Complotype affects the extent of down‐regulation by Factor I of the C3b feedback cycle in vitro

Sera from a large panel of normal subjects were typed for three common polymorphisms, one in C3 (R102G) and two in Factor H (V62I and Y402H), that influence predisposition to age‐related macular degeneration and to some forms of kidney disease. Three groups of sera were tested; those that were homozygous for the three risk alleles; those that were heterozygous for all three; and those homozygous for the low‐risk alleles. These groups vary in their response to the addition of exogenous Factor I when the alternative complement pathway is activated by zymosan. Both the reduction in the maximum amount of iC3b formed and the rate at which the iC3b is converted to C3dg are affected. For both reactions the at‐risk complotype requires higher doses of Factor I to produce similar down‐regulation. Because iC3b reacting with the complement receptor CR3 is a major mechanism by which complement activation gives rise to inflammation, the breakdown of iC3b to C3dg can be seen to have major significance for reducing complement‐induced inflammation. These findings demonstrate for the first time that sera from subjects with different complement alleles behave as predicted in an in‐vitro assay of the down‐regulation of the alternative complement pathway by increasing the concentration of Factor I. These results support the hypothesis that exogenous Factor I may be a valuable therapeutic aid for down‐regulating hyperactivity of the C3b feedback cycle, thereby providing a treatment for age‐related macular degeneration and other inflammatory diseases of later life.     

Cleavage of complement C3b to iC3b on the surface of Staphylococcus aureus is mediated by serum complement factor I

Complement-mediated opsonization of Staphylococcus aureus bearing the dominant capsule serotypes, serotypes 5 and 8, remains incompletely understood. We have previously shown that complement plays a vital role in the efficient phagocytosis of a serotype 5 S. aureus strain and that the opsonic fragments of the central complement protein C3, C3b and iC3b, were present on the bacterial surface after incubation in human serum. In the present studies, C3b and iC3b were found on several serotype 5 and 8 S. aureus strains after incubation in human serum. Using purified classical activation pathway complement proteins and the Western blot assay, we showed that when C3b was generated on the S. aureus surface no iC3b fragments were found, suggesting that other serum proteins may be required for cleaving C3b to iC3b. When C3b-coated S. aureus was incubated with serum factor I, a complement regulatory protein, iC3b was generated. Purified factor H, a serum protein cofactor for factor I, did not enhance factor I-mediated cleavage of C3b. These findings suggest that C3b cleavage to iC3b on S. aureus is mediated by serum factor I and does not require factor H.     

The classical and alternative pathways of complement activation play distinct roles in spontaneous C3 fragment deposition and membrane attack complex (MAC) formation on human B lymphocytes

The contributions of the classical (CP) and alternative (AP) pathways of complement activation to the spontaneous deposition of C3 fragments and the formation of membrane attack complexes (MAC) on human B lymphocytes, were assessed by incubating peripheral blood mononuclear cells with autologous serum in the absence and presence of selective inhibitors of the AP and CP, respectively. While the total amount of C3 fragments deposited was relatively unaffected by blocking either pathway individually, deposition was virtually abrogated by their combined blockade. A marked difference was observed, however, in the nature of the fragments deposited as a result of CP and AP activation: C3b fragments deposited via the CP were extensively ( approximately 90%) converted to the terminal degradation product, C3dg, whereas about 50% of those deposited by the AP persisted as C3b/iC3b fragments. The extent of MAC formation was also found to be highly pathway dependent, with the AP being about 15-fold more efficient at initiating this process than the CP. A model accounting for the effectiveness of the AP in both preserving C3 fragment integrity and initiating MAC is presented.     

