Lipid A, the active part of bacterial endotoxins in inducing serum colony stimulating activity and proliferation of splenic granulocyte/macrophage progenitor cells.

An analysis of which component of lipopolysaccharides (LPS), the lipid or the polysaccharide (PS), is active in stimulating the murine granulopoietic system has been performed. LPS with different structures, isolated from different mutant strains of Salmonella and chemical degradation products of lipopolysaccharides have been used. Lipid A obtained by acid hydrolysys of the LPS and complexed to bovine serum albumin (BSA) (lipid A-BSA) was shown to be active in generating serum colony stimulating factor (CSF) and in increasing the splenic colony forming cells (CFC) levels, although it was less active than the parent LPS. The polysaccharide (PS) showed no significant activity at the concentrations used. LPS (glycolipids) from R mutants of Salmonella minnesota were active to the same extent as the LPS. The fact that even the most defective LPS from the R mutant R595 which contains lipid A and KDO only is a potent endotoxin, points unequivocally, to lipid A, as the active principle in stimulating the granulopoietic system.     

A rapid method for determining the fatty acid composition of lipid A

Lipid A is the most conservative part of LPS. Its fatty acids composition can serve as an important taxonomic marker of bacteria. The isolation of LPS and studying their chemical composition are difficult and protracted procedure. We propose the rapid method of determining the prevailed fatty acids of lipid A without isolation of LPS from the cell. The essence of the method is in the release of cell from the lipids which are not components of LPS. These lipids, in contrast to the lipid A, are more easily extractable from the cell structures. The fatty acids, which prevailed in the lipid-free cells, are the structural components of lipid A.     

The Lipid A substructure of the Sinorhizobium meliloti lipopolysaccharides is sufficient to suppress the oxidative burst in host plants

Medicago sativa (alfalfa), Medicago truncatula and Nicotiana tabacum cell suspension cultures, responding to elicitation with the production of reactive oxygen species (ROS), were used to analyse the suppressor (and elicitor) activity of lipopolysaccharides (LPS) of the symbiotic soil bacterium Sinorhizobium meliloti. In order to identify the epitopes of the LPS molecule recognized by the plant, S. meliloti mutants defective in LPS biosynthesis and hydrolytically obtained Lipid A were analysed for biological activity. Lipopolysaccharides isolated from Sinorhizobium meliloti mutants 6963 (altered core region) and L994 (no long-chain fatty acid) showed the same ability to suppress the oxidative burst in host plant cell cultures as the wild-type LPS. Lipid A also displayed the same suppressor activity. By contrast, rhizobial LPS, but not Lipid A, was active as an inducer of the oxidative burst reaction in cell cultures of the nonhost Nicotiana tabacum. In host plants of Sinorhizobium meliloti the Lipid A part is sufficient to suppress the oxidative burst, but in non-host plants at least some sugars of the LPS core region are required to induce defence reactions.     

Detection of submicrogram quantities of Escherichia coli lipopolysaccharides by agarose-gel electrophoresis

A sensitive agarose-gel electrophoresis method has been developed for the visualization of lipopolysaccharide (LPS) samples from several Escherichia coli serotypes, such as 026:B6, 055:B5, 0128:B12, 0111:B4, 0127:B8, and K235. This method can detect as little as 0.5-6 microg of LPS depending on the serotype by treatment of the plates with toluidine blue, and it is able to measure sub-microgram amounts of samples, approx. 0.05-0.5 microg, when the staining with toluidine blue followed by Stains-All procedure is adopted. Treatment of LPS with alkali under anhydrous conditions removes the ester-linked fatty acids and the phosphate groups of the Lipid A component, producing the detoxified LPS. The carbohydrate neutral moiety obtained from the hydrolysate does not migrate during electrophoresis. This was utilized to monitor quantitatively the removal process of the Lipid A component for the formation of the detoxified LPS.     

