HLA-B*15 diversity in the Korean population

Alleles in the HLA-B*15 group encode molecules belonging to several serologic subgroups, B15 (B62, B63, B75, B76, B77) and B70 (B71, B72), representing many of the most problematic types to assign in routine clinical typing laboratories due to their serologic cross-reactivity resulting from structural similarity. More than 25% of Koreans express HLA-B molecules encoded by the HLA-B*15 alleles. To further characterize HLA-B*15 in this population, B*15-specific polymerase chain reaction (PCR) and sequence-specific oligonucleotide probe (SSOP) hybridization analysis using 39 digoxigenin-labeled probes were applied to DNA samples obtained from 237 B15/B70 serologically positive unrelated individuals. Nine B*15 alleles were identified. B*1501 was the most frequent allele (64.8%) followed by B*1511 (14.1%), B*1507 (8.6%), and B*1518 (5.5%) comprising more than 90% of B*15-positive samples. B62 molecules encoded by 4 of the identified alleles (B*1501, B*1507, B*1525, and B*1527) could not be discriminated by serologic reaction patterns. Among the fifteen B15/B70 apparent homozygotes, eight were heterozygotes carrying two different B*15 alleles. Several B*15 alleles exhibited strong associations with specific Cw, DRB1, and A allelic types (e.g., B*1507-Cw3 (22/22); B*1507-DRB1*04 (21/22), B*1507-A24 (17/22)). The data obtained in this study confirmed B*15 diversity in the study population and will be useful in hematopoietic stem cell donor searches as well as in determining the supplementary DNA typing strategy for B15/B70-positive samples in this population.     

HLA-B*4021: hybrid linking the B15 and B40 families

Twenty alleles encoding molecules with the B60 or B61 serologic specificity have been reported thus far. This study characterized a new allele encoding a molecule exhibiting partial serologic reactivity with B15- and B40-related alloantisera from unrelated Korean individuals. Based on the DNA sequence, it appears that the novel allele has a sequence identical to some of alleles in B*15 family including B*1501 in exon 2. The sequence in exon 3, however, is identical to alleles in the B*40 family (B*4001/07/10/12) and B*4803. This implies that the novel allele, B*4021, has evolved by a reciprocal gene recombination involving members of these two families. The haplotype associated with B*4021 is likely to be A11-Cw4-B*4021-DRB1*04-DRB4*01-DQA1*03-DQB1*0301 .     

HLA-B Alleles Associated with the B15 Serologically Defined Antigens

ABSTRACT: Cells expressing HLA molecules in the B15 family were identified by serologic typing in routine testing of volunteer donors of various ethnic backgrounds for a bone marrow registry. DNA sequencing was used to identify HLA-B15 alleles associated with each serologic type and to examine the diversity within the B15 antigen family. Alleles which appeared predominantly in each B15 serologic cluster included: B15 with no defined serologic subdivision (B*1501), B62 (B*1501), B63 (B*1516, B*1517), B75 (B*1502, B*1521), and B76/77 (B*1513). Other B*15 alleles were also found associated with the serotypes and some of these alleles (e.g., B*1501 and B*1516) were found in two or more serologic clusters illustrating the complexity of this family. The B15 unsplit and B75 groups were the most complex exhibiting 16 and 7 alleles, respectively, within each serotype. Five new B*15 alleles (B*1530, B*1531, B*1533, B*1534, B*1535) and 5 other new HLA-B alleles (B*38022, B*3910, B*4010, B*51012, and B*5108) were also identified.     

Polymorphism of the HLA-B*15 group of alleles is generated following 5 lineages of evolution

Generation of the HLA-B*15 group of alleles has been analyzed using exon 1, intron 1, exon 2, intron 2, and exon 3 sequences from human and nonhuman primates. Results indicated that the 230 alleles analyzed could be grouped into 5 different lineages of evolution coming from nonhuman primate MHC-B* alleles sharing characteristic nucleotide sequences. The major evolutionary mechanism of evolution in this group of alleles is the gene conversion event with the exchange of genomic sequences present in other HLA-B*alleles. This evolutionary event reflects the importance of the exchanges between different genomic regions of distinct HLA-A*, -B*, or -C* alleles and only 1 group of HLA-B* alleles (B*15 in the present paper). These data also correlated with the geographic distribution of the lineages postulated and with the corresponding serologic specificities (B62, -63, -71, -72, -75, -76, and -77). In conclusion, the high degree of polymorphism of 1 group of alleles has a specific and simple pathway of evolution, which could result in new insight into the study of immune system functionality, disease association studies, and anthropological studies.     

