Quantum chemical studies on the conformational structure of bacterial peptidoglycan. II. PCILO calculations on the mono-saccharides

Conformational energy calculations were performed on mono-saccharides of the glycan moiety of bacterial peptidoglycan using PCILO semiempirical quantum chemical method to re-examine the preferred conformations of these molecules so far reported in the empirical studies. The PCILO dihedral angles for some side groups are different from those found in MNDO studies. However, in almost every case the PCILO and empirical calculations suggest the same orientations for the different side groups. Moreover, the strengths of the hydrogen bonds between several groups found in the PCILO calculations are more than those of the empirical and MNDO results.     

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.     

Structural studies on the bacterial cell wall peptidoglycan pseudomurein. I. Conformational energy calculations on the glycan strands in C1 conformation and comparison with murein

Conformational energy calculations have been used to explore the conformations which may be realized for the sugar moiety of murein and pseudomurein. For the building blocks of the pseudomurein sugar strands, i.e. for the monosaccharides beta-D-N-acetylglucosamine (NAG) and alpha-L-N-acetyltalosaminuronic acid (NAT), both in C1 ring conformation, as well as for their 1,3 and 1,4 linked disaccharides, the favoured conformations were obtained. The helical parameters of sugar strands of both linkage types, which describe the regular structure of the corresponding polysaccharides, poly-(1,3-NAT-NAG) and poly-(1,4-NAT-NAG), were calculated. Both types of polysaccharides poly-(NAG-NAT) considered in this study favoured extended conformations, which in the case of 1,3 linked polymers showed less gain of length per saccharide unit compared to 1,4 linked poly-(NAG-NAT) residues. For a 1,3 linked sugar moiety of pseudomurein every pair of neighbouring peptides attached to glycan chain pointed in favoured conformations approximately to opposite sides of the strands, whereas in a 1,4 linked poly-(NAG-NAT) the peptides protruded approximately to the same side of the glycan moiety. A comparison between pseudomurein and murein revealed that the sugar moieties of both peptidoglycans have similar features in respect to their overall structure, i.e. both favoured more or less extended structures. In contrast to these data the shapes of the resulting polysaccharide moieties were remarkably different. In poly-(1,3-NAG-NAT) the glycan chains possessed a zig-zag-like arrangement, whereas for glycan chains of the murein type relatively flat structures were preferred. These remaining differences in the conformational arrangement between both peptidoglycans depend strongly on the C1 chair conformation of NAT. It is, therefore, attractive to speculate about an hypothetical pseudomurein sugar chain configuration comprising beta-L-N-acetyltalosaminuronic acid in its 1C conformation.     

Quantum chemical studies on the conformational structure of nucleic acids. IV. Calculation of backbone structure by CNDO method

Quantum chemical calculations using the CNDO/2 method, have been carried out to determine the energetically favoured ranges of the torsional angles (φ′, ω′, ω, φ, ψ) which fix the conformational structure of nucleic acid backbone. The two dimensional isoenergy maps have been constructed in the (ω′, ω) and (φ, ψ) hyperspaces. The variation of total energy with respect to φ′ has also been studied. The results show that the non-bonding interactions play a major role in the conformational stability of nucleic acids and polynucleotides. The theoretical predictions show good correspondence with the experimental data (X-ray and ¹³C NMR) as well as the other reported theoretical calculations (EHT, PCILO and classical potential functions). The most favoured structure has the conformational angles close to 240, 290, 290, 180 and 60° and these values lead to a helical structure with a pitch of 34 Å and about ten nucleotide units per turn of the helix. The proposed models of Watson &; Crick, DNA-B and DNA-C lie in high energy regions.     

Quantum chemical studies on the conformational structure of bacterial peptidoglycan. III. CNDO and INDO calculations on the N-acetyl-giucosamine

CNDO and INDO semi-empirical all valence M.O. methods have been applied to predict the side group dihedral angles of N-acetyl glucosamine in order to compare the results of empirical, MNDO and PCILO studies already reported.The net atomic charges and dipole moments have also been computed. The present calculation suggests that the net atomic charges remain almost constant for the different conformers considered.The CNDO, INDO and PCILO methods predict nearly the same orientations for the side groups. Moreover, the quantum chemical methods suggest significant improvements over the empirical results although, in general, similar conformational features are observed. However, the MNDO results for some of the side groups are different from the ones obtained by all the above methods.     

Immunochemical study of the peptidoglycan of gram-negative bacteria.

