Aminoacyl adenylate, a normal intermediate or a dead end in aminoacylation of transfer ribonucleic acid.

The shape of the time curve for the aminoacylation of tRNA has been investigated using five different amino acid:tRNA ligases. Four of these enzymes showed a lag in the time curve during the early phase of the first catalytic turnover of the enzyme. In each case, the lag period could be abolished by preincubating the ligase with amino acid, ATP, and Mg2+ under conditions known to give an aminoacyl adenylate-enzyme complex. With all five ligases the steady state rate of transfer from the preformed aminoacyl-adenylate complex to tRNA was approximately the same as that of the overall reaction.     

A substrate-assisted concerted mechanism for aminoacylation by a class II aminoacyl-tRNA synthetase

Aminoacyl-tRNA synthetases (aaRS) join amino acids to their cognate transfer RNAs, establishing an essential coding relationship in translation. To investigate the mechanism of aminoacyl transfer in class II Escherichia coli histidyl-tRNA synthetase (HisRS), we devised a rapid quench assay. Under single turnover conditions with limiting tRNA, aminoacyl transfer proceeds at 18.8 s(-)(1), whereas in the steady state, the overall rate of aminoacylation is limited by amino acid activation to a rate of 3 s(-)(1). In vivo, this mechanism may serve to allow the size of amino acid pools and energy charge to control the rate of aminoacylation and thus protein synthesis. Aminoacyl transfer experiments using HisRS active site mutants and phosphorothioate-substituted adenylate showed that substitution of the nonbridging Sp oxygen of the adenylate decreased the transfer rate at least 10 000-fold, providing direct experimental evidence for the role of this group as a general base for the reaction. Other kinetic experiments revealed that the rate of aminoacyl transfer is independent of the interaction between the carboxyamide group of Gln127 and the alpha-carboxylate carbon, arguing against the formation of a tetrahedral intermediate during the aminoacyl transfer. These experiments support a substrate-assisted concerted mechanism for HisRS, a feature that may generalize to other aaRS, as well as the peptidyl transferase center.     

A model for the coevolution of the genetic code and the process of protein synthesis: Review and assessment.

The contemporary genetic code and the process of protein biosynthesis most assuredly evolved from a simpler code and process. We believe that there was obligatory coevolution of the two and that the earlier code and process must have involved a more direct linkage between the amino acids and the information macromolecule. We propose that an early form of translating existed in which amino acids were attached directly to the 'messenger' RNA along the backbone as 2'OH aminoacyl esters. These esters then condensed with each other on the RNA backbone yielding a peptide covalently attached to the RNA, without the use of tRNA's and ribosomes. THis presentation is concerned with experimental data which indicate that such a simple translation system is possible and must have involved the following steps: (1) formation of the aminoacyl adenylate anhydride, (2) transfer of the amino acid from the adenylate to immidazole, (3) transfer of the amino acid from imidazole to 2'OH groups along the backbone of RNAs, (4) condensation of the amino acids to yield peptides. Steps (1)-(3) have been confirmed in chemical systems. Our preliminary evidence indicates step (4) is also possible. The aminoacylation of polyribonucleotides and the subsequent formation of peptides is a dynamic and experimentally accessible system for studying genetic coding specfities and our present studies are now concentrated on step (4), looking for such specifities.     

Transiently misacylated tRNA is a primer for editing of misactivated adenylates by class I aminoacyl-tRNA synthetases

The genetic code depends on amino acid fine structure discrimination by aminoacyl-tRNA synthetases. For isoleucyl- (IleRS) and valyl-tRNA synthetases (ValRS), reactions that hydrolyze misactivated noncognate amino acids help to achieve high accuracy in aminoacylation. Two editing pathways contribute to aminoacylation fidelity: pretransfer and post-transfer. In pretransfer editing, the misactivated amino acid is hydrolyzed as an aminoacyl adenylate, while in post-transfer editing a misacylated tRNA is deacylated. Both reactions are dependent on a tRNA cofactor and require translocation to a site located approximately 30 A from the site of amino acid activation. Using a series of 3'-end modified tRNAs that are deficient in either aminoacylation, deacylation, or both, total editing (the sum of pre- and post-transfer editing) was shown to require both aminoacylation and deacylation activities. These and additional results with IleRS are consistent with a post-transfer deacylation event initiating formation of an editing-active enzyme/tRNA complex. In this state, the primed complex processively edits misactivated valyl-adenylate via the pretransfer route. Thus, misacylated tRNA is an obligatory intermediate for editing by either pathway.     

