Conformational changes during enzyme catalysis: role of water in the transition state

The entropy of activation for the synthesis of Ile-tRNA is high and positive. The only likely source of a high delta S is the loss of structured water as the enzyme . substrate complex moves toward the transition state. This requires a change in the orientation or nature of water-organizing residues in the interface between the enzyme . substrate complex and the water. Such changes, which may be some distance from the "active site," are coupled to the active site in such a way that the increased entropy and decreased free energy of the water--enzyme interface is available at the "active site" to reduce the free energy of activation. The effects of Hofmeister anions on KmS and KcatS are consistent with the entropy data.

The catalytic mechanism of the glutamyl-tRNA synthetase from Escherichia coli. Detection of an intermediate complex in which glutamate is activated

Up to now it was not possible to isolate an enzyme . adenylate complex after mixing the glutamyl-tRNA synthetase from Escherichia coli with ATP, MgCl2, and glutamate. This enzyme catalyzes an AMP-dependent and PPi-independent deacylation of Glu-tRNAGlu. The labeled glutamate which disappears from Glu-tRNAGlu in the presence of AMP remains linked to the enzyme in a complex isolated by filtration on nitrocellulose discs. The addition of tRNAGlu to this reaction mixture at the deacylation plateau gives rise to a synthesis of Glu-tRNAGlu, via an ATP-independent reaction. These results indicate the existence of the following equilibrated reaction catalyzed by the glutamyl-tRNA synthetase E + Glu-tRNAGlu + AMP in equilibrium E . AMP approximately Glu + tRNAGlu. This transfer of glutamate from an activated complex to tRNAGlu indicates that the formation of glutamyl-tRNA is catalyzed via a two-step reaction mechanism. The AMP-dependent and PPi-independent deacylation of Glu-tRNAGlu is the rate-limiting step of the reverse of the AMP- and PPi-dependent deacylation.

tRNA in developing human placenta

Amino acid acceptor activity of tRNA in the human placenta as measured throughout gestation was found to be the lowest in post-term placenta. Aminoacylation of tRNA proceeded with maximum activity in the stage of formation of the placenta.

Arginyl-transfer ribonucleic acid synthetase of Bacillus stearothermophilus. Purification and kinetic analysis

Arginyl-tRNA synthetase from Bacillus stearothermophilus (NCA 1518) has been purified 880-fold to apparent homogeneity as demonstrated by electrophoresis in the presence of sodium dodecyl sulphate. The molecular weight is 59 000 as confirmed by Sephadex G-100 and by sucrose gradient ultracentrifugation. The enzyme is monomeric, no subunits were detected. Its cognate tRNA induces an apparent increase in molecular weight suggesting the dimerisation of the enzyme. Nevertheless, it is not obvious that the enzyme dimer forms prior to the aminoacylation reaction catalysed by the enzyme. An ATPase activity was found associated to the synthetase but can be neglected because the ATP consumption is too low for hampering the arginyl-tRNA synthetase activity. The order of addition of substrates and release of products has been studied by measurements of initial velocity, product inhibition and dead-end inhibition. The nature of the kinetic patterns indicates that the aminoacylation reaction conforms to the classical concept of the mechanism which includes the formation of an enzyme-bound aminoacyl-adenylate as an intermediate in the first step followed by transfer of the amino acid to tRNA. The first partial reaction, measured by the ATP-32PPi exchange or AMP synthesis in the presence of ATP and arginine, requires tRNA, which is consistent with the model in which tRNAArg is an activator of the arginyladenylate synthesis.

[Fluorescence spectroscopy studies of interactions of leucyl-tRNA-synthetase with substrates]

Interactions of leucyl-tRNA synthetase with substrates were studied by fluorescence spectroscopy. The formation of enzyme-substrate complexes results in the quenching of protein fluorescence. The equilibrium binding constants were determined for L-leucine, ATP, tRNAleu and leucyladenylate. It is shown that the interaction of the enzyme with ATP or tRNAleu leads to 10-30-fold increase in the binding constants for subsequent interaction of the second substrate. The data obtained indicate to the cooperative interaction between ATP and tRNA binding sites.

