Methanococcus jannaschii prolyl-cysteinyl-tRNA synthetase possesses overlapping amino acid binding sites

The protein translation apparatus of Methanococcus jannaschii possesses the unusual enzyme prolyl-cysteinyl-tRNA synthetase (ProCysRS), a single enzyme that attaches two different amino acids, proline and cysteine, to their cognate tRNA species. Measurement of the ATP-PP(i) exchange reaction revealed that amino acid activation, the first reaction step, differs for the two amino acids. While Pro-AMP can be formed in the absence of tRNA, Cys-AMP synthesis is tRNA-dependent. Studies with purified tRNAs indicate that tRNA(Cys) promotes cysteine activation. The k(cat) values of wild-type ProCysRS for tRNA prolylation (0.09 s(-1)) and cysteinylation (0.02 s(-1)) demonstrate that both aminoacyl-tRNAs are synthesized with comparable rates, the cysteinyl-tRNA synthetase activity being only 4.5-fold lower than prolyl-tRNA synthetase activity. Kinetic analysis of ProCysRS mutant enzymes, generated by site-directed mutagenesis, shows glutamate at position 103 to be critical for proline binding, and proline at position 100 to be involved in cysteine binding. The proximity in ProCysRS of amino acid residues affecting binding of either cysteine or proline strongly suggests that structural elements of the two amino acid binding sites overlap.     

The tRNA-dependent activation of arginine by arginyl-tRNA synthetase requires inter-domain communication

The tRNA-dependent amino acid activation catalyzed by mammalian arginyl-tRNA synthetase has been characterized. A conditional lethal mutant of Chinese hamster ovary cells that exhibits reduced arginyl-tRNA synthetase activity (Arg-1), and two of its derived revertants (Arg-1R4 and Arg-1R5) were analyzed at the structural and functional levels. A single nucleotide change, resulting in a Cys to Tyr substitution at position 599 of arginyl-tRNA synthetase, is responsible for the defective phenotype of the thermosensitive and arginine hyper-auxotroph Arg-1 cell line. The two revertants have a single additional mutation resulting in a Met222 to Ile change for Arg-1R4 or a Tyr506 to Ser change for Arg-1R5. The corresponding mutant enzymes were expressed in yeast and purified. The Cys599 to Tyr mutation affects both the thermal stability of arginyl-tRNA synthetase and the kinetic parameters for arginine in the ATP-PP(i) exchange and tRNA aminoacylation reactions. This mutation is located underneath the floor of the Rossmann fold catalytic domain characteristic of class 1 aminoacyl-tRNA synthetases, near the end of a long helix belonging to the alpha-helix bundle C-terminal domain distinctive of class 1a synthetases. For the Met222 to Ile revertant, there is very little effect of the mutation on the interaction of arginyl-tRNA synthetase with either of its substrates. However, this mutation increases the thermal stability of arginyl-tRNA synthetase, thereby leading to reversion of the thermosensitive phenotype by increasing the steady-state level of the enzyme in vivo. In contrast, for the Arg-1R5 cell line, reversion of the phenotype is due to an increased catalytic efficiency of the C599Y/Y506S double mutant as compared to the initial C599Y enzyme. In light of the location of the mutations in the 3D structure of the enzyme modeled using the crystal structure of the closely related yeast arginyl-tRNA synthetase, the kinetic analysis of these mutants suggests that the obligatory tRNA-induced activation of the catalytic site of arginyl-tRNA synthetase involves interdomain signal transduction via the long helices that build the tRNA-binding domain of the enzyme and link the site of interaction of the anticodon domain of tRNA to the floor of the active site.     

