Initial velocity, spectral, and pH studies of the serine-glyoxylate aminotransferase from Hyphomicrobiuim methylovorum.

Serine-glyoxylate aminotransferase (SGAT) from Hyphomicrobium methylovorum is a pyridoxal 5'-phosphate (PLP) enzyme that catalyzes the interconversion of L-serine and glyoxylate to hydroxypyruvate and glycine. The initial velocity and dead-end inhibition patterns are consistent with a ping-pong kinetic mechanism. The Km values for L-serine and the alternative substrate ketomalonate are 0.28 +/- 0.02 and 1.13 +/- 0.08 mM, respectively. The spectrum of SGAT at pH 7.5 shows an absorbance maximum at 413 nm and a shoulder centered at 330 nm corresponding to the ketoenamine and enolimine forms of the protonated Schiff's base with the enolimine tautomer predominating. As determined by the changes in the enzyme absorbance spectrum the enzyme can be converted from the E-PLP to the E-pyridoxamine 5'-phosphate (E-PMP) form on addition of L-serine. The enzyme can subsequently be converted back to E-PLP by addition of glyoxylate or hydroxypyruvate. The enzyme displays a pH-dependent spectral change with a pK of about 8.2 which is ascribed to the ionization of an enzymatic residue that effects the tautomeric equilibrium between the ketoenamine and enolimine tautomers of the protonated aldimine. The V/K(L-serine) pH profile displays two pK values at pH 7.5 and 8.5 with limiting slopes of 1 and -1. The V/K(ketomalonate) pH profile displays one pK at 8.2 on the basic side with a limiting slope of 1 and the log K(I oxalate) pH profile shows one pK on the basic side at pH 7.2. The data suggest the active enzyme is the protonated aldimine and an enzymatic base with a pK of 7.5 accepts a proton from the alpha-amine of substrate to initiate catalysis.

Lysine 199 is the general acid in the NAD-malic enzyme reaction.

Site-directed mutagenesis was used to change K199 in the Ascaris suum NAD-malic enzyme to A and R and Y126 to F. The K199A mutant enzyme gives a 10(5)-fold decrease in V and a 10(6)-fold decrease in V/K(malate) compared to the WT enzyme. In addition, the ratio for partitioning of the oxalacetate intermediate toward pyruvate and malate changes from a value of 0.4 for the WT enzyme to 1.6 for K199A, and repeating the experiment with A-side NADD gives isotope effects of 3 and 1 for the WT and K199A mutant enzymes, respectively. The K199R mutant enzyme gives only a factor of 10 decrease in V, and the pK for the general acid in this mutant enzyme has increased from 9 for the WT enzyme to >10 for the K199R mutant enzyme. Tritium exchange from solvent into pyruvate is catalyzed by the WT enzyme, but not by the K199A mutant enzyme. The Y126F mutant enzyme gives a 10(3)-fold decrease in V. The oxalacetate partition ratio and isotope effect on oxalacetate reduction for the Y126F mutant enzyme are identical, within error, to those measured for the WT enzyme. Thus, Y126 is important to the overall reaction, but its role at present is unclear. Data are consistent with K199 functioning as the general acid that protonates C3 of enolpyruvate to generate the pyruvate product in the malic enzyme reaction.

Mapping the active site topography of the NAD-malic enzyme via alanine-scanning site-directed mutagenesis.

The NAD-malic enzyme cDNA has been subcloned into the pQE expression vector, expressed with a six-His tag, and purified. The His-tagged enzyme is purified by a combination of Ni-NTA and orange A agarose column chromatography with a yield of 45% and an estimated purity of >90%. The tag and linker have no effect on the kinetic parameters of the enzyme compared to the wild-type enzyme. Alanine-scanning site-directed mutagenesis has been carried out on all of the conserved neutral acid residues of the NAD-malic enzyme from Ascaris suum. Data obtained confirm the predicted role of D178 and D295 in metal ion binding, the likely role of D294, D361, and E440 in the NAD binding site, and the role of E58 and D272 in malate binding. Decreases in V/E(t) by 10(4)-fold and in V/K(malate)E(t) by 10(7)-fold, when D295 is changed to alanine, suggest that it is a likely candidate for the general base that accepts a proton from the malate hydroxyl in the oxidation step.

