There are two C4 genetic loci and a null allele in the chimpanzee

Genetic polymorphism in C4 in the chimpanzee was studied by agarose gel electrophoresis of desialated plasma and development of patterns by immunofixation with antiserum to human C4 and by a C4-sensitive hemolytic overlay. In general, immunofixation patterns showed multiple partially overlapping bands of which only the most cathodal had strong hemolytic activity. In analogy to human C4, the latter were designated C4B, whereas those detected by immunofixation which had little hemolytic activity were designated C4A. Chimp C4A and C4B reacted with human and mouse (monoclonal) anti-C4B and human anti-Ch1 but neither reacted with monoclonal anti-C4A or human anti-Ch2, Ch3, Rg1, or Rg2. On sodium dodecyl sulfate polyacrylamide gel electrophoresis, the alpha chain of C4B showed a slightly lower apparent relative mass than that of C4A at around M _r 93 000. There were three C4A variants and two C4B variants inherited in families as autosomal codominant traits, as C4A-C4B cosegregating pairs with no detectable crossing-over. These pairs were inherited with chimpanzee leukocyte antigen types C2 and BF variants without detectable crossing-over. Half-null C4 haplotypes with C4B ^*Q0 were observed in family studies. Nine BF, C2, C4A, C4B allelic haplotypic combinations (complotypes) were identified among presumably unrelated chimpanzees.Abbreviations used in this paper: ChLA chimpanzee leukocyte antigen - HLA human leukocyte antigen - EDTA ethylenediaminetetraacetate     

DNA polymorphism of MHC III genes in inbred and wild mouse strains

Genes encoding the second component (C2), factor B, and complement protein C4 and Slp (sex-limited protein) are members of the major histocompatibility complex class III gene cluster. In this report we describe isolation of a mouse C2 cDNA clone and its use together with factor B and C4 cDNA clones to examine the S region in a panel of 42 haplotypes in laboratory and wild mice representing 5 species and subspecies of Mus. Conservation of the C2 factor B gene duplex was evidenced by relatively limited polymorphism associated with speciation and nucleotide sequence homology between mouse and human C2 and factor B The C4-Slp gene duplex, on the other hand, showed extensive polymorphism by DNA blot analysis. This polymorphism correlated poorly with the C2/factor B restriction fragment length polymorphism, suggesting independent evolution of these two segments of the S region. Taken together, these data will be of particular importance in studies of mouse strains with abnormal regulation of immune effector systems since the class III gene products are essential for activation of the complement cascade.     

Trans-regulatory genes affect Slpa and Slpo expression and act in a tissue-specific manner

The plasma protein C4 and its androgen-dependent homologue Slp are encoded by genes located in the mouse major histocompatibility complex, H-2. The C4 and Slp protein levels and liver mRNA levels are influenced by non-H-2-linked regulatory genes. The allele-specific regulation of C4 expression and the androgen regulation of Slp expression are manifest only in some of the tissues where these genes are expressed. Therefore, we studied tissues in which the effects of the non-H-2 regulatory genes are apparent. We show that these genes only affect the Slp expression in tissues where it is androgen-dependent. This indicates that the non-H-2 regulatory genes most likely act through interaction with the androgen regulation of Slp expression. We also show that liver cells of mice with the Slp ^o allele, which do not produce Slp protein, do express Slp mRNA; this expression is also androgen-induced and regulated by non-H-2 genes. Thus, both the Slp ^a and Slp ^o alleles appear to be regulated in the same way.     

Mice constitutive for sex-limited protein (SLP) expression contain multiple Slp gene sequences

The murine fourth component of complement (C4) and sex-limited protein (Slp) are two closely related serum proteins whose structural genes map to the S region of H-2. Serum C4 levels vary as much as 20-fold between C4 high (C4H) and C4 low (C4L) strains, and Slp expression can be null (SlpO), limited to male mice of a subset of C4H strains (Slp+), or "constitutive" (SlpC), in which female as well as male mice express Slp. In this study, we compare, by genomic Southern blot analysis, the C4 and Slp genes from eight congenic inbred mouse strains representative of three distinct phenotypes: C4H, Slp+ (two strains), C4H, SlpO (two strains), C4H, SlpC (three strains), and C4L, SlpO (one strain). By using cDNA probes that recognize both C4 and Slp genes, and are derived from the extreme 5' and 3' ends of the mRNA as well as internal coding sequences, we find no evidence to suggest that strain-specific variations in the expression of C4 and Slp are due to gross deletions of major portions of the structural genes. In most cases, two distinct C4/Slp genes are detected; hybridization with C4- and Slp-specific probes indicate that one of these is C4 and the other is Slp. The three SlpC strains are exceptional: they carry at least four C4/Slp genes; one of these hybridizes to the C4-specific probe whereas the remaining genes hybridize to the Slp-specific probe. Hence, multiple duplication of a gene containing Slp sequences has occurred in certain strains of mice, and this is accompanied by constitutive expression of the Slp protein.     

