Synthetase competition and tRNA context determine the in vivo identify of tRNA discriminator mutants

Plasmodium apicoplast tyrosyl-tRNA synthetase recognizes an unusual, simplified identity set in cognate tRNATyr

The life cycle of Plasmodium falciparum, the agent responsible for malaria, depends on both cytosolic and apicoplast translation fidelity. Apicoplast aminoacyl-tRNA synthetases (aaRS) are bacterial-like enzymes devoted to organellar tRNA aminoacylation. They are all encoded by the nuclear genome and are translocated into the apicoplast only after cytosolic biosynthesis. Apicoplast aaRSs contain numerous idiosyncratic sequence insertions: An understanding of the roles of these insertions has remained elusive and they hinder efforts to heterologously overexpress these proteins. Moreover, the A/T rich content of the Plasmodium genome leads to A/U rich apicoplast tRNA substrates that display structural plasticity. Here, we focus on the P. falciparum apicoplast tyrosyl-tRNA synthetase (Pf-apiTyrRS) and its cognate tRNATyr substrate (Pf-apitRNATyr). Cloning and expression strategies used to obtain an active and functional recombinant Pf-apiTyrRS are reported. Functional analyses established that only three weak identity elements in the apitRNATyr promote specific recognition by the cognate Pf-apiTyrRS and that positive identity elements usually found in the tRNATyr acceptor stem are excluded from this set. This finding brings to light an unusual behavior for a tRNATyr aminoacylation system and suggests that Pf-apiTyrRS uses primarily negative recognition elements to direct tyrosylation specificity.

Altered expression of plant lysyl tRNA synthetase promotes tRNA misacylation and translational recoding of lysine

The Arabidopsis thaliana lysyl tRNA synthetase (AtKRS) structurally and functionally resembles the well-characterized prokaryotic class IIb KRS, including the propensity to aminoacylate tRNA(Lys) with suboptimal identity elements, as well as non-cognate tRNAs. Transient expression of AtKRS in carrot cells promotes aminoacylation of such tRNAs in vivo and translational recoding of lysine at nonsense codons. Stable expression of AtKRS in Zea mays causes translational recoding of lysine into zeins, significantly enriching the lysine content of grain.

Evolution of the tRNATyr/TyrRS aminoacylation systems

The tRNA identity rules ensuring fidelity of translation are globally conserved throughout evolution except for tyrosyl-tRNA synthetases (TyrRSs) that display species-specific tRNA recognition. This discrimination originates from the presence of a conserved identity pair, G1-C72, located at the top of the acceptor stem of tRNA(Tyr) from eubacteria that is invariably replaced by an unusual C1-G72 pair in archaeal and eubacterial tRNA(Tyr). In addition to the key role of pair 1-72 in tyrosylation, discriminator base A73, the anticodon triplet and the large variable region (present in eubacterial tRNA(Tyr) but not found in eukaryal tRNA(Tyr)) contribute to tyrosylation with variable strengths. Crystallographic structures of two tRNA(Tyr)/TyrRS complexes revealed different interaction modes in accordance with the phylum-specificity. Recent functional studies on the human mitochondrial tRNA(Tyr)/TyrRS system indicates strong deviations from the canonical tyrosylation rules. These differences are discussed in the light of the present knowledge on TyrRSs.

A yeast arginine specific tRNA is a remnant aspartate acceptor

High specificity in aminoacylation of transfer RNAs (tRNAs) with the help of their cognate aminoacyl-tRNA synthetases (aaRSs) is a guarantee for accurate genetic translation. Structural and mechanistic peculiarities between the different tRNA/aaRS couples, suggest that aminoacylation systems are unrelated. However, occurrence of tRNA mischarging by non-cognate aaRSs reflects the relationship between such systems. In Saccharomyces cerevisiae, functional links between arginylation and aspartylation systems have been reported. In particular, it was found that an in vitro transcribed tRNAAsp is a very efficient substrate for ArgRS. In this study, the relationship of arginine and aspartate systems is further explored, based on the discovery of a fourth isoacceptor in the yeast genome, tRNA4Arg. This tRNA has a sequence strikingly similar to that of tRNAAsp but distinct from those of the other three arginine isoacceptors. After transplantation of the full set of aspartate identity elements into the four arginine isoacceptors, tRNA4Arg gains the highest aspartylation efficiency. Moreover, it is possible to convert tRNA4Arg into an aspartate acceptor, as efficient as tRNAAsp, by only two point mutations, C38 and G73, despite the absence of the major anticodon aspartate identity elements. Thus, cryptic aspartate identity elements are embedded within tRNA4Arg. The latent aspartate acceptor capacity in a contemporary tRNAArg leads to the proposal of an evolutionary link between tRNA4Arg and tRNAAsp genes.

