Modified nucleotides in Bacillus subtilis tRNA(Trp) hyperexpressed in Escherichia coli.

In the present study, modified nucleotides in the B. subtilis tRNA(Trp) cloned and hyperexpressed in E. coli have been identified by TLC and HPLC analyses. The modification patterns of the two isoacceptors of cloned B. subtilis tRNA(Trp) have been compared with those of native tRNA(Trp) from B. subtilis and from E. coli. The modifications of the A73 mutant of B. subtilis tRNA(Trp), which is inactive toward its cognate TrpRS, were also investigated. The results indicate the formation of the modified nucleotides S4U8, Gm18, D20, Cm32, i6A/ms2i6A37, T54 and psi 55 on cloned B. subtilis tRNA(Trp). This modification pattern resembles the pattern of E. coli tRNA(Trp), except that m7G is missing from the cloned tRNA(Trp), probably on account of its short extra loop. In contrast, the pattern departs substantially from that of native B. subtilis tRNA(Trp). Therefore, the cloned B. subtilis tRNA(Trp) has taken on largely the modification pattern of E. coli tRNA(Trp) despite the 26% sequence difference between the two species of tRNA, gaining in particular the Cm32 and Gm18 modifications from the E. coli host. A notable difference between the isoacceptors of the cloned tRNA(Trp) was seen in the extent of modification of A37, which occurred as either the hypomodified i6A or the hypermodified ms2i6A form. Surprisingly, base substitution of guanosine by adenosine at position 73 of the cloned tRNA(Trp) has led to the abolition of the 2'-O-methylation modification of the remote G18 residue.     

Residues Lys-149 and Glu-153 switch the aminoacylation of tRNA(Trp) in Bacillus subtilis

Tryptophanyl-tRNA synthetase (TrpRS) consists of two identical subunits that induce the cross-subunit binding mode of tRNA(Trp). It has been shown that eubacterial and eukaryotic TrpRSs cannot efficiently cross-aminoacylate the corresponding tRNA(Trp). Although the identity elements in tRNA(Trp) that confer the species-specific recognition have been identified, the corresponding elements in TrpRS have not yet been reported. In this study two residues, Lys-149 and Glu-153, were identified as being crucial for the accurate recognition of tRNA(Trp). These residues reside adjacent to the binding pocket for Trp-AMP and show phylogenic diversities in the charge on their side chains between eubacteria and eukaryotes. Single mutagenesis at Lys-149 or Glu-153 reduced the activity of TrpRS in the activation of Trp. The reduction was less than that caused by the double mutant WBHA (K149D/E153R). It is unusual that E153G had no detectable activity in the activation of Trp unless tRNA(Trp) was added to the reaction. In addition, we successfully switched the species specificity of Bacillus subtilis TrpRS recognition of tRNA(Trp). The affinity of WBHA, K149E and E153K to human tRNA(Trp) was 31-, 13.5-, and 12.9-fold greater than that of wild type B. subtilis TrpRS, respectively. Indeed WBHA and E153K were found to prefer genuine human tRNA(Trp) to their cognate eubacteria tRNA(Trp).     

3种水稻线粒体tRNA~(Trp)突变体的克隆和活力鉴定

 设计并完成了 3种水稻线粒体tRNATrp的突变 ,体外转录并用枯草杆菌和人色氨酰tRNA合成酶 (TrpRS)对tRNATrp及其突变体进行了活力测定 .3种突变体的氨酰化活力比野生型水稻线粒体tRNATrp分别上升了 1 8、1 5和 5倍 .说明A1 U72和G5 C68对于提高线粒体tRNATrp被细胞质TrpRS氨酰化能力的作用并不大 ,细胞质tRNATrp与细胞质TrpRS的识别方式并不适用于线粒体tRNATrp与细胞质TrpRS的相互识别 .研究结果对于了解线粒体tRNATrp和细胞质TrpRS的相互识别及药物设计有重要意义     

Recognition of tRNA Trp by initiation factors from Escherichia coli.

