Replacement of two invariant serine residues in chorismate synthase provides evidence that a proton relay system is essential for intermediate formation and catalytic activity

Chorismate synthase is the last enzyme of the common shikimate pathway, which catalyzes the anti-1,4-elimination of the 3-phosphate group and the C-(6proR) hydrogen from 5-enolpyruvylshikimate 3-phosphate (EPSP) to generate chorismate, a precursor for the biosynthesis of aromatic compounds. Enzyme activity relies on reduced FMN, which is thought to donate an electron transiently to the substrate, facilitating C(3)-O bond breakage. The crystal structure of the enzyme with bound EPSP and the flavin cofactor highlighted two invariant serine residues interacting with a bound water molecule that is close to the C(3)-O of EPSP. In this article we present the results of a mutagenesis study where we replaced the two invariant serine residues at positions 16 and 127 of the Neurospora crassa chorismate synthase with alanine, producing two single-mutant proteins (Ser16Ala and Ser127Ala) and a double-mutant protein (Ser16AlaSer127Ala). The residual activity of the Ser127Ala and Ser16Ala single-mutant proteins was found to be six-fold and 70-fold lower, respectively, than that of the wild-type protein. No residual activity was detected for the Ser16AlaSer127Ala double-mutant protein, and formation of the typical transient intermediate, characteristic for the chorismate synthase-catalysed reaction, was not observed, in contrast to the single-mutant proteins. On the basis of the structure of the enzyme, we propose that Ser16 and Ser127 form part of a proton relay system among the isoalloxazine ring of FMN, histidine 106 and the phosphate group of EPSP that is essential for the formation of the transient intermediate and for substrate turnover.     

A Secondary beta Deuterium Kinetic Isotope Effect in the Chorismate Synthase Reaction

Chorismate synthase (EC 4.6.1.4) is the shikimate pathway enzyme that catalyzes the conversion of 5-enolpyruvylshikimate 3-phosphate (EPSP) to chorismate. The enzyme reaction is unusual because it involves a trans-1,4 elimination of the C-3 phosphate and the C-6 proR hydrogen and it has an absolute requirement for reduced flavin. Several mechanisms have been proposed to account for the cofactor requirement and stereochemistry of the reaction, including a radical mechanism. This paper describes the synthesis of [4-(2)H]EPSP and the observation of kinetic isotope effects using this substrate with both Neurospora crassa and Escherichia coli chorismate synthases. The magnitude of the effects were (D)(V) = 1.08 +/- 0.01 for the N. crassa enzyme and 1.10 +/- 0.02 on phosphate release under single-turnover conditions for the E. coli enzyme. The effects are best rationalised as substantial secondary beta isotope effects. It is most likely that the C(3)-O bond is cleaved first in a nonconcerted E1 or radical reaction mechanism. Although this study alone cannot rule out a concerted E2-type mechanism, the C(3)-O bond would have to be substantially more broken than the proR C(6)-H bond in a transition state of such a mechanism. Importantly, although the E. coli and N. crassa enzymes have different rate limiting steps, their catalytic mechanisms are most likely to be chemically identical. Copyright 2000 Academic Press.     

Mechanism of chorismate synthase. Role of the two invariant histidine residues in the active site

Chorismate synthase catalyzes the last step in the common shikimate pathway leading to aromatic compounds such as the aromatic amino acids. The reaction consists of the 1,4-anti-elimination of the 3-phosphate group and the C-(6proR) hydrogen from 5-enolpyruvylshikimate 3-phosphate to yield chorismate. Although this reaction does not involve a net redox change, the enzyme has an absolute requirement for reduced flavin mononucleotide, which is not consumed during the reaction. Two invariant histidine residues are found in the active site of the enzyme: His(17) and His(106). Using site-directed mutagenesis, both histidines were replaced by alanine, reducing the activity 10- and 20-fold in the H106A and H17A mutant protein, respectively. Based on the characterization of the two single mutant proteins, it is proposed that His(106) serves to protonate the monoanionic reduced FMN, whereas His(17) protonates the leaving phosphate group of the substrate. An enzymatic reaction mechanism in keeping with the experimental results is presented.     