Activation of methionine by Escherichia coli methionyl-tRNA synthetase

In the present work, we have examined the function of three amino acid residues in the active site of Escherichia coli methionyl-tRNA synthetase (MetRS) in substrate binding and catalysis using site-directed mutagenesis. Conversion of Asp52 to Ala resulted in a 10,000-fold decrease in the rate of ATP-PPi exchange catalyzed by MetRS with little or no effect on the Km's for methionine or ATP or on the Km for the cognate tRNA in the aminoacylation reaction. Substitution of the side chain of Arg233 with that of Gln resulted in a 25-fold increase in the Km for methionine and a 2000-fold decrease in kcat for ATP-PPi exchange, with no change in the Km for ATP or tRNA. These results indicate that Asp52 and Arg233 play important roles in stabilization of the transition state for methionyl adenylate formation, possibly directly interacting with complementary charged groups (ammonium and carboxyl) on the bound amino acid. Primary sequence comparisons of class I aminoacyl-tRNA synthetases show that all but one member of this group of enzymes has an aspartic acid residue at the site corresponding to Asp52 in MetRS. The synthetases most closely related to MetRS (including those specific for Ile, Leu, and Val) also have a conserved arginine residue at the position corresponding to Arg233, suggesting that these conserved amino acids may play analogous roles in the activation reaction catalyzed by each of these enzymes. Trp305 is located in a pocket deep within the active site of MetRS that has been postulated to form the binding cleft for the methionine side chain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of Escherichia coli glutaminyl-tRNA synthesis with noncognate tRNA''s.

Several noncognate tRNA's from Escherichia coli were mischarged with glutamine by E. coli glutaminyl-tRNA synthetase if dimethylsulfoxide was present in the reaction mixture. Kinetic analysis of the mischarging revealed that dimethyl sulfoxide stimulated the misacylation by affecting the maximum velocity. Several noncognate tRNA's were shown to interact with glutaminyl-tRNA synthetase as measured by their ability to protect the enzyme against thermal inactivation or to replace cognate tRNA in stimulating glutamine-dependent ATP-PPi exchange reaction. These tRNA's, however, did not coincide with those which were mischargeable with glutamine.     

Assays for transfer RNA-dependent amino acid biosynthesis

Selenocysteinyl-tRNA(Sec), cysteinyl-tRNA(Cys), glutaminyl-tRNA(Gln), and asparaginyl-tRNA(Asn) in many organisms are formed in an indirect pathway in which a non-cognate amino acid is first attached to the tRNA. This non-cognate amino acid is then converted to the cognate amino acid by a tRNA-dependent modifying enzyme. The in vitro characterization of these modifying enzymes is challenging due to the fact the substrate, aminoacyl-tRNA, is labile and requires a prior enzymatic step to be synthesized. The need to separate product aa-tRNA from unreacted substrate is typically a labor- and time-intensive task; this adds another impediment in the investigation of these enzymes. Here, we review four different approaches for studying these tRNA-dependent amino acid modifications. In addition, we describe in detail a [32P]/nuclease P1 assay for glutaminyl-tRNA(Gln) and asparaginyl-tRNA(Asn) formation which is sensitive, enables monitoring of the aminoacyl state of the tRNA, and is less time consuming than some of the other techniques. This [32P]/nuclease P1 method should be adaptable to studying tRNA-dependent selenocysteine and cysteine synthesis.     

Interaction of yeast arginyl-tRNA synthetase and aspartyl-tRNA synthetase with Blue-dextran Sepharose : assignment of the Blue-Dextran Binding site on the synthetases

Yeast arginyl-tRNA synthetase and aspartyl-tRNA synthetase like nucleotidyl transferases previously investigated interact with the Blue-Dextran-Sepharose affinity ligand through their tRNA binding domain: the enzymes are readily displaced from the affinity column by their cognate tRNAs but not by ATP or a mixture of ATP and the cognate amino acid in contrast to other aminoacyl-tRNA synthetases. In the absence of Mg⁺⁺, the arginyl-tRNA synthetase can be dissociated from the column by tRNA^Asp and tRNA^Phe which have been shown to be able to form a complex with the synthetase, but in presence of Mg⁺⁺ the elution is only obtained by the specific tRNA.The procedure described here can thus be used: (i) to detect polynucleotide binding sites in a protein; (ii) to estimate the relative affinities of different tRNAs for a purified synthetase; (iii) to purify an aminoacyl-tRNA synthetase by selective elution with the cognate tRNA.     

