Structure and activation of complement components C2 and factor B

The activation of complement is initiated by two independent pathways. Each leads to the formation of a complex protease, C3 convertase, with equivalent specificity and function but different composition. The convertase derived from the classical pathway is composed of complement components C4 and C2 while that from the alternative pathway consists of components C3 and Factor B. C2 and Factor B contain the catalytic site of each convertase respectively. The amino acid sequence of Factor B has been determined. Limited sequence of CNBr-peptides isolated from C2 has also been obtained. The two enzymes are shown to be homologous and to represent a novel type of serine proteinase, characterized by their unusual structure and mechanism of activation, when compared to known serine proteinases.     

Purification and functional analysis of the polymorphic variants of the C3b/C4b receptor (CR1) and comparison with H, C4b-binding protein (C4bp), and decay accelerating factor (DAF)

Four CR1 variants have been found in the normal population and are designated CR1-A (190,000 daltons), CR1-B (220,000 daltons), CR1-C (160,000 daltons), and CR1-D (250,000 daltons). In the present study, we first developed an improved chromatographic purification scheme for CR1 that does not employ a C3b affinity step. CR1 variants (A, B, and C) were then isolated, and their individual functional activity was assessed. Each possessed similar co-factor activity for I-mediated cleavage of C3(H2O), as well as for the inhibitory activity for fluid phase C3 convertases. These results indicate that, despite relatively large Mr differences, in the purified state these three CR1 variants have similar functional activities. The functional activity of CR1 was also compared with C4bp, H, and decay accelerating factor (DAF) in fluid phase assays designed to assess the inhibition of the C3 convertases and co-factor activity. On a molar basis, CR1 had approximately the same inhibitory activity as C4bp for the classical pathway convertase, and had the same as H for the alternative pathway convertase. These results indicate that CR1 encompasses the functional capabilities of both proteins. They also raise a number of interesting genetic and structural questions in regard to these complement regulatory proteins, because C4bp is thought to have multiple C4b binding domains, whereas H is reported to bind one C3b. DAF was an approximately fourfold better inhibitor of the alternative pathway convertase than CR1 or H, but was a fourfold less efficient inhibitor of the classical pathway convertase than CR1 or C4bp. The effective inhibitory capacity of DAF in these fluid phase assay systems suggests that the DAF substrate specificity is for the convertases. Fluid phase CR1 was twofold less efficient than H in serving as a co-factor for the first cleavage of fluid phase C3b, and hardly mediated the second cleavage. These data are in contrast to the co-factor activity of CR1 on a cell membrane, and provide additional evidence for the local environment being a critical modulator of the function of proteins that regulate the activation of C3.     

Eosinophil granule major basic protein regulates generation of classical and alternative-amplification pathway C3 convertases in vitro

Eosinophil major basic protein (MBP), a highly charged polycation, forms the core of the eosinophil granule and mediates tissue damage in allergic disease. Purified MBP was studied for capacity to regulate the generation of classical and alternative-amplification pathway C3 convertases because previous studies have shown that other polycations (protamine, poly-L-lysine) and polyanions (heparin) may play important roles in regulating C activation. MBP inhibited the generation of EAC1,4b,2a and EAC4b,3b,Bb,P but appeared to inhibit the generation of classical pathway convertase more than the alternative amplification pathway convertase at a given dose. Dose-response curves with MBP were steeper than curves seen with polyanion (heparin). MBP did not lyse cellular intermediates at concentrations that caused almost total inhibition of convertase generation. One mechanism of inhibition of convertase generation may have been through an action on C3b, because preincubation of MBP with an EAC4b,3b cellular intermediate interfered with the ability of this cellular intermediate to be lysed. Furthermore, MBP prevented consumption of B in a reaction mixture that contained factors B, D, and C3b, also suggesting an action on C3b. Reduced and alkylated MBP (A-MBP) was compared with native MBP, which possesses two reactive sulfhydryl groups, to determine whether charge alone is responsible for blocking convertase generation; native MBP rapidly associates and is relatively insoluble at neutral and alkaline pH whereas A-MBP remains soluble. A-MBP impaired convertase generation, did not appear to remain bound to cellular intermediates and did not suppress B consumption in the fluid phase assay. This suggests that the ability of MBP to regulate C activation is complex and not entirely through its net charge. Finally, although heparin or MBP alone may prevent C activation, when these substances were present at the same time there was no effect on C activation suggesting that charge neutralization may abrogate the effects of these charged substances on C activation. Taken together, these studies suggest that MBP at physiologic concentrations may regulate in vivo C activation at the tissue level.     