Selective and efficient inhibition of the alternative pathway of complement by a mAb that recognizes C3b/iC3b

The alternative pathway (AP) of the complement system plays an important role in tissue damage and inflammation associated with certain autoimmune diseases and with ischemia-reperfusion injury. Selective inhibition of the AP could prevent such pathologies while allowing the classical and lectin pathways of complement activation to continue to provide protection. Here we present data describing selective inhibition of the AP of complement by anti-C3b/iC3b monoclonal antibody (mAb) 3E7, and by a chimeric, "deimmunized" form of this mAb, H17, which contains the human IgG1 Fc region and was further modified by substitution of amino acids in order to remove T cell epitopes. Both mAbs block AP-mediated deposition of C3b onto zymosan or Sepharose 4B, and they also inhibit AP-promoted lysis of rabbit erythrocytes. MAbs 3E7 and H17 also successfully compete with both factors B and H for binding to C3b-opsonized substrates, and the ability of both mAbs to inhibit the AP is blocked by pre-incubation with two different sources of C3(H2O). Kinetic measurements demonstrate that mAb 3E7 effectively stops progression of C3b deposition after AP activation is initiated. Our results therefore suggest that these mAbs block activation of the AP by binding to both C3(H2O) and to C3b, and thus prevent binding and activation of factor B. Based on these and other observations, mAb H17 may find future use in therapeutic applications focused on selective inhibition of the AP.     

Characterization of a Monoclonal Antibody MoAb bH6 Reacting with a Neoepitope of Human C3 Expressed on C3b, iC3b, and C3c

Activation products of the complement cascade contain neoepitopes that are not present in the individual native components. Monoclonal antibodies detecting neoepitopes have been used for direct quantification of activation at different steps in the cascade. These methods are suggested to be more sensitive and reliable than conventional complement activation tests, which are hampered by precipitation or fractionation procedures. The present study describes production screening and characterization of a monoclonal antibody (MoAb) bH6. MoAb bH6 exhibited a significantly higher binding capacity to ELISA plates coated with zymosan-activated human serum than to plates coated with EDTA plasma. When fixed to the enzyme-linked immunosorbent assay (ELISA) plates, MoAb bH6 retained material from zymosan-activated serum that only reacted with anti-C3 antibodies. Crossed immunoelectrophoresis performed on zymosan-activated serum demonstrated that MoAb bH6 co-precipitated with anti-C3c antibodies. In experiments using highly purified cell-bound fragments MoAb bH6 showed reactivity with C3b and iC3b, but not with C3d. MoAb bH6 reacted in ELISA with purified C3c, but not with C3dg, both as capture antibody and in tests with the fragments absorbed to the solid phase. Thus, MoAb bH6 is highly specific for a neoepitope of human C3 expressed on the cleavage fragments of C3b, iC3b, and C3c.     

A Comparative Study of Normal B Cells and the EBV-Positive Burkitt's Lymphoma Cell Line, Raji, as Activators of the Complement System

Contradictory reports regarding the ability of complement receptor type 2 (CR2,CD21) on normal B cells to activate complement (C') via the alternative pathway (AP), prompted us to compare the performance of human peripheral blood B cells and the Epstein–Barr virus-positive Burkitt's lymphoma cell line, Raji (a well characterized AP activator) by using flow cytometry. Measured in terms of the membrane deposition of C3 fragments per cell, Raji cells were significantly (6- to 26-fold) more effective as complement activators than were normal B cells. Raji cells were also found to express approximately four to five times as many CR2 as normal B cells. In addition, they distinguished themselves by displaying a greater Ca²⁺-dependent activation, with pooled normal human sera (NHS) as the complement source, and by degrading unprotected C3b fragments from iC3b to C3dg/C3d at a significantly lower rate than the B cells. The Ca²⁺ dependency of Raji cell activation was found to be partially a result of classical pathway (CP) triggering by specific antibodies in the NHS, although other triggering mechanisms may also be involved. If the influence of these variations between Raji cells and normal B cells was excluded, by relating deposition of anti-C3d-reactive fragments, during AP activation, to the number of CR2 expressed, the difference in performance between the two cell types was found to be insignificant.     

