Structure of the peptide network of pneumococcal peptidoglycan

The peptide network of Streptococcus pneumoniae cell walls was solubilized using the pneumococcal autolytic amidase (N-acetylmuramoyl-L-alanine amidase, EC 3.5.1.28). The peptide material was fractionated into size classes by gel filtration followed by reverse-phase high-performance liquid chromatography which resolved the peptide population into over 40 fractions. About 40% of the lysines present participate in cross-links between stem peptides. The main components (3 monomers, 5 dimers, and 2 trimers), accounting for 77% of all the wall peptides, were purified. Their structures were determined using a combination of amino acid and end-group analysis, mass spectrometry, and gas-phase sequencing. Two different types of cross-links between stem peptides were found. In the most abundant type there is an alanylserine cross-bridge between the alanine in position 4 of the donor stem peptide and the lysine at position 3 of the acceptor peptide, as in type A3 peptidoglycan. In the second type of cross-link there is no intervening cross-bridge, as in the type A1 peptidoglycan of Gram-negative bacteria. The data indicate that pneumococcal peptidoglycan has a structural complexity comparable to that recently shown in some Gram-negative species.     

Peptidoglycan cross-linking and teichoic acid attachment in Streptococcus pneumoniae.

Autolysin-defective pneumococci continue to synthesize both peptidoglycan and teichoic acid polymers (Fischer and Tomasz, J. Bacteriol. 157:507-513, 1984). Most of these peptidoglycan polymers are released into the surrounding medium, and a smaller portion becomes attached to the preexisting cell wall. We report here studies on the degree of cross-linking, teichoic acid substitution, and chemical composition of these peptidoglycan polymers and compare them with normal cell walls. peptidoglycan chains released from the penicillin-treated pneumococci contained no attached teichoic acids. The released peptidoglycan was hydrolyzed by M1 muramidase; over 90% of this material adsorbed to vancomycin-Sepharose and behaved like disaccharide-peptide monomers during chromatography, indicating that the released peptidoglycan contained un-cross-linked stem peptides, most of which carried the carboxy-terminal D-alanyl-D-alanine. The N-terminal residue of the released peptidoglycan was alanine, with only a minor contribution from lysine. In addition to the usual stem peptide components of pneumococcal cell walls (alanine, lysine, and glutamic acid), chemical analysis revealed the presence of significant amounts of serine, aspartate, and glycine and a high amount of alanine and glutamate as well. We suggest that these latter amino acids and the excess alanine and glutamate are present as interpeptide bridges. Heterogeneity of these was suggested by the observation that digestion of the released peptidoglycan with the pneumococcal murein hydrolase (amidase) produced peptides that were resolved by ion-exchange chromatography into two distinct peaks; the more highly mobile of these was enriched with glycine and aspartate. The peptidoglycan chains that became attached to the preexisting cell wall in the presence of penicillin contained fewer peptide cross-links and proportionally fewer attached teichoic acids than did their normal counterparts. The normal cell wall was heavily cross-linked, and the cross-linked peptides were distributed equally between the teichoic acid-linked and teichoic acid-free fragments.     

Separation of abnormal cell wall composition from penicillin resistance through genetic transformation of Streptococcus pneumoniae.

Compared with most penicillin-susceptible isolates of Streptococcus pneumoniae, penicillin-resistant clinical isolate Hun 663 contains mosaic penicillin-binding protein (PBP) genes encoding PBPs with reduced penicillin affinities, anomalous molecular sizes, and also cell walls of unusual chemical composition. Chromosomal DNA prepared from Hun 663 was used to transform susceptible recipient cells to donor level penicillin resistance, and a resistant transformant was used next as the source of DNA in the construction of a second round of penicillin-resistant transformants. The greatly reduced penicillin affinity of the high-molecular-weight PBPs was retained in all transformants through both genetic crosses. On the other hand, PBP pattern and abnormal cell wall composition, both of which are stable, clone-specific properties of strain Hun 663, were changed: individual transformants showed a variety of new, abnormal PBP patterns. Furthermore, while the composition of cell walls resembled that of the DNA donor in the first-round transformants, it became virtually identical to that of susceptible pneumococci in the second-round transformants. The findings indicate that genetic elements encoding the low affinity of PBPs and the penicillin resistance of the bacteria are separable from determinants that are responsible for the abnormal cell wall composition that often accompanies penicillin resistance in clinical strains of pneumococci.     

