A catalytic triad is responsible for acid-base chemistry in the Ascaris suum NAD-malic enzyme

The pH dependence of kinetic parameters of several active site mutants of the Ascaris suum NAD-malic enzyme was investigated to determine the role of amino acid residues likely involved in catalysis on the basis of three-dimensional structures of malic enzyme. Lysine 199 is positioned to act as the general base that accepts a proton from the 2-hydroxyl of malate during the hydride transfer step. The pH dependence of V/K(malate) for the K199R mutant enzyme reveals a pK of 5.3 for an enzymatic group required to be unprotonated for activity and a second pK of 6.3 that leads to a 10-fold loss in activity above the pK of 6.3 to a new constant value up to pH 10. The V profile for K199R is pH independent from pH 5.5 to pH 10 and decreases below a pK of 4.9. Tyrosine 126 is positioned to act as the general acid that donates a proton to the enolpyruvate intermediate to form pyruvate. The pH dependence of V/K(malate) for the Y126F mutant is qualitatively similar to K199R, with a requirement for a group to be unprotonated for activity with a pK of 5.6 and a partial activity loss of about 3-fold above a pK of 6.7 to a new constant value. The Y126F mutant enzyme is about 60000-fold less active than the wild-type enzyme. In contrast to K199R, the V rate profile for Y126F also shows a partial activity loss above pH 6.6. The wild-type pH profiles were reinvestigated in light of the discovery of the partial activity change for the mutant enzymes. The wild-type V/K(malate) pH-rate profile exhibits the requirement for a group to be unprotonated for catalysis with a pK of 5.6 and also shows the partial activity loss above a pK of 6.4. The wild-type V pH-rate profile decreases below a pK of 5.2 and is pH independent from pH 5.5 to pH 10. Aspartate 294 is within hydrogen-bonding distance to K199 in the open and closed forms of malic enzyme. D294A is about 13000-fold less active than the wild-type enzyme, and the pH-rate profile for V/K(malate) indicates the mutant is only active above pH 9. The data suggest that the pK present at about pH 5.6 in all of the pH profiles represents D294, and during catalysis D294 accepts a proton from K199 to allow K199 to act as a general base in the reaction. The pK for the general acid in the reaction is not observed, consistent with rapid tautomerization of enolpyruvate. No other ionizable group in the active site is likely responsible for the partial activity change observed in the pH profiles, and thus the group responsible is probably remote from the active site and the effect on activity is transmitted through the protein by a conformational change.     

Ascaris suum NAD-malic enzyme is activated by L-malate and fumarate binding to separate allosteric sites

The kinetic mechanism of activation of the mitochondrial NAD-malic enzyme from the parasitic roundworm Ascaris suum has been studied using a steady-state kinetic approach. The following conclusions are suggested. First, malate and fumarate increase the activity of the enzyme in both reaction directions as a result of binding to separate allosteric sites, i.e., sites that exist in addition to the active site. The binding of malate and fumarate is synergistic with the K(act) decreasing by >or=10-fold at saturating concentrations of the other activator. Second, the presence of the activators decreases the K(m) for pyruvate 3-4-fold, and the K(i) (Mn) >or=20-fold in the direction of reductive carboxylation; similar effects are obtained with fumarate in the direction of oxidative decarboxylation. The greatest effect of the activators is thus expressed at low reactant concentrations, i.e., physiologic concentrations of reactant, where activation of >or=15-fold is observed. A recent crystallographic structure of the human mitochondrial NAD malic enzyme [13] shows fumarate bound to an allosteric site. Site-directed mutagenesis was used to change R105, homologous to R91 in the fumarate activator site of the human enzyme, to alanine. The R105A mutant enzyme exhibits the same maximum rate and V/K(NAD) as does the wild-type enzyme, but 7-8-fold decrease in both V/K(malate) and V/K(Mg), indicating the importance of this residue in the activator site. In addition, neither fumarate nor malate activates the enzyme in either reaction direction. Finally, a change in K143 (a residue in a positive pocket adjacent to that which contains R105), to alanine results in an increase in the K(act) for malate by about an order of magnitude such that it is now of the same magnitude as the K(m) for malate. The K143A mutant enzyme also exhibits an increase in the K(act) for fumarate (in the absence of malate) from 200 microM to about 25 mM.     

