The stereochemical course of nucleotidyl transfer catalyzed by ATP sulfurylase

ATP sulfurylase catalyzes the synthesis of ATP from adenosine 5'-phosphosulfate and magnesium pyrophosphate with inversion of configuration at phosphorus. This implies an "in line" displacement mechanism in the ternary complex and effectively eliminates both an adjacent mechanism followed by pseudorotation and a double displacement mechanism involving an adenylyl-enzyme intermediate. The double displacement mechanism had been invoked previously to account for a number of observations, including the ability of the enzyme to catalyze the hydrolysis of MgATP to AMP and MgPPi, and the exchange of Mg32PPi into MgATP in the absence of sulfate.     

The stereochemical course of phosphoryl transfer catalysed by glucokinase.

Adenosine 5'-[gamma(S)-16O,17O,18O]triphosphate has been used to determine the stereo-chemical course of phosphoryl transfer catalysed by rat liver glucokinase. The chirality of the product, D-glucose 6-[16O,17O,18O]phosphate was analysed by 31P n.m.r. spectroscopy. The reaction proceeds with inversion of configuration at phosphorus. The simplest interpretation of this result, which is the same as that observed with yeast hexokinase [Lowe & Potter (1981) Biochem. J. 199, 277-233], is that the phosphoryl group is transferred between MgATP2- and glucose in the ternary complex by an 'in-line' mechanism. It accords with the veiw that the kinetic differences between glucokinase and the other hexokinases arise from differences in rate constants and not from any fundamental differences in chemical mechanism.     

The stereochemical course of phosphoryl transfer catalysed by glucose 6-phosphatase.

Rat liver microsomal glucose 6-phosphatase catalyses phosphoryl transfer between D-glucose 6-[(R)-16O,17O,18O]phosphate and D-glucose with retention of configuration at the phosphorus atom. Since individual phosphoryl-transfer steps appear in general to occur with inversion of configuration, this observation is most simply interpreted in terms of a double-displacement mechanism with a phosphoryl-enzyme intermediate. Such an intermediate has been proposed previously from kinetic and 32P-labelling experiments.     

The stereochemical course of phosphoryl transfer catalysed by polynucleotide kinase (bacteriophage-T4-infected Escherichia coli B).

Polynucleotide kinase (bacteriophage-T4-infected Escherichia coli B) catalyses the transfer of the [gamma-16O,17O,18O]phosphoryl group from 5'[gamma(S)-16O,17O,18O]ATP to 3'-AMP with inversion of configuration at the phosphorus atom. The simplest interpretation of this observation is that the [gamma-16O,17O,18O]phosphoryl group is transferred directly from ATP to the co-substrate by an 'in-line' mechanism.     

The stereochemical course of hydrolysis catalysed by snake venom 5''-nucleotide phosphodiesterase.

Adenosine 5'-(S)-[16O,17O,18O]phosphate was pyrophosphorylated by the combined action of adenylate kinase and pyruvate kinase. The isotopomers of adenosine 5'-[alpha-16O,17O,18O]triphosphate were hydrolysed by venom 5'-nucleotide phosphodiesterase (Crotalus adamanteus) in H2(17)O. Analysis by 31P nuclear magnetic resonance spectroscopy of the resulting adenosine 5'-[16O,17O,18O]phosphate, after cyclization and esterification, showed that the hydrolysis occurs with retention of configuration at phosphorus. The most likely explanation of this observation is that the enzymic hydrolysis involves a double displacement at phosphorus with a covalent nucleotidyl--enzyme intermediate on the reaction pathway.     

The stereochemical course of thiophosphoryl group transfer catalyzed by adenosine kinase

Adenosine kinase was partially purified form beef liver and used to catalyze the conversion of (γR)ATPγS,γ¹⁸O and adenosine to ADP and AMPαS,α¹⁸O. The configuration at phosphorus in AMPαS,α¹⁸O was established by subjecting it to stereospecific phosphorylation to (αS)ATPαS,α¹⁸O and showing that only the nonbridging oxygen bonded to the α-P was enriched with ¹⁸O. The configuration at α-P in AMPαS,α¹⁸O was therefore S, and the transfer of the [¹⁸O]thiophosphoryl group occurred with $\text{inversion}$ of configuration.     

The stereochemical course of phosphoric residue transfer catalyzed by sarcoplasmic reticulum ATPase

The stereochemical course of the phosphoric residue transfer from ADP to water catalyzed by the (Mg2+ + Ca2+)-dependent ATPase of sarcoplasmic reticulum has been determined. For this determination, the preparation is described of ATP gamma S, stereospecifically labeled in the gamma-position with both 17O and 18O. After hydrolysis of this nucleotide, the analysis of the product inorganic [16O,17O,18O]thiophosphate showed that the reaction proceeded with retention of configuration at the gamma-phosphorus atom. This result is expected since a phosphoenzyme is well characterized for this ATPase and provides support for the hypothesis that each phosphate transfer step occurs with inversion. In this case, the formation and breakdown of the phosphoenzyme occur each with inversion leading to the retention observed for the whole reaction.     

