18O isotope exchange experiments on phospholipase A2 determined by 13C-NMR: monomeric phosphatidylcholine and micellar phosphatidylethanolamine substrates

Experiments were carried out to determine whether the hydrolytic step or the product release step is the rate-limiting step for non-activated phospholipase A2 hydrolysis (Dennis, E.A. (1983) in The Enzymes, 3rd Edn., Vol 16 (Boyer, P., ed.), pp. 307-353, Academic Press, New York) of mixed micelles of phosphatidylethanolamine and Triton X-100 in the absence of activator phospholipids and of monomeric short chain phosphatidylcholine in the absence of an interface (Lombardo, D. et al. (1986) J. Biol. Chem. 261, 11663-11666). Phospholipase A2-catalyzed exchange of H2(18)O into 1-alkyl-2-[1(13)C]lauroyl-sn-glycero-3-phosphorylethanolamine and into 1-hexanoyl-2-[1-13C]hexanoyl-sn-glycero-3-phosphorylcholine were examined. Incorporation of 18O was detected by the effect of 18O on 13C chemical shifts in 13C-NMR. Both the substrate and products of the reactions were examined for 18O incorporation. 18O was incorporated into the fatty acid product, but no incorporation of 18O into the substrate was found. These results suggest that the hydrolytic step is not followed by a higher energy transition state and that it, or a step before it, is rate-limiting. Coupled with kinetic experiments, this strongly suggests that the hydrolytic step is the rate-limiting step. Thus, the role of micellar and membrane interfaces in phospholipase A2 reactions does not appear to be by aiding product removal from the enzyme active site.     

Permeable membrane/mass spectrometric measurement of solvent 1H/2H, 12C/13C, and 16O/18O kinetic isotope effects associated with alpha-chymotrypsin deacylation: evidence for reaction mechanism plasticity

We have measured, by permeable membrane/mass spectrometry, the 16O/18O, 12C/13C, and solvent H2O/D2O kinetic isotope effects (kie) associated with acyl-alpha-chymotrypsin hydrolysis and transesterification. The hydrolysis of alpha-chymotrypsinyl 2-furoate has a 12C/13C kie of approximately 1.06. Transesterification of the same acyl enzyme shows 16O/18O, 12C/13C, and solvent H2O/D2O kinetic isotope effects of 1.015 (0.003), 1.01-1.02, and 2.226 (0.007), respectively. From the temperature independence of the 16O/18O transesterification kinetic isotope effect and kinetic data reported elsewhere [Wang, C.-L. A., Calvo, K. C., & Klapper, M. H. (1981) Biochemistry 20, 1401-1408], we conclude that there are two active forms of acylchymotrypsin. We also propose that formation of the tetrahedral intermediate is the rate-limiting step in both hydrolysis and transesterification and that the position of the transition state in the transesterification is closer to the starting enzyme ester while that for the hydrolytic reaction is closer to the tetrahedral intermediate. These results are discussed in terms of reaction mechanism plasticity.     

Determination of substrate specificity of carboxylases by nuclear magnetic resonance

Determination of whether CO2 or HCO3- is the substrate for an enzymatic carboxylation has generally been accomplished by taking advantage of the fact that equilibration of these two compounds requires more than a minute at temperatures below 15 degrees C; thus different kinetics of carboxylation are obtained depending on whether CO2 or HCO3- is used to initiate the reaction. We report a new method using 13C18O2 as substrate for determining the CO2/HCO3- specificity of carboxylases. If CO2 is the substrate, then the 18O content of the 13C-containing product is the same as that of the 13CO2 used, whereas if HCO3- is the substrate, the 18O content is 2/3 that of the starting material. The method is independent of the detailed kinetics of the CO2/HCO3- interconversion and independent of the presence of contaminating unlabeled CO2 or HCO3-. Isotopic analysis is accomplished by 13C NMR. The method has been used to confirm that HCO3- is the substrate for phosphoenolpyruvate carboxylase. Studies of oxygen-18 isotope shifts in phosphorus NMR spectra have permitted confirmation of the observation that label is transferred from HC18O3- into Pi during the carboxylation of phosphoenolpyruvate.     

