Fourth Component Of Human Complement Research Articles

Copy Number Analysis of Complement C4A, C4B and C4A Silencing Mutation by Real-Time Quantitative Polymerase Chain Reaction

Low protein levels and copy number variation (CNV) of the fourth component of human complement (C4A and C4B) have been associated with various diseases. High-throughput methods for analysing C4 CNV are available, but they commonly do not detect the most common C4A mutation, a silencing CT insertion (CTins) leading to low protein levels. We developed a SYBR® Green labelled real-time quantitative polymerase chain reaction (qPCR) with a novel concentration range approach to address C4 CNV and deficiencies due to CTins. This method was validated in three sample sets and applied to over 1600 patient samples. CTins caused C4A deficiency in more than 70% (76/105) of the carriers. Twenty per cent (76/381) of patients with a C4A deficiency would have been erroneously recorded as having none, if the CTins had not been assessed. C4A deficiency was more common in patients than a healthy reference population, (OR = 1.60, 95%CI = 1.02–2.52, p = 0.039). The number of functional C4 genes can be straightforwardly analyzed by real-time qPCR, also with SYBR® Green labelling. Determination of CTins increases the frequency of C4A deficiency and thus helps to elucidate the genotypic versus phenotypic disease associations.

Transcriptional Repression of C4 Complement by Hepatitis C Virus Proteins

The fourth component of human complement (C4) plays an important role in innate immune function. C4 activity has been observed to be significantly lower in patients with chronic hepatitis C virus (HCV) infections, although the mechanism remains unknown. In this study, we have examined the mechanisms of C4 regulation by HCV. Liver biopsy specimens from patients with chronic HCV infections displayed significantly lower C4 mRNA levels than liver tissue samples from patients with unrelated liver disease. Further, C4 mRNA levels of the two isoforms (C4A and C4B) were significantly reduced in hepatocytes transfected with RNA from HCV genotype 1a or 2a. Subsequently, a significant C4 regulatory role of HCV core or NS5A upon C4 promoter activity was observed. HCV core or NS5A transgenic mice displayed a reduction in C4 mRNA. Gamma interferon (IFN-γ)-induced C4 promoter activation was also impaired in the presence of HCV proteins. We further demonstrated that HCV core reduced the expression of upstream stimulating factor 1 (USF-1), a transcription factor important for basal C4 expression. On the other hand, the expression of interferon regulatory factor 1 (IRF-1), which is important for IFN-γ-induced C4 expression, was inhibited by hepatocytes expressing HCV NS5A. These results underscore the roles of HCV proteins in innate immune regulation in establishing a chronic infection.

Quantitative analysis of C4Ab and C4Bb binding to the C3b/C4b receptor (CR1, CD35).

Complement-dependent clearance of immune complexes in humans is dependent on the activation and binding of the early components of the classical complement cascade. This prevents immune complex precipitation and promotes binding of the complexes by the C4b/C3b complement receptor CR1 (CD35) found on erythrocytes. The fourth component of human complement is encoded by two closely linked genes within the MHC. These genes give rise to the isotypic forms C4A and C4B, and recent studies suggest that CR1 binds activated C4A (C4Ab) to a greater extent than activated C4B (C4Bb). To study this difference in a more quantitative way the binding reactions between CR1 and C4Ab- and C4Bb-coated immune complexes and between CR1 and soluble dimers of C4Ab (C4Ab2) and C4Bb (C4Bb2) were analysed using the native receptor on human erythrocytes. The binding reaction between immune complexes with equivalent amounts of covalently bound C4Ab or C4Bb and erythrocyte CR1 showed a two-fold higher binding of complexes coated with C4A. Furthermore, erythrocyte CR1 bound C4Ab2 with an apparent four-fold higher affinity (Kd approximately 1.4 x 10(-7) M) than C4Bb2 (Kd approximately 4.8 x 10(-7) M), indicating a preferential binding of CR1 for C4A.

