Complement inhibition at the level of C3 or C5: mechanistic reasons for ongoing terminal pathway activity.

Blocking the terminal complement pathway with the C5 inhibitor eculizumab has revolutionized the clinical management of several complement-mediated diseases and has boosted the clinical development of new inhibitors. Data on the C3 inhibitor Compstatin and the C5 inhibitors eculizumab and Coversin reported here demonstrate that C3/C5 convertases function differently from prevailing concepts. Stoichiometric C3 inhibition failed to inhibit C5 activation and lytic activity during strong classical pathway activation, demonstrating a "C3 bypass" activation of C5. We show that, instead of C3b, surface-deposited C4b alone can also recruit and prime C5 for consecutive proteolytic activation. Surface-bound C3b and C4b possess similar affinities for C5. By demonstrating that the fluid phase convertase C3bBb is sufficient to cleave C5 as long as C5 is bound on C3b/C4b-decorated surfaces, we show that surface fixation is necessary only for the C3b/C4b opsonins that prime C5 but not for the catalytic convertase unit C3bBb. Of note, at very high C3b densities, we observed membrane attack complex formation in absence of C5-activating enzymes. This is explained by a conformational activation in which C5 adopts a C5b-like conformation when bound to densely C3b-opsonized surfaces. Stoichiometric C5 inhibitors failed to prevent conformational C5 activation, which explains the clinical phenomenon of residual C5 activity documented for different inhibitors of C5. The new insights into the mechanism of C3/C5 convertases provided here have important implications for the development and therapeutic use of complement inhibitors as well as the interpretation of former clinical and preclinical data.

Inhibition of CXCL10 release by monomeric C3bi and C4b.

Cellulose acetate (CA) beads are often used for leucocyte apheresis therapy against inflammatory bowel disease. In order to clarify the mechanism of the anti-inflammatory effects of CA, global analysis of the molecules generated in blood by the interaction with CA beads was performed in this study. An activated medium was collected from whole blood that had been preincubated with CA beads, and the effects of the CA-activated medium on leucocyte function were investigated. Fresh blood was stimulated with lipopolysaccharide (LPS) or interferon (IFN)-ß in the presence of the activated medium, and levels of chemokines and cytokines, including CXCL10 (IFN-inducible protein-10), and phosphorylated STAT1 (signal transducer and activator of transcription 1), which is known to be essential for CXCL10 production in leucocytes, were measured. IFN-ß- or LPS-induced CXCL10 production, expression of CXCL10 mRNA and phosphorylation of STAT1 were significantly reduced in the presence of the medium pretreated with CA beads compared with the control without the CA bead treatment. The factors inhibiting CXCL10 production were identified as the C3 and C4 fragments by mass spectrometry. The monomeric C3bi and C4b proteins were abundant in the medium pretreated with CA beads. Furthermore, purified C3bi and C4b were found to inhibit IFN-ß-induced CXCL10 production and STAT1 phosphorylation. Thus, STAT1-mediated CXCL10 production induced by stimulation with LPS or IFN was potently inhibited by monomeric C3bi and C4b generated by the interaction of blood with CA beads. These mechanisms mediated by monomeric C3bi and C4b may be involved in the anti-inflammatory effects of CA.

C4d deposition is associated with chronic allograft nephropathy in rats and could be influenced by immunosuppressants.

