The binding of human complement component C4 to antibody-antigen aggregates.

The binding of human complement component C4 to antibody-antigen aggregates and the nature of the interaction have been investigated. When antibody-antigen aggregates with optimal C1 bound are incubated with C4, the C4 is rapidly cleaved to C4b, but only a small fraction (1-2%) is bound to the aggregates, the rest remaining in the fluid phase as inactive C4b. It has been found that C4b and th antibody form a very stable complex, due probably to the formation of a covalent bond. On reduction of the C4b-immunoglobulin G (IgG) complex, the beta and gamma chains, but not the alpha' chain, of C4b are released together with all the light chain, but only about half of the heavy chain of IgG. The reduced aggregates contain two main higher-molecular-weight complexes, one shown by the use of radioactive components to contain both IgG and C4b and probably therefore the alpha' chain of C4b and the heavy chain of IgG, and the other only C4b and probably an alpha' chain dimer. The aggregates with bound C1 and C4b show maximal C3 convertase activity, in the presence of excess C2, when the alpha'-H chain component is in relatively highest amounts. When C4 is incubated with C1s in the absence of aggregates, up to 15% of a C4b dimer is formed, which on reduction gives an alpha' chain complex, probably a dimer. The apparent covalent interaction between C4b and IgG and between C4b and other C4b molecules cannot be inhibited by iodoacetamide and hence cannot be catalysed by transglutaminase (factor XIII). The reaction is, however, inhibited by cadaverine and putrescine and 14C-labelled putrescine is incorporated into C4, again by a strong, probably covalent, bond. It is suggested that a reactive group, possibly an acyl group, is generated when C4 is activated by C1 and that this reactive group can react with IgG, with another C4 molecule, or with water.     

Polymorphism of human complement component C4

An assessment has been made of the polymorphism of human complement component C4 by comparing derived amino acid sequences of cDNA and genomic DNA with limited amino acid sequences. In all, one complete and six partial sequences have been obtained from material from three individuals and include two C4A and two C4B alleles. Differences were found between the 4 alleles from 2 loci in only 15 of the 1722 amino acid residues, and 12 lie within one section of 230 residues, which in 1 allele also contains a 3-residue deletion. In three variable positions, an allelic difference in one C4 type was common to the other types. Three nucleotide differences were found in four introns. In spite of marked differences in their chemical reactivity, the many allelic forms appear to differ in less than 1% of their amino acid residue positions. This unusual pattern of polymorphism may be due to recent duplication of the C4 gene, or may have arisen by selection as a result of the biological role of C4, which interacts in the complement sequence with nine other proteins necessitating conservation of much of the surface structure.     

The covalent-binding reaction of complement component C3.

The complement protein C3, when activated by limited proteolysis, forms a short-lived reactive intermediate fragment, 'nascent' C3b, which is known to bind covalently to certain surfaces. The characteristics of the covalent binding reaction have been studied by using Sepharose-trypsin as a combined proteolytic activator and binding surface for C3. Binding of C3 to Sepharose-trypsin is saturable, with a maximum of 25-26 molecules of C3b bound per molecule of trypsin. A minimum life-time of about 60 microseconds for the reactive intermediate has been calculated from binding of C3 at saturation. Initial binding efficiencies of over 30% can be obtained at physiological pH and ionic strength. The efficiency of C3 binding to Sepharose-trypsin decreases as pH increases and also shows a slight decline at high ionic strength. The covalent binding of C3 to Sepharose-trypsin can be inhibited by a range of oxygen and nitrogen nucleophiles. Activation of C3 in the presence of radioactive forms of four such nucleophiles, phenylhydrazine, methylamine, glycerol and glucosamine results in apparent covalent incorporation of the nucleophile into the C3d fragment of C3. The quantity of radioactive nucleophile bound can be predicted from the observed potency of the nucleophile as an inhibitor of the binding of C3 to Sepharose-trypsin. The radioactive nucleophiles may be considered as 'active-site' labels for C3.     

The low C5 convertase activity of the C4A6 allotype of human complement component C4.