A model for the coevolution of the genetic code and the process of protein synthesis: Review and assessment

The contemporary genetic code and the process of protein biosynthesis most assuredly evolved from a simpler code and process. We believe that there was obligatory coevolution of the two and that the earlier code and process must have involved a more direct linkage between the amino acids and the informational macromolecule. We propose that an early form of translating existed in which amino acids were attached directly to the ‘messenger’ RNA along the backbone as 2'OH aminoacyl esters. These esters then condensed with each other on the RNA backbone yielding a peptide covalently attached to the RNA, without the use of tRNAs and ribosomes. This presentation is concerned with experimental data which indicate that such a simple translation system is possible and must have involved the following steps: (1) formation of the aminoacyl adenylate anhydride, (2) transfer of the amino acid from the adenylate to imidazole, (3) transfer of the amino acid from imidazole to 2'OH groups along the backbone of RNAs (4) condensation of the amino acids to yield peptides. Steps (1)–(3) have been confirmed in chemical systems. Our preliminary evidence indicates step (4) is also possible. The aminoacylation of polyribonucleotides and the subsequent formation of peptides is a dynamic and experimentally accessible system for studying genetic coding specifities and our present studies are now concentrated on step (4), looking for such specifities.     

Active site of an aminoacyl-tRNA synthetase dissected by energy-transfer-dependent fluorescence.

Aminoacyl-tRNA synthetases establish the rules of the genetic code by catalyzing attachment of amino acids to specific transfer RNAs (tRNAs) that bear the anticodon triplets of the code. Each of the 20 amino acids has its own distinct aminoacyl-tRNA synthetase. Here we use energy-transfer-dependent fluorescence from the nucleotide probe N-methylanthraniloyl dATP (mdATP) to investigate the active site of a specific aminoacyl-tRNA synthetase. Interaction of the enzyme with the cognate amino acid and formation of the aminoacyl adenylate intermediate were detected. In addition to providing a convenient tool to characterize enzymatic parameters, the probe allowed investigation of the role of conserved residues within the active site. Specifically, a residue that is critical for binding could be distinguished from one that is important for the transition state of adenylate formation. Amino acid binding and adenylate synthesis by two other aminoacyl-tRNA synthetases was also investigated with mdATP. Thus, a key step in the synthesis of aminoacyl-tRNA can in general be dissected with this probe.     

Characterization of yeast seryl-tRNA synthetase active site mutants with improved discrimination against substrate analogues

The involvement of amino acids within the motif 2 loop of Saccharomyces cerevisiae seryl-tRNA synthetase (SerRS) in serine and ATP binding was demonstrated previously [B. Lenhard et al., J. Biol. Chem. 272 (1997) 1136-1141]. In our attempt to analyze the structural basis for the substrate specificity and to explore further the catalytic mechanism employed by S. cerevisiae SerRS, two new active site mutants, SerRS11 and SerRS12, were constructed. The catalytic effects of amino acid replacement at positions Lys287, Asp288 and Ala289 with purified wild-type and mutant seryl-tRNA synthetases were tested. The alteration of these semi-conserved amino acids interferes with tRNA-dependent optimization of serine recognition. Additionally, mutated enzymes SerRS11 (Lys287Thr, Asp288Tyr, Ala289Val) and SerRS12 (Lys287Arg) are less sensitive to inhibition by two competitive inhibitors: serine hydroxamate, an analogue of serine, and 5'-O-[N-(L-seryl)-sulfamoyl]adenosine, a stable analogue of aminoacyl adenylate, than the wild-type enzyme. SerRS mutants also display different activation kinetics for serine and serine hydroxamate, indicating that specificity toward the substrates is modulated by amino acid replacement in the motif 2 loop.     

Gramicidin S-synthetase. A further characterization of phenylalanine racemase, the light enzyme of gramicidin s-synthetase.

1. Chromatography on hydroxyapatite and on aminohexyl-Sepharose as well as isoelectric focusing were introduced as new effective purification procedures for phenylalanine racemase (EC 5.1.1.11). The enzyme preparations obtained were essentially homogeneous, as demonstrated by specific activity measurements and polyacrylamide gel electrophoresis. 2. The enzyme is not dissociable by sodium dodecyl sulfate. 3. Phenylalanine racemase is an acidic protein with an isoelectric point of approx. 4.6 (isoelectric focusing). 4. The Michaelis constants of L-Phe and D-Phe in the aminoacyl adenylate activation are 0.06 and 0.13 mM, respectively. 5. From our studies with structural analogues of phenylalanine we infer that the amino group of this amino acid is essential for its binding to the aminoacyl adenylate reaction center. The carboxyl group is not at all or only weakly bound. The benzene ring of phenylalanine which determines substrate recognition also seems to be of minor importance for substrate binding.     