Real-time PCR quantification of human complement C4A and C4B genes

BackgroundThe fourth component of human complement (C4), an essential factor of the innate immunity, is represented as two isoforms (C4A and C4B) in the genome. Although these genes differ only in 5 nucleotides, the encoded C4A and C4B proteins are functionally different. Based on phenotypic determination, unbalanced production of C4A and C4B is associated with several diseases, such as systemic lupus erythematosus, type 1 diabetes, several autoimmune diseases, moreover with higher morbidity and mortality of myocardial infarction and increased susceptibility for bacterial infections. Despite of this major clinical relevance, only low throughput, time and labor intensive methods have been used so far for the quantification of C4A and C4B genes.ResultsA novel quantitative real-time PCR (qPCR) technique was developed for rapid and accurate quantification of the C4A and C4B genes applying a duplex, TaqMan based methodology. The reliable, single-step analysis provides the determination of the copy number of the C4A and C4B genes applying a wide range of DNA template concentration (0.3–300 ng genomic DNA). The developed qPCR was applied to determine C4A and C4B gene dosages in a healthy Hungarian population (N = 118). The obtained data were compared to the results of an earlier study of the same population. Moreover a set of 33 samples were analyzed by two independent methods. No significant difference was observed between the gene dosages determined by the employed techniques demonstrating the reliability of the novel qPCR methodology. A Microsoft Excel worksheet and a DOS executable are also provided for simple and automated evaluation of the measured data.ConclusionThis report describes a novel real-time PCR method for single-step quantification of C4A and C4B genes. The developed technique could facilitate studies investigating disease association of different C4 isotypes.

Structural comparison of human C4A3 and C4B1 after proteolytic activation by C1s

The fourth component of human complement is an essential part of the classical and lectin pathways performing multifunctional roles in both host defense and immune regulation. C4 is the most polymorphic member of the complement proteins, and complete deficiency is strongly associated with autoimmune disease, especially, systemic lupus erythematosus (SLE). Of the two C4 genes C4A, but not C4B, null alleles have been implicated as important independent disease susceptibility genes occurring in more than half of SLE patients. Whether and how this deficiency contributes to the development or pathology remains unclear. We do know that activation of C4 by C1s cleaves the thioester bond, thus inducing a conformational change that exposes numerous ligand-binding sites involved in functional activity. Structural comparison, among many other tools, plays an important role in predicting function. In this report, the tertiary structures of C4A and C4B were compared using near and far-UV circular dichroism, ANS fluorescence, site-specific monoclonal antibodies and isoelectric focusing. Negligible differences in the native proteins were found. However, the activated proteins were dissimilar in secondary and tertiary structure that was accompanied by significant differences in charge distribution and surface hydrophobicity. These conformational differences, together with known acceptor preferences, have functional implications for the association between C4A null alleles and SLE.

The role of Sp family members, basic Kruppel-like factor, and E box factors in the basal and IFN-gamma regulated expression of the human complement C4 promoter.

The fourth component of human complement (C4) is a serum protein that is expressed in the liver and other organs. The promoter region of the C4 gene has been analyzed in reporter gene assays in two cell lines that represent hepatic (HepG2) and monocytic (U937) lineages. Analysis indicated that regions important for basal transcription in HepG2 cells included Sp1 and E box sites within the first 100 bp upstream of the transcription initiation site but not the nuclear factor-1 site important in the control of the mouse C4 gene. Also, a region encompassing -468 to -310 was able to repress activity 2-fold. However, when a CACCC or GT box sequence at -140 was mutated the repressive activity of the upstream region resulted in almost no activity. The -140 region consists of a series of four closely positioned GT boxes that were shown to bind Sp1, Sp3, and basic Krupple-like factor in EMSA. This novel two-part regulatory element may be involved in the regulated expression of C4. However, IFN-gamma a major activator of C4 expression did not signal through this two-part regulatory element. We were able to map the position of an IFN-gamma responsive element in U937. IFN-gamma was able to increase transcription by up to 20-fold with mutations in the E box sequence at -78 to -73, thus completely abolishing induction. We conclude that the E box binding factors, which appear to be distinct from upstream stimulatory factors 1 and 2, are totally responsible for IFN-gamma induction of C4.

Genetic polymorphism of the fourth component of human complement: population study and proposal for a revised nomenclature based on genomic PCR typing of Rodgers and Chido determinants.

