The catalytic mechanism of glucose 6-phosphate dehydrogenases: assignment and 1H NMR spectroscopy pH titration of the catalytic histidine residue in the 109 kDa Leuconostoc mesenteroides enzyme

The chemical shifts of the C(epsilon1) and C(delta2) protons of His-240 from the 109 kDa Leuconostoc mesenteroides glucose 6-phosphate dehydrogenase (G6PD) were assigned by comparing 1H and 13C spectra of the wild-type and mutant G6PDs containing the His-240 to asparagine mutation (H240N). Unambiguous assignment of the His-240 1H(epsilon1) resonance was obtained from comparing 13C-1H heteronuclear multiple quantum coherence NMR spectra of wild-type and H240N G6PDs that were selectively labeled with 13C(epsilon1) histidine. The results from NOESY experiments with wild-type and H240N variants were consistent with these assignments and the three-dimensional structure of G6PD. pH titrations show that His-240 has a pK(a) of 6.4. This value is, within experimental error, identical to the value of 6.3 derived from the pH dependence of kcat [Viola, R. E. (1984) Arch. Biochem. Biophys. 228, 415-424], suggesting that the pK(a) of His-240 is unperturbed in the apoenzyme despite being part of a His-Asp catalytic dyad. The results obtained for this 109 kDa enzyme indicate that 1H NMR spectroscopy in combination with heteronuclear methods can be a useful tool for functional analysis of large proteins.     

Delineation of the roles of amino acids involved in the catalytic functions of Leuconostoc mesenteroides glucose 6-phosphate dehydrogenase

The roles of particular amino acids in substrate and coenzyme binding and catalysis of glucose-6-phosphate dehydrogenase of Leuconostoc mesenteroides have been investigated by site-directed mutagenesis, kinetic analysis, and determination of binding constants. The enzyme from this species has functional dual NADP(+)/NAD(+) specificity. Previous investigations in our laboratories determined the three-dimensional structure. Kinetic studies showed an ordered mechanism for the NADP-linked reaction while the NAD-linked reaction is random. His-240 was identified as the catalytic base, and Arg-46 was identified as important for NADP(+) but not NAD(+) binding. Mutations have been selected on the basis of the three-dimensional structure. Kinetic studies of 14 mutant enzymes are reported and kinetic mechanisms are reported for 5 mutant enzymes. Fourteen substrate or coenzyme dissociation constants have been measured for 11 mutant enzymes. Roles of particular residues are inferred from k(cat), K(m), k(cat)/K(m), K(d), and changes in kinetic mechanism. Results for enzymes K182R, K182Q, K343R, and K343Q establish Lys-182 and Lys-343 as important in binding substrate both to free enzyme and during catalysis. Studies of mutant enzymes Y415F and Y179F showed no significant contribution for Tyr-415 to substrate binding and only a small contribution for Tyr-179. Changes in kinetics for T14A, Q47E, and R46A enzymes implicate these residues, to differing extents, in coenzyme binding and discrimination between NADP(+) and NAD(+). By the same measure, Lys-343 is also involved in defining coenzyme specificity. Decrease in k(cat) and k(cat)/K(m) for the D374Q mutant enzyme defines the way Asp-374, unique to L. mesenteroides G6PD, modulates stabilization of the enzyme during catalysis by its interaction with Lys-182. The greatly reduced k(cat) values of enzymes P149V and P149G indicate the importance of the cis conformation of Pro-149 in accessing the correct transition state.     

Structural diversity within the mononuclear and binuclear active sites of N-acetyl-D-glucosamine-6-phosphate deacetylase