Multiple roles of arginine 181 in binding and catalysis in the NAD-malic enzyme from Ascaris suum

The NAD-malic enzyme catalyzes the oxidative decarboxylation of l-malate. Structures of the enzyme indicate that arginine 181 (R181) is within hydrogen bonding distance of the 1-carboxylate of malate in the active site of the enzyme and interacts with the carboxamide side chain of the nicotinamide ring of NADH, but not with NAD+. Data suggested R181 might play a central role in binding and catalysis in malic enzyme, and it was thus changed to lysine and glutamine to probe its potential function. A nearly 100-fold increase in the Km for malate and a 30-fold increase in the Ki for oxalate, an analogue of the enolpyruvate intermediate, in the R181Q and R181K mutants are consistent with a role for R181 in binding substrates. The mutant enzymes also exhibit a >10-fold increase in KiNADH, but only a slight or no change in KNAD, consistent with rotation of the nicotinamide ring into the malate binding site upon reduction of NAD+ to NADH. The activity of the R181Q mutant can be rescued by ammonium ion likely by binding in the pocket vacated by the guanidinium group of R181. Results suggest 2 mol of ammonia bind per mole of active sites with a high-affinity KNH4 of 0.7 +/- 0.1 mM and a low-affinity KNH4 of approximately 420 mM. Occupancy of the high-affinity site, likely by NH4+, results in an increase in the affinity of malate, oxalate, and NADH (with no change in NAD affinity), consistent with the above-proposed roles for R181. The second molecule to bind is likely neutral NH3, and its binding increases V/Et approximately 20-fold. Primary deuterium and 13C isotope effects measured in the absence and presence of ammonium ion suggest R181Q predominantly affects the rate of the reaction by changing the rate of the precatalytic conformational change. The isotope effects do not change upon binding the second mole of ammonia in spite of the 20-fold increase in V/Et. Thus, the R181Q mutant enzyme exists as an equilibrium mixture between active and less active forms, and NH3 stabilizes the more active conformation of the enzyme.     

Evidence for a two-base mechanism involving tyrosine-265 from arginine-219 mutants of alanine racemase

A positively charged residue, R219, was found to interact with the pyridine nitrogen of pyridoxal phosphate in the structure of alanine racemase from Bacillus stearothermophilus [Shaw et al. (1997) Biochemistry 36, 1329-1342]. Three site-directed mutants, R219K, R219A, and R219E, have been characterized and compared to the wild type enzyme (WT) to investigate the role of R219 in catalysis. The R219K mutation is functionally conservative, retaining approximately 25% of the WT activity. The R219A and R219E mutations decrease enzyme activity by approximately 100- and 1000-fold, respectively. These results demonstrate that a positively charged residue at this position is required for efficient catalysis. R219 and Y265 are connected through H166 via hydrogen bonds. The R219 mutants exhibit similar kinetic isotope effect trends: increased primary isotope effects (1.5-2-fold) but unchanged solvent isotope effects in the L --> D direction and increased solvent isotope effects (1.5-2-fold) but unchanged primary isotope effects in the D --> L direction. These results support a two-base racemization mechanism involving Y265 and K39. They additionally suggest that Y265 is selectively perturbed by R219 mutations through the H166 hydrogen-bond network. pH profiles show a large pKa shift from 7.1-7.4 (WT and R219K) to 9. 5-10.4 (R219A and R219E) for kcat/KM, and from 7.3 to 9.9-10.4 for kcat. The group responsible for this ionization is likely to be the phenolic hydroxyl of Y265, whose pKa is electrostatically perturbed in the WT by the H166-mediated interaction with R219. Accumulation of an absorbance band at 510 nm, indicative of a quinonoid intermediate, only in the D --> L direction with R219E provides additional evidence for a two-base mechanism involving Y265.     

Proper positioning of the nicotinamide ring is crucial for the Ascaris suum malic enzyme reaction