We have compared the C5-convertase-forming ability of different C4 allotypes, including the C4A6 allotype, which has low haemolytic activity and which has previously been shown to be defective in C5-convertase formation. Recent studies suggest that C4 plays two roles in the formation of the C5 convertase from the C3 convertase. Firstly, C4b acts as the binding site for C3 which, upon cleavage by C2, forms a covalent linkage with the C4b. Secondly, C4b with covalently attached C3b serves to form a high-affinity binding site for C5. Purified allotypes C4A3, C4B1 and C4A6 were used to compare these two activities of C4. Covalently linked C4b-C3b complexes were formed on sheep erythrocytes with similar efficiency by using C4A3 and C4B1, indicating that the two isotypes behave similarly as acceptors for covalent attachment of C3b. C4A6 showed normal efficiency in this function. However, cells bearing C4b-C3b complexes made from C4A6 contained only a small number of high-affinity binding sites for C5. Therefore a lack of binding of C5 to the C4b C3b complexes is the reason for the inefficient formation of C5 convertase by C4A6. The small number of high-affinity binding sites created, when C4A6 was used, were tested for inhibition by anti-C3 and anti-C4. Anti-C4 did not inhibit C5 binding, whereas anti-C3 did. This suggests that the sites created when C4A6 is used to make C3 convertase may be C3b-C3b dimers, and hence the low haemolytic activity of C4A6 results from the creation of low numbers of alternative-pathway C5-convertase sites.     

The purification and characterization of bovine C4, the fourth component of complement.

The fourth component of complement, C4, was isolated from bovine plasma in high yield, by using simple purification techniques. The protein, like human component C4, is a beta-globulin with a mol.wt. of about 200 000 and consists of three polypeptide chains, alpha, beta and gamma, with apparent mol. wts. of 98 000, 82 000 and 32 000 respectively. The chains of C4 have been separated by methods previously used for human C4. Their amino acid compositions are very similar to those of the human component, but differences in carbohydrate distribution have been observed. The haemolytic activity of bovine C4 is totally destroyed by incubation with bovine C1s, the activated subcomponent of the first component of complement. Component C4, treated in this way, was shown to be cleaved in the alpha chain, which was decreased in mol.wt. by about 9000, corresponding to the removal of subcomponent C4a.     

The isolation and structure of C4, the fourth component of human complement.

The fourth component of complement, C4, was isolated from human serum in good yield, and in confirmation of previous reports was shown to be formed from three peptide chains, alpha, beta and gamma, with apparent mol.wts. 90 000, 80 000 and 30 000 respectively. Preparative methods are described for the isolation of the three peptide chains and their amino acid analyses reported. Component C4 contains 7.0% carbohydrate, alpha-chain 8.6% and the beta-chain 5.6%. The N-terminal amino acid sequences are given for 12 residues of the alpha-chain, eight of the beta-chain and 19 of the gamma-chain.     

Isolation of the fourth component (C4) of rat complement.

The fourth component of rat complement was purified to homogeneity by sequential chromatography of rat plasma in benzamidine on QAE-A50, SP-C50, hydroxyapatite, and gel filtration on Bio-Gel A 1.5. The final material was homogeneous on SDS-PAGE analysis and had a calculated m.w. of 198,000. A monospecific antibody against rat C4 was obtained from immunized rabbits. The concentration of rat C4 in the plasma of normal 4-month-old Wistar rats was 190 +/- 34 microgram/ml (mean +/- 1 S.D.).     

Phenotyping of human complement component C4, a class-III HLA antigen.

The plasma complement protein C4 is encoded at two highly polymorphic loci, A and B, within the class-III region of the major histocompatibility complex. At least 34 different polymorphic variants of human C4 have been identified, including non-expressed or 'null' alleles. The main method of identification of C4 polymorphic allotypes is separation on the basis of charge by agarose-gel electrophoresis of plasma. On staining by immunofixation with anti-C4 antibodies, each C4 type gives three major bands, but, since individuals can have up to five allotypes, the overlapping banding pattern is difficult to interpret. We show that digestion of plasma samples with carboxypeptidase B, which removes C-terminal basic amino acids, before electrophoresis, produces a single, sharp, distinct band for each allotype and allows identification of the biochemical basis of the multiple banding pattern previously observed in C4 phenotype determination.     