AIMS: Deposition of C4d in peritubular capillaries (PTC) has been considered to be a marker of humoral immunity in renal transplant. This study is to investigate C4d deposition in rat renal allografts undergoing CAN and the effects of immunosuppressants on it. METHODS: Fisher 344 rat renal grafts were orthotopically transplanted into Lewis rats following the procedure of Kamada with our modification. All the recipients were given CsA 10 mg/kg(-1).d(-1) x 10 d and then divided into 5 groups (each n = 9); (1) Vehicle: vehicle orally, (2) CsA: 6 mg/kg(-1).d(-1), (3) RAPA: 0.8 mg/kg(-1).d(-1), (4) FK 506: 0.15 mg/kg(-1).d(-1), (5) MMF: 20 mg/ kg(-1).d(-1). At 4 weeks, 8 weeks, 12 weeks, the rats were sacrificed, renal allografts were harvested and sera were collected. The deposition of C4d was detected by immunofluorescence and analyzed by Integrated Optical Density (IOD). The pathological changes were accessed according to the Banff 97 criteria. RESULTS: C4d deposition in PTC was found in all the allografts at 4 weeks, while there was no obvious manifestations of CAN in all the groups; the differences of Banff Score between all groups were not significant (P > .05). The values of IOD in RAPA and MMF group were lower than those in other 3 groups (P = .002, .006). The differences between RAPA and MMF, and between other 3 groups were not significant (P > .05). The intensity of C4d increased along with the progression of CAN, the heaviest C4d deposits in PTC were found at 12 weeks, and meanwhile the severest CAN was found. Comparing with Vehicle group, CsA and FK 506 had no effect on C4d deposition (P > .05), however, MMF and RAPA obviously decreased the C4d deposition (P = .000). The intensity of C4d deposition had a significant correlation with the severity of CAN (r = 0.894, P = .000). CONCLUSIONS: Our study suggests that the deposition of C4d in allografts appears earlier than pathological changes of CAN and has a correlation with the progression of CAN. MMF and RAPA can attenuate CAN by inhibiting humoral immunity. In contrast, CsA and FK 506 have no effect on humoral immunity.

The role of complement in myasthenia gravis: serological evidence of complement consumption in vivo.

BACKGROUND: Antibodies to the acetylcholine receptor (AChR) titin and the ryanodine receptor (RyR) occur in myasthenia gravis (MG). These antibodies are capable of complement activation in vitro. The involvement of the complement system should cause consumption of complement components such as C3 and C4 in vivo. MATERIALS AND METHODS: Complement components C3 and C4 were assayed in sera from 78 AChR antibody-positive MG patients and 52 healthy controls. Forty-eight of the patient sera contained titin antibodies as well, and 20 were also RyR antibody-positive. RESULTS: MG patients with AChR antibody concentrations above the median (11.2 nmol/l) had significantly lower mean C3 and C4 concentrations in serum compared to those with AChR antibody concentrations below the median. Titin antibody-positive MG patients, titin antibody-negative early-onset MG patients, titin antibody-negative late-onset MG patients, and controls had similar C3 and C4 concentrations. Nor did mean C3 and C4 concentrations differ in MG patients with RyR antibodies. Patients with severe MG (grades 4 and 5) had similar C3 and similar C4 levels compared to those with mild MG (grades 1 and 2). CONCLUSION: An increased in vivo complement consumption was detected in MG patients with high AChR antibody concentrations, unrelated to MG severity and non-AChR muscle antibodies.

Genetic, structural and functional diversities of human complement components C4A and C4B and their mouse homologues, Slp and C4.

