Linkage of the gene controlling the synthesis of the fourth component of complement to the major histocompatibility complex of the guinea pig

C4-deficient (C4D) guinea pigs are lacking in C4 synthesis, a condition that appears to be caused by a structural gene defect. This defect is inherited as a simple autosomal recessive trait. We have demonstrated linkage between C4D and the major histocompatibility complex of the guinea pig (GPLA). Inbred C4D and inbred strain 13 guinea pigs appear to have the same GPLA haplotype. The use of these two strains should provide an animal model for reconstitution studies of C4 synthesis and for studied exploring the possible role of C4 in cellular and humoral immune responses.Abbreviations used in this paper are C4D deficiency of the fourth component of complement - MHC major histocompatibility complex - GPLA major histocompatibility complex of the guinea pig - MLC mixed lymphocyte culture     

MHC-linked class III genes. Analysis of C4 gene frequencies,complotypes and associations with distinct HLA haplotypes in German Caucasians

The class III complement components, C4, C2 and factor B (BF), are encoded in the human major histocompatibility complex (MHC). The two genes determining C4 (C4A and C4B) display considerable polymorphism and, thus, are important markers for HLA. In combination with alleles of C2 and BF they can be grouped into unique complotypes. We have analyzed the C4 alleles in a panel of 204 unrelated German Caucasians and studied their segregation with HLA haplotypes in 24 normal families. Inclusion of the class III markers with the class I and 11 alleles provides a more refined picture of the genetic structure of the MHC in these families. When charted according to the HLA-B locus specificities the MHCs can be clustered into groups showing distinctly homogenous or heterogenous complotypes. The identification of such groups is valuable for the selection of genetic material to analyze the molecular genetics of the human MHC.Abbreviations BF factor B - C2 second component of complement - C4 fourth component of complement - EDTA ethylenediamine tetraacetate - GLO glyoxalase-I - MHC major histocompatibility complex     

Heterogeneity of human C4 gene size

In this article we present a study showing that the human C4 genes differ in length because of the presence or absence of a 6.5 kb intron near the 5 end of the gene. DNA from individuals of known HLA, factor B, and C4 haplotypes was analyzed for restriction fragment length polymorphism (RFLP) by Southern blot analysis with C4-specific cDNA probes. The RFLP patterns obtained showed that the C4 genes are either 22.5 kb or 16 kb in length. They are referred to as long and short C4 genes, respectively. A population study was carried out to examine the distribution of the gene size according to C4 allotypes and haplotypes. Long C4 genes included all C4A genes studied and also some C4B allotypes, e. g., B1 on most C4 A3B1 haplotypes. Similarly, C4B null genes were found to be of the long form. Other C4B allotypes tested were found to be coded for by short C4 genes, including B2, B1 in C4 A6B1 and C4 AQOB1 (with a single C4B gene haplotype).Abbreviations used in this paper C4 fourth component of complement - C2 second component of complement - BF factor B - MHC major histocompatibility complex - RFLP restriction fragment length polymorphism - EDTA ethylenediaminetetraacetic acid - SDS lauryl sulfate, sodium salt     

C4B3 allotype with a novel Ch phenotype

The fourth component of complement (C4) has two classes of protein, C4A and C4B, both of which have many allelic forms. The serological determinants Rodgers (Rg1, Rg2) and Chido (Ch1, Ch2, Ch3) are generally associated with C4A and C4B, respectively. The C4B3 allotype has been detected in a single Canadian family that expresses a novel Ch phenotype, Ch:–1, 2, –3. There was no information for the Rg determinants, as the C4A ^* 2B ^* 3 haplotype would normally express Rg on the C4A protein. Other C4B3 allotypes in informative families have different Ch phenotypes, and the relationships of these within extended major histocompatibility complex haplotypes are discussed in this paper.     

