Novel mechanism of antibody-independent complement neutralization of herpes simplex virus type 1

The envelope surface glycoprotein C (gC) of HSV-1 interferes with the complement cascade by binding C3 and activation products C3b, iC3b, and C3c, and by blocking the interaction of C5 and properdin with C3b. Wild-type HSV-1 is resistant to Ab-independent complement neutralization; however, HSV-1 mutant virus lacking gC is highly susceptible to complement resulting in > or =100-fold reduction in virus titer. We evaluated the mechanisms by which complement inhibits HSV-1 gC null virus to better understand how gC protects against complement-mediated neutralization. C8-depleted serum prepared from an HSV-1 and -2 Ab-negative donor neutralized gC null virus comparable to complement-intact serum, indicating that C8 and terminal lytic activity are not required. In contrast, C5-depleted serum from the same donor failed to neutralize gC null virus, supporting a requirement for C5. EDTA-treated serum did not neutralize gC null virus, indicating that complement activation is required. Factor D-depleted and C6-depleted sera neutralized virus, suggesting that the alternative complement pathway and complement components beyond C5 are not required. Complement did not aggregate virus or block attachment to cells. However, complement inhibited infection before early viral gene expression, indicating that complement affects one or more of the following steps in virus replication: virus entry, uncoating, DNA transport to the nucleus, or immediate early gene expression. Therefore, in the absence of gC, HSV-1 is readily inhibited by complement by a C5-dependent mechanism that does not require viral lysis, aggregation, or blocking virus attachment.     

Herpes simplex virus type 1 and 2 glycoprotein C prevents complement-mediated neutralization induced by natural immunoglobulin M antibody

Glycoprotein C (gC) of herpes simplex virus type 1 (HSV-1) and type 2 (HSV-2) binds complement component C3b and protects virus from complement-mediated neutralization. Differences in complement interacting domains exist between gC of HSV-1 (gC1) and HSV-2 (gC2), since the amino terminus of gC1 blocks complement C5 from binding to C3b, while gC2 fails to interfere with this activity. We previously reported that neutralization of HSV-1 gC-null virus by HSV antibody-negative human serum requires activation of C5 but not of downstream components of the classical complement pathway. In this report, we evaluated whether activation of C5 is sufficient to neutralize HSV-2 gC-null virus, or whether formation of the membrane attack complex by C6 to C9 is required for neutralization. We found that activation of the classical complement pathway up to C5 was sufficient to neutralize HSV-2 gC-null virus by HSV antibody-negative human serum. We evaluated the mechanisms by which complement activation occurred in seronegative human serum. Interestingly, natural immunoglobulin M antibodies bound to virus, which triggered activation of C1q and the classical complement pathway. HSV antibody-negative sera obtained from four individuals differed over an approximately 10-fold range in their potency for complement-mediated virus neutralization. These findings indicate that humans differ in the ability of their innate immune systems to neutralize HSV-1 or HSV-2 gC-null virus and that a critical function of gC1 and gC2 is to prevent C5 activation.     

Binding of complement component C3b to glycoprotein C is modulated by sialic acid on herpes simplex virus type 1-infected cells.

Neuraminidase treatment of cells infected with herpes simplex virus type 1 (HSV-1) markedly enhanced the binding of complement component C3b to HSV 1 glycoprotein C (gC). When HSV-1 was grown in BHK RicR14 cells in which glycoproteins had reduced amounts of N-linked complex oligosaccharides, including sialic acid, the binding of C3b to gC was markedly enhanced. We used neuraminidase treatment to demonstrate that cloning the gC gene from the HSV-1 F strain into an HSV-1 mutant which fails to express gC converted the mutant virus from C3b receptor negative to receptor positive. These results further support a role for gC as a C3b receptor and indicate that sialic acid modifies receptor activity.     

Binding of complement component C3b to glycoprotein gC of herpes simplex virus type 1: mapping of gC-binding sites and demonstration of conserved C3b binding in low-passage clinical isolates.

