Identification of the novel HLA‐B*40:221 allele in a Taiwanese hematopoietic stem cell donor using a sequence‐based typing method

Using DNA sequence‐based typing method, we found a new HLA‐B*40 variant, B*40:221, in a Taiwanese hematopoietic stem cell donor. The allele sequence of B*40:221 is identical to the sequence of B*40:01:01 in exons 2, 3 and 4 except the nucleotides at codon 265 (GGG→AGG). The sequence variation caused one amino acid exchange at residue 265 where Gly was replaced by Arg. The probable HLA‐A, ‐B, ‐C, ‐DRB1 and ‐DQB1 haplotype in association with B*40:221 may be deduced as HLA‐A*11:01‐B*40:221‐C*03:04‐DRB1*14:54‐DQB1*05:02. The generation of B*40:221 is thought as a result of a nucleotide point mutation involving B*40:01:01. Our discovery of B*40:221 increases the polymorphism of B*40 in Taiwanese.     

Detection of the rare HLA‐B*40:97 allele in an unrelated Taiwanese bone marrow donor

We detected a rare HLA‐B locus allele, B*40:97, in a Taiwanese unrelated donor in our routine HLA SBT (sequence‐based typing) exercise for a possible hematopoietic stem cell donation. In exons 2, 3 and 4, the sequence of B*40:97 is identical to the sequence of B*40:02:01 except one nucleotide at nucleotide position 760 (C‐>T) in exon 4. The nucleotide variation caused one amino acid alteration at residue 230 (L‐>F). B*40:97 was probably derived from a nucleotide substitution event where C was replaced by T at nucleotide 760 involving B*40:02:01. The HLA‐A, HLA‐B, HLA‐C, HLA‐DRB1 and HLA‐DQB1 haplotype in association with B*40:97 may be deduced as A*26:01‐B*40:97‐C*03:03‐DRB1*11:01‐DQB1*03:03. Our recognition of B*40:97 in Taiwanese helps to fill the void of ethnic information for the allele B*40:97 reported to the IMGT/HLA Database.     

Discovery of a novel HLA‐DRB1*04:05 variant,DRB1*04:05:15, in a Taiwanese and the probable HLA haplotype in association with DRB1*04:05:15

Here, we report a novel HLA‐DRB1*04 allele, DRB1*04:05:15, found in a Taiwanese unrelated volunteer bone marrow hematopoietic stem cell donor by a sequence‐based typing (SBT) method. The DNA sequence of DRB1*04:05:15 is identical to the sequence of DRB1*04:05:01 in exon 2, except the nucleotide at the position 198 where C is substituted by T (TAC→TAT at codon 37). Due to the silent mutation, the nucleotide replacement generated no amino acid variation in comparison with DRB1*04:05:01. We postulate the allele DRB1*04:05:15 was probably derived from DRB1*04:05:01 via a nucleotide point mutation event. The probable HLA‐A, ‐B, ‐C, ‐DRB1 and ‐DQB1 haplotype in association with DRB1*04:05:15 may be deduced as A*02:01‐B*48:01‐C*08:03‐DRB1*04:05:15‐DQB1*04:01.     

Discovery of the novel HLA‐DRB1*10:04 allele in a Taiwanese volunteer bone marrow donor and identification of the probable HLA‐A, ‐B, ‐C and ‐DRB1 haplotype in association with DRB1*10:04

We report here a novel variant of HLA‐DRB1*10, DRB1*10:04, discovered in a Taiwanese volunteer bone marrow donor by a sequence‐based typing (SBT) method. The DNA sequence of DRB1*10:04 differs from DRB1*10:01:01, in exon 2, at nucleotide positions 296 (G→A) and 303 (T→G). The nucleotide changes caused an amino acid substitution at amino acid residue 70 (R→Q). We hypothesize that the formation of DRB1*10:04 was probably the result of a gene recombination event where DRB1*10:01:01 received a minimum length of DNA sequence from DRB1*04:05:01, as the sequence of DRB1*10:04 is identical to DRB1*10:01:01 in exon 2 except the sequence from nucleotide 296 to nucleotide 303, which is identical to DRB1*04:05:01. The plausible HLA‐A, ‐B, ‐C and ‐DRB1 haplotypes in association with DRB1*10:04 was deduced as A*01:01‐B*37:01‐C*06:02‐DRB1*10:04.     

