Scission of the lactyl ether bond of N-acetylmuramic acid by Escherichia coli "etherase"

The ubiquitous bacterial cell wall sugar N-acetylmuramic acid (MurNAc) carries a unique D-lactyl ether substituent at the C3 position. Recently, we proposed an etherase capable of cleaving this lactyl ether to be part of the novel bacterial MurNAc dissimilation pathway (Dahl, U., Jaeger, T., Nguyen, B. T., Sattler, J. M., Mayer, C. (2004) J. Bacteriol. 186, 2385-2392). Here, we report the identification of the first known MurNAc etherase. The encoding gene murQ is located at 55 min on the Escherichia coli chromosome adjacent to murP, the MurNAc-specific phosphotransferase system. A murQ deletion mutant could not grow on MurNAc as the sole source of carbon and energy but could be complemented by expressing murQ from a plasmid. The mutant had no obvious phenotype when grown on different carbon sources but accumulated MurNAc 6-phosphate at millimolar concentrations from externally supplied MurNAc. Purified MurQ-His6 fusion protein and extracts of cells expressing murQ both catalyze the cleavage of MurNAc 6-phosphate, with GlcNAc 6-phosphate and D-lactate being the primary products. The 18O label from enriched water is incorporated into the sugar molecule, showing that the C3-O bond is cleaved and reformed by the enzyme. Moreover, an intermediate was detected and identified as an unsaturated sugar molecule. Based on this observation, we suggested a lyase-type mechanism (beta-elimination/hydration) for the cleavage of the lactyl ether bond of MurNAc 6-phosphate. Close homologs of murQ were found on the chromosome of several bacteria, and amino acid sequence similarity with the N-terminal domain of human glucokinase-regulatory protein (GckR or GKRP) was recognized.     

Theoretical studies on peptidoglycans. II. Conformations of the disaccharide–peptide subunit and the three-dimensional structure of peptidoglycan

Possible conformations of the disaccharide–peptide subunit of peptidoglycan (of Staphylococcus aureus or Micrococcus luteus) have been studied by an energy-minimization procedure. The favored conformation of the disaccharide N-acetyl-glucosaminyl-β(1–4)-N-acetylmuramic acid (NAG-NAM) is different from that of cellulose or chitin; this disagrees with the assumption of earlier workers. The disaccharide–peptide subunit favors three types of conformations, among which two are compact and the third is extended. All these conformations are stabilized by intramolecular hydrogen bonds. Based on these conformations of the subunit, two different models are proposed for the three-dimensional arrangement of peptidoglycan in the bacterial cell wall.     

A new proposal for the primary and secondary structure of the glycan moiety of pseudomurein. Conformational energy calculations on the glycan strands with talosaminuronic acid in 1C conformation and comparison with murein

Using the method of conformational energy calculations, favoured conformations of a pseudomurein sugar strand built up from beta 1,3-linked N-acetyl-D-glucosamine and N-acetyl-L-talosaminuronic acid were obtained. Such a completely beta 1,3-linked polysaccharide primary structure, although contrasting with the originally proposed alternating beta 1,3-alpha 1,3-linked structure [K?nig, H., Kandler, O., Jensen, M. and Rietschel, E. Th. (1983) Hoppe-Seyler's Z. Physiol. Chem. 364, 627-636] would be in agreement with all experimental data hitherto known. Starting from an analysis of favoured conformations of the monosaccharide building blocks and those obtained for disaccharide parts, the favoured helical conformations of the complete polysaccharide chains could be explored. Our completely beta 1,3-linked chain could adopt two types of conformation: extended and hollow; the latter was discarded as unsuitable for cell wall assembly. The extended conformation type was shown to exhibit a remarkable similarity if compared to the secondary structures accessible to murein-type polysaccharide chains. In contrast to the conformations accessible for the beta 1,3-alpha 1,3-linked primary structure, the new hypothetical pseudomurein structure was found to be more extended, possessed a flexible peptide attachment site at every second sugar residue and led to an orientation of consecutive peptide attachment sites analogous to the data known for murein-type chains. From the two possibilities compatible with the experimental data available, the completely beta 1,3-linked sugar strand structure could well be realized in the native pseudomurein network of methanobacteria. In this case the hypothesis for a similar three-dimensional architecture for murein and pseudomurein would be supported.     

