Yeast phenylalanyl-tRNA synthetase. Stoichiometry of the phenylalanyl adenylate-enzyme complex and transfer of phenylalanine from this complex to tRNA-PHE

Expression and characterization of a human mitochondrial phenylalanyl-tRNA synthetase

Human mitochondrial phenylalanyl-tRNA synthetase (mtPheRS) has been identified from the human EST database. Using consensus sequences derived from conserved regions of the alpha and beta-subunits from bacterial PheRS, two partially sequenced cDNA clones were identified. Unexpectedly, sequence analysis indicated that one of these clones was a truncated form of the other. Detailed analysis indicates that unlike the (alphabeta)2 structure of the prokaryotic and eukaryotic cytoplasmic forms of PheRS, the human mtPheRS consists of a single polypeptide chain. This protein has been cloned and expressed in Escherichia coli. Gel filtration and analytical velocity sedimentation centrifugation indicate that the human mtPheRS is active in a monomeric form. The N-terminal 314 amino acid residues appear to be analogous to the alpha-subunit of the prokaryotic PheRS, while the C-terminal 100 amino acid residues correspond to a region of the beta-subunit known to interact with the anticodon of tRNAPhe. Comparisons with the sequences of PheRS from yeast and Drosophila mitochondria indicate they are 42 % and 51 % identical with the human mtPheRS, respectively. Sequence analysis confirms the presence of motifs characteristic of class II aminoacyl-tRNA synthetases. KM and kcat values for ATP:PPi exchange and for the aminoacylation reaction carried out by human mtPheRS have been determined. Evolutionary origins of this small monomeric human mtPheRS are unknown, however, implications are that this enzyme is a result of the simplification of the more complex (alphabeta)2 bacterial PheRS in which specific functional regions were retained.

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.

Fast dissociation of phe-tRNA synthetase from Aspergillus nidulans immobilized on sepharose-6B column by NaCl

Phenylalanyl-tRNA2) synthetase from Aspergillus nidulans was efficiently immobilised to sepharose 6B column containing phenylalanine as the ligand. NaCl was found to be a potent dissociating agent for the immobilised enzyme. While 0.5 M NaCl in discontinuous elution showed a slow impetus on dissociation giving a plateaux profile, a solution of 0.8 M NaCl made the elution rapid giving a sharp peak. On the other hand, in a gradient (continuous) elution the rapidity of dissociation was found to be enhanced with the increase in the difference of the two concentrations. The result suggests that Na+ ions interact with the protein binding site of the ligand eventually dissociating the enzyme molecule by disrupting the covalent bond without affecting its normal catalytic activity.

Identification of the major tRNA(Phe) binding domain in the tetrameric structure of cytoplasmic phenylalanyl-tRNA synthetase from baker's yeast

Native cytoplasmic phenylalanyl-tRNA synthetase from baker's yeast is a tetramer of the alpha 2 beta 2 type. On mild tryptic cleavage it gives rise to a modified alpha 2 beta 2 form that has lost the tRNA(Phe) binding capacity but is still able to activate phenylalanine. In this paper are presented data concerning peptides released by this limited proteolytic conversion as well as those arising from exhaustive tryptic digestion of the truncated beta subunit. Each purified peptide was unambiguously assigned to a unique stretch of the beta subunit amino acid sequence that was recently determined via gene cloning and DNA sequencing. Together with earlier results from affinity labelling studies the present data show that the Lys 172-Ile 173 bond is the unique target of trypsin under mild conditions and that the N-terminal domain of each beta subunit (residues 1-172) contains the major tRNA(Phe) binding sites.

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.

Yeast phenylalanyl-tRNA synthetase: evidence for the formation of ADP by phosphorolysis of enzyme-bound aminoacyladenylate

ADP and Ap3A are synthesized by the yeast phenylalanyl-tRNA synthetase, according to reaction pathways similar to the pyrophosphorolysis of the intermediate aminoacyladenylate or to the one leading to Ap4A synthesis. The enzyme-bound phenylalanyladenylate reacts with inorganic phosphate or ADP to yield, respectively, ADP or Ap3A. The rate of synthesis is strongly stimulated by Zn2+. This new phosphorolysis activity accounts for the complex pattern of bisnucleoside polyphosphate syntheses starting from ATP.

