Activation of human serum complement by bacterial lipopolysaccharides: structural requirements for antibody independent activation of the classical and alternative pathways

A variety of bacterial lipopolysaccharide (LPS) preparations with highly defined primary polysaccharide chemical structure and/or aggregate macromolecular composition have been employed to examine the molecular requirements for activation of the classical and alternative pathways of human serum complement. Evidence is presented for two independent modes of polysaccharide dependent activation of the APC by LPS. One mechanism is dependent upon specific O-antigen polysaccharides and the second is defined by a specific L-glycero-D-mannoheptose/glucose region of the core oligosaccharide. LPS O-antigen polysaccharide but not core oligosaccharide determinants can convert sheep erythrocytes to cells capable of initiating the APC. The data presented provide convincing evidence that the tertiary assembly of individual LPS subunits into an aggregate macromolecule is a critical determinant in the expression of APC activity by LPS. The results of these studies provide strong evidence that CPC activation by LPS is restricted to the Re-chemotype and isolated lipid A. LPS isolated from other R-chemotypes as well as native wild type LPS preparations do not activate the CPC, in spite of the fact that the former LPS preparations contain more lipid A than polysaccharide on a percentage by wt basis. The presence of core polysaccharide L-glycero-D-mannoheptose, which provides a critical recognition role for activation of the APC, appears to negatively regulate CPC activation in a similar inverse relationship. In addition, the presence of polysaccharide containing LPS subunits in synthetic mixed LPS micellar aggregates can also restrict CPC activation by Re LPS subunits, most probably by steric hindrance at the LPS macromolecular surface. Our data are consistent with the hypothesis that activation of either pathway of human serum complement by a given LPS preparation is a mutually exclusive event dictated by the presence or absence of L-glycero-D-mannoheptose.     

Activation of the alternative complement pathway by enveloped viruses containing limited amounts of sialic acid

We have demonstrated that purified enveloped viruses grown in MDBK cells, such as influenza virus, Simian virus 5 (SV5), and vesicular stomatitis virus (VSV) grown in the presence of SV5 activate the alternative complement pathway, whereas VSV grown in BHK21-F or HKCC cells and Sindbis virus grown in BHK21-F cells do not. A direct correlation between the amount of sialic acid associated with the viral surface and its ability to activate the alternative complement pathway has been demonstrated. Our results indicate that enveloped viruses that lack sialic acid are efficient activators of the alternative complement pathway, whereas those with ≥10 μg of sialic acid/mg of protein do not. Enveloped viruses with 5–10 μg of sialic acid/mg of protein are intermediate in their ability to activate the alternative complement pathway. The results of our experiments employing different enveloped viruses with biologically derived sialic acid content support the hypothesis (D. T. Fearon, 1978, Proc. Nat. Acad. Sci. USA75 1971–1975) that sialic acid is a key membrane constituent for modulating activation of C3 via the alternative complement pathway.     

Binding of bacterial endotoxin to murine spleen lymphocytes.

The early events in lipopolysaccharide (LPS)-induced B-cell activation were investigated by studying the binding of 14C-labeled LPS to murine lymphocytes in vitro. In these studies we utilized intrinsically labeled 14C-labeled LPS from Salmonella minnesota or the 14C-labeled glycolipid derived from the Re mutant of S. minnesota (R595). Bone marrow-derived (B) lymphocytes bound more LPS than did thymus-derived (T) lymphocytes. Binding of LPS to murine spleen lymphocytes from strain C3H/HeN was compared with the binding to spleen lymphocytes from strain C3H/HeJ, a strain resistant to certain biological activities of LPS including mitogenesis. Spleen cells from both strains bound LPS equally well, suggesting that unresponsiveness of C3H/HeJ mice to LPS is due to factors other than a defect in binding of LPS. LPS binding to cells appeared to be due to a nonspecific interaction between the lipid moiety of LPS and the lipid components of the cell membrane. Thus, the highly lipophilic, polysaccharide-deficient glycolipid from R595 bound at least 20 times better than did LPS. Furthermore, partial removal of cell surface proteins with trypsin or sialic acids with neuraminidase enhanced glycolipid binding, suggesting that binding is not through a protein- or sialic acid-containing receptor. The binding of glycolipid to lymphocytes was only partially specific since unlabeled glycolipid R595, lipid A, and LPS did not completely inhibit the uptake of 14C-labeled glycolipid R595. In addition, binding could be inhibited by a nonmitogenic phospholipid (phosphatidyl ethanolamine), which also is consistent with a nonspecific lipid-lipid interaction. Experiments were performed to determine the relationship of LPS binding to lymphocyte activation in the lymphocytes. The process of activation of lymphocytes by LPS was a slow one, since LPS was required to be present in culture for at least 24 h in order to obtain significant lymphocyte activation, suggesting that the amounts of LPS bound earlier are either quantitatively or qualitatively insufficient to irreversibly activate the cell.     