The requirement of localized, CR2-mediated, alternative pathway activation of complement for covalent deposition of C3 fragments on normal B cells.

We have shown previously that normal B cells share, with Epstein-Barr virus-transformed and malignant B cells, the ability to activate the alternative pathway (AP) of complement in vitro, resulting in the deposition of C3 fragments on the cell surface. Complement receptor type 2 (CR2, CD21) has been implicated directly as the site for formation of an AP convertase, which provides nascent C3b for deposition at secondary sites on the B-cell surface. In the present study, we have examined C3 fragment deposition in vitro in more detail by (1) assessing the importance of locally generated C3b for the deposition process, (2) investigating whether CR2 is the sole requirement for conferring AP activation capacity on a cell, and (3) determining whether CR2's function, as an AP activator, has different structural requirements from ligand binding. Increasing the availability of native C3, by increasing the serum (NHS) concentration, resulted in enhanced C3 fragment deposition on the B cells, whereas use of factor 1-depleted NHS, which showed massive fluid phase C3 conversion during the incubation, diminished the deposition. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) and Western blotting of untreated and hydroxylamine-treated lysates from B cells, after in vitro activation, revealed that the majority of C3 fragments (primarily iC3b and C3dg) had been covalently bound to the cell surface. Transfection of COS cells with wild-type CR2 or a deletion mutant lacking 11 of the molecule's 15 homologous domains, but retaining the ligand-binding site, revealed that expression of intact CR2 conferred a 12-fold increase in AP-activating capacity on these cells, while no increase in AP activity was apparent on cells transfected with the mutant CR2.     

Analysis of C3 deposition and degradation on Neisseria meningitidis and Neisseria gonorrhoeae.

The deposition and degradation of human complement component C3 on the cell surfaces of Neisseria meningitidis and Neisseria gonorrhoeae were studied. Bacteria were incubated in human serum, and ester-linked C3 fragments were analyzed by hydroxylamine release and immunoblot detection. Similar patterns of C3 degradation were found for both serum-resistant and serum-sensitive meningococcal strains of serogroups A, B, C, Y, and W135, as well as for serum-sensitive gonococcal strains and their sialylated serum-resistant variants. The predominant fragments in all cases were the 40-kDa alpha' 2 chain of iC3b and the 75-kDa beta chain common to both C3b and iC3b. The 67-kDa alpha' 1 chain of iC3b was also detected. The 105-kDa alpha' chain of intact C3b represented a minor proportion of deposited C3. Capsule-specific immunoglobulin G or immunoglobulin A1 did not alter the observed degradation patterns, nor did incubation of meningococci in properdin-deficient serum. The degradation of C3 in C5-, C6-, or C8-deficient serum was the same as that in normal serum, although the deposition of C3 was severely limited, based as indicated by the intensity of the fragments. With the use of an enzyme-linked immunosorbent assay that measured total iC3b and C3, I found that both iC3b deposition and C3 deposition varied among meningococcal and gonococcal strains and that the amounts of iC3b and C3 were independent of the relative quantities of cell surface sialic acid and of serum sensitivity for meningococci but not for gonococci. I conclude that complement activation on neisserial cell surface results in the formation of an identical repertoire of predominantly iC3b fragments of ester-linked C3b molecules regardless of the presence of sialic acid in either the capsule or the lipooligosaccharide or of the sensitivity of the organism to complement-mediated lysis but that the quantities of both ester- and amide-linked iC3b molecules deposited exhibit strain variability.     