Yeast tRNAAsp tertiary structure in solution and areas of interaction of the tRNA with aspartyl-tRNA synthetase. A comparative study of the yeast phenylalanine system by phosphate alkylation experiments with ethylnitrosourea

Ethylnitrosourea is an alkylating reagent preferentially modifying phosphate groups in nucleic acids. It was used to monitor the tertiary structure, in solution, of yeast tRNAAsp and to determine those phosphate groups in contact with the cognate aspartyl-tRNA synthetase. Experiments involve 3' or 5'-end-labelled tRNA molecules, low yield modification of the free or complexed nucleic acid and specific splitting at the modified phosphate groups. The resulting end-labelled oligonucleotides are resolved on polyacrylamide sequencing gels and data analysed by autoradiography and densitometry. Experiments were conducted in parallel on yeast tRNAAsp and on tRNAPhe. In that way it was possible to compare the solution structure of two elongator tRNAs and to interpret the modification data using the known crystal structures of both tRNAs. Mapping of the phosphates in free tRNAAsp and tRNAPhe allowed the detection of differential reactivities for phosphates 8, 18, 19, 20, 22, 23, 24 and 49: phosphates 18, 19, 23, 24 and 49 are more reactive in tRNAAsp, while phosphates 8, 20 and 22 are more reactive in tRNAPhe. All other phosphates display similar reactivities in both tRNAs, in particular phosphate 60 in the T-loop, which is strongly protected. Most of these data are explained by the crystal structures of the tRNAs. Thermal transitions in tRNAAsp could be followed by chemical modifications of phosphates. Results indicate that the D-arm is more flexible than the T-loop. The phosphates in yeast tRNAAsp in contact with aspartyl-tRNA synthetase are essentially contained in three continuous stretches, including those at the corner of the amino acid accepting and D-arm, at the 5' side of the acceptor stem and in the variable loop. When represented in the three-dimensional structure of the tRNAAsp, it clearly appears that one side of the L-shaped tRNA molecule, that comprising the variable loop, is in contact with aspartyl-tRNA synthetase. In yeast tRNAPhe interacting with phenylalanyl-tRNA synthetase, the distribution of protected phosphates is different, although phosphates in the anticodon stem and variable loop are involved in both systems. With tRNAPhe, the data cannot be accommodated by the interaction model found for tRNAAsp, but they are consistent with the diagonal side model proposed by Rich & Schimmel (1977). The existence of different interaction schemes between tRNAs and aminoacyl-tRNA synthetases, correlated with the oligomeric structure of the enzyme, is proposed.

Interactions of some naturally occurring cations with phenylalanine and initiator tRNA from yeast as reflected by their thermal stability

The thermal unfolding of phenylalanine and initiator tRNA from yeast was investigated over a broad range of solution conditions by differential ultraviolet absorption at 260 nm. Under most conditions, the initiator tRNA exhibits two clearly separated transitions in its differential melting curve which were assigned to unfolding of tertiary and secondary structure elements, respectively. The tertiary transition of this tRNA and the overall transition observed for tRNAPhe do not show a maximum in a curve of Tm values plotted as a function of [Na+]. Such a maximum is usually observed for other nucleic acids at about 1 M Na+. In the presence of 5 mM of the divalent cation Mg2+ (or Ca2+), an overall destabilization of the tRNAs is observed when increasing the sodium concentration. The largest fall in Tm (approximately 15 degrees C) is observed for the tertiary transition of the initiator tRNA. Among various cations tested the following efficiency in the overall stabilization of tRNAPhe is observed: spermine greater than spermidine greater than putrescine greater than Na+ (approximately NH4+). Mg2+ is most efficient at concentrations above 5 mM, but below this concentration spermine and spermidine appear to be more efficient. The same hierarchy in stabilizing power of the polyamines and Na+ is observed for both transitions of the initiator tRNA. However, when compared with Mg2+, the polyamines are far less capable of stabilizing the tertiary structure. In contrast, spermine and spermidine are slightly better than Mg2+ in stabilizing the secondary structure. At increasing concentrations of the polyvalent cations (at fixed [Na+] ) the Tm values of the tRNAs attain a constant value.