Binding of acetyl or formyltryptophanyl-tRNA Trp from Escherichia coli or beef liver to E. coli ribosomes is strongly stimulated by E. coli initiation factors and requires GTP. The N-acylated tryptophan is puromycin reactive. Polypeptide chain initiation with acetyltryptophan dependent on poly(U,G) has been demonstrated and is highly dependent on added initiation factors. tRNA Trp appears, therefore, to share some structural features with tRNAfMet of significance to the process of polypeptide chain initiation.     

NMR studies of Bacillus subtilis tRNA(Trp) hyperexpressed in Escherichia coli. Assignment of imino proton signals and determination of thermal stability

15N-Labeled Bacillus subtilis tRNA(Trp) wild type and a series of mutants were hyperexpressed in Escherichia coli and purified for NMR studies with the use of two-dimensional nuclear Overhauser effect spectroscopy (NOESY) and heteronuclear single quantum correlation (HSQC) and three-dimensional NOESY-HSQC techniques. These made possible chemical shift assignments of imino protons and determination of the thermal stability of the tRNA(Trp) molecules. Almost all of the imino protons in the helical regions and the tertiary base pairs were assigned, except three imino protons of the AU base pairs whose peaks were not clearly observed. Several base triplets found in the crystal structure of tRNA were observed in the present study as well. These studies also revealed two components of tRNA(Trp), which could not be separated by high pressure liquid chromatography, corresponding to s(4)U and U at position 8 of the tRNA(Trp), as indicated by two different sets of peaks for the TpsiC and D arms. The modification at position 8 altered the local conformation of the core region of the tRNA. Thermal unfolding experiments showed that the unfolding process is cooperative in the presence of a high concentration of magnesium ions and that the component corresponding to the s(4)U8 is more stable than the U8 component, thus providing evidence that the thiolation of U8 stabilizes the tertiary structure of tRNA.     

Identity elements required for enzymatic formation of N2,N2-dimethylguanosine from N2-monomethylated derivative and its possible role in avoiding alternative conformations in archaeal tRNA

Here, we have investigated the specificity of purified recombinant tRNA:m(2)(2)G10 methyltransferase of Pyrococcus abyssi ((Pab)Trm-m(2)(2)G10 enzyme). This archaeal enzyme catalyses mono- and dimethylation of the N(2)-exocyclic amino group of guanine at position 10 of several tRNA species. Our results indicate that only few identity elements are required for the efficient formation of m(2)(2)G10. They are composed of a G10.U25 wobble base-pair in the dihydrouridine arm (D-arm) and a four nucleotide variable loop (V-loop) within a canonical three-dimensional (3D) structure. The types of base-pairs in the D-arm or amino acid acceptor stem are also important for the enzymatic reaction, but appear to affect only the rate of tRNA methylation. However, in tRNA species harbouring a G10-C25 Watson-Crick base-pair and/or five nucleotide V-loop, only m(2)G10 is produced. To impair the monomethylation reaction, drastic amputation in the T-arm is required. Our observations contrast with those reported earlier for the identity elements required for a remotely related Pyrococcus furiosus Trm-m(2)(2)G26 enzyme (alias (Pfu)Trm1) that also catalyses the two step formation of m(2)(2)G but at position 26 in several tRNA species. In this case, a G10-C25 base-pair together with the five nucleotide V-loop were shown to be required for efficient formation of m(2)(2)G26. Thus, in the Pyrococcus genus, the major identity elements that preclude formation of m(2)(2)G at positions 10 or 26 in tRNA are mutually exclusive. Therefore, the Trm-m(2)(2)G10 and Trm-m(2)(2)G26 enzymes have evolved independently towards different specificities. In addition, identity elements for m(2)/m(2)(2)G10 formation in archaeal tRNA are different from the ones required for m(2)G10 formation in eukaryal tRNA. We propose that archaeal tRNA:m(2)(2)G10 methyltransferases, unlike the orthologous eukaryal tRNA:m(2)G10 methyltransferases, evolved towards m(2)(2)G10 specificity due to the possible requirement of preventing formation of alternative structures in G/C rich archaeal tRNA species.     

