Unusual mechanism for an aminomutase rearrangement: retention of configuration at the migration termini

The phenylalanine aminomutase from Taxus catalyzes the vicinal exchange of the amino group and the pro-3S hydrogen of (2S)-alpha-phenylalanine to make (3R)-beta-phenylalanine. While the migration of the amino group from C2 of the substrate to C3 of the product is already known to proceed intramolecularly with retention of configuration, the stereochemistry of the hydrogen transfer remained unknown, until now. The chemical shifts of the prochiral hydrogens of authentic (3R)-beta-phenylalanine were established by 1H NMR, and the configuration of each hydrogen was assigned by 2H NMR analysis of a racemic mixture of [2,3-2H2]-(2S,3R)- and (2R,3S)-beta-phenylalanines synthesized via syn addition of deuterium gas with palladium catalyst to stereospecifically reduce the double bond of an N-acetyl enamine. After the aminomutase was incubated with [3,3-2H2]-(2S)-alpha-phenylalanine, the derived deuterium-labeled beta-diastereoisomer product, derivatized as the N-acetyl methyl ester, was analyzed by 2H NMR, which revealed that the mutase shuttles the pro-3S hydrogen to C2 of the beta-isomer product (designated 2S,3R) with retention of configuration. Retention of configuration at both reaction termini is unique among all aminomutase mechanisms examined so far. Furthermore, the dynamics of the Cbeta-H bond of the substrate were measured in a competitive experiment with deuterium-labeled substrate to calculate a primary kinetic isotope effect on Vmax/KM of 2.0 +/- 0.2, indicating that C-H bond cleavage is likely rate limiting. Isotope exchange data indicate that the migratory deuterium of [2H8]-(2S)-alpha-phenylalanine, at saturation, dynamically exchanges up to 75%, with protons from the solvent during the reaction after the first 10% of product is formed. The calculated equilibrium constant of 1.1 indicates that the beta-isomer was slightly favored relative to the alpha-isomer at 30 degrees C.     

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.     

Stereochemistry and mechanism of reactions catalyzed by tryptophanase Escherichia coli.

Several beta replacement and alpha,beta elimination reactions catalyzed by tryptophanase from Escherichia coli are shown to proceed stereospecifically with retention of configuration. These conversions include synthesis of tryptophan from (2S,3R)- and (2s,3s)-[3(-3H)]serine in the presence of indole, deamination of these serines in D2O to pyruvate and ammonia, and cleavage of (2S,3R)-and (2S,3S)-[3(-3H)]tryptophan in D2O to indole, pyruvate, and ammonia. A coupled reaction with lactate dehydrogenase was used to trap the stereospecifically labeled [3-H,2H,3H]pryuvates as lactate, which was oxidized to acetate for chirality analysis of the methyl group. During deamination of tryptophan there is significant intramolecular transfer of the alpha proton of the amino acid to C-3 of indole. To determine the exposed face of the cofactor.substrate complex on the enzyme surface and to analyze its conformational orientation, sodium boro[3H]hydride was used to reduce tryptophanase-bound alaninepyridoxal phosphate Schiff's base. Degradation of the resulting pyridoxylalanine to (2S)-[2(-3H)]alanine and (4'S)-[4'(-3H)]pyridoxamine demonstrates that reduction occurs from the exposed si face at C-4' of the complex and that the ketimine double bond is trans.     

Stereochemistry of lysine formation by meso-diaminopimelate decarboxylase from wheat germ: use of 1H-13C NMR shift correlation to detect stereospecific deuterium labeling

The stereochemical course of the wheat germ meso-diaminopimelate (DAP) decarboxylase reaction is compared to that of the decarboxylase isolated from Bacillus sphaericus, which has been reported to proceed with an unusual inversion of configuration [Asada, Y., Tanizawa, K., Sawada, S., Suzuki, T., Misono, H., & Soda, K. (1981) Biochemistry 20, 6881-6886]. Reaction of each enzyme with either unlabeled diaminopimelic acid in D2O or [2,6-2H2]diaminopimelic acid in H2O gave stereospecifically deuterium-labeled lysine samples that were derivatized with (-)-camphanoyl chloride and diazomethane. Analysis by two-dimensional 1H-13C heteronuclear NMR shift correlation spectroscopy with 2H decoupling confirmed the stereochemistry of the B. sphaericus enzyme reaction and showed that the eukaryotic wheat germ meso-DAP decarboxylase also operates with inversion of configuration. This suggests similar mechanisms for the prokaryotic and eukaryotic enzymes and contrasts the retention mode observed with other pyridoxal phosphate dependent alpha-decarboxylases.     

