Non-essential role of lysine residues for the catalytic activities of aspartyl-tRNA synthetase and comparison with other aminoacyl-tRNA synthetases

Essential lysine residues were sought in the catalytic site of baker's yeast aspartyl-tRNA synthetase (an alpha 2 dimer of Mr 125,000) using affinity labeling methods and periodate-oxidized adenosine, ATP, and tRNA(Asp). It is shown that the number of periodate-oxidized derivatives which can be bound to the synthetase via Schiff's base formation with epsilon-NH2 groups of lysine residues exceeds the stoichiometry of specific substrate binding. Furthermore, it is found that the enzymatic activities are not completely abolished, even for high incorporation levels of the modified substrates. The tRNA(Asp) aminoacylation reaction is more sensitive to labeling than is the ATP-PPi exchange one; for enzyme preparations modified with oxidized adenosine or ATP this activity remains unaltered. These results demonstrate the absence of a specific lysine residue directly involved in the catalytic activities of yeast aspartyl-tRNA synthetase. Comparative labeling experiments with oxidized ATP were run with several other aminoacyl-tRNA synthetases. Residual ATP-PPi exchange and tRNA aminoacylation activities measured in each case on the modified synthetases reveal different behaviors of these enzymes when compared to that of aspartyl-tRNA synthetase. When tested under identical experimental conditions, pure isoleucyl-, methionyl-, threonyl- and valyl-tRNA synthetases from E. coli can be completely inactivated for their catalytic activities; for E. coli alanyl-tRNA synthetase only the tRNA charging activity is affected, whereas yeast valyl-tRNA synthetase is only partly inactivated. The structural significance of these experiments and the occurrence of essential lysine residues in aminoacyl-tRNA synthetases are discussed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutation and evolution of the magnesium-binding site of a class II aminoacyl-tRNA synthetase

Aminoacyl-tRNA synthetases contain one or three Mg(2+) ions in their catalytic sites. In addition to their role in ATP binding, these ions are presumed to play a role in catalysis by increasing the electropositivity of the alpha-phosphate and stabilizing the pentavalent transition state. In the class II aaRS, two highly conserved carboxylate residues have been shown to participate with Mg(2+) ions in binding and coordination. It is shown here that these carboxylate residues are absolutely required for the activity of Saccharomyces cerevisiae aspartyl-tRNA synthetase. Mutants of these residues exhibit pleiotropic effects on the kinetic parameters suggesting an effect at an early stage of the aminoacylation reaction, such as the binding of ATP, Mg(2+), aspartic acid, or the amino acid activation. Despite genetic selections in an APS-knockout yeast strain, we were unable to select a single active mutant of these carboxylate residues. Nevertheless, we isolated an intragenic suppressor from a combinatorial library. The active mutant showed a second substitution close to the first one, and exhibited a significant increase of the tRNA aminoacylation rate. Structural analysis suggests that the acceptor stem of the tRNA might be repositioned to give a more productive enzyme:tRNA complex. Thus, the initial defect of the activation reaction was compensated by a significant increase of the aminoacylation rate that led to cellular complementation.     

Structural studies of lysyl-tRNA synthetase: conformational changes induced by substrate binding

Lysyl-tRNA synthetase is a member of the class II aminoacyl-tRNA synthetases and catalyses the specific aminoacylation of tRNA(Lys). The crystal structure of the constitutive lysyl-tRNA synthetase (LysS) from Escherichia coli has been determined to 2.7 A resolution in the unliganded form and in a complex with the lysine substrate. A comparison between the unliganded and lysine-bound structures reveals major conformational changes upon lysine binding. The lysine substrate is involved in a network of hydrogen bonds. Two of these interactions, one between the alpha-amino group and the carbonyl oxygen of Gly 216 and the other between the carboxylate group and the side chain of Arg 262, trigger a subtle and complicated reorganization of the active site, involving the ordering of two loops (residues 215-217 and 444-455), a change in conformation of residues 393-409, and a rotation of a 4-helix bundle domain (located between motif 2 and 3) by 10 degrees. The result of these changes is a closing up of the active site upon lysine binding.     

Aminoacylation of tRNAs as critical step of protein biosynthesis.

