Isolation, characterization, and mechanism of action of rat beta 1H

beta 1Hrat was purified to homogeneity from fresh rat plasma by precipitation with 28.6% ammonium sulfate followed by sequential chromatography on DEAE-Sephacel, Biorex-70, and gel filtration on Sephacryl-S300. The final material was homogeneous on SDS-PAGE analysis and had an apparent m.w. of 150,000. Reduction with dithiothreitol did not affect its m.w., suggesting that the molecule is composed of one polypeptide chain. The recovery of beta 1H was approximately 10%. A monospecific antibody against beta 1Hrat was obtained from immunized rabbits, which recognized beta 1Hrat as a protein with beta-electrophoretic mobility upon immunoelectrophoresis of fresh rat plasma. The concentration of beta 1H in plasma of normal 4-mo-old Wistar rats was 243.5 +/- 36.3 micrograms/ml (mean +/- S.D.). beta 1Hrat in this study was detected by its capacity to inhibit formation of the P-stabilized cell-bound amplification C3/C5 convertase composed of cell-bound C3bhu and Bbhu. Purified beta 1Hrat produced a dose-related, first-order loss of convertase function and release of 126I-Bbhu from the P-stabilized C3bhuBbhu convertase, indicating a mechanism of action by decay-dissociation of Bbhu from the complex C3bhuBbhuP. beta 1Hrat was at least four times less effective than beta 1Hhu in release of 125I-Bbhu from the homologous convertase composed of C3bhu and Bbhu. On the other hand beta 1H was twice as effective in releasing 125I-Bbrat from the convertase composed of C3bratBbratP when compared to beta 1Hhu. These differences are presumably dependent upon the species-specific affinity of beta 1H from humans or rats for C3bhu or C3brat, respectively.     

Guinea pig erythrocytes, after their contact with influenza virus, acquire the ability to activate the human alternative complement pathway through virus-induced desialation of the cells

Guinea pig erythrocytes that had been exposed to influenza A virus activated the alternative complement pathway in whole human serum in the absence of natural antibodies. Because all virus particles were eluted from the treated cells, activation was not dependent on antiviral antibodies or on virus particles themselves. The relative capacity of treated erythrocytes to activate the alternative pathway was dependent on the amount of virus to which the cells had been exposed and was directly related to the amount of sialic acid removed from the erythrocyte membrane during incubation with either whole virus particles or purified viral sialidase. C3b bound to cells that had been treated with virus, and P-stabilized amplification convertase sites P,C3b,Bb formed on these cells, exhibited increased resistance to the action of the regulatory proteins beta-1H and C3b Ina compared with C3b and P,C3b,Bb on untreated, nonactivating cells. The acquired resistance of the cell-bound, P-stabilized amplification convertase to decay-dissociation by beta-1H was directly related to the activating capacity of the treated cells in whole serum (r = 0.95) and to the amount of sialic acid removed from the cells by the virus (r = 0.98). Desialation represents a specific alteration of the cell surface by which a nonimmune host, through activation of the alternative pathway, may deposit C3b on a target cell that had been exposed to influenza virus and may lyse virus virus-modified cells during orthomyxovirus infections.     

Stabilization of the amplification convertase of complement by monoclonal antibodies directed against human factor B

Three IgM mouse monoclonal antibodies (MoAb), 5B5-A, 2D2-B, and 5B12-A, were prepared by fusion of spleen cells from mice immunized with human B with the SP 2/0 myeloma cell line. They were assessed for their effect on cell-bound and fluid-phase amplification convertases of complement (C) with purified proteins in vitro. 5B5-A and 2D2-B were similar in their effects on cell-bound preformed C3bBb in that they bound to cell-bound C3bBb, stabilized the C3bBb convertase, and rendered the C3bBb convertase relatively resistant to the plasma protein H. These two MoAb were also able to enhance C3 consumption in vitro in reaction mixtures containing C3b, C3, B, and D. At the same time, they presumably stabilized the C3 convertase and caused relative sparing of B hemolytic activity in the reaction mixtures. In contrast, 5B12-A, which also bound to Bb and C3bBb, did not induce any stabilization, but rather caused accelerated decay of cell-bound C3bBb. These results indicate that MoAb against B can have C3NeF-like activity. On the other hand, not all MoAb against B have stabilizing activity on the C3bBb convertase.     