NagA catalyzes the hydrolysis of N-acetyl-d-glucosamine-6-phosphate to d-glucosamine-6-phosphate and acetate. X-ray crystal structures of NagA from Escherichia coli were determined to establish the number and ligation scheme for the binding of zinc to the active site and to elucidate the molecular interactions between the protein and substrate. The three-dimensional structures of the apo-NagA, Zn-NagA, and the D273N mutant enzyme in the presence of a tight-binding N-methylhydroxyphosphinyl-d-glucosamine-6-phosphate inhibitor were determined. The structure of the Zn-NagA confirms that this enzyme binds a single divalent cation at the beta-position in the active site via ligation to Glu-131, His-195, and His-216. A water molecule completes the ligation shell, which is also in position to be hydrogen bonded to Asp-273. In the structure of NagA bound to the tight binding inhibitor that mimics the tetrahedral intermediate, the methyl phosphonate moiety has displaced the hydrolytic water molecule and is directly coordinated to the zinc within the active site. The side chain of Asp-273 is positioned to activate the hydrolytic water molecule via general base catalysis and to deliver this proton to the amino group upon cleavage of the amide bond of the substrate. His-143 is positioned to help polarize the carbonyl group of the substrate in conjunction with Lewis acid catalysis by the bound zinc. The inhibitor is bound in the alpha-configuration at the anomeric carbon through a hydrogen bonding interaction of the hydroxyl group at C-1 with the side chain of His-251. The phosphate group of the inhibitor attached to the hydroxyl at C-6 is ion paired with Arg-227 from the adjacent subunit. NagA from Thermotoga maritima was shown to require a single divalent cation for full catalytic activity.     

Structure and function of the catalytic site mutant Asp 99 Asn of phospholipase A2: absence of the conserved structural water.

To probe the role of the Asp-99 ... His-48 pair in phospholipase A2 (PLA2) catalysis, the X-ray structure and kinetic characterization of the mutant Asp-99-->Asn-99 (D99N) of bovine pancreatic PLA2 was undertaken. Crystals of D99N belong to the trigonal space group P3(1)21 and were isomorphous to the wild type (WT) (Noel JP et al., 1991, Biochemistry 30:11801-11811). The 1.9-A X-ray structure of the mutant showed that the carbonyl group of Asn-99 side chain is hydrogen bonded to His-48 in the same way as that of Asp-99 in the WT, thus retaining the tautomeric form of His-48 and the function of the enzyme. The NH2 group of Asn-99 points away from His-48. In contrast, in the D102N mutant of the protease enzyme trypsin, the NH2 group of Asn-102 is hydrogen bonded to His-57 resulting in the inactive tautomeric form and hence the loss of enzymatic activity. Although the geometry of the catalytic triad in the PLA2 mutant remains the same as in the WT, we were surprised that the conserved structural water, linking the catalytic site with the ammonium group of Ala-1 of the interfacial site, was ejected by the proximity of the NH2 group of Asn-99. The NH2 group now forms a direct hydrogen bond with the carbonyl group of Ala-1.     

Catalytic roles for two water bridged residues (Asp-98 and His-255) in the active site of copper-containing nitrite reductase

Two active site residues, Asp-98 and His-255, of copper-containing nitrite reductase (NIR) from Alcaligenes faecalis have been mutated to probe the catalytic mechanism. Three mutations at these two sites (D98N, H255D, and H255N) result in large reductions in activity relative to native NIR, suggesting that both residues are involved intimately in the reaction mechanism. Crystal structures of these mutants have been determined using data collected to better than 1. 9-A resolution. In the native structure, His-255 Nepsilon2 forms a hydrogen bond through a bridging water molecule to the side chain of Asp-98, which also forms a hydrogen bond to a water or nitrite oxygen ligated to the active site copper. In the D98N mutant, reorientation of the Asn-98 side chain results in the loss of the hydrogen bond to the copper ligand water, consistent with a negatively charged Asp-98 directing the binding and protonation of nitrite in the native enzyme. An additional solvent molecule is situated between residues 255 and the bridging water in the H255N and H255D mutants and likely inhibits nitrite binding. The interaction of His-255 with the bridging water appears to be necessary for catalysis and may donate a proton to reaction intermediates in addition to Asp-98.     

