Valylation of the two RNA components of turnip-yellow mosaic virus and specificity of the tRNA aminoacylation reaction.

A comparative study of the aminoacylation of the two RNA components of turnip yellow mosaic virus, of yeast tRNAVal, tRNAfMet and of tRNAPhe by purified yeast valyl-tRNA synthetase is reported. Aminoacylations were performed in the presence of pure yeast tRNA nucleotidyltransferase, since 85% of the viral RNA molecules lacked the 3'-adenosine. We find that aminoacylation of the viral RNAs, like tRNA aminoacylation, reflects an equilibrium between the acylation and deacylation reactions. The kinetic parameters of TYM virus RNA valylation resemble the values found for tRNAVal valylation; in particular, there is a strong affinity between the viral RNA and valyl-tRNA synthetase and the rate constant for TYM virus RNA valylation is only slightly lower than that for tRNAVal. This result contrasts with the reduced rates observed in tRNA mischarging, and suggests that the viral RNA could be easily aminoacylated in vivo. Considering the fact that the 3'-terminal sequence of TYM virus RNA has only a few points of resemblance to a tRNA sequence, we propose that there are some structural motifs found in both tRNAVal and TYM virus RNA which are brought in a similar spatial arrangement recognized by valyl-tRNA synthetase.     

Purification and characterization of Chlamydomonas reinhardtii chloroplast glutamyl-tRNA synthetase, a natural misacylating enzyme

Glutamyl-tRNA synthetase from Chlamydomonas reinhardtii was purified by sequential column chromatography on DEAE-cellulose, phosphocellulose, Mono Q, and Mono S. The apparent molecular mass of the protein when analyzed under both denaturing conditions (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and nondenaturing conditions (rate zonal sedimentation on glycerol gradients) was 62,000 Da; this indicates that the active enzyme is a monomer. The purified glutamyl-tRNA synthetase was identified as the chloroplast enzyme by its tRNA charging specificity. Reversed-phase chromatography of unfractionated C. reinhardtii tRNA resolved four peaks of glutamate acceptor RNA when assayed with the purified enzyme. The enzyme can also glutamylate Escherichia coli tRNA(2Glu), but not cytoplasmic tRNA(Glu) from yeast or barley. In addition, the enzyme misacylates chloroplast tRNA(Gln) with glutamate. A similar mischarging phenomenon has been demonstrated for the barley chloroplast enzyme (Sch?n, A., Kannangara, C.G., Gough, S., and S?ll, D. (1988) Nature 331, 187-190) and for Bacillus subtilis glutamyl-tRNA synthetase (Proulx, M., Duplain, L., Lacoste, L., Yaguchi, M., and Lapointe, J. (1983) J. Biol. Chem. 258, 753-759).     

Interaction of turnip yellow mosaic virus Val-RNA with eukaryotic elongation factor EF-1 [alpha]. Search for a function

The 3'-terminal tRNA-like structure in turnip yellow mosaic virus (TYMV) RNA can be adenylated by tRNA nucleotidyltransferase and subsequently aminoacylated by valyl-tRNA synthetase.Here we present evidence that TYMV Val-RNA can form a stable complex with eukaryotic wheat germ elongation factor EF-1alpha and GTP: the Val-RNA is protected by EF-1alpha.. GTP against digestion by RNase A. By affinity chromatography of TYMV Val-RNA fragments on immobilized EF-1alpha . GTP, it has been established that the valylated aminoacyl RNA domain, which in TYMV RNA is formed by the 3' half of the tRNA-like region, is sufficient for complex formation with EF-1alpha . GTP. The aminoacyl RNA domain is equivalent in tRNAs to the continuous helix formed by the acceptor stem and the T stem and loop. In line with these results, the aminoacyl RNA domain in TYMV Val-RNA complexed to EF-1 alpha . GTP is resistant to digestion by RNase A. It is also shown that the TYMV RNA replicase (RNA-dependent RNA polymerase) isolated from TYMV-infected Chinese cabbage leaves does not contain tRNA nucleotidyltransferase, valyl-tRNA synthetase or EF-1alpha. This suggests that interaction of TYMV RNA with EF-1alpha is not mandatory for replicase activity.     

