Phosphoenolpyruvate Binding Research Articles

Structure and Mechanism of 3-Deoxy-d-manno-octulosonate 8-Phosphate Synthase

3-deoxy-D-manno-octulosonate 8-phosphate (KDO8P) synthase catalyzes the condensation of phosphoenolpyruvate (PEP) with arabinose 5-phosphate (A5P) to form KDO8P and inorganic phosphate. KDO8P is the phosphorylated precursor of 3-deoxy-D-manno-octulosonate, an essential sugar of the lipopolysaccharide of Gram-negative bacteria. The crystal structure of the Escherichia coli KDO8P synthase has been determined by multiple wavelength anomalous diffraction and the model has been refined to 2.4 A (R-factor, 19.9%; R-free, 23.9%). KDO8P synthase is a homotetramer in which each monomer has the fold of a (beta/alpha)(8) barrel. On the basis of the features of the active site, PEP and A5P are predicted to bind with their phosphate moieties 13 A apart such that KDO8P synthesis would proceed via a linear intermediate. A reaction similar to KDO8P synthesis, the condensation of phosphoenolpyruvate, and erythrose 4-phosphate to form 3-deoxy-D-arabino-heptulosonate 7-phosphate (DAH7P), is catalyzed by DAH7P synthase. In the active site of DAH7P synthase the two substrates PEP and erythrose 4-phosphate appear to bind in a configuration similar to that proposed for PEP and A5P in the active site of KDO8P synthase. This observation suggests that KDO8P synthase and DAH7P synthase evolved from a common ancestor and that they adopt the same catalytic strategy.

Role of the Loop Containing Residue 115 in the Induced-Fit Mechanism of the Bacterial Cell Wall Biosynthetic Enzyme MurA

The induced-fit mechanism in Enterobacter cloacae MurA has been investigated by kinetic studies and X-ray crystallography. The antibiotic fosfomycin, an irreversible inhibitor of MurA, induced a structural change in UDP-N-acetylglucosamine (UDPGlcNAc)-liganded enzyme with a time dependence similar to that observed for the inactivation progress. The mechanism of action of fosfomycin on MurA appeared to be of the bimolecular type, the overall rate constants of inactivation and structural change being = 104 M(-1) s(-1) and = 85 M(-1) s(-1), respectively. Fosfomycin as well as the second MurA substrate, phosphoenolpyruvate (PEP), are known to interact with the side chain of Cys115. Like wild-type MurA, the catalytically inactive single-site mutant protein Cys115Ser structurally interacted with UDPGlcNAc in a rapidly reversible reaction. However, in contrast to wild-type enzyme, binding of PEP to mutant protein induced a rate-limited, biphasic structural change. Fosfomycin did not affect the structure of the mutant protein. The crystal structure of unliganded Cys115Ser MurA at 1.9 A resolution revealed that the overall conformation of the loop comprising residues 112-121 is not influenced by the mutation. However, other than Cys115 in wild-type MurA, Ser115 exhibits two distinct side-chain conformations. A detailed view on the loop revealed the existence of an elaborate hydrogen-bonding network mainly supplied by water molecules, presumably stabilizing its conformation in the unliganded state. The comparison between the known crystal structures of MurA, together with the kinetic data obtained, suggest intermediate conformational states in the MurA reaction, in which the loop undergoes multiple structural changes upon ligand binding.

Insight into the mechanism of phosphoenolpyruvate mutase catalysis derived from site-directed mutagenesis studies of active site residues.

