TNFB polymorphisms characterize three lineages of TNF region microsatellite haplotypes

 The human major histocompatibility complex (MHC) contains a variety of genes, many of which are highly polymorphic and of immunological importance. A database of MHC extended haplotypes was used to integrate experimental, cell line, and population data. Three alleles of the human TNF-beta (lymphotoxin-alpha) gene were identified, named TNFB ^*1SL, TNFB ^*2LL, and TNFB ^*1LS, each representing a different lineage in the evolution of TNF region haplotypes. Lower variability in the length of the associated microsatellite alleles indicates that ^*1SL characterizes the youngest of the three haplotype lineages. Microsatellite haplotypes in the two older lineages show evidence for a coevolution of alleles through concerted expansions. Genetic predispositions to high and low TNF-alpha (cachectin) responses seem to have evolved independently in more than one lineage. The literature data suggest different, or even opposite, associations concerning the regulation of TNF-alpha in macrophages and lymphoid cells. Microsatellite ud may be the most informative marker for studies of the associations of individual TNF region markers with secretion levels, immunity, and disease. Received: 10 December 1996 / Revised: 21 May 1997     

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.     

Evolutionary relationship between human major histocompatibility complexHLA-DR haplotypes

 HLA-DR haplotypes of the human major histocompatibility complex are organized in five different groups. They can be identified based on the serological specificity expressed by the polymorphic DRB1 locus and by the presence of a characteristic set of DRB genes. The nucleotide sequences of introns 4 and 5 of the two DRB genes (DRB1 ^* 01 and DRB6 ^* 01) from a DR1 haplotype and the three DRB genes (DRB1 ^* 15, DRB6 ^* 15, and DRB5 ^* 15), from a DR51 haplotype were determined. This study identified endogenous retroviral long terminal repeat elements (ERV9 LTR) located at identical positions in intron 5 of the DRB1 genes in both the DR1 and DR51 haplotypes. Phylogenetic analyses revealed a close evolutionary relationship between these two haplotypes. The DRB5 gene, unique for the DR51 haplotype, may have been lost by a recent gene deletion event creating the DR1 haplotype. A model for the evolution of the human DR haplotypes involving separate duplication and contraction events is presented. Received: 10 October 1995 / Revised: 22 November 1995     

Heterogeneity inHLA-DR2-relatedDR,DQ haplotypes in eight populations of Asia-Oceania

The relative distributions of 480DR2-relatedDR, DQ haplotypes have been determined in Australian Aborigines, Papua New Guinean Highlanders, coastal Melanesians, Micronesians, Polynesians, Javanese, and Southern and Northern Chinese. Using sequence-specific oligonucleotides (SSOs) for hybridization of polymerase chain reaction (PCR) products from DRBI,DRBS,DQA1, andDQBI genes, 15 differentDR2-related haplotypes were identified. The predominantDR2 haplotype in Oceania involved a novel combination ofDRBI ^* 1502,DRB5 ^* 0101 alleles; this haplotype occurred sporadically in Java, but not in China. In Southern China, the most frequent DR2 haplotype involved the unusual arrangementDRB1 ^* 1602,DRB5 ^* 0101; alternatively,DRB1 ^* 1602 was associated with a newDRB5 SSO pattern. This study has important implications for molecular HLA-typing protocols that assume particularDRB1 DRB5 orDR,DQ linkage relationships. Further, the novelDRBI,DRB5 haplotype in Oceania suggests that the mixed lymphocyte culture (MLC) determinants Dw2 and Dw12 are discriminated by codon 86 at theDRBI locus.     

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.     

Diversity associated with the second expressed H L A - D R B locus in the human population

Although diversity within the HLA-DRB region is predominantly focused in the DRB1 gene, the second expressed DRB loci, DRB3, DRB4, and DRB5, also exhibit variation. Within DRB1 ^* 15 or DRB1 ^* 16 haplotypes, four new variants were identified: 1) two new DRB5 alleles, DRB5 ^* 0104 and DRB5 ^* 0204, 2) a haplotype carrying a DRB1 ^* 15 or ^* 16 allele without the usual accompanying DRB5 allele, and 3) a haplotype carrying a DRB5^* 0101 allele without a DRB1 ^* 15 or ^* 16 allele. The evolutionary origins of these haplotypes were postulated based on their associations with the DRB6 pseudogene. Within HLA haplotypes which carry DRB3, a new DRB3 ^* 0205 allele and one unusual DRB3 association were identified. Finally, two new null DRB4 alleles are described: DRB4 ^* 0201N, which exhibits a deletion in the second exon, and a second allele, DRB4 ^* null, which lacks the second exon completely. Gene conversion-like events and variation in the number of functional genes through reciprocal recombination and inactivation contribute to the diversity observed in the second expressed HLA-DRB loci. Received: 2 November 1996 / Revised: 23 December 1996     

