Induction of delayed-type hypersensitivity by the T cell line specific to bacterial peptidoglycans

A T cell line specific for the chemically well-defined peptidoglycan of bacterial cell wall, disaccharide tetrapeptide, was established from Lewis rats immunized with the antigen covalently linked to the autologous rat serum albumin. The antigen specificity was examined with various analogues or derivatives of the peptidoglycan. The cell line was reactive to analogues with the COOH-terminal D-amino acid, but least reactive to those with L-amino acid as COOH terminus. Transferring of the T cell line into X-irradiated normal Lewis rats induced delayed-type hypersensitivity in an antigen specific manner.     

Adjuvant activity of monomeric bacterial cell wall peptidoglycans

We have previously shown that lysozyme solubilized cell walls of Mycobacteria or Nocardiae can replace whole mycobacterial cells or Wax D in Freund's complete adjuvant and it was found quite recently that hydrosoluble peptidoglycans, free of neutral sugars, are also adjuvant active. We show now that the simplest fragment tested — the disaccharide tetrapeptide (I) — increases circulating antibodies to ovalbumin and induces a delayed hypersensitivity toward this antigen. Similar compounds obtained from the basal layer of the cell wall of $\text{E. coli}$ are also active. Thus the immunoadjuvant activity of soluble cell wall peptidoglycans is a property of the monomeric unit and is not restricted to acid fast bacteria.     

Two proposed general configurations for bacterial cell wall peptidoglycans shown by space-filling molecular models

Bacterial cell wall peptidoglycans are built from unbranched β-(1 → 4)-linked glycan chains composed of alternately repeating units of N-acetylglucosamine and N-acetylmuramic acid residues, with peptide side chains attached to the muramic acid residues. The glycan chains are interconnected by peptide bonds formed between the peptide side chains. Through the use of three-dimensional molecular models, two configurations of the glycan strands and the peptide side chains are described, which by their constancy of form reflect the fundamental constancies of the covalent structures. Each of these two models will accommodate any chemical modification that has been observed in bacteria without change in the configuration of the peptide backbone. Some alterations in the chemical structure, which have been sought in bacteria, but not found, would not be tolerated by the models. In these models, glycan strands are parallel, with their lengths and widths predominantly in the plane of the cell wall. The cross-bridging portions of the peptide side chains are at right angles to the glycan strand, in a separate, parallel plane. A compact model is presented in which the peptide side chain is closely appressed to the glycan strand and is stabilized by three hydrogen bonds per disaccharide–peptide subunit. In a second model, the peptide side chain is raised away from the glycan strand in an entirely extended configuration. The compact and extended forms are interconvertible. The thickness of a sheet of peptidoglycan would be from 10.6 to 11.1 Å for the compact model, and 19.1 Å for the extended model.     

Activation of the human complement cascade by bacterial cell walls, peptidoglycans, water-soluble peptidoglycan components, and synthetic muramylpeptides--studies on active components and structural requirements

Cell walls isolated from 29 strains of 24 gram-positive bacterial species, whose peptidoglycans belong to the group A type of Schleifer and Kandler's classification, with one exception (Arthrobacter sp.), were shown to activate the complement cascade in pooled fresh human serum mainly through the alternative pathway and partly through the classical one. The complement-activating effect of cell walls (5 species) possessing group B type peptidoglycan, except those of Corynebacterium insidiosum, was weaker than that of the walls with group A type peptidoglycan. Preparations of peptidoglycan isolated from cell walls of Staphylococcus aureus, Streptococcus pyogenes, and Lactobacillus plantarum also activated the alternative pathway of the complement cascade, but less effectively than the respective parent cell walls. A water-soluble "polymer" of peptidoglycan subunits (SEPS), which was prepared from Staphylococcus epidermidis peptidoglycans by treatment with a cross-bridge degrading endopeptidase, retained most of the complement-activating ability of the parent cell walls. A peptidoglycan "monomer," SEPS-M, which was obtained by hydrolysis of the glycan chain of SEPS with endo-N-acetylmuramidase to disaccharide units did not activate complement. In conformity with this finding, neither synthetic N-acetylmuramyl-L-alanyl-D-isoglutamine (MDP) nor MDP-L-Lys-D-Ala activated the complement cascade. Among several lipophilic derivatives of MDP, 6-O-(3-hydroxy-3-docosylhexacosanoyl)-MDP-L-Lys-D-Ala (BH48-MDP-L-Lys-D-Ala) and 6-O-(2-tetradecylhexadecanoyl)-MDP (B30-MDP) were shown to activate complement through the alternative as well as the classical pathway and exclusively through the classical pathway, respectively. The finding that a D-isoasparagine analog of B30-MDP caused the same effect as the parent molecule strongly suggests that the activation of complement by B30-MDP is different from that caused by cell wall peptidoglycans and a water-soluble "polymer" of peptidoglycan subunits.     

