A new BF variant (F025)

A rare variant of Factor B exhibiting a mobility intermediate between BF F and BF S was described. After comparison with the mobilities of BF F and F075, this variant was designated BF F025. The allele was transmitted together with C2*C, C4A*3, and C4B*1.     

Partial C4 deficiency in subacute sclerosing panencephalitis

In an immunogenetic study, 23 subacute sclerosing panencephalitis (SSPE) patients and their families were studied for the HLA region markers HLA-A, B, C, DR, BF, C2, C4A, C4B, GLO I, and PGM3. In addition, C3, C4, and factor B serum levels were determined. A highly significant association of C4A^*QO with SSPE was found. Furthermore, two rare haplotypes, C4A*QOB*9QO, two C4ACh+ allotypes, and four Ch partial inhibitors were detected, which possibly impair the function of the C4 molecules. HLA-DR5 was increased. In addition, a number of rare HLA-A, C, B, DR haplotypes were observed. It is postulated that rare C4 molecular deficiency might be a predisposing factor in the pathogenesis of SSPE.     

Human C4 haplotypes with duplicated C4A or C4B

In the course of study of families for the sixth chromosome markers HLA-A, C, B, D/DR, BF, and C2, the two loci for C4, C4A, and C4B, and glyoxalase I, we encountered five examples of probable duplication of one or the other of the two loci for C4. In one of these, both parents and one sib expressed two different structural genes for C4B, one sib expressed one, and one sib expressed none, suggesting that two C4B alleles were carried on a single haplotype: HLA-A2, B7, DR3, BFS1, C2C, C4A2, C4B1, C4B2, GLO1. In a second case, two siblings inherited C4B*1 and C4B*2 from one parent and C4B*Q0 from the other. This duplication appeared on the chromosome as HLA-AW33, B14, DR1, BFS, C2C, C4A2, C4B1, C4B2, GLO2. In a third, very large family with 3 generations, a duplication of the C4B locus occurred which was followed in 2 generations. In one individual, there were three C4B alleles and two C4A alleles. One of the C4B alleles had a hemolytically active product with electrophoretic mobility near C4B2 and was designated C4B*22. It segregated with C4B1 in the family studied. The complete haplotype was HLA-A11, CW1, BW56, DR5, BFS, C2C, C4A3, C4B22, C4B1, GLO2. In another family with 12 siblings, one parent and eight children expressed two C4A alleles on the haplotype HLA-AW30, BW38, DR1, BFF, C2C, C4A3, C4A2, C4BQ0, GLO1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Another family with a silent allele of properdin factor B polymorphism (BF*QO)

Summary In five of eight members of a three generation family the existence of a silent allele of the properdin factor B polymorphism (BF^*QO) was indicated by immunofixation of BF electrophoretic variants and by the hemolytic overlay after isoelectric focusing of BF allotypes. This was further supported by the results of HLA-A, B, C, DR, C2, C4A, C4B, GLO-typing. BF protein was decreased in all heterozygous BF deficient family members. The absolute hemolytic activity, however, was obviously compensated for by an increased relative functional activity of the normal S or F alleles on the other chromosome.     

Allelic differences in hemolytic activity and protein concentration of BF molecules are found in association with particular HLA haplotypes

After separating the *F and *S alleles by electrophoresis the allele-specific hemolytic activity was detected by agarose overlay method using the programmable densitometer for scanning. The hemolytic activity of BF allotypes was analyzed from 81 individuals. In thirteen FS heterozygous serum samples BF F had lower hemolysis than BF S. Four FF homozygous samples also exhibited lower hemolysis than a homozygous control sample. The low hemolytic activity of F in FS heterozygotes was not due to decreased protein concentrations relative to S. On the contrary, BF F was associated with higher protein concentration than BF S. The relative quantitation of the allele specific BF protein was done by crossed immunoelectrophoresis. BF F with low hemolytic activity but with high protein concentration associated strongly with HLA B35 phenotype and the family material confirmed the association with the haplotypes A3, Cw4, B35, DR1, BFFB, C4A3BQO (or A2BQO, A3,2BQO). The results suggest that particular MHC haplotypes contain a factor B allele with encoding for poor hemolytic activity or that MHC haplotype specific regulatory elements affect pre- or post-translational activity levels.     