Single amino acid changes in AspRS reveal alternative routes for expanding its tRNA repertoire in vivo

Aminoacyl-tRNA synthetases (aaRSs) are enzymes that are highly specific for their tRNA substrates. Here, we describe the expansion of a class IIb aaRS-tRNA specificity by a genetic selection that involves the use of a modified tRNA displaying an amber anticodon and the argE(amber) and lacZ(amber) reporters. The study was performed on Escherichia coli aspartyl-tRNA synthetase (AspRS) and amber tRNA(Asp). Nine AspRS mutants able to charge the amber tRNA(Asp) and to suppress the reporter genes were selected from a randomly mutated library. All the mutants exhibited a new amber tRNA(Asp) specificity in addition to the initial native tRNA(Asp). Six mutations were found in the anticodon-binding site located in the N-terminal OB-fold. The strongest suppressor was a mutation of residue Glu-93 that contacts specifically the anticodon nucleotide 34 in the crystal structure. The other mutations in the OB-fold were found at close distance from the anticodon in the so-called loop L45 and strand S1. They concern residues that do not contact tRNA(Asp) in the native complex. In addition, this study shows that suppressors can carry mutations located far from the anticodon-binding site. One such mutation was found in the synthetase hinge-module where it increases the tRNA(Asp)-charging rate, and two other mutations were found in the prokaryotic-specific insertion domain and the catalytic core. These mutants seem to act by indirect effects on the tRNA acceptor stem binding and on the conformation of the active site of the enzyme. Altogether, these data suggest the existence of various ways for modifying the mechanism of tRNA discrimination.

tRNA requirements for glyQS antitermination: a new twist on tRNA

Transcription antitermination of the Bacillus subtilis glyQS gene, a member of the T box gene regulation family, can be induced during in vitro transcription in a minimal system using purified B. subtilis RNA polymerase by the addition of unmodified T7 RNA polymerase-transcribed tRNA(Gly). Antitermination was previously shown to depend on base-pairing between the glyQS leader and the tRNA at the anticodon and acceptor ends. In this study, variants of tRNA(Gly) were generated to identify additional tRNA elements required for antitermination activity, and to determine the effect of structural changes in the tRNA. We find that additions to the 3' end of the tRNA blocked antitermination, in agreement with the prediction that uncharged tRNA is the effector in vivo, whereas insertion of 1 nucleotide between the acceptor stem and the 3' UCCA residues had no effect. Disruption of the D-loop/T-loop tertiary interaction inhibited antitermination function, as was previously demonstrated for tRNA(Tyr)-directed antitermination of the B. subtilis tyrS gene in vivo. Insertion of a single base pair in the anticodon stem was tolerated, whereas further insertions abolished antitermination. However, we find that major alterations in the length of the acceptor stem are tolerated, and the insertions exhibited a pattern of periodicity suggesting that there is face-of-the-helix dependence in the positioning of the unpaired UCCA residues at the 3' end of the tRNA for interaction with the antiterminator bulge and antitermination.

Class I tyrosyl-tRNA synthetase has a class II mode of cognate tRNA recognition

Bacterial tyrosyl-tRNA synthetases (TyrRS) possess a flexibly linked C-terminal domain of approximately 80 residues, which has hitherto been disordered in crystal structures of the enzyme. We have determined the structure of Thermus thermophilus TyrRS at 2.0 A resolution in a crystal form in which the C-terminal domain is ordered, and confirm that the fold is similar to part of the C-terminal domain of ribosomal protein S4. We have also determined the structure at 2.9 A resolution of the complex of T.thermophilus TyrRS with cognate tRNA(tyr)(G Psi A). In this structure, the C-terminal domain binds between the characteristic long variable arm of the tRNA and the anti-codon stem, thus recognizing the unique shape of the tRNA. The anticodon bases have a novel conformation with A-36 stacked on G-34, and both G-34 and Psi-35 are base-specifically recognized. The tRNA binds across the two subunits of the dimeric enzyme and, remarkably, the mode of recognition of the class I TyrRS for its cognate tRNA resembles that of a class II synthetase in being from the major groove side of the acceptor stem.

Function of the extra 5'-phosphate carried by histidine tRNA

Among elongator tRNAs, tRNA specific for histidine has the peculiarity to possess one extra nucleotide at position -1. This nucleotide is believed to be responsible for recognition by histidyl-tRNA synthetase. Here, we show that, in fact, it is the phosphate 5' to the extra nucleotide which mainly supports the efficiency of the tRNA aminoacylation reaction catalyzed by Escherichia coli histidyl-tRNA synthetase. In the case of the reaction of E. coli peptidyl-tRNA hydrolase, this atypical phosphate is dispensable. Instead, peptidyl-tRNA hydrolase recognizes the phosphate of the phosphodiester bond between residues -1 and +1 of tRNA(His). Recognition of the +1 phosphate of tRNA(His) by peptidyl-tRNA hydrolase resembles, therefore, that of the 5'-terminal phosphate of other elongator tRNAs.