The stereochemical course of thiophosphoryl group transfer catalyzed by T4 polynucleotide kinase

The stereochemical course of the phosphoryl transfer reaction catalyzed by T4 polynucleotide kinase has been determined using the chiral ATP analog, (Sp)-adenosine-5'-(3-thio-3-[18O]triphosphate). T4 polynucleotide kinase catalyzes the transfer of the gamma-thiophosphoryl group of (Sp)-adenosine-5'-(3-thio-3-[18O]triphosphate) to the 5'-hydroxyl group of ApA to give the thiophosphorylated dinucleotide adenyl-5'-[18O]phosphorothioate-(3'-5')adenosine. A sample of adenyl-5'-[18O]phosphorothioate-(3'-5')adenosine was subjected to venom phosphodiesterase digestion. The resulting adenosine-5'-[18O]phosphorothioate was shown to have the Rp configuration, thus indicating that the thiophosphoryl transfer reaction occurs with overall inversion of configuration of phosphorus.     

The stereochemical course of phosphoric residue transfer catalyzed by beef heart mitochondrial ATPase

The stereochemical course of phosphoric residue transfer has been determined for beef heart mitochondrial ATPase. When aden 5'-(3-thiotriphosphate), stereospecifically labeled with 18O in the gamma position, was hydrolyzed in [17O]water in the presence of the ATPase, the product inorganic [16O, 17O, 18O]thiophosphate was chiral. The configuration of the product showed that the hydrolysis had proceeded with inversion at the gamma-phosphorus atom. This result suggests that there is a direct, in-line transfer of the phosphoric residue between ADP and water and that there is no phosphoenzyme intermediate.     

The stereochemical course of phosphoryl transfer catalyzed by herpes simplex virus type I-induced thymidine kinase

Herpes simplex virus type I (HSV-I)-induced thymidine kinase has been shown to catalyze phosphoryl transfer from adenosine 5'-[gamma-(S)-16O,17O,18O]triphosphate to thymidine with inversion of configuration at phosphorus. The simplest interpretation of this result is that phosphoryl transfer occurs by a single in-line group transfer between ATP and thymidine within the ternary enzyme complex.     

The stereochemical course of phosphoric residue transfer during the myosin ATPase reaction

When adenosine 5'-(3-thiotriphosphate), stereospecifically labeled in the gamma position with 18O, was hydrolyzed in the presence of myosin subfragment 1 in 17O-enriched water, the product inorganic [16O,17O,18O]thiophosphate was chiral. The configuration of this product showed that the hydrolysis proceeds with inversion at the transferred phosphoric residue. This result suggests a direct, in-line hydrolysis mechanism for the ATPase.     

The stereochemical course of phosphoryl transfer catalysed by Bacillus stearothermophilus and rabbit skeletal-muscle phosphofructokinase with a chiral [16O,17O,18O]phosphate ester.

1. Soluble extracts from rat heart and liver mitochondria were used to evaluate the early steps in the conversion of pent-4-enoyl-CoA into tricarboxylic acid-cycle intermediates. Hitherto the unresolved problem was the reduction of the double bond of pent-4-enoate. 2. Soluble extracts from heart mitochondria reduced pent-4-enoyl-CoA and penta-2,4-dienoyl-CoA in the presence of NADPH at rates (nmol/min per mg of protein) of 0.9 +/- 0.1 and 132 +/- 8 and from the liver mitochondria at the rates of 1.9 +/- 0.2 and 52 +/- 6 respectively. No reduction of acryloyl-CoA was found. 3. We show that primarily the double bond in position 4, not in position 2, of penta-2,4-dienoyl-CoA is reduced. 4. It is concluded that the principal metabolic pathway of penta-4-enoate is reduction of the double bond in position 4 after an initial oxidation of penta-2,4-dienoyl-CoA. The pent-2-enoyl-CoA thus formed can be further metabolized by the usual enzymes of beta-oxidation, and by the further metabolism of propionyl-CoA to tricarboxylic acid-cycle intermediates.     

The stereochemical course of acetate activation by yeast acetyl-CoA synthetase.

The purified alpha-thiophosphate diastereoisomers of adenosine 5'-(1-thio)-triphosphate were used to study the stereochemical course of the reaction catalyzed by yeast acetyl-CoA synthetase. Asymmetrically labeled adenosine 5'-thiophosphate was formed from the "B" diastereoisomer of adenosine 5'-(1-thio)-triphosphate and [18O]acetate. The label was found to be in the opposite orientation from the leaving pyrophosphate group showing that the acetate activation step occurred with inversion of configuration at the alpha-phosphorus.     