Specific inhibition of C3 to facilitate general complement inhibition on endotoxin affinity sorbents for apheresis applications

Complement activation, as a result of human blood exposure to biomaterial surfaces, continues to be a concern in medical applications. The purpose of this study was to identify sorbent(s) and surface modification(s) that allow specific removal of endotoxin, while minimizing complement activation. Maleic anhydride (MA) modification of Sepharose CL-4B, cellulose, and Toyopearl HW-65F resulted in reduced generation of C3a, a marker of complement activation, by two orders of magnitude over unmodified surfaces. Surfaces modified with both MA and polymyxin B (PMB), utilized for binding endotoxin, reduced complement activation in a similar manner. Western Blot analysis of the larger C3 cleavage product C3dg showed a similar reduction, for all MA-modified sorbents, as observed for C3a by ELISA. C3alpha43 levels (constituent of iC3b and C3c) were also reduced, although only MA-Sepharose CL-4B levels were similar to C3a. Activation of C5, measured as the SC5b-9 complex, was also reduced by two orders of magnitude after MA modification of Sepharose CL-4B; the decrease was similar to all chemical modifications tested. PMB immobilized via CNBr on MA-modified cellulose maintained its endotoxin-binding capacity, while the latter was eliminated when PMB was immobilized via CNBr to MA-modified Sepharose CL-4B and Toyopearl HW-65F.     

Direct quantitation of activated C3 in human plasma with monoclonal anti-iC3b-C3d-neoantigen

We developed a microtiter solid-phase radioimmunoassay for quantitating C3 breakdown products (iC3b, C3dg, C3d) in human plasma with a unique monoclonal antibody specific for a neoantigen present on iC3b and C3d (MoAb 130). This monoclonal antibody reacts with a neoantigen which appears when C3b is converted to iC3b. The neoantigen is also present on the C3dg and C3d fragments derived from iC3b. The concentration of the neoantigen is elevated in the plasma of most patients with rheumatoid arthritis and systemic lupus erythematosus as compared to normal volunteers. Some patients with glomerulonephritis also had elevated concentration of the neoantigen in their plasma.     

Evidence for iC3 generation during cardiopulmonary bypass as the result of blood-gas interaction.

Earlier we have shown that iC3 is generated at the blood-gas interface in vitro and that the generation of this molecule is independent of complement activation and the composition of the gas. In order to investigate whether iC3 is also generated during cardiopulmonary bypass where blood comes into contact with oxygen bubbles, two bubble oxygenators were incubated at 37 degrees C with human heparinized blood. A continuous increase in the level of iC3 was shown in the oxygen-perfused bubble oxygenator (up to 100 nmol/l after 180 min) in contrast to the unbubbled control. Similarly, in plasma drawn from patients undergoing cardiopulmonary bypass using either bubble or membrane oxygenators, the levels of iC3 were shown to increase continuously during the operation. Furthermore, this form of C3 was found to be susceptible to cleavage by factor I. The formation of iC3 at the blood-gas interface in vivo could be a mechanism by which gas bubbles induce clinical manifestations associated with complement activation, e.g. during cardiopulmonary bypass, adult respiratory distress syndrome and decompression sickness.     

Regulatory proteins for the activated third and fourth components of complement (C3b and C4b) in mice. I. Isolation and characterization of factor H: the serum cofactor for the C3b/C4b inactivator (factor I)

Factor H, purified from mouse EDTA-plasma using a 4-step procedure, consists of a single polypeptide chain of Mr 150,000 on SDS-PAGE. Mouse H (Hmo) was required for the cleavage of fluid-phase mouse C3b by mouse I (Imo). The final product of degradation of fluid-phase mouse C3b was iC3b, consisting of fragments of the alpha'-chain (alpha'-70, alpha'-43) linked by disulfide bonds to an intact beta-chain. Imo alone was capable of cleavage of membrane-bound mouse C3b and of generating iC3b. The addition of Hmo nevertheless had an enhancing effect on Imo activity, but cleavage did not proceed beyond iC3b. These observations suggest that one important function of Hmo is to permit the inactivation of fluid-phase C3b, and to inhibit irreversibly its activity. The concentration of H in the plasma of male and female BALB/c mice was not significantly different. Among different inbred strains of mice, large differences were observed in the plasma levels of H, and plasma H levels were positively correlated with the plasma levels of C3. This observation, taken together with the well known role of H in the control of the activation of the alternative pathway, suggests that the turnover of C3 is controlled to some extent by H.     