Investigation of the catalytic mechanism of the hotdog-fold enzyme superfamily Pseudomonas sp. strain CBS3 4-hydroxybenzoyl-CoA thioesterase

The 4-hydroxybenzoyl-CoA (4-HB-CoA) thioesterase from Pseudomonas sp. strain CBS3 catalyzes the final step of the 4-chlorobenzoate degradation pathway, which is the hydrolysis of 4-HB-CoA to coenzyme A (CoA) and 4-hydroxybenzoate (4-HB). In previous work, X-ray structural analysis of the substrate-bound thioesterase provided evidence of the role of an active site Asp17 in nucleophilic catalysis [Thoden, J. B., Holden, H. M., Zhuang, Z., and Dunaway-Mariano, D. (2002) X-ray crystallographic analyses of inhibitor and substrate complexes of wild-type and mutant 4-hydroxybenzoyl-CoA thioesterase. J. Biol. Chem. 277, 27468-27476]. In the study presented here, kinetic techniques were used to test the catalytic mechanism that was suggested by the X-ray structural data. The time course for the multiple-turnover reaction of 50 μM [(14)C]-4-HB-CoA catalyzed by 10 μM thioesterase supported a two-step pathway in which the second step is rate-limiting. Steady-state product inhibition studies revealed that binding of CoA (K(is) = 250 ± 70 μM; K(ii) = 900 ± 300 μM) and 4-HB (K(is) = 1.2 ± 0.2 mM) is weak, suggesting that product release is not rate-limiting. A substantial D(2)O solvent kinetic isotope effect (3.8) on the steady-state k(cat) value (18 s(-1)) provided evidence that a chemical step involving proton transfer is the rate-limiting step. Taken together, the kinetic results support a two-chemical pathway. The microscopic rate constants governing the formation and consumption of the putative aspartyl 17-(4-hydroxybenzoyl)anhydride intermediate were determined by simulation-based fitting of a kinetic model to time courses for the substrate binding reaction (5.0 μM 4-HB-CoA and 0.54 μM thioesterase), single-turnover reaction (5 μM [(14)C]-4-HB-CoA catalyzed by 50 μM thioesterase), steady-state reaction (5.2 μM 4-HB-CoA catalyzed by 0.003 μM thioesterase), and transient-state multiple-turnover reaction (50 μM [(14)C]-4-HB-CoA catalyzed by 10 μM thioesterase). Together with the results obtained from solvent (18)O labeling experiments, the findings are interpreted as evidence of the formation of an aspartyl 17-(4-hydroxybenzoyl)anhydride intermediate that undergoes rate-limiting hydrolytic cleavage at the hydroxybenzoyl carbonyl carbon atom.     

Human immunodeficiency virus-1 protease. 1. Initial velocity studies and kinetic characterization of reaction intermediates by 18O isotope exchange

The peptidolytic reaction of HIV-1 protease has been investigated by using four oligopeptide substrates, Ac-Ser-Gln-Asn-Tyr-Pro-Val-Val-NH2, Ac-Arg-Ala-Ser-Gln-Asn-Tyr-Pro-Val-Val-NH2, Ac-Ser-Gln-Ser-Tyr-Pro-Val-Val-NH2, and Ac-Arg-Lys-Ile-Leu-Phe-Leu-Asp-Gly-NH2, that resemble two cleavage sites found within the naturally occurring polyprotein substrates Pr55gag and Pr160gag-pol. The values for the kinetic parameters V/KEt and V/Et were 0.16-7.5 mM-1 s-1 and 0.24-29 s-1, respectively, at pH 6.0, 0.2 M NaCl, and 37 degrees C. By use of a variety of inorganic salts, it was concluded that the peptidolytic reaction is nonspecifically activated by increasing ionic strength. V/K increased in an apparently parabolic fashion with increasing ionic strength, while V was either increased or decreased slightly. From product inhibition studies, the kinetic mechanism of the protease is either random or ordered uni-bi, depending on the substrate studied. The reverse reaction or a partial reverse reaction (as measured by isotope exchange of the carboxylic product into substrate) was negligible for most of the oligopeptide substrates, but the enzyme catalyzed the formation of Ac-Ser-Gln-Asn-Tyr-Phe-Leu-Asp-Gly-NH2 from the products Ac-Ser-Gln-Asn-Tyr and Phe-Leu-Asp-Gly-NH2. The protease-catalyzed exchange of an atom of 18O from H2 18O into the re-formed substrates occurred at a rate which was 0.01-0.12 times that of the forward peptidolytic reaction. The results of these studies are in accord with the formation of a kinetically competent enzyme-bound amide hydrate intermediate, the collapse of which is the rate-limiting chemical step in the reaction pathway.     

