Regulation of proteolytic activity of complement factor I by pH: C3b/C4b receptor (CR1) and membrane cofactor protein (MCP) have different pH optima for factor I-mediated cleavage of C3b

C3b/C4b receptor (CR1) and membrane cofactor protein (MCP) are integral membrane glycoproteins with factor I-dependent cofactor activity. They bind to C3b, allowing factor I to cleave C3b at two sites (first and second cleavage), which results in the generation of C3bi, a hemolytically inactive form which is a ligand for complement receptor type three (CR3). C3bi is further degraded by factor I and CR1 (third cleavage) to C3dg (a ligand for complement receptor type two, CR2) and C3c. Using two different substrates, fluid-phase C3b and cell-bound C3b, the cleavage of C3b by MCP and factor I was compared to that by CR1 and factor I under various conditions. The optimal pH for the first and second cleavage of either substrate was 6.0 for MCP and 7.5 for CR1. The third cleavage was mediated only by CR1 and factor I, the optimal pH being 8.0. Low ionic conditions enhanced the C3b binding and cofactor activity of both CR1 and MCP. The efficiency of binding C3b to CR1 or MCP was maximal at pH 6.2. The isoelectric point (pI) of MCP was acidic (approximately 4.0), while that of CR1 was 6.8. Therefore, compared to CR1, MCP possesses distinct functional profiles relative to C3b-binding and factor I-cofactor activity.     

Disease-associated loss of erythrocyte complement receptors (CR1, C3b receptors) in patients with systemic lupus erythematosus and other diseases involving autoantibodies and/or complement activation

Although surface membrane density of complement receptor type one (CR1) on erythrocytes (E) is probably an inherited trait among normal individuals, recent evidence from our laboratories suggests that the reduced number of CR1 per E observed in patients with systemic lupus erythematosus (SLE) results from acquired as well as genetic factors. In the present investigation, the number of CR1 per E was quantitated with 125I-monoclonal anti-CR1 and was found to vary inversely with disease activity in patients with SLE who were followed serially for as long as 14 mo. Although evidence for E surface-bound immune complexes or fixed C3b/iC3b was not obtained, periods of disease activity and low amounts of CR1 per E correlated with the presence of 100 to 800 molecules per E of fixed C3dg fragments (less than 100 C3dg per E in normal subjects). Reduced CR1 and excess fixed C3dg on E also were observed in patients with other disorders associated with complement activation, including chronic cold agglutinin disease, autoimmune hemolytic anemia, paroxysmal nocturnal hemoglobinuria (PNH), Sj?gren's syndrome, and mycoplasma pneumonia. A significant negative correlation (r = -0.498) between CR1/E and fixed C3dg/E was demonstrable in 255 individual assays evaluated by regression analysis. CR1 decreased and fixed C3dg increased during active disease; the converse was obtained during remission. In patients with active SLE, both serum complement activity and E CR1 decreased, whereas fixed C3dg fragments increased. By piecewise linear regression analysis, the appearance of 100 to 400 C3dg molecules on patients' E corresponded to a 27 to 60%, reduction in the number of CR1 per E (p less than 0.0002), confirming that fixation of C3 to E was correlated with a loss of CR1. In patients with PNH, low values for CR1 were observed on moderately complement-sensitive PNH type II E in association with increased fixed C3 fragments; however, the markedly complement-sensitive PNH type III E had essentially normal amounts of CR1 and bore little fixed C3. The addition of soluble DNA/anti-DNA immune complexes to normal blood generated levels of fixed C3dg fragments on E comparable to those observed on E from patients with SLE. Kinetic experiments indicated that C3b was fixed to E during the process of immune complex binding and release from E CR1, and that this fixed C3b was subsequently degraded rapidly to fixed iC3b and more slowly to fixed C3dg without the loss of CR1 that occurs in vivo.(ABSTRACT TRUNCATED AT 400 WORDS)     

