Nucleotides of tRNA governing the specificity of Escherichia coli methionyl-tRNA(fMet) formyltransferase.

In Escherichia coli, the free amino group of the aminoacyl moiety of methionyl-tRNA(fMet) is specifically modified by a transformylation reaction. To identify the nucleotides governing the recognition of the tRNA substrate by the formylase, initiator tRNA(fMet) was changed into an elongator tRNA with the help of an in vivo selection method. All the mutations isolated were in the tRNA acceptor arm, at positions 72 and 73. The major role of the acceptor arm was further established by the demonstration of the full formylability of a chimaeric tRNA(Met) containing the acceptor stem of tRNA(fMet) and the remaining of the structure of tRNA(mMet). In addition, more than 30 variants of the genes encoding tRNA(mMet) or tRNA(fMet) have been constructed, the corresponding mutant tRNA products purified and the parameters of the formylation reaction measured. tRNA(mMet) became formylatable by the only change of the G1.C72 base-pair into C1-A72. It was possible to render tRNA(mMet) as good a substrate as tRNA(fMet) for the formylase by the introduction of a limited number of additional changes in the acceptor stem. In conclusion, A73, G2.C71, C3.G70 and G4.C69 are positive determinants for the specific processing of methionyl-tRNA(fMet) by the formylase while the occurrence of a G.C or C.G base-pair between positions 1 and 72 acts as a major negative determinant. This pattern appears to account fully for the specificity of the formylase and the lack of formylation of any aminoacylated tRNA, excepting the methionyl-tRNA(fMet).     

Role of the 1-72 base pair in tRNAs for the activity of Escherichia coli peptidyl-tRNA hydrolase.

Previous work by Schulman and Pelka (1975) J. Biol. Chem. 250, 542-547, indicated that the absence of a pairing between the bases 1 and 72 in initiator tRNA(fMet) explained the relatively small activity of peptidyl-tRNA hydrolase towards N-acetyl-methionyl-tRNA(fMet). In the present study, the structural requirements for the sensitivity of an N-acetyl-aminoacyl-tRNA to Escherichia coli peptidyl-tRNA hydrolase activity have been further investigated. Ten derivatives of tRNA(fMet) with various combinations of bases at positions 1 and 72 in the acceptor stem have been produced, aminoacylated and chemically acetylated. The release of the aminoacyl moiety from these tRNA derivatives was assayed in the presence of peptidyl-tRNA hydrolase purified from an overproducing strain. tRNA(fMet) derivatives with either C1A72, C1C72, U1G72, U1C72 or A1C72 behaved as poor substrates of the enzyme, as compared to those with C1G72, U1A72, G1C72, A1U72 or G1U72. With the exception of U1G72, it could be therefore concluded that the relative resistance of tRNA(fMet) to peptidyl-tRNA hydrolase did not depend on a particular combination of nucleotides at positions 1 and 72, but rather reflected the absence of a base pairing at these positions. In a second series of experiments, the unpairing of the 1 and 72 bases, created with C-A or A-C bases, instead of G-C in methionyl-tRNA(mMet) or in valyl-tRNA(Val1), was shown to markedly decrease the rate of hydrolysis catalysed by peptidyl-tRNA hydrolase. Altogether, the data indicate that the stability of the 1-72 pair governs the degree of sensitivity of a peptidyl-tRNA to peptidyl-tRNA hydrolase.     

Conversion of a methionine initiator tRNA into a tryptophan-inserting elongator tRNA in vivo.

