Active site of an aminoacyl-tRNA synthetase dissected by energy-transfer-dependent fluorescence

Aminoacyl-tRNA synthetases establish the rules of the genetic code by catalyzing attachment of amino acids to specific transfer RNAs (tRNAs) that bear the anticodon triplets of the code. Each of the 20 amino acids has its own distinct aminoacyl-tRNA synthetase. Here we use energy-transfer-dependent fluorescence from the nucleotide probe N-methylanthraniloyl dATP (mdATP) to investigate the active site of a specific aminoacyl-tRNA synthetase. Interaction of the enzyme with the cognate amino acid and formation of the aminoacyl adenylate intermediate were detected. In addition to providing a convenient tool to characterize enzymatic parameters, the probe allowed investigation of the role of conserved residues within the active site. Specifically, a residue that is critical for binding could be distinguished from one that is important for the transition state of adenylate formation. Amino acid binding and adenylate synthesis by two other aminoacyl-tRNA synthetases was also investigated with mdATP. Thus, a key step in the synthesis of aminoacyl-tRNA can in general be dissected with this probe.

Editing by a tRNA synthetase: DNA aptamer-induced translocation and hydrolysis of a misactivated amino acid

Aminoacyl-tRNA synthetases establish the rules of the genetic code by aminoacylation reactions. Occasional activation of the wrong amino acid can lead to errors of protein synthesis. For isoleucyl-tRNA synthetase, these errors are reduced by tRNA-dependent hydrolytic editing reactions that occur at a site 25 A from the active site. These reactions require that the misactivated amino acid be translocated from the active site to the center for editing. One mechanism describes translocation as requiring the mischarging of tRNA followed by a conformational change in the tRNA that moves the amino acid from one site to the other. Here a specific DNA aptamer is investigated. The aptamer can stimulate amino acid-specific editing but cannot be aminoacylated. Although the aptamer could in principle stimulate hydrolysis of a misactivated amino acid by an idiosyncratic mechanism, the aptamer is shown here to induce translocation and hydrolysis of misactivated aminoacyl adenylate at the same site as that seen with the tRNA cofactor. Thus, translocation to the site for editing does not require joining of the amino acid to the nucleic acid. Further experiments demonstrated that aptamer-induced editing is sensitive to aptamer sequence and that the aptamer is directed to a site other than the active site or tRNA binding site of the enzyme.

Simultaneous binding of two proteins to opposite sides of a single transfer RNA

Transfer RNA (tRNA) is a small nucleic acid (typically 76 nucleotides) that forms binary complexes with proteins, such as aminoacyl tRNA synthetases (RS) and Trbp111. The latter is a widely distributed structure-specific tRNA-binding protein that is incorporated into cell signaling molecules. The structure of Trbp111 was modeled onto to the outer, convex side of the L-shaped tRNA. Here we present RNA footprints that are consistent with this model. This binding mode is in contrast to that of tRNA synthetases, which bind to the inside, or concave side, of tRNA. These opposite locations of binding for these two proteins suggest the possibility of a ternary complex. The formation of a tRNA synthetase--tRNA--Trbp111 ternary complex was detected by two independent methods. The results indicate that the tRNA is sandwiched between the two protein molecules. A thermodynamic and functional analysis is consistent with the tRNA retaining its native structure in the ternary complex. These results may have implications for how the translation apparatus is linked to other cellular machinery.

Amino acid selectivity in the aminoacylation of coenzyme A and RNA minihelices by aminoacyl-tRNA synthetases