Accelerated decay of C3b to iC3b when C3b is bound to the Cryptococcus neoformans capsule.

Incubation of encapsulated and nonencapsulated Cryptococcus neoformans in normal human serum (NHS) leads to activation and binding of potentially opsonic fragments of complement component C3 to the yeast cells. Analysis of the molecular forms of C3 after incubation of encapsulated cryptococci in NHS showed that the percentage of bound C3 occurring as iC3b approached 100% after 8 min. The percentage of bound C3 occurring as iC3b on nonencapsulated cryptococci never exceeded 70%, even after 60 min of incubation in NHS. Conversion of C3b to iC3b was assessed further by incubating C3b-coated cryptococci for various times with a mixture of complement factors H and I at 40% of their respective physiological concentrations. Most, if not all, of the C3b on encapsulated cryptococci was converted to iC3b at a single fast rate. Conversion of C3b to iC3b on nonencapsulated cryptococci did not follow a single rate constant and appeared to have a fast and a slow component. Studies of the requirements for factors H and I in cleavage of C3b to iC3b showed steep dose-response curves for both factors in the case of encapsulated cryptococci and shallow curves with C3b bound to nonencapsulated cryptococci. Taken together, our results indicate that C3b molecules bound to encapsulated cryptococci have a uniformly high susceptibility to conversion to iC3b by factors H and I. In contrast, a significant portion of the C3b bound to nonencapsulated cryptococci is very resistant to conversion to iC3b by factors H and I.     

Phosphorylation of C3 by a casein kinase released from activated human platelets increases opsonization of immune complexes and binding to complement receptor type 1

We have previously demonstrated that complement component C3 is phosphorylated both in vitro and in vivo by a casein kinase released from activated human platelets. In vitro, the studies have shown that cleavage of C3b by factor I is decreased, and binding to various target surfaces is enhanced by affecting the thiol ester. In the present study we have examined the effect of phosphorylation on the binding of C3b to complement receptor 1 (CR1, CD35). Upon phosphorylation by platelet casein kinase, C3b covalently bound to activated thiol Sepharose bound higher amounts of soluble recombinant CR1. Similar effects were demonstrated with two ELISA systems in which microtiter plates were coated with phosphorylated or unphosphorylated purified C3b or with C3 activated by the alternative pathway convertase. Phosphorylated C3b was also four times more efficient than unphosphorylated C3b in inhibiting the binding of complement-opsonized human aggregated gammaglobulin to erythrocytes. A similar increase in binding was found at low serum concentrations when the C3 activation occurred in C3-deficient serum reconstituted with phosphorylated or unphosphorylated C3. In this serum system, using a monoclonal antibody specific for iC3b, we also demonstrated that the phosphorylated C3b was protected against cleavage to iC3b. Corresponding experiments using factor H showed a decrease in binding of both fluid-phase and bound C3b to factor H. We postulate that phosphorylation of C3 by activated platelets amplifies the complement-mediated binding of immune complexes to CR1 by three different mechanisms: decreased cleavage of C3b to iC3b, increased deposition of C3b to immune complexes, and increased binding of C3b to CR1.     

Bovine conglutinin binds to an oligosaccharide determinant presented by iC3b, but not by C3, C3b or C3c.

