Multiple duplications of complement C4 gene correlate with H-2-controlled testosterone-independent expression of its sex-limited isoform, C4-Slp

Mutations in CPAMD8 Cause a Unique Form of Autosomal-Recessive Anterior Segment Dysgenesis

Anterior segment dysgeneses (ASDs) comprise a spectrum of developmental disorders affecting the anterior segment of the eye. Here, we describe three unrelated families affected by a previously unclassified form of ASD. Shared ocular manifestations include bilateral iris hypoplasia, ectopia lentis, corectopia, ectropion uveae, and cataracts. Whole-exome sequencing and targeted Sanger sequencing identified mutations in CPAMD8 (C3 and PZP-like alpha-2-macroglobulin domain-containing protein 8) as the cause of recessive ASD in all three families. A homozygous missense mutation in the evolutionarily conserved alpha-2-macroglobulin (A2M) domain of CPAMD8, c.4351T>C (p. Ser1451Pro), was identified in family 1. In family 2, compound heterozygous frameshift, c.2352_2353insC (p.Arg785Glnfs^∗23), and splice-site, c.4549-1G>A, mutations were identified. Two affected siblings in the third family were compound heterozygous for splice-site mutations c.700+1G>T and c.4002+1G>A. CPAMD8 splice-site mutations caused aberrant pre-mRNA splicing in vivo or in vitro. Intriguingly, our phylogenetic analysis revealed rodent lineage-specific CPAMD8 deletion, precluding a developmental expression study in mice. We therefore investigated the spatiotemporal expression of CPAMD8 in the developing human eye. RT-PCR and in situ hybridization revealed CPAMD8 expression in the lens, iris, cornea, and retina early in development, including strong expression in the distal tips of the retinal neuroepithelium that form the iris and ciliary body, thus correlating CPAMD8 expression with the affected tissues. Our study delineates a unique form of recessive ASD and defines a role for CPAMD8, a protein of unknown function, in anterior segment development, implying another pathway for the pathogenicity of ASD.

Dancing with complement C4 and the RP-C4-CYP21-TNX (RCCX) modules of the major histocompatibility complex

The number of the complement component C4 genes varies from 2 to 8 in a diploid genome among different human individuals. Three quarters of the C4 genes in Caucasian populations have the endogenous retrovirus, HERV-K(C4), in the ninth intron. The remainder does not. The C4 serum proteins are highly polymorphic and their concentrations vary from 100 to approximately 1000 microg/ml. There are two distinct classes of C4 protein, C4A and C4B, which have diversified to fulfill (a) the opsonization/immunoclearance purposes and (b) the well-known complement function in the killing of microbes by lysis and neutralization, respectively. Many infectious and autoimmune diseases are associated with complete or partial deficiency of C4A and/or C4B. The adverse effects of high C4 gene dosages, however, are just emerging, as the concepts of human C4 genetics are revised and accurate techniques are applied to distinguish partial deficiencies from differential expression caused by unequal C4A and C4B gene dosages and gene sizes. This review attempts to dissect the sophisticated genetics of complement C4A and C4B. The emphases are on the qualitative and quantitative diversities of C4 genotypes and phenotypes. The many allotypic variants and the processed products of human and mouse C4 proteins are described. The modular variation of C4 genes together with the serine/threonine nuclear kinase gene RP, the steroid 21-hydroxylase CYP21, and extracellular matrix protein TNX (RCCX modules) are investigated for the effects on homogenization of C4 protein polymorphisms, and on the unequal genetic crossovers that knocked out the functions of CYP21 and/or TNX. Furthermore, the influence of the endogenous retrovirus HERV-K(C4) on C4 gene expression and the dispersal of HERV-K(C4) family members in the human genome are discussed.

Linkage relationships of genes coding for alpha2-macroglobulin, C3 and C4 in the zebrafish: implications for the evolution of the complement and Mhc systems

The alpha2-macroglobulin (A2M) and the complement components C3 and C4 are related proteins derived from a common ancestor. Theoretically, this derivation could have occurred either by tandem duplications of their encoding genes or by polyploidization involving chromosomal segments, a chromosome or the whole genome. In tetrapods the A2M-, C3- and C4-encoding genes are generally each located on a different chromosome. This observation has been interpreted as supporting their origin by polyploidization. We identified and mapped (with the help of a radiation hybrid panel of cell lines) the A2M, C3 and C4 loci in the zebrafish, Danio rerio. Each of the three types of loci is present in the zebrafish in multiple copies, but all of the identified copies of a given type map to the same region in linkage groups 1 (C3) and 15 (A2M, C4). The A2M and C4 loci are mapped in the same region not linked to any of the class I or class II major histocompatibility complex (Mhc) loci. These observations are interpreted as supporting the origin of the A2M family of genes by tandem duplications, followed by the dispersal of the copies to different chromosomes. It is also argued that the association of C4 with the class I/II loci in tetrapods is accidental and without functional significance.

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.

The human and mouse MHC class III region: a parade of 21 genes at the centromeric segment

The human major histocompatibility complex (MHC) class III region contains 57-60 structural genes spanning 654-759 kb of genomic DNA. Analysis of the sequence identities of the human and mouse genomic regions between NOTCH4 and complement C2 yields important information on the locations of the coding and regulatory sequences. It also provides insights into the relationship between protein function and level of sequence conservation, and on the clustering of genes with related functions.