Kinetic studies of the reactions catalyzed by glucose-6-phosphate dehydrogenase from Leuconostoc mesenteroides: pH variation of kinetic parameters

The specificity and kinetic parameters of the reactions catalyzed by glucose-6-phosphate dehydrogenase from Leuconostoc mesenteroides has been examined under a range of conditions in order to elucidate details about the mechanism of action of this enzyme. The rate of oxidation of glucose 6-phosphate is inhibited by the addition of various organic solvents. However, the low, inherent glucose dehydrogenase activity of this enzyme was stimulated under these conditions, and was further activated by divalent anions that were observed to be inhibitors of the glucose 6-phosphate dehydrogenation. From an examination of the pH variation of the enzyme kinetic parameters two groups on the enzyme that appear to be involved in the binding of the phosphate group of the sugar substrate have been detected. An enzyme catalytic group, probably a carboxylic acid, has been identified that accepts the proton from the hydroxyl group at carbon-1 of the sugar substrate during its oxidation to a lactone. The ionization of a group on the enzyme with a pK of 8.7 resulted in an increase in the maximum velocity of the glucose-6-phosphate dehydrogenase activity of the enzyme as a consequence of a pH-dependent product release step that is no longer rate limiting at high pH. Stabilization of gluconic acid-delta-lactone against nonenzymatic hydrolysis by organic solvents has allowed the kinetic parameters of the reverse reaction to be reliably measured for the first time in a narrow pH range.     

Purification and properties of NADP-linked glucose-6-phosphate dehydrogenase from Acetobacter hansenii (Acetobacter xylinum)

The NADP-linked glucose-6-phosphate dehydrogenase from Acetobacter hansenii (formerly known as Acetobacter xylinum) has been purified to apparent homogeneity. The sequence of the 10 N-terminal amino acids was determined. The subunit molecular weight of the enzyme is 53,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis; gel filtration studies under nondenaturing conditions revealed that the molecular weight of the enzyme is 200,000 to 220,000 at pH 6.5 and 9.5, suggesting that the native enzyme is a tetramer. Specificity studies at both pH 6.5 and 9.5 demonstrated that the enzyme is a typical NADP-preferring glucose-6-phosphate dehydrogenase. The enzyme's catalytic activity increases with increasing pH, kcat being approximately 4 times greater at pH 9.5 than at pH 6.7 and the Km for NADP+ being 3 times lower at the higher pH; but the Km for glucose 6-phosphate is nearly 20 times higher at pH 9.5 than at pH 6.7, suggesting that the enzyme is catalytically more efficient at the lower pH. At pH 6.7, initial velocity measurements, product inhibition by NADPH, and inhibition by glucosamine 6-phosphate yielded results that were consistent with a steady-state random mechanism. At pH 9.5, steady-state kinetic analyses suggested that the mechanism is ordered, with coenzyme binding first, but nonlinear double-reciprocal plots were observed in the presence of NADPH when glucose 6-phosphate was varied and a complete kinetic analysis was not undertaken. Among several nucleotides and potential inhibitory ligands examined, only 2',5'-ADP inhibited the enzyme significantly.     

Structural and functional effects of mutations altering the subunit interface of mitochondrial malate dehydrogenase

Among highly conserved residues in eucaryotic mitochondrial malate dehydrogenases are those with roles in maintaining the interactions between identical monomeric subunits that form the dimeric enzymes. The contributions of two of these residues, Asp-43 and His-46, to structural stability and catalytic function were investigated by construction of mutant enzymes containing Asn-43 and Leu-46 substitutions using in vitro mutagenesis of the Saccharomyces cerevisiae gene (MDH1) encoding mitochondrial malate dehydrogenase. The mutant enzymes were expressed in and purified from a yeast strain containing a disruption of the chromosomal MDH1 locus. The enzyme containing the H46L substitution, as compared to the wild type enzyme, exhibits a dramatic shift in the pH profile for catalysis toward an optimum at low pH values. This shift corresponds with an increased stability of the dimeric form of the mutant enzyme, suggesting that His-46 may be the residue responsible for the previously described pH-dependent dissociation of mitochondrial malate dehydrogenase. The D43N substitution results in a mutant enzyme that is essentially inactive in in vitro assays and that tends to aggregate at pH 7.5, the optimal pH for catalysis for the dimeric wild type enzyme.     