Novel HLA-B alleles, B*8201, B*3515 and B*5106, add to the complexity of serologic identification of HLA types

Three class I alleles, B*8201, B*3515 and B*5106, have been described using DNA and cDNA sequencing. The B*8201 allele is most structurally related to B*5602, differing from it by 14 nucleotide substitutions resulting in 5 amino acid differences. The other two alleles, B*3515 and B*5106, differ from their most closely related HLA-B alleles by 2–3 nucleotide substitutions resulting in 1–2 amino acid substitutions, respectively. The majority of nucleotide substitutions marking these new alleles are observed in other HLA-B alleles suggesting that gene conversion and/or reciprocal recombination have created this diversity. All of the amino acid substitutions are predicted to alter the antigen binding site of the HLA-B molecule. The newly defined HLA-B allelic products were originally defined by their unusual serologic reactivity patterns. The B*8201 allelic product is serologically typed as a B "blank" or as a variant of B22 or B45. These patterns and the serologic reactivity of the other newly described allelic products are consistent with the protein sequence homology among specific HLA-B molecules. While serology remains a powerful tool for detecting HLA diversity, alleles generated by events resulting in the sharing of HLA sequence polymorphisms among alleles at a locus will continue to create complexity in the interpretation of typing results.     

HLA-B*15 subtypes in Burmese population by sequence-based typing

Human leukocyte antigen (HLA)-B*15 encompasses an increasing number of subtypes of more than 150. Frequency studies and a strong genetic association between HLA subtypes and susceptibility to drug hypersensitivity have been reported in different ethnic populations. To identify HLA-B*15 subtypes in Burmese using sequence-based typing (SBT) method, we selected 65 HLA-B*15 -positive samples from 170 unrelated healthy Burmese who were genotyped HLA-B * by polymerase chain reaction with the sequence-specific primer method. The frequency of HLA-B*15 in Burmese was found to be 38.2%. By the SBT method, results showed 10 alleles of HLA-B*15 subtypes. Four common alleles, B*1502 (45.2%), B*1532 (16.4%), B*1525 (12.3%), and B*1501 (8.2%), were found in 82.1% of HLA-B*15 -positive Burmese. Whereas the B*1501 was the highest in the Caucasians, Koreans, and Japanese, the highest frequency of HLA-B*15 alleles in Burmese was B*1502 (45.2%) that is similar to the frequency found in northeastern Thais and Vietnamese. This study is the first report of HLA-B*15 subtypes in Burmese. These results will provide the basic data in the further study in transplantations, genetic association with diseases, and drug hypersensitivity.     

Allele-specific HLA-B*15 typing by PCR-SSP and its application to four distinct ethnic populations

Abstract: We present a set of primer mixes for the allele-specific typing of the HLA-B*15 group by PCR-SSP. The set comprises 46 primer mixes which are designed to unequivocally resolve all but two of the 666 possible combinations of the B*15 alleles, B*1501–37 (B*1536 sequence unavailable). A core subset of 34 of the 46 mixes can be used alone to give a high resolution B*15 typing set. This allows for the identification of each B*15 allele when present as the only B*15 allele and the majority of the possible B*15 homozygotic combinations. The method was validated using reference DNA samples and the B*15 allele frequency in 4 distinct ethnic populations was investigated. The results show that these populations contain predominantly mutually exclusive sets of B*15 alleles.     

Haplotypic association of two new HLA class I alleles: Cw*15052 and B*0706: evolutionary relationships of HLA-Cw*15 alleles

A novel HLA-Cw*15, B7 haplotype has been found in Caucasians. Molecular cloning studies demonstrate that this haplotype is constituted by the new alleles Cw*15052 and B*0706, which seem to be intermediate steps in the diversification of their respective allelic families. A pathway for the evolution of Cw*15 alleles is proposed.     

Sequence of an HLA-B56 variant (B*5604) identified in the Korean Population

Abstract: Three alleles encoding molecules with the B56 serologic specificity have been reported thus far. This study characterized an additional allele encoding a B56 molecule from two unrelated Korean individuals. The novel allele, B*5604, differs from B*5602 by a single nucleotide substitution at codon 103 (CTG→GTG) resulting in an amino acid change from leucine to valine. The putative haplotype associated with the novel allele was A2-B*5604-Bw6-Cw7-DRB1*15-DRB5*02-DQAl*01-DQB1*05.     

HLA-B22 diversity including a novel B54 variant (B*5507) in the Korean population.