The mitochondrial NAD-malic enzyme catalyzes the oxidative decarboxylation of malate to pyruvate and CO2. The role of the dinucleotide substrate in oxidative decarboxylation is probed in this study using site-directed mutagenesis to change key residues that line the dinucleotide binding site. Mutant enzymes were characterized using initial rate kinetics, and isotope effects were used to obtain information on the contribution of these residues to binding energy and catalysis. Results obtained for the N479 mutant enzymes indicate that the hydrogen bond donated by N479 to the carboxamide side chain of the nicotinamide ring is important for proper orientation in the hydride transfer step. The stepwise oxidative decarboxylation mechanism observed for the wt enzyme changed to a concerted one, which is totally rate limiting, for the N479Q mutant enzyme. In this case, it is likely that the longer glutamine side chain causes reorientation of malate such that it binds in a conformation that is optimal for concerted oxidative decarboxylation. Converting N479 to the shorter serine side chain gives very similar values of KNAD, Kmalate, and isotope effects relative to wt, but V/Et is decreased 2 000-fold. Data suggest an increased freedom of rotation, resulting in nonproductively bound cofactor. Changes were also made to two residues, S433 and N434, which interact with the nicotinamide ribose of NAD. In addition, N434 donates a hydrogen bond to the beta-carboxylate of malate. The KNAD for the S433A mutant enzyme increased by 80-fold, indicating that this residue provides significant binding affinity for the dinucleotide. With N434A, the interaction of the residue with malate is lost, causing the malate to reorient itself, leading to a slower decarboxylation step. The longer glutamine and methionine side chains stick into the active site and cause a change in the position of malate and/or NAD resulting in more than a 104-fold decrease in V/Et for these mutant enzymes. Overall, data indicate that subtle changes in the orientation of the cofactor and substrate dramatically influence the reaction rate.     

Changes in NAD(P)+-dependent malic enzyme and malate dehydrogenase activities during fibroblast proliferation

A sensitive isotope exchange method was developed to assess the requirements for and compartmentation of pyruvate and oxalacetate production from malate in proliferating and nonproliferating human fibroblasts. Malatedependent pyruvate production (malic enzyme activity) in the particulate fraction containing the mitochondria was dependent on either NAD⁺ or NADP⁺. The production of pyruvate from malate in the soluble, cytosolic fraction was strictly dependent on NADP⁺. Oxalacetate production from malate (malate dehydrogenase, EC 1.1.1.37) in both the particulate and soluble fraction was strictly dependent on NAD⁺. Relative to nonproliferating cells, NAD⁺-linked malic enzyme activity was slightly reduced and the NADP⁺-linked activity was unchanged in the particulate fraction of serum-stimulated, exponentially proliferating cells. However, a reduced activity of particulate malate dehydrogenase resulted in a two-fold increase in the ratio of NAD(P)⁺-linked malic enzyme to NAD⁺-linked malate dehydrogenase activity in the particulate fraction of proliferating fibroblasts. An increase in soluble NADP⁺-dependent malic enzyme activity and a decrease in NAD⁺-linked malate dehydrogenase indictated an increase in the ratio of pyruvate-producing to oxalacetate-producing malate oxidase activity in the cytosol of proliterating cells. These coordinate changes may affect the relative amount of malate that is oxidized to oxalacetate and pyruvate in proliferating cells and, therefore, the efficient utilization of glutamine as a respiratory fuel during cell proliferation.     

Loss of serotonin oxidation as a component of the altered substrate specificity in the Y444F mutant of recombinant human liver MAO A.

To investigate the roles of tyrosyl residues located near the covalent 8alpha-S-cysteinyl FAD in monoamine oxidase A (MAO A) and to test the suggestion that MAO A and plant polyamine oxidase may have structural homology, tyrosyl to phenylalanyl mutants of MAO A at positions 377, 402, 407, 410, 419, and 444 were constructed and expressed in Saccharomyces cerevisiae. All mutant enzymes were expressed and exhibited lower specific activities as compared to WT MAO A using kynuramine as substrate. The lowest specific activities in this assay are exhibited by the Y407F and Y444F mutant enzymes. On purification and further characterization, these two mutants were found to each contain covalent FAD. Both mutant enzymes are irreversibly inhibited by the MAO A inhibitor clorgyline and exhibit binding stoichiometries of 0.54 (Y407F) and 0.95 (Y444F) as compared to 1.05 for WT MAO A. Y444F MAO A oxidizes kynuramine with a k(cat) <2% of WT enzyme and is greater than 100-fold slower in catalyzing the oxidation of phenylethylamine or of serotonin. In contrast, Y444F MAO A oxidizes p-CF(3)-benzylamine at a rate 25% that of WT enzyme. Steady state and reductive half-reaction stopped-flow data using a series of para-substituted benzylamine analogues show Y444F MAO A exhibits quantitative structure activity relationships (QSAR) properties on analogue binding and rates of substrate oxidation very similar to that exhibited by the WT enzyme (Miller and Edmondson (1999) Biochemistry 38, 13670): log K(d) = -(0.37 +/- ()()0.07)V(W)(x0.1) - 4.5 +/- 0.1; log k(red) = +(2.43 +/- 0.19)sigma + 0.17 +/- 0.05. The Y444F MAO A mutant also exhibits similar QSAR properties on the binding of phenylalkyl side chain amine analogues as WT enzyme: log K(i) = (4.37 +/- 0.51)E(S) + 1.21 +/- 0.77. These data show that mutation of Y444F in MAO A results in a mutant that has lost its ability to efficiently oxidize serotonin (its physiological substrate) but, however, exhibits unaltered quantitative structure-activity parameters in the binding and rate of benzylamine analogues. The mechanism of C-H abstraction is therefore unaltered. The suggestion that polyamine oxidase and monoamine oxidase may have structural homology appears to be valid as regards Y444 in MAO A and Y439 in plant polyamine oxidase.     