The fourth component of human complement (C4) is coded for by two homologous genes, C4A and C4B, located in the class III region of the major histocompatibility complex (MHC). Genetic typing of C4A and B alleles is routinely carried out by high-voltage agarose gel electrophoresis. The electrophoretic C4 polymorphism can be further subdivided by the Rodgers (Rg) and Chido (Ch) blood groups, which are antigenic determinants of the C4A and B alpha-chains, respectively. We have used a recently described direct PCR typing method using sequence-specific primers (PCR-SSP) in combination with electrophoretic C4 typing as well as genomic RFLP analysis to determine the frequency of C4 allotypes, Rg/Ch subtypes and C4A-B haplotypes in a family study of the German population. As the current C4 allele designation does not provide any information about the presence or absence of Rodgers and Chido antigens, we have developed an extension to the existing C4 nomenclature. This revised allele designation combines the existing numerical allotypes defined by electrophoretic mobility with eight subtypes (01-08) based on Rg/Ch PCR genotyping results. Using this approach, most electrophoretic allotypes could be subdivided. Among the C4A allotypes, the most common allele was A*0301 (59.9%), and the most common subtype among all electrophoretic allotypes was 01 (85.1%; = Rg1,2-positive, Ch-negative). For C4B, the most common allele was B*0101 (64.3%), and the most common subtype was 01 (79.6%; = Ch1,2,3,4,5,6-positive, Rg-negative). The subtypes 03, 04, 07 and 08 of the C4A allotypes, and the subtypes 03, 07 and 08 of the C4B allotypes, were not detected in this study. The analysis of duplicated C4 alleles revealed considerable heterogeneity of their subtypes. The results demonstrate that all known C4 allotypes can now be assigned unambiguously, which facilitates the identification of MHC haplotypes relevant for transplantation and disease association studies.

Sequences Promoting the Transcription of the Human XA Gene Overlapping P450c21A Correctly Predict the Presence of a Novel, Adrenal-Specific, Truncated Form of Tenascin-X

A compact region in the human class III major histocompatibility locus contains the human genes for the fourth component of human complement (C4) and steroid 21-hydroxylase (P450c21) in one transcriptional orientation, while the gene for the extracellular matrix protein tenascin-X (TN-X) overlaps the last exon of P450c21 on the opposite strand of DNA in the opposite transcriptional orientation. This complex locus is duplicated into A and B loci, so that the organization is 5′-C4A-21A-XA-C4B-21B-XB-3′. Although this duplication event truncated the 65-kb X(B) gene to a 4.5-kb XA gene, the XA gene is transcriptionally active in the adrenal cortex. To examine the basis of the tissue-specific expression of XA and C4B, we cloned the 1763.bp region that lies between the cap sites for XA and C4B and analyzed its promoter activity in both the XA and the C4 orientations. Powerful, liver-specific sequences lie within the first 75 to 138 bp from the C4B cap site, and weaker elements lie within 128 bp of the XA cap site that function in both liver and adrenal cells. Because these 128 bp upstream from the XA cap site are perfectly preserved in the XB gene encoding TN-X, we sought to determine whether a transcript similar to XA arises within the XB gene. RNase protection assays, cDNA cloning, and RT/PCR show that adrenal cells contain a novel transcript, termed short XB (XB-S), which has the same open reading frame as TN-X. Cell-free translation and immunoblotting show that this transcript encodes a novel 74-kDa XB-S protein that is identical to the carboxy-terminal 673 residues of TN-X. Because this protein consists solely of fibronectin type III repeats and a fibrinogen-like domain, it appears to correspond to an evolutionary precursor of the tenascin family of extracellular matrix proteins.