Serum amyloid P component bound to gram-negative bacteria prevents lipopolysaccharide-mediated classical pathway complement activation

Although serum amyloid P component (SAP) is known to bind many ligands, its biological function is not yet clear. Recently, it was demonstrated that SAP binds to lipopolysaccharide (LPS). In the present study, SAP was shown to bind to gram-negative bacteria expressing short types of LPS or lipo-oligosaccharide (LOS), such as Salmonella enterica serovar Copenhagen Re and Escherichia coli J5, and also to clinical isolates of Haemophilus influenzae. It was hypothesized that SAP binds to the bacteria via the lipid A part of LPS or LOS, since the htrB mutant of the nontypeable H. influenzae strain NTHi 2019-B29-3, which expresses a nonacetylated lipid A, did not bind SAP. This was in contrast to the parental strain NTHi 2019. The binding of SAP resulted in a clear inhibition of the deposition of complement component C3 on the bacteria. SAP inhibited only the activation of the classical complement pathway; the alternative route remained unaffected. In the classical route, SAP prevented the deposition of the first complement component, Clq, probably by interfering with the binding of Clq to LPS. Since antibody-mediated Clq activation was not inhibited by SAP, SAP seems to inhibit only the LPS-induced classical complement pathway activation. The SAP-induced inhibition of C3 deposition strongly diminished the complement-mediated lysis as well as the phagocytosis of the bacteria. The binding of SAP to gram-negative bacteria, therefore, might influence the pathophysiology of an infection with such bacteria.     

Interactions between complement system and bacterial walls

The complement system is involved in the antibacterial defence either with a delay, following the specific antibody response, or immediately through a direct interaction between complement components and the bacterial cell wall. Several gram- bacteria initiate the classical pathway through direct interaction between C1 and the lipid A of the lipopolysaccharides; this activation depends upon the structure, the accessibility and the state of polymerization of the lipopolysaccharides. Gram+ and gram- bacteria are able to activate the alternative pathway through a covalent C3b binding. Capsules appear to prevent activation due to their high content of sialic acid, which probably accounts for the virulence. As targets, bacteria may undergo opsonization mainly by C3b, or lysis through transmembrane channels formed by terminal components from C5b to C9.     

Diminished complement-activating capacity through the classical pathway in sera from type 2 diabetes mellitus

Complement-activating capacity through the classical pathway in type 2 diabetes mellitus (T2DM) was examined in the context of free sialic acid as a potential modulator of complement activation. Complement-activating capacity was investigated in an incubation study of heat-aggregated IgG (HAG) and sera from 42 T2DM patients. The study demonstrated diminished in-vitro complement-activating capacity through the classical pathway in T2DM. Various doses of N-acetyl neuraminic acid (NANA) were incubated with normal serum and HAG. Complement activation product levels decreased in a NANA dose-dependent manner. Isoelectrofocusing analysis in a mixture of NANA and purified C3 indicated that C3 changed pI dose-dependently, resulting in the downregulation of complement activation. The serum levels of free sialic acid were determined by fluorometric assay in the 42 T2DM sera samples, and were significantly increased in patients with diminished complement activation. These data indicate that increased serum sialic acid may become a candidate for decreasing complement-activating capacity in T2DM.     