A new BF F variant by polyacrylamide gel isoelectric focusing

Summary Polyacrylamide gel isoelectric focusing followed by electroblotting with enzyme immunoassay was done for the investigation of allotypes of properdin factor B (BF) in serum from 326 Japanese subjects. A new BF F variant tentatively designated BF*Fb1 (b=basic) was detected, the isoelectric point of each band of homozygous BF Fb1 being higher than of BF FF. Family data were in accordance with transmission by mendelian inheritance. The allele frequencies calculated from 326 Japanese subjects were 0.7945, 0.1825, 0.0215, and 0.0015 for BF*S, BF*F, BF*Fb1, and BF*F075, respectively, with that of variant BF*Fb1 being a polymorphic frequency. The distribution of phenotypes fitted the Hardy-Weinberg equilibrium.     

Human C4 polymorphism: Pedigree analysis of qualitative,quantiative, and functional parameters as a basis for phenotype interpretations

Summary Ten families with 82 members were investigated for C4A- and B polymorphism in a blind trial. Phenotyping was done on neuraminidase treated sera by immunofixation and simulataneously by hemolytic overlay electrophoresis. In addition Rg, Ch, BF, C2, HLA-A, B, C, DR, and GLO were determined. After decoding the samples the reliability of blind typing was found to be 84.4% according to segregation patters. Inconsistencies occurred mostly when A 4, A 2, or A 92 were present. The detection of silent A*Q0 and B*Q0 alleles was more critical than that of difficult allotypes. The quantitation of the C4A/B ratio by densitometry of stained gels or by conventional immunochemical measurements of serum C4 level could not substantially improve the identification of A*Q0 or B*Q0. C4 dependent activity in radial diffusion hemolysis showed satisfactory correspondence with the number of expressed C4B alleles. At least three haplotypes with two C4A genes (duplicated A genes) were observed as ascertained from offspring analysis in accordance with the MHC segregation pattern. Individuals with the duplicated C4A gene (C4A*3. A*2. in the absence of any other expressed A allele or together with C4A*92) showed only partial inhibition of Rodgers antisera. Partial inhibition of Chido antisera was seen in individuals with C4B 2 (in the absence of other B allotypes). The findings support the hypothesis of at least two structural C4 loci. The also demonstrate the inconsistency of quantitative data in the recognition of silent alleles.     

Major histocompatibility complex (MHC) class III genetics in two Amerindian tribes from Southern Brazil: the Kaingang and the Guarani

Population genetic studies of the major histocompatibility complex (MHC) class III region, comprising C2, BF and C4 phenotypes, and molecular genetic data are rarely available for populations other than Caucasoids. We have investigated three Amerindian populations from Southern Brazil: 131 Kaingang from Ivaí (KIV), 111 Kaingang (KRC) and 100 Guarani (GRC) from Rio das Cobras. Extended MHC haplotypes were derived after standard C2, BF, C4 phenotyping and restriction fragment length polymorphism (RFLP) analysis with TaqI, together with HLA data published previously by segregation analysis. C2 and BF frequencies corresponded to other Amerindian populations. C4B*Q0 frequency was high in the GRC (0.429) but low in the Kaingang. Unusual C4 alleles were found, viz. C4A*58, A*55 and C4B*22 (presumably non-Amerindian) and aberrant C4A*3 of Amerindian origin occurring with a frequency of 0.223 in the GRC. C4A*3 bands of homo- and heterozygous individuals carrying this variant were Rodgers 1 positive and Chido 1,3 positive, showed a C4A specific lysis type and a C4A like α-chain. Polymerase chain reaction studies and sequencing showed that this is based on a C4A*3 duplication with a regular C4A*3 and a partially converted C4A*0304 carrying the C4B specific epitopes Ch 6 and Ch 1,3. Associations of class III haplotypes with particular RFLP patterns were similar to those reported for Caucasoids. The previously described association between combined C4A and CYP21P deletions and the 6.4 kb TaqI fragment was not seen in these Amerindians. This fragment occurred within a regular two locus gene structure in the Kaingang, representing a “short” gene at C4 locus I. C4 and CYP21 duplications were frequently observed. The distribution of extended MHC haplotypes provides evidence for a close relationship between the KIV and KRC and a larger genetic distance between the two Kaingang groups and the GRC. Received: 6 March 1997 / Accepted: 13 May 1997     