The specificity of antibodies directed against the peptidoglycan of gram-negative bacteria was studied. The peptidoglycans of Proteus vulgaris, Escherichia coli, Moraxella glucidolytica, Neisseria perflava, give identical precipitin reactions. By means of inhibition studies with various peptidoglycan subunits and synthetic peptides, it was shown that the antibodies are essentially directed against the peptide moiety of the peptidoglycan: L-Ala-D-Glu (L)-mesoA2pm-(L)-D-Ala, that the peptide reacts better with antibodies when it is not cross-linked, and that the C-terminal portion-meso-A2pm-D-Ala of the peptide is immunodominant. These results explain the immunological identity of the peptidoglycans of gram-negative bacteria, which possess the same peptide subunit. Only weak cross-reactivity was observed with the peptidoglycans of gram-positive bacteria (Streptococcus faecium, Micrococcus lysodeikticus, Corynebacterium poinsettiae) where meso-diaminopimelic acid is replaced by L-lysine or L-homoserine. However, the peptidoglycan of Bacillus megaterium which possesses the same peptide subunit as gram-negative bacteria, gives only a reaction of partial identity with these bacteria. This result suggests the presence on the peptidoglycan of gram-negative bacteria, of other undefined antigenic determinants.     

Examination of the reduced affinity of the thymidylate synthase G52S mutation for FdUMP by ab initio and semi-empirical studies

BACKGROUND: The G52S mutation in the Arg50 loop of thymidylate synthase leads to decreased binding of FdUMP. It has been suggested that the mutation affects the Arg50 residue (within the Arg50 loop) responsible for binding the phosphate of FdUMP. The binding of the methylguanidinium moiety as a model for Arg50 to a methylphosphate entity as a model for FdUMP was investigated with theoretical calculations, as well as the structure of the Arg50-Thr51-Gly52 tripeptide in comparison with the Arg50-Thr51-Ser52 tripeptide. METHODS: Gaussian-98 and PC Spartan programs were used to perform Hartree-Fock and Post-Hartree-Fock quantum chemical calculations as well as MNDO (semi-empirical calculations). RESULTS: It was found that the strongest binding occurs between the negative methylphosphate ion and methylguanidine. The replacement of Gly52 by Ser52 leads to a significant displacement of Arg50, which may be responsible for the decreased binding to FdUMP. CONCLUSION: The arginine-phosphate binding appears to be geometry dependent. Thus, the displacement of the Arg50 residue, as observed in these calculated models, upon mutation of Gly52 to Ser may contribute to decreased binding of FdUMP to mTS (G52S).     

Theoretical studies on peptidoglycans. I. Effect of L-alanyl,D-butyl,or D-valyl residuces at the positions 4 or 5 of the pentapeptide moiety of peptidoglycan on the cross-linking reaction

Possible conformations of X-D -alanyl⁴-D -alanine₅ and its analogs X-L -analyl₄-D -alanine₅ X-D -alanyl₄-L -alanine₅, X-D -butyl₄-D -alanine₅, X-D -alanyl₄-D -butyric acid₅, X-D -valyl₄-D -alanine₅, and X-D -alanyl₄-D -valine₅ have been analyzed by theoretical methods. These studies suggest that L -alanine and D -valine at the 4 or 5 postion of the pentapeptide moiety of peptidoglycan will drastically reduce the cross-linking in peptidoglycan biosynthesis, whereas the effect of D - butyric acid will be marked at the 4 postition and modeate at the 5 position. This is in good agreement with experimental results. The cross-linking enzyme transpeptidase requires a specific confroamation for the 4th and 5th residues for optimal binding.     

A study of the complexes of borate ions and some cyclitols using 11B-n.m.r. spectroscopy

Complexes between borate ion and cyclohexane-cis-1,2-diol, cyclohexane-cis,cis-1,3,5-triol, and myo- and epi-inositol have been investigated by ¹¹B-n.m.r. spectroscopy. Three different complexes of myo-inositol have been identified. Formation constants have been determined for the borate complexes of each cyclitol. Where the complex is formed from the less-stable chair conformer, MNDO calculations have been performed to determine the enthalpies of inversion. For myo-inositol, an iterative method of calculation gave a set of constants which provided a good match with experimental data and supported the proposed formulation of its borate complexes.     