Further evidence for the antibody nature of C3 nephritic factor (C3NeF).

C3 nephritic factor (C3NeF), found in the sera of some patients with membranoproliferative glomerulonephritis, has been shown to be composed of two heavy and two light chains, like IgG; in addition it shares antigenic determinants with IgG. Purified C3NeF binds to the amplification convertase of complement, C3b,Bb, and thereby prevents decay of its C3-cleaving potential. The capability of C3NeF to bind to C3b,Bb was used as a means for purifying C3NeF to homogeneity. The investigation described in this report suggests that binding of C3NeF to C3b,Bb occurs via the Fab portion of the molecule. Pepsin treatment of eight C3NeF preparations resulted in an average loss of 76% of C3NeF functional activity. Papain treatment induced a loss of approximately 90%. The decrease in functional activity could be attributed to the accelerated rate of dissociation of 125I-F(ab')2 and 125I-Fab fragments from stabilized cell-bound C3b,Bb. The dissociation rate of 125I-F(ab')2 from C3b,Bb was comparable with the decay of the functional activity of C3b,Bb stabilized by F(ab')2 or Fab fragments of C3NeF. Although these results suggest that the stabilizing activity of C3NeF is mediated by the Fab portion of the molecule, it was found that the Fc portion also contributes to its functional activity.     

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.     

Surface-dependent modulation by H of C5 cleavage by the cell-bound alternative pathway C5 convertase of human complement

Regulation by H of formation of the C3 and C5 alternative pathway convertases of complement on cells is dependent on such chemical characteristics of the cell surfaces as their membrane content in sialic acid. Properdin-stabilized C5 convertase sites were assembled on the non-activating cells of the alternative pathway, sheep erythrocytes (Es), and on the activating cells, desialated Es and rabbit erythrocytes (Er). C5 hemolytic sites were revealed by incubation of the convertase-bearing cells with limiting C5 and excess C6-C9. H inhibited generation of C5 hemolytic sites in a dose-related fashion on Es, Er, and desialated Es at molar ratios of H/C5 of 0.03 to 0.5. H similarly inhibited C5 utilization by the cell-bound C5 convertase on Es and desialated Es regardless of the cell membrane sialic acid content; however, H was three to five times less effective on Er. Kinetic experiments also suggested that C5 hemolytic sites are generated more rapidly on Er than on Es and desialated Es. The inhibition effect of H was independent of the number of C5 convertase sites per cell on all cell types; two to three times more residual hemolytic sites were found on convertase-bearing Es that had been incubated with C5 and H as compared with cells that had been decayed by H before incubation with C5. Furthermore, H also inhibited C5 interaction with a preformed classical pathway C5 convertase. These results suggest that H interacts with C5 so as to alter C5 binding and/or cleavage by the cell-bound C5 alternative pathway convertase. Sialic acid-independent modulation by H of C5 cleavage by the C5 convertase represents an additional regulatory step in the activation of the human alternative complement pathway.     

C3b generation is affected by the structure of the O-antigen polysaccharide in lipopolysaccharide from salmonellae

Salmonellae differing in the O-antigen side chain of their lipopolysaccharide were previously shown to activate the alternative pathway of complement to different extents. We now examine the generation of the major cleavage fragment of the complement component C3 (C3b) on these bacteria in a system that contains the purified components C3, B, D, and P but lacks the regulatory proteins H and I. The deposition of C3b in this system reproduces the same pattern obtained earlier with the use of whole serum, with the expected differences among the strains bearing different O-antigen. However, two distinct mechanisms for these differences in C3b generation became apparent. The intermediate activating strain showed 3 to 4 times less initial deposition of C3b than the other two strains. In contrast, the least activating strain showed adequate initial deposition but poor amplification, as shown by 2 to 3.4 lower amplification indexes as compared with those on the other two strains. Binding studies with factor B showed that decreased C3 convertase formation was responsible for the low amplification on this strain. Only 25% of the C3b bound to its surface was able to bind factor B with a high affinity, in comparison with 90% on the other two strains. No differences were found for the binding of factor H among the strains. These studies identify the molecular mechanisms by which these bacteria avoid complement activation.     