Interaction of tRNAPhe and tRNAVal with aminoacyl-tRNA synthetases. A chemical modification study

The alkylation by ethylnitrosourea of phosphodiester bonds in tRNAPhe from yeast and in tRNAVal from yeast and from rabbit liver and that by 4-(N-2-chloroethyl-N-methylamino)-benzylamine of N-7 atoms of guanosine residues in yeast tRNAVal have been used to study the interaction of these tRNAs with aminoacyl-tRNA synthetases. The modifications occurring at low yield were carried out on 3' and/or 5' end-labelled tRNAs either free or in the presence of cognate or non-cognate synthetases. After splitting of the tRNAs at the alkylated positions, the position of the modification sites in the tRNA sequences were detected by acrylamide gel electrophoresis. It was found that the synthetases protect against alkylation certain phosphate or guanosine residues in their cognate tRNAs. Non-cognate synthetases failed to protect efficiently specific positions in tRNA against modification. In yeast tRNAPhe the cognate phenylalanyl-tRNA synthetase protects certain phosphates located in all four stems and in the anticodon and extra-loop of the tRNA. Particularly strong protections occur on phosphate 34 in the anticodon loop and on phosphates 23, 27, 28, 41 and 46 in the D and anticodon stems. In yeast tRNAVal complexed with yeast valyl-tRNA synthetase the protected phosphates are essentially located in the corner between the amino-acid-accepting and D stems, in the D loop, anticodon stem and in the variable region of the tRNA. Three guanosine residues, located in the D stem, and another one in the 3' part of the anticodon stem were also found protected by the synthetase. In mammalian tRNAVal, complexed with the cognate but heterologous yeast valyl-tRNA synthetase, the protected phosphates lie in the anticodon stem, in the extra-loop and in the T psi arm. The location of the protected residues in the structure of three tRNAs suggests some common features in the binding of tRNAs to aminoacyl-tRNA synthetases. These results will be discussed in the light of informations on interaction sites obtained by nuclease digestion and ultraviolet cross-linking methods.

Conformational activation of aminoacyl-tRNA synthetases upon binding of tRNA. A facet of a multi-step adaptation process leading to the optimal biological activity

The activation of the catalytic center of aminoacyl-tRNA synthetases upon binding of the tRNA, previously reported in the case of yeast phenylalanyl-tRNA and valyl-tRNA synthetases [Renaud et al., (1981) Proc. Natl Acad. Sci. USA, 78, 1606-1608] has been investigated in other systems. It is shown that this property is encountered not only in cognate systems (phenylalanyl, valyl and arginyl) but also in the non-cognate systems which are particularly efficient in misaminoacylation reactions. The arginyl system, the peculiarity of which is to form the aminoacyladenylate only in the presence of the cognate tRNA, is shown to be a border-line case of this general process of catalytic center activation. In the case of the phenylalanyl system, the crucial role of the wybutine residue (adjacent to the anticodon) in the activation of phenylalanyl-tRNA synthetase by the tRNA core has been analysed by comparison with native or modified non-cognate tRNAs (tRNATyr, tRNAArg). It is proposed that upon complex formation between a tRNA and its cognate aminoacyl-tRNA synthetase, a multistep adaptation process takes place in order to promote the optimal rate for the aminoacylation reaction, thus contributing to the specificity of this reaction.