PEP mutase catalyzes the conversion of phosphoenolpyruvate (PEP) to phosphonopyruvate in biosynthetic pathways leading to phosphonate secondary metabolites. A recent X-ray structure [Huang, K., Li, Z., Jia, Y., Dunaway-Mariano, D., and Herzberg, O. (1999) Structure (in press)] of the Mytilus edulis enzyme complexed with the Mg(II) cofactor and oxalate inhibitor reveals an alpha/beta-barrel backbone-fold housing an active site in which Mg(II) is bound by the two carboxylate groups of the oxalate ligand and the side chain of D85 and, via bridging water molecules, by the side chains of D58, D85, D87, and E114. The oxalate ligand, in turn, interacts with the side chains of R159, W44, and S46 and the backbone amide NHs of G47 and L48. Modeling studies identified two feasible PEP binding modes: model A in which PEP replaces oxalate with its carboxylate group interacting with R159 and its phosphoryl group positioned close to D58 and Mg(II) shifting slightly from its original position in the crystal structure, and model B in which PEP replaces oxalate with its phosphoryl group interacting with R159 and Mg(II) retaining its original position. Site-directed mutagenesis studies of the key mutase active site residues (R159, D58, D85, D87, and E114) were carried out in order to evaluate the catalytic roles predicted by the two models. The observed retention of low catalytic activity in the mutants R159A, D85A, D87A, and E114A, coupled with the absence of detectable catalytic activity in D58A, was interpreted as evidence for model A in which D58 functions in nucleophilic catalysis (phosphoryl transfer), R159 functions in PEP carboxylate group binding, and the carboxylates of D85, D87 and E114 function in Mg(II) binding. These results also provide evidence against model B in which R159 serves to mediate the phosphoryl transfer. A catalytic motif, which could serve both the phosphoryl transfer and the C-C cleavage enzymes of the PEP mutase superfamily, is proposed.

Plausible phospho enolpyruvate binding site revealed by 2.6 Å structure of Mn 2+-bound phospho enolpyruvate carboxylase from Escherichia coli

We have determined the crystal structure of Mn 2+-bound Escherichia coli phospho enolpyruvate carboxylase (PEPC) using X-ray diffraction at 2.6 Å resolution, and specified the location of enzyme-bound Mn 2+, which is essential for catalytic activity. The electron density map reveals that Mn 2+ is bound to the side chain oxygens of Glu-506 and Asp-543, and located at the top of the α/β barrel in PEPC. The coordination sphere of Mn 2+ observed in E. coli PEPC is similar to that of Mn 2+ found in the pyruvate kinase structure. The model study of Mn 2+-bound PEPC complexed with phospho enolpyruvate (PEP) reveals that the side chains of Arg-396, Arg-581 and Arg-713 could interact with PEP.

Kinetics and equilibrium binding of phosphoenolpyruvate to phosphoenolpyruvate carboxylase from Zea mays

Phosphoenolpyruvate carboxylase (PEPC) the carbon dioxide processing enzyme of C4 plants shows different affinities for the substrate phosphoenolpyruvate (PEP) at pH 7.0 and pH 8.0. This has been demonstrated by determination of the enzymatic activity, applying fluorescence titrations and fast reaction techniques such as iodine laser temperature jump (ILTJ) and stopped flow (SF). The binding reaction of PEP to PEPC from Zeamays was measured using the fluorescence probe 2-p-toluidinonaphthalene-6-sulfonate (TNS). The kinetics are described by an allosteric mechanism with a fast reversible bimolecular binding reaction of PEP to a high affinity (tensed) form of PEPC which is in equilibrium with its low affinity (relaxed) form. The association and dissociation rate constants k+A and k-A for the fast binding reaction to the high affinity form were determined to be 1.4±0.15×104 M-1 s-1 and 17±6 s-1 at pH 8.0. The corresponding dissociation constants Kd=1.2±0.5 mM for PEP calculated from the kinetic constants, measured by ILTJ and SF, are in good agreement with Kd values achieved in our equilibrium titration experiments or from the data of Michaelis–Menten-type kinetic experiments. PEP preferentially binds to the high affinity binding site of PEPC, shifting the isomerisation equilibrium strongly towards the tensed form, with the consequence that PEPC is activated. Rate constants for the isomerisation process were obtained as kB+(0)=4.95±0.35 s-1 and kB-(0)=1.25±0.1 s-1 at pH 8. Our kinetic data are consistent with the concerted sequential allosteric mechanism introduced by Monod, Wyman and Changeux. In summary, in this study we present, for the first time, data on the kinetics of PEP binding and on the rate of the isomerisation reaction between the two allosteric forms of PEPC.

Catalytic mechanism of Kdo8P synthase: transient kinetic studies and evaluation of a putative reaction intermediate.

