Arginyl-tRNA synthetase from baker's yeast. Purification and some properties

Elucidating the structure-function attributes of a trypanosomal arginyl-tRNA synthetase

Aminoacyl-tRNA synthetases (aaRSs) are fundamental components of the protein translation machinery. In light of their pivotal role in protein synthesis and structural divergence among species, they have always been considered potential targets for the development of antimicrobial compounds. Arginyl-tRNA synthetase from Trypanosoma cruzi (TcArgRS), the parasite responsible for causing Chagas Disease, contains a 100-amino acid insertion that was found to be completely absent in the human counterpart of similar length, as ascertained from multiple sequence alignment results. Thus, we were prompted to perform a preliminary characterization of TcArgRS using biophysical, biochemical, and bioinformatics tools. We expressed the protein in E. coli and validated its in-vitro enzymatic activity. Additionally, analysis of DTNB kinetics, Circular dichroism (CD) spectra, and ligand-binding studies using intrinsic tryptophan fluorescence measurements aided us to understand some structural features in the absence of available crystal structures. Our study indicates that TcArgRS can discriminate between L-arginine and its analogues. Among the many tested substrates, only L-canavanine and L-thioarginine, a synthetic arginine analogue exhibited notable activation. The binding of various substrates was also determined using in silico methods. This study may provide a viable foundation for studying small compounds that can be targeted against TcArgRS.

MIST, a Novel Approach to Reveal Hidden Substrate Specificity in Aminoacyl-tRNA Synthetases

Aminoacyl-tRNA synthetases (AARSs) constitute a family of RNA-binding proteins, that participate in the translation of the genetic code, by covalently linking amino acids to appropriate tRNAs. Due to their fundamental importance for cell life, AARSs are likely to be one of the most ancient families of enzymes and have therefore been characterized extensively. Paradoxically, little is known about their capacity to discriminate tRNAs mainly because of the practical challenges that represent precise and systematic tRNA identification. This work describes a new technical and conceptual approach named MIST (Microarray Identification of Shifted tRNAs) designed to study the formation of tRNA/AARS complexes independently from the aminoacylation reaction. MIST combines electrophoretic mobility shift assays with microarray analyses. Although MIST is a non-cellular assay, it fully integrates the notion of tRNA competition. In this study we focus on yeast cytoplasmic Arginyl-tRNA synthetase (yArgRS) and investigate in depth its ability to discriminate cellular tRNAs. We report that yArgRS in submicromolar concentrations binds cognate and non-cognate tRNAs with a wide range of apparent affinities. In particular, we demonstrate that yArgRS binds preferentially to type II tRNAs but does not support their misaminoacylation. Our results reveal important new trends in tRNA/AARS complex formation and potential deep physiological implications.

Modeling of tRNA-assisted mechanism of Arg activation based on a structure of Arg-tRNA synthetase, tRNA, and an ATP analog (ANP)

The ATP-pyrophosphate exchange reaction catalyzed by Arg-tRNA, Gln-tRNA and Glu-tRNA synthetases requires the assistance of the cognate tRNA. tRNA also assists Arg-tRNA synthetase in catalyzing the pyrophosphorolysis of synthetic Arg-AMP at low pH. The mechanism by which the 3'-end A76, and in particular its hydroxyl group, of the cognate tRNA is involved with the exchange reaction catalyzed by those enzymes has yet to be established. We determined a crystal structure of a complex of Arg-tRNA synthetase from Pyrococcus horikoshii, tRNA(Arg)(CCU) and an ATP analog with Rfactor = 0.213 (Rfree = 0.253) at 2.0 A resolution. On the basis of newly obtained structural information about the position of ATP bound on the enzyme, we constructed a structural model for a mechanism in which the formation of a hydrogen bond between the 2'-OH group of A76 of tRNA and the carboxyl group of Arg induces both formation of Arg-AMP (Arg + ATP --> Arg-AMP + pyrophosphate) and pyrophosphorolysis of Arg-AMP (Arg-AMP + pyrophosphate --> Arg + ATP) at low pH. Furthermore, we obtained a structural model of the molecular mechanism for the Arg-tRNA synthetase-catalyzed deacylation of Arg-tRNA (Arg-tRNA + AMP --> Arg-AMP + tRNA at high pH), in which the deacylation of aminoacyl-tRNA bound on Arg-tRNA synthetase and Glu-tRNA synthetase is catalyzed by a quite similar mechanism, whereby the proton-donating group (-NH-C+(NH2)2 or -COOH) of Arg and Glu assists the aminoacyl transfer from the 2'-OH group of tRNA to the phosphate group of AMP at high pH.