Alpha-secondary tritium kinetic isotope effects indicate hydrogen tunneling and coupled motion occur in the oxidation of L-malate by NAD-malic enzyme.

The NAD-malic enzyme from Ascaris suum catalyzes the divalent metal ion-dependent oxidative decarboxylation of L-malate to give pyruvate and CO2, with NAD+ as the oxidant. Alpha-secondary tritium kinetic isotope effects were measured with NAD+ or APAD+ and L-malate-2-H(D) and several different divalent metal ions. The alpha-secondary tritium kinetic isotope effects are slightly higher than 1 with NAD+ and L-malate as substrates, much larger than the expected inverse isotope effect for a hybridization change from sp2 to sp3. The alpha-secondary tritium kinetic isotope effects are reduced to values near 1 with L-malate-2-D as the substrate, regardless of the metal ion that is used. Data suggest the presence of quantum mechanical tunneling and coupled motion in the malic enzyme reaction when NAD+ and malate are used as substrates. Isotope effects were also measured using the D/T method with NAD+ and Mn2+ as the substrate pair. A Swain-Schaad exponent of 2.2 (less than the value of 3.26 expected for strictly semiclassical behavior) is estimated, suggesting the presence of other slow steps along the reaction pathway. With APAD+ and Mn2+ as the substrate pair, inverse alpha-secondary tritium kinetic isotope effects are observed, and a Swain-Schaad exponent of 3.3 is estimated, consistent with rate-limiting hydride transfer and no quantum mechanical tunneling or coupled motion. Data are discussed in terms of the malic enzyme mechanism and the theory developed by Huskey for D/T isotope effects as an indicator of tunneling [Huskey, W. P. (1991) J. Phys. Org. Chem. 4, 361-366].

Glutamate 190 is a general acid catalyst in the 6-phosphogluconate-dehydrogenase-catalyzed reaction.

Site-directed mutagenesis was used to change E190 of sheep liver 6-phosphogluconate dehydrogenase to A, D, H, K, Q, and R to probe its possible role as a general acid catalyst. Each of the mutant proteins was characterized with respect to the pH dependence of kinetic parameters. Mutations that eliminate a titrable group at position 190, result in pH-rate profiles with no observable pK on the basic side of the V/K6PG profile. Mutations that change the pK of the group at position 190 result in the expected pK perturbations in the V/K6PG profile. Kinetic parameters obtained at the pH optimum in the pH-rate profiles are consistent with a rate-limiting tautomerization of the 1,2-enediol of ribulose 5-phosphate consistent with the proposed role of E190. Data are also consistent with some participation of E190 in an isomerization required to form the active Michaelis complex.

Oxidative decarboxylation of 6-phosphogluconate by 6-phosphogluconate dehydrogenase proceeds by a stepwise mechanism with NADP and APADP as oxidants.

Primary kinetic deuterium, 13C, and multiple deuterium/13C-isotope effects on V/K6PG have been measured for the Candida utilis (cu) and sheep liver (sl) 6-phosphogluconate dehydrogenases (6PGDH). With NADP as the dinucleotide substrate, the following values of D(V/K6PG), 13(V/K6PG)H, and 13(V/K6PG)D were measured at pH 8 for cu6PGDH (sl6PGDH): 1.57 +/- 0.08 (1.87 +/- 0.10), 1.0209 +/- 0.0005 (1.0059 +/- 0.000 10), 1.0158 +/- 0.0001 (1.0036 +/- 0.0008). With APADP as the dinucleotide substrate, values for the above isotope effects at pH 8 are as follows: 2.98 +/- 0.08 (2.47 +/- 0.06), 1. 0106 +/- 0.0002 (1.0086 +/- 0.000 09), and 0.9934 +/- 0.0003 (0.9950 +/- 0.0003). Results indicate the oxidative decarboxylation of 6PG to the 1,2-enediol of ribulose 5-phosphate proceeds via a stepwise mechanism with hydride transfer preceding decarboxylation in all cases. The inverse 13C-isotope effect observed with APADP and 6PG-3d may reflect a preequlibrium isotope effect on the binding of 6PG preceding hydride transfer. Deuterium-isotope effects on V, V/KNADP, and V/K6PG are identical at all pHs and for both enzymes. The primary deuterium-isotope effect on V/K6PG for both enzymes is constant at pH values below the pK in the pH profile for V/K6PG, and decreases as the pH increases. Data suggest the development of rate limitation by a step or steps other than the hydride-transfer step as the pH is increased.