Second lytic target of beta-lactam compounds that have a terminal D-amino acid residue

A new biochemical mechanism of lysing bacterial cells by treatment with certain beta-lactam compounds that possess a terminal D-amino acid moiety in their side chain was demonstrated. The two functions of the molecule, the beta-lactam and terminal D-amino acid moiety, are both involved in the activity of lysing gram-negative bacteria, which is characterized by very rapid lysis of the cells in the first few hours after their contact with the compound. This mechanism was proved by studies on one such compound, named MT-141, which contains a terminal D-cysteine moiety with free amino and carboxyl groups in the 7 beta-side chain of the 7 alpha-methoxy-cephalosporin skeleton. This compound bound to the cell-wall peptidoglycan of Escherichia coli through the D-amino group of its terminal D-amino acid moiety and this seemed to cause rapid cell lysis. Both activities, of binding to peptidoglycan and of causing rapid cell lysis, were inhibited by certain D-amino acids, but not by L-amino acids. Mutants were isolated that had simultaneously gained decreased sensitivity to this kind of beta-lactam compound and supersensitivity to globomycin, an inhibitor of formation of lipoproteins which function in linking the peptidoglycan to the outer membrane. These results suggest that binding of the terminal D-amino acid moiety of the beta-lactam compound to peptidoglycan somehow influences formation of the linkage between the outer membrane and the peptidoglycan and consequently enhances the cell lytic activity of the beta-lactam portion of the molecule.     

Steric effects on penicillin-sensitive peptidoglycan synthesis in a membrane-wall system Gaffkya homari.

Residues 4 and 5 of the pentapeptide moiety, R-Ala1-DGlu2-Lys3-DAla4-DAla5, of peptidoglycan play an important role in the donor phase of cross-linked glycan synthesis. To assess the role of these residues in this phase, a series of UDP-MurNAc-peptides were biosynthesized with residues 4 and 5 replaced singly by either D-alpha-amino-n-butyric acid, D-norvaline, or D-valine. The six nucleotides were compared with UDP-MurNAc-Ala-DGlu-Lys-DAla-DAla (reference) in nascent (penicillin-insensitive) peptidoglycan synthesis and in penicillin-sensitive peptidoglycan synthesis. The synthesis of penicillin-sensitive peptidoglycan is catalyzed by membrane-walls isolated from Gaffkya homari and would appear to require the concerted action of transglycosylase and transpeptidase. The membrane-wall system shows a high degree of discrimination for the steric substituents, -CH3 and -CH2CH3, in residue 4. For example, for UDP-MurNAc-Ala-DGly-Lys-DAbu-DAla and -Ala-DGlu-Lys-DAla-DAbu, Vmax/km is 0.19 and 0.95 and Vmax is 0.03 and 0.52, respectively, of the value for the reference nucleotide. In contrast, for the synthesis of nascent peptidoglycan with these nucleotides Vmax/Km is 0.75 and 0.80, and Vmax is 0.71 and 1.0, respectively, of the value for the reference nucleotide. This trend was also illustrated with the other nucleotides in the time course experiments. These results indicate that the penicillin-sensitive enzyme(s), presumably the transpeptidase, has a higher degree of specificity in the donor phase for D-alanine in residue 4 than for D-alanine in residue 5 in the cross-linking stage of peptidoglycan synthesis.     

Aptamers that recognize the lipid moiety of the antibiotic moenomycin A

Moenomycin A is an amphiphilic phosphoglycolipid antibiotic that interferes with the transglycosylation step in peptidoglycan biosynthesis. The antibiotic consists of a branched pentasaccharide moiety, connected to the moenocinol lipid via a glycerophosphate linker. We have previously described the selection of aptamers that require the lipid group and the disaccharide epitopes of the oligosaccharide moiety for moenomycin binding. Here we report that the enriched moenomycin-binding library contains sequences that evolved for specific recognition of the unpolar lipid group of the antibiotic. These results suggest that the evolution of hydrophobic binding pockets in RNA molecules may be much more common than previously assumed.     

Molecular orbital studies on the conformation of phospholipids. II. Preferred conformations of hydrocarbon chains and molecular organization in biomembranes.