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.     

First-principles molecular dynamics investigation of the D-amino acid oxidative half-reaction catalyzed by the flavoenzyme D-amino acid oxidase

Large-scale Car-Parrinello molecular dynamics simulations of D-alanine oxidation catalyzed by the flavoenzyme D-amino acid oxidase have been carried out. A model of the enzyme active site was built by starting from the enzyme X-ray structure, and by testing different subsystems comprising different sets of aminoacyl residues. In this process, the stability of the enzyme-substrate complex was taken as a measure of the accuracy of the model. The activated transfer of the amino acid alpha-hydrogen from the substrate to the flavin N5 position was then induced by constraining a suitable transfer reaction coordinate, and the free energy profile of the reaction was calculated. The evolution of electronic and structural properties of both enzyme-bound substrate and flavin cofactor along the reaction path is consistent with a hydride-transfer mechanism. The calculated free energy barrier for this process (13 kcal/mol) is in excellent agreement with the activation energy value derived from the experimentally determined rate constant for the corresponding enzyme-catalyzed reaction. The electronic distribution of the reduced flavin shows that the transferred electrons tend to be centered near the C4a position rather than delocalized over the flavin pyrimidine ring. This feature is mechanistically relevant in that such an electronic distribution may promote the subsequent enzyme-catalyzed reduction of molecular oxygen to yield hydrogen peroxide via a postulated flavin 4a-peroxide intermediate. These results also show that a first-principles molecular dynamics approach is suitable to study the mechanism of complex enzymatic processes, provided that a smaller, yet reliable, subsystem of the enzyme can be identified, and special computational techniques are employed to enhance the sampling of the reactive event.     

N-Glycans protect proteins from protease digestion through their binding affinities for aromatic amino acid residues

It was previously revealed [Yamaguchi, H., Nishiyama, T., and Uchida, M. (1999) J. Biochem. 126, 261-265] that N-glycans of both the high-mannose and complex types have binding affinity for aromatic amino acid residues. This study shows that free N-glycans protect proteins from protease digestion through their binding affinities for the aromatic amino acid residues exposed on protein molecules. Protease digestion of bovine pancreatic RNase A and bovine a-lactalbumin was depressed in solutions (1 mM or so) of free N-glycans of both the high-mannose and complex types. The increasing order of the protective effects of the N-glycans paralleled that of their affinities for aromatic amino acid residues; and the presence of aromatic amino acids practically abolished the protective effects of the N-glycans. The N-glycans also depressed the protease digestion of metallothionein, an aromatic amino acid-free protein, in agreement with the observation that the N-glycans also interact with the solvent-exposed aromatic amino acid residues of the proteases. Thus it seems probable that the N-glycans protect proteins from protease digestion by steric hindrance attributable to their binding affinity for the solvent-exposed aromatic amino acid residues of both substrate proteins and proteases.     

Dipeptide synthesis by an aminopeptidase from Streptomyces septatus TH-2 and its application to synthesis of biologically active peptides

Dipeptide synthesis by aminopeptidase from Streptomyces septatus TH-2 (SSAP) was demonstrated using free amino acid as an acyl donor and aminoacyl methyl ester as an acyl acceptor in 98% methanol (MeOH). SSAP retained its activity after more than 100 h in 98% MeOH, and in the case of phenylalanyl-phenylalanine methyl ester synthesis, the enzyme reaction reached equilibrium when more than 50% of the free phenylalanine was converted to the product. In an investigation of the specificity of SSAP toward acyl donors and acyl acceptors, SSAP showed a broad specificity toward various free amino acids and aminoacyl methyl esters. Furthermore, we applied SSAP to the synthesis of several biologically active peptides, such as aspartyl-phenylalanine, alanyl-tyrosine, and valyl-tyrosine methyl esters.     

Gramicidin S synthetase. Temperature dependence and thermodynamic parameters of substrate amino acid activation reactions

In the biosynthesis of the cyclic decapeptide antibiotic gramicidin S, the constituent amino acids are activated by a two-step mechanism involving aminoacyl adenylate and thio ester formation which are both reversible processes. The dissociation constants (KD) for the gramicidin S synthetase-substrate amino acid-thio ester complexes are 100-1000-fold lower compared to the KM data of the preceding aminoacyl adenylate reactions. The affinity for these substrates is appreciably higher at the thio template sites than at the aminoacyl adenylate reaction centers. Therefore, the activation equilibria are quantitatively shifted toward thio ester formation. A set of thermodynamic parameters for the activation processes was determined from the temperature dependence of the KM and KD data. Reaction enthalpies were obtained from a van't Hoff analysis of these constants. delta G degree for the substrate activation reactions of the heavy enzyme of gramicidin S synthetase (GS 2) is predominantly controlled by entropy contributions. In contrast, the overall activation and concomitant racemization of phenylalanine by phenylalanine racemase (GS 1) are exothermic processes which are distinguished by a small negative reaction entropy.     

