Purification and characterization of phosphomannomutase/phosphoglucomutase from Pseudomonas aeruginosa involved in biosynthesis of both alginate and lipopolysaccharide.

The algC gene from Pseudomonas aeruginosa has been shown to encode phosphomannomutase (PMM), an essential enzyme for biosynthesis of alginate and lipopolysaccharide (LPS). This gene was overexpressed under control of the tac promoter, and the enzyme was purified and its substrate specificity and metal ion effects were characterized. The enzyme was determined to be a monomer with a molecular mass of 50 kDa. The enzyme catalyzed the interconversion of mannose 1-phosphate (M1P) and mannose 6-phosphate, as well as that of glucose 1-phosphate (G1P) and glucose 6-phosphate. The apparent Km values for M1P and G1P were 17 and 22 microM, respectively. On the basis of Kcat/Km ratio, the catalytic efficiency for G1P was about twofold higher than that for M1P. PMM also catalyzed the conversion of ribose 1-phosphate and 2-deoxyglucose 6-phosphate to their corresponding isomers, although activities were much lower. Purified PMM/phosphoglucomutase (PGM) required Mg2+ for maximum activity; Mn2+ was the only other divalent metal that showed some activation. The presence of other divalent metals in addition to Mg2+ in the reaction inhibited the enzymatic activity. PMM and PGM activities could not be detected in nonmucoid algC mutant strain 8858 and in LPS-rough algC mutant strain AK1012, while they were present in the wild-type strains as well as in algC-complemented mutant strains. This evidence suggests that AlgC functions as PMM and PGM in vivo, converting phosphomannose and phosphoglucose in the biosynthesis of both alginate and LPS.     

Functional analysis of active site residues of the fosfomycin resistance enzyme FosA from Pseudomonas aeruginosa

The metalloglutathione transferase FosA catalyzes the conjugation of glutathione to carbon-1 of the antibiotic fosfomycin, rendering it ineffective as an antibacterial drug. Codon randomization and selection for the ability of resulting clones to confer fosfomycin resistance to Escherichia coli were used to identify residues critical for FosA function. Of the 24 codons chosen for randomization, 16 were found to be essential because only the wild type amino acid was selected. These included ligands to the Mn(2+) and the K(+), residues that furnish hydrogen bonds to fosfomycin, and residues located in a putative glutathione/fosfomycin-binding site. The remaining eight positions randomized were tolerant to substitutions. Site-directed mutagenesis of some of the essential and tolerant amino acids to alanine was performed, and the activity of the purified proteins was determined. Mutation of the residues that are within hydrogen bonding distance to the oxirane or phosphonate oxygens of fosfomycin resulted in variants with very low or no activity. Mutation of Ser(94), which bridges one of the phosphonate oxygens with a potassium ion, resulted in insoluble protein. The Y39A mutation in the putative glutathione-binding site resulted in a 4-fold increase in the apparent K(m) for glutathione. Only two of the amino acids in the substrate-binding site are conserved in the related fosfomycin resistance proteins FosB and FosX, whereas no amino acids in the putative glutathione-binding site are conserved.     

Role of arginine residues in the active site of the membrane-bound lytic transglycosylase B from Pseudomonas aeruginosa

Lytic transglycosylases cleave the beta-(1-->4)-glycosidic bond in the bacterial cell wall heteropolymer peptidoglycan between the N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc) residues with the concomitant formation of a 1,6-anhydromuramoyl residue. On the basis of both sequence alignments with and structural considerations of soluble lytic transglycosylase Slt35 from Escherichia coli, four residues were predicted to be involved in substrate binding at the -1 subsite in the soluble derivative of Pseudomonas aeruginosa membrane-bound lytic transglycosylase MltB. These residues were targeted for site-specific replacement, and the effect on substrate binding and catalysis was determined. The residues Arg187 and Arg188, believed to be involved in binding the stem peptide on MurNAc, were shown to play an important role in substrate binding, as evidenced by peptidoglycan affinity assays and SUPREX analysis using MurNAc-dipeptide as ligand. The Michaelis-Menten parameters were determined for the respective mutants using insoluble peptidoglycan as substrate. In addition to affecting the steady-state binding of ligand to enzyme, as indicated by increases in K(M) values, significant decreases in k(cat) values suggested that replacement of either Arg187 and Arg188 with alanine perturbed the stabilization of both the transition state(s) and reaction intermediate. Thus, it appears that Arg187 and Arg188 are vital for proper orientation of the substrate in the active site, and furthermore this supports the proposed role of the stem peptide at binding subsite -2 in catalysis. Replacement of Gln100, a residue that would appear to interact with the N-acetyl group on MurNAc, did not show any changes in substrate affinity or activity.     