The role of the anticodon and discriminator base in aminoacylation of tRNAs with tryptophan has been explored using a recently developed in vivo assay based on initiation of protein synthesis by mischarged mutants of the Escherichia coli initiator tRNA. Substitution of the methionine anticodon CAU with the tryptophan anticodon CCA caused tRNA(fMet) to be aminoacylated with both methionine and tryptophan in vivo, as determined by analysis of the amino acids inserted by the mutant tRNA at the translational start site of a reporter protein containing a tryptophan initiation codon. Conversion of the discriminator base of tRNA(CCA)fMet from A73 to G73, the base present in tRNA(Trp), eliminated the in vivo methionine acceptor activity of the tRNA and resulted in complete charging with tryptophan. Single base changes in the anticodon of tRNA(CCA)fMet containing G73 from CCA to UCA, GCA, CAA, and CCG (changes underlined) essentially abolished tryptophan insertion, showing that all three anticodon bases specify the tryptophan identity of the tRNA. The important role of G73 in tryptophan identity was confirmed using mutants of an opal suppressor derivative of tRNA(Trp). Substitution of G73 with A73, C73, or U73 resulted in a large loss of the ability of the tRNA to suppress an opal stop codon in a reporter protein. Base pair substitutions at the first three positions of the acceptor stem of the suppressor tRNA caused 2-12-fold reductions in the efficiency of suppression without loss of specificity for aminoacylation of the tRNA with tryptophan.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural and sequence elements important for recognition of Escherichia coli formylmethionine tRNA by methionyl-tRNA transformylase are clustered in the acceptor stem

We show that the structure and/or sequence of the first three base pairs at the end of the amino acid acceptor stem of Escherichia coli initiator tRNA and the discriminator base 73 are important for its formylation by E. coli methionyl-tRNA transformylase. This conclusion is based on mutagenesis of the E. coli initiator tRNA gene followed by measurement of kinetic parameters for formylation of the mutant tRNAs in vitro and function in protein synthesis in vivo. The first base pair found at the end of the amino acid acceptor stem in all other tRNAs is replaced by a C.A. "mismatch" in E. coli initiator tRNA. Mutation of this C.A. to U:A, a weak base pair, or U.G., a mismatch, has little effect on formylation, whereas mutation to C:G, a strong base pair, has a dramatic effect lowering Vmax/Kappm by 495-fold. Mutation of the second basepair G2:C71 to U2:A71 lowers Vmax/Kappm by 236-fold. Replacement of the third base-pair C3:G70 by U3:A70, A3:U70, or G3:C70 lowers Vmax/Kappm by about 67-, 27-, and 30-fold, respectively. Changes in the rest of the acceptor stem, dihydrouridine stem, anticodon stem, anticodon sequence, and T psi C stem have little or no effect on formylation.     

A nucleotide that enhances the charging of RNA minihelix sequence variants with alanine.

We showed earlier that a single G3.U70 base pair within the amino acid acceptor helix is a major determinant of the identity of tRNA(Ala). In addition, we demonstrated that an RNA hairpin minihelix that recreates the 12 base pair acceptor-T psi C stem of tRNA(Ala) is also aminoacylated in a G3.U70-dependent manner. Determinants for efficient aminoacylation at pH 7.5 have been further investigated with minihelix substrates that have sequence variations at 3.70 and other locations. Although a U,U mismatch and other 3.70 nucleotide alternatives to G.U were recently proposed by others as also important for alanine acceptance, neither that mismatch nor any of four other 3.70 nucleotide combinations confer aminoacylation in vitro with alanine, even with substrate levels of enzyme. In contrast, permutations of the so-called discriminator nucleotide N73 (at position 73) strongly modulate, but do not block, aminoacylation of those substrates that encode G3.U70. In particular, the efficiency of G3.U70-dependent aminoacylation with alanine is strongly enhanced by having the wild-type A73. The effect of N73 alone can explain most of the difference in aminoacylation efficiency of a G3.U70-containing tRNA and a minihelix substrate whose sequences vary significantly from their tRNA(Ala) counterparts. Comparison with earlier work suggests that the substantial modulating effect of N73 is partly or completely obscured when N73 tRNA variants are expressed as amber suppressors in vivo.     