Biotin-dependent carboxylation catalyzed by transcarboxylase is a stepwise process

To investigate the mechanism of the carboxylation of pyruvate to oxalacetate catalyzed by the enzyme transcarboxylase, we have measured the D(V/K) and 13(V/K) isotope effects. Comparison of the double-reciprocal plots of the initial velocities with [1H3]pyruvate and with [2H3]pyruvate as substrate yields a deuterium isotope effect on Vmax/Km of 1.39 +/- 0.04. The 13C kinetic isotope effect on the carboxylation of pyruvate to oxalacetate has been measured by the competitive method and is 1.0227 +/- 0.0008. To determine whether the removal of the proton from pyruvate and the addition of the carboxyl group occur in the same or in different steps, the double-isotope fractionation test has been used. When [2H3]pyruvate replaces [1H3]pyruvate as the substrate, the observed 13(V/K) isotope effect falls from 1.0227 to 1.0141 +/- 0.001. The latter value is in excellent agreement with the value of 1.0136, predicted for a stepwise pathway. We may conclude, therefore, that the carboxylation of pyruvate catalyzed by transcarboxylase proceeds by a stepwise mechanism involving the intermediate formation of the substrate carbanion.     

Mechanism of activation of the NAD-malic enzyme from Ascaris suum by fumarate.

The mechanism of activation of the NAD-malic enzyme from Ascaris suum by fumarate has been probed using initial velocity studies, deuterium isotope effects, and isotope partitioning of the E:Mg:malate complex. Fumarate exerts its activating effect by decreasing the off-rate for malate from the E:Mg:malate and E:NAD:Mg:malate complexes. Fumarate is a positive heterotropic effector of the NAD-malic enzyme at low concentrations (K act approximately 0.05 mM) and an inhibitor competitive against malate (Ki approximately 25 mM). The activation by fumarate results in a decrease in the Ki malate and an increase in V/K malate of about 2-fold, while the maximum velocity remains constant. Isotope partitioning studies of E:Mg:[14C]malate indicate that the presence of fumarate results in a decrease in the malate off-rate constant by about 2.2-fold. The deuterium isotope effects on V and V/K malate are both 1.6 +/- 0.1 in the absence of fumarate, while in the presence of 0.5 mM fumarate DV is 1.6 +/- 0.1 and D(V/K malate) is 1.1 +/- 0.1. These data are also consistent with a decrease in the off-rate for malate from E:NAD:Mg:malate, resulting in an increase in the forward commitment factor for malate and manifested as a lower value for D(V/K malate). There is a discrimination between active and activator sites for the binding of dicarboxylic acids, with the activator site preferring the extended configuration of 4-carbon dicarboxylic acids, while the active site prefers a configuration in which the 4-carboxyl is twisted out of the C1-C3 plane. The physiologic importance and regulatory properties of fumarate in the parasite are also discussed.     

Alternative substrates for malic enzyme: oxidative decarboxylation of L-aspartate

The NAD-malic enzyme from Ascaris suum will utilize L-aspartate, (2S,3R)-tartrate, and meso-tartrate as substrates with V/K values 10(-4)-10(-5) with respect to malate. There is a strict requirement for the 2S stereochemistry for all of these reactants. Since aspartate is unique as an amino acid reactant for malic enzyme, it was informative to determine the details of its mechanism of oxidative decarboxylation. The initial rate of NADH appearance is directly proportional to the concentration of aspartate, and saturation is difficult to achieve. The pH dependence of V/K(aspartate)E(t) shows a decrease at low pH, giving a pK of 5.7. The pH-independent value of V/K(aspartate)E(t) is 3 M(-1) s(-1), 12500-fold lower than that obtained with L-malate. The dissociation constant for aspartate as a competitive inhibitor of malate is 60 mM at neutral pH, allowing an estimate of about 0.18 s(-1) for V/E(t) with L-aspartate compared to a value of 39 s(-1) obtained with L-malate. The deuterium isotope effect on V/K(aspartate) is pH independent over the range 5.1-6.9 with an average value of 3.3. Data suggest that the monoanion of L-aspartate binds to enzyme and that the same general base, general acid mechanism that is responsible for the oxidative decarboxylation of malate to pyruvate applies to the oxidative decarboxylation of aspartate to iminopyruvate. In addition, the oxidation step appears to be largely rate determining with aspartate as the substrate.     