Sequence-based association analysis of HLA class I and II alleles in Japanese supports conservation of common haplotypes

 Alleles of HLA-A, B, C, DRB1, DQB1, and DPB1 loci were fully determined in 117 healthy Japanese. A ^* 2402, A ^* 3303, A ^* 1101, A ^* 0201, B ^* 4403, B ^* 5201, Cw ^* 0102, Cw ^* 1403, Cw ^* 0304, Cw ^* 0702, Cw ^* 0801, and Cw ^* 1202 showed frequencies of over 10%. Multi-locus haplotype frequencies were estimated by the maximum likelihood method. Strength of association between C and B loci was comparable with that between DRB1 and DQB1 loci. Alleles unidentified by a serological method and having very similar nucleotide sequences (A2: A ^* 0201, A ^* 0206, A ^* 0207, B61: B ^* 4002, B ^* 4006) were carried by different haplotypes. Several frequent five-locus haplotypes were identified including A ^* 3303-Cw ^* 1403-B ^* 4403-DRB1 ^* 1302-DQB1 ^* 0604, and A ^* 2402-Cw ^* 1202-B ^* 5201-DRB1 ^* 1502-DQB1 ^* 0601. These sequence-based haplotypes corresponded to serology-based common haplotypes which have already been described in Japanese. These findings indicate that common HLA haplotypes consist of particular sets of HLA alleles and that these haplotypes have been conserved through recent human evolution. Received: 25 November 1996 / Revised: 20 January 1997     

Ancestral haplotypes reveal the role of the central MHC in the immunogenetics of IDDM

The major histocompatibility complex (MHC) contains multiple and diverse genes which may be relevant to the induction adn regulation of autoimmune responses in insulin dependent diabetes mellitus (IDDM). In addition to HLA class I and II, the possible candidates include TNF, C4, and several other poorly defined polymorphic genes in the central MHC region. This study describes two approaches which take advantage of the fact that the relevant genes are carried by highly conserved ancestral haplotypes such as 8.1 (HLA-B8, TNFS, C4AQO, C4B1, DR3, DQ2). First, three diabetogenic haplotypes (two Caucasoid and one Mongoloid) have been compared and it has been shown that all three share a rare allele of BAT3 as well as sharing DR3, DQ2. In 43 sequential patients with IDDM the cross product ration for BAT3S was 4.8 (p<0.01) and 6.9 for HLA-B8 plus BAT3S (p<0.001). Second, partial or recombinant ancestral haplotypes with either HLA class I (HLA-B8) or II (HLA-DR3, DQ2) alleles were identified. Third, using haplotypic polymorphisms such as the one in BAT3, we have shown that all the patients carrying recombinants of the 8.1 ancestral haplotype share the central region adjacent to HLA-B. These findings suggest that both HLA and non-HLA genes are involved in conferring susceptibility to IDDM, and that the region between HLA-B and BAT3 contains some of the relevant genes. By contrast, similar approaches suggest that protective genes map to the HLA class II region.     

Transcription and diversity of immunoglobulin lambda chain variable genes in the rat