Rate-limiting steps in the DNA polymerase I reaction pathway

The initial rates of incorporation of dTTP and thymidine 5'-O-(3-thiotriphosphate) (dTTP alpha S) into poly(dA) X oligo(dT) during template-directed synthesis by the large fragment of DNA polymerase I have been measured by using a rapid-quench technique. The rates were initially equal, indicating a nonrate-limiting chemical step. However, the rate of thionucleotide incorporation steadily diminished to 10% of its initial value as the number of consecutive dTMP alpha S residues in the primer strand increased. This anomalous behavior can be attributed to the helix instability inherent in phosphorothioate-containing duplexes. Positional isotope exchange experiments employing the labeled substrate [alpha-18O2]dATP have revealed negligible alpha, beta-bridging----beta-nonbridging isotope exchange in template-directed reactions of Escherichia coli DNA polymerase I (Pol I) both in the presence and in the absence of added inorganic pyrophosphate (PPi), suggesting rapid PPi release following the chemical step. These observations are consistent with a rate-limiting step that is tentatively assigned to a conformational change of the E X DNA X dNTP complex immediately preceding the chemical step. In addition, the substrate analogue (Sp)-dATP alpha S has been employed to examine the mechanism of the PPi exchange reaction catalyzed by Pol I. The net retention of configuration at the alpha-P is interpreted in terms of two consecutive inversion reactions, namely, 3'-hydroxyl attack, followed by PPi attack on the newly formed primer terminus. Kinetic analysis has revealed that while alpha-phosphorothioate substitution has no effect upon the initial rate of polymerization, it does attenuate the PPi exchange reaction by a factor of 15-18 fold.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of fatty acid 18O exchange catalyzed by pancreatic carboxylester lipase. 1. Mechanism and kinetic properties.

The exchange of 18O between H2O and long-chain free fatty acids is catalyzed by pancreatic carboxylester lipase (EC 1.1.1.13). For palmitic, oleic, and arachidonic acid in aqueous suspension and for 13,16-cis,cis-docosadienoic acid (DA) in monomolecular films, carboxyl oxygens were completely exchanged with water oxygens of the bulk aqueous phase. With enzyme at either substrate or catalytic concentrations in the argon-buffer interface, the exchange of DA oxygens obeyed a random sequential mechanism, i.e., 18O,18O-DA in equilibrium with 18O,16O-DA in equilibrium with 16O,16O-DA. This indicates that the dissociation of the enzyme-DA complex is much faster than the rate-limiting step in the overall exchange reaction. Kinetic analysis of 18O exchange showed a first-order dependence on surface enzyme and DA concentrations, i.e., the reaction was limited by the acylation rate. The values of kcat/Km, 0.118 cm2 pmol-1 s-1, for the exchange reaction was comparable to that for methyl oleate hydrolysis and 5-fold higher than that for cholesteryl oleate hydrolysis in monolayers [Bhat, S., & Brockman, H. L. (1982) Biochemistry 21, 1547]. Thus, fatty acids are good "substrates" for carboxylester lipase. With substrate levels of carboxylester lipase in the interfacial phase, the acylation rate constant kcat/Km was 200-fold lower than that obtained with catalytic levels of enzyme. This suggests a possible restriction of substrate diffusion in the protein-covered substrate monolayer.     