Human ferrochelatase: characterization of substrate-iron binding and proton-abstracting residues

The terminal step in heme biosynthesis, the insertion of ferrous iron into protoporphyrin IX to form protoheme, is catalyzed by the enzyme ferrochelatase (EC 4.99.1.1). A number of highly conserved residues identified from the crystal structure of human ferrochelatase as being in the active site were examined by site-directed mutagenesis. The mutants Y123F, Y165F, Y191H, and R164L each had an increased K(m) for iron without an altered K(m) for porphyrin. The double mutant R164L/Y165F had a 6-fold increased K(m) for iron and a 10-fold decreased V(max). The double mutant Y123F/Y191F had low activity with an elevated K(m) for iron, and Y123F/Y165F had no measurable activity. The mutants H263A/C/N, D340N, E343Q, E343H, and E343K had no measurable enzyme activity, while E343D, E347Q, and H341C had decreased V(max)s without significant alteration of the K(m)s for either substrate. D340E had near-normal kinetic parameters, while D383A and H231A had increased K(m)s for iron. On the basis of these data and the crystal structure of human ferrochelatase, it is proposed that residues E343, H341, and D340 form a conduit from H263 in the active site to the protein exterior and function in proton extraction from the porphyrin macrocycle. The role of H263 as the porphyrin proton-accepting residue is central to catalysis since metalation only occurs in conjunction with proton abstraction. It is suggested that iron is transported from the exterior of the enzyme at D383/H231 via residues W227 and Y191 to the site of metalation at residues R164 and Y165 which are on the opposite side of the active site pocket from H263. This model should be general for mitochondrial membrane-associated eucaryotic ferrochelatases but may differ for bacterial ferrochelatases since the spatial orientation of the enzyme within prokaryotic cells may differ.     

Isotope effect studies of chicken liver NADP malic enzyme: role of the metal ion and viscosity dependence

The role of the metal ion in the oxidative decarboxylation of malate by chicken liver NADP malic enzyme and details of the reaction mechanism have been investigated by 13C isotope effects. With saturating NADP and the indicated metal ion at a total concentration 10-fold higher than its Km, the following primary 13C kinetic isotope effects at C4 of malate [13(V/Kmal)] were observed at pH 8.0: Mg2+, 1.0336; Mn2+, 1.0365; Cd2+, 1.0366; Zn2+, 1.0337; Co2+, 1.0283; Ni2+, 1.025. Knowing the partitioning of the intermediate oxalacetate between decarboxylation to pyuvate and reduction to malate allows calculation of the intrinsic carbon isotope effect for decarboxylation. For Mg2+ as activator, this was 1.049 with NADP and 1.046 with 3-acetylpyridine adenine dinucleotide phosphate, although the intrinsic primary deuterium isotope effects on dehydrogenation were 5.6 and 4.2, and the partition ratios of the oxalacetate intermediate for decarboxylation as opposed to hydride transfer were 0.11 and 3.96 (the result of the different redox potentials of NADP and the acetylpyridine analogue). The close agreement of the intrinsic 13C isotope effects with each other and with the 13C isotope effect for the Mg2+-catalyzed nonenzymatic decarboxylation of oxalacetate of 1.0489 [Grissom, C. B., & Cleland, W. W. (1986) J. Am. Chem. Soc. 108, 5582] indicates a similarity of transition states for these reactions. It was not possible to calculate reasonable intrinsic carbon isotope effects with the other metal ions by use of the partitioning ratio of oxalacetate because of decarboxylation by another mechanism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Implication by site-directed mutagenesis of Arg314 and Tyr316 in the coenzyme site of pig mitochondrial NADP-dependent isocitrate dehydrogenase

