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Ferrihydrite, an iron oxide hydroxide, is found in all kinds of environments, from hydrothermal hot springs to extraterrestrial materials. It has been shown that this material is nanoporous, and because of its high surface area, it has outstanding adsorption properties and in some cases catalysis properties. In this work we studied the adsorption properties of ferrihydrite with respect to amino acids. Samples of pure ferrihydrite were synthesised and exposed to solutions of amino acids including both proteinaceous and non-proteinaceous species. These experiments revealed important characteristics of this mineral as both an adsorbent of amino acids and a promoter of peptide bond formation.

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Enzymes MurD, MurE, MurF, folylpolyglutamate synthetase and cyanophycin synthetase, which belong to the Mur synthetase superfamily, possess an invariant lysine residue (K198 in the Escherichia coli MurD numbering). Crystallographic analysis of MurD and MurE has recently shown that this residue is present as a carbamate derivative, a modification presumably essential for Mg(2+) binding and acyl phosphate formation. In the present work, the importance of the carbamoylated residue was investigated in MurD, MurE and MurF by site-directed mutagenesis and chemical rescue experiments. Mutant proteins MurD K198A/F, MurE K224A and MurF K202A, which displayed low enzymatic activity, were rescued by incubation with short-chain carboxylic acids, but not amines. The best rescuing agent was acetate for MurD K198A, formate for K198F, and propionate for MurE K224A and MurF K202A. In the last of these, wild-type levels of activity were recovered. A complementarity between the volume of the residue replacing lysine and the length of the carbon chain of the acid was noted. These observations support a functional role for the carbamate in the three Mur synthetases. Experiments aimed at recovering an active enzyme by introducing an acidic residue in place of the invariant lysine residue were also undertaken. Mutant protein MurD K198E was weakly active and was rescued by formate, indicating the necessity of correct positioning of the acidic function with respect to the peptide backbone. Attempts at covalent rescue of mutant protein MurD K198C failed because of its lack of reactivity towards haloacids.

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Infection of the respiratory tract is a frequent cause of lung pathologies, morbidity, and death. When bacterial endotoxin [lipopolysaccharide (LPS)] reaches the alveolar spaces, it encounters the lipid-rich surfactant that covers the epithelium. Although binding of hydrophilic surfactant protein (SP) A and SP-D with LPS has been established, nothing has been reported to date on possible cross talks between LPS and hydrophobic SP-B and SP-C. We designed a new binding technique based on the incorporation of surfactant components to lipid vesicles and the separation of unbound from vesicle-bound LPS on a density gradient. We found that among the different hydrophobic components of mouse surfactant separated by gel filtration or reverse-phase HPLC, only SP-C exhibited the capacity to bind to a tritium-labeled LPS. The binding of LPS to vesicles containing SP-C was saturable, temperature dependent, related to the concentrations of SP-C and LPS, and inhibitable by distinct unlabeled LPSs. Unlike SP-A and SP-D, the binding of SP-C to LPS did not require calcium ions. This LPS binding capacity of SP-C may represent another antibacterial defense mechanism of the lung.

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A series of N-(5-phthalimidopentanoyl)-, N-[2-(2-ethoxy)acetyl]-, and N-(7-oxooctanoyl)-phosphono and phosphinoalanine derivatives has been synthesized and evaluated for inhibition of the D-glutamic acid-adding enzyme (MurD) of peptidoglycan biosynthesis.

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Expression of a 126-kDa protein in the plasmalemma (cytoplasmic membrane) from Synechococcus PCC 7942 is dependent on the nitrogen source. Polyclonal antibody raised against the NrtA protein reacted with the 126-kDa protein. Two peptide sequences from the 126-kDa protein were retrieved in NrtA. FPLC purification of plasmalemma solubilised in Triton X-100 gave a fraction consisting mainly of a 126-kDa component (72.6%), as shown by sedimentation velocity. Equilibrium sedimentation of the same fraction gave evidence of the existence of an oligomeric structure (Ka = 2 x 10(3) and 2.9 subunits). Thus, the 126-kDa protein is considered as a trimeric arrangement of the 45-kDa protein in the plasmalemma.