Identity of tRNA for yeast tyrosyl-tRNA synthetase: tyrosylation is more sensitive to identity nucleotides than to structural features

The specific aminoacylation of tRNA by yeast tyrosyl-tRNA synthetase does not rely on the presence of modified residues in tRNA(Tyr), although such residues stabilize its structure. Thus, the major tyrosine identity determinants were searched by the in vitro approach using unmodified transcripts produced by T7 RNA polymerase. On the basis of the tyrosylation efficiency of tRNA variants, the strongest determinants are base pair C1-G72 and discriminator residue A73 (the 5'-phosphoryl group on C1, however, is unimportant for tyrosylation). The three anticodon bases G34, U35, and A36 contribute also to the tyrosine identity, but to a lesser extent, with G34 having the most pronounced effect. Mutation of the GUA tyrosine anticodon into a CAU methionine anticodon, however, leads to a loss of tyrosylation efficiency similar to that obtained after mutation of the C1-G72 or A73 determinants. Transplantation of the six determinants into four different tRNA frameworks and activity assays on heterologous Escherichia coli and Methanococcus jannaschii tRNA(Tyr) confirmed the completeness of the tyrosine set and the eukaryotic character of the C1-G72 base pair. On the other hand, it was found that tyrosine identity in yeast does not rely on fine architectural features of the tRNA, in particular the size and sequence of the D-loop. Noticeable, yeast TyrRS efficiently charges a variant of E. coli tRNA(Tyr) with a large extra-region provided its G1-C72 base pair is changed to a C1-G72 base pair. Finally, tyrosylation activity is compatible with a +1 shift of the anticodon in the 3'-direction but is strongly inhibited if this shift occurs in the opposite 5'-direction.

Effect of modified nucleotides on Escherichia coli tRNAGlu structure and on its aminoacylation by glutamyl-tRNA synthetase. Predominant and distinct roles of the mnm5 and s2 modifications of U34

Overproducing Escherichia coli tRNAGlu in its homologous host results in the presence of several distinctly modified forms of this molecule that we name modivariants. The predominant tRNAGlu modivariant in wild-type E. coli contains five modified nucleosides: Psi13, mnm5s2U34, m2A37, T54 and Psi55. Four other overproduced modivariants differ from it by, respectively, either the presence of an additional Psi, or the presence of s2U34, or the lack of A37 methylation combined with either s2U34 or U34. Chemical probing reveals that the anticodon loop of the predominant modivariant is less reactive to the probes than that of the four others. Furthermore, the modivariant with neither mnm5s2U34 nor m2A37 has additional perturbations in the D- and T-arms and in the variable region. The lack of a 2-thio group in nucleoside 34, which is mnm5s2U in the predominant tRNAGlu modivariant, decreases by 520-fold the specificity of E. coli glutamyl-tRNA synthetase for tRNAGlu in the aminoacylation reaction, showing that this thio group is the identity element in the modified wobble nucleotide of E. coli tRNAGlu. The modified nucleosides content also influences the recognition of ATP and glutamate by this enzyme, and in this case also, the predominant modivariant is the one that allows the best specificity for these two substrates. These structural and kinetic properties of tRNAGlu modivariants indicate that the modification system of tRNAGlu optimizes the stability of tRNAGlu and its action as cofactor of the glutamyl-tRNA synthetase for the recognition of glutamate and ATP.

Aminoacylation of hypomodified tRNAGlu in vivo

The highly specific interaction of each aminoacyl-tRNA synthetase and its substrate tRNAs constitutes an intriguing problem in protein-RNA recognition. All tRNAs have the same overall three-dimensional structure in order to fit interchangeably into the translational apparatus. Thus, the recognition by aminoacyl-tRNA synthetase must be more or less limited to discrimination between bases at specific positions within the tRNA. The hypermodified nucleotide 5-methylaminomethyl-2-thiouridine (mnm5s2U) present at the wobble position of bacterial tRNAs specific for glutamic acid, lysine and possibly glutamine has been shown to be important in the recognition of these tRNAs by their synthetases in vitro. Here, we have determined the aminoacylation level in vivo of tRNAGlu, tRNALys, and tRNA1GIn in Escherichia coli strains containing undermodified derivatives of mnm5s2U34. Lack of the 5-methylaminomethyl group did not reduce charging levels for any of the three tRNAs. Lack of the s2U34 modification caused a 40% reduction in the charging level of tRNAGlu. Charging of tRNALys and tRNA1Gln were less affected. There was no compensating regulation of expression of glutamyl-tRNA synthetase because the relative synthesis rate was the same in the wild-type and mutant strains. These results indicate that the mnm5U34 modification is not an important recognition element in vivo for the glutamyl-tRNA synthetase. In contrast, lack of the s2U34 modification reduced the efficiency of charging by at least 40%. This is the minimal estimate because the turn-over rate of Glu-tRNAGlu was also reduced in the absence of the 2-thio group. Lack of either modification did not affect mischarging or mistranslation.

