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.     

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.     

Natural variation of tyrosyl-tRNA synthetase and comparison with engineered mutants

We report the cloning and sequence analysis of the gene for the tyrosyl-tRNA synthetase from Bacillus caldotenax and properties of the gene product. The amino acid sequence of the tyrosyl-tRNA synthetase was found to be 99% homologous with the corresponding enzyme from B. stearothermophilus, with only four amino acid differences. Two of these natural variations were found to involve active site residues of the enzyme and correspond to mutations that have been engineered previously in vitro. One, Thr-51----Ala-51, produced a more active enzyme, possessing a higher value of kcat/KM for ATP. Position 51 is a "hot spot" in the tyrosyl-tRNA synthetase, differing in enzymes derived from Escherichia coli, B. stearothermophilus, and B. caldotenax. The other, His-48----Asn-48, is found to be a neutral mutation but is in one of the rare regions that are conserved with other aminoacyl-tRNA synthetases. The equivalence of histidine and asparagine at position 48 extends the homology in this region to more enzymes. These residues, His-Ile-Gly-His, and now His-Ile-Gly-Asn, form part of the binding site for ATP in the transition state of the reaction. Although B. caldotenax is an obligate thermophile with an optimal growth temperature of 80 degrees C, as much as 20 degrees C above the growth optima of strains of Bacillus stearothermophilus, its tyrosyl-tRNA synthetase has an identical thermal stability in vitro to that from B. stearothermophilus.     

Evidence for the Existence of Two Arginyl-Transfer Ribonucleic Acid Synthetase Activities in Escherichia coli

Two arginyl-transfer ribonucleic acid (tRNA) synthetase (EC 6.1.1.13, arginine: ribonucleic acid ligase adenosine monophosphate) activities were found in extracts of Escherichia coli strains AB1132 and NP2. The two arginyl-tRNA synthetase activities in extracts of strain AB1132 were found to be separable by diethylaminoethyl-cellulose column chromatography, Sephadex column fractionation, and by sucrose density gradient centrifugation. In addition, in the standard assay using extracts of strain AB1132 there were two pH optima for arginyl-tRNA synthetase activity. Furthermore, when arginyl-tRNA synthetase of strain NP2 was fractionated by hydroxylapatite column chromatography, two activities were observed which were similar to those of strain AB1132.     

Stable ammonia-specific NAD synthetase from Bacillus stearothermophilus: purification,characterization, gene cloning,and applications

Bacillus stearothermophilus H-804 isolated from a hot spring in Beppu, Japan, produced an ammonia-specific NAD synthetase (EC 6.3.1.5). The enzyme specifically used NH3 as an amide donor for the synthesis of NAD as it formed AMP and pyrophosphate from deamide-NAD and ATP. None of the l-amino acids tested, such as l-asparagine or l-glutamine, or other amino compounds such as urea, uric acid, or creatinine was used instead of NH3. Mg2+ was needed for the activity, and the maximum enzyme activity was obtained with 3 mM MgCl2. The molecular mass of the native enzyme was 50 kDa by gel filtration, and SDS-PAGE showed a single protein band at the molecular mass of 25 kDa. The optimum pH and temperature for the activity were from 9.0 to 10.0 and 60 degrees C, respectively. The enzyme was stable at a pH range of 7.5 to 9.0 and up to 60 degrees C. The Km for NH3, ATP, and deamide-NAD were 0.91, 0.052, and 0.028 mM, respectively. The gene encoding the enzyme consisted of an open reading frame of 738 bp and encoded a protein of 246 amino acid residues. The deduced amino acid sequence of the gene had about 32% homology to those of Escherichia coli and Bacillus subtilis NAD synthetases. We caused the NAD synthetase gene to be expressed in E. coli at a high level; the enzyme activity (per liter of medium) produced by the recombinant E. coli was 180-fold that of B. stearothermophilus H-804. The specific assay of ammonia and ATP (up to 25 microM) with this stable NAD synthetase was possible.     

