Characterization of a Trypanosoma cruzi C3 binding protein with functional and genetic similarities to the human complement regulatory protein, decay-accelerating factor.

Evasion of the complement system by microorganisms is an essential event in the establishment of infection. In the case of Trypanosoma cruzi, the causative agent of Chagas disease, resistance to complement-mediated lysis is a developmentally regulated characteristic. Infectious trypomastigotes are resistant to complement-mediated lysis in the absence of immune antibodies, whereas the insect forms (epimastigotes) are sensitive to lysis via the alternative complement pathway. We have purified a developmentally regulated, trypomastigote glycoprotein, gp160, and shown that it has complement regulatory activity. The T. cruzi gp160 restricts complement activation by binding the complement component C3b and inhibiting C3 convertase formation. The protein is anchored in the parasite membrane via a glycosyl phosphatidylinositol linkage, similar to the human complement regulatory protein, decay-accelerating factor. Using anti-gp160 antibodies we have isolated a bacteriophage lgt11 clone expressing a portion of the gp160 gene that shares significant DNA sequence homology with the human DAF gene. These results provide functional, biochemical, and genetic evidence that the T. cruzi gp160 is a member of the C3/C4 binding family of complement regulatory proteins, and that gp160 may provide the infectious trypomastigotes with a means of evading the destructive effects of complement.     

Mapping of epitopes, glycosylation sites, and complement regulatory domains in human decay accelerating factor.

Decay accelerating factor (DAF, CD55) is a glycophospholipid-anchored membrane protein that protects cells from complement-mediated damage by inhibiting the formation and accelerating the decay of C3/C5 convertases. DAF deletion mutants lacking each of the four short consensus repeats (SCR) or the serine/threonine-rich region (S/T) were created by site-directed mutagenesis. These deletion mutants were expressed by stable transfection in Chinese hamster ovary cells for the purpose of mapping important structural and functional sites in DAF. The epitopes on DAF for 16 murine mAb were mapped by immunoprecipitation studies as follows: SCR1, 6; SCR2, 3; SCR3, 3; SCR4, 3; S/T, 1. Testing of 13 mAb showed complete blocking of DAF function only by 1C6 and 1H4, both directed at SCR3. The single N-linked glycosylation site was confirmed at a location between SCR1 and SCR2, and the multiple O-linked oligosaccharides were localized to the S/T region. Functional activity of DAF mutants was assessed by the ability of these transfected constructs to protect Chinese hamster ovary cells from cytotoxicity induced by rabbit antibody plus human complement. Removal of SCR1 had no effect on DAF function, but individual deletion of SCR2, SCR3, or SCR4 totally abolished DAF function. Surprisingly, deletion of the S/T region totally abrogated DAF function, but this could be restored by a fusion construct placing the four SCR domains of DAF onto the HLA-B44 molecule, implying that the O-glycosylated S/T region serves as an important but nonspecific spacer projecting the DAF functional domains above the plasma membrane. Overall, the creation of DAF deletion mutants has elucidated important structure-function relations in the DAF molecule.     

Two major serum components antigenically related to complement factor H are different glycosylation forms of a single protein with no factor H-like complement regulatory functions.

Factor H is a 150-kDa serum glycoprotein with key regulatory functions in the alternative pathway of complement activation. Two glycoproteins with a molecular mass of approximately 42 and 37 kDa that react with an antiserum against factor H were purified from human plasma. The two glycoproteins have identical N-terminal amino acid sequences but differ in glycosylation. Sequence comparisons indicated that they both correspond to a 1.4-kb mRNA recently cloned from human liver cDNA. The serum concentration of the two glycoproteins together was estimated to be approximately 40 mg/liter. They were found not to exert factor H-like regulatory functions in the alternative pathway. Thus, the 42-kDa glycoprotein described here appears to be distinct from the previously characterized factor H-related protein of similar size, suggesting that human serum contains two factor-H related molecules which both have a molecular mass of 41 to 43 kDa but which differ largely in structure.     