Coenzyme A (CoA-SH), a cofactor in carboxyl group activation reactions, carries out a function in nonribosomal peptide synthesis that is analogous to the function of tRNA in ribosomal protein synthesis. The amino acid selectivity in the synthesis of aminoacyl-thioesters by nonribosomal peptide synthetases is relaxed, whereas the amino acid selectivity in the synthesis of aminoacyl-tRNA by aminoacyl-tRNA synthetases is restricted. Here I show that isoleucyl-tRNA synthetase aminoacylates CoA-SH with valine, leucine, threonine, alanine, and serine in addition to isoleucine. Valyl-tRNA synthetase catalyzes aminoacylations of CoA-SH with valine, threonine, alanine, serine, and isoleucine. Lysyl-tRNA synthetase aminoacylates CoA-SH with lysine, leucine, threonine, alanine, valine, and isoleucine. Thus, isoleucyl-, valyl-, and lysyl-tRNA synthetases behave as aminoacyl-S-CoA synthetases with relaxed amino acid selectivity. In contrast, RNA minihelices comprised of the acceptor-TpsiC helix of tRNA(Ile) or tRNA(Val) were aminoacylated by cognate synthetases selectively with isoleucine or valine, respectively. These and other data support a hypothesis that the present day aminoacyl-tRNA synthetases originated from ancestral forms that were involved in noncoded thioester-dependent peptide synthesis, functionally similar to the present day nonribosomal peptide synthetases.

Errors from selective disruption of the editing center in a tRNA synthetase

Some aminoacyl-tRNA synthetases have two catalytic centers that together achieve fine-structure discrimination of closely similar amino acids. The role of tRNA is to stimulate translocation of a misactivated amino acid from the active site to the editing site where the misactivated substrate is eliminated by hydrolysis. Using isoleucyl-tRNA synthetase as an example, we placed mutations in the catalytic center for editing at residues strongly conserved from bacteria to humans. A particular single substitution and one double substitution resulted in production of mischarged tRNA, by interfering specifically with the chemical step of hydrolytic editing. The substitutions affected neither amino acid activation nor aminoacylation, with the cognate amino acid. Thus, because of the demonstrated functional independence of the two catalytic sites, errors of aminoacylation can be generated by selective mutations in the center for editing.

Rational design of femtomolar inhibitors of isoleucyl tRNA synthetase from a binding model for pseudomonic acid-A

This paper describes the design and characterization of novel inhibitors of IleRS, whose binding affinity approaches the tightest reported for noncovalent inhibition. Compounds were designed from a binding model for the natural product pseudomonic acid-A (PS-A) together with a detailed understanding of the reaction cycle of IleRS and characterization of the mode of binding of the reaction intermediate IleAMP. The interactions of the compounds with IleRS were characterized by inhibition of aminoacylation of tRNA or PP(i)/ATP exchange at supersaturating substrate concentration and by transient kinetics and calorimetry methods. A detailed understanding of the interaction of a comprehensive series of compounds with IleRS allowed the identification of key features and hence the design of exquisitely potent inhibitors. Predictions based on these results have been recently supported by a docking model based on the crystal structure of IleRS with PS-A [Silvian, L. F., Wang J. M., and Steitz T. A. (1999) Science 285 1074-1077].

Misactivated amino acids translocate at similar rates across surface of a tRNA synthetase

Certain aminoacyl-tRNA synthetases have a second active site that destroys (by hydrolysis) errors of amino acid activation. For example, isoleucyl-tRNA synthetase misactivates valine (to produce valyl adenylate or Val-tRNA(Ile)) at its active site. The misactivated amino acid is then translocated to an editing site located >25 A away. The role of the misactivated amino acid in determining the rate of translocation is not known. Valyl-tRNA synthetase, a close homolog of isoleucyl-tRNA synthetase, misactivates threonine, alpha-aminobutyrate, and cysteine. In this paper, we use a recently developed fluorescence-energy-transfer assay to study translocation of misactivated threonine, alpha-aminobutyrate, and cysteine. Although their rates of misactivation are clearly distinct, their rates of translocation are similar. Thus, the rate of translocation is independent of the nature of the misactivated amino acid. This result suggests that the misactivated amino acid per se has little or no role in directing translocation.