The complement protein C4 is a non-enzymatic component of the C3 and C5 convertases and thus essential for the propagation of the classical complement pathway. The covalent binding of C4 to immunoglobulins and immune complexes (IC) also enhances the solubilization of immune aggregates, and the clearance of IC through complement receptor one (CR1) on erythrocytes. Human C4 is the most polymorphic protein of the complement system. In this review, we summarize the current concepts on the 1-2-3 loci model of C4A and C4B genes in the population, factors affecting the expression levels of C4 transcripts and proteins, and the structural, functional and serological diversities of the C4A and C4B proteins. The diversities and polymorphisms of the mouse homologues Slp and C4 proteins are described and contrasted with their human homologues. The human C4 genes are located in the MHC class III region on chromosome 6. Each human C4 gene consists of 41 exons coding for a 5.4-kb transcript. The long gene is 20.6 kb and the short gene is 14.2 kb. In the Caucasian population 55% of the MHC haplotypes have the 2-locus, C4A-C4B configurations and 45% have an unequal number of C4A and C4B genes. Moreover, three-quarters of C4 genes harbor the 6.4 kb endogenous retrovirus HERV-K(C4) in the intron 9 of the long genes. Duplication of a C4 gene always concurs with its adjacent genes RP, CYP21 and TNX, which together form a genetic unit termed an RCCX module. Monomodular, bimodular and trimodular RCCX structures with 1, 2 and 3 complement C4 genes have frequencies of 17%, 69% and 14%, respectively. Partial deficiencies of C4A and C4B, primarily due to the presence of monomodular haplotypes and homo-expression of C4A proteins from bimodular structures, have a combined frequency of 31.6%. Multiple structural isoforms of each C4A and C4B allotype exist in the circulation because of the imperfect and incomplete proteolytic processing of the precursor protein to form the beta-alpha-gamma structures. Immunofixation experiments of C4A and C4B demonstrate > 41 allotypes in the two classes of proteins. A compilation of polymorphic sites from limited C4 sequences revealed the presence of 24 polymophic residues, mostly clustered C-terminal to the thioester bond within the C4d region of the alpha-chain. The covalent binding affinities of the thioester carbonyl group of C4A and C4B appear to be modulated by four isotypic residues at positions 1101, 1102, 1105 and 1106. Site directed mutagenesis experiments revealed that D1106 is responsible for the effective binding of C4A to form amide bonds with immune aggregates or protein antigens, and H1106 of C4B catalyzes the transacylation of the thioester carbonyl group to form ester bonds with carbohydrate antigens. The expression of C4 is inducible or enhanced by gamma-interferon. The liver is the main organ that synthesizes and secretes C4A and C4B to the circulation but there are many extra-hepatic sites producing moderate quantities of C4 for local defense. The plasma protein levels of C4A and C4B are mainly determined by the corresponding gene dosage. However, C4B proteins encoded by monomodular short genes may have relatively higher concentrations than those from long C4A genes. The 5' regulatory sequence of a C4 gene contains a Spl site, three E-boxes but no TATA box. The sequences beyond--1524 nt may be completely different as the C4 genes at RCCX module I have RPI-specific sequences, while those at Modules II, III and IV have TNXA-specific sequences. The remarkable genetic diversity of human C4A and C4B probably promotes the exchange of genetic information to create and maintain the quantitative and qualitative variations of C4A and C4B proteins in the population, as driven by the selection pressure against a great variety of microbes. An undesirable accompanying byproduct of this phenomenon is the inherent deleterious recombinations among the RCCX constituents leading to autoimmune and genetic disorders.

Interaction between protein S and complement C4b-binding protein (C4BP). Affinity studies using chimeras containing c4bp beta-chain short consensus repeats.

Human C4b-binding protein (C4BP) is a regulator of the complement system and plays an important role in the regulation of the anticoagulant protein C pathway. C4BP can bind anticoagulant protein S, resulting in a decreased cofactor function of protein S for activated protein C. C4BP is a multimeric protein containing several identical alpha-chains and a single beta-chain (C4BPbeta), each chain being composed of short consensus repeats (SCRs). Previous studies have localized the protein S binding site to the NH2-terminal SCR (SCR-1) of C4BPbeta. To further localize the protein S binding site, we constructed chimeras containing C4BPbeta SCR-1, SCR-2, SCR-3, SCR-1+2, SCR-1+3, and SCR-2+3 fused to tissue-type plasminogen activator. Binding assays of protein S with these chimeras indicated that SCR-2 contributes to the interaction of protein S with SCR-1, since the affinity of protein S for SCR-1+2 was up to 5-fold higher compared with SCR-1 and SCR-1+3. Using an assay that measures protein S cofactor activity, we showed that cofactor activity was decreased due to binding to constructs that contain SCR-1. SCR-1+2 inhibited more potently than SCR-1 and SCR-1+3. SCR-3 had no additional effect on SCR-1, and therefore the effect of SCR-2 was specific. In conclusion, beta-chain SCR-2 contributes to the interaction of C4BP with protein S.

Mouse complement component C4 is devoid of classical pathway C5 convertase subunit activity.