Studies with substrate and cofactor analogues provide evidence for a radical mechanism in the chorismate synthase reaction

Chorismate synthase catalyzes the conversion of 5-enolpyruvylshikimate 3-phosphate (EPSP) to chorismate. The strict requirement for a reduced FMN cofactor and a trans-1,4-elimination are unusual. (6R)-6-Fluoro-EPSP was shown to be converted to chorismate stoichiometrically with enzyme-active sites in the presence of dithionite. This conversion was associated with the oxidation of FMN to give a stable flavin semiquinone. The IC(50) of the fluorinated substrate analogue was 0.5 and 250 microm with the Escherichia coli enzyme, depending on whether it was preincubated with the enzyme or not. The lack of dissociation of the flavin semiquinone and chorismate from the enzyme appears to be the basis of the essentially irreversible inhibition by this analogue. A dithionite-dependent transient formation of flavin semiquinone during turnover of (6S)-6-fluoro-EPSP has been observed. These reactions are best rationalized by radical chemistry that is strongly supportive of a radical mechanism occurring during normal turnover. The lack of activity with 5-deaza-FMN provides additional evidence for the role of flavin in catalysis by the E. coli enzyme.     

Spectroscopic and kinetic characterization of the bifunctional chorismate synthase from Neurospora crassa: evidence for a common binding site for 5-enolpyruvylshikimate 3-phosphate and NADPH

Chorismate synthase catalyzes the anti-1,4-elimination of the phosphate group and the C-(6proR) hydrogen from 5-enolpyruvylshikimate 3-phosphate to yield chorismate, a central building block in aromatic amino acid biosynthesis. The enzyme has an absolute requirement for reduced FMN, which in the case of the fungal chorismate synthases is supplied by an intrinsic FMN:NADPH oxidoreductase activity, i.e. these enzymes have an additional catalytic activity. Therefore, these fungal enzymes have been termed "bifunctional." We have cloned chorismate synthase from the common bread mold Neurospora crassa, expressed it heterologously in Escherichia coli, and purified it in a three-step purification procedure to homogeneity. Recombinant N. crassa chorismate synthase has a diaphorase activity, i.e. it catalyzes the reduction of oxidized FMN at the expense of NADPH. Using NADPH as a reductant, a reduced flavin intermediate was observed under single and multiple turnover conditions with spectral features similar to those reported for monofunctional chorismate synthases, thus demonstrating that the intermediate is common to the chorismate synthase-catalyzed reaction. Furthermore, multiple turnover experiments in the presence of oxygen have provided evidence that NADPH binds in or near the substrate (5-enolpyruvylshikimate 3-phosphate) binding site, suggesting that NADPH binding to bifunctional chorismate synthases is embedded in the general protein structure and a special NADPH binding domain is not required to generate the intrinsic oxidoreductase activity.     

How the mutation glycine96 to alanine confers glyphosate insensitivity to 5-enolpyruvyl shikimate-3-phosphate synthase from Escherichia coli

The enzyme 5-enolpyruvyl shikimate-3-phosphate (EPSP) synthase (EC 2.5.1.19) is essential for the biosynthesis of aromatic compounds in plants and microbes and is the unique target of the herbicide glyphosate. One of the first glyphosate-insensitive enzymes reported was a Gly96Ala mutant of EPSP synthase from Klebsiella pneumoniae. We have introduced this single-site mutation into the highly homologous EPSP synthase from Escherichia coli. The mutant enzyme is insensitive to glyphosate with unaltered affinity for its first substrate, shikimate-3-phosphate (S3P), but displays a 30-fold lower affinity for its second substrate, phosphoenolpyruvate (PEP). Using X-ray crystallography, we solved the structure of Gly96Ala-EPSP synthase liganded with S3P to 0.17 nm resolution. The crystal structure shows that the additional methyl group from Ala96 protrudes into the active site of the enzyme. While the interactions between enzyme and S3P remain unaffected, the accessible volume for glyphosate binding is substantially reduced. Exploiting the crystallographic results for molecular modeling, we demonstrate that PEP but not glyphosate can be docked in the Gly96Ala-modified binding site. The predicted PEP binding site satisfies the earlier proposed interaction pattern for PEP with EPSP synthase and corroborates the assumption that glyphosate and PEP target the same binding site.     