Nucleotide determinants for tRNA-dependent amino acid discrimination by a class I tRNA synthetase

The high accuracy of the genetic code relies on the ability of tRNA synthetases to discriminate rigorously between closely similar amino acids. While the enzymes can detect differences between closely similar amino acids at an accuracy of about 1 part in 100-200, a finer discrimination requires the presence of the cognate tRNA. The role of the tRNA is to direct the misactivated amino acid to a distinct catalytic site for editing where hydrolysis occurs. Previous work showed that three nucleotides at the corner of the L-shaped tRNA were collectively required. Here we show that each of these nucleotides individually contributes to the efficiency of editing. However, all are dispensable for the chemical step of hydrolysis. Instead, these nucleotides are required for translocation of a misactivated amino acid from the active site to the center for editing.

Insights into editing from an ile-tRNA synthetase structure with tRNAile and mupirocin

Isoleucyl-transfer RNA (tRNA) synthetase (IleRS) joins Ile to tRNA(Ile) at its synthetic active site and hydrolyzes incorrectly acylated amino acids at its editing active site. The 2.2 angstrom resolution crystal structure of Staphylococcus aureus IleRS complexed with tRNA(Ile) and Mupirocin shows the acceptor strand of the tRNA(Ile) in the continuously stacked, A-form conformation with the 3' terminal nucleotide in the editing active site. To position the 3' terminus in the synthetic active site, the acceptor strand must adopt the hairpinned conformation seen in tRNA(Gln) complexed with its synthetase. The amino acid editing activity of the IleRS may result from the incorrect products shuttling between the synthetic and editing active sites, which is reminiscent of the editing mechanism of DNA polymerases.

The antifungal activity of mupirocin

The antibacterial agent mupirocin (pseudomonic acid A) is used as a topical agent in the treatment of superficial infections by Gram-positive bacteria, particularly Staphylococcus aureus. However, we demonstrate here that the compound also inhibits the growth of a number of pathogenic fungi in vitro, including a range of dermatophytes and Pityrosporum spp. It inhibited the incorporation of amino acids and precursors of RNA, but not that of acetate, by Trichophyton mentagrophytes. It also inhibited the isoleucyl-tRNA synthetase from Candida albicans, indicating a mechanism of action similar to that in bacteria. When administered topically, mupirocin was efficacious in a T. mentagrophytes ringworm model in guinea pigs. These results suggest that mupirocin could have clinical utility for superficial infections caused by dermatophytes.

Mupirocin resistance in staphylococci: development and transfer of isoleucyl-tRNA synthetase-mediated resistance in vitro

Mupirocin resistance could be transferred from highly resistant clinical isolates of Staphylococcus aureus to highly sensitive recipients of Staph. aureus, Staph. epidermidis and Staph. haemolyticus. Transconjugants of the latter two organisms could transfer this resistance into mupirocin-sensitive Staph. aureus. Moderately resistant strains did not transfer this resistance to sensitive recipients, nor did strains with high-level mupirocin resistance developed by serial transfer or habituation. The inhibitory effects of mupirocin on crude isoleucyl-tRNA synthetases (IRS) isolated from mupirocin-sensitive and -resistant strains of Staph. aureus have been determined. Drug concentrations needed to produce 50% inhibition, I50 values, were very low against IRS from a highly sensitive strain, somewhat higher against IRS from moderately resistant strains, much higher against enzyme from strains trained in vitro to high-level resistance, and considerably higher still against IRS extracted from clinical isolates possessing high-level mupirocin resistance and from the transconjugates of such strains resulting from crosses with mupirocin-sensitive strains. It is concluded that high-level resistance in clinical isolates is plasmid-mediated involving a second, mupirocin-resistant IRS whereas in moderately resistant strains, and in strains trained in vitro to high-level resistance, chromosomal mutations are likely to be responsible for decreasing IRS sensitivity.