Polymorphism of the C3b/C4b receptor (CR1): characterization of a fourth allele

The receptor for C3b/C4b (C3bR or CR1) has an unusual polymorphism in which three codominant alleles determine variants with a large difference in Mr (160,000, 190,000, or 220,000). We found an individual who has, in addition to the common 190,000 Mr molecule, a C3bR whose Mr is 250,000. In this proband and in some members of his family, this novel heterozygous phenotype can be isolated from 125I surface-labeled cells by iC3 or iC4 affinity chromatography or by immunoprecipitation with the use of polyclonal or monoclonal anti-C3bR. Relative to the 190,000 Mr C3bR, E from individuals in this family have 20 to 30% of the total receptor counts in the 250,000 Mr C3bR. However, on C3bR-bearing leukocytes there is a much larger amount of the 250,000 Mr C3bR (approximately 60%) relative to the 190,000 Mr C3bR. Similar to the other three C3bR variants, the Mr is 5,000 greater on polymorphonuclear cells than on E, and treatment of this new C3bR with endoglycosidase F decreases its Mr by approximately 10,000. Therefore, because this variant is inherited and has structural and functional similarities to the other three C3bR, we conclude that this 250,000 Mr CR1 probably represents a fourth allele.     

Neutrophils express a receptor for iC3b, C3dg, and C3d that is distinct from CR1, CR2, and CR3

In the present study we examined human neutrophils for the expression of a receptor capable of binding C3dg and defined the relationship of this receptor to those that have been previously described, namely CR1, CR2, and CR3. C3dg was isolated from serum depleted of plasminogen, supplemented with 20 mM Mg++, and incubated at 37 degrees C for 6 to 8 days. The purified protein was homogeneous when analyzed by polyacrylamide gel electrophoresis and exhibited an apparent m.w. of 41,000. C3dg was polymerized by treatment with dimethyl suberimidate, and the dimer was isolated by gel filtration. Binding of both monomeric and dimeric 125I-labeled C3dg to neutrophils was saturable, and the latter ligand bound to an average of 12,400 sites/cell among nine normal individuals. At 4 degrees C, bound monomeric C3dg dissociated from neutrophils with an average t1/2 of 30 min, whereas dimeric C3dg dissociated with a t1/2 in excess of 120 min. Specific binding of multimeric C3dg was cation independent and was competitively inhibited by molar concentrations of iC3b and C3d that were equivalent to the inhibitory concentrations of unlabeled C3dg; C3b was less able to compete with C3dg for binding to these sites. The capacity of this neutrophil receptor to bind iC3b, C3dg, and C3d suggested its possible identity as CR2 or CR3. However, no specific binding to neutrophils of 125I-labeled HB-5 monoclonal anti-CR2 was detected. Furthermore, uptake of 125I-labeled C3dg was not inhibited by saturating concentrations of rabbit anti-CR1, anti-Mac-1, or OKM10. Thus, a receptor resides on neutrophils that binds the C3d region of iC3b and C3dg and is distinct from CR1, CR2, and CR3.     

Characterization of a soluble form of the C3b/C4b receptor (CR1) in human plasma

A radioimmunoassay with the use of soluble 125I-Fab monoclonal anti-CR1 and rabbit IgG anti-CR1 bound to Staphylococcus aureus particles was employed to detect and quantitate CR1 antigen in human plasma. Among 16 normal individuals the concentration of soluble CR1 in plasma ranged from 13 to 81 ng/ml, and a similar range of concentration was found in plasma from 15 patients having systemic lupus erythematosus (SLE). The amount of plasma CR1 in normal donors, but not in SLE patients, significantly correlated with the number of CR1 sites on erythrocytes (r = 0.90, p less than 0.001), and was 7.1% of the amount of receptor that was present on erythrocytes in blood. The concentration of soluble CR1 was not diminished by ultracentrifugation or ultrafiltration of plasma, was not affected by various modes of anti-coagulation or even by clotting of blood, and did not change during incubation of blood at 4 degrees C for up to 4 hr. On sucrose density gradient ultracentrifugation of plasma the CR1 was distributed as a broad peak that overlapped the plasma protein profile. The Mr of plasma CR1 was identical to that of erythrocyte CR1 when assessed by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and immunoblotting. In addition, the plasma form of CR1 exhibited the same structural phenotype as did receptor from erythrocytes of the same individual. CR1 antigen purified from plasma was as active as CR1 from erythrocytes in promoting the cleavage by factor I of C3b to iC3b, C3c, and C3dg. Therefore, a functionally and structurally intact form of soluble CR1 resides in plasma.     