Cloning, expression, purification, and characterization of the 6-phosphogluconate dehydrogenase from sheep liver.

The mRNA encoding the 51-kDa subunit of 6-phosphogluconate dehydrogenase (6PGDH) from sheep liver was reverse-transcribed and amplified. The resulting cDNA was reamplified in N-terminal and C-terminal segments and spliced to generate a full-length clone, and an internal cDNA fragment was also amplified. The full-length clone containing the complete coding sequence of the 6PGDH cDNA was sequenced and found to contain two mutations and two deletions in the internal region and two mutations outside of the internal region, an A to G point mutation at position 1407 that resulted in the amino acid change Gln 445 to Arg and a silent mutation at position 1426. The internal clone was sequenced and shown to be free of any mutations; therefore the internal piece was used to replace the same region in the full-length clone to correct the mutations in this region. The mutation at position 1407 which was outside of the internal region was corrected using site-directed mutagenesis. The cDNA with the correct codon was then subcloned into the bacterial expression vector pQE-30 and overproduced in Escherichia coli strain M15. A protein with a subunit molecular weight of 51,000 was expressed at a level of about 4.5% of the total soluble protein in M15 as judged by SDS/PAGE. Cloning into pQE-30 adds six histidines and a short linker to the N-terminus of the enzyme. The recombinant 6PGDH with His-tag was purified using the Ni-NTA affinity column supplied by Qiagen. The purification procedure resulted in a homogeneous protein by SDS/PAGE with 22.4-fold purification with an overall yield of 61%. The recombinant enzyme exhibits kinetic parameters within error identical to those measured for native sheep liver enzyme.

Expression, purification, and characterization of the recombinant NAD-malic enzyme from Ascaris suum.

The cDNA encoding the 65-kDa subunit of malic enzyme from Ascaris suum was cloned into the bacterial expression vector pKK223-3 and overproduced in Escherichia coli. A protein with a subunit molecular mass of 65,000 was expressed at a level of up to 3% of the total soluble protein in JM109, as judged by SDS-PAGE. The enzyme was purified using column chromatography on phenyl-Sepharose followed by orange-A agarose. The purification procedure resulted in a 32-fold purification with an overall yield of 51%. The bacterially expressed enzyme exhibits kinetic constants identical to those measured for native A. suum NAD-malic enzyme.

Dihydrodipicolinate synthase from Escherichia coli: pH dependent changes in the kinetic mechanism and kinetic mechanism of allosteric inhibition by L-lysine.

Dihydrodipicolinate synthase (DHDPS) catalyzes the formation of dihydrodipicolinate from pyruvate and L-aspartate beta-semialdehyde (ASA). A parallel initial velocity pattern that displays competitive substrate inhibition by ASA and dead-end inhibition patterns obtained at pH 8 are consistent with a ping pong kinetic mechanism for DHDPS. The results suggest that pyruvate binds to free enzyme with subsequent formation of a Schiff base with an enzymic lysine residue followed by binding of ASA to the F enzyme form to initiate the second half-reaction. At low pH (5.7) the initial velocity and dead-end inhibition patterns are consistent with a sequential steady state ordered kinetic mechanism with pyruvate binding to enzyme prior to ASA. The irreversible step in the reaction, leading to the ping pong kinetic mechanism at high pH, is proposed to be loss of a proton from the methyl group of pyruvate in Schiff base with enzyme to form an enamine intermediate. Consistent with this proposal is the change to a sequential steady state ordered kinetic mechanism at low pH at or below the pK of the enamine intermediate. L-Lysine is an allosteric inhibitor of the DHDPS reaction that causes partial inhibition (approximately 90%) at saturating concentrations. Inhibition patterns for L-lysine vs pyruvate and ASA suggest that lysine binds to the F enzyme form at pH 8 with a Ki value of about 0.3 mM. An examination of the effects of different L-lysine concentrations on the kinetic parameters V/Kpyruvate, V/KASA, and V indicate that L-lysine decreases only the values of V/KASA and Vmax, which is consistent with the inhibitory effects of lysine manifested on the second half-reaction. In contrast at low pH the data suggest L-lysine binds to free enzyme with an inhibition constant of about 5 mM.

