Nucleotide stereochemistry in the formyltetrahydrofolate synthetase reaction

In a recent study, we have shown that N10-formyltetrahydrofolate synthetase prefers (Sp)-MgATP beta S over the Rp isomer in the forward reaction. In this report the stereochemistry of ATP beta S produced from prochiral ADP beta S in the reverse reaction was determined. The ATP beta S product was purified and tested as a substrate for hexokinase (preference for the Rp isomer), adenylate kinase (preference for the Sp isomer) and N10-formyltetrahydrofolate synthetase. A comparison of kinetic constants for the product and the authentic Sp and Rp isomers shows that the product is the Sp diastereomer. 31P NMR was also used to identify the product as (Sp)-ATP beta S.     

Stereochemical probes of the argininosuccinate synthetase reaction

The stereochemical course of the argininosuccinate synthetase reaction has been determined. The SP isomer of [alpha-17O,alpha-18O,alpha beta-18O]ATP is cleaved to (SP)-[16O,17O,18O]AMP by the action of argininosuccinate synthetase in the presence of citrulline and aspartate. The overall stereochemical transformation is therefore net inversion, and thus the enzyme does not catalyze the formation of an adenylylated enzyme intermediate prior to the synthesis of citrulline adenylate. The RP isomer of adenosine 5'-O-(2-thiotriphosphate) (ATP beta S) is a substrate in the presence of Mg2+, but the SP isomer is a substrate when Cd2+ is used as the activating divalent cation. Therefore, the lambda screw sense configuration of the beta,gamma-bidentate metal--ATP complex is preferred by the enzyme as the actual substrate. No significant discrimination could be detected between the RP and SP isomers of adenosine 5'-O-(1-thiotriphosphate) (ATP alpha S) when Mg2+ or Mn2+ are used as the divalent cation. Argininosuccinate synthetase has been shown to require a free divalent cation for full activity in addition to the metal ion needed to complex the ATP used in the reaction.     

Factors affecting the isopenicillin N synthetase reaction.

1. Isopenicillin N synthetase (IPNS) from Cephalosporium acremonium, which requires Fe2+ and O2 for activity, was highly purified for studies of factors affecting its conversion of delta-(L-alpha-aminoadipoyl)-L-cysteinyl-D-valine (LLD-ACV) into isopenicillin N (IPN). EDTA was used to quench the reaction by removal of Fe2+. 2. IPNS was inactivated during the course of the conversion of LLD-ACV into IPN, although it was relatively stable in the absence of LLD-ACV under otherwise similar conditions. In the presence of GSH and ascorbate each IPNS molecule carried out about 200 catalytic events before inactivation, but the turnover number was decreased 5-fold in the absence of ascorbate. 3. After trace metal ions had been removed from IPNS and other components of the reaction mixture by Chelex-100 resin, only about 10 microM-Fe2+ was required for maximum stimulation. Several other transition-metal ions were inhibitors of the enzyme. 4. Both dithiothreitol (DTT) and GSH stimulated IPNS activity, but GSH, unlike DTT, was not rapidly oxidized in the presence of O2 and Fe2+. 5. IPNS was rapidly inhibited by the thiol-blocking reagents N-ethylmaleimide and 2,2'- and 4,4'-dipyridyl disulphide, but not by 5,5'-dithiobis-(2-nitrobenzoic acid) in the same concentration. Inhibition by 2,2'-dipyridyl disulphide could be reversed by DTT.     