Comparison of the complexed and free forms of rat liver arginyl-tRNA synthetase and origin of the free form

Arginyl-tRNA synthetase is found in multiple molecular weight forms in extracts from a variety of mammalian tissues. The rat liver enzyme can be isolated either as a component of the synthetase complex (Mr greater than 10(6) or as a free protein (Mr = 60,000). However, based on activity measurements after sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the molecular weight of the free form differs from its counterpart in the complex (Mr = 72,000). Both forms of arginyl-tRNA synthetase cross-react with an antibody directed against the complex, and both have similar catalytic properties. Thus, the two proteins have similar apparent Km values for arginine and ATP, the same pH optimum, are inhibited equally by elevated ionic strength and PPi, and they aminoacylate the same population of tRNA molecules. On the other hand, the free and complexed forms differ with respect to their apparent Km values for tRNA (free, 4 microM; complexed, 28 microM), their temperature sensitivity (complexed greater sensitivity), and their hydrophobicity (complexed more hydrophobic). Limited proteolysis of the synthetase complex with papain releases a low molecular weight form of arginyl-tRNA synthetase whose size, temperature sensitivity, and hydrophobicity are similar to that of the endogenous free form. Nevertheless, the usual 2:1 ratio of complexed-to-free form of rat liver arginyl-tRNA synthetase is not altered by a variety of homogenization or incubation conditions in the presence or absence of multiple protease inhibitors. In contrast to extracts of rat liver, rabbit liver extracts do not contain a free form of arginyl-tRNA synthetase. These results suggest that the complexed and free forms of arginyl-tRNA synthetase are probably the same gene product and that the free form in rat liver extracts is derived from the complexed form by a limited endogenous proteolysis that removes the portion of the protein required for anchoring it in the complex. The question of whether the free form is an artifact of isolation or whether it pre-exists in the cell is discussed.     

Cysteinyl-tRNA synthetase is a direct descendant of the first aminoacyl-tRNA synthetase.

The gene encoding the cysteinyl-tRNA synthetase of E. coli was cloned from an E. coli genomic library made in lambda 2761, a lambda vector which can integrate and which carries a chloramphenicol resistance gene. A thermosensitive cysS mutant of E. coli was lysogenised and chloramphenicol-resistant colonies able to grow at 42 degrees C were selected to isolate phages containing the wild-type cysS gene. The sequence of the gene was determined. It codes for a 461 amino-acid protein and includes the sequences HIGH and KMSK known to be involved in the ATP and tRNA binding respectively of class I synthetases. The cysteinyl enzyme has segments in common with the cytoplasmic leucyl-tRNA synthetase of Neurospora crassa, the tryptophanyl-tRNA synthetase of Bacillus stearothermophilus, and the phenylalanyl-tRNA synthetase of Saccharomyces cerevisiae. Sequence comparisons show that the amino end of the cysteinyl-tRNA synthetase has similarities with prokaryotic elongation factors Tu; this region is close to the equivalent acceptor binding domain of the glutaminyl-tRNA synthetase of E. coli. There is a further similarity with the seryl enzyme (a class II enzyme) which has led us to propose that both classes had a common origin and that this was the ancestor of the cysteinyl-tRNA synthetase.     

A comparison of purified valyl-transfer ribonucleic acid synthetase from Bacillus stearothermophilus and from Escherichia coli

The purification of valyl-tRNA synthetase from Bacillus stearothermophilus is described. The protein was greater than 90% homogeneous on polyacrylamide-gel electrophoresis after more than 850-fold purification. It has a molecular weight of 110000, and no evidence was found for the presence of subunit structure. The properties of the purified enzyme were compared with those of purified valyl-tRNA synthetase from Escherichia coli. The thermal stability, pH-stability and dependence of activity on the temperature and pH of the assay are reported. The two enzymes recognize and charge tRNA(Val) from crude tRNA of the mesophile E. coli and of the thermophile B. stearothermophilus, indiscriminately. The gel-filtration method was extended to measure the binding of tRNA to synthetase directly. Binding constants for tRNA(Val) to valyl-tRNA synthetase from B. stearothermophilus were determined between 5 degrees and 60 degrees C.     

Structure-function relationship of arginyl-tRNA synthetase from Escherichia coli: isolation and characterization of the argS mutation MA5002.