5-Lipoxygenase Activating Protein (FLAP) Dependent Leukotriene Biosynthesis Inhibition (MK591) Attenuates Lipid A Endotoxin-Induced Inflammation

The Lipid A moiety of endotoxin potently activates TLR-4 dependent host innate immune responses. We demonstrate that Lipid-A mediated leukotriene biosynthesis regulates pathogen-associated molecular patterns (PAMP)-dependent macrophage activation. Stimulation of murine macrophages (RAW264.7) with E. coli 0111:B4 endotoxin (LPS) or Kdo2-lipid A (Lipid A) induced inflammation and Lipid A was sufficient to induce TLR-4 mediated macrophage inflammation and rapid ERK activation. The contribution of leukotriene biosynthesis was evaluated with a 5-lipoxygenase activating protein (FLAP) inhibitor, MK591. MK591 pre-treatment not only enhanced but also sustained ERK activation for up to 4 hours after LPS and Lipid A stimulation while inhibiting cell proliferation and enhancing cellular apoptosis. Leukotriene biosynthesis inhibition attenuated inflammation induced by either whole LPS or the Lipid A fraction. These responses were regulated by inhibition of the key biosynthesis enzymes for the proinflammatory eicosanoids, 5-lipoxygenase (5-LO), and cyclooxygenase-2 (COX-2) quantified by immunoblotting. Inhibition of leukotriene biosynthesis differentially regulated TLR-2 and TLR-4 cell surface expression assessed by flow cytometry, suggesting a close mechanistic association between TLR expression and 5-LO associated eicosanoid activity in activated macrophages. Furthermore, MK591 pre-treatment enhanced ERK activation and inhibited cell proliferation after LPS or Lipid A stimulation. These effects were regulated in part by increased apoptosis and modulation of cell surface TLR expression. Together, these data clarify the mechanistic association between 5-lipoxygenase activating protein-mediated leukotriene biosynthesis and 5-LO dependent eicosanoid metabolites in mediating the TLR-dependent inflammatory response after endotoxin exposure typical of bacterial sepsis.     

Ammonium hydroxide hydrolysis: a valuable support in the MALDI-TOF mass spectrometry analysis of Lipid A fatty acid distribution

Lipid A is the lipophilic moiety of lipopolysaccharides (LPSs), the major components of the external membrane of almost all gram-negative bacteria. It is responsible for the toxicity of LPS and has a heterogeneous structure composed of a bis-phosphorylated glucosamine disaccharide backbone that is acylated at the positions 2, 3 of the GlcN I (proximal) and GlcN II (distal) residue with O- and N-linked 3-hydroxy fatty acids (primary substitution). These fatty acids are further acylated by means of their 3-hydroxy groups (secondary substitution). The toxicity of Lipid A is dependent on its primary structure; the number, the length, and the distribution of the fatty acids on the disaccharide backbone strongly influence the endotoxic activity. In this paper a general and easy methodology to obtain secondary fatty acid distribution, which is one of the most difficult issues in the structural determination of Lipid A, is proposed. The method combines ammonium hydroxide hydrolysis and matrix assisted laser desorption ionization (MALDI)-mass spectrometry analysis and has been successfully proven with five different Lipid A species. The procedure exploits the lower stability under mild alkaline conditions of acyl and acyloxyacyl esters with respect to that of the acyl and acyloxyacyl amides. The partially degraded Lipid A species obtained are analyzed by MALDI-MS. The generality of this approach was tested on five Lipid As, namely those arising from Escherichia coli, Klebsiella pneumoniae, Klebsiella oxytoca, Pseudomonas reactans, and Burkholderia caryophylli.     

Spin-labeled lipid A

Lipopolysaccharide (LPS), a major component of the outer membranes of gram-negative bacteria, is composed of a polysaccharide chain attached to a lipid A base that contains a disaccharide headgroup with two negative phosphate groups and at least four acyl chains. Lipid A is an essential component of the membranes of a large number of bacteria and is also a substrate for a wide variety of proteins. Here we report the synthesis of a nitroxide spin-labeled lipid A, characterize its localization at the membrane bilayer surface, and demonstrate that it remains a viable substrate for the Escherichia coli lipid flippase MsbA.     

