The mechanism of glycogen synthetase as determined by deuterium isotope effects and positional isotope exchange experiments

The reaction mechanism for glycogen synthetase from rabbit muscle was examined by alpha-secondary deuterium isotope effects and positional exchange experiments. Incubation of glycogen synthetase with [beta-18O2,alpha beta-18O]UDP-Glc did not result in any detectable positional isotope exchange from the beta-nonbridge position to the anomeric oxygen of the glucose moiety. Glucono-1,5-lactone was found to be a noncompetitive inhibitor versus UDP-Glc. The kinetic constants, K(is) and K(ii), were found to be 91 +/- 4 microM and 0.70 +/- 0.09 mM, respectively. Deoxynojirimycin was a nonlinear inhibitor at pH 7.5. The alpha-secondary deuterium isotope effects were measured with [1-2H]UDP-Glc by the direct comparison method. The isotope effects on Vmax and Vmax/K were found to be 1.23 +/- 0.04 and 1.09 +/- 0.06, respectively. The inhibitory effects by glucono-lactone and deoxynojirimycon plus the large alpha-secondary isotope effect on Vmax have been interpreted to show that an oxocarbonium ion is an intermediate in this reaction mechanism. The lack of a detectable positional isotope exchange reaction in the absence of glycogen suggests the formation of a rigid tight ion pair between UDP and the oxocarbonium ion intermediate.     

Examination of the mechanism of sucrose synthetase by positional isotope exchange

The mechanism of the sucrose synthetase reaction has been probed by the technique of positional isotope exchange. [beta-18O2, alpha beta-18O]UDP-Glc has been synthesized starting from oxygen-18-labeled phosphate and the combined activities of carbamate kinase, hexokinase, phosphoglucomutase, and uridine diphosphoglucose pyrophosphorylase. The oxygen-18 at the alpha beta-bridge position of the labeled UDP-Glc has been shown to cause a 0.014 ppm upfield chemical shift in the 31P NMR spectrum of both the alpha- and beta-phosphorus atoms in UDP-Glc relative to the unlabeled compound. The chemical shift induced by each of the beta-nonbridge oxygen-18 atoms was 0.030 ppm. Incubation of [beta-18O2, alpha beta-18O]UDP-Glc with sucrose synthetase in the presence and absence of 2,5-anhydromannitol did not result in any significant exchange of an oxygen-18 from the beta-nonbridge position to the anomeric oxygen of the glucose moiety. It can thus be concluded that either sucrose synthetase does not catalyze the cleavage of the scissile carbon-oxygen bond of UDP-Glc in the absence of fructose or, alternatively, the beta-phosphoryl group of the newly formed UDP is rotationally immobilized.     

Peroxidase-catalyzed N-demethylation reactions: deuterium solvent isotope effects

The effect of D2O on the kinetic parameters for the hydroperoxide-supported N-demethylation of N,N-dimethylaniline catalyzed by chloroperoxidase and horseradish peroxidase was investigated in order to assess the roles of exchangeable hydrogens in the demethylation reaction. The initial rate of the chloroperoxidase-catalyzed N-demethylation of N,N-dimethylaniline supported by ethyl hydroperoxide exhibited a pL optimum (where L denotes H or D) of 4.5 in both H2O and D2O. The solvent isotope effect on the initial rate of the chloroperoxidase-catalyzed demethylation reaction was independent of pL, suggesting that the solvent isotope effect is not due to a change in the pK of a rate-controlling ionization in D2O. The solvent isotope effect on the Vmax for the chloroperoxidase-catalyzed demethylation reaction was 3.66 +/- 0.62. In contrast, the solvent isotope effect on the Vmax for the horseradish peroxidase catalyzed demethylation reaction was approximately 1.5 with either ethyl hydroperoxide or hydrogen peroxide as the oxidant, indicating that the exchange of hydrogens in the enzyme and hydroperoxide for deuterium in D2O has little effect on the rate of the demethylation reaction. The solvent isotope effect on the Vmax/KM for ethyl hydroperoxide in the chloroperoxidase-catalyzed demethylation reaction was 8.82 +/- 1.57, indicating that the rate of chloroperoxidase compound I formation is substantially decreased in D2O. This isotope effect is suggested to arise from deuterium exchange of the hydroperoxide hydrogen and of active-site residues involved in compound I formation. A solvent isotope effect of 2.96 +/- 0.57 was observed on the Vmax/KM for N,N-dimethylaniline in the chloroperoxidase-catalyzed reaction.(ABSTRACT TRUNCATED AT 250 WORDS)     

