Kinetic and thermodynamic properties of wild-type and engineered mutants of tyrosyl-tRNA synthetase analyzed by pyrophosphate-exchange kinetics.

The first step of the reaction catalyzed by the aminoacyl-tRNA synthetases is the formation of enzyme-bound aminoacyl adenylate. The steady-state kinetics of this step has conventionally been studied by measuring the rate of isotopic exchange between pyrophosphate and ATP. A simple kinetic analysis of the pyrophosphate-exchange reaction catalyzed by the tyrosyl-tRNA synthetase from Bacillus stearothermophilus is given in which all the observed rate and binding constants can be assigned to identifiable physical processes under a variety of limiting conditions. The free energies of binding to the enzyme of tyrosine, ATP, and the transition state for tyrosyl adenylate formation can be measured in relatively straightforward experiments. The excellent agreement between parameters measured in these experiments and those from earlier pre-steady-state kinetics confirms that the intermediates isolated in the presteady state are kinetically competent. The dissociation constant of ATP from the unligated enzyme, a constant that has previously been experimentally inaccessible, has been measured for wild-type and several mutant enzymes. The changes in enthalpy and entropy of activation on mutation have been measured by a rapid procedure for mutants that have altered contacts with tyrosine and ATP. Those mutants that have large changes of enthalpy and entropy of binding are likely to have structural changes and so warrant further examination by protein crystallography.     

Internal thermodynamics of position 51 mutants and natural variants of tyrosyl-tRNA synthetase

Natural variation and evolution impose structural changes on an enzyme that can affect the energetics of catalysis. The energy profile of reaction could, in theory, be altered in three distinct ways: uniform binding changes, differential binding changes, and catalysis of elementary steps. Residue threonine-51 of tyrosyl-tRNA synthetase from Bacillus stearothermophilus is subject to natural variation, being replaced by alanine and proline in the enzymes from Bacillus caldotenax and Escherichia coli, respectively. The consequences of this variation on the energetics of formation of tyrosyl adenylate have been investigated by constructing free energy profiles for wild-type and mutant enzymes constructed by introducing these amino acids into the B. stearothermophilus enzyme. Mutation of Thr-51 to alanine, proline, and cysteine by site-directed mutagenesis improves the stabilization of the transition state in the formation of tyrosyl adenylate. Most marked is the mutation Thr-51----Pro-51 which stabilizes the transition state by 2.2 kcal/mol and accelerates the forward rate 20-fold to a level near that of the enzyme from E. coli. However, the improved transition-state binding is accompanied by an even greater stabilization of tyrosyl adenylate. This reduces the rate of pyrophosphorolysis of tyrosyl adenylate and/or weakens the binding of pyrophosphate in the reverse reaction, shifting the equilibrium between enzyme-bound reactants greatly in favor of the enzyme-intermediate complex. The more stable mutant enzyme-tyrosyl adenylate complexes have lower rates of aminoacylation, suggesting that mutations which stabilize the intermediate slow down the subsequent transfer of tyrosine from tyrosyl adenylate to tRNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Use of binding energy in catalysis analyzed by mutagenesis of the tyrosyl-tRNA synthetase

The utilization of enzyme-substrate binding energy in catalysis has been investigated by experiments on mutant tyrosyl-tRNA synthetases that have been generated by site-directed mutagenesis. The mutants are poorer enzymes because they lack side chains that form hydrogen bonds with ATP and tyrosine during stages of the reaction. The hydrogen bonds are not directly involved in the chemical processes but are at some distance from the seat of reaction. The free energy profiles for the formation of enzyme-bound tyrosyl adenylate and the equilibria between the substrates and products were determined from a combination of pre-steady-state kinetics and equilibrium binding methods. By comparison of the profile of each mutant with wild-type enzyme, a picture is built up of how the course of reaction is affected by the influence of each side chain on the energies of the complexes of the enzyme with substrates, transition states, and intermediates (tyrosyl adenylate). As the activation reaction proceeds, the apparent binding energies of certain side chains with the tyrosine and nucleotide moieties increase, being weakest in the enzyme-substrate complex, stronger in the transition state, and strongest in the enzyme-intermediate complex. Most marked is the interaction of Cys-35 with the 3'-hydroxyl of the ribose. Removal of the side chain of Cys-35 leads to no change in the dissociation constant of ATP but causes a 10-fold lowering of the catalytic rate constant. It contributes no net apparent binding energy in the E X Tyr X ATP complex and stabilizes the transition state by 1.2 kcal/mol and the E X Tyr-AMP complex by 1.6 kcal/mol.(ABSTRACT TRUNCATED AT 250 WORDS)     

