Determination of structure and absolute configuration of a new modified nucleoside isolated from tRNA-2Gly of Bombyx mori by a total synthesis to be 5-(S-carboxy(hydroxy)methyl) uridine

A synthesis of a new modified nucleoside isolated from tRNA2Gly of Bombyx mori was accomplished. This synthesis confirmed its structure and proved its absolute configuration to be 5-(S-carboxy(hydroxy)methyl)uridine.     

5-(Carboxy-hydroxymethyl)uridine, a new modified nucleoside located in the anticodon of tRNA2Gly from the posterior silk glands of Bombyx mori

A new modified nucleoside located in the anticodon of tRNA2Gly from the posterior silk glands of Bombyx mori has been isolated and its structure determined as 5-(carboxy-hydroxymethyl)uridine mainly by analyses of its UV, 1H NMR, and FD mass spectra.     

Doublet translocation at GGA is mediated directly by mutant tRNA(2Gly).

Members of the sufS class of -1 frameshift suppressors have alterations of the GGA/G-decoding tRNA(2Gly). Suppressor-promoted frameshifting at GGA was shown in this study to be directly mediated by the mutant tRNA(2Gly). We disproved the possibility that, in the presence of the compromised mutant tRNA(2Gly), either wild-type tRNA(1Gly), wild-type tRNA(3Gly), a GGA-reading mutant form of tRNA(3Gly), or any other agent suppresses the frameshift mutation trpE91.     

Identification and synthesis of a naturally occurring selenonucleoside in bacterial tRNAs: 5-[(methylamino)methyl]-2-selenouridine

Escherichia coli, Clostridium sticklandii, and Methanococcus vannielii synthesize 75Se-labeled amino acid transfer ribonucleic acids [( 75Se]tRNAs) when grown with low levels (approximately equal to 1 microM) of 75SeO32-. When E. coli [75Se]tRNA was digested to nucleosides and analyzed by reversed-phase high-performance liquid chromatography, a single selenonucleoside accounted for 70-90% of the 75Se label in the bulk tRNA. This nucleoside was shown to be indistinguishable in a number of its properties from authentic 5-[(methylamino)methyl]-2-selenouridine. Preparation of the authentic selenonucleoside was accomplished and the synthetic compound characterized by its UV and 1H NMR spectral properties. The new selenonucleoside also accounted for 40-60% of the 75Se found in [75Se]tRNA from C. sticklandii or M. vannielii. Each of these anaerobic bacteria contains one additional selenonucleoside in their tRNA populations distinct from 5-[(methylamino)methyl]-2-selenouridine. Pure seleno-tRNAGlu isolated from C. sticklandii contains one 5-[(methylamino)methyl]-2-selenouridine and one 4-thiouridine per tRNA molecule.     

tRNA genes of Streptomyces lividans: new sequences and comparison of structure and organization with those of other bacteria.

Three closely linked Streptomyces lividans tRNA genes encoding two tRNA(Lys)s and a tRNA(Gly) were cloned and sequences. The structure of tRNA(Gly) is unusual for eubacterial tRNAs. Including those in previous reports (R. Sedlmeier and H. Schmieger, Nucleic Acids Res. 18:4027, 1990, and R. Sedlmeier, G. Linti, K. Gregor, and H. Schmieger, Gene 132:125-130, 1993), 18 S. lividans tRNA genes were physically mapped on the chromosome of the closely related strain Streptomyces coelicolor A3(2). The structure and organization of tRNA genes of S. lividans and S. coelicolor are compared with those of Escherichia coli and Bacillus subtilis.     

Gel retardation analysis of E. coli M1 RNA-tRNA complexes.

We have analyzed complexes between tRNA and E. coli M1 RNA by electrophoresis in non-denaturing polyacrylamide gels. The RNA subunit of E. coli RNase P formed a specific complex with mature tRNA molecules. A derivative of the tRNA(Gly), endowed with the intron of yeast tRNA(ile) (60 nt), was employed to improve separation of complexed and unbound M1 RNA. Binding assays with tRNA(Gly) and intron-tRNA(Gly) as well as analysis of intron-tRNA/M1 RNA complexes on denaturing gels showed that one tRNA is bound per molecule of M1 RNA. A tRNA carrying a truncation as small as the 5'-nucleotide had a strongly reduced affinity to M1 RNA and was also a weak competitor in the cleavage reaction, suggesting that nucleotide +1 is a major determinant of tRNA recognition and that the thermodynamically stable tRNA-M1 RNA complex is relevant for enzyme function. Binding was shown to be dependent on the M1 RNA concentration in a cooperative fashion. Only a fraction of M1 RNAs (50-60%) readily formed a complex with intron-tRNA(Gly), indicating that distinct conformational subpopulations of M1 RNA may exist. Formation of the M1 RNA-tRNA(Gly), complex was very similar at 100 mM Mg++ and Ca++, corroborating earlier data that Ca++ is competent in promoting M1 RNA folding and tRNA binding. Determination of apparent equilibrium constants (app Kd) for tRNA(Gly) as a function of the Mg++ concentration supports an uptake of at least two additional Mg++ ions upon complex formation. At 20-30 mM Mg++, highest cleavage rates but strongly reduced complex formation were observed. This indicates that tight binding of the tRNA to the catalytic RNA at higher magnesium concentrations retards product release and therefore substrate turnover.     