Peroxidase-catalyzed N-demethylation reactions. Substrate deuterium isotope effects

Deuterium isotope effects on the kinetic parameters for the hydroperoxide-supported N-demethylation of N,N-dimethylaniline catalyzed by chloroperoxidase and horseradish peroxidase were determined using N,N-di-(trideuteromethyl)aniline. The isotope effect on the Vmax for the chloroperoxidase-catalyzed demethylation reaction supported by ethyl hydroperoxide was 1.42 +/- 0.31. The isotope effects on the Vmax for the horseradish peroxidase-catalyzed reaction supported by ethyl hydroperoxide and hydrogen peroxide were 1.99 +/- 0.39 and 4.09 +/- 0.27, respectively. Isotope effects ranging from 1.76 to 5.10 were observed on the Vmax/Km for the hydroperoxide substrate (i.e. the second order rate constant for the reaction of the hydroperoxide with the peroxidase to form compound I) in both enzyme systems when the N-methyl groups of N,N-dimethylaniline were deuterated. These results are not predicted by the simple ping-pong kinetic model for peroxidase-catalyzed N-demethylation reactions. The data are most simply explained by a mechanism involving the transfer of deuterium (or hydrogen) from N,N-dimethylaniline to the enzyme during catalysis. The deuterium must subsequently be displaced from the enzyme by the hydroperoxide, causing the observed isotope effects.     

Isotopic probes of the argininosuccinate lyase reaction

The mechanism of the argininosuccinate lyase reaction has been probed by the measurement of the effects of isotopic substitution at the reaction centers. A primary deuterium isotope effect of 1.0 on both V and V/K is obtained with (2S,3R)-argininosuccinate-3-d, while a primary 15N isotope effect on V/K of 0.9964 +/- 0.0003 is observed. The 15N isotope effect on the equilibrium constant is 1.018 +/- 0.001. The proton that is abstracted from C-3 of argininosuccinate is unable to exchange with the solvent from the enzyme-intermediate complex but is rapidly exchanged with solvent from the enzyme-fumarate-arginine complex. A deuterium solvent isotope effect of 2.0 is observed on the Vmax of the forward reaction. These and other data have been interpreted to suggest that argininosuccinate lyase catalyzes the cleavage of argininosuccinate via a carbanion intermediate. The proton abstraction step is not rate limiting, but the inverse 15N primary isotope effect and the solvent deuterium isotope effect suggest that protonation of the guanidino group and carbon-nitrogen bond cleavage of argininosuccinate are kinetically significant.     

A kinetic isotope effect study and transition state analysis of the S-adenosylmethionine synthetase reaction

The biosynthesis of S-adenosylmethionine occurs in a unique enzymatic reaction in which the synthesis of the sulfonium center results from displacement of the entire polyphosphate chain from MgATP. The mechanism of S-adenosylmethionine synthetase (ATP:L-methionine s-adenosyltransferase) from Escherichia coli has been characterized by kinetic isotope effect and substrate trapping measurements. Replacement of 12C by 14C at the 5' carbon of ATP yields a primary Vmax/Km isotope effect (12C/14C) of 1.128 +/- 0.003 in the absence of added monovalent cation activator (K+). At saturating K+ concentrations (10 mM) the primary isotope effect diminishes slightly to 1.108 +/- 0.003, indicating that the step in the mechanism involving bond breaking at the 5' carbon of MgATP has a small commitment to catalysis at conditions near Vmax. No alpha-secondary 3H isotope effect from [5'-3H]ATP was detected, (1H/3H) = 1.000 +/- 0.002, even in the absence of KCl. There was no significant primary sulfur isotope effect from [35S]methionine at KCl concentrations from 0 to 10 mM. Substitution of the methyl group of methionine with tritium yielded a beta-secondary isotope effect (CH3/C3H3) = 1.009 +/- 0.008 independent of KCl concentration. The reaction of selenomethionine and [5'-14C]ATP gave a primary isotope effect of 1.097 +/- 0.006, independent of KCl concentration. Substrate trapping experiments demonstrated that the step in the mechanism involving bond making to sulfur of methionine does not have a significant commitment to catalysis at 0.25 mM KCl, therefore intrinsic isotope effects were observed. Substrate trapping experiments indicated that the step involving bond breaking at carbon 5' of MgATP has a 10% commitment to catalysis at 0.25 mM KCl. The isotope effects are interpreted in terms of an Sn2-like transition state structure in which bonding of the C5' is symmetric with respect to the departing tripolyphosphate group and the incoming sulfur of methionine. With selenomethionine as substrate an earlier transition state is implicated.     