Crystal structure of the bifunctional chorismate synthase from Saccharomyces cerevisiae

Chorismate synthase (EC 4.2.3.5), the seventh enzyme in the shikimate pathway, catalyzes the transformation of 5-enolpyruvylshikimate 3-phosphate (EPSP) to chorismate, which is the last common precursor in the biosynthesis of numerous aromatic compounds in bacteria, fungi, and plants. The chorismate synthase reaction involves a 1,4-trans-elimination of phosphoric acid from EPSP and has an absolute requirement for reduced FMN as a cofactor. We have determined the three-dimensional x-ray structure of the yeast chorismate synthase from selenomethionine-labeled crystals at 2.2-A resolution. The structure shows a novel betaalphabetaalpha fold consisting of an alternate tight packing of two alpha-helical and two beta-sheet layers, showing no resemblance to any documented protein structure. The molecule is arranged as a tight tetramer with D2 symmetry, in accordance with its quaternary structure in solution. Electron density is missing for 23% of the amino acids, spread over sequence regions that in the three-dimensional structure converge on the surface of the protein. Many totally conserved residues are contained within these regions, and they probably form a structured but mobile domain that closes over a cleft upon substrate binding and catalysis. This hypothesis is supported by previously published spectroscopic measurements implying that the enzyme undergoes considerable structural changes upon binding of both FMN and EPSP.     

Aspartate 120 of Escherichia coli methylenetetrahydrofolate reductase: evidence for major roles in folate binding and catalysis and a minor role in flavin reactivity

Escherichia coli methylenetetrahydrofolate reductase (MTHFR) catalyzes the NADH-linked reduction of 5,10-methylenetetrahydrofolate (CH(2)-H(4)folate) to 5-methyltetrahydrofolate (CH(3)-H(4)folate) using flavin adenine dinucleotide (FAD) as cofactor. MTHFR is unusual among flavin oxidoreductases because it contains a conserved, negatively rather than positively charged amino acid (aspartate 120) near the N1-C2=O position of the flavin. At this location, Asp 120 is expected to influence the redox properties of the enzyme-bound FAD. Modeling of the CH(3)-H(4)folate product into the enzyme active site suggests that Asp 120 may also play crucial roles in folate binding and catalysis. We have replaced Asp 120 with Asn, Ser, Ala, Val, and Lys and have characterized the mutant enzymes. Consistent with a loss of negative charge near the flavin, the midpoint potentials of the mutants increased from 17 to 30 mV. A small kinetic effect on the NADH reductive half-reaction was also observed as the mutants exhibited a 1.2-1.5-fold faster reduction rate than the wild-type enzyme. Catalytic efficiency (k(cat)/K(m)) in the CH(2)-H(4)folate oxidative half-reaction was decreased significantly (up to 70000-fold) and in a manner generally consistent with the negative charge density of position 120, supporting a major role for Asp 120 in electrostatic stabilization of the putative 5-iminium cation intermediate during catalysis. Asp 120 is also intimately involved in folate binding as increases in the apparent K(d) of up to 15-fold were obtained for the mutants. Examining the E(red) + CH(2)-H(4)folate reaction at 4 degrees C, we obtained, for the first time, evidence for the rapid formation of a reduced enzyme-folate complex with wild-type MTHFR. The more active Asp120Ala mutant, but not the severely impaired Asp120Lys mutant, demonstrated the species, suggesting a connection between the extent of complex formation and catalytic efficiency.     

The structure of chorismate synthase reveals a novel flavin binding site fundamental to a unique chemical reaction

The crystal structure of chorismate synthase (CS) from Streptococcus pneumoniae has been solved to 2.0 A resolution in the presence of flavin mononucleotide (FMN) and the substrate 5-enolpyruvyl-3-shikimate phosphate (EPSP). CS catalyses the final step of the shikimate pathway and is a potential therapeutic target for the rational design of novel antibacterials, antifungals, antiprotozoals, and herbicides. CS is a tetramer with the monomer possessing a novel beta-alpha-beta fold. The interactions between the enzyme, cofactor, and substrate reveal the structural reasons underlying the unique catalytic mechanism and identify the amino acids involved. This structure provides the essential initial information necessary for the generation of novel anti-infective compounds by a structure-guided medicinal chemistry approach.     