3-D graphics modelling of the tRNA-like 3'-end of turnip yellow mosaic virus RNA: structural and functional implications

The tRNA-like structure of the aminoacylatable 3'-end of turnip yellow mosaic virus (TYMV) RNA was submitted to 3-D graphics modelling. A model of this structure has been inferred previously from both biochemical results and sequence comparisons which presents a new RNA folding feature, the "pseudoknot". It has been verified that this structure can be constructed without compromising accepted RNA stereochemical rules, namely base stacking and preferential 3'-endo sugar pucker. The model has aided interpretation of previous structural mapping experiments using chemical and enzymatic probes, and new accessibilities of residues could be predicted and tested. Pseudoknots have been considered as potential splice sites because they form antiparallel helical segments in a single RNA molecule. We have examined this possibility with the constructed 3-D model and could verify the hypothesis on a structural basis. The model presents a striking similarity with canonical tRNA and allows a valuable comparison between the protection patterns of yeast tRNA(Val) and tRNA-like viral RNA by cognate yeast valyl-tRNA synthetase against structural probes.     

Covariation of a specificity-determining structural motif in an aminoacyl-tRNA synthetase and a tRNA identity element

Transfer RNA (tRNA) identity determinants help preserve the specificity of aminoacylation in vivo, and prevent cross-species interactions. Here, we investigate covariation between the discriminator base (N73) element in histidine tRNAs and residues in the histidyl-tRNA synthetase (HisRS) motif 2 loop. A model of the Escherichia coli HisRS--tRNA(His) complex predicts an interaction between the prokaryotic conserved glutamine 118 of the motif 2 loop and cytosine 73. The substitution of Gln 118 in motif 2 with glutamate decreased discrimination between cytosine and uracil some 50-fold, but left overall rates of adenylation and aminoacylation unaffected. By contrast, substitutions at neighboring Glu 115 and Arg 121 affected both adenylation and aminoacylation, consistent with their predicted involvement in both half-reactions. Additional evidence for the involvement of the motif 2 loop was provided by functional analysis of a hybrid Saccharomyces cerevisiae-- E. coli HisRS possessing the 11 amino acid motif 2 loop of the yeast enzyme. Despite an overall decreased activity of nearly 1000-fold relative to the E. coli enzyme, the chimera nevertheless exhibited a modest preference for the yeast tRNA(His) over the E. coli tRNA, and preferred wild-type yeast tRNA(His) to a variant with C at the discriminator position. These experiments suggest that part of, but not all of, the specificity is provided by the motif 2 loop. The close interaction between enzyme loop and RNA sequence elements suggested by these experiments reflects a covariation between enzyme and tRNA that may have acted to preserve aminoacylation fidelity over evolutionary time.     

The tRNA-like structure at the 3' terminus of turnip yellow mosaic virus RNA. Differences and similarities with canonical tRNA.

The 3' terminus of TYMV RNA, which possesses tRNA-like properties, has been studied. A 3' terminal fragment of 112 nucleotides was obtained by cleavage with RNase H after hybridization of a synthetic oligodeoxynucleotide to the viral RNA. The accessibility of cytidine and adenosine residues was probed with chemical modification. Enzymatic digestion studies were performed with RNase T1, nuclease S1 and the double-strand specific RNase from the venom of the cobra Naja naja oxiana. A model is proposed for the secondary structure of the 3' terminal region of TYMV RNA comprising 86 nucleotides. The main feature of this secondary structure is the absence of a conventional acceptor stem as present in canonical tRNA. However, the terminal 42 nucleotides can be folded in a tertiary structure which bears strong resemblance with the acceptor arm of canonical tRNA. Comparison of this region of TYMV RNA with that of other RNAs from both the tymovirus group and the tobamovirus group gives support to our proposal for such a three-dimensional arrangement. The consequences for the recognition by TYMV RNA of tRNA-specific enzymes is discussed.     

The fidelity of protein synthesis: can mischarging by aspartyl-tRNA(Asp) synthetase lead to the formation of isoaspartyl residues in proteins?