Human tryptophanyl-tRNA synthetase is switched to a tRNA-dependent mode for tryptophan activation by mutations at V85 and I311

For most aminoacyl-tRNA synthetases (aaRS), their cognate tRNA is not obligatory to catalyze amino acid activation, with the exception of four class I (aaRS): arginyl-tRNA synthetase, glutamyl-tRNA synthetase, glutaminyl-tRNA synthetase and class I lysyl-tRNA synthetase. Furthermore, for arginyl-, glutamyl- and glutaminyl-tRNA synthetase, the integrated 3' end of the tRNA is necessary to activate the ATP-PPi exchange reaction. Tryptophanyl-tRNA synthetase is a class I aaRS that catalyzes tryptophan activation in the absence of its cognate tRNA. Here we describe mutations located at the appended β1–β2 hairpin and the AIDQ sequence of human tryptophanyl-tRNA synthetase that switch this enzyme to a tRNA-dependent mode in the tryptophan activation step. For some mutant enzymes, ATP-PPi exchange activity was completely lacking in the absence of tRNA^Trp, which could be partially rescued by adding tRNA^Trp, even if it had been oxidized by sodium periodate. Therefore, these mutant enzymes have strong similarity to arginyl-tRNA synthetase, glutaminyl-tRNA synthetase and glutamyl-tRNA synthetase in their mode of amino acid activation. The results suggest that an aaRS that does not normally require tRNA for amino acid activation can be switched to a tRNA-dependent mode.

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.

Limited set of amino acid residues in a class Ia aminoacyl-tRNA synthetase is crucial for tRNA binding

The aim of this work was to characterize crucial amino acids for the aminoacylation of tRNA(Arg) by yeast arginyl-tRNA synthetase. Alanine mutagenesis was used to probe all the side chain mediated interactions that occur between tRNA(Arg2)(ICG) and ArgRS. The effects of the substitutions were analyzed in vivo in an ArgRS-knockout strain and in vitro by measuring the aminoacylation efficiencies for two distinct tRNA(Arg) isoacceptors. Nine mutants that generate lethal phenotypes were identified, suggesting that only a limited set of side chain mediated interactions is essential for tRNA recognition. The majority of the lethal mutants was mapped to the anticodon binding domain of ArgRS, a helix bundle that is characteristic for class Ia synthetases. The alanine mutations induce drastic decreases in the tRNA charging rates, which is correlated with a loss in affinity in the catalytic site for ATP. One of those lethal mutations corresponds to an Arg residue that is strictly conserved in all class Ia synthetases. In the known crystallographic structures of complexes of tRNAs and class Ia synthetases, this invariant Arg residue stabilizes the idiosyncratic conformation of the anticodon loop. This paper also highlights the crucial role of the tRNA and enzyme plasticity upon binding. Divalent ions are also shown to contribute to the induced fit process as they may stabilize the local tRNA-enzyme interface. Furthermore, one lethal phenotype can be reverted in the presence of high Mg(2+) concentrations. In contrast with the bacterial system, in yeast arginyl-tRNA synthetase, no lethal mutation has been found in the ArgRS specific domain recognizing the Dhu-loop of the tRNA(Arg). Mutations in this domain have no effects on tRNA(Arg) aminoacylation, thus confirming that Saccharomyces cerevisiae and other fungi belong to a distinct class of ArgRS.

Leucyl-tRNA synthetase consisting of two subunits from hyperthermophilic bacteria Aquifex aeolicus

In a hyperthermophilic bacterium, Aquifex aeolicus, leucyl-tRNA synthetase (LeuRS) consists of two non-identical polypeptide subunits (alpha and beta), different from the canonical LeuRS, which has a single polypeptide chain. By PCR, using genome DNA of A. aeolicus as a template, genes encoding the alpha and beta subunits were amplified and cloned in Escherichia coli. The alpha subunit could not be expressed stably in vivo, whereas the beta subunit was overproduced and purified by a simple procedure. The beta subunit was inactive in catalysis but was able to bind tRNA(Leu). Interestingly, the heterodimer alphabeta-LeuRS could be overproduced in E. coli cells containing both genes and was purified to 95% homogeneity as a hybrid dimer. The kinetics of A. aeolicus LeuRS in pre-steady and steady states and cross-recognition of LeuRS and tRNA(Leu) from A. aeolicus and E. coli were studied. Magnesium concentration, pH value, and temperature aminoacylation optima were determined to be 12 mm, 7.8, and 70 degrees C, respectively. Under optimal conditions, A. aeolicus alphabeta-LeuRS is stable up to 65 degrees C.

A highly conserved mechanism of regulated ribosome stalling mediated by fungal arginine attenuator peptides that appears independent of the charging status of arginyl-tRNAs

The Arg attenuator peptide (AAP) is an evolutionarily conserved peptide involved in Arg-specific negative translational control. It is encoded as an upstream open reading frame (uORF) in fungal mRNAs specifying the small subunit of Arg-specific carbamoyl phosphate synthetase. We examined the functions of the Saccharomyces cerevisiae CPA1 and Neurospora crassa arg-2 AAPs using translation extracts from S. cerevisiae, N. crassa, and wheat germ. Synthetic RNA containing AAP and firefly luciferase (LUC) sequences were used to program translation; analyses of LUC activity indicated that the AAPs conferred Arg-specific negative regulation in each system. The AAPs functioned either as uORFs or fused in-frame at the N terminus of LUC. Mutant AAPs lacking function in vivo did not function in vitro. Therefore, trans-acting factors conferring AAP-mediated regulation are in both fungal and plant systems. Analyses of ribosome stalling in the fungal extracts by primer extension inhibition (toeprint) assays showed that these AAPs acted similarly to stall ribosomes in the region immediately distal to the AAP coding region in response to Arg. The regulatory effect increased as the Arg concentration increased; all of the arginyl-tRNAs examined appeared maximally charged at low Arg concentrations. Therefore, AAP-mediated Arg-specific regulation appeared independent of the charging status of arginyl-tRNA.