Affinity labelling of yeast phenylalanyl-tRNA synthetase with a 3'-oxidised tRNAPhe. Isolation and sequence of the labelled peptide

Yeast phenylalanyl-tRNA synthetase was specifically labelled with a 3'-oxidised tRNAPhe. Stoichiometric inactivation was achieved with the incorporation of 2 mol oxidised tRNA Phe/mol enzyme which corresponds exactly to the stoichiometry of tRNA binding. The labelled peptide has been isolated using a quick chromatographic procedure which can be applied to any covalent complex formed between a tRNA and an aminoacyl tRNA synthetase. The isolated peptide (18 amino acids) was found to encompass the unique cysteine sequence of the smaller beta subunit of the enzyme.

Phenylalanyl-tRNA synthetase of baker's yeast. Modulation of adenosine triphosphate-pyrophosphate exchange by transfer ribonucleic acid

Native and modified phenylalanine transfer ribonucleic acid (tRNAPhe) can modulate phenylalanine-dependent adenosine triphosphate--inorganic [32P]pyrophosphate (ATP--[32P]PPi) exchange activity via inhibition of adenylate synthesis. Inhibition is visualized if concentrations of L-phenylalanine, ATP, and pyrophosphate are subsaturating. In the proposed mechanism, tRNAPhe is a noncompetitive inhibitor at conditions where only one of the two active sites per molecule of enzyme is occupied by L-phenylalanine, ATP, and pyrophosphate. At saturating concentrations of these reactants, both active sites are occupied and, according to the model, inhibition is eliminated. Occupation by these reactants is assumed to follow homotropic negative cooperativity. The type of effects depends on modification of tRNAPhe. Native tRNAPhe, tRNA2'-dAPhe, and tRNAoxi-redPhe are inhibitors, tRNAPhepCpC has no effect, and tRNAoxPhe is an activator. Kinetics of activation by tRNAoxPhe are slow, following the time course of Schiff base formation and subsequent reduction by added cyanoborohydride. Besides showing that a putative enzyme amino group is nonessential for substrate binding and adenylate synthesis, this result may suggest that an enzyme amino group could interact with the 3'-terminal adenyl group of cognate tRNA. In the case of asymmetrical occupation of the enzyme active sites by all of the small reactants ATP, L-phenylalanine, and pyrophosphate, the interaction with the amino group might trigger the observed noncompetitive inhibition of the pyrophosphate exchange by tRNAPhe.

Study of the interaction between yeast tRNAphe and yeast phenylalanyl-tRNA synthetase by monochromatic ultraviolet irradiation at various wavelengths. Advantages and limits of the method

The interactions between yeast tRNAphe and phenylalanyl-tRNA synthetase were studied by analysis of the covalent adducts obtained upon monochromatic ultraviolet irradiation at different wavelengths (248, 282, 292, 302 and 313 nm). The high extent of inactivation of phenylalanyl-tRNA synthetase, together with the partial modification of tRNA, as well as the peculiar instability of most of the covalent bonds formed upon irradiation constitute severe limitations to the use of the technique and to the interpretation of the results. These disadvantages led us to select an irradiation wavelength of 248 nm and to use only mild isolation procedures allowing a good recovery of the covalent adducts formed. Seven major tryptic peptides of the enzyme were found to be cross-linked to tRNAPhe whereas six major T1-oligonucleotides were covalently linked to the protein, among these, the three cross-linked oligonucleotides previously described by Shoemaker and Schimmel (J. Biol. Chem. 250 (1975) 4440-4444) in the same system. The difference in the number of covalently linked oligonucleotides is discussed in the light of the instability of the covalent linkages. The localization of the six oligonucleotides at the inside of the two branches forming the L-shaped tRNA molecule is similar to that observed in the yeast valine system (Renaud et al., Eur. J. Biochem. 101 (1979) 475-483) and is consistent with the interaction model previously described (Rich and Schimmel, Nucl. Acids Res. 4 (1977) 1649-1665 and Ebel et al. in Transfer RNA: structure, properties and recognition, (1979) pp. 325-343 Cold Spring Harbor Laboratory, NY). The occurrence of covalent cross-linking upon irradiation in the tryptophan absorption band (302 nm) strongly suggests the participation of this residue in the stabilization of the tRNA enzyme complex.