Roles of active site aromatic residues in catalysis by ketosteroid isomerase from Pseudomonas putida biotype B.

The aromatic residues Phe-54, Phe-82, and Trp-116 in the hydrophobic substrate-binding pocket of Delta(5)-3-ketosteroid isomerase from Pseudomonas putida biotype B have been characterized in their roles in steroid binding and catalysis. Kinetic and equilibrium binding analyses were carried out for the mutant enzymes with the substitutions Phe-54 --> Ala or Leu, Phe-82 --> Ala or Leu, and Trp-116 --> Ala, Phe, or Tyr. The removal of their bulky, aromatic side chains at any of these three positions results in reduced k(cat), particularly when Phe-82 or Trp-116 is replaced by Ala. The results are consistent with the binding interactions of the aromatic residues with the bound steroid contributing to catalysis. All the mutations except the F82A mutation increase K(m); the F82A mutation decreases K(m) by ca. 3-fold, suggesting a possibility that the phenyl ring at position 82 might be unfavorable for substrate binding. The K(D) values for d-equilenin, an intermediate analogue, suggest that a space-filling hydrophobic side chain at position 54, a phenyl ring at position 82, and a nonpolar aromatic or small side chain at position 116 might be favorable for binding the reaction intermediate. In contrast to the increased K(D) for equilenin, the enzymes with any substitutions at positions 54 and 116 display a decreased K(D) for 19-nortestosterone, a product analogue, indicating that Phe-54 and Trp-116 might be unfavorable for product binding. The crystal structure of F82A determined to 2.1-A resolution reveals that Phe-82 is important for maintaining the active site geometry. Taken together, our results demonstrate that Phe-54, Phe-82, and Trp-116 contribute differentially to the stabilization of steroid species including substrate, intermediate, and product.     

Mapping the enzymatic active site of Pseudomonas aeruginosa exotoxin A

Pseudomonas aeruginosa exotoxin A is representative of a class of enzymes, the monoADP-ribosyl, which catalyze the covalent transfer of an ADP-ribose moiety of NAD⁺ to a target substrate. Availability of the three-dimensional structure of exotoxin A provides the opportunity for mapping substrate binding sites and suggesting which amino acid residues may be involved in catalysis. Data from several sources have been combined to develop a proposal for the NAD⁺ binding site of exotoxin A: the binding of NAD⁺ fragments adenosine, AMP, and ADP have been delineated crystallographically to 6.0, 6.0, and 2.7 Å, respectively; significant sequence homology spanning 60 residues has been found between exotoxin A and diphtheria toxin, which has the identical enzymatic activity; iodination of exotoxin A, under conditions in which only tyrosine 481 is iodinated in the enzymatic domain, abolishes ADP-ribosyl transferase activity.     

Roles of active site and novel K+ ion-binding site residues in human mitochondrial branched-chain alpha-ketoacid decarboxylase/dehydrogenase