Cooperation between decay-accelerating factor and membrane cofactor protein in protecting cells from autologous complement attack

Decay-accelerating factor (DAF or CD55) and membrane cofactor protein (MCP or CD46) function intrinsically in the membranes of self cells to prevent activation of autologous complement on their surfaces. How these two regulatory proteins cooperate on self-cell surfaces to inhibit autologous complement attack is unknown. In this study, a GPI-anchored form of MCP was generated. The ability of this recombinant protein and that of naturally GPI-anchored DAF to incorporate into cell membranes then was exploited to examine the combined functions of DAF and MCP in regulating complement intermediates assembled from purified alternative pathway components on rabbit erythrocytes. Quantitative studies with complement-coated rabbit erythrocyte intermediates constituted with each protein individually or the two proteins together demonstrated that DAF and MCP synergize the actions of each other in preventing C3b deposition on the cell surface. Further analyses showed that MCP's ability to catalyze the factor I-mediated cleavage of cell-bound C3b is inhibited in the presence of factors B and D and is restored when DAF is incorporated into the cells. Thus, the activities of DAF and MCP, when present together, are greater than the sum of the two proteins individually, and DAF is required for MCP to catalyze the cleavage of cell-bound C3b in the presence of excess factors B and D. These data are relevant to xenotransplantation, pharmacological inhibition of complement in inflammatory diseases, and evasion of tumor cells from humoral immune responses.     

Effects of O-linked glycosylation on the cell surface expression and stability of decay-accelerating factor, a glycophospholipid-anchored membrane protein

Decay accelerating factor (DAF) is a glycophospholipid-anchored membrane glycoprotein that protects mammalian host cells from inadvertant complement lysis. The effects of inhibiting mucin-type O-glycosylation on the cell surface expression of DAF were studied by introducing an expression vector for human DAF into wild-type Chinese hamster ovary and ldlD cells. The ldlD cells express reversible defects in the addition of galactose and N-acetylgalactosamine (GalNAc) to oligosaccharide chains on glycoproteins and glycolipids. Mucin-type O-glycosylation of proteins is inhibited in ldlD cells and can be selectively corrected by the addition of GalNAc to the culture medium. The attachment of a phosphatidylinositol phospholipase C-sensitive glycolipid anchor to DAF and its efficient sorting to the cell surface in ldlD cells were independent of galactose and GalNAc additions to glycolipids and proteins. Attachment of galactose and GalNAc to DAF's glycolipid anchor were apparently not required for its normal function. However, in the absence of O-glycosylation DAF was proteolytically cleaved soon after reaching the cell surface, and a large fragment of DAF was released into the culture medium. This rapid proteolysis/release resulted in the expression of very low steady state levels of O-glycosylation-deficient DAF as measured by immunoblotting. These results, in conjunction with those obtained from studies of three other membrane glycoproteins expressed in ldlD cells, suggest that O-linked sugars on membrane glycoproteins may frequently play a role in determining the level of cell surface expression of these proteins.     

Disease-associated N-terminal complement factor H mutations perturb cofactor and decay-accelerating activities

Many mutations associated with atypical hemolytic uremic syndrome (aHUS) lie within complement control protein modules 19-20 at the C terminus of the complement regulator factor H (FH). This region mediates preferential action of FH on self, as opposed to foreign, membranes and surfaces. Hence, speculation on disease mechanisms has focused on deficiencies in regulation of complement activation on glomerular capillary beds. Here, we investigate the consequences of aHUS-linked mutations (R53H and R78G) within the FH N-terminal complement control protein module that also carries the I62V variation linked to dense-deposit disease and age-related macular degeneration. This module contributes to a four-module C3b-binding site (FH1-4) needed for complement regulation and sufficient for fluid-phase regulatory activity. Recombinant FH1-4(V62) and FH1-4(I62) bind immobilized C3b with similar affinities (K(D) = 10-14 μM), whereas FH1-4(I62) is slightly more effective than FH1-4(V62) as cofactor for factor I-mediated cleavage of C3b. The mutant (R53H)FH1-4(V62) binds to C3b with comparable affinity (K(D) ～12 μM) yet has decreased cofactor activities both in fluid phase and on surface-bound C3b, and exhibits only weak decay-accelerating activity for C3 convertase (C3bBb). The other mutant, (R78G)FH1-4(V62), binds poorly to immobilized C3b (K(D) >35 μM) and is severely functionally compromised, having decreased cofactor and decay-accelerating activities. Our data support causal links between these mutations and disease; they demonstrate that mutations affecting the N-terminal activities of FH, not just those in the C terminus, can predispose to aHUS. These observations reinforce the notion that deficiency in any one of several FH functional properties can contribute to the pathogenesis of this disease.     