3-Hydroxy-3-methylglutaryl-CoA synthase: participation of invariant acidic residues in formation of the acetyl-S-enzyme reaction intermediate

Inactivation of HMG-CoA synthase by a carboxyl-directed reagent, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), in a concentration-dependent and substrate-protectable manner suggested that the active site contains reactive acidic amino acids. This observation prompted functional evaluation of 11 invariant acidic amino acids by site-directed mutagenesis. Characterization of the isolated synthase variants' ability to catalyze overall and partial reactions identified three mutant synthases (D99A, D159A, and D203A) that exhibit significant diminution of k(cat) for the overall reaction (10(2)-, 10(3)-, and 10(4)-fold decreases, respectively). D99A, D159A, and D203A form the acetyl-S-enzyme intermediate very slowly (0.0025, 0.0026, 0.0015 U/mg, respectively, measured at pH 7. 0 and 22 degrees C) as compared to the wild-type synthase (1.59 U/mg), where intermediate formation approaches rate-limiting status. Differences in substrate saturation do not account for impaired activities or rates of intermediate formation. The structural integrity of the purified mutants' active sites is demonstrated by their abilities to bind a spin-labeled acyl-CoA analogue (R.CoA) with affinities and stoichiometries comparable to values measured for wild-type synthase. The impact of three distinct amino acids on reaction intermediate formation supports a mechanism of acetyl-S-enzyme formation that probably requires formation and directed collapse of a tetrahedral adduct. (18)O-induced shift of the (13)C NMR signal of (13)C acetyl-S-enzyme demonstrates that an analogous tetrahedral species is produced upon solvent exchange with the acetyl-S-enzyme. Partial discrimination between the functions of D99, D159, and D203 becomes possible based on the observation that D159A and D203A synthases exhibit retarded kinetics of solvent (18)O exchange while D99A fails to support (18)O exchange.     

Evidence for a gem-diol reaction intermediate in bacterial C-C hydrolase enzymes BphD and MhpC from 13C NMR spectroscopy

C-C hydrolase enzymes MhpC and BphD catalyze the hydrolytic C-C cleavage of meta-ring fission intermediates on the Escherichia coli phenylpropionic acid and Burkholderia xenovorans LB400 biphenyl degradation pathways and are both members of the alpha/beta-hydrolase family containing a Ser-His-Asp catalytic triad. The catalytic mechanism of this family of enzymes is thought to proceed via a gem-diol reaction intermediate, which has not been observed directly. Site-directed single mutants of BphD in which catalytic residues His-265 and Ser-112 were replaced with Ala were found to possess 10(4)-fold reduced k(cat) values, and in each case, the C-C cleavage step was shown by pre-steady-state kinetic analysis to be rate-limiting. The processing of a 6-(13)C-labeled aryl-containing substrate by these H265A or S112A mutant BphD enzymes was monitored directly by (13)C NMR spectroscopy. A new line-broadened signal was observed at 128 ppm for each enzyme, corresponding to the proposed gem-diol reaction intermediate, over a time scale of 1-24 h. A similar signal was observed upon incubation of the (13)C-labeled substrate with an H114A MhpC mutant, which is able to accept the 6-phenyl-containing substrate, on a shorter time scale. The direct observation of a gem-diol intermediate provides further evidence that supports a general base mechanism for this family of enzymes.     

Conversion of 5-S-methyl-5-thio-D-ribose to methionine in Klebsiella pneumoniae. Stable isotope incorporation studies of the terminal enzymatic reactions in the pathway