Polymerase chain reaction analysis of the Xba I polymorphism of the human complement C4 genes provides evidence for strong haplotype conservation

The genes coding for the two isotypes of the fourth component of human complement, C4A and C4B, are located between the HLA-B and -DR loci of the MHC. We studied the linkage relationship of the previously described XbaI RFLP to obtain further insight into the evolution of the tandemly arranged C4 genes. Using exon-specific PCR amplification followed by restriction analysis and direct DNA sequencing, the polymorphic site could be located in exon 40 of the C4 gene (cDNA position 5095). The polymorphism does not change an amino acid residue. Using nested PCR amplification with isotype-specific primers to amplify either C4A or C4B alleles the haplotype arrangement of the XbaI sites in both isotypic C4 genes was analyzed independently. It was observed that the XbaI restriction site was either present or absent in both C4 genes of a given haplotype. In a study of 106 Caucasian haplotypes, only two different haplotypes could be identified carrying a C4A gene with and a C4B gene without the XbaI restriction site. Also, the XbaI site could only be detected in long C4 genes possessing the 6.5-kb insertion in intron 9. Our findings provide evidence that the mutation creating the XbaI polymorphism occurred in an ancestral C4 gene already carrying the long intron 9. The duplicating resulting in the presence of two isotypic genes, C4A and C4B, must have taken place subsequently giving rise to haplotypes with or without the XbaI site.

Evidence showing that the 1105 and 1106 isotypic residues of the fourth component of human complement, C4A, are not involved in amide bond formation

Human C4A and C4B have different functions that may stem from their ability to bind hydroxyl or free amino groups on complement activating surfaces. Previous studies suggest that C4B binds to hydroxyl or amino groups whereas C4A binds to free amino groups on acceptor molecules. Comparison of the derived amino acid sequences of C4A and C4B has shown that differences exist between them at positions 1101, 1102, 1105 and 1106. These residues appear to be involved in the binding specificity of C4B. Less is known about the corresponding residues of C4A. It has been suggested that the aspartic acid of C4A at position 1106 is involved in amide bond formation by serving as a catalytic residue for the reaction or by promoting an increased interaction with amino nucleophilic groups. To examine the functional role of residues 1101–1106, we studied the effects of the C4A site-specific antipeptide mAb, AII-1 in assays dependent on the covalent binding properties of C4A; the C4 mediated inhibition of hemolysis and the C4 mediated inhibition of immune precipitation. This study shows that mAb AII-1 has no effect on C4-mediated hemolysis or its ability to inhibit the rate of immune precipitate formation. The lack of interference by AII-1 in these assays could not be explained by low affinity interaction between antibody and C4A showing that mAb AII-1 does not affect the covalent binding activity of C4A. Furthermore, results from epitope mapping studies show that AII-1 binds to Leu 1105 and Asp 1106 suggesting that these residues are not critical for amide bond formation by C4A.

Interferon-gamma regulation of C4 gene expression in cultured human glomerular epithelial cells.

The fourth component of human complement is mainly produced in liver, but extrahepatic gene expression has been reported in human renal tissue and other tissues, and is thought to contribute to the inflammatory reaction in local tissue. To identify the cellular origin of C4 synthesis in human kidney, we studied C4 gene expression and regulation by interferon-gamma (IFN-gamma) and C4 protein biosynthesis in isolated glomerular epithelial cells. cDNA/polymerase chain reaction analysis showed that C4 transcripts are present in glomerular epithelial cells (GEC), and that gene expression is up-regulated by IFN-gamma. Metabolic labeling studies showed that GEC synthesize and secrete C4 as three polypeptide chains of approximately 90, 70, and 30 kDa, which correspond to the bands produced by hepatoma cells. These results suggest that the fourth component of complement is produced by GEC. The GEC has an important role in the maintenance of glomerular barrier function, which is lost in a number of complement-dependent conditions; glomerular epithelial synthesis of C4 could have a bearing on the possible physiological or pathological roles of complement under different circumstances.

Identification of a surface structure in the fourth component of human complement, C4, which becomes hidden upon activation by C1(-)s.