Loss of complement receptor type 1 (CR1) on ageing of erythrocytes. Studies of proteolytic release of the receptor.

Complement receptor type 1 (CR1) is a glycoprotein of Mr about 250 000 present on erythrocytes and other cell types. CR1 acts as a cofactor in the factor I-mediated breakdown of complement fragment C3b to form iC3b. Using an assay of cofactor activity, a wide variation in mean CR1 levels between erythrocytes from individual donors is observed. CR1 levels also decrease on ageing of erythrocytes in vivo, and again the rate of loss is widely variable between individuals. However, variable loss of CR1 during ageing of erythrocytes is likely to make only a minor contribution to the observed variation in mean CR1 levels. CR1 is very sensitive to proteolysis, and random proteolytic removal of CR1 from erythrocytes is likely to be an important factor in loss of CR1 on ageing of red cells in vivo. In vitro, mild trypsin treatment, plasmin or thrombin digestion of erythrocytes results in the loss of the factor I cofactor activity from the cell surface, and appearance of this activity in the supernatant. We conclude that an active fragment of CR1 is released from the cell surface on proteolysis. Subsequent prolonged trypsin treatment destroys most of the activity of this fragment. Proteolytic removal of CR1 from red cells may account not only for loss on ageing of cells, but also for the acquired CR1 deficiencies observed by others in systemic lupus erythematosus.     

Functional properties of membrane cofactor protein of complement.

Membrane cofactor protein (MCP or gp45-70) of the complement system is a cofactor for factor I-mediated cleavage of fluid-phase C3b and C3b-like C3, which opens the thioester bond. In the present study the activity of MCP was further characterized. Unexpectedly, in the absence of factor I, MCP stabilized the alternative- and, to a lesser extent, the classical-pathway cell-bound C3 convertases and thereby enhanced C3b deposition. Soluble MCP, if added exogenously, hardly functioned as cofactor for the cleavage of erythrocyte-bound C3b to iC3b; i.e. its activity, compared with the cofactor activity of factor H, was inefficient, since less than 10% of the bound C3b was MCP-sensitive. Further, exogenously added soluble MCP was also a weak cofactor for the cleavage of C3b bound to zymosan. Likewise, factor I, in the presence of cells bearing MCP, cleaved fluid-phase C3b inefficiently. These results imply that MCP has very little extrinsic cofactor activity for factor I. In contrast, exogenously added MCP and factor I mediated efficient cleavage of erythrocyte-bound C3b if the concentration of Nonidet P40 was sufficient to solubilize the cells. Interestingly, soluble MCP and factor I degraded C3b attached to certain solubilized acceptor membrane molecules more readily than others. The cleavage reaction of fluid-phase and cell-bound C3b by soluble MCP and factor I produced iC3b, but no C3c and C3dg. These and prior data indicate that soluble MCP has potent cofactor activity for fluid-phase C3b or C3b bound to solubilized molecules, but acts inefficiently towards C3b on other cells. This functional profile is unique for a C3b/C4b binding protein and, taken together with its wide tissue distribution, suggests an important role for MCP in the regulation of the complement system.     

Physiologic inactivation of fluid phase C3b: isolation and structural analysis of C3c, C3d,g (alpha 2D), and C3g

