HLA‐A,HLA‐B and HLA‐DRB1 allele and haplotype frequencies of 10 918 Koreans from bone marrow donor registry in Korea

The human leucocyte antigen (HLA) system is the most polymorphic genetic system in humans, and HLA matching is crucial in organ transplantation, especially in hematopoietic stem cell transplantation. We investigated HLA‐A, HLA‐B and HLA‐DRB1 allele and haplotype frequencies at allelic level in 10 918 Koreans from bone marrow donor registry in Korea. Intermediate resolution HLA typing was performed using Luminex technology (Wakunaga, Japan), and additional allelic level typing was performed using PCR–single‐strand conformation polymorphism method and/or sequence‐based typing (Abbott Molecular, USA). Allele and haplotype frequencies were calculated by direct counting and maximum likelihood methods, respectively. A total of 39 HLA‐A, 66 HLA‐B and 47 HLA‐DRB1 alleles were identified. High‐frequency alleles found at a frequency of ≥5% were 6 HLA‐A (A*02:01, *02:06, *11:01, *24:02, *31:01 and *33:03), 6 HLA‐B (B*15:01, *35:01, *44:03, *51:01, 54:01 and *58:01) and 8 HLA‐DRB1 (DRB1*01:01, *04:05, *04:06, *07:01, *08:03, *09:01, *13:02 and *15:01) alleles. At each locus, A*02, B*15 and DRB1*14 generic groups were most diverse at allelic level, consisting of 9, 12 and 11 different alleles, respectively. A total of 366, 197 and 21 different HLA‐A‐B‐DRB1 haplotypes were estimated with frequencies of ≥0.05%, ≥0.1% and ≥0.5%, respectively. The five most common haplotypes with frequencies of ≥2.0% were A*33:03‐B*44:03‐DRB1*13:02 (4.97%), A*33:03‐B*58:01‐DRB1*13:02, A*33:03‐B*44:03‐DRB1*07:01, A*24:02‐B*07:02‐DRB1*01:01 and A*24:02‐B*52:01‐DRB1*15:02. Among 34 serologic HLA‐A‐B‐DR haplotypes with frequencies of ≥0.5%, 17 haplotypes revealed allele‐level diversity and majority of the allelic variation was arising from A2, A26, B61, B62, DR4 and DR14 specificities. Haplotype diversity obtained in this study is the most comprehensive data thus far reported in Koreans, and the information will be useful for unrelated stem cell transplantation as well as for disease association studies.     

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.     

Characterization of a novel HLA‐B*39:01:01‐related allele,HLA‐B*39:130, by cloning and phasing

A novel HLA‐B*39:01:01‐related variant, HLA‐B*39:130, has been identified in a normal individual of Han ethnicity in Hunan province, southern China. Following Sanger polymerase chain reaction–sequence‐based typing (PCR‐SBT), this new allele was further confirmed by cloning, phasing and sequencing. Aligned with HLA‐B*39:01:01, HLA‐B*39:130 has a nonsynonymous thymine substitution at nucleotide position 94 in exon 4, resulting in amino acid change from threonine to isoleucine at codon 214 (ACA→ATA) of the mature HLA‐BmRNA molecule.     

Characterization of a new HLA‐A allele,HLA‐A*02:07:08, by cloning and sequencing

In this report, we present a novel HLA‐A*02:07 allele, HLA‐A*02:07:08. HLA‐A*02:07:08 was identified in an individual of Han ethnicity in Hunan province, southern China. Following polymerase chain reaction‐sequence‐based typing (PCR‐SBT), this new allele was further confirmed by cloning and sequencing. HLA‐A*02:07:08 differs from HLA‐A*02:07:01 by a single synonymous C to T substitution at nucleotide position 131 in exon 3.     

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.     

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.     

