Mutagenesis of putative catalytic and regulatory residues of Streptomyces chromofuscus phospholipase D differentially modifies phosphatase and phosphodiesterase activities

Phospholipase D from Streptomyces chromofuscus (sc-PLD) is a member of the diverse family of metallo-phosphodiesterase/phosphatase enzymes that also includes purple acid phosphatases, protein phosphatases, and nucleotide phosphodiesterases. Whereas iron is an essential cofactor for scPLD activity, Mn2+ is also found in the enzyme. A third metal ion, Ca2+, has been shown to enhance scPLD catalytic activity although it is not an essential cofactor. Sequence alignment of scPLD with known phosphodiesterases and phosphatases requiring metal ions suggested that His-212, Glu-213, and Asp-389 could be involved in Mn2+ binding. H212A, E213A, and D389A were prepared to test this hypothesis. These three mutant enzymes and wild type scPLD show similar metal content but considerably different catalytic properties, suggesting different roles for each residue. His-212 appears involved in binding the phosphate group of substrates, whereas Glu-213 acts as a ligand for Ca2+. D389A showed a greatly reduced phosphodiesterase activity but almost unaltered ability to hydrolyze the phosphate group in p-nitrophenyl phosphate suggesting it had a critical role in aligning groups at the active site to control phosphodiesterase versus phosphatase activities. We propose a model for substrate and cofactor binding to the catalytic site of scPLD based on these results and on sequence alignment to purple acid phosphatases of known structure.     

Mechanism of hydrolysis of phosphate esters by the dimetal center of 5'-nucleotidase based on crystal structures

5'-Nucleotidase belongs to a large superfamily of distantly related dinuclear metallophosphatases including the Ser/Thr protein phosphatases and purple acid phosphatases. The protein undergoes a 96 degrees domain rotation between an open (inactive) and a closed (active) enzyme form. Complex structures of the closed form with the products adenosine and phosphate, and with the substrate analogue inhibitor alpha,beta-methylene ADP, have been determined at 2.1 A and 1.85 A resolution, respectively. In addition, a complex of the open form of 5'-nucleotidase with ATP was analyzed at a resolution of 1.7 A. These structures show that the adenosine group binds to a specific binding pocket of the C-terminal domain. The adenine ring is stacked between Phe429 and Phe498. The N-terminal domain provides the ligands to the dimetal cluster and the conserved His117, which together form the catalytic core structure. However, the three C-terminal arginine residues 375, 379 and 410, which are involved in substrate binding, may also play a role in transition-state stabilization. The beta-phosphate group of the inhibitor is terminally coordinated to the site 2 metal ion. The site 1 metal ion coordinates a water molecule which is in an ideal position for a nucleophilic attack on the phosphorus atom, assuming an in-line mechanism of phosphoryl transfer. Another water molecule bridges the two metal ions.     

Metalloenzymes and signal transduction: the protein serine/threonine phosphatases,a novel class of binuclear metal-containing enzymes

The serine/threonine protein phosphatases are important regulatory enzymes involved in signal transduction pathways in eukaryotic organisms. These enzymes include protein phosphatases 1, 2A, and 2B (also known as calcineurin). Recent structural data have indicated that the serine/threonine protein phosphatases are novel metalloenzymes containing a dinuclear metal ion cofactor at the active site. The dinuclear metal site is situated in a unique protein fold, a β-α-β-α-β motif which provides the majority of ligands to the metal ions. A similar fold is also seen in plant purple acid phosphatases, which also contain a dinuclear iron–zinc cofactor. In these enzymes, the two metal ions are bridged by a solvent molecule and a carboxylate group from an aspartic acid residue, juxtaposing the two metal ions to within 3.0–4.0?Å of each other. A similar motif has been identified in a number of other enzymes which exhibit phosphoesterase activity, implicating several of them as metalloenzymes which contain dinuclear metal ion cofactors.     

Analysis of the mechanism of the Serratia nuclease using site-directed mutagenesis.