Involvement of colchicine binding site of tubulin in the polymerisation process

Role of lysine residues in the colchicine binding site and in the assembly-disassembly process was examined. It was observed that at 4 degrees C (pH 7.5-8, 8 +/- 1) lysine residues and the N-terminal methionine residue of tubulin were all buried within the molecule. Evidence indicates that epsilon-amino groups of lysine residues of tubulin are shared by both the colchicine binding site and the polymerisation process.     

Comparison of binding characteristics of factors B and H to C3b on normal and paroxysmal nocturnal hemoglobinuria erythrocytes

To determine if aberrant interactions of the endogenous control proteins with cell-bound C3b contribute to the greater fixation of C3b to paroxysmal nocturnal hemoglobinuria (PNH) erythrocytes when whole serum complement is activated, we compared the characteristics of binding of factors B and H to normal and PNH red cells bearing C3b (EC3b). Factor B binding is homogeneous, there is 1:1 stoichiometry, and the affinity constant at equilibrium for factor B binding is the same for normal and PNH EC3b. In contrast, analysis by Scatchard's method of factor H binding results in a curvilinear plot, the deviation from linearity being exaggerated for the PNH EC3b. The heterogeneity of binding of factor H appears to be a consequence of the nonrandom distribution of C3b about the alternative pathway convertase site. This nonrandom distribution does not induce negative cooperativity but rather effects a biophysical milieu which enhances factor H binding. The greater heterogeneity of binding of factor H to PNH E bearing nonrandomly distributed C3b appears to be due to the presence of a greater proportion of lower affinity binding sites on the PNH EC3b. However, it appears unlikely that this greater heterogeneity of factor H binding contributes to the enhanced fixation of C3b to PNH erythrocytes.     

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 assembly of early components of complement on antibody-antigen aggregates and on antibody-coated erythrocytes.

Radioimmune assays were developed to assay the binding of complement components C1q, C1s and C4 to antibody aggregates and to cell-bound antibody. The binding of the components was compared with the haemolytic activity and with the capacity to form the C3 convertase activity in the presence of excess C2. The destruction of whole complement and of C4 activity is similar per 1,000 molecules of antibody in aggregates and cell-bound antibody, as is the binding of C1g and C1s, the latter being in a 1:2 molar ratio. The binding of C4 is about 12 times greater, per 1,000 molecules of antibody, on cells than in aggregates. However, the effective C4 molecules, as judged by the formation of C3 convertase activity, are much more similar on cells and aggregates. An assembly mechanism of the early components of complement on antibody-coated cells, which is compatible with these results, is suggested.     

The binding of human complement proteins C5, factor B, beta 1H and properdin to complement fragment C3b on zymosan.

The covalent binding of complement fragment C3b to zymosan by the action of the alternative-pathway C3 convertase and the reversible binding of several complement proteins (component C5, factor B, beta 1H and properdin) to C3b on zymosan have been investigated. When C3b is deposited on zymosan after activation by a surface-bound C3 convertase, the C3b molecules are deposited in foci around the C3 convertase site, with an average of 30 C3b molecules per site. The association constants of C5, factor B, beta 1H, and properdin for C3b bound to zymosan have been determined. The association constants ranged from 6.5 x 10(-5) M-1 for factor B to 2.9 x 10(7) M-1 for properdin. An approximate stoichiometry of 1 : 1 for C5, factor B, and properdin binding to C3b has been observed. Curvilinear Scatchard plots were observed for beta 1H binding to C3b, with the maximal extrapolated ratio of beta 1H to C3b of 0.32. Physiological amounts of properdin increase by 7-fold the affinity constant for factor B binding to C3b with no alteration in the stoichiometry. Similarly, physiological amounts of factor B increase the affinity constant of properdin to C3b about 4-fold with only a small measured difference in stoichiometry. Competition binding studies and protein modification suggest that C5, factor B, beta 1H, and properdin each bind to a distinct region on C3b.     