Reconstitution of C5 convertase of the alternative complement pathway with isolated C3b dimer and factors B and D

C5 convertase of the alternative complement pathway is a trimolecular complex consisting of two molecules of C3b and one molecule of Bb. We previously proposed a model of the alternative pathway C5 convertase in which the second C3b molecule binds covalently to the first C3b molecule bearing Bb, and the C5 molecule binds to each C3b molecule of the covalently linked C3b dimer, resulting in its appropriate presentation to the catalytic site on Bb. In the present study, we purified the covalently linked C3b dimer and reconstituted the C5 convertase with the C3b dimer and factors B and D to obtain evidence in support of this model. An insoluble glucan, OMZ-176, was incubated with human serum to activate the alternative pathway and to allow formation of the alternative C5 convertase on the surface of the glucan, and the glucan bearing the C5 convertase was then solubilized by incubation with glucosidases. In this way, the covalently linked C3b dimer was obtained in solution without using a detergent. The C3b dimer was then separated from enzymes, C3b monomer, C3b oligomer, and other materials by chromatographies. SDS-PAGE analysis demonstrated that the purified C3b dimer had intact alpha'-chains. Alternative pathway C5 convertase was reconstituted when the isolated C3b dimer was incubated with factors B and D. The presence of P enhanced C5 convertase formation threefold. These results support the notions that the formation of the covalently linked C3b dimer is a general phenomenon associated with activation of the alternative pathway and that the C3b dimer acts as a part of the C5 convertase.     

C3 nephritic factor (C3NeF): stabilization of fluid phase and cell-bound alternative pathway convertase.

C3 nephritic factor (C3NeF) defined by the capacity of nephritic serum and its fractions to initiate loss of the B antigen of C3 in normal serum was purified from the serum of three different donors and shown to function by stabilization of membrane-bound and fluid phase alternative pathway C3 convertase. C3NeF converts cell-bound C3B sites in a dose-related manner to CEB(NeF) sites, which exhibit an approximate 10-fold increase in half-life. The linear relationship between the C3NeF input and the residual hemolytic sites on EAC43B present after incubation for 20 min at 30 degrees C, during which labile C3B sites have decayed, indicates that the number of residual C3B sites is directly related to the dose of C3NeF. The capacity of C3NeF to stabilize the C3B convertase in a temperature- and dose-dependent manner, which is independent of binding or consumption of C3NeF, in a fluid phase reaction mixture of 125I-B, 131I-C3 and D permits isolation of a 10S complex containing radiolabeled C3 and B and exhibiting C3, convertase activity on an exogenous C3 source. Thus, the stabilizing effect of C3NeF is not limited to membrane-bound C3B but is also sufficient to permit recovery of a fluid phase C3 convertase formed during the interaction of C3, B, and D.     

Lessons from functional and structural analyses of disease-associated genetic variants in the complement alternative pathway

Complement is an essential component of innate immunity and a major trigger of inflammatory responses. A critical step in complement activation is the formation of the C3 convertase of the alternative pathway (AP), a labile bimolecular complex formed by activated fragments of the C3 and factor B components that is fundamental to provide exponential amplification of the initial complement trigger. Regulation of the AP C3 convertase is essential to maintain complement homeostasis in plasma and to protect host cells and tissues from damage by complement. During the last decade, several studies have associated genetic variations in components and regulators of the AP C3 convertase with a number of chronic inflammatory diseases and susceptibility to infection. The functional characterization of these protein variants has helped to decipher the critical pathogenic mechanisms involved in some of these complement related disorders. In addition, these functional data together with recent 3D structures of the AP C3 convertase have provided fundamental insights into the assembly, activation and regulation of the AP C3 convertase.     