The sites on glycoprotein gC of herpes simplex virus type 1 (HSV-1) which bind complement component C3b were evaluated by using anti-gC monoclonal antibodies and mutants which have alterations at defined regions of the glycoprotein. Monoclonal antibodies were incubated with HSV-1-infected cells in a competitive assay to block C3b binding. Each of 12 different monoclonals, which recognize the four major antigenic sites of gC, completely inhibited C3b binding. With this approach, no one antigenic group on gC could be assigned as the C3b-binding region. Next, 21 gC mutants were evaluated for C3b binding, including 1 which failed to synthesize gC, 4 which synthesized truncated forms of the glycoprotein such that gC did not insert into the cell's membrane, and 16 which expressed gC on the cell's surface but which had mutations in various antigenic groups. Eleven strains did not bind C3b. This included the 1 strain which did not synthesize gC, the 4 strains which secreted gC without inserting the glycoprotein into the cell membrane, and 6 of 16 strains which expressed gC on the cell surface. In these six strains, the mutations were at three different antigenic sites. One hypothesis to explain these findings is that C3b binding is modified by changes in the conformation of gC which develop either after antibodies bind to gC or as a result of mutations in the gC gene. Attachment of C3b to gC was also evaluated in 31 low-passage clinical isolates of HSV-1. Binding was detected with each HSV-1 isolate, but not with nine HSV-2 isolates. Therefore, although mutants that lack C3b binding are readily selected in vitro, the C3b-binding function of gC is maintained in vivo. These results indicate that the sites on gC that bind C3b are different from those that bind monoclonal antibodies, that antibodies directed against all sites on gC block C3b binding, and that C3b binding is a conserved function of gC in vivo.     

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.     

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.     

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 role of properdin in the assembly of the alternative pathway C3 convertases of complement

Complement is a powerful host defense system that contributes to both innate and acquired immunity. There are three pathways of complement activation, the classical pathway, lectin pathway, and alternative pathway. Each generates a C3 convertase, a serine protease that cleaves the central complement protein, C3. Nearly all the biological consequences of complement are dependent on the resulting cleavage products. Properdin is a positive regulator of complement activation that stabilizes the alternative pathway convertases (C3bBb). Properdin is composed of multiple identical protein subunits, with each subunit carrying a separate ligand-binding site. Previous reports suggest that properdin function depends on multiple interactions between its subunits with its ligands. In this study I used surface plasmon resonance assays to examine properdin interactions with C3b and factor B. I demonstrated that properdin promotes the association of C3b with factor B and provides a focal point for the assembly of C3bBb on a surface. I also found that properdin binds to preformed alternative pathway C3 convertases. These findings support a model in which properdin, bound to a target surface via C3b, iC3b, or other ligands, can use its unoccupied C3b-binding sites as receptors for nascent C3b, bystander C3b, or pre-formed C3bB and C3bBb complexes. New C3bP and C3bBP intermediates can lead to in situ assembly of C3bBbP. The full stabilizing effect of properdin on C3bBb would be attained as properdin binds more than one ligand at a time, forming a lattice of properdin: ligand interactions bound to a surface scaffold.     

Herpes simplex virus type 1 evades the effects of antibody and complement in vivo

Herpes simplex virus type 1 (HSV-1) encodes a complement-interacting glycoprotein, gC, and an immunoglobulin G (IgG) Fc binding glycoprotein, gE, that mediate immune evasion by affecting multiple aspects of innate and acquired immunity, including interfering with complement components C1q, C3, C5, and properdin and blocking antibody-dependent cellular cytotoxicity. Previous studies evaluated the individual contributions of gC and gE to immune evasion. Experiments in a murine model that examines the combined effects of gC and gE immune evasion on pathogenesis are now reported. Virulence of wild-type HSV-1 is compared with mutant viruses defective in gC-mediated C3 binding, gE-mediated IgG Fc binding, or both immune evasion activities. Eliminating both activities greatly increased susceptibility of HSV-1 to antibody and complement neutralization in vitro and markedly reduced virulence in vivo as measured by disease scores, virus titers, and mortality. Studies with C3 knockout mice indicated that other activities attributed to these glycoproteins, such as gC-mediated virus attachment to heparan sulfate or gE-mediated cell-to-cell spread, do not account for the reduced virulence of mutant viruses. The results support the importance of gC and gE immune evasion in vivo and suggest potential new targets for prevention and treatment of HSV disease.     

Antigenic variants of herpes simplex virus selected with glycoprotein-specific monoclonal antibodies.