Molecular cloning and linkage analysis of complement C3 and C4 genes of the Japanese medaka fish

 The thioester-containing complement components, C3 and C4, are believed to have arisen by gene duplication from a common ancestor, and the mammalian C4 gene resides in the vicinity of the C2 and B genes within the major histocompatibility complex (MHC) class III region. To analyze the evolution of both the complement system and the MHC, we determined the complete primary structures of two C3 genes, termed Orla C3-1 and Orla C3-2, and one C4 gene, termed Orla C4, of a teleost, Japanese medaka fish (Oryzias latipes), by analyzing cDNA clones isolated from a liver library constructed using the inbred AA2 strain. The deduced basic structures of Orla C3-1, C3-2, and C4, such as the subunit chain structure, the thioester site, and the proteolytic activation site, are similar to their mammalian counterparts. However, the catalytic His residue which greatly increases the rate of thioester reaction, is replaced by Ala in Orla C3-2, implying functional differentiation between two C3 molecules. Mapping analysis revealed a close linkage between the C3-1 and C3-2 genes, indicating that they arose by a local duplication rather than by a genome-wide tetraploidization. The C4 gene belongs to a different linkage group, and no linkage was observed among the C3, C4, Bf/C2, MHC class I, and MHC class II loci. These results suggest that the MHC class III complement region was established in the tetrapod lineage, or lost in the teleost lineage. Received: 15 July 1999 / Revised: 3 September 1999     

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. Address correspondence and offprint requests to: J. Klein.     

Serological studies on the major histocompatibility complex of new inbred strains of the guinea pig.

New inbred strains of guinea pigs, JY 1, JY 2, JY 3, JY 6, JY 9 and JY 10 have been established in this Institute. Serologic studies of guinea pig leukocyte antigens (GPLA antigens) were carried out in order to examine their major histocompatibility complex (GPLA complex). Antisera specific for Ia antigens were raised by cross-immunization of NIH strain 2 (NIH 2) and NIH strain 13 (NIH 13) guinea pigs, well known inbred guinea pigs. The sera identified four distinct Ia specificities, which were designated as Ia.2a, Ia2b, Ia.13a and Ia.13b. Six antigenic specificities different from the above Ia specificities were identified by sera obtained by appropriate immunization of the inbred guinea pigs and were designated as P.1, P.2, P.3, P.4, P.5 and P.6. Antigenic specificities of GPLA antigens recognized in inbred guinea pigs were : NIH 2 (Ia.2a, Ia.2b, P.1, P.2, P.O, P.4), NIH 13 (Ia.13a, Ia.13b, P.1, P.2, P.3, P.4), JY 1 (Ia.13a, Ia.13b, P.5), JY 2 (Ia.2b, Ia.13b, P.3, P.4, P.6), JY 3 (Ia.13a, Ia.13b, P.2, P.4, P.5), JY 6 (Ia.2b, Ia.13b, P.3, P.6), JY 9 (Ia.13a, Ia.13b, P.4, P.5), JY 10 (Ia.13a, Ia.13b, P.2, P.3, P.4, P.6), JY 9 (Ia.13a, Ia.13b, P.4, P.5), JY 10 (Ia.13a, Ia.13b, P.2, P.3, P.4, P.6). The correspondence of these specificities to those already reported was discussed and the P.2 or P.4 was considered to be an additional specificity of GPLA antigens that have not been reported yet. As the new inbred strains of guinea pigs were thus found to possess characteristic GPLA complex, which differ from each other and from those of NIH 2 and NIH 13 strain, they should be useful for studies of roles of the major histocompatibility complex in the immune system.     

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.     

BF types and the mode of inheritance of insulin-dependent diabetes mellitus (IDDM)

Insulin-dependent diabetes mellitus (IDDM) has been found to be highly associated with a rare allele of the complement protein, properdin factor B (BF). Assuming that there is a susceptibility gene for IDDM tightly linked to the genetic locus forBF and the major histocompatibility complex (MHC), the distribution of BF types in more than 1100 North American IDDM patients strongly argues for the rejection of dominant, epistatic, and overdominant modes of inheritance. Other evidence suggesting complex modes of inheritance for IDDM is reviewed and it is concluded that our observations and published data are consistent with the idea of susceptibility to IDDM being inherited as a simple autosomal recessive trait. — C4 and C2 types, also linked toBF and theMHC, were investigated too. C4 Fs⁰ was found to be increased in association with BF F1, while C4 f⁰S and C2 B were each found to occur twice as frequently as in a control population and will be of value in defining haplotypes associated with susceptibility to IDDM.     