Transfer RNA identity rules and conformation of the tyrosine tRNA-like domain of BMV RNA imply additional charging by histidine and valine

This paper reports the first example of a triple aminoacylation specificity of a viral tRNA-like domain. These findings were based on structural studies on the brome mosaic virus (BMV) tRNA-like domain (Felden et al., 1994, J. Mol. Biol. 235, 508-531) together with knowledge on tRNA aminoacylation identity rules suggesting potential histidinylation and valylation capacities of the viral RNA in addition to its already known tyrosylation ability. Here, both predictions are demonstrated by in vitro aminoacylation assays. Kinetic parameters of histidinylation and valylation of BMV tRNA-like structure have been determined and compared to those of the corresponding tRNA transcripts and to the tyrosylation capacity of the molecule. The influence of experimental conditions on aminoacylation reactions was also studied. The novel aminoacylation capacities of BMV tRNA-like domain support its already reported three-dimensional fold and illustrate the predictive potential of modeling data. Biological necessity of specific or non specific aminoacylation will be discussed.

Mirror image alternative interaction patterns of the same tRNA with either class I arginyl-tRNA synthetase or class II aspartyl-tRNA synthetase

Gene cloning, overproduction and an efficient purification protocol of yeast arginyl-tRNA synthetase (ArgRS) as well as the interaction patterns of this protein with cognate tRNAArgand non-cognate tRNAAspare described. This work was motivated by the fact that the in vitro transcript of tRNAAspis of dual aminoacylation specificity and is not only aspartylated but also efficiently arginylated. The crystal structure of the complex between class II aspartyl-tRNA synthetase (AspRS) and tRNAAsp, as well as early biochemical data, have shown that tRNAAspis recognized by its variable region side. Here we show by footprinting with enzymatic and chemical probes that transcribed tRNAAspis contacted by class I ArgRS along the opposite D arm side, as is homologous tRNAArg, but with idiosyncratic interaction patterns. Besides protection, footprints also show enhanced accessibility of the tRNAs to the structural probes, indicative of conformational changes in the complexed tRNAs. These different patterns are interpreted in relation to the alternative arginine identity sets found in the anticodon loops of tRNAArgand tRNAAsp. The mirror image alternative interaction patterns of unmodified tRNAAspwith either class I ArgRS or class II AspRS, accounting for the dual identity of this tRNA, are discussed in relation to the class defining features of the synthetases. This study indicates that complex formation between unmodified tRNAAspand either ArgRS and AspRS is solely governed by the proteins.

Cysteinyl-tRNA synthetase from Saccharomyces cerevisiae. Purification, characterization and assignment to the genomic sequence YNL247w

Cysteinyl-tRNA synthetase (CRS) from Saccharomyces cerevisiae was purified 2300-fold with a yield of 33%, to a high specific activity (kcat4.3 s-1 at 25 degrees C for the aminoacylation of yeast tRNACys). SDS-PAGE revealed a single polypeptide corresponding to a molecular mass of 86 kDa. Polyclonal antibodies to the purified protein inactivated CRS activity and detected only one polypeptide of 86 kDa in a yeast extract subjected to SDS-PAGE followed by immunoblotting. In contrast to bacterial CRS which is a monomer of about 50 kDa, the native yeast enzyme behaved as a dimer, as assessed by gel filtration and cross-linking. Its subunit molecular mass is in good agreement with the value of 87.5 kDa calculated for the protein encoded by the yeast genomic sequence YNL247w. The latter was previously tentatively assigned to CRS, based on limited sequence similarities to the corresponding enzyme from other sources. Determination of the amino acid sequence of internal polypeptides derived from the purified yeast enzyme confirmed this assignment. Alignment of the primary sequences of prokaryotic and yeast CRS reveals that the larger size of the latter is accounted for mostly by several insertions within the sequence.

Crystallization and preliminary X-ray diffraction analysis of arginyl-tRNA synthetase from Escherichia coli

Arginyl-tRNA Synthetase, a class I aminoacyl tRNA synthetase playing a crucial role in protein biosynthesis, has been crystallized for the first time. Polyethylene glycol (PEG) was used as a precipitant, and the crystallization proceeded at pH 6.5. These single crystals diffracted to 2.8 A with a rotating anode X-ray source and R-axis IIc image plate detector. They have an orthorhombic space group P2(1)2(1)2 with unit cell parameters of a = 251.51 A, b = 53.12 A, and c = 52.35 A. A complete native data set has been collected at 3.1 A resolution for these crystals.