HLA‐A, ‐B and ‐DRB1 polymorphism in Koreans defined by sequence‐based typing of 4128 cord blood units

Human leucocyte antigen (HLA) alleles and haplotypes differ significantly among different ethnic groups, and high‐resolution typing methods allow for the detection of a wider spectrum of HLA variations. In this study, HLA‐A, ‐B and ‐DRB1 genotypes were analysed in 4128 cord blood units obtained from Korean women using the sequence‐based typing method. A total of 44 HLA‐A, 67 HLA‐B and 48 HLA‐DRB1 most probable alleles were identified. Of these, high‐frequency alleles found at a frequency of ≥5% were 6 HLA‐A (A*02:01, A*02:06, A*11:01, A*24:02, A*31:01, A*33:03), 5 HLA‐B (B*15:01, B*44:03, B*51:01, B*54:01, B*58:01) and 7 HLA‐DRB1 (DRB1*01:01, DRB1*04:05, DRB1*07:01, DRB1*08:03, DRB1*09:01, DRB1*13:02, DRB1*15:01) alleles. At each locus, A*02, B*15 and DRB1*04 generic groups were most diverse at allelic level, consisting of 8, 11 and 10 different alleles, respectively. Two‐ and three‐locus haplotypes estimated by the maximum likelihood method revealed 73 A‐B, 74 B‐DRB1 and 42 A‐B‐DRB1 haplotypes with frequencies of ≥0.3%. A total of 193 A‐B‐DRB1 haplotypes found at a frequency of ≥0.1% were presented, and the six most common haplotypes were A*33:03‐B*44:03‐DRB1*13:02 (4.6%), A*33:03‐B*58:01‐DRB1*13:02 (3.0%), A*24:02‐B*07:02‐DRB1*01:01 (2.7%), A*33:03‐B*44:03‐DRB1*07:01 (2.5%), A*30:01‐B*13:02‐DRB1*07:01 (2.2%) and A*24:02‐B*52:01‐DRB1*15:02 (2.1%). Compared with previous smaller scale studies, this study further delineated the allelic and haplotypic diversity in Koreans including low‐frequency alleles and haplotypes. Information obtained in this study will be useful for the search for unrelated bone marrow donors and for anthropologic and disease association studies.     

MICA,MICB Polymorphisms and Linkage Disequilibrium with HLA‐B in a Chinese Mongolian Population

In this study, polymorphisms of major histocompatibility complex class I chain‐related genes A and B (MICA and MICB) and human leucocyte antigen (HLA)‐B gene were investigated for 158 unrelated Chinese Mongolian subjects recruited from central Inner Mongolia Autonomous Region, northern China, by polymerase chain reaction–sequence‐based typing (PCR‐SBT) and cloning. Collectively, 79 alleles, including 20 MICA, 12 MICB and 47 HLA‐B alleles, were identified. MICA*008:01 (21.2%), MICB*005:02 (48.1%) and HLA‐B*51:01 (7.91%) were the most common alleles. Significant global linkage disequilibrium (LD) was detected between HLA‐B and MICA, HLA‐B and MICB, and MICA and MICB loci (all P < 0.000001). The most frequent haplotypes were HLA‐B*51:01‐MICA*009:01 (7.28%), HLA‐B*58:01‐MICB*008 (6.96%), MICA*010‐MICB*005:02 (13.92%) and HLA‐B*58:01‐MICA*002:01‐MICB*008 (6.96%). HLA‐B‐MICA haplotypes such as HLA‐B*50:01‐MICA*009:02 were associated with single MICB allele. Some HLA‐B‐MICA haplotypes were associated with multiple MICB alleles, including HLA‐B*51:01‐MICA*009:01. One novel MICB allele, MICB*031, was identified, which has possibly arisen from MICB*002:01 through single mutation event. We also confirmed the existence of a recently recognized MICA allele, MICA*073, whose ethnic origin has not been previously described. Genotype distributions at MICA, MICB and HLA‐B were consistent with a neutrality model. Our results provide new insight into MIC genetic polymorphisms in Chinese ethnic groups. Findings shown here are important from an anthropologic perspective and will inform future studies of the potential role of MIC genes in allogeneic organ transplantation and HLA‐linked disease association in populations of related ancestry.     

