Bactericidal response of channel catfish (Ictalurus punctatus) by the classical and alternative complement pathways against bacterial pathogens

The alternative and classical complement pathways of channel catfish (Ictalurus punctatus), most importantly the classical complement pathway which requires antibody, demonstrated bactericidal activity against two Gram-negative bacterial fish pathogens, Flexibacter columnaris and Vibrio anguillarum. This shows the importance of antibody-mediated bactericidal immunity in fish by the classical complement pathway in providing protection following immunization or natural infections.     

Evidence for different requirements in physical state for the interaction of lipopolysaccharides with the classical and alternative pathways of complement

The influence of the state of aggregation of lipopolysaccharides upon their ability to interact with serum complement via either the classical or alternative pathway was studied. The anticomplement properties of two chromatographically distinct fractions of a phenol-extracted lipopolysaccharide isolated from Serratia marcescens were assessed by means of the standard sheep erythrocyte hemolytic assay and an alternative pathway-selective kinetic assay using rabbit erythrocytes. Both the high molecular weight PI fraction and the lower molecular weight PII fraction exerted anti-complement activity as determined in the sheep erythrocyte assay. Conversion of fractions PI and PII to their more soluble triethylamine salt forms resulted in a decrease in sedimentation coefficients and a corresponding loss of anticomplement activity. Further, the anticomplement activity of fractions PI and PII in the sheep erythrocyte assay was inhibited by polymyxin B, indicating a role for the lipid A region. Unlike the PII fraction, only the PI fraction can activate serum complement via the alternative pathway. This activity is not inhibited by polymyxin B, indicating that the response is not lipid A-mediated. Significantly, solubilization of the PI fraction with triethylamine had no effect on its ability to activate the alternative pathway. These studies clearly demonstrate that the interaction between lipopolysaccharides and serum complement is influenced by the state of lipopolysaccharide aggregation. However, this appears to be the case for lipopolysaccharide activation of the classical pathway but not of the alternative pathway.     

Induction of ornithine decarboxylase in macrophages by bacterial lipopolysaccharides (LPS) and mycobacterial cell wall material

Lipopolysaccharide from $\text{E. Coli}$ (LPS) and BCG cell walls (BCGcw) are recognized immunoadjuvants that directly stimulate some macrophage functions. The macrophage cell line J774.1 and peritoneal exudate cells (PEC) from mice can be stimulated by LPS or other adjuvants $\text{in vitro}$ to synthesize and release protein factor(s) that activate thymus-derived lymphocytes. We have utilized J774.1 cells and PEC to demonstrate that an increase in ornithine decarboxylase (ODC) activity is a marker of early biochemical changes in adjuvant-stimulated macrophages. BCGcw and LPS increased ODC within 2 hours in J774.1 cells as well as murine peritoneal exudate macrophages. Maximal increases in ODC were detected 4 hours after the addition of adjuvants to J774.1 cells. The marked increases (12–23 fold) in ODC observed with BCGcw (20 μg/ml) did not appear to involve an effect on cell proliferation which was suppressed by this adjuvant. Cycloheximide inhibited the induction of ODC by LPS and BCGcw in the macrophage cell line. Evidence that the induction of ODC may be promoted by an increase in cyclic AMP was provided by experiments demonstrating that prostaglandin E₁ (PGE₁) and 8-bromo-adenosine-3′:5′-monophosphate (8Br-cyclic AMP) can mimic the effects of LPS and BCGcw in J774.1 cells. These observations indicate that one of the early biochemical changes in macrophages promoted by adjuvants is an induction of ODC.     

Interaction between complement subcomponent C1q and bacterial lipopolysaccharides.