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     

The fate of the initiator tRNAs is sensitive to the critical balance between interacting proteins

Formylation of the initiator tRNA is essential for normal growth of Escherichia coli. The initiator tRNA containing the U35A36 mutation (CUA anticodon) initiates from UAG codon. However, an additional mutation at position 72 (72A --> G) renders the tRNA (G72/U35A36) inactive in initiation because it is defective in formylation. In this study, we isolated U1G72/U35A36 tRNA containing a wobble base pair at 1-72 positions as an intragenic suppressor of the G72 mutation. The U1G72/U35A36 tRNA is formylated and participates in initiation. More importantly, we show that the mismatch at 1-72 positions of the initiator tRNA, which was thus far thought to be the hallmark of the resistance of this tRNA against peptidyl-tRNA hydrolase (PTH), is not sufficient. The amino acid attached to the initiator tRNA is also important in conferring protection against PTH. Further, we show that the relative levels of PTH and IF2 influence the path adopted by the initiator tRNAs in protein synthesis. These findings provide an important clue to understand the dual function of the single tRNA(Met) in initiation and elongation, in the mitochondria of various organisms.     

Structural basis for orthogonal tRNA specificities of tyrosyl-tRNA synthetases for genetic code expansion

The archaeal/eukaryotic tyrosyl-tRNA synthetase (TyrRS)-tRNA(Tyr) pairs do not cross-react with their bacterial counterparts. This 'orthogonal' condition is essential for using the archaeal pair to expand the bacterial genetic code. In this study, the structure of the Methanococcus jannaschii TyrRS-tRNA(Tyr)-L-tyrosine complex, solved at a resolution of 1.95 A, reveals that this archaeal TyrRS strictly recognizes the C1-G72 base pair, whereas the bacterial TyrRS recognizes the G1-C72 in a different manner using different residues. These diverse tRNA recognition modes form the basis for the orthogonality. The common tRNA(Tyr) identity determinants (the discriminator, A73 and the anticodon residues) are also recognized in manners different from those of the bacterial TyrRS. Based on this finding, we created a mutant TyrRS that aminoacylates the amber suppressor tRNA with C34 65 times more efficiently than does the wild-type enzyme.     

The anticodon and discriminator base are major determinants of cysteine tRNA identity in vivo.

Mutants of the Escherichia coli initiator tRNA (tRNA(fMet)) have been used to examine the role of the anticodon and discriminator base in in vivo aminoacylation of tRNAs by cysteinyl-tRNA synthetase. Substitution of the methionine anticodon CAU with the cysteine anticodon GCA was found to allow initiation of protein synthesis by the mutant tRNA from a complementary initiation codon in a reporter protein. Sequencing of the protein revealed that cysteine comprised about half of the amino acid at the N terminus. An additional mutation, converting the discriminator base of tRNA(GCAfMet) from A73 to the base present in tRNA(Cys) (U73), resulted in a 6-fold increase in the amount of protein produced and insertion of greater than or equal to 90% cysteine in response to the complementary initiation codon. Substitution of C73 or G73 at the discriminator position led to insertion of little or no cysteine, indicating the importance of U73 for recognition of the tRNA by cysteinyl-tRNA synthetase. Single base changes in the anticodon of tRNA(GCAfMet) containing U73 from GCA to UCA, GUA, GCC, and GCG (changes underlined) eliminated or dramatically reduced cysteine insertion by the mutant initiator tRNA indicating that all three cysteine anticodon bases are essential for specific aminoacylation of the tRNA with cysteine in vivo.     

tRNA glycylation system from Thermus thermophilus. tRNAGly identity and functional interrelation with the glycylation systems from other phylae.