Binding of the yeast tRNA(Met) anticodon by the cognate methionyl-tRNA synthetase involves at least two independent peptide regions

As for Escherichia coli methionine tRNAs, the anticodon triplet of yeast tRNA(Met) plays an important role in the recognition by the yeast methionyl-tRNA synthetase (MetRS), indicating that this determinant for methionine identity is conserved in yeast. Efficient aminoacylation of the E. coli tRNA(Met) transcript by the heterologous yeast methionine enzyme also suggests conservation of the protein determinants that interact with the CAU anticodon sequence. We have analysed by site-directed mutagenesis the peptide region 655 to 663 of the yeast MetRS that is equivalent to the anticodon binding region of the E. coli methionine enzyme. Only one change, converting Leu658 into Ala significantly reduced tRNA aminoacylation. Semi-conservative substitutions of L658 allow a correlation to be drawn between side-chain volume of the hydrophobic residue at this site and activity. The analysis of the L658A mutant shows that Km is mainly affected. This suggests that the peptide region 655 to 663 contributes partially to the binding of the anticodon, since separate mutational analysis of the anticodon bases shows that kcat is the most critical parameter in the recognition of tRNA(Met) by the yeast synthetase. We have analysed the role of peptide region (583-GNLVNR-588) that is spatially close to the region 655 to 663. Replacements of residues N584 and R588 reduces significantly the kcat of aminoacylation. The peptide region 583-GNLVNR-588 is highly conserved in all MetRS so far sequenced. We therefore propose that the hydrogen donor/acceptor amino acid residues within this region are the most critical protein determinants for the positive selection of the methionine tRNAs.

Efficient mischarging of a viral tRNA-like structure and aminoacylation of a minihelix containing a pseudoknot: histidinylation of turnip yellow mosaic virus RNA

Mischarging of the valine specific tRNA-like structure of turnip yellow mosaic virus (TYMV) RNA has been tested in the presence of purified arginyl-, aspartyl-, histidinyl-, and phenylalanyl-tRNA synthetases from bakers' yeast. Important mischarging of a 264 nucleotide-long transcript was found with histidinyl-tRNA synthetase which can acylate this fragment up to a level of 25% with a loss of specificity (expressed as Vmax/KM ratios) of only 100 fold as compared to a yeast tRNA(His) transcript. Experiments on transcripts of various lengths indicate that the minimal valylatable fragment (n = 88) is the most efficient substrate for histidinyl-tRNA synthetase, with kinetic characteristics similar to those found for the control tRNA(His) transcript. Mutations in the anticodon or adjacent to the 3' CCA that severely affect the valylation capacity of the 264 nucleotide long TYMV fragment are without negative effect on its mischarging, and for some cases even improve its efficiency. A short fragment (n = 42) of the viral RNA containing the pseudoknot and corresponding to the amino acid accepting branch of the molecule is an efficient histidine acceptor.

Efficient aminoacylation of a yeast tRNA(Asp) transcript with a 5' extension

A yeast aspartic acid tRNA with a 5' extension of 14 nucleotides was obtained by in vitro transcription with T7 DNA dependent RNA polymerase. This transcript, called extended tRNA(Asp) transcript, retains its aspartylation capacity with the same Km and only three times reduced kcat values as compared to those measured for canonical tRNA(Asp). This result indicates that the 5' extension of the amino acid acceptor stem of tRNA(Asp) does not interfere with recognition by aspartyl-tRNA synthetase. However, in contrast to the wild-type tRNA(Asp) transcript, the 5' extended molecule presents a reduced capacity to be mischarged by arginyl-tRNA synthetase, suggesting the existence of different structural requirements in aspartyl- and arginyl-tRNA synthetases for tRNA(Asp) recognition.

Relaxation of a transfer RNA specificity by removal of modified nucleotides

The molecular recognition of specific transfer RNAs by the appropriate aminoacyl-tRNA synthetase is an important step in determining the accuracy of translation of the genetic message from nucleic acids into proteins. Recent studies using variant tRNAs with specific sequence modifications have indicated particular regions that determine their identity. Here we consider whether the base modifications commonly found in tRNAs contribute to their identity. Although unmodified tRNA(Asp) is charged with aspartate as efficiently as the modified native tRNA, it is mischarged with arginine with considerably increased efficiency. Our results indicate that post-transcriptional modification of tRNAs introduces structural 'anti-determinants', restricting the efficiency with which the tRNAs are charged with inappropriate amino acids.

Arginyl-tRNA synthetase from yeast. Discrimination between 20 amino acids in aminoacylation of tRNA(Arg)-C-C-A and tRNA(Arg)-C-C-A(3'NH2)

For discrimination between arginine and 19 other amino acids in aminoacylation of tRNA(Arg)-C-C-A by arginyl-tRNA synthetase from baker's yeast, discrimination factors (D) have been determined from kcat and Km values. The lowest values were found for Trp, Cys, Lys (D = 800-8500), showing that arginine is 800-8500 times more often incorporated into tRNA(Arg)-C-C-A than noncognate acids at the same amino acid concentrations. The other noncognate amino acids exhibit D values between 10,000 and 60,000. In aminoacylation of tRNA(Arg)-C-C-A(3'NH2) discrimination factors D1 are in the range 10-600. From these values and AMP formation stoichiometry, pretransfer proof-reading factors II1 were determined; from D values and AMP stoichiometry in aminoacylation of tRNA(Arg)-C-C-A, posttransfer proof-reading factors II2 could be calculated, II1 values between 2 and 120 show that pretransfer proof-reading is the main correction step, posttransfer proof-reading (II2 approximately 1-10) plays a marginal role. Initial discrimination factors due to different Gibbs free energies of binding between arginine and the noncognate amino acids were calculated from discrimination and proof-reading factors. According to a two-step binding process, two factors (I1 and I2) were determined. They can be related to hydrophobic interaction forces and hydrogen bonds that are especially formed by the arginine side chain. A hypothetical 'stopper' model of the amino acid recognition site is discussed.