The fragments that result from the inactivation of C3b have not been completely characterized. Initial inactivation is catalyzed by the protease factor I, which, in the presence of its cofactor (factor H), cleaves two peptide bonds in the alpha'-chain of C3b. This results in the release of a small peptide (C3f, Mr 3000) from iC3b, which consists of the C3 beta chain covalently bonded to two alpha'-chain-derived peptides (Mr 68,000 and Mr 43,000). Surface-bound iC3b is cleaved at a third site by factor I to produce C3c and C3d,g (or alpha 2D). The factor I cofactor for this cleavage is the C3b receptor that is present on erythrocyte and leukocyte membranes. This report describes the isolation and initial structural characterization of C3c and C3d,g generated in whole blood after complement activation with cobra venom factor. These fragments were compared with the C3 fragments isolated from the serum and plasma of a patient with complement activation in vivo. The fragments were isolated with two solid phase monoclonal antibodies, one of which recognizes a determinant on C3g (clone 9) and one of which recognizes a determinant on C3c (clone 4). C3c isolated from normal blood showed three polypeptides that had apparent m.w. of 75,000, 43,000, and 27,000. The C3d,g consisted of a single polypeptide chain with a m.w. of 40,000. Amino terminal sequence analysis showed that the Mr 27,000 peptide from C3c is derived from the amino terminal portion of the alpha'-chain of C3b, whereas the Mr 43,000 peptide is derived from the carboxy terminus of the same chain. Amino terminal sequence analysis showed also that C3g is derived from the amino terminus of C3d,g. The C3 fragments isolated from a patient with partial lipodystrophy, nephritic factor activity, low serum C3 levels, and circulating C3 cleavage products showed a more complicated pattern on SDS-PAGE. The fragment isolated with clone 9 had an apparent m.w. of 40,000, identical to C3d,g generated in vitro, and it had the same amino terminal sequence as C3d,g generated in vitro. The eluate from insolubilized clone 4, however, showed prominent bands with Mr of 75,000, 56,000, 43,000, and 27,000, together with a triple-banded pattern at 68,000 and a minor band at 80,000. This eluate thus appears to contain C3c, and iC3b or an iC3b-like product. The origin of the Mr 56,000 and Mr 80,000 peptides have not yet been determined. These studies, with previous data, definitively order the C3c and C3d,g peptides in the alpha-chain of C3.(ABSTRACT TRUNCATED AT 400 WORDS)     

Analysis of C3-receptor activity on human B-lymphocytes and isolation of the complement receptor type 2 (CR2).

The rosetting of defined C3-fragment-coated sheep erythrocytes to B-cell-enriched tonsil lymphocytes was measured. The rosetting lymphocytes were homogeneous with respect to expression of C3b, iC3b and C3d receptors. Isolation of receptors for C3 fragments from surface-radioiodinated lymphocytes by affinity chromatography on immobilized C3u, iC3b and C3d,g produced two proteins with partially overlapping specificities. A protein of 240 000 Mr, recognized by the monoclonal antibody To5 and identified as CR1 (complement receptor type 1), had affinity for C3u and iC3b. A protein of 145 000 Mr, recognized by the monoclonal antibody B2, had affinity for all three C3 fragments. Inhibition of rosetting by antibodies to these proteins indicates that CR1 is responsible for C3b-mediated rosetting and that the 145000-Mr receptor (CR2) is responsible for C3d-mediated rosetting. Partial inhibition by both anti-CR1 and anti-CR2 antibodies of iC3b-mediated rosetting indicates that both receptors are involved in iC3b-mediated rosetting. No other protein appears to be involved in tonsil B-cell rosetting to C3-fragment-coated cells. A method for preparing CR2 from tonsil lymphocytes based on affinity chromatography on C3d,g-Sepharose has been developed. Forty tonsil pairs (2 X 10(10) B-cells) yield about 40 micrograms of pure protein equivalent to a purification of 6500-fold from a detergent extract.     

Characterization of CR1- and membrane cofactor protein-like proteins of two primates

We have identified and characterized C3b binding proteins of two primates, orangutan (Pongo pygmaeus) and gorilla (Gorilla gorilla). Detergent solubilized 125I surface-labeled E and PBMC were subjected to affinity chromatography with homologous or human iC3/C3b. These ligands bound a 225,000 single chain protein from orangutan E and PBMC and a 220,000 protein from gorilla E. Proteins of the same Mr were immunoprecipitated by a rabbit polyclonal and two murine mAb to the human CR1 (CD35). The C3b binding protein of gorilla E aligned with that of the common human CR1 polymorphic size variant. Human or orangutan iC3 was also a ligand for a surface-labeled protein doublet of 59,000 and 65,000 from orangutan E. The doublet pattern and mol wts are similar to membrane cofactor protein (or CD46). Further, this doublet was immunoprecipitated by a mAb to human MCP. The MCP-like protein doublet was not isolated from gorilla or human E. Decay accelerating factor (DAF) of orangutan E was also identified and was structurally and antigenically distinct from the MCP-like protein. Orangutan or gorilla E preparations were a cofactor for the cleavage of human iC3 by human factor I and produced the same cleavage fragments as human CR1. Cofactor activity of orangutan E was partially inhibited by preclearance of CR1 and more completely inhibited by preclearance of MCP. Cofactor activity of gorilla E was inhibited by coincubation with a monoclonal antibody to human CR1. These data indicate that the orangutan and gorilla high m.w. proteins are equivalent to human CR1. The orangutan E membrane protein doublet with m.w. of 59,000 and 65,000 possesses biochemical, antigenic, and functional properties of human membrane cofactor protein.     