The effect of endotoxin lipopolysaccharide from different bacterial species on the generation of intracellular inositol trisphosphate and superoxide in a human phagocytic cell line

The acute effects of endotoxins and lipid A on two intracellular responses, inositol phosphate generation and superoxide production were analysed in the DMSO differentiated premyelocytic leukaemic HL-60 cell line. Short-term incubation (1-10 min) with Escherichia coli-type LPS, Salmonella-type LPS and Lipid A caused significant increases in cellular InsP1 and InsP3, compared with control cells (P less than 0.5-P less than 0.001). The Escherichia coli-type LPS released approximately twice the quantity of InsP3 compared with Salmonella-type LPS (P less than 0.001). Lipid A-dependent stimulation of InsP3 production was also detected. The rate of superoxide production increased 1-10 min after addition of both Escherichia coli- and Salmonella-type LPS and Lipid A. Endotoxins and Lipid A caused a dose-dependent increase in intracellular oxidative activity. The superoxide response showed less species dependence and a higher response to particulate lipid A compared with the inositol phosphate response.     

The effect of endotoxin lipopolysaccharide from different bacterial species on the generation of intracellular inositol triphosphate and superoxide in a human phagocytic cell line

Abstract The acute effects of endotoxins and lipid A on two intracellular responses, inositol phosphate generation and superoxide production were analysed in the DMSO differentiated premyelocytic leukamic HL-60 cell line. Short-term incubation (1–10 min) with Escheria coli -type LPS, Salmonella -type LPS and Lipid A caused significant increases in cellular InsP₁ and InsP₃, compared with control cells ( P < 0.5 − P < 0.001). The Escheria coli -type B LPS released approximately twice the quantity of InsP₃ compared with Salmonella -type LPS ( P < 0.001). Lipid A-dependent stimulation of InsP₃ production was also detected. The rate of superoxide production increased 1–10 min after addition of both Escheria coli - and Salmonella -type LPS and Lipid A. Endotoxins and Lipid A caused a dose-dependent increase in intracellular oxidative activity. The superoxide response showed less species dependence and a higher response to particulate lipid A compared with the inositol phosphate response.     

Evolution of the Kdo<Subscript>2</Subscript>-lipid A biosynthesis in bacteria

Background  

Lipid A is the highly immunoreactive endotoxic center of lipopolysaccharide (LPS). It anchors the LPS into the outer membrane of most Gram-negative bacteria. Lipid A can be recognized by animal cells, triggers defense-related responses, and causes Gram-negative sepsis. The biosynthesis of Kdo₂-lipid A, the LPS substructure, involves with nine enzymatic steps.     

A two‐component Kdo hydrolase in the inner membrane of Francisella novicida

Lipid A coats the outer surface of the outer membrane of Gram‐negative bacteria. In Francisella tularensis subspecies novicida lipid A is present either as the covalently attached anchor of lipopolysaccharide (LPS) or as free lipid A. The lipid A moiety of Francisella LPS is linked to the core domain by a single 2‐keto‐3‐deoxy‐D‐manno‐octulosonic acid (Kdo) residue. F. novicida KdtA is bi‐functional, but F. novicida contains a membrane‐bound Kdo hydrolase that removes the outer Kdo unit. The hydrolase consists of two proteins (KdoH1 and KdoH2), which are expressed from adjacent, co‐transcribed genes. KdoH1 (related to sialidases) has a single predicted N‐terminal transmembrane segment. KdoH2 contains 7 putative transmembrane sequences. Neither protein alone catalyses Kdo cleavage when expressed in E. coli. Activity requires simultaneous expression of both proteins or mixing of membranes from strains expressing the individual proteins under in vitro assay conditions in the presence of non‐ionic detergent. In E. coli expressing KdoH1 and KdoH2, hydrolase activity is localized in the inner membrane. WBB06, a heptose‐deficient E. coli mutant that makes Kdo₂‐lipid A as its sole LPS, accumulates Kdo‐lipid A when expressing the both hydrolase components, and 1‐dephospho‐Kdo‐lipid A when expressing both the hydrolase and the Francisella lipid A 1‐phosphatase (LpxE).     

The production of tumor necrosis factor by mouse bone marrow-derived macrophages in response to bacterial lipopolysaccharide and a chemically synthesized monosaccharide precursor

Lipid X, a monosaccharide biosynthetic precursor of lipid A, has been chemically synthesized and was shown to induce bone marrow-derived macrophages to release tumor necrosis factor (TNF) in vitro. However, relatively high amounts of lipid X were necessary for induction, and the levels of TNF were much less than those induced by small amounts of lipid A itself or LPS. Lipid X prepared by extraction of Escherichia coli mutants induced higher levels of TNF than the chemically synthesized material, but this is probably partially due to amounts of impurities in the extracted material. Pretreatment of macrophages with IFN-gamma resulted in the release of higher amounts of TNF on subsequent induction with either LPS or lipid X. In contrast, pretreatment of macrophages with LPS induced hyporesponsiveness for TNF production on subsequent rechallenge with LPS. Lipid X, on the other hand, was incapable of making macrophages hyporesponsive for TNF production.     