Use of isotope effects to elucidate enzyme mechanisms

The chemical bond breaking steps are normally not rate limiting for enzymatic reactions. However, comparison of deuterium and tritium isotope effects on the same reaction, especially when coupled with 13C isotope effects for the same step measured with deuterated as well as unlabeled substrates, allows calculation of the intrinsic isotope effects on the bond breaking steps and thus a determination of the commitments to catalysis for the reactants. The variation in observed isotope effects as a function of reactant concentration can be used to determine kinetic mechanisms, while the pH variation of isotope effects can determine the stickiness of the reactants and which portions of the reactant mechanism are pH dependent. Finally the size of primary and secondary intrinsic isotope effects can be used to determine transition state structure.     

Kinetic isotope effects of nucleoside hydrolase from Escherichia coli

rihC is one of a group of three ribonucleoside hydrolases found in Escherichia coli (E. coli). The enzyme catalyzes the hydrolysis of selected nucleosides to ribose and the corresponding base. A family of Vmax/Km kinetic isotope effects using uridine labeled with stable isotopes, such as 2H, 13C, and 15N, were determined by liquid chromatography/mass spectrometry (LC/MS). The kinetic isotope effects were 1.012+/-0.006, 1.027+/-0.005, 1.134+/-0.007, 1.122+/-0.008, and 1.002+/-0.004 for [1'-13C], [1-15N], [1'-2H], [2'-2H], and [5'-2H2] uridine, respectively. A transition state based upon a bond-energy bond-order vibrational analysis (BEBOVIB) of the observed kinetic isotope effects is proposed. The main features of this transition state are activation of the heterocyclic base by protonation of/or hydrogen bonding to O2, an extensively broken C-N glycosidic bond, formation of an oxocarbenium ion in the ribose ring, C3'-exo ribose ring conformation, and almost no bond formation to the attacking nucleophile. The proposed transition state for the prokaryotic E. coli nucleoside hydrolase is compared to that of a similar enzyme isolated from Crithidia fasciculata (C. fasciculata).     

Evidence that both protium and deuterium undergo significant tunneling in the reaction catalyzed by bovine serum amine oxidase

The magnitudes of primary and secondary H/T and D/T kinetic isotope effects have been measured in the bovine serum amine oxidase catalyzed oxidation of benzylamine from 0 to 45 degrees C. Secondary H/T and D/T kinetic effects are small and in the range anticipated from equilibrium isotope effects; Arrhenius preexponential factors (AH/AT and AD/AT) determined from the temperature dependence of isotope effects also indicate semiclassical behavior. By contrast, primary H/T and D/T isotope effects, 35.2 +/- 0.8 and 3.07 +/- 0.07, respectively, at 25 degrees C, are larger than semiclassical values and give anomalously low preexponential factor ratios, AH/AT = 0.12 +/- 0.04 and AD/AT = 0.51 +/- 0.10. Stopped-flow studies indicate similar isotope effects on cofactor reduction as seen in the steady state, consistent with a single rate-limiting C-H bond cleavage step for Vmax/Km. The comparison of primary and secondary isotope effects allows us to rule out appreciable coupling between the primary and secondary hydrogens at C-1 of the substrate. From the properties of primary isotope effects, we conclude that both protium and deuterium undergo significant tunneling in the course of substrate oxidation. These findings represent the first example of quantum mechanical effects in an enzyme-catalyzed proton abstraction reaction.     