Regulation of expression of mouseC4 andSlp genes by non-H-2-linked genes

C4 (the fourth complement component) and Slp (sexlimited protein) are two homologous plasma proteins encoded by genes in theS-region of theH-2 gene complex. We studied the genetic factors influencing the plasma levels of these proteins and their mRNA levels in liver. Considerable differences in both protein and mRNA levels were found between mouse strains carrying the sameS-region allele on different genetic backgrounds, indicating a pretranslational effect of non-H-2-linked genes on the expression of the twoS-region genes. The expression of Slp is androgen-dependent in the strains tested. However, testosterone treatment cannot increase the low levels of Slp caused by non-H-2-linked regulatory genes. In mice with Slp-negativeS-region alleles we found liver mRNA hybridizing with Slp-specific oligonucleotides, indicating expression of theSlp gene in Slp-negative strains. Our data demonstrate the complexity of the regulation of theC4 andSlp genes and pave the way for the analysis of the regulatory factors involved.     

Nonlinkage between C6 and chromosome 6 markers

Summary C6 typing was performed in a family material by two different techniques: serum or plasma samples were subjected either to high-voltage agarose gel electrophoresis or to isoelectric focusing in polyacrylamide gel slabs. Proteins with C6 activity were then visualized by a specific, hemolytic assay.In 81 unrelated adults within the family material the following allele frequencies were found: C6 ^A:0.61 and C6 ^B:0.39.Linkage studies exclude linkage between C6 and HLA region marker loci, and also between C6 and another chromosome 6 marker locus PGM3.     

Murine sex-limited protein: complete cDNA sequence and comparison with murine fourth complement component

Murine sex-limited protein (Slp) is a structural homologue of the murine fourth complement component (C4) that lacks C4 activity and has no known function. The genes for C4 and Slp lie closely linked in the S region of the murine major histocompatibility complex. We have sequenced a cDNA clone that spans the entire protein-coding region of Slp from the mouse strain B10.WR. The sequence contains a 1735 amino acid-long open reading frame encoding a putative prepro-Slp flanked by 51 and 103 untranslated nucleotides at the 5' and 3' ends respectively; it shows 96% nucleotide and 94% amino acid identity with our previously reported complete sequence of murine C4 from the same mouse strain. The present complete Slp sequence differs slightly from our previously reported partial sequence from the same mouse strain; this suggests that at least two distinct Slp genes are transcribed in B10.WR mice. We suggest, by analogy with procaryotic DNA-binding proteins, that a three amino acid deletion in Slp, close to the Cls cleavage site, makes that site resistant to proteolysis; this renders Slp inactive. We also speculate on the possibility that Slp might be a gene in evolutionary transition; one that is midway in the evolution of a completely silent pseudogene or a new gene with a novel function.     

Genetic polymorphism of the complement C2 in Japanese

Summary Genetic polymorphism of the second component of human complement (C2) was investigated in 521 unrelated healthy adult Japanese using isoelectric focusing in polyacrylamide gel followed by a specific hemolytic overlay method. Besides the phenotypes reported previously (C, AC and BC), a relatively infrequent double-banded phenotype (tentatively named A'C) was observed. Moreover, a homozygous variant (A) and a heterozygous double variant (AB) were observed. The estimated frequencies for the common allele. C2 ² (=C2 ¹ ), and the variant alleles, C2 ^A , C2 ^B (=C2 ² ) and C2 ^A were 0.939, 0.034, 0.022, and 0.006, respectively.The results of further typing for HLA-A,-B,-C specificities indicated the presence of significant associations of C2 ^A with HLA-B15 and with A26, and of C2 ^B with HLA-Bw61. These findings support our previous observation that in Japanese there are allelic combinations showing linkage disequilibrium between C2 and HLA loci which are different from those in Caucasians, and that the C2 structural locus is more closely linked to HLA-B than to HLA-A.C2 hemolytic activities of each phenotypes were assayed. The mean activity of type AC sera was significantly higher than that of type C or type BC, while there were no differences in the activities among the types C, BC or A'C.Also presented are two pedigrees demonstrating the segregation of C2 with HLA alleles in which a homozygous C2A or C2B individual was observed.     

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.     

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.     