Maturation of a hypermodified nucleoside in transfer RNA.

E. coli C6 rel- met- cys- was cultured in a fully supplemented medium and in media lacking cysteine or methionine. tRNA isolated from the three cultures containted, respectively, a normal complement of modified nucleosides; a deficiency in thiolated nucleosides and a deficiency in methylated nucleosides. Both sulfur-deficient tRNA and methyl-deficient tRNA contained large amounts of N-6- (delta-2-isopentenyl) adenosine and small amounts of the 2-methylthio derivative. Methyl-deficient tRNA contained, in addition a large amount of a cytokinin active, differently modified nucleoside that is believed to be a sulfur derivative of N6-(delta-2-isopentenyl) adenosine. The structure of this compound is unknown. When methly-deficient tRNA and the precusor the tRNA-Tyr su3-+ A25 were enzymatically methylated in vitro, methyl groups were incorporated into derivatives of isopentenyladenosine. These results indicate that the biosynthesis of the 2-methylthio derivative of isopentenyladenosine may occur in a sequential manner, i.e., thiolation of isopentenyladenosine followed by methylation.     

tRNA residues that have coevolved with their anticodon to ensure uniform and accurate codon recognition

The structure, phylogeny and in vivo function of the base pair formed between nucleotides 32 and 38 of the tRNA anticodon loop are reviewed. The A32-U38 pair, which is highly conserved in tRNA2(Ala) and sometimes observed in tRNA2(Pro), was recently found to decrease the affinity of tRNAs to the ribosomal A site relative to other 32-38 combinations. This suggests that the role of 32-38 pair is to tune the tRNA affinity in the A site to a uniform value. New experiments presented here show that the U32C mutation in tRNA1(Gly) increases its affinity to the cognate codon and to codons with third position mismatches in the A site. This suggests that one reason for uniform tRNA binding to evolve was to avoid incorrect codon recognition.     

A novel lysine-substituted nucleoside in the first position of the anticodon of minor isoleucine tRNA from Escherichia coli

A minor species of isoleucine tRNA (tRNA(minor Ile)) specific to the codon AUA has been isolated from Escherichia coli B and a modified nucleoside N+ has been found in the first position of the anticodon (Harada, F., and Nishimura, S. (1974) Biochemistry 13, 300-307). In the present study, tRNA(minor Ile)) was purified from E. coli A19, and nucleoside N+ was prepared, by high-performance liquid chromatography, in an amount (0.6) A260 units) sufficient for the determination of chemical structures. By 400 MHz 1H NMR analysis, nucleoside N+ was found to have a pyrimidine moiety and a lysine moiety, the epsilon amino group of which was involved in the linkage between these two moieties. From the NMR analysis together with mass spectrometry, the structure of nucleoside N+ was determined as 4-amino-2-(N6-lysino)-1-(beta-D-ribofuranosyl)pyrimidinium ("lysidine"), which was confirmed by chemical synthesis. Lysidine is a novel type of modified cytidine with a lysine moiety and has one positive charge. Probably because of such a unique structure, lysidine in the first position of anticodon recognizes adenosine but not guanosine in the third position of codon.     

Crystal structure of an Escherichia coli tRNA(Gly) microhelix at 2.0 A resolution

tRNA identity elements determine the correct aminoacylation by the cognate aminoacyl-tRNA synthetase. In class II aminoacyl tRNA synthetase systems, tRNA specificity is assured by rather few and simple recognition elements, mostly located in the acceptor stem of the tRNA. Here we present the crystal structure of an Escherichia coli tRNA(Gly) aminoacyl stem microhelix at 2.0 A resolution. The tRNA(Gly) microhelix crystallizes in the space group P3(2)21 with the cell constants a=b=35.35 A, c=130.82 A, gamma=120 degrees . The helical parameters, solvent molecules and a potential magnesium binding site are discussed.     