RNA determinants for translational editing. Mischarging a minihelix substrate by a tRNA synthetase

The fidelity of protein synthesis requires efficient discrimination of amino acid substrates by aminoacyl-tRNA synthetases. Accurate discrimination of the structurally similar amino acids, valine and isoleucine, by isoleucyl-tRNA synthetase (IleRS) results, in part, from a hydrolytic editing reaction, which prevents misactivated valine from being stably joined to tRNAIle. The editing reaction is dependent on the presence of tRNAIle, which contains discrete D-loop nucleotides that are necessary to promote editing of misactivated valine. RNA minihelices comprised of just the acceptor-TPsiC helix of tRNAIle are substrates for specific aminoacylation by IleRS. These substrates lack the aforementioned D-loop nucleotides. Because minihelices contain determinants for aminoacylation, we thought that they might also play a role in editing that has not previously been recognized. Here we show that, in contrast to tRNAIle, minihelixIle is unable to trigger the hydrolysis of misactivated valine and, in fact, is mischarged with valine. In addition, mutations in minihelixIle that enhance or suppress charging with isoleucine do the same with valine. Thus, minihelixIle contains signals for charging (by IleRS) that are independent of the amino acid and, by itself, minihelixIle provides no determinants for editing. An RNA hairpin that mimics the D-stem/loop of tRNAIle is also unable to induce the hydrolysis of misactivated valine, both by itself and in combination with minihelixIle. Thus, the native tertiary fold of tRNAIle is required to promote efficient editing. Considering that the minihelix is thought to be the more ancestral part of the tRNA structure, these results are consistent with the idea that, during the development of the genetic code, RNA determinants for editing were added after the establishment of an aminoacylation system.

Characterization of isoleucyl-tRNA synthetase from Staphylococcus aureus. II. Mechanism of inhibition by reaction intermediate and pseudomonic acid analogues studied using transient and steady-state kinetics

The interactions of isoleucyl-tRNA synthetase (IleRS, E) from Staphylococcus aureus with both intermediate analogues and pseudomonic acid (PS-A) have been investigated using transient and steady-state techniques. Non-hydrolyzable analogues of isoleucyl-AMP (I) were simple competitive inhibitors (Ile-ol-AMP, Ki = 50 nM and Ile-NHSO2-AMP, Ki = 1 nM;). PS-A (J) inhibits IleRS via a slow-tight binding competitive mechanism where E.J (Kj = approximately 2 nM), undergoes an isomerization to form a stabilized E*.J complex (K*j = 50 pM). To overcome tight-binding artifacts when K*j << [E], K*j values were estimated from PPi/ATP exchange where [S] >> Km, thus raising K*j,app well above [E]. Using [3H]PS-A, it was confirmed that binding occurs with 1:1 stoichiometry and is reversible. Formation of inhibitor complexes was monitored directly through changes in enzyme tryptophan fluorescence. For Ile-ol-AMP and Ile-NHSO2-AMP, the fluorescence intensity of E.I was identical to that when E.Ile-AMP forms catalytically. Binding of PS-A induced only a small change in IleRS fluorescence that was characterized using transient kinetic competition. SB-205952, a PS-A analogue, produced a 37% quenching of IleRS fluorescence upon binding as a result of radiationless energy transfer. Inhibitor reversal rates were obtained by measuring relaxation between spectroscopically different complexes. Together, these data represent a comprehensive solution to the kinetics of inhibition by these compounds.

Effects of substrate and inhibitor binding on proteolysis of isoleucyl-tRNA synthetase from Staphylococcus aureus