Extracts of Klebsiella pneumoniae convert 5-S-methyl-5-thio-D-ribose (methylthioribose) to methionine and formate. To probe the terminal steps of this biotransformation, [1-13C]methylthioribose has been synthesized and its metabolism examined. When supplemented with Mg2+, ATP, L-glutamine, and dioxygen, cell-free extracts of K. pneumoniae converted 50% of the [1-13C]methylthioribose to [13C]formate. The formation of [13C]formate was established by 13C and 1H NMR spectroscopy studies of the purified formate, and by 13C and 1H NMR spectroscopy and mass spectrometry studies of its p-phenylphenacyl derivative. By contrast, no incorporation of label from [1-13C]methylthioribose into the biosynthesized methionine was detected by either mass spectrometry or 13C and 1H NMR spectroscopy. The most reasonable interpretation of these results is that C-1 of methylthioribose is converted directly to formate concomitant with the conversion of carbon atoms 2-5 to methionine. The penultimate step in the conversion of methylthioribose to methionine and formate is an oxidative carbon-carbon bond cleavage reaction in which an equivalent of dioxygen is consumed. To investigate the fate of the dioxygen utilized in this reaction, the metabolism of [1-13C]methylthioribose in the presence of 18O2 was also examined. Mass spectrometry revealed the biosynthesis of substantial amounts of both [18O1]methionine and [13C, 18O1]formate under these conditions. These results suggest that the oxidative transformation in the conversion of methylthioribose to methionine and formate may be catalyzed by a novel intramolecular dioxygenase. A mechanism for this dioxygenase is proposed.     

Product release is rate-limiting in the activation of the prodrug 5-fluorocytosine by yeast cytosine deaminase

Yeast cytosine deaminase (yCD), a zinc metalloenzyme, catalyzes the hydrolytic deamination of cytosine to uracil. The enzyme is of great biomedical interest because it also catalyzes the deamination of the prodrug 5-fluorocytosine (5FC) to form the anticancer drug 5-fluorouracil (5FU). yCD/5FC is one of the most widely used enzyme/prodrug combinations for gene-directed enzyme prodrug therapy for the treatment of cancers. A pH indicator assay has been developed for the measurement of the steady-state kinetic parameters for the deamination reaction. Transient kinetic studies have shown that the product release is a rate-limiting step in the activation of the prodrug 5FC by yCD. The rate constant of the chemical step for the forward reaction (250 s(-)(1)) is approximately 8 times that of the product release (31 s(-)(1)) and approximately 15 times k(cat) (17 s(-)(1)). The transient kinetic results are consistent with those of the steady-state kinetic analysis in the sense that the k(cat) and K(m) values calculated from the rate constants determined by the transient kinetic analysis are in close agreement with those measured by the steady-state kinetic analysis. NMR experiments have demonstrated that free 5FU is in slow exchange with its complex with yCD but has a low affinity for yCD. The transient kinetic and NMR results together suggest that the release of 5FU is rate-limiting in the activation of the prodrug 5FC by yCD and may involve multiple steps.     

On the water and proton permeabilities across membranes from erythrocyte ghosts

The diffusional permeability of water across membranes from bovine and human erythrocyte ghosts was measured by a recently developed method which is based on the different indices of refraction of H2O and 2H2O. Resealed erythrocyte ghosts were prepared by a gel-filtration technique. Pd (2H2O/H2O) values of 1.2 X 10(-3) cm/s (human) and 1.7 X 10(-3) cm/s (bovine) were calculated at 20 degrees C. The activation energies of the water exchange were 23.5 kJ/mol (human) and 25.4 kJ/mol (bovine). Treatment of the ghosts with p-chloromercuribenzenesulfonic acid (PCMBS) led to a 60-70% inhibition of the diffusional water exchange. The pH equilibration across membranes of erythrocyte ghosts was measured by intracellular carboxyfluorescein. The rates of proton flux after pH-jumps (pH 7.3 to pH 6.1) were about 100-fold lower than those of the water exchange and dependent on the kind of anions present (Cl-, NO-3, SO2-4). The activation energies of proton flux were 60-70 kJ/mol. 4,4'-Diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS) inhibited the exchange by 97-98% and lowered the activation energy. The inhibitor of water exchange, PCMBS, increased the proton-permeation rate by a factor of 4-5. It is assumed that the rate-limiting step for the proton permeation is determined by the anion exchange. Under this condition our results are not in accord with one channel as a common pathway for both the passive water and anion transport.     