The human mitochondrial branched-chain alpha-ketoacid decarboxylase/dehydrogenase (BCKD) is a heterotetrameric (alpha(2)beta(2)) thiamine diphosphate (TDP)-dependent enzyme. The recently solved human BCKD structure at 2.7 A showed that the two TDP-binding pockets are located at the interfaces between alpha and beta' subunits and between alpha' and beta subunits. In the present study, we show that the E76A-beta' mutation results in complete inactivation of BCKD. The result supports the catalytic role of the invariant Glu-76-beta' residue in increasing basicity of the N-4' amino group during the proton abstraction from the C-2 atom on the thiazolium ring. A substitution of His-146-beta' with Ala also renders the enzyme completely inactive. The data are consistent with binding of the alpha-ketoacid substrate by this residue based on the Pseudomonas BCKD structure. Alterations in Asn-222-alpha, Tyr-224-alpha, or Glu-193-alpha, which coordinates to the Mg(2+) ion, result in an inactive enzyme (E193A-alpha) or a mutant BCKD with markedly higher K(m) for TDP and a reduced level of the bound cofactor (Y224A-alpha and N222S-alpha). Arg-114-alpha, Arg-220-alpha, and His-291-alpha interact with TDP by directly binding to phosphate oxygens of the cofactor. We show that natural mutations of these residues in maple syrup urine disease (MSUD) patients (R114W-alpha and R220W-alpha) or site-directed mutagenesis (H291A-alpha) also result in an inactive or partially active enzyme, respectively. Another MSUD mutation (T166M-alpha), which affects one of the residues that coordinate to the K(+) ion on the alpha subunit, also causes inactivation of the enzyme and an attenuated ability to bind TDP. In addition, fluorescence measurements establish that Trp-136-beta in human BCKD is the residue quenched by TDP binding. Thus, our results define the functional roles of key amino acid residues in human BCKD and provide a structural basis for MSUD.     

Identification of the active site residues of Pseudomonas aeruginosa protease IV. Importance of enzyme activity in autoprocessing and activation

Protease IV is a lysine-specific endoprotease produced by Pseudomonas aeruginosa whose activity has been correlated with corneal virulence. Comparison of the protease IV amino acid sequence to other bacterial proteases suggested that amino acids His-72, Asp-122, and Ser-198 could form a catalytic triad that is critical for protease IV activity. To test this possibility, site-directed mutations by alanine substitution were introduced into six selected residues including the predicted triad and identical residues located close to the triad. Mutations at any of the amino acids of the predicted catalytic triad or Ser-197 caused a loss of enzymatic activity and absence of the mature form of protease IV. In contrast, mutations at His-116 or Ser-200 resulted in normal processing into the enzymatically active mature form. A purified proenzyme that accumulated in the His-72 mutant was shown in vitro to be susceptible to cleavage by protease IV purified from P. aeruginosa. Furthermore, similarities of protease IV to the lysine-specific endoprotease of Achromobacter lyticus suggested three possible disulfide bonds in protease IV. These results identify the catalytic triad of protease IV, demonstrate that autodigestion is essential for the processing of protease IV into a mature protease, and predict sites essential to enzyme conformation.     

The bifunctional active site of S-adenosylmethionine synthetase. Roles of the basic residues

S-adenosylmethionine (AdoMet) synthetase catalyzes a unique two-step enzymatic reaction leading to formation of the primary biological alkylating agent. The crystal structure of Escherichia coli AdoMet synthetase shows that the active site, which lies between two subunits, contains four lysines and one histidine as basic residues. In order to test the proposed charge and hydrogen bonding roles in catalytic function, each lysine has been changed to an uncharged methionine or alanine, and the histidine has been altered to asparagine. The resultant enzyme variants are all tetramers like the wild type enzyme; however, circular dichroism spectra show reductions in helix content for the K245*M and K269M mutants. (The asterisk denotes that the residue is in the second subunit.) Four mutants have k(cat) reductions of approximately 10(3)-10(4)-fold in AdoMet synthesis; however, the k(cat) of K165*M variant is only reduced 2-fold. In each mutant, there is a smaller catalytic impairment in the partial reaction of tripolyphosphate hydrolysis. The K165*A enzyme has a 100-fold greater k(cat) for tripolyphosphate hydrolysis than the wild type enzyme, but this mutant is not activated by AdoMet in contrast to the wild type enzyme. The properties of these mutants require reassessment of the catalytic roles of these residues.     

A fluorescence investigation of the active site of Pseudomonas aeruginosa exotoxin A.