Diversity in the HLA-B22 group was investigated in the Korean population using PCR-SSOP and DNA sequencing analyses. Allelic typing of the B22 gene was performed by gene amplification of the polymorphic exons 2 and 3 of the HLA-B genes from 91 B22 positive individuals followed by a hybridization assay using 63 digoxigenin-labelled probes. Five different SSOP patterns including an unexpected pattern were identified and correlated well with the observed serologic types and with data obtained from DNA sequencing analyses. Novel allele, B*5507, was identified from two unrelated individuals who exhibited standard B54 serologic reactivity but an unexpected SSOP pattern. The DNA sequence of B*5507 is identical to B*5502 in exons 2 and 3 except for a single nucleotide substitution at codon 45 (GAG-->GGG) altering glutamic acid to glycine. Among the already known B molecules, this substitution has been observed only in the B54 molecule encoded by B*5401 allele. This is the evidence that Gly-45 is a crucial site forming the B54 serologic epitope. Interestingly, both alleles (B*5401 and B*5507) exhibit strong association with Cw*0102. Along with previous data, B22 appears to be a very diverse group in the Korean population consisting of at least seven different alleles. B*5401, B*5502, and B*5601 are the most frequent alleles. B*5507, B*5501, B*5504, and B*5604 appear at lower frequencies. Data obtained from this study will be useful in hematopoietic stem cell donor searches as well as in determination of a typing strategy for the HLA-B22 types in this population.     

Generation of HLA-B*1516/B*1567/B*1595 and B*1517 alleles (B15 specific group) by transpecies evolution

The generation of the human leukocyte antigen (HLA)–B*1516, B*1517, B*1567, and B*1595 alleles has been analyzed using exon 1, intron 1, exon 2, intron 2, and exon 3 sequences from human and non-human primates. Results showed that at the first place three evolutionary steps would have been necessary for the generation of HLA-B*1516 and B*1517 alleles: (1) a non-human primate step with the generation of a major histocompatibility complex (MHC)–B*1516/1517–like allele; (2) a human or non-human primate step with two different ways of evolution generating a MHC-B*1516 and a MHC-B*1517 ancestors; and (3) a human step consisting of the generation of HLA-B*1516 and HLA-B*15170101 alleles. After that, HLA-B*1567, B*1595 B*151701012, and B*151702 alleles would be generated by point mutation events. In conclusion these alleles are generated by two different evolutionary pathways. The generation of these alleles points out the importance of the exons/introns in the generation of the evolution of HLA alleles.     

Characterization of an HLA-B62 variant (B*1538) exhibiting an additional B52 serologic reactivity

Antigens bearing the B62 serologic specificity are a heterogeneous group being encoded by at least 10 alleles and are widespread in most populations including the Korean population (10.5%). This study characterized a new allele encoding a B62 molecule with extra B52 serologic reactivity from a Korean family and unrelated individuals. Based on the DNA sequence, it appears that the single nucleotide substitution at codon 171 (TACCAC), resulting in an amino acid change from tyrosine to histidine, is responsible for creating the extra reactivity. B*1538 was confirmed by PCR-SSP using a primer annealing to codon 171 in two additional unrelated individuals also exhibiting the same serologic reaction pattern. The haplotype associated with the novel allele, A31-B*1538-Bw6-Cw3-DRB1*1101-DRB3*02-DQB1*0301, was identified in the family members and two unrelated individuals. The novel B*1538 allele and its associated haplotype adds to the HLA diversity in this population.     

Typing of HLA-B*15 alleles using sequence-specific primers

Abstract: We have developed a DNA based typing method to detect 38 known B*15 alleles using sequence-specific primers (PCR-SSP). This method involves 38 primers and 39 PCR-SSP reactions with results that can be obtained in 3 hours. The method is easy, fast and suitable for clinical typing for bone marrow and organ transplantation. We have typed 106 HLA-B15 samples using this method. For homozygous HLA-B15 samples, some B*15 allele combinations need to be resolved by additional PCR reactions not included in this article. The method allows the detection of potential new alleles requiring sequencing for confirmation, and it is useful to resolve unusual serological reaction patterns for different HLA-B15 serological specificities. In addition, it could be used to resolve ambiguous PCR-SSOP typing results and for recognition of mismatches in serologically matched unrelated individuals.     

Identification of HLA-B*1566

A novel polymorphism was identified in a B*15 allele. B*1566 possesses a nucleotide substitution of C to G at nucleotide 272. This polymorphism encodes an amino acid difference from serine in B*1501101 to cysteine in B*1566 at residue 67. Residue 67 is a constituent of the B pocket and is situated on the alpha1 helix facing into the groove. This mutation may have arisen through interallelic recombination as it has been seen in other B*15 alleles and is also present in most B*14, B*27, B*38, B*39 alleles and in B*7301.     