Conformational energy calculation on the peptide part of murein.

Conformational energy calculations have been carried out on N-acetyl-L-alanyl-D-gamma-glutamyl-L-lysyl-D-alanyl-D-alanine as a model of the peptide moiety of peptidoglycan. Although many conformations were of comparable energy, particular favoured conformations were selected by assuming conformational similarity between the pentapeptide and the tetrapeptide found during biosynthesis subsequent to the cross-linking of the peptide chains in murein. The common feature of these conformations, which include the global minimum of the pentapeptide, is a ring-shaped backbone. The global minimum is stabilised by a hydrogen bond between the -NH group of L-alanine and the -CO group of the penultimate D-alanine. The distance between the D-lactyl group and the side-chain of the diamino acid is about 1.5 nm. The ring-like structures will accomodate chemical modifications that have been observed in peptidoglycan. The present ring-like structure differs considerably from the models proposed as yet. Energetically beta-pleated sheet conformations and a flat 2.2(7) helical structure are not favoured. Furthermore, an alpha helix cannot occur. The suggested new model exhibits no significant relationship to the solid state conformation of beta-lactam antibiotics.     

Low-molecular-weight substrate for the lysozyme of T4 bacteriophage.

It has been shown that muropeptide CB, the chemically defined product of Escherichia coli B murein digestion by phage lambda endolysin, is the substrate for T4 lysozyme. This is the tetrasaccharide GlcNAc-MurNAc-GlcNAc-anMurNAc in which the carboxyl groups of MurNAc and anMurNAc residues are substituted by tetrapeptide LAla-DGlu-msA2pm-DAla (MurNAc = N-acetylmuramic acid, GlcNAc = N-acetyl-D-glucosamine, anMurNAc = 1,6-anhydro-N-acetylmuramic acid, LAla = L-alanine, DGlu = D-glutamic acid, msA2pm = meso-diaminopimelic acid). The substrate contains one bond hydrolysable by T4 lysozyme. The products of hydrolysis are the easily identifiable disaccharide muropeptides C6 (GlcNAc-MurNAc-LAla-DGlu-msA2pm-DAla) and CA (GlcNAc-anMurNac-LAla-DGlu-msA2pm-DAla). Thus the substrate may be used for the specific identification of murein N-acetylmuramoylhydrolases of the T4 lysozyme type, as well as for any quantitative measurement of the enzymatic reaction.     

The composition of the murein of Escherichia coli

Escherichia coli murein, the polymer from which the shape-maintaining structure of the cell envelope is made, shows unexpected complexity. The separation of murein building blocks with high performance liquid chromatography reveals about 80 different types of muropeptides. Their behavior in high performance liquid chromatography and their chemical structure are described. The complexity of E. coli murein is due to the free combination of seven different types of side chains (L-Ala-D-Glu-R with R = -OH, -m-A2pm, -m-A2pm-D-Ala, -m-A2 pm-Gly, -m-A2pm-D-Ala-D-Ala, -m-A2pm-D-Ala-Gly, -m-A2pm-Lys-Arg) with two types of cross-bridges (D-Ala-m-A2pm, -m-A2pm-m-A2pm). The novel type of cross-bridge, A2pm-A2pm, contains an L,D-peptide bond, as shown by Edman degradation and chemical analysis of the reaction products. The A2pm-A2pm cross-bridge is assumed to play a role in the adaptation of the cross-linkage of murein to different growth conditions of the cell. The structural data of E. coli murein agree best with a model of a thin, however multilayered, murein sacculus.     