Based on crystal structure analysis of the Serratia nuclease and a sequence alignment of six related nucleases, conserved amino acid residues that are located in proximity to the previously identified catalytic site residue His89 were selected for a mutagenesis study. Five out of 12 amino acid residues analyzed turned out to be of particular importance for the catalytic activity of the enzyme: Arg57, Arg87, His89, Asn119 and Glu127. Their replacement by alanine, for example, resulted in mutant proteins of very low activity, < 1% of the activity of the wild-type enzyme. Steady-state kinetic analysis of the mutant proteins demonstrates that some of these mutants are predominantly affected in their kcat, others in their Km. These results and the determination of the pH and metal ion dependence of selected mutant proteins were used for a tentative assignment for the function of these amino acid residues in the mechanism of phosphodiester bond cleavage by the Serratia nuclease.     

Heterologous expression and catalytic properties of the C-terminal domain of starfish cdc25 dual-specificity phosphatase, a cell cycle regulator

The 3'-terminal region of starfish Asterina pectinifera cdc25 cDNA encoding the C-terminal catalytic domain was overexpressed in Escherichia coli. The C-terminal domain consisted of 226 amino acid residues containing the signature motif HCxxxxxR, a motif highly conserved among protein tyrosine and dual-specificity phosphatases, and showed phosphatase activity toward p-nitrophenyl phosphate. The enzyme activity was strongly inhibited by SH inhibitors. Mutational studies indicated that the cysteine and arginine residues in the conserved motif are essential for activity, but the histidine residue is not. These results suggest that the enzyme catalyzes the reaction through a two-step mechanism involving a phosphocysteine intermediate like in the cases of other protein tyrosine and dual-specificity phosphatases. The C-terminal domain of Cdc25 activated the histone H1 kinase activity of the purified, inactive form of Cdc2.cyclin B complex (preMPF) from extracts of immature starfish oocytes. Synthetic diphosphorylated di- to nonadecapeptides mimicking amino acid sequences around the dephosphorylation site of Cdc2 still retained substrate activity. Phosphotyrosine and phosphothreonine underwent dephosphorylation in this order. This is the reverse order to that reported for the in vivo and in vitro dephosphorylation of preMPF. Monophosphopeptides having the same sequence served as much poorer substrates. As judged from the results with synthetic phosphopeptides, the presence of two phosphorylated residues was important for specific recognition of substrates by the Cdc25 phosphatase.     

Crystal structures of Bacillus alkaline phytase in complex with divalent metal ions and inositol hexasulfate

Alkaline phytases from Bacillus species, which hydrolyze phytate to less phosphorylated myo-inositols and inorganic phosphate, have great potential as additives to animal feed. The thermostability and neutral optimum pH of Bacillus phytase are attributed largely to the presence of calcium ions. Nonetheless, no report has demonstrated directly how the metal ions coordinate phytase and its substrate to facilitate the catalytic reaction. In this study, the interactions between a phytate analog (myo-inositol hexasulfate) and divalent metal ions in Bacillus subtilis phytase were revealed by the crystal structure at 1.25 Å resolution. We found all, except the first, sulfates on the substrate analog have direct or indirect interactions with amino acid residues in the enzyme active site. The structures also unraveled two active site-associated metal ions that were not explored in earlier studies. Significantly, one metal ion could be crucial to substrate binding. In addition, binding of the fourth sulfate of the substrate analog to the active site appears to be stronger than that of the others. These results indicate that alkaline phytase starts by cleaving the fourth phosphate, instead of the third or the sixth that were proposed earlier. Our high-resolution, structural representation of Bacillus phytase in complex with a substrate analog and divalent metal ions provides new insight into the catalytic mechanism of alkaline phytases in general.     

Identification of an essential acidic residue in Cdc25 protein phosphatase and a general three-dimensional model for a core region in protein phosphatases.