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.     

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.     

Two novel alleles HLA‐DRB1*11:150 and HLA‐DRB1*14:145 identified in Saudi individuals

Two new HLA‐ DRB1 alleles were identified by sequence‐based typing method (SBT) in 1100 participants in the Saudi Stem Cell Donor Registry. HLA‐DRB1*11:150 differs from HLA‐DRB1*11:01:01G by a single C to A substitution at nucleotide position 5580 in exon 2, resulting in an amino acid change from alanine to glutamic acid at position 74. HLA‐DRB1*14:145 differs from HLA‐DRB1*14:04 by a C to G substitution at nucleotide position 5511 in exon 2, resulting in an amino acid change from threonine to arginine at position 51.     

Identification and characterization of a novel HLA‐A allele,HLA‐A*68:105, by genomic sequencing

A novel HLA‐A allele, HLA‐A*68:105, was detected by sequence‐based typing (SBT) in an Italian bone marrow donor. It differs from HLA‐A*68:01:02 at five nucleotides, three intronic, nt 699 T‐>G (intron 2), nt 705 T‐>C (intron 2) and nt 2770 G‐>A (intron 7), and two located in exon 3, at positions 726 A‐G (codon 94 Ile‐>Val) and 733 T‐G (codon 97 Arg‐>Met), respectively.     

Two novel alleles at HLA‐B locus identified in two volunteer bone marrow donors by sequence‐based typing

Two novel human leucocyte antigen (HLA) class I alleles have been identified in two Italian individuals. HLA‐B*27:07:02 is identical to HLA‐B*27:07:01 except for a nucleotide substitution at position 846 (A‐>G) resulting in a silent mutation. HLA‐B*35:206 differs from the most similar allele, HLA‐B*35:08:01, because of a single base mutation at position 149 (G‐>C) causing an aminoacidic change at codon 26 from Gly to Ala.     

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.     

Two novel alleles HLA‐A*02:433 and HLA‐A*02:434 identified in Saudi bone marrow donors using sequence‐based typing

In this report, we present two novel HLA‐A alleles: HLA‐A*02:433 and HLA‐A*02:434. These alleles were identified by sequence‐based typing method (SBT), in two donors for the Saudi Bone Marrow Donor Registry (SBMDR). Allele A*02:433 is identical to A*02:05:01G except for a G to A substitution at nucleotide position 449 in exon 2. This substitution results in glycine to serine substitution at position 83. Whereas, allele A*02:434 is identical to A*02:01:01G except for a C to A substitution at nucleotide position 245 in exon 2, which results in phenylalanine to threonine substitution at position 15. The generation of both alleles appears to be the result of nucleotide point mutation involving 02:01:01 and 02:05:01.     

A novel HLA‐B*40 allele,B*40:01:40, identified in a Chinese individual

A new allele, officially named B*40:01:40, was detected in a Chinese individual by sequence‐based typing (SBT). The new allele differs from B*40:01:01 by a single nucleotide exchange at position 99 in codon 9, which results in synonymous substitution and seems not to compromise the HLA complex and T‐cell receptor interaction.     

HLA‐A,HLA‐B,HLA‐DRB1 allele and haplotype frequencies of 14 529 Chinese Han bone marrow donors living in Dalian,China

We investigated the allele and haplotype frequencies of HLA‐A, HLA‐B and HLA‐DRB1 loci in Dalian Chinese Han population using blood samples of unrelated marrow donors who live in Dalian. The genetic relationship between Dalian and different regions worldwide was further explored based on HLA status of different populations. A total of 14 529 samples were genotyped at 2‐digit level only by sequence‐specific oligonucleotide and sequence‐based typing methods. Allele frequencies of HLA‐A, HLA‐B and HLA‐DRB1 were calculated by the direct counting method. Haplotype frequencies and linkage disequilibrium (LD) values were calculated by the maximum likelihood method. F_ST values were calculated by allele frequency data of each locus. Phylogeny tree of Nei's D_A genetic distances was constructed by the UPGMA method. HLA‐A*02 was the most frequent allele at HLA‐A locus followed by A*11 and A*24. Alleles at HLA‐B locus ranked in decreasing order by frequency were B*40, B*15 and B*13. The three highest frequency alleles were DRB1*15, DRB1*09 and DRB1*12 at HLA‐DRB1 locus. A*30‐B*13‐DRB1*07 was the most frequent three‐locus haplotype. For the population relationships, Dalian had a relative close genetic relationship with Liaoning and Yantai‐Weihai and a relative distant genetic relationship with Australia. The information obtained in this study may provide useful information for anthropological studies, for disease‐association studies and helping bone marrow transplantation patients to search HLA‐matched donors.     