The Scl1 protein of M6-type group A Streptococcus binds the human complement regulatory protein, factor H, and inhibits the alternative pathway of complement

Non-specific activation of the complement system is regulated by the plasma glycoprotein factor H (FH). Bacteria can avoid complement-mediated opsonization and phagocytosis through acquiring FH to the cell surface. Here, we characterize an interaction between the streptococcal collagen-like protein Scl1.6 of M6-type group A Streptococcus (GAS) and FH. Using affinity chromatography with immobilized recombinant Scl1.6 protein, we co-eluted human plasma proteins with molecular weight of 155 kDa, 43 kDa and 38 kDa. Mass spectrometry identified the 155 kDa band as FH and two other bands as isoforms of the FH-related protein-1. The identities of all three bands were confirmed by Western immunoblotting with specific antibodies. Structure-function relation studies determined that the globular domain of the Scl1.6 variant specifically binds FH while fused to collagenous tails of various lengths. This binding is not restricted to Scl1.6 as the phylogenetically linked Scl1.55 variant also binds FH. Functional analyses demonstrated the cofactor activity of the rScl1.6-bound FH for factor I-mediated cleavage of C3b. Finally, purified FH bound to the Scl1.6 protein present in the cell wall material obtained from M6-type GAS. In conclusion, we have identified a functional interaction between Scl1 and plasma FH, which may contribute to GAS evasion of complement-mediated opsonization and phagocytosis.     

Association of cytoskeletal re-organization with capping of the complement decay-accelerating factor on T lymphocytes

Recent studies have identified cell-associated proteins that are membrane anchored by glycosyl-inositol-phospholipid structures but the biologic implications of this mode of membrane attachment are incompletely understood. Among proteins anchored in this way is the decay-accelerating factor (DAF), a complement (C) regulatory factor that functions on blood cell surfaces to prevent autologous C attack. As one approach to investigate the functional consequences of glycosyl-inositol-phospholipid-anchoring of DAF in T lymphocytes, the effects of crosslinking surface DAF molecules were compared to those of crosslinking conventionally by anchored cluster of differentiation (CD) proteins. Upon incubation with anti-DAF mAb and anti-murine IgG, DAF re-distributed to a pole of the cell with a t1/2 at 37 degrees C of 4.4 min as compared to t1/2 of 3.5 to 7 min for CD3, CD4, and CD8. Re-distribution of DAF occurred independently of CD2, CD3, CD4, or CD8. Anti-DAF immunoprecipitates of membrane extracts of cells chemically cross-linked with dithiobis(succinimidylpropionate) contained only monomeric DAF. Immunofluorescent staining demonstrated clustered actin, tubulin, and vimentin beneath the capped DAF protein. Pre-treatment of cells with colchicine or 8-azidoadenosine 3',5'-cyclic phosphate, but not lumicolchicine, resulted in reduction of the t1/2 for DAF to 1 to 2.6 min. Conversely, treatment of cells with cytochalasins B or D completely blocked DAF capping. The results indicate that, upon cross-linking, glycosyl-inositol-phospholipid-anchored DAF molecules undergo capping similar to conventionally anchored CD molecules and that DAF capping is associated with cytoskeletal reorganization.     

Domain swapping reveals complement control protein modules critical for imparting cofactor and decay-accelerating activities in vaccinia virus complement control protein

Vaccinia virus encodes a structural and functional homolog of human complement regulators named vaccinia virus complement control protein (VCP). This four-complement control protein domain containing secretory protein is known to inhibit complement activation by supporting the factor I-mediated inactivation of complement proteins, proteolytically cleaved form of C3 (C3b) and proteolytically cleaved form of C4 (C4b) (termed cofactor activity), and by accelerating the irreversible decay of the classical and to a limited extent of the alternative pathway C3 convertases (termed decay-accelerating activity [DAA]). In this study, we have mapped the VCP domains important for its cofactor activity and DAA by swapping its individual domains with those of human decay-accelerating factor (CD55) and membrane cofactor protein (MCP; CD46). Our data indicate the following: 1) swapping of VCP domain 2 or 3, but not 1, with homologous domains of decay-accelerating factor results in loss in its C3b and C4b cofactor activities; 2) swapping of VCP domain 1, but not 2, 3, or 4 with corresponding domains of MCP results in abrogation in its classical pathway DAA; and 3) swapping of VCP domain 1, 2, or 3, but not 4, with homologous MCP domains have marked effect on its alternative pathway DAA. These functional data together with binding studies with C3b and C4b suggest that in VCP, domains 2 and 3 provide binding surface for factor I interaction, whereas domain 1 mediates dissociation of C2a and Bb from the classical and alternative pathway C3 convertases, respectively.     