Universal rules and idiosyncratic features in tRNA identity

Correct expression of the genetic code at translation is directly correlated with tRNA identity. This survey describes the molecular signals in tRNAs that trigger specific aminoacylations. For most tRNAs, determinants are located at the two distal extremities: the anticodon loop and the amino acid accepting stem. In a few tRNAs, however, major identity signals are found in the core of the molecule. Identity elements have different strengths, often depend more on k cat effects than on K m effects and exhibit additive, cooperative or anti-cooperative interplay. Most determinants are in direct contact with cognate synthetases, and chemical groups on bases or ribose moieties that make functional interactions have been identified in several systems. Major determinants are conserved in evolution; however, the mechanisms by which they are expressed are species dependent. Recent studies show that alternate identity sets can be recognized by a single synthetase, and emphasize the importance of tRNA architecture and anti-determinants preventing false recognition. Identity rules apply to tRNA-like molecules and to minimalist tRNAs. Knowledge of these rules allows the manipulation of identity elements and engineering of tRNAs with switched, altered or multiple specificities.

Retracing the evolution of amino acid specificity in glutaminyl-tRNA synthetase

Molecular phylogenetic studies of glutaminyl-tRNA synthetase suggest that it has relatively recently evolved from the closely related enzyme glutamyl-tRNA synthetase. We have now attempted to retrace one of the key steps in this process by selecting glutaminyl-tRNA synthetase mutants displaying enhanced glutamic acid recognition. Mutagenesis of two residues proximal to the active site, Phe-90 and Tyr-240, was found to improve glutamic acid recognition 3-5-fold in vitro and resulted in the misacylation of tRNA(Gln) with glutamic acid. In vivo expression of the genes encoding these misacylating variants of glutaminyl-tRNA synthetase reduced cellular growth rates by 40%, probably as a result of an increase in translational error rates. These results provide the first biochemical evidence that glutaminyl-tRNA synthetase originated through duplication and consequent diversification of an ancestral glutamyl-tRNA synthetase-encoding gene.

A tRNA identity switch mediated by the binding interaction between a tRNA anticodon and the accessory domain of a class II aminoacyl-tRNA synthetase

Identity elements in tRNAs and the intracellular balance of tRNAs allow accurate selection of tRNAs by aminoacyl-tRNA synthetases. The histidyl-tRNA from Escherichia coli is distinguished by a unique G-1.C73 base pair that upon exchange with other nucleotides leads to a marked decrease in the rate of aminoacylation in vitro. G-1.C73 is also a major identity element for histidine acceptance, such that the substitution of C73 brings about mischarging by glycyl-, glutaminyl-, and leucyl-tRNA synthetases. These identity conversions mediated by the G-1.C73 base pair were exploited to isolate secondary site revertants in the histidyl-tRNA synthetase from E. coli which restore histidine identity to a histidyl-tRNA suppressor carrying U73. The revertant substitutions confer a 3-4 fold reduction in the Michaelis constant for tRNAs carrying the amber-suppressing anticodon and map to the C-terminal domain of HisRS and its interface with the catalytic core. These findings demonstrate that the histidine tRNA anticodon plays a significant role in tRNA selection in vivo and that the C-terminal domain of HisRS is in large part responsible for recognizing this trinucleotide. The kinetic parameters determined also show a small degree of anticooperativity (delta delta G = -1.24 kcal/mol) between recognition of the discriminator base and the anticodon, suggesting that the two helical domains of the tRNA are not recognized independently. We propose that these effects substantially account for the ability of small changes in tRNA binding far removed from the site of a major determinant to bring about a complete conversion of tRNA identity.