Interaction of C3 with antigen-antibody complexes in the process of solubilization of immune precipitates

The binding properties of activated C3 to immune complexes were studied by using solubilization phenomenon as a model system. IgG or F(ab')2 immune precipitates were solubilized by the six isolated alternative pathway proteins, and the solubilized complexes were analyzed by SDS-PAGE. As a result of solubilization, we observed some high m.w. bands. Under reducing conditions, the bands with m.w. of 150,000 and 115,000 appeared in the case of IgG and F(ab')2 complexes, respectively. Two-dimensional SDS-PAGE revealed that hydroxylamine treatment resulted in the dissociation of the 150,000-m.w. polypeptide into the C3 alpha-65 and the heavy chain of IgG. Similarly, the 115,000-m.w. polypeptide was dissociated into the C3 alpha-65 and the Fd chain. Therefore, it is likely that iC3b binds covalently to the Fd region of the heavy chain of IgG via an ester bond. Under nonreducing conditions, iC3b-IgG and iC3b-F(ab')2 complexes had apparent m.w. of 340,000 and 270,000, respectively, corresponding to one iC3b molecule bound to one antibody molecule. In addition, a considerable amount of iC3b also binds to antigen molecules via an ester bond. The findings that C3 binds to the F(ab')2 molecules and bovine serum albumin, which contain only a small amount of carbohydrate, suggest that C3 may not bind to the carbohydrate moiety of antibody molecules. Indeed, various carbohydrate molecules did not inhibit the solubilization even at high concentrations. In contrast, acetyl tyrosine having an aromatic ring and a hydroxyl group produced the best inhibition of the solubilization. Furthermore, we demonstrated that generation of C3b in the presence of 3H-tyrosine resulted in covalent binding of the tyrosine specifically to the C3 alpha' chain, indicating that the inhibition of solubilization may be due to the competition between tyrosine and immune complexes for the covalent binding of C3. Thus, it could be concluded that C3 binds covalently to the amino acid residues of antigen and antibody molecules during solubilization.     

NADH binding to cytochrome b5 reductase blocks the acetylation of lysine 110

Lysine residues outside of the NADH-binding site in the soluble catalytic fragment of cytochrome b5 reductase were modified with ethyl acetimidate and acetic anhydride while the binding site was protected by formation of the stable oxidized nucleotide-reduced flavoprotein complex. This treatment had a minimal effect on enzyme activity; the turnover number with potassium ferricyanide was 45,300 in the native reductase and 39,200 in the derivative. Subsequent reaction with [3H]acetic anhydride after the removal of NADH resulted in the loss of 91% of the enzyme activity and the incorporation of 1.9 eq of acetyl groups into the protein. Treatment with 1 M hydroxylamine at pH 13 indicated that only lysine residues were acetylated, and fragmentation of the derivative with cyanogen bromide and subfragmentation with trypsin and chymotrypsin demonstrated that only Lys110 was labeled at high specific activity, with a stoichiometry of 0.83 acetyl groups/mol, in good agreement with the loss of enzyme activity observed. The remaining label was distributed at low levels among four or more additional lysine residues. These results demonstrate that only Lys110 is specifically protected by NADH and is therefore the residue which provides the epsilon-amino group implicated in NADH binding in cytochrome b5 reductase.     

Critical role of the C-terminal domains of factor H in regulating complement activation at cell surfaces

The plasma protein factor H primarily controls the activation of the alternative pathway of complement. The C-terminal of factor H is known to be involved in protection of host cells from complement attack. In the present study, we show that domains 19-20 alone are capable of discriminating between host-like and complement-activating cells. Furthermore, although factor H possesses three binding sites for C3b, binding to cell-bound C3b can be almost completely inhibited by the single site located in domains 19-20. All of the regulatory activities of factor H are expressed by the N-terminal four domains, but these activities toward cell-bound C3b are inhibited by isolated recombinant domains 19-20 (rH 19-20). Direct competition with the N-terminal site is unlikely to explain this because regulation of fluid phase C3b is unaffected by domains 19-20. Finally, we show that addition of isolated rH 19-20 to normal human serum leads to aggressive complement-mediated lysis of normally nonactivating sheep erythrocytes and moderate lysis of human erythrocytes, which possess membrane-bound regulators of complement. Taken together, the results highlight the importance of the cell surface protective functions exhibited by factor H compared with other complement regulatory proteins. The results may also explain why atypical hemolytic uremic syndrome patients with mutations affecting domains 19-20 can maintain complement homeostasis in plasma while their complement system attacks erythrocytes, platelets, endothelial cells, and kidney tissue.     

