HLA-B*15 subtypes in the population of north-eastern Thailand.

The HLA-B*15 group is the most polymorphic HLA-B allele and so has several subtypes. These subtypes have not been defined in the population of north-eastern Thailand (NET). In a previous study, using polymerase chain reaction-sequence-specific primers (PCR-SSP), subtypes were categorized into four groups, namely: group I: HLA-B*15 (01, 04-07, 12, 14, 19, 20, 24, 25, 26N, 27, 32, 33, 34 and 35); group II: HLA-B*15 (02, 08, 11, 15, 28 and 30); group III: HLA-B*1503/4802; group IV: HLA-B*1521. Groups I and II occurred frequently (allele frequency = 8.0 and 2.5%), and thus we optimized the polymerase chain reaction-single-stranded conformation polymorphism (PCR-SSCP) method to identify HLA-B*15 subtypes of groups I and II. Eighty samples of DNA carrying HLA-B*15 from 300 healthy unrelated individuals were tested. B*1502 (52.5%) and B*1525 (13.8%) were the most common subtypes found in NET. They also showed strong linkage disequilibrium with HLA-Cw and heterogeneity of HLA-A, DR, DQ haplotypes. Although limited conclusions can be drawn from this study because of the small number of DNA references used, the baseline data will be useful in the selection of common HLA-B*15 alleles when subtyping for unrelated donor transplantations.     

Genomic sequences of HLA‐A*68:169, HLA‐B*07:298 and HLA‐B*39:129.

Three new HLA class I alleles were described in the Spanish population. HLA‐A*68:169 and ‐B*39:129 show one amino acid replacement at the α1‐domain, compared to A*68:02 (P47 > L47) and ‐B*39:06 (S11 > A11), respectively. HLA‐B*07:298 presents one nucleotide mutation within exon 1, resulting in a new amino acid position ?14, L>Q, which has not been previously described in any HLA protein. Prediction of the B*07:298 signal peptide cleavage did not show significant differences in comparison with that obtained for the rest of HLA‐B genes.     

Immunogenetics of a new HLA‐B null allele,HLA‐B*4423N

The second example of an HLA‐B*44 null allele (B*4423N) was identified by discrepancies between serological and polymerase chain reaction–sequence‐specific primer (PCR‐SSP) typing in two north‐western European Caucasoid unrelated stem cell donor volunteers. HLA‐B*4423N was identical to B*440201 except for a single nucleotide substitution at position 493 in exon 3, resulting in a premature stop codon at bases 493–495 (TAG rather than CAG at codon 141). As expected, comprehensive serological testing using 54 antisera, directed towards B44 or Bw4, failed to identify the HLA‐B44 (Bw4) specificity. The B*4423N‐bearing haplotype was identified as A*0201, Cw*0501, DRB1*0408, DRB4*01, DQA1*03, DQB1*0304 and the frequency of B*4423N estimated as 0.00006 (carriage frequency 0.0121%) in 16 533 subjects resident in Wales.     

Three new HLA‐C alleles (HLA‐C*14:02:13, HLA‐C*15:72 and HLA‐C*15:74) in Saudi bone marrow donors

Three new HLA‐C alleles were identified by sequence‐based typing method (SBT) in donors for the Saudi Bone Marrow Donor Registry (SBMDR). HLA‐C*14:02:13 differs from HLA‐C*14:02:01 by a silent G to A substitution at nucleotide position 400 in exon 2, where lysine at position 66 remains unchanged. HLA‐C*15:72 differs from HLA‐C*15:22 by a nonsynonymous C to A substitution at nucleotide position 796 in exon 3, resulting in an amino acid change from phenylalanine to leucine at position 116. HLA‐C*15:74 differs from HLA‐C*15:08 by a nonsynonymous C to T substitution at nucleotide position 914 in exon 3, resulting in an amino acid change from arginine to tryptophan at position 156.     

HLA‐B50 polymorphism in the Saudi population

The HLA‐B50 serologic family is very frequent in people of Arabic origin. In Saudi Arabia, HLA‐B50 is the most frequent HLA‐B allele. The aim of this study was to investigate the distribution of HLA‐B50 alleles in healthy Saudi individuals. A total of 162 healthy Saudi individuals were selected based on low‐resolution HLA typing. DNA samples were typed by sequence‐based typing method for exons 2, 3 and 4 of the HLA‐B locus (Genome Diagnostics B.V.). The HLA‐B*50 alleles were analysed using SBT engine software. HLA‐B*50:01:01 was found in 161 of 162 individuals (99.4%), while HLA‐B*50:09 was found in one individual (0.6%). HLA‐B*50:01:01 is the most common HLA‐B50 allele in Saudi Arabia.     