Binding of ligands to isoleucyl-tRNA synthetase (IleRS; E) from Staphylococcus aureus was investigated through effects on proteolytic digestion. Approximately 50-fold higher concentrations of protease (trypsin or chymotrypsin) were required to inactivate IleRS after incubation with substrates and formation of the E. Ile-AMP intermediate compared with free E. Binding of pseudomonic acid A (PS-A) or isoleucynol adenylate (Ile-ol-AMP) also induced resistance to proteolysis and altered the patterns of IleRS cleavage fragments in an inhibitor-class specific manner. The determinants for PS-A binding were investigated via proteolysis of E.[3H]PS-A. Limited proteolysis of E.[3H]PS-A (excising residues 186-407) could be achieved without significant loss of bound inhibitor, eliminating this region as contributing to inhibitor binding. Assays were developed which allowed IleRS proteolysis to be readily followed using fluorescence polarization. Inhibitor-protected IleRS was labeled with fluorescein isothiocyanate with only a small effect upon catalytic activity (Fl-IleRS). The (pseudo) kinetics of proteolytic cleavage of Fl-IleRS could be measured at low nanomolar Fl-IleRS concentrations in 96/384-well microtiter plates, allowing real-time monitoring of dose-dependent protection from proteolysis. Thus, inhibitor (and substrate) binding could be reproducibly assessed in the absence of measurements of catalytic acitvity. This could potentially form the basis of novel screening assays for ligands to other proteins.

Characterization of isoleucyl-tRNA synthetase from Staphylococcus aureus. I: Kinetic mechanism of the substrate activation reaction studied by transient and steady-state techniques

The kinetic mechanism for the amino acid activation reaction of Staphylococcus aureus isoleucyl-tRNA synthetase (IleRS; E) has been determined from stopped-flow measurements of the tryptophan fluorescence associated with the formation of the enzyme-bound aminoacyl adenylate (E.Ile-AMP; Scheme 1). Isoleucine (Ile) binds to the E.ATP complex (K4 = 1.7 +/- 0.9 microM) approximately 35-fold more tightly than to E (K1 = 50-100 microM), primarily due to a reduction in the Ile dissociation rate constant (k-1 approximately 100-150 s-1, cf. k-4 = 3 +/- 1.5 s-1). Similarly, ATP binds more tightly to E.Ile (K3 = approximately 70 microM) than to E (K2 = approximately 2.5 mM). The formation of the E.isoleucyl adenylate intermediate, E.Ile-AMP, resulted in a further increase in fluorescence allowing the catalytic step to be monitored (k+5 = approximately 60 s-1) and the reverse rate constant (k-5 = approximately 150-200 s-1) to be determined from pyrophosphorolysis of a pre-formed E.Ile-AMP complex (K6 = approximately 0.25 mM). Scheme 1 was able to globally predict all of the observed transient kinetic and steady-state PPi/ATP exchange properties of IleRS by simulation. A modification of Scheme 1 could also provide an adequate description of the kinetics of tRNA aminoacylation (kcat,tr = approximately 0.35 s-1) thus providing a framework for understanding the kinetic mechanism of aminoacylation in the presence of tRNA and of inhibitor binding to IleRS.

Decreased accumulation or increased isoleucyl-tRNA synthetase activity confers resistance to the cyclic beta-amino acid BAY 10-8888 in Candida albicans and Candida tropicalis

BAY 10-8888, a cyclic beta-amino acid, exerts its antifungal activity by inhibition of isoleucyl-tRNA synthetase activity after accumulation to a millimolar concentration inside the cell. We have selected and characterized BAY 10-8888-resistant Candida albicans mutants. Reduced BAY 10-8888 accumulation as well as increased isoleucyl-tRNA synthetase activity was observed in these mutants. Some of the mutants were cross-resistant to cispentacin, a structurally related beta-amino acid, while sensitivities to 5-fluorocytosine and fluconazole remained unchanged in all mutants. All except two in vitro-resistant mutants were pathogenic in a murine candidiasis model, and BAY 10-8888 failed to cure the infection. Furthermore, we have characterized BAY 10-8888 transport and isoleucyl-tRNA synthetase activity in several Candida tropicalis strains which showed MICs higher than those of other Candida strains. An analysis of the C. tropicalis strains revealed that intracellular concentrations of BAY 10-8888 were in the millimolar range, comparable to those for C. albicans. However, these isolates expressed isoleucyl-tRNA synthetase activities about fourfold higher than those for C. albicans. To test the possibility of resistance modeling, we determined the correlations between the intracellular concentration of BAY 10-8888, the specific activity of isoleucyl-tRNA synthetase, the number of free, i.e., noninhibited, isoleucyl-tRNA synthetase molecules/cell, and growth, assuming a linear relation. We found significant correlations between growth and the intracellular concentration of BAY 10-8888 and between growth and the number of free isoleucyl-tRNA synthetase molecules/cell, but not between growth and the specific activity of isoleucyl-tRNA synthetase.