The androgen-dependent C4-Slp gene is driven by a constitutively competent promoter

The androgen-dependent liver protein Slp, together with its constitutively expressed closely related isoform C4, provides a model to address the question of which minimal alteration in DNA can shut off the expression of a gene in a manner reversible by testosterone or by trans-acting mutations. Previous work indicated that sequences located at -1.9, -0.45, and -0.25 kb from the transcription start site of the C4-Slp gene played a critical role in determining its unusual functional divergence from C4. Now, using quantitatively and qualitatively controlled transfection assays in HepG2 human hepatoma cells and mouse L fibroblasts, we have observed that the C4-Slp promoter is fully effective and unhindered by upstream sequences and that the C4 promoter has a consistent albeit modest superiority. The determinant of this nearly 2-fold difference does not coincide with the sites highlighted in previous studies but lies within the most cap-site-proximal nucleotides, at positions -189 to +48. We have also established conditions for cell-free transcription of C4 and C4-Slp from plasmid and cosmid templates by using nuclear extracts from rat and mouse liver of both sexes as well as from L cells. At variance with the rat alpha 2u-globulin gene, C4-Slp transcription in vitro does not require male factors, for it is expressed as efficiently as C4 by all nuclear extracts. Further, the minimal promoter sequences required to direct accurate initiation extend not farther than the most proximal 19 nucleotides. Because L cells efficiently express transfected cosmids covering the whole C4 gene or C4/C4-Slp recombinants, as well as plasmids carrying the C4-Slp promoter, but fail to express the full C4-Slp gene, we favor a model in which the expression of the gene is modulated intragenically.

Dating the primigenial C4-CYP21 duplication in primates

C4 and CYP21 are two adjacent, but functionally unrelated genes residing in the middle of the mammalian major histocompatibility complex (Mhc). The C4 gene codes for the fourth component of the complement cascade, whereas the CYP21 gene specifies an enzyme (cytochrome P450c21) of the glucocorticoid and mineralocorticoid pathways. The genes occur frequently in multiple copies on a single chromosome arranged in the order C4 ... CYP21 ... C4 ... CYP21. The unit of duplication (a module) is the C4-CYP21 gene pair. We sequenced the flanking regions of the C4-CYP21 modules and the intermodular regions of the chimpanzee, gorilla, and orangutan, as well as the intermodular region of an Old World monkey, the pigtail macaque. By aligning the sequences, we could identify the duplication breakpoints in these species. The breakpoint turned out to be at exactly the same position as that found previously in humans. The sequences flanking paralogous genes in the same species were found to be more similar to one another than sequences flanking orthologous genes in different species. We interpret these results as indicating that the original (primigenial) duplication occurred before the separation of apes from Old World monkeys more than 23 million years ago. The nature of the sequence at the breakpoint suggests that the duplication occurred by nonhomologous recombination. Since then, the C4-CYP21 haplotypes have been expanding and contracting by homologous crossing over which has homogenized the sequences in each species.(ABSTRACT TRUNCATED AT 250 WORDS)

The thioester and isotypic sites of complement component C4 in sheep and cattle

The region inclusive of the thioester and the isotype-determining sites of the sheep C4 genes from a single animal was amplified by polymerase chain reaction (PCR). Two bands, at 880 base pairs (bp) and 1000 bp, were resolved by agarose gel electrophoresis. Four different clones were obtained for the 880 bp (type 1) product and two from the 1000 bp (type 2) product. Two of the type 1 clones (type 1H) and both type 2 clones (type 2H) code for the PCPVIH sequence at the isotypic site whereas the other two type 1 clones (type 1D) code for the PFPVMD sequence. By restriction mapping and Southern blot analysis, there appears to be four C4 gene loci for the sheep: two type 1H, one type 1D, and one type 2H. The type 1H and type 2H genes are likely to code for proteins with C4B-like properties whereas the type 1D genes for proteins with C4A-like properties. The same region of the sheep C4 genes of nine other breeds of sheep are also amplified by PCR and analyzed by restriction mapping and Southern hybridization. Each of the sheep has type 1H, type 2H, and type 1D genes and appears to have four C4 gene loci except for the Orkney, which may have five. A single band of 880 bp was obtained from the PCR product from the genomic DNA of a single cow. Five different clones were identified, two of which code for the PFPVMD sequence and three for the PCPVIH sequence at the isotypic site, which is consistent with previous finding that C4 proteins with A- and B-like activities could be purified from the plasma of the same animal. Comparison of the nucleotide sequences of the isotype-determining region of the sheep and cattle C4 genes with those of the primates and mouse suggests that the C4A-like genes evolved independently in the primates and the ungulates.

Organization and evolution of C4 and CYP21 genes in primates: importance of genomic segments

The evolutionary relationship between two central major histocompatibility complex (MHC) genes, C4 and CYP21, was investigated by employing pulsed field gel electrophoresis (PFGE) and conventional restriction fragment length polymorphism (RFLP) analyses in human and nonhuman primates. Using Taq I in conjunction with C4 and CYP21 probes, it has been found that there are four major types of C4 genes [defined by 7.0, 6.4, 6.0, and 5.4 kilobases (kb) Taq I fragments] and two major types of CYP21 genes (3.7 and 3.2 kb fragments) in human and nonhuman primates including chimpanzee, gorilla, and orangutan. All of the eight possible combinations of C4 and CYP21 genes can be identified on one or more human ancestral haplotypes (AH). It is concluded that each of the major types of C4 and CYP21 (and each of the combinations between these) predated human speciation. PFGE analysis with Mlu I and Pvu I suggested that each C4+CYP21 segment has a specific length of 30-50 kb and that each AH carries one, two, three, or even more segments. In the case of C4, it is important to note that there is no simple relationship between the RFLP and the protein classifications. Thus, at least some of the expressed polymorphisms could be relatively recent in that they are carried by the same or different gene types. These findings are consistent with the hypothesis that MHC AHs have been formed from a large pool of specific genomic segments and that further haplospecific polymorphism has developed subsequently.