Immunogenetics of the rare HLA‐B allele B*4408†

The nucleotide sequence of exons 2 and 3 of B*4408 has been confirmed. This allele has now been found in five, apparently unrelated, north‐western European Caucasoid subjects, residing in Wales, on HLA haplotypes bearing: A*0201, Cw*0501 with DRB1*0401, DQA1*03, DQB1*0301 in four instances and DRB1*0701, DQA1*0201, DQB1*0202 in one instance. The unique serological reactivity of ‘HLA‐B44BO’ was established using up to nine B*4408 subjects and was easily identified using a variety of B44 and B62 antisera. The phenotype and gene frequencies of B*4408, in a sample of 40 473 subjects residing in Wales, were 0.01235% and 0.00006, respectively.     

Epitopes and motifs of the HLA‐B*14 allele family products and related HLA‐B14 cross‐reactive specificities

The split specificities of HLA‐B14 (B64, B65) are assigned to the B*14:01 (B64) and B*14:02 (B65) products only. Of the further 50 B*14 expressed products, only B*14:03 and B*14:06 are officially designated as HLA‐B14. The B*14:08 product differs from B64 by a single amino acid substitution of W97R, while the B*14:53 specificity (which is a “short” B14 and neither B64 nor B65) differs from B64 by three residues (W97S, Y113H and F116Y). Comprehensive testing of B*14:08:01 cells (using 49 alloantisera with B64 or B64, B65 specificities, and five monoclonal antibodies with B65 or B64, B65 activity) showed that the B*14:08 specificity is, like the B*14:53 product, neither B64 nor B65 and appears as a “short” B14 specificity. To help understand the serological reactivity of the B*14:08 and B*14:53 products, and B64 and B65, we identified seven published epitopes (11AV, 97W, 61ICT, 116F, 131S+163T, 170RH and 420) and, by inspection, 29 motifs, that encompass one or more of B64, B65 and various HLA‐B14 cross‐reactive group specificities. We then considered the possession of these epitopes and motifs by the products of B*14:01 to B*14:06, B*14:08 and B*14:53. Seventeen of the 29 motifs fully complied with the one‐/two‐patch functional epitope concept for amino acid proximity, as determined by Cn3D software, the remainder partially complied. The nature and patterns of epitopes and motifs possessed by both B*14:08 and B*14:53 specificities supported their designation as HLA‐B14 but non‐B64/B65. Also that epitope 97W, with 11S or 11A, is critical for serological B64 and B65 reactivity. And conversely, that epitope 116F, and several identified motifs, are probably unimportant for HLA‐B14 antibody reactivity. The previous submission that the B*14:03 specificity is HLA‐B65 was compatible with its epitope/motif pattern. B*14:04 cells would also be expected to react as B65, based on its epitope/motif pattern, and not as B64 as previously implied. Also, from their epitope/motif patterns, and external serological information, it is probable that the B*14:05 and B*14:06 specificities will both appear as “short” HLA‐B14, non‐B64/B65. Several epitopes and motifs encompassed a range of HLA‐B specificities included in the serological HLA‐B14 cross‐reactive group, thus supporting these original serological findings.     

HLA‐B*15:47:01 allele with undefined serological equivalent considered as B Blank

We report a discordance between complement‐dependent cytotoxicity and next‐generation sequencing molecular typing revealing HLA‐B*15:47:01 allele with undefined serological equivalent confirmed by high‐level immunization against the B15 serotype. Due to the high‐level immunization against HLA‐B15 and B70 antigens, we considered the HLA‐B*15:47:01 allele to be B Blank and not as B15 or B70 serological specificity.     

Molecular modelling of HLA‐B*35:132

Here we describe the molecular modelling of the new variant HLA‐B*35:132. This allele shows one mismatch with B*35:01:01:01 in exon 3 at position 575 where a T is substituted by a C, which implies an amino acidic change from Leucine to Proline. This seems not to alter the molecular structure and not to compromise the HLA complex and T‐cell receptor interaction.     

Molecular analysis of HLA‐DRB1 polymorphism in north‐east Spain

The DRB1* polymorphism in 941 randomly selected individuals from the Umbilical Cord Blood Bank of Barcelona (92.75% of Spanish origin) was determined by sequence‐based typing. The HLA profile was similar to that of other Mediterranean populations, with DRB1*0701 and *0301 being the most frequent alleles. This may be a consequence of the mixture of alleles as a result of migration from contiguous geographical areas.     