We have tested the hypothesis that isoaspartic acid residues in proteins can arise via errors that occur during protein synthesis. One such error involves a mischarging step in which the aspartic acid side-chain beta-carboxyl group is linked to the tRNA(Asp) instead of the main chain alpha-carboxyl group. If this altered Asp-tRNA(Asp) is a substrate for the ribosomal elongation reactions, a polypeptide will be made with an isoaspartic acid, or beta-linkage, in which the peptide chain is branched at the side chain of the aspartic acid residue. Using an ammonium sulfate fraction of aspartyl-tRNA(Asp) synthetase from Escherichia coli and [3H]aspartic acid, we have prepared [3H]aspartyl-tRNA(Asp) complexes and directly analyzed the linkage of the [3H]aspartate to the tRNA by identifying the products of ammonolysis. Normal attachment of the alpha-carboxyl group of aspartate to the tRNA produces [3H]isoasparagine, while the mischarging reaction leads to [3H]asparagine formation after ammonolysis. We have separated [3H]isoasparagine from [3H]asparagine and found an upper limit of 1 asparagine per 10,000 isoasparagines. These results show that the bacterial aminoacyl-tRNA synthetase can very accurately distinguish between the alpha- and beta-carboxyl groups of aspartic acid and suggest that only a very small fraction of the isoaspartic acid residues found to occur in cellular proteins may be the result of mischarging steps.     

G-1:C73 recognition by an arginine cluster in the active site of Escherichia coli histidyl-tRNA synthetase

Aminoacylation of a transfer RNA (tRNA) by its cognate aminoacyl-tRNA synthetase relies upon the recognition of specific nucleotides as well as conformational features within the tRNA by the synthetase. In Escherichia coli, the aminoacylation of tRNA(His) by histidyl-tRNA synthetase (HisRS) is highly dependent upon the recognition of the unique G-1:C73 base pair and the 5'-monophosphate. This work investigates the RNA-protein interactions between the HisRS active site and these critical recognition elements. A homology model of the tRNA(His)-HisRS complex was generated and used to design site-specific mutants of possible G-1:C73 contacts. Aminoacylation assays were performed with these HisRS mutants and N-1:C73 tRNA(His) and microhelix(His) variants. Complete suppression of the negative effect of 5'-phosphate deletion by R123A HisRS, as well as the increased discrimination of Q118E HisRS against a 5'-triphosphate, suggests a possible interaction between the 5'-phosphate and active-site residues Arg123 and Gln118 in which these residues create a sterically and electrostatically favorable pocket for the binding of the negatively charged phosphate group. Additionally, a network of interactions appears likely between G-1 and Arg116, Arg123, and Gln118 because mutation of these residues significantly reduced the sensitivity of HisRS to changes at G-1. Our studies also support an interaction previously proposed between Gln118 and C73. Defining the RNA-protein interactions critical for efficient aminoacylation by E. coli HisRS helps to further characterize the active site of this enzyme and improves our understanding of how the unique identity elements in the acceptor stem of tRNA(His) confer specificity.     

In vitro conversion of a methionine to a glutamine-acceptor tRNA

A derivative of Escherichia coli tRNAfMet containing an altered anticodon sequence, CUA, has been enzymatically synthesized in vitro. The variant tRNA was prepared by excision of the normal anticodon, CAU, in a limited digestion of intact tRNAfMet with RNase A, followed by insertion of the CUA sequence into the anticodon loop with T4 RNA ligase and polynucleotide kinase. The altered methionine tRNA showed a large enhancement in the rate of aminoacylation by glutaminyl-tRNA synthetase and a large decrease in the rate of aminoacylation by methionyl-tRNA synthetase. Measurement of kinetic parameters for the charging reaction by the cognate and noncognate enzymes revealed that the modified tRNA is a better acceptor for glutamine than for methionine. The rate of mischarging is similar to that previously reported for a tryptophan amber suppressor tRNA containing the anticodon CUA, su+7 tRNATrp, which is aminoacylated with glutamine both in vivo and in vitro [Yaniv, M., Folk, W. R., Berg, P., & Soll, L. (1974) J. Mol. Biol. 86, 245-260; Yarus, M., Knowlton, R. E., & Soll, L. (1977) in Nucleic Acid-Protein Recognition (Vogel, H., Ed.) pp 391-408, Academic Press, New York]. The present results provide additional evidence that the specificity of aminoacylation by glutaminyl-tRNA synthetase is sensitive to small changes in the nucleotide sequence of noncognate tRNAs and that uridine in the middle position of the anticodon is involved in the recognition of tRNA substrates by this enzyme.