The mechanistic pathway for the reaction catalyzed by Kdo8P synthase has been investigated, and the cyclic bisphosphate 2 has been examined as a putative reaction intermediate. Two parallel approaches were used: (1) chemical synthesis of 2 and evaluation as an alternate substrate for the enzyme and (2) transient kinetic studies using rapid chemical quench methodology to provide direct observation and characterization of putative intermediate(s) during enzyme catalysis. The putative cyclic bisphosphate intermediate 2, possessing the stereochemistry of the beta-pyranose form, was synthesized and evaluated as a substrate and as an inhibitor of Kdo8P synthase. The substrate activity was examined by monitoring the release of anomeric phosphate over time using proton-decoupled 31P NMR spectroscopy. A very similar time course for the formation of inorganic phosphate was found in each experiment and the corresponding control experiment; i.e., no enzyme-catalyzed acceleration in the anomeric phosphate hydrolysis was detected. It was found however that 2 binds to the enzyme and is a competitive inhibitor with respect to phosphoenolpyruvate binding, having a Ki value of 35 microM. In a parallel study, we have performed single-turnover rapid chemical quench experiments to examine both the forward and reverse directions to identify a putative enzyme intermediate(s). Our results clearly demonstrate that the cyclic bisphosphate intermediate 2 does not accumulate under single-enzyme turnover conditions. This observation, coupled with the results obtained through the evaluation of synthetic 2 as a substrate, strongly suggests that the Kdo8P synthase catalytic pathway does not involve the formation of 2 as a reaction intermediate. Taken together, these combined results support the original hypothesis [Hedstrom, L., and Abeles, R. H. (1988) Biochem. Biophys. Res. Commun. 157, 816-820], which suggests a reaction pathway involving an acyclic bisphosphate intermediate 1.

Interfacial communications in recombinant rabbit kidney pyruvate kinase.

Tissue-specific isozymes of pyruvate kinase are particularly attractive systems to elucidate the molecular mechanism(s) of conferring allostery. The muscle- and kidney-type isozymes are coded by the same gene. As a consequence of alternative message RNA splicing, the two primary sequences differ by a small number of residues. However, they exhibit very different regulatory behavior. In an effort to identify the roles of specific residues in conferring allostery, the gene encoding rabbit kidney-type pyruvate kinase was cloned and expressed in Escherichia coli. The primary structure of recombinant rabbit kidney-type pyruvate kinase (rRKPK) and recombinant rabbit muscle-type pyruvate kinase (rRMPK) differ at 22 positions, which are located in a region that forms important intersubunit contacts in the RMPK structure. Velocity sedimentation and analytical gel chromatographic studies show that rRKPK undergoes reversible dimer left and right arrow tetramer assembly with an equilibrium constant of 28 +/- 3 mL/mg. This subunit assembly process provides the opportunity to elucidate the role of this dimer interface in transmission of signal upon binding of substrates and allosteric effectors. The assembly to tetrameric rRKPK is favored by the binding of phosphoenolpyruvate (PEP), one of the two substrates, or fructose 1,6-bisphosphate (FBP), an activator. In contrast, the equilibrium is shifted toward dimeric rRKPK upon binding of adenosine diphosphate (ADP), the other substrate, or l-phenylalanine (Phe), the inhibitor. These observations provide significant new insights to the molecular mechanism of allosteric regulation in the pyruvate kinase system. First, all substrates and effectors communicate through this particular dimer-dimer interface. Second, the thermodynamic signatures of these communications are qualitatively different for the two substrates and between the activator, FBP, and inhibitor, Phe.

Mechanism of Enolase: The Crystal Structure of Asymmetric Dimer Enolase−2-Phospho-d-glycerate/Enolase−Phosphoenolpyruvate at 2.0 Å Resolution,