Allelic and haplotype diversity of HLA‐A,HLA‐B and HLA‐DRB1 gene at high resolution in the Nanning Han population

The distribution of human leucocyte antigen (HLA) allele and haplotype varied among different ethnic populations. In this study, we investigated the allele and haplotype frequencies of HLA‐A, HLA‐B and HLA‐DRB1 loci in the Nanning Han population who live in Guangxi province of China. We identified 26 HLA‐A, 56 HLA‐B and 31 HLA‐DRB1 alleles in 562 Nanning individuals of Han ethnic group by sequence‐based typing method. Of these, the three most common alleles in HLA‐A, HLA‐B and HLA‐DRB1 loci, respectively, were A*11:01 (32.12%), A*02:07 (12.54%), A*24:02 (12.01%); B*46:01 (14.41%), B*15:02 (13.61%), B*40:01 (11.48%); DRB1*15:01 (14.15%), DRB1*16:02 (11.57%) and DRB1*12:02 (10.14%). With the exception of HLA‐DRB1, the p values of the HLA‐A and HLA‐B loci showed that the HLA allelic distribution in this population was in accordance with Hardy–Weinberg expectation (p > 0.05). A total of 173 HLA~A‐B~DRB1 haplotype with a frequency of >0.1% were presented and the three most common haplotype were HLA‐A*33:03~B*58:01~DRB1*03:01 (6.12%), HLA‐A*11:01~B*15:02~DRB1*12:02 (3.39%) and HLA‐A*11:01~B*15:02~DRB1*15:01 (3.22%). The phylogenetic tree and the principal component analysis suggested that Nanning Han population had a relative close genetic relationship with Chinese Zhuang population and a relative distant genetic relationship with Northern Han Chinese. The information will be useful for anthropological studies, for HLA matching in transplantation and disease association studies in the Chinese population.     

Human herpesvirus 6B immediate‐early I protein contains functional HLA‐A*02, HLA‐A*03, and HLA‐B*07 class I restricted CD8+ T‐cell epitopes

Human herpesvirus 6B (HHV‐6B) is a ubiquitous pathogen with frequent reactivation observed in immunocompromised patients such as BM transplant (BMT) recipients. Adoptive immunotherapy is a promising therapeutic avenue for the treatment of opportunistic infections, including herpesviruses. While T‐cell immunotherapy can successfully control CMV and EBV reactivations in BMT recipients, such therapy is not available for HHV‐6 infections, in part due to a lack of identified protective CD8⁺ T‐cell epitopes. Our goal was to identify CD8⁺ T‐cell viral epitopes derived from the HHV‐6B immediate‐early protein I and presented by common human leukocyte Ag (HLA) class I alleles including HLA‐A*02, HLA‐A*03, and HLA‐B*07. These epitopes were functionally tested for their ability to induce CD8⁺ T‐cell expansion and kill HHV‐6‐infected autologous cells. Cross‐reactivity of specific HHV‐6B‐expanded T cells against HHV‐6A‐infected cells was also confirmed for a conserved epitope presented by HLA‐A*02 molecule. Our findings will help push forward the field of adoptive immunotherapy for the treatment and/or the prevention of HHV‐6 reactivation in BMT recipients.     

Characterization of a novel HLA‐B*40 allele,HLA‐B*40:186:02, by cloning and sequencing

A novel HLA‐B*40 variant, HLA‐B*40:186:02, has been identified by cloning and sequencing in a southern Chinese Han population. Aligned with HLA‐B*40:01:01, HLA‐B*40:186:02 has a nonsynonymous cytosine mutation at nucleotide position 165 in exon 2, leading to amino acid change from glycine to arginine at codon 56. It differs from HLA‐B*40:186:01 by a synonymous change (adenine to cytosine) at position 165 in exon 2.     

Complementary DNA sequence of the HLA‐B*3924 allele1

We have isolated the complete coding region of HLA‐B*39 from a Spanish Caucasoid, using a new PCR primer for its 5′ untranslated region. The cDNA matched partial genomic sequences of B*3924, an allele whose distribution appears to be restricted to Mediterranean and Arabian Caucasoids. A single amino acid change exclusive to B*3924 (threonine‐98) distinguishes it from B*3903.     

Characterization of three new HLA Class I Alleles in Spanish Caucasians,HLA‐A*02:620, HLA‐B*27:150 and HLA‐B*07:05:01:02

Three new HLA class I alleles, HLA‐A*02:620, HLA‐B*27:150 and HLA‐B*07:05:01:02, were described in the Spanish Caucasoid population.     