Arginyl-tRNA synthetase from Escherichia coli, purification by affinity chromatography, properties, and steady-state kinetics

A Blue Sephadex G-150 affinity column adsorbs the arginyl-tRNA synthetase of Escherichia coli K12 and purifies it with high efficiency. The relatively low enzyme content was conveniently purified by DEAE-cellulose chromatography, affinity chromatography, and fast protein liquid chromatography to a preparation with high activity capable of catalyzing the esterification of about 23,000 nmol of arginine to the cognate tRNA per milligram of enzyme within 1 min, at 37 degrees C, pH 7.4. The turnover number is about 27 s-1. The purification was about 1200-fold, and the overall yield was more than 30%. The enzyme has a single polypeptide chain of about Mr 70,000 and binds arginine and tRNA with 1:1 stoichiometry. For the aminoacylation reaction, the Km values at pH 7.4, 37 degrees C, for various substrates were determined: 12 microM, 0.9 mM, and 2.5 microM for arginine, ATP, and tRNA, respectively. The Km value for cognate tRNA is higher than those of most of the aminoacyl-tRNA synthetase systems so far reported. The ATP-PPi exchange reaction proceeds only in the presence of arginine-specific tRNA. The Km values of the exchange at pH 7.2, 37 degrees C, are 0.11 mM, 2.9 mM, and 0.5 mM for arginine, ATP, and PPi, respectively, with a turnover number of 40 s-1. The pH dependence shows that the reaction is favored toward slightly acidic conditions where the aminoacylation is relatively depressed.

Aminoacyl-tRNA synthetases catalyze AMP----ADP----ATP exchange reactions, indicating labile covalent enzyme-amino-acid intermediates

Aminoacyl-tRNA synthetases (amino acid-tRNA ligases, EC 6.1.1.-) catalyze the aminoacylation of specific amino acids onto their cognate tRNAs with extraordinary accuracy. Recent reports, however, indicate that this class of enzymes may play other roles in cellular metabolism. Several aminoacyl-tRNA synthetases are herein shown to catalyze the AMP----ADP and ADP----ATP exchange reactions (in the absence of tRNAs) by utilizing a transfer of the gamma-phosphate of ATP to reactive AMP and ADP intermediates that are probably the mixed anhydrides of the nucleotide and the corresponding amino acid. AMP and ADP produce active intermediates with amino acids by entering the back-reaction of amino acid activation, reacting with labile covalent amino acid-enzyme intermediates. Gramicidin synthetases 1 and 2, which are known to activate certain amino acids through the formation of intermediate thiol-esters of the amino acids and the enzymes, catalyze the same set of reactions with similar characteristics. Several lines of evidence suggest that these activities are an inherent part of the enzymatic reactions catalyzed by the aminoacyl-tRNA synthetases and gramicidin synthetases and are not due to impurities of adenylate kinase, NDP kinase, or low levels of tRNAs bound to the enzymes. The covalent amino acid-enzyme adducts are likely intermediates in the aminoacylation of their cognate tRNAs. The use of gramicidin synthetases has thus helped to illuminate mechanistic details of amino acid activation catalyzed by the aminoacyl-tRNA synthetases.

Inhibition of aminoacyl-tRNA synthetases by the mycotoxin patulin

The effect of patulin on tRNA aminoacylation has been determined. This mycotoxin inhibits the aminoacylation process by irreversibly inactivating aminoacyl-tRNA synthetases. At neutral and alkaline pH-values, the inactivation occurs mainly by modification of essential thiol groups of the protein, whereas at acidic pH, where the effect is the most pronounced, the modification of other amino acid residues cannot be excluded.

Large scale purification and structural properties of yeast aspartyl-tRNA synthetase

A large scale purification procedure of baker's yeast aspartyl-tRNA synthetase is described which yields more than 200 mg pure protein starting from 30 Kg of wet commercial cells. The synthetase is an alpha 2 dimer of Mr = 125,000 +/- 5,000 which can be crystallized (J. Mol. Biol. 138, 1980, 129-135). The enzyme has an elongated shape with a Stokes radius of 50 A and a frictional ratio of 1.5. The synthetase has a tendency to aggregate but methods are described where this effect is overcome.

Isoelectric focusing and isoelectric points of aminoacyl-tRNA synthetases

Isoelectric points and isoelectric focusing behaviour of 10 highly purified eukaryotic aminoacyl-tRNA synthetases from 3 sources, Saccharomyces cerevisiae, Euglena gracilis and Phaseolus vulgaris were examined. The pI-values measured on polyacrylamide gels under native conditions are situated between pH 5.0-7.5. A microheterogeneity was observed for 9 enzymes appearing otherwise homogeneous on gel electrophoresis. A compilation of the isoelectric points of aminoacyl-tRNA synthetases is given and literature data are compared with our experimental results.