Enolase, a glycolytic enzyme that catalyzes the dehydration of 2-phospho-d-glycerate (PGA) to form phosphoenolpyruvate (PEP), is a homodimer in all eukaryotes and many prokaryotes. Here, we report the crystal structure of a complex between yeast enolase and an equilibrium mixture of PGA and PEP. The structure has been refined using 29 854 reflections with an F/sigma(F) of >/=3 to an R of 0.137 with average deviations of bond lengths and bond angles from ideal values of 0.013 A and 3.1 degrees , respectively. In this structure, the dimer constitutes the crystallographic asymmetric unit. The two subunits are similar, and their superposition gives a rms distance between Calpha atoms of 0.91 A. The exceptions to this are the catalytic loop Val153-Phe169 where the atomic positions in the two subunits differ by up to 4 A and the loop Ser250-Gln277, which follows the catalytic loop Val153-Phe169. In the first subunit, the imidazole side chain of His159 is in contact with the phosphate group of the substrate/product molecule; in the other it is separated by water molecules. A series of hydrogen bonds leading to a neighboring enolase dimer can be identified as being responsible for ordering and stabilization of the conformationally different subunits in the crystal lattice. The electron density present in the active site suggests that in the active site with the direct ligand-His159 hydrogen bond PGA is predominantly bound while in the active site where water molecules separate His159 from the ligand the binding of PEP dominates. The structure indicates that the water molecule hydrating carbon-3 of PEP in the PEP --> PGA reaction is activated by the carboxylates of Glu168 and Glu211. The crystals are unique because they have resolved two intermediates on the opposite sides of the transition state.

Purification and Characterization of Cytosolic Pyruvate Kinase from Leaves of the Castor Oil Plant

Cytosolic pyruvate kinase (PKc) from leaves of the castor oil plant (Ricinus communisL.) has been purified 3900-fold to apparent homogeneity and a final specific activity of 51 μmol of pyruvate produced/min/mg protein. PAGE, immunoblot, and gel filtration analyses of the final preparation indicated that this enzyme is an α2β2heterotetramer of about 250 kDa that is composed of an equivalent ratio of 57- and 56-kDa subunits. The enzyme was relatively heat-stable and displayed a broad pH optimum of approximately 6.5. However, optimal efficiency in substrate utilization [in terms ofVmax/Kmfor phosphoenolpyruvate (PEP) or ADP] occurred at pH 7.5. Enzyme activity was absolutely dependent upon the simultaneous presence of bivalent and a univalent metal cation, with Mg2+and K+fulfilling this requirement. Hyperbolic saturation kinetics were observed with PEP, ADP, and K+, whereas Mg2+binding exhibited positive cooperativity. Mg2citrate, oxalate, and glutamate were the most effective inhibitors at pH 7.5. Inhibition by these compounds was more pronounced at pH 7.5 than at pH 6.5 and they yielded additive inhibition when tested in pairs. Aspartate functioned as an activator by facilitating the binding of PEP and relieving the inhibition of PKcby glutamate. Thein vivoactivity of leaf PKcis probably regulated by the relative cytosolic levels of citrate, glutamate, and aspartate. This provides a possible rationale for the known activation of leaf PKcthat occurs during periods of enhanced ammonia assimilation. Together with our previous studies, the results also indicate that castor oil plant PKcexists as tissue-specific isoforms that demonstrate substantial differences in their respective physical and/or kinetic and regulatory properties.

Point mutation of a conserved arginine (104) to lysine introduces hypersensitivity to inhibition by glyphosate in the 5-enolpyruvylshikimate-3-phosphate synthase of Bacillus subtilis

The role of a conserved arginine (R104) in the putative phosphoenol pyruvate binding region of 5-enolpyruvyl shikimate-3-phosphate synthase of Bacillus subtilis has been investigated. Employing site directed mutagenesis arginine was substituted by lysine or glutamine. Native and mutant proteins were expressed and purified to near homogeneity. Estimation of Michaelis and inhibitor constants of the native and mutant proteins exhibited altered substrate—inhibitor binding mode and constants. Mutation R104K hypersensitized the enzyme reaction to inhibition by glyphosate. The role of R104 in discriminating between glyphosate and phosphoenol pyruvate is discussed.

Site-directed mutagenesis and NMR studies of histidine-385 mutants of 5-enolpyruvylshikimate-3-phosphate synthase.