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UDP-N-acetylmuramoyl-l-alanine:d-glutamate (MurD) ligase catalyses the addition of d-glutamate to the nucleotide precursor UDP-N-acetylmuramoyl-l-alanine (UMA). The crystal structures of Escherichia coli in the substrate-free form and MurD complexed with UMA have been determined at 2.4 A and 1.88 A resolution, respectively. The MurD structure comprises three domains each of a topology reminiscent of nucleotide-binding folds. In the two structures the C-terminal domain undergoes a large rigid-body rotation away from the N-terminal and central domains. These two "open" structures were compared with the four published "closed" structures of MurD. In addition the comparison reveals which regions are affected by the binding of UMA, ATP and d-Glu. Also we compare and discuss two structurally characterized enzymes which belong to the same ligase superfamily: MurD and folylpolyglutamate synthetase (FGS). The analysis allows the identification of key residues involved in the reaction mechanism of FGS. The determination of the two "open" conformation structures represents a new step towards the complete elucidation of the enzymatic mechanism of the MurD ligase.

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The monomer units in the Escherichia coli and Staphylococcus aureus cell wall peptidoglycans differ in the nature of the third amino acid in the L-alanyl-gamma-D-glutamyl-X-D-alanyl-D-alanine side chain, where X is meso-diaminopimelic acid or L-lysine, respectively. The murE gene from S. aureus encoding the UDP-N-acetylmuramoyl-L-alanyl-D-glutamate: L-lysine ligase was identified and cloned into plasmid vectors. Induction of its overexpression in E. coli rapidly results in abnormal morphological changes and subsequent cell lysis. A reduction of 28% in the peptidoglycan content was observed in induced cells, and analysis of the peptidoglycan composition and structure showed that ca. 50% of the meso-diaminopimelic acid residues were replaced by L-lysine. Lysine was detected in both monomer and dimer fragments, but the acceptor units from the latter contained exclusively meso-diaminopimelic acid, suggesting that no transpeptidation could occur between the epsilon-amino group of L-lysine and the alpha-carboxyl group of D-alanine. The overall cross-linking of the macromolecule was only slightly decreased. Detection and analysis of meso-diaminopimelic acid- and L-lysine-containing peptidoglycan precursors confirmed the presence of L-lysine in precursors containing amino acids added after the reaction catalyzed by the MurE ligase and provided additional information about the specificity of the enzymes involved in these latter processes.

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To evaluate their role in the active site of the UDP-N-acetylmuramoyl-L-alanine:D-glutamate ligase (MurD) from Escherichia coli, 12 residues conserved either in the Mur superfamily [Eveland, S. S., Pompliano, D. L., and Anderson, M. S. (1997) Biochemistry 36, 6223-6229; Bouhss, A., Mengin-Lecreulx, D., Blanot, D., van Heijenoort, J., and Parquet, C. (1997) Biochemistry 36, 11556-11563] or in the sequences of 26 MurD orthologs were submitted to site-directed mutagenesis. All these residues lay within the cleft of the active site of MurD as defined by its 3D structure [Bertrand, J. A., Auger, D., Fanchon, E., Martin, L., Blanot, D., van Heijenoort, J., and Dideberg, O. (1997) EMBO J. 16, 3416-3425]. Fourteen mutant proteins (D35A, K115A, E157A/K, H183A, Y194F, K198A/F, N268A, N271A, H301A, R302A, D317A, and R425A) containing a C-terminal (His)(6) extension were prepared and their steady-state kinetic parameters determined. All had a reduced enzymatic activity, which in many cases was very low, but no mutation led to a total loss of activity. Examination of the specificity constants k(cat)/K(m) for the three MurD substrates indicated that most mutations affected both the binding of one substrate and the catalytic process. These kinetic results correlated with the assigned function of the residues based on the X-ray structures.