The heptose-less mutant of Escherichia coli, D31m4, bound complement subcomponent C1q and its collagen-like fragments (C1qCLF) with Ka values of 1.4 x 10(8) and 2.0 x 10(8) M-1 respectively. This binding was suppressed by chemical modification of C1q and C1qCLF using diethyl pyrocarbonate (DEPC). To investigate the role of lipopolysaccharides (LPS) in this binding, biosynthetically labelled [14C]LPS were purified from E. coli D31m4 and incorporated into liposomes prepared from phosphatidylcholine (PC) and phosphatidylethanolamine (PE) [PC/PE/LPS, 2:2:1, by wt.]. Binding of C1q or its collagen-like fragments to the liposomes was estimated via a flotation test. These liposomes bound C1q and C1qCLF with Ka values of 8.0 x 10(7) and 2.0 x 10(7) M-1; this binding was totally inhibited after chemical modification of C1q and C1qCLF by DEPC. Liposomes containing LPS purified from the wild-strain E. coli K-12 S also bound C1q and C1qCLF, whereas direct binding of C1q or C1qCLF to the bacteria was negligible. Diamines at concentrations which dissociate C1 into C1q and (C1r, C1s)2, strongly inhibited the interaction of C1q or C1qCLF with LPS. Removal of 3-deoxy-D-manno-octulosonic acid (2-keto-3-deoxyoctonic acid; KDO) from E. coli D31m4 LPS decreases the binding of C1qCLF to the bacteria by 65%. When this purified and modified LPS was incorporated into liposomes, the C1qCLF binding was completely abolished. These results show: (i) the essential role of the collagen-like moiety and probably its histidine residues in the interaction between C1q and the mutant D31m4; (ii) the contribution of LPS, particularly the anionic charges of KDO, to this interaction.     

Activation of classical pathway of complement cascade by soluble oligomers of prion

Mice defective for C1q complement factor show enhanced resistance to peripheral prion inoculation, and previous work demonstrated a direct interaction between C1q and conformationally modified PrP. However, the nature and physiological consequences of this interaction remain uncharacterized. PrP amino acids 141-159 has been identified as a potential C1q binding site; we show, by both surface plasmon resonance (SPR) spectroscopy and ELISA, that C1q and its globular region bind to PrP mutagenized in the region of interest with comparable efficiency to that of wild-type protein. To test PrP's ability to activate complement, soluble oligomers of the PrP constructs were made. Only PrP and mutagenized PrP oligomers activate the classical complement cascade while PrP monomer and the C-terminal domain, both in oligomeric and in monomeric form, failed to induce activation. This suggests that a conformational change in PrP, which occurs both when PrP is bound to an SPR sensor chip and when it undergoes oligomerization, is requisite for PrP/C1q interaction and activation of the complement cascade. We propose that C1q may act as a natural sensor for prions, leading to activation of the classical complement cascade, which could result in local inflammation and subsequent recruitment of the immune cells that prions initially infect.     

Activation of the classical pathway of human complement by a human monoclonal IgE, IgE(DES)

Activation of the classical pathway of human complement by monoclonal IgE from patient DES was demonstrated by using IgE(DES) coupled to latex particles. This material depleted human serum of C1 and C4 hemolytic activities. In addition, C3bi was deposited in a calcium-dependent way onto the insolubilized IgE as shown by the agglutination of latex by conglutinin. The alternative pathway was also activated. These anticomplementary activities were dose and time dependent. Moreover, we confirmed that another monoclonal IgE, IgE(PS), activated the alternative pathway exclusively. Particular attention was paid to exclude contamination by other immunoglobulins or C-reactive protein, generation of artifacts due to the chemical coupling, and the presence of proteolytic enzymes in the IgE(DES) preparation. Moreover, evidence is also presented against the involvement of IgG or IgM anti-IgE autoantibodies that could activate the classical pathway after their binding to insolubilized IgE(DES). Although one cannot exclude the possibility that IgE(DES) or IgE(PS) are abnormal proteins, these findings suggest the existence of an isotypic or allotypic variation of IgE.     

Activation of the classical pathway of complement by the C3NeF-stabilized cell-bound amplification convertase.