Factor I-dependent inactivation of human complement C4b of the classical pathway by C3b/C4b receptor (CR1, CD35) and membrane cofactor protein (MCP, CD46).

Proteolytic inactivation of C4b is a crucial step for regulation of the classical complement pathway. A plasma protease factor I and membrane cofactors, C3b/C4b receptor (CR1) and membrane cofactor protein (MCP), participate in the regulation of cell-bound C4b although the physiological potency of these cofactors remains unknown. We have examined the optimal conditions of the factor I-mediated C4b regulatory system using purified cofactors. CR1 being a cofactor at a cofactor/C4b ratio less than 0.1 (w/w), fluid phase C4b, and methylamine-treated C4 (C4ma) were degraded by factor I into C4bi: minimal Cd4 was generated in the fluid phase. Liposome-bound C4b (LAC4b), on the other hand, was degraded into C4c and C4d. CR1 showed two optimal pHs (6.0 and 7.5) for fluid phase C4b, but one (6.0) for LAC4b, and in both cases low conductivity conditions enhanced the C4bi generation. CR1 cofactor activity was barely influenced by the NP-40 concentration. On the other hand, MCP degraded C4b and C4ma, as a factor I-cofactor, more efficiently into C4c and C4d. Though MCP cofactor activity, like that of CR1, was enhanced under low conductivity conditions, it has only one optimal pH, 6.0, in both fluid and solid phases. Furthermore, as in the case of C3b cleavage, a sufficient NP-40 concentration to solubilize membrane was needed for MCP to express full cofactor activity for C4b, in contrast to CR1. MCP was less potent for C4b inactivation than for C3b inactivation, while CR1 acted as a slightly more effective cofactor for C4b cleavage than for C3b cleavage.(ABSTRACT TRUNCATED AT 250 WORDS)     

Factor I co-factor activity of CR1 overcomes the protective effect of IgG on covalently bound C3b residues

We have shown previously that C3b resides in a protected site when it is covalently bound to IgG (C3b-IgG). Such C3b displays a reduced affinity for factor H, with consequent enhanced survival in the presence of factors H and I and increased capacity for promoting alternative pathway consumption of C3. Because erythrocyte CR1 may be a major co-factor for factor I-mediated inactivation of immune complex-borne C3b in blood, we have examined the effect of covalently bound IgG on the C3b-CR1 interaction. Binding of monomeric C3b and C3b-IgG to human erythrocyte CR1 demonstrates identical ionic strength dependence for both species. Identical numbers of binding sites with indistinguishable affinities are detected by both ligands. Cleavage of the alpha'-chain of C3b and the alpha'-heavy chain of C3b-IgG proceeds at the same rate when erythrocyte CR1 serves as co-factor for factor I. Unlike factor H, CR1 supports a second cleavage of fluid-phase iC3b alpha'1 chain (free or bound to IgG) that generates C3c and a 33,000 m.w. fragment, which bears antigenic markers characteristic of C3g. Inactivation of C3b and C3b-IgG by CR1 and factor I also occurs at physiologic ionic strength, but proceeds very slowly relative to rates attainable with sub-physiologic inputs of factor H. CR1 does not recognize IgG-bound C3b as being in a protected site but, because of low binding affinity at physiologic ionic strength, is probably highly dependent on multivalent ligand-receptor interactions to efficiently exert its co-factor functions. Thus, inactivation of C3b-IgG heterodimers or small immune complexes bearing limited numbers of C3b residues may remain largely factor H-dependent in vivo, with resultant enhanced C3b survival.     