Mechanism and activation for allosteric adenosine 5'-monophosphate nucleosidase. Kinetic alpha-deuterium isotope effects for the enzyme-catalyzed hydrolysis of adenosine 5'-monophosphate and nicotinamide mononucleotide

The kinetic alpha-deuterium isotope effect on Vmax/Km for hydrolysis of NMN catalyzed by AMP nucleosidase at saturating concentrations of the allosteric activator MgATP2- is kH/kD = 1.155 +/- 0.012. This value is close to that reported previously for the nonenzymatic hydrolysis of nucleosides of related structure, suggesting that the full intrinsic isotope effect for enzymatic NMN hydrolysis is expressed under these conditions; that is, bond-changing reactions are largely or completely rate-determining and the transition state has marked oxocarbonium ion character. The kinetic alpha-deuterium isotope effect for this reaction is unchanged when deuterium oxide replaces water as solvent, corroborating this conclusion. Furthermore, this isotope effect is independent of pH over the range 6.95-9.25, for which values of Vmax/Km change by a factor of 90, suggesting that the isotope-sensitive and pH-sensitive steps for AMP-nucleosidase-catalyzed NMN hydrolysis are the same. Values of kH/kD for AMP nucleosidase-catalyzed hydrolysis of NMN decrease with decreasing saturation of enzyme with MgATP2- and reach unity when the enzyme is less than half-saturated with this activator. This requires that the rate-determining step changes from cleavage of the covalent C-N bond to one which is isotope-independent. In contrast to the case for NMN hydrolysis, AMP nucleosidase-catalyzed hydrolysis of AMP at saturating concentrations of MgATP2- shows a kinetic alpha-deuterium isotope effect of unity. Thus, covalent bond-changing reactions are largely or completely rate-determining for hydrolysis of a poor substrate, NMN, but make little or no contribution to rate-determining step for hydrolysis of a good substrate, AMP, by maximally activated enzyme. This behavior has several precedents.     

Deuterium isotope effects in the unusual addition of toluene to fumarate catalyzed by benzylsuccinate synthase

The first step in the anaerobic metabolism of toluene is a highly unusual reaction: the addition of toluene across the double bond of fumarate to produce (R)-benzylsuccinate, which is catalyzed by benzylsuccinate synthase. Benzylsuccinate synthase is a member of the glycyl radical-containing family of enzymes, and the reaction is initiated by abstraction of a hydrogen atom from the methyl group of toluene. To gain insight into the free energy profile of this reaction, we have measured the kinetic isotope effects on Vmax and Vmax/Km when deuterated toluene is the substrate. At 30 degrees C the isotope effects are 1.7 +/- 0.2 and 2.9 +/- 0.1 on Vmax and Vmax/Km, respectively; at 4 degrees C they increase slightly to 2.2 +/- 0.2 and 3.1 +/- 0.1, respectively. We compare these results with the theoretical isotope effects on Vmax and Vmax/Km that are predicted from the free energy profile for the uncatalyzed reaction, which has previously been computed using density functional theory [Himo, F. (2002) J. Phys. Chem. B 106, 7688-7692]. The comparison allows us to draw some conclusions on how the enzyme may catalyze this unusual reaction.     

Secondary isotope effects and structure-reactivity correlations in the dopamine beta-monooxygenase reaction: evidence for a chemical mechanism

The chemical mechanism of hydroxylation, catalyzed by dopamine beta-monooxygenase, has been explored with a combination of secondary kinetic isotope effects and structure-reactivity correlations. Measurement of primary and secondary isotope effects on Vmax/Km under conditions where the intrinsic primary hydrogen isotope effect is known allows calculation of the corresponding intrinsic secondary isotope effect. By this method we have obtained an alpha-deuterium isotope effect, Dk alpha = 1.19 +/- 0.06, with dopamine as substrate. The beta-deuterium isotope effect is indistinguishable from one. The large magnitude of Dk alpha, together with our previous determination of a near maximal primary deuterium isotope effect of 9.4-11, clearly indicates the occurrence of a stepwise process for C-H bond cleavage and C-O bond formation and hence the presence of a substrate-derived intermediate. To probe the nature of this intermediate, a structure-reactivity study was performed by using a series of para-substituted phenylethylamines. Deuterium isotope effects on Vmax and Vmax/Km parameters were determined for all of the substrates, allowing calculation of the rate constants for C-H bond cleavage and product dissociation and dissociation constants for amine and O2 loss from the enzyme-substrate ternary complex. Multiple regression analysis yielded an electronic effect of p = -1.5 for the C-H bond cleavage step, eliminating the possibility of a carbanion intermediate. A negative p value is consistent with formation of either a radical or a carbocation; however, a significantly better correlation is obtained with sigma p rather than sigma p+, implying formation of a radical intermediate via a polarized transition state. Additional effects determined from the regression analyses include steric effects on rate constants for substrate hydroxylation and product release and on KDamine, consistent with a sterically restricted binding site, and a positive electronic effect of p = 1.4 on product dissociation, ascribed to a loss of product from an enzyme-bound Cu(II)-alkoxide complex. These results lead us to propose a mechanism in which O-O homolysis [from a putative Cu(II)-OOH species] and C-H homolysis (from substrate) occur in a concerted fashion, circumventing the formation of a discrete, high energy oxygen species such as hydroxyl radical. The substrate and peroxide-derived radical intermediates thus formed undergo a recombination, kinetically limited by displacement of an intervening water molecule, to give the postulated Cu(II)-alkoxide product complex.     