The site-directed mutagenesis of His-385 of 5-enolpyruvylshikimate-3-phosphate (EPSP) synthase is reported. The steady-state kinetics for two mutants, H385Q and H385A, are compared with that of the wild-type enzyme. H385Q EPSP synthase was found to have 25% wild-type enzyme activity, whereas H385A EPSP synthase retained 1% activity. The KM values for Pi and shikimate 3-phosphate were unaffected, whereas the KM for phosphoenolpyruvate (PEP) was increased 10 times for H385Q EPSP synthase. The KM for EPSP was unaffected in H385Q but raised by a factor of 10 in H385A EPSP synthase. The binding of glyphosate was studied by fluorescence spectroscopy and by 31P NMR spectroscopy. Direct observation of the enzyme-intermediate complexes by 13C NMR spectroscopy with [2,3-13C]phosphoenolpyruvate was studied for the mutant enzymes and compared with the wild type. Under equilibrium conditions, H385A EPSP synthase does not accumulate enzyme-bound EPSP. These results suggest that, while critically located in the PEP binding site, His-385 is not the residue responsible for initiating catalysis through the protonation of PEP.

Comparison of the Inhibition by Phospho(enol)Pyruvate and Phosphoglycolate of Phosphofructokinase from B. stearothermophilus

A comparison between the inhibition by phospho(enol)pyruvate (PEP) versus the inhibition by phosphoglycolate (PG) of phosphofructokinase (PFK) from Bacillus stearothermophilus is presented. Both inhibitors act by decreasing the apparent affinity displayed by the enzyme for its substrate fructose 6-phosphate (Fru-6-P) while having little effect on V max. However, the two ligands differ in both their affinity for the enzyme and their effectiveness at antagonizing the subsequent binding of Fru-6-P. Although PG binds with approximately 10-fold lower affinity, it antagonizes the binding of Fru-6-P 3.5-fold more strongly than does PEP. Moreover, the enthalpy and entropy contributions to the coupling free energy between inhibitor and Fru-6-P, from which these antagonisms derive, reveal even greater differences between the ligands. These data indicate, therefore, that the changes in the structure of PFK from B. stearothermophilus that result from PG binding, which have been determined by X-ray crystallography (T. Schirmer and P. R. Evans, 1990 Nature 343, 140-145), may not be comparable to those that result from PEP binding and consequently do not represent the generic "T-state," as has been presumed.

Catalytic mechanism of 3‐deoxy‐d‐manno‐2‐octulosonate‐8‐phosphate synthase

The proposed mechanistic pathway for the reaction catalyzed by 3-deoxy-D-manno-2-octulosonate-8-phosphate (Kdo8P) synthase was examined in terms of the structure of the putative bisphosphate intermediate. Two 2-deoxy analogues of the product Kdo8P, having been structurally prohibited from undergoing the ring-opening and possessing the stereochemistry of either the alpha-pyranase (compound 1) or the beta-pyranose form (compound 2) of the product, were synthesized and probed as inhibitors for the synthase. It was found that both analogues bind to the enzyme and are competitive inhibitors with respect to phosphoenolpyruvate binding, having Ki values of 470 microM and 303 microM, respectively. Comparison of this data to the Ki value of the tautomeric mixture of the product Kdo8P (Ki = 590 microM) suggests that both the alpha- and the beta-pyranose anomers (65.8% and 3.1%, respectively at neutral pH) bind to the enzyme with a slight (1.13 kJ/mol) preference for the beta-anomer, and that the C2 hydroxyl does not contribute to the binding. This uncertain stereochemical preference exhibited by the enzyme for the stereoisomers at the anomeric carbon suggests that the carboxylate binding site of the product is indistinct, while the hydroxyl and carboxylate binding sites may be interchangeable. More importantly, however, the isosteric phosphonate analogue 2,6-anhydro-3-deoxy-2 beta-phosphonylmethyl-8-phosphate-D-glycero-D-talo-octonate (3), which mimics the topological and electrostatic properties of the proposed cyclic intermediate, was found to be the most potent inhibitor of the enzyme with a Ki value of 5 microM. Two hitherto unrecognized aspects of the mechanism of the synthase were identified. First, the results showing that the cyclic analogues 1, 2 and 3 are inhibitors of the enzyme whereas the previously reported acyclic analogue, which contains no carbonyl group at C2 and may thus resemble the open-chain form of Kdo8P, is not an inhibitor, suggest that the pyranose form and not the open-chain acyclic form of the putative bisphosphate intermediate is handled by the enzyme. Second, since the overall stereochemical course of the transformation mediated by the synthase has been shown to involve si face addition of phosphoenolpyruvate to the re face of the carbonyl of arabinose 5-phosphate, the present observation involving analogue 3 suggest that the bisphosphate intermediate formed during the initial steps of synthesis may have the pyranose structure with the anomeric phosphate located in the beta-configuration.

