Nucleotide sequence of an arginine transfer ribonucleic acid from bacteriophage T4.

The nucleotide sequence of a phage T4-coded low molecular weight RNA, previously designated polyacrylamide gel band epsilon, has been determined. This RNA can be arranged in the cloverleaf configuration common to tRNAs, with an anticodon sequence, U-C-U, which corresponds to the arginine-specific codons A-G-A and A-G-G; it is therefore assumed to be an arginine tRNA. The complete nucleotide sequence of this RNA species is: pG-U-C-C-C-G-C-U-G-G-U-G-U-A-A-U-Gm2'-G-A-D-A-G-C-A-U-A-C-G-A-U-C-C-U-U-C-U-A-A-G-psi-U-U-G-C-G-G-U-C-C-U-G-G-T-psi-C-G-A-U-C-C-C-A-G-G-G-C-G-G-G-A-U-A-C-C-AOH. The nucleotide sequence was determined by analysis of RNA, uniformly labeled in vivo, according to the conventional techniques. In addition, RNA synthesized in vitro in the presence of alpha-32P-labeled nucleoside triphosphates was analyzed through the use of nearest neighbor sequencing techniques. Although a unique sequence could not be determined by this latter analysis, restrictions on the sequence imposed by nearest neighbor data and secondary structure common to tRNA molecules allowed prediction of the correct nucleotide sequence.     

Nucleotide sequence studies of normal and genetically altered glycine transfer ribonucleic acids from Escherichia coli.

The total nucleotide sequence of tRNAGGA/G -Gly2 from Escherichia coli is pG-C-G-G-G-C-A-U-C-G-U-A-U-A-A-U-G-G-C-U-A-U-U-A-C-C-U-C-A-G-C-C-U-N-C-C-A-A-G-C-U-G-A-U-G-A-U-G-C-G-G-G-T-psi-C-G-A-U-U-C-C-C-G-C-U-G-C-C-C-G-C-U-C-C-AOH, where T- at position 53 is ribothymidylic acid, and psi- at position 54 is pseudouridylic acid; N- at position 36 is an unidentified derivative of uridylic acid, and is present in modified form in a portion of tRNAGGA/G -Gly 2 molecules isolated from E. coli cells. The missense suppressor mutation, glyTsuA36(HA), results in a C yields U base substitution at the 3' end of the anticodon of tRNAGGA/G -Gly 2 (nucleotide position 38). A secondary effect of this base substitution is the modification of the A residue directly adjacent to the 3' end of the anticodon of tRNAsuA36(HA), -Gly 2 suggesting that the enzymes responsible for this modification recognize the anticodon sequences of prospective tRNA substrates. The creation of a missense-suppressing tRNA, tRNAsuA36(HA), -Gly 2 by an alteration of the anticodon sequence of tRNAGGA/G -Gly 2 is analogous to mechanisms whereby other suppressor tRNAs have arisen. The high degree of nucleotide sequence homology between the amino acid acceptor stems and anticodon regions of four glycine isoaccepting tRNAs specified by E. coli and bacteriophage T4 suggests that these regions may be recognized by the glycyl-tRNA synthetase; the involvement of the anticodon region in the synthetase recognition process is supported by the greatly decreased rate of aminoacylation of tRNAsuA36(HA) -Gly 2.     

The nucleotide sequences of the two glutamine transfer ribonucleic acids from Escherichia coli.

The nucleotide sequences of the two glutamine tRNA species in Escherichia coli K12 have been determined. Sufficient data was obtained to order unambiguously the products of complete RNase digestion of tRNA2Gln, and all but one oligonucleotide from tRNA1Gln. The sequence of tRNA1Gln was established by analogy with tRNA1Gln, as the two tRNAs are very similar, differing by only 7 residues out of 75. tRNA1Gln has the anticodon NUG, where N is a modified nucleotide which is likely to be a derivative of 2-thiouridine, and is specific for the codon CAA. tRNA1Gln has the anticodon CUG, and is specific for the codon CAG (Folk, W. R., and Yaniv, M. (1972) Nature 237, 165). The complete sequences of the tRNAGln species are: See journal for formula (Unique residues are enclosed in parentheses, with the residue in tRNA1Gln above that in tRNA2Gln.).     

Isoaccepting lysine transfer ribonucleic acid species of Pseudomonas aeruginosa.