Additional forms of human decay-accelerating factor (DAF)

Decay-accelerating factor (DAF) of human erythrocytes is a glycoprotein with a Mr of 65,000 that is anchored in the membrane via a glycolipid tail. During the purification of DAF, two lower m.w. forms were noted. DAF-A had an Mr of 63,000, and DAF-B had an Mr of 55,000. In a fluid phase assay, both forms accelerated the decay of the classical and the alternative C3 convertases with a specific activity similar to that of DAF. However, the decay-accelerating activity for the cell-bound C3 convertases was abolished, suggesting that neither could insert into E membranes and therefore that the glycolipid tail is altered. Analysis by molecular sieve high-pressure liquid chromatography demonstrated that DAF-A eluted with a Mr of approximately 450,000, similar to native DAF, and was thus in an aggregated form. In contrast, DAF-B eluted as a monomer with a Mr of approximately 60,000. DAF-A, but not DAF-B, bound to a hydrophobic column. To further characterize these two forms, surface-labeled human erythrocytes were incubated with phosphatidyl inositol-specific phospholipase C or papain. The phospholipase inefficiently released a form of DAF that was slightly larger (Mr of 64,000) than DAF-A. Papain efficiently released a 55,000 fragment that had the same Mr as DAF-B. To determine if DAF was cleaved by endogenous enzymes, surface-labeled erythrocytes were incubated with leukocytes. The kinetics of the leukocyte-induced degradation was similar to those observed with papain, and the released fragment aligned on seizing gels with the papain-derived fragment. We hypothesize that endogenous phospholipases and proteases cleave DAF to produce fragments similar to DAF-A and DAF-B, respectively.     

Intestinal trefoil factor induces decay-accelerating factor expression and enhances the protective activities against complement activation in intestinal epithelial cells

Mucosal damage induces a massive influx of serum complement components into the lumen. The epithelium produces a number of factors that can potentially ameliorate injury including intestinal trefoil factor (ITF), a small protease-resistant peptide produced and secreted onto the mucosal surface by goblet cells, and decay-accelerating factor (DAF), a protein produced by columnar epithelium which protects the host tissue from autologous complement injury. However, coordination of these intrinsic defensive products has not been delineated. DAF protein and mRNA expression were evaluated by immunoblotting and Northern blotting, respectively. NF-kappaB-DNA binding activity and DAF promoter activity were assessed by an electrophoretic gel mobility shift assay and a reporter gene luciferase assay, respectively. ITF induced a dose- and time-dependent increase in DAF protein and mRNA expression in human (HT-29 and T84) and rat (IEC-6) intestinal epithelial cells. In differentiated T84 cells grown on cell culture inserts, basolateral stimulation with ITF strongly enhanced DAF expression, but apical stimulation had no effects. The C3 deposition induced by complement activation was significantly blocked by the treatment with ITF. In HT-29 cells, ITF increased the stability of DAF mRNA. ITF also enhanced the promoter activity of the DAF gene via NF-kappaB motif and induced activation of NF-kappaB-DNA binding activity. ITF promotes protection of epithelial cells from complement activation via up-regulation of DAF expression, contributing to a robust mucosal defense.     

Retrovirus-mediated over-expression of decay-accelerating factor rescues Crry-deficient erythrocytes from acute alternative pathway complement attack

Decay-accelerating factor (DAF) and complement receptor 1-related gene/protein y (Crry) are two membrane-bound complement regulators on murine erythrocytes that inhibit C3/C5 convertases. Previously, we found that Crry- but not DAF-deficient erythrocytes were susceptible to alternative pathway complement-mediated elimination in vivo. To determine whether it is a unique activity or a higher level expression of Crry makes it indispensable on murine erythrocytes, we over-expressed DAF on Crry-deficient (Crry(-/-)) erythrocytes by retroviral vector-mediated DAF gene transduction of bone marrow stem cells. DAF retrovirus-transduced erythrocytes expressed 846 +/- 127 DAF molecules/cell (DAF(high)) compared with 249 +/- 94 DAF molecules/cell (DAF(low)) and 774 +/- 135 Crry molecules/cell on control mouse erythrocytes. DAF(high)-Crry(-/-) erythrocytes were significantly more resistant than either DAF(low)-Crry(-/-), DAF(-/-) -Crry(+/+) or wild-type erythrocytes to classical pathway complement-mediated C3 deposition in vitro. Furthermore, increased DAF expression rescued Crry(-/-) erythrocytes from acute alternative pathway complement attack in vivo. Notably, long term monitoring revealed that DAF(high)-Crry(-/-) erythrocytes were still more susceptible than wild-type erythrocytes to complement-mediated elimination as they had a shorter half-life in complement-sufficient mice but survived equally well in complement-deficient mice. These results suggest that both a high level expression and a more potent anti-alternative pathway complement activity of Crry contributed to its indispensable role on murine erythrocytes. Additionally, they demonstrate the feasibility of using stem cell gene therapy to correct membrane complement regulator deficiency on blood cells in vivo.     