Substrate synergism and the steady-state kinetic reaction mechanism for EPSP synthase from Escherichia coli.

Previous studies of Escherichia coli 5-enolpyruvoylshikimate-3-phosphate synthase (EPSPS, EC 2.5.1.19) have suggested that the kinetic reaction mechanism for this enzyme in the forward direction is equilibrium ordered with shikimate 3-phosphate (S3P) binding first followed by phosphoenolpyruvate (PEP). Recent results from this laboratory, however, measuring direct binding of PEP and PEP analogues to free EPSPS suggest more random character to the enzyme. Steady-state kinetic and spectroscopic studies presented here indicate that E. coli EPSPS does indeed follow a random kinetic mechanism. Initial velocity studies with S3P and PEP show competitive substrate inhibition by PEP added to a normal intersecting pattern. Substrate inhibition is proposed to occur by competitive binding of PEP at the S3P site [Ki(PEP) = 6-8 mM]. To test for a productive EPSPS.PEP binary complex, the reaction order of EPSPS was evaluated with shikimic acid and PEP as substrates. The mechanism for this reaction is equilibrium ordered with PEP binding first giving a Kia value for PEP in agreement with the independently measured Kd of 0.39 mM (shikimate Km = 25 mM). Results from this study also show that the 3-phosphate moiety of S3P offers 8.7 kcal/mol in binding energy versus a hydroxyl in this position. Over 60% of this binding energy is expressed in binding of substrate to enzyme rather than toward increasing kcat. Glyphosate inhibition of shikimate turnover was poor with approximately 8 x 10(4) loss in binding capacity compared to the normal reaction, consistent with the independently measured Kd of 12 mM for the EPSPS.glyphosate binary complex. The EPSPS.glyphosate complex induces shikimate binding, however, by a factor of 7 greater than EPSPS.PEP. Carboxyallenyl phosphate and (Z)-3-fluoro-PEP were found to be strong inhibitors of the enzyme that have surprising affinity for the S3P binding domain in addition to the PEP site as measured both kinetically and by direct observation with 31P NMR. The collective data indicate that the true kinetic mechanism for EPSPS in the forward direction is random with synergistic binding occurring between substrates and inhibitors. The synergism explains how the mechanism can be random with S3P and PEP, but yet equilibrium ordered with PEP binding first for shikimate turnover. Synergism also accounts for how glyphosate can be a strong inhibitor of the normal reaction, but poor versus shikimate turnover.

EPSP synthase: binding studies using isothermal titration microcalorimetry and equilibrium dialysis and their implications for ligand recognition and kinetic mechanism.

Isothermal titration calorimetry measurements are reported which give important new binding constant (Kd) information for various substrate and inhibitor complexes of Escherichia coli EPSP synthase (EPSPS). The validity of this technique was first verified by determining Kd's for the known binary complex with the substrate, shikimate 3-phosphate (S3P), as well as the herbicidal ternary complex with S3P and glyphosate (EPSPS.S3P.glyphosate). The observed Kd's agreed very well with those from previous independently determined kinetic and fluorescence binding measurements. Further applications unequivocally demonstrate for the first time a fairly tight interaction between phosphoenolpyruvate (PEP) and free enzyme (Kd = 390 microM) as well as a correspondingly weak affinity for glyphosate (Kd = 12 mM) alone with enzyme. The formation of the EPSPS.PEP binary complex was independently corroborated using equilibrium dialysis. These results strongly suggest that S3P synergizes glyphosate binding much more effectively than it does PEP binding. These observations add important new evidence to support the hypothesis that glyphosate acts as a transition-state analogue of PEP. However, the formation of a catalytically productive PEP binary complex is inconsistent with the previously reported compulsory binding order process required for catalysis and has led to new studies which completely revise the overall EPSPS kinetic mechanism. A previously postulated ternary complex between S3P and inorganic phosphate (EPSPS.S3P.Pi, Kd = 4 mM) was also detected for the first time. Quantitative binding enthalpies and entropies were also determined for each ligand complex from the microcalorimetry data. These values demonstrate a clear difference in thermodynamic parameters for recognition at the S3P site versus those observed for the PEP, Pi, and glyphosate sites.