Nucleotide sequence of three isoaccepting lysine tRNAs from rabbit liver and SV40-transformed mouse fibroblasts.

The lysine isoacceptor tRNAs differ in two aspects from the majority of the other mammalian tRNA species: they do not contain ribosylthymine (T) in loop IV, and a 'new' lysine tRNA, which is practically absent in non-dividing tissue, appears at elevated levels in proliferating cells. We have therefore purified the three major isoaccepting lysine tRNAs from rabbit liver and the 'new' lysine tRNA isolated from SV40-transformed mouse fibroblasts, and determined their nucleotide sequences. Our basic findings are as follows. a) The three major lysine tRNAs (species 1, 2 and 3) from rabbit liver contain 2'-O-methylribosylthymine (Tm) in place of T. tRNA1Lys and tRNA2Lys differ only by a single base pair in the middle of the anticodon stem; the anticodon sequence C-U-U is followed by N-threonyl-adenosine (t6A). TRNA3Lys has the anticodon S-U-U and contains two highly modified thionucleosides, S (shown to be 2-thio-5-carboxymethyl-uridine methyl ester) and a further modified derivative of t6 A (2-methyl-thio-N6-threonyl-adenosine) on the 3' side of the anticodon. tRNA3Lys differs in 14 and 16 positions, respectively, from the other two isoacceptors. b) Protein synthesis in vitro, using synthetic polynucleotides of defined sequence, showed that tRNA2Lys with anticodon C-U-U recognized A-A-G only, whereas tRNA3Lys, which contains thio-nucleotides in and next to the anticodon, decodes both lysine codons A-A-G and A-A-A, but with a preference for A-A-A. In a globin-mRNA-translating cell-free system from ascites cells, both lysine tRNAs donated lysine into globin. The rate and extent of lysine incorporation, however, was higher with tRNA2Lys than with tRNA3Lys, in agreement with the fact that alpha-globin and beta-globin mRNAs contain more A-A-G than A-A-A- codons for lysine. c) A comparison of the nucleotide sequences of lysine tRNA species 1, 2 and 3 from rabbit liver, with that of the 'new' tRNA4Lys from transformed and rapidly dividing cells showed that this tRNA is not the product of a new gene or group of genes, but is an undermodified tRNA derived exclusively from tRNA2Lys. Of the two dihydrouridines present in tRNA2Lys, one is found as U in tRNA4Lys; the purine next to the anticodon is as yet unidentified but is known not be t6 A. In addition we have found U, T and psi besides Tm as the first nucleoside in loop IV.     

Codon recognition patterns as deduced from sequences of the complete set of transfer RNA species in Mycoplasma capricolum. Resemblance to mitochondria

The nucleotide sequences of the complete set of tRNA species in Mycoplasma capricolum, a derivative of Gram-positive eubacteria, have been determined. This bacterium represents the first genetic system in which the sequences of all the tRNA species have been determined at the RNA level. There are 29 tRNA species: three for Leu, two each for Arg, Ile, Lys, Met, Ser, Thr and Trp, and one each for the other 12 amino acids as judged from aminoacylation and the anticodon nucleotide sequences. The number of tRNA species is the smallest among all known genetic systems except for mitochondria. The tRNA anticodon sequences have revealed several features characteristic of M. capricolum. (1) There is only one tRNA species each for Ala, Gly, Leu, Pro, Ser and Val family boxes (4-codon boxes), and these tRNAs all have an unmodified U residue at the first position of the anticodon. (2) There are two tRNAThr species having anticodons UGU and AGU; the first positions of these anticodons are unmodified. (3) There is only one tRNA with anticodon ICG in the Arg family box (CGN); this tRNA can translate codons CGU, CGC and CGA. No tRNA capable of translating codon CGG has been detected, suggesting that CGG is an unassigned codon in this bacterium. (4) A tRNATrp with anticodon UCA is present, and reads codon UGA as Trp. On the basis of these and other observations, novel codon recognition patterns in M. capricolum are proposed. A comparatively small total, 13, of modified nucleosides is contained in all M. capricolum tRNAs. The 5' end nucleoside of the T psi C-loop (position 54) of all tRNAs is uridine, not modified to ribothymidine. The anticodon composition, and hence codon recognition patterns, of M. capricolum tRNAs resemble those of mitochondrial tRNAs.     