Blocking of bacteriophages phi W and phi 5 with lipopolysaccharides from Escherichia coli K-12 mutants.

In the preceding paper we presented a formula for the composition of lipopolysaccharides (LPS) from Escherichia coli K-12. This formula contains four regions defined from analyses of LPS from four key strains, the parent and mutants which had lost one, two, or three regions of their carbohydrates. Support for the formula was derived from the susceptibility of the key mutants to several bacteriophages. One of these, phage phi W, was found specific for strains which had lost region 4. In this paper we described inactivation in vitro of phage phi W and its host-range mutant phi 5, using LPS devoid of regions 2 to 4. The blocking of phi W was found to require about 0.15 M concentrations of monovalent cations and to be inhibited by low concentrations of calcium and magnesium ions. One particle of phage phi W required 2 times 10-16 g of LPS devoid of region 4 for stoichiometric inactivation. Phage phi 5 was blocked by both heptose-less LPS (devoid of regions 2 to 4) and glucose-less LPS (devoid of regions 3 to 4) but was unaffected by LPS devoid of region 4. LPS from a heptose-less mutant of Salmonella minnesota showed the same inactivation ability as did LPS from heptose-less strains of E. coli K-12. Lipid A was prepared from LPS containing all four regions. Such lipid A was found to inactivate phi 5, whereas both the polysaccharide moiety as well as the intact LPS were without effect. It is suggested that lipid A is part of the receptor site for phage phi 5.     

Adipokinetic hormone enhances nodule formation and phenoloxidase activation in adult locusts injected with bacterial lipopolysaccharide

Interactions between the locust endocrine and immune systems have been studied in vivo in relation to nodule formation and activation of the prophenoloxidase cascade in the haemolymph. Injection of bacterial lipopolysaccharide (LPS) extracted from Escherichia coli induces nodule formation in larval and adult locusts but does not increase phenoloxidase activity in the haemolymph. Nodule formation starts rapidly after injection of LPS and is virtually complete within 8 h, nodules occurring mainly associated with the dorsal diaphragm on either side of the heart, but sometimes with smaller numbers associated with the ventral diaphragm on either side of the nerve cord. Co-injection of adipokinetic hormone-I (Lom-AKH-I) with LPS stimulates greater numbers of nodules to be formed in larval and adult locusts, and activates phenoloxidase in the haemolymph of mature adults but not of nymphs. The effect of co-injection of Lom-AKH-I with LPS on nodule formation is seen at low doses of hormone; only 0.4 pmol of Lom-AKH-I per adult locust is needed to produce a 50% increase in the number of nodules formed. When different components of LPS from the E. coli Rd mutant are tested, the mono- and the diphosphoryl Lipid A components have similar effects to the intact LPS. Remarkably, detoxified LPS activates phenoloxidase in the absence of Lom-AKH-I, although co-injection with hormone does enhance this response. Both diphosphoryl Lipid A and detoxified LPS induce a level of nodule formation that is enhanced by co-injection of Lom-AKH-I, but monophosphoryl Lipid A does not initiate nodule formation even when injected with hormone. Co-injection of a water-soluble inhibitor of eicosanoid synthesis, diclofenac (2-[(2, 6-dichlorophenyl)amino] benzeneacetic acid), reduces nodule formation in response to injections of LPS (both in the absence and presence of hormone) in a dose-dependent manner, but does not prevent activation of phenoloxidase in adult locusts. It is shown that nodule formation and activation of the prophenoloxidase in locust haemolymph can both be enhanced by Lom-AKH-I, but it is argued that these processes involve distinct mechanisms in which eicosanoid synthesis is important for nodule formation, but not for the increased phenoloxidase activity.     