Isoleucyl-tRNA synthetases isolated from commercial baker's yeast and E coli were investigated for their sequences of substrate additions and product releases. The results show that aminoacylation of tRNA is catalyzed by these enzymes in different pathways, eg isoleucyl-tRNA synthetase from yeast can act with four different catalytic cycles. Amino acid specificities are gained by a four-step recognition process consisting of two initial binding and two proofreading steps. Isoleucyl-tRNA synthetase from yeast rejects noncognate amino acids with discrimination factors of D = 300-38000, isoleucyl-tRNA synthetase from E coli with factors of D = 600-68000. Differences in Gibbs free energies of binding between cognate and noncognate amino acids are related to different hydrophobic interaction energies and assumed conformational changes of the enzyme. A simple hypothetical model of the isoleucine binding site is postulated. Comparison of gene sequences of isoleucyl-tRNA synthetase from yeast and E coli exhibits only 27% homology. Both genes show the 'HIGH'- and 'KMSKS'-regions assigned to binding of ATP and tRNA. Deletion of 250 carboxyterminal amino acids from the yeast enzyme results in a fragment which is still active in the pyrophosphate exchange reaction but does not catalyze the aminoacylation reaction. The enzyme is unable to catalyze the latter reaction if more than 10 carboxyterminal residues are deleted.     

Initial position of aminoacylation of individual Escherichia coli, yeast, and calf liver transfer RNAs.

Transfer RNAs from Escherichia coli, yeast (Sacharomyces cerevisiae), and calf liver were subjected to controlled hydrolysis with venom exonuclease to remove 3'-terminal nucleotides, and then reconstructed successively with cytosine triphosphate (CTP) and 2'- or 3'-deoxyadenosine 5'-triphosphate in the presence of yeast CTP(ATP):tRNA nucleotidyltransferase. The modified tRNAs were purified by chromatography on DBAE-cellulose or acetylated DBAE-cellulose and then utilized in tRNA aminoacylation experiments in the presence of the homologous aminoacyl-tRNA synthetase activities. The E. coli, yeast, and calf liver aminoacyl-tRNA synthetases specific for alanine, glycine, histidine, lysine, serine, and threonine, as well as the E. coli and yeast prolyl-tRNA synthetases and the yeast glutaminyl-tRNA synthetase utilized only those homologous modified tRNAs terminating in 2'-deoxyadenosine (i.e., having an available 3'-OH group). This is interpreted as evidence that these aminoacyl-tRNA synthetases normally aminoacylate their unmodified cognate tRNAs on the 3'-OH group. The aminoacyl-tRNA synthetases from all three sources specific argining, isoleucine, leucine, phenylalanine, and valine, as well as the E. coli and yeast enzymes specific for methionine and the E. coli glutamyl-tRNA synthetase, used as substrates exclusively those tRNAs terminating in 3'-deoxyadenosine. Certain aminoacyl-tRNA synthetases, including the E. coli, yeast, and calf liver asparagine and tyrosine activating enzymes, the E. coli and yeast cysteinyl-tRNA synthetases, and the aspartyl-tRNA synthetase from yeast, utilized both isomeric tRNAs as substrates, although generally not at the same rate. While the calf liver aspartyl- and cysteinyl-tRNA synthetases utilized only the corresponding modified tRNA species terminating in 2'-deoxyadenosine, the use of a more concentrated enzyme preparation might well result in aminoacylation of the isomeric species. The one tRNA for which positional specificity does seem to have changed during evolution is tryptophan, whose E. coli aminoacyl-tRNA synthetase utilized predominantly the cognate tRNA terminating in 3'-deoxyadenosine, while the corresponding yeast and calf liver enzymes were found to utilize predominantly the isomeric tRNAs terminating in 2'-deoxyadenosine. The data presented indicate that while there is considerable diversity in the initial position of aminoacylation of individual tRNA isoacceptors derived from a single source, positional specificity has generally been conserved during the evolution from a prokaryotic to mammalian organism.     

Conformational movements and cooperativity upon amino acid,ATP and tRNA binding in threonyl-tRNA synthetase

The crystal structures of threonyl-tRNA synthetase (ThrRS) from Staphylococcus aureus, with ATP and an analogue of threonyl adenylate, are described. Together with the previously determined structures of Escherichia coli ThrRS with different substrates, they allow a comprehensive analysis of the effect of binding of all the substrates: threonine, ATP and tRNA. The tRNA, by inserting its acceptor arm between the N-terminal domain and the catalytic domain, causes a large rotation of the former. Within the catalytic domain, four regions surrounding the active site display significant conformational changes upon binding of the different substrates. The binding of threonine induces the movement of as much as 50 consecutive amino acid residues. The binding of ATP triggers a displacement, as large as 8A at some C(alpha) positions, of a strand-loop-strand region of the core beta-sheet. Two other regions move in a cooperative way upon binding of threonine or ATP: the motif 2 loop, which plays an essential role in the first step of the aminoacylation reaction, and the ordering loop, which closes on the active site cavity when the substrates are in place. The tRNA interacts with all four mobile regions, several residues initially bound to threonine or ATP switching to a position in which they can contact the tRNA. Three such conformational switches could be identified, each of them in a different mobile region. The structural analysis suggests that, while the small substrates can bind in any order, they must be in place before productive tRNA binding can occur.     