The relationship between HLA-B45 and B* 5002 in the five major U.S. population groups

The antigen encoded by B*5002 differs in sequence from that encoded by B*5001 only at amino acid residue 167 (consensus tryptophan vs. serine) which results in B45 serologic reactivity. To search for B*5002, the frequencies of alleles encoding the serologically defined B45 antigen were determined by sequence-based typing in 5 major U.S. populations: Caucasians, African Americans, Asians/Pacific Islanders, Hispanics, and Native Americans. The percent of serologically defined B45-positive individuals in the 5 populations ranged from 0.7-9.0%. Thirty-two B45-positive individuals were randomly chosen, when available, for sequence-based typing from each ethnic group from a database of 82,979 consecutively typed unrelated individuals. The B*5002 allele was most prevalent in Hispanic (22%) and Caucasian (9%) individuals, while conspicuously absent in African Americans. In addition, a new allele associated with the B45 antigenic specificity, B*4502, has been identified from an African American individual of Middle Eastern descent. In light of the continuing need to reconcile differences between relationships determined by the sequence homologies among alleles and relationships based on the serologic determinants carried by allelic products when determining the level of HLA match for hematopoietic stem cell transplantation, it is suggested that B*5002 be recognized individually from other B*50 alleles when reporting HLA-B typings for clinical purposes.     

Characterization of HLA-B*5516, -B*1313, -B*9512, and -DRB1*1457 alleles identified in a southwest Chinese population

The human leukocyte antigen (HLA)-B*5516 allele differs from the B*5502 by a single 97 T --> C substitution (His to Tyr at position 33) in exon 2. The B*1313 allele results from 419 T --> A and 420 A --> C substitutions, encoding a Leu to Tyr substitution at 140 in exon 2 of the B*1301 allele. The B*9512 allele differs from B*1502 by a single 360 G --> C substitution (Gln to His at 120) in exon 3. The DRB1*1457 allele appears to be a hybrid molecule generated by recombination between the DRB1*13 and DRB1*14 alleles. The serological equivalents of these new alleles are HLA-B22, -B13, -B15, and DR13, respectively. Family studies detected two rare haplotypes: A*11, B*9512, DRB1*14 and A*24, B*52, Cw*07, DRB1*1457, DRB3*020201, DQB1*050301. The gene frequencies of these alleles in the Chinese population are less than 0.0001.     

New alleles in the B44 family including B*44022, B*44032, B*4411, B*4420, B*4421, B*4424, and B*8301

Seven new HLA-B locus alleles have been described. B*44022 and B*44032 are silent substitutions altering known alleles. B*4411 carries a unique Bw4-like epitope. B*4420, B*4421, and B*4424 carry new combinations of motifs previously observed in other alleles. B*8301 appears to be the result of the replacement of exon 2 from B*4402 with exon 2 from B*5603.     

Discovery of two novel HLA-B alleles, B*46:13:03 and B*15:189, in two Taiwanese volunteer bone marrow donors by sequence-based typing

We report here two novel HLA-B alleles, B*46:13:03 and B*15:189, discovered in two Taiwanese volunteer bone marrow donors. The sequence of B*15:189 has a nucleotide sequence possibly derived from a recombination event between HLA-B*39:01:01 and B*15:01:01:01, while the origin of the sequence B*46:13:03 was less obvious to postulate, considering the low frequency of B*46:13 in the general population and the silent mutations involved. Our report here adds further HLA polymorphism to the growing lists of HLA-B*46 and HLA-B*15 and provides an additional HLA information for donor search programme for patients undergoing transplant.     

Identification of the novel allele HLA-B*1545: assessment of alloreactivity in case of mismatch with other B*15 alleles

The novel allele HLA-B*1545, which has been serologically typed as B62, was identified in a male Caucasian. In the sequence analysis the new allele differs from B*1507 by nucleotide 419 which is located in exon 3. Its structure suggests that it may have originated by a point mutation or by gene conversion with a variety of HLA-B alleles. At the protein level, the nucleotide substitution results in an amino add exchange compared to B*1507 (Tyr116Ser). Due to probably substantial differences to B*1507 and the other B*15 variants with regard to peptide binding, a mismatch is likely to impair clinical outcome of bone marrow transplantation.     

A nonsense mutation in exon 3 results in the HLA-B null allele B*5127N

A new HLA-B null allele has been identified within the B*51 group by combined serological and molecular typing of an Italian Caucasoid family. Serological data indicated that the proband typed homozygous for A2 and B60. Confirmatory typing using sequence specific oligonucleotide hybridization (SSPOH) detected a second B allele within the B*51 group. Allele specific typing (SSP) for B*51 subtypes, including the known B*5111N allele, was performed, and typing results were consistent with B*5101, suggesting the presence of a new null variant. Cloning and sequencing of this allele identified a B*5101 variant with a nonsense mutation in exon 3. This new null allele has been designated B*5127N. The combined use of serologic and DNA-based typing methods facilitates the identification of null and low-expression alleles. An overview of null alleles of class I HLA is presented.