Fractionation and partial characterization of the products of autolysis of cell walls of Bacillus subtilis

Young, Frank E. (Western Reserve University, Cleveland, Ohio). Fractionation and partial characterization of the products of autolysis of cell walls of Bacillus subtilis. J. Bacteriol. 92:839-846. 1966.-Autolysis of the cell wall of Bacillus subtilis by an indigenous autolytic enzyme results in solubilization of 90% of the cell wall. The solubilized cell wall (supernatant fraction) was fractionated by the combination of ion-exchange chromatography on diethylaminoethyl cellulose and gel filtration on Sephadex G-25 into polysaccharides (composed of N-acyl glucosamine and N-acyl muramic acid), mucopeptides, peptides, and teichoic acid. The chemical composition of the products of autolysis confirms the proposed mechanism of autolysis and establishes the autolytic enzyme as an N-acyl muramyl-l-alanine amidase. The heteropolymers in the cell wall are linked by peptide bridges. Two peptides which account for 70% of the peptides of the cell wall have a molar ratio of 1.0:0.9:1.3 for diaminopimelic acid, glutamic acid, and alanine, respectively. Other minor peptides contain diaminopimelic acid, glutamic acid, and alanine in molar ratios of 1.0:0.9:1.5, 1.0:0.5:1.0, and 1.0:1.5:1.7, respectively. The procedures employed in this study should be applicable to the fractionation of heteropolymers in cell walls of other gram-positive organisms and thereby aid in the study of the structure of antigenic determinants and endotoxins.     

Chemical and ultrastructural studies on the cell wall ofStaphylococcus simulans biovarstaphylolyticus

Cell walls of strains ofStaphylococcus simulans biovarstaphylolyticus andS. aureus FDA 209P were compared ultrastructurally and chemically to investigate the mechanism of resistance of this strain ofS. simulans to its own staphylolytic endopeptidase. Chemical analysis of the peptidoglycans of the various strains examined showed that cells that were more resistant to lysis by the endopeptidase had lower glycine/serine ratios in their cross bridges and that, within a species, the more resistant cells had either fewer residues in these cross bridges or fewer cross bridges. Ultrastructural studies showed that cell wall thickness was not involved in resistance to the enzyme. Comparisons of the endopeptidase susceptibility of intact cells and isolated peptidoglycans from these cells suggested that the three-dimensional structure of the cell wall may play a role in resistance to lysis by the endopeptidase.     

Naturally occurring peptidoglycan variants of Streptococcus pneumoniae.

Analysis by high-performance liquid chromatography of the stem peptide composition of cell walls purified from a large number of pneumococcal strains indicates that these bacteria produce a highly conserved species-specific peptidoglycan independent of serotype, isolation date, and geographic origin. Characteristic features of this highly reproducible peptide pattern are the dominance of linear stem peptides with a monomeric tripeptide, a tri-tetra linear dimer, and two indirectly cross-linked tri-tetra dimers being the most abundant components. Screening of strains with the high-performance liquid chromatography technique has identified two naturally occurring peptidoglycan variants in which the species-specific stem peptide composition was replaced by two drastically different and distinct stem peptide patterns, each unique to the particular clone of pneumococci producing it. Both isolates were multidrug resistant, including resistance to penicillin. In one of these clones--defined by multilocus enzyme analysis and pulsed-field gel electrophoresis of the chromosomal DNAs--the linear stem peptides were replaced by branched peptides that most frequently carried an alanyl-alanine substituent on the epsilon amino group of the diamino acid residue. In the second clone, the predominant stem peptide species replacing the linear stem peptides carried a seryl-alanine substituent. The abnormal peptidoglycans may be related to the altered substrate preference of transpeptidases (penicillin-binding proteins) in the pneumococcal variants.     