Definitive RFLPs to distinguish between the human complement C4A/C4B isotypes and the major Rodgers/Chido determinants: Application to the study of C4 null alleles

Definitive restriction fragment length polymorphisms (RFLPs) representing the exact locations responsible for isotypicity between the human complement components C4A and C4B, and their generally associated major Rodgers (Rg1) and Chido (Ch1) antigenic determinants, have been designed. By means of a C4d-specific genomic probe for Southern blot analysis, a C4A gene can be defined by the presence of the 276 bp and 191 bp N 1 a IV fragments, while a C4B gene can be defined by a single 467 bp N1aIV fragment. In addition, an Rgl-expressing C4 gene can be represented by a 565 bp EcoO 109 fragment, and a Chl-expressing C4 gene by a 458 by EcoO 109 fragment, under the same conditions. All these polymorphic restriction fragments can be unambiguously and conveniently detected. In combination with the Taq I polymorphic patterns specific for the C4 loci and for the neighboring 21-hydroxylase genes, the nature and structure of the tandem C4,21-hydroxylase gene complex can be elucidated. In this study, it is inferred that the null allele of the HLA haplotype B44 DR6 C4A3 C4BQO is not a C4B allele, but probably encodes another C4A 3 allotype at the second C4 locus.Abbreviations used in this paper C4 (long) - C4 gene of 22 kb, with a 6–7 kb intron - C4 (short) - C4 gene of 16 kb, without a 6–7 kb intron; complotype SCO1, factor B S, C2 C, C4A QO; C4B 1 Dedicated to the memory of our teacher, the late Professor Rodney Porter C. H. F. R. S.     

A three-locus model for the chicken major histocompatibility complex

The major histocompatibility complexes (B complexes) of chickens of various origins have been studied by serological and biochemical methods. TwoB complexes are of particular interest:B ^R1, a recombinant haplotype derived from theB complexes of the inbred CB and CC strains, andB ^G-B1 , theB haplotype of the G-B1 strain. TheB ^R1 haplotype differs detectably from theB ^CB haplotype only at a locus controlling the synthesis of an antigen, B-G, which (in peripheral blood) is present only on red cells. Anti-B-G sera precipitate, from¹²⁵I-labeled red cell lysates, two chains of apparent molecular weights 42,000 and 31,000 (measured under reducing conditions); the smaller is perhaps derived by proteolysis from the larger. TheB ^G-B1 haplotype differs detectably from theB ^CC haplotype only at a locus controlling the synthesis of an antigen whose tissue distribution and biochemical and biological properties are identical to those of B-G. The chicken major histocompatibility complex therefore contains at least three loci—those controlling synthesis of the B-G, and of the previously defined B and B-L antigens.The following abbreviations are used in this paper MHC major histocompatibility complex - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - MLR mixed leukocyte reaction - GVH graft-versus-host reaction     

The expression of Mls c determinants on Mls a,Mls b,and Mls x prototypic strains

In the mouse sytem, specific determinants other than major histocompatibility complex (MHC) gene products are capable of inducing strong primary proliferative responses in naive T cells. These determinants are encoded by at least two gene loci designated as minor lymphocyte stimulatory (Mls) loci. In order to elucidate the biological role of the Mls system, an effort has been initiated to clarify the fundamental immunogenetic characteristics of the Mls system. In this report, we describe the unexpected finding that Mls ^c determinants are expressed on splenocytes of strains including those which have been used as prototypic examples of three other Mls types: Mls ^a (DBA/2, DBA/1), Mls ^b , (BALB/c), and Mls ^x (PL/J). The expression of Mls ^c by these strains was demonstrated both by the response patterns of unprimed T cells from MHC-identical inbred or F₁ hybrid strains and by the responses of a panel of Mls-specific T-cell clones. The experimental results reported here also suggest that the expression of Mls determinants may be influenced by multiple other genes, including MHC-linked genes.Abbreviations used in this paper MHC major histocompatibility complex - MLR mixed lymphocyte reaction - Mls minor lymphocyte stimulating locus antigen - MMC mitomycin C - NNT nylon wool nonadherent T cells     