The systems of tRNA glycylation belong to the most complex aminoacylation systems since neither the oligomeric structure of glycyl-tRNA synthetases (GlyRS) nor the discriminator bases in tRNAGly are conserved in the phylae. To better understand the structure-function relationship in glycylation systems of various origins and the functional peculiarities related to their structural divergences, the elements in tRNA conferring its glycine identity in Thermus thermophilus were characterized and compared to those of other systems. Thermophilic identity is conferred by the G1-C72, C2-G71, G3-C70, and C50-G64 pairs together with the G10, U16, C35, and C36 single residues. In contrast to most other aminoacylation systems, the discriminator base is not directly involved in identity. Transplantation of these elements in tRNAAsp and tRNAPhe converts specificity toward glycine albeit conservation of nucleotide 73. Analysis of the functional interrelation of the identity elements shows coupling in synthetase recognition of the elements from anticodon and G10 whereas those from acceptor arm are recognized independently. Despite nondirect implication in identity, the discriminator base contributes cooperatively with C36 in specificity of glycylation. The link between the structural heterogeneity and the functional divergence of the glycylation systems and the phylogenic interrelation of these systems were approached by comparing the ability of GlyRSs of various phylae to glycylate heterologous tRNAGly. Dimeric GlyRSs from mammalian and archaebacteria acylate efficiently only eukaryotic and archaebacterial tRNAGly with a discriminatory A73, whereas tetrameric Escherichia coli GlyRS acylates only eubacterial tRNAGly with a discriminatory U73. In contrast, dimeric yeast GlyRS acylates efficiently both eukaryotic and archaebacterial tRNAGly as well as peculiar prokaryotic isoacceptors. Species specificity is lost with the dimeric GlyRS from Thermus thermophilus that acylates efficiently eubacterial, archaebacterial, and eukaryotic tRNAGly. These features are discussed in the context of the evolution of the glycylation systems and the phylogenic interrelation of the organisms.     

NMR analysis of bovine tRNATrp: conformation dependence of Mg2+ binding

NMR was used to study the solution structure of bovine tRNA(Trp) hyperexpressed in Escherichia coli. With the use of (15)N labeling and site-directed mutagenesis to assign overlapping resonances through the base pair replacement of U(71)A(2) by G(2)C(71), U(27)A(43) by G(27)C(43), and G(12)C(23) by U(12)A(23), the resonances of all 26 observable imino protons in the helical regions and in the tertiary interactions were assigned unambiguously by means of two-dimensional nuclear Overhauser effect spectroscopy and heteronuclear single quantum coherence methods. When the discriminator base A(73) and the G(12)C(23) base pair on the D stem, two identity elements on bovine tRNA(Trp) that are important for effective recognition by tryptophanyl-tRNA synthetase, were mutated to the ineffective forms of G(73) and U(12)A(23), respectively, NMR analysis revealed an important conformational change in the U(12)A(23) mutant but not in the G(73) mutant molecule. Thus A(73) appears to be directly recognized by tryptophanyl-tRNA synthetase, and G(12)C(23) represents an important structural determinant. Mg(2+) effects on the assigned resonances of imino protons allowed the identification of strong, medium, and weak Mg(2+) binding sites in tRNA(Trp). Strong Mg(2+) binding modes were associated with the residues G(7), s(4)U(8) (where s(4)U is 4-thiouridine), G(12), and U(52). The observations that G(42) was associated with strong Mg(2+) binding in only the U(12)A(23) mutant tRNA(Trp) but not the wild type or G(73) mutant tRNA(Trp) and that the G(7), s(4)U(8), G(24), and G(22) imino protons are associated with a two-site Mg(2+) binding mode in wild type and G(73) mutant but only a one-site mode in the U(12)A(23) mutant established the occurrence of conformational change in the U(12)A(23) mutant tRNA(Trp). These observations also established the dependence of Mg(2+) binding on tRNA conformation and the usefulness of Mg(2+) binding sites as conformational probes. The thermal titration of tRNA(Trp) in the presence and absence of 10 mm Mg(2+) indicated that overall tRNA(Trp) structure stability was increased by more than 15 degrees C by the presence of Mg(2+).     

Common location of determinants in initiator transfer RNAs for initiator-elongator discrimination in bacteria and in eukaryotes