Kinetic mechanism and location of rate-determining steps for aspartase from Hafnia alvei

Coupled spectrophotometric assays that monitor the formation of fumarate and ammonia in the direction of aspartate deamination and aspartate in the direction of fumarate amination were used to collect initial velocity data for the aspartase reaction. Data are consistent with rapid equilibrium ordered addition of Mg2+ prior to aspartate but completely random release of Mg2+, NH4+, or fumarate. In addition to Mg2+, Mn2+ can also be used as a divalent metal with Vmax 80% and a Kaspartate 3.5-fold lower than when Mg2+ is used. Monovalent cations such as Li+, K+, Cs+, and Rb+ are competitive vs. either aspartate or NH4+ but noncompetitive vs. fumarate. A primary deuterium isotope effect of about 1 on both V and V/Kaspartate is obtained with (3R)-L-aspartate-3-d, while a primary 15N isotope effect on V/Kaspartate of 1.0239 +/- 0.0014 is obtained in the direction of aspartate deamination. A secondary isotope effect on V of 1.13 +/- 0.04 is obtained with L-aspartate-2-d. In addition, a secondary isotope effect of 0.81 +/- 0.05 on V is obtained with fumarate-d2, while a value of 1.18 +/- 0.05 on V is obtained by using (2S,3S)-L-aspartate-2,3-d2. These data are interpreted in terms of a two-step mechanism with an intermediate carbanion in which C-N bond cleavage limits the overall rate and the rate-limiting transition state is intermediate between the carbanion and fumarate.     

UDPgalactose:glucosylceramide beta 1----4-galactosyltransferase activity in human proximal tubular cells from normal and familial hypercholesterolemic homozygotes

The activity of a galactosyltransferase (GalT-2) that catalyzes the transfer of galactose from uridinediphosphogalactose to glucosylceramide in cultured normal human proximal tubular (PT) cells was characterized with respect to substrate saturation and metal ion requirements. Using a membrane-bound enzyme source, optimum activity was obtained in the presence of 1.0 mM Mn2+/Mg2+ (1:1) and a detergent mixture, Triton X-100/Cutscum (1:2, v/v), 0.1 mg/ml. The apparent Km values for glucosylceramide and UDP[14C]galactose were 3 microM and 0.5 microM, respectively. The Vmax values for glucosylceramide and UDP[U-14C]galactose were 0.12 nmol/mg protein per 2 h and 173 nmol/mg protein per 2 h, respectively. The purified 14C-labelled product comigrated with authentic lactosylceramide (LacCer) on TLC and HPLC analysis. The presence of a terminal beta-[14C]galactosyl group in the enzymatic product was proved by its cleavage (79%) by beta-galactosidase. Following the development of optimal assay conditions in normal PT cells, GalT-2 activity was next measured in urinary PT cells from homozygous familial hypercholesterolemic (FH) patients previously shown to accumulate large amounts of lactosylceramide. Urinary PT cells from familial hypercholesterolemic homozygous patients contained 35% higher GalT-2 activity as compared to control cells. We speculate that elevated GalT-2 activity may contribute to the storage of LacCer in FH-PT cells.     