Characterization of the human glomerular C3 receptor as the C3b/C4b complement type one (CR1) receptor

The functional and immunochemical characteristics of the human glomerular C3 receptor were investigated by adherence of sheep erythrocytes (Es) coated with defined C3 fragments and by using polyclonal and/or monoclonal antibodies directed against epitopes expressed on complement receptors CR1, CR2, and CR3. C3b-bearing Es (EsC3b) strongly adhered to glomeruli in frozen kidney sections in a reaction that was selectively inhibited by F(ab')2 anti-CR1 antibodies. There was no adherence of EsC3dg, EsC3d, and EsC3bi in the presence or absence of Ca++ and Mg++ under physiologic buffer conditions. The weak glomerular binding of EsC3bi, which was observed in half-isotonic buffer was selectively suppressed by anti-CR1 antibodies. By indirect immunofluorescence, anti-CR1 antibodies stained all podocytes in glomeruli, whereas no staining of kidney sections was seen with OKM1 and anti-Mol antibodies directed against the alpha-chain of CR3 and with anti-CR2 antibodies anti-B2 and BL13. Solubilization of membrane glycoproteins from freshly isolated glomeruli from three human kidneys, in the presence of 0.1% Nonidet P-40, yielded a material that bound to lentil lectin Sepharose and could accelerate the decay of preformed cell-bound amplification C3 convertase sites in a reaction that was inhibited by anti-CR1 antibodies. The material containing CR1 activity was labeled with 125I, immunoprecipitated with anti-CR1, and analyzed by SDS-PAGE and autoradiography. Anti-CR1 immunoprecipitated a form of CR1 of Mr 205,000 in solubilized glomeruli from three donors, and an additional form of Mr 160,000 in glomeruli from two of the donors. Immunoprecipitation of CR1 from surface-labeled erythrocytes from these individuals demonstrated them to be homozygous for the 205,000 Mr form of the receptor. Whether the 160,000 band represents in vitro or in vivo proteolytic cleavage of CR1, or cell specific-modulation of gene expression of glomerular CR1, remains unclear. Thus, CR1 is the only type of C3 receptor expressed in the human kidney. Glomerular CR1 shares the functional antigenic and biochemical properties of the C3b/C4b CR1 receptor of peripheral blood cells.     

The embryotrophic activity of oviductal cell-derived complement C3b and iC3b, a novel function of complement protein in reproduction

The oviduct-derived embryotrophic factor, ETF-3, enhances the development of trophectoderm and the hatching process of treated embryos. Monoclonal anti-ETF-3 antibody that abolishes the embryotrophic activity of ETF-3 recognized a 115-kDa protein from the conditioned medium of immortalized human oviductal cells. Mass spectrometry analysis showed that the protein was complement C3. Western blot analysis using an antibody against C3 confirmed the cross-reactivities between anti-C3 antibody with ETF-3 and anti-ETF-3 antibody with C3 and its derivatives, C3b and iC3b. Both derivatives, but not C3, were embryotrophic. iC3b was most efficient in enhancing the development of blastocysts with larger size and higher hatching rate, consistent with the previous reported embryotrophic activity of ETF-3. Embryos treated with iC3b contained iC3b immunoreactivity. The oviductal epithelium produced C3 as evidenced by the presence of C3 immunoreactivity and mRNA in the human oviduct and cultured oviductal cells. Cyclical changes in the expression of C3 immunoreactivity and mRNA were also found in the mouse oviduct with the highest expression at the estrus stage. Molecules involving in the conversion of C3b to iC3b and binding of iC3b were present in the human oviduct (factor I) and mouse preimplantation embryo (Crry and CR3), respectively. In conclusion, the present data showed that the oviduct produced C3/C3b, which was converted to iC3b to stimulate embryo development.     

Kinetic analysis of the interactions between vaccinia virus complement control protein and human complement proteins C3b and C4b

The vaccinia virus complement control protein (VCP) is an immune evasion protein of vaccinia virus. Previously, VCP has been shown to bind and support inactivation of host complement proteins C3b and C4b and to protect the vaccinia virions from antibody-dependent complement-enhanced neutralization. However, the molecular mechanisms involved in the interaction of VCP with its target proteins C3b and C4b have not yet been elucidated. We have utilized surface plasmon resonance technology to study the interaction of VCP with C3b and C4b. We measured the kinetics of binding of the viral protein to its target proteins and compared it with human complement regulators factor H and sCR1, assessed the influence of immobilization of ligand on the binding kinetics, examined the effect of ionic contacts on these interactions, and sublocalized the binding site on C3b and C4b. Our results indicate that (i) the orientation of the ligand is important for accurate determination of the binding constants, as well as the mechanism of binding; (ii) in contrast to factor H and sCR1, the binding of VCP to C3b and C4b follows a simple 1:1 binding model and does not involve multiple-site interactions as predicted earlier; (iii) VCP has a 4.6-fold higher affinity for C4b than that for C3b, which is also reflected in its factor I cofactor activity; (iv) ionic interactions are important for VCP-C3b and VCP-C4b complex formation; (v) VCP does not bind simultaneously to C3b and C4b; and (vi) the binding site of VCP on C3b and C4b is located in the C3dg and C4c regions, respectively.     