Multienzyme complexes of eukaryotic aminoacyl-tRNA synthetases

Eukaryotic aminoacyl-tRNA synthetases, unlike their prokaryotic counterparts, may occur as high-Mr multienzyme complexes. Recently, successful purification of synthetase complexes makes possible the elucidation of the structural organization of these high-Mr complexes. Although their physiological significance remains unknown, recent studies suggest some possible functional roles for these complexes.

Enrichment and characterization of the mRNAs of four aminoacyl-tRNA synthetases from yeast

We have partially purified the messenger RNAs for yeast arginyl-, aspartyl-, valyl-, alpha and beta subunits of phenylalanyl-tRNA synthetases in order to study their biosynthesis and ultimately, to isolate their genes. Sucrose gradient fractionation of poly U-Sepharose selected mRNAs resulted in a ten fold enrichment of the in vitro translation activity of these mRNAs. The translation products of messenger RNAs for arginyl- and valyl-tRNA synthetases have the same molecular weight as the purified enzymes; translation of aspartyl-tRNA synthetase messenger RNA yielded a 68 kD molecular weight polypeptide (while the purified cristallisable enzyme appears as a 64-66 kD doublet, which, as we showed is a proteolysis product). The translation of the mRNAs for alpha and beta phenylalanyl-tRNA synthetase gave polypeptides having the same molecular weight as those obtained from the purified enzyme, but the major translation products are slightly heavier, indicating that they may be translated as precursors. As estimated from centrifugation experiments mRNAs of arginyl-, aspartyl-, alpha and beta subunits of phenylalanyl-tRNA synthetase were 1700-2000 nucleotides long, indicating that alpha and beta are translated from two different mRNAs.

Study of the interaction of yeast arginyl-tRNA synthetase with yeast tRNAArg2 and tRNAArg3 by partial digestions with cobra venom ribonuclease

Yeast tRNAArg2 and tRNAArg3 are two isoacceptors which show similar V and Km for yeast arginyl-tRNA synthetase despite important differences in their primary structures. Fragments resulting from the partial digestion of 3' or 5' end-labelled tRNAArg2 and tRNAArg3 in the presence or absence of arginyl-tRNA synthetase by cobra venom ribonuclease, an enzyme which cuts preferentially in double-stranded regions, were analysed by electrophoresis on polyacrylamide gels. In the absence of arginyl-tRNA synthetase, major cuts were observed in tRNAArg2 and tRNAArg3 at the end of the 3' part of the acceptor stem and in the 5' part of the anticodon stem, whereas the 5' part of the acceptor stem and the 3' part of the anticodon stem are only slightly cleaved. The D and the T stems are almost fully resistant to cobra venom ribonuclease attack confirming the strong tertiary structural organization of this region. In the presence of arginyl-tRNA synthetase the two or three last sites of the 3' halves of the acceptor stems and the sites in the 3' halves of the anticodon stems are almost completely protected against ribonuclease hydrolysis in both tRNAs; 31-69% protection of the sites located in the 5' halves of the anticodon stem is also observed. However, the cleavage levels are enhanced for the three head positions in the 3' halves of the acceptor stems and a new cut appears at the first position of this region in the case of tRNAArg3. The similarity of the protection patterns of tRNAArg2 and tRNAArg3 suggests that both molecules interact in nearly the same manner with arginyl-tRNA synthetase, which in turn implies great similarities in their tertiary structure when involved in the complex. If this tertiary organization is like that described for tRNAPhe, all protected sites are located in the inside of its L-shaped model.

Arginyl-tRNA synthetase from brewer's yeast. Purification, properties, and steady-state mechanism

tRNAArg and arginyl-tRNA synthetase have been purified to homogeneity from brewer's yeast by chromatographic methods. Arginyl-tRNA synthetase is a monomeric enzyme with a molecular weight of 72000. Two active forms of the enzyme can be found, they are interconvertible. The more stable conformation is probably the natural one. Arginyl-tRNA synthetase seems to recognize arginine very specifically. No evidence for any proof-reading mechanism could be found. The steady-state mechanism is somewhat different from the types found with arginyl-tRNA synthetase from other sources. However, all these results are compatible with a concerted reaction. Simultaneously with the release of AMP or pyrophosphate an allosteric rearrangement occurs. This conversion seems to be determining for the reaction mechanism.

The catalytic mechanism of glutamyl-tRNA synthetase of Escherichia coli. A steady-state kinetic investigation

The sequence of substrate binding and of end-product dissociation at the steady state of the catalytic process of tRNAGlu aminoacylation by glutamyl-tRNA synthetase from Escherichia coli has been investigated using bisubstrate kinetics, dead-end and end-product inhibition studies. The nature of the kinetic patterns indicates that ATP and tRNAGlu bind randomly to the free enzyme, whereas glutamate binds only to the ternary enzyme . tRNAGlu . ATP complex. Binding of ATP to the enzyme hinders that of tRNAGlu and vice versa. After interconversion of the quaternary enzyme . substrates complex the end-products dissociate in the following order: PPi first, AMP second and Glu-tRNA last. In addition to its role as substrate and as effector with ATP for the binding of glutamate, tRNAGlu promotes the catalytically active enzyme state. Whereas at saturating tRNAGlu concentration the catalysis is rate-determining, this conformational change can be rate-determining at low tRNAGlu concentrations. The results are discussed in the light of the two-step aminoacylation pathway catalyzed by this synthetase.