Magnitude of intrinsic isotope effects in the dopamine beta-monooxygenase reaction

Intrinsic primary hydrogen isotope effects (kH/kD) have been obtained for the carbon-hydrogen bond cleavage step catalyzed by dopamine beta-monooxygenase. Irreversibility of this step is inferred from the failure to observe back-exchange of tritium from TOH into substrate under conditions of dopamine turnover; this result cannot be due to solvent inaccessibility at the enzyme active site, since we will demonstrate [Ahn, N., & Klinman, J. P. (1983) Biochemistry (following paper in this issue)] that a solvent-derived proton or triton must be at the enzyme active site prior to substrate activation. As shown by Northrop [Northrop, D. B. (1975) Biochemistry 14, 2644], for enzymatic reactions in which the carbon-hydrogen bond cleavage step is irreversible, comparison of D(V/K) to T(V/K) allows an explicit solution for kH/kD. Employing a double-label tracer method, we have been able to measure deuterium isotope effects on Vmax/Km with high precision, D(V/K) = 2.756 +/- 0.054 at pH 6.0. The magnitude of the tritium isotope effect under comparable experimental conditions is T(V/K) = 6.079 +/- 0.220, yielding kH/kD = 9.4 +/- 1.3. This result was obtained in the presence of saturating concentrations of the anion activator fumarate. Elimination of fumarate from the reaction mixture leads to high observed values for isotope effects on Vmax/Km, together with an essentially invariant value for kH/kD = 10.9 +/- 1.9. Thus, the large disparity between isotope effects, plus or minus fumarate, cannot be accounted for by a change in kH/kD, and we conclude a role for fumarate in the modulation of the partitioning of enzyme-substrate complex between catalysis and substrate dissociation. On the basis of literature correlations of primary hydrogen isotope effects and the thermodynamic properties of hydrogen transfer reactions, the very large magnitude of kH/kD = 9.4-10.9 for dopamine beta-monooxygenase suggests an equilibrium constant not very far from unity for the carbon-hydrogen bond cleavage step. This feature, together with the failure to observe re-formation of dopamine from enzyme-bound intermediate or product and overall rate limitation of enzyme turnover by product release, leads us to propose a stepwise mechanism for norepinephrine formation from dopamine in which carbon-hydrogen bond cleavage is uncoupled from the oxygen insertion step.     

Strong inhibitory effect of furanoses and sugar lactones on beta-galactosidase Escherichia coli

Various sugars and their lactones were tested for their inhibition of beta-galactosidase (Escherichia coli). L-Ribose, which in the furanose form has a hydroxyl configuration similar to that of D-galactose at positions equivalent to the 3- and 4-positions of D-galactose, was a very strong inhibitor, and D-lyxose, which in the furanose form also resembles D-galactose, was a much better inhibitor than expected. Structural comparisons prelude the pyranose forms of these sugars from being significant contributors to the inhibition, and inhibition at different temperatures (at which there are different furanose concentrations) strongly supported the conclusion that the furanose form is inhibitory. Studies with sugar derivatives that can only be in the furanose form also supported the conclusion. This is the first report of the inhibitory effect of furanose on beta-galactosidase. Lactones were also inhibitory. Every lactone tested was much more inhibitory than was its parent sugar. D-Galactonolactone was especially good. Experiments indicated that it was D-galactono-1,5-lactone rather than D-galactono-1,4-lactone which was inhibitory. Inhibition of beta-galactosidases from mammalian sources by lactones has been reported previously, but this is the first report of the effect of beta-galactosidase from E. coli. Since furanoses in the envelope form are analogous (in some ways) to half-chair or sofa conformations and since lactones with six-membered rings probably have half-chair or sofa conformations, the results indicate that beta-galactosidase probably destabilizes its substrate into a planar conformation of some type and that the galactose in the transition state may, therefore, also be quite planar.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alpha-secondary tritium kinetic isotope effects for the hydrolysis of alpha-D-glucopyranosyl fluoride by exo-alpha-glucanases

alpha-Secondary tritium kinetic isotope effects ranging from 1.17 to 1.26 were measured for the hydrolysis of alpha-D-glucopyranosyl fluoride (forming beta-D-glucose) catalyzed by several glucoamylases and a glucodextranase. These results indicate that cleavage of the C-F bond is slow and that the enzymic transition state has significant oxo-carbonium ion character. Strong support for this conclusion is provided by the agreement found in the case of Rhizopus niveus glucoamylase (alpha-TV/K 1.26; Km 26 mM) between measured values of the alpha-secondary deuterium kinetic isotope effects (alpha-DV/K 1.16; alpha-DV 1.20) and those calculated from the tritium isotope effect. The data are consistent with the promotion of an intramolecular elimination of fluoride by the present exo-alpha-glucanases based on their ability to stabilize, perhaps with a counter ion, the development of a carbonium ion-like transition state. Although the oxo-carbonium ion is formally denoted as an intermediate it could represent a transition state along a reaction pathway to a covalent glucosyl intermediate.     