Divergent anticodon recognition in contrasting glutamyl-tRNA synthetases

The pathogenic bacterium Helicobacter pylori utilizes two essential glutamyl-tRNA synthetases (GluRS1 and GluRS2). These two enzymes are closely related in evolution and yet they aminoacylate contrasting tRNAs. GluRS1 is a canonical discriminating GluRS (D-GluRS) that biosynthesizes Glu-tRNA(Glu) and cannot make Glu-tRNA(Gln). In contrast, GluRS2 is non-canonical as it is only essential for the production of misacylated Glu-tRNA(Gln). The co-existence and evident divergence of these two enzymes was capitalized upon to directly examine how GluRS2 acquired tRNA(Gln) specificity. One key feature that distinguishes tRNA(Glu) from tRNA(Gln) is the third position in the anticodon of each tRNA (C36 versus G36, respectively). By comparing sequence alignments of different GluRSs, including GluRS1s and GluRS2s, to the crystal structure of the Thermus thermophilus D-GluRS:tRNA(Glu) complex, a divergent pattern of conservation in enzymes that aminoacylate tRNA(Glu)versus those specific for tRNA(Gln) emerged and was experimentally validated. In particular, when an arginine conserved in discriminating GluRSs and GluRS1s was inserted into Hp GluRS2 (Glu334Arg GluRS2), the catalytic efficiency of the mutant enzyme (k(cat)/K(Mapp)) was reduced by approximately one order of magnitude towards tRNA(Gln). However, this mutation did not introduce activity towards tRNA(Glu). In contrast, disruption of a glycine that is conserved in all GluRS2s but not in other GluRSs (Gly417Thr GluRS2) generated a mutant GluRS2 with weak activity towards tRNA(Glu1). Synergy between these two mutations was observed in the double mutant (Glu334Arg/Gly417Thr GluRS2), which specifically and more robustly aminoacylates tRNA(Glu1) instead of tRNA(Gln). As GluRS1 and GluRS2 are related by an apparent gene duplication event, these results demonstrate that we can experimentally map critical evolutionary events in the emergence of new tRNA specificities.     

Transfer RNAs of potato (Solanum tuberosum) mitochondria have different genetic origins.

Total transfer RNAs were extracted from highly purified potato mitochondria. From quantitative measurements, the in vivo tRNA concentration in mitochondria was estimated to be in the range of 60 microM. Total potato mitochondrial tRNAs were fractionated by two-dimensional polyacrylamide gel electrophoresis. Thirty one individual tRNAs, which could read all sense codons, were identified by aminoacylation, sequencing or hybridization to specific oligonucleotides. The tRNA population that we have characterized comprises 15 typically mitochondrial, 5 'chloroplast-like' and 11 nuclear-encoded species. One tRNA(Ala), 2 tRNAs(Arg), 1 tRNA(Ile), 5 tRNAs(Leu) and 2 tRNAs(Thr) were shown to be coded for by nuclear DNA. A second, mitochondrial-encoded, tRNA(Ile) was also found. Five 'chloroplast-like' tRNAs, tRNA(Trp), tRNA(Asn), tRNA(His), tRNA(Ser)(GGA) and tRNA(Met)m, presumably transcribed from promiscuous chloroplast DNA sequences inserted in the mitochondrial genome, were identified, but, in contrast to wheat (1), potato mitochondria do not seem to contain 'chloroplast-like' tRNA(Cys) and tRNA(Phe). The two identified tRNAs(Val), as well as the tRNA(Gly), were found to be coded for by the mitochondrial genome, which again contrasts with the situation in wheat, where the mitochondrial genome apparently contains no tRNA(Val) or tRNA(Gly) gene (2).     

Nuclear magnetic resonance signal assignments of purified [13C]methyl-enriched yeast phenylalanine transfer ribonucleic acid