Human BF*F-subtypes: segregation analysis with inclusion of MHC haplotypes

Summary The segregation of factor B(BF)F subtypes was analyzed in conjunction with other MHC markers in 15 families with 89 offspring. Informative data for BF F subtypes were obtained from 11 families, 6 of them with known recombinant individuals for the HLA-B/DR/GLO region. The subtypes did not contribute further to the localization of the cross-overs, but followed the known segregation of conventional BF allotypes. In 2 families of one kinship, the recognition of heterozygous BF^*FAFB individuals could be established following the inclusion of three generations. The rarer of the two BF F subtype alleles, BF^*FA, is positively associated with the HLA haplotypes BW62, CW3, C4A^*3 and A29, CWX, B44, C4A^*3, B^*1, DR7. BF F subtypes are regarded as a very useful additional tool for studies of MHC organization and disease association.     

Identification of novel Tapasin polymorphisms and linkage disequilibrium to MHC class I alleles

Tapasin is a Mr 48,000 glycoprotein and has a specialized role in MHC class I-restricted antigen presentation. It is encoded by a gene which maps centromeric to the MHC class II region of human Chromosome 6 within 200 kb of HLA-DP. There is variable dependence upon tapasin for MHC class I expression among different MHC class I alleles. HLA-B*4402 and to a lesser extent HLA-A1 and B8 are tapasin dependent, whereas HLA-B27, A2 and to a lesser extent B7 and A3 are tapasin independent. We investigated whether tapasin is polymorphic and whether these Tapasin alleles are in linkage with any MHC class I alleles. We identified three new mutations within intron 4, which are in a particular linkage with the previously described exon 4 (G16003C) dimorphism. The intronic mutations are G16146T, G16232A, and T16317A (numbering according to cosmid clone F0811; GenBank accession number Z97184). The allele frequency of Tapasin*01 (G16003) was 0.47 and Tapasin*02 (C16003) was 0.53 in this UK population. Four of the eight possible intronic haplotypes were identified and their cis linkage with the tapasin dimorphism ascertained. Tapasin*01 was associated with all the identified haplotypes, while Tapasin*02 was only associated with the wild-type intronic sequence (GGT). There was no significant linkage (P>0.01) of the Tapasin dimorphism or new Tapasin alleles to any of the MHC class I A, B, or C alleles studied or to the extended A1 B8 DR3 haplotype.     

Identification of HLA-B44 subtypes associated with extended MHC haplotypes

The HLA class I antigen B44 is found in each of two different extended major histocompatibility haplotypes (allele combinations of HLA-B, HLA-DR, and complement genes BF, C2, C4A, and C4B in linkage disequilibrium). Using isoelectric focusing, two variants of HLA-B44 were identified. The basic variant was found in all cell lines with the extended haplotype HLA-B44, DR7, FC31, and the acidic variant in all cell lines with the extended haplotype HLA-B44, DR4, SC30. The occurrence of each antigen variant with a unique extended haplotype explains previous observations concerning the nonrandom association of B44 variants with DR antigens.     

Serum protein polymorphisms in Arab Moslems and Druze of Israel: BF, F13B, AHSG, GC, PLG, PI, and TF.