Free energy of hydrolysis of tyrosyl adenylate and its binding to wild-type and engineered mutant tyrosyl-tRNA synthetases

The equilibrium constant for the formation of tyrosyl adenylate and pyrophosphate from ATP and tyrosine in solution has been measured by applying the Haldane relationship to wild-type and three mutant tyrosyl-tRNA synthetases from Bacillus stearothermophilus. The formation constant (=[Tyr-AMP] [PPi]/[ATP] [Tyr]) at pH 7.78, 25 degrees C, and 10 mM MgCl2 is (3.5 +/- 0.5) X 10(-7). This corresponds to a free energy of hydrolysis of tyrosyl adenylate at pH 7.0 and 25 degrees C of -16.7 kcal mol-1. All necessary rate constants had been determined previously for the calculations apart from the dissociation constant of tyrosyl adenylate from its enzyme-bound complex. This was measured by taking advantage of the 100-fold difference in hydrolysis rates of the tyrosyl adenylate when sequestered by the enzyme and when free in solution. These are technically difficult measurements because the dissociation constants are so low and the complexes unstable. The task was simplified by using mutants prepared by site-directed mutagenesis. These were designed to have different rate and equilibrium constants for dissociation of tyrosyl adenylate from the enzyme-bound complexes. The dissociation constants were in the range (3.5-38) X 10(-12) M, with that for wild type at 13 X 10(-12) M. The four enzymes all gave consistent data for the formation constant of tyrosyl adenylate in solution. This not only improves the reliability of the measurement but also provides confirmation of the reliability of the measured kinetic constants for the series of enzymes.     

Active site stoichiometry of L-phenylalanine: tRNA ligase from Escherichia coli K(-10).

The existence of two active siter per molecule of L-phenylalanine:tRNA ligase from Escherichia coli K(-10) has been demonstrated by isolation of the E-aminoacyl adenylate and tel filtration and the nitrocellulose filter assay at pH 5.0 revealed the same stoichiometry for the E-tRNAPhe comples as protection against degradation by snake venom phosphodiesterase and equilibrium gel filtration at pH 7.5. Using a fluorescence titration technique, it was found that the dissociation constant for ligase-tRNAPhe complex is decreased 20-fold when the hydrogen ion concentration is changed from pH 6.0 to pH 5.0. The existence of two active sites binding the aminoacyl adenylate intermediate was demonstrated by gel filtration and retention on DEAE-cellulose filters. "Burst" experiments indicated that two sites were involved in a rapid ATP consumption at conditions of catalytic amino acid activation. Furthermore, it was observed that the activated amino acid could be transferred from both sites to cognate tRNA.     

A fluorescence spectroscopic study of glutaminyl-tRNA synthetase from Escherichia coli and its implications for the enzyme mechanism

Interaction between Escherichia coli glutaminyl-tRNA synthetase (GlnRS) and its substrates have been studied by fluorescence quenching. In the absence of other substrates, glutamine, tRNA(Gln) and ATP bind with dissociation constants of 460, 0.22 and 180 microM, respectively. The presence of other substrates has either no effect or, at best a weak effect, on binding of ligands. Attempts to isolate enzyme-bound aminoacyl adenylate did not succeed. Binding of the phosphodiester, 5'-(methyl)adenosine monophosphate (MeAMP), to GlnRS was studied by fluorescence quenching and radioactive-ligand binding. tRNA also only has a weak effect on phosphodiester binding. Selectively pyrene-labeled GlnRS was used to obtain shape and size information for free GlnRS. A comparison with the GlnRS shape in the GlnRS/tRNA(Gln) crystal structure indicates that no major change in shape and size occurs upon tRNA(Gln) binding to GlnRS. 5,5'-Bis(8-anilino-1-naphthalene sulfonate) (bis-ANS), a non-covalent fluorescent probe, was also used to probe for conformational changes in GlnRS. This probe also indicated that no major conformational change occurs upon tRNA(Gln) binding. We conclude that lack of tRNA-independent pyrophosphate-exchange activity in this enzyme is not a result of either lack of glutamine or ATP binding in the absence of tRNA, or formation of aminoacyl adenylate and slow release of pyrophosphate. A conformational change is implied upon tRNA binding, which promotes pyrophosphate exchange. Fluorescence studies indicate that this conformational change must be limited and local in nature.     