The stereochemical course of amino acid activation by methionyl- and tyrosyl-tRNA synthetases

Stereochemical analysis has long been recognised as a powerful tool for elucidating the mechanisms of chemical and enzyme-catalysed reactions. Although much is known about the stereochemical course of reactions at saturated carbon, phosphate and thiophosphate esters whose ligands to phosphorus are also tetrahedrally disposed, are capable in principle of revealing sterochemical information about events at the active site of enzymes that transform such substrates. Nucleotidyl transferases are a group of enzymes which in general selectively use one of the diastereoisomers of a nucleoside 5'(1-thiotriphosphate), such as isomers A and B of adenosine 5'(1-thiotriphosphate), designated ATP alpha S-A and ATP alpha S-B, and allow investigation of the stereochemical course of nucleotidyl transfer. We have developed a simple method based on 31P nuclear magnetic resonance spectroscopy for determining the stereochemical course of these reactions, and using this method show here that the nucleotidyl transfer step in two aminoacyl-tRNA synthetases from Escherichia coli occurs with inversion of configuration at phosphorus. These observations greatly constrain the mechanistic possibilities for these enzymes, and are interpreted most simply as a direct 'in line' transfer from ATP to the amino acid.

Transfer RNA control of the activation of isomeric tRNATrp's

Previous studies of the homologous aminoacylations of Escherichia coli and yeast tRNATrp's terminating in 2'- and 3'-deoxyadenosine established that E. coli tryptophanyl-tRNA synthetase activates its cognate tRNA preferentially on the 2' position, while the corresponding yeast enzyme utilizes the 3' position on its homologous substrate tRNA. As this seemed to be the only change in positional specificity during evolution, the heterologous activations were investigated in an effort to determine the basis for this change. Remarkably, E. coli tRNATrp terminating in 3'-deoxyadenosine was found to be the preferred substrate for both the E. coli and yeast activating enzymes, while the same tryptophanyl-tRNA synthetase preparations both activated the isomeric yeast tRNATrp's preferentially on the 3' position. Thus, the preferred position of activation was found to be specified by the tRNA rather than the activating enzyme and, additionally, to be due to some process not reflected in initial velocity measurements. The variable utilization of individual modified aminoacyl-tRNA's as substrates in an enzyme-catalyzed deacylation process appears to provide the most likely explanation for the experimental observations.

Isolation and binding properties of leucyl-tRNA synthetase from Escherichia coli MRE 600

A procedure for the large-scale isolation of leucyl-tRNA synthetase from E. cole MRE 600 is described: The enzyme was purified about 320-fold to homogeneity by precipitation with cetyl-trimethyl-ammonium bromide, two consecutive chromatographies on DEAE-cellulose and three on hydroxyapatite with an over-all yield of 4%. The molecular weight of leucyl-tRNA synthetase from E. coli MRE 600 was found to be 99 000 daltons. Bindings studies by ultracentrifugation and equilibrium partition showed that the enzyme binds leucine, leucyl-adenylate and tRNA Leu, each in a 1 : 1 stoichiometry. For ATP only a very weak binding to the enzyme could be observed, which did not allow the evaluation of the complex stoichiometry. The presence of ATP was not required for the binding of leucine or tRNA to leucyl-tRNA synthetase from E. coli MRE 600.

The binding of tyrosinyl-5'-AMP to tyrosyl-tRNA synthetase (E.coli)

The binding between tyrosyl-tRNA synthetase (E.coli) and the alkylanalogue of the aminoacyladenylate, tyrosinyl-5'-AMP, has been investigated by fluorescence titrations and rapid mixing experiments. Tyrosyl-tRNA synthetase has two equivalent and independent binding sites for tyrosinyl-5'-AMP. The intrinsic binding constant is 4 x 10(7)M-1. The binding sites for tRNATyr and tyrosinyl-5'-AMP are independent of each other, the anticooperative mode of tRNA binding being preserved in the presence of tyrosinyl-5-AMP.

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.

Splenic protein synthesis in magnesium deficiency: mechanism of the inhibition

To investigate the basis for the depressed protein synthesis in vivo in magnesium deficient spleens, the activities of splenic subcellular fractions in polypeptide synthesis were studied in vitro. Splenic ribosomes from Mg deficient animals were normal structurally and functionally. In contrast, supernatant fractions from the deficient spleens had a reduced ability to incorporate labeled amino acids into protein, both in the presence of endogenous mRNA and in the presence of added polyuridylic acid. The specific defects observed in the Mg deficient supernatants were twofold: There was a modest reduction in the rate of acylation of tRNA and a more marked reduction in the activity of the elongation factors, EF-I and EF-II. The reduction in elongation factor activity was quantitatively sufficient to account for the inhibition of protein synthesis in vivo.