The reaction mechanism of protein tyrosine phosphatases (PTPases) and dual-specificity protein phosphatases is thought to involve a catalytic aspartic acid residue. This residue was recently identified by site-directed mutagenesis in Yersinia PTPase, VHR protein phosphatase, and bovine low molecular weight protein phosphatase. Herein we identify aspartic acid 383 as a potential candidate for the catalytic acid in human Cdc25A protein phosphatase, using sequence alignment, structural information, and site-directed mutagenesis. The D383N mutant enzyme exhibits a 150-fold reduction in kcat, with Kw only slightly changed. Analysis of sequence homologies between several members of the Cdc25 family and deletion mutagenesis substantiate the concept of a two-domain structure for Cdc25, with a regulatory N-terminal and a catalytic C-terminal domain. Based on the alignment of catalytic residues and secondary structure elements, we present a three-dimensional model for the core region of Cdc25. By comparing this three-dimensional model to the crystal structures of PTP1b, Yersinia PTPase, and bovine low molecular weight PTPase, which share only very limited amino acid sequence similarities, we identify a general architecture of the protein phosphatase core region, encompassing the active site loop motif HCXXXXXR and the catalytic aspartic acid residue.     

Picomolar concentrations of free zinc(II) ions regulate receptor protein-tyrosine phosphatase β activity

As key enzymes in the regulation of biological phosphorylations, protein-tyrosine phosphatases are central to the control of cellular signaling and metabolism. Zinc(II) ions are known to inhibit these enzymes, but the physiological significance of this inhibition has remained elusive. Employing metal buffering for strict metal control and performing a kinetic analysis, we now demonstrate that zinc(II) ions are reversible inhibitors of the cytoplasmic catalytic domain of the receptor protein-tyrosine phosphatase β (also known as vascular endothelial protein-tyrosine phosphatase). The K(i)((Zn)) value is 21 ± 7 pm, 6 orders of magnitude lower than zinc inhibition reported previously for this enzyme. It exceeds the affinity of the most potent synthetic small molecule inhibitors targeting these enzymes. Inhibition is in the range of cellular zinc(II) ion concentrations, suggesting that zinc regulates this enzyme, which is involved in vascular physiology and angiogenesis. Thus, for some enzymes that are not recognized as zinc metalloenzymes, zinc binding inhibits rather than activates as in classical zinc enzymes. Activation then requires removal of the inhibitory zinc.     

Crystal Structure of the Bacillus subtilis Phosphodiesterase PhoD Reveals an Iron and Calcium-containing Active Site

The PhoD family of extra-cytoplasmic phosphodiesterases are among the most commonly occurring bacterial phosphatases. The exemplars for this family are the PhoD protein of Bacillus subtilis and the phospholipase D of Streptomyces chromofuscus. We present the crystal structure of B. subtilis PhoD. PhoD is most closely related to purple acid phosphatases (PAPs) with both types of enzyme containing a tyrosinate-ligated Fe³⁺ ion. However, the PhoD active site diverges from that found in PAPs and uses two Ca²⁺ ions instead of the single extra Fe²⁺, Mn²⁺, or Zn²⁺ ion present in PAPs. The PhoD crystals contain a phosphate molecule that coordinates all three active site metal ions and that is proposed to represent a product complex. A C-terminal helix lies over the active site and controls access to the catalytic center. The structure of PhoD defines a new phosphatase active site architecture based on Fe³⁺ and Ca²⁺ ions.     

Evidence for a catalytic Mg2+ ion and effect of phosphate on the activity of Escherichia coli phosphofructokinase-2: regulatory properties of a ribokinase family member

Phosphofructokinase-2 (Pfk-2) from Escherichia coli belongs to the ribokinase family of sugar kinases. One of the signatures observed in amino acid sequences from the ribokinase familiy members is the NXXE motif, which locates at the active site in the ribokinase fold. It has been suggested that the effect of Mg2+ and phosphate ions on enzymatic activity, observed in several adenosine kinases and ribokinases, would be a widespread feature in the ribokinase family, with the conserved amino acid residues in the NXXE motif playing a role in the binding of these ions at the active site [Maj, M. C., et al. (2002) Biochemistry 41, 4059-4069]. In this work we study the effect of Mg2+ and phosphate ions on Pfk-2 activity and the involvement of residue E190 from the NXXE motif in this behavior. The kinetic data are in agreement with the requirement of a Mg2+ ion, besides the one present in the metal-nucleotide complex, for catalysis in the wild-type enzyme. Since the response to free Mg2+ concentration is greatly affected in the E190Q mutant, we conclude that this residue is required for the proper binding of the catalytic Mg2+ ion at the active site. The E190Q mutant presents a 50-fold decrease in the kcat value and a 15-fold increment in the apparent Km for MgATP(2-). Inorganic phosphate, typically considered an activator of adenosine kinases, ribokinases, and phosphofructokinases (nonhomologous to Pfk-2) acted as an inhibitor of wild-type and E190Q mutant Pfk-2. We suggest that phosphate can bind to the allosteric site of Pfk-2, producing an inhibition pattern qualitatively similar to MgATP(2-), which can be reversed to some extent by increasing the concentration of fructose-6-P. Given that the E190Q mutant presents alterations in the inhibition by MgATP(2-) and phosphate, we conclude that the E190 residue has a role not only in catalysis but also in allosteric regulation.     