Structure-activity relationships in engineered proteins: analysis of use of binding energy by linear free energy relationships

The activity of mutant enzymes can be analyzed quantitatively by structure-activity relationships in a manner analogous to Br?nsted or Hammett plots for simple organic reactions. The slopes of such plots, the beta values, indicate for the enzymatic reactions the fraction of the overall binding energy used in stabilizing particular complexes. In particular, information can be derived about the interactions between the enzyme and the transition state. The activities of many mutant tyrosyl-tRNA synthetases fit well simple linear free energy relationships. The formation of enzyme-bound tyrosyl adenylate (E.Tyr-AMP) from enzyme-bound tyrosine and ATP (E.Tyr-ATP) results in an increase in binding energy between the enzyme and the side chain of tyrosine and the ribose ring of ATP. Linear free energy plots of enzymes mutated in these positions give the fraction of the binding energy change that occurs on formation of the transition state for the chemical reaction and the various complexes. It is shown that groups that specifically stabilize the transition state of the reaction are characterized by beta values much greater than 1. This is found for residues that bind the gamma-phosphate of ATP (Thr-40 and His-45) and have previously been postulated to be involved in transition-state stabilization.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isoleucyl-tRNA synthetase from Escherichia coli MRE 600. Different pathways of the aminoacylation reaction depending on presence of pyrophosphatase, order of substrate addition in the pyrophosphate exchange, and substrate specificity with regard to ATP analogs

The substrate specificity of isoleucyl-tRNA synthetase from Escherichia coli MRE 600 with regard to ATP analogs has been compared with the results obtained with isoleucyl-tRNA synthetase from yeast. The enzyme from E. coli is less specific, the two enzymes exhibit different topographies of their active centres. The order of substrate addition to isoleucyl-tRNA synthetase from E. coli MRE 600 has been investigated by bisubstrate kinetics, product inhibition and inhibition by substrate analogs. The inhibition studies were done in the aminoacylation and in the pyrophosphate exchange reaction, the aminoacylation was investigated in the absence and presence of inorganic pyrophosphatase. As found for isoleucyl-tRNA synthetase from yeast, the results of the pyrophosphate exchange studies indicate the possibility of formation of E . Ile-AMP . ATP complexes by random addition of one ATP and one isoleucine molecule, followed by adenylate formation, release of pyrophosphate and subsequent addition of a second molecule of ATP. For the aminoacylation in the absence of pyrophosphatase, a rapid-equilibrium random ter addition of the substrates is found whereas the enzyme from yeast exhibits a steady-state ordered ter-ter mechanism; in the presence of pyrophosphatase the mechanism is bi-uni uni-bi ping-pong similarly as observed for the yeast enzyme. A comparison of inhibition patterns obtained with N(6)-benzyladenosine 5'-triphosphate under different assay conditions (spermine or magnesium ions, addition of pyrophosphatase) indicates that even more than two pathways of the aminoacylation may exist. The catalytic cycles of the two mechanisms derived from the observed orders of substrate addition and product release include the same enzyme substrate complex (E . tRNA . Ile-AMP) for the aminoacyl transfer reaction. The kcat values, however, are considerably different: kcat of the sequential pathway is about 40% lower than kcat of the ping-pong mechanism.     

Reconstruction by site-directed mutagenesis of the transition state for the activation of tyrosine by the tyrosyl-tRNA synthetase: a mobile loop envelopes the transition state in an induced-fit mechanism

Site-directed mutagenesis of the tyrosyl-tRNA synthetase followed by kinetic studies has shown that residues which are distant from the active site of the free enzyme are brought into play as the structure of the enzyme changes during catalysis. Positively charged side chains which are in mobile loops of the enzyme envelope the negatively charged pyrophosphate moiety during the transition state for the formation of tyrosyl adenylate in an induced-fit mechanism. Residues Lys-82 and Arg-86, which are on one side of the rim of the binding site pocket, and Lys-230 and Lys-233, which are on the other side, have been mutated to alanine residues and also to asparagine or glutamine. The resultant mutants still form 1 mol of tyrosyl adenylate/mol of dimer but with rate constants up to 8000 times lower. Construction of difference energy diagrams reveals that all the residues specifically interact with the transition state for the reaction and with pyrophosphate in the E.Tyr-AMP.PPi complex. Yet, the epsilon-NH3+ groups of Lys-230 and Lys-233 in the crystalline enzyme are at least 8 A too far away to interact with the pyrophosphate moiety in the transition state at the same time as do Lys-82 and Arg-86. Binding of substrates must, therefore, induce a conformational change in the enzyme that brings these residues into range. Consistent with this proposal is the observation that all four residues are in flexible regions of the protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Redesigning the PheA domain of gramicidin synthetase leads to a new understanding of the enzyme's mechanism and selectivity