Monoclonal antibodies specific for herpes simplex virus type 1 (HSV-1) glycoproteins were used to demonstrate that HSV undergoes mutagen-induced and spontaneous antigenic variation. Hybridomas were produced by polyethylene glycol-mediated fusion of P3-X63-Ag8.653 myeloma cells with spleen cells from BALB/c mice infected with HSV-1 (strain KOS). Hybrid clones were screened for production of HSV-specific neutralizing antibody. The glycoprotein specificities of the antibodies were determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of immunoprecipitates of radiolabeled infected-cell extracts. Seven hybridomas producing antibodies specific for gC, one for gB, and one for gD were characterized. All antibodies neutralized HSV-1 but not HSV-2. Two antibodies, one specific for gB and one specific for gC, were used to select viral variants resistant to neutralization by monoclonal antibody plus complement. Selections were made from untreated and bromodeoxyuridine- and nitrosoguanidine-mutagenized stocks of a plaque-purified isolate of strain KOS. After neutralization with monoclonal antibody plus complement, surviving virus was plaque purified by plating at limiting dilution and tested for resistance to neutralization with the selecting antibody. The frequency of neutralization-resistant antigenic variants selected with monoclonal antibody ranged from 4 X 10(-4) in nonmutagenized stocks to 1 X 10(-2) in mutagenized stocks. Four gC and four gB antigenic variants were isolated. Two variants resistant to neutralization by gC-specific antibodies failed to express gC, accounting for their resistant phenotype. The two other gC antigenic variants and the four gB variants expressed antigenically altered glycoproteins and were designated monoclonal-antibody-resistant, mar, mutants. The two mar C mutants were tested for resistance to neutralization with a panel of seven gC-specific monoclonal antibodies. The resulting patterns of resistance provided evidence for at least two antigenic sites on glycoprotein gC.     

Herpes Simplex Virus Type 1 Glycoprotein gC Mediates Immune Evasion In Vivo

Many microorganisms encode proteins that interact with molecules involved in host immunity; however, few of these molecules have been proven to promote immune evasion in vivo. Herpes simplex virus type 1 (HSV-1) glycoprotein C (gC) binds complement component C3 and inhibits complement-mediated virus neutralization and lysis of infected cells in vitro. To investigate the importance of the interaction between gC and C3 in vivo, we studied the virulence of a gC-null strain in complement-intact and C3-deficient animals. Using a vaginal infection model in complement-intact guinea pigs, we showed that gC-null virus grows to lower titers and produces less severe vaginitis than wild-type or gC rescued virus, indicating a role for gC in virulence. To determine the importance of complement, studies were performed with C3-deficient guinea pigs; the results demonstrated significant increases in vaginal titers of gC-null virus, while wild-type and gC rescued viruses showed nonsignificant changes in titers. Similar findings were observed for mice where gC null virus produced significantly less disease than gC rescued virus at the skin inoculation site. Proof that C3 is important was provided by studies of C3 knockout mice, where disease scores of gC-null virus were significantly higher than in complement-intact mice. The results indicate that gC-null virus is approximately 100-fold (2 log₁₀) less virulent that wild-type virus in animals and that gC-C3 interactions are involved in pathogenesis.     

Enhanced reactive lysis of paroxysmal nocturnal hemoglobinuria erythrocytes by C5b-9 does not involve increased C7 binding or cell-bound C3b