A single arginine to tryptophan interchange at beta-chain residue 458 of human complement component C4 accounts for the defect in classical pathway C5 convertase activity of allotype C4A6. Implications for the location of a C5 binding site in C4.

In general, C4A allotypes of human C4 show one-fourth to one-third the hemolytic activity of C4B allotypes. An exception to this rule is C4A6 which is almost totally deficient in hemolytic activity. Previous studies have localized the defect in C4A6 to the C5 convertase stage. Of the two critical events required for C5 cleavage, namely formation of a covalent adduct between C3b and the C4b subunit of the C3 convertase (C4b2a), and binding of C5 to this C4b-C3b complex, it is a defect in the latter step that accounts for the aberrant activity of C4A6. DNA sequencing studies described in a companion paper have suggested that the sole C4A6-specific difference was a Trp for Arg replacement at beta-chain residue 458. To directly ascertain whether this single substitution was responsible for the hemolytic defect in C4A6, we have used site-directed mutagenesis to introduce this change into both C4A and C4B cDNA expression plasmids. We found that the R to W replacement totally abrogated hemolytic activity. However, irrespective of the amino acid at residue 458, the mutant proteins behaved like their wild-type counterparts with respect to covalent binding to C1-bearing targets, i.e., the C4B recombinants displayed higher binding to sheep and human red cells than did the C4A counterparts. Furthermore, the mutants were able to form covalent C4b-C3b adducts. There was, however, substantially less C5 cleavage produced by cell-bound C4boxy23b complexes made with R458W mutant C4B than with wild-type C4B. These results are consistent with the sole defect in the mutants being at the C5 binding stage and strongly suggest that Arg 458 of the C4 beta-chain contributes to the C5 binding site of the molecule.     

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.     

Molecular Basis for Complement Recognition and Inhibition Determined by Crystallographic Studies of the Staphylococcal Complement Inhibitor (SCIN) Bound to C3c and C3b

The human complement system plays an essential role in innate and adaptive immunity by marking and eliminating microbial intruders. Activation of complement on foreign surfaces results in proteolytic cleavage of complement component 3 (C3) into the potent opsonin C3b, which triggers a variety of immune responses and participates in a self-amplification loop mediated by a multi-protein assembly known as the C3 convertase. The human pathogen Staphylococcus aureus has evolved a sophisticated and potent complement evasion strategy, which is predicated upon an arsenal of potent inhibitory proteins. One of these, the staphylococcal complement inhibitor (SCIN), acts at the level of the C3 convertase (C3bBb) and impairs downstream complement function by trapping the convertase in a stable but inactive state. Previously, we have shown that SCIN binds C3b directly and competitively inhibits binding of human factor H and, to a lesser degree, that of factor B to C3b. Here, we report the co-crystal structures of SCIN bound to C3b and C3c at 7.5 and 3.5 Å limiting resolution, respectively, and show that SCIN binds a critical functional area on C3b. Most significantly, the SCIN binding site sterically occludes the binding sites of both factor H and factor B. Our results give insight into SCIN binding to activated derivatives of C3, explain how SCIN can recognize C3b in the absence of other complement components, and provide a structural basis for the competitive C3b-binding properties of SCIN. In the future, this may suggest templates for the design of novel complement inhibitors based upon the SCIN structure.     

Radiolabeling of immunoglobulin without loss of antibody activity--use of 14C-phenylisothiocyanate with human cytotoxic antibody.

Radioiodination of immunoglobulins, particularly human cytotoxic IgG, induced a marked loss of antibody activity. Phenylisothiocyanate (PITC) readily reacts with alpha-amino groups and the epsilon-amino groups of lysines to form phenylthiocarbamyl derivatives. Since PITC is commercially available with 14C, 3H, and 35S substitutions, it provided an alternative means for labeling immunoglobulin which preserved antibody activity. There were approximately 80 PITC binding sites per IgG molecule, and 14C-PITC was bound with an efficiency in excess of 80%. With as many as 40 PITC molecules bound per IgG molecule, full cytotoxic activity was retained by both anti-HLA isoantisera and human anti-melanoma autoantisera. Even with 70 to 80 molecules of PITC bound per IgG molecule, over 80% of the antibody activity remained. Radiolabeling of antibody with 3H, 14C, or 35S-substituted PITC will greatly facilitate studies of antibody binding, particularly to cell surface antigens.     

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.