The Escherichia coli K12 argS MA5002 mutant appears to have a functionally altered arginyl-tRNA synthetase (ArgRS). The gene coding for this enzyme was isolated from E. coli genomic DNA using the PCR procedure and inserted into a pUC18 multicopy vector. Sequencing revealed that it differs from the wildtype ArgRS structural gene only by one mutation: a replacement of a C by an A residue which results in substitution of an arginine by a serine at position 134, located two residues downstream from the HVGH consensus sequence. As compared to the genomic enzyme level, this recombinant vector, containing the mutated gene, produces in E. coli JM103, about 100 times as much modified ArgRS. This enzyme was obtained nearly pure after only two chromatographic steps; it exhibits a 4-6 times as low activity and a 5 times as high Km value for ATP as the wildtype enzyme in the aminoacylation and ATP-PPi reactions; Km values for arginine and tRNAArg remained unaltered. The position of this mutation and its effect on enzymatic properties suggest the implication of arginine 134 in ATP binding as well as in the activation catalytic process.     

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.     

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.     

Multiple forms of arginyl- and lysyl-tRNA synthetases in rat liver: a re-evaluation

The size distribution of lysyl- and arginyl-tRNA synthetases in crude extracts from rat liver was re-examined by gel filtration. It is shown that irrespective of the addition or not of several proteinase inhibitors, lysyl-tRNA synthetase was present exclusively as a high-Mr entity, while arginyl-tRNA synthetase occurred as high- and low-Mr forms, in the constant proportions of 2:1, respectively. The polypeptide molecular weights of the arginyl-tRNA synthetase in these two forms were 74000 and 60000, respectively. The high-Mr forms of lysyl- and arginyl-tRNA synthetases were co-purified to yield a multienzyme complex, the polypeptide composition of which was virtually identical to that of the complexes from rabbit liver and from cultured Chinese hamster ovary cells. Of the nine aminoacyl-tRNA synthetases, specific for lysine, arginine, methionine, leucine, isoleucine, glutamine, glutamic and aspartic acids and proline, which characterize the purified complex, each, except prolyl-tRNA synthetase, was assigned to the constituent polypeptides by the protein-blotting procedure, using the previously characterized antibodies to the aminoacyl-tRNA synthetase components of the corresponding complex from sheep liver.     

Stringent response of Bacillus stearothermophilus: evidence for the existence of two distinct guanosine 3',5'-polyphosphate synthetases.

Bacillus stearothermophilus reacted to pseudomonic acid-induced inhibition of isoleucine-transfer ribonucleic acid (RNA) acylation and to energy downshift caused by alpha-methylglucoside addition with accumulation of guanosine 3',5'-polyphosphates [(p)ppGpp] and restriction of RNA synthesis. In vitro studies indicated that (p)ppGpp was synthesized by two different enzymes. One enzyme, (p)ppGpp synthetase I, was present in the ribosomal fraction, required the addition of a ribosome-messenger RNA-transfer RNA complex for activation, and was inhibited by tetracycline and thiostrepton. It is suggested that (p)ppGpp synthetase I is comparable to the relA gene product from Escherichia coli and is responsible for (p)ppGpp accumulation during amino acid starvation. The other enzyme, (p)ppGpp synthetase II, was found in the high-speed supernatant fraction (S100). It functioned independently of ribosomes, transfer RNA, and messenger RNA and was not inhibited by the above-mentioned antibiotics. (p)ppGpp synthetase II is thought to be responsible for (p)ppGpp accumulation during carbon source downshift. The two enzymes differ in their Km values for adenosine triphosphate (ATP):2mM ATP for synthetase I and 0.05 mM ATP for synthetase II. They also have different molecular weights: apparent Mr of 86,000 (+/- 5,000) for synthetase I and 74,000 (+/- 5,000) for synthetase II.     