It has long been known that mouse C4 has unusually low hemolytic activity relative to the C4 of other mammalian species (e.g. human and guinea pig), the measurements being done in most cases using a C4-deficient guinea pig serum reagent in a one-step assay with EA. This low activity for mouse C4 previously had been attributed to "technical" difficulties such as lability of the protein during blood collection and partial species incompatibilities with guinea pig components. Recently, we presented evidence for the involvement of human C4 beta-chain residues 455-469, a putatively exposed hydrophilic segment, in contributing to a C5 binding site in the C4b subunit of the classical pathway C5 convertase, C4b3b2a. Given that there were five sequence differences between the human and mouse protein within this segment, we hypothesized that these substitutions may have compromised the C5 convertase subunit activity of mouse C4, thereby resulting in its low hemolytic activity. Using a multi-step hemolytic assay which was totally dependent upon C5 cleavage by the classical pathway, we found that mouse C4 was completely devoid of classical pathway C5 convertase subunit activity. We have been able to rule out the most obvious potential species incompatibilities (e.g. between C4mo and C5gp) as being responsible for this lack of activity. Moreover, we found that the low level of hemolytic activity of mouse C4 measured in the one-step assay can be ascribed totally to C5 cleavage, and subsequent terminal component assembly, by the alternative pathway C5 convertase, (C3b)2Bb. However, the assembly of the latter enzyme complex is dependent upon the presence of C3b molecules deposited initially via the classical pathway C3 convertase in which mouse C4b is a subunit. Finally, whereas conversion of human residues 458RP to the mouse-like sequence PL was sufficient to abrogate classical pathway C5 convertase subunit activity in human C4, the five substitutions which "humanized" the 452-466 segment of mouse C4 (corresponding to human residues 455-469) were on their own insufficient to impart this activity to mouse C4. This implies that, in addition to the 455-469 beta-chain segment of human C4, there are other regions of the molecule contributing to C5 binding which are also non-conserved between human and mouse C4.

Covalently-bound human C4b dimers consisting of C4B isotype show higher hemolytic activity than those of C4A in the C3-bypass complement pathway.

The ability to form a covalent dimer of human C4b was investigated with purified isotypes C4A and C4B, and antibody-sensitized liposomes supplemented with C1. In this system, no C4A or C4B formed a complex with the antibody or C1. Whereas both C4A and C4B isotypes formed dimers to a similar extent, C4B formed an ester-linked dimer and C4A an amide-linked dimer. Both of these dimers served as a subunit for the C3-bypass pathway C5 convertase, since liposomes bearing Ab, C1 and a dimer of C4A or C4B, allowed the formation of C5 convertase by the addition of C2. The degree of complement-mediated liposome lysis however, was observed to be 2-3 times higher in the C4B-bearing particles than in those bearing C4A. These results indicate that the second C4b-binding site on the first C4b is different between C4A and C4B, and that in the C3-bypass pathway, C4B has a higher degree of hemolytic activity than C4A, as in the conventional classical complement pathway.

Functional properties of heterogeneous human asialo-C4 and its isotypes C4A and C4B.

The fourth component of human complement (C4) is encoded at two separate but closely linked loci within the MHC on the short arm of chromosome 6. Thus, there are two types of C4 protein in most individual and pooled normal human sera (NHS): C4A and C4B. Incubation of individual sera, pooled NHS, or purified heterogeneous C4 (C4A/C4B) with bacterial sialidase at 37 degrees C increased C-mediated hemolysis of antibody-sensitized sheep erythrocytes 1.54- to 1.93-fold. Comparative studies of Tmax of human C2, using asialo-C4 or buffer-treated C4 on EAC1gp and extrapolation to time 0 indicated a z value 4-fold higher with asialo-C4. This indicated that more hemolytically active C42 complexes are available with sialidase-treated C4 compared to untreated C4. There was no appreciable difference in the % 125I-C4 bound to EAC1gp (sialidase- or buffer-treated). Sera from two different blood donors with C4A3 phenotype (C4BQ0), two different donors with C4B1 phenotype (C4AQ0), and serum from an individual heterozygous deficient at both C4A3 and C4B1 regions (A3, AQ0; B1, BQ0) were investigated. The C4 allotypes, purified from these sera, were treated with sialidase; the C4A3 was enhanced in hemolytic assays by sialidase-treatment (1.52- to 2.3-fold), whereas the C4B1 allotype was not enhanced. Fluorometric determinations revealed that approximately the same percentage of sialic acid was released from sialidase-treated C4A3 and C4B1. Therefore, the increase in hemolytic titer observed after treatment of NHS or purified heterogeneous C4 with sialidase is a property of C4A3 but not a property of C4B1.