C4 urernic variant: An acquired C4 allotype

The major histocompatibility complex (MHC)-linked complotype region includes alleles for B, C2, and C4 loci. These loci are closely linked to each other and to HLA-DR on chromosome 6. The duplicated C4 loci,, C4A and B, are especially polymorphic. In seven patients with renal insufficiency, we observed a C4 variant with electrophoretic mobility between C4B2 and C4B3. Four of these patients were detected during a study of MHC markers in mernbranoproliferative glomerulonephritis. Complete complotype and HLA data from families of five of the seven patients demonstrated that the variant was not inherited. The pattern was revealed by immunofixation electrophoresis and also by C4-specific hemolytic overlay. In serial plasma specimens taken from one patient, the C4 variant appeared only after the patient became uremic. However, the variant could not be produced in normal plasma after incubation with C4-depleted uremic plasma. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions of immunoprecipitated C4 from these patients showed C4A and C4B chains of normal molecular mass; incompletely processed forms of C4 were not observed. We believe that this variant is probably acquired in the presence of uremia and may represent the C4B2.9 allele found by Wank and co-workers in many patients with glomerulonephritis. Family studies are mandatory to distinguish genetic variants from acquired alterations in the C4 phenotype.     

Genetics of human C4 polymorphism: Detection and segregation of rare and duplicated haplotypes

Applying a combined technology for the detection of allotypec variation of the fourth component of human complement (C4), including immunofixation with anti-C4 and C4-dependent lysis after agarose electrophoresis, sodium dodecyl sulfate-polyacrylamide gel electrophoresis of C4 to separate the C4A and B -chains, and the determination of Rodgers (Rg) and Chido (Ch) determinants of C4 in serum and at the blotted C4 -chains, we detected rare human C4 allotypes and studied the genetic linkage. Partial inhibitors (p. i.) of anti-Rg and anti-Ch sera were found; the C4A51 allotype characterized as Rg p. i. and the C4A1 and C4B51 allotypes as Ch p. i. were genetically inherited. The C4A1 allotype has a unique Rg^- Ch⁺ C4A -chain. Duplicated C4A loci, A ^*3, A ^*2, and A ^*5, A ^*2 were both associated with a C4BQO and the HLA haplotype A3-Cw4-Bw35-DR1. These additions to the already known extensive C4 polymorphism may help to sort out their significance for the biological functions of human C4.Abbreviations used in this paper BF Factor B polymorphism of the alternative pathway of complement activation - C2 second component of complement - C4 fourth component of complement - C4D C4-deficient (C4^*QO/QO) - Ch Chido determinant on C4B^* products - EDTA ethylendiaminetetraacetic acid - GLO I glyoxalase I - HLA human leucocyte antigens, A, B, C and DR (D =related) loci - PAGE polyacrylamide gel electrophoresis - PGM3 phosphoglucomutase, third locus - p. i. partial inhibitor = serological inhibition of some, but not all anti-Ch and anti-Rg sera at selected dilutions - SDS sodium dodecyl sulphate; 94k/96k, 94 000 and 96 000 dalton molecular weight Presented in part at the 1V International Workshop on the Genetics of Complement, July 13–15, 1982, Boston, MA, and the Xth International Complement Workshop, May 25–27,1983 in Mainz, Federal Republic of Germany.     

Genetics of complement C4. Two homoduplication haplotypes C4S C4S and C4F C4F in a family

Summary A family in which two homoduplicated C4 haplotypes (or supergenes) segregate is described. One haplotype C4F ^* 3 C4F ^*2.2 is composed of two C4F alleles and the other C4S ^* 5.1 C4S ^*1 of two C4S alleles. The C4F duplication haplotype is a partial inhibitor of the Rodgers antigen, and judged from our family and population material, it seems to be rather frequent and associated with HLAB ^*35, Bf ^* F, and HLAD/DR ^*1. The C4S duplication haplotype is Rg(a-) and is not identified in individuals without another S, Ch(a+) variant.This work was supported by grant No 12-1727 from the Danish Medical Research Council     

Genetic definition of a further gene region and identification of at least three different histocompatibility genes in the rat major histocompatibility system