Amino acid modifications on tRNA

The accurate formation of cognate aminoacyl-transfer RNAs (aa-tRNAs) is essential for the fidelity of translation. Most amino acids are esterified onto their cognate tRNA isoacceptors directly by aa-tRNA synthetases. However, in the case of four amino acids (Gln, Asn, Cys and Sec), aminoacyl-tRNAs are made through indirect pathways in many organisms across all three domains of life. The process begins with the charging of noncognate amino acids to tRNAs by a specialized synthetase in the case of Cys-tRNA(Cys) formation or by synthetases with relaxed specificity, such as the non-discriminating glutamyl-tRNA, non-discriminating aspartyl-tRNA and seryl-tRNA synthetases. The resulting misacylated tRNAs are then converted to cognate pairs through transformation of the amino acids on the tRNA, which is catalyzed by a group of tRNA-dependent modifying enzymes, such as tRNA-dependent amidotransferases, Sep-tRNA:Cys-tRNA synthase, O-phosphoseryl-tRNA kinase and Sep-tRNA:Sec-tRNA synthase. The majority of these indirect pathways are widely spread in all domains of life and thought to be part of the evolutionary process.     

Importance of the anticodon sequence in the aminoacylation of tRNAs by methionyl-tRNA synthetase and by valyl-tRNA synthetase in an Archaebacterium

The mode of recognition of tRNAs by aminoacyl-tRNA synthetases and translation factors is largely unknown in archaebacteria. To study this process, we have cloned the wild type initiator tRNA gene from the moderate halophilic archaebacterium Haloferax volcanii and mutants derived from it into a plasmid capable of expressing the tRNA in these cells. Analysis of tRNAs in vivo show that the initiator tRNA is aminoacylated but is not formylated in H. volcanii. This result provides direct support for the notion that protein synthesis in archaebacteria is initiated with methionine and not with formylmethionine. We have analyzed the effect of two different mutations (CAU-->CUA and CAU-->GAC) in the anticodon sequence of the initiator tRNA on its recognition by the aminoacyl-tRNA synthetases in vivo. The CAU-->CUA mutant was not aminoacylated to any significant extent in vivo, suggesting the importance of the anticodon in aminoacylation of tRNA by methionyl-tRNA synthetase. This mutant initiator tRNA can, however, be aminoacylated in vitro by the Escherichia coli glutaminyl-tRNA synthetase, suggesting that the lack of aminoacylation is due to the absence in H. volcanii of a synthetase, which recognizes the mutant tRNA. Archaebacteria lack glutaminyl-tRNA synthetase and utilize a two-step pathway involving glutamyl-tRNA synthetase and glutamine amidotransferase to generate glutaminyl-tRNA. The lack of aminoacylation of the mutant tRNA indicates that this mutant tRNA is not a substrate for the H. volcanii glutamyl-tRNA synthetase. The CAU-->GAC anticodon mutant is most likely aminoacylated with valine in vivo. Thus, the anticodon plays an important role in the recognition of tRNA by at least two of the halobacterial aminoacyl-tRNA synthetases.     

Misaminoacylation and tRNA-dependent transamidation in Streptomyces coelicolor A3(2)

Abstract Streptomyces coelicolor was found to be devoid of glutaminyl-tRNA synthetase. In this bacterium, tRNA^Gln is aminoacylated by glutamyl-tRNA synthetase to yield glutamyl-tRNA^Gln, followed by correction to glutaminyl-tRNA^Gln by a tRNA-dependent amidotransferase.     

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.     