Functional activity of the complement regulator encoded by Kaposi's sarcoma-associated herpesvirus

Kaposi's sarcoma-associated herpesvirus (KSHV) is closely associated with Kaposi's sarcoma and certain B-cell lymphomas. The fourth open reading frame of the KSHV genome encodes a protein (KSHV complement control protein (KCP, previously termed ORF4)) predicted to have complement-regulating activity. Here, we show that soluble KCP strongly enhanced the decay of classical C3-convertase but not the alternative pathway C3-convertase, when compared with the host complement regulators: factor H, C4b-binding protein, and decay-accelerating factor. The equilibrium affinity constant (KD) of KCP for C3b and C4b was determined by surface plasmon resonance analysis to range between 0.47-10 microM and 0.025-6.1 microM, respectively, depending on NaCl concentration and cation presence. Soluble and cell-associated KCP acted as a cofactor for factor I (FI)-mediated cleavage of both C4b and C3b and induced the cleavage products C4d and iC3b, respectively. In the presence of KCP, FI further cleaved iC3b to C3d, which has never been described before as complement receptor 1 only mediates the production of C3dg by FI. KCP would enhance virus pathogenesis through evading complement attack, opsonization, and anaphylaxis but may also aid in targeting KSHV to one of its host reservoirs since C3d is a ligand for complement receptor 2 on B-cells.     

Role of membrane cofactor protein (CD46) in regulation of C4b and C3b deposited on cells

C4b and C3b deposited on host cells undergo limited proteolytic cleavage by regulatory proteins. Membrane cofactor protein (MCP; CD46), factor H, and C4b binding protein mediate this reaction, known as cofactor activity, that also requires the plasma serine protease factor I. To explore the roles of the fluid phase regulators vs those expressed on host cells, a model system was used examining complement fragments deposited on cells transfected with human MCP as assessed by FACS and Western blotting. Following incubation with Ab and complement on MCP(+) cells, C4b was progressively cleaved over the first hour to C4d and C4c. There was no detectable cleavage of C4b on MCP(-) cells, indicating that MCP (and not C4BP in the serum) primarily mediates this cofactor activity. C3b deposition was not blocked on MCP(+) cells because classical pathway activation occurred before substantial C4b cleavage. Cleavage, though, of deposited C3b was rapid (<5 min) and iC3b was the dominant fragment on MCP(-) and MCP(+) cells. Studies using a function-blocking mAb further established factor H as the responsible cofactor. If the level of Ab sensitization was reduced 8-fold or if Mg(2+)-EGTA was used to block the classical pathway, MCP efficiently inhibited C3b deposition mediated by the alternative pathway. Thus, for the classical pathway, MCP is the cofactor for C4b cleavage and factor H for C3b cleavage. However, if the alternative pathway mediates C3b deposition, then MCP's cofactor activity is sufficient to restrict complement activation.     

Factor I-mediated processing of complement fragments on HIV immune complexes targets HIV to CR2-expressing B cells and facilitates B cell-mediated transmission of opsonized HIV to T cells

Our study demonstrates that binding of complement-opsonized HIV to complement receptor type 1 on human erythrocytes (E) via C3b fragments is followed by a rapid normal human serum-mediated detachment of HIV from E. The release was dependent on the presence of factor I indicating a conversion of C3b fragments to iC3b and C3d on the viral surface. This in turn resulted in an efficient binding of opsonized HIV to CR2-expressing B cells, thus facilitating B cell-mediated transmission of HIV to T cells. These data provide a new dynamic view of complement opsonization of HIV, suggesting that association of virus with E might be a transient phenomenon and the factor I-mediated processing of C3b to iC3b and C3d on HIV targets the virus to complement receptor type 2-expressing cells. Thus, factor I in concert with CR1 on E and factor H in serum due to their cofactor activity are likely to be important contributors for the generation of C3d-opsonized infectious HIV reservoirs on follicular dendritic cells and/or B cells in HIV-infected individuals.     