Aminoacyl-tRNA synthetases from yeast: generality of chemical proofreading in the prevention of misaminoacylation of tRNA

The specificity of valyl-, phenylalanyl-, and tyrosyl-tRNA synthetases from yeast has been examined by a series of stringent tests designed to eliminate the possibility of artefactual interference. Valyl-tRNA synthetase, as well as activating a number of amino acid analogues, will accept alanine, cysteine, isoleucine, and serine in addition to threonine as substrates for both ATP-PPi exchange and transfer to some tRNAVal species. The transfer is not observed if atempts are made to isolate the appropriate aminoacyl-tRNAVal-C-C-A but its role in the overall aminoacylation can be suspected from both the formation of a stable aminoacyl-tRNAVal-C-C-A(3'NH2) compound and from the stoichiometry of ATP hydrolysis during the aminoacylation of the native tRNA. Similar tests with phenylalanyl-tRNA synthetase indicate that this enzyme will also activate and transfer other naturally occurring amino acids, namely, leucine, methionine, and tyrosine. The tyrosine enzyme, which lacks the hydrolytic capacity of the other two enzymes (von der Haar, F., & Cramer, F (1976) Biochemistry 15, 4131--4138) is probably absolutely specific for tyrosine. It is concluded that chemical proofreading, in terms of an enzymatic hydrolysis of a misacylated tRNA, plays an important part in maintaining the specificity in the overall reaction and that this activity may be more widespread than has so far been suspected.

"Chemical aminoacylation" of tRNA's

Incubation of abbreviated tRNA's (tRNA-C-COH's) with (chemically) preaminoacylated P1, P2-di(adenosine 5'-)diphosphates in the presence of purified RNA ligase effected transfer of an aminoacyladenylate moiety to the 3'-terminus of the abbreviated tRNA's in good yield. Aminoacylated (or misacylated) tRNA's may thus be prepared from fractionated or unfractionated tRNA-C-COH's; each of the five aminoacylated dinucleoside diphosphates tested was utilized as a substrate by RNA ligase. That the resulting "chemically aminoacylated" tRNA's were identical with those prepared by enzymatic aminoacylation was judged by comparison of 1) chromatographic properties on benzolated diethylaminoethyl-cellulose, 2) rates of chemical deacylation, and 3) affinities for elongation factor Tu, as well as 4) the ability of misacylated tRNA's so derived to be deacylated chemically and then reactivated enzymatically with their cognate amino acids.

Evidence for structural gene alterations affecting aminoacyl-tRNA synthetases in CHO cell mutants and revertants

Aminoacyl-tRNA synthetase (aaRS) activities in extracts of mutant strains of the Chinese hamster ovary line (CHO) were examined for alterations in thermal stability. Mutants having low activity for MetRS, AsnRS, or GlnRS contained aaRSs that were inactivated much more rapidly upon heating than those from wild-type cells. Revertant lines, isolated from cultures of these mutants (Asn-5, Met-2, and Gln-2) after treatment with nitrosoguanidine or ethyl methanesulfonate, had thermolabilities intermediate between mutant and wild-type, and consistently had higher activities than the mutants. With a modified in vivo aminoacylation procedure, two previously exceptional mutants. Arg-1 and His-1, showed pronounced reductions in the amount of arginyl-tRNA or histidyl-tRNA, respectively, under restrictive conditions, compared to wild type. Revertants of Arg-1 (like the mutant itself) had no measurable ArgRS in vitro activity (less than 0.4% of wild type) although in vivo aminoacylation in the one revertant tested was partially restored. These data provide evidence that the forward mutations have occurred in the structural genes of the aaRSs and that most of the reversions are probably the result of second-site point mutations in the aaRS genes.