The DRB region of the human major histocompatibility complex displays length polymorphism: Five major haplotypes differing in the number and type of genes they contain have been identified, each at appreciable frequency. In an attempt to determine whether this haplotype polymorphism, like the allelic polymorphism, predates the divergence of humansfrom great apes, we have worked out the organization of the DRB region of the chimpanzee Hugo using a combination of chromosome walking, pulsed-field gel electrophoresis, and sequencing. Hugo is a DRB homozygote whose single DRB haplotype is some 440 kilobases (kb) long and contains five genes. At least one and possibly two of these are pseudogenes, while three are presumably active genes. The genes are designated DRB ^* A0201, DRB2 ^* 0101, DRB3 ^* 0201, DRB6 ^* 0105, and DRB5 ^* 0301, and are arranged in this order on the chromosome. The DRB2 and DRB3 genes are separated by approximately 250 kb of sequence that does not seem to contain any additional DRB genes. The DRB ^* A0201 gene is related to the DRB1 gene of the human DR2 haplotype; the DRB2 ^* 0101 and DRB3 ^* 0201 genes are related to the DRB2 and DRB3 genes of the human DR3 haplotype, respectively; the DRB6 ^* 0105 and DRB5 ^* 0301 genes are related to the DRBVI and DRB5 genes of the human DR2 haplotype, respectively. Thus the Hugo haplotype appears to correspond to the entire human DR2 haplotype, into which a region representing a portion of the human DR3 haplotype has been inserted. Since other chimpanzees have their DRB regions organized in different ways, we conclude that, first, the chimpanzee DRB region, like the human DRB region, displays length polymorphism; second, some chimpanzee DRB haplotypes are longer than the longest known human DRB haplotypes; third, in some chimpanzee haplotypes at least, the DRB genes occur in combinations different from those of the human haplotypes; fourth, and most importantly, certain DRB gene combinations have been conserved in the evolution of chimpanzees and humans from their common ancestors. These data thus provide evidence that not only allelic but also haplotype polymorphism can be passed on from one species to another in a given evolutionary lineage.     

H2-A polymorphism contributes to H2-Eβ-mediated protection in collagen-induced arthritis

 Collagen-induced arthritis (CIA) is an animal model of auto-immune inflammatory polyarthritis which has features similar to rheumatoid arthritis (RA). Much like RA, susceptibility to mouse CIA is influenced by the major histocompatibility complex (MHC) and is restricted to the H2 haplotypes q and r. In previous experiments, we have found that the introduction of an H2-Eb ^d transgene in H2-A^q CIA-susceptible mice was able to protect these mice against disease development. More recently, we have proposed that the polymorphism of the first domain of the Eβ molecule modulates this protection, and that the presentation of a peptide from the third hypervariable region of the Eβ chain by the H2-A^q molecule plays an important role in this mechanism. In the present report, we investigated whether the H2-E-mediated protection is H2-A^q-specific and whether the source of collagen has any influence. While the source of collagen had no effect on the protection, our results showed that the H2-E molecule failed to protect B10.RIII (H2^r) mice against CIA. Further, the H2 haplotype r exerted a negative effect on the Eβ^d-mediated protection in H2-A^q-restricted disease. Our results provide additional proof that self-MHC-derived peptides, such as Eβ peptides, may play an important role in the T-cell repertoire education and/or modulation of the T-cell response in the periphery. Received: 29 May 1996 / Revised: 26 June 1996     

Strong association between microsatellites and anHLA-B,DR haplotype (B18-DR3): implication for microsatellite evolution

TheHLA haplotypeB18-DR3 has a widespread geographical distribution, but has its greatest frequencies in Southern Europe, probably vestigial of the earliest populations of this region, particularly in the Pays Basque and Sardinia. This haplotype is of medical significance, being that most implicated as a factor of risk in insulin-dependent diabetes mellitus. In this study, the closely linked microsatellite markers (TNFa,b,c) in the region of the tumor necrosis factor (TNF) genes have been used in an attempt to subtype this haplotype in the two populations and/or in healthy and diabetic populations. A total of 79HLA-B18-DR3 haplotypes were analyzed: 54 in Basques (12 from healthy individuals and 42 from diabetics or their first-degree relatives) and 25 in Sardinians (13 from healthy and 12 from diabetic individuals). TheTNF haplotypea1-b5-c2 is completely associated withB18-DR3 in both populations. The homogeneity of theB18-DR3 haplotype in two ethnically pure populations implies stability in evolution, which suggests that the mutation rate of these microsatellite markers must be less than is usually assumed (i.e., ∼ 5×10⁻⁴ per site per generation). Such markers should be powerful tools for studying genetic drift and admixture of populations, but it remains to be established whether this stability is a rule for all microsatellites inHLA haplotypes or whether it is restricted to some microsatellites and/or someHLA haplotypes. The population genetics of those microsatellites associated withHLA B18-DR3 was also studied in a random sample of the Basque population.     