Mutagenesis of the Arg-Gly-Asp triplet in human complement component C3 does not abolish binding of iC3b to the leukocyte integrin complement receptor type III (CR3, CD11b/CD18).

The leukocyte integrin complement receptor type III (CR3, CD11b/CD18) binds the C3 cleavage product iC3b. Many other integrins bind their ligands via an Arg-Gly-Asp (RGD) triplet. Both the RGD-containing C3 peptide 1390TRYRGDQDATMS1401 (pro-C3 numbering) and the RGD-like fibrinogen peptide GGAKQAGDV, which binds to the platelet integrin glycoprotein IIb-IIIa, were shown to inhibit the iC3b-CR3 interaction, suggesting that this binding is also RGD-mediated (Wright, S.D., Weitz, J.I., Huang, A. J., Levin, S.M., Silverstein, S.C., and Loike, J.D. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 7734-7738). However, unlike other integrin-ligand interactions, that of CR3 and iC3b is unaffected by the hexapeptide GRGDSP, and substitutions in the RGD triplet of C3 from other species appear to be tolerated. It was, therefore, proposed (Grossberger, D., Marcuz, A., du Pasquier, L., and Lambris, J.D. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 1323-1327) that the highly conserved DATMS portion of the inhibitory C3 peptide may have been responsible for its binding. To address these inconsistencies and directly assess the role of the 1390-1401 segment within the complete iC3b molecule in mediating binding to CR3, a human C3 cDNA was altered by site-directed mutagenesis and the expressed recombinant proteins were examined in a CR3-specific assay. Replacement of RGD by AAA did not abolish rosetting of the corresponding iC3b-coated erythrocytes to human CR3-bearing leukocytes. In addition, mutant iC3b molecules in which the positively charged R1391 (corresponding to K in the fibrinogen peptide) and the highly conserved 1397DATMS sequence were replaced by Q and NAAMA respectively, were still bound by CR3. We conclude that the iC3b-CR3 interaction is not mediated by the RGD triplet or its neighboring residues.     

Inhibition of factor I by diisopropylfluorophosphate. Evidence of conformational changes in factor I induced by C3b and additional studies on the specificity of factor I

The factor I-mediated cleavage of C3b, using factor H as a cofactor was completely inhibited by diisopropylfluorophosphate (DFP) when factor I and C3b were incubated with DFP before the addition of factor H. Inhibition, although to a lesser degree, was observed when factor H was present during DFP-exposure. No inhibition in factor I activity was seen when factor I and H were incubated with DFP either alone or together. It was also demonstrated that the 38-kDa subunit of factor I bound radiolabeled DFP when factor I and C3b together were exposed to DFP. These observations suggest that factor I interacts with C3b in a manner that exposes its catalytic site to DFP, an interaction that is independent of factor H. The inhibitory effect by DFP on factor I led us to further investigate the factor I cleavage products of iC3b, inasmuch as previous reports were ambiguous as to whether digestion occurs in the presence of DFP. Digestion of C3b bound to activated thiol Sepharose (ATS-C3b) in the presence of factor H at low pH and ionic strength and in serum by complement activation produced C3d,g-like fragments with apparent molecular mass of 41 and 43 kDa. These fragments were shown to have three different N-terminal and two different C-terminal ends. The major fragments had N-terminal sequences starting with Glu933, as shown by sequence determination. Traces of fragments extending beyond this point were also found, shown by Western blot analysis using a panel of mAb previously shown to bind to epitopes exposed within a region of C3 spanning residues 929 to 943, as well as a shorter fragment starting with Glu938. When digestion of C3b is carried out in the presence of DFP, the factor I level necessary for digestion is elevated and may explain how the first two cleavages producing iC3b but not the following giving C3d,g, can occur. The finding of several factor I cleavage sites in the C3d,g region of C3 demonstrates that factor I has a broad specificity, mainly for arginyl bonds. It has also been shown to digest a lysyl bond exposed in ATS-bound C3b.