Mutational control of bioenergetics of bacterial reaction center probed by delayed fluorescence

The free energy gap between the metastable charge separated state P⁺Q_A⁻ and the excited bacteriochlorophyll dimer P* was measured by delayed fluorescence of the dimer in mutant reaction center proteins of the photosynthetic bacterium Rhodobacter sphaeroides. The mutations were engineered both at the donor (L131L, M160L, M197F and M202H) and acceptor (M265I and M234E) sides. While the donor side mutations changed systematically the number of H-bonds to P, the acceptor side mutations modified the energetics of Q_A by altering the van-der-Waals and electronic interactions (M265IT) and H-bond network to the acidic cluster around Q_B (M234EH, M234EL, M234EA and M234ER). All mutants decreased the free energy gap of the wild type RC (~ 890 meV), i.e. destabilized the P⁺Q_A⁻ charge pair by 60–110 meV at pH 8. Multiple modifications in the hydrogen bonding pattern to P resulted in systematic changes of the free energy gap. The destabilization showed no pH-dependence (M234 mutants) or slight increase (WT, donor-side mutants and M265IT above pH 8) with average slope of 10–15 meV/pH unit over the 6–10.5 pH range. In wild type and donor-side mutants, the free energy change of the charge separation consisted of mainly enthalpic term but the acceptor side mutants showed increased entropic (even above that of enthalpic) contributions. This could include softening the structure of the iron ligand (M234EH) and the Q_A binding pocket (M265IT) and/or increase of the multiplicity of the electron transfer of charge separation in the acceptor side upon mutation.     

Rumen bacterial degradation of forage cell walls investigated by electron microscopy

The association of rumen bacteria with specific leaf tissues of the forage grass Kentucky-31 tall fescue (Festuca arundinacea Schreb.) during in vitro degradation was investigated by transmission and scanning electron microscopy. Examination of degraded leaf cross-sections revealed differential rates of tissue degradation in that the cell walls of the mesophyll and pholem were degraded prior to those of the outer bundle sheath and epidermis. Rumen bacteria appeared to degrade the mesophyll, in some cases, and phloem without prior attachment to the plant cell walls. The degradation of bundle sheath and epidermal cell walls appeared to be preceded by attachment of bacteria to the plant cell wall. Ultrastructural features apparently involved in the adhesion of large cocci to plant cells were observed by transmission and scanning electron microscopy. The physical association between plant and rumen bacterial cells during degradation apparently varies with tissue types. Bacterial attachment, by extracellular features in some microorganisms, is required prior to degradation of the more resistant tissues.     

Species dependency of in vitro macrophage activation by bacterial peptidoglycans.

The effect of various bacterial cell wall components on in vitro biological function of murine peritoneal exudate macrophages was evaluated. We examined four different parameters of metabolic activity and monokine secretion. Peritoneal exudate macrophages from rats and guinea pigs, all of the strains tested, were stimulated by whole bacterial cell wall preparations, purified bacterial cell wall peptidoglucans, its water-soluble peptidolglycan fragments, muramyl dipeptides and amphipathic substances. Murine peritoneal exudate macrophages were activated by amphipathic substances of gram-positive bacteria. However, macrophages from mice, irrespective of strains, were not stimulated in the in vitro assay systems by purified bacterial cell wall peptidoglycan, water-soluble bacterial peptidoglycan fragments or muramyl dipeptides. These results suggest that macrophage activation by bacterial peptidoglycan in vitro is animal species specific.