Chorismate synthase from the hyperthermophile Thermotoga maritima combines thermostability and increased rigidity with catalytic and spectral properties similar to mesophilic counterparts

Chorismate synthase, the last enzyme in the shikimate pathway, catalyzes the transformation of 5-enolpyruvylshikimate 3-phosphate to chorismate, a biochemically unique reaction in that it requires reduced FMN as a cofactor. Here we report on the cloning, expression, and characterization of the protein for the first time from an extremophilic organism Thermotoga maritima which is also one of the oldest and most slowly evolving eubacteria. The protein is monofunctional in that it does not have an intrinsic ability to reduce the FMN cofactor and thereby reflecting the nature of the ancestral enzyme. Circular dichroism studies indicate that the melting temperature of the T. maritima protein is above 92 degrees C compared with 54 degrees C for the homologous Escherichia coli protein while analytical ultracentrifugation showed that both proteins have the same quaternary structure. Interestingly, UV-visible spectral studies revealed that the dissociation constants for both oxidized FMN and 5-enolpyruvylshikimate 3-phosphate decrease 46- and 10-fold, respectively, upon heat treatment of the T. maritima protein. The heat treatment also results in the trapping of the flavin cofactor in an apolar environment, a feature which is enhanced by the presence of the substrate 5-enolpyruvylshikimate 3-phosphate. Nevertheless, stopped-flow spectrophotometric evidence suggests that the mechanism of the T. maritima protein is similar to that of the E. coli protein. In essence, the study shows that T. maritima chorismate synthase exhibits considerably higher rigidity and thermostability while it has conserved features relevant to its catalytic function.     

Folate activation and catalysis in methylenetetrahydrofolate reductase from Escherichia coli: roles for aspartate 120 and glutamate 28

The flavoprotein Escherichia coli methylenetetrahydrofolate reductase (MTHFR) catalyzes the reduction of 5,10-methylenetetrahydrofolate (CH(2)-H(4)folate) to 5-methyltetrahydrofolate (CH(3)-H(4)folate). The X-ray crystal structure of the enzyme has revealed the amino acids at the flavin active site that are likely to be relevant to catalysis. Here, we have focused on two conserved residues, Asp 120 and Glu 28. The presence of an acidic residue (Asp 120) near the N1-C2=O position of the flavin distinguishes MTHFR from all other known flavin oxidoreductases and suggests an important function for this residue in modulating the flavin reactivity. Modeling of the CH(3)-H(4)folate product into the enzyme active site also suggests roles for Asp 120 in binding of folate and in electrostatic stabilization of the putative 5-iminium cation intermediate during catalysis. In the NADH-menadione oxidoreductase assay and in the isolated reductive half-reaction, the Asp120Asn mutant enzyme is reduced by NADH 30% more rapidly than the wild-type enzyme, which is consistent with a measured increase in the flavin midpoint potential. Compared to the wild-type enzyme, the mutant showed 150-fold decreased activity in the physiological NADH-CH(2)-H(4)folate oxidoreductase reaction and in the oxidative half-reaction involving CH(2)-H(4)folate, but the apparent K(d) for CH(2)-H(4)folate was relatively unchanged. Our results support a role for Asp 120 in catalysis of folate reduction and perhaps in stabilization of the 5-iminium cation. By analogy to thymidylate synthase, which also uses CH(2)-H(4)folate as a substrate, Glu 28 may serve directly or via water as a general acid catalyst to aid in 5-iminium cation formation. Consistent with this role, the Glu28Gln mutant was unable to catalyze the reduction of CH(2)-H(4)folate and was inactive in the physiological oxidoreductase reaction. The mutant enzyme was able to bind CH(3)-H(4)folate, but reduction of the FAD cofactor was not observed. In the NADH-menadione oxidoreductase assay, the mutant demonstrated a 240-fold decrease in activity.     

Catalytic mechanism of phosphorylase kinase probed by mutational studies.

