growth arrest following different stress conditions. We find substantially increased tRNA^His m⁵C levels after temperature-sensitive strains are grown at nonpermissive temperature, and after wild-type strains are grown to stationary phase, starved for required amino acids, or treated with rapamycin. We observe more modest accumulations of m⁵C in tRNA^His after starvation for glucose and after starvation for uracil. In virtually all cases examined, the additional m⁵C on tRNA^His occurs while cells are fully viable, and the increase is neither due to the GCN4 pathway, nor to increased Trm4 levels. Moreover, the increased m⁵C appears specific to tRNA^His, as tRNA^Val(AAC) and tRNA^Gly(GCC) have much reduced additional m⁵C during these growth arrest conditions, although they also have C₄₈ and C₅₀ and are capable of having increased m⁵C levels. Thus, tRNA^His m⁵C levels are unusually responsive to yeast growth conditions, although the significance of this additional m⁵C remains unclear.