The preferred conformations of the nonpolar β and γ (hydrocarbon) chains in phospholipids have been derived using EHT and CNDO calculations. These calculations indicate that the possible conformations of phospholipids are highly restricted. The calculations find support from X-ray diffraction studies and NMR measurements on model compounds. When considering conformations relevant to structures in cell membranes, a further selection is possible because of the fact that in aqueous solutions hydrophobic interactions stabilize an arrangement where the hydrocarbon chains (β and γ) are stacked almost parallel to one another, leading to a bilayer structure. The various models for β and γ-chains which satisfy this condition have been compared and it has been shown that of these only four are favoured by energy considerations. These arrangements differ from one another in the orientation of the β-chain and γ-chains in the interior of the bilayer structure. A low energy pathway connects these conformations and thus the molecule can easily flip from one stable bilayer arrangement to another. The possible conformations of the polar group (α) are likewise restricted. The proposed model provides explanations to a number of dynamic and static properties of phospholipids, in particular to the observed NMR coupling constants, ¹H and ¹³C relaxation times, studies based on ESR spin labels and the observed X-ray diffraction results on model compounds.     

Studies on the conformations of sialyloligosaccharides and implications

Theoretical investigations, using semi-empirical potential functions have been carried out to predict the favoured conformations of the terminal dissaccharide fragments of various sialyloligosaccharides. The proposed conformational similarity for these fragments has been correlated to the binding specificity of neuraminidases. These calculations predict that bacterial neuraminidases have a binding site which can accommodate only two sugar residues and virus neuraminidases have a binding site which can accommodate more than two sugar residues.     

Host recognition of bacterial muramyl dipeptide mediated through NOD2. Implications for Crohn's disease

NOD2, a protein associated with susceptibility to Crohn's disease, confers responsiveness to bacterial preparations of lipopolysaccharide and peptidoglycan, but the precise moiety recognized remains elusive. Biochemical and functional analyses identified muramyl dipeptide (MurNAc-L-Ala-D-isoGln) derived from peptidoglycan as the essential structure in bacteria recognized by NOD2. Replacement of L-Ala for D-Ala or D-isoGln for L-isoGln eliminated the ability of muramyl dipeptide to stimulate NOD2, indicating stereoselective recognition. Muramyl dipeptide was recognized by NOD2 but not by TLR2 or co-expression of TLR2 with TLR1 or TLR6. NOD2 mutants associated with susceptibility to Crohn's disease were deficient in their recognition of muramyl dipeptide. Notably, peripheral blood mononuclear cells from individuals homozygous for the major disease-associated L1007fsinsC NOD2 mutation responded to lipopolysaccharide but not to synthetic muramyl dipeptide. Thus, NOD2 mediates the host response to bacterial muropeptides derived from peptidoglycan, an activity that is important for protection against Crohn's disease. Because muramyl dipeptide is the essential structure of peptidoglycan required for adjuvant activity, these results also have implications for understanding adjuvant function and effective vaccine development.     

Peptidoglycans synthesized by a membrane preparation of Micrococcus luteus.

By incubation of cell-free particulate preparations from Micrococcus luteus with nucleotidic precursors uridine 5'-diphosphate-N-acetylglucosamine and uridine 5'-diphosphate-N-acetylmuramic acid-L-Ala-D-iso-Glu-L-Lys-D-Ala-D-Ala, several types of peptidoglycans were obtained: soluble peptidoglycan, insoluble peptidoglycan bound to the membrane and solubilized by trypsin, and peptidoglycan, which remained insoluble after the action of trypsin. The structure of each type of peptidoglycan was studied by action of lytic enzymes and separation of the fragments on Sephadex. Soluble peptidoglycans consist of a mixture of un-cross-linked polymers of various molecular weights. Trypsin-solubilized peptidoglycans are also a mixture of polymers of various sizes. They contain a preponderance of un-cross-linked material and some bridges with dimer peptides. Insoluble peptidoglycans, after the action of trypsin, contain about 50% of un-cross-linked peptide residues; in the other moiety, peptide units are cross-linked by D-Ala leads to L-Lys and D-Ala leads to L-Ala bonds which characterize the natural peptidoglycan. Therefore, the cell-free particulate preparation possesses the whole enzymatic system necessary for synthesis of cross-linked peptidoglycan.     

Crystallographic and molecular dynamics analysis of loop motions unmasking the peptidoglycan-binding site in stator protein MotB of flagellar motor

Background

The C-terminal domain of MotB (MotB-C) shows high sequence similarity to outer membrane protein A and related peptidoglycan (PG)-binding proteins. It is believed to anchor the power-generating MotA/MotB stator unit of the bacterial flagellar motor to the peptidoglycan layer of the cell wall. We previously reported the first crystal structure of this domain and made a puzzling observation that all conserved residues that are thought to be essential for PG recognition are buried and inaccessible in the crystal structure. In this study, we tested a hypothesis that peptidoglycan binding is preceded by, or accompanied by, some structural reorganization that exposes the key conserved residues.