Stereochemistry of the dTDP-glucose oxidoreductase reaction.

The stereochemical course of the dTDP-glucose oxidoreductase (EC 4.2.1.46) reaction was studied using enzyme partially purified from Escherichia coli and dTDP-(6R)- and (6S)-[4-2H, 6-3H]glucose as substrate. The latter was prepared enzymatically by reduction of (3R)- and (3S)-3-P-[3-3H]glycerate to the 1-deuterated 3-P-glyceraldehyde with (4S)-[4-2H]NADH, followed first by conversion to glucose-1-P with the glycolytic enzymes, and then by transformation into the dTDP derivative. The stereospecifically labeled dTDP-glucose samples were mixed with nonlabeled carrier material and converted to dTDP-4-keto-6-deoxyglucose, which contained a chiral methyl group as shown by chirality analysis of the acetic acid resulting from Kuhn-Roth oxidation of the sugar nucleotide. These results confirm that the hydrogen transfer from C4 to C6 is intramolecular and show that the migrating hydrogen replaces the 6-hydroxyl group with inversion of configuration. Assuming that the hydrogen transfer, since it is intramolecular, must be suprafacial, it follows that the elimination of water from C5 and C6 is formally syn, whereas the reduction of the resulting delta5,6-double bond formally involves an anti addition of H+ and H-.     

Stereochemistry of the β-cyanoalanine synthetase and S-alkylcysteine lyase reactions

The stereochemistry of the replacement of the SH-group of cysteine by CN catalyzed by β-cyanoalanine synthetase was studied using cysteine stereospecifically tritiated at C-3. Analysis of the resulting β-cyanoalanine by conversion into fumarate via aspartate and malate showed that the reaction had occurred with retention of configuration at C-3. Using cystine stereospecifically labeled at C-3 with tritium or with tritium and deuterium, it was found that the α,β-elimination reaction catalyzed by S-alkylcysteine lyase involves stereo-specific replacement of the β-substituent of the substrate by a hydrogen derived from the solvent, D₂O or H₂O, with retention of configuration to give pyruvate containing a chiral methyl group. The results are discussed, particularly in the light of mechanistic proposals by Braunstem and co-workers.     

Stereochemistry and mechanism of the GDP-mannose dehydratase reaction.

The reaction catalyzed by bacterial GDP-mannose dehydratase (E.C. 4.2.1.47), the conversion of GDP-D-mannose to GDP-4-keto-6-deoxymannose (GDP-6-deoxy-D-lyxo-hexos-4-ulose), was studied with (6R)- and (6S)-GDP-D-[4-2H1,6-3H]mannose. Conversion of these stereospecifically labeled substrates in the presence of excess unlabeled GDP-mannose into the 4-keto-6-deoxy derivatives followed by Kuhn-Roth oxidation gave acetic acid samples which were subjected to configurational analysis of the isotopically chiral methyl group. The observed F values of 64 for the material from the (6S) substrate and 31 for that from the (6R) isomer, corresponding to 48% e.e. R and 66% e.e. S configuration, respectively, of the methyl group indicate that (a) the oxidoreductase reaction involves transfer of H-4 to C-6, (b) the transfer is predominantly intramolecular, and (c) the transfer is stereospecific, H-4 replacing the C-6 hydroxyl group with inversion of configuration. A mechanism for the reaction is proposed on the basis of these results.     

Stereochemistry at C-1 of geranyl pyrophosphate and neryl pyrophosphate in the cyclization to (+)- and (-)-bornyl pyrophosphate

(1R)-1-3H-labeled and (1S)-1-3H-labeled geranyl pyrophosphate and neryl pyrophosphate were prepared from the corresponding 1-3H-labeled aldehydes by a combination of enzymatic and synthetic procedures. Following admixture with the corresponding 2-14C-labeled internal standard, each substrate was converted to (+)-bornyl pyrophosphate and (-)-bornyl pyrophosphate by cell-free enzyme preparations from sage (Salvia officinalis) and tansy (Tanacetum vulgare), respectively. Each pyrophosphate ester was hydrolyzed, and the resulting borneol was oxidized to camphor. The stereochemistry of labeling at C-3 of the derived ketone was determined by base-catalyzed exchange, taking advantage of the known selective exchange of the exo-alpha-protons. By comparison of such exchange rates to those of product generated from (1RS)-2-14C,1-3H2-labeled substrate, it was demonstrated that geranyl pyrophosphate was cyclized to bornyl pyrophosphate with net retention of configuration at C-1 of the acyclic precursor, whereas neryl pyrophosphate was cyclized to product with inversion of configuration at C-1. The observed stereochemistry is consistent with a reaction mechanism whereby geranyl pyrophosphate is first stereospecifically isomerized to linalyl pyrophosphate which, following rotation about C-2-C-3 to the cisoid conformer, cyclizes from the anti-endo configuration. Neryl pyrophosphate cyclizes either directly or via the linalyl intermediate without the attendant rotation.     