Cell wall components of gramicidin S resistant Staphylococcus aureus]

Comparative study of two staphylococcus aureus 209P strains--resistant and susceptible to gramicidin S demonstrated that peptidoglycanes of two strains differ by ratio glycine/serine at peptide bridges. Besides peptidoglycanes significantly differ by amidation of alfa-carboxyles of glutamic acid in muropeptide. This peptidoglycane modification of resistant cells along with enhanced content of etherized D-alanine in teichoic acid provides lower negative charge of cell wall components. It may influence the cell wall ability to react with positively charged gramicidin molecules. It was shown that isolated cell walls and peptidoglycane of resistant cells binds significantly less gramicidin than cell walls and peptodoglyce of susceptable cells. Simultaneous determination of gramicidin binding by intact S. aureus cells and their killing revealed that lower ability of resistant cells to bind gramicidin is significant but not critical factor of gramicidin resistance.     

Composition and properties of the outer cell wall layer in Bacillus brevis--the producer of gramicidin S

Two membrane antigens were found by cross immunoelectrophoresis in the cell walls of Bacillus brevis var. G.-B., R form, which started to synthesize gramicidin S (20 mg per 1 ml of cultural broth). The cell wall contained no membrane components in cells at the beginning of the logarithmic growth phase. The protein with a molecular mass of 100 kDa is a component of the cell wall outer layer. The protein is not digested by trypsin or pronase when it comprises the cell walls of cells synthesizing gramicidin S. In the preparation of isolated cell walls, this protein becomes susceptible to the action of the above proteases only when the peptidoglycan layer is broken down by lysozyme. Electron microscopy of cells treated with proteases and shadowed with a metal revealed that many cells lacked the cytoplasm. Therefore, the outer layer of B. brevis R cell wall contains small regions susceptible to the action of protease along with regions composed of the 100 kDa protein and resistant to these enzymes. It is possible that the small regions contain membrane components.     

Cleavage and resynthesis of peptide cross bridges in Escherichia coli murein.

In Escherichia coli, peptide cross bridges in the murein undergo turnover after they are synthesized. Peptide cross bridges formed in the presence of [3H]diaminopimelic acid were found to lose 3H label from their donor peptides after the [3H]diaminopimelic acid was removed from the growth medium. There was a corresponding increase in the amount of 3H label in acceptor peptides so that the total amount of label in the peptide cross bridges remained constant. Our explanation of this observation is that the cross bridges are cleaved by the cell, and the original 3H-labeled donor peptides are incorporated into new cross bridges. Since these 3H-labeled peptides are now only tetrapeptides, they can only be used as acceptors when new cross bridges are formed.     

Mechanism of pneumococcal cell wall degradation in vitro and in vivo.

We compared the products of autolytic amidase-catalyzed wall degradation in vivo (in penicillin-induced lysis) and in vitro. Pneumococci labeled in their cell wall stem peptides by radioactive lysine were treated with penicillin, and the nature of wall degradation products released to the medium during lysis of the bacteria was determined. At early times of lysis (20% loss of wall label), virtually all the radioactive peptides released (greater than 94%) were of high molecular size and were still attached to glycan and teichoic acid. At times of more extensive bacterial lysis (56%), progressively larger and larger fractions of the released peptides became free, i.e., detached from glycan and teichoic acid. Analysis of the nondegraded residual wall material by high-resolution high-pressure liquid chromatography revealed that this in vivo-triggered autolysis did not involve selective hydrolysis of some of the chemically distinct stem peptides. Parallel in vitro experiments yielded completely different results. Purified pneumococcal cell walls labeled with radioactive lysine were treated in vitro with low concentrations of pure amidase, and the nature of wall degradation products released during limited hydrolysis and after more extensive degradation was determined. In sharp contrast to the in vivo experiments, the main products of in vitro hydrolysis were free peptides. After a short treatment with amidase (resulting in a 20% loss of label), the material released was enriched for the monomeric stem peptides. At all times of hydrolysis (including the time of extensive degradation), only a relatively small fraction of the released wall peptides was covalently attached to glycan and teichoic acid components (17% as compared with 40% in the intact cell wall). We propose that the in vivo-triggered amidase activity first attacks the amide bonds in some strategically located (or unprotected) stem peptides that hold large segments of cell wall material together. The observations indicate that the in vivo activity of the pneumococcal autolysin is under topographic constraints.     