A conserved threonine within Escherichia coli leucyl-tRNA synthetase prevents hydrolytic editing of leucyl-tRNALeu

Aminoacyl-tRNA synthetases ensure the fidelity of protein synthesis by accurately selecting and activating cognate amino acids for aminoacylation of the correct tRNA. Some tRNA synthetases have evolved an editing active site that is separate from the amino acid activation site providing two steps or "sieves" for amino acid selection. These two sieves rely on different strategies for amino acid recognition to significantly enhance the accuracy of aminoacylation. We have performed alanine scanning mutagenesis in a conserved threonine-rich region of the Escherichia coli leucyl-tRNA synthetase's CP1 domain that is hypothesized to contain a putative editing active site. Characterization of purified mutant proteins led to the identification of a single conserved threonine that prevents the cognate leucine amino acid from being hydrolyzed after aminoacylation of the tRNA. Mutation of this threonine to an alanine eliminates discrimination of the cognate amino acid in the editing active site. This provides a molecular example of an amino acid discrimination mechanism in the tRNA synthetase's editing active site.     

A single glutamyl-tRNA synthetase aminoacylates tRNAGlu and tRNAGln in Bacillus subtilis and efficiently misacylates Escherichia coli tRNAGln1 in vitro.

In the presence or absence of its regulatory factor, the monomeric glutamyl-tRNA synthetase from Bacillus subtilis can aminoacylate in vitro with glutamate both tRNAGlu and tRNAGln from B. subtilis and tRNAGln1 but not tRNAGln2 or tRNAGlu from Escherichia coli. The Km and Vmax values of the enzyme for its substrates in these homologous or heterologous aminoacylation reactions are very similar. This enzyme is the only aminoacyl-tRNA synthetase reported to aminoacylate with normal kinetic parameters two tRNA species coding for different amino acids and to misacylate at a high rate a heterologous tRNA under normal aminoacylation conditions. The exceptional lack of specificity of this enzyme for its tRNAGlu and tRNAGln substrates, together with structural and catalytic peculiarities shared with the E. coli glutamyl- and glutaminyl-tRNA synthetases, suggests the existence of a close evolutionary linkage between the aminoacyl-tRNA synthetases specific for glutamate and those specific for glutamine. A comparison of the primary structures of the three tRNAs efficiently charged by the B. subtilis glutamyl-tRNA synthetase with those of E. coli tRNAGlu and tRNAGln2 suggests that this enzyme interacts with the G64-C50 or G64-U50 in the T psi stem of its tRNA substrates.     

In vitro assays for the determination of aminoacyl-tRNA synthetase editing activity

Aminoacyl-tRNA synthetases are essential enzymes that help to ensure the fidelity of protein translation by accurately aminoacylating (or "charging") specific tRNA substrates with cognate amino acids. Many synthetases have an additional catalytic activity to confer amino acid editing or proofreading. This activity relieves ambiguities during translation of the genetic code that result from one synthetase activating multiple amino acid substrates. In this review, we describe methods that have been developed for assaying both pre- and post-transfer editing activities. Pre-transfer editing is defined as hydrolysis of a misactivated aminoacyl-adenylate prior to transfer to the tRNA. This reaction has been reported to occur either in the aminoacylation active site or in a separate editing domain. Post-transfer editing refers to the hydrolysis reaction that cleaves the aminoacyl-ester linkage formed between the carbonyl carbon of the amino acid and the 2' or 3' hydroxyl group of the ribose on the terminal adenosine. Post-transfer editing takes place in a hydrolytic active site that is distinct from the site of amino acid activation. Here, we focus on methods for determination of steady-state reaction rates using editing assays developed for both classes of synthetases.     