Sequence alignment of pig mitochondrial NADP-dependent isocitrate dehydrogenase with eukaryotic (human, rat, and yeast) and Escherichia coli isocitrate dehydrogenases reveals that Tyr316 is completely conserved and is equivalent to the E. coli Tyr345, which interacts with the 2'-phosphate of NADP in the crystal structure [Hurley et al., Biochemistry 30 (1991) 8671-8678]. Lys321 is also completely conserved in the five isocitrate dehydrogenases. Either an arginine or lysine residue is found among the enzymes from other species at the position corresponding to the pig enzyme Arg314. While Arg323 is not conserved among all species, its proximity to the coenzyme site makes it a good candidate for investigation. The importance of these four amino acids to the function of pig mitochondrial NADP-isocitrate dehydrogenase was studied by site-directed mutagenesis. Mutants (R314Q, Y316F, Y316L, K321Q, and R323Q) were generated by a megaprimer polymerase chain reaction method. Wild-type and mutant enzymes were expressed in E. coli and purified to homogeneity. All mutant and wild-type enzymes exhibited comparable molecular weights indicative of the dimeric enzyme. Mutations do not cause an appreciable change in enzyme secondary structure as revealed by circular dichroism measurements. The kinetic parameters (V(max) and K(M) values) of K321Q and R323Q are similar to those of wild-type, indicating that Lys321 and Arg323 are not involved in enzyme function. R314Q exhibits a 10-fold increase in K(M) for NADP as compared to that of wild-type, while they have comparable V(max) values. These results suggest that Arg314 contributes to the affinity between the enzyme and NADP. The hydroxyl group of Tyr316 is not required for enzyme function since Y316F exhibits similar kinetic parameters to those of wild-type. Y316L shows a 4-fold increase in K(M) for NADP and a decrease in V(max) as compared to wild-type, suggesting that the aromatic ring of the Tyr of isocitrate dehydrogenase contributes to the affinity for coenzyme, as well as to catalysis. The K(i) for NAD of R314Q, Y316F, and Y316L is comparable to that of wild-type, indicating that the Arg314 and Tyr316 may be located near the 2'-phosphate of enzyme-bound NADP.     

Solvent and primary deuterium isotope effects show that lactate CH and OH bond cleavages are concerted in Y254F flavocytochrome b2, consistent with a hydride transfer mechanism

Yeast flavocytochrome b(2) catalyzes the oxidation of lactate to pyruvate; because of the wealth of structural and mechanistic information available, this enzyme has served as the model for the family of flavoproteins catalyzing oxidation of alpha-hydroxy acids. Primary deuterium and solvent isotope effects have now been used to analyze the effects of mutating the active site residue Tyr254 to phenylalanine. Both the V(max) and the V/K(lactate) values decrease about 40-fold in the mutant enzyme. The primary deuterium isotope effects on the V(max) and the V/K(lactate) values increase to 5.0, equivalent to the intrinsic isotope effect for the wild-type enzyme. In addition, both the V(max) and the V/K(lactate) values exhibit solvent isotope effects of 1.5. Measurement of the solvent isotope effect with deuterated lactate establishes that the primary and solvent isotope effects arise from the same chemical step, consistent with concerted cleavage of the lactate OH and CH bonds. The pH dependence of the mutant enzyme is not significantly different from that of the wild-type enzyme; this is most consistent with a requirement that the side chain of Tyr254 be uncharged for catalysis. The results support a hydride transfer mechanism for the mutant protein and, by extension, wild-type flavocytochrome b(2) and the other flavoproteins catalyzing oxidation of alpha-hydroxy acids.     

Catalytic residues Lys197 and Arg199 of Bacillus subtilis phosphoribosyl diphosphate synthase. Alanine-scanning mutagenesis of the flexible catalytic loop

Eleven of the codons specifying the amino acids of the flexible catalytic loop [KRRPRPNVAEVM(197-208)] of Bacillus subtilis phosphoribosyl diphosphate synthase have been changed individually to specify alanine. The resulting variant enzyme forms, as well as the wildtype enzyme, were produced in an Escherichia coli strain lacking endogenous phosphoribosyl diphosphate synthase activity and purified to near homogeneity. The B. subtilis phosphoribosyl diphosphate synthase mutant variants K197A and R199A were studied in detail. The physical properties of the two enzymes were similar to those of the wildtype enzyme. Kinetic characterization showed that the V(max) values of the K197A and R199A mutant enzymes were more than 30 000- and more than 24 000-fold reduced, respectively, compared to the wildtype enzyme. The K(m) values for ATP and ribose 5-phosphate of the two mutant enzymes were essentially unchanged. V(app) values of the remaining mutant enzymes were much less affected, ranging from 20 to 100% of the V(max) value of the wildtype enzyme. The data presented show that Lys197 and Arg199 are important in stabilization of the transition state.     