Structural studies on aminoacyl-tRNA synthetases. A tentative correlation between the subunit size and the occurrence of repeated sequences

Recent studies have shown that those synthetases with subunits greater than 85,000 daltons contain extensive repeated sequences, whilst those with small subunits (40,000 daltons) do not. We have undertaken a comparative study of four aminoacyl-tRNA synthetases (glutamyl-, arginyl-, valyl-, and phenylalanyl-tRNA synthetases) with subunit sizes ranging from 56,000 to 130,000 daltons in an attempt to correlate the occurrence and extent of the repeats with the length of the polypeptide chain. Our results show that monomeric glutamyl-tRNA synthetase from Escherichia coli (56,000 daltons) contains few repeated sequences, whereas both subunits of yeast phenylalanyl-tRNA synthetase (alpha, 73,000 daltons; beta, 62,000 daltons) and yeast arginyl-tRNA synthetase (74,000 daltons) do have a significant amount of repeats. Thus 56,000 dalton appears to be the minimum size compatible with the existence of such repeats.

Phenylalanyl-tRNA, lysyl-tRNA, isoleucyl-tRNA and arginyl-tRNA synthetases. Substrate specificity in the ATP/PPi exchange with regard to ATP analogs

The analogs of ATP have been tested in the ATP/PPi exchange reaction of phenylalanyl-tRNA, lysyl-tRNA, isoleucyl-tRNA and arginyl-tRNA synthetases from baker's yeast. Three compounds are substrates for phenylalanyl-tRNA, seven for lysyl-tRNA, two for isoleucyl-tRNA and five for arginyl-tRNA synthetase. Their Km and V values have been determined. No analog was an inhibitor. (3'-dATP), 3'-Deoxyadenosine 5'-triphosphate which is an inhibitor of the four enzymes in the aminoacylation reaction, becomes a good substrate in the PPi exchange. Additionally lysyl-tRNA synthetase accepts two analogs with modifications at position 6 of the purine and three analogs modified at the ribose moiety as substrates in the PPi exchange, whereas these compounds are inactive or inhibitors in the aminoacylation reaction. In general the enzymes are less specific in the ATP/PPi exchange and the results indicate a more sophisticated proof of the nucleotide moiety upon aminoacylation. This could occur with the aminoacyladenylate intermediate as well as with any other intermediate.

The glutaminyl-transfer RNA synthetase of Escherichia coli. Purification, structure and function relationship

Glutaminyl-tRNA synthetase from Escherichia coli has been purified to homogeneity with a yield of about 50%. It is a monomer of about 69 000 daltons. Arginyl and glutamyl-tRNA synthetases are also monomeric synthetases of molecular weight significantly lower than 100 000. In addition it is well known that these three synthetases require their cognate tRNA to catalyze the [32P]PPi-ATP exchange. Like arginyl-tRNA synthetase, but unlike glutamyl-tRNA synthetase, glutaminyl-tRNA synthetase seems to contain some repeated sequences. Therefore no correlation can be established between the tRNA requirement of these synthetases for the catalysis of the isotope-exchange and the presence or the absence of sequence duplication. In the native enzyme four sulfhydryl groups react with dithiobisnitrobenzoic acid causing a loss of both the aminoacylation and the [32P]PPi-ATP exchange activities. The rate-limiting steps of the overall aminoacylation and its reverse reaction correspond, respectively, to the catalysis of the aminoacylation of tRNA Gln and of the the deacylation of glutaminyl-tRNA Gln. At acidic pH, glutaminyl-tRNA synthetase catalyzes the synthesis of the glutaminyl-tRNA Gln and its deacylation at significantly lower rates than the [32P]PPi-ATP exchange, indicating than glutaminyl-tRNA Gln cannot be an obligatory intermediate in this isotope exchange. These results suggest the existence of a two-step aminoacylation mechanism catalyzed by this enzyme.

The twenty aminoacyl-tRNA synthetases from Escherichia coli. General separation procedure, and comparison of the influence of pH and divalent cations on their catalytic activities

A general separation procedure of the twenty E. coli aminoacyl-tRNA synthetases including either a 105 000 g centrifugation or a poly-ethyleneglycol-dextran two-phases partition fractionation, and chromatographies on DEAE-cellulose, phosphocellulose and hydroxyapatite is described. The specific activities of the synthetases have been determined after each chromatographic step and compared to their respective activities in the 105 000 g supernatant. Some aminoacyl-tRNA synthetases were obtained at 80 per cent purity. The presence of phenylmethylsulfonyl fluoride does not significantly modify either the elution patterns of the synthetases during the various chromatographic steps or their specific activities. Thus, contrarily to enzymes from various eukaryotic organisms no significant inactivation of the E. coli aminoacyl-tRNA synthetases occurs via proteolytic processes during the purification procedure. The effects of various factors: pH, magnesium, and other bivalent cations including spermidine, were tested on the aminoacylation and the [32P] PPi-ATP isotope-exchange reactions, and the optimal aminoacylation and isotope-exchange conditions determined for 18 of the 20 E. coli aminoacyl-tRNA synthetases.