A preferential role for lysyl-tRNA4 in the synthesis of diadenosine 5',5'-P1,P4-tetraphosphate by an arginyl-tRNA synthetase-lysyl-tRNA synthetase complex from rat liver

The synthesis of diadenosine 5',5'-P1,P4-tetraphosphate (Ap4A) can be catalyzed in vitro by a tetrameric tRNA synthetase complex from rat liver containing two lysyl-tRNA synthetase and two arginyl-tRNA synthetase subunits. This reaction required ATP, AMP, 50-100 microM zinc, and inorganic pyrophosphatase. We show here that AMP can be omitted from the reaction and that the zinc levels can be markedly reduced provided catalytic amounts of tRNA(Lys) are added to the reaction mixture. Ap4A synthesis with purified tRNA(Lys) isoacceptors showed that the minor species, tRNA(4Lys), was 3-fold more active than either of the two major tRNA(Lys) species, tRNA(2Lys) and tRNA(5Lys). No activity could be demonstrated with tRNA(Lys) from Escherichia coli or with tRNA(Lys) or tRNA(Phe) from yeast. Aminoacylation of tRNA(4Lys) was strictly required as determined by the fact that Ap4A synthesis was not observed until aminoacylation was nearly complete, inhibitors of aminoacylation blocked Ap4A synthesis, and there was a strict requirement for added lysine. None of the above observations could be demonstrated, however, when lysyl-tRNA(Lys) was directly supplied to the reaction mixture. Optimum Ap4A synthesis was obtained by the addition of 1 mol of tRNA(Lys)/mol of the synthetase complex. This reaction is unique because it does not require the prior formation of an aminoacyl-AMP intermediate and because it can actively synthesize Ap4A at physiological zinc concentrations. The preferential role for tRNA(4Lys) in Ap4A synthesis is consistent with its prior implication in cell division.     

S-Adenosylmethionine synthetase from Escherichia coli

Adenosylmethionine (AdoMet) synthetase has been purified to homogeneity from Escherichia coli. For this purification, a strain of E. coli which was derepressed for AdoMet synthetase and which harbors a plasmid containing the structural gene for AdoMet synthetase was constructed. This strain produces 80-fold more AdoMet synthetase than a wild type E. coli. AdoMet synthetase has a molecular weight of 180,000 and is composed of four identical subunits. In addition to the synthetase reaction, the purified enzyme catalyzes a tripolyphosphatase reaction that is stimulated by AdoMet. Both enzymatic activities require a divalent metal ion and are markedly stimulated by certain monovalent cations. AdoMet synthesis also takes place if adenyl-5'yl imidodiphosphate (AMP-PNP) is substituted for ATP. The imidotriphosphate (PPNP) formed is not hydrolyzed, permitting dissociation of AdoMet formation from tripolyphosphate cleavage. An enzyme complex is formed which contains one equivalent (per subunit) of adenosylmethionine, monovalent cation, imidotriphosphate, and presumably divalent cation(s). The rate of product dissociation from this complex is 3 orders of magnitude slower than the rate of AdoMet formation from ATP. Studies with the phosphorothioate derivatives of ATP (ATP alpha S and ATP beta S) in the presence of Mg2+, Mn2+, or Co2+ indicate that a divalent ion is bound to the nucleotide during the reaction and provide information on the stereochemistry of the metal-nucleotide binding site.     

Comparison of the thermolability and hydrophobic properties of high- and low-molecular-weight forms of rabbit liver arginyl-tRNA synthetase

Summary Two preparations with arginyl-tRNA synthetase activity have been obtained from rabbit liver post-microsomal fraction: a) a high-molecular-weight containing the multienzyme aminoacyl-tRNA synthetase complex and b) a low-molecular-weight preparation containing free enzymes. Thermal inactivation of arginyl-tRNA synthetase in both preparations has been compared in a solution which was successively supplemented with tRNA, reduced glutathione, L-ascorbic acid, ZnCl₂ and Triton × 100. Moreover, hydrophobic properties of both enzyme preparations have been compared. It was found that the complexed arginyl-tRNA synthetase is more stable than the free enzyme. A role of hydrophobic interactions in the maintenance of the complexed enzyme stability is suggested.Abbreviations DFP Diisopropylfluorophosphate - GSH Glutathione (reduced) - PMSF Phenylmethylsulfonyl Fluoride - Ap₄A Diadenosine 5, 5-P₁, P₄-tetraphosphate - Preparation I high-molecular-weight arginyl-tRNA synthetase preparation - Preparation II low-molecular-weight arginyl-tRNA synthetase preparation     

Methionyl-tRNA synthetase from Bacillus stearothermophilus: structural and functional identities with the Escherichia coli enzyme.