Identification of the catalytic residues of bifunctional glycogen debranching enzyme

Eukaryotic glycogen debranching enzyme (GDE) possesses two different catalytic activities (oligo-1,4-->1,4-glucantransferase/amylo-1,6-glucosidase) on a single polypeptide chain. To elucidate the structure-function relationship of GDE, the catalytic residues of yeast GDE were determined by site-directed mutagenesis. Asp-535, Glu-564, and Asp-670 on the N-terminal half and Asp-1086 and Asp-1147 on the C-terminal half were chosen by the multiple sequence alignment or the comparison of hydrophobic cluster architectures among related enzymes. The five mutant enzymes, D535N, E564Q, D670N, D1086N, and D1147N were constructed. The mutant enzymes showed the same purification profiles as that of wild-type enzyme on beta-CD-Sepharose-6B affinity chromatography. All the mutant enzymes possessed either transferase activity or glucosidase activity. Three mutants, D535N, E564Q, and D670N, lost transferase activity but retained glucosidase activity. In contrast, D1086N and D1147N lost glucosidase activity but retained transferase activity. Furthermore, the kinetic parameters of each mutant enzyme exhibiting either the glucosidase activity or transferase activity did not vary markedly from the activities exhibited by the wild-type enzyme. These results strongly indicate that the two activities of GDE, transferase and glucosidase, are independent and located at different sites on the polypeptide chain.     

Catalytic mechanism of S-adenosylhomocysteine hydrolase. Site-directed mutagenesis of Asp-130, Lys-185, Asp-189, and Asn-190

S-Adenosylhomocysteine hydrolase (AdoHcyase) catalyzes the hydrolysis of S-adenosylhomocysteine to form adenosine and homocysteine. On the bases of crystal structures of the wild type enzyme and the D244E mutated enzyme complexed with 3'-keto-adenosine (D244E.Ado*), we have identified the important amino acid residues, Asp-130, Lys-185, Asp-189, and Asn-190, for the catalytic reaction and have proposed a catalytic mechanism (Komoto, J., Huang, Y., Gomi, T., Ogawa, H., Takata, Y., Fujioka, M., and Takusagawa, F. (2000) J. Biol. Chem. 275, 32147-32156). To confirm the proposed catalytic mechanism, we have made the D130N, K185N, D189N, and N190S mutated enzymes and measured the catalytic activities. The catalytic rates (k(cat)) of D130N, K185N, D189N, and N190S mutated enzymes are reduced to 0.7%, 0.5%, 0.1%, and 0.5%, respectively, in comparison with the wild type enzyme, indicating that Asp-130, Lys-185, Asp-189, and Asn-190 are involved in the catalytic reaction. K(m) values of the mutated enzymes are increased significantly, except for the N190S mutation, suggesting that Asp-130, Lys-185, and Asp-189 participate in the substrate binding. To interpret the kinetic data, the oxidation states of the bound NAD molecules of the wild type and mutated enzymes were measured during the catalytic reaction by monitoring the absorbance at 340 nm. The crystal structures of the WT and D244E.Ado*, containing four subunits in the crystallographic asymmetric unit, were re-refined to have the same subunit structures. A detailed catalytic mechanism of AdoHcyase has been revealed based on the oxidation states of the bound NAD and the re-refined crystal structures of WT and D244E.Ado*. Lys-185 and Asp-130 abstract hydrogen atoms from 3'-OH and 4'-CH, respectively. Asp-189 removes a proton from Lys-185 and produces the neutral N zeta (-NH(2)), and Asn-190 facilitates formation of the neutral Lys-185. His-54 and His-300 hold and polarize a water molecule, which nucleophilically attacks the C5'- of 3'-keto-4',5'-dehydroadenosine to produce 3'-keto-Ado.     

The active site topology of Aspergillus niger endopolygalacturonase II as studied by site-directed mutagenesis

Strictly conserved charged residues among polygalacturonases (Asp-180, Asp-201, Asp-202, His-223, Arg-256, and Lys-258) were subjected to site-directed mutagenesis in Aspergillus niger endopolygalacturonase II. Specific activity, product progression, and kinetic parameters (K(m) and V(max)) were determined on polygalacturonic acid for the purified mutated enzymes, and bond cleavage frequencies on oligogalacturonates were calculated. Depending on their specific activity, the mutated endopolygalacturonases II were grouped into three classes. The mutant enzymes displayed bond cleavage frequencies on penta- and/or hexagalacturonate different from the wild type endopolygalacturonase II. Based on the biochemical characterization of endopolygalacturonase II mutants together with the three-dimensional structure of the wild type enzyme, we suggest that the mutated residues are involved in either primarily substrate binding (Arg-256 and Lys-258) or maintaining the proper ionization state of a catalytic residue (His-223). The individual roles of Asp-180, Asp-201, and Asp-202 in catalysis are discussed. The active site topology is different from the one commonly found in inverting glycosyl hydrolases.     