The discriminator bases G73 in human tRNA(Ser) and A73 in tRNA(Leu) have significantly different roles in the recognition of aminoacyl-tRNA synthetases

The recognition of human tRNA(Leu) or tRNA(Ser) by cognate aminoacyl- tRNA synthetases has distinct requirements. Only one base change (A73-->G) in tRNA(Leu) is required to generate an efficient serine acceptor in vitro, whereas several changes in three structural domains (the acceptor stem, DHU loop and long extra arm) of tRNA(Ser) are necessary in order to produce a leucine acceptor. Hence, the molecular basis for the discrimination between human tRNA(Ser) and tRNA(Leu) by the seryl-tRNA synthetase depends almost exclusively on a highly specific recognition of the discriminator base G73. In order to elucidate the specific role of the functional groups of this base in discrimination, tRNA(Ser) constructs were made which contain the artificial base analogues 2-aminopurine riboside or inosine at the discriminator position 73. Aminoacylation of these constructs by a HeLa S100 extract showed that molecules with 2-aminopurine riboside, but not with inosine, in position 73 could be serylated at low efficiency. However, the 2-aminopurine riboside and the inosine derivatives of tRNA(Ser) were equally efficient competitive inhibitors of serylation, whereas tRNAs(Ser) with any other natural base at position 73 did not competitively inhibit serylation of tRNA(Ser). This was in contrast to leucylation of tRNA(Leu), where tRNA(Leu) transcripts with any other nucleotide in the discriminator position acted as strong competitive inhibitors. These results suggest that the discriminator bases in human tRNA(Ser) and tRNA(Leu) play completely different roles in recognition of the tRNAs by their cognate aminoacyl-tRNA synthetases.

Aminoacyl-tRNA synthetases optimize both cognate tRNA recognition and discrimination against noncognate tRNAs

Specific protein--nucleic acid interactions are usually the product of sequence-dependent hydrogen bonding. However, in the crystal structure of Escherichia coli glutaminyl-tRNA synthetase (GlnRS) in complex with tRNAGln, leucine 136 (Leu136) stabilizes the disruption of the weak first (U1-A72) base pair in tRNAGln by stacking between A72 and G2. We have demonstrated, by a combined in vivo and in vitro mutational analysis, that Leu136 is important for tRNA specificity despite making no hydrogen bonds with tRNAGln. Both more (L136F) and less (L136V, L136M, L136A, and L136T) mischarging mutants of GlnRS have been identified. GlnRS(L136F) is more mischarging and less specific than wild-type GlnRS in vivo, due not to an increased affinity for the noncognate tRNAs but to a decreased affinity for tRNAGln. Also, unlike other mischarging mutants of GlnRS that have been characterized, it does not exhibit generally relaxed tRNA specificity in vivo and mischarges only a subset of the tRNAs tested. A possible sequence preference for a Py1-Pu72/Pu2-Py71 combination is suggested. The L136A/M/T/V mutants are the first GlnRS variants, including wild-type, expressed on pBR322 which no longer mischarge tyrT(UAG) in vivo. We have shown that, while the L136A mutant is less mischarging than wild-type both in vivo and in vitro, it is not more specific as it also exhibits reduced affinity for its cognate glutamine tRNA. On the basis of these results, we suggest that the aminoacyl-tRNA synthetases have evolved to balance cognate tRNA recognition and discrimination against noncognate tRNAs.

Aminoacyl-tRNA synthetase gene regulation in Bacillus subtilis

In this review, we summarize progress on the regulation of the aminoacyl-tRNA synthetase genes in Bacillus subtilis. Most of the genes encoding this set of enzymes in B subtilis are members of a large family of Gram-positive genes and operons controlled by a novel antitermination mechanism that uses their cognate uncharged tRNA as the effector. A subset of these genes is, in addition, likely to be controlled at the level of mRNA processing and degradation. We describe the key experiments leading to these conclusions.

Divergence of glutamate and glutamine aminoacylation pathways: providing the evolutionary rationale for mischarging

Aminoacyl-tRNA for protein synthesis is produced through the action of a family of enzymes called aminoacyl-tRNA synthetases. A general rule is that there is one aminoacyl-tRNA synthetase for each of the standard 20 amino acids found in all cells. This is not universal, however, as a majority of prokaryotic organisms and eukaryotic organelles lack the enzyme glutaminyl-tRNA synthetase, which is responsible for forming Gln-tRNAGln in eukaryotes and in Gram-negative eubacteria. Instead, in organisms lacking glutaminyl-tRNA synthetase, Gln-tRNAGln is provided by misacylation of tRNAGln with glutamate by glutamyl-tRNA synthetase, followed by the conversion of tRNA-bound glutamate to glutamine by the enzyme Glu-tRNAGln amidotransferase. The fact that two different pathways exist for charging glutamine tRNA indicates that ancestral prokaryotic and eukaryotic organisms evolved different cellular mechanisms for incorporating glutamine into proteins. Here, we explore the basis for diverging pathways for aminoacylation of glutamine tRNA. We propose that stable retention of glutaminyl-tRNA synthetase in prokaryotic organisms following a horizontal gene transfer event from eukaryotic organisms (Lamour et al. 1994) was dependent on the evolving pool of glutamate and glutamine tRNAs in the organisms that acquired glutaminyl-tRNA synthetase by this mechanism. This model also addresses several unusual aspects of aminoacylation by glutamyl- and glutaminyl-tRNA synthetases that have been observed.

