Isolation and characterization of the third complement component of axolotl (Ambystoma mexicanum)

1. Using a monoclonal anti-human C3 antibody and a polyclonal anti-cobra venom factor antibody as probes, a protein homologous to the mammalian third complement component (C3) was purified from axolotl plasma and found to be axolotl C3. 2. Axolotl C3 consists of two polypeptide chains (Mr = 110,000 and 73,000) linked by disulfide bonds. An internal thiolester bond in the alpha chain was identified by the incorporation of [14C]methylamine and NH2-terminal sequence from the C3d fragment of C3. 3. Digestion of C3 by trypsin resulted in the cleavage of both the alpha and beta chains, generating fragments with a cleavage pattern similar to that of human C3. 4. The amino acid composition of axolotl C3 and the amino acid sequences of the thiolester site (and the surrounding amino acids), the cleavage site for the C3-convertase, and one of the factor I cleavage sites are similar to C3 from other vertebrates. 5. In contrast to human C3, which has concanavalin A binding carbohydrates on both the alpha and beta chains, only the beta chain of axolotl C3 contains such carbohydrates.     

Polymorphism of the third component of human complement

Genetic polymorphism of the third component of human complement (C3) has been considered as a powerful marker for population genetics. Some studies on the distribution of gene frequencies have been performed among numerous populations all over the world. This review takes stock of population genetic studies reported up to now and points out some remarks on the distribution of the observed allelic frequencies.     

Measurement of hemolytic complement and the third component of complement in nonhuman primates.

Complement, determined by hemolytic assay, and the third component of complement (C3), determined by radial immunodiffusion assay, were measured in nine nonhuman primate species. The species studied were the titi (Callicebus mollach). The sooty mangabey (Cercocebus atys), the thick-tailed galago or bushbaby (Galago crassicaudatus panganiensis), the crab-eating monkey (Macaca fascicularis), the rhesus monkey (Macaca mulatta), the bonnet monkey (Macaca radiata), the stumptailed macaque (Macaca speciosa), the yellow baboon (Papio cynocephalus), and the black-and-red tamarin (Saguinus nigricollis). Both sheep and bovine erythrocytes were used in the hemolytic complement assays. With the sheep erythrocyte system, sera from four species (yellow baboon, sooty mangabey, bonnet monkey, black-and-red tamarin) had similar titers with both antibody sensitized and non-sensitized erythrocytes. In contrast, the titers obtained using sensitized bovine erythrocytes was always higher than the values obtained using non-sensitized bovine erythrocytes. In all species, the titers for non-sensitized sheep erythrocytes was higher than the titer for non-sensitized bovine erythrocytes. When the species were compared for cross reactivity using the radial immunodiffusion assay for human C3, the rhesus monkey showed the strongest cross reaction; the thick-tailed galago, a prosimian, showed no detectable cross reactivity; and the other species examined showed intermediate degrees of reactivity.     

Isolation and characterization of the third component of complement in the serum of the clawed frog, Xenopus laevis

The hemolytic activity against SRBC in the serum of normal Xenopus is dependent on specific antibody and both Ca++ and Mg++, whereas the activity against RRBC is dependent on Mg++ alone. Both of these hemolytic activities disappeared after treatment of the serum with zymosan or with the specific rabbit antiserum against one of the zymosan-binding proteins in Xenopus serum. By using this antiserum as a probe, a complement component (XC) was purified as a single entity from the Xenopus plasma after polyethylene glycol precipitation, DEAE-Sepharose CL-6B, Sepharose CL-6B, and Sephadex G-200 column chromatographies. The XC, contained at 2.3 mg/ml in normal serum, showed an electrophoretic mobility of beta-globulin, with a m.w. of 204,000 (204K) comprising two distinct subunits of 125K and 85K, which are linked with each other by disulfide bonds. The 204K protein exhibited a strong hemolytic activity in association with other components in Xenopus serum. Digestion of 204K protein by trypsin resulted in a specific cleavage of the 125K subunit and a conversion of its immunoelectrophoretic mobility to the anodal side, leaving the 85K subunits intact. The treatment of XC with SDS and urea resulted in the splitting of 125K subunits into 78K and 40K, but this splitting was inhibited upon pretreatment with methylamine, suggesting the presence of a thiol ester bond in the XC. The amino acid composition of the XC revealed a striking resemblance to that of mammalian C3. In all aspects, the 204K protein (XC) is regarded as representing the C3 of Xenopus laevis, which plays a key role in both the classical and alternative hemolytic pathways.     