X-ray fibre diffraction study of conformational changes in hyaluronate induced in the presence of sodium,potassium and calcium cations

Hyaluronate purified from all cations by ion exchange chromatography was introduced to the cations sodium, potassium and calcium in a controlled way. The conformations formed in the presence of these ions were studied as a function of ionic strength, hydrogen ion activity, humidity and temperature using X-ray fibre diffraction. In sodium hyaluronate above pH 4.0 a contracted helix is found which approximates to a four-fold helix with an axial rise per disaccharide of 0.84 nm. There is no requirement for water molecules in the unit cell as the Na⁺ can be coordinate by the hyaluronate chains alone. On crystallizing hyaluronate below pH 4.0 an extended 2-fold helix with an axial rise per disaccharide of 0.98 nm is formed. In the presence of potassium above pH 4.0 a conformation similar, but not identical, to that of sodium was found where the helix backbone is again four-fold with an axial rise per disaccharide h=0.90 nm. To maintain the coordination of the potassium ion, four water molecule/disaccharide are required and on removal of these the conformation is destabilized going to a new helix where n = 4 and h = 0.97 nm. Below pH 4.0 the conformation is a contracted 4-fold helix with h = 0.82 nm. In this structure two antiparallel chains intertwine to form a double helix. The packing of the double helical units is stabilized by water molecules, the unit cell requiring 8 water molecules/disaccharide. Formation of the calcium hyaluronate complex above pH 3.5 yields a three-fold helix with h = 0.95 nm. The requirement for water in the unit cell to maintain full crystallinity is high, at 9 water molecules/disaccharide; however, on removal of this water, though the crystallinity is disrupted, the conformation remains constant. The acid form of calcium-hyaluronate yields an equivalent conformation to that of sodium under the same condition, i.e. a helix with n = 2, h = 0.98 nm. The presence of small quantities of calcium in what are otherwise potassium or sodium solutions of hyaluronate yield the 3-fold conformation for hyaluronate. Thus calcium has an important role to play in deciding the dominating conformation present in hyaluronate. The variety of conformations yielded by the different cations indicates a subtle interaction between hyaluronate and its environment, in which the balance between the cations will control to some degree the interactions between hyaluronate chains and thus affect the mechanical properties of the matrix which they form. The conformations of individual chains are all stabilized in varying degrees by intra-chain hydrogen bonds.     

Mannose-binding lectin recognizes peptidoglycan via the N-acetyl glucosamine moiety, and inhibits ligand-induced proinflammatory effect and promotes chemokine production by macrophages

Peptidoglycan (PGN) is the major cell wall component (90%, w/w) of Gram-positive bacteria and consists of N-acetylglucosamine (GlcNAc) and N-acetylmuramic acid (MurNAc) disaccharide repeating arrays that are cross-linked by short peptides. We hypothesized that PGN is a ligand for pathogen-associated pattern-recognition proteins. Mannose-binding lectin (MBL) and serum amyloid component P are two carbohydrate-binding innate immune proteins present in the blood. In this study we show that human MBL, but not serum amyloid component P, binds significantly to PGN via its C-type lectin domains, and that the interaction can be more effectively competed by GlcNAc than by MurNAc. Surface plasmon resonance analyses show that native MBL binds immobilized PGN with high avidity. Competition experiments also show that both native MBL and MBL(n/CRD), a 48-kDa recombinant trimeric fragment of MBL containing neck and carbohydrate recognition domains, have higher affinity for GlcNAc than for MurNAc. Protein arrays and ELISA show that PGN increases the secretion of TNF-alpha, IL-8, IL-10, MCP-2, and RANTES from PMA-stimulated human monocytic U937 cells. Interestingly, the presence of MBL together with PGN increases the production of IL-8 and RANTES, but reduces that of TNF-alpha. Our results indicate that Gram-positive bacterial is a biologically relevant ligand for MBL, and that the collectin preferentially binds to the GlcNAc moiety of the PGN via its C-type lectin domains. MBL inhibits PGN-induced production of proinflammatory cytokines while enhancing the production of chemokines by macrophages, which suggests that MBL may down-regulate macrophage-mediated inflammation while enhancing phagocyte recruitment.     

Conformation of a triple collagen spiral as a function of primary structure]

It has been shown by the method of conformational analysis that conformation of the polypeptide chain of a collagen molecule varies from one type of sequence to another, but in all the sequences the only two types of conformations can be characterized by minimal conformational energy. The collagen molecule as a whole is a combination of the single-bond Rich and Crick model and new double-bonded structure. Rigorous comparison with "thick" conformations obtained by Scheraga and coworkers was undertaken using precise calculations with flexible proline.     