Mechanism and consequences of the duplication of the human C4/P450c21/gene X locus

The adjacent C4 and P450c21 genes encode the fourth component of serum complement and steroid 21-hydroxylase respectively, and are tandemly duplicated in the human, murine, and bovine genomes. We recently cloned a cDNA for another duplicated gene, operationally termed X, which overlaps the 3' end of human P450c21 and has the opposite transcriptional orientation. Thus, the organization of the locus is 5'-C4A-21A-XA-C4B-21B-XB-3' (Y. Morel, J. Bristow, S. E. Gitelman, and W. L. Miller, Proc. Natl. Acad. Sci. USA 86:6582-6586, 1989). To determine how this locus was duplicated, we sequenced the DNA at the duplication boundaries and the 7 kb between P450c21A and C4B comprising the XA locus. The sequences located the duplication boundaries precisely and indicate that the duplication occurred by nonhomologous recombination. The boundaries are substantially different from those of the corresponding duplication in the mouse genome, suggesting that similar gene duplications may have occurred independently in ancestors of rodents and primates after mammalian speciation. Compared with XB, the XA gene is truncated at its 5' end and bears a 121-bp intragenic deletion causing a frameshift and premature translational stop signal. Nevertheless, XA is transcribed into a stable 2.6-kb polyadenylated RNA that is expressed uniquely in the adrenal gland.

Mechanism and consequences of the duplication of the human C4/P450c21/gene X locus

The adjacent C4 and P450c21 genes encode the fourth component of serum complement and steroid 21-hydroxylase respectively, and are tandemly duplicated in the human, murine, and bovine genomes. We recently cloned a cDNA for another duplicated gene, operationally termed X, which overlaps the 3' end of human P450c21 and has the opposite transcriptional orientation. Thus, the organization of the locus is 5'-C4A-21A-XA-C4B-21B-XB-3' (Y. Morel, J. Bristow, S. E. Gitelman, and W. L. Miller, Proc. Natl. Acad. Sci. USA 86:6582-6586, 1989). To determine how this locus was duplicated, we sequenced the DNA at the duplication boundaries and the 7 kb between P450c21A and C4B comprising the XA locus. The sequences located the duplication boundaries precisely and indicate that the duplication occurred by nonhomologous recombination. The boundaries are substantially different from those of the corresponding duplication in the mouse genome, suggesting that similar gene duplications may have occurred independently in ancestors of rodents and primates after mammalian speciation. Compared with XB, the XA gene is truncated at its 5' end and bears a 121-bp intragenic deletion causing a frameshift and premature translational stop signal. Nevertheless, XA is transcribed into a stable 2.6-kb polyadenylated RNA that is expressed uniquely in the adrenal gland.

Physical mapping of the MHC and grc by pulse field electrophoresis

The development of the physical map of the major histocompatibility complex of the rat was undertaken using pulse field gel electrophoresis of fragments of genomic DNA from the BIL/2 (grc+) and BIL/1 (grc-) strains obtained primarily from single and double digests with the enzymes Mlu I, Not I, and Sfi I and hybridized with a variety of mouse, rat, and human probes. Both strains are maintained by inbreeding the BIL heterozygote (forced heterozygosity; F31); hence, their differences lie almost entirely in the MHC-grc regions. The MHC-grc region was contained in five fragments of DNA comprising 3000-3200 kilobases (kb); thus, its size appears to be closer to that of the human MHC than to that of the mouse MHC. This distance may be an underestimate of the size of the entire region, however, because the cluster of class I loci in the RT1. A region could not be defined in detail in this study. The most striking difference between the BIL/2 strain, which has normal growth and reproductive characteristics, and the BIL/1 strain, which has growth and reproductive defects and an enhanced susceptibility to chemical carcinogens, is a deletion of approximately 70 kb in the latter strain. The studies on grc+ and grc- strains suggest that the phenotypic defects of the grc- strains may be due to the loss of genes that are normally present in this deleted region.

C4 genes of the chimpanzee, gorilla, and orang-utan: evidence for extensive homogenization

The human complement component 4 is encoded in two genes, C4A and C4B, residing between the class I and class II genes of the major histocompatibility complex. The C4A and C4B molecules differ in their biological activity, the former binding more efficiently to proteins than to carbohydrates while for the latter, the opposite holds true. To shed light on the origin of the C4 genes we isolated cosmid clones bearing the C4 genes of a chimpanzee, a gorilla, and an orang-utan. From the clones, we isolated the fragments coding for the C4d part of the gene (exons and introns) and sequenced them. Altogether we sequenced eight gene fragments: three chimpanzee (Patr-C4-1*01, Patr-C4-1*02, Patr-C4-2*01), two gorilla (Gogo-C4-1*01, Gogo-C4-2*01), and three orang-utan (Popy-C4-1*01, Popy-C4-2*01, Popy-C4-3*01). Comparison of the sequences with each other and with human C4 sequences revealed that in the region believed to be responsible for the functional difference between the C4A and C4B proteins the C4A genes of the different species fell into one group and the C4B genes fell into another. In the rest of the sequence, however, the C4A and C4B genes of each species resembled each other more than they did C4 genes of other species. These results are interpreted as suggesting extensive homogenization (concerted evolution) of the C4 genes in each species, most likely by repeated unequal, homologous, intragenic crossing-over.