Chiral [18O]phosphorothioates. The stereochemical course of thiophosphoryl group transfer catalyzed by nucleoside phosphotransferase.

Nucleoside phosphotransferase from barley seedlings was used to catalyze the equilibration of adenosine-5'-[18O]phosphorothioate having the S configuration at phosphorus with [adenine-8-14C]adenosine to produce [adenine-8-14C]adenosine-5'-[18O]phosphorothioate and adenosine. The configuration of the chiral phosphorus in adenosine-5'-[18O]phosphorothioate which was used as the donor substrate was then compared with that of the [adenine-8-14C]adenosine-5'-[18O]phosphorothioate isolated from the reaction mixture. They were found to be the same, showing that the reaction proceeds with 99.7% retention of configuration of the [18O]phosphorothioate. This is interpreted to be indicative of the involvement of a thiophosphoryl-enzyme intermediate in the nucleoside phosphotransferase reaction. The synthesis of adenosine-5'-[18O]phosphorothioate having the R and S configurations at the phosphorus atoms is described.     

The stereochemical course of 4-hydroxy-2-nonenal metabolism by glutathione S-transferases

4-Hydroxy-2-nonenal (HNE) is a toxic aldehyde generated during lipid peroxidation and has been implicated in a variety of pathological states associated with oxidative stress. Glutathione S-transferase (GST) A4-4 is recognized as one of the predominant enzymes responsible for the metabolism of HNE. However, substrate and product stereoselectivity remain to be fully explored. The results from a product formation assay indicate that hGSTA4-4 exhibits a modest preference for the biotransformation of S-HNE in the presence of both enantiomers. Liquid chromatography mass spectrometry analyses using the racemic and enantioisomeric HNE substrates explicitly demonstrate that hGSTA4-4 conjugates glutathione to both HNE enantiomers in a completely stereoselective manner that is not maintained in the spontaneous reaction. Compared with other hGST isoforms, hGSTA4-4 shows the highest degree of stereoselectivity. NMR experiments in combination with simulated annealing structure determinations enabled the determination of stereochemical configurations for the GSHNE diastereomers and are consistent with an hGSTA4-4-catalyzed nucleophilic attack that produces only the S-configuration at the site of conjugation, regardless of substrate chirality. In total these results indicate that hGSTA4-4 exhibits an intriguing combination of low substrate stereoselectivity with strict product stereoselectivity. This behavior allows for the detoxification of both HNE enantiomers while generating only a select set of GSHNE diastereomers with potential stereochemical implications concerning their effects and fates in biological tissues.     

The stereochemical course of the restriction endonuclease EcoRI-catalyzed reaction

The restriction endonuclease EcoRI hydrolyzes the Rp diastereomer of d(pGGsAATTCC), an analogue of d(pGGAATTCC) containing a chiral phosphorothioate group at the cleavage site between the deoxyguanosine and the deoxyadenosine residues (Connolly, B.A., Potter, B.V.L., Eckstein, F., Pingoud, A., and Grotjahn, L. (1984) Biochemistry 23, 3343-3453). Performing the reaction in H2(18)O leads to d(pGG) and the hexanucleotide d([18O, S]pAATTCC) which has an 18O-containing phosphorothioate group at the 5' terminus. Further hydrolysis of this hexamer with nuclease P1 yields deoxyadenosine 5'-O-[18O]phosphorothioate which can be stereospecifically phosphorylated with adenylate kinase and pyruvate kinase to give Sp-[18O] deoxyadenosine 5'-O-(1-thiotriphosphate). 31P NMR spectroscopy shows the oxygen-18 in this compound to be in a bridging position between the alpha- and beta-phosphorus atoms. Thus, the hydrolysis reaction catalyzed by EcoRI proceeds with inversion of configuration at phosphorus. This result is compatible with a direct enzyme-catalyzed nucleophilic attack of H2O at phosphorus without involvement of a covalent enzyme intermediate.     

The stereochemical course of phospho transfer catalyzed by adenylosuccinate synthetase. A reaction pathway via a phosphorylated intermediate with net inversion

The stereochemical course of phospho transfer in the reaction catalyzed by adenylosuccinate synthetase from rat muscle has been determined with chiral [gamma-17O,18O]GTP gamma S as a substrate. The stereochemical configuration of the product, inorganic thiophosphate, was determined by 31P NMR after the compound was stereospecifically incorporated into ATP beta S. The reaction goes with net inversion of configuration, which is the course for a single phospho transfer, even though 6-phospho-IMP is probably an intermediate on the normal reaction pathway (Liebermann, I. (1956) J. Biol. Chem. 223, 327-339). The breakdown of this intermediate goes by C-O bond cleavage and so is not a true phospho transfer step. Thus, inversion of configuration during the course of this ligase reaction is consistent with a single phospho transfer step in the overall reaction, the formation of the phosphorylated intermediate.