Genetic selection for active E.coli amber tRNA(Asn) exclusively led to glutamine inserting suppressors

Suppressor tRNAs are useful tools for determining identity elements which define recognition of tRNAs in vivo by their cognate aminoacyl-tRNA synthetases. This study was aimed at the isolation of active amber tRNA(Asn). Nineteen mutated tRNA(Asn)CUA having amber suppressor activity were selected by an in vivo genetic screen, and all exclusively inserted glutamine. From analysis of the different mutations it is concluded that glutamine accepting activity was obtained upon reducing the interaction strength between the first base pair of the tRNA(Asn)CUA by direct or indirect effects. Failure to isolate tRNA(Asn)CUA suppressors charged with asparagine as well as other evolutionary related amino acids is discussed.

Aminoacylation of transfer RNAs with 2-thiouridine derivatives in the wobble position of the anticodon

The first position or 'wobble base' in the anticodon of tRNAs is frequently the site of post-transcriptional modification. In Escherichia coli, glutamine, glutamate, and lysine tRNAs contain 2-thiouridine derivatives in this position, and the significance of these modifications has been under investigation since their discovery. Here we describe the investigations to link 2-thiouridine derivatives to aminoacylation of these tRNAs. The implications of these findings on the evolution of specificity of aminoacyl-tRNA synthetases and on translational regulation are also discussed.

tRNA-directed transcription antitermination

At least 18 aminoacyl-tRNA synthetase and amino acid biosynthesis genes in several Gram-positive genera appear to be regulated by a common transcription antitermination mechanism. Each gene is induced by limitation for the appropriate amino acid, and not by general amino acid limitation. The mRNA leader regions of these genes exhibit extensive structural conservation. Characterization of the Bacillus subtilis tyrS gene revealed that uncharged tyrosyl-tRNA promotes readthrough of a leader-region terminator; a conformational switch in the leader mRNA between a terminator structure and an antiterminator structure is postulated to mediate antitermination. Two sites of interaction between the tRNA and the leader have been identified by genetic analysis: the tRNA anticodon interacts with a single codon displayed at a precise position in the leader-region structure, and the acceptor end of the tRNA interacts with a side-bulge on the antiterminator.

Interaction between the acceptor end of tRNA and the T box stimulates antitermination in the Bacillus subtilis tyrS gene: a new role for the discriminator base

The Bacillus subtilis tyrS gene is a member of a group of gram-positive aminoacyl-tRNA synthetase and amino acid biosynthesis genes which are regulated by transcription antitermination. Each gene in the group is specifically induced by limitation for the appropriate amino acid. This response is mediated by interaction of the cognate tRNA with the mRNA leader region to promote formation of an antiterminator structure. The tRNA interacts with the leader by codon-anticodon pairing at a position designated the specifier sequence which is upstream of the antiterminator. In this study, an additional site of possible contact between the tRNA and the leader was identified through covariation of leader mRNA and tRNA sequences. Mutations in the acceptor end of tRNA(Tyr) could suppress mutations in the side bulge of the antiterminator, in a pattern consistent with base pairing. This base pairing may thereby directly affect the formation and/or function of the antiterminator. The discriminator position of the tRNA, an important identity determinant for a number of tRNAs, including tRNA(Tyr), was shown to act as a second specificity determinant for assuring response to the appropriate tRNA. Furthermore, overproduction of an unchargeable variant of tRNA(Tyr) resulted in antitermination in the absence of limitation for tyrosine, supporting the proposal that uncharged tRNA is the effector in this system.

Functional communication in the recognition of tRNA by Escherichia coli glutaminyl-tRNA synthetase

Wild-type Escherichia coli glutaminyl-tRNA synthetase (GlnRS; EC 6.1.1.18) poorly aminoacylates opal suppressors (GLN) derived from tRNA(Gln). Mutations in glnS (the gene encoding GlnRS) that compensate for impaired aminoacylation were isolated by genetic selection. Two glnS mutants were obtained by using opal suppressors differing in the nucleotides composing the base pair at 3.70: glnS113 with an Asp-235-->Asn change selected with GLNA3U70 (GLN carrying G3-->A and C70-->U changes), and glnS114 with a Gln-318-->Arg change selected with GLNU70 (GLN carrying a C70-->U change). The Asp-235-->Asn change was identified previously by genetic selection. Additional mutants were isolated by site-directed mutagenesis followed by genetic selection; the mutant enzymes have single amino acid changes (Lys-317-->Arg and Gln-318-->Lys). A number of mutants with no phenotype also were obtained randomly. In vitro aminoacylation of a tRNA(Gln) transcript by GlnRS enzymes with Lys-317-->Arg, Gln-318-->Lys, or Gln-318-->Arg changes shows that the enzyme's kinetic parameters are not greatly affected by the mutations. However, aminoacylation of a tRNA(Gln) transcript with an opal (UCA) anticodon shows that the specificity constants (kcat/Km) for the mutant enzymes were 5-10 times above that of the wild-type GlnRS. Interactions between Lys-317 and Gln-318 with the inside of the L-shaped tRNA and with the side chain of Gln-234 provide a connection between the acceptor end-binding and anticodon-binding domains of GlnRS. The GlnRS mutants isolated suggest that perturbation of the interactions with the inside of the tRNA L shape results in relaxed anticodon recognition.