The contributions to catalysis of the conserved catalytic aspartate (Asp149) in the phosphorylase kinase catalytic subunit (PhK; residues 1-298) have been studied by kinetic and crystallographic methods. Kinetic studies in solvents of different viscosity show that PhK, like cyclic AMP dependent protein kinase, exhibits a mechanism in which the chemical step of phosphoryl transfer is fast and the rate-limiting step is release of the products, ADP and phosphoprotein, and possibly viscosity-dependent conformational changes. Site-directed mutagenesis of Asp149 to Ala and Asn resulted in enzymes with a small increase in K(m) for glycogen phosphorylase b (GPb) and ATP substrates and dramatic decreases in k(cat) (1.3 x 10(4) for Asp149Ala and 4.7 x 10(3) for Asp149Asn mutants, respectively). Viscosometric kinetic measurements with the Asp149Asn mutant showed a reduction in the rate-limiting step for release of products by 4.5 x 10(3) and a significant decrease (possibly as great as 2.2 x 10(3)) in the rate constant characterizing the chemical step. The date combined with the crystallographic evidence for the ternary PhK-AMPPNP-peptide complex [Lowe et al. (1997) EMBO J. 6, 6646-6658] provide powerful support for the role of the carboxyl of Asp149 in binding and orientation of the substrate and in catalysis of phosphoryl transfer. The constitutively active subunit PhK has a glutamate (Glu182) residue in the activation segment, in place of a phosphorylatable serine, threonine, or tyrosine residue in other protein kinases that are activated by phosphorylation. Site-directed mutagenesis of Glu182 and other residues involved in a hydrogen bond network resulted in mutant proteins (Glu182Ser, Arg148Ala, and Tyr206Phe) with decreased catalytic efficiency (approximate average decrease in k(cat)/K(m) by 20-fold). The crystal structure of the mutant Glu182Ser at 2.6 A resolution showed a phosphate dianion about 2.6 A from the position previously occupied by the carboxylate of Glu182. There was no change in tertiary structure from the native protein, but the activation segment in the region C-terminal to residue 182 showed increased disorder, indicating that correct localization of the activation segment is necessary in order to recognize and present the protein substrate for catalysis.     

Role of Asp222 in the catalytic mechanism of Escherichia coli aspartate aminotransferase: the amino acid residue which enhances the function of the enzyme-bound coenzyme pyridoxal 5'-phosphate.

Asp222 is an invariant residue in all known sequences of aspartate aminotransferases from a variety of sources and is located within a distance of strong ionic interaction with N(1) of the coenzyme, pyridoxal 5'-phosphate (PLP), or pyridoxamine 5'-phosphate (PMP). This residue of Escherichia coli aspartate aminotransferase was replaced by Ala, Asn, or Glu by site-directed mutagenesis. The PLP form of the mutant enzyme D222E showed pH-dependent spectral changes with a pKa value of 6.44 for the protonation of the internal aldimine bond, slightly lower than that (6.7) for the wild-type enzyme. In contrast, the internal aldimine bond in the D222A or D222N enzyme did not titrate over the pH range 5.3-9.5, and a 430-nm band attributed to the protonated aldimine persisted even at high pH. The binding affinity of the D222A and D222N enzymes for PMP decreased by 3 orders of magnitude as compared to that of the wild-type enzyme. Pre-steady-state half-transamination reactions of all the mutant enzymes with substrates exhibited anomalous progress curves comprising multiphasic exponential processes, which were accounted for by postulating several kinetically different enzyme species for both the PLP and PMP forms of each mutant enzyme. While the replacement of Asp222 by Glu yielded fairly active enzyme species, the replacement by Ala and Asn resulted in 8600- and 20,000-fold decreases, respectively, in the catalytic efficiency (kmax/Kd value for the most active species of each mutant enzyme) in the reactions of the PLP form with aspartate. In contrast, the catalytic efficiency of the PMP form of the D222A or D222N enzyme with 2-oxoglutarate was still retained at a level as high as 2-10% of that of the wild-type enzyme. The presteady-state reactions of these two mutant enzymes with [2-2H]aspartate revealed a deuterium isotope effect (kH/kD = 6.0) greater than that [kH/kD = 2.2; Kuramitsu, S., Hiromi, K., Hayashi, H., Morino, Y., & Kagamiyama, H. (1990) Biochemistry 29, 5469-5476] for the wild-type enzyme. These findings indicate that the presence of a negatively charged residue at position 222 is particularly critical for the withdrawal of the alpha-proton of the amino acid substrate and accelerates this rate-determining step by about 5 kcal.mol-1. Thus it is concluded that Asp222 serves as a protein ligand tethering the coenzyme in a productive mode within the active site and stabilizes the protonated N(1) of the coenzyme to strengthen the electron-withdrawing capacity of the coenzyme.     