Antibody-independent activation of the classical pathway of human serum complement by lipid A is restricted to re-chemotype lipopolysaccharide and purified lipid A

Incubation of most bacterial lipopolysaccharides (LPS) with normal human sera at 37 degrees C activates the serum complement system, resulting in decreased levels of hemolytic complement. A panel of R-chemotype LPS preparations isolated from Salmonella minnesota rough mutant strains, as well as smooth wild-type LPS from S. minnesota, Escherichia coli O55-B5, Serratia marcescens, and Yersinia enterolitica, were used to examine the effect of LPS polysaccharide chain length on LPS lipid (lipid A)-dependent activation of the classical pathway of complement (CPC). To examine specific lipid A-dependent activation of the CPC, sera deficient in alternative pathway of complement activity were prepared by the removal of factor D. Absorption of normal human sera with formalinized rabbit erythrocytes was found to remove natural antibodies, factors capable of forming LPS complexes which activate the CPC, or both. By using such factor D-depleted formalinized rabbit erythrocyte-absorbed normal human sera, only isolated lipid A and Re-chemotype LPS (R595 LPS) were found to activate the CPC. Thus, the presence of the additional monosaccharide L-glycero-D-mannoheptose in the Rd2 LPS oligosaccharide chain compared with the L-glycero-D-mannoheptose-deficient Re-chemotype LPS structure is sufficient to block lipid A-dependent activation of the CPC by LPS.     

Sialic acid of group B Neisseria meningitidis regulates alternative complement pathway activation.

The effect of meningococcal cell-associated sialic acid on activation of the human alternative complement pathway was examined by using a quantitative fluorescence immunoassay to assess alternative pathway-mediated C3 binding to a group B strain of Neisseria meningitidis from which graded amounts of sialic acid had been removed with neuraminidase. Using human serum absorbed with strain B16B6 (B:2a:L2,3) and chelated with 10 mM MgCl2 and 10 mM ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid, we found an increase in the amount of C3 bound by enzymatically desialylated B16B6 organisms over the amount bound by fully sialylated organisms. This increase was proportional to the amount of sialic acid cleaved from the bacteria. Enhanced C3 binding was accompanied by an increase in factor B deposition. A sialic acid-deficient mutant of strain B16B6, designated 2T4-1, bound C3 via the alternative pathway at a level equivalent to that bound by wild-type meningococci from which 88% of the sialic acid had been removed. Strain B16B6 was resistant to the alternative pathway-mediated bactericidal activity of both absorbed and hypogammaglobulinemic human sera, whereas noncapsular variant 2T4-1 was sensitive to these sera. The addition of purified immune immunoglobulin M (IgM) and IgG significantly increased the alternative pathway-mediated killing of strain B16B6 organisms. IgM mediated increased bactericidal activity without an increase in C3 or factor B deposition. In contrast, the IgG-mediated killing was associated with increased binding of C3 and factor B to the organisms. Absorption studies showed that the IgM bound to the sialic acid capsule, whereas the IgG bound to noncapsular surface antigens. We conclude from these results that the group B meningococcal sialic acid capsule inhibits activation of the alternative pathway in the nonimmune host and that both IgM and IgG, although specific for different surface antigens, are capable of augmenting the alternative pathway-mediated killing of group B meningococci.     