Attenuation of penicillin resistance in a peptidoglycan O-acetyl transferase mutant of Streptococcus pneumoniae

The level of penicillin resistance in clinical isolates of Streptococcus pneumoniae depends not only on the reduced affinity of penicillin binding proteins (PBPs) but also on the functioning of enzymes that modify the stem peptide structure of cell wall precursors. We used mariner mutagenesis in search of additional genetic determinants that may further attenuate the level of penicillin resistance in the bacteria. A mariner mutant of the highly penicillin-resistant S. pneumoniae strain Pen6 showed reduction of the penicillin minimum inhibitory concentration (MIC) from 6 to 0.75 microg ml(-1). Decrease in penicillin MIC was also observed upon introduction of the mutation (named provisionally adr, for attenuator of drug resistance) into representatives of major epidemic clones of penicillin-resistant pneumococci. Attenuation of resistance levels was specific for beta-lactams. The adr mutant has retained unchanged (low affinity) PBPs, unaltered murM gene and unchanged cell wall stem peptide composition, but the mutant became hypersensitive to exogenous lysozyme and complementation experiments showed that both phenotypes--reduced resistance and lysozyme sensitivity--were linked to the defective adr gene. DNA sequence comparison and chemical analysis of the cell wall identified adr as the structural gene of the pneumococcal peptidoglycan O-acetylase.     

X-ray Diffraction Studies of Cell Walls and Peptidoglycans from Gram-positive Bacteria

THE cell walls of Gram-positive bacteria consist principally of a water-insoluble polymer and peptidoglycan (synonyms, murein, mucopeptide, glycosaminopeptide), which in some cases accounts for as much as 90% of the cell wall. After other components (teichoic acid, teichuronic acid, polysaccharide or protein) have been gently removed from the cell walls, peptidoglycan remains as a cell-shaped structure at least 100 Å thick. We report here results of X-ray diffraction observations on whole cell walls and peptidoglycans of Staphylococcus aureus, Bacillus licheniformis and Micrococcus lysodeikticus. Chemical data shows that all the muramic acid residues in the glycan chains of the peptidoglycan of S. aureus are substituted with the peptide L Ala-D GluNH₂-L Lys-D Ala and that there is extensive cross linking by pentaglycine bridges between peptides on adjacent glycan chains^1,3. Such a peptidoglycan might be expected to have an ordered crystalline structure. On the contrary, peptidoglycans of the bacilli, in which the cross linking between peptides is direct and considerably less^4,5 might be expected to have a less ordered structure. The mode of packing of the glycan and peptide moieties has been considered by Kelemen and Rogers⁶. When the glycan chains are stacked in pairs, as in the analogous polysaccharide chitin⁷, the muramic acid residues are orientated in such a way as to allow a three-dimensional structure to be built. If the bulk of the peptides are then arranged in a pseudo β configuration, calculations show that the expected dimensions of the cell wall calculated from the model are of the right order and also such a model allows for the existence of extensive stabilizing hydrogen bonds between adjacent peptide chains.     

Relationship between lysostaphin endopeptidase production and cell wall composition in Staphylococcus staphylolyticus.