Positional isotope exchange analysis of the pantothenate synthetase reaction

Pantothenate synthetase from Mycobacterium tuberculosis catalyzes the formation of pantothenate from ATP, D-pantoate, and beta-alanine. The formation of a kinetically competent pantoyl-adenylate intermediate was established by the observation of a positional isotope exchange (PIX) reaction within (18)O-labeled ATP in the presence of d-pantoate. When [betagamma-(18)O(6)]-ATP was incubated with pantothenate synthetase in the presence of d-pantoate, an (18)O label gradually appeared in the alphabeta-bridge position from both the beta- and the gamma-nonbridge positions. The rates of these two PIX reactions were followed by (31)P NMR spectroscopy and found to be identical. These results are consistent with the formation of enzyme-bound pantoyl-adenylate and pyrophosphate upon the mixing of ATP, D-pantoate, and enzyme. In addition, these results require the complete torsional scrambling of the two phosphoryl groups of the labeled pyrophosphate product. The rate of the PIX reaction increased as the D-pantoate concentration was elevated and then decreased to zero at saturating levels of D-pantoate. These inhibition results support the ordered binding of ATP and D-pantoate to the enzyme active site. The PIX reaction was abolished with the addition of pyrophosphatase; thus, PP(i) must be free to dissociate from the active site upon formation of the pantoyl-adenylate intermediate. The PIX reaction rate diminished when the concentrations of ATP and D-pantoate were held constant and the concentration of the third substrate, beta-alanine, was increased. This observation is consistent with a kinetic mechanism that requires the binding of beta-alanine after the release of pyrophosphate from the active site of pantothenate synthetase. Positional isotope exchange reactions have therefore demonstrated that pantothenate synthetase catalyzes the formation of a pantoyl-adenylate intermediate upon the ordered addition of ATP and pantoate.     

Mechanism and stereochemistry of the 5-aminolaevulinate synthetase reaction

1. Two mechanisms for the biosynthesis of 5-aminolaevulinate from glycine and succinyl-CoA (3-carboxypropionyl-CoA) are considered. One of the mechanisms involves the retention of both the C-2 H atoms of glycine during the synthesis of 5-aminolaevulinate, whereas the other predicts the retention of only one of the C-2 H atoms of glycine. 2. Highly purified 5-aminolaevulinate synthetase from Rhodopseudomonas spheroides was used to show that the C-2 H atom of glycine with R configuration is specifically removed during the biosynthesis of 5-aminolaevulinate. 3. The mechanism of the condensation therefore differs from the analogous reaction of the biosynthesis of sphinganine from palmitoyl-CoA and serine, in which the C-2 H of serine is retained (Wiess, 1963).     

Palmitoyl-coenzyme A synthetase. Mechanism of reaction

The mechanism of long-chain fatty acid activation catalysed by highly purified microsomal palmitoyl-CoA synthetase was investigated. The kinetics of the overall reaction were found to conform to the Bi Uni Uni Bi Ping Pong mechanism. (18)O was transferred from [(18)O]palmitate to AMP and palmitoyl-CoA exclusively. The enzyme intermediate formed appeared to consist of enzyme-bound palmitate; this formation occurred only in the presence of ATP. However, the involvement of palmitoyl-AMP in the reaction catalysed by the purified enzyme has proved difficult to establish.     

Studies of the ammonia-dependent reaction of beef pancreatic asparagine synthetase

We have studied the asparagine synthetase reaction with regard to the ammonia-dependent production of asparagine. Hydroxylamine was shown to be an alternate substrate for the asparagine synthetase reaction, and some of its kinetic properties were examined. The ammonia-dependent reaction was examined with regard to inhibition by asparagine. It was found that asparagine inhibition was partial competitive with respect to ammonia, regardless of the concentration of aspartate. However, when MgATP was not saturating, the inhibition by asparagine became linear competitive. These results were interpreted to be consistent with a kinetic mechanism for asparagine synthetase where ammonia is bound to the enzyme followed by MgATP causing asparagine release.     