We report results of typing two population samples, Israeli Arab Moslems and Arab Druze, for seven serum protein genetic variants. Data are presented in comparison with results for the same markers in a sample of Jordanian Arabs. In Israeli Moslems gene frequencies for BF (n = 169) were BF*S = 0.6361, BF*F = 0.3343, BF*S07 = 0.0296, and BF*1 = 0, and for TF (n = 90) the gene frequencies were: TF*C1 = 0.7167, TF*C2 = 0.2611, and TF*C3 = 0.0222. Allele frequencies for AHSG in Israeli Moslems (n = 155) and Druze (n = 192) were AHSG*1 = 0.9129 and 0.8750 and AHSG*2 = 0.0806 and 0.1250, respectively. Gene frequencies for PLG in Moslems (n = 149) and Druze (n = 190) were PLG*A = 0.4597 and 0.5288 and PLG*B = 0.5101 and 0.4188, respectively. The typing of Israeli Arab Druze (n = 194) for F13B resulted in F13B*1 = 0.8454, F13B*2 = 0.0387, F13B*3 = 0.0979, and F13B*4 = 0.0180. Results on the same population for PI (n = 192) were PI*M1 = 0.7839, PI*M2 = 0.1276, PI*M3 = 0.0781, PI*M4 = 0.0026, and PI*M5 = 0.0026. Observed rare alleles in various systems indicate gene flow from Europe, Africa, and Asia into the Middle East. The results on Arab populations were considered in relation to available population data in the three adjacent continents. The emerging gene frequency profile for Arabs seems to fit with the central geographic and climatic position of the Middle East.     

Although divergent in residues of the peptide binding site, conserved chimpanzee Patr-AL and polymorphic human HLA-A*02 have overlapping peptide-binding repertoires

Patr-AL is an expressed, non-polymorphic MHC class I gene carried by ～50% of chimpanzee MHC haplotypes. Comparing Patr-AL(+) and Patr-AL(-) haplotypes showed Patr-AL defines a unique 125-kb genomic block flanked by blocks containing classical Patr-A and pseudogene Patr-H. Orthologous to Patr-AL are polymorphic orangutan Popy-A and the 5' part of human pseudogene HLA-Y, carried by ～10% of HLA haplotypes. Thus, the AL gene alternatively evolved in these closely related species to become classical, nonclassical, and nonfunctional. Although differing by 30 aa substitutions in the peptide-binding α(1) and α(2) domains, Patr-AL and HLA-A*0201 bind overlapping repertoires of peptides; the overlap being comparable with that between the A*0201 and A*0207 subtypes differing by one substitution. Patr-AL thus has the A02 supertypic peptide-binding specificity. Patr-AL and HLA-A*0201 have similar three-dimensional structures, binding peptides in similar conformation. Although comparable in size and shape, the B and F specificity pockets of Patr-AL and HLA-A*0201 differ in both their constituent residues and contacts with peptide anchors. Uniquely shared by Patr-AL, HLA-A*0201, and other members of the A02 supertype are the absence of serine at position 9 in the B pocket and the presence of tyrosine at position 116 in the F pocket. Distinguishing Patr-AL from HLA-A*02 is an unusually electropositive upper face on the α(2) helix. Stimulating PBMCs from Patr-AL(-) chimpanzees with B cells expressing Patr-AL produced potent alloreactive CD8 T cells with specificity for Patr-AL and no cross-reactivity toward other MHC class I molecules, including HLA-A*02. In contrast, PBMCs from Patr-AL(+) chimpanzees are tolerant of Patr-AL.     