Antiganglioside antibodies--their pathophysiological effects on Guillain-Barré syndrome and variants

Gangliosides, N-acetylneuraminic acid (sialic acid)-bearing glycosphingolipids, are believed to reside in clusters within membrane microdomains, called lipid rafts or glycosynapse. Recent studies demonstrated that antiganglioside antibodies play an important role in the pathogenesis of Guillain-Barré syndrome (GBS) and Fisher syndrome (FS). The anti-GM1 antibodies are likely to damage peripheral nerves through complement activation with dysfunction of voltage-gated sodium channels. Some antiganglioside antibodies may cause dysfunction of voltage-gated calcium channels without complement activation. Clustered epitopes of ganglioside complexes (GSCs) consisting of two gangliosides can be targeted by serum antibodies in GBS and FS. Anti-GD1a/GD1b complex antibodies are associated with severe GBS. Approximately 50% of FS patients have antibodies to GSCs containing GQ1b or GT1a. Various glycolipids including GSCs may form complex glycolipid environment in the cell membrane, regulating the accessibility and the avidity of antiganglioside antibodies. In addition to antibody specificity, the glycolipid environment or specific distribution of target gangliosides in peripheral nervous system can influence pathogenic effects of antiganglioside antibodies in GBS and FS. Conformational and functional analyses of glycoepitopes of GSCs in the biological membrane will provide new vistas to research on antibody-antigen interaction in GBS, and shed light on microdomain function mediated by carbohydrate-to-carbohydrate interaction.     

Activation of the classical and alternative pathways of complement by Treponema pallidum subsp. pallidum and Treponema vincentii

Both in vivo and in vitro studies have indicated that complement plays an important role in the syphilitic immune responses. Few quantitative data are available concerning activation of the classical pathway by Treponema pallidum subsp. pallidum, and no information is available on treponemal activation of the alternative pathway. Activation of both pathways was compared by using T. pallidum subsp. pallidum and the nonpathogen T. vincentii. With rabbit and human sources of complement, both organisms rapidly activated the classical pathway, as shown by hemolysis of sensitized sheep erythrocytes and by the generation of soluble C4a. With human sources of complement, both organisms also activated the alternative pathway, as shown by hemolysis of rabbit erythrocytes and by the generation of soluble C3a in the presence of magnesium ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA). During incubation, organisms remained actively mobile and did not lyse, indicating that activation was a function of complement reactivity with the intact outer treponemal surface. In addition, freshly harvested T. pallidum subsp. pallidum immediately activated both pathways of complement; preincubation of organisms did not enhance complement reactivity. T. vincentii was a more potent activator of this pathway. T. pallidum subsp. pallidum contained almost four times as much surface sialic acid as T. vincentii did. When sialic acid was enzymatically removed from T. pallidum subsp. pallidum, enhanced activation of the alternative pathway was detected. It is proposed that T. pallidum subsp. pallidum retards complement-mediated damage by the alternative pathway through surface-associated sialic acid. This may be an important virulence determinant that enables these organisms to readily disseminate through the bloodstream to infect other tissues.     

Helicobacter pylori and complex gangliosides

Recognition of sialic acid-containing glycoconjugates by the human gastric pathogen Helicobacter pylori has been repeatedly demonstrated. To investigate the structural requirements for H. pylori binding to complex gangliosides, a large number of gangliosides were isolated and characterized by mass spectrometry and proton nuclear magnetic resonance. Ganglioside binding of sialic acid-recognizing H. pylori strains (strains J99 and CCUG 17874) and knockout mutant strains with the sialic acid binding adhesin SabA or the NeuAcalpha3Galbeta4GlcNAcbeta3Galbeta4GlcNAcbeta-binding neutrophil-activating protein HPNAP deleted was investigated using the thin-layer chromatogram binding assay. The wild-type bacteria bound to N-acetyllactosamine-based gangliosides with terminal alpha3-linked NeuAc, while gangliosides with terminal NeuGcalpha3, NeuAcalpha6, or NeuAcalpha8NeuAcalpha3 were not recognized. The factors affecting binding affinity were identified as (i) the length of the N-acetyllactosamine carbohydrate chain, (ii) the branches of the carbohydrate chain, and (iii) fucose substitution of the N-acetyllactosamine core chain. While the J99/NAP(-) mutant strain displayed a ganglioside binding pattern identical to that of the parent J99 wild-type strain, no ganglioside binding was obtained with the J99/SabA(-) mutant strain, demonstrating that the SabA adhesin is the sole factor responsible for the binding of H. pylori bacterial cells to gangliosides.     

