The direction of glycan synthesis in a bacterial peptidoglycan

A cell-free membrane preparation from a poorly lytic mutant of Bacillus licheniformis was used to synthesize radioactive peptidoglycan. The product was apparently un-cross-linked. When UDP-N-acetyl[(14)C]glucosamine was used and the final peptidoglycan subjected to Smith degradation, no radioactive glycerol was found. On the other hand, when peptidoglycan labelled with meso-diamino[(14)C]pimelic acid was first hydrolysed in 0.1m-HCl at 60 degrees C for 2h and then subjected to alkaline conditions, radioactive lactyl-peptides were eliminated. The proportion of radioactive lactyl-peptide decreased with increasing time of incorporation. It is concluded that the glycan chains grow by extension at their reducing ends while remaining attached by some linkage labile to mild acid, such as a glycosyl link to undecaprenol pyrophosphate.     

Formation of the glycan chains in the synthesis of bacterial peptidoglycan

The main structural features of bacterial peptidoglycan are linear glycan chains interlinked by short peptides. The glycan chains are composed of alternating units of N-acetylglucosamine (GlcNAc) and N-acetylmuramic acid (MurNAc), all linkages between sugars being beta,1-->4. On the outside of the cytoplasmic membrane, two types of activities are involved in the polymerization of the peptidoglycan monomer unit: glycosyltransferases that catalyze the formation of the linear glycan chains and transpeptidases that catalyze the formation of the peptide cross-bridges. Contrary to the transpeptidation step, for which there is an abundant literature that has been regularly reviewed, the transglycosylation step has been studied to a far lesser extent. The aim of the present review is to summarize and evaluate the molecular and cellullar data concerning the formation of the glycan chains in the synthesis of peptidoglycan. Early work concerned the use of various in vivo and in vitro systems for the study of the polymerization steps, the attachment of newly made material to preexisting peptidoglycan, and the mechanism of action of antibiotics. The synthesis of the glycan chains is catalyzed by the N-terminal glycosyltransferase module of class A high-molecular-mass penicillin-binding proteins and by nonpenicillin-binding monofunctional glycosyltransferases. The multiplicity of these activities in a given organism presumably reflects a variety of in vivo functions. The topological localization of the incorporation of nascent peptidoglycan into the cell wall has revealed that bacteria have at least two peptidoglycan-synthesizing systems: one for septation, the other one for elongation or cell wall thickening. Owing to its location on the outside of the cytoplasmic membrane and its specificity, the transglycosylation step is an interesting target for antibacterials. Glycopeptides and moenomycins are the best studied antibiotics known to interfere with this step. Their mode of action and structure-activity relationships have been extensively studied. Attempts to synthesize other specific transglycosylation inhibitors have recently been made.     

The different shapes of cocci

The shape of bacteria is determined by their cell wall and can be very diverse. Even among genera with the suffix 'cocci', which are the focus of this review, different shapes exist. While staphylococci or Neisseria cells, for example, are truly round-shaped, streptococci, lactococci or enterococci have an ovoid shape. Interestingly, there seems to be a correlation between the shape of an organism and its set of penicillin-binding proteins--the enzymes that assemble the peptidoglycan, the main constituent of the cell wall. While only one peptidoglycan biosynthesis machinery seems to exist in staphylococci, two of these machineries are proposed to function in ovoid-shaped bacteria, reinforcing the intrinsic differences regarding the morphogenesis of different classes of cocci. The present review aims to integrate older ultra-structural data with recent localization studies, in order to clarify the relation between the mechanisms of cell wall synthesis and the determination of cell shape in various cocci.     