The metS gene encoding homodimeric methionyl-tRNA synthetase from Bacillus stearothermophilus has been cloned and a 2880 base pair sequence solved. Comparison of the deduced enzyme protomer sequence (Mr 74,355) with that of the E. coli methionyl-tRNA synthetase protomer (Mr 76,124) revealed a relatively low level (32%) of identities, although both enzymes have very similar biochemical properties (Kalogerakos, T., Dessen, P., Fayat, G. and Blanquet, S. (1980) Biochemistry 19, 3712-3723). However, all the sequence patterns whose functional significance have been probed in the case of the E. coli enzyme are found in the thermostable enzyme sequence. In particular, a stretch of 16 amino acids corresponding to the CAU anticodon binding site in the E. coli synthetase structure is highly conserved in the metS sequence. The metS product could be expressed in E. coli and purified. It showed structure-function relationships identical to those of the enzyme extracted from B. stearothermophilus cells. In particular, the patterns of mild proteolysis were the same. Subtilisin converted the native dimer into a fully active monomeric species (62 kDa), while trypsin digestion yielded an inactive form because of an additional cleavage of the 62 kDa polypeptide into two subfragments capable however of remaining firmly associated. The subtilisin cleavage site was mapped on the enzyme polypeptide, and a gene encoding the active monomer was constructed and expressed in E. coli. Finally, trypsin attack was demonstrated to cleave a peptidic bond within the KMSKS sequence common to E. coli and B. stearothermophilus methionyl-tRNA synthetases. This sequence has been shown, in the case of the E. coli enzyme, to have an essential role for the catalysis of methionyl-adenylate formation.     

Sizes of two amino acyl-tRNA synthetase complexes from E. coli with their cognate tRNAs.

The complexes of valyl-tRNA synthetase with tRNA_I^Val and arginyl-tRNA synthetase with tRNA_II^Arg from $\text{E. coli}$ were studied by light scattering measurements and analytical ultracentrifugation of concentrations as low as 40 μg/ml. The molecular weights determined from these studies were 260,000 ± 2,000 for the valyl-tRNA synthetase·tRNA complex, and 310,000 ± 1,500 for the arginyl-tRNA synthetase·tRNA complex at pH 7.1. The stoichiometry for the complexes are apparently 2:1 for valyl-tRNA synthetase and tRNA and 4:1 in the case of the arginyl-tRNA synthetase and tRNA. From the angular dependence of the scattered intensity a radius of gyration of 54.5 Å for the complex between valyl-tRNA synthetase and tRNA was found, whereas for the other complex a value of 59.1 Å was found.     

Ligand binding and enzymic catalysis coupled through subunits in tyrosyl-tRNA synthetase.

The interaction of the tyrosyl-tRNA synthetase from Bacillus stearothermophilus with its substrates in the aminoacyl adenylation reaction has been studied by stopped-flow fluorescence. The observed changes have been assigned to their chemical and physical processes by comparison with equilibrium dialysis, pyrophosphate exchange kinetics and rapid quenching and sampling techniques to give the rate constants for ligand binding, the formation of tyrosyl adenylate, and the reverse reaction. The stoichiometry of tyrosine and ATP binding in the catalytic process has been determined directly by equilibrium dialysis and equilibrium gel filtration under pyrophosphate exchange conditions, i.e., where a steady state has been set up in which the equilibrium position favors starting materials. It is shown that the rate-determining step in the formation of tyrosyl adenylate involves 1 mole each of tyrosine and ATP. A second mole of tyrosine and ATP bind to the aminoacyl adenylate complex stabilizing the high-energy intermediate. The enzyme tyrosyl adenylate complex that is isolated by gel filtration is in a different conformational state from that in the presence of tyrosine and ATP.