Mutants of Staphylococcus staphylolyticus incapable of producing an extracellular staphylolytic glycylglycine endopeptidase were isolated and found to have cells in the population susceptible to lysis by this enzyme, as did the wild-type organism under conditions in which the endopeptidase was not produced. These results suggest that cultures of this organism normally contain a heterogeneous population of cells with regard to cell wall composition and susceptibility to the enzyme. Production of the endopeptidase appears to act as a selective pressure which removes the susceptible cells in the population as the enzyme appears in the medium. A comparison of the peptidoglycan of the wild-type organism grown under conditions in which the endopeptidase was produced with that of this organism grown under nonproducing conditions and with those of endopeptidase-less mutants showed that in the presence of the endopeptidase the cell population had peptidoglycan with shorter peptide cross bridges and a greater percentage of serine in these cross bridges than was found in cells grown in the absence of the enzyme. The inability of the endopeptidase to hydrolyze glycylserine and serylglycine peptide bonds suggests that at least part of the resistance this organism has to the endopeptidase is due to relative amounts of serine found in the peptide cross bridges of some cells in the population.     

Amino-terminal and hydrophobic regions of the Chlamydomonas reinhardtii plastocyanin transit peptide are required for efficient protein accumulation in vivo

Nucleus-encoded chloroplast proteins of vascular plants are synthesized as precursors and targeted to the chloroplast by stroma-targeting domains in N-terminal transit peptides. Transit peptides in Chlamydomonas reinhardtii are considerably shorter than those in vascular plants, and their stroma-targeting domains have similarities to both mitochondrial and chloroplast targeting sequences. To examine Chlamydomonas transit peptide function in vivo, deletions were introduced into the transit peptide coding region of the petE gene, which encodes the thylakoid lumen protein plastocyanin (PC). The mutant petE genes were introduced into a plastocyanin-deficient Chlamydomonas strain, and transformants that accumulated petE mRNA were analyzed for PC accumulation. The most profound defects were observed with deletions at the N-terminus and those that extended into the hydrophobic region in the C-terminal half of the transit peptide. PC precursors were detected among pulse-labeled proteins in transformants with N-terminal deletions, suggesting that these precursors cannot be imported and are degraded in the cytosol. Intermediate PC species were observed in a transformant deleted for part of the hydrophobic region, suggesting that this protein is defective in lumen translocation and/or processing. Thus, despite its shorter length, the bipartite nature of the Chlamydomonas PC transit peptide appears similar to that of lumen-targeted proteins in vascular plants. Analysis of the synthesis, stability, and accumulation of PC species in transformants bearing deletions in the stroma-targeting domain suggests that specific regions probably have distinct roles in vivo. Abbreviations: cyt, cytochrome; ECL, enhanced chemiluminescence; LSU, large subunit; PC, plastocyanin; TP, transit peptide     

Mechanism of resistance to benzalkonium chloride by Pseudomonas aeruginosa

The mechanisms of resistance of Pseudomonas aeruginosa to benzalkonium chloride (BC) were studied. The effluence of cell components was observed in susceptible P. aeruginosa by electron microscopy, but resistant P. aeruginosa seemed to be undamaged. No marked changes in cell surface potential between Escherichia coli NIHJC-2 and a spheroplast strain were found. The contents of phospholipids (PL) and fatty and neutral lipids (FNL) in the cell walls of resistant P. aeruginosa were higher than those in the cell walls of susceptible P. aeruginosa. The amounts of BC adsorbed to PL and FNL of cell walls of BC-resistant P. aeruginosa were lower than those for BC-susceptible P. aeruginosa. Fifteen species of cellular fatty acids were identified by capillary gas chromatography and gas chromatography-mass spectrometry. The ability of BC to permeate the cell wall was reduced because of the increase in cellular fatty acids. These results suggested that the resistance of P. aeruginosa to BC is mainly a result of increased in the contents of PL and FNL. In resistant P. aeruginosa, the decrease in the amount of BC adsorbed is likely to be the result of increases in the contents of PL and FNL.     