Differential expression of the five C4-related genes of H-2w7 mice

Mice bearing the H-2w7 haplotype have five C4-related genes, one C4, one Slp, and three C4/Slp hybrid genes. The expression of these five genes in the liver of H-2w7 mice was estimated at the steady state level of their respective mRNA. We have amplified by the polymerase chain reaction (PCR) three regions of the C4/Slp mRNA where some of these five genes show nucleotide substitution. A relative amount of each gene product was estimated by single-strand conformation polymorphism (SSCP) analysis or by direct counting of the number of respective clones after subcloning into a plasmid vector. A steady state level of the C4 mRNA was most abundant among C4-related gene transcripts. The hybrid 1 and 3 genes were expressed at a similar level which is about 1/2-1/3 of the C4 level. The hybrid 2 gene was expressed at about 1/5 of the hybrid 1 or 3 level. Neither male nor female H-2w7 mice expressed the Slp gene. These results showed that the expression of the five C4-related genes of H-2w7 mice is differentially regulated in spite of the close similarity in the nucleotide sequences in both the 5' flanking and coding regions of these genes.

Three extra copies of a C4-related gene in H-2w7 mice are C4/Slp hybrid genes generated by multiple recombinational events

Mice bearing the H-2w7 haplotype have five C4-related genes and constitutively express the Slp antigen. To understand the structure and evolution of the five C4-related genes of the C3H.W7 mouse, we have determined nucleotide sequences of the 5' end region of these genes. A C4/Slp hybrid nature was confirmed for three of five C4-related genes as predicted previously by restriction enzyme analysis. The nucleotide sequences of the 5' flanking regions of these three hybrid genes showed close similarity to that of the C4 gene, while the 3' side of the ninth exon of the three hybrid genes showed close similarity to that of the Slp gene. In contrast, the regions between the first exon and the middle of the ninth exon of the three hybrid genes showed a mosaic structure of C4-like and Slp-like sequences. Moreover, the boundaries of the C4-like and Slp-like sequences were quite different among the three hybrid genes. The pattern of nucleotide sequence diversity in this region among the five C4-related sequences could be mainly explained not by point mutations but by gene conversions or unequal crossovers. These results suggest that multiple genetic recombinational events between two homologous sequences played an important role in the generation and diversification of the extra copies of the C4/Slp gene in the H-2w7 mouse.

Post-transcriptional regulation of complement C4 in low C4-producing strain of mouse

The expression of the fourth component of complement (C4) of the mouse can differ 20-fold and is determined by C4-high (C4h) or C4-low (C4l) alleles. To investigate the molecular mechanisms underlying the differences in C4 expression, we compared the transcriptional activity of the C4 genes between high and low C4-producer strains of mice (B10 and FM vs B10.BR) using nuclear transcriptional and chloramphenicol acetyltransferase (CAT) assays. We also compared the level of C4-specific RNA in total and nuclear RNA of the liver. The results revealed no significant difference in transcriptional activity between C4h and C4l genes. However, the steady-state levels of C4 mRNA are ten times lower in C4l strains than in C4h strains, suggesting that the major regulation of C4 plasma levels occurs at the post-transcriptional level.

A previously undetected MHC gene with an unusual periodic structure

The major histocompatibility complex is a chromosomal segment embodying several gene clusters among which those with immune functions are the best characterized. This region is suspected to host other as yet undetected genes whose characterization may shed light on the population genetics and evolution of the whole gene complex and thus on its unexplained character of marker locus for a number of diseases of nonimmune or unknown pathogenesis. A novel gene was identified that is transcribed in all tissues tested and is located in mouse and man between the CA and Bf genes of the H-2 and HLA complexes, respectively. From the nucleotide sequence, derived from liver complementary DNA clones, it is predicted that this novel single-copy gene encodes a 42-kilodalton polypeptide that bears no recognizable relation to the protein families known so far, but it displays striking hallmarks of natural selection.

P450XXI (steroid 21-hydroxylase) gene deletions are not found in family studies of congenital adrenal hyperplasia

Congenital adrenal hyperplasia (CAH) is a common genetic disorder due to defective 21-hydroxylation of steroid hormones. The human P450XXIA2 gene encodes cytochrome P450c21 [steroid 21-monooxygenase (steroid 21-hydroxylase), EC 1.14.99.10], which mediates 21-hydroxylation. The P450XXIA2 gene may be distinguished from the duplicated P450XXIA1 pseudogene by cleavage with the restriction endonuclease Taq I, with the XXIA2 gene characterized by a 3.7-kilobase (kb) fragment and the XXIA1 pseudogene characterized by a 3.2-kb fragment. Restriction endonuclease mapping by several laboratories has suggested that deletion of the P450XXIA2 gene occurs in about 25% of patients with CAH, as their genomic DNA lacks detectable 3.7-kb Taq I fragments. We have cloned human P450c21 cDNA and used it to study genomic DNA prepared from 51 persons in 10 families, each of which includes 2 or more persons with CAH. After Taq I digestion, apparent deletions are seen in 7 of the 20 alleles of the probands; using EcoRI, apparent deletions are seen in 9 of the 20 alleles. However, the apparently deleted alleles seen with Taq I do not coincide with those seen with EcoRI. Furthermore, studies with Bgl II, EcoRI, Kpn I, and Xba I yield normal patterns with at least two enzymes in all cases. Since all probands yielded normal patterns with at least two of the five enzymes used, we conclude that the P450XXIA2 gene "deletions" widely reported in CAH patients probably represent gene conversions, unequal crossovers, or polymorphisms rather than simple gene deletions.