The most complement (C)-sensitive type of erythrocytes (E) occurring in paroxysmal nocturnal hemoglobinuria (type III PNH E) have previously been found to exhibit approximately twofold to fourfold greater lysis than normal human E when exposed to isolated human C5b6, C7, C8, and C9 (reactive lysis), in the absence of a known source of C3- or C5-convertases or fluid-phase C3. In further studies on the mechanism of this phenomenon, we now report that C5b6-dependent binding of 125I-C7 to two samples of PNH E (greater than 95% type III) is equal to that found with normal human E at each of several C5b6 inputs tested. Lysis developed by excess C8 and C9, however, was consistently greater for the PNH E. Thus, the exaggerated sensitivity of type III PNH E to reactive lysis cannot be explained by abnormally high uptake of C5b6 or C7 from the fluid phase. Rather, the data indicate that cell-bound C5b67 sites are converted to effective hemolytic sites with greater efficiency on type III PNH E than on normal human E, assuming that the distribution of cell-bound C7 throughout both cell populations is similar. In related studies we have addressed the proposal by other investigators that C3b putatively bound to PNH E in vivo might account for their increased sensitivity to reactive lysis in vitro, by analogy to prior observations on C3b-potentiated reactive lysis of sheep E. The latter hypothesis was made more appealing by the recent discovery that type III PNH E lack an integral membrane protein, decay-accelerating factor (DAF), which in normal E accelerates the decay of membrane-bound C3 convertases. Against this hypothesis, however, is our present finding that preincubation of PNH E with four different goat or rabbit polyclonal antibodies to human C3 failed to inhibit the subsequent reactive lysis of these cells. Under these same conditions, the C3b-dependent increment in reactive lysis of sheep EAC4b3b was abrogated by pretreatment with similar dilutions of these anti-C3 antibodies, generally in association with agglutination. Furthermore, sheep EAC4b3b displayed increased 125I-C7 binding in proportion to augmented lysis, in contrast to the findings with PNH E. Therefore, deficiency of DAF in type III PNH E does not adequately explain their supranormal sensitivity to reactive lysis unless DAF can modulate the terminal lytic steps by a mechanism distinct from its effect on C3 convertase decay. Alternatively, type III PNH E could have a more general abnormality in which DAF deficiency is one manifestation and increased sensitivity to reactive lysis is another.     

Characterization of the complement inhibitory function of rhesus rhadinovirus complement control protein (RCP)

Rhesus rhadinovirus (RRV) is currently the closest known, fully sequenced homolog of human Kaposi sarcoma-associated herpesvirus. Both these viruses encode complement inhibitors as follows: Kaposi sarcoma-associated herpesvirus-complement control protein (KCP) and RRV-complement control protein (RCP). Previously we characterized in detail the functional properties of KCP as a complement inhibitor. Here, we performed comparative analyses for two variants of RCP protein, encoded by RRV strains H26-95 and 17577. Both RCP variants and KCP inhibited human and rhesus complement when tested in hemolytic assays measuring all steps of activation via the classical and the alternative pathway. RCP variants from both RRV strains supported C3b and C4b degradation by factor I and decay acceleration of the classical C3 convertase, similar to KCP. Additionally, the 17577 RCP variant accelerated decay of the alternative C3 convertase, which was not seen for KCP. In contrast to KCP, RCP showed no affinity to heparin and is the first described complement inhibitor in which the binding site for C3b/C4b does not interact with heparin. Molecular modeling shows a structural disruption in the region of RCP that corresponds to the KCP-heparin-binding site. This makes RRV a superior model for future in vivo investigations of complement evasion, as RCP does not play a supportive role in viral attachment as KCP does.     

Mucin-like Region of Herpes Simplex Virus Type 1 Attachment Protein Glycoprotein C (gC) Modulates the Virus-Glycosaminoglycan Interaction

Glycoprotein C (gC) mediates the attachment of HSV-1 to susceptible host cells by interacting with glycosaminoglycans (GAGs) on the cell surface. gC contains a mucin-like region located near the GAG-binding site, which may affect the binding activity. Here, we address this issue by studying a HSV-1 mutant lacking the mucin-like domain in gC and the corresponding purified mutant protein (gCΔmuc) in cell culture and GAG-binding assays, respectively. The mutant virus exhibited two functional alterations as compared with native HSV-1 (i.e. decreased sensitivity to GAG-based inhibitors of virus attachment to cells and reduced release of viral particles from the surface of infected cells). Kinetic and equilibrium binding characteristics of purified gC were assessed using surface plasmon resonance-based sensing together with a surface platform consisting of end-on immobilized GAGs. Both native gC and gCΔmuc bound via the expected binding region to chondroitin sulfate and sulfated hyaluronan but not to the non-sulfated hyaluronan, confirming binding specificity. In contrast to native gC, gCΔmuc exhibited a decreased affinity for GAGs and a slower dissociation, indicating that once formed, the gCΔmuc-GAG complex is more stable. It was also found that a larger number of gCΔmuc bound to a single GAG chain, compared with native gC. Taken together, our data suggest that the mucin-like region of HSV-1 gC is involved in the modulation of the GAG-binding activity, a feature of importance both for unrestricted virus entry into the cells and release of newly produced viral particles from infected cells.     