The prevalence of gentamicin 2'-N-acetyltransferase in the Proteeae and its role in the O-acetylation of peptidoglycan

Abstract The prevalence of aac(2')-Ia , a gene coding for gentamicin 2'-JV-acetyltransferase in Providenda stuartii , among species of the Proteeae was investigated to determine if it is a common resistance factor and whether the correlation observed in P. stuartii between its expression and the levels of peptidoglycan O -acetylation represents a general feature of bacteria producing this form of modified peptidoglycan. An evaluation of the MICs of gentamicin for each of the species of the Proteeae did not reveal any apparent relationship between resistance and the degree of O-acetylation of peptidoglycan. The entire aac(2')-Ia gene was used as a probe in Southern hybridization experiments against genomic DNA from each species of the Proteeae. A sequence with strong homology to aac(2')-Ia was present only in Proteus penneri while weak hybridization was also observed to the restriction digested DNA from Providenda rettgeri . Other bacteria that O -acetylate peptidoglycan were also screened with this probe and a homologous DNA sequence was only found in Neisseria subflava . These data suggest that AAC(2')-Ia may contribute to the rO -acetylation of peptidoglycan in P. stuartii , but a more specific enzyme must also be produced for this function.     

An Arabidopsis homolog of the bacterial peptidoglycan synthesis enzyme MurE has an essential role in chloroplast development

Enzymes encoded by bacterial MurE genes catalyze the ATP-dependent formation of uridine diphosphate- N -acetylmuramic acid-tripeptide in bacterial peptidoglycan biosynthesis. The Arabidopsis thaliana genome contains one gene with homology to the bacterial MurE : AtMurE . Under normal conditions AtMurE is expressed in leaves and flowers, but not in roots or stems. Sequence-based predictions and analyses of GFP fusions of the N terminus of AtMurE, as well as the full-length protein, suggest that AtMurE localizes to plastids. We identified three T-DNA-tagged and one Ds -tagged mutant alleles of AtMurE in A. thaliana . All four alleles show a white phenotype, and A. thaliana antisense AtMurE lines showed a pale-green phenotype. These results suggest that AtMurE is involved in chloroplast biogenesis. Cells of the mutants were inhibited in thylakoid membrane development. RT-PCR analysis of the mutant lines suggested that the expression of genes that depend on a multisubunit plastid-encoded RNA polymerase was decreased. To analyze the functional relationships between the MurE genes of cyanobacteria, the moss Physcomitrella patens and higher plants, a complementation assay was carried out with a P. patens ( Pp ) MurE knock-out line, which exhibits a small number of macrochloroplasts per cell. Although the Anabaena MurE, fused with the N-terminal region of PpMurE, complemented the macrochloroplast phenotype in P. patens , transformation with AtMurE did not complement this phenotype. These results suggest that AtMurE is functionally divergent from the bacterial and moss MurE proteins.     

The role of peptidoglycan structure and structural dynamics during endospore dormancy and germination

Dormant, bacterial endospores are the most resistant living structures known. The spore cell wall (cortex) maintains dormancy, core dehydration, and heat resistance. The cortex peptidoglycan has a unique, spore specific structure that enables it to fulfill its role. The cross-linking index of spore cortex peptidoglycan is very low, occurring at only 2.9% of the muramic acid residues compared to 33% in vegetative cells. The level of cross-linking of the cortex may be important in maintaining spore dormancy and heat resistance. Approximately 50% of the muramic acid residues in spore cortex are substituted with muramic -lactam. This modification is spore specific and is the major characteristic feature of the cortex. The muramic -lactam has no apparent role in establishing core dehydration, maintaining dormancy or heat resistance. However, the muramic -lactam residues are necessary for spore cortex hydrolysis during germination. They constitute part of the substrate recognition profile of the germination specific lytic enzymes (GSLEs) which are responsible for cortex hydrolysis.Germination results in loss of dormant spore properties and hydrolysis of the cortex is essential for later germination events and outgrowth. Application of muropeptide analysis to determine peptidoglycan structural dynamics during germination has revealed an unexpected degree of complexity in peptidoglycan hydrolysis. At least three hydrolytic activities, an N-acetyl glucosaminidase, a lytic transglycosylase and a possible amidase, are involved. A non-hydrolytic acitivity, likely to be an epimerase of muramic acid also occurs early during germination.The lytic transglycosylase generates anhydro-muropeptides which are released during germination and may be recycled during outgrowth to form part of the new vegetative cell wall.     