Fluorescence Study of Chemical Modification of Phosphoenolpyruvate Carboxylase from Crassula argentea

The chemical modification of phosphoenolpyruvate carboxylase purified from Crassula argentea leaves was studied using the fluorescence of the extrinsic probe 8-anilino-1-naphalenesulfonate. The effects of ligands on kinetic parameters of phosphoenolpyruvate carboxylase activity, and its response to pH and metal cations, were associated with the binding of the ligands to the enzyme as measured by fluorescence. Binding of the ligands phosphoenolpyruvate, malate, and glucose-6-phosphate revealed by fluorescence measurements corresponds to competitive phenomena observed in kinetic studies. The fluorescence measurements also suggest the involvement of specific amino acids in the binding of a given ligand. Arginyl residues modified by 2,3-butanedione appear to be directly involved in the binding of phosphoenolpyruvate and malate to the active and the inhibition sites, respectively. A histidyl residue was involved in the binding of malate, accounting for the lack of inhibition by malate in kinetic studies of the enzyme treated with diethylpyrocarbonate. Although activity was lost, there was no decrease in the ability of the treated enzyme to bind phosphoenolpyruvate, suggesting that additional histidyl residues are essential for activity although not directly involved in the binding of phosphoenolpyruvate. The lysine reagent trinitrobenzenesulfonate caused a loss of activity and a reduction in malate inhibition and glucose-6-phosphate activation, but these modifications were not related to changes in the ability of the enzyme to bind any of the three ligands. This suggests that lysine residues were not directly involved in the binding of these ligands.

Inactivation of chicken mitochondrial phosphoenolpyruvate carboxykinase by o-phthalaldehyde.

Chicken liver mitochondrial phosphoenolpyruvate carboxykinase is inactivated by o-phthalaldehyde. The inactivation followed pseudo first-order kinetics, and the second-order rate constant for the inactivation process was 29 M-1 s-1 at pH 7.5 and 25 degrees C. The modified enzyme showed maximal fluorescence at 427 nm upon excitation at 337 nm, consistent with the formation of isoindole derivatives by the cross-linking of proximal cysteine and lysine residues. Activities in the physiologic reaction and in the oxaloacetate decarboxylase reaction were lost in parallel upon modification with o-phthalaldehyde. Plots of (percent of residual activity) versus (mol of isoindole incorporated/mol of enzyme) were biphasic, with the initial loss of enzymatic activity corresponding to the incorporation of one isoindole derivative/enzyme molecule. Complete inactivation of the enzyme was accompanied by the incorporation of 3 mol of isoindole/mol of enzyme. beta-Sulfopyruvate, an isoelectronic analogue of oxaloacetate, completely protected the enzyme from reacting with o-phthalaldehyde. Other substrates provided protection from inactivation, in decreasing order of protection: oxaloacetate greater than phosphoenolpyruvate greater than MgGDP, MgGTP greater than oxalate. Cysteine 31 and lysine 39 have been identified as the rapidly reacting pair in isoindole formation and enzyme inactivation. Lysine 56 and cysteine 60 are also involved in isoindole formation in the completely inactivated enzyme. These reactive cysteine residues do not correspond to the reactive cysteine residue identified in previous iodoacetate labeling studies with the chicken mitochondrial enzyme (Makinen, A. L., and Nowak, T. (1989) J. Biol. Chem. 264, 12148-12157). Protection experiments suggest that the sites of o-phthalaldehyde modification become inaccessible when the oxaloacetate/phosphoenolpyruvate binding site is saturated, and sequence analyses indicate that cysteine 31 is located in the putative phosphoenolpyruvate binding site.