Identification of Tyr413 as an active site residue in the flavoprotein tryptophan 2-monooxygenase and analysis of its contribution to catalysis

The flavoenzyme tryptophan 2-monooxygenase catalyzes the oxidation of tryptophan to indoleacetamide, carbon dioxide, and water. The enzyme is a homologue of l-amino acid oxidase. In the structure of l-amino acid oxidase complexed with aminobenzoate, Tyr372 hydrogen bonds with the carboxylate of the inhibitor in the active site. All 10 conserved tyrosine residues in tryptophan 2-monooxygenase were mutated to phenylalanine; steady state kinetic characterization of the purified proteins identified Tyr413 as the residue homologous to Tyr372 of l-amino acid oxidase. Y413F and Y413A tryptophan 2-monooxygenase were characterized more completely with tryptophan as the substrate to probe the contribution of this residue to catalysis. Mutation of Tyr413 to phenylalanine results in a decrease in the value of the first-order rate constant for reduction of 35-fold and a decrease in the rate constant for oxidation of 11-fold. Mutation to alanine decreases the rate constant for reduction by 200-fold and that for oxidation by 33-fold. Both mutations increase the K(d) value for tryptophan and the K(i) values for the competitive inhibitors indoleacetamide and indole pyruvate by 5-10-fold. Both mutations convert the enzyme to an oxidase, in that the products of the catalytic reactions of both are indolepyruvate and hydrogen peroxide. The V/K(trp)-pH profiles for the Tyr413 mutant enzymes no longer show the pK(a) value of 9.9 seen in that for the wild-type enzyme, allowing identification of Tyr413 as the active site residue in the wild-type enzyme which must be protonated for catalysis. Substitution of Tyr413 abolishes the formation of the long wavelength charge transfer species observed in the wild-type enzyme. The data are consistent with the main role of Tyr413 being to maintain the correct orientation of tryptophan for effective hydride transfer and imino acid decarboxylation.     

Contribution of amino acid region 334-335 from factor Va heavy chain to the catalytic efficiency of prothrombinase

We have demonstrated that amino acids E (323), Y (324), E (330), and V (331) from the factor Va heavy chain are required for the interaction of the cofactor with factor Xa and optimum rates of prothrombin cleavage. We have also shown that amino acid region 332-336 contains residues that are important for cofactor function. Using overlapping peptides, we identified amino acids D (334) and Y (335) as contributors to cofactor activity. We constructed recombinant factor V molecules with the mutations D (334) --> K and Y (335) --> F (factor V (KF)) and D (334) --> A and Y (335) --> A (factor V (AA)). Kinetic studies showed that while factor Va (KF) and factor Va (AA) had a K D for factor Xa similar to the K D observed for wild-type factor Va (factor Va (WT)), the clotting activities of the mutant molecules were impaired and the k cat of prothrombinase assembled with factor Va (KF) and factor Va (AA) was reduced. The second-order rate constant of prothrombinase assembled with factor Va (KF) or factor Va (AA) for prothrombin activation was approximately 10-fold lower than the second-order rate constant for the same reaction catalyzed by prothrombinase assembled with factor Va (WT). We also created quadruple mutants combining mutations in the amino acid region 334-335 with mutations at the previously identified amino acids that are important for factor Xa binding (i.e., E (323)Y (324) and E (330)V (331)). Prothrombinase assembled with the quadruple mutant molecules displayed a second-order rate constant up to 400-fold lower than the values obtained with prothrombinase assembled with factor Va (WT). The data demonstrate that amino acid region 334-335 is required for the rearrangement of enzyme and substrate necessary for efficient catalysis of prothrombin by prothrombinase.     

Converting the guanine phosphoribosyltransferase from Giardia lamblia to a hypoxanthine-guanine phosphoribosyltransferase