Restriction fragment analysis of duplication of the fourth component of complement (C4A)

The two genes encoding the fourth component of complement (C4A and C4B) reside between HLA-B and HLA-DR on human chromosome 6. Two kilobases downstream from each C4 gene lies a 21-hydroxylase gene (CA21HA and CA21HB, respectively). Utilizing the method of Southern blotting and a 5'-end 2.4-kb BamHI/KpnI fragment of the C4 cDNA, we have analyzed TaqI-digested DNA from four pedigrees with one or more extended haplotypes containing a C4A duplication, as demonstrated by protein electrophoresis and segregation analysis. Two C4A protein duplications (C4A*2,A*3,C4B*QO and C4A*3,A*5,C4B*QO) segregated with two large TaqI DNA restriction fragments (7.0 and 6.0). In pedigree Fi, one individual homozygous for HLA-A3,B35,C4,DR1,DQ1,BFF,C2C,-C4A2,3,C4BQO had TaqI 7.0- and 6.0-kb restriction fragments with equal hybridization intensities as measured by two-dimensional densitometry (7.0/6.0 kb = 0.83, SD = 0.12, N = 7). A hybridization probe for the 21-hydroxylase gene also demonstrated equal gene dosage (CA21HA/CA21HB = 1.01). DNA from another individual (Ma I-2) with a different C4A gene duplication (C4A*3,A*5,C4B*QO) also had equal densitometry measurements (7.0/6.0 kb = 1.07). We conclude that two extended haplotypes from unrelated pedigrees have two C4 genes and both C4 genes encode separate C4A alleles. These findings are compatible with a gene conversion event of C4B to C4A.     

Complotype genetic loci segregate more frequently with HLA-DR than with HLA-B

The loci for BF, C2, C4A, and C4B are very closely linked to each other so that alleles of these plasma protein markers occur in populations in linkage disequilibrium and are inherited as single genetic units called complotypes. These complotypes are coded by a DNA region of the short arm of chromosome 6 embracing approximately 100 kilobases, which serve as a marker of the major histocompatibility complex. We have studied the complotypes of nine families with known HLA-B/DR crossovers. In seven families, the complotypes were inherited with HLA-DR, including in one family with a double recombination. The haplotype HLA-A28, Cw1, B27, FC3, 20, DR4 of JTr resulted from two recombinations between HLA-A2, Cwl, B27, SC42, DR7 and HLA-A28, Cwx or Cw1, B37, FC3, 20, DR4. In the remaining two families (Ro and Lo) the complotypes were inherited with HLA-B. The haplotype A2, Cw5, Bw44, SC30, DR3 of StLo resulted from paternal recombination between the haplotypes A2, Cw5, Bw44, SC30, DR4 and A24, B8, SC01, DR3, and the haplotype A24, Cw4, Bw35, SC31, DR3 of NaRo resulted from maternal recombination between A24, Cw4, Bw35, SC31, DR4 and A26, Bw41, FC31, DR3. Our data suggest that the complotype region maps closer to HLA-D than to HLA-B.     

The location ofC2, C4, andBF relative toHLA-B andHLA-D

The loci forHLA-A, B, C, D, andDR are known to be closely linked to the structural loci for the complement components C2, BF, and the duplicated loci for C4, C4A and C4B. Conflicting evidence has been presented for the order of these genes. However, new techniques have made possible identification of markers in theHLA-D andC4 region for nearly all identified haplotypes. In our population we have confirmed fiveHLA-B-D crossovers and in each case informative allotypes of C2, BF, or C4A and C4B segregated withHLA-D orDR suggesting that the loci for these proteins lie close toHLA-D andDR. These findings may be of importance for resolving problems encountered in the assignment ofHLA-D alleles.     

Linkage disequilibrium of HLA-SB1 with the HLA-A1, B8, DR3, SCO1 and of HLA-SB4 with the HLA-A26, Bw38, Dw10, DR4, SC21 extended haplotypes