Factor H-related protein 4 activates complement by serving as a platform for the assembly of alternative pathway C3 convertase via its interaction with C3b protein

Human complement factor H-related protein (CFHR) 4 belongs to the factor H family of plasma glycoproteins that are composed of short consensus repeat (SCR) domains. Although factor H is a well known inhibitor of the alternative complement pathway, the functions of the CFHR proteins are poorly understood. CFHR4 lacks SCRs homologous to the complement inhibitory domains of factor H and, accordingly, has no significant complement regulatory activities. We have previously shown that CFHR4 binds C-reactive protein via its most N-terminal SCR, which leads to classical complement pathway activation. CFHR4 binds C3b via its C terminus, but the significance of this interaction is unclear. Therefore, we set out to clarify the functional relevance of C3b binding by CFHR4. Here, we report a novel role for CFHR4 in the complement system. CFHR4 serves as a platform for the assembly of an alternative pathway C3 convertase by binding C3b. This is based on the sustained ability of CFHR4-bound C3b to bind factor B and properdin, leading to an active convertase that generates C3a and C3b from C3. The CFHR4-C3bBb convertase is less sensitive to the factor H-mediated decay compared with the C3bBb convertase. CFHR4 mutants containing exchanges of conserved residues within the C-terminal C3b-binding site showed significantly reduced C3b binding and alternative pathway complement activation. In conclusion, our results suggest that, in contrast to the complement inhibitor factor H, CFHR4 acts as an enhancer of opsonization by promoting complement activation.     

The influence of membrane components on regulation of alternative pathway activation by decay-accelerating factor.

Decay-accelerating factor (DAF) is a C regulatory protein which functions in membranes to inhibit autologous C activation on cell surfaces. A liposome model was used to study the mechanism of DAF action and examine the effects of membrane-bound glycophorin and LPS on the regulatory activity of DAF. Liposomes were incubated in MgEGTA-treated human serum and activation of the alternative pathway measured by C3b binding. Liposomes composed of phosphatidylcholine, phosphatidylethanolamine, and cholesterol activated the alternative pathway in proportion to their content of PE. Incorporation of 10(-7) mol/mol phospholipid of either human E or HeLa cell-derived DAF inhibited C activation by liposomes containing 40% phosphatidylethanolamine by 50%, an efficiency comparable to that observed in intact E. HeLa DAF that had been treated with phosphatidylinositol-specific phospholipase C to remove its glycolipid anchor had no effect on C activation by liposomes at concentrations as high as 10(-5) mol/mol phospholipid. Incorporation of DAF into liposomes prepared with bound C3b inhibited the deposition of additional C3b by C3bBbP. However, the incorporated DAF increased the amount of Bb generated from B in the presence of D indicating that accelerated decay of the convertase was the primary effect of DAF. Similarly, treatment of intact human E with anti-DAF decreased the amount of Bb generated by the alternative pathway convertase. To study the effects of other membrane components on DAF activity, liposomes were prepared with purified human glycophorin A or LPS. In glycophorin liposomes the presence of PE was required to activate the alternative pathway and DAF inhibited this activation. In contrast, LPS liposomes bound C3b independently of PE and the incorporation of DAF had no effect. These results demonstrate that within a membrane, DAF's inhibitory activity on the alternative pathway C3 convertase is mediated independently of other membrane proteins, that in this model the major activity of DAF is to accelerate convertase decay, and that the presence of other membrane molecules that may serve as C3 acceptors can circumvent DAF function.     