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The mechanism of the Mur synthetases of peptidoglycan biosynthesis is thought to involve in each case the successive formation of an acyl phosphate and a tetrahedral intermediate. The existence of the acyl phosphates for the MurC and MurD enzymes from Escherichia coli was firmly established by their in situ reduction by sodium borohydride followed by acid hydrolysis, yielding the corresponding amino alcohols. Furthermore, it was found that MurD, but not MurC, catalyses the synthesis of adenosine 5'-tetraphosphate from the acyl phosphate, thereby substantiating its existence and pointing out a difference between the two enzymes.

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UDP -N- acetylmuramoyl- L -alanine: D -glutamate (MurD) ligase catalyses the addition of d -glutamate to the nucleotide precursor UDP -N- acetylmuramoyl- L -alanine (UMA). The crystal structures of three complexes of Escherichia coli MurD with a variety of substrates and products have been determined to high resolution. These include (1) the quaternary complex of MurD, the substrate UMA, the product ADP, and Mg2+, (2) the quaternary complex of MurD, the substrate UMA, the product ADP, and Mn2+, and (3) the binary complex of MurD with the product UDP - N- acetylmuramoyl- L -alanine- D -glutamate (UMAG). The reaction mechanism supported by these structures proceeds by the phosphorylation of the C-terminal carboxylate group of UMA by the gamma-phosphate group of ATP to form an acyl-phosphate intermediate, followed by the nucleophilic attack by the amino group of D-glutamate to produce UMAG. A key feature in the reaction intermediate is the presence of two magnesium ions bridging negatively charged groups.

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The phosphoglucosamine mutase (GlmM) from Escherichia coli, specifically required for the interconversion of glucosamine-6-phosphate and glucosamine-1-phosphate (an essential step in the pathway for cell-wall peptidoglycan and lipopolysaccharide biosyntheses) was purified to homogeneity and its kinetic properties were investigated. The enzyme was active in a phosphorylated form and catalysed its reaction according to a classical ping-pong bi-bi mechanism. The dephosphorylated and phosphorylated forms of GlmM could be separated by HPLC and coupled MS showed that only one phosphate was covalently linked to the active site of the enzyme. The site of phosphorylation was clearly identified as Ser102 in the 445-amino acid polypeptide. GlmM was also capable of catalysing the interconversion of glucose-1-phosphate and glucose-6-phosphate isomers, although at a much lower (1400-fold) rate. Interestingly, the mutational change of the Ser100 to a threonine residue resulted in a 20-fold increase of the nonspecific phosphoglucomutase activity of GlmM, suggesting that the presence of either a serine or a threonine at this position in the consensus sequence of hexosephosphate mutases could be one of the factors that determines the specificity of these enzymes for either sugar-phosphate or amino sugar-phosphate substrates.

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The UDP-N-acetylmuramoyl-L-alanine:D-glutamate ligase from Escherichia coli, an enzyme involved in the biosynthesis of the bacterial peptidoglycan monomer unit, was overproduced and purified to homogeneity on a large scale, yielding 4 mg of protein per liter of bacterial culture. Crystals of the complex with the substrate UDP-MurNAc-L-Ala were grown by the hanging drop method using ammonium sulfate as the precipitant. They are tetragonal with cell dimensions a = b = 65.5 A and c = 134.59 A, space group P4(1) or P4(3), and contain one monomer of 46,842 Da in the asymmetric unit. In order to use the multiple-wavelength anomalous diffraction method for phasing, a selenomethionine derivative of the protein has also been overproduced, purified, and crystallized.