C3 nephritic factor (C3NeF) has been shown to be composed of two heavy and two light chains, like IgG; in addition it shares antigenic determinants with IgG. C3NeF, purified from the sera of eight patients by incorporation of C3NeF into the stabilized fluid phase amplification C3 convertase, C3bBb(C3NeF), followed by its release after decay of convertase function, was investigated for its ability to bind 125I-C1q and to activate 125I-C1. It was found that although fluid phase C3b,Bb(C3NeF) is fully capable of binding 125I-C1q, it is not able to activate 125I-C1 even at concentrations of 1.3 x 10(12) C3bBb(C3NeF) complexs/ml. On the other hand, cell-bound C3bBb(C3NeF) is capable of both binding 125I-C1q and activating 125I-C1. This discrepancy between fluid phase and cell-bound, C3bBb(C3NeF) was found for C3NeF preparations from eight different patients and therefore seems to apply to all C3NeF preparations.     

Pseudomonas aeruginosa alkaline protease blocks complement activation via the classical and lectin pathways

The complement system rapidly detects and kills Gram-negative bacteria and supports bacterial killing by phagocytes. However, bacterial pathogens exploit several strategies to evade detection by the complement system. The alkaline protease (AprA) of Pseudomonas aeruginosa has been associated with bacterial virulence and is known to interfere with complement-mediated lysis of erythrocytes, but its exact role in bacterial complement escape is unknown. In this study, we analyzed how AprA interferes with complement activation and whether it could block complement-dependent neutrophil functions. We found that AprA potently blocked phagocytosis and killing of Pseudomonas by human neutrophils. Furthermore, AprA inhibited opsonization of bacteria with C3b and the formation of the chemotactic agent C5a. AprA specifically blocked C3b deposition via the classical and lectin pathways, whereas the alternative pathway was not affected. Serum degradation assays revealed that AprA degrades both human C1s and C2. However, repletion assays demonstrated that the mechanism of action for complement inhibition is cleavage of C2. In summary, we showed that P. aeruginosa AprA interferes with classical and lectin pathway-mediated complement activation via cleavage of C2.     

Stimulation of guinea pig macrophage pinocytosis by lipopolysaccharides (LPS): Evidence that LPS acts directly on the macrophage

Bacterial lipopolysaccharide can enhance the pinocytosis of horseradish peroxidase in guinea pig macrophages. This increased uptake can be seen as early as 6 hr after incubation in a spinner suspension culture. An equivalent amount of enhanced pinocytosis can be seen if plated, washed peritoneal exudate macrophages are used. Plated guinea pigs PECs, washed five times, were examined for the presence of B cells, and none were found. Thus, LPS appears to stimulate the macrophage directly and does not require a lymphocyte intermediary. The active stimulatory moiety appears to be lipid A, which can be blocked by preincubation of LPS with polymyxin B.     

Substitution pattern of 3-deoxy-D-manno-oct-2-ulosonic acid in bacterial lipopolysaccharides investigated by methylation analysis of whole LPS

3-Deoxy-D-manno-oct-2-ulosonic acid (Kdo) is a constituent of the inner core part of bacterial lipopolysaccharides (LPS). This sugar may contribute to biological activities of the LPS, the type of substitution of Kdo is thus of importance and this work is aimed at the evaluation of a method for monitoring the substitution of Kdo in LPS. The procedure consists of three steps, namely permethylation of the lipopolysaccharide, with iodomethane and sodium methylsulfinylmethanide or NaOH in Me(2)SO, or with methyl triflate, then the product is methanolysed with HCl in MeOH and acetylated with acetic anhydride in pyridine. The resulting partially methylated acetates of Kdo methyl glycosides were analyzed by gas-liquid chromatography-electron impact ionization mass spectrometry (GLC-MS). For several derivatives of Kdo, specific GLC retention times and MS fragmentation patterns were determined. Lipopolysaccharides from several bacterial strains were isolated and analyzed with three different methods of methylation. The complete solubilization of the LPS in the acid form allows diminishing possible undermethylation. Sodium methylsulfinylmethanide is the most efficient agent in the permethylation of the whole LPS, of all the tested procedures. Methylation with methyl triflate allows the detection of base labile substituents on Kdo residues.     