The human complement system: assembly of the classical pathway C3 convertase.

The assembly of the classical pathway C3 convertase in the fluid phase has been studied. The enzyme is assembled from C2 and C4 on cleavage of these proteins by C1s. Once assembled, the enzyme activity decays rapidly. Kinetic evidence has been obtained that this decay is even more rapid than previously suggested (kdecay is 2.0 min-1 at 37 degrees C). As a result, optimal C3 convertase activity is only observed with high C1s levels, which result in rapid rates of cleavage of C2 and increased rates of formation of the C3 convertase. Using high concentrations of C1s at lower temperatures (22 degrees C) in the presence of excess substrate we have demonstrated kinetically that the enzyme comprises an equimolar complex of C4b and cleaved C2. We have obtained direct evidence from gel-filtration experiments for the role of C2a as the catalytic subunit of the enzyme. C2b appears to mediate the interaction between C4 (or C4b) and C2 at pH 8.5 and at low ionic strength where the interactions can easily be detected. It may therefore be important in the assembly of the enzyme, though it is not involved in the catalytic activity. The decay of the C3 convertase reflects the release of C2a from the C4b x (C2b) x C2a complex, and the stabilizing effect of iodine on the C3 convertase is therefore apparently one of stabilizing the C4b-C2z interaction, which is otherwise weak. C1s is not a part of the C3 convertase enzyme.     

Functional Analyses of Complement Convertases Using C3 and C5-Depleted Sera

C3 and C5 convertases are central stages of the complement cascade since they converge the different initiation pathways, augment complement activation by an amplification loop and lead to a common terminal pathway resulting in the formation of the membrane attack complex. Several complement inhibitors attenuate convertase formation and/or accelerate dissociation of convertase complexes. Functional assays used to study these processes are often performed using purified complement components, from which enzymatic complexes are reconstituted on the surface of erythrocytes or artificial matrices. This strategy enables identification of individual interactions between convertase components and putative regulators but carries an inherent risk of detecting non-physiological interactions that would not occur in a milieu of whole serum. Here we describe a novel, alternative method based on C3 or C5-depleted sera, which support activation of the complement cascade up to the desired stages of convertases. This approach allows fast and simple assessment of the influence of putative regulators on convertase formation and stability. As an example of practical utility of the assay, we performed studies on thioredoxin-1 in order to clarify the mechanism of its influence on complement convertases.     

Activation of the alternative complement pathway by isolated human glomerular basement membrane

The capacity of isolated human glomerular basement membrane (GBM) to initiate surface activation of the human alternative complement pathway was defined by the deposition of C3b under circumstances in which the classical complement pathway was inoperative. The deposition of C3b from normal or C2-deficient serum was time- and magnesium-dependent, implying a role for the alternative pathway. Normal human serum rendered deficient in D did not sustain C3b deposition until its reconstitution with D, indicating an absolute requirement for a protein unique to the alternative pathway and essential to the cleavage activation of the C3 amplification convertase of that pathway. The capacity of the excess control proteins H and I to prevent C3b deposition onto GBM incubated in C2-deficient serum provided further evidence for the direct activation of the alternative pathway in this system. The use of radiolabeled monoclonal antibody to localize the deposited C3b afforded specificity and quantitation of about 100 ng of C3b/mg of GBM. Immunohistochemical analysis with a monoclonal antibody to detect C3b demonstrated its deposition to be confined to the epithelial surface of the GBM.     