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Site-directed mutagenesis and chemical modification of the two cysteine residues of the MurC L-alanine-adding enzyme from Escherichia coli were undertaken to study their possible role in activity and stability. Their replacement by alanine was not critical for activity. However, C230 played a role in enzyme stability and substrate binding. N-Ethylmaleimide alkylation led to monoalkylated and dialkylated proteins. The monoalkylated protein had mostly unmodified C230 residues. The extent of alkylation of C230 paralleled the loss of activity, whereas that of C426 did not. Protection against inactivation by beta,gamma-imidoadenosine 5'-triphosphate implied the involvement of C230 in the ATP binding site.

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The comparison of the amino acid sequences of 20 cytoplasmic peptidoglycan synthetases (MurC, MurD, MurE, MurF, and Mpl) from various bacterial organisms has allowed us to detect common invariants: seven amino acids and the ATP-binding consensus sequence GXXGKT/S all at the same position in the alignment. The Mur synthetases thus appeared as a well-defined class of closely functionally related proteins. The conservation of a constant backbone length between certain invariants suggested common structural motifs. Among the other enzymes catalyzing a peptide bond formation driven by ATP hydrolysis to ADP and Pi, only folylpoly-gamma-l-glutamate synthetases presented the same common conserved amino acid residues, except for the most N-terminal invariant D50. Site-directed mutageneses were carried out to replace the K130, E174, H199, N293, N296, R327, and D351 residues by alanine in the MurC protein from Escherichia coli taken as model. For this purpose, plasmid pAM1005 was used as template, MurC being highly overproduced in this genetic setting. Analysis of the Vmax values of the mutated proteins suggested that residues K130, E174, and D351 are essential for the catalytic process whereas residues H199, N293, N296, and R327 were not. Mutations K130A, H199A, N293A, N296A, and R327A led to important variations of the Km values for one or more substrates, thereby indicating that these residues are involved in the structure of the active site and suggesting that the binding order of the substrates could be ATP, UDP-MurNAc, and alanine. The various mutated murC plasmids were tested for their effects on the growth, cell morphology, and peptidoglycan cell content of a murC thermosensitive strain at 42 degrees C. The observed effects (complementation, altered morphology, and reduced peptidoglycan content) paralleled more or less the decreased values of the MurC activity of each mutant.

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UDP-N-acetylmuramoyl-L-alanine:D-glutamate ligase (MurD) is a cytoplasmic enzyme involved in the biosynthesis of peptidoglycan which catalyzes the addition of D-glutamate to the nucleotide precursor UDP-N-acetylmuramoyl-L-alanine (UMA). The crystal structure of MurD in the presence of its substrate UMA has been solved to 1.9 A resolution. Phase information was obtained from multiple anomalous dispersion using the K-shell edge of selenium in combination with multiple isomorphous replacement. The structure comprises three domains of topology each reminiscent of nucleotide-binding folds: the N- and C-terminal domains are consistent with the dinucleotide-binding fold called the Rossmann fold, and the central domain with the mononucleotide-binding fold also observed in the GTPase family. The structure reveals the binding site of the substrate UMA, and comparison with known NTP complexes allows the identification of residues interacting with ATP. The study describes the first structure of the UDP-N-acetylmuramoyl-peptide ligase family.

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Several analogues of diaminopimelic acid (A2pm) were tested as substrates or inhibitors of the meso-diaminopimelate-adding enzyme from Escherichia coli. They included lanthionine derivatives, a phosphonic analogue, heterocyclic compounds, 3-fluoro-A2pm, 4-methylene-A2pm and N-hydroxy-A2pm. The best substrates were, in decreasing order of specific enzyme activity, (2S,3R,6S)-3-fluoro-A2pm, meso-lanthionine sulfoxide and N-hydroxy-A2pm (mixture of stereoisomers). In those cases where all the stereoisomers were available, the specificity could be described as meso > > DD approximately to LL. N-Hydroxy-A2pm (mixture of stereoisomers) strongly inhibited the addition of radioactive meso-A2pm to UDP-N-acetylmuramoyl-dipeptide.