Identification of a novel HLA‐B*27 allele,B*27:79 and the B*27 subtype polymorphism in the Hunan ethnic Han population of China

This article describes a novel HLA‐B*27 allele, HLA‐B*27:79, which was identified in a Hunan Han ethnic individual of China by a PCR sequence‐based typing method. The new sequence has one nucleotide mutation at position 437(A→T) compared with the allele B*27:04:01. This nucleotide change causes an amino acid substitution from Aspartate (Asp) to Valine (Val) at codon 122. This is the first report of mutation at this position in the HLA‐B locus. Then, we investigated the HLA‐B*27 subtype polymorphism of the Hunan Han population, and the results showed that B*27:04, B*27:05 and B*27:06 are the predominant subtypes with the allele frequencies 0.97%, 0.26% and 0.10% respectively.     

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.     

The distributions of HLA‐A,HLA‐B,HLA‐C,HLA‐DRB1 and HLA‐DQB1 allele and haplotype at high‐resolution level in Zhejiang Han population of China

The distributions of HLA allele and haplotype are variable in different ethnic populations and the data for some populations have been published. However, the data on HLA‐C and HLA‐DQB1 loci and the haplotype of HLA‐A, HLA‐B, HLA‐C, HLA‐DRB1 and HLA‐DQB1 loci at a high‐resolution level are limited in Zhejiang Han population, China. In this study, the frequencies of the HLA‐A, HLA‐B, HLA‐C, HLA‐DRB1 and HLA‐DQB1 loci and haplotypes were analysed among 3,548 volunteers from the Zhejiang Han population using polymerase chain reaction sequencing‐based typing method. Totals of 51 HLA‐A, 97 HLA‐B, 45 HLA‐C, 53 HLA‐DRB1 and 27 HLA‐DQB1 alleles were observed. The top three frequent alleles of HLA‐A, HLA‐B, HLA‐C, HLA‐DRB1 and HLA‐DQB1 loci were A*11:01 (23.83%), A*24:02 (17.16%), A*02:01 (11.36%); B*40:01 (14.08%), B*46:01 (12.20%), B*58:01 (8.50%); C*07:02 (18.25%), C*01:02:01G (18.15%), C*03:04 (9.88%); DRB1*09:01 (17.52%), DRB1*12:02 (10.57%), DRB1*15:01 (9.70%); DQB1*03:01 (22.63%), DQB1*03:03 (18.26%) and DQB1*06:01 (10.88%), respectively. A total of 141 HLA‐A‐C‐B‐DRB1‐DQB1 haplotypes with a frequency of ≥0.1% were found and the haplotypes with frequency greater than 3% were A*02:07‐C*01:02:01G‐B*46:01‐DRB1*09:01‐DQB1*03:03 (4.20%), A*33:03‐C*03:02‐B*58:01‐DRB1*03:01‐DQB1*02:01 (4.15%), A*30:01‐C*06:02‐B*13:02‐DRB1*07:01‐DQB1*02:02 (3.20%). The likelihood ratios test for the linkage disequilibrium of two loci haplotypes was revealed that the majority of the pairwise associations were statistically significant. The data presented in this study will be useful for searching unrelated HLA‐matched donor, planning donor registry and for anthropology studies in China.     

A novel HLA‐B allele,HLA‐B*35:279, identified by sequencing‐based typing in a Czech patient

The identification of a novel HLA‐B*35:279 allele in a Czech patient is described. This allele is identical to the B*35:03:01 variant except the G/A nucleotide exchange at position 652 of the HLA‐B gene that corresponds to the amino acid substitution from valine to isoleucine in alpha 3 domain of the HLA‐B antigen.     

Characterization of a novel allelic variant in HLA‐B*40 lineage,HLA‐B*40:298:02, by cloning and sequencing

A novel allelic variant in HLA‐B*40 lineage, HLA‐B*40:298:02, has been identified in an individual of Han ethnicity afflicted with nasopharyngeal carcinoma in Hunan province, southern China. Following polymerase chain reaction–Sanger sequence‐based typing (PCR–SBT), this new variant was further confirmed by two distinct strategies of cloning and sequencing. HLA‐B*40:298:02 differs from HLA‐B*40:298:01 by a single synonymous cytosine substitution at nucleotide position 26 (T→C) in exon 3, which corresponds to codon 99 of the mature HLA‐B mRNA molecule. This new allele has an estimated frequency of 0.0002, in about 2,500 sequence‐based typed subjects from the same population.