Activation of human monocyte chemiluminescence response by acylpoly(1,3)galactosides derived from Klebsiella pneumoniae.

The stimulating activity of several preparations isolated from a membrane proteoglycan of a nonencapsulated smooth strain of Klebsiella pneumoniae (Kp-MPG) on the oxidative burst of human blood monocytes was assessed by luminol-enhanced chemiluminescence (CL). Five Kp derivatives were studied: a 34-kd acylpoly(1,3)galactoside (APG), obtained by drastic alkaline hydrolysis and purified by chromatography; an APG preparation subjected to acid hydrolysis that removed the core part and all fatty acids, leaving intact the galactose chain of APG (GC-APG); an APG preparation subjected to mild oxidation (ox APG); a preparation obtained by mild alkaline hydrolysis of Kp-MPG, containing additional ester-linked C14 and C16 fatty acids bound to the APG molecule (EFA-APG); and a polymer of the latter compound, APG pol. EFA-APG directly stimulated monocyte CL, whereas Kp-MPG, APG pol, and the whole bacterial cells had little or no activity. APG itself and ox APG induced a weaker response than EFA-APG. Polymyxin B sulfate completely inhibited the CL response to bacterial lipopolysaccharide (LPS) but not to EFA-APG. The stimulating action of EFA-APG on blood monocytes was dependent on the extracellular levels of both calcium and magnesium. Preincubation of monocytes with monoclonal antibody anti-Mac-1 directed against CD11b, the alpha chain of complement receptor type 3 (CR3; CD11b/CD18), strongly inhibited CL activation by EFA-APG and to a lesser extent CL activation by unopsonized zymosan and rough LPS. Altogether, these findings provide indirect evidence for the contribution of the CD11b/CD18 integrin in the functional interaction of EFA-APG with monocyte membranes. They demonstrate the role of fatty acids in the triggering of monocyte oxidative burst, while the polysaccharide chain itself does not contribute to induction of the CL response in this model. In keeping with the effects of EFA-APG and APG, we show that the monocyte CL response was triggered by bacterial LPS from the rough strain of Salmonella minnesota Re 595 and its lipid A, but not by LPS from smooth strains, again suggesting a critical role for the lipid moiety.     

Complementary Recognition of Alternative Pathway Activators by Decay-Accelerating Factor and Factor H

The alternative complement pathway (ACP) functions as a surveillance mechanism by which microorganisms are opsonized with C3b in the absence of specific antibodies. The effectiveness of the ACP relies on its ability to distinguish self from non-self. This recognition function is mediated by C3 regulatory proteins including serum factor H, membrane cofactor protein (MCP), and membrane decay-accelerating factor (DAF). H activity against bound C3b can be increased by host components such as sialic acid and decreased by microbial polysaccharides. DAF and MCP may also recognize cell surface changes such as the presence of viral glycoproteins, since some virus-infected and tumor cells activate the ACP. In the present study, liposomes containing wild-type and mutant Salmonella minnesota lipopolysaccharide (LPS) were tested for ACP activation in serum. LPS-containing liposomes with bound C3b were then tested for their susceptibility to C3 convertase regulation by H and membrane DAF and for the sensitivity of their bound C3b to the cofactor activity of H. The results indicate that while the shortest mutant, Re595 LPS, did not induce ACP activation, R7 LPS containing an additional disaccharide did. This activation was poorly regulated by DAF but was inhibited by H. The regulatory activity of H for liposome-bound C3b, however, decreased when LPS of greater polysaccharide size was present in the membrane. In contrast the ACP activation induced by the phospholipid phosphatidylethanolamine was effectively inhibited by DAF but only poorly inhibited by H.     