Synthesis of an octamannosyled glycan chain, the key oligosaccharide structure in ER-associated degradation

The high-mannose type decasaccharide (Man(8)GlcNAc(2)), the proposed ligand of ER residing mannosidase-like proteins (MLP), and its monoglycosylated homologue (alpha-Glc(1)Man(8)GlcNAc(2)) were synthesized. The oligosaccharide assembly was performed in a convergent and stereoselective manner, using three oligosaccharide components, a core trisaccharide having a beta-mannoside bond, a liner mannotriose, and a branched mannotetraose.     

Structural basis of high-affinity glycan recognition by bacterial and fungal lectins

The structural diversity of bacterial and fungal lectins has been highlighted during the past few years. Some of the new structures reproduce folds previously observed in plants or mammals, but many constitute new folds that have never been observed before, either at all or not with a lectin function, testifying to the increasing diversity. The novelty of the new structures is greater at the level of the sugar-binding sites, with some bacterial lectins displaying unusually high affinity for oligosaccharides and even monosaccharides. Analysis of the thermodynamic contributions to the energy of binding gives clues to the strategies used by bacteria to recognise and attach to their host.     

Folds and activities of peptidoglycan amidases

Bacterial peptidoglycan amidases are a large and diverse group of enzymes. During the last few years, genomic sequence information has accumulated to an extent such that lists of proven or predicted peptidoglycan amidases can now be expected to be fairly complete. Moreover, representative crystal structures for most groups of phylogenetically related peptidoglycan amidases have been solved. Here, sequence and structural information is combined with published biochemical findings to demonstrate that (a) peptidoglycan amidases have evolved for almost every bond that occurs in peptidoglycan, (b) there are enzymes that share the fold, yet cleave different bonds and (c) there are enzymes that have entirely different folds and must have evolved independently, and yet cleave the same peptide bond. It is shown that despite these complications, some rules can be deduced from the available biochemical and structural information that can be useful to predict the specificity of hypothetical peptidoglycan hydrolases, for which only sequence information is available.     

An anionic inositol phosphate glycan pseudotetrasaccharide exhibits high insulin-mimetic activity in rat adipocytes

Inositol phosphate glycan pseudotetrasaccharides consisting of man-(1-6)-man-(1-4)-glcN-(,β1-6)-myo-inositol-1,2-cyclic phosphate possessing a sulfate group at either O-6 (compounds 3,β) or O-2 (compounds 4,β) of the terminal mannose have been prepared. Compound 4 was able to stimulate lipogenesis in native rat adipocytes to 78% of the maximal insulin response (MIR) with an EC₅₀ of 1.1 μM. The other compounds exhibited lower maximal stimulations (47–63% MIR) and higher EC₅₀ values (9.5–10.6 μM).     

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.     

Molecular modeling of a disialylated monofucosylated biantennary glycan of theN-acetyllactosamine type

The conformations of a disialylated monofucosylated biantennary glycan of theN-acetyllactosamine type were analysed using the Tripos 5.3 force field from the Sybyl software currently used for molecular modelling. The conformation of each glycosidic linkage was calculated when included in oligosaccharide structures of up to 5 units and the influence of the glycosidic environment on the overall structure was measured. The study clearly shows that the conformation of a branched glycan cannot result from the simple addition of the different low energy conformers of each of the glycosidic linkages constituting the glycan structure. The asymmetrical conformation of the two antennae was demonstrated. The lowest energy conformations of the overall glycan structure were built and classified into 5 main models: the Y, T, bird and broken wing conformations already described and a new one called the back folded wing conformation.     