Homozygous typing cells from 13 normal HLA-A1, B8, Dw3, DR3 and five normal HLA-A26, Bw38, Dw10, DR4 individuals were typed for the following markers: HLA-SB, MB, MT; complement proteins BF, C2, C4A, C4B; and GLO. Ninety-one percent of A1, B8, Dw3, DR3 homozygous individuals (HI) tested were homozygous for BF ^* S, C2 ^* C, C4A ^* QO, and C4B ^*1 (SCO1 complotype), which indicates that the SCO1 complotype is in linkage disequilibrium with the A1, B8, DR3 haplotype in randomly selected normal populations. Sixty-seven percent of HLA-A1, B8, Dw3, DR3, SCO1 positive HI also expressed SB1; since the frequency of SB 1 in random Caucasian populations is 11.2%, this finding indicates that SB1 is in linkage disequilibrium with the A1, B8, DR3, SCO1 extended haplotype. All HI with the A26, Bw38, Dw10, DR4 haplotype were homozygous for both SC21 and SB4, suggesting that SC21 and SB4 should be included in the A26, Bw38, Dw10, DR4 extended haplotype. On the other hand, neither of the GLO markers were found in association with either haplotype. The results of this study indicate that HLA-SB is included in some extended haplotypes and may be important in these markers for diseases such as insulin-dependent diabetes mellitus. This study also demonstrated an apparent influence of HLA-SB on primary mixed lymphocyte culture (MLC) responses. The mean relative response of primary MLCs between individuals matched for HLA-A, B, D, DR, MB and MT but not SB was 40% of that for the MLCs with mismatched HLA-D, significantly higher than the MLCs matched for all HLA and complotypes.     

BF and C3 genetic polymorphisms in Kaingang Indians from southern Brazil.

The distribution of C3 and BF variants was determined in a sample of 239 Kaingang Indians. The corresponding gene frequencies were as follows: BF*S = 0.9393, BF*F = 0.0356, BF*S05 = 0.0251, C3*S = 0.9769, C3*F = 0.0231. The presence of the BF*S05 allele, which has previously been found only in a Brazilian population, suggests that this allele originated in Amerindians. The comparatively low degree of polymorphism with high frequencies of BF*S and C3*S is in accordance with the relatedness of the Kaingang with other Amerindians, Eskimos and Asian populations.     

内蒙古地区蒙古族HLA-A、B、DRB1基因座多态性分析

应用序列特异性寡核苷酸探针反向斑点杂交技术对内蒙古地区蒙古族106名无关健康个体的HLA-A、B和DRB1 基因座进行基因分型, 以研究内蒙古地区蒙古族人群HLA-A、B、DRB1基因座的等位基因及其组成的单倍型频率分布特征。 采用最大数学预期值算法计算HLA基因座的等位基因频率和单倍型频率。106 名内蒙古地区蒙古族个体的HLA-A、B、DRB1基因座分别检出13、29、13个等位基因。高频单倍型分别为 HLA-A*02-B*46 (0.0510); HLA-A*02-B*13(0.0495); HLA-A*02-B*51(0.0442); HLA-B*13-DRB1*07 (0.0555); HLA- B*46-DRB1*09(0.0378); HLA-B*35-DRB1*13(0.03300); HLA-A*02-B*13-DRB1*07(0.033019); HLA-A*02-B*46- DRB1*09(0.031985)。研究表明: 内蒙古地区蒙古族人群HLA基因座的等位基因和单倍型具有较高的遗传多态性。HLA- A*24-B*14, HLA-A*32-B*63在该民族具有极强的连锁不平衡。     

Factor B (BF) allotypes and multiple sclerosis in north-east England.

A significant decrease in the frequency of BF*F allele and an increase of BF*F1 allele was found in 101 clinically definite multiple sclerosis patients compared to 270 normal controls from North-East England. In Dw2 types 41 patients and 60 controls, only the rare allele BF*F1 showed a significant increase in the patients group. For the common BF*S allele a significant increase was found in Dw2+ patients compared to the Dw2- patients, but a slight similar increase observed in Dw2+ controls did not attain significance. This increase in the patient group is attributed to a strong linkage disequilibrium between BF*S and Dw2 alleles. No such linkage disequilibrium exists in the normal controls. There is a suggestion that the BF*S and Dw2+ alleles are more prevalent in chronic progressive patients, implying that in Dw2+ patients BF may influence the progression of the disease.