From one amino acid to another: tRNA-dependent amino acid biosynthesis

Aminoacyl-tRNAs (aa-tRNAs) are the essential substrates for translation. Most aa-tRNAs are formed by direct aminoacylation of tRNA catalyzed by aminoacyl-tRNA synthetases. However, a smaller number of aa-tRNAs (Asn-tRNA, Gln-tRNA, Cys-tRNA and Sec-tRNA) are made by synthesizing the amino acid on the tRNA by first attaching a non-cognate amino acid to the tRNA, which is then converted to the cognate one catalyzed by tRNA-dependent modifying enzymes. Asn-tRNA or Gln-tRNA formation in most prokaryotes requires amidation of Asp-tRNA or Glu-tRNA by amidotransferases that couple an amidase or an asparaginase to liberate ammonia with a tRNA-dependent kinase. Both archaeal and eukaryotic Sec-tRNA biosynthesis and Cys-tRNA synthesis in methanogens require O-phosophoseryl-tRNA formation. For tRNA-dependent Cys biosynthesis, O-phosphoseryl-tRNA synthetase directly attaches the amino acid to the tRNA which is then converted to Cys by Sep-tRNA: Cys-tRNA synthase. In Sec-tRNA synthesis, O-phosphoseryl-tRNA kinase phosphorylates Ser-tRNA to form the intermediate which is then modified to Sec-tRNA by Sep-tRNA:Sec-tRNA synthase. Complex formation between enzymes in the same pathway may protect the fidelity of protein synthesis. How these tRNA-dependent amino acid biosynthetic routes are integrated into overall metabolism may explain why they are still retained in so many organisms.     

Kinetic mechanism of arginyl-tRNA synthetase from human placenta

Like arginyl-tRNA synthetases from other organisms, human placental arginyl-tRNA synthetase catalyzes the arginine-dependent ATP-PPi exchange reaction only in the presence of tRNA. We have investigated the order of substrate addition and product release of this human enzyme in the tRNA aminoacylation reaction by using initial velocity experiments and dead-end product inhibition studies. The kinetic patterns obtained are consistent with a random Ter Ter sequential mechanism, instead of the common Bi Uni Uni Bi ping-pong mechanism for all other human aminoacyl-tRNA synthetases so far investigated in this respect.     

Solvation change and ion release during aminoacylation by aminoacyl-tRNA synthetases

Discrimination between cognate and non-cognate tRNAs by aminoacyl-tRNA synthetases occurs at several steps of the aminoacylation pathway. We have measured changes of solvation and counter-ion distribution at various steps of the aminoacylation pathway of glutamyl- and glutaminyl-tRNA synthetases. The decrease in the association constant with increasing KCl concentration is relatively small for cognate tRNA binding when compared to known DNA–protein interactions. The electro-neutral nature of the tRNA binding domain may be largely responsible for this low ion release stoichiometry, suggesting that a relatively large electrostatic component of the DNA–protein interaction free energy may have evolved for other purposes, such as, target search. Little change in solvation upon tRNA binding is seen. Non-cognate tRNA binding actually increases with increasing KCl concentration indicating that charge repulsion may be a significant component of binding free energy. Thus, electrostatic interactions may have been used to discriminate between cognate and non-cognate tRNAs in the binding step. The catalytic constant of glutaminyl-tRNA synthetase increases with increasing osmotic pressure indicating a water release of 8.4 ± 1.4 mol/mol in the transition state, whereas little change is seen in the case of glutamyl-tRNA synthetase. We propose that the significant amount of water release in the transition state, in the case of glutaminyl-tRNA synthetase, is due to additional contact of the protein with the tRNA in the transition state.     

