The frequent variations of human complement component C4 gene size and gene numbers, plus the extensive polymorphism of the proteins, render C4 an excellent marker for major histocompatibility complex disease associations. As shown by definitive RFLPs, the tandemly arranged genes RP, C4, CYP21, and TNX are duplicated together as a discrete genetic unit termed the RCCX module. Duplications of the RCCX modules occurred by the addition of genomic fragments containing a long (L) or a short (S) C4 gene, a CYP21A or a CYP21B gene, and the gene fragments TNXA and RP2. Four major RCCX structures with bimodular L-L, bimodular L-S, monomodular L, and monomodular S are present in the Caucasian population. These modules are readily detectable by TaqI RFLPs. The RCCX modular variations appear to be a root cause for the acquisition of deleterious mutations from pseudogenes or gene segments in the RCCX to their corresponding functional genes. In a patient with congenital adrenal hyperplasia, we discovered a TNXB-TNXA recombinant with the deletion of RP2-C4B-CYP21B. Elucidation of the DNA sequence for the recombination breakpoint region and sequence analyses yielded definitive proof for an unequal crossover between TNXA from a bimodular chromosome and TNXB from a monomodular chromosome.Besides the immunoglobulins, complement component C4 is probably the most polymorphic serum protein. There are two isotypes, C4A and C4B, that manifest remarkable differences in chemical reactivities and serological properties (reviewed in Ref. 1). More than 34 allotypes for C4A and C4B have been demonstrated by agarose gel electrophoresis, based on gross differences in electric charge (2). Similar to the protein, the complement C4 genes are unusually complex with frequent variations in gene size and gene number. In addition, the genes surrounding C4A or C4B also exhibit considerable variations. These neighboring genes include RP1 or RP2 at the 5Ј region, CYP21A, or CYP21B and TNXA or TNXB at the 3Ј region ( Fig.
The human complement components C4A and C4B are highly homologous proteins, but they show markedly different, class‐specific, chemical reactivities. They also differ serologically in that C4A generally expresses the Rodgers (Rg) blood group antigens while C4B generally expresses the Chido (Ch) blood group antigens. C4A 1 and C4B 5 are exceptional variants which possess their class‐specific chemical reactivities, but express essentially the reversed antigenicities. The genes encoding the typical Rg‐positive C4A 3a and Ch‐positive C4B 3 allotypes and the interesting variants C4A 1 and C4B 5 have been cloned. Characterization of the cloned DNA has revealed that the genes encoding the A 3a, A 1 and B 3 allotypes are 22 kb long, but that encoding B 5 is only 16 kb long. Comparison of derived amino acid sequences of the polymorphic C4d fragment has shown that C4A and C4B can be defined by only four isotypic amino acid differences at position 1101‐1106. Over this region C4A has the sequence PCPVLD while C4B has the sequence LSPVIH, and this presumably is the cause of their different chemical reactivities. Moreover, the probable locations of the two Rg and the six Ch antigenic determinants have been deduced. Our structural data on the C4A and C4B polymorphism pattern suggests a gene conversion‐like mechanism is operating in mixing the generally discrete serological phenotypes between C4A and C4B.
It was observed about 50 years ago that low serum complement activity or low protein concentrations of complement C4 concurred with disease activities of systemic lupus erythematosus (SLE). Complete deficiencies of complement components C4A and C4B, albeit rare in human populations, are among the strongest genetic risk factors for SLE or lupus-like disease, across HLA haplotypes and racial backgrounds. However, whether heterozygous or partial deficiency of C4A (C4AQ0) or C4B (C4BQ0) is a predisposing factor for SLE has been a highly controversial topic. In this review we critically analyzed past epidemiologic studies on deficiency of C4A or C4B in human SLE. Cumulative results from more than 35 different studies revealed that heterozygous and homozygous deficiencies of C4A were present in 40-60% of SLE patients from almost all ethnic groups or races investigated, which included northern and central Europeans, Anglo-Saxons, Caucasians in the US, African Americans, Asian Chinese, Koreans and Japanese. In addition, French SLE and control populations had relatively low frequencies of C4AQ0, but the difference between the patient and control groups was statistically significant. The relative risk of C4AQ0 in SLE varied between 2.3 and 5.3 among different ethnic groups. In Caucasian and African SLE patients, the two major causes for C4AQ0 are (1) the presence of a mono-S RCCX (RP-C4-CYP21-TNX) module with a single, short C4B gene in the major histocompatibility complex; and (2) a 2-bp insertion into the sequence for codon 1213 at exon 29 of the mutant C4A gene. Both mono-S structures and 2-bp insertion in exon 29 are absent or extremely rare in the C4AQ0 of Oriental SLE patients. The highly significant association of C4AQ0 with SLE across multiple HLA haplotypes and ethnic groups, and the presence of different mechanisms leading to a C4A protein deficiency among SLE patients suggested that deficiency or low expression level of C4A protein is a primary risk factor for SLE disease susceptibility per se. On the other hand, Spanish, Mexican, Australian Aborigine SLE patients had increased frequencies of C4B deficiency instead of C4A deficiency. Such observations underscore the importance of both C4A and C4B proteins in the fine control of autoimmunity. Different racial and genetic backgrounds could change the thresholds for the requirement of C4A or C4B protein levels in immune tolerance and immune regulation. Most past epidemiological studies of C4 in human SLE did not consider the polygenic and gene size variations of C4A and C4B. In addition, many studies were overly dependent on phenotypic observations or methods that did not distinguish differential C4A and C4B protein expression caused by unequal gene number or different gene size from the absence of a functional C4A or C4B gene. For further longitudinal studies on clinical manifestations of SLE, it would be informative to stratify the patients with accurately defined C4A and C4B genotypes. Likewise, elucidation of epistatic genetic factors interacting with C4AQ0 wou...
2DeCeaSed Communicated by A.F.Williams 21-Hydroxylase deficiency which causes congenital adrenal hyperplasia is one of the most common defects of adrenal steroidogenesis. There are two 21-hydroxylase genes in man, A and B, and these have been mapped to the HLA class HI region. Only the 21-hydroxylase B gene is thought to be active. To understand the molecular basis of congenital adrenal hyperplasia in a patient with the salt-wasting form of the diseas, we cloned and characterized his single 21-hydroxylase B gene. The nucleotide sequence of this gene and a 21-hydroxylase B gene from a normal individual have been determined. Comparison of the two sequences has revealed 11 nucleotide alterations, of which two are in the 5' flanking region, four are in introns, one is in the 3' untranslated region and four are in exons. Two of the differences in exons cause codon changes, with Ser-269 and Asn494 in the normal 21-hydroxylase B gene being converted to Thr and Ser, respectively. These amino acid substitutions may give an insight into those residues necessary for 21-hydroxylase enzymatic activity. We have also confirmed that the 21-hydroxylase A gene is a pseudogene due to three deleterious mutations in the exons. In addition, comparison of the 21-hydroxylase B gene sequence with other published sequences indicates that this microsomal cytochrome P450 may be polymorphic.
This unit describes methods that can accurately determine the genotypes and phenotypes of human complement components C4A and C4B. Specifically, they allow investigators to determine how many C4 genes are present in a diploid genome of a human subject and to quantify how many of them encode C4A proteins and how many of them encode C4B proteins. In addition, methods to determine how many long and short C4 genes are present in a diploid genome of a subject are described together with experimental strategies to determine haplotypes and order or configuration of these genes in the MHC. Finally, methods to assess the degree of polymorphism in C4A and C4B proteins and whether low protein levels of plasma C4 may be caused by low C4 gene dosages and/or by mutant C4 genes.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.