A change in the internal aldimine lysine (K42) in O-acetylserine sulfhydrylase to alanine indicates its importance in transimination and as a general base catalyst.

O-Acetylserine sulfhydrylase (OASS) is a pyridoxal 5'-phosphate dependent enzyme that catalyzes a beta-replacement reaction forming L-cysteine and acetate from O-acetyl-L-serine (OAS) and sulfide. The pyridoxal 5'-phosphate (PLP) is bound at the active site in Schiff base linkage with a lysine. In the present study, the Schiff base lysine was identified as lysine 42, and its role in the OASS reaction was determined by changing it to alanine using site-directed mutagenesis. K42A-OASS is isolated as an external aldimine with methionine or leucine and shows no reaction with the natural substrates. Apo-K42A-OASS can be reconstituted with PLP, suggesting that K42 is not necessary for cofactor binding and formation of the external Schiff base. The apo-K42A-OASS, reconstituted with PLP, shows slow formation of the external aldimine but does not form the alpha-aminoacrylate intermediate on addition of OAS, suggesting that K42 is involved in the abstraction of the alpha-proton in the beta-elimination reaction. The external aldimines formed upon addition of L-Ala or L-Ser are stable and represent a tautomer that absorbs maximally at 420 nm, while L-Cys gives a tautomeric form of the external aldimine that absorbs at 330 nm, and is also seen in the overall reaction after addition of primary amines to the assay system. The use of a small primary amine such as ethylamine or bromoethylamine in the assay system leads to the initial formation of an internal (gamma-thialysine) or external (ethylamine) aldimine followed by the slow formation of the alpha-aminoacrylate intermediate on addition of OAS. Activity could not be fully recovered, and only a single turnover is observed. Data suggest a significant rate enhancement resulting from the presence of K42 for transimination and general base catalysis.

Acid-base chemical mechanism of aspartase from Hafnia alvei.

An acid-base chemical mechanism is proposed for Hafnia alvei aspartase in which a proton is abstracted from C-3 of the monoanionic form of L-aspartate by an enzyme general base with a pK of 6.3-6.6 in the absence and presence of Mg2+. The resulting carbanion is presumably stabilized by delocalization of electrons into the beta-carboxyl with the assistance of a protonated enzyme group in the vicinity of the beta-carboxyl. Ammonia is then expelled with the assistance of a general acid group that traps an initially expelled NH3 as the final NH4+ product. In agreement with the function of the general acid group, potassium, an analog of NH4+, binds optimally when the group is unprotonated. The pK for the general acid is about 7 in the absence of Mg2+, but is increased by about a pH unit in the presence of Mg2+. Since the same pK values are observed in the pKi(succinate) and V/K pH profile, both enzyme groups must be in their optimum protonation state for efficient binding of reactant in the presence of Mg2+. At the end of a catalytic cycle, both the general base and general acid groups are in a protonation state opposite that in which they started when aspartate was bound. The presence of Mg2+ causes a pH-dependent activation of aspartase exhibited as a partial change in the V and V/Kasp pH profiles. When the aspartase reaction is run in D2O to greater than 50% completion no deuterium is found in the remaining aspartate, indicating that the site is inaccessible to solvent during the catalytic cycle.

Metal ion activator effects on intrinsic isotope effects for hydride transfer from decarboxylation in the reaction catalyzed by the NAD-malic enzyme from Ascaris suum.