Stereochemistry of 2-phenylethylamine oxidation catalyzed by bacterial copper amine oxidase

The stereochemical course of the reaction catalyzed by a copper amine oxidase from Arthrobacter globiformis has been investigated using 2-phenylethylamine stereospecifically deuterium-labeled at the C1 position. Measurements of deuterium content in the product, phenylacetaldehyde, by gas chromatography-mass spectrometry revealed stereospecific abstraction of the pro-S hydrogen during the enzymatic oxidation, as predicted from the structure modeling for the enzyme-bound substrate.     

Detailed reaction mechanism of macrophomate synthase. Extraordinary enzyme catalyzing five-step transformation from 2-pyrones to benzoates

Macrophomate synthase from the fungus Macrophoma commelinae IFO 9570 is a Mg(II)-dependent dimeric enzyme that catalyzes an extraordinary, complex five-step chemical transformation from 2-pyrone and oxalacetate to benzoate involving decarboxylation, C-C bond formation, and dehydration. The catalytic mechanism of the whole pathway was investigated in three separate chemical steps. In the first decarboxylation step, the enzyme loses oxalacetate decarboxylation activity upon incubation with EDTA. Activity is fully restored by addition of Mg(II) and is not restored with other divalent metal cations. The dissociation constant of 0.93 x 10(-)(7) for Mg(II) and atomic absorption analysis established a 1:1 stoichiometric complex. Inhibition of pyruvate formation with 2-pyrone revealed that the actual product in the first step is a pyruvate enolate, which undergoes C-C bond formation in the presence of 2-pyrone. Incubation of substrate analogs provided aberrant adducts that were produced via C-C bond formation and rearrangement. This strongly indicates that the second step is two C-C bond formations, affording a bicyclic intermediate. Based on the stereospecificity, involvement of a Diels-Alder reaction at the second step is proposed. Incubation of the stereospecifically deuterium-labeled malate with 2-pyrones in the presence of malate dehydrogenase provided information for the stereochemical course of the reaction catalyzed by macrophomate synthase, indicating that the first decarboxylation provides pyruvate (Z)-[3-(2)H]enolate and that dehydration at the final step occurs with anti-elimination accompanied by concomitant decarboxylation. Examination of kinetic parameters in the individual steps suggests that the third step is the rate-determining step of the overall transformation.     

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.     

Stereochemistry of internucleotidic bond formation by tRNA nucleotidyltransferase from baker's yeast.

Isomer A of adenosine 5'-O-(1-thiotriphosphate) (ATP alpha S) is a substrate for tRNA nucleotidyltransferase from baker's yeast, whereas isomer B is a competitive inhibitor. The tRNA resulting from this reaction has a phosphorothioate instead of a phosphate diester linkage at the last internucleotidic linkage between cytidine and adenosine. On limited digestion of this tRNA with RNase A, one can isolate cytidine 2',3'-cyclic phosphorothioate which can be deaminated to uridine 2',3'-cyclic phosphorothioate. It can be shown that this compound is the endo isomer and that, therefore, the phosphorothioate diester bond in the tRNA must have had the R configuration. This result indicates that no racemization during the condensation of ATP alpha S, isomer A, onto the tRNA had occurred. Whether inversion or retention of configuration had taken place awaits elucidation of the absolute configuration of isomer A of ATP alpha S.     

Mevalonate-5-diphosphate decarboxylase: stereochemical course of ATP-dependent phosphorylation of mevalonate 5-diphosphate

Chicken liver mevalonate-5-diphosphate decarboxylase catalyzes the reaction of mevalonate 5-diphosphate (MVADP) with ATP to produce isopentenyl diphosphate, ADP, CO2, and inorganic phosphate. The overall reaction involves an anti elimination of the tertiary hydroxyl and carboxyl groups. To investigate the mechanism for transfer of the terminal phosphoryl group of ATP to the C-3 oxygen of MVADP, we have carried out the reaction using stereospecifically labeled (Sp)-adenosine 5'-O-(3-thio[3-17O2,18O]triphosphate) [( gamma-17O2,18O]ATP gamma S) in place of ATP. The configuration of the [17O,18O]thiophosphate produced was found to be Rp, corresponding to overall inversion of configuration at phosphorus in the thiophosphoryl group transfer step. This result is consistent with the direct transfer of the thiophosphoryl group from (Sp)-[gamma-17O2,18O]ATP gamma S to MVADP at the active site. Our result does not indicate the involvement of a covalent thiophosphoryl-enzyme on the reaction pathway.     