Immunofixation for C2 typing: C2 allotypes in Spaniards in relation to HLA,Bf and C4

Summary C2 typing is performed by immunofixation with anti-C2 antiserum instead of by a hemolytic overlay. This method gives sharp band definition, is less cumbersome than the hemolytic overlay, gel files are easily made, and it also enables one to describe putative new nonhemolytic variants. C2 allele frequencies were studied in a sample of the normal Spanish population and were found to be similar to other Caucasoids. HLA-Bw62,-Cw3, and-DR4 were significantly associated with C2 B. Concordantly, the only C2^*B extended HLA haplotype found in family material was Bw62-Cw3-Bw6-(DR4)-Bf^*S-C2^*B-C4A^*3 B^*2-(GLO^*1). C4A^*4 B^*2 and C4A^*4 B^*4 are not found within the same haplotype together with C2^*B and Bw62 or Bw22 respectively, nor do other C2^*B haplotypes occur with common HLA-B alleles. These results may favour the hypothesis that the Bw62-C2^*B haplotype is produced by one mutation arising in the Bw62-C2^*C haplotype and that subsequent crossovers can explain other C2^*B haplotypes (including Bw22-C2^*B).     

Deletion,insertion, and restriction site polymorphism of the T-cell receptor gamma variable locus in French,Lebanese, Tunisian,and Black African populations

The human T-cell receptor gamma region spans 160 kb of genomic DNA and is densely populated by coding sequences. Restriction fragment length polymorphisms have been previously documented for the constant region genes, the joining segments, and the variable genes belonging to subgroups I and IV. Here were further define the polymorphism of theV gamma I subgroup genes, based on complete mapping of theEco RI andTaq I allelic restriction fragments. We describe seven haplotypes; five result from polymorphic restriction sites, the sixth corresponds to a deletion of about 10 kb encompassingV4 andV5, and the seventh results from an insertion of an additional gene,V3P, betweenV3 andV4. As a consequence of the deletion or insertion polymorphism, the number ofV gamma I subgroup genes vary from seven in haplotypeTRGVI ^*3 to ten in haplotypeTRGVI ^*4, whereas the most common haplotype,TRGVI ^*1, has nineV genes, five of them being functional. Frequencies of the differentTRGVI haplotypes in French, Lebanese, Tunisian, and Black African populations are given.     

Characterization of S tester lines in Brassica oleracea: polymorphism of restriction fragment length of SLG homologues and isoelectric points of S-locus glycoproteins

 Forty three S tester lines of Brassica oleracea were characterized using DNA and protein gel-blotting analyses. DNA gel-blot analysis of HindIII-digested genomic DNA with class-I and class-II SLG probes revealed that 40 lines could be classified as class-I S haplotypes while three lines could be classified as class-II S haplotypes. The band patterns in the S tester lines were highly polymorphic. Although the S tester lines typically showed two bands corresponding to SLG and SRK in the analysis with the class-I SLG probe, only one band was observed in the S ²⁴ homozygote. This band was identified as SRK, suggesting that this haplotype has no class-I SLG band. In the analysis using the class-II SLG probe, one plant yielded a different band pattern from the known class-II haplotypes, S ² , S ⁵ and S ¹⁵ . Unexpectedly, this plant was reciprocally cross-incompatible with the S ² haplotype. Therefore, it was designated as S ^2-b . We found an S ¹³ haplotype having a restriction fragment length polymorphism different from that of the S ¹³ homozygotes of the S tester line. These findings indicate that S homozygous lines with the same S specificity do not necessarily show the same band pattern in the DNA gel-blot analysis. Soluble stigma proteins of 32 S homozygotes were separated by isoelectric focusing and detected using anti-S ²² SLG antiserum. S haplotype-specific bands were detected in 27 S homozygotes but not in five S homozygotes, including the S ²⁴ homozygote. This is consistent with the observation that the S ²⁴ haplotype had no SLG band. Received: 13 July 1998 / Accepted: 29 September 1998     

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.     