Guanine phosphoribosyltransferase from Giardia lamblia, a key enzyme in the purine salvage pathway, is a potential target for anti-giardiasis chemotherapy. Recent structural determination of GPRTase (Shi, W., Munagala, N. R., Wang, C. C., Li, C. M., Tyler, P. C., Furneaux, R. H., Grubmeyer, C., Schramm, V. L., and Almo, S. C. (2000) Biochemistry 39, 6781-6790) showed distinctive features, which could be responsible for its singular guanine specificity. Through characterizing specifically designed site-specific mutants of GPRTase, we identified essential moieties in the active site for substrate binding. Mutating the unusual Tyr-127 of GPRTase to the highly conserved Ile results in 6-fold lower K(m) for guanine. A L186F mutation in GPRTase increased the affinity toward guanine by 3. 3-fold, whereas the corresponding human HGPRTase mutant L192F showed a 33-fold increase in K(m) for guanine. A double mutant (Y127I/K152R) of GPRTase retained the improved binding of guanine and also enabled the enzyme to utilize hypoxanthine as a substrate with a K(m) of 54 +/- 15.5 microm. A triple mutant (Y127I/K152R/L186F) resulted in further increased binding affinity with both guanine and hypoxanthine with the latter showing a lowered K(m) of 29.8 +/- 4.1 microm. Dissociation constants measured by fluorescence quenching showed 6-fold tighter binding of GMP with the triple mutant compared with wild type. Thus, by increasing the binding affinity of 6-oxopurine, we were able to convert the GPRTase to a HGPRTase.     

Identification of active site residues in E. coli ketopantoate reductase by mutagenesis and chemical rescue

Ketopantoate reductase (EC 1.1.1.169) catalyzes the NADPH-dependent reduction of alpha-ketopantoate to D-(-)-pantoate in the biosynthesis of pantothenate. The pH dependence of V and V/K for the E. coli enzyme suggests the involvement of a general acid/base in the catalytic mechanism. To identify residues involved in catalysis and substrate binding, we mutated the following six strictly conserved residues to Ala: Lys72, Lys176, Glu210, Glu240, Asp248, and Glu256. Of these, the K176A and E256A mutant enzymes showed 233- and 42-fold decreases in V(max), and 336- and 63-fold increases in the K(m) value of ketopantoate, respectively, while the other mutants exhibited WT kinetic properties. The V(max) for the K176A and E256A mutant enzymes was markedly increased, up to 25% and 75% of the wild-type level, by exogenously added primary amines and formate, respectively. The rescue efficiencies for the K176A and E256A mutant enzymes were dependent on the molecular volume of rescue agents, as anticipated for a finite active site volume. The protonated form of the amine is responsible for recovery of activity, suggesting that Lys176 functions as a general acid in catalysis of ketopantoate reduction. The rescue efficiencies for the K176A mutant by primary amines were independent of the pK(a) value of the rescue agents (Bronsted coefficient, alpha = -0.004 +/-0.008). Insensitivity to acid strength suggests that the chemical reaction is not rate-limiting, consistent with (a) the catalytic efficiency of the wild-type enzyme (k(cat)/K(m) = 2x10(6) M(-1) s(-1) and (b) the small primary deuterium kinetic isotope effects, (D)V = 1.3 and (D)V/K = 1.5, observed for the wild-type enzyme. Larger primary deuterium isotope effects on V and V/K were observed for the K176A mutant ((D)V = 3.0, (D)V/K = 3.7) but decreased nearly to WT values as the concentration of ethylamine was increased. The nearly WT activity of the E256A mutant in the presence of formate argues for an important role for this residue in substrate binding. The double mutant (K176A/E256A) has no detectable ketopantoate reductase activity. These results indicate that Lys176 and Glu256 of the E. coli ketopantoate reductase are active site residues, and we propose specific roles for each in binding ketopantoate and catalysis.     

Contribution of K99 and D319 to substrate binding and catalysis in the saccharopine dehydrogenase reaction

Saccharopine dehydrogenase catalyzes the NAD-dependent oxidative deamination of saccharopine to l-lysine and α-ketoglutarate. Lysine 99 is within hydrogen-bond distance to the α-carboxylate of the lysine substrate and D319 is in the vicinity of the carboxamide side chain of NADH. Both are conserved and may be important to the overall reaction. Replacing K99 with M gives decreases of 110-, 80- and 20-fold in the V(2)/K(m) values for lysine, α-ketoglutarate and NADH, respectively. Deuterium isotope effects on V and V/K(Lys) increase, while the solvent deuterium isotope effects decrease compared to the C205S mutant enzyme. Data for K99M suggest a decreased affinity for all reactants and a change in the partition ratio of the imine intermediate to favor hydrolysis. A change in the bound conformation of the imine and/or the distance of the imine carbon to C4 of the nicotinamide ring of NADH is also suggested. Changing D319 to A decreases V(2)/K(NADH) by 33-fold. Primary deuterium and solvent deuterium isotope effects decrease compared to C205S suggesting a non-isotope sensitive step has become slower. NADH binds to enzyme first, and sets the site for binding of lysine and α-ketoglutarate. The slower step is likely the conformational change generated upon binding of NADH.