A new low molecular-weight protein effector of human complement from the venom of the Central Asian cobra Naja naja oxiana

Six protein effectors of human complement were isolated from the whole venom of the Central Asian cobra Naja naja oxiana. Three of them have acidic properties and molecular weights of 61 000, 5000 and 3000, and the rest are basic proteins with molecular weights of 54 000, 9000 and 7000. Two low molecular weight basic proteins CFB-II and CFB-III are isolated in as high amounts as 115 and 85 mg per g of dry venom. All the effectors inhibit the classical pathway of complement activation and, with the exception of CFB-II and CFB-III, the alternative pathway. The latter, on the contrary, enhances the alternative pathway of activation. N-Terminal sequence determination for CFB-III demonstrated its identity to the earlier characterized cytotoxin II. The action of CFB-III on the classical pathway of complement activation consists in the component C4 inactivation. A mechanism for the CFB-III activation of the alternative pathway is proposed implying the CFB-III induced transformation of the C3 component into a C3b-like one producing a soluble C3 convertase.     

The conversion of human complement component C5 into fragment C5b by the alternative-pathway C5 convertase.

The cleavage of human complement component C5 to fragment C5b by the alternative pathway C5 convertase was studied. The alternative-pathway C5 convertase on zymosan can be represented by the empirical formula zymosan--C3b2BbP. Both properdin-stabilized C3 and C5 convertase activities decay with a half life of 34 min correlating with the loss of the Bb subunit. The C5 convertase functions in a stepwise fashion: first, C5 binds to C3b and this is followed by cleavage of C5 to C5b. The capacity to bind C3b is a stable feature of component C5, as C5b also has this binding capacity. Component C5, unlike component C3, does not form covalent bonds with zymosan after activation, and C5 is not inhibited by amines. Therefore C5, although similar in structure to C3, does not appear to contain the internal thioester group reported for C3 and C4.     

Complement inhibitor of C5 activation from the soft tick Ornithodoros moubata

Blood-feeding ticks must control C activation or be damaged by the host inflammatory response. We report the characterization and expression of a novel, relatively small, broad-acting C inhibitory protein (termed OmCI) from the soft tick Ornithodoros moubata. The native 17-kDa nonglycosylated protein inhibits both human and guinea pig classical and alternative C activation pathways. The IC50 values for each pathway were 12 and 27 nM, respectively, in hemolytic assays using human serum diluted 40-fold. The cDNA encodes a protein of 168 aa, including an 18-aa secretion signal sequence that is absent in the mature form. The inhibitor has 46% amino acid identity with moubatin, a platelet aggregation inhibitor also from O. moubata that is an outlying member of the lipocalin family. Native OmCI had no inhibitory effect on the addition of C8 and C9 to preformed C5b-C7 and C5b-C8 to form the membrane attack complex and no effect on the rate of C3a production by the C3 convertase enzymes C4bC2a, C3(H2O)Bb, or C3bBb. Both recombinant and native OmCI abolish production of C5a by human classical (C4bC3bC2a) and alternative (C3bC3bBb) C5 convertases. Addition of excess C5 but not C3 competes away the inhibitory activity of OmCI, indicating that OmCI targets C5 itself rather than inhibiting the C5 convertase C4bC3bC2a itself. Direct binding of OmCI to C5 was demonstrated by Western blotting and gel filtration chromatography using 125I-labeled proteins. OmCI is the first lipocalin family member shown to inhibit C and also the first natural inhibitor that specifically targets the C5 activation step.     

Soluble C3 proconvertase and convertase of the classical pathway of human complement. Conditions of stabilization in vitro.

Soluble classical-pathway C3 convertase and proconvertase were prepared from purified C4b-C2ox complex in the presence of Ni2+; the two complexes, stable for at least 15 h at 4 degrees C, were isolated by sucrose-density-gradient ultracentrifugation. The C3 convertase alone was able to cleave C3, and its decay was accelerated in the presence of C4-binding protein. The individual roles of Ni2+ and I2 treatment of C2 in the stabilization of the complexes seemed to be different and additive. 63Ni2+ binding coupled to h.p.l.c. analysis showed that 63Ni2+ bound only to the C2ox proteolytic fragment a (1 mol/mol) with a Kd of 26 microM. Competition studies between Ni2+ and Mg2+ indicated that only half of the Ni2+ bound to the C3 convertase was removed by Mg2+, whereas, in the same conditions, Ni2+ bound to C2ox proteolytic fragment a was not displaced, suggesting the presence of two sets of sites on the convertase. EDTA prevented the formation of both C3 convertase and proconvertase; EDTA had no effect on the preformed C3 convertase, whereas it dissociated the preformed proconvertase.     