Reversing Evolution: Re-establishing Obligate Metal Ion Dependence in a Metal-independent KDO8P Synthase

Two distinct groups of 3-deoxy-d-manno-octulosonate 8-phosphate synthase (KDO8PS), a key enzyme of cell-wall biosynthesis, differ by their requirement for a divalent metal ion for enzymatic activity. The unique difference between these groups is the replacement of the metal-binding Cys by Asn. Substitution of just this Asn for a Cys in metal-independent KDO8PS does not create the obligate metal-ion dependency of natural metal-dependent enzymes. We describe how three or four mutations of the metal-independent KDO8PS from Neisseria meningitidis produce a fully functional, obligately metal-dependent KDO8PS. For the substitutions Asn23Cys, Asp247Glu (this Asp binds to the metal ion in all metal-dependent KDO8PS) and Pro249Ala, and for double and triple combinations, mutant enzymes that contained Cys in place of Asn showed an increase in activity in the presence of divalent metal ions. However, combining these mutations with substitution by Ser of the Cys residue in the conserved ²⁴⁶CysAspGlyPro²⁴⁹ motif of metal-independent KDO8PS created enzymes with obligate metal dependency. The quadruple mutant (Asn23Cys/Cys246Ser/Asp247Glu/Pro249Ala) showed comparable activity to wild-type enzymes only in the presence of metal ions, with maximum activity with Cd²⁺, the metal ion that is strongly inhibitory at micromolar concentrations for the wild-type enzyme. In the absence of metal ions, activity was barely detectable for this quadruple mutant or for triple mutants bearing both Cys246Ser and Asn23Cys mutations. The structures of NmeKDO8PS and its Asn23Cys/Asp247Glu/Pro249Ala and quadruple mutants at pH 4.6 were characterized at resolutions better than 1.85 Å. Aged crystals of the Asn23Cys/Asp247Glu/Pro249Ala mutant featured a Cys23-Cys246 disulfide linkage, explaining the spectral bleaching observed when this mutant was incubated with Cu²⁺. Such bleaching was not observed for the quadruple mutant. Reverse evolution to a fully functional obligately metal-dependent KDO8PS has been achieved with just three directed mutations for enzymes that have, at best, 47% identity between metal-dependent and metal-independent pairs.     

Role of aspartate 400, arginine 262, and arginine 401 in the catalytic mechanism of human coproporphyrinogen oxidase

Coproporphyrinogen oxidase (CPO) is the sixth enzyme in the heme biosynthetic pathway, catalyzing two sequential oxidative decarboxylations of propionate moieties on coproporphyrinogen-III forming protoporphyrinogen-IX through a monovinyl intermediate, harderoporphyrinogen. Site-directed mutagenesis studies were carried out on three invariant amino acids, aspartate 400, arginine 262, and arginine 401, to determine residue contribution to substrate binding and/or catalysis by human recombinant CPO. Kinetic analyses were performed on mutant enzymes incubated with three substrates, coproporphyrinogen-III, harderoporphyrinogen, or mesoporphyrinogen-VI, in order to determine catalytic ability to perform the first and/or second oxidative decarboxylation. When Asp400 was mutated to alanine no divinyl product was detected, but the production of a small amount of monovinyl product suggested the K(m) value for coproporphyrinogen-III did not change significantly compared to the wild-type enzyme. Upon mutation of Arg262 to alanine, CPO was again a poor catalyst for the production of a divinyl product, with a catalytic efficiency <0.01% compared to wild-type, including a 15-fold higher K(m) for coproporphyrinogen-III. The efficiency of divinyl product formation for mutant enzyme Arg401Ala was approximately 3% compared to wild-type CPO, with a threefold increase in the K(m) value for coproporphyrinogen-III. These data suggest Asp400, Arg262, and Arg401 are active site amino acids critical for substrate binding and/or catalysis. Possible roles for arginine 262 and 401 include coordination of carboxylate groups of coproporphyrinogen-III, while aspartate 400 may initiate deprotonation of substrate, resulting in an oxidative decarboxylation.     