Synchronization of the three reaction centers within carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase from E. coli catalyzes the synthesis of carbamoyl phosphate through a series of four reactions occurring at three active sites connected by a molecular tunnel of 100 A. To understand the mechanism for coordination and synchronization among the active sites, the pre-steady-state time courses for the formation of phosphate, ADP, glutamate, and carbamoyl phosphate were determined. When bicarbonate and ATP were rapidly mixed with CPS, a stoichiometric burst of acid-labile phosphate and ADP was observed with a formation rate constant of 1100 min(-)(1). The burst phase was followed by a linear steady-state phase with a rate constant of 12 min(-)(1). When glutamine or ammonia was added to the initial reaction mixture, the magnitude and the rate of formation of the burst phase for either phosphate or ADP were unchanged, but the rate constant for the linear steady-state phase increased to an average value of 78 min(-)(1). These results demonstrate that the initial phosphorylation of bicarbonate is independent of the binding or hydrolysis of glutamine. The pre-steady-state time course for the hydrolysis of glutamine in the absence of ATP exhibited a burst of glutamate formation with a rate constant of 4 min(-)(1) when the reaction was quenched with base. In the presence of ATP and bicarbonate, the rate constant for the formation of the burst of glutamate was 1100 min(-)(1). The hydrolysis of ATP thus enhanced the hydrolysis of glutamine by a factor of 275, but there was no effect by glutamine on the initial phosphorylation of bicarbonate. The pre-steady-state time course for the formation of carbamoyl phosphate was linear with an overall rate constant of 72 min(-)(1). The absence of an initial burst of carbamoyl phosphate formation eliminates product release as a rate-determining step for CPS. Overall, these results have been interpreted to be consistent with a mechanism whereby the phosphorylation of bicarbonate serves as the initial trigger for the rest of the reaction cascade. The formation of the carboxy phosphate intermediate within the large subunit must induce a conformational change to the active site of the small subunit that enhances the hydrolysis of glutamine. Thus, ammonia is not released into the molecular tunnel until the activated bicarbonate is ready to form carbamate. The rate-limiting step for the steady-state assembly of carbamoyl phosphate is either the formation, migration, or phosphorylation of the carbamate intermediate.     

Bovine lenticular gamma-glutamylcysteine synthetase: reaction sequence.

The sequence of substrate addition and product release during the reaction catalyzed by gamma-glutamylcysteine synthetase was investigated with purified enzyme from bovine lens. Thermal inactivation and kinetic studies suggest that L-glutamate is the first substrate to bind to the enzyme. L-beta-Chloroalanine was used as the L-cysteine analogue. Utilizing substrate activation and product inhibition studies, the following reaction sequence was determined: L-glutamate binding. ATP binding, ADP release, L-beta-chloroalanine binding, followed by inorganic phosphate and then dipeptide release. The implications of this mechanism with regard to control of the enzyme in situ and its importance in glutathione synthesis are discussed.     

Effects of the diastereoisomers of methylenetetrahydrofolate on the reaction catalyzed by thymidylate synthetase

Diastereoisomers of methylenetetrahydrofolate were prepared and shown to have equal and opposite CD spectra. In addition to being inactive in the spectrophotometric assay for $\text{Lactobacillus casei}$ thymidylate synthetase, the diastereoisomer having the unnatural configuration at carbon 6, does not promote removal of tritium from 5-(³H)-dUMP. It is a competitive inhibitor of the reaction with a K₁ of 5 × 10^?5$\text{M}$.     

Evidence that arginyl-adenylate is not an intermediate in the arginyl-tRNA synthetase reaction

Arginyl-tRNA synthetase has a reaction mechanism not typical of most aminoacyl-tRNA synthetases. It does not catalyze an amino acid-dependent ATP-PP₁ exchange in the absence of tRNA as do most enzymes of this class. In order to clarify the reaction mechanism by performing experiments with substrate levels of enzyme, we have modified the previous purification procedure. By the method presented, homogeneous enzyme can be prepared in approximately 10% yield. Pulse-labeling experiments indicate that no enzyme-bound arginyl-adenylate is formed in the absence of tRNA. Equilibrium experiments show that no arginyl-adenylate accumulates either in the presence or absence of tRNA^arg. Two mechanisms compatible with these data are suggested.     

An alternative mechanism for the nitrogen transfer reaction in asparagine synthetase.

In the absence of crystallographic data, the mechanism of nitrogen transfer from glutamine in asparagine synthetase (AS) remains under active investigation. Surprisingly, the glutamine-dependent AS from Escherichia coli (AsnB) appears to lack a conserved histidine residue, necessary for nitrogen transfer if the reaction proceeds by the accepted pathway in other glutamine amidotransferases, but retains the ability to synthesize asparagine. We propose an alternative mechanism for nitrogen transfer in AsnB which obviates the requirement for participation of histidine in this step. Our hypothesis may also be more generally applicable to other glutamine-dependent amidotransferases.     

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

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