Formation of high affinity C5 convertase of the classical pathway of complement

C3/C5 convertase is a serine protease that cleaves C3 and C5. In the present study we examined the C5 cleaving properties of classical pathway C3/C5 convertase either bound to the surface of sheep erythrocytes or in its free soluble form. Kinetic parameters revealed that the soluble form of the enzyme (C4b,C2a) cleaved C5 at a catalytic rate similar to that of the surface-bound form (EAC1,C4b,C2a). However, both forms of the enzyme exhibited a poor affinity for the substrate, C5, as indicated by a high Km (6-9 microM). Increasing the density of C4b on the cell surface from 8,000 to 172,000 C4b/cell did not influence the Km. Very high affinity C5 convertases were generated only when the low affinity C3/C5 convertases (EAC1,C4b,C2a) were allowed to deposit C3b by cleaving native C3. These C3b-containing C3/C5 convertases exhibited Km (0.0051 microM) well below the normal concentration of C5 in blood (0.37 microM). The data suggest that C3/C5 convertase assembled with either monomeric C4b or C4b-C4b complexes are inefficient in capturing C5 but cleave C3 opsonizing the cell surface with C3b for phagocytosis. Deposition of C3b converts the enzymes to high affinity C5 convertases, which cleave C5 in blood at catalytic rates approaching Vmax, thereby switching from C3 to C5 cleavage. Comparison of the kinetic parameters with those of the alternative pathway convertase indicates that the 6-9-fold greater catalytic rate of the classical pathway C5 convertase may compensate for the fewer numbers of C5 convertase sites generated upon activation of this pathway.     

Role of L-ficolin/mannose-binding lectin-associated serine protease complexes in the opsonophagocytosis of type III group B streptococci

Serotype III group B streptococci (GBS) are a common cause of neonatal sepsis and meningitis. Although deficiency in maternal capsular polysaccharide (CPS)-specific IgG correlates with susceptibility of neonates to the GBS infection, serum deficient in CPS-specific IgG mediates significant opsonophagocytosis. This IgG-independent opsonophagocytosis requires activation of the complement pathway, a process requiring the presence of both Ca(2+) and Mg(2+), and is significantly reduced by chelating Ca(2+) with EGTA. In these studies, we defined a role of L-ficolin/mannose-binding lectin-associated serine protease (MASP) complexes in Ca(2+)-dependent, Ab-independent opsonophagocytosis of serotype III GBS. Incubation of GBS with affinity-purified L-ficolin/MASP complexes and C1q-depleted serum deficient in CPS-specific Ab supported opsonophagocytic killing, and this killing was inhibited by fluid-phase N-acetylglucosamine, the ligand for L-ficolin. Binding of L-ficolin was proportional to the CPS content of individual strains, and opsonophagocytic killing and C4 activation were inhibited by fluid-phase CPS, suggesting that L-ficolin binds to CPS. Sialic acid is known to inhibit alternative complement pathway activation, and, as expected, the bactericidal index (percentage of bacteria killed) for individual strains was inversely proportional to the sialic acid content of the CPS, and L-ficolin-initiated opsonophagocytic killing was significantly increased by addition of CPS-specific IgG2, which increased activation of the alternative pathway. We conclude that binding of L-ficolin/MASP complexes to the CPS generates C3 convertase C4b2a, which deposits C3b on GBS. C3b deposited by this lectin pathway forms alternative pathway C3 convertase C3bBb whose activity is enhanced by CPS-specific IgG2, leading to increased opsonophagocytic killing by further deposition of C3b on the GBS.     