Structure and mutational analysis of the PhoN protein of Salmonella typhimurium provide insight into mechanistic details

The Salmonella typhimurium PhoN protein is a nonspecific acid phosphatase and belongs to the phosphatidic acid phosphatase type 2 (PAP2) superfamily. We report here the crystal structures of phosphate-bound PhoN, the PhoN-tungstate complex, and the T159D mutant of PhoN along with functional characterization of three mutants: L39T, T159D, and D201N. Invariant active site residues, Lys-123, Arg-130, Ser-156, Gly-157, His-158, and Arg-191, interact with phosphate and tungstate oxyanions. Ser-156 also accepts a hydrogen bond from Thr-159. The T159D mutation, surprisingly, severely diminishes phosphatase activity, apparently by disturbing the active site scaffold: Arg-191 is swung out of the active site resulting in conformational changes in His-158 and His-197 residues. Our results reveal a hitherto unknown functional role of Arg-191, namely, restricting the active conformation of catalytic His-158 and His-197 residues. Consistent with the conserved nature of Asp-201 in the PAP2 superfamily, the D201N mutation completely abolished phosphatase activity. On the basis of this observation and in silico analysis we suggest that the crucial mechanistic role of Asp-201 is to stabilize the positive charge on the phosphohistidine intermediate generated by the transfer of phosphoryl to the nucleophile, His-197, located within hydrogen bond distance to the invariant Asp-201. This is in contrast to earlier suggestions that Asp-201 stabilizes His-197 and the His197-Asp201 dyad facilitates formation of the phosphoenzyme intermediate through a charge-relay system. Finally, the L39T mutation in the conserved polyproline motif (39LPPPP43) of dimeric PhoN leads to a marginal reduction in activity, in contrast to the nearly 50-fold reduction observed for monomeric Prevotella intermedia acid phosphatase, suggesting that the varying quaternary structure of PhoN orthologues may have functional significance.     

The roles of the essential Asp-48 and highly conserved His-43 elucidated by the pH dependence of the pseudouridine synthase TruB

All known pseudouridine synthases have a conserved aspartic acid residue that is essential for catalysis, Asp-48 in Escherichia coli TruB. To probe the role of this residue, inactive D48C TruB was oxidized to generate the sulfinic acid cognate of aspartic acid. The oxidation restored significant but reduced catalytic activity, consistent with the proposed roles of Asp-48 as a nucleophile and general base. The family of pseudouridine synthases including TruB also has a nearly invariant histidine residue, His-43 in the E. coli enzyme. To examine the role of this conserved residue, site-directed mutagenesis was used to generate H43Q, H43N, H43A, H43G, and H43F TruB. Except for phenylalanine, the substitutions seriously impaired the enzyme, but all of the altered TruB retained significant activity. To examine the roles of Asp-48 and His-43 more fully, the pH dependences of wild-type, oxidized D48C, and H43A TruB were determined. The wild-type enzyme displays a typical bell-shaped profile. With oxidized D48C TruB, logk(cat) varies linearly with pH, suggesting the participation of specific rather than general base catalysis. Substitution of His-43 perturbs the pH profile, but it remains bell-shaped. The ascending limb of the pH profile is assigned to Asp-48, and the descending limb is tentatively ascribed to an active site tyrosine residue, the bound substrate uridine, or the bound product pseudouridine.     

Human lipoprotein lipase. Analysis of the catalytic triad by site-directed mutagenesis of Ser-132, Asp-156, and His-241.