Slp1 and Slp2-a localize to the plasma membrane of CTL and contribute to secretion from the immunological synapse

Rab27a is required for polarized secretion of lysosomes from cytotoxic T lymphocytes (CTLs) at the immunological synapse. A series of Rab27a-interacting proteins have been identified; however, only Munc13-4 has been found to be expressed in CTL. In this study, we screened for expression of the synaptotagmin-like proteins (Slps): Slp1/JFC1, Slp2-a/exophilin4, Slp3-a, Slp4/granuphilin, Slp5 and rabphilin in CTL. We found that both Slp1 and Slp2-a are expressed in CTL. Isoforms of Slp2-a in CTL showed variation of the linker region but conserved the C2A and C2B and Slp homology (SHD) domains. Both Slp1 and Slp2-a interact with Rab27a in CTL, and Slp2-a, but not Slp1, is rapidly degraded when Rab27a is absent. Slp2-a contains PEST-like sequences within its linker region, which render it susceptible to degradation. Both Slp1 and Slp2-a localize predominantly to the plasma membrane of both human and mouse CTLs, and we show that Slp2-a can focus tightly at the immunological synapse formed with a target cell. Individual knockouts of either Slp2-a or Slp1 fail to impair CTL-mediated killing of targets; however, overexpression of a dominant-negative construct consisting of the SHD of Slp2-a, which is 56% identical to that of Slp1, reduces target cell death, suggesting that both Slp1 and Slp2-a contribute to secretory lysosome exocytosis from CTL. These results suggest that both Slp1 and Slp2-a may form part of a docking complex, capturing secretory lysosomes at the immunological synapse.     

Genetic Differences between the Pancytosolic and Perinuclear Forms of Murine Mortalin

To determine the genetic relation between the pancytosolic (uniformly distributed in cytoplasm-p66^mot-1) and the perinuclear (p66^mot-2) mortalin proteins found in normal and immortal mouse cells, respectively, we initiated the present study using PCR cloning, sequencing, and single nucleotide primer extension analyses. The results indicate that the difference betweenmot-1andmot-2at 2 bp in the open reading frame does not arise by mutations in the immortalized cells. Intriguingly, both mot-1 and mot-2 sequences were detected in genomic DNA from normal (CMEF) and immortal (RS-4) cells derived from the CD1-ICR mouse strain. We extended the analyses to four other strains of mouse and detected both mot-1 and mot-2 sequences in genomic DNA from the Balb/c mouse also. Swiss and C57BL/6 mice exhibited only mot-2 and the C3H He mouse only mot-1. Southern analyses on a mouse strain that showed the presence of only mot-2 (Swiss) and one that showed both mot-1 and mot-2 (CD1-ICR) by PCR revealed that there are structural differences between mot-1 and mot-2 loci. Furthermore, there appears to be a correlation between frequency of spontaneous immortalization of cultured mouse fibroblasts and the mot loci present in the mouse strain from which they were derived.     

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.     

Tissue-specific variation in C4 and Slp gene regulation.

C4 and Slp are highly homologous mouse genes that differ in function and regulation. Allelic variants exist in quantitative regulation of C4 and in hormonal regulation of Slp. We have examined expression in several tissues, including liver and peritoneal macrophages which are the major sites of synthesis, using a probe that allows direct comparison of C4 and Slp mRNAs. Correctly-sized and initiated RNA, within an order of magnitude of liver levels, is found in mammary gland, lung, spleen, and kidney; lower levels are detectable in testis, brain, heart and submaxillary gland. By comparing expression in congenic mouse strains differing in C4 and Slp loci, regulation of these genes is seen to vary in different tissues. This provides a well-defined genetic system in which to examine cis-acting sequences and trans-acting factors that result in tissue-specific patterns of gene regulation.     

An approach to mapping haplotype-specific recombination sites in human MHC class III

Studies of the major histocompatibility complex (MHC) in mouse indicate that the recombination sites are not randomly distributed and their occurrence is haplotype-dependent. No data concerning haplotype-specific recombination sites in human are available due to the low number of informative families. To investigate haplotype-specific recombination sites in human MHC, we here describe an approach based on identification of recombinant haplotypes derived from one conserved haplotype at the population level. The recombination sites were mapped by comparing polymorphic markers between the recombinant and assumed original haplotypes. We tested this approach on the extended haplotype HLA A3; B47; Bf ^* F; C4A ^* 1; C4B ^* Q0; DR7, which is most suitable for this analysis. First, it carries a number of rare markers, and second, the haplotype, albeit rare in the general population, is frequent in patients with 21-hydroxylase (21OH) defect. We observed recombinants derived from this haplotype in patients with 21OH defect. All these haplotypes had the centromeric part (from Bf to DR) identical to the original haplotype, but they differed in HLA A and B. We therefore assumed that they underwent recombinations in the segment that separates the Bf and HLA B genes. Polymorphic markers indicated that all break points mapped to two segments near the TNF locus. This approach makes possible the mapping of preferential recombination sites in different haplotypes.     