Structures of sugar chains of the third component of human complement

Human C3, the third component of human complement, contained mannose and N-acetylglucosamine as sugar components. The sugar chains were liberated from the polypeptide chains by hydrazinolysis, and the free amino groups were N-acetylated. The reducing end residues of the sugar chains thus obtained were tagged with 2-aminopyridine, and the pyridylamino (PA-) derivatives of sugar chains were separated by high-performance liquid chromatography. The structures of purified PA-sugar chains were analyzed by a combination of stepwise exoglycosidase digestions, size determination by paper electrophoresis, methylation analysis, Smith degradation, and partial acetolysis. These results showed that C3 contained two high-mannose type sugar chains ranging from Man5GlcNAc2 to Man9GlcNAc2. Analyses of the sugar chains of alpha- and beta-chains of C3 indicated that the alpha-chain contained mainly Man8GlcNAc2 and Man9GlcNAc2, while the beta-chain contained mainly Man5GlcNAc2 and Man6GlcNAc2.     

Polymorphic variants of the third component of complement in Graves' disease

We have examined electrophoretic variants of the third complement component (C3) in 294 controls and in 44 patients suffering from Graves' disease, drawn from the Avalon Peninsula of Newfoundland. Two common C3 variants, S and F, account for 99% of the gene frequencies. The S homozygote phenotype was observed in 170 controls and in 27 patients; 18 controls were found to be homozygous for the F allele (3 patients), and the FS phenotype was observed in 103 controls and 14 patients. The phenotypic frequencies did not differ significantly between controls and patients. It is concluded that C3 variants do not distinguish individuals who have Graves' disease.     

Biosynthesis of the internal thioester bond of the third component of complement

C3-translational product, which was synthesized with rabbit liver mRNA in a reticulocyte lysate protein-synthesizing system, did not react with [14C]methylamine, indicating the lack of an internal thioester bond. Instead, the C3-translational product reacted with iodo[1-14C]acetamide, as determined by gel electrophoresis in the presence of sodium dodecyl sulfate after immunoprecipitation of the product, indicating the presence of a reactive thiol group. When the C3-translational product was treated with rabbit liver homogenate, the product acquired reactivity with [14C]methylamine and lost the reactivity with iodo[1-14C]acetamide. Thus, the liver homogenate seemed to contain a factor (or factors) required for the formation of an internal thioester bond. The factor was partially purified from the liver homogenate by ammonium sulfate precipitation and ion-exchange chromatography on DEAE-cellulose.     

Mapping of the properdin-binding site in the third component of complement.

The properdin-binding site in the human third complement component (C3) was mapped by using isolated C3b, C3c, alpha- and beta-chains of C3 and C3 polypeptide fragments and an enzyme-linked-immunosorbent-assay procedure. The C3 chains and the polypeptide fragments were purified to homogeneity by preparative sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. The alpha-chain polypeptides included a 68 kDa and a 43 kDa polypeptide, which were generated by cleavage of C3b with factors I and H, and a 40 kDa, 33 kDa (C3d) and 27 kDa polypeptide, which were generated by cleavage of C3b with porcine elastase. It was shown that properdin binds to C3b, C3c, alpha-chain, and to the 43 kDa (factor-I + H-derived), as well as to 40 kDa (elastase-derived) alpha-chain fragment, but not to the beta-chain 68 kDa, 33 kDa (C3d) and 27 kDa alpha-chain fragments. Thus the binding site for properdin resides on the 40-43 kDa C-terminal alpha-chain fragment of C3.     