A broadly applicable continuous spectrophotometric assay for measuring aminoacyl-tRNA synthetase activity.

We describe a convenient, simple and novel continuous spectrophotometric method for the determination of aminoacyl-tRNA synthetase activity. The assay relies upon the measurement of inorganic pyrophosphate generated in the first step of the aminoacylation of a tRNA. Pyrophosphate release is coupled to inorganic pyrophosphatase, to generate phosphate, which in turn is used as the substrate of purine nucleoside phosphorylase to catalyze the N-glycosidic cleavage of 2-amino 6-mercapto 7-methylpurine ribonucleoside. Of the reaction products, ribose 1-phosphate and 2-amino 6-mercapto 7-methylpurine, the latter has a high absorbance at 360 nm relative to the nucleoside and hence provides a spectrophotometric signal that can be continuously followed. The non-destructive nature of the spectrophotometric assay allowed the re-use of the tRNAs in question in successive experiments. The usefulness of this method was demonstrated for glutaminyl-tRNA synthetase (GlnRS) and tryptophanyl-tRNA synthetase. Initial velocities measured using this assay correlate closely with those assayed by quantitation of [3H]Gln-tRNA or [14C]Trp-tRNA formation respectively. In both cases amino acid transfer from the aminoacyl adenylate to the tRNA represents the rate determining step. In addition, aminoacyl adenylate formation by aspartyl-tRNA synthetase was followed and provided a more sensitive means of active site titration than existing techniques. Finally, this novel method was used to provide direct evidence for the cooperativity of tRNA and ATP binding to GlnRS.     

Proton release during the reductive half-reaction of D-amino acid oxidase

Changes in the net protonation of D-amino acid oxidase during binding of competitive inhibitors and during reduction by amino acids have been monitored using phenol red as a pH indicator. At pH 8.0, no uptake or release of protons from solution occurs upon binding the inhibitors benzoate, anthranilate, picolinate, or L-leucine. The Kd values for both picolinate and anthranilate were determined from pH 5.4 to 9.0. The results are consistent with a single group on the enzyme having a pK of 6.3 which must be unprotonated for tight binding, as is the case with benzoate binding (Quay, S., and Massey, V. (1977) Biochemistry 16, 3348-3354) and with tight binding of the inhibitor form with an unprotonated amino group. Upon reduction of the enzyme by amino acid substrates, two protons are released to solution. The first is released concomitantly with reduction to the reduced enzyme-imino acid charge transfer complex. The second is released only upon dissociation of the charge transfer complex to free reduced enzyme and imino acid. The first proton is assigned as arising from the amino acid group and the second from the amino acid alpha-hydrogen. These results are consistent with the flavin in reduced D-amino acid oxidase being anionic.     

Aminoacyl transfer from adenylate anhydride to the 2'OH groups along the backbone of polyribonucleotides

This work reports the transfer of the N-acetylglycine from the adenylate anhydride to the 2′OH groups along the backbone of homopolyribonucleotides. This transfer involves an N-acetylglycylimidazole intermediate; no transfer was observed in the absence of imidazole, and the rate of transfer was different for the various polynucleotides: poly U > poly A > poly C = poly G = 0. These results suggest that catalysis is necessary for transfer of aminoacyl from adenylates to polyribonucleotides and the data are consistent with a model involving a histidine residue in the active site of aminoacyl-tRNA synthetases. They are also consistent with a model for primordial protein formation involving polymerization of amino acids which are attached at the 2′OH groups along the polyribonucleotide backbone.     