A multifunctional repeated motif is present in human bifunctional tRNA synthetase

Tandem repeats located in the human bifunctional glutamyl-prolyl-tRNA synthetase (EPRS) have been found in many different eukaryotic tRNA synthetases and were previously shown to interact with another distinct repeated motifs in human isoleucyl-tRNA synthetase. Nuclear magnetic resonance and differential scanning calorimetry analyses of an isolated EPRS repeat showed that it consists of a helix-turn-helix with a melting temperature of 59 degrees C. Specific interaction of the EPRS repeats with those of isoleucyl-tRNA synthetase was confirmed by in vitro binding assays and shown to have a dissociation constant of approximately 2.9 microM. The EPRS repeats also showed the binding activity to the N-terminal motif of arginyl-tRNA synthetase as well as to various nucleic acids, including tRNA. Results of the present work suggest that the region comprising the repeated motifs of EPRS provides potential sites for interactions with various biological molecules and thus plays diverse roles in the cell.

Enzyme structure with two catalytic sites for double-sieve selection of substrate

High-fidelity transfers of genetic information in the central dogma can be achieved by a reaction called editing. The crystal structure of an enzyme with editing activity in translation is presented here at 2.5 angstroms resolution. The enzyme, isoleucyl-transfer RNA synthetase, activates not only the cognate substrate L-isoleucine but also the minimally distinct L-valine in the first, aminoacylation step. Then, in a second, "editing" step, the synthetase itself rapidly hydrolyzes only the valylated products. For this two-step substrate selection, a "double-sieve" mechanism has already been proposed. The present crystal structures of the synthetase in complexes with L-isoleucine and L-valine demonstrate that the first sieve is on the aminoacylation domain containing the Rossmann fold, whereas the second, editing sieve exists on a globular beta-barrel domain that protrudes from the aminoacylation domain.

Aminoacylation of coenzyme A and pantetheine by aminoacyl-tRNA synthetases: possible link between noncoded and coded peptide synthesis

Isoleucyl-tRNA synthetase (IleRS) catalyzes transfer of isoleucine from the enzyme-bound Ile-AMP and Ile-tRNA to the thiol group of coenzyme A, forming a thioester, Ile-S-CoA. Identity of Ile-S-CoA has been confirmed by several enzymatic and chemical tests. The synthesis of Ile-S-CoA, like the synthesis of other isoleucyl thioesters, is strongly shifted toward products. Other aminoacyl-tRNA synthetases, such as MetRS, AspRS, and SerRS also use CoA-SH as an acceptor for their cognate amino acids. Pantetheine also serves as an amino acid acceptor in reactions catalyzed by AspRS, IleRS, and MetRS, forming corresponding aminoacyl-S-pantetheine thioesters. It appears that CoA-SH reacts with activated amino acids by binding to each synthetase at a site, separate from the tRNA and ATP binding sites, that includes the thiol-binding subsite. These and other data support a hypothesis that the present-day aminoacyl-tRNA synthetases have originated from ancestral forms that were involved in noncoded thioester-dependent peptide synthesis, functionally similar to the present-day nonribosomal peptide synthesis by multi-enzyme thiotemplate systems.