Lipoprotein lipase (LPL) plays a central role in normal lipid metabolism as the key enzyme involved in the hydrolysis of triglycerides present in chylomicrons and very low density lipoproteins. LPL is a member of a family of hydrolytic enzymes that include hepatic lipase and pancreatic lipase. Based on primary sequence homology of LPL to pancreatic lipase, Ser-132, Asp-156, and His-241 have been proposed to be part of a domain required for normal enzymic activity. We have analyzed the role of these potential catalytic residues by site-directed mutagenesis and expression of the mutant LPL in human embryonic kidney-293 cells. Substitution of Ser-132, Asp-156, and His-241 by several different residues resulted in the expression of an enzyme that lacked both triolein and tributyrin esterase activities. Mutation of other conserved residues, including Ser-97, Ser-307, Asp-78, Asp-371, Asp-440, His-93, and His-439 resulted in the expression of active enzymes. Despite their effect on LPL activity, substitutions of Ser-132, Asp-156, and His-241 did not change either the heparin affinity or lipid binding properties of the mutant LPL. In summary, mutation of Ser-132, Asp-156, and His-241 specifically abolishes total hydrolytic activity without disrupting other important functional domains of LPL. These combined results strongly support the conclusion that Ser-132, Asp-156, and His-241 form the catalytic triad of LPL and are essential for LPL hydrolytic activity.     

Nucleotide sequence of the malate dehydrogenase gene of Thermus flavus and its mutation directing an increase in enzyme activity

The nucleotide sequence of the malate dehydrogenase (mdh) gene from a thermophilic bacterium, Thermus flavus, was determined. The amino acid sequence of the Thermus malate dehydrogenase resembled that of the porcine heart cytoplasmic enzyme to a certain extent, and Asp-159 and His-187 were identified as possible essential residues for the catalytic function. The mutated mdh gene was also cloned from a spontaneous mutant of T. flavus containing a higher activity of the enzyme. Its mutation point was determined to be a single nucleotide exchange from C to T which caused Thr-190 to be substituted by isoleucine. The mutated enzyme showed resistance to substrate inhibition, an increase in both kcat and Km, and a shift toward a more acid optimum pH for the enzyme reaction.     

Kinetic properties and structural characteristics of an unusual two-domain arginine kinase of the clam Corbicula japonica

Arginine kinase (AK) from the clam Corbicula japonica is a unique enzyme in that it has an unusual two-domain structure with molecular mass of 80 kDa. It lacks two functionally important amino acid residues, Asp-62 and Arg-193, which are conserved in other 40 kDa AKs and are assumed to be key residues for stabilizing the substrate-bound structure. K m arg and Vmax values for the recombinant two-domain AK were determined. These values were close to those of usual 40 kDa AKs, although Corbicula AK lacks the functionally important Asp-62 and Arg-193. Domain 2 of Corbicula AK was separated from the two-domain enzyme and was expressed in Escherichia coli. Domain 2 still exhibited activity. However, kinetic parameters for domain 2 appeared to be slightly, but significantly, different from those of two-domain AK. Thus, it is likely that the formation of the contiguous dimer alters the kinetic properties of its constituent domains significantly. Comparison of K d arg and K m arg for two-domain AK and its domain 2 showed that the affinity of the enzyme for arginine is greater in the presence of substrate ATP than in its absence. Presumably this difference is correlated with the large structural differences in the enzyme in the presence or absence of substrate, namely open and closed structures. We expressed three mutants of Corbicula AK domain 2 (His-60 to Gly or Arg, Asp-197 to Gly), and determined their K m arg and Vmax values. The affinity for the substrate arginine in mutant enzymes was reduced considerably, accompanied by a decrease in Vmax. These results suggest that His-60 and Asp-197 affect the substrate binding system, and are consistent with the hypothesis that a hydrogen bond is formed between His-60 and Asp-197 in Corbicula AK as a substitute for the Asp-62 and Arg-193 bond in normal AKs.     