The PheA domain of gramicidin synthetase A, a non-ribosomal peptide synthetase, selectively binds phenylalanine along with ATP and Mg2+ and catalyzes the formation of an aminoacyl adenylate. In this study, we have used a novel protein redesign algorithm, K*, to predict mutations in PheA that should exhibit improved binding for tyrosine. Interestingly, the introduction of two predicted mutations to PheA did not significantly improve KD, as measured by equilibrium fluorescence quenching. However, the mutations improved the specificity of the enzyme for tyrosine (as measured by kcat/KM), primarily driven by a 56-fold improvement in KM, although the improvement did not make tyrosine the preferred substrate over phenylalanine. Using stopped-flow fluorometry, we examined binding of different amino acid substrates to the wild-type and mutant enzymes in the pre-steady state in order to understand the improvement in KM. Through these investigations, it became evident that substrate binding to the wild-type enzyme is more complex than previously described. These experiments show that the wild-type enzyme binds phenylalanine in a kinetically selective manner; no other amino acids tested appeared to bind the enzyme in the early time frame examined (500 ms). Furthermore, experiments with PheA, phenylalanine, and ATP reveal a two-step binding process, suggesting that the PheA-ATP-phenylalanine complex may undergo a conformational change toward a catalytically relevant intermediate on the pathway to adenylation; experiments with PheA, phenylalanine, and other nucleotides exhibit only a one-step binding process. The improvement in KM for the mutant enzyme toward tyrosine, as predicted by K*, may indicate that redesigning the side-chain binding pocket allows the substrate backbone to adopt productive conformations for catalysis but that further improvements may be afforded by modeling an enzyme:ATP:substrate complex, which is capable of undergoing conformational change.     

Protection of an unstable reaction intermediate examined with linear free energy relationships in tyrosyl-tRNA synthetase

Linear free energy relationships (LFERs) are powerful tools in the search to understand the relationship between molecular structure and activity. They frequently link the changes in the rate constants for a reaction to changes in the equilibrium constant caused by alterations in structure. In physical-organic chemistry, these have been interpreted to give information on the structure of the transition state. Similar phenomena have been observed for reactions catalyzed by a series of engineered mutants of tyrosyl-tRNA synthetase from Bacillus stearothermophilus. LFERs are applied in this study to probe how the enzyme minimizes its side reactions. A linear free energy relationship is shown between the binding of the unstable enzyme-tyrosyl adenylate complex and its rate constant of hydrolysis. However, mutations of a key residue, His48, show significant deviation from the relationship, implying a role for the side chain in protection of the complex from hydroxide attack. A second linear free energy relationship is shown linking the rate and equilibrium constants for tyrosyl adenylate binding to the enzyme. Four distinct classes of mutation are discussed in the context of this relationship. The data from all but one of these groups of mutations conform well to a linear free energy relationship between the dissociation rate and dissociation equilibrium constants for the enzyme-tyrosyl adenylate complex with slope beta = 1.01 +/- 0.08. The specificity of binding of tyrosyl adenylate is determined solely by its dissociation rate constant of the intermediate, and the mutations have relatively little effect on the enzyme-tyrosyl adenylate association rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Yellow lupin (Lupinus luteus) aminoacyl-tRNA synthetases. Isolation and some properties of enzyme-bound valyl adenylate and seryl adenylate.