Optimization of a small-molecule Lipid II binder

Lipid II is an essential precursor of bacterial cell wall biosynthesis and an attractive target for antibiotics. Lipid II is comprised of specialized lipid (bactoprenol) linked to a hydrophilic head group consisting of a peptidoglycan subunit (N-acetylglucosamine (GlcNAc)-N-acetylmuramic acid (MurNAc) disaccharide coupled to a short pentapeptide moiety) via a pyrophosphate. We previously identified a (E)-2,4-bis(4-bromophenyl)-6-(4-(dimethylamino)styryl)pyrylium boron tetrafluoride salt, termed 6jc48-1, that interacts with the MurNAc moiety, the phosphate cage and the isoprenyl tail of Lipid II. Here, we report on the structure-activity relationship of 6jc48-1 derivatives obtained by de novo chemical synthesis. Our results indicate that bacterial killing is positively driven by bi-phenyl stacking with peptidoglycan units. Replacement of bromides by fluorides resulted in activity against S. aureus without affecting Lipid II binding and cytotoxicity. Antibacterial activity was affected negatively by extended interaction of the scaffold with Lipid II isoprenyl units.     

Quantum chemical studies on the conformational structure of bacterial peptidoglycan. I. MNDO calculations on the glycan moiety

Semi-empirical quantum chemical calculations at MNDO level of approximations have been carried out on the monosaccharide and disaccharide moiety of bacterial peptidoglycan to determine the energetically favoured conformation of their side groups and the relative orientations of sugar rings. The results have been compared with those obtained from empirical energy calculations. The MNDO results have also been discussed with available experimental data and suggest that a chitin-like structure is not favoured for the glycan moiety of peptidoglycan.     

Glycosyl transferase activity of the Escherichia coli penicillin-binding protein 1b: specificity profile for the substrate

The glycosyl transferase of the Escherichia coli bifunctional penicillin-binding protein (PBP) 1b catalyzes the assembly of lipid-transported N-acetylglucosaminyl-beta-1,4-N-acetylmuramoyl-L-Ala-gamma-D-Glu-meso-A2pm-D-Ala-D-Ala units (lipid II) into linear peptidoglycan chains. These units are linked, at C1 of N-acetylmuramic acid (MurNAc), to a C55 undecaprenyl pyrophosphate. In an in vitro assay, lipid II functions both as a glycosyl donor and as a glycosyl acceptor substrate. Using substrate analogues, it is suggested that the specificity of the enzyme for the glycosyl donor substrate differs from that for the acceptor. The donor substrate requires the presence of both N-acetylglucosamine (GlcNAc) and MurNAc and a reactive group on C1 of the MurNAc and does not absolutely require the lipid chain which can be replaced by uridine. The enzyme appears to prefer an acceptor substrate containing a polyprenyl pyrophosphate on C1 of the MurNAc sugar. The problem of glycan chain elongation that presumably proceeds by the repetitive addition of disaccharide peptide units at their reducing end is discussed.     

Prediction of protein--ligand interactions: the complex of porcine pancreatic elastase with a valine-derived benzoxazinone

Prior to availability of the crystal structure of the complex, we evaluated models of the complex between porcine pancreatic elastase and a t-Boc–Val-derived benzoxazinone inhibitor. Models of the noncovalent and covalent complex were generated using computer graphics and each model was subjected to energy minimization using molecular mechanics. After the crystal structure became available, we found that the model with the lowest energy was in good agreement with the crystal structure, except for the position of the His57 side chain. Permissible conformations of the inhibitor were based on information from x-ray crystal structures and an earlier conformational energy investigation of t-Boc–amino acids. We did not, however, limit ourselves to these conformations. The conformation of the inhibitor in the lowest energy model and crystal structure, was not similar to any of the minimum-energy conformations of t-Boc–amino acids. This suggests that limiting proposed binding modes only to the lowest energy conformations of a ligand (prior to binding) may sometimes unfairly bias the procedure.     