A unique reaction in a common pathway: mechanism and function of chorismate synthase in the shikimate pathway

Chorismate synthase, the seventh enzyme in the shikimate pathway, catalyzes the transformation of 5-enolpyruvylshikimate 3-phosphate to chorismate which is the last common precursor in the biosynthesis of numerous aromatic compounds in bacteria, fungi and plants. The enzyme has an absolute requirement for reduced FMN as a cofactor, although the 1,4-anti elimination of phosphate and the C(6proR)-hydrogen does not involve a net redox change. The role of the reduced FMN in catalysis has long been elusive. However, recent detailed kinetic and bioorganic approaches have fundamentally advanced our understanding of the mechanism of action, suggesting an initial electron transfer from tightly bound reduced flavin to the substrate, a process which results in C—O bond cleavage. Studies on chorismate synthases from bacteria, fungi and plants revealed that in these organisms the reduced FMN cofactor is made available in different ways to chorismate synthase: chorismate synthases in fungi – in contrast to those in bacteria and plants – carry a second enzymatic activity which enables them to reduce FMN at the expense of NADPH. Yet, as shown by the analysis of the corresponding genes, all chorismate synthases are derived from a common ancestor. However, several issues revolving around the origin of reduced FMN, as well as the possible regulation of the enzyme activity by means of the availability of reduced FMN, remain poorly understood. This review summarizes recent developments in the biochemical and genetic arena and identifies future aims in this field. Received: 22 June 1998 / Accepted: 7 August 1998     

The role of the Ca2+ binding ligand Asn879 in the function of the plasma membrane Ca2+ pump

Asn879 in the transmembrane segment M6 of the plasma membrane Ca²⁺ pump (PMCA human isoform 4xb) has been proposed to coordinate Ca²⁺ at the transport site through its carboxylate. This idea agrees with the fact that this Asn is conserved in other Ca²⁺-ATPases but is replaced by Asp, Glu, and other residues in closely related 2P-type ATPases of different ionic specificity. Previous mutagenesis studies have shown that the substitution of Ala for Asn abolishes the activity of the enzyme (Adebayo et al., 1995; Guerini et al., 1996). We have constructed a mutant PMCA in which the Asn879 was substituted by Asp. The mutant protein was expressed in Saccharomyces cerevisiae, solubilized and purified by calmodulin affinity chromatography. The Asn879Asp PMCA mutant exhibited about 30% of the wild type Ca²⁺-dependent ATPase activity and only a minor reduction of the apparent affinity for Ca²⁺. The decrease in the Ca²⁺-ATPase of the mutant enzyme was in parallel with the reduction in the amount of phosphoenzyme formed from Ca²⁺ plus ATP. Noteworthy, the mutation nearly eliminated the ability of the enzyme to hydrolyze pNPP which is maximal in the absence of Ca²⁺ revealing a major effect of the mutation on the Ca²⁺-independent reactions of the transport cycle. At a pH low enough to protonate the Asp carboxylate the pNPPase activity of Asn879Asp increased, suggesting that the binding of protons to Asn879 is essential for the activities catalyzed by E₂-like forms of the enzyme.     

Studies of the mechanism of phenol hydroxylase: mutants Tyr289Phe, Asp54Asn, and Arg281Met

Three residues in the active site of the flavoprotein phenol hydroxylase (PHHY) were independently changed by site-directed mutagenesis. One of the mutant forms of PHHY, Tyr289Phe, is reduced by NADPH much slower than is the wild-type enzyme, although it has a slightly higher redox potential than the wild-type enzyme. In the structure of the wild-type enzyme, residue Tyr289 is hydrogen-bonded with the FAD when the latter is at the "out" position but has no direct contact with the flavin when it is "in". The oxidative half-reaction of PHHY is not significantly affected by this mutation, contrary to the concept that Tyr289 is a critical residue in the hydroxylation reaction [Enroth, C., Neujahr, H., Schneider, G., and Lindqvist, Y. (1998) Structure 6, 605-617; Ridder, L., Mullholland, A. J., Rietjens, I. M. C. M., and Vervoort, J. (2000) J. Am. Chem. Soc. 122, 8728-8738]. Tyr289 may help stabilize the FAD in the out conformation where it can be reduced by NADPH. For the Asp54Asn mutant form of PHHY, the initial step of the oxidative half-reaction is significantly slower than for the wild-type enzyme. Asp54Asn utilizes less than 20% of the reduced flavin for hydroxylating the substrate with the remainder forming H(2)O(2). Similar changes are observed when Arg281, a residue between Asp54 and the solvent, is mutated to Met. These two residues are suggested to be part of the active site environment the enzyme provides for the flavin cofactor to function optimally in the oxidative half-reaction. In the construction of the mutant forms of PHHY, it was determined that 11 of the previously reported amino acid residues in the sequence of PHHY were incorrect.     