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

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

C4b-binding protein exacerbates the host response to Escherichia coli.

Activated protein C is a plasma anticoagulant. For activated protein C to function as an anticoagulant, it must form a complex with protein S. Protein S anticoagulant activity is neutralized by formation of a reversible complex with C4b binding protein (C4bBP). C4bBP is an acute-phase plasma protein. When C4bBP levels increase, mass action forces the level of free protein S to decrease, giving rise to an acquired functional protein S deficiency. It has been proposed that these elevated C4bBP levels and the resultant acquired deficiency of protein S that occurs in inflammation could contribute to a hypercoagulable state. An experimental model to test this hypothesis was suggested by our previous studies that demonstrated that inhibition of protein C activation rendered baboons hypercoagulable in response to sublethal Escherichia coli infusion (J Clin Invest 79:918, 1987). We have extended these studies to examine the effect of inhibition of protein S activity with C4bBP in the host (baboon) response to infusion of sublethal concentrations of E coli organisms. Five sets of animals were studied: (1) those challenged with sublethal concentrations of E coli alone (0.4 x 10(10)/kg); (2) those supplemented only with C4bBP (20 mg/kg); (3) those challenged with the same level of E coli but supplemented with C4bBP (20 mg/kg); (4) those challenged with sublethal E coli and supplemented with C4bBP (20 mg/kg) and sufficient protein S (2.3 mg/kg) to fill the protein S binding sites on C4bBP; and (5) those challenged with lethal concentrations of E coli. Sublethal E coli infusion (group 1 animals) caused only an acute-phase response with no consumption of fibrinogen, detectable organ damage, or detectable tumor necrosis factor (TNF) in the plasma. C4bBP infusion (group 2 animals) resulted in no significant physiologic changes, no detectable plasma TNF, and little change in fibrinogen level. The group 3 animals, receiving both sublethal E coli and C4bBP, exhibited rapid consumption of fibrinogen, systemic organ damage, and detectable circulating TNF ultimately leading to death. The overall response of this group was very similar to the response of the group 5 animals receiving an LD100 dose of E coli. The group 4 animals, which were treated exactly as above except that C4bBP was supplemented with a slight excess of protein S, responded essentially like those that received sublethal E coli alone. These studies suggest that the elevation of C4bBP during an inflammatory response can contribute to fibrinogen consumption and vascular damage. This vascular damage may be associated with enhanced elaboration of cytokines like TNF.(ABSTRACT TRUNCATED AT 400 WORDS)

Protein S and C4b-binding protein: components involved in the regulation of the protein C anticoagulant system.