Transacylation rates of (aminoacyl)adenosine moiety at the 3'-terminus of aminoacyl transfer ribonucleic acid

The rates of migration of the aminoacyl group (transacylation) between 2'-O-(aminoacyl)-tRNA and 3'-O-(aminoacyl)-tRNA were studied by the nuclear magnetic resonance (NMR) analyses of 3'-terminal fragment models, with regard to the significance of transacylation in the process of protein biosynthesis. 2'(3')-O-L-Alanyladenosine, -valyladenosine, -isoleucyladenosine, -phenylalanyladenosine, and -methionyladenosine, and 2'(3')-O-L-phenylalanyladenosine 5'-phosphate and methionyladenosine 5'-phosphate were chemically synthesized, and the rates of transacylation in deuterated buffer were directly measured by the NMR saturation transfer method. The dependences of transacylation rates on p2H and temperature were analyzed. The results indicate that the transacylation rates are significantly affected by the ionization states of the alpha-amino group of the amino acid moiety but not by the presence of the 5'-phosphate group of the adenylate moiety. The second-order rate constants for the base-catalyzed transacylation reactions were also determined for the ionized form (with alpha-N2H3+ group) of (aminoacyl)adenosines. The transacylation rates of (aminoacyl)adenosines in 1H2O solution at p1H 7.3 and 37 degrees C (intracellular environment) were evaluated as 3-11 s-1 for the 2' leads to 3' transacylation and 1-4 s-1 for the 3' leads to 2' transacylation, indicating that the transacylation rate of free aminoacyl-tRNA is slower than the overall rate of polypeptide chain elongation per ribosome. This suggests the presence of some enzymatic factor for enhancing the transacylation rates of aminoacyl-tRNAs in the polypeptide chain elongation process in vivo.     

Stereoselective formation of bis(alpha-aminoacyl) esters of 5'-AMP suggests a primitive peptide synthesizing system with a preference for L-amino acids

In the biosynthesis of proteins, each amino acid passes from the aminoacyl adenylate to become an amino acid ester and finally a 2' (3') peptidyl ester of the AMP residue at the end of a tRNA. Consequently, the chemistry of protein synthesis is the chemistry of aminoacyl and peptidyl AMP. Our data has revealed properties of 5'-AMP and its esters which should allow the preferential catalytic synthesis of L-amino acid peptides via a bis(2', 3'-aminoacyl) ester intermediate. Results in this paper concern one step in the proposed process and show that preexisting Ac-L-Phe monoester reacts about 2.5-times faster to form diester than preexisting Ac-D-Phe monoester.     

Purification and characterization of actinomycin synthetase I, a 4-methyl-3-hydroxyanthranilic acid-AMP ligase from Streptomyces chrysomallus.

Actinomycin synthetase I was purified to homogeneiety from actinomycin-producing Streptomyces chrysomallus. The purified enzyme is a single polypeptide chain of M(r) 45,000. It catalyzes the formation of the adenylate of 4-methyl-3-hydroxyanthranilic acid (4-MHA) from the free acid and ATP in an equilibrium reaction. 4-MHA is the precursor of the chromophoric part of actinomycin. By using the 4-MHA analogue, 4-methyl-3-hydroxybenzoic acid, as a model substrate it could be established that the equilibrium constant Keq is independent on enzyme concentration, which suggests that no stoichiometric acyladenylate-enzyme complex is formed in contrast to observations made with aminoacyl adenylates formed by aminoacyl-tRNA synthetases or multifunctional peptide synthetases. Actinomycin synthetase I does not charge itself with substrate carboxylic acid via a covalent thioester bond as is usual for amino acid activation in non-ribosomal peptide synthesis. In addition, the enzyme does not act as an acyl-coenzyme A ligase as revealed by its inability to release AMP in the presence of 4-MHA or other structurally related aromatic carboxylic acids, coenzyme A and ATP. Additional analysis of the activation reaction showed that it is exothermic, whereas the free enthalpy change delta G0 is positive due to a negative entropy change indicating a strong influence of restriction of random motion on the course of the reaction. Determinations of Km and kcat of various substrate carboxylic acids revealed the highest kcat/Km ratio for the natural substrate 4-MHA. From these properties, actinomycin synthetase I represents the prototype of novel chromophore activating enzymes involved in non-ribosomal synthesis of chromopeptide lactones in streptomycetes.     

Active site titration of gramicidin S synthetase 2: evidence for misactivation and editing in non-ribosomal peptide biosynthesis

The catalytic competence of gramicidin S synthetase 2 (GS2) was determined by following the kinetics of PP(i) generation using active site titration measurements with [gamma-(32)P]ATP. The initial 'burst' of product formation can be correlated to the generation of the aminoacyl adenylate:enzyme complexes at the four amino acid activation domains and the subsequent aminoacylation of carrier domains, followed by a slow linear turnover of substrate due to breakdown of the intermediate. Simultaneous activation of all four amino acid substrates at a saturating concentration displayed a consumption of 8.3 ATP/GS2. In the presence of single amino acids, a binding stoichiometry higher than the anticipated two ATP per active site was obtained, implying misactivation at non-cognate domains. Breakdown of acyladenylate intermediates reflects a possible corrective mechanism by which the enzyme controls the fidelity of product formation.