Specific binding of lipopolysaccharides to mouse macrophages--I. Characteristics of the interaction and inefficiency of the polysaccharide region

Tritium-labeled lipopolysaccharide interacted specifically and reversibly with mouse peritoneal macrophages. The binding was higher at 22 degrees C than at 4 degrees C, but was no longer observable at 37 degrees C. The specificity of the interaction (inhibition with unlabeled LPS) was strictly dependent on the presence of serum, and required divalent cations. The binding was saturable. The specific binding sites of peritoneal macrophages were saturated with 6-9 x 10(6) LPS molecules/cell, and those of macrophage-like cell lines with 2-3 x 10(6) molecules/cell. The binding of LPS was not inhibited by ligands of scavenger receptors (maleylated BSA) or complement receptors (zymosan), but was strongly inhibited with dexamethasone, a glucocorticoid which is known to modulate the expression of other surface markers of macrophages. The polysaccharide region of the LPS, as well as 3-deoxy-2-octulosonic acid (KDO) coupled to bovine serum albumin, did not bind to macrophages, whereas a specific binding was observed with a lipid A-BSA conjugate.     

Possible mechanisms of the first step of the classical complement activation pathway: binding and activation of C1.

Different immunoglobulin preparations of human monoclonal IgM, normal human and rat IgG, as well as purified rabbit antibodies were treated by various methods, fragmentation, aggregation and complexing with antigen. The ability of the treated and untreated preparations to fix isolated human C1, to activate the classical complement pathway (to consume C4 in normal human serum) were compared. It was found that the different methods affected the conformation of the immunoglobulin molecules in different ways and induced changes to a greater or lesser extent in the two capacities of the preparations tested. In the case of the monoclonal IgM preparation a strong C1-fixation was observed without measurable complement activation. Other preparations, interfacially aggregated human IgG, BSA-anti-BSA and OA-anti-OA immune complexes had a very weak C1-fixing but a marked complement activating capacity. Some preparations, e.g. heat-aggregated IgG, both fixed and activated C1 effectively, aggregates with a complement-activating capacity without C1-fixing effect were separated by gel-filtration. It was demonstrated further, that at a given time only a part of the activated C1 molecules could be found fixed to the immunoglobulins, the other part was released into the fluid phase after activation. On the basis of the results of this and previous studies a hypothesis is proposed suggesting three possible results of the interaction between C1 and the different preparations: (1) firm fixation and activation; (2) binding not followed by activation and (3) a transient binding leading to activation. The possible application of this hypothesis for the interpretation of the results of the different methods for detecting immune complexes is discussed.     

Epitope specificities of murine monoclonal and rabbit polyclonal antibodies against enterobacterial lipopolysaccharides of the Re chemotype.

Murine monoclonal and rabbit polyclonal antibodies raised against the lipopolysaccharides (LPS) of Re mutants of Salmonella minnesota, Proteus mirabilis, and Escherichia coli were serologically characterized. Using natural Re LPS and natural and synthetic partial structures thereof, representing the 3-deoxy-D-manno-2-octulosonic acid (KDO) or lipid A region or both, the epitope specificities of four monoclonal antibodies were defined. Clones 20 (immunoglobulin M [IgM]) and 25 (IgG3) recognize a terminal alpha-pyranosidically linked KDO monosaccharide residue and the alpha-2,4-linked KDO disaccharide, respectively, as the immunodominant group. Therefore, these two antibodies are core antibodies which do not require the presence of lipid A constituents for binding. The minimal structure enabling binding of clone 17 (IgG2b) is a pseudotetrasaccharide of the sequence alpha-KDO-(2----4)-alpha-KDO-(2----6)-beta-glucosamine-(1----6)- glucosaminitol with two amide-linked 3-hydroxytetradecanoic acid residues. The smallest structure with which clone 22 (IgG3) reacted was de-O-acylated Re LPS. Therefore, clones 17 and 22 are LPS antibodies requiring both the lipid A and the KDO region for binding. Phosphoryl residues of the lipid A moiety in Re LPS are dispensable for the reaction with clone 17, whereas they are necessary for that with clone 22. These four different antibody types were also detected in polyclonal rabbit antisera and could be distinguished from each other by absorption experiments. It was found that type 20 and 25 antibodies either were not present or were present only in small amounts and that the majority of the antibodies were of types 17 and 22. From these data, we conclude that the immunodominant structures of Re LPS comprise both the KDO and lipid A domains.     