长双歧杆菌完整肽聚糖对小鼠免疫功能的影响

目的比较长双歧杆菌及其完整肽聚糖的免疫调节作用。方法通过研究长双歧杆菌完整肽聚糖对植瘤小鼠淋巴细胞的转化、抑瘤率、生命延长期以及对细胞Bcl-2和Bax表达的影响来探讨它们对小鼠细胞免疫的调节作用。结果与对照组相比,完整肽聚糖使淋巴细胞转化增加、抑瘤率提高、延长生命期增加、Bcl-2阳性表达率减小而Bax基因表达增加。结论长双歧杆菌与其完整肽聚糖均有抑制S180肿瘤的作用,但完整肽聚糖的效果优于长双歧杆菌。     

Efficient and quantitative incorporation of diaminopimelic acid into the peptidoglycan of Salmonella typhimurium

Abstract Diaminopimelic acid is incorporated into the peptidoglycan of Salmonella typhimurium in an efficient and quantitative manner. The amount of DAP incorporated is similar to the number of molecules estimated to exist in the Salmonella cell wall. In contrast, strains of E. coli , including those most used for studies of cell wall synthesis, are much less efficient in the incorporation of diaminopimelic acid. The lysine-requiring strains of E. coli appear to excrete diaminopimelic acid related material during growth and this accounts, in part, for the inefficient incorporation of radioactive diaminopimelic acid into Escherichia strains. In addition, the Escherichia strains are much less permeable to DAP than Salmonella strains. Cysteine and cystine inhibit the incorporation of DAP into the cell and this result suggests that Salmonella uses the cystine uptake system to allow DAP into the cell.     

GLYDE-an expressive XML standard for the representation of glycan structure

The amount of glycomics data being generated is rapidly increasing as a result of improvements in analytical and computational methods. Correlation and analysis of this large, distributed data set requires an extensible and flexible representational standard that is also ‘understood’ by a wide range of software applications. An XML-based data representation standard that faithfully captures essential structural details of a glycan moiety along with additional information (such as data provenance) to aid the interpretation and usage of glycan data, will facilitate the exchange of glycomics data across the scientific community. To meet this need, we introduce GLYcan Data Exchange (GLYDE) standard as an XML-based representation format to enable interoperability and exchange of glycomics data. An online tool (http://128.192.9.86/stargate/formatIndex.jsp) for the conversion of other representations to GLYDE format has been developed.     

Cytoplasmic steps of peptidoglycan biosynthesis

The biosynthesis of bacterial cell wall peptidoglycan is a complex process that involves enzyme reactions that take place in the cytoplasm (synthesis of the nucleotide precursors) and on the inner side (synthesis of lipid-linked intermediates) and outer side (polymerization reactions) of the cytoplasmic membrane. This review deals with the cytoplasmic steps of peptidoglycan biosynthesis, which can be divided into four sets of reactions that lead to the syntheses of (1) UDP-N-acetylglucosamine from fructose 6-phosphate, (2) UDP-N-acetylmuramic acid from UDP-N-acetylglucosamine, (3) UDP-N-acetylmuramyl-pentapeptide from UDP-N-acetylmuramic acid and (4) D-glutamic acid and dipeptide D-alanyl-D-alanine. Recent data concerning the different enzymes involved are presented. Moreover, special attention is given to (1) the chemical and enzymatic synthesis of the nucleotide precursor substrates that are not commercially available and (2) the search for specific inhibitors that could act as antibacterial compounds.     

Glycosyl phosphatidylinositol (GPI)/inositolphosphate glycan (GPI): An intracellular signalling system involved in the control of thyroid cell proliferation

In porcine thyrocytes, TSH alone does not induce cell growth. Recently, it has been demonstrated that acute stimulation by TSH of porcine thyrocytes leads to release an inositolphosphate glycan (IPG) described as a putative second messenger for various growth factors in different cell types. IPG isolated from porcine thyrocytes induces proliferation of fibroblasts EGFR T17 and porcine thyrocytes. In porcine thyrocytes we have confirmed that cell growth requires the presence of both TSH and insulin. This effect is reproduced by 8-bromo cyclic AMP suggesting a mediation by intracellular cyclic AMP. Cooperative effects between 8-bromo cyclic AMP and IPG have also been evidenced and are in favour of a crosstalk between distinct signalling pathways.     