Isoleucylation properties of native human mitochondrial tRNAIle and tRNAIle transcripts. Implications for cardiomyopathy-related point mutations (4269, 4317) in the tRNAIle gene

A growing number of mutated mitochondrial tRNA genes have been found associated with severe human diseases. To investigate the potential interference of such mutations with the primordial function of tRNAs, i.e. their aminoacylation by cognate aminoacyl-tRNA synthetases, a human mitochondrial in vitro aminoacylation system specific for isoleucine has been established. Both native tRNAIleand isoleucyl-tRNA synthetase activity have been recovered from human placental mitochondria and the kinetic parameters of tRNA aminoacylation determined. The effect of pathological point mutations present in the mitochondrial gene encoding tRNAIlehas been tackled by investigating the isoleucylation properties of wild-type and mutated in vitro transcripts. Data show that: (i) modified nucleotides contribute to efficient isoleucylation; (ii) point mutation A4269G in the gene (A-->G at nt 7 in the tRNA), associated with a cardiomyopathy, does not affect aminoacylation significantly; (iii) point mutation A4317G (A-->G at nt 59 in the tRNA), reported in a case of fatal infantile cardiomyopathy, induces a small but significant decrease in isoleucylation. The potential implications of these findings on the understanding of the molecular mechanisms involved in the expression of pathology are discussed.

The modified wobble base inosine in yeast tRNAIle is a positive determinant for aminoacylation by isoleucyl-tRNA synthetase

Earlier work by two independent groups has established the fact that anticodons GAU and LAU of Escherichia coli tRNAIle isoacceptors play a critical role in the tRNA identity. Yeast possesses two isoleucine transfer RNAs, a major one with anticodon IAU and a minor one with anticodon PsiAPsi which are derived from the post-transcriptional modification of AAU and UAU gene sequences, respectively. We present direct evidence which reveals that inosine is a positive determinant for yeast isoleucyl-tRNA synthetase. We also show that yeast tRNAMet with guanosine at the wobble position becomes aminoacylated with isoleucine while methionine acceptance is lost. As inosine and guanosine share the 6-keto and the N-1 hydrogen groups, this suggests that these hydrogen donor and acceptor groups are determinants for isoleucine specificity. The role of the minor tRNAIle anticodon pseudouridines in tRNA isoleucylation could not be tested directly but was deduced from a 40-fold decrease in the activity of the unmodified transcript. The presence of the NHCO structure in guanosine, inosine, pseudouridine, and lysidine suggests a unifying model of wobble base recognition by the yeast and E. coli isoleucyl-tRNA synthetase. In contrast to lysidine which switches the identity of the tRNA from methionine to isoleucine [Muramatsu, T., Nishikawa, K., Nemoto, F., Kuchino, Y., Nishimura, S., Miyazawa, T., & Yokoyama, S. (1988) Nature 336, 179-181], pseudouridine-34 does not modify the specificity of the yeast minor tRNAIle since U-34 is a strong negative determinant for yeast MetRS. Therefore, the major role of Psi-34 (in combination with Psi-36 or not) is likely in isoleucine AUA codon specificity and translational fidelity.

Zinc-dependent tRNA binding by a peptide element within a tRNA synthetase

The class I aminoacyl-tRNA synthetases are defined by an N-terminal nucleotide binding fold that contains the active site for adenylate synthesis. Insertions and additions of idiosyncratic RNA binding elements that facilitate docking of the L-shaped tRNA structure are superimposed onto this basic fold. These RNA binding elements are imagined to have been acquired during the evolution and development of the modern genetic code. The monomeric Escherichia coli isoleucyl-tRNA synthetase has a zinc-containing peptide at its C terminus. Removal of the zinc-containing peptide was shown previously to create a shortened enzyme with activity for adenylate synthesis but no detectable binding to tRNA(Ile). We show here that the isolated zinc-containing peptide binds to tRNA with relatively low affinity. This binding is not tRNA-specific but shows a strict requirement for zinc. In contrast, the zinc-containing peptide conferred specific and high-affinity binding when combined with the shortened enzyme. Thus, when combined with another protein, a nonspecific tRNA binding peptide is essential for formation of a high-affinity and specific tRNA binding site. These results demonstrate the feasibility of the idea that noncovalent complexes of general RNA-binding peptides with a domain for adenylate synthesis were precursors to modern tRNA synthetases. In addition, the results offer the first direct evidence of a role for zinc in the tRNA-binding activity of one of these peptide elements.