Treatment of complement component C4 with C1(-)s and methylamine induces a series of conformation changes such as to generate functional binding sites. A monoclonal antibody (mAb), Al 121/6, which does not inhibit the haemolytic activity of C4 was found to bind to native C4 and C4d, but not to C4b and methylamine-treated C4, unless these C4 derivatives were denatured. These results suggested that a linear epitope for mAb Al 121/6 in the C4d domain is originally located at the surface of C4 and becomes hidden as a result of conformational changes induced by C1(-)s or methylamine treatment. The hidden linear epitope was exposed again upon further cleavage of C4b into C4c and C4d. Trypsin digestion of C4d and its chemical modification with phthalic anhydride suggested that the epitope is located at the C-terminal 13 kDa region of C4d and that lysine residues are involved in the epitope. There is a single lysine residue at 1259 in the 13 kDa C-terminal side of C4d and the synthetic undecapeptide Leu1254-Asp1264 was found to inhibit the binding of C4 to mAb Al 121/6, suggesting that the epitope for mAb Al 121/6 is involved in the sequence. The N-terminal portion of the peptide is partly overlapping, with a highly hydrophobic amino acid sequence spanning residues Ala1249-Leu-Leu-His-Leu-Leu-Leu1255. The surface hydrophobicity of C4 has been reported to decrease upon treatment with C1(-)s and methylamine. So it appears that the hydrophobic sequence spanning Ala1249-Leu1255 may be hidden, together with the linear epitope, into the inner region of C4 upon treatment with C1s and methylamine.

Separation of different forms of the fourth component of human complement by fast protein liquid chromatography

Disruption of the thiolester in native C4 yields a ‘C4b-like C4’ molecule (iC4) that functionally resembles C4b and is therefore probably accompanied by conformational changes in the C4 molecule. In most purified C4 preparations, iC4 and C4b are present to a variable extent. In this study we evaluated the use of fast protein liquid chromatography (FPLC) to resolve and isolate these various forms of C4. C4 was purified from fresh human plasma in a 4-step procedure that included barium citrate adsorption, polyethylene glycol 6000 (PEG) precipitation, Q-Sepharose Fast Flow and mono Q ion exchange chromatography. The final preparation appeared to be homogeneous on SDS-PAGE and under reducing conditions consisted of three bands that corresponded to the intact α, β and γ chains of C4. In some preparations the α′ chain of C4b was also observed. On a Mono Q column the purified C4 preparations could be separated into three peaks that by hemolytic assay and SDS-PAGE were characterized as representing native C4, and monomeric and dimeric iC4 (or monomeric and dimeric C4b). Finally, the apparent K A of the various forms of C4 for C4b-binding protein (C4BP) was investigated. The monomeric iC4 and C4b species demonstrated similar C4BP binding affinity with an apparent K A of 5.6–6.4 × 10 8 M −1, whereas their dimeric forms demonstrated a higher affinity for C4BP with an apparent K A: 0.9–2.3 × 10 9 M −1. Binding of native C4 to C4BP was undetectable.

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°C increased C-mediated hemolysis of antibody-sensitized sheep erythrocytes 1.54- to 1.93-fold. Comparative studies of T max of human C2, using asialo-C4 or buffer-treated C4 on {ieEAC1gp} and extrapolation to time 0 indicated a z value 4-fold higher with asialo-C4. This indicated that more hemolytically active {ieC42} complexes are available with sialidase-treated C4 compared to untreated C4. There was no appreciable difference in the % 125I-C4 bound to {ieEAC1gp} (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, AQO; 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 C4B 1.

In vivo and in vitro binding of C4 molecules on red cells: a correlation of numbers of molecules and agglutination

The fourth component of human complement (C4) is one that is essential to the antibody-mediated classical activation pathway. C4d, present on all normal and most patient red cells (RBCs), may be detected by the human antisera anti-Rodgers (Rg) and -Chido (Ch). A study has been made of the Rg/Ch antigens on normal and patient RBCs in an attempt to understand the mechanism by which C4 is bound to normal RBCs in the absence of RBC antibodies (Abs). Because RBCs from C1q-deficient patients express Rg/Ch, it seems that C1q is not essential for C4 binding. Treatment of normal RBCs with proteolytic enzymes, including trypsin, eliminated positive reactions with anti-Rg/Ch even though the C4d fragment is considered to be resistant to cleavage by trypsin. By correlating agglutination reactions with numbers of bound C4d and C3d molecules, it is evident that both C4d and C3d were affected by trypsin treatment and that anti-Rg/Ch were not capable of agglutinating RBCs with less than 50 molecules of bound C4d. It is concluded that trypsin-sensitive and -insensitive RBC membrane structures may both act as acceptors for C4. RBCs with null phenotypes of the major blood group systems all expressed Rg/Ch antigens, so none of the structures that carry these antigens act preferentially as acceptors for C4.