As a continuation of our studies on plant (yellow lupin, Lupinus luteus) aminoacyl-tRNA synthetases we describe here formation and some properties of valyl-tRNA synthetase-bound valyl adenylate (EVal(Val-AMP)) and seryl-tRNA synthetase-bound seryl adenylate (ESer(Ser-AMP)). Valyl-tRNA synthetase-bound valyl adenylate was detected and isolated by several approaches in the pH range 6--10. In that range inorganic pyrophosphatase increases the amount of valyl adenylate by factor 1.8 regardless of pH. 50% of valine from the EVal(Val-AMP) complex isolated by Sephadex G-100 gel filtration was transferred to tRNA with a rate constant greater than 4 min-1 (pH 6.2, 10 degrees C). The ratio of valine to AMP in the enzyme-bound valyl adenylate is 1 : 1 and it is not changed by the presence of periodate-oxidized tRNA. In contrast to enzyme-bound valyl adenylate, formation of ESer(Ser-AMP) is very sensitive to pH. Inorganic pyrophosphatase increases the amount of seryl adenylate by a factor 6 at pH 8.0 and 30 at pH 6.9 60% of serine from the ESer(Ser-AMP) complex was transferred to tRNA with a rate constant greater than 4 min-1 (pH 8.0, 0 degrees C). The ratio of serine to AMP in the enzyme-bound seryl adenylate is 1 : 1. The rate of synthesis of the enzyme-bound aminoacyl adenylates was measured by ATP-PPi exchange. Michaelis constants for the substrates of valyl-tRNA and seryl-tRNA synthetases in ATP-PPi exchange were determined. Effects of pH, MgCl2 and KCl on the initial velocity of aminoacyl adenylate formation are described. For comparison, catalytic indices in the aminoacylation reactions catalyzed by both lupin enzymes are given and effects of pH, MgCl2 and KCl on tRNA aminoacylation are presented as well. Under some conditions, e.g. at low pH or high salt concentration, lupin valyl-tRNA and seryl-tRNA synthetase are active exclusively in ATP-PPi exchange reaction.     

Tryptophanyl adenylate formation by tryptophanyl-tRNA synthetase from Escherichia coli

By gel filtration and titration on DEAE-cellulose filters we show that Escherichia coli tryptophanyl-tRNA synthetase forms tryptophanyl adenylate as an initial reaction product when the enzyme is mixed with ATP-Mg and tryptophan. This reaction precedes the synthesis of the tryptophanyl-ATP ester known to be formed by this enzyme. The stoichiometry of tryptophanyl adenylate synthesis is 2 mol per mole of dimeric enzyme. When this reaction is studied either by the stopped-flow method, by the fluorescence changes of the enzyme, or by radioactive ATP depletion, three successive chemical processes are identified. The first two processes correspond to the synthesis of the two adenylates, at very different rates. The rate constants of tryptophanyl adenylate synthesis are respectively 146 +/- 17 s-1 and 3.3 +/- 0.9 s-1. The third process is the synthesis of tryptophanyl-ATP, the rate constant of which is 0.025 s-1. The Michaelis constants for ATP and for tryptophan in the activation reaction are respectively 179 +/- 35 microM and 23.9 +/- 7.9 microM, for the fast site, and 116 +/- 45 microM and 3.7 +/- 2.2 microM, for the slow site. No synergy between ATP and tryptophan can be evidenced. The data are interpreted as showing positive cooperativity between the subunits associated with conformational changes evidenced by fluorometric methods. The pyrophosphorolysis of tryptophanyl adenylate presents a Michaelian behavior for both sites, and the rate constant of the reverse reaction is 360 +/- 10 s-1 with a binding constant of 196 +/- 12 microM for inorganic pyrophosphate (PPi).(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for single mechanism for aminoacyl-tRNA synthetases including aminoacyl adenylates as intermediates.

The rate of transfer of amino acid from enzyme-bound aminoacyl adenylate to tRNA has been compared with the rate of esterification of free amino acid. The approach of L?vgren et al. (L?vgren, T. N. E., Heinonen, J., and Loftfield, R. B. (1975) J. Biol. Chem. 250, 3854-3860) was used, with 14C in the aminoacyl adenylate and 3H in the free amino acid and with both the lysine and isoleucine systems of Escherichia coli. In both systems kinetic analyses show more rapid transfer from the preformed enzyme complex when interference by the back reaction with inorganic pyrophosphate was eliminated. Parallel experiments, in which the amount of enzyme complex was measured, confirmed that aminoacyl adenylate is an intermediate in both systems. No evidence was found for an alternative mechanism.     

Binding of tyrosine, adenosine triphosphate and analogues to crystalline tyrosyl transfer RNA synthetase

Crystalline complexes of tyrosyl tRNA synthetase were prepared with the following substrates and substrate analogues: ATP, AMP, α-β methylene ATP, tyrosine and tyrosinyl adenylate. Using ¹⁴C-labelled ligands, the binding constants for tyrosine and ATP to crystals were shown to be similar to those observed in solution. Two tyrosine molecules were found to bind to the symmetrical dimer in the crystalline enzyme, while only one tyrosine binds with high affinity in solution. Electron density difference maps show that tyrosine and the AMP derivatives all bind at the same site, in a cleft 10 Å deep at one side of the pleated sheet, tyrosine binding over 100 times more strongly. The phosphate groups of AMP and ATP are not unambiguously observed in the difference electron density maps. Tyrosinyl adenylate is clearly delineated in the electron density difference map, with the tyrosyl side-chain occupying the site previously observed. The adenosine group is in a wide cup-like depression outside the pocket, lying between the carboxyl-terminal continuations of strands 3 and 5 of the pleated sheet. The adenine ring is lying against an α-helix. The binding of tyrosinyl adenylate causes no detectable conformational changes of the enzyme.     