Use of an altered sugar-nucleotide to unmask the transition state for alpha(2-->6) sialyltransferase

Rat liver alpha(2-->6) sialyltransferase catalyzes the formation of a glycosidic bond between N-acetylneuraminic acid and the 6-hydroxyl group of a galactose residue at the nonreducing terminus of an oligosaccharide. This reaction has been investigated through the use of the novel sugar-nucleotide donor substrate UMP-NeuAc. A series of UMP-NeuAc radioisotopomers were prepared by chemical deamination of the corresponding CMP-NeuAc precursors. Kinetic isotope effects (KIEs) on V/K were measured using mixtures of radiolabeled UMP-NeuAc's as the donor substrate and N-acetyllactosamine as the acceptor. The secondary beta-(2)H KIE was 1.218 +/- 0.010, and the primary (14)C KIE was 1.030 +/- 0.010. A large inverse (3)H binding isotope effect of 0.944 +/- 0.010 was measured at the terminal carbon of the NeuAc glycerol side chain. These KIEs observed using UMP-NeuAc are much larger than those previously measured with CMP-NeuAc [Bruner, M., and Horenstein, B. A. (1998) Biochemistry 37, 289-297]. Solvent deuterium isotope effects of 1.3 and 2.6 on V/K and V(max) were observed with CMP-NeuAc as the donor, and it is revealing that these isotope effects vanished with use of the slow donor substrate UMP-NeuAc. Bell-shaped pH versus rate profiles were observed for V(max) (pK(a) values = 5.5, 9.0) and V/K(UMP)(-)(NeuAc) (pK(a)values = 6.2, 9.0). The results are considered in terms of a mechanism involving an isotopically sensitive conformational change which is independent of the glycosyl transfer step. The isotope effects reveal that the enzyme-bound transition state bears considerable charge on the N-acetylneuraminic acid residue, and this and other features of this mechanism provide new directions for sialyltransferase inhibitor design.     

Cytochrome P450 3A4-catalyzed testosterone 6beta-hydroxylation stereochemistry, kinetic deuterium isotope effects, and rate-limiting steps

Testosterone 6beta-hydroxylation is a prototypic reaction of cytochrome P450 (P450) 3A4, the major human P450. Biomimetic reactions produced a variety of testosterone oxidation products with 6beta-hydroxylation being only a minor reaction, indicating that P450 3A4 has considerable control over the course of steroid hydroxylation because 6beta-hydroxylation is not dominant in a thermodynamically controlled oxidation of the substrate. Several isotopically labeled testosterone substrates were prepared and used to probe the catalytic mechanism of P450 3A4: (i) 2,2,4,6,6-(2)H(5); (ii) 6,6-(2)H(2); (iii) 6alpha-(2)H; (iv) 6beta-(2)H; and (v) 6beta-(3)H testosterone. Only the 6beta-hydrogen was removed by P450 3A4 and not the 6alpha, indicating that P450 3A4 abstracts hydrogen and rebounds oxygen only at the beta face. Analysis of the rates of hydroxylation of 6beta-(1)H-, 6beta-(2)H-, and 6beta-(3)H-labeled testosterone and application of the Northrop method yielded an apparent intrinsic kinetic deuterium isotope effect ((D)k) of 15. The deuterium isotope effects on k(cat) and k(cat)/K(m) in non-competitive reactions were only 2-3. Some "switching" to other hydroxylations occurred because of 6beta-(2)H substitution. The high (D)k value is consistent with an initial hydrogen atom abstraction reaction. Attenuation of the high (D)k in the non-competitive experiments implies that C-H bond breaking is not a dominant rate-limiting step. Considerable attenuation of a high (D)k value was also seen with a slower P450 3A4 reaction, the O-dealkylation of 7-benzyloxyquinoline. Thus P450 3A4 is an enzyme with regioselective flexibility but also considerable regioselectivity and stereoselectivity in product formation, not necessarily dominated by the ease of C-H bond breaking.