Triple aminoacylation specificity of a chimerized transfer RNA

We report here the rational design and construction of a chimerized transfer RNA with tripartite aminoacylation specificity. A yeast aspartic acid specific tRNA was transformed into a highly efficient acceptor of alanine and phenylalanine and a moderate acceptor of valine. The transformation was guided by available knowledge of the requirements for aminoacylation by each of the three amino acids and was achieved by iterative changes in the local sequence context and the structural framework of the variable loop and the two variable regions of the dihydrouridine loop. The changes introduced to confer efficient acceptance of the three amino acids eliminate aminoacylation with aspartate. The interplay of determinants and antideterminants for different specific aminoacylations, and the constraints imposed by the structural framework, suggest that a tRNA with an appreciable capacity for more than three efficient aminoacylations may be inherently difficult to achieve.

The discriminator base influences tRNA structure at the end of the acceptor stem and possibly its interaction with proteins

For many tRNAs, the discriminator base preceding the CCA sequence at the 3' end is important for aminoacylation. We show that the discriminator base influences the stability of the 1.72 base pair onto which it is stacked. Mutations of the discriminator base from adenosine to cytidine or uridine make the cytidine residue in the C1-G72 base pair of mutant Escherichia coli initiator tRNAs more reactive toward sodium bisulfite, the single-strand-specific reagent. The activity of the enzyme Met-tRNA transformylase toward these and other mutant initiator tRNAs is also consistent with destabilization of the 1.72 base pair in vitro and in vivo. By influencing the strength of the 1.72 base pair, the discriminator base could affect the energetic cost of opening the base pair and modulate the structure of the tRNA near the site of aminoacylation. For some aminoacyl-tRNA synthetases and other proteins that interact with tRNA, these factors could be important for specific recognition and/or formation of the transition state during catalysis.

A 2-thiouridine derivative in tRNAGlu is a positive determinant for aminoacylation by Escherichia coli glutamyl-tRNA synthetase

Early investigations into the interaction between Escherichia coli glutamyl-tRNA synthetase (GluRS) and tRNAGlu have implicated the modified nucleoside 5-[(methylamino)methyl]-2-thiouridine in the first position of the anticodon as an important contact for efficient aminoacylation. However, the experimental methods employed were not sufficient to determine whether the interaction was dependent on the presence of the modification or simply involved other anticodon loop-nucleotides, now occluded from interaction with the synthetase. Unmodified E. coli tRNA(Glu), derived by in vitro transcription of the corresponding gene, is a poor substrate for GluRS, exhibiting a 100-fold reduction in its specificity constant (kcat/KM) compared to that of tRNA(Glu) prepared from an overproducing strain. Through the use of recombinant RNA technology, we created several hybrid tRNAs which combined sequences from the in vitro transcript with that of the native tRNA, resulting in tRNA molecules differing in modified base content. By in vitro aminoacylation of these hybrid tRNA molecules and of tRNAs with base substitutions at positions of nucleotide modification, we show conclusively that the modified uridine at position 34 in tRNA(Glu) is required for efficient aminoacylation by E. coli GluRS. This is only the second example of a tRNA modification acting as a positive determinant for interaction with its cognate aminoacyl-tRNA synthetase.

Acceptor end binding domain interactions ensure correct aminoacylation of transfer RNA