HLA‐B*38:55Q: a new alternatively expressed allele identified in a three‐generation Italian family

The new allelic variant HLA‐B*38:55Q differs from the closest related B*38:01:01 by one nucleotide substitution at position 373 in exon 3 (TGC>CGC). This results in a difference of one amino acid at residue 101 of the HLA‐B heavy chain, from a neutral‐polar Cys to a basic‐polar Arg, thus impairing disulphide bridge formation in the alpha‐2 domain. This alteration of the secondary structure probably affects the maturation of the heavy chain and the level of surface expression, making the HLA‐B*38:55Q undetectable by standard serological typing.     

Frequency of HLA‐A alleles in the Syrian population genotyped by sequence‐based typing

HLA‐A molecules are highly polymorphic. Their accurate typing at a high‐resolution level is crucial for successful organ, bone marrow and cord blood transplantation. Furthermore, several HLA alleles have been involved in susceptibility to autoimmune diseases, allergies, cancers and inflammations. In order to determine common HLA‐A alleles in Syria and their frequencies, sequence‐based typing (SBT) was used to genotype HLA‐A alleles at high resolution (four digit level) among one hundred and thirty randomly selected Syrian individuals. Exons 2, 3 and 4 of the HLA‐A gene were amplified by PCR and sequenced. The sbt ‐engine software was used for allele assignment. Ambiguities were solved using group‐specific sequencing primers (GSSPs). We could identify 32 different HLA‐A alleles which were divided into 3 groups: high frequency (approximately 10%, A*01:01; A*24:02; A*03:01; A*02:01), moderate frequency (approximately 3%, such as A*02:05, A*31:01 and A*33:01), and low frequency (approximately 1%, such as A*02:11, A*29:01, A*02:02 and A*36:01). Homozygosity rate was higher than expected (11.5% vs. 7.15%). For high frequency alleles, our results show similarity to neighbouring countries. However, 15 alleles (such as A*02:04, A*02:06, A*02:11 and A*02:17) found in our cohort in low frequencies were never reported in some or all neighbouring countries. This is the first report on HLA‐A allele frequencies in Syria. In spite of the relatively low number of tested subjects, our results revealed a high degree of diversity, with 32 different alleles, reflecting the high ethnic heterogeneity of the Syrian population. The identification of alleles rarely or never reported in neighbouring countries indicates a higher genetic diversity in Syria.     

Discovery of the novel HLA‐DRB1*09:01:08 allele in a Taiwanese volunteer bone marrow donor and identification of the probable HLA‐A,HLA‐B and HLA‐DRB1 haplotype in association with DRB1*09:01:08

We report here the novel variant of HLA‐DRB1*09:01, DRB1*09:01:08, discovered in a Taiwanese volunteer bone marrow donor by a sequence‐based typing (SBT) method. The DNA sequence of DRB1*09:01:08 is identical to the sequence of DRB1*09:01:02 in exon 2 except a silent mutation at nucleotide position 261(C→T) (GCC→GCT at codon 58). We hypothesize DRB1*09:01:08 was probably derived from DRB1*09:01:02 via a nucleotide point mutation event. The plausible HLA‐A, HLA‐B and HLA‐DRB1 haplotype in association with DRB1*09:01:08 was deduced as A*02:07‐B*46:01‐DRB1*09:01:08.