Bovine conglutinin is a serum lectin that agglutinates erythrocytes preincubated with antibodies and complement. This agglutination occurs through the binding of conglutinin to iC3b, a fragment of the complement component C3. It was reported that conglutinin binds fluid-phase C3b and C3c as well as iC3b. We re-investigated the reactivity of conglutinin towards fluid-phase C3 degradation products. ELISA wells were coated with conglutinin and reacted with C3 split products generated in normal human serum, in factor I-deficient serum, or in factor I-depleted serum. Conglutinin-bound C3 fragments were detected with anti-C3c and anti-C3d antibodies. An increased signal was observed during the activation of complement in normal human serum with the peak response after 1-2 hr, following which the signal decreased, reaching background level after 72 hr. The oligosaccharides on C3c, generated in serum, are thus not recognized by conglutinin. No signal was observed when factor I-deficient serum or factor I-depleted serum was used instead of normal serum. Reconstitution with purified factor I re-established the normal pattern. Examination of the conglutinin-bound C3 molecules by SDS-PAGE and Western blotting with anti-C3c and anti-C3d antibodies revealed bands characteristic for iC3b, and no bands corresponding to C3b or C3c. Reduction of the disulphide bonds prior to the incubation of the activated serum with the conglutinin-coated wells revealed a band of 63,000 MW, characteristic of the N-terminal fragment of the alpha-chain of iC3b. We also investigated the binding to the solid-phase conglutinin of purified C3 and degradation products generated with enzymes. In this case, C3 as well as C3b and C3c were bound, suggesting conformational changes in C3 during purification. In conclusion, when C3 conversion takes place at near physiological conditions, conglutinin interacts specifically with the oligosaccharide on the alpha-chain of iC3b.     

Function of C3 in a humoral response: iC3b/C3dg bound to an immune complex generated with natural antibody and a primary antigen promotes antigen uptake and the expression of co-stimulatory molecules by all B cells,but only stimulates immunoglobulin synthesis by antigen-specific B cells

Previous studies have shown that an optimal humoral response to a primary protein antigen requires C3 and CR2 (CD21). Sera from non-immunized donors contain natural IgM and IgG antibodies to the primary antigen keyhole limpet haemocyanin (KLH), and these have been previously shown to form immune complexes (IC) that activate the classical pathway of C, fixing iC3b/C3dg onto the KLH antigen. Such KLH IC bind to CR2 on KLH-non-specific B lymphocytes, resulting in antigen processing and MHC class II-dependent presentation to KLH-specific helper T cells. KLH IC also induce B lymphocytes to express the CD80 co-stimulatory molecule via simultaneous CR2 ligation with C3 and FcγRII (CD32) stimulation by IgG natural antibody. The current study demonstrated that KLH IC ligation to either CR2 or FcγRII resulted in activation of a second co-stimulatory molecule, LFA-1 (CD11a, CD18). The possibility of polyclonal B cell stimulation by the presentation of KLH-iC3b/C3dg by antigen-non-specific B cells was excluded by demonstration that in vitro cultivation of peripheral blood mononuclear cells (PBMC) with KLH-iC3b/C3dg elicited only anti-KLH, and did not stimulate synthesis of antibodies to hepatitis C virus (HCV) or tetanus toxoid (TT). Of greatest significance, a specific anti-KLH response was only detectable in cultures stimulated with KLH-iC3b/C3dg and not in cultures stimulated with KLH alone or KLH-IgG. Thus, iC3b/C3dg that was bound to a primary protein antigen enhanced recognition and specific immunoglobulin synthesis by antigen-specific B cells, even though the antigen was taken up and processed via CR2 by both antigen-specific and non-specific B cells.     

Generation of iC3 at the Interface between Blood and Gas

Earlier studies have shown that C3 can be denatured when blood comes in contact with a polystyrene surface. This study was undertaken to see if similar denaturation of C3 occurs at the gas-plasma interface which is found in all kinds of oxygenator used during cardio-pulmonary operations. An in vitro system consisting of gas bubbling through human blood, serum or plasma was used. The generation of C3a, as an indicator of complement activation, and iC3 and iC3 fragments were monitored. Both C3a and iC3/iC3 fragments levels were increased during bubbling. In contrast to the C3a level, no reduction in iC3/iC3 fragments formation was seen in the presence of EDTA, indicating that it was independent of complement activation. The rate of iC3/iC3 fragments generation was unaffected by the composition of the gas (pure oxygen, pure nitrogen or air), suggesting that the denaturation of C3 indeed occurred at the serum-gas interface. C3 and iC3/iC3 fragments were isolated from bubbled EDTA-chelated serum by PEG precipitation and chromatography on FPLC, using a Mono S column and detected by two ELISAs, specific for native C3 and iC3/iC3 fragments. After 240 min approximately 20% of the total amount of C3 consisted of intact iC3 and it was confirmed that this population bound to human erythrocytes.     