The presence of essential histidine residues in manganese(III)-containing acid phosphatase from sweet potato

Chemical modification studies of manganese(III)-containing acid phosphatase [EC 3.1.3.2] were carried out to investigate the contributions of specific amino-acid side-chains to the catalytic activity. Incubation of the enzyme with N-ethylmaleimide at pH 7.0 caused a significant loss of the enzyme activity. The inactivation followed pseudo-first-order kinetics. Double log plots of pseudo-first-order rate constant vs. concentration gave a straight line with a slope of 1.02, suggesting that the reaction of one molecule of reagent per active site is associated with activity loss. The enzyme was protected from inactivation by the presence of molybdate or phosphate ions. Amino acid analyses of the N-ethylmaleimide-modified enzyme showed that the 96%-inactivated enzyme had lost about one histidine and one-half lysine residue per enzyme subunit without any significant decrease in other amino acids, and also demonstrated that loss of catalytic activity occurred in parallel with the loss of histidine residue rather than that of lysine residue. Molybdate ions also protected the enzyme against modification of the histidine residue. The enzyme was inactivated by photooxidation mediated by methylene blue according to pseudo-first-order kinetics. The pH profile of the inactivation rates of the enzyme showed that an amino acid residue having a pKa value of approximately 7.2 was involved in the inactivation. These studies indicate that at least one histidine residue per enzyme subunit participates in the catalytic function of Mn(III)-acid phosphatase.     

3-D Model of the bee venom acid phosphatase: Insights into allergenicity

The acid phosphatase Api m 3 is the major allergen of the honeybee venom. Except for the amino acid sequence, no other structural information for the enzyme is available. We applied homology modeling to assign the three-dimensional structure of Api m 3. The structure of the homodimeric human prostatic acid phosphatase was used to model the Api m 3 tertiary structure. IgE epitopes and antigenic sites were predicted using programs based on the structure of known epitopes and analysis of the 3-D model. The model of Api m 3 revealed an active site similar to those of the histidine—type acid phosphatases with conservation of the catalytically important residues. The observed substitutions in the phosphate ion binding site suggest differences in the substrate specificity in comparison to other acid phosphatases. The analysis of the Api m 3 three-dimensional model revealed a very likely mechanism of enzyme action.     

Prediction of a ligand-induced conformational change in the catalytic core of Cdc25A

The cell cycle control phosphatases Cdc25 are dual specificity phosphatases that dephosphorylate both phosphothreonine and phosphotyrosine residues on their substrate proteins. The determination of the apo-protein structure of Cdc25A revealed that this enzyme has a completely different fold compared to all other phosphatases crystallised to date. The conformation of the active site residues does not seem very suitable for catalysis in this unliganded structure. We have studied some structural features of the Cdc25A apo-structure and a modelled Cdc25A-ligand complex by molecular dynamics simulations. The simulations predict a conformational change in the peptide backbone of the complex, which is not observed in the apo-structure. This ligand-induced conformational change yields a structure that is similar to other protein tyrosine phosphatase-ligand complexes that have been crystallised. The change in conformation takes place in the position between a serine and a glutamic acid residue in the phosphate binding loop. We suggest that this type of conformational change is an important molecular switch in the catalytic process.     