Investigating the candidacy of lipopolysaccharide-based glycoconjugates as vaccines to combat <Emphasis Type="Italic">Mannheimia haemolytica</Emphasis>

Inner core lipopolysaccharide (LPS) has been shown to be conserved in the majority of veterinary strains from the species Mannheimia haemolytica, Actinobacillus pleuropneumoniae and Pasteurella multocida and as such is being considered as a possible vaccine antigen. The proof-in-principle that a LPS-based antigen could be considered as a vaccine candidate has been demonstrated from studies with monoclonal antibodies raised to the inner core LPS of Mannheimia haemolytica, which were shown to be both bactericidal and protective in a mouse model of disease. In this study we confirm and extend the candidacy of the inner core LPS by demonstrating that it is possible to elicit functional antibodies against Mannheimia haemolytica wild-type strains following immunisation of rabbits with glycoconjugates elaborating the conserved inner core LPS antigen. The present study describes a conjugation strategy that uses amidases produced by Dictyostelium discoideum, targeting the amino functionality created by the amidase activity as the attachment point on the LPS molecule. To protect the amino functionality on the phosphoethanolamine (PEtn) residue of the inner core, we developed a novel blocking and unblocking strategy with t-butyl oxycarbonyl. A maleimide-thiol linker strategy with the thiol linker on the carboxyl residues of the carrier protein and the maleimide linker on the carbohydrate resulted in a high loading of carbohydrates per carrier protein. Immunisation derived antisera from rabbits recognised fully extended Mannheimia haemolytica LPS and whole cells from serotypes 1 and 2, despite a somewhat immunodominant response to the linkers also being observed. Moreover, bactericidal activity was demonstrated to a strain elaborating the immunising carbohydrate antigen and crucially to wild-type cells of serotypes 1 and 2, thus further supporting the consideration of inner core LPS as a potential vaccine antigen to combat disease caused by Mannheimia haemolytica.     

The selective binding of aggregated IgG to lipid A-rich bacterial lipopolysaccharides

To explore the mechanism by which certain bacterial lipopolysaccharides (LPS) enhance platelet stimulation by aggregated IgG, we studied potential interactions between the two ligands. Lipid A or the lipid A-rich LPS from Salmonella minnesota R595 (LPS R595) selectively increased the sedimentation of aggregated rather than monomer IgG in sucrose density gradients. Insolubilized IgG aggregates adsorbed LPS R595 from solution. These two experiments suggested binding of IgG aggregates to LPS R595 or lipid A and this was confirmed by isopycnic density gradient ultracentrifugation studies. The presence of R595 LPS shifted the equilibrium density profile of aggregated IgG from its usual equilibrium density at 1.30 g/ml to a new position superimposable with that of the LPS R595. The possibility that a selective binding of IgG aggregates to LPS may represent a fundamental mechanism of the action of LPS on cellular mediation systems is proposed.     

Sinorhizobium meliloti acpXL mutant lacks the C28 hydroxylated fatty acid moiety of lipid A and does not express a slow migrating form of lipopolysaccharide

Lipid A is the hydrophobic anchor of lipopolysaccharide (LPS) in the outer membrane of Gram-negative bacteria. Lipid A of all Rhizobiaceae is acylated with a long fatty acid chain, 27-hydroxyoctacosanoic acid. Biosynthesis of this long acyl substitution requires a special acyl carrier protein, AcpXL, which serves as a donor of C28 (omega-1)-hydroxylated fatty acid for acylation of rhizobial lipid A (Brozek, K.A., Carlson, R.W., and Raetz, C. R. (1996) J. Biol. Chem. 271, 32126-32136). To determine the biological function of the C28 acylation of lipid A, we constructed an acpXL mutant of Sinorhizobium meliloti strain 1021. Gas-liquid chromatography and mass spectrometry analysis of the fatty acid composition showed that the acpXL mutation indeed blocked C28 acylation of lipid A. SDS-PAGE analysis of acpXL mutant LPS revealed only a fast migrating band, rough LPS, whereas the parental strain 1021 manifested both rough and smooth LPS. Regardless of this, the LPS of parental and mutant strains had a similar sugar composition and exposed the same antigenic epitopes, implying that different electrophoretic profiles might account for different aggregation properties of LPS molecules with and without a long acyl chain. The acpXL mutant of strain 1021 displayed sensitivity to deoxycholate, delayed nodulation of Medicago sativa, and a reduced competitive ability. However, nodules elicited by this mutant on roots of M. sativa and Medicago truncatula had a normal morphology and fixed nitrogen. Thus, the C28 fatty acid moiety of lipid A is not crucial, but it is beneficial for establishing an effective symbiosis with host plants. acpXL lies upstream from a cluster of five genes, including msbB (lpxXL), which might be also involved in biosynthesis and transfer of the C28 fatty acid to the lipid A precursor.     