Conformational activation of the yeast phenylalanyl-tRNA synthetase catalytic site induced by tRNAPhe interaction: triggering of adenosine or CpCpA trinucleoside diphosphate aminoacylation upon binding of tRNAPhe lacking these residues

Adenosine or CpCpA trinucleoside diphosphate can be aminoacylated by phenylalanyl-tRNA synthetase [L-phenylalanine:tRNAPhe ligase (AMP forming), EC 6.1.1.20] when the reaction takes place in the presence of tRNAPhe deprived of its 3' adenosine or pCpCpA terminus. This shows that, upon interaction with tRNA, a structural alteration of the enzyme's active site is achieved. This process may be a determining step in the specificity of the aminoacylation reaction.

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.

Fluorimetric study of the complex between yeast phenylalanyl-tRNA synthetase and tRNA-Phe. 2. Evidence for an asymmetric behaviour of the enzyme

The variations of several spectroscopic properties of yeast tRNA-Phe and phenylalanyl-tRNA synthetase upon complex formation, were used to study the stoichiometry of the complex in different experimental conditions. In all cases, for the tRNA-Phe-enzyme complex, in the absence of other ligands, the saturations of the different conformational changes monitored for both macromolecules, are achieved at a 2:1 tRNA/enzyme stoichiometry. Phenylalanine does not modify this saturation. In contrast, the presence of 1 mM ATP induces an asymmetric behaviour of the synthetase: two tRNAs are still bound per enzyme molecule but the conformational change of the latter is completed upon binding of a single tRNA molecule.

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.

Yeast phenylalanyl-tRNA synthetase. Affinity and photoaffinity labelling of the stereospecific binding sites

The localization of the binding sites of the different ligands on the constitutive subunits of yeast phenylalanyl-tRNA synthetase was undertaken using a large variety of affinity and photoaffinity labelling techniques. The RNAPhe was cross-linked to the enzyme by non-specific ultraviolet irradiation at 248 nm, specific irradiation in the wye base absorption band (315 nm), irradiation at 335 nm, in the absorption band of 4-thiouridine (S4U) residues introduced in the tRNA molecule, or by Schiff's base formation between periodate-oxidized tRNAPhe (tRNAPheox) and the protein. ATP was specifically incorporated in its binding site upon photosensitized irradiation. The amino acid could be linked to the enzyme upon ultraviolet irradiation, either in the free state, engaged in the adenylate or bound to the tRNA. The tRNA, the ATP molecule and the amino acid linked to the tRNA were found to interact exclusively with the beta subunit (Mr 63000). The phenylalanine residue, either free or joined to the adenylate, could be cross-linked with equal efficiency to eigher type of subunit, suggesting that the amino acid binding site is located in a contact area between the two subunits. The Schiff's base formation between tRNAPheox and the enzyme shows the existence of a lysyl group close to the binding site for the 3'-terminal adenosine of tRNA. This result was confirmed by the study of the inhibition of yeast phenylalanyl-tRNA synthetase with pyridoxal phosphate and the 2',3'-dialdehyde derivative of ATP, oATP.

Yeast phenylalanyl-tRNA synthetase. Properties of the histidyl residues

Reactivity of the histidyl groups of yeast phenylalanyl-tRNA synthetase was studied in the absence or presence of substrates. In the absence of substrates about 10 histidine residues were found to react with similar kinetic constants. Phenylalanine at 10(-3) M was found to protect two histidyl residues; increasing the amino acid concentration to 5 . 10(-3) M resulted in the protection of two more histidyl groups. tRNAPhe did not afford any protection to histidine residues, but acylated phenylalanyl-tRNA (Phe-tRNAPhe) protected two of the four histidyl groups already protected by phenylalanine. These results suggest the existence of two different sets of accepting sites for phenylalanine: one specific for the free amino acid, the other one specific for the amino acid linked to the tRNA, but being accessible to free phenylalanine, with a somewhat lower binding constant, ATP was found to mask around four histidyl residues against diethylpyrocarbonate modification. By photoirradiation of enzyme-phenylalanine complex in the presence of rose bengale, a significant amount of amino acid was bound to the alpha subunit (Mr = 73 000) of phenylalanyl-tRNA synthetase, confirming that the amino acid binding site is located on this subunit, as previously suggested by modification of thiol groups. Upon irradiation of an enzyme-tRNA complex, almost no covalent binding of tRNA occurred during enzyme inactivation, suggesting that the histidyl residues involved in the enzymic activity are not required for tRNA binding.