Structure of the gene for human complement protein decay accelerating factor.

Decay accelerating factor (DAF) is a glycophospholipid-anchored membrane protein that is part of the regulators of complement activation (RCA) gene family located on human chromosome 1, band q32. These proteins, beginning at their amino terminus, consist largely of multiple copies of an approximately 60 amino acid short consensus repeat (SCR). A DAF cDNA clone was used to identify overlapping bacteriophage genomic clones. The human DAF gene spans approximately 40 kb and consists of 11 exons. The length of these exons and introns varies considerably, with the exons ranging from 21 to 956 bp and the introns ranging from approximately 0.5 to 19.8 kb. SCR I, II, and IV are all encoded by single exons; however, SCR III is encoded by two separate exons, with the splice junction occurring after the second nucleotide of the codon for the glycine residue at position 34 of the consensus sequence. This feature has also been found in CR1, CR2, membrane cofactor protein, and murine factor H. Following the SCR in DAF is a 76 amino acid serine/threonine-rich domain encoded on three separate exons. Exon 10 encodes the Alu family sequence that has been found as an insert in a minor class of DAF cDNA, thus indicating that this mRNA arises by standard alternative splicing. The last DAF exon, which comes after the largest intron of 19.8 kb, encodes the hydrophobic carboxy terminus and the 3'UT region. The nature of the signal that directs posttranslational attachment of a glycophospholipid anchor to DAF is not known, but that signal is apparently spread over three exons and greater than 20 kb. An analysis of the DAF gene provides additional evidence for the common evolutionary heritage of the RCA gene family. The exon/intron structure of this gene will facilitate experiments aimed at understanding the functions of the various domains of DAF.     

Identification of complement regulatory domains in vaccinia virus complement control protein

Vaccinia virus encodes a homolog of the human complement regulators named vaccinia virus complement control protein (VCP). It is composed of four contiguous complement control protein (CCP) domains. Previously, VCP has been shown to bind to C3b and C4b and to inactivate the classical and alternative pathway C3 convertases by accelerating the decay of the classical pathway C3 convertase and (to a limited extent) the alternative pathway C3 convertase, as well as by supporting the factor I-mediated inactivation of C3b and C4b (the subunits of C3 convertases). In this study, we have mapped the CCP domains of VCP important for its cofactor activities, decay-accelerating activities, and binding to the target proteins by utilizing a series of deletion mutants. Our data indicate the following. (i) CCPs 1 to 3 are essential for cofactor activity for C3b and C4b; however, CCP 4 also contributes to the optimal activity. (ii) CCPs 1 to 2 are enough to mediate the classical pathway decay-accelerating activity but show very minimal activity, and all the four CCPs are necessary for its efficient activity. (iii) CCPs 2 to 4 mediate the alternative pathway decay-accelerating activity. (iv) CCPs 1 to 3 are required for binding to C3b and C4b, but the presence of CCP 4 enhances the affinity for both the target proteins. These results together demonstrate that the entire length of the protein is required for VCP's various functional activities and suggests why the four-domain structure of viral CCP is conserved in poxviruses.     

Biosynthesis of the first component of complement by human fibroblasts

1. Haemolytic activity corresponding to that of the first component of complement (C1) was synthesized and secreted by all nine human fibroblast cell lines examined. No activity was found in the culture media of a variety of other human cell lines. 2. The component-C1 haemolytic activity secreted by the fibroblast lines behaved in an identical manner, in most respects, with that of the component-C1 haemolytic activity of human serum. The component-C1 haemolytic activity secreted by fibroblasts, however, was less susceptible to inhibition by rabbit fragment F(ab′)₂ anti-(human subcomponent C1q) than was the component-C1 haemolytic activity of human serum. 3. Biosynthesis of fibroblast component-C1 haemolytic activity was inhibited by the presence of cycloheximide and regained on its removal. 4. Incorporation of radioactivity into proteins secreted by the fibroblasts and release of component-C1 haemolytic activity by the fibroblasts both increased in a linear manner until several days after the cultures had reached a state of confluent growth. 5. Radioactivity was incorporated into subcomponents C1q, C1r and C1s, as judged by the formation of specific immunoprecipitates and by absorption with immune aggregates. 6. The immunoprecipitates formed by using antisera against subcomponents C1r and C1s were run on polyacrylamide gels in sodium dodecyl sulphate, and this provided convincing physiochemical evidence for the biosynthesis of these subcomponents de novo. 7. The results obtained with immunoprecipitates formed by using anti-(subcomponent C1q) suggest that subcomponent C1q may be synthesized and secreted by fibroblast cell lines in vitro, in a form with a higher molecular weight than that of subcomponent C1q which is isolated by conventional techniques of protein fractionation from fresh serum.     