Fidelity in the aminoacylation of tRNA(Val) with hydroxy analogues of valine, leucine, and isoleucine by valyl-tRNA synthetases from Saccharomyces cerevisiae and Escherichia coli

Several analogues of valine, leucine, and isoleucine carrying hydroxyl groups in the gamma- or delta-position have been tested in the aminoacylation of tRNA by valyl-tRNA synthetases from Saccharomyces cerevisiae and Escherichia coli. Results of the ATP/PPi exchange and of the aminoacylation reactions indicate that the amino acid analogues not only can form the aminoacyl adenylate intermediate but are also transferred to tRNA. However, the fact that the reaction consumes an excess of ATP indicates that the misactivated amino acid analogue is hydrolytically removed. Thus, valyl-tRNA synthetase from S. cerevisiae shows a high fidelity in forming valyl-tRNA. Although the much bulkier amino acid analogues allo- and iso-gamma-hydroxyvaline and allo- and iso-gamma-hydroxyisoleucine are initially charged to tRNA, the misaminoacylated tRNA(Val) is enzymatically deacylated. This cleavage reaction is mediated by the hydroxyl groups of the amino acid analogues which are converted into the corresponding lactones.     

Amino acid discrimination by a class I aminoacyl-tRNA synthetase specified by negative determinants

The 2.5 A crystal structure of Escherichia coli glutaminyl-tRNA synthetase in a quaternary complex with tRNA(Gln), an ATP analog and glutamate reveals that the non-cognate amino acid adopts a distinct binding mode within the active site cleft. In contrast to the binding of cognate glutamine, one oxygen of the charged glutamate carboxylate group makes a direct ion-pair interaction with the strictly conserved Arg30 residue located in the first half of the dinucleotide fold domain. The nucleophilic alpha-carboxylate moiety of glutamate is mispositioned with respect to both the ATP alpha-phosphate and terminal tRNA ribose groups, suggesting that a component of amino acid discrimination resides at the catalytic step of the reaction. Further, the other side-chain carboxylate oxygen of glutamate is found in a position identical to that previously proposed to be occupied by the NH(2) group of the cognate glutamine substrate. At this position, the glutamate oxygen accepts hydrogen bonds from the hydroxyl moiety of Tyr211 and a water molecule. These findings demonstrate that amino acid specificity by GlnRS cannot arise from hydrogen bonds donated by the cognate glutamine amide to these same moieties, as previously suggested. Instead, Arg30 functions as a negative determinant to drive binding of non-cognate glutamate into a non-productive orientation. The poorly differentiated cognate amino acid-binding site in GlnRS may be a consequence of the late emergence of this enzyme from the eukaryotic lineage of glutamyl-tRNA synthetases.     

Aminoacylation of RNA Minihelices: Implications for tRNA Synthetase Structural Design and Evolution

Abstract

The genetic code is based on the aminoacylation of tRNA with amino acids catalyzed by the aminoacyl-tRNA synthetases. The synthetases are constructed from discrete domains and all synthetases possess a core catalytic domain that catalyzes amino acid activation, binds the acceptor stem of tRNA, and transfers the amino acid to tRNA. Fused to the core domain are additional domains that mediate RNA interactions distal to the acceptor stem. Several synthetases catalyze the aminoacylation of RNA oligonucleotide substrates that recreate only the tRNA acceptor stems. In one case, a relatively small catalytic domain catalyzes the aminoacylation of these substrates independent of the rest of the protein. Thus, the active site domain may represent a primordial synthetase in which polypeptide insertions that mediate RNA acceptor stem interactions are tightly integrated with determinants for aminoacyl adenylate synthesis. The relationship between nucleotide sequences in small RNA oligonucleotides and the specific amino acids that are attached to these oligonucleotides could constitute a second genetic code.     

Functional guanine-arginine interaction between tRNAPro and prolyl-tRNA synthetase that couples binding and catalysis

Aminoacyl-tRNA synthetases catalyze the attachment of specific amino acids to their cognate tRNAs. Specific aminoacylation is dictated by a set of recognition elements that mark tRNA molecules as substrates for particular synthetases. Escherichia coli prolyl-tRNA synthetase (ProRS) has previously been shown to recognize specific bases of tRNA(Pro) in both the anticodon domain, which mediate initial complex formation, and in the acceptor stem, which is proximal to the site of catalysis. In this work, we unambiguously define the molecular interaction between E. coli ProRS and the acceptor stem of cognate tRNA(Pro). Oxidative cross-linking studies using 2'-deoxy-8-oxo-7,8-dihydroguanosine-containing proline tRNAs identify a direct interaction between a critical arginine residue (R144) in the active site of E. coli ProRS and the G72 residue in the acceptor stem of tRNA(Pro). Assays conducted with motif 2 loop variants and tRNA mutants wherein specific atomic groups of G72 were deleted, are consistent with a functionally important hydrogen-bonding network between R144 and the major groove of G72. These results taken together with previous studies suggest that breaking this key contact uncouples the allosteric interaction between the anticodon domain and the aminoacylation active site, providing new insights into the communication network that governs the synthetase-tRNA interaction.     