Substitution of Gly-96 to Ala in the 5-enolpyruvylshikimate-3-phosphate synthase of Klebsiella pneumoniae results in a greatly reduced affinity for the herbicide glyphosate

The aroA gene of Klebsiella pneumoniae encoding the shikimate pathway enzyme 5-enolpyruvylshikimate 3-phosphate (EPSP) synthase, which is the target of the herbicide glyphosate, was cloned and sequenced from both the wild-type and the glyphosate-resistant mutant K. pneumoniae K1, which possesses a glyphosate-insensitive EPSP synthase. Both genes were expressed in Escherichia coli and were capable of complementing an auxotrophic aroA mutation. The transformed cells showed increased tolerance to glyphosate due to the overproduction of either the mutant or the wild type EPSP synthase. Nucleotide sequence analysis of the K. pneumoniae aroA gene indicated a protein-coding region of 427 amino acids with a derived Mr for the EPSP synthase of 45,976. Comparison of the two aroA alleles showed a single base change resulting in a substitution of Gly-96 to Ala in the deduced amino acid sequence. By comparison with other known EPSP synthase sequences the mutation was shown to be located in a highly conserved region, indicating that this region is essential for the binding of the herbicide glyphosate.     

Specificity and mutational analysis of the metal-dependent 3-deoxy-d-manno-octulosonate 8-phosphate synthase from Acidithiobacillus ferrooxidans

3-Deoxy-d-manno-octulosonate 8-phosphate synthase (KDO8PS) catalyzes the reaction between phosphoenol pyruvate and d-arabinose 5-phosphate to generate KDO8P. This reaction is part of the biosynthetic pathway to 3-deoxy-d-manno-octulosonate, a component of the lipopolysaccharide of the Gram-negative bacterial cell wall. Two distinct groups of KDO8PSs exist, differing by the absolute requirement of a divalent metal ion. In this study Acidithiobacillus ferrooxidans KDO8PS has been expressed and purified and shown to require a divalent metal ion, with Mn²⁺, Co²⁺ and Cd²⁺ (in decreasing order) being able to restore activity to metal-free enzyme. Cd²⁺ significantly enhanced the stability of the enzyme, raising the T_m by 14 °C. d-Glucose 6-phosphate and d-erythrose 4-phosphate were not substrates for A. ferrooxidans KDO8PS, whereas 2-deoxy-d-ribose 5-phosphate was a poor substrate and there was negligible activity with d-ribose 5-phosphate. The ²⁴³AspGlyPro²⁴⁵ motif is absolutely conserved in the metal-independent group of synthases, but the Gly and Pro sites are variable in the metal-dependent enzymes. Substitution of the putative metal-binding Asp243 to Ala in A. ferrooxidans KDO8PS gave inactive enzyme, whereas substitutions Asp243Glu or Pro245Ala produced active enzymes with altered metal-dependency profiles. Prior studies indicated that exchange of a metal-binding Cys for Asn converts metal-dependent KDO8P synthase into a metal-independent form. Unexpectedly, this mutation in A. ferrooxidans KDO8P synthase (Cys21Asn) gave inactive enzyme. This finding, together with modest activity towards 2-deoxy-d-ribose 5-phosphate suggests similarities between the A. ferrooxidans KDO8PS and the related metal-dependent 3-deoxy-d-arabino-heptulosonate phosphate synthase, and highlights the importance of the AspGlyPro loop in positioning the substrate for effective catalysis in all KDO8P synthases.