Associations between restriction fragment length polymorphisms detected with a probe for human C4 and allotype of C4B5 allele

We studied the fourth component of human complement (C4) allotypes in 58 Japanese individuals. The technique of Southern, with C4 and 21-OH cDNA probes, was used to examine the genomic DNA of 45 individuals typed for C4 by protein electrophoresis. Novel HindIII C4 10- and 5-kb and EcoRI C4 13-Kb restriction fragments were identified in each of nine Japanese individuals. The novel fragments were different from the previously described C4B long (HindIII 31-kb, TaqI 6-kb, BamHI 4.3-kb, and EcoRI 12-kb) and C4B short (HindIII 25-kb, TaqI 5.4-kb, BamHI 3.5-kb, and EcoRI 15-kb) fragments. All novel HindIII- and EcoRI-positive individuals carried C4B5, BfS, and HLA-Bw54. Therefore, the fragments were characteristic for the C4B5 allele. The C4 region was analyzed to determine the restriction sites by single and double digests of uncloned genomic DNA with several restriction endonucleases. It is speculated that an insertion gene lies between the 3' end of the 21-OH and the 5' end of the C4B genes.

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.

C4 DNA RFLP Reference Typing Report

One hundred and three individual DNA samples (including 23 families) were studied at the gene level during the reference typing of the fourth component of human complement at the VIth Complement Genetics Workshop in Mainz (1989). All samples were analyzed with the restriction enzyme Taq I and with two DNA probes recognizing the 5' ends of both C4 genes and the two adjacent 21-hydroxylase genes. This RFLP is informative for the number of C4 genes as well as for their respective gene size. We found a high degree of variation regarding the number of C4 genes, i.e. haplotypes with 1-3 structural C4 genes of 16 or 22 kb size. By correlating these haplotypes to the complotypes obtained by protein typing for C2, BF and C4, it became evident that only minor variation of the C4 gene structure within a given complotype is present.

Null alleles of human complement C4. Evidence for pseudogenes at the C4A locus and for gene conversion at the C4B locus.

The two genes for the C4A and C4B isotypes of the fourth component of human complement are located in the MHC class III region. Previous studies have demonstrated the unusual expression of C4 genes in the form of aberrant or duplicated haplotypes. Null alleles of C4A or C4B (AQ0 or BQ0) have been defined by the absence of gene products and occur at frequencies of 0.1-0.3. However, only some C4 null alleles are due to gene deletions, the remainder were thought to be nonexpressed genes. We have analyzed the C4 gene structure of 26 individuals lacking either C4A or C4B protein. The DNA of individuals with apparently nonexpressed C4 genes was tested for the presence of C4A- and C4B-specific sequences using restriction fragment analysis and isotype-specific oligonucleotide hybridization of DNA amplified by polymerase chain reaction. All nondeleted AQ0 allels had C4A-specific sequences and may thus be described as pseudogenes, whereas the nondeleted BQ0 alleles had C4A-instead of C4B-specific sequences. Gene conversion is the probable mechanism by which a C4A gene is found at the second C4 locus normally occupied by C4B genes.

Sandwich enzyme-linked immunosorbent assays for the quantification of the C4 isotypes (C4A and C4B) in human plasma

Sandwich enzyme-linked immunosorbent assays were developed to determine the concentration of the isotypes of the fourth component of human complement (C4A and C4B) in human plasma. In the case of C4A a monoclonal antibody against a common determinant of the α chain was used to capture the protein. The bound antigen was then detected with a biotinylated monoclonal antibody reacting exclusively with the C4A isotype, followed by peroxidase labeled avidin. For the quantification of C4B, C4B-specific monoclonal antibodies were coated onto a microtitration plate in order to capture the protein. Bound antigen was then detected with a biotinylated monoclonal antibody directed against C4 followed by peroxidase labeled avidin. The assays, which were rapid, selective and specific for C4A and C4B, respectively, provide an alternative to gel electrophoresis and blot procedures for the study of unexpressed alleles (‘null alleles’) at each of the C4 loci.