Single tryptophan mutant proteins of a catalytically active domain III recombinant protein (PE24) from Pseudomonas aeruginosa exotoxin A were prepared by site-directed mutagenesis. The binding of the dinucleotide substrate, NAD+, to the PE24 active site was studied by exploiting intrinsic tryptophan fluorescence for the wild-type, single Trp, and tryptophan-deficient mutant proteins. Various approaches were used to study the substrate binding process, including dynamic quenching, CD spectroscopy, steady-state fluorescence emission analysis, NAD+-glycohydrolase activity, NAD+ binding analysis, protein denaturation experiments, fluorescence lifetime analysis, steady-state anisotropy measurement, stopped flow fluorescence spectroscopy, and quantum yield determination. It was found that the conservative replacement of tryptophan residues with phenylalanine had little or no effect on the folded stability and enzyme activity of the PE24 protein. Dynamic quenching experiments indicated that when bound to the active site of the enzyme, the NAD+ substrate protected Trp-558 from solvent to a large extent but had no effect on the degree of solvent exposure for tryptophans 417 and 466. Also, upon substrate binding, the anisotropy of the Trp-417(W466F/W558F) protein showed the largest increase, followed by Trp-466(W417F/W558F), and there was no effect on Trp-558(W417F/W466F). Furthermore, the intrinsic tryptophan fluorescence exhibited the highest degree of substrate-induced quenching for the wild-type protein, followed in decreasing order by Trp-417(W466F/W558F), Trp-558(W417F/W466F), and Trp-466(W417F/W558F). These data provide evidence for a structural rearrangement in the enzyme domain near Trp-417 invoked by the binding of the NAD+ substrate.     

Probing the active site of Pseudomonas aeruginosa porphobilinogen synthase using newly developed inhibitors

Porphobilinogen synthase catalyzes the first committed step of the tetrapyrrole biosynthesis pathway. In an aldol-like condensation, two molecules of 5-aminolevulinic acid (ALA) form the first pyrrole, porphobilinogen. Newly synthesized analogues of a reaction intermediate of porphobilinogen synthase have been employed in studying the active site and the catalytic mechanism of this early enzyme of tetrapyrrole biosynthesis. This study combines structural and kinetic evaluation of the inhibition potency of these inhibitors. In addition, one of the determined protein structures provides for the first time structural evidence of a magnesium ion in the active site. From these results, we can corroborate an earlier postulated enzymatic mechanism that starts with formation of a C-C bond, linking C3 of the A-side ALA to C4 of the P-side ALA through an aldole addition. The obtained data are discussed with respect to the current literature.     

Cloning, expression and characterization of a phosphoglucomutase/phosphomannomutase from sphingan-producing Sphingomonas sanxanigenens

Several strains of the genus Sphingomonas produce sphingans, extracellular polysaccharides used as thickeners, emulsifiers and gelling agents. The pgmG gene from Sphingomonas sanxanigenens, which encodes a bifunctional protein with phosphoglucomutase and phosphomannomutase activities, was cloned and sequenced. The predicted amino acid sequence of the PgmG protein possessed 460 amino acids and a calculated molecular mass of 49.8 kDa, and it was 80 % identical to PGM/PMM from S. elodea. We overexpressed pgmG in Escherichia coli, and the purified protein displayed a K _m of 0.2 mM and a V _max of 1.3 μmol min^?1 mg^?1 with glucose 1-phosphate as substrate. The catalytic efficiency (K _cat/K _m) of PgmG was about 15-fold higher for glucose 1-phosphate than for mannose 1-phosphate. Overexpression of pgmG in S. sanxanigenens resulted in a 17 ± 0.3 % increase in sphingan production to ~12.5 g l^?1.     