Yeast tRNA Phe, enriched in carbon-13 specifically at the naturally occurring methyl groups, has been produced through biosynthesis, then purified, and analyzed. Transfer RNA Phe was purified from the [13C]methyl-enriched, unfractionated tRNA that had been extracted from a methionine auxotroph of Saccharomyces cerevisiae [Agris, P. F., Kovacs, S. A. H., Smith, C., Kopper, R. H., & Schmidt, P. G. (1983) Biochemistry 22, 1402-1408]. The yeast had been grown in minimal medium supplemented with [13C]methylmethionine. Transfer RNA Phe purity and the full extent of nucleoside modification were confirmed by high-performance liquid chromatography of constituent nucleosides with simultaneous UV spectral identification and quantitation. Mass spectometry of [13C]methyl-enriched nucleosides and NMR of the tRNA indicated an enrichment of at least 70 atom %. Twelve resolved and prominent carbon-13 NMR signals from the tRNA were seen between 10 and 60 ppm. These have been assigned to 13 of the 14 naturally occurring methyl groups. However, the partially resolved signals assigned to the two 5-methylcytidines could not be assigned to their specific nucleoside positions of either 40 or 49 in the molecule. In addition, the partially resolved signals of the two methyl esters of wybutosine could not be distinguished. The methyl group found not to be enriched with 13C is bound to the ring carbon in the hypermodified nucleoside wybutosine (Y). A 13th enriched signal downfield (120.9 ppm) has been assigned to one of the two carbons added to guanosine to form the third ring in the biosynthesis of Y. The 13C enrichment of this ring carbon demonstrates its origin from the methionine methyl group.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural analysis of O2'-methyl-5-carbamoylmethyluridine, a newly discovered constituent of yeast transfer RNA.

A compound tentatively identified as O2-methyl-5-carboxymethyluridine (cm5Um) was recently isolated in this laboratory from bulk yeast transfer RNA (Gray, M. W. (1975), Can, J. Biochem. 53, 735-746). Alkaline hydrolysis of yeast tRNA releases this nucleoside as part of an alkali-stable dinucleotide, cm5Um-Ap, from which sufficient cm5Um was prepared in the present investigation for a detailed examination of its properties. The ultraviolet absorption spectra and chromatographic and electrophoretic properties of cm5Um were consistent with the proposed structure, which was confirmed by characterization of the base and sugar moieties as 5-carboxymethyluracil and 2-O-methylribose, respectively. Snake venom hydrolysis of yeast tRNA releases cm5Um in the form of a carboxyl-blocked 5'-nucleotide, designated pU-2. Identification of the alkali-labile blocking group in pU-2 as an amide was based on quantitative assay for ammonia released upon acid hydrolysis of the corresponding nucleoside, U-2, and by chromatographic comparison of U-2 with the semisynthetic methyl ester and amide derivatives of cm5Um (mcm5Um and ncm5Um, respectively). Quantitative analysis has indicated that ncm5Um may be confined to a single species of yeast tRNA. In view of the unique localization (the "Wobble" position of the anticodon sequence) and coding properties (pairing with A but not with G) of other cm5U derivatives in transfer RNA, the dinucleotide cm5Um-Ap may be derived from the first two positions of the anticodon sequence of a yeast tRNA species recognizing an NUA codon. This predicts that O2-methyl-5-carbamoylmethyluridine will be found in an isoleucine, leucine, or valine isoacceptor.     

Crystal structure of archaeal tRNA(m(1)G37)methyltransferase aTrm5

Methylation of the N1 atom of guanosine at position 37 in tRNA, the position 3'-adjacent to the anticodon, generates the modified nucleoside m(1)G37. In archaea and eukaryotes, m(1)G37 synthesis is catalyzed by tRNA(m(1)G37)methyltransferase (archaeal or eukaryotic Trm5, a/eTrm5). Here we report the crystal structure of archaeal Trm5 (aTrm5) from Methanocaldococcus jannaschii (formerly known as Methanococcus jannaschii) in complex with the methyl donor analogue at 2.2 A resolution. The crystal structure revealed that the entire protein is composed of three structural domains, D1, D2, and D3. In the a/eTrm5 primary structures, D2 and D3 are highly conserved, while D1 is not conserved. The D3 structure is the Rossmann fold, which is the hallmark of the canonical class-I methyltransferases. The a/eTrm5-defining domain, D2, exhibits structural similarity to some class-I methyltransferases. In contrast, a DALI search with the D1 structure yielded no structural homologues. In the crystal structure, D3 contacts both D1 and D2. The residues involved in the D1:D3 interactions are not conserved, while those participating in the D2:D3 interactions are well conserved. D1 and D2 do not contact each other, and the linker between them is disordered. aTrm5 fragments corresponding to the D1 and D2-D3 regions were prepared in a soluble form. The NMR analysis of the D1 fragment revealed that D1 is well folded by itself, and it did not interact with either the D2-D3 fragment or the tRNA. The NMR analysis of the D2-D3 fragment revealed that it is well folded, independently of D1, and that it interacts with tRNA. Furthermore, the D2-D3 fragment was as active as the full-length enzyme for tRNA methylation. The positive charges on the surface of D2-D3 may be involved in tRNA binding. Therefore, these findings suggest that the interaction between D1 and D3 is not persistent, and that the D2-D3 region plays the major role in tRNA methylation.