The structural basis of the multiple forms of human complement component C4

cDNA clones of human complement components C4A and C4B alleles were prepared from mRNA obtained from the liver of a donor heterozygous at both loci. cDNA from one C4A allele was sequenced to give the derived complete amino acid sequence of 1722 amino acid residues of the C4 single chain precursor molecule and the estimated sequences of the three peptide chains of secreted C4. Comparison with partial sequences of a second C4A allele and a C4B allele has led to the tentative identification of some class differences in nucleotide sequences between C4A and C4B and of allelic differences between C4A alleles in this highly polymorphic system.     

Structural basis for the C4d.1/C4d.2 serologic allotypes of murine complement component C4

The C4d.1 antigenic specificity was first defined serologically in 1959 as an H-2-associated cellular alloantigen first designated "G," later H-2.7. It was subsequently shown to be an allotype of component C4 of the C system, with the antigenic determinant carried on the C4d proteolytic fragment of the alpha-chain, thus the designation C4d.1. Alloantisera defining an antithetical Ag, C4d.2, were also prepared. Previous studies in our laboratory showed that the structural difference between the two specificities resides in a single tryptic peptide of C4d. As an efficient approach to definition of the amino acid difference(s) involved, genomic clones covering the C4d regions from two H-2 haplotypes of the C4d.1 type have been prepared and sequenced, and compared with two sequences already available for C4d.2-type molecules. The results indicate that the rather striking serologic difference between C4d.1 and C4d.2 is attributable to the single amino acid substitution of arginine in C4d.2 for glutamine in C4d.1. The substituted residue is in a highly hydrophilic region of the C4 molecule, at a position homologous to one that contributes to the Chido/Rodgers serologic difference of human C4 molecules. This substitution also determines a new Pst I site in C4d.1 strains. A HindIII restriction fragment length polymorphism between C4d.1 and C4d.2 has also been observed.     

Macrophage-derived complement component C4 can restore humoral immunity in C4-deficient mice

Mice with a disrupted C4 locus (C4(-/-)) have an impaired immune response to thymus-dependent Ags. To test the role of bone marrow-derived C4 in humoral immunity, we reconstituted deficient animals with wild-type bone marrow or an enriched fraction of bone marrow-derived macrophages. C4 chimeras were immunized with 4-hydroxy-3-nitrophenyl(5) conjugated to keyhole limpet hemocyanin (NP(5)- KLH) or infected with HSV-1, and the Ab response was evaluated. Wild-type bone marrow rescued the humoral immune response to both Ags, i.e., the soluble Ag and HSV-1, demonstrating that local C4 production is sufficient for humoral responses. Although the C4 chimeric animals lacked detectable C4 in their sera, C4 mRNA was identified in splenic sections by in situ hybridization, and C4 protein deposits were identified in the germinal center areas of splenic follicles by immunofluorescence staining. Macrophages derived from bone marrow produced sufficient C4 protein to restore the humoral response to NP(5)-KLH in C4-deficient animals when administered along with Ag. Cell-sorting experiments, followed by C4-specific RT-PCR, identified splenic macrophages (CD11b(+), CD11c(-)) as a cellular source for C4 synthesis within the spleen.     

The complement component C1s catalysed hydrolysis of peptide 4-nitroanilide substrates

The kinetic parameter kcat/Km has been determined for the hydrolysis of peptide 4-nitroanilides, catalysed by complement component C1s. Substrates based on the C-terminal sequence of human C4a (Leu-Gln-Arg) were synthesised. Replacement of the glutamine residue by glycine or serine increased kcat/Km. Substitution of valine for the leucine residue increased kcat/Km, while substitution of glycine or lysine for the leucine residue decreased kcat/Km slightly. D-Val-Ser-Arg 4-nitroanilide is the most reactive 4-nitroanilide substrate towards C1s, so far. These results are discussed in relation to the amino acid sequences near the bonds cleaved by C1s in C4, C2 and C1 inhibitor.     

The sequence and topology of human complement component C9.