Isolation and characterization of a protein from hagfish serum that is homologous to the third component of the mammalian complement system.

The 192-kDa protein HX, a major component of serum that specifically binds to zymosan particles, was prepared from the plasma of the hagfish (Eptatretus burgeri) by ion-exchange chromatography and gel filtration. HX, present at a concentration of 0.8 mg/ml in the original plasma, was composed of two distinct subunits of 115 kDa and 77 kDa, respectively, which were linked by disulfide bonds. The protein had the same electrophoretic mobility as beta-globulin. Digestion by trypsin resulted in a specific cleavage of the 115-kDa subunit and a change in its immunoelectrophoretic mobility in the anodal direction, leaving the 77-kDa subunit intact. Treatment with SDS and urea resulted in the splitting of the 115-kDa subunits into 68-kDa and 45-kDa components, but this splitting was inhibited by pretreatment with methylamine, suggesting the presence of a thiol ester bond in the 115-kDa subunit. The amino acid composition of HX revealed a striking resemblance to that of human C3. We conclude, therefore, that the 192-kDa protein isolated in this study is analogous to C3, which plays a key role in the mammalian C system.     

Location of the inter-chain disulfide bonds of the third component of human complement

Location of the disulfide bonds connecting three polypeptide chains (alpha 3, 27kd; 2, 43kd; beta, 75kd) of C3c has been investigated by partial reduction with cysteine followed by alkylation with 14C-monoiodoacetic acid. Treatment of C3c with cysteine produced a partially reduced fragment, composed of disulfide-linked beta and alpha 3 chains. A single thiol residue was detected on the alpha 3 chain but not on the beta chain of the fragment, suggesting that the alpha 2 chain in C3c is linked through a single disulfide bond to the alpha 3 chain but not to the beta chain.     

Localization of the conglutinin binding site on the third component of human complement

The binding site on the human third complement component for bovine conglutinin has been located. C3 fragments were purified to homogeneity by preparative SDS-polyacrylamide-gel electrophoresis. Only the N-terminal 27,000 dalton (Da) fragment of the alpha'-chain and the beta-chain were found to be glycosylated, and the carbohydrate was susceptible to endo-beta-N-acetylglucosaminidase H. This finding indicates that only high mannose or hybrid-type oligosaccharide chains are present on the C3 molecule. Binding to conglutinin was determined by an enzyme-linked immunosorbent assay and occurred with C3b, iC3b, C3c, the alpha-chain, and the 27,000 Da fragment of the alpha'-chain, but not with C3d or the C-terminal 40,000 Da fragment of the alpha'-chain. The beta-chain displayed very weak interaction. Binding to conglutinin could be inhibited by EDTA, N-acetylglucosamine, and to a lesser degree by mannose. Enzymatic removal of the carbohydrate from the C3 molecule abolished binding to conglutinin. It is concluded that bovine conglutinin binds to the carbohydrate moiety located on the N-terminal 27,000 Da polypeptide of the alpha-chain.     

Catabolites of the third component of complement in urines of hereditary nephritis patients

Hereditary nephritis protein (HNP), an unusual urine protein from patients with hereditary nephritis (Alport Syndrome), was purified 120-fold to homogeneity. A slightly larger protein, pro-HNP, was similarly purified and was found to be a precursor of HNP. Both pro-HNP and HNP showed immunological identity to the third component of human complement, C3, and to its catabolite C3c. Pro-HNP had a molecular weight of 143,000 and, in equimolar ratio, polypeptide chains or fragments of molecular weights 75,000, 40,000, and 28,000. The largest and smallest chains contained carbohydrate. HNP had a molecular weight of 141,000 and fragments of molecular weights 60,000, 38,000, 26,000, and 17,000 in equimolar ratio; the two smallest fragments contained carbohydrate. Plasmin digestion of pro-HNP showed that the 75,000-Da chain, identical with the intact beta-chain of C3, broke down to the 60,000- and 17,000-Da fragments of HNP. In both pro-HNP and HNP, the polypeptide chains were linked by disulfide bonds, with the exception of the 17,000-Da fragment of HNP. This fragment was readily dissociated from the rest of the HNP molecule in the presence of sodium dodecyl sulfate. Amino acid analyses showed that both pro-HNP and HNP contained approximately 22 half-cystine residues per molecule. Extinction coefficients, epsilon 1% 1cm, at 280 nm were calculated to be 8.5 and 8.8 for pro-HNP and HNP, respectively.     