Molecular genetics of androgen-dependent and -independent expression of mouse sex-limited protein

Genes of the mouse S locus encoding C4 (the fourth component complement) and Slp (sex-limited protein) show extensive homology but are distinct in their function and regulation. In some mouse strains, such as B10.D2, Slp is androgen regulated, whereas in others, such as B10.W7R, expression of Slp is constitutive. We have previously shown that the B10.W7R strain has multiple Slp genes. In this report, we present the structure of the single C4 and four Slp genes of the B10.W7R S locus and compare the upstream flanking regions by partial sequence analysis and function in transfection assays. Of the four Slp genes, three (Slpw7.A, Slpw7.B, and Slpw7.C) have upstream and promoter regions very similar to those of C4. The fourth Slp gene (Slpw7.D) is instead virtually identical to the androgen-regulated allele (Slpd from the B10.D2 mouse) in upstream regions. In particular, far-upstream sequences from both Slpd and Slpw7.D render the bacterial chloramphenicol acetyltransferase gene hormonally responsive upon transfection into mammary carcinoma cell lines. The upstream sequences between 2 to 3 kilobases of the Slp promoter initiate transcription from multiple sites when fused proximal to the chloramphenicol acetyltransferase gene, and these transcripts are threefold more abundant in the presence of androgen. This behavior is similar for Slpd and Slpw7.D, which suggests that Slpw7.D may be androgen regulated but that this is masked in vivo by constitutive expression of the other Slp genes. Nonhomologous recombination is implicated not only in expanding the copy number of C4 and Slp genes in the B10.W7R mouse but also in creating hybrid genes with regulatory features of C4 and structural features of Slp.

DNase I-hypersensitive sites associated with expression and hormonal regulation of mouse C4 and Slp genes

There are four major regions of DNase I hypersensitivity in the 5' regions of the genes for the murine fourth component of complement (C4) and its homologous neighbor, Slp (sex-limited protein). Hypersensitivity around the start site of transcription and approximately equal to 0.5 kilobases upstream correlates qualitatively with expression of these genes. Two hypersensitive sites, at -2.3 and -2.0 kilobases, map specifically to the Slp gene and correlate with its hormonal regulation. That is, these sites are more prominent in male liver chromatin and become more apparent in chromatin from females treated with testosterone. Further, these sites are established in males to a greater extent than in females prior to expression of Slp and may reflect gene-commitment events. Comparison of chromatin from mouse strains differing in C4 and Slp alleles indicates that the four regions of hypersensitivity may be necessary but are not sufficient for high levels of expression.

Lethal deletion of the complement component C4 and steroid 21-hydroxylase genes in the mouse H-2 class III region, caused by meiotic recombination

A recombinant H-2 haplotype, designated aw18, was produced that underwent meiotic recombination in the E alpha (I-E alpha chain)--Slp (sex-limited protein) interval of the H-2 class III region between B10.A (H-2a) and wild-derived B10.MOL-SGR (H-2wm7) strains. It appeared that the H-2aw18 haplotype has a single, recessive, lethal mutation, since homozygotes for H-2aw18 were not detected in progeny generated from the intercross of mice that were heterozygous for this H-2 haplotype. Nine newly established recombinant H-2 haplotypes, which arose from the heterozygous mice that resulted from a cross between common inbred H-2 haplotypes and the aw18 haplotype, allowed us to map the lethal gene to the class III region of the H-2 complex. Southern blot analysis indicated that the aw18 haplotype has a deletion of the C4 gene and a deletion of one of the steroid 21-hydroxylase genes. This result was confirmed by an immunodiffusion test that demonstrated the absence of production of the C4 protein in mice of haplotype H-2aw18. All data that were obtained supported the hypothesis that the meiotic, presumably unequal, recombination between homologous chromosomes of the H-2a and H-2wm7 haplotypes caused the deletion of the C4 and the 21-hydroxylase genes.