The mechanism of the oxidative decarboxylation reaction catalyzed by the NAD-malic enzyme from Ascaris suum has been examined with several different divalent metal ion activators and dinucleotide substrates. Primary deuterium and tritium isotope effects have been obtained and, in combination with the partitioning ratios of the oxalacetate intermediate to malate and pyruvate, have been used to calculate commitment factors, intrinsic deuterium isotope effects on the hydride transfer step, and intrinsic 13C isotope effects for the decarboxylation step. A survey of malate analogs has been undertaken to define the geometry of the active site and to identify functional groups on malate important for substrate binding. With NAD as dinucleotide substrate, a direct correlation between the size of the divalent metal ion activator and the intrinsic deuterium isotope effect is observed. An isotope effect significantly greater than the semiclassical limit is seen when Cd2+ is the metal ion activator, indicating a substantial tunneling contribution. The primary intrinsic 13C isotope effect on the decarboxylation step increases over the series Mg2+ < Mn2+ < Cd2+, which is in contrast to the equal isotope effects measured for these metal ions for the nonenzymatic decarboxylation of oxalacetate [Grissom, C. B., & Cleland, W. W. (1986) J. Am. Chem. Soc. 108, 5582]. With Mn2+ or Cd2+ as the divalent metal ion activator, the data support a stepwise mechanism for the enzymatic oxidative decarboxylation with NAD as the dinucleotide substrate, but a change to a concerted mechanism is indicated with more redox-positive dinucleotide substrates as suggested previously with Mg2+ as activator [Karsten, W. E., & Cook, P. F. (1994) Biochemistry 33, 2096].(ABSTRACT TRUNCATED AT 250 WORDS)

Stepwise versus concerted oxidative decarboxylation catalyzed by malic enzyme: a reinvestigation.

The NAD-malic enzyme catalyzes the divalent metal-ion-dependent oxidative decarboxylation of L-malate to yield CO2, pyruvate, and the reduced dinucleotide. With Mg2+ as the divalent metal ion activator, primary deuterium and tritium isotope effects have been obtained with several different alternative dinucleotide substrates. The partitioning ratio of oxalacetate to malate and pyruvate has also been determined with either NAD or 3-acetylpyridine adenine dinucleotide (3-APAD). These data have been used to calculate estimates of commitment factors and intrinsic isotope effects for the NAD-malic enzyme reaction. The calculated values of the intrinsic 13C and deuterium isotope effects with NADP are similar to the previously determined values for the chicken liver malic enzyme (Grissom, C.B., & Cleland, W. W. (1988) Biochemistry 27, 2927) and suggest that the transition-state structures are similar for the Ascaris NAD- and chicken liver NADP-malic enzymes. With NAD or NADP as the dinucleotide substrate, the data are all consistent with a stepwise chemical mechanism with oxidation of L-malate at C2 preceding decarboxylation of the bound oxalacetate intermediate. However, none of the data with the alternative dinucleotide substrates, 3-acetylpyridine adenine dinucleotide and 3-pyridine aldehyde adenine dinucleotide (PAAD), can be fit with satisfaction to the various criteria that support a stepwise mechanism with NAD(P). The mechanism with 3-APAD and PAAD is likely concerted. The most likely explanation for a change in the mechanism for oxidative decarboxylation from stepwise with NAD(P) to concerted with alternative dinucleotide substrates such as 3-APAD and PAAD is a difference in the configuration of bound malate when the different dinucleotide substrates are used.

Identification of an essential cysteine in the reaction catalyzed by aspartate-beta-semialdehyde dehydrogenase from Escherichia coli.