Penicillin-induced changes in the cell wall composition of Staphylococcus aureus before the onset of bacteriolysis

To analyze if chemical cell wall alterations contribute to penicillin-induced bacteriolysis, changes in the amount, stability, and chemical composition of staphylococcal cell walls were investigated. All analyses were performed before onset of bacteriolysis i.e. during the first 60 min following addition of different penicillin G doses. Only a slight reduction of the amount of cell wall material incorporated after penicillin addition at the optimal lytic concentration was observed as compared to control cells. However, the presence of higher penicillin G concentrations reduced the incorporation of wall material progressively without bacteriolysis. Losses of wall material during isolation of dodecylsulfate insoluble cell walls were monitored to assess the stability of the wall material following penicillin addition. Wall material grown at the lytic penicillin concentration was least stable but about 30% of the newly incorporated wall material withstood even the harsh conditions of mechanical breakage and dodecylsulfate treatment. Dodecylsulfate insoluble cell walls were used for chemical analyses. While peptidoglycan chain length was unaffected in the presence of penicillin, other wall parameters were considerably altered: peptide cross-linking was reduced in the wall material synthesized after addition of penicillin; reductions from approx. 85% in controls to about 60% were similar for lytic and also for very high penicillin concentrations leading to nonlytic death. O-acetylation was also reduced after treatment with penicillin; this effect paralleled the occurence of subsequent bacteriolysis at different drug concentrations. The results are not consistent with hypotheses explaining penicillin-induced lysis as a result of an overall weakened cell wall structure or an overall activation of autolytic wall enzymes but not conflicting with the model that ascribes penicillin-induced bacteriolysis as the result of a very restricted, local perforation of the peripheral cell wall (murosome-induced bacteriolysis).Abbreviations CL Cross-linking - DNFB 2,4-dinitro-1-fluorobenzole - MIC Minimal inhibitory concentration - OD Optical density at 578 nm - PEN Penicillin G     

Functional analysis of Streptococcus pneumoniae MurM reveals the region responsible for its specificity in the synthesis of branched cell wall peptides

The recently identified murMN operon of Streptococcus pneumoniae encodes enzymes involved in the synthesis of branched structured muropeptides of the pneumococcal cell wall peptidoglycan. Its inactivation was shown to cause production of a peptidoglycan composed exclusively of linear muropeptides and a virtually complete loss of resistance in penicillin-resistant strains. The studies described in this communication follow up these observations in several directions. The substrate of the MurM-catalyzed reaction (addition of alanine or serine) was identified as the lipid-linked N-acetylglucosamine-muramyl pentapeptide. Different murM alleles from several penicillin-resistant S. pneumoniae strains, each with a characteristic branched peptide pattern, were cloned into pLS578, a pneumococcal plasmid capable of replicating in S. pneumoniae, and transformed into the penicillin-susceptible laboratory strain R36A. All transformants remained penicillin-susceptible; however, their cell wall composition changed in directions corresponding to the muropeptide pattern of the strain from which the murM allele was derived. This suggests that the muropeptide composition of the pneumococcal cell walls is determined by the particular murM allele carried by the cells. A 30-amino acid long sequence within the MurM protein was shown to be the main determinant of the specificity of the reaction (addition of alanine versus serine).     

Investigation of cell wall components in actinomycin D resistant Staphylococcus aureus]

Cell walls in 2 strains of Staphylococcus aureus 209P, i.e. actinomycin D susceptible and resistant ones were comparatively investigated. The resistant cells contained much more wall material per a unit of the biomass weight vs the susceptible strain cells, that conformed to thickening of the resistant cell walls detected by electron microscopy and a sharp increase of their electron density. Investigation of peptidoglycans and teichoic acids did not reveal any significant alterations in the structure of the wall components in the actinomycin D resistant cells. Only some increase of glucosamine in the peptidoglycan fraction of the resistant cells vs the susceptible ones was observed. It was shown that preparations of the resistant cell walls and peptidoglycan isolated from the resistant cells were able to bind somewhat lower quantities of actinomycin D vs the analogous preparations of the susceptible cells. The significant decrease of the antibiotic binding by live cells of the resistant strain probably slightly depended on the structure characteristics of the main wall components. The barrier properties of the walls in resistant staphylococci are most likely defined by the wall thickening and consolidation while adapting to actinomycin D.     