Role for a conserved structural motif in assembly of a class I aminoacyl-tRNA synthetase active site

The catalytic domains of class I aminoacyl-tRNA synthetases are built around a conserved Rossmann nucleotide binding fold, with additional polypeptide domains responsible for tRNA binding or hydrolytic editing of misacylated substrates. Structural comparisons identified a conserved motif bridging the catalytic and anticodon binding domains of class Ia and Ib enzymes. This stem contact fold (SCF) has been proposed to globally orient each enzyme's cognate tRNA by interacting with the inner corner of the L-shaped tRNA. Despite the structural similarity of the SCF among class Ia/Ib enzymes, the sequence conservation is low. We replaced amino acids of the MetRS SCF with portions of the structurally similar glutaminyl-tRNA synthetase (GlnRS) motif or with alanine residues. Chimeric variants retained significant tRNA methionylation activity, indicating that structural integrity of the helix-turn-strand-helix motif contributes more to tRNA aminoacylation than does amino acid identity. In contrast, chimeras were significantly reduced in methionyl adenylate synthesis, suggesting a role for the SCF in formation of a structured active site domain. A highly conserved aspartic acid within the MetRS SCF is proposed to make an electrostatic interaction with an active site lysine; these residues were replaced with alanines or conservative substitutions. Both methionyl adenylate formation and methionine transfer were impaired, and activity was not significantly recovered by making the compensatory double substitution.     

Partitioning of tRNA-dependent Editing between Pre- and Post-transfer Pathways in Class I Aminoacyl-tRNA Synthetases

Hydrolytic editing activities are present in aminoacyl-tRNA synthetases possessing reduced amino acid discrimination in the synthetic reactions. Post-transfer hydrolysis of misacylated tRNA in class I editing enzymes occurs in a spatially separate domain inserted into the catalytic Rossmann fold, but the location and mechanisms of pre-transfer hydrolysis of misactivated amino acids have been uncertain. Here, we use novel kinetic approaches to distinguish among three models for pre-transfer editing by Escherichia coli isoleucyl-tRNA synthetase (IleRS). We demonstrate that tRNA-dependent hydrolysis of noncognate valyl-adenylate by IleRS is largely insensitive to mutations in the editing domain of the enzyme and that noncatalytic hydrolysis after release is too slow to account for the observed rate of clearing. Measurements of the microscopic rate constants for amino acid transfer to tRNA in IleRS and the related valyl-tRNA synthetase (ValRS) further suggest that pre-transfer editing in IleRS is an enzyme-catalyzed activity residing in the synthetic active site. In this model, the balance between pre-transfer and post-transfer editing pathways is controlled by kinetic partitioning of the noncognate aminoacyl-adenylate. Rate constants for hydrolysis and transfer of a noncognate intermediate are roughly equal in IleRS, whereas in ValRS transfer to tRNA is 200-fold faster than hydrolysis. In consequence, editing by ValRS occurs nearly exclusively by post-transfer hydrolysis in the editing domain, whereas in IleRS both pre- and post-transfer editing are important. In both enzymes, the rates of amino acid transfer to tRNA are similar for cognate and noncognate aminoacyl-adenylates, providing a significant contrast with editing DNA polymerases.     

Crystal structure of glutamyl-queuosine tRNAAsp synthetase complexed with L-glutamate: structural elements mediating tRNA-independent activation of glutamate and glutamylation of tRNAAsp anticodon

Glutamyl-queuosine tRNA^Asp synthetase (Glu-Q-RS) from Escherichia coli is a paralog of the catalytic core of glutamyl-tRNA synthetase (GluRS) that catalyzes glutamylation of queuosine in the wobble position of tRNA^Asp. Despite important structural similarities, Glu-Q-RS and GluRS diverge strongly by their functional properties. The only feature common to both enzymes consists in the activation of Glu to form Glu-AMP, the intermediate of transfer RNA (tRNA) aminoacylation. However, both enzymes differ by the mechanism of selection of the cognate amino acid and by the mechanism of its activation. Whereas GluRS selects l-Glu and activates it only in the presence of the cognate tRNA^Glu, Glu-Q-RS forms Glu-AMP in the absence of tRNA. Moreover, while GluRS transfers the activated Glu to the 3′ accepting end of the cognate tRNA^Glu, Glu-Q-RS transfers the activated Glu to Q34 located in the anticodon loop of the noncognate tRNA^Asp. In order to gain insight into the structural elements leading to distinct mechanisms of amino acid activation, we solved the three-dimensional structure of Glu-Q-RS complexed to Glu and compared it to the structure of the GluRS·Glu complex. Comparison of the catalytic site of Glu-Q-RS with that of GluRS, combined with binding experiments of amino acids, shows that a restricted number of residues determine distinct catalytic properties of amino acid recognition and activation by the two enzymes. Furthermore, to explore the structural basis of the distinct aminoacylation properties of the two enzymes and to understand why Glu-Q-RS glutamylates only tRNA^Asp among the tRNAs possessing queuosine in position 34, we performed a tRNA mutational analysis to search for the elements of tRNA^Asp that determine recognition by Glu-Q-RS. The analyses made on tRNA^Asp and tRNA^Asn show that the presence of a C in position 38 is crucial for glutamylation of Q34. The results are discussed in the context of the evolution and adaptation of the tRNA glutamylation system.     