C to U editing of the anticodon of imported mitochondrial tRNA(Trp) allows decoding of the UGA stop codon in Leishmania tarentolae

All mitochondrial tRNAs in kinetoplastid protists are encoded in the nucleus and imported into the organelle. The tRNA(Trp)(CCA) can decode the standard UGG tryptophan codon but can not decode the mitochondrial UGA tryptophan codon. We show that the mitochondrial tRNA(Trp) undergoes a specific C to U nucleotide modification in the first position of the anticodon, which allows decoding of mitochondrial UGA codons as tryptophan. Functional evidence for the absence of a UGA suppressor tRNA in the cytosol, using a reporter gene, was also obtained, which is consistent with a mitochondrial localization of this editing event. Leishmania cells have dealt with the problem of a lack of expression within the organelle of this non-universal tRNA by compartmentalizing an editing activity that modifies the anticodon of the imported tRNA.     

The leaky UGA termination codon of tobacco rattle virus RNA is suppressed by tobacco chloroplast and cytoplasmic tRNAs(Trp) with CmCA anticodon.

RNA-1 molecules from tobacco rattle virus (TRV) and pea early-browning virus (PEBV), two members of the tobravirus group, have recently been shown to contain internal, in-frame UGA termination codons which are suppressed in vitro. Our results suggest that a UGA stop codon also exists in RNA-1 of pepper ringspot virus (PRV), another tobravirus. UGA suppression may therefore be a universal feature of the expression of tobravirus genomes. We have isolated two natural suppressor tRNAs from uninfected tobacco plants on the basis of their ability to promote readthrough over the leaky UGA codon of TRV RNA-1 in a wheat germ extract depleted of endogenous mRNAs and tRNAs. Their amino acid acceptance and nucleotide sequences identify the two UGA-suppressor tRNAs as chloroplast (chl) and cytoplasmic (cyt) tryptophan-specific tRNAs with the anticodon CmCA. These are the first UGA suppressor tRNAs to be identified in plants. They have several interesting features. (i) Chl tRNA(Trp) suppresses the UGA stop codon more efficiently than cyt tRNA(Trp). (ii) Chl tRNA(Trp) contains an A24:U11 pair in the D-stem as does the mutated Escherichia coli UGA-suppressor tRNA(Trp) which is a more active suppressor than wild-type tRNA(Trp). (iii) The suppressor activity of chl tRNA(Trp) is dependent on the nucleotides surrounding the stop codon because it recognizes UGA in the TRV context but not the UGA in the beta-globin context.     

Effect of variation of charged and uncharged tRNA(Trp) levels on ppGpp synthesis in Escherichia coli.

We introduced into a stringent Escherichia coli tryptophan auxotroph a plasmid bearing the tRNA(Trp) gene under the control of an inducible promoter. This allows us to manipulate the total concentration of tRNA(Trp) in the cell according to whether and when inducer is added to the culture. We also manipulated the concentration of Trp-tRNA(Trp) in vivo since the strain used bears a mutation in the Trp-tRNA synthetase affecting the Km for tryptophan, such that varying the exogenous concentration of tryptophan led to variation in the level of Trp-tRNA(Trp) in the cell. With this system, we found that the signal eliciting ppGpp synthesis during a stringent response triggered by tryptophan limitation did not depend on the absolute concentration of either charged or uncharged tRNA(Trp) but rather depended on a decline in the ratio of charged/uncharged tRNA(Trp). In addition, we found that the amplitude of the response, once triggered by tryptophan limitation, was determined by the total concentration of tRNA(Trp) present in the cell (which is mostly uncharged at that point in time). However, excess uncharged tRNA(Trp) did not amplify ppGpp synthesis triggered by limitation of a different amino acid. These data provide in vivo support for the in vitro-derived model of ppGpp synthesis on ribosomes.