Regulation of the synthesis and hydrolysis of ATP by mitochondrial ATPase. Role of Mg2+

ATP hydrolysis, the exchange of inorganic phosphate with ATP, and ATP synthesis have been studied as a function of Mg2+ concentration in bovine heart submitochondrial particles. The rate of exchange is low at concentrations of Mg2+ below 3 mM, at higher concentrations, the exchange is several times higher. ATP hydrolysis shows a different pattern with respect to the concentration of Mg2+. The ratio of ATP hydrolyzed to ATP exchanged is above 20 at Mg2+ concentrations below 3 mM and about 5 at high Mg2+ concentrations; ADP induces a further drop of the ratio (2-3). By assays of the sensitivity of the hydrolytic reaction to organic solvents (dimethyl sulfoxide), it has been possible to determine the rate-limiting step of ATP hydrolysis. At 3 mM Mg2+, the rate-limiting step is the release of ADP in the soluble, but not in the particulate enzyme. However at higher Mg2+ concentrations, the rate-limiting step in the particulate enzyme is also ADP release. Therefore, the decrease in the ratio of ATP hydrolysis to inorganic phosphate incorporated into ATP coincides with a change in the kinetics of the enzyme, i.e. when the terminal step of ATP hydrolysis becomes rate-limiting, the inorganic phosphate-ATP exchange increases. Ca2+ induces an increase in the phosphate-ATP exchange at low Mg2+ concentrations.     

Interaction of group IA phospholipase A2 with metal ions and phospholipid vesicles probed with deuterium exchange mass spectrometry

Deuterium exchange mass spectrometric evaluation of the cobra venom (Naja naja naja) group IA phospholipase A 2 (GIA PLA 2) was carried out in the presence of metal ions Ca (2+) and Ba (2+) and phospholipid vesicles. Novel conditions for digesting highly disulfide bonded proteins and a methodology for studying protein-lipid interactions using deuterium exchange have been developed. The enzyme exhibits unexpectedly slow rates of exchange in the two large alpha-helices of residues 43-53 and 89-101, which suggests that these alpha-helices are highly rigidified by the four disulfide bonds in this region. The binding of Ca (2+) or Ba (2+) ions decreased the deuterium exchange rates for five regions of the protein (residues 24-27, 29-40, 43-53, 103-110, and 111-114). The magnitude of the changes was the same for both ions with the exception of regions of residues 24-27 and 103-110 which showed greater changes for Ca (2+). The crystal structure of the N. naja naja GIA PLA 2 contains a single Ca (2+) bound in the catalytic site, but the crystal structures of related PLA 2s contain a second Ca (2+) binding site. The deuterium exchange studies reported here clearly show that in solution the GIA PLA 2 does in fact bind two Ca (2+) ions. With dimyristoylphosphatidylcholine (DMPC) phospholipid vesicles with 100 microM Ca (2+) present at 0 degrees C, significant areas on the i-face of the enzyme showed decreases in the rate of exchange. These areas included regions of residues 3-8, 18-21, and 56-64 which include Tyr-3, Trp-61, Tyr-63, and Phe-64 proposed to penetrate the membrane surface. These regions also contained Phe-5 and Trp-19, proposed to bind the fatty acyl tails of substrate.     

Phospholipase A2 as a mechanosensor.

Osmotic swelling of large unilamellar vesicles (LUVs) causes membrane stretching and thus reduces the lateral packing of lipids. This is demonstrated to modulate strongly the catalytic activity of phospholipase A2 (PLA2) toward a fluorescent phospholipid, 1-palmitoyl-2-[(6-pyren-1-yl)]decanoyl-sn-glycero-3-phosphocholine (PPDPC) residing in LUVs composed of different unsaturated and saturated phosphatidylcholines. The magnitude of the osmotic pressure gradient delta omega required for maximal PLA2 activity as well as the extent of activation depend on the degree of saturation of the membrane phospholipid acyl chains. More specifically, delta omega needed for maximal hydrolytic activity increases in the sequence DOPC < SOPC < DMPC in accordance with the increment in the intensity of chain-chain van der Waals interactions. Previous studies on the hydrolysis of substrate monolayers by C. adamanteus and N. naja PLA2 revealed maximal hydrolytic rates for these two enzymes to be achieved at lipid packing densities corresponding to surface pressures of 12 and 18 mN m-1, respectively. In keeping with the above the magnitudes of delta omega producing maximal activity of Crotalus adamanteus and Naja naja toward PPDPC/DMPC LUVs were 40 and 20 mOsm/kg, respectively. Our findings suggest a novel possibility of regulating the activity of PLA2 and perhaps also other lipid packing density-dependent enzymes in vivo by osmotic forces applied on cellular membranes. Importantly, our results reveal serendipitously that the responsiveness of membranes to osmotic stress is modulated by the acyl chain composition of the lipids.     