Role of CO2 in proton activation by histidine decarboxylase (pyruvoyl).

The amino acid decarboxylases that use an intrinsic pyruvoyl cofactor have been viewed in terms of the pyridoxal-P paradigm whereby a Schiff base is formed between the enzyme-bound cofactor and the substrate, setting up a cation sink for electrons of the C alpha-CO2- bond, ejecting CO2, and the reversal of these steps with a proton with overall retention stereochemistry. With histidine decarboxylase (pyruvoyl) it is found that the presence of CO2 is required for T-exchange between histamine and water. Since the forward reaction including formation of the C-H bond does not require added CO2, it might be assumed that the CO2 that is formed in the fragmentation step is retained by the enzyme perhaps to assist in proton transfer. No such requirement for CO2 has been reported for the pyridoxal-P-dependent decarboxylases which are generally thought to liberate CO2 prior to proton transfer. In seeking a connection between bound CO2 and proton transfer in the histidine decarboxylase reaction, one is reminded of the carboxybiotin enzymes also known for an invariant stereochemistry of retention and for the requirement that the biotin be in the carboxylated form for H-exchange to occur. Perhaps the bound CO2 of histidine decarboxylase forms a carbamate by addition to Lys155 or to an amide group of the active site. The new carboxy group could then be the vehicle for protonating the carbon from which it originated, giving overall retention of the stereochemistry at the alpha-C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stereochemistry of 2-Phenylethylamine Oxidation Catalyzed by Bacterial Copper Amine Oxidase

The stereochemical course of the reaction catalyzed by a copper amine oxidase from Arthrobacter globiformis has been investigated using 2-phenylethylamine stereospecifically deuterium-labeled at the C1 position. Measurements of deuterium content in the product, phenylacetaldehyde, by gas chromatography-mass spectrometry revealed stereospecific abstraction of the pro-S hydrogen during the enzymatic oxidation, as predicted from the structure modeling for the enzyme-bound substrate.     

Benzylic alcohols as stereospecific substrates and inhibitors for aryl sulfotransferase

Aryl sulfotransferase IV catalyzes the 3'-phosphoadenosine-5'-phosphosulfate (PAPS)-dependent formation of sulfuric acid esters of benzylic alcohols. Since the benzylic carbon bearing the hydroxyl group can be asymmetric, the possibility of stereochemical control of substrate specificity of the sulfotransferase was investigated with benzylic alcohols. Benzylic alcohols of known stereochemistry were examined as potential substrates and inhibitors for the homogeneous enzyme purified from rat liver. For 1-phenylethanol, both the (+)-(R)- and (-)-(S)-enantiomers were substrates for the enzyme, and the kcat/Km value for the (-)-(S)-enantiomer was twice that of the (+)-(R)-enantiomer. The enzyme displayed an absolute stereospecificity with ephedrine and pseudoephedrine, and with 2-methyl-1-phenyl-1-propanol; that is, only (-)-(1R,2S)-ephedrine, (-)-(1R,2R)-pseudoephedrine, and (-)-(S)-2-methyl-1-phenyl-1-propanol were substrates for the sulfotransferase. In the case of 1,2,3,4-tetrahydro-1-naphthol, only the (-)-(R)-enantiomer was a substrate for the enzyme. Both (+)-(R)-2-methyl-1-phenyl-1-propanol and (+)-(S)-1,2,3,4-tetrahydro-1-naphthol were competitive inhibitors of the aryl sulfotransferase-catalyzed sulfation of 1-naphthalenemethanol. Thus, the configuration of the benzylic carbon bearing the hydroxyl group determined whether these benzylic alcohols were substrates or inhibitors of the rat hepatic aryl sulfotransferase IV. Furthermore, benzylic alcohols such as (+)-(S)-1,2,3,4-tetrahydro-1-naphthol represent a new class of inhibitors for the aryl sulfotransferase.     

The stereochemistry of beta-lactam formation in cephalosporin biosynthesis.

3H and 14C from (2R,3S)[U-14C,3-3H1]cysteine and (2R,3R)-[U-14C,2,3-3H2]cysteine were incorporated into cephalosporin C by Cephalosporium acremonium. Analysis of the radioactive cephalosporin C indicated that the formation of its beta-lactam ring occurs stereospecifically and with retention of configuration at C-3 of cysteine.     