Molecular genetics of androgen-dependent and -independent expression of mouse sex-limited protein

Genes of the mouse S locus encoding C4 (the fourth component complement) and Slp (sex-limited protein) show extensive homology but are distinct in their function and regulation. In some mouse strains, such as B10.D2, Slp is androgen regulated, whereas in others, such as B10.W7R, expression of Slp is constitutive. We have previously shown that the B10.W7R strain has multiple Slp genes. In this report, we present the structure of the single C4 and four Slp genes of the B10.W7R S locus and compare the upstream flanking regions by partial sequence analysis and function in transfection assays. Of the four Slp genes, three (Slpw7.A, Slpw7.B, and Slpw7.C) have upstream and promoter regions very similar to those of C4. The fourth Slp gene (Slpw7.D) is instead virtually identical to the androgen-regulated allele (Slpd from the B10.D2 mouse) in upstream regions. In particular, far-upstream sequences from both Slpd and Slpw7.D render the bacterial chloramphenicol acetyltransferase gene hormonally responsive upon transfection into mammary carcinoma cell lines. The upstream sequences between 2 to 3 kilobases of the Slp promoter initiate transcription from multiple sites when fused proximal to the chloramphenicol acetyltransferase gene, and these transcripts are threefold more abundant in the presence of androgen. This behavior is similar for Slpd and Slpw7.D, which suggests that Slpw7.D may be androgen regulated but that this is masked in vivo by constitutive expression of the other Slp genes. Nonhomologous recombination is implicated not only in expanding the copy number of C4 and Slp genes in the B10.W7R mouse but also in creating hybrid genes with regulatory features of C4 and structural features of Slp.

Multiple C4/Slp genes distinguished by expression after transfection

The S region of the murine major histocompatibility complex contains two closely related genes: C4, encoding the fourth component of complement, and Slp, encoding sex-limited protein. We cloned these genes from a cosmid library of the B10.W7R strain that does not show androgen regulation of the Slp protein. Restriction site polymorphisms revealed at least four C4-like genes within the Sw7 locus, indicating evolutionary amplification of this region. Transfection of these genes into L cells resulted in expression, processing, and secretion of immunologically correct C4 and Slp proteins. At least two different Slp genes and one C4 gene were capable, after transfection, of expressing C4 and Slp indistinguishable from macrophage-derived protein. A third Slp gene exists within this locus whose recombinant cognate did not express in L cells. Thus, the B10.W7R S region includes one C4 gene and at least three Slp-like genes.

Identification of the 5'-flanking regulatory region responsible for the difference in transcriptional control between mouse complement C4 and Slp genes

To elucidate the molecular basis underlying the difference in the mode of gene expression between mouse complement C4 (constitutive) and sex-limited protein (Slp) (testosterone-regulated), we compared nucleotide sequences and transcriptional regulatory activities of the 5'-flanking regions of these two genes. Although the two sequences showed a high degree of overall homology (95%) up to 1.9 kilobases (kb) upstream from the transcription initiation site, the Slp sequence lacked a 31-nucleotide segment containing ACACCC repeats and a 60-nucleotide segment containing ACAC repeats, which are present, respectively, 1.6 kb and 200 base pairs (bp) upstream from the transcription initiation site of the C4 gene. When assayed in human hepatoma-derived HepG2 cells, the 1.8-kb 5'-flanking DNA fragment of the C4 gene demonstrated strong transcriptional activity, whereas the corresponding DNA fragment of the Slp gene showed only negligible activity. By progressive deletion experiments, it was shown that the difference in the constitutive transcriptional activity of the C4 and Slp genes was accounted for by the presence or absence of the positive regulatory domain located between 1700 bp and 400 bp upstream of the transcription initiation site.

Sequence comparison of alleles of the fourth component of complement (C4) and sex-limited protein (Slp)

cDNA clones specific for the fourth component of complement (C4) and its androgen-regulated isotype, sex-limited protein (Slp), have been isolated from two mouse haplotypes (H-2d and H-2w7) that show differential C4 activity and differential regulation of Slp. Clones were first isolated using a cDNA probe enriched by subtractive hybridization. Subsequent screening has resulted in cDNAs spanning the entire C4d mRNA, as well as much of C4w7, Slpw7 and a short region of Slpd. The cDNAs for C4 and Slp show extensive sequence homology, but can be distinguished using oligonucleotide probes synthesized to regions of greatest sequence divergence. Sequence differences between C4 and Slp indicate structurally important features of C4 that have been altered in Slp such that Slp is unable to participate in the complement pathway. Of the few nucleotide differences between C4d and C4w7, a single base change resulting in one less glycosylation site in the C4w7 alpha chain could account for its 4-fold reduced hemolytic efficiency. Sequence comparison of multiple alleles of C4 and Slp indicates that possible gene conversion events occurred in the H-2w7 strain that has multiple Slp genes.

Complete sequence of HLA-B27 cDNA identified through the characterization of structural markers unique to the HLA-A, -B, and -C allelic series

Antigen HLA-B27 is a high-risk genetic factor with respect to a group of rheumatoid disorders, especially ankylosing spondylitis. A cDNA library was constructed from an autozygous B-cell line expressing HLA-B27, HLA-Cw1, and the previously cloned HLA-A2 antigen. Clones detected with an HLA probe were isolated and sorted into homology groups by differential hybridization and restriction maps. Nucleotide sequencing allowed the unambiguous assignment of cDNAs to HLA-A, -B, and -C loci. The HLA-B27 mRNA has the structural features and the codon variability typical of an HLA class I transcript but it specifies two uncommon amino acid replacements: a cysteine in position 67 and a serine in position 131. The latter substitution may have functional consequences, because it occurs in a conserved region and at a position invariably occupied by a species-specific arginine in humans and lysine in mice. The availability of the complete sequence of HLA-B27 and of the partial sequence of HLA-Cw1 allows the recognition of locus-specific sequence markers, particularly, but not exclusively, in the transmembrane and cytoplasmic domains.