13C NMR investigation of the anomeric specificity of CMP-N-acetylneuraminic acid synthetase from Escherichia coli.

The anomeric specificity of Escherichia coli CMP-N-acetylneuraminic acid (CMP-NeuAc) synthetase was investigated by NMR using 13C-labeled N-acetylneuraminic acid (NeuAc). Consumption of the beta-anomer of [2-13C]N-acetylneuraminic acid was observed upon addition of enzyme, with a concomitant appearance of an anomeric resonance for CMP-N-acetylneuraminic acid. Inhibition by substrate analogues the anomeric oxygen was determined in a similar manner using [2-13C,(50 atom %)18O]N-acetylneuraminic acid. An upfield shift of 1.5 Hz in the anomeric resonance of both the [13C]NeuAc substrate and CMP-[13C]NeuAc product was observed due to the 18O substitution. This result implies conservation of the NeuAc oxygen. Results of steady-state kinetic analysis suggest a sequential-type mechanism and therefore no covalent intermediate. Thus, CMP-beta-NeuAc is probably formed by a direct transfer of the anomeric oxygen of beta-NeuAc to the alpha-phosphate of CTP.     

Hydrolytic dehalogenation of 4-chlorobenzoic acid by an Acinetobacter sp

Acinetobacter sp. strain ST-1, isolated from garden soil, can mineralize 4-chlorobenzoic acid (4-CBA). The bacterium degrades 4-CBA, starting with dehalogenation to yield 4-hydroxybenzoic acid (4-HBA) under both aerobic and anaerobic conditions, suggesting that the dehalogenating enzyme in the strain is not an oxygenase; the enzyme may catalyze halide hydrolysis. To identify the oxygen source of the C(4)-hydroxy groups in the dehalogenation step, we used H(2)(18)O as the solvent under anaerobic conditions. When resting cells were incubated in the presence of 4-CBA and H(2)(18)O under a nitrogen gas stream, the hydroxy group on the aromatic nucleus of the 4-HBA produced was derived from water, not from molecular oxygen. This dehalogenation was hydrolytic, because analysis of the mass spectrum of the trimethylsilyl derivative of one of the metabolites, (18)O-labeled 4-HBA, showed that 80% of the C4-hydroxy groups were labeled with (18)O. Hydrolytic dehalogenation of 4-CBA in intact cells has not been reported earlier. To identify substrate specificity, we next examined the ability of the strain to dehalogenate 4-CBA analogues and dichlorobenzoic acids. The results of metabolite analysis by high-pressure liquid chromatography showed that the strain dehalogenated 4-bromobenzoic acid and 4-iodobenzoic acid, yielding 4-HBA, suggesting that these compounds could be further degraded and mineralized by the strain via the beta-ketoadipate pathway, as occurs with 4-CBA. This strain, however, did not dehalogenate 4-fluorobenzoic acid, 2- and 3-chlorobenzoic acids, or 2,4-, 3,4-, and 3,5-dichlorobenzoic acids during 4 days of incubation, implying that the dehalogenating enzyme of the strain has high substrate specificity.     