Incomplete aminoacylation of tRNALeu catalyzed in vitro by leucyl-tRNA synthetase from Escherichia coli B

The extent of esterification of [14C] leucine into Escherichia coli B tRNALeu apparently depends on the concentration of leucyl-tRNA synthetase. The effect is more pronounced at pH 9.0 than at pH 7.4. When reciprocals of leucyl-tRNA concentration at plateau [aa-tRNA]-1 are plotted against reciprocals of initial velocities vo-1 of aminoacylations a straight line is obtained with a slope equal to the rate constant of non-enzymatic deacylation of leucyl-tRNA. Factors which change the stability of leucyl-tRNA, e.g. pH and temperature, also change the shape of the function [aa-tRNA]-1 vs. vo-1. The data are consistent with the idea that the rate constant of spontaneous deacylation of aminoacyl-tRNA is the factor which accounts for the dependence of the level of aminoacylation on initial velocity of aminoacylation.

Photobinding of 8-methoxypsoralen to transfer RNA and 5-fluorouracil-enriched transfer RNA

The photobinding of [3H]8MOP to tRNA upon irradiation at 365 nm in the absence of O2 was determined by gel filtration. The maximum photobinding was found to be ca. 4 mol of 8MOP er mol of tRNA and 5FU-tRNA, with an overall quantum yield of 2.3 X 10(-3). The photobinding kinetics for 8MOP-tRNA showed an apparent induction period or sigmoidal kinetic curve, indicating a specific initial photobinding site on tRNA which was identified as 4-thiouridine at position 8 from the 5'-end of Escherichia coli tRNA. Photobinding of 8MOP to 5FU-tRNA proceeded without an apparent induction period. 8MOP-tRNA and 8MOP-5FU-tRNA adducts were characterized by absorption, fluorescence, and CD spectroscopy. A modified procedure was also developed to analyze the nucleoside composition in modified 8MOP-tRNA and 8MOP-5FU-tRNA. The results showed that 8MOP photochemically added mainly to pyrimidine bases. The photobinding of 8MOP changed the conformation (secondary in particular) of tRNA and inhibited aminoacyl-tRNA synthetase activity.

Yeast seryl tRNA synthetase: two sets of substrate sites involved in aminoacylation

Seryl tRNA synthetase from Saccharomyces Carlsbergensis C836 contains two sets of sites for tRNASer, L-serine, and Mg2+-ATP, both of which are involved in aminoacylation. This is based on the following experimental results: (a) at low serine concentrations, second order kinetics in tRNASer are observed; (b) biphasic kinetics result when the amino acid is the varied substrate indicating anticooperative binding of two serine molecules to the synthetase; (c) when two molecules of serine are bound the rate of aminoacylation increases strongly and becomes first order in tRNASer; (d) the involvement of more than one site for Mg2+ and ATP is deduced from systematic variations of the concentrations of Mg2+ and ATP. Implications of the anticooperative binding of the substrates for possible reaction mechanisms are discussed. The results indicate that under normal conditions, the activity of seryl tRNA synthetase is regulated mainly by tRNASer while at high serine concentrations regulation by the amino acid itself prevails.

Valylation of the two RNA components of turnip-yellow mosaic virus and specificity of the tRNA aminoacylation reaction

A comparative study of the aminoacylation of the two RNA components of turnip yellow mosaic virus, of yeast tRNAVal, tRNAfMet and of tRNAPhe by purified yeast valyl-tRNA synthetase is reported. Aminoacylations were performed in the presence of pure yeast tRNA nucleotidyltransferase, since 85% of the viral RNA molecules lacked the 3'-adenosine. We find that aminoacylation of the viral RNAs, like tRNA aminoacylation, reflects an equilibrium between the acylation and deacylation reactions. The kinetic parameters of TYM virus RNA valylation resemble the values found for tRNAVal valylation; in particular, there is a strong affinity between the viral RNA and valyl-tRNA synthetase and the rate constant for TYM virus RNA valylation is only slightly lower than that for tRNAVal. This result contrasts with the reduced rates observed in tRNA mischarging, and suggests that the viral RNA could be easily aminoacylated in vivo. Considering the fact that the 3'-terminal sequence of TYM virus RNA has only a few points of resemblance to a tRNA sequence, we propose that there are some structural motifs found in both tRNAVal and TYM virus RNA which are brought in a similar spatial arrangement recognized by valyl-tRNA synthetase.