Initiator tRNAs are used exclusively for initiation of protein synthesis and not for elongation. We show that both Escherichia coli and eukaryotic initiator tRNAs have negative determinants, at the same positions, that block their activity in elongation. The primary negative determinant in E. coli initiator tRNA is the C1xA72 mismatch at the end of the acceptor stem. The primary negative determinant in eukaryotic initiator tRNAs is located in the TPsiC stem, whereas a secondary negative determinant is the A1:U72 base pair at the end of the acceptor stem. Here we show that E. coli initiator tRNA also has a secondary negative determinant for elongation and that it is the U50.G64 wobble base pair, located at the same position in the TPsiC stem as the primary negative determinant in eukaryotic initiator tRNAs. Mutation of the U50.G64 wobble base pair to C50:G64 or U50:A64 base pairs increases the in vivo amber suppressor activity of initiator tRNA mutants that have changes in the acceptor stem and in the anticodon sequence necessary for amber suppressor activity. Binding assays of the mutant aminoacyl-tRNAs carrying the C50 and A64 changes to the elongation factor EF-Tu.GTP show marginally higher affinity of the C50 and A64 mutant tRNAs and increased stability of the EF-Tu.GTP. aminoacyl-tRNA ternary complexes. Other results show a large effect of the amino acid attached to a tRNA, glutamine versus methionine, on the binding affinity toward EF-Tu.GTP and on the stability of the EF-Tu.GTP.aminoacyl-tRNA ternary complex.     

Prediction of pairing schemes in RNA molecules-loop contributions and energy of wobble and non-wobble pairs.

Previously published models for predicting pairing schemes in RNA molecules, when applied to tRNA, give the clover leaf structure in only half the cases. We made a systematic investigation of the predictability of the clover leaf structure under various assumptions concerning the energetic contributions of single and double-stranded regions. We tested 21 different models and variants on a set of 100 tRNA sequences and many other variants on a smaller set of sequences. In our models we allowed not only G.C, A.U and G.U pairing, but also every other pair. Under conditions which are much less restrictive than those of previous attempts, we can nevertheless reach 90 per cent predictability for the clover leaf structure of tRNA. A most surprising and far-reaching result is that we can assign to C.G and C.C pairs binding energies quite close to the energies of G.U pairs, and still predict the clover leaf. The following ranking for non-complementary pairs was obtained : G.U, G.G and C.C, U.U, C.A, A.A and G.A, U.C. The main practical innovation which made possible the improvements in predictability are: i) not counting the stacking of base pairs separated by a bulge loop; ii) making the terminal C.C's in stems more stable than the terminal A.U's by merely -- 0.7 kcal; iii) replacing the distinction between G.C and A.U-closed loops by a distinction based on the presence of loop-favoring residues; iv) carefully adjusting the energetic balance between the various kinds of loops; v) narrowing the gap between the GC/GC and the GC/AU contributions; vi) using observations on nearest-neighbours in tRNA sequences to refine the contributions of G.U pairs.     

Structural and functional accommodation of nucleotide variations at a conserved tRNA tertiary base pair.

The U8:A14 tertiary base pair of transfer RNAs (tRNAs) stabilizes the sharp turn from the acceptor stem to the dihydrouridine stem. This tertiary base pair is important for the overall L-shaped tRNA structure. Inspection of tRNA sequences shows that U8:A14 is highly conserved. However, variations of U8:A14 are found in natural sequences. This raises the question of whether all 16 permutations of U8:A14 can be accommodated by a single tRNA sequence framework and by the bacterial translational apparatus. Here we expressed the wild type and 15 variants of U8:A14 of an alanine tRNA amber suppressor in Escherichia coli and tested the ability of each to suppress an amber mutation. We showed that 12 of the 15 variants are functional suppressors (sup+) and 3 are nonfunctional (sup-). Of the 12 functional suppressors, the G8:G14 variant is the most efficient suppressor, whose suppression efficiency is indistinguishable from that of the wild type. Analysis of tRNA structure with chemical probes and the lead-cleavage reaction, however, showed a distinct difference between the G8:G14 variant and the wild type. Thus, two different structures of E. coli tRNAAla/CUA share an identical functional phenotype in protein synthesis. The remaining 11 sup+ variants with reduced suppression efficiencies are likely to have other structural variations. We suggest that the variations of these sup+ mutants are structurally and functionally accommodated by the bacterial translational apparatus. In contrast, the three sup- mutants harbor variations that alter the backbone structure in the corner of the L. These variations are likely to reduce the stability of the tRNA inside the cell or, among others, to interfere with the ability of the tRNA to functionally interact with elongation factor Tu and with the ribosome.