Activities and regulation of peptidoglycan synthases

Peptidoglycan (PG) is an essential component in the cell wall of nearly all bacteria, forming a continuous, mesh-like structure, called the sacculus, around the cytoplasmic membrane to protect the cell from bursting by its turgor. Although PG synthases, the penicillin-binding proteins (PBPs), have been studied for 70 years, useful in vitro assays for measuring their activities were established only recently, and these provided the first insights into the regulation of these enzymes. Here, we review the current knowledge on the glycosyltransferase and transpeptidase activities of PG synthases. We provide new data showing that the bifunctional PBP1A and PBP1B from Escherichia coli are active upon reconstitution into the membrane environment of proteoliposomes, and that these enzymes also exhibit DD-carboxypeptidase activity in certain conditions. Both novel features are relevant for their functioning within the cell. We also review recent data on the impact of protein–protein interactions and other factors on the activities of PBPs. As an example, we demonstrate a synergistic effect of multiple protein–protein interactions on the glycosyltransferase activity of PBP1B, by its cognate lipoprotein activator LpoB and the essential cell division protein FtsN.     

Comparison of two approaches for quantitative O-linked glycan analysis used in characterization of recombinant proteins

The principal aim of this study was to demonstrate the optimization and fine-tuning of quantitative and nonselective analysis of O-linked glycans released from therapeutic glycoproteins. Two approaches for quantitative release of O-linked glycans were examined: ammonia-based β-elimination and hydrazinolysis deglycosylation strategies. A significant discrepancy in deglycosylation activity was observed between the ammonia-based and hydrazinolysis procedures. Specifically, the release of O-glycans from glycoproteins was approximately 20 to 30 times more efficient with hydrazine compared with ammonia-based β-elimination reagent. In addition, the ammonia-based reagent demonstrated bias in the release of particular glycan species. A robust quantitative hydrazinolysis procedure was developed for characterization of O-glycans. The method performance parameters were evaluated. It was shown that this procedure is superior for quantitative nonselective release of O-glycans. Identity confirmation and structure elucidation of O-glycans from hydrophilic interaction chromatography (HILIC) fractions was also demonstrated using linear ion trap Fourier transform mass spectrometry (LTQ FT MS) with mass accuracy below 1 ppm.     

Crystal structure of the peptidoglycan recognition protein at 1.8 A resolution reveals dual strategy to combat infection through two independent functional homodimers

The mammalian peptidoglycan recognition protein-S (PGRP-S) binds to peptidoglycans (PGNs), which are essential components of the cell wall of bacteria. The protein was isolated from the samples of milk obtained from camels with mastitis and purified to homogeneity and crystallized. The crystals belong to orthorhombic space group I222 with a = 87.0 Å, b = 101.7 Å and c = 162.3 Å having four crystallographically independent molecules in the asymmetric unit. The structure has been determined using X-ray crystallographic data and refined to 1.8 Å resolution. Overall, the structures of all the four crystallographically independent molecules are identical. The folding of PGRP-S consists of a central β-sheet with five β-strands, four parallel and one antiparallel, and three α-helices. This protein fold provides two functional sites. The first of these is the PGN-binding site, located on the groove that opens on the surface in the direction opposite to the location of the N terminus. The second site is implicated to be involved in the binding of non-PGN molecules, it also includes putative N-terminal segment residues (1-31) and helix α2 in the extended binding. The structure reveals a novel arrangement of PGRP-S molecules in which two pairs of molecules associate to form two independent dimers. The first dimer is formed by two molecules with N-terminal segments at the interface in which non-PGN binding sites are buried completely, whereas the PGN-binding sites of two participating molecules are fully exposed at the opposite ends of the dimer. In the second dimer, PGN-binding sites are buried at the interface while non-PGN binding sites are fully exposed at the opposite ends of the dimer. This form of dimeric arrangement is unique and seems to be aimed at enhancing the capability of the protein against specific invading bacteria. This mode of functional dimerization enhances efficiency and specificity, and is observed for the first time in the family of PGRP molecules.