An AC-repeat adjacent to mouse Cdkn2B allows the detection of specific allelic losses in the p15 INK4b and p16 INK4a tumor suppressor genes

The cyclin-dependent kinase inhibitors p15 ^INK4b and p16 ^INK4a are involved in the development of a wide range of human and murine tumors. These tumor suppressor genes are inactivated by deletions frequently associated to point mutations in the coding regions or hypermethylation of their promoters. In this work, we describe a simple-sequence length polymorphism located in mouse Chromosome (Chr) 4, between the Cdkn2B (p15 ^INK4b ) and Cdkn2A (p16 ^INK4a ) genes, only 700 bp downstream of the Cdkn2B locus. This DNA region was analyzed in different inbred strains showing a variable AC-repetitive DNA sequence. We used this microsatellite to detect loss of heterozygosity of the Cdkn2A and Cdkn2B loci in γ-irradiation-induced thymic lymphomas of C57BL/6J × RF/J F₁ hybrids. Using this specific marker, we were able to locate additional allelic losses not detected by other microsatellites. Since the allelic losses can be detected by a simple PCR amplification, this AC-repetitive sequence is specially useful as a genetic marker for these Cdkn2 genes and specifically for the p15 ^INK4b cell cycle inhibitor. Received: 27 August 1997 / Accepted: 13 November 1997     

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.     

Close linkage between mouse genes determining the two forms of complement component C6 and component C7, and cis action of a C6 Regulatory Gene

Two forms of mouse complement component C6, with molecular weights (M _rs) of 90 and 100 kilodaltons (kd), are present in the sera from certain inbred strains such as the CBA strain; other strains, such as the BALB/c and DBA/2 strains, have only the 90 kd C6A form. The present work was undertaken to determine whether the two M _r forms were the products of genes coding at separate loci. We screened sera from mice from a number of inbred strains by isoelectric focusing and found one strain, AKR, exhibiting allotypic structural variations of C6 forms. To distinguish the various types, we designated the 90 kd types from CBA and AKR mice C6A1 and C6A2, respectively, and the corresponding 100 kd types C6B 1 and C6B2, respectively. Mice possessing only one M _r form were all typed as C6A1. Results of breeding experiments strongly suggested that the two M _r forms of C6 are coded for at two closely linked loci. Sera from a number of inbred strains were also screened for a complement C7 polymorphism by means of isoelectric focusing and functional overlay. C7 from all strains, excepting the AKR strain, produced identical C7 band patterns. AKR C7 produced a unique band pattern, and results of breeding experiments with AKR and BALB/c mice showed the C6 and C7 loci to be closely linked. In addition, we identified a regulatory gene for C6 production. The gene apparently requires androgen to facilitate C6 production in the majority of strains. In these strains C6 activity is virtually absent from female sera. However, we observed moderate levels of C6 activity in sera from IS/Cam females, indicating that, in this strain, male physiological androgen levels are not necessary for C6 production. IS/Cam possess one form of circulating C6 which appears identical with BALB/c C6A1, and therefore IS/Cam mice differ from AKR mice at both the C6 structural and regulatory loci. These two strains were thus suitable for use in breeding experiments to determine the manner of action of the regulatory gene. Results showed that it acted in a cis manner.Abbreviations used in this paper M _r molecular weight - kd kilodaltons - SDS sodium dodecyl sulfate - PAGE polyacrylamide gel electrophoresis - IEF isoelectric focusing - Slp sex-limited protein - MHC major histocompatibility complex     

Constitutive expression of Slp genes in mouse strain B10.WR directed by C4 regulatory sequences

The murine fourth component of complement (C4) and sex-limited protein (Slp) are two closely related serum proteins that exhibit very disparate patterns of gene expression: all mice constitutively express C4, whereas only adult male mice from a limited number of standard inbred strains express Slp. Several exceptional strains exhibit constitutive (C4-like) Slp expression, a phenotype that correlates with multiple copies of the Slp gene. To determine the molecular basis for constitutive Slp expression we have isolated genomic clones and compared the sequences of 1.5 kb of 5' flanking DNA from 1 C4 gene and three different Slp genes from the Slp-constitutive strain B10.WR. These sequence comparisons demonstrate C4-like regulatory sequences adjacent to two of the Slp genes. By analysis of cDNA clones isolated from a B10.WR liver library we demonstrate that the constitutive Slp phenotype is due primarily to expression of one of these C4/Slp hybrid genes. It appears likely that Slp gene duplication in strain B10.WR came about via homologous unequal crossover events between C4 and Slp genes; this would accommodate both the gene sequence data and the pattern of C4-like Slp expression in mouse strain B10.WR.