Multiple C4/Slp genes distinguished by expression after transfection

The S region of the murine major histocompatibility complex contains two closely related genes: C4, encoding the fourth component of complement, and Slp, encoding sex-limited protein. We cloned these genes from a cosmid library of the B10.W7R strain that does not show androgen regulation of the Slp protein. Restriction site polymorphisms revealed at least four C4-like genes within the Sw7 locus, indicating evolutionary amplification of this region. Transfection of these genes into L cells resulted in expression, processing, and secretion of immunologically correct C4 and Slp proteins. At least two different Slp genes and one C4 gene were capable, after transfection, of expressing C4 and Slp indistinguishable from macrophage-derived protein. A third Slp gene exists within this locus whose recombinant cognate did not express in L cells. Thus, the B10.W7R S region includes one C4 gene and at least three Slp-like genes.

The molecular genetics of components of complement

Rapid progress has been made in establishing linkages and in chromosome allocation of the genes of some 9 complement components. In the MHC, C2, Factor B, and two C4 or C4 related genes have been placed in some detail in both man and mouse. The gene coding for the cytochrome P-450 21-hydroxylase has been shown to be duplicated and immediately 3' to the two C4 genes, though it appears to be functionally and structurally unrelated to the complement components. Thus six genes have been mapped to this region where particular haplotypes are associated with increased susceptibility to a number of diseases, some of which are autoimmune in character. The complete gene structure of Factor B has been solved in man and rapid progress is being made with the C2 and C4 genes. The structural basis of the polymorphisms of these genes is being established. In C4, the polymorphism is exceptionally complex with varying numbers of loci and probably more than 50 allotypes occurring in man. A structural basis has also been found for the big differences in the biological activity of some of the C4 allotypes in man. Apart from the genes in the MHC, linkage has been found between the genes coding for C4bp, CR1, and Factor H. Remarkably there are sequence homologies between these proteins and C2 and Factor B, probably related to the ability to bind to one or other of the structurally similar proteins C3b and C4b. The complete cDNA sequences of C3 and C4 in mouse and man have given much information on the many posttranslational modifications of these proteins. A partial structure has been obtained for the C3 gene and the homology shown between C3, C4, C5, alpha 2-macroglobulin, and pregnancy zone protein. Although the amount of detailed information in the molecular genetics of complement components is accumulating rapidly, there appears to be a reasonable prospect that linkages and homologies will classify the data into a comprehensible form.

Structure and expression of murine fourth complement component (C4) and sex-limited protein (Slp)

During the past 4 years we have used recombinant DNA technology to build upon previous genetic and biochemical studies of the C4 and Slp genes and their products. We have isolated DNA probes specific for C4 and Slp, determined the complete sequences of C4 and Slp molecules, established the role of liver mRNA levels in determining serum C4 and Slp levels identified the C4 and Slp genes in Balb/c mice, and begun to probe the structures of the C4 and Slp genes in a variety of inbred mouse strains. This work has provided the tools and a framework for future studies aimed at understanding the multiple functions of the C4 protein and the regulatory mechanisms controlling the expression of the C4 and Slp genes.

Adrenal 21-hydroxylase cytochrome P-450 genes within the MHC class III region

Genes encoding several serum complement components and the gene(s) for steroid 21-hydroxylase (21-OH) have been located in the class III region of the major histocompatibility complex (MHC). All these genes are highly polymorphic in man, and these polymorphisms have been used to draw conclusions about the structure and function of these genes. For example, electrophoretic polymorphisms of the fourth component of complement (C4) have been shown to be controlled by two closely linked genes, which also control expression of the red cell antigens Rodgers and Chido. Steroid 21-OH deficiency (D) can occur in several forms which differ in severity, and because of genetic linkage disequilibrium with different HLA antigens the inheritance of these forms is consistent with the existence of several alleles at a single locus. When severe 21-OH D occurs in association with the HLA haplotype A3;Bw47;DR7, there is a simultaneous null allele at one of the C4 loci. This was hypothesized to result from a single deletion or rearrangement affecting the 21-OH and C4 loci and perhaps the HLA-B gene as well. To test this hypothesis and identify the 21-OH gene, a cDNA clone was isolated which encoded the cytochrome P450 specific for steroid 21-hydroxylation in the bovine adrenal gland. This clone hybridized to two genes in normal human DNA, but to only one gene in DNA from an individual homozygous for A3;Bw47;DR7. All individuals heterozygous for A3;Bw47;DR7 carry a heterozygous deletion of a gene. These experiments showed that at least one structural gene for the cytochrome P450 specific for 21-hydroxylation is located in the MHC, probably very near the C4 genes, and a mutation in this gene results in 21-OH D. Cosmid clones have been used to locate the 21-OH genes both in man and mouse. In both species, there are two 21-OH genes, each located immediately 3' of one of the two C4 genes, and oriented in the same direction as the C4 genes. In man, the gene located 3' of the C4B gene is deleted in 21-OH D on the Bw47 haplotype, but the gene 3' of the C4A gene is deleted in hormonally normal individuals on the A1;B8;C4AQO;C4B1;DR3 haplotype. Thus the 21-OH B gene is normally active in man, but the 21-OH A gene is not.