Assignment of side-chain conformation using adiabatic energy mapping, free energy perturbation, and molecular dynamic simulations

NMR spectroscopic analysis of the C-terminal Kunitz domain fragment (alpha3(VI)) from the human alpha3-chain of type VI collagen has revealed that the side chain of Trp21 exists in two unequally populated conformations. The major conformation (M) is identical to the conformation observed in the X-ray crystallographic structure, while the minor conformation (m) cannot structurally be resolved in detail by NMR due to insufficient NOE data. In the present study, we have applied: (1) rigid and adiabatic mapping, (2) free energy simulations, and (3) molecular dynamic simulations to elucidate the structure of the m conformer and to provide a possible pathway of the Trp21 side chain between the two conformers. Adiabatic energy mapping of conformations of the Trp21 side chain obtained by energy minimization identified two energy minima: One corresponding to the conformation of Trp21 observed in the X-ray crystallographic structure and solution structure of alpha3(VI) (the M conformation) and the second corresponding to the m conformation predicted by NMR spectroscopy. A transition pathway between the M and m conformation is suggested. The free-energy difference between the two conformers obtained by the thermodynamic integration method is calculated to 1.77+/-0.7 kcal/mol in favor of the M form, which is in good agreement with NMR results. Structural and dynamic properties of the major and minor conformers of the alpha3(VI) molecule were investigated by molecular dynamic. Essential dynamics analysis of the two resulting 800 ps trajectories reveals that when going from the M to the m conformation only small, localized changes in the protein structure are induced. However, notable differences are observed in the mobility of the binding loop (residues Thr13-Ile18), which is more flexible in the m conformation than in the M conformation. This suggests that the reorientation of Trp2 might influence the inhibitory activity against trypsin, despite the relative large distance between the binding loop and Trp21.     

Loop modeling: Sampling, filtering, and scoring

We describe a fast and accurate protocol, LoopBuilder, for the prediction of loop conformations in proteins. The procedure includes extensive sampling of backbone conformations, side chain addition, the use of a statistical potential to select a subset of these conformations, and, finally, an energy minimization and ranking with an all-atom force field. We find that the Direct Tweak algorithm used in the previously developed LOOPY program is successful in generating an ensemble of conformations that on average are closer to the native conformation than those generated by other methods. An important feature of Direct Tweak is that it checks for interactions between the loop and the rest of the protein during the loop closure process. DFIRE is found to be a particularly effective statistical potential that can bias conformation space toward conformations that are close to the native structure. Its application as a filter prior to a full molecular mechanics energy minimization both improves prediction accuracy and offers a significant savings in computer time. Final scoring is based on the OPLS/SBG-NP force field implemented in the PLOP program. The approach is also shown to be quite successful in predicting loop conformations for cases where the native side chain conformations are assumed to be unknown, suggesting that it will prove effective in real homology modeling applications.     

Chemical structure of the peptidoglycan of Vibrio parahaemolyticus A55 with special reference to the extent of interpeptide cross-linking.

The chemical structure of the cell wall peptidoglycan of Vibrio parahaemolyticus A55 was studied. Estimation of cross linkages between peptide subunits in the peptidoglycan by dinitrophenylation showed that about 30% of the total 2,6-diaminopimelic acid (A2pm) residues were involved in cross linkages. The presence of interpeptide bridges was also demonstrated by isolating bisdisaccharide peptide subunit dimers from Chalaropsis muramidase digests of the cell wall peptidoglycan by gel filtration followed by ion-exchange column chromatography, although most of the building blocks obtained were uncross-linked disaccharide peptide monomers. The chain length of a glycan moiety of the peptidoglycan obtained by treatment with the L-11 enzyme and gel filtration of the digest was also studied. The chain length varied from 7 to 44, but 30% of the glycan fragments had muramic acid at the reducing end and a chain length of 28 to 44. In conformity with the above structural study it was demonstrated that a particulate enzyme fraction obtained by differential centrifugation of a sonicated preparation of V. parahaemolyticus catalyzed a penicillin-sensitive transpeptidation reaction, using UDP-MurNAc-14C-pentapeptide and UDP-GlcNAc as substrates.     