Pseudomonas aeruginosa tRNA was treated with iodine, CNBr and N-ethylmaleimide, three thionucleotide-specific reagents. Reaction with iodine resulted in extensive loss of acceptor activity by lysine tRNA, glutamic acid tRNA, glutamine tRNA, serine tRNA and tyrosine tRNA. CNBr treatment resulted in high loss of acceptor ability by lysine tRNA, glutamic acid tRNA and glutamine tRNA. Only the acceptor ability of tyrosine tRNA was inhibited up to 66% by N-ethylmaleimide treatment, a reagent specific for 4-thiouridine. By the combined use of benzoylated DEAE-cellulose and DEAE-Sephadex columns, lysine tRNA of Ps. aeruginosa was resolved into two isoaccepting species, a major, tRNA Lys1 and a minor, tRNALys1. Co-chromatography of 14C-labelled tRNALys1 and 3H-labelled tRNALys2 on benzoylated DEAE-cellulose at pH 4.5 gave two distinct, non-superimposable profiles for the two activity peaks, suggesting that they were separate species. The acceptor activity of these two species was inhibited by about 95% by iodine and CNBr. Both the species showed equal response to codons AAA and AAG and also for poly(A) and poly(A1,G1) suggesting that the anticodon of these species was UUU. Chemical modification of these two species by iodine did not inhibit the coding response. The two species of lysine of Ps. aeruginosa are truly redundant in that they are indistinguishable either by chemical modification or by their coding response.     

A primer ribonucleic acid for initiation of in vitro Rous sarcarcoma virus deoxyribonucleic acid synthesis.

The nucleotide sequence of an RNA primer molecule for initiation of Rous sarcoma virus DNA synthesis in vitro has been determined. The sequence can be drawn in a cloverleaf structure typical of tRNAs with an anticodon for tryptophan. Aminoacylation of the molecule confirms that it is tRNA-Trp. The same sequence and aminoacylation results are obtained regardless of whether the RNA is isolated from virions or from cells of chickens, the natural host for this virus. It is the only species of tRNA-Trp that is dectected in chicked cell tRNA.     

Nucleotide sequence determination of bacteriophage T4 glycine transfer ribonucleic acid

The nucleotide sequence of a T4 tRNA with an anticodon for glycine has been determined using ³²P-labeled material from T4-infected cultures of Escherichia coli. The sequence is: pGCGGAUAUCGUAUAAUGmGDAUUACCUCAGACUUCCAAψCUGAUGAUGUGAGTψCGAUUCUCAUUAUCCGCUCCA-OH. The 74 nucleotide sequence can be arranged in the classic cloverleaf pattern for tRNAs. The anticodon of T4 tRNA^Gly is UCC with a possible modification of the U. The tRNA molecule would thus be expected to recognize the glycine codons GGG and GGA. Comparative analysis of tRNAs^Gly from T2 and T6 indicate that their sequences are identical with that from T4.     

molecular mechanism of lysidine synthesis that determines tRNA identity and codon recognition

Lysidine (2-lysyl cytidine) is a lysine-containing cytidine derivative commonly found at the wobble position of bacterial AUA codon-specific tRNA(Ile). This modification determines both codon and amino acid specificities of tRNA(Ile). We previously identified tRNA(Ile)-lysidine synthetase (tilS) that synthesizes lysidine, for which it utilizes ATP and lysine as substrates. Here, we show that lysidine synthesis consists of two consecutive reactions that involve an adenylated tRNA intermediate. A mutation study revealed that Escherichia coli TilS discriminates tRNA(Ile) from the structurally similar tRNA(Met) having the same anticodon loop by recognizing the anticodon loop, the anticodon stem, and the acceptor stem. TilS was shown to bind to the anticodon region and 3' side of the acceptor stem, which cover the recognition sites. These findings reveal a dedicated mechanism embedded in tRNA(Ile) that controls its recognition and discrimination by TilS, and indicate the significance of this enzyme in the proper deciphering of genetic information.     

Responsibility of tRNA(Ile) for spermine stimulation of rat liver Ile-tRNA formation

To determine whether tRNA or aminoacyl-tRNA synthetase is responsible for spermine stimulation of rat liver Ile-tRNA formation, homologous and heterologous Ile-tRNA formations were carried out with Escherichia coli and rat liver tRNA(Ile) and their respective purified Ile-tRNA synthetases. Spermine stimulation was observed only when tRNA from the rat liver was used. Spermine bound to rat liver tRNA(Ile) but not to the purified aminoacyl-tRNA synthetase complex. Kinetic analysis of Ile-tRNA formation revealed that spermine increased the Vmax and Km values for rat liver tRNA(Ile). The Km value for ATP and isoleucine did not change significantly in the presence of spermine. Furthermore, higher concentrations of rat liver tRNA(Ile) tended to inhibit Ile-tRNA formation if spermine was absent. Spermine restored isoleucine-dependent PPi-ATP exchange in the presence of rat liver tRNA(Ile), an inhibitor of this exchange. The nucleotide sequence of rat liver tRNA(Ile) was determined and compared with that of E. coli tRNA(Ile). Differences in nucleotide sequences of the two tRNAs(Ile) were observed mainly in the acceptor and anticodon stems. Limited ribonuclease V1 digestion of the 3'-32P-labeled rat liver tRNA(Ile) showed that both the anticodon and acceptor stems were structurally changed by spermine, and that the structural change by spermine was different from that by Mg2+. The influence of spermine on the ribonuclease V1 digestion of E. coli tRNA(Ile) was different from that of rat liver tRNA(Ile). The results suggest that the interaction of spermine with the acceptor and anticodon stems may be important for spermine stimulation of rat liver Ile-tRNA formation.     