Engineering of an Orthogonal Aminoacyl-tRNA Synthetase for Efficient Incorporation of the Non-natural Amino Acid O-Methyl-L-tyrosine using Fluorescence-based Bacterial Cell Sorting

We describe a strategy for the rapid selection of mutant aminoacyl-tRNA synthetases (aaRS) with specificity for a novel amino acid based on fluorescence-activated cell sorting of transformed Escherichia coli using as reporter the enhanced green fluorescent protein (eGFP) whose gene carries an amber stop codon (TAG) at a permissive site upstream of the fluorophore. To this end, a one-plasmid expression system was developed encoding an inducible modified Methanocaldococcus jannaschii (Mj) tyrosyl-tRNA synthetase, the orthogonal cognate suppressor tRNA, and eGFP_UAG in an individually regulatable fashion. Using this system a previously described aaRS with specificity for O-methyl-L-tyrosine (MeTyr) was engineered for 10-fold improved incorporation of the foreign amino acid by selection from a mutant library, prepared by error-prone as well as focused random mutagenesis, for MeTyr-dependent eGFP fluorescence. Applying alternating cycles of positive and negative fluorescence-activated bacterial cell sorting in the presence or in the absence, respectively, of the foreign amino acid was crucial to select for high specificity of MeTyr incorporation. The optimized synthetase was used for the preparative expression of a modified uvGFP carrying MeTyr at position 66 as part of its fluorophore. This biosynthetic protein showed quantitative incorporation of the non-natural amino acid, as determined by mass spectrometry, and it revealed a unique emission spectrum due to the altered chemical structure of its fluorophore. Our combined genetic/selection system offers advantages over earlier approaches that relied wholly or in part on antibiotic selection schemes, and it should be generally useful for the engineering and optimization of orthogonal aaRS/tRNA pairs to incorporate non-natural amino acids into recombinant proteins.     

Determinants in tRNA for activation of arginyl-tRNA synthetase: evidence that tRNA flexibility is required for the induced-fit mechanism

Arginyl-tRNA synthetase (ArgRS) catalyzes formation of arginyl-adenylate in a tRNA-dependent reaction. Previous studies have revealed that conformational changes occur upon tRNA binding. In this study, we analyzed the sequence and structural features of tRNA that are essential to activate the catalytic center of mammalian arginyl-tRNA synthetase. Here, tRNA variants with different activator potential are presented. The three regions that are crucial for activation of ArgRS are the terminal adenosine, the D-loop, and the anticodon stem-loop of tRNA. The Add-1 N-terminal domain of ArgRS, which has the very unique property among aminoacyl-tRNA synthetases to interact with the D-loop in the corner of the convex side of tRNA, has an essential role in anchoring tRNA and participating in tRNA-induced amino acid activation. The results suggest that locking the acceptor extremity, the anticodon loop, and the D-loop of tRNA on the catalytic, anticodon-binding, and Add-1 domains of ArgRS also requires some flexibility of the tRNA molecule, provided by G:U base pairs, to achieve the productive conformation of the active site of the enzyme by induced fit.