Domain-domain communication for tRNA aminoacylation: the importance of covalent connectivity

Aminoacyl-tRNA synthetases form complexes with tRNA to catalyze transfer of activated amino acids to the 3' end of tRNA. The tRNA synthetase complexes are roughly divided into the activation and tRNA-binding domains of synthetases, which interact with the acceptor and anticodon ends of tRNAs, respectively. Efficient aminoacylation of tRNA by Escherichia coli cysteinyl-tRNA synthetase (CysRS) requires both domains, although the pathways for the long-range domain-domain communication are not well understood. Previous studies show that dissection of tRNA(Cys) into acceptor and anticodon helices seriously reduces the efficiency of aminoacylation, suggesting that communication requires covalent continuity of the tRNA backbone. Here we tested if communication requires the continuity of the synthetase backbone. Two N-terminal fragments and one C-terminal fragment of E. coli CysRS were generated. While the N-terminal fragments were active in adenylate synthesis, they were severely defective in the catalytic efficiency and specificity of tRNA aminoacylation. Conversely, although the C-terminal fragment was not catalytically active, it was able to bind and discriminate tRNA. However, addition of the C-terminal fragment to an N-terminal fragment in trans did not improve the aminoacylation efficiency of the N-terminal fragment to the level of the full-length enzyme. These results emphasize the importance of covalent continuity of both CysRS and tRNA(Cys) for efficient tRNA aminoacylation, and highlight the energetic costs of constraining the tRNA synthetase complex for domain-domain communication. Importantly, this study also provides new insights into the existence of several natural "split" synthetases that are now identified from genomic sequencing projects.     

Superspecificity of aminoacyl-tRNA-synthases

The correct aminoacylation of tRNA with the proper aminoacid by aminoacyl-tRNA synthetase is one of the key reactions which determines the overall high fidelity of protein biosynthesis. The initial selection of the amino acid is achieved in the active centre of the synthetase at the activation step due to differences in the side chains binding energies of specific substrate and the competing amino acids present in cell. If, nevertheless, the activation of amino acids structurally similar to the cognate one does proceed, additional mechanisms of correction which are based on the decomposition of unstable noncognate (intermediate or final) product of the tRNA aminoacylation reaction, by synthetase are switched on. In this review the literature on the specificity of aminoacyl-tRNA synthetases at amino acid activation step is analyzed along with the proofreading mechanisms which allow the elimination of the errors, leading to so called superspecifity of aminoacyl-tRNA synthetases.     

Correlating amino acid conservation with function in tyrosyl-tRNA synthetase

Sequence comparisons have been combined with mutational and kinetic analyses to elucidate how the catalytic mechanism of Bacillus stearothermophilus tyrosyl-tRNA synthetase evolved. Catalysis of tRNA(Tyr) aminoacylation by tyrosyl-tRNA synthetase involves two steps: activation of the tyrosine substrate by ATP to form an enzyme-bound tyrosyl-adenylate intermediate, and transfer of tyrosine from the tyrosyl-adenylate intermediate to tRNA(Tyr). Previous investigations indicate that the class I conserved KMSKS motif is involved in only the first step of the reaction (i.e. tyrosine activation). Here, we demonstrate that the class I conserved HIGH motif also is involved only in the tyrosine activation step. In contrast, one amino acid that is conserved in a subset of the class I aminoacyl-tRNA synthetases, Thr40, and two amino acids that are present only in tyrosyl-tRNA synthetases, Lys82 and Arg86, stabilize the transition states for both steps of the tRNA aminoacylation reaction. These results imply that stabilization of the transition state for the first step of the reaction by the class I aminoacyl-tRNA synthetases preceded stabilization of the transition state for the second step of the reaction. This is consistent with the hypothesis that the ability of aminoacyl-tRNA synthetases to catalyze the activation of amino acids with ATP preceded their ability to catalyze attachment of the amino acid to the 3' end of tRNA. We propose that the primordial aminoacyl-tRNA synthetases replaced a ribozyme whose function was to promote the reaction of amino acids and other small molecules with ATP.     