Eosinophil granule cationic proteins regulate complement. I. Activity on the alternative pathway.

Eosinophil granules contain several cationic proteins that mediate tissue damage in allergic disease. The present study examined the capacity and mechanisms by which these cationic proteins regulate activity of the alternative pathway of C. Eosinophil peroxidase and eosinophil cationic protein inhibited formation of cell-bound alternative pathway C3 convertase, causing 50% inhibition of lysis at about 0.19 and 0.75 microgram/10(7) cellular intermediates, respectively. Major basic protein inhibited alternative pathway C3 activity by only 19% at 1.5 micrograms/10(7) cellular intermediates. Eosinophil-derived neurotoxin had no activity on the alternative pathway. The eosinophil granule proteins were examined for the mechanism by which they inhibited alternative pathway activity. Eosinophil peroxidase and major basic protein inhibited fluid phase factor B consumption in a reaction mixture that also contained factors D and C3b, eosinophil-derived neurotoxin had no activity on factor B consumption, and eosinophil cationic protein consumed factor B in the absence of C3b and factor D. Both eosinophil cationic protein and eosinophil peroxidase enhanced the decay of preformed alternative pathway convertase. Lysis of EAC4b,3b cellular intermediates formed to contain a low surface amount of C3b was more inhibited than was lysis of cells formed with a standard amount of C3b on the surface. This suggests that these eosinophil proteins acted predominantly on C3b to regulate alternative pathway activity. We also found that none of the eosinophil granule cationic proteins had any effect on later events after the formation of the C3 convertase. We conclude that although eosinophil-derived neurotoxin (isoelectric pH value (pI) = 8.9) does not regulate alternative pathway activity, the more highly charged eosinophil granule cationic proteins--major basic protein (pI = 10.9), eosinophil cationic protein (pI = 10.8), and eosinophil peroxidase (pI = 10.8)--do share the capacity to regulate C activity and may exert this activity in vivo.     

Isolation of two forms of decay-accelerating factor (DAF) from human urine.

Decay-accelerating factor (DAF) was purified from human pooled urine by conventional techniques. The urine DAF was separated into two peaks, pool I and pool II, by gel chromatography. DAF-U1 was isolated from pool I by hydrophobic chromatography, and DAF-U2 from pool II by anti-DAF IgG column. The specific activities of DAF-U1 and DAF-U2 to decay membrane-phase C5 convertase were about 3% and 70% of membrane form DAF, respectively. However, both urine DAFs revealed a similar activity to each other and slightly higher activity than that of membrane form DAF in decay-accelerating fluid-phase C3 convertase of the alternative pathway.     

C3, C4, and the terminal complement complex differ from C1q by binding predominantly to the antigenic part of solid phase immune complexes

The binding of the C components C1q, C4, C3, the terminal C5b-9 complement complex (TCC) and S protein to immune complexes was studied. The hapten 5-iodo-4-hydroxy-3-nitrophenacetyl (NIP) conjugated to BSA was adsorbed to polystyrene plates and reacted with a human IgG3-mouse chimeric anti-NIP antibody. After addition of serum a dose-dependent binding of C1q, C4, C3, and TCC to the immune complexes was found. An increase in the amount of NIP-BSA was associated with an increase in the binding of TCC and a decrease in the binding of S-protein. After addition of soluble NIP only 4 to 6% of the anti-NIP antibody remained bound to the Ag. C1q showed diminished binding after addition of NIP, whereas C4, C3, and TCC quantitatively remained bound to the Ag. Binding of TCC to the immune complexes was also found in an alternative assay, in which the anti-NIP antibody was adsorbed to the solid phase before NIP-BSA and an additional layer of anti-NIP antibody were added. The supernatants from the solid phase assay were tested for C3 activation and formation of the fluid phase TCC (SC5b-9). Activation of the C3 was reflected in the fluid phase by a dose-dependent increase in C3 activation products. This was not seen for TCC despite increased binding to the solid phase.