Suppression of amber codons in vivo as evidence that mutants derived from Escherichia coli initiator tRNA can act at the step of elongation in protein synthesis

The absence of a Watson-Crick base pair at the end of the amino acid acceptor stem is one of the features which distinguishes prokaryotic initiator tRNAs as a class from all other tRNAs. We show that this structural feature prevents Escherichia coli initiator tRNA from acting as an elongator in protein synthesis in vivo. We generated a mutant of E. coli initiator tRNA in which the anticodon sequence is changed from CAU to CUA (the T35A36 mutant). This mutant tRNA has the potential to read the amber termination codon UAG. We then coupled this mutation to others which change the C1.A72 mismatch at the end of the acceptor stem to either a U1:A72 base pair (T1 mutant) or a C1:G72 base pair (G72 mutant). Transformation of E. coli CA274 (HfrC Su- lacZ125am trpEam) with multicopy plasmids carrying the mutant initiator tRNA genes show that mutant tRNAs carrying changes in both the anticodon sequence and the acceptor stem suppress amber codons in vivo, whereas mutant tRNA with changes in the anticodon sequence alone does not. Mutant tRNAs with the above anticodon sequence change are aminoacylated with glutamine in vitro. Measurement of kinetic parameters for aminoacylation by E. coli glutaminyl-tRNA synthetase show that both the nature of the base pair at the end of the acceptor stem and the presence or absence of a base pair at this position can affect aminoacylation kinetics. We discuss the implications of this result on recognition of tRNAs by E. coli glutaminyl-tRNA synthetase.     

The selective reaction of methoxyamine with cytidine residues in mammalian initiator transfer ribonucleic acid

Methoxyamine reacts selectively with tRNA molecules at certain exposed cytosine residues usually located in non base-paired regions of the two dimensional clover leaf structure. Here methoxyamine is used for the first time in a study of a mammalian tRNA structure. One of the sequence abnormalities of myeloma initiator tRNA is a cytosine instead of the usual uracil immediately preceding the anticodon. A study of the reaction of the cytosine residues with methoxyamine indicates that the accessibility of bases to chemical reagents in the anticodon loop of this mammalian initiator tRNA is very similar to that observed for the bacterial initiator tRNA.     

The corrected nucleotide sequence of yeast leucine transfer ribonucleic acid

The nucleotide sequence of “Renaturable” leucine transfer RNA from Baker's yeast has been re-investigated. The results showed that (i) this tRNA has a sequence of DCD at positions 19–21, (ii) it has an anticodon m⁵CAA and (iii) it has a pseudouridine at position 40.     

The nucleotide sequence of threonine transfer RNA coded by bacteriophage T4.

The nucleotide sequence of a low molecular weight RNA coded by bacteriophage T4 (and previously identified as species alpha) has been determined. The molecule is of particular biological interest for its associated biosynthetic properties. This RNA is 76 nucleotides in length, contains eight modified bases, and can be arranged in a cloverleaf configuration common to tRNAs. The anticodon sequence is UGU, which corresponds to the threonine-specific codons ACA G. The nucleotide sequence was determined primarily by nearest-neighbor analysis of RNA synthesized in vitro using [alpha-32P]nucleoside triphosphates. Using the single-strand specific nuclease S1, two in vivo labeled half-molecules were generated and analysed. This information together with restrictions imposed by nearest-neighbor data, provided a unique linear sequence of nucleotides with the features of secondary structure common to tRNA molecules.     

Correlation between spermine stimulation of rat liver Ile-tRNA formation and structural change of the acceptor stem by spermine

We have recently reported that the interaction of spermine with the acceptor and anticodon stems may be important for spermine stimulation of rat liver Ile-tRNA formation [Peng, Z. et al. (1990) Arch. Biochem. Biophys. 279, 138-145]. To pinpoint which interaction of spermine is more important for spermine stimulation of Ile-tRNA formation, Ile-tRNA formation and ribonuclease V1 sensitivity of tRNA(Ile) were studied using purified tRNAs(Ile) from rat liver, wheat germ, brewer's yeast, torula yeast and Escherichia coli. The results indicate that spermine stimulation of rat liver Ile-tRNA formation correlated with the structural change of the acceptor stem by spermine. The nucleotide sequence of wheat germ tRNA(Ile) was also determined.     