A 28,000-dalton protein of normal mouse serum binds specifically to the inner core region of bacterial lipopolysaccharide.

Normal mouse serum was found to contain a protein, referred to here as factor, which binds to the inner core region of lipopolysaccharides (LPSs) of various bacterial families. Since factor-LPS interactions resulted in activation of guinea pig complement, factor activity could be assayed by a passive hemolysis test with sheep erythrocytes coated with LPS or lipid A from Acinetobacter calcoaceticus (which was found earlier to bind particularly well to factor). Factor was purified by G-50 and hydroxyapatite chromatography whereby the specific hemolytic activity was enriched 1,675-fold. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions revealed the presence of a 28,000-dalton protein as the main band. The identity of this band was determined by absorption experiments with LPS-coated sheep erythrocytes or latex beads, whereby the 28,000-dalton band disappeared after specific absorption and could be recovered from the absorbent. The binding specificity of factor was determined in a passive hemolysis inhibition assay with defined oligosaccharides representative for the inner core region of LPS. Thus, the di- and trisaccharides alpha-D-mannoheptopyranosyl-(1----5)-2-keto-3-deoxy-D-mannoocto nic acid and alpha-D-mannoheptopyranosyl-(1----3)-alpha-D-mannoheptopyranosy l-(1----5)-2- keto-3-deoxy-D-mannooctonic acid, respectively, were able to inhibit binding of factor to LPS. The results are in accordance with our earlier observation that the heptose-2-keto-3-deoxy-D-mannooctonic acid region represents a common antigen of bacterial LPS. Rabbit hyperimmune serum directed against this common antigen and purified factor was found to exhibit the same specificity for LPS. Factor activity was followed in mice in vivo after injection of LPS; it disappeared completely 15 min after the injection of LPS and reappeared within 1 h.     

Gangliosides can activate human alternative complement pathway

The alternative complement pathway (ACP) in vertebrates is knownto be important in inflammatory reactions, and to be activatedby foreign substances such as bacterial lipopolysaccharide (LPS)and zymosan, although to date no intrinsic activators have beenidentified except complement receptor type 2. From the pointof the structural similarity of LPS to ganglioside, we haveinvestigated gangliosides which are abundantly present in animalcells for their activity on the human ACP. All of seven gangliosidestested were found to activate this pathway in a manner dependingon the number of sialic acids and neutral sugars contained inthe molecules. A dose - response study suggested a correlationof the threshold in ganglioside concentration with its criticalmicelle concentration. Gangliosides may thus serve as an intrinsicactivator for ACP in animals, thereby leading to inflammation.The possibility of the participation of sialidase in complementactivation is also discussed.     

Modulation of murine macrophage metabolism by glycolipids: inhibition of LPS-induced metabolism by specific gangliosides

We have investigated the ability of gangliosides isolated from murine brain to modulate macrophage metabolism. LPS elicits a profound increase in glucose consumption by cultured resident macrophages. When highly purified mouse brain gangliosides are added to macrophage cultures, a modest inhibition of baseline glucose utilization occurs. Both disialogangliosides and trisialogangliosides mediate this effect. In the absence of serum, these gangliosides may be toxic to cultured macrophages. GT1b is the only brain ganglioside tested that specifically inhibited LPS-induced macrophage metabolism. Sialic acid appears to be a necessary component of the gangliosides, although it is not sufficient to induce inhibition. Asialoganglioside and free sialic acid have no effect on macrophage metabolism in comparison with intact gangliosides. The inhibition of LPS-induced metabolism may be explained by the ability of LPS to form stable molecular complexes with both disialogangliosides and trisialogangliosides. These experiments also suggest that the ganglioside content of macrophages may influence functional responses of macrophages to exogenous stimuli.