A partial nucleotide sequence of human complement component C9 cDNA representing 94% of the coding region of the mature protein is presented. The amino acid sequence predicted from the open reading frame of this cDNA concurs with the amino acid sequence at the amino-terminal end of three proteolytic fragments of purified C9 protein. No long stretches of hydrophobic residues are present, even in the carboxy-terminal half of the molecule which reacts with lipid-soluble photoaffinity probes. Monoclonal antibody epitopes have been mapped by comparing overlapping fragments of C9 molecule to which the antibodies bind on Western blots. Several of these epitopes map to small regions containing other surface features (e.g., proteolytic cleavage sites and N-linked oligosaccharide). The amino-terminal half of C9 is rich in cysteine residues and contains a region with a high level of homology to the LDL receptor cysteine-rich domains. A model for C9 topology based on these findings is proposed.     

X-ray crystal structure of the C4d fragment of human complement component C4

C4 fulfills a vital role in the propagation of the classical and lectin pathways of the complement system. Although there are no reports to date of a C4 functional activity that is mediated solely by the C4d region, evidence clearly points to it having a vital role in a number of the properties of native C4 and its major activation fragment, C4b. Contained within the C4d region are the thioester-forming residues, the four isotype-specific residues controlling the C4A/C4B transacylation preferences, a binding site for nascent C3b important in assembling the classical pathway C5 convertase and determinants for the Chido/Rodgers (Ch/Rg) blood group antigens. In view of its functional importance, we undertook to determine the three-dimensional structure of C4d by X-ray crystallography. Here we report the 2.3A resolution structure of C4Ad, the C4d fragment derived from the human C4A isotype. Although the approximately 30% sequence identity between C4Ad and the corresponding fragment of C3 might be expected to establish a general fold similarity between the two molecules, C4Ad in fact displays a fold that is essentially superimposable on the structure of C3d. By contrast, the electrostatic characteristics of the various faces of the C4Ad molecule show marked differences from the corresponding faces of C3d, likely reflecting the differences in function between C3 and C4. Residues previously predicted to form the major Ch/Rg epitopes were proximately located and accessible on the concave surface of C4Ad. In addition to providing further insights on the current models for the covalent binding reaction, the C4Ad structure allows one to rationalize why C4d is not a ligand for complement receptor 2. Finally the structure allows for the visualization of the face of the molecule containing the binding site for C3b utilized in the assembly of classical pathway C5 convertase.     

Primary structure of cobra complement component C3.

Complement component C3 is a multifunctional protein known to interact specifically with more than 10 different plasma proteins or cell surface receptors. Cobra venom contains cobra venom factor, a structural analogue of C3 that shares some properties with C3 (e.g., formation of a C3/C5 convertase) but differs in others (e.g., susceptibility to regulation by factors H and I). The elucidation of structural differences between C3 and cobra venom factor can be expected to help identify functionally important regions of C3 molecules. To that end we have undertaken the molecular cloning of both cobra C3 and cobra venom factor to take advantage of the unique biologic system where both proteins are produced by the same species. We report the primary structure of cobra C3 mRNA and the derived protein structure. Cobra C3 mRNA is 5211 bp in length. It contains an open reading frame of 4953 bp coding for a single pre-pro-C3 molecule, consisting of a 22-amino acid signal sequence, a 633-amino acid beta-chain (70 kDa), and a 992-amino acid alpha-chain (112 kDa) which is separated from the beta-chain by four arginine residues. There are no N-glycosylation sites in cobra C3. Cobra C3 exhibits approximately 58% nucleotide sequence identity with C3 from mammalian species. At the protein level, sequence identity is approximately 52% and sequence similarity approximately 71%. All 27 cysteine residues are highly conserved as are the C3 convertase cleavage site, the thioester site, and the factor B binding site. Cobra C3 also seems to have homologous binding sites for factor H and properdin, as well as a conserved sequence in the functionally important region of the C3a anaphylatoxin. The sequence homology at the CR2 and CR3 binding sites does not exceed the overall sequence homology. Accordingly, the existence of CR2 and CR3 binding sites can neither be deduced nor excluded.