Multiple gene loci for a single species of glycine transfer ribonucleic acid.

The study of suppressors of tryptophan synthase A protein missense mutations in Escherichia coli has led to the establishment of two nonadjacent genetic loci (gly V and gly W) specifying identical nucleotide sequences for a single isoaccepting species of glycine transfer ribonucleic acid (tRNA GLY 3 GGU/C). In one case, suppression of the missense mutation trpA78 was due to a mutation in a structural gene (gly W) for tRNA Gly 3 GGU/C. This mutation resulted in a base change in the anticodon and modification of an A residue adjacent to the 3' side of the anticodon, leading to the production of a tRNA Gly 3 UGU/C species. The resulting glyW51 (SU UGU/C) allele was mapped by interrupted mating and was located at approximately 37 min on the Escherichia coli genetic map. Other suppressor mutations affecting the primary sequence of tRNA Gly GGU/C and giving rise to the Ins and SU+A58 phenotypes were positioned at 86 min (glyV). Several independently arising missense suppressor mutations resulting in the SU+A78 phenotypes were isolated and mapped at these two genetic loci (glyV and glyW). The ratio of appearance of suppressor mutations at glyV and glyW suggests that there are three of four tRNAGly3 GGU/C structural gene copies at the glyV locus to one copy at the glyW locus. Structural genes for tRNA ly isoacceptors are now known at four distinct locations on the Escherichia coli chromosome: glyT (77 MIN), TRNA Gly 2 GGA/G; gly U (55 min), tRNAGly-1 minus; and gly V (86 MIN) AND GLYW (37 min), tRNAGly 3 GGU/C.     

The selenocysteine-inserting opal suppressor serine tRNA from E. coli is highly unusual in structure and modification.

Selenocysteine is cotranslationally incorporated into selenoproteins in a unique pathway involving tRNA mediated suppression of a UGA nonsense codon (1-3). The DNA sequence of the gene for this suppressor tRNA from Escherichia coli predicts unusual features of the gene product (4). We determined the sequence of this serine tRNA (tRNA(UCASer]. It is the longest tRNA (95 nt) known to date with an acceptor stem of 8 base pairs and lacks some of the 'invariant' nucleotides found in other tRNAs. It is the first E. coli tRNA that contains the hypermodified nucleotide i6A, adjacent to the UGA-recognizing anticodon UCA. The implications of the unusual structure and modification of this tRNA on recognition by seryl-tRNA synthetase, by tRNA modifying enzymes, and on codon recognition are discussed.     

Yeast mitochondrial tRNAIle and tRNAMetm: nucleotide sequence and codon recognition patterns.

The nucleotide sequence of yeast mitochondrial isoleucine- and methionine-elongator tRNA have been determined. Interestingly, long stretches of almost identical nucleotide sequences are found within these two tRNAs and also within the yeast mt tRNAMetf, suggesting that the 3 tRNAs may have arisen from a common ancestor. Both mt tRNAMetm and tRNAIle contain all the structural characteristics which are present in the standard cloverleaf, except that the mt tRNAMetm contains an extra unpaired nucleotide within the base-paired T psi C stem. This rather unusual feature may have an influence on the decoding properties of the C-A-U anticodon of mt tRNAMetm by conferring the ability to translate not only the codon A-U-G but also A-U-A.     

Divergent adaptation of tRNA recognition by Methanococcus jannaschii prolyl-tRNA synthetase

Analysis of prolyl-tRNA synthetase (ProRS) across all three taxonomic domains (Eubacteria, Eucarya, and Archaea) reveals that the sequences are divided into two distinct groups. Recent studies show that Escherichia coli ProRS, a member of the "prokaryotic-like" group, recognizes specific tRNA bases at both the acceptor and anticodon ends, whereas human ProRS, a member of the "eukaryotic-like" group, recognizes nucleotide bases primarily in the anticodon. The archaeal Methanococcus jannaschii ProRS is a member of the eukaryotic-like group, although its tRNA(Pro) possesses prokaryotic features in the acceptor stem. We show here that, in some respects, recognition of tRNA(Pro) by M. jannaschii ProRS parallels that of human, with a strong emphasis on the anticodon and only weak recognition of the acceptor stem. However, our data also indicate differences in the details of the anticodon recognition between these two eukaryotic-like synthetases. Although the human enzyme places a stronger emphasis on G35, the M. jannaschii enzyme places a stronger emphasis on G36, a feature that is shared by E. coli ProRS. These results, interpreted in the context of an extensive sequence alignment, provide evidence of divergent adaptation by M. jannaschii ProRS; recognition of the tRNA acceptor end is eukaryotic-like, whereas the details of the anticodon recognition are prokaryotic-like. This divergence may be a reflection of the unusual dual function of this enzyme, which catalyzes specific aminoacylation with proline as well as with cysteine.