Quantitative analysis of protein co-localization on B cells opsonized with rituximab and complement using the ImageStream multispectral imaging flow cytometer

Binding of the chimeric, humanized anti-CD20 mAb Rituximab (RTX) to B lymphocytes activates complement and promotes covalent deposition of C3 fragments (C3b/iC3b) on cells. Previous fluorescence microscopy studies, based on examination of B cell lines and of blood samples from RTX-treated CLL patients, suggest that C3b/iC3b is closely associated with cell-bound RTX. We examined Raji cells opsonized with serum and RTX with the ImageStream imaging flow cytometer. Cells were stained with fluorescently-labeled RTX and mAbs specific for C3b/iC3b fragments or for human IgG, and then imaged using the ImageStream cytometer and analyzed with an algorithm (Similarity Bright Detail Score, SBDS) which tests for co-localization of fluorescent probes. SBDS, calculated on 10,000 cells, verified that the majority of deposited C3b/iC3b is co-localized with bound RTX. In contrast, when cells were first opsonized in serum alone, washed and then reacted with RTX, SBDS confirmed that RTX and C3b/iC3b are poorly co-localized, thus demonstrating that cell-bound RTX directs deposition of C3b. In addition, a sulfhydryl-specific probe, maleimide conjugated to AF488, exhibited substantial co-localization with an anti-C3b/iC3b mAb on Raji cells opsonized with RTX and serum, thus validating maleimide labeling as an alternative for detecting cell-bound C3b/iC3b. The digital imaging method described should have wide applicability for quantitative analysis of co-localization.     

Herpes simplex virus glycoprotein C: molecular mimicry of complement regulatory proteins by a viral protein.

Herpes simplex virus (HSV) encodes a protein, glycoprotein C (gC), which binds to the third complement component, the central mediator of complement activation. In this study the structural and functional relationships of gC from HSV type 1 (HSV-1) and known human complement regulatory proteins factor H, properdin, factor B, complement receptor 1 (CR1) and 2 (CR2) were investigated. The interaction of gC with C3b was studied using purified complement components, synthetic peptides, antisera against different C3 fragments and anti-C3 monoclonal antibodies (mAb) with known inhibitory effects on C3-ligand interactions. All the mAb that inhibited gC/C3b interactions, in a differential manner, also prevented binding of C3 fragments to factors H, B, CR1 or CR2. No blocking was observed with synthetic peptides representing different C3 regions or with factor B and C3d, whereas C3b, C3c and factor H were inhibitory, as well as purified gC. There was no binding of gC to cobra venom factor (CVF), a C3c-like fragment derived from cobra gland. Purified gC bound to iC3, iC3b and C3c, but failed to bind to C3d. Glycoprotein C bound only weakly to iC3 derived from bovine and porcine plasma, thus indicating a preference of the viral protein for the appropriate host. Binding of gC was also observed to proteolytic C3 fragments, especially to the beta-chain, thus suggesting the importance of the C3 region as a binding site. Purified gC from HSV-1, but not HSV-2, inhibited the binding of factor H and properdin but not of CR1 to C3b. The binding of iC3b to CR2, a molecule involved in B-cell activation and binding of the Epstein-Barr virus, was also inhibited by the HSV-1 protein. As factor H and properdin, the binding of which was inhibited by gC, are important regulators of the alternative complement pathway, these data further support a role of gC in the evasion of HSV from a major first-line host defence mechanism, i.e. the complement system. In addition, the inhibition of the C3/CR2 interaction may suggest a possible immunoregulatory role of HSV glycoprotein C.