Roles of active site residues and the HUH motif of the F plasmid TraI relaxase

Bacterial conjugation, transfer of a single strand of a conjugative plasmid between bacteria, requires sequence-specific single-stranded DNA endonucleases called relaxases or nickases. Relaxases contain an HUH (His-hydrophobe-His) motif, part of a three-His cluster that binds a divalent cation required for the cleavage reaction. Crystal structures of the F plasmid TraI relaxase domain, with and without bound single-stranded DNA, revealed an extensive network of interactions involving HUH and other residues. Here we study the roles of these residues in TraI function. Whereas substitutions for the three His residues alter metal-binding properties of the protein, the same substitution at each position elicits different effects, indicating that the residues contribute asymmetrically to metal binding. Substitutions for a conserved Asp that interacts with one HUH His demonstrate that the Asp modulates metal affinity despite its distance from the metal. The bound metal enhances binding of ssDNA to the protein, consistent with a role for the metal in positioning the scissile phosphate for cleavage. Most substitutions tested caused significantly reduced in vitro cleavage activities and in vivo transfer efficiencies. In summary, the results suggest that the metal-binding His cluster in TraI is a finely tuned structure that achieves a sufficient affinity for metal while avoiding the unfavorable electrostatics that would result from placing an acidic residue near the scissile phosphate of the bound ssDNA.     

Cloning of the Pseudomonas glumae lipase gene and determination of the active site residues.

The lipA gene encoding the extracellular lipase produced by Pseudomonas glumae PG1 was cloned and characterized. A sequence analysis revealed an open reading frame of 358 codons encoding the mature lipase (319 amino acids) preceded by a rather long signal sequence of 39 amino acids. As a first step in structure-function analysis, we determined the Ser-Asp-His triad which makes up the catalytic site of this lipase. On the basis of primary sequence homology with other known Pseudomonas lipases, a number of putative active site residues located in conserved areas were found. To determine the residues actually involved in catalysis, we constructed a number of substitution mutants for conserved Ser, Asp, and His residues. These mutant lipases were produced by using P. glumae PG3, from which the wild-type lipase gene was deleted by gene replacement. By following this approach, we showed that Ser-87, Asp-241, and His-285 make up the catalytic triad of the P. glumae lipase. This knowledge, together with information on the catalytic mechanism and on the three-dimensional structure, should facilitate the selection of specific modifications for tailoring this lipase for specific industrial applications.     

Cloning of the Pseudomonas glumae lipase gene and determination of the active site residues.

The lipA gene encoding the extracellular lipase produced by Pseudomonas glumae PG1 was cloned and characterized. A sequence analysis revealed an open reading frame of 358 codons encoding the mature lipase (319 amino acids) preceded by a rather long signal sequence of 39 amino acids. As a first step in structure-function analysis, we determined the Ser-Asp-His triad which makes up the catalytic site of this lipase. On the basis of primary sequence homology with other known Pseudomonas lipases, a number of putative active site residues located in conserved areas were found. To determine the residues actually involved in catalysis, we constructed a number of substitution mutants for conserved Ser, Asp, and His residues. These mutant lipases were produced by using P. glumae PG3, from which the wild-type lipase gene was deleted by gene replacement. By following this approach, we showed that Ser-87, Asp-241, and His-285 make up the catalytic triad of the P. glumae lipase. This knowledge, together with information on the catalytic mechanism and on the three-dimensional structure, should facilitate the selection of specific modifications for tailoring this lipase for specific industrial applications.     

Essential residues in the chromate transporter ChrA of Pseudomonas aeruginosa

The chrA gene of Pseudomonas aeruginosa plasmid pUM505 encodes the hydrophobic protein ChrA, which confers resistance to chromate by the energy-dependent efflux of chromate ions. Chromate-sensitive mutants were isolated by in vivo random mutagenesis. Transport experiments with cell suspensions of selected mutants showed that 51CrO4(2-) extrusion was drastically lowered as compared to suspensions of the strain with the wild-type plasmid, confirming that the mutations affected a chromate efflux system. DNA sequence analysis showed that most point mutations affected amino acids clustered in the N-terminal half of ChrA, altering either cytoplasmic regions or transmembrane segments, and replaced residues moderately to highly conserved in ChrA homologs. PhoA and LacZ translational fusions were used to confirm the membrane topology at the N-terminal half of the ChrA protein.