Glutamyl transfer ribonucleic acid synthetase of Escherichia coli. Study of the interactions with its substrates

The binding of the various substrates to Escherichia coli glutamyl-tRNA synthetase has been investigated by using as experimental approaches the binding study under equilibrium conditions and the substrate-induced protection of the enzyme against its thermal inactivation. The results show that ATP and tRNAGlu bind to the free enzyme, whereas glutamate binds only to an enzyme form to which glutamate-accepting tRNAGlu is associated. By use of modified E. coli tRNAsGlu and heterologous tRNAsGlu, a correlation could be established between the ability of tRNAGlu to be aminoacylated by glutamyl-tRNA synthetase and its abilities to promote the [32P]PPi-ATP isotope exchange and the binding of glutamate to the synthetase. These results give a possible explanation for the inability of blutamyl-tRNA synthetase to catalyze the isotope exchange in the absence of amino acid accepting tRNAGlu and for the failure to detect an enzyme-adenylate complex for this synthetase by using the usual approaches. One binding site was detected for each substrate. The specificity of the interaction of the various substrates has been further investigated. Concerning ATP, inhibition studies of the aminoacylation reaction by various analogues showed the existence of a synergistic effect between the adenine and the ribose residues for the interaction of adenosine. The primary recognition of ATP involves the N-1 and the 6-amino group of adenine as well as the 2'-OH group of ribose. This first interaction is then strengthened by the phosphate groups- Inhibition studies by various analogues of glutamate showed a strong decrease in the affinity of this substrate for the synthetase after substitution of the alpha- or gamma-carboxyl groups. The enzyme exhibits a marked tendency to complex tRNAs of other specificities even in the presence of tRNAGlu. MgCl2 and spermidine favor the specific interactions. The influence of monovalent ions and of pH on the interaction between glutamyl-tRNA synthetase and tRNAGlu is similar to those reported for other synthetases not requiring their cognate tRNA to bind the amino acid. Finally, contrary to that reported for other monomeric synthetases, no dimerization of glutamyl-tRNA synthetase occurs during the catalytic process.

Arginyl-tRNA synthetase from Escherichia coli K12. Purification, properties, and sequence of substrate addition

Arginyl-tRNA synthetase from Escherichia coli K12 has been purified more than 1000-fold with a recovery of 17%. The enzyme consists of a single polypeptide chain of about 60 000 molecular weight and has only one cysteine residue which is essential for enzymatic activity. Transfer ribonucleic acid completely protects the enzyme against inactivation by p-hydroxymercuriben zoate. The enzyme catalyzes the esterification of 5000 nmol of arginine to transfer ribonucleic acid in 1 min/mg of protein at 37 degrees C and pH 7.4. One mole of ATP is consumed for each mole of arginyl-tRNA formed. The sequence of substrate binding has been investigated by using initial velocity experiments and dead-end and product inhibition studies. The kinetic patterns are consistent with a random addition of substrates with all steps in rapid equilibrium except for the interconversion of the cental quaternary complexes. The dissociation constants of the different enzyme-substrate complexes and of the complexes with the dead-end inhibitors homoarginine and 8-azido-ATP have been calculated on this basis. Binding of ATP to the enzyme is influenced by tRNA and vice versa.

Pairing properties of the methylester of 5-carboxymethyl uridine in the wobble position of yeast tRNA3Arg

At optimum magnesium concentration (10 mM) both yeast tRNA1Arg and tRNA3Arg are able to bind to poly (A,G) and A-G-A in presence of Escherichia coli robisomes. With A-G-G only tRNA1Arg ginds, wherea tRNA3Arg (anticodon mcm5 U-C-U) is not bound. This result means that the methylcarboxymethyl substituant in position 5 of U prevents its wobble with G.

Threonyl-tRNA, lysyl-tRNA and arginyl-tRNA synthetases from Baker's yeast. Substrate specificity with regard to ATP analogues

Sixteen analogues of ATP have been tested in the aminoacylation reaction of threonyl-tRNA, lysyl-tRNA, and arginyl-tRNA synthetases from baker's yeast. Two compounds are substrates for threonyl-tRNA and for lysyl-tRNA synthetases and five compounds for arginyl-tRNA synthetase. There are six inhibitors for threonyl-tRNA, nine for lysyl-tRNA, and six for arginyl-tRNA synthetase. Their Km and Ki values have been determined. Thus positions 2, 6, 7, 8 and 9 of the purine moiety and 2' and 3' of the sugar moiety of the ATP molecule are important for catalytic action of these aminoacyl-tRNA synthetases. Remarkably arginyl-tRNA synthetase is the first aminoacyl-tRNA synthetase which tolerates bulky substituents at the sugar moiety of ATP. These data fit with the idea that synthetases of subunit structure need magnesium-ion-ATP complexes with an anti conformation as substrates whereas single-chain enzymes accept this substrate in the syn conformation.