The lysostaphin endopeptidase resistance gene (epr) specifies modification of peptidoglycan cross bridges in Staphylococcus simulans and Staphylococcus aureus.

Staphylococcus simulans biovar staphylolyticus produces an extracellular glycylglycine endopeptidase (lysostaphin) that lyses other staphylococci by hydrolyzing the cross bridges in their cell wall peptidoglycans. The genes for endopeptidase (end) and endopeptidase resistance (epr) reside on plasmid pACK1. An 8.4-kb fragment containing end was cloned into shuttle vector pL150 and was then introduced into Staphylococcus aureus RN4220. The recombinant S. aureus cells produced endopeptidase and were resistant to lysis by the enzyme, which indicated that the cloned fragment also contained epr. Treatments to remove accessory wall polymers (proteins, teichoic acids, and lipoteichoic acids) did not change the endopeptidase sensitivity of walls from strains of S. simulans biovar staphylolyticus or of S. aureus with and without epr. Immunological analyses of various wall fractions showed that there were epitopes associated with endopeptidase resistance and that these epitopes were found only on the peptidoglycans of epr+ strains of both species. Treatment of purified peptidoglycans with endopeptidase confirmed that resistance or susceptibility of both species was a property of the peptidoglycan itself. A comparison of the chemical compositions of these peptidoglycans revealed that cross bridges in the epr+ cells contained more serine and fewer glycine residues than those of cells without epr. The presence of the 8.4-kb fragment from pACK1 also increased the susceptibility of both species to methicillin.     

Peptidoglycan synthesis and structure in Staphylococcus haemolyticus expressing increasing levels of resistance to glycopeptide antibiotics.

The structures of cytoplasmic peptidoglycan precursor and mature peptidoglycan of an isogenic series of Staphylococcus haemolyticus strains expressing increasing levels of resistance to the glycopeptide antibiotics teicoplanin and vancomycin (MICs, 8 to 32 and 4 to 16 microg/ml, respectively) were determined. High-performance liquid chromatography, mass spectrometry, amino acid analysis, digestion by R39 D,D-carboxypeptidase, and N-terminal amino acid sequencing were utilized. UDP-muramyl-tetrapeptide-D-lactate constituted 1.7% of total cytoplasmic peptidoglycan precursors in the most resistant strain. It is not clear if this amount of depsipeptide precursor can account for the levels of resistance achieved by this strain. Detailed structural analysis of mature peptidoglycan, examined for the first time for this species, revealed that the peptidoglycan of these strains, like that of other staphylococci, is highly cross-linked and is composed of a lysine muropeptide acceptor containing a substitution at its epsilon-amino position of a glycine-containing cross bridge to the D-Ala 4 of the donor, with disaccharide-pentapeptide frequently serving as an acceptor for transpeptidation. The predominant cross bridges were found to be COOH-Gly-Gly-Ser-Gly-Gly-NH2 and COOH-Ala-Gly-Ser-Gly-Gly-NH2. Liquid chromatography-mass spectrometry analysis of the peptidoglycan of resistant strains revealed polymeric muropeptides bearing cross bridges containing an additional serine in place of glycine (probable structures, COOH-Gly-Ser-Ser-Gly-Gly-NH2 and COOH-Ala-Gly-Ser-Ser-Gly-NH2). Muropeptides bearing an additional serine in their cross bridges are estimated to account for 13.6% of peptidoglycan analyzed from resistant strains of S. haemolyticus. A soluble glycopeptide target (L-Ala-gamma-D-iso-glutamyl-L-Lys-D-Ala-D-Ala) was able to more effectively compete for vancomycin when assayed in the presence of resistant cells than when assayed in the presence of susceptible cells, suggesting that some of the resistance was directed towards the cooperativity of glycopeptide binding to its target. These results are consistent with a hypothesis that alterations at the level of the cross bridge might interfere with the binding of glycopeptide dimers and therefore with the cooperative binding of the antibiotic to its target in situ. Glycopeptide resistance in S. haemolyticus may be multifactorial.