Analysis of the steady-state mechanism of the aminoacylation of tRNAPhe by phenylalanyl-tRNA synthetase from yeast

The steady-state mechanism of the aminoacylation of tRNAPhe by the corresponding synthetase from yeast has been investigated in detail by kinetic experiments. It was found that there are two alternative mechanisms: one favoured at low tRNA concentrations and the other at high tRNA concentrations. ATP and Phe are bound randomly to the enzyme. AMP is released immediately after the binding of ATP and Phe. Between the release of AMP and pyrophosphate (PPi) there is at least one additional step. Based on the experimental results a model of the steady-state mechanism is proposed. This model includes the sequence of addition of substrates to the enzyme and the release of products from the enzyme as well as the composition of the intermediate complexes with the enzyme. This model is in accordance with previous results based on different techniques. The results are explained by a "flip-flop" mechanism for all the substrates and products involved in the reaction.

The aminoacyladenylate mechanism in the aminoacylation reaction of yeast phenylalanyl-tRNA synthetase

It is shown from a combination of rapid quenching and steady-state kinetics that the phenylalanyl-tRNA synthetase from yeast catalyses the formation of phenylalanyl-tRNA by the amino-acyladenylate pathway at pH 7.8 and 25 degrees C. The rate-determining step at saturating reagent concentrations is not the dissociation of the charged tRNA from the enzyme.

The yeast aminoacyl-tRNA synthetases. Methodology for their complete or partial purification and comparison of their relative activities under various extraction conditions

Several fractionation steps are described which can be applied to the partial purification of the 20 aminoacyl-tRNA synthetases from commercial baker's yeast. Comparative experiments performed in the presence or absence of protease inhibitors revealed that some enzymes prepared in the presence of the inhibitor exhibit much higher specific activities than the proteins extracted in the absence of the inhibitor. The methodology reported can be used for the simultaneous preparation of several pure aminoacyl-tRNA synthetases. As examples, the large scale purification of phenylalanyl-and valyl-tRNA synthetases are described.

Non-equivalence of the sites of yeast phenylalanyl-tRNA synthetase during catalysis

Yeast phenylalanyl-tRNA synthetase, an enzyme with an alpha2beta2 structure, has two active sites for phenylalanine, tRNAphe, phenylalanyladenylate and phenylalanyl-tRNAphe. Determination of phenylalanine binding properties to the free enzyme by equilibrium dialysis shows that only one mole of amino acid binds per mole of enzyme, i.e. absolute negative cooperativity. Binding of the amino acid in the presence of tRNA or of ATP and PPi unmasks the second phenylalanine binding site. The difference between the affinities at the tight and loose binding sites under such conditions is about 10--15. Titration of phenylalanyladenylate sites by the burst of ATP consumption shows the formation of a (enzyme-phenylalanyladenylate)2 complex in the presence of pyrophosphatase; however, the two sites differ widely in their affinity as shown by dialysis experiments. Measurements of hydrolysis rates of enzyme-bound phenylalanyladenylate suggests that when only the high-affinity adenylate site is occupied, the other protomer can still bind phenylalanine and ATP (in the presence of phenylalanine). Two moles of Phe-tRNAphe bind to the enzyme with a very high affinity (Kd less than 48 nM). The presence of millimolar concentrations of ATP, phenylalanine and pyrophosphate triggers negative cooperativity and under these conditions only one mole of Phe-tRNAphe is bound per mole of enzyme with a Kd value of 0.15 muM. The present results give support to interprotomer catalytic cooperativity in the mechanism of action of yeast phenylalanyl-tRNA synthetase.