The enzyme L-aspartate-beta-semialdehyde dehydrogenase from Escherichia coli has been studied by oligonucleotide-directed mutagenesis. The focus of this investigation was to examine the role of a cysteine residue that had been previously identified by chemical modification with an active site directed reagent (Biellmann et al. (1980) Eur. J. Biochem. 104, 59-64). Substitution of this cysteine at position 135 with an alanine results in complete loss of enzyme activity. However, changing this cysteine to a serine yields a mutant enzyme with a maximum velocity that is 0.3% that of the native enzyme. This C135S mutant has retained essentially the same affinity for substrates as the native enzyme, and the same overall conformation as reflected in identical behavior on gel electrophoresis and in identical fluorescence spectra. The pH profile of the native enzyme shows a loss in catalytic activity upon protonation of a group with a pKa value of 7.7. The same activity loss is observed at this pH with the serine-135 mutant, despite the differences in the pKa values for a cysteine sulfhydryl and a serine hydroxyl group that have been measured in model compounds. This observed pKa value may reflect the protonation of an auxiliary catalyst that enhances the reactivity of the active site cysteine nucleophile in the native aspartate-beta-semialdehyde dehydrogenase.

Kinetic studies of L-aspartase from Escherichia coli: pH-dependent activity changes.

The pH dependence of the kinetic parameters of the L-aspartase-catalyzed reaction have been examined in both the amination and the deamination directions. The enzyme isolated from Escherichia coli exists in a pH-dependent equilibrium between a higher pH form that has an absolute requirement for a divalent metal ion and for substrate activation, and a low pH form that does not require activation by either substrate or metal ions. The interconversion between these enzyme forms is observed near neutral pH in the profiles examined for the reaction in either direction. This pH-dependent activation has not been observed for other bacterial aspartases. Loss of activity is observed at high pH with a pK value of 9. The pH profiles of competitive inhibitors such as 3-nitropropionic acid and succinic acid have shown that the enzyme group responsible for this activity loss must be protonated for substrate binding at the active site. An enzymatic group has also been identified that must be protonated in the amination reaction, with a pK value near 6.5, and deprotonated in the deamination reaction. This group, tentatively assigned as a histidyl residue, fulfills the criteria for the acid-base catalyst at the active site of L-aspartase.

Chemical and kinetic mechanisms of aspartate-beta-semialdehyde dehydrogenase from Escherichia coli.

The chemical and kinetic mechanisms of purified aspartate-beta-semialdehyde dehydrogenase from Escherichia coli have been determined. The kinetic mechanism of the enzyme, determined from initial velocity, product and dead end inhibition studies, is a random preferred order sequential mechanism. For the reaction examined in the phosphorylating direction L-aspartate-beta-semialdehyde binds preferentially to the E-NADP-Pi complex, and there is random release of the products L-beta-aspartyl phosphate and NADPH. Substrate inhibition is displayed by both Pi and NADP. Inhibition patterns versus the other substrates suggest that Pi inhibits by binding to the phosphate subsite in the NADP binding site, and the substrate inhibition by NADP results from the formation of a dead end E-beta-aspartyl phosphate-NADP complex. The chemical mechanism of the enzyme has been examined by pH profile and chemical modification studies. The proposed mechanism involves the attack of an active site cysteine sulfhydryl on the carbonyl carbon of aspartate-beta-semialdehyde, with general acid assistance by an enzyme lysine amino group. The resulting thiohemiacetal is oxidized by NADP to a thioester, with subsequent attack by the dianion of enzyme bound phosphate. The collapse of the resulting tetrahedral intermediate leads to the acyl-phosphate product and liberation of the active site cysteine.

L-aspartase from Escherichia coli: substrate specificity and role of divalent metal ions.

The enzyme L-aspartase from Escherichia coli has an absolute specificity for its amino acid substrate. An examination of a wide range of structural analogues of L-aspartic acid did not uncover any alternate substrates for this enzyme. A large number of competitive inhibitors of the enzyme have been characterized, with inhibition constants ranging over 2 orders of magnitude. A divalent metal ion is required for enzyme activity above pH 7, and this requirement is met by many transition and alkali earth metals. The binding stoichiometry has been established to be one metal ion bound per subunit. Paramagnetic relaxation studies have shown that the divalent metal ion binds at the recently discovered activator site on L-aspartase and not at the enzyme active site. Enzyme activators are bound within 5 A of the enzyme-bound divalent metal ion. The activator site is remote from the active site of the enzyme, since the relaxation of inhibitors that bind at the active site is not affected by paramagnetic metal ions bound at the activator site.