Methodology/Principal Findings

We determined the structure of a new crystalline form (Form B) of Helicobacter pylori MotB-C. Comparisons with the existing Form A revealed conformational variations in the petal-like loops around the carbohydrate binding site near one end of the β-sheet. These variations are thought to reflect natural flexibility at this site required for insertion into the peptidoglycan mesh. In order to understand the nature of this flexibility we have performed molecular dynamics simulations of the MotB-C dimer. The results are consistent with the crystallographic data and provide evidence that the three loops move in a concerted fashion, exposing conserved MotB residues that have previously been implicated in binding of the peptide moiety of peptidoglycan.

Conclusion/Significance

Our structural analysis provides a new insight into the mechanism by which MotB inserts into the peptidoglycan mesh, thus anchoring the power-generating complex to the cell wall.     

The metabolic fate of 14C-labeled immunoadjuvant peptidoglycan monomer. II. In vitro studies

Peptidoglycan monomer (GlcNAc-MurNAc-L-Ala-D-isoglutamine-meso-diaminopimelic acid-D-Ala-D-Ala), labeled with 14C both in the disaccharide and pentapeptide portions, was incubated with slices of mouse liver, kidney or spleen as well as with mouse and human blood, blood cells plasma and serum. Peptidoglycan monomer was isolated unchanged after incubations with mouse organs and blood cells. However, upon incubation with mouse or human blood, 10-50% of the peptidoglycan monomer underwent hydrolysis to the corresponding disaccharide and pentapeptide. After incubations with plasma and serum more than 90% of the [14C]peptidoglycan monomer was metabolized: about 50% of the administered radioactive dose was recovered in the disaccharide unit and about 35% in the pentapeptide part. These results suggest that in blood, plasma and serum of mouse and man, an N-acetylmuramoyl-L-alanine amidase (mucopeptide amidohydrolase, EC 3.5.1.28) exists which splits the amide bond between the lactyl carboxyl group of the muramyl residue and the amino group of the peptide moiety in the peptidoglycan molecule.     

Towards artificial ribonucleases: the sequence-specific cleavage of RNA in a duplex.

Lanthanide complexes covalently attached to oligonucleotides have been shown to cleave RNA in a sequence-specific manner. Efficient cleavage, however, is at present limited to single-stranded RNA regions, as RNA in a duplex is considerably more resistant to strand scission. To overcome this limitation, we have designed and synthesised artificial nucleases comprising lanthanide complexes covalently linked to oligodeoxyribonucleotides which cleave a partially complementary RNA at a bulged site, in the duplex region. Strand scission occurs at or near the bulge. Cleavage of the RNA target by the metal complex can be addressed via the major or the minor groove. In an example of a competitive situation, where the cleavage moiety has access to both a bulge and a single-strand region, transesterification at the bulge is favoured. Such artificial ribonucleases may find application as antisense agents and as tools in molecular biology. In addition, the results may have importance for the design of artificial ribonucleases which are able to act with catalytic turnover.     

A search for quantum mechanical methods suitable for the conformational analysis of models related to some inverse agonists of the benzodiazepine receptor

The target of this work consists in a search, among several methods of quantum mechanical calculations, for the most suitable one (both with regard to accuracy and speed) for doing conformational analysis on models related to molecules belonging to a group of indol-3-yl glyoxylyl derivatives, many of which behave as ligands of the benzodiazepine receptor (BzR). Among the wide variety of ligands of the BzR, -carboline derivatives are included, many of which show a pharmacological profile similar to the one exhibited by compounds of interest to us. A structure analogy between our compounds and -carboline derivatives could be hypothesized, depending upon the preferred arrangement of the investigated molecules with respect to the dihedral angles of the indol glyoxylyl moiety. Therefore a potential energy surface scan has been carried out on selected models either by the quantum mechanical semiempirical methods MNDO, AM1, PM3 (by using the programs included in themopac package) or by a quantum mechanical SCFab initio method (by using thegaussian-80 program), both in order to find support for the choice of the more suitable semiempirical method, and in order to verify a structural analogy between our compounds and the -carboline ring. The results showed that AM1 and PM3, unlike MNDO, seem to be suitable semiempirical methods for doing potential energy surface scans on this kind of molecule. The preferred arrangement showed by the models with respect to the indol glyoxylyl moiety appeared to support the hypothesis about the structure analogy between the investigated ligands and -carboline derivatives.