Role of aspartate-133 and histidine-458 in the mechanism of tryptophan indole-lyase from Proteus vulgaris

Tryptophan indole-lyase (Trpase) from Proteus vulgaris is a pyridoxal 5'-phosphate dependent enzyme that catalyzes the reversible hydrolytic cleavage of L-Trp to yield indole and ammonium pyruvate. Asp-133 and His-458 are strictly conserved in all sequences of Trpase, and they are located in the proposed substrate-binding region of Trpase. These residues were mutated to alanine to probe their role in substrate binding and catalysis. D133A mutant Trpase has no measurable activity with L-Trp as substrate, but still retains activity with S-(o-nitrophenyl)-L-cysteine, S-alkyl-L-cysteines, and beta-chloro-L-alanine. H458A mutant Trpase has 1.6% of wild-type Trpase activity with L-Trp, and high activity with S-(o-nitrophenyl)-L-cysteine, S-alkyl-L-cysteines, and beta-chloro-L-alanine. H458A mutant Trpase does not exhibit the pK(a) of 5.3 seen in the pH dependence of k(cat)/K(m) of L-Trp for wild-type Trpase. Both mutant enzymes are inhibited by L-Ala, L-Met, and L-Phe, with K(i) values similar to those of wild-type Trpase, but oxindolyl-L-alanine and beta-phenyl-DL-serine show much weaker binding to the mutant enzymes, suggesting that Asp-133 and His-458 are involved in the binding of these ligands. D133A and H458A mutant Trpase exhibit absorption and CD spectra in the presence of substrates and inhibitors that are similar to wild-type Trpase, with peaks at about 420 and 500 nm. The rate constants for formation of the 500 nm bands for the mutant enzymes are equal to or greater than those of wild-type Trpase, indicating that Asp-133 and His-458 do not play a role in the formation of quinonoid intermediates. In constrast to wild-type and H458A mutant Trpase, D133A mutant Trpase forms an intermediate from S-ethyl-L-Cys that absorbs at 345 nm, and is likely to be an alpha-aminoacrylate. Crystals of D133A and H458A mutant Trpase bind amino acids with similar affinity as the proteins in solution, except for L-Ala, which binds to D133A mutant Trpase crystals about 20-fold stronger than in solution. These results suggest that Asp-133 and His-458 play an important role in the elimination reaction of L-Trp. Asp-133 likely forms a hydrogen bond directly to the indole NH of the substrate, while His-458 probably is hydrogen bonded to Asp-133.     

Acid-base catalysis in the extradiol catechol dioxygenase reaction mechanism: site-directed mutagenesis of His-115 and His-179 in Escherichia coli 2,3-dihydroxyphenylpropionate 1,2-dioxygenase (MhpB)

The extradiol catechol dioxygenases catalyze the non-heme iron(II)-dependent oxidative cleavage of catechols to 2-hydroxymuconaldehyde products. Previous studies of a biomimetic model reaction for extradiol cleavage have highlighted the importance of acid-base catalysis for this reaction. Two conserved histidine residues were identified in the active site of the class III extradiol dioxygenases, positioned within 4-5 A of the iron(II) cofactor. His-115 and His-179 in Escherichia coli 2,3-dihydroxyphenylpropionate 1,2-dioxygenase (MhpB) were replaced by glutamine, alanine, and tyrosine. Each mutant enzyme was catalytically inactive for extradiol cleavage, indicating the essential nature of these acid-base residues. Replacement of neighboring residues Asp-114 and Pro-181 gave D114N, P181A, and P181H mutant enzymes with reduced catalytic activity and altered pH/rate profiles, indicating the role of His-179 as a base and His-115 as an acid. Mutant H179Q was catalytically active for the lactone hydrolysis half-reaction, whereas mutant H115Q was inactive, implying a role for His-115 in lactone hydrolysis. A catalytic mechanism involving His-179 and His-115 as acid-base catalytic residues is proposed.     

The roles of Glu-327 and His-446 in the bisphosphatase reaction of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase probed by NMR spectroscopic and mutational analyses of the enzyme in the transient phosphohistidine intermediate complex