Two new recombinant haplotypes of the rat major histocompatibility system,RT1, have been detected in [LEW.1A (RT1 ^a ) ×LEW.1W (RT1 ^u )] × LEW 1N(RT1 ⁿ ) segregating hybrids. Recombinantr3 carries theRTL1. A region (determining classical transplantation antigens) and theRT1.B region (determining strong mixed lymphocyte reactivity and genetic control of antipolypeptide immune responsiveness) of the RT1^a parent, bur rejects RT1^a skin grafts. Recombinantr4 carries theA andB regions of the RT1^u parent, but rejects RT1^u skin grafts. The two histocompatibility genes detected are allelic to each other. The relevant locus, designated asH-C, maps to theB-region side of theRT1 system and appears to mark a thirdRT1 gene region,RT1.C. Availability of haplotypes r3 andr4 allowed the definition of a histocompatibility locus in theB region,H-B. The products ofH-C, H-B and of the previously describedH-A gene vary in antigenic strength.     

Immune response genes in inbred rats. II. Segregation studies of the GT and GA genes and their linkage to the major histocompatibility locus

Genetic analysis of the high responder-non-(or low) responder differences between WF and ACI rats to the synthetic copolymers GT and GA established singleIr-genes for both antigens and dominance for high responder status.Ir-GT andIr-GA are linked to the major histocompatibility locus. It could be demonstrated that only T cells carrying the high responderIr-GT gene undergo in vitro blast transformation to GT. The advantages of the rat systems for further studies of the regulatory role ofIr-genes on the cellular level are discussed.Abbreviations cpm counts per minute - DHR delayed hypersensitivity reaction - GA random synthetic copolymer of L-glutamic acid⁵⁰, L-alanine⁵⁰, M.W. 45,000 - GT random synthetic copolymer of L-glutamic acid⁵⁰, L-tyrosine⁵⁰, M.W. 22,000 - Ir gene immune response gene - MLC mixed lymphocyte cultures - LDH lactic dehydrogenase - (T,G)-A-L branched chain synthetic polymer of poly-L (tyrosine, glutamic acid)-poly-D, L-alanine-poly-L-lysine Rat Strains ACI ACI/MaI - WF Wistar Furth - AUG August 28807/Cr     

Subdivision of the S region of the mouse major histocompatibility complex by identification of genomic polymorphisms of the class III genes

The S region of the mouse major histocompatibility complex (MHC) encodes the class III proteins, the second (C2) and fourth (C4) components of complement, and factor B. Previously, the assignment of S-region haplotypes was based on analysis of protein polymorphisms. The recent availability of C2, C4, and factor B cDNA probes prompted a search for restriction fragment length polymorphisms which would serve as additional genetic markers for these loci. DNA was isolated from livers of mice of all standard inbred H-2 haplotypes and of haplotypes pz and bs. These DNA samples were digested with restriction endonucleases and analyzed by Southern blot. By the pattern of restriction fragment length polymorphism observed, specific markers have been identified in factor B of haplotypes f, u, z, bs, r, and v, and in C4 of haplotypes b, q,f,j,p,s, pz, r, and v. These genetic markers were used in the analysis of S-region composition in strains B10.TFR5 (H-2 ^ap5) and C3H.LG (H-2 ^dx), and a possible intra-S-region recombinant was revealed in the H-2 ^dxhaplotype. The genetic markers identified here subdivide the S region and will be of value in defining further the composition of the complement gene complex of the mouse MHC.     

The genetic control of the immune response to murine histocompatibility antigens

The genetic control of the immune response to H-4 histocompatibility alloantigens is described. The rejection of H-4.2-incompatible skin grafts is regulated by anH-2-linkedIr gene. Fast responsiveness is determined by a dominant allele at theIrH-4.2 locus. TheH-2 ^b ,H-2 ^d , andH-2 ^s haplotypes share the fast response allele;H-2 ^a has the slow response allele. Through the use of intra-H-2 recombinants, we have mapped theIrH-4.2 locus to theI-B subregion of theH-2 complex; theH-2 ^h4 ,H-2 ¹⁵, andH-2 ^t4 haplotypes are fast responder haplotypes. These observations suggest that the strength of non-H-2 histocompatibility antigens is ultimately determined by the antigen-specific recipient responsiveness.