Functional asymmetry in the lysyl-tRNA synthetase explored by molecular dynamics,free energy calculations and experiment

Background  

Charging of transfer-RNA with cognate amino acid is accomplished by the aminoacyl-tRNA synthetases, and proceeds through an aminoacyl adenylate intermediate. The lysyl-tRNA synthetase has evolved an active site that specifically binds lysine and ATP. Previous molecular dynamics simulations of the heat-inducible Escherichia coli lysyl-tRNA synthetase, LysU, have revealed differences in the binding of ATP and aspects of asymmetry between the nominally equivalent active sites of this dimeric enzyme. The possibility that this asymmetry results in different binding affinities for the ligands is addressed here by a parallel computational and biochemical study.     

Unilateral aminoacylation specificity between bovine mitochondria and eubacteria

The present study shows unilateral aminoacylation specificity between bovine mitochondria and eubacteria (Escherichia coli and Thermus thermophilus) in five amino acid-specific aminoacylation systems. Mitochondrial synthetases were capable of charging eubacterial tRNA as well as mitochondrial tRNA, whereas eubacterial synthetases did not efficiently charge mitochondrial tRNA. Mitochondrial phenylalanyl-, threonyl-, arginyl-, and lysyl-tRNA synthetases were shown to charge and discriminate cognate E. coli tRNA species from noncognate ones strictly, as did the corresponding E. coli synthetases. By contrast, mitochondrial seryl-tRNA synthetase not only charged cognate E. coli serine tRNA species but also extensively misacylated noncognate E. coli tRNA species. These results suggest a certain conservation of tRNA recognition mechanisms between the mitochondrial and E. coli aminoacyl-tRNA synthetases in that anticodon sequences are most likely to be recognized by the former four synthetases, but not sufficiently by the seryl-tRNA synthetase. The unilaterality in aminoacylation may imply that tRNA recognition mechanisms of the mitochondrial synthetases have evolved to be, to some extent, simpler than their eubacterial counterparts in response to simplifications in the species-number and the structural elements of animal mitochondrial tRNAs.     

ATP binding by glutamyl-tRNA synthetase is switched to the productive mode by tRNA binding

Aminoacyl-tRNA synthetases catalyze the formation of an aminoacyl-AMP from an amino acid and ATP, prior to the aminoacyl transfer to tRNA. A subset of aminoacyl-tRNA synthetases, including glutamyl-tRNA synthetase (GluRS), have a regulation mechanism to avoid aminoacyl-AMP formation in the absence of tRNA. In this study, we determined the crystal structure of the 'non-productive' complex of Thermus thermophilus GluRS, ATP and L-glutamate, together with those of the GluRS.ATP, GluRS.tRNA.ATP and GluRS.tRNA.GoA (a glutamyl-AMP analog) complexes. In the absence of tRNA(Glu), ATP is accommodated in a 'non-productive' subsite within the ATP-binding site, so that the ATP alpha-phosphate and the glutamate alpha-carboxyl groups in GluRS. ATP.Glu are too far from each other (6.2 A) to react. In contrast, the ATP-binding mode in GluRS.tRNA. ATP is dramatically different from those in GluRS.ATP.Glu and GluRS.ATP, but corresponds to the AMP moiety binding mode in GluRS.tRNA.GoA (the 'productive' subsite). Therefore, tRNA binding to GluRS switches the ATP-binding mode. The interactions of the three tRNA(Glu) regions with GluRS cause conformational changes around the ATP-binding site, and allow ATP to bind to the 'productive' subsite.     

tRNA-dependent active site assembly in a class I aminoacyl-tRNA synthetase

The crystal structure of ligand-free E. coli glutaminyl-tRNA synthetase (GlnRS) at 2.4 A resolution shows that substrate binding is essential to construction of a catalytically proficient active site. tRNA binding generates structural changes throughout the enzyme, repositioning key active site peptides that bind glutamine and ATP. The structure gives insight into longstanding questions regarding the tRNA dependence of glutaminyl adenylate formation, the coupling of amino acid and tRNA selectivities, and the roles of specific pathways for transmission of tRNA binding signals to the active site. Comparative analysis of the unliganded and tRNA-bound structures shows, in detail, how flexibility is built into the enzyme architecture and suggests that the induced-fit transitions are a key underlying determinant of both amino acid and tRNA specificity.