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The UDP-N-acetylmuramate:L-alanine ligase of Escherichia coli is responsible for the addition of the first amino acid of the peptide moiety in the assembly of the monomer unit of peptidoglycan. It catalyzes the formation of the amide bond between UDP-N-acetylmuramic acid (UDP-MurNAc) and L-alanine. The UDP-MurNAc-L-alanine ligase was overproduced 2000-fold in a strain harboring a recombinant plasmid (pAM1005) with the murC gene under the control of the inducible promoter trc. The murC gene product appears as a 50-kDa protein accounting for ca. 50% of total cell proteins. A two-step purification led to 1 g of a homogeneous protein from an 8-liter culture. The N-terminal sequence of the purified protein correlated with the nucleotide sequence of the gene. The stability of the enzymatic activity is strictly dependent on the presence of 2-mercaptoethanol. The K(m) values for substrates UDP-N-acetylmuramic acid, L-alanine, and ATP were estimated; 100, 20, and 450 microM, respectively. The specificity of the enzyme for its substrates was investigated with various analogues. Preliminary experiments attempting to elucidate the enzymatic mechanism were consistent with the formation of an acylphosphate intermediate.

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The D-glutamic acid-adding enzyme of Escherichia coli, or MurD, was purified from an overproducing strain and a few aspects of its reaction mechanism were studied. The existence of a reactive cysteinyl residue was shown by the following experiments: (1) two thiol-modifying reagents, (5,5'-dithiobis)2-nitrobenzoic acid and 2-nitro-5-thiocyanobenzoic acid, inactivated the enzyme; (2) incubation with tetranitromethane led to inactivation and to the appearance of cysteic acid (not to 3-nitrotyrosine); (3) in each case, ATP or UDP-MurNAc-L-Ala (but not D-glutamic acid) protected the enzyme from inactivation. The existence of a reactive lysyl residue was shown by the action of 2,4,6-trinitrobenzenesulfonic acid, a reagent specific for lysyl residues present in phosphate-binding sites. The formation of an acyl phosphate intermediate was consistent with three types of results: (1) the molecular isotope exchange reaction, which took place only in the presence of phosphate, but which was not strictly dependent on the presence of ADP; (2) a release of phosphate, measured by the molybdate assay, observed when the enzyme was incubated with ATP and UDP-MurNAc-L-Ala (without D-glutamic acid); (3) the appearance of a new radioactive compound (besides ATP and Pi) after incubation for a few minutes with UDP-MurNAc-L-Ala and [gamma-32P]ATP. Finally, the fact that phosphinate 1 was a good inhibitor of the enzyme (IC50 = 0.7 microM) strongly suggested that a tetrahedral transition state follows the acyl phosphate in the reaction pathway.

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The UDP-N-acetylmuramate:L-alanine ligase of Escherichia coli was over-produced in strains harbouring recombinant plasmids bearing the murC gene under the control of the lac or trc promoter. Plasmid pAM1005, in which the promoter and ribosome-binding site region of murC were removed and in which the gene was directly under the control of promoter trc, led to a 2000-fold amplification of the L-alanine-adding activity after induction by isopropyl-thio-beta-D-galactopyranoside. The murC gene product was visualized as a 50-kDa protein accounting for approximately 50% of the cell protein. A two-step purification led to 1 g of a homogeneous protein from an 18-1 culture. The N-terminal sequence of the purified protein correlated with the nucleotide sequence of the murC gene. The presence of 2-mercaptoethanol and glycerol was essential for the stability of the enzyme. The Km values for UDP-N-acetylmuramic acid, L-alanine and ATP/Mg2+ were estimated at 100, 20 and 450 microM, respectively. Under the optimal in vitro conditions a turnover number of 928 min-1 was calculated and a copy number/cell of 600 could be roughly estimated. The specificity of the enzyme for its substrates was investigated with various analogues. The enzyme also catalysed the reverse reaction.

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