A corresponding tyrosine residue in the C2/factor B type A domain is a hot spot in the decay acceleration of the complement C3 convertases

The cleavage of C3 by the C3 convertases (C3bBb and C4b2a) determines whether complement activation proceeds. Dissociation (decay acceleration) of these central enzymes by the regulators decay-accelerating factor (DAF), complement receptor 1 (CR1), factor H, and C4-binding protein (C4BP) controls their function. In a previous investigation, we obtained evidence implicating the alpha4/5 region of the type A domain of Bb (especially Tyr338) in decay acceleration of C3bBb and proposed this site as a potential interaction point with DAF and long homologous repeat A of CR1. Because portions of only two DAF complement control protein domains (CCPs), CCP2 and CCP3, are necessary to mediate its decay of the CP C3 convertase (as opposed to portions of at least three CCPs in all other cases, e.g. CCPs 1-3 of CR1), DAF/C4b2a provides the simplest structural model for this reaction. Therefore, we examined the importance of the C2 alpha4/5 site on decay acceleration of C4b2a. Functional C4b2a complexes made with the C2 Y327A mutant, the C2 homolog to factor B Y338A, were highly resistant to DAF, C4BP, and long homologous repeat A of CR1, whereas C2 substitutions in two nearby residues (N324A and L328A) resulted in partial resistance. Our new findings indicate that the alpha4/5 region of C2a is critical to decay acceleration mediated by DAF, C4BP, and CR1 and suggest that decay acceleration of C4b2a and C3bBb requires interaction of the convertase alpha4/5 region with a CCP2/CCP3 site of DAF or structurally homologous sites of CR1 and C4BP.     

A complement-resistant HeLa cell line (T638) is blocked at the step of C3 deposition

A complement-resistant line of HeLa cells (T638) was derived by serial passage of complement-susceptible HeLa cells in anti-beta 2-microglobulin (b2m) antiserum and complement. The T638 line maintained stable complement resistance when passed for an additional 1500 generations in the absence of antiserum and complement. T638 cells expressed equivalent levels of cell-associated b2m as did the parent HeLa cell line. Furthermore, T638 cells were resistant to killing by complement and anti-HeLa antiserum with specificity for molecules other than b2m. These results indicate that the resistance of T638 cells does not simply reflect loss of anti-b2m binding antigens. We next investigated the mechanism of resistance of T638 cells to complement-mediated killing. Antibody-sensitized HeLa and T638 cells both consumed CH50 activity completely from normal human serum; cytotoxicity was not mediated via the alternative complement pathway. HeLa and T638 cells caused equivalent utilization of C4 from normal human serum in the presence of antibody. Consumption of C2, greater with T638 than with HeLa cells during incubation in serum, was complete when cells bearing purified C1 and limited C4 were incubated with C2. T638 cells bound more 3H-C4 than HeLa cells during incubation in serum, but binding of 3H-C3 by T638 cells was fourfold to fivefold less than by HeLa cells. Finally, we investigated the rate of decay in the capacity of C142 on HeLa and T638 to cleave and deposit 3H-C3. The T1/2 for decay of C142-mediated binding of 3H-C3 on HeLa was 3.9 min, whereas minimal C3 deposition was detected on T638 cells at all time points. These results show that T638 cells evade complement-mediated lysis despite activating early components of the classical complement pathway. The mechanism of resistance is a failure to form an effective C3 convertase.     

Membrane factors responsible for homologous species restriction of complement-mediated lysis: evidence for a factor other than DAF operating at the stage of C8 and C9

Species-restricted lysis of complement refers to the relative inefficiency of complement to lyse cells from the homologous species. Restriction occurs at least at the steps involving C3/C5 convertase formation and the C9 insertion phase of the complement cascade, and is presumed to be mediated by inhibitory factors in the target cell membrane. In this study, we have examined whether decay accelerating factor (DAF), a membrane protein known to modulate C3/C5 convertase activities on cell surfaces, acts as a regulatory protein in species-restricted lysis of human erythrocyte (E). The role of DAF was assessed in homologous lysis by the classic pathway, in reactive lysis, and in lytic steps requiring C8 and C9. The results indicated that DAF participated in regulating C3/C5 deposition on the surface of homologous E, but had no effect on homologous restriction in reactive lysis and in the reaction of C8 and C9 with antibody-sensitized E C1-7. Treatment of E with pronase or with dithiothreitol (DTT) abolished the restricting effect of homologous C8/C9, indicating that species-restricted lysis by C5b-9 involves membrane factor(s) sensitive to pronase and DTT.     