Enzymatic H-transfer requires vibration-driven extreme tunneling

Enzymatic breakage of the substrate C-H bond by Methylophilus methyltrophus (sp. W3A1) methylamine dehydrogenase (MADH) has been studied by stopped-flow spectroscopy. The rate of reduction of the tryptophan tryptophylquinone (TTQ) cofactor has a large kinetic isotope effect (KIE = 16.8 +/- 0.5), and the KIE is independent of temperature. Analysis of the temperature dependence of C-H bond breakage revealed that extreme (ground state) quantum tunneling is responsible for the transfer of the hydrogen nucleus. Reaction rates are strongly dependent on temperature, indicating thermally induced, vibrational motion drives the H-transfer reaction. The data provide direct experimental evidence for enzymatic bond breakage by extreme tunneling driven by vibrational motion of the protein scaffold. The results demonstrate that classical transition state theory and its tunneling derivatives do not adequately describe this enzymatic reaction.     

Further insight into the mechanism of stereoselective proton abstraction by bacterial copper amine oxidase

During the catalytic reaction of copper amine oxidase, one of the two prochiral hydrogen atoms at the C1 position of substrate amine is stereoselectively abstracted by a conserved Asp residue serving as a general base. Using stereospecifically deuterium-labeled enantiomers of 2-phenylethylamine, we previously showed that the pro-S alpha-proton is abstracted by the enzyme from Arthrobacter globiformis (AGAO) [Uchida, M., et al. (2003) Biosci. Biotechnol. Biochem. 67, 2664-2667]. More recently, we have also demonstrated that the pro-S selectivity of alpha-proton abstraction is fully retained even in the reaction of a mutant AGAO lacking the catalytic base [Chiu, Y.-C., et al. (2006) Biochemistry 45, 4105-4120]. On the basis of these findings, we have proposed that the stereoselectivity of alpha-proton abstraction is primarily determined by the conformation of the Schiff base intermediate formed between the substrate and the topa quinone cofactor (TPQ), stabilized by the binding of the distal part of the substrate to a hydrophobic pocket of the enzyme. In this conformation, the pro-S hydrogen atom to be abstracted is nearly perpendicular to the plane of the Schiff base-TPQ conjugate system, achieving the maximum overlap of sigma- and pi-orbitals. To further elucidate the stereochemical details, we have synthesized stereospecifically deuterium-labeled enantiomers of ethylamine, a very poor substrate for AGAO, in addition to those structurally related to the preferred substrate, 2-phenylethylamine. In marked contrast to the nearly complete pro-S selectivity of alpha-proton abstraction for most substrates that have been examined, the stereoselectivity for ethylamine decreased significantly to as little as 88%. The crystal structure of AGAO soaked with ethylamine showed very poor electron densities for the substrate Schiff base intermediate, showing that its conformation is not defined uniquely. Thus, the stereoselectivity of alpha-proton abstraction during the copper amine oxidase reaction is closely associated with the conformational flexibility of the substrate Schiff base intermediate.     

Importance of barrier shape in enzyme-catalyzed reactions. Vibrationally assisted hydrogen tunneling in tryptophan tryptophylquinone-dependent amine dehydrogenases

C-H bond breakage by tryptophan tryptophylquinone (TTQ)-dependent methylamine dehydrogenase (MADH) occurs by vibrationally assisted tunneling (Basran, J., Sutcliffe, M. J., and Scrutton, N. S. (1999) Biochemistry 38, 3218--3222). We show here a similar mechanism in TTQ-dependent aromatic amine dehydrogenase (AADH). The rate of TTQ reduction by dopamine in AADH has a large, temperature independent kinetic isotope effect (KIE = 12.9 +/- 0.2), which is highly suggestive of vibrationally assisted tunneling. H-transfer is compromised with benzylamine as substrate and the KIE is deflated (4.8 +/- 0.2). The KIE is temperature-independent, but reaction rates are strongly dependent on temperature. With tryptamine as substrate reaction rates can be determined only at low temperature as C-H bond cleavage is rapid, and an exceptionally large KIE (54.7 +/- 1.0) is observed. Studies with deuterated tryptamine suggest vibrationally assisted tunneling is the mechanism of deuterium and, by inference, hydrogen transfer. Bond cleavage by MADH using a slow substrate (ethanolamine) occurs with an inflated KIE (14.7 +/- 0.2 at 25 degrees C). The KIE is temperature-dependent, consistent with differential tunneling of protium and deuterium. Our observations illustrate the different modes of H-transfer in MADH and AADH with fast and slow substrates and highlight the importance of barrier shape in determining reaction rate.