Multiple molecular forms of cysteinyl-tRNA synthetase from rat liver: purification and subunit structure

Cysteinyl-tRNA synthetase (L-cysteine:tRNACys ligase (AMP-forming), EC 6.1.1.16) has been purified from rat liver in 23% overall yield. The enzyme was resolved by hydroxyapatite chromatography into three active forms (Fractions CRS-1, CRS-2 and CRS-3). The total activity ratio was about 0.7:2:1. The fractions CRS-2 and CRS-3 contained no other detectable aminoacyl-tRNA synthetase activity. CRS-2 was homogeneous by polyacrylamide gel electrophoresis, CRS-3 gave two active bands with mobilities corresponding to those of CRS-1 and CRS-2. The molecular weight of CRS-2 was about 240 000 by electrophoretic mobilities on the gels of various porosity, and 115 000-140 000 by sucrose gradient centrifugation. By gel-filtration, CRS-1, CRS-2 and CRS-3 exhibited apparent molecular weights of 122 000, 235 000 and 300 000, respectively. By sodium dodecyl sulfate gel electrophoresis, both CRS-2 and CRS-3 gave a single major band of 120 000 daltons. Stoichiometric study of cysteinyl adenylate formation indicated that CRS-2 has two active sites per molecule. These results are consistent with a dimeric structure of the type alpha2 for the major form of rat liver cysteinyl-tRNA synthetase, composed of two probably identical subunits of about 120 000 daltons. Available evidence also suggests that CRS-1 and CRS-3 are alpha and alpha3 (or alpha4), respectively.

Interpretation of tRNA-mischarging kinetics

Incorrect tRNA aminoacylation reactions are characterized by very slow reaction rates and by the fact that in most cases they are incomplete. In a previous study some of us explained the incompleteness of the correct aminoacylation reactions of tRNA, which can be encountered under certain experimental conditions (for instance low enzyme concentration or high ionic strength) by an equilibrium between the aminoacylation and the deacylation reactions [J. Bonnet and J.P. Ebel (1972) Eur. J.Biochem. 31, 335-344]. In the present report we bring evidence that the incorrect valylation of yeast tRNAfMet by yeast valyl-tRNA synthetase studied under standard experimental conditions, can also be described by a kinetic rate law including the rate equations of the aminoacylation and of the various deacylation reactions. In particular we show that the incomplete mischarging plateaus reflect the existence of an equilibrium between the valylation reaction on the one hand and the spontaneous and enzymic deacylation of valyl-tRNAfMet and the reverse of the valylation reaction on the other hand. However, when the valyl-tRNA synthetase concentration is not very high the reverse reaction of the amino-acylation does not play a predominant part in the establishment of the plateau. These interpretations have been extended to other mischarging systems: valylation of yeast tRNAPhE by yeast valyl-tRNA synthetase and mischarging of tRNAfMet and tRNA2Val from yeast by yeast phenylalanyl-tRNA synthetase. Unusual mischarging kinetics have been discussed. Furthermore, and as in correct systems, we found that during the mischarging of tRNAfMet one ATP is hydrolyzed per tRNA charged with valine. We conclude that the correct and the incorrect amino-acylation of tRNA behave kinetically in a similar way.

Interaction of aminoacyl-tRNA synthetases and tRNA: positive and negative cooperativity of their active centres

The influence of tRNA on the kinetics of PP-ATP exchange and aminoacyl-tRNA formation catalysed by leucyl-, phenylalanyl-, and tryptophanyl-tRNA synthetases has been investigated. These enzymes were chosen because they belong to three main classes of quaternary structure alpha1, alpha2beta2 and alpha2, respectively. The present paper shows that the investigated synthetases manifest kinetic cooperativity of the active centres which is negative in the case of AAA formation and positive in the case of leucyl- and tryptophanyl-tRNA synthesis. The obtained data were interpreted with the aid of the trigger model of the enzyme.