Solution conformation of a pectin fragment disaccharide using molecular modelling and nuclear magnetic resonance

In the present study, the conformational behaviour of methylated pectic disaccharide 4-O-alpha-D-galactopyranurosyl 1-O-methyl-alpha-D-galactopyranuronic 6,6'-dimethyl diester 1 has been completely characterized through combined n.m.r. and molecular modelling studies. The 1H-1H n.O.e. across the glycosidic bond was measured by both steady-state and transient 1D and 2D experiments. In parallel, the complete conformational analysis of the disaccharide has been achieved with the MM3 molecular mechanics method. The conformation of the pyranose ring is confirmed by the excellent agreement between the experimental and calculated intracyclic scalar coupling constants. The iso-energy contours displayed on the 'relaxed' map indicate an important flexibility about the glycosidic linkage. There is no significant influence of the methoxyl group on the conformational behaviour of the disaccharide. The theoretical n.m.r. data were calculated taking into account all the accessible conformations and using the averaging methods appropriate for slow internal motions. 3JC-H coupling constants were calculated using an equation suitable for C-O-C-H segments. The agreement between experimental and theoretical data is excellent. Within the potential energy surface calculated for the disaccharide, several conformers can be identified. When these conformations are extrapolated to a regular polymer structure, they generate pectins with right- and left-handed chirality along with a two-fold helix. These different types of helical structure are the result of small changes in conformation, without any drastic variation of the fibre repeat.     

Molecular dynamics simulation of Lewis blood groups and related oligosaccharides.

Molecular dynamics simulations without explicit inclusion of solvent molecules have been performed to study the motions of Lewisa and Lewisb blood group oligosaccharides, and two blood group A tetrasaccharides having type I and type II core chains. The blood group H trisaccharide has also been studied and compared with the blood group A type II core chain. The potential energy surface developed by Rasmussen and co-workers was used with the molecular mechanics code CHARMM. The lowest energy minima of the component disaccharide fragments were obtained from conformational energy mapping. The lowest energy minima of these disaccharide fragments were used to build the tri- and tetrasaccharides that were further minimized before the actual heating/equilibration and dynamics simulations. The trajectories of the disaccharide fragments, e.g., Fuc alpha- (1----4)GlcNAc, Gal beta-(1----4)GlcNAc, etc., show transitions among various minima. However, the oligosaccharides were found to be dynamically stable and no transitions to other minimum energy conformations were observed in the time series of the glycosidic dihedral angles even during trajectories as long as 300 ps. The stable conformations of the glycosidic linkages in the oligosaccharides are not necessarily the same as the minimum energy conformation of the corresponding isolated disaccharides. The average fluctuations of the glycosidic angles in the oligosaccharides were well within the range of +/- 15 degrees. The results of these trajectory calculations were consistent with the relatively rigid single-conformation models derived for these oligosaccharides from 1H-nmr data.     

Characterization of an N-acetylmuramic acid/N-acetylglucosamine kinase of Clostridium acetobutylicum

We report here the cloning and characterization of a cytoplasmic kinase of Clostridium acetobutylicum, named MurK (for murein sugar kinase). The enzyme has a unique specificity for both amino sugars of the bacterial cell wall, N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc), which are phosphorylated at the 6-hydroxyl group. Kinetic analyses revealed Km values of 190 and 127 μM for MurNAc and GlcNAc, respectively, and a kcat value (65.0 s(-1)) that was 1.5-fold higher for the latter substrate. Neither the non-N-acetylated forms of the cell wall sugars, i.e., glucosamine and/or muramic acid, nor epimeric hexoses or 1,6-anhydro-MurNAc were substrates for the enzyme. MurK displays low overall amino acid sequence identity (24%) with human GlcNAc kinase and is the first characterized bacterial representative of the BcrAD/BadFG-like ATPase family. We propose a role of MurK in the recovery of muropeptides during cell wall rescue in C. acetobutylicum. The kinase was applied for high-sensitive detection of the amino sugars in cell wall preparations by radioactive phosphorylation.