Identification of the C3b receptor-binding domain in third component of complement

We report here that complement receptor type one (CR1) binds to a region of C3b that is contained within the NH2 terminus of the alpha' chain. In an enzyme-linked immunosorbent assay, CR1 bound to C3b, iC3b, and C3c but not to C3d, and this binding was inhibited by soluble C3b and C3c. Further attempts to generate a small C3 fragment capable of binding CR1 were unsuccessful. However, elastase degradation of C3 generated four species of C3c (C3c I-IV), two of which bound CR1. NH2-terminal sequence analysis and sodium dodecyl sulfate-gel electrophoresis of the C3cs indicated that the beta chains and the 40,000-dalton COOH-terminal alpha' chain fragments were identical; the NH2-terminal alpha' chain fragments of C3c I-IV varied from 21,000 to 27,000 daltons and accounted for the differential binding to CR1. C3c-I and II, which do not bind CR1, were missing 8 and 9 residues from the NH2 terminus of the alpha' chain when compared with the intact alpha' chain of C3b. C3c-III and IV, which bind CR1, had NH2 termini identical to the intact NH2-terminal alpha' chain of C3b. Using iodinated concanavalin A and endoglycosidase H, we showed that the NH2-terminal alpha' chains of C3c-I and III were glycosylated, while C3c-II and IV were not. Therefore, these data indicated that the amino terminus of the NH2-terminal alpha' chain fragment of C3c was responsible for binding CR1 while the COOH terminus of this fragment was not involved since the presence or absence of this region in C3c did not affect CR1 binding to C3c. Subsequently, two peptides were synthesized from the NH2-terminal alpha' chain fragment of C3c: X42, 42 residues in length from the NH2 terminus and C30, 30 residues in length from the COOH terminus. X42 inhibited binding of CR1 to C3b, and this effect was also observed with antipeptide antibodies against the X42 peptide. The C30 and other C3-derived peptides and antipeptide antibodies had no effect on the binding of CR1 to C3b.     

Inhibition of secondary in vitro antibody responses by the third component of complement

Purified human C3 was found to inhibit rat in vitro secondary antibody responses. Fifty percent inhibition of antibody-forming cell development occurred with C3 concentrations of 26 micrograms/ml. This decrease was not the result of a general toxicity or a shift in the antibody response kinetics. Using cell mixing experiments, we could not detect a C3-induced suppressor lymphocyte or macrophage. C3 was active when added to culture early (day 0 or 1 or during a 24-hr antigen prepulse) or late (day 3, 5, or 7)--the early addition being more suppressive. Regardless of the addition time, there was a characteristic 48- to 72-hr lag before the inhibitory effect was manifested. C3 could inhibit antibody-forming cell development after stimulation with the thymus-independent antigens, trinitrophenyl-Brucella abortus and dinitrophenyl-Ficoll, as well as the thymus-dependent antigens, dinitrophenyl-bovine gamma-globulin and chicken gamma-globulin suggesting that C3 was not selective for B memory cell subpopulations. Further characterization of our C3 preparation indicated that the majority of the suppressive activity resided in a small m.w. protein resembling the C3a fragment of C3. Human C3a preparations generated either by trypsin cleavage or zymosan activation of C3 were also tested in our antibody response system and were able to inhibit antibody-forming cell development. These data implicate C3 cleavage products as negative regulators of antibody formation.