Carbamoyl-phosphate synthetase II of the mammalian CAD protein: kinetic mechanism and elucidation of reaction intermediates by positional isotope exchange.

The kinetic mechanism of carbamoyl-phosphate synthetase II from Syrian hamster kidney cells has been determined at pH 7.2 and 37 degrees C. Initial velocity, product inhibition, and dead-end inhibition studies of both the biosynthetic and bicarbonate-dependent adenosinetriphosphatase (ATPase) reactions are consistent with a partially random sequential mechanism in which the ordered addition of MgATP, HCO3-, and glutamine is followed by the ordered release of glutamate and Pi. Subsequently, the binding of a second MgATP is followed by the release of MgADP, which precedes the random release of carbamoyl phosphate and a second MgADP. Carbamoyl-phosphate synthetase II catalyzes beta gamma-bridge:beta-nonbridge positional oxygen exchange of [gamma-18O]ATP in both the ATPase and biosynthetic reactions. Negligible exchange is observed in the strict absence of HCO3- (and glutamine or NH4+). The ratio of moles of MgATP exchanged to moles of MgATP hydrolyzed (nu ex/nu cat) is 0.62 for the ATPase reaction, and it is 0.39 and 0.16 for the biosynthetic reaction in the presence of high levels of glutamine and NH4+, respectively. The observed positional isotope exchange is suppressed but not eliminated at nearly saturating concentrations of either glutamine or NH4+, suggesting that this residual exchange results from either the facile reversal of an E-MgADP-carboxyphosphate-Gln(NH4+) complex or exchange within an E-MgADP-carbamoyl phosphate-MgADP complex, or both. In the 31P NMR spectra of the exchanged [gamma-18O]ATP, the distribution patterns of 16O in the gamma-phosphorus resonances in all samples reflect an exchange mechanism in which a rotationally unhindered molecule of [18O3, 16O]Pi does not readily participate. These results suggest that the formation of carbamate from MgATP, HCO3-, and glutamine proceeds via a stepwise, not concerted mechanism, involving at least one kinetically competent covalent intermediate, such as carboxyphosphate.

Kinetic studies of L-aspartase from Escherichia coli: substrate activation.

The enzyme L-aspartase from Escherichia coli was observed to have a time lag during the production of aspartic acid from fumarate and ammonia. This time lag is pH dependent, with little lag observed below pH 7.0 and a very extensive lag observed above pH 8.0. This time lag was also found to be dependent on both substrate and divalent metal ion concentrations and on the degree of proteolysis of L-aspartase. The observed lag, in the reaction examined in the amination direction, has been found to be correlated with the nonlinear kinetics seen at higher pH in the deamination direction. Both phenomena are consistent with a model in which there is a separate activator site for the substrate, L-aspartic acid, that is distinct from the enzyme active site. Occupation of this site by the substrate, or by various substrate analogues, eliminates both the nonlinearity and the time lag. The D isomer of aspartic acid, which does not bind at the active site, can bind at this newly identified activator site.

Purification of aspartase and aspartokinase-homoserine dehydrogenase I from Escherichia coli by dye-ligand chromatography.

Improved purification schemes are reported for the enzymes L-aspartase and aspartokinase-homoserine dehydrogenase I from Escherichia coli. Dye-ligand chromatography on commercially available dye matrices are incorporated as key steps in these purifications. Red A-agarose has a high affinity for L-aspartase, which is then eluted as a homogeneous protein fraction with 1 mM L-aspartic acid. Green A-agarose shows a high binding affinity for the bifunctional enzyme aspartokinase-homoserine dehydrogenase I. Purification is accomplished by elution with NADP+, followed by formation of a ternary complex with NADP and cysteine, a good competitive inhibitor of the homoserine dehydrogenase activity, and rechromatography on Green A-agarose. The final specific activity of each purified enzyme equaled or exceeded previously reported values, the overall yield of enzymes obtained was significantly higher, and these improved purification schemes were found to be more amenable to being scaled up for the production of large quantities of purified enzyme.