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

Arginyl-tRNA synthetase from baker's yeast (Saccharomyces cerevisiae, strain 836) was obtained pure by a large-scale preparative method, which involves four chromatographic columns and one preparative polyacrylamide gel electrophoretic step. The enzyme has a high specific activity (9000 U/mg) and consists of a single polypeptide chain of molecular weight approximately 73000 as determined by polyacrylamide gel electrophoresis in the presence of sodium dodecylsulphate. Amino acid analysis of the enzyme permitted calculation of the absorption coefficient of arginyl-tRNA synthetase (A(1 mg/ml 280 nm)=1.26). Concerning kinetic parameters of the enzyme we found the following Km values: 0.28 muM, 300 muM, 1.5 muM for tRNA(Arg III), ATP and arginine in the aminoacylation reaction, and 1400 muM, 2.5 muM, and 50 muM for ATP, arginine and PP(i) in the ATP-PP(i) exchange reaction. Arginyl-tRNA synthetase required tRNA(Arg III) to catalyse the ATP-PP(i) exchange reaction.

Phenylalanyl-tRNA synthetase from baker's yeast. Salt dependence of steady-state kinetics indicates two molecular forms of the enzyme

Steady-state kinetic data of aminoacylation of tRNAPhe by phenylalanyl-tRNA synthetase depend on salt concentration. At 5 mM KCl and 20 mM MgSO4 a non-linear curve is found in the double-reciprocal plot for ATP and phenylalanine, while at 200 mM KCl and 50 mM MgSO4 a linear curve is observed. KCl and MgSO4 dependence of the reaction also show biphasic curves with intersection points of the two extrapolated linear parts at 50 mM and 10 mM, respectively. A biphasic curve is also found if the concentration of CTP is varied at constant low ATP concentration. Extrapolations of the linear parts of the curves for ATP as well as for CTP at 5 mM KCl and 20 mM MgSO4 intersected the 1/[NTP] axis at 1.2 +/- 0.1 mM. Hence the existence of a non-linear curve for ATP as well as phenylalanine does not necessarily indicate two non-equivalent binding sites for these substrates. A more likely explanation is the existence of two different molecular forms of phenylalanyl-tRNA synthetase which are interconvertible by salt. This explanation is substantiated by the observation that proteolytic digestion of phenylalanyl-tRNA synthetase is more easily achieved at low than at medium ionic strength. In addition mischarging of tRNAIle with phenylalanine by phenylalanyl-tRNA synthetase occurs at a moderate rate at 5 mM KCl and 20 mM MgSO4 whereas it is largely depressed by addition of either 5 mM CTP or 150 mM KCl.

Complete purification and studies on the structural and kinetic properties of two forms of yeast valyl-tRNA synthetase

Two forms of baker's yease valyl-tRNA synthetase have been purified to apparent homogeneity by classical methods. It was demonstrated that one of the two forms of the enzyme originates from the other by proteolysis, the respective amounts of each form depending on the physiological state of the yeast. The species mainly isolated from exponential growing yeast cells is a monomer of 130,000 daltons molecular weight. In stationary phase cells or in commercial yeast the major species is a degraded monomer of 120,000 daltons molecular weight ; however when the purification is carried out in the presence of phenylmethyl-sulphonyl fluoride, or diisopropylfluorophosphate large amounts of the not - degreded monomer can be obtained. Of great practical usefulness is the fact that large amounts of the native enzyme can be obtained pure after only two chromatographic steps on DEAE-cellulose and hydroxylapatite. The kinetic constants for valine, ATP and tRNAVal were determined, as well as the optimum aminoacylation conditions. It was found that the specific activity of the nondegraded valyl-tRNA synthetase is higher than that of the proteolysed enzyme for the aminoacylation reaction. On the contrary, both forms have the same ATP-pyroposphate exchange activity. The amino acids composition of the native enzyme was established. The tryptic fingerprints of the two valyl-tRNA synthetases were studied. Essentially similar maps were obtained. The number of the spots in the fingerprints indicates that the enzymes contain a high proportion of repeated sequences.