Characterization of EntF as a serine-activating enzyme.

EntF is the enzyme responsible for serine activation during the biosynthesis of enterobactin (a cyclic trimer of N-dihydroxybenzoyl serine) in Escherichia coli. EntF has been overexpressed and purified to > 90% homogeneity. The enzyme has been shown to complement the entF- MK1 strain in the synthesis of 2,3-dihydroxybenzoyl serine derivatives and exhibits L-serine-dependent ATP[32P] pyrophosphate exchange activity with a Km for serine of 260 mM and a turnover number of 760 min-1. Release of PPi during incubation of EntF with serine and ATP was observed, but with a low turnover number of 1.0 min-1. These results suggested the presence of an enzyme-bound intermediate, which has been shown by gel filtration analysis to be (L-serine)adenylate.     

Investigation of transition-state stabilization by residues histidine-45 and threonine-40 in the tyrosyl-tRNA synthetase

We have analyzed various mutations involving residues Thr-40 and His-45 in the tyrosyl-tRNA synthetase of Bacillus stearothermophilus. The utilization of binding energy in catalysis of tyrosyl adenylate formation from tyrosine and ATP was determined from the free energy profiles for the mutant enzymes. Our results confirm that the side chains of Thr-40 and His-45 provide a binding site for the pyrophosphoryl portion of the transition state of this reaction and for pyrophosphate in the reverse reaction. Deletion of these side chains destabilizes the transition-state by 4.9 and 4.1 kcal mol-1, respectively, consistent with a charged hydrogen-bonding interaction. To examine the role of His-45 further, we constructed the potentially conservative mutations His----Gln-45 and His----Asn-45. Both mutant enzymes are debilitated compared with the native enzyme. The His----Gln-45 enzyme is more active than enzyme in which the complete side chain is deleted (His----Ala-45), and so in this location glutamine is a semiconservative replacement. In contrast, the His----Asn-45 mutation is significantly worse than simple deletion of the side chain, indicating that asparagine at this position causes active destabilization of the transition state compared to His----Ala-45. The amide-NH2 of glutamine may be considered stereochemically equivalent to the epsilon-NH of histidine whereas the amide-NH2 of asparagine is comparable to the delta-NH of histidine. The results suggest that the epsilon-NH rather than the delta-NH group of His-45 is involved in the transition-state stabilization.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Binding of bile salts to pancreatic colipase and lipase.

The binding of conjugated bile salts to pancreatic colipase and lipase has been studied by equilibrium dialysis and gel filtration. The results indicate that at physiological ionic strength and pH, conjugated bile salts bind as micelles to colipase: 12-15 moles/mole of colipase for the dihydroxy conjugates and 2-4 for the trihydroxy conjugates. No binding of bile salt takes place from monomeric solutions. Under the same experimental conditions, only 1-2 moles of conjugated dihydroxy bile salts bind to pancreatic lipase.     

Aminoacyl-tRNA synthetases from Bacillus stearothermophilus. Asymmetry of substrate binding to tyrosyl-tRNA synthetase.

The interaction of L-tyrosine, L-tyrosyladenylate and tRNA-Tyr with tyrosyl-tRNA synthetase from Bacillus stearothermophilus was studied by equilibrium dialysis, gel filtration and fluorescence spectroscopy. The enzyme, which consists of two identical subunits (mol. wt 2 x 44000), binds only a single molecule of L-tyrosine per dimer with a K-d of 2 x 10-5 M at pH 7.8 and 23 degrees C. The tyrosyl-tRNA synthetase--tyrosyladenylate complex which was isolated by gel filtration also has one adenylate bound per dimeric enzyme molecule. In contrast, two tRNA-Tyr molecules bind per enzyme dimer, but the two binding sites are not equivalent having K-d values of 2 x 10-7 M and 1.3 x 10-6 M respectively at pH 6.5 and 25 degrees C. Since crystallographic analysis of the free enzyme [2] shows that the monomer is the asymmetric unit, the data indicate that substrate binding induces asymmetry in the enzyme.