Steady-state fluorescence of Escherichia coli phosphofructokinase reveals a regulatory role for ATP

We have investigated the effects of ligands and effectors on the intrinsic fluorescence of Escherichia coli phosphofructokinase (PFK). We have found that the substrate fructose 6-phosphate (Fru6P) or the allosteric activator ADP can quench the fluorescence up to 35%. The response is hyperbolic with Ks[Fru6P] of 20 microM and Ks[ADP] of 13 microM. The allosteric inhibitor phosphoenolpyruvate (PEP) converts the hyperbolic response with respect to Fru6P to a sigmoidal response. AMP-PNP, a nonhydrolyzable analogue of ATP, also inhibits the Fru6P fluorescence response. PFK mutant KA213, which is insensitive to effectors, has a decreased fluorescence response with respect to ADP, and PEP does not convert the Fru6P response to sigmoidicity. However, its fluorescence response with respect to Fru6P is decreased by ATP or AMP-PNP. Taken together, these results suggest that, in the absence of effectors or ligands, E. coli PFK exists in a state with high affinity for Fru6P ("R" state). This state can be altered to a low affinity ("T" state) by PEP binding to the allosteric site or by ATP binding to the enzyme.

Site-Directed Mutagenesis of Phosphoenolpyruvate Carboxylase from E. coli: The Role of His579 in the Catalytic and Regulatory Functions1

Phosphoenolpyruvate carboxylases (PEPC) [EC 4.1.1.31] from a wide variety of organisms contain a unique and highly conserved sequence, 578FHGRGGSIGRGGAP591 (coordinates for the Escherichia coli enzyme), which has been presumed to participate in the binding of phosphoenolpyruvate (PEP). Since previous chemical modification studies had suggested the importance of His for the catalytic activity, the role of His579 was investigated by constructing variants of E. coli PEPC, in which this residue was substituted to Asn (H579N) or Pro (H579P). Kinetic studies with partially purified enzymes revealed the following: (1) The apparent maximal velocities in the presence of acetyl-CoA (CoASAc, one of the allosteric activators) were 29% and 5.4% of the wild-type enzyme, for H579N and H579P, respectively. (2) The half-saturation concentration for PEP was increased about 40-fold by the substitutions, while those for another substrate (HCO3-) and the metal cofactor (Mg2+) were increased only 2- to 4-fold. (3) The half-saturation concentrations of four kinds of allosteric activators and of dioxane, an artificial activator, were also changed to various extents. Among them the most remarkable increase was observed for CoASAc (28-fold). (4) The concentration of an allosteric inhibitor, aspartate, required for 50% inhibition remained substantially unchanged. It was concluded that the imidazole group of His579 is not obligatory for the enzyme catalysis, but plays important roles in catalytic and regulatory functions.

Kinetic evidence of the existence of a regulatory phosphoenolpyruvate binding site in maize leaf phosphoenolpyruvate carboxylase

Phenylphosphate, a structural analog of phosphoenolpyruvate (PEP), was found to be an activator of phosphoenolpyruvate carboxylase (PEP carboxylase) purified from maize leaves. This finding suggested the presence in the enzyme of a regulatory site, to which PEP could bind. We carried out kinetic studies on this enzyme using controlled concentrations of free PEP and of Mg-PEP complex and developed a theoretical kinetic model of the reaction. In summary, the main conclusions drawn from our results, and taken as assumptions of the model, were the following: (i) The affinity of the active site for the complex Mg-PEP is much higher than that for free PEP and Mg 2+ ions, and therefore it can be considered that the preferential substrate of the PEP-catalyzed reaction is Mg-PEP. (ii) The enzyme has a regulatory site specific for free PEP, to which Mg 2+ ions can not bind, (iii) The binding of free PEP, or an analog molecule, to this regulatory site yields a modified enzyme that has much lower apparent K m values and apparent V max values than the unmodified enzyme. So, free PEP behaves as an excellent activator of the reaction at subsaturating substrate concentrations, and as an inhibitor at saturating substrate concentrations. These findings may have important physiological implications on the regulation of the PEP carboxylase in vivo activity and, consequently, of the C 4 pathway, since increased reaction rates would be obtained when the concentration of PEP rises, even at limiting Mg 2+ concentrations.