C3b receptor activity on transfected cells expressing glycoprotein C of herpes simplex virus types 1 and 2.

Glycoprotein C from herpes simplex virus type 1 (gC-1 from HSV-1) acts as a receptor for the C3b fragment of the third component of complement on HSV-1-infected cell surfaces. Direct binding assays with purified gC-1 and C3b demonstrate that other viral and cellular proteins are not required for this interaction. Although C3b receptor activity is not expressed on HSV-2-infected cell surfaces, purified gC-2 specifically binds C3b in direct binding assays, suggesting that gC-1 and gC-2 are functionally similar. Here, we used a transient transfection system to further characterize the role of gC-1 and gC-2 as C3b receptors and to localize the site(s) on gC involved in C3b binding. The genes for gC-1 and gC-2 were each cloned into a eucaryotic expression vector containing the Rous sarcoma virus long terminal repeat as the promoter and transfected into NIH 3T3 cells. The expressed proteins were similar in molecular size, extent of carbohydrate processing, and antigenic properties to gC-1 and gC-2 purified from infected cells. Using a double-label immunofluorescence assay, we found that both gC-1 and gC-2 were expressed on the surfaces of transfected cells and bound C3b. These results suggest that other proteins expressed during HSV-2 infection prevent receptor activity. We constructed three in-frame deletion mutants of gC-2 to identify domains on the protein important for C3b receptor activity. These mutants lacked amino acids 26 to 73, 219 to 244, or 318 to 346. The mutant protein lacking residues 26 to 73 was reactive with two monoclonal antibodies recognizing distinct epitopes, showed a wild-type pattern of carbohydrate processing, and bound C3b on the transfected cell surface. These results suggest that residues 26 to 73 are not involved in C3b binding. The other two mutant proteins were present on the cell surface, but did not bind C3b. In addition, these mutant proteins showed altered patterns of carbohydrate processing, formed aggregates, and were no longer recognized by the monoclonal antibodies. These properties indicate that removal of residues 219 to 244 or 318 to 346 disrupted the native conformation of gC-2, possibly owing to an alteration in the spacing between critical cysteine residues.     

Production of nephritic factor of the alternative complement pathway by Epstein Barr virus-transformed B cell lines derived from a patient with membranoproliferative glomerulonephritis

Nephritic factor of the alternative complement pathway (C3NeF) is an IgG autoantibody which binds to and stabilizes the C3 convertase (C3bBb) enzyme, and which has been detected mainly in sera from patients with membranoproliferative glomerulonephritis (MPGN) and partial lipodystrophy. To study the production of C3NeF, mononuclear cells isolated from the peripheral blood of patients with MPGN and C3NeF activity in their sera were infected with Epstein Barr virus (EBV) to establish active B lymphocyte cell lines. By using a modified C3NeF screening assay, we detected C3NeF activity in the supernatant of a B cell line derived from a patient with MPGN Type II, but in none of the supernatants of B cell lines derived from normal individuals. C3NeF-positive supernatants were investigated for their ability to conserve classical or alternative pathway C3 convertase activity by using EAC3bBb and EAC4b2a stabilization assays. C3NeF-positive supernatants stabilized the C3bBb convertase activity, but not the C4b2a convertase activity. Studies of the supernatants, using anti-human IgG affinity columns, showed that the C3NeF activity was in the IgG fraction; furthermore, C3NeF antibody agglutinated sheep erythrocytes coated with C3bBb, but not with C3b alone. On gel electrophoresis, both heavy and light chains of the C3NeF were comparable in size to that of normal human IgG molecules. We conclude that C3NeF, produced in vitro by EBV-transformed B cell lines derived from a patient with MPGN Type II, is functionally identical to the conventional C3NeF in serum. In vitro preparation of homogeneous NeF(s) should greatly facilitate the studies of the role of these autoantibodies in complement dysmetabolism.