Distribution and characterization of mineral-binding phosphoprotein particles in Bivalvia

Representative species of four bivalve subclasses were examined for the presence of mineral-binding phosphoprotein particles in the physiological fluids. The particles were identified in Heterodont bivalves only, and particles from nine different Heterodont species were isolated and characterized. All phosphoprotein particles are internally cross-linked via histidinoalanine residues. In all species over 80% of the amino acid residues in the particles are aspartic acid, phosphoserine (and/or phosphothreonine), and histidine. These amino acids are probably the only residues directly related to mineral ion binding, since all phosphoprotein particles bind mineral irrespective of the minor amino acid content, which is species dependent. In their native state the phosphoprotein particles contain large amounts of calcium, magnesium, and inorganic phosphate ions (up to 45 metal ions and 8 phosphate ions per 100 amino acid residues) and trace amounts of transition elements. Evidence for the presence of calcium phosphate complexes in the native phosphoprotein particles was obtained by observing a concomitant increase in the inorganic phosphate and calcium ion content of the particles with pH in vivo.     

Mutation of active site residues Asn67 to Ile, Gln92 to Val and Leu204 to Ser in human carbonic anhydrase II: influences on the catalytic activity and affinity for inhibitors

Site-directed mutagenesis has been used to change three amino acid residues involved in the binding of inhibitors (Asn67Ile; Gln92Val and Leu204Ser) within the active site of human carbonic anhydrase (CA, EC 4.2.1.1) II (hCA II). Residues 67, 92 and 204 were changed from hydrophobic to hydrophilic ones, and vice versa. The Asn67Ile and Leu204Ser mutants showed similar k(cat)/K(M) values compared to the wild type (wt) enzyme, whereas the Gln92Val mutant was around 30% less active as a catalyst for CO(2) hydration to bicarbonate compared to the wt protein. Affinity for sulfonamides/sulfamates was decreased in all three mutants compared to wt hCA II. The effect was stronger for the Asn67Ile mutant (the closest residue to the zinc ion), followed by the Gln92Val mutant (residue situated in the middle of the active site) and weakest for the Leu204Ser mutant, an amino acid situated far away from the catalytic metal ion, at the entrance of the cavity. This study shows that small perturbations within the active site architecture have influences on the catalytic efficiency but dramatically change affinity for inhibitors among the CA enzymes, especially when the mutated amino acid residues are nearby the catalytic metal ion.     

Crystal structure of methyl parathion hydrolase from Pseudomonas sp. WBC-3

Methyl parathion hydrolase (MPH, E.C.3.1.8.1), isolated from the soil-dwelling bacterium Pseudomonas sp. WBC-3, is a Zn(II)-containing enzyme that catalyzes the degradation of the organophosphate pesticide methyl parathion. We have determined the structure of MPH from Pseudomonas sp. WBC-3 to 2.4 angstroms resolution. The enzyme is dimeric and each subunit contains a mixed hybrid binuclear zinc center, in which one of the zinc ions is replaced by cadmium. In both subunits, the more solvent-exposed beta-metal ion is substituted for Cd2+ due to high cadmium concentration in the crystallization condition. Both ions are surrounded by ligands in an octahedral arrangement. The ions are separated by 3.5 angstroms and are coordinated by the amino acid residues His147, His149, Asp151, His152, His234 and His302 and a water molecule. Asp255 and a water molecule serve to bridge the zinc ions together. MPH is homologous with other metallo-beta-lactamases but does not show any similarity to phosphotriesterase that can also catalyze the degradation of methyl parathion with lower rate, despite the lack of sequence homology. Trp179, Phe196 and Phe119 form an aromatic cluster at the entrance of the catalytic center. Replacement of these three amino acids by alanine resulted in a significant increase of K(m) and loss of catalytic activity, indicating that the aromatic cluster has an important role to facilitate affinity of enzyme to the methyl parathion substrates.     

The YRD motif is a major determinant of substrate and inhibitor specificity in T-cell protein-tyrosine phosphatase