The protein C anticoagulant system provides important control of the blood coagulation cascade. The key protein is protein C, a vitamin K-dependent zymogen which is activated to a serine protease by the thrombin-thrombomodulin complex on endothelial cells. Activated protein C functions by degrading the phospholipid-bound coagulation factors Va and VIIIa. Protein S is a cofactor in these reactions. It is a vitamin K-dependent protein with multiple domains. From the N-terminal it contains a vitamin K-dependent domain, a thrombin-sensitive region, four EGF) epidermal growth factor (EGF)-like domains and a C-terminal region homologous to the androgen binding proteins. Three different types of post-translationally modified amino acid residues are found in protein S, 11 gamma-carboxy glutamic acid residues in the vitamin K-dependent domain, a beta-hydroxylated aspartic acid in the first EGF-like domain and a beta-hydroxylated asparagine in each of the other three EGF-like domains. The EGF-like domains contain very high affinity calcium binding sites, and calcium plays a structural and stabilising role. The importance of the anticoagulant properties of protein S is illustrated by the high incidence of thrombo-embolic events in individuals with heterozygous deficiency. Anticoagulation may not be the sole function of protein S, since both in vivo and in vitro, it forms a high affinity non-covalent complex with one of the regulatory proteins in the complement system, the C4b-binding protein (C4BP). The complexed form of protein S has no APC cofactor function. C4BP is a high molecular weight multimeric protein with a unique octopus-like structure. It is composed of seven identical alpha-chains and one beta-chain. The alpha- and beta-chains are linked by disulphide bridges. The cDNA cloning of the beta-chain showed the alpha- and beta-chains to be homologous and of common evolutionary origin. Both subunits are composed of multiple 60 amino acid long repeats (short complement or consensus repeats, SCR) and their genes are located in close proximity on chromosome 1, band 1q32. Available experimental data suggest the beta-chain to contain the single protein S binding site on C4BP, whereas each of the alpha-chains contains a binding site for the complement protein, C4b. As C4BP lacking the beta-chain is unable to bind protein S, the beta-chain is required for protein S binding, but not for the assembly of the alpha-chains during biosynthesis.(ABSTRACT TRUNCATED AT 400 WORDS)

The mechanism of activation of the alternative pathway of complement by cell-bound C4b.

Investigations into the mechanism of alternative pathway-dependent lysis of C4b-coated cells are reported. Test cells (EAC1q4b) were formed by reaction of sheep erythrocytes with antibody, C1 and C4. In C5-deficient serum, more C3b was deposited onto EAC1qC4b than onto control cells (EAC1q). The possibility that the C4bBb enzyme could form was considered, but no C3 convertase activity was generated when magnesium, properdin and factors B and D were added to EAC1qC4b. Binding studies employing radiolabeled components provided evidence that C4b bound the C3 convertase, C3bBbP, through a weak interaction with C3b. These data implied C3 conversion would be localized to the cell surface, thereby amplifying C3b deposition. This could be demonstrated in vitro. C3b, properdin, factor B and factor D were all required and the amplified C3b deposition was not due to deposition onto C4b itself. In serum, C5 convertase activity would be consequently expressed and cell lysis would result. This could be the mechanism by which the sera of C2-deficient patients mediate lysis of antibody coated sheep erythrocytes.

Substitution of a single amino acid (aspartic acid for histidine) converts the functional activity of human complement C4B to C4A.

The C4B isotype of the fourth component of human complement (C4) displays 3- to 4-fold greater hemolytic activity than does its other isotype C4A. This correlates with differences in their covalent binding efficiencies to erythrocytes coated with antibody and complement C1. C4A binds to a greater extent when C1 is on IgG immune aggregates. The differences in covalent binding properties correlate only with amino acid changes between residues 1101 and 1106 (pro-C4 numbering)--namely, Pro-1101, Cys-1102, Leu-1105, and Asp-1106 in C4A and Leu-1101, Ser-1102, Ile-1105, and His-1106 in C4B, which are located in the C4d region of the alpha chain. To more precisely identify the residues that are important for the functional differences, C4A-C4B hybrid proteins were constructed by using recombinant DNA techniques. Comparison of these by hemolytic assay and binding to IgG aggregates showed that the single substitution of aspartic acid for histidine at position 1106 largely accounted for the change in functional activity and nature of the chemical bond formed (ester vs. amide). Surprisingly, substitution of a neutral residue, alanine, for histidine at position 1106 resulted in an increase in binding to immune aggregates without subsequent reduction in the hemolytic activity. This result strongly suggests that position 1106 is not "catalytic" as previously proposed but interacts sterically/electrostatically with potential acceptor sites and serves to "select" binding sites on potential acceptor molecules.