Analysis of the sheep MHC using HLA class I, II, and C4 cDNA probes

Four cDNA probes for the human major histocompatibility complex (MHC) were used to investigate the sheep MHC, in conjunction with serological typing for ovine lymphocyte antigen (OLA). Lymphocytes from a family (two parents and five offspring) of Romanov sheep were subjected to genomic DNA digestion by the restriction endonuclease Eco RI, followed by gel electrophoresis. A single Southern blot representing all seven individuals was then consecutively hybridized with the class I, alpha-DC, beta-DR, and C4 probes, which were originally designed to identify HLA class I, class II (DC and DR), and C4 products, respectively. Using each of the three class I/class II probes, several bands showing DNA polymorphism were detected. The segregation of these bands in the five offspring exactly paralleled the OLA haplotype segregation established by serological typing. A further eight individuals carrying haplotypes which were phenotypically identical to those in the above-mentioned family showed bands in the corresponding positions when tested with the same three probes. Using the C4 probe, no polymorphism was detected in these fifteen individuals.

Molecular organization and in vitro expression of murine class III genes

These experiments demonstrate that at least two types of gene duplications have occurred during the evolution of the S region. The first type, which produced the C2 and factor B genes, involved a short segment of the chromosome encompassing a single gene. The related products have subsequently diverged yielding sequences which do not cross-hybridize. Further duplication of these genes has not been observed. The second type of duplication consisted of a much longer primordial sequence, spanning approximately 55 kb of genomic DNA and including at least two genes, C4/Slp and 21-hydroxylase. The duplicated sequences are separated by a segment of single copy sequence of as yet undefined length. These duplicated sequences have been relatively conserved. There is evidence that further duplication of this region is possible (as seen in the H-2w7 strain) although the exact nature of the increase in gene number has not been fully characterized. Detailed analysis of cosmid clones which span these two duplications has permitted the assignment of a new pair of loci to the S region, encoding 21-hydroxylase A and B. The advantage conferred by linkage of the gene encoding this adrenal steroid biosynthesis enzyme to the genes encoding complement components C2, factor B, and C4 is unclear, as is the advantage of the association of all of the class III genes with the remainder of the MHC. The availability of cloned sequences containing all of the class III genes permits further study of the factors which govern the tissue specificity of their expression and which confer androgen responsiveness on certain of the Slp alleles.

Liver mRNA probes disclose two cytochrome P-450 genes duplicated in tandem with the complement C4 loci of the mouse H-2S region

A search for uncharacterized genes of the S region of the murine H-2 major histocompatibility complex was undertaken; a series of cosmid clones previously aligned by overlap hybridizations were used as radiolabeled probes. Sequences hybridizing with liver poly(A)+ RNA were found within a cosmid covering a region 3' to the C4-Slp gene (the gene encoding the hemolytically inactive isoform of the fourth component of serum complement). Radiolabeled, short cDNA complementary to liver poly(A)+ RNA was used to establish the transcriptional polarity of the newly detected gene and to define fragments containing its 3' end. DNA sequence analyses and comparisons with porcine peptides established that the gene encodes the enzyme steroid 21-hydroxylase (EC 1.14.99.10), a cytochrome P-450 often referred to as P-450(C21), whose major site of expression is the adrenal gland. Two copies of the P-450(C21) gene, very similar yet distinguishable by restriction endonuclease analysis, were found individually associated with C4 and C4-Slp, genes that encode isoforms of mouse fourth component of complement. One of the P-450(C21) genes is coamplified with C4-Slp in H-2w7, a haplotype carrying a rare elongation of the S region. Comparisons with other members of the P-450 gene family show that the P-450(C21) genes encode peptides of extraordinary evolutionary conservation. The detection of a liver transcript of P-450(C21) raises the issue of the specific metabolic role of this enzyme in this organ and may have implications for the interpretation of human congenital adrenal hyperplasia.

Molecular genetics of the S region of the murine H-2 major histocompatibility complex

The mouse H-2S region has been conventionally identified by the functional, serological and electrophoretic variations of two plasma proteins which constitute its primary genetic markers, C4 (the fourth component of complement) and C4-Slp (sex-limited protein). Recently, recombinant DNA procedures applied in our laboratory as well as in several others have made available molecular clones corresponding to these two nonallelic genes. This paper focuses on the progress provided by the study of C4 and C4-Slp cDNA and genomic clones, as well as by the application of such clones to the probing of the S region structure in conventional and special H-2 haplotypes. At variance with the K, I and D regions of H-2, the S region contains genes which have no obvious structural interrelationship, although in some cases they display a functional interaction. The heterogeneity of S region products is emphasized by the recent detection of steroid 21-hydroxylase genes associated with each of the C4 gene copies.

Restriction fragment length polymorphism of C4 genes in mice with t chromosomes

Genomic DNA was isolated from 29 t strains and 4 congenic lines of mice, digested with restriction endonucleases, and hybridized with a probe representing the complement component 4 (C4) gene. All but one of the enzymes revealed restriction fragment length polymorphism in this sample of C4-related genes. Double digestion analysis suggested the presence of three C4 gene copies in some of the t chromosomes and two copies in others. The enzymes distinguished 16 different haplotypes among the 33 strains tested. Based on their restriction fragment length patterns, the t strains could be divided into four groups with strains in each group more closely related to each other with respect to their C4-region genes than strains belonging to different groups. At least three of these four groups represent different branches of the evolutionary tree constructed for the t chromosomes. The C4-related genes of the chromosomes are in strong linkage disequilibrium with the class II genes of the H-2 complex. Typing for the Ss and Slp allotypes of C4 has revealed the presence of the Ss1 phenotype in two t strains and of the Slpa phenotype in one strain.