Synthesis and regulation of complement protein factor H in human skin fibroblasts

The alternative pathway of C activation is Ag-independent and forms a first line of defense against infection before immune response. The C3 convertase, C3bBb, formed during activation of the alternative pathway is tightly regulated, with destabilization produced by factor H. Using metabolic labeling with [35S]methionine, immunoprecipitation, and SDS-PAGE, we demonstrated that human skin fibroblasts synthesized and secreted factor H protein. Two forms of the protein were identified, the approximately 160-kDa form seen more prominently in serum and a 45-kDa form that has also been identified in serum. The cells contained two forms of factor H mRNA, 4.4 and 1.8 kb. IFN-gamma increased factor H protein synthesis and mRNA content. No effect was observed with LPS. Neither HepG2 cells or human peripheral blood monocytes synthesized factor H protein or contained factor H mRNA.     

Human complement factor I glycosylation: structural and functional characterisation of the N-linked oligosaccharides

Factor I (fI) is a key serine protease that modulates the complement cascade by regulating the levels of C3 convertases. Human fI circulates in plasma as a heavily N-glycosylated (25-27% w/w) heterodimer composed of two disulphide linked chains, each carrying three N-linked oligosaccharide chains. It had been suggested that the oligosaccharides may have both structural and functional roles in the interactions with the natural substrate and the cofactor during a catalysis. The N-linked glycans of each fI chain were characterised in detail and the analysis revealed a similar composition of the glycan pools with both chains heavily sialylated. Disialylated structures were in excess over monosialylated ones: 55% over 40% for the heavy chain and 62% over 35% for the light chain. The dominant type of glycan identified on both chains was A(2)G(2)S(2), a biantennary structure with chains terminating in sialic acid linked to galactose. The glycan characterisation facilitated a strategy for the partial deglycosylation of the enzyme. Assessment of the proteolytic activities of the native and partially deglycosylated forms of fI showed that both forms of the enzyme have very similar proteolytic activities against C3(NH(3)) indicating that the charged glycans of fI do not influence the fI-cofactor-substrate interactions.     

The meningococcal vaccine candidate GNA1870 binds the complement regulatory protein factor H and enhances serum resistance

Neisseria meningitidis binds factor H (fH), a key regulator of the alternative complement pathway. A approximately 29 kD fH-binding protein expressed in the meningococcal outer membrane was identified by mass spectrometry as GNA1870, a lipoprotein currently under evaluation as a broad-spectrum meningococcal vaccine candidate. GNA1870 was confirmed as the fH ligand on intact bacteria by 1) abrogation of fH binding upon deleting GNA1870, and 2) blocking fH binding by anti-GNA1870 mAbs. fH bound to whole bacteria and purified rGNA1870 representing each of the three variant GNA1870 families. We showed that the amount of fH binding correlated with the level of bacterial GNA1870 expression. High levels of variant 1 GNA1870 expression (either by allelic replacement of gna1870 or by plasmid-driven high-level expression) in strains that otherwise were low-level GNA1870 expressers (and bound low amounts of fH by flow cytometry) restored high levels of fH binding. Diminished fH binding to the GNA1870 deletion mutants was accompanied by enhanced C3 binding and increased killing of the mutants. Conversely, high levels of GNA1870 expression and fH binding enhanced serum resistance. Our findings support the hypothesis that inhibiting the binding of a complement down-regulator protein to the neisserial surface by specific Ab may enhance intrinsic bactericidal activity of the Ab, resulting in two distinct mechanisms of Ab-mediated vaccine efficacy. These data provide further support for inclusion of this molecule in a meningococcal vaccine. To reflect the critical function of this molecule, we suggest calling it fH-binding protein.