Induction by lipopolysaccharide of intracellular and extracellular interleukin 1 production: analysis with synthetic models

An attempt was made to identify the molecular structures that are present in bacterial LPS and induce the production of intracellular and extracellular pools of IL 1 by peritoneal macrophages of the mouse and by human monocytes. Activities of glycolipids and carbohydrates prepared by synthesis, and structurally related to the hydrophobic (Lipid A) and to the polysaccharide (PS) regions of LPS were compared with those induced by Bordetella pertussis endotoxin and by fragments derived therefrom. Both isolated regions of this LPS (PS and Lipid A) were able to induce IL 1 synthesis by monocytes and macrophages. Among the synthetic glycolipids employed, propyl-2-deoxy-2-[(3R)-3-hydroxytetrade-canamido]-4-O-pho sph ono-6-O-tetradecanoyl-beta-D-glucopyranoside (glycolipid M9) induced IL 1 secretion more efficiently than Lipid A and LPS, whereas the amounts of intracellular IL 1 produced upon induction by these three substances were comparable. Macrophages from C3H/HeJ mice were unresponsive to Lipid A and to glycolipid M9, but produced IL 1 when incubated with PS or with a hydrophilic fragment isolated after methanolysis of the endotoxin. However, all synthetic derivatives of 3-deoxy-D-manno-2-octulosonic acid (KDO) used in this study failed to induce IL 1 production by both mouse macrophages and human monocytes. The implications of these findings for a more precise comprehension of the molecular mechanism of LPS-induced activation of macrophages, and the relations between the molecular structures required for the induction of IL 1 production vs cytostatic activity in macrophages, are discussed.     

The effect of gram-negative bacteria lipopolysaccharides on the development of Rauscher leukosis in BALB/c mice

The dose-dependent action of Shigella sonnei lipopolysaccharide (LPS) on the development of acute erythroleukocytosis, as well as Rauscher chronic myeloid and lymphoid leukosis, in BALB/c mice sensitive to Rauscher virus was shown. Bordetella pertussis LPS in the doses used in this investigation stimulated the development of both acute erythroleukosis and chronic myeloid and lymphoid leukosis in BALB/c mice infected with Rauscher virus. Lipid A isolated from B. pertussis LPS was found to produce a stimulating effect on the development of Rauscher leukosis in mice. After the treatment of B. pertussis LPS with polymyxin B blocking lipid A no stimulating effect of B. pertussis LPS on the development of Rauscher leukosis was observed. A suggestion is made that lipid A is the active principle contributing to the stimulation of the development of Rauscher leukosis in BALB/c mice.     

Biosynthesis, transport, and modification of lipid A.

Lipopolysaccharide (LPS) is the major surface molecule of Gram-negative bacteria and consists of three distinct structural domains: O-antigen, core, and lipid A. The lipid A (endotoxin) domain of LPS is a unique, glucosamine-based phospholipid that serves as the hydrophobic anchor of LPS and is the bioactive component of the molecule that is associated with Gram-negative septic shock. The structural genes encoding the enzymes required for the biosynthesis of Escherchia coli lipid A have been identified and characterized. Lipid A is often viewed as a constitutively synthesized structural molecule. However, determination of the exact chemical structures of lipid A from diverse Gram-negative bacteria shows that the molecule can be further modified in response to environmental stimuli. These modifications have been implicated in virulence of pathogenic Gram-negative bacteria and represent one of the molecular mechanisms of microbial surface remodeling used by bacteria to help evade the innate immune response. The intent of this review is to discuss the enzymatic machinery involved in the biosynthesis of lipid A, transport of the molecule, and finally, those enzymes involved in the modification of its structure in response to environmental stimuli.