We have studied T-cell protein-tyrosine phosphatase (TCPTP) as a model phosphatase in an attempt to unravel amino acid residues that may influence the design of specific inhibitors. Residues 48--50, termed the YRD motif, a region that is found in protein-tyrosine phosphatases, but absent in dual-specificity phosphatases was targeted. YRD derivatives of TCPTP were characterized by steady-state kinetics and by inhibition studies with BzN-EJJ-amide, a potent inhibitor of TCPTP. Substitution of Asp(50) to alanine or Arg(49) to lysine, methionine, or alanine significantly affected substrate hydrolysis and led to a substantial decrease in affinity for BzN-EJJ-amide. The influence of residue 49 on substrate/inhibitor selectivity was further investigated by comparing subsite amino acid preferences of TCPTP and its R49K derivative by affinity selection coupled with mass spectrometry. The greatest effect on selectivity was observed on the residue that precedes the phosphorylated tyrosine. Unlike wild-type TCPTP, the R49K derivative preferred tyrosine to aspartic or glutamic acid. BzN-EJJ-amide which retains the preferred specificity requirements of TCPTP and PTP1B was equipotent on both enzymes but greater than 30-fold selective over other phosphatases. These results suggest that Arg(49) and Asp(50) may be targeted for the design of potent and selective inhibitors of TCPTP and PTP1B.     

The active site of 6-phosphogluconate dehydrogenase: A phosphate binding site and its surroundings

Tetrahedral anions bind to a phosphate binding site of 6-phosphogluconate dehydrogenase from Candida utilis, inhibit the enzyme competitively with the 6-phosphogluconate, decrease the reactivity of the SH groups, and mimic the protective effect of 6-phosphogluconate against some inactivating agents. The reaction of the enzyme with butanedione results in the inactivation of the enzyme associated with the modification of a single arginine residue per subunit. This arginine residue may be involved in the binding of the phosphate to the enzyme. Inactivation of the enzyme, upon reaction with permanganate, appears to be due to the oxidation to cysteic acid of a single cysteine residue per enzyme subunit. The reaction of the enzyme with either periodate or hexachloroplatinate causes the loss of the catalytic activity. This inactivation, due to an affinity labeling, is correlated with the oxidation of two SH groups per subunit to an S-S bridge. Photoinactivation of the enzyme by pyridoxal 5′-phosphate is also restricted to the active site of the enzyme. The lysine and the histidine residues involved in this photoinactivation should thus be in the vicinity of the phosphate binding site.     

Structure-based analysis of the metal-dependent mechanism of H-N-H endonucleases

Controversy surrounds the metal-dependent mechanism of H-N-H endonucleases, enzymes involved in a variety of biological functions, including intron homing and DNA repair. To address this issue we determined the crystal structures for complexes of the H-N-H motif containing bacterial toxin colicin E9 with Zn(2+), Zn(2+).DNA, and Mg(2+).DNA. The structures show that the rigid V-shaped architecture of the active site does not undergo any major conformational changes on binding to the minor groove of DNA and that the same interactions are made to the nucleic acid regardless of which metal ion is bound to the enzyme. The scissile phosphate contacts the single metal ion of the motif through distortion of the DNA brought about by the insertion of the Arg-96-Glu-100 salt bridge into the minor groove and a network of contacts to the DNA phosphate backbone that straddle the metal site. The Mg(2+)-bound structure reveals an unusual coordination scheme involving two H-N-H histidine residues, His-102 and His-127. The mechanism of DNA cleavage is likely related to that of other single metal ion-dependent endonucleases, such as I-PpoI and Vvn, although in these enzymes the single alkaline earth metal ion is coordinated by oxygen-bearing amino acids. The structures also provide a rationale as to why H-N-H endonucleases are inactive in the presence of Zn(2+) but active with other transition metal ions such as Ni(2+). This is because of coordination of the Zn(2+) ion through a third histidine, His-131. "Active" transition metal ions are those that bind more weakly to the H-N-H motif because of the disengagement of His-131, which we suggest allows a water molecule to complete the catalytic cycle.     

Amino Acid Residues Involved in the Functional Integrity of Escherichia coli Methionine Aminopeptidase

Amino acid residues in the metal-binding and putative substrate-binding sites of Escherichia coli methionine aminopeptidase (MAP) were mutated, and their effects on the function of the enzyme were investigated. Substitution of any amino acid residue at the metal-binding site resulted in complete loss of the two cobalt ions bound to the protein and diminished the enzyme activity. However, only Cys70 and Trp221 at the putative substrate-binding site are involved in the catalytic activity of MAP. Changing either of them caused partial loss of enzyme activity, while mutations at both positions abolished MAP function. Both residues are found to be conserved in type I but not type II MAPs.