The recognition of the acceptor stem of tRNA(Gln) is an important element ensuring the accuracy of aminoacylation by Escherichia coli glutaminyl-tRNA synthetase (GlnRS; EC 6.1.1.18). On the basis of known mutations and the crystal structure of the tRNA(Gln).GlnRS complex, we mutagenized at saturation two motifs in the acceptor end binding domain of GlnRS. Mutants with lowered tRNA specificity were then selected in vivo by suppression of a glutamine-specific amber mutation (lacZ1000) with an amber suppressor tRNA derived from tRNA(1Ser). The mischarging GlnRS mutants obtained in this way retain the ability to charge tRNA(Gln), but in addition, they misacylate a number of noncognate amber suppressor tRNAs. The critical residues responsible for specificity are Arg-130 and Glu-131, located in a part of GlnRS that binds the acceptor stem of tRNA(Gln). On the basis of the spectrum of tRNAs capable of being misacylated by such mutants we propose that, in addition to taking part in productive interactions, the acceptor end binding domain contributes to recognition specificity by rejecting noncognate tRNAs through negative interactions. Analysis of the catalytic properties of one of the mischarging enzymes, GlnRS100 (Arg-130-->Pro, Glu-131-->Asp), indicates that, while the kinetic parameters of the mutant enzyme are not dramatically changed, it binds noncognate tRNA(Glu) more stably than the wild-type enzyme does (Kd is 1/8 that of the wild type). Thus, the stability of the noncognate complex may be the basis for mischarging in vivo.

Discrimination between transfer-RNAs by tyrosyl-tRNA synthetase

We have constructed a model of the complex between tyrosyl-tRNA synthetase (TyrRS) from Bacillus stearothermophilus and tRNA(Tyr) by successive cycles of predictions, mutagenesis of TyrRS and molecular modeling. We confront this model with data obtained independently, compare it to the crystal structures of other complexes and review recent data on the discrimination between tRNAs by TyrRS. Comparison of the crystal structures of TyrRS and GlnRS, both of which are class I synthetases, and comparison of the identity elements of tRNA(Tyr) and tRNA(Gln) indicate that the two synthetases bind their cognate tRNAs differently. The mutagenesis data on tRNA(Tyr) confirm the model of the TyrRS:tRNA(Tyr) complex on the following points. TyrRS approaches tRNA(Tyr) on the side of the variable loop. The bases of the first three pairs of the acceptor stem are not recognized. The presence of the NH2 group in position C6 and the absence of a bulky group in position C2 are important for the recognition of the discriminator base A73 by TyrRS, which is fully realized only in the transition state for the acyl transfer. The anticodon is the major identity element of tRNA(Tyr). We have set up an in vivo approach to study the effects of synthetase mutations on the discrimination between tRNAs. Using this approach, we have shown that residue Glu152 of TyrRS acts as a purely negative discriminant towards non-cognate tRNAs, by electrostatic and steric repulsions. The overproductions of the wild type TyrRSs from E coli and B stearothermophilus are toxic to E coli, due to the mischarging or the non-productive binding of tRNAs. The construction of a family of hybrids between the TyrRSs from E coli and B stearothermophilus has shown that their sequences and structures have remained locally compatible through evolution, for folding and function, in particular for the specific recognition and charging of tRNA(Tyr).

Acceptor stem and anticodon RNA hairpin helix interactions with glutamine tRNA synthetase

The class I glutamine (Gln) tRNA synthetase interacts with the anticodon and acceptor stem of glutamine tRNA. RNA hairpin helices were designed to probe acceptor stem and anticodon stem-loop contacts. A seven-base pair RNA microhelix derived from the acceptor stem of tRNA(Gln) was aminoacylated by Gln tRNA synthetase. Variants of the glutamine acceptor stem microhelix implicated the discriminator base as a major identity element for glutaminylation of the RNA helix. A second RNA microhelix representing the anticodon stem-loop competitively inhibited tRNA(Gln) changing. However, the anticodon stem-loop microhelix did not enhance aminoacylation of the acceptor stem microhelix. Thus, transduction of the anticodon identity signal may require covalent continuity of the tRNA chain to trigger efficient aminoacylation.

Selectivity and specificity in the recognition of tRNA by E coli glutaminyl-tRNA synthetase

The specific recognition by Escherichia coli glutaminyl-tRNA synthetase (GlnRS) of tRNA(Gln) is mediated by extensive protein:RNA contacts and changes in the conformation of tRNA(Gln) when complexed with GlnRS. In vivo accuracy of aminoacylation depends on two factors: competition between synthetases, and the context and recognition of identity elements in the tRNA. The structure of the tRNA(Gln):GlnRS complex supports studies from amber and opal suppressor tRNAs, complemented by in vitro aminoacylation of the mutated tRNA transcripts, that the glutamine identity elements are located in the anticodon and acceptor stem of tRNA(Gln). Recognition of individual functional groups in tRNA, for example the 2-amino group of guanosine, is also evident from the result with inosine-substituted tRNAs. Communication between anticodon and acceptor stem recognition is indicated by mutants in GlnRS isolated by genetic selection with opal suppressor tRNAs which are altered in interactions with the inside of the L-shaped tRNA. We have also used genetic selection to obtain mutants of GlnRS altered in acceptor stem recognition with relaxed specificity for amber suppressor tRNAs, and a more extensive mutational analysis shows the importance of the acceptor binding domain to accurate recognition of tRNA.