The bisphosphatase domain derived from the rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase was studied by 1H-13C HMQC NMR spectroscopy of the histidine C2' and H2' nuclei. The bacterially expressed protein was specifically labeled with 13C at the ring C2' position of the histidines. Each of the seven histidine residues gave rise to a single cross-peak in the HMQC spectra, and these were assigned by use of a series of histidine-to-alanine point mutants. His-304, His-344, and His-469 exhibit 13C and 1H resonances that titrated with pH, while the remaining histidine-associated resonances did not. The 13C and 1H chemical shifts indicate that at neutral pH, His-304 and His-446 are deprotonated, while His-469 is protonated. The pKa of His-344 was determined to be 7.04. The 13C chemical shifts suggest that the deprotonated His-258 exists as the N1' tautomer, while His-392 and His-419 are protonated in the resting, wild-type enzyme. Mutation of the remaining member of the catalytic triad, Glu-327, to alanine in the resting enzyme caused an upfield shift of 1.58 and 1.30 ppm in the 1H and 13C dimensions, respectively, and significant narrowing of the His-258 cross-peak. Mutation of His-446 to alanine produced perturbations of the His-258 cross-peak that were similar to those detected in the E327A mutant. The His-392 resonances were also shifted by the E327A and H446A mutations. These observations strongly suggest that residues His-258, Glu-327, His-392, and His-446 exist within a network of interacting residues that encompasses the catalytic site of the bisphosphatase and includes specific contacts with the C-terminal regulatory region of the enzyme. The specifically 13C-labeled bisphosphatase was monitored during turnover by HMQC spectra acquired from the transient N3' phosphohistidine intermediate complex in the wild-type enzyme, the E327A mutant, and the H446A mutant. These complexes were formed during reaction with the physiological substrate fructose-2, 6-bisphosphate. Upon formation of the phosphohistidine at His-258, the 13C and 1H resonances of this residue were shifted downfield by 1.7 and 0.31 ppm, respectively, in the wild-type enzyme. The upfield shifts of the His-258 resonances in the E327A and H446A mutant resting enzymes were reversed when the phosphohistidine was formed, generating spectra very similar to that of the wild-type enzyme in the intermediate complex. In contrast, the binding of fructose-6-phosphate, the reaction product, to the resting enzyme did not promote significant changes in the histidine-associated resonances in either the wild-type or the mutant enzymes. The interpretation of these data within the context of the X-ray crystal structures of the enzyme is used to define the role of Glu-327 in the catalytic mechanism of the bisphosphatase and to identify His-446 as a putative link in the chain of molecular events that results in activation of the bisphosphatase site by cAMP-dependent phosphorylation of the hepatic bifunctional enzyme.     

Effect of Asp-235-->Asn substitution on the absorption spectrum and hydrogen peroxide reactivity of cytochrome c peroxidase.

The spectroscopic properties of a mutant cytochrome c peroxidase, in which Asp-235 has been replaced by an asparagine residue, were examined in both nitrate and phosphate buffers between pH 4 and 10.5. The spin state of the enzyme is pH dependent, and four distinct spectroscopic species are observed in each buffer system: a predominantly high-spin Fe(III) species at pH 4, two distinct low-spin forms between pH 5 and 9, and the denatured enzyme above pH 9.3. The spectrum of the mutant enzyme at pH 4 is dependent upon specific ion effects. Increasing the pH above 5 converts the mutant enzyme to a predominantly low-spin hydroxy complex. Subsequent conversion to a second low-spin form is essentially complete at pH 7.5. The second low-spin form has the distal histidine, His-52, coordinated to the heme iron. To evaluate the effect of the changes in coordination state upon the reactivity of the enzyme, the reaction between hydrogen peroxide and the mutant enzyme was also examined as a function of pH. The reaction of CcP(MI,D235N) with peroxide is biphasic. At pH 6, the rapid phase of the reaction can be attributed to the bimolecular reaction between hydrogen peroxide and the hydroxy-ligated form of the mutant enzyme. Despite the hexacoordination of the heme iron in this form, the bimolecular rate constant is approximately 22% that of pentacoordinate wild-type yeast cytochrome c peroxidase. The bimolecular reaction of the mutant enzyme with peroxide exhibits the same pH dependence in nitrate-containing buffers that has been described for the wild-type enzyme, indicating a loss of reactivity with the protonation of a group with an apparent pKa of 5.4. This observation eliminates Asp-235 as the source for this heme-linked ionization and strengthens the hypothesis that the pKa of 5.4 is associated with His-52. The slower phase of the reaction between peroxide and the mutant enzyme saturates at high peroxide concentration and is attributed to conversion of unreactive to reactive forms of the enzyme. The fraction of enzyme which reacts via the slow phase is dependent upon both pH and specific ion effects.