The role of surface charge in the activation of the classical and alternative pathways of complement by liposomes

We have studied the complement-activating properties of liposomes. We show that surface charge is a key determinant of complement-activating liposomes. The nature of the charge, whether negative or positive, appears to dictate which pathway of the complement system is activated. Phosphatidylcholine:cholesterol (PC:CHOL, 55:45 mol/mol) liposomes were made to exhibit a positive or negative surface charge by the addition of cationic or anionic lipids, respectively. Normal human or guinea pig serum was incubated with liposomes, followed by determining the residual hemolytic activity of the serum as a measure of complement activation. Negatively charged liposomes containing phosphatidyl-glycerol, phosphatidic acid, cardiolipin, phosphatidylinositol, or phosphatidylserine activated complement in a Ca(2+)-dependent manner suggesting activation occurred via the classical pathway. Positively charged liposomes containing stearylamine or 1,2-bis(oleoyloxy)-3-(trimethylammonio)propane activated complement via the alternative pathway. Neutral liposomes, PC:CHOL (55:45) and PC:CHOL:dipalmitoylphosphatidylethanolamine (35:45:20), failed to activate complement as measured by the hemolytic assays. We show that unsaturated liposomes are more potent complement activators than saturated liposomes and that 45 mol% cholesterol promotes complement protein-liposome interactions. Immunoblot analysis of phosphatidylglycerol-containing liposomes showed that C3b and C9 were associated with these liposomes. Thus, the complement consumption measured in the hemolytic assays represents active cleavage of the complement components and not passive adsorption to the liposome surface. These studies suggest that membranes composed of net charged phospholipids can activate the complement system. This observation underlines the importance in biologic membranes of complement regulatory proteins that protect normal cells from complement attack.     

Activation of the complement cascade by trypsin

In twenty-three patients with acute pancreatitis, the plasma levels of immunoreactive trypsin were determined with a RIA method. The patients were divided into groups according to the severity of the disease. Ranson's criteria and the development of multisystem organ failure were used for the classification. Elevated plasma levels of immunoreactive trypsin were found in all groups after admittance. Incubation of fresh human serum and plasma with bovine trypsin in concentrations between 10(-6) and 10(-4) M at 20 degrees C activated the complement cascade. The anaphylatoxins C3a and C5a were determined with a RIA and the terminal complement complex (TCC) with an ELISA method. C3a and C5a were released and TCC was formed. The effect of trypsin on leukocyte activation was determined with a chemiluminescence technique. Trypsin dissolved in saline did not activate the leukocytes. However, serum digested by trypsin-activated leukocytes in a dose-dependent manner. The present study supports the theory that trypsin can activate complement components and results in formation of split products which have potent vascular, and leukocyte activating effects.     

Activation of complement component C5: comparison of C5 convertases of the lectin pathway and the classical pathway of complement

Although the initiating complex of lectin pathway (called M1 in this study) generates C3/C5 convertases similar to those assembled by the initiating complex (C1) of the classical pathway, activation of complement component C5 via the lectin pathway has not been examined. In the present study kinetic analysis of lectin pathway C3/C5 convertases assembled on two surfaces (zymosan and sheep erythrocytes coated with mannan (E(Man))) revealed that the convertases (ZymM1,C4b,C2a and E(Man)M1,C4b,C2a) exhibited a similar but weak affinity for the substrate, C5 indicated by a high K(m) (2.73-6.88 microm). Very high affinity C5 convertases were generated when the low affinity C3/C5 convertases were allowed to deposit C3b by cleaving native C3. These C3b-containing convertases exhibited K(m) (0.0086-0.0075 microm) well below the normal concentration of C5 in blood (0.37 microm). Although kinetic parameters, K(m) and k(cat), of the lectin pathway C3/C5 convertases were similar to those reported for classical pathway C3/C5 convertases, studies on the ability of C4b to bind C2 indicated that every C4b deposited on zymosan or E(Man) was capable of forming a convertase. These findings differ from those reported for the classical pathway C3/C5 convertase, where only one of four C4b molecules deposited formed a convertase. The potential for four times more amplification via the lectin pathway than the classical pathway in the generation of C3/C5 convertases and production of pro-inflammatory products, such as C3a, C4a, and C5a, implies that activation of complement via the lectin pathway might be a more prominent contributor to the pathology of inflammatory reactions.