The study of a French family with two duplicated C4A haplotypes

Summary The finding of two duplicated C4A haplotypes in a normal French family led to a detailed study of their C4 polymorphism. The father had an extremely rare A^*6A^*11, B^* QO haplotype inherited by all of his children and the mother had the more common A^*3A^*2, B^*QO haplotype. Two HLA identical daughters only have four C4A alleles. The father's A11 allotype expresses Ch: 1 (Chido) rather than Rg:1 (Rodgers) and represents a new Ch phenotype Ch: 1,-2,-3,-4,-5,-6. In order to clarify the genetic background in this unusual family, DNA studies of restriction fragment length polymorphisms (RFLPs) were undertake. The father's rare haplotype, which expresses two C4A allotypes, results from a long and a short C4 gene normally associated with the A^*6, B^*1 that also exhibits the BglII RFLP. As it travels in an extended MHC haplotype HLA A2, B57 (17), C2^*C, BF^*S, DR7 that is most frequently associated with A^*6, B^*1, we postulate that the short C4B has been converted in the chain region to a C4A gene which produces a C4A protein. This report of a short C4A gene is the first example in the complex polymorphism of C4.     

Generation of the HLA-B35, -B5, -B16, and B15 groups of alleles studied by intron 1 and 2 sequence analysis

 HLA-B is the most polymorphic of the major histocompatibility complex classical class I loci. This polymorphism is mainly in exons 2 and 3, which code for the molecule’s α1 and α2 domains and include the antigenic peptide binding site. Recent studies have indicated that not only exons but also the intron 2 region may be involved in the generation of certain HLA-B alleles such as B ^* 3906 and B ^* 1522. To study the degree of intron 2 participation and the mechanisms that generate polymorphism at the HLA-B locus, intron 1 and 2 sequences from the HLA-B35, -B5, -B16 and -B15 groups of alleles were obtained. A group-specific intronic polymorphism was found: namely, B ^* 5301 shows intron 1 and 2 sequences identical to those found in all B35 alleles studied. On the other hand, B ^* 5101 and B ^* 52012 show the same intron 1 and 2 sequences and their intron 1 is the same as that found in the B35 group. This suggests that B5 and B35 groups of alleles may have arisen from a common ancestor. All known B16 alleles show the same introns 1 and 2, with the exception of B ^* 39061 and B ^* 39062, and all B15 alleles also bear the same introns 1 and 2, with the exception of B ^* 1522. Variability at intron 1 is more restricted than at intron 2, and the use of intron 1 for HLA-B allele phylogenetic analysis is better for grouping alleles of a postulated common origin. In conclusion, there is a remarkable conservation of intronic sequences within related HLA-B alleles, which probably reflects a common origin and perhaps a selective force avoiding DNA changes. Intronic sequences are also potentially useful to design DNA typing strategies. Received: 11 March 1997 / Revised: 29 May 1997     

HLA-G gene polymorphism in a Japanese population

 Polymorphism of the HLA-G gene in a Japanese population was investigated employing polymerase chain reaction (PCR)-single-strand conformation polymorphism (SSCP) analysis, PCR sequence-specific oligonucleotide (SSO) analysis, and DNA direct sequencing. Nucleotide sequence variations in exons 2, 3, and 4 of the HLA-G gene in 54 healthy Japanese individuals were examined. In addition, seven Japanese samples carrying common HLA haplotypes were analyzed. In total, nine single-base substitutions compared with the sequence of G ^* 01011 were identified: one in intron 1 (nucleotide position 970), one in exon 2 (the third base of codon 57: G → A), three in intron 2 (1264, 1276, and 1292), three in exon 3 (the third base of codon 93: C → T, the third base of codon 107: A → T, and the first base of codon 110: C → A), and one in intron 3 (2334). The substitution at codon 110 was non-synonymous and led to an amino acid substitution from leucine to isoleucine. The other three nucleotide substitutions in exons were synonymous. Through analysis of combinations of the exon 2, 3, and 4 nucleotide sequences we identified four alleles, which we provisionally designated GJ1, GJ2, GJ3, and GJ4. The allele frequencies were estimated to be 0.33, 0.16, 0.45, and 0.06, respectively. Nucleotide sequences of GJ1, GJ2, and GJ4 were identical to G ^* 01011, the clone 7.0E, and G ^* 01013, respectively. GJ3 was a newly observed allele and was officially designated G ^* 0104 by the WHO Nomenclature Committee in January 1996. Strong positive associations were observed between HLA-G alleles and HLA-A, -B, or -DRB1 alleles. Received: 15 February 1996 / Revised: 26 March 1996