The 18O isotope effect in 13C nuclear magnetic resonance spectroscopy: mechanistic studies on asparaginase from Escherichia coli

The mechanism of the enzyme asparaginase (L-asparagine amidohydrolase, EC 3.5.1.1) from Escherichia coli was examined using 13C NMR spectroscopy. The pH-dependent oxygen exchange reactions between water and aspartic acid were followed by use of the 18O isotope-induced shift of the resonance positions of directly bonded 13C nuclei. Both L-1- and L-1,4-[13C]aspartic acid were used in experiments with previously 18O-labeled aspartic acid, or in experiments involving the use of 18O-labeled solvent water. Asparaginase catalyzes a relatively efficient exchange between the oxygens of water and those on one carboxyl group of aspartic acid. Exchange at C-4 occurs rapidly but, within experimental error, no exchange at C-1 could be detected. These and related experiments involving the position of 18O incorporation during hydrolysis of aspartic acid beta-methyl ester are all consistent with possible acyl-enzyme mechanisms involving C-4, but do not support a free aspartic acid anhydride mechanism.     

Bicarbonate is a recycling substrate for cyanase

Cyanase is an inducible enzyme in Escherichia coli that catalyzes bicarbonate-dependent decomposition of cyanate to ammonia and bicarbonate. Previous studies provided evidence that carbamate is an initial product and that the kinetic mechanism is rapid equilibrium random (bicarbonate serving as substrate as opposed to activator); the following mechanism was proposed (Anderson, P. M. (1980) Biochemistry 19, 2282-2888; Anderson, P. M., and Little, R. M. (1986) Biochemistry 25, 1621-1626). (formula; see text) Direct evidence for this mechanism was obtained in this study by 1) determining whether CO2 or HCO3- serves as substrate and is formed as product, 2) identifying the products formed from [14C]HCO3- and [14C] OCN-, 3) identifying the products formed from [13C] HCO3- and [12C]OCN- in the presence of [18O]H2O, and 4) determining whether 18O from [18O]HCO3- is incorporated into CO2 derived from OCN-. Bicarbonate (not CO2) is the substrate. Carbon dioxide (not HCO3-) is produced in stoichiometric amounts from both HCO3- and OCN-. 18O from [18O]H2O is not incorporated into CO2 formed from either HCO3- or OCN-. Oxygen-18 from [18O]HCO3- is incorporated into CO2 derived from OCN-. These results support the above mechanism, indicating that decomposition of cyanate catalyzed by cyanase is not a hydrolysis reaction and that bicarbonate functions as a recycling substrate.     

GDP-mannose mannosyl hydrolase catalyzes nucleophilic substitution at carbon, unlike all other Nudix hydrolases

GDP-mannose mannosyl hydrolase (GDPMH) from Escherichia coli is a 36. 8 kDa homodimer which, in the presence of Mg(2+), catalyzes the hydrolysis of GDP-alpha-D-mannose or GDP-alpha-D-glucose to yield sugar and GDP. On the basis of its amino acid sequence, GDPMH is a member of the Nudix family of enzymes which catalyze the hydrolysis of nucleoside diphosphate derivatives by nucleophilic substitution at phosphorus. However, GDPMH has a sequence rearrangement (RE to ER) in the conserved Nudix motif and is missing a Glu residue characteristic of the Nudix signature sequence. By (1)H NMR, the initial hydrolysis product of GDP-alpha-D-glucose is beta-D-glucose, indicating nucleophilic substitution with inversion at C1' of glucose. Substitution at carbon was confirmed by two-dimensional (1)H-(13)C HSQC spectra of the products of hydrolysis in 48.4% (18)O-labeled water which showed an additional C1' resonance of beta-D-glucose with a typical upfield (18)O isotope shift of 18 ppb and an intensity of 47.6% of the total signal. No (18)O isotope-shifted resonances (<4%) were found in the (31)P NMR spectrum of the GDP product. Thus, unlike all other Nudix enzymes studied so far, GDPMH catalyzes nucleophilic substitution at carbon rather than at phosphorus. A small solvent kinetic deuterium isotope effect on k(cat) of 1.76 +/- 0.25, independent of pH over the range of 6.0-9.3, suggests that the deprotonation of water may be part of the rate-limiting step.