A conserved HLA‐A*02:28 associated HLA haplotype,A*02:28‐B*15:11‐DRB1*09:01, restricted to Taiwanese

HLA‐A*02:28, found in a Korean and a Japanese, was reported independently to the IMGT/HLA database in 2003 and 2005, respectively. We report here eight Taiwanese unrelated bone marrow hematopoietic stem cell donors carrying A*02:28 detected during our routine HLA typing exercise. The probable HLA‐A, ‐B and ‐DRB1 haplotype in association with A*02:28 may be deduced from the eight marrow stem cell donor as A*02:28‐B*15:11‐DRB1*09:01. Our result suggests A*02:28‐B*15:11‐DRB1*09:01 is a conserved HLA haplotype restricted to Taiwanese.     

Discovery of the novel HLA‐DRB1*04:05:14 allele in a Taiwanese unrelated haematopoietic stem cell donor by a sequence‐based typing method

We report here a de novo HLA‐DRB1*04 allele, DRB1*04:05:14, discovered in a Taiwanese unrelated volunteer bone marrow stem cell donor by a sequence‐based typing method. In exon 2, the DNA sequence of DRB1*04:05:14 is identical to the sequence of DRB1*04:05:01 except the nucleotide at positions 321 where C is replaced by T (at codon 78; TAC→TAT). Due to the silent mutation, the nucleotide substitution produced no amino acid variation in comparison with DRB1*04:05:01. We assume DRB1*04:05:14 was derived from DRB1*04:05:01 via a point mutation. The probable HLA‐A, ‐B and ‐DRB1 haplotype in association with DRB1*04:05:14 may be deduced as A*11‐B*55‐DRB1*04:05:14. We here report the Taiwanese ethnicity of DRB1*04:05:14.     

Discovery of HLA‐DRB1*03:20 allele in a Taiwanese volunteer hematopoietic stem cell donor and the probable HLA‐A, ‐B, ‐C and ‐DRB1 haplotype in association with DRB1*03:20

The allele HLA‐DRB1*03:20, a variant of DRB1*03, was first reported to the IMGT HLA database in April 2001 without indication on the ethnicity of the blood donor (Cell ID: HC 125775). We found a Taiwanese volunteer hematopoietic stem cell donor carries DRB1*03:20 by a sequence‐based typing (SBT) method. The DNA sequence of DRB1*03:20 is identical to the sequence of DRB1*03:01:01 in exon 2, except a nucleotide substitution at position 341(T→C) (GTT→GCT at codon 85). The nucleotide replacement produced an amino acid variation at residue 85 (V→A). We hypothesize that DRB1*03:20 was probably derived from DRB1*03:01:01 via a nucleotide point mutation event. The probable HLA haplotype in association with DRB1*03:20 was deduced as A*11:02‐B*58:01‐C*07:02‐DRB1*03:20. We here report the Taiwanese/Chinese ethnicity of DRB1*03:20.     

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.     

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.     

Study on the polymorphisms of HLA‐ABCDQB1DRB1 alleles and haplotypes in Hubei Han population of China

The present study aimed to analyse the frequencies of human leukocyte antigen HLA‐ABCDQB1 and HLA‐DRB1 alleles and haplotypes in a subset of 3,732 Han population from Hubei of China. All samples were typed in the HLA‐ABCDQB1 and HLA‐DRB1 loci using the sequence‐based typing method; subsequently, the HLA polymorphisms were analysed. A total of 47 HLA‐A, 89 HLA‐B, 43 HLA‐C, 49 HLA‐DRB1 and 24 HLA‐DQB1 alleles were identified in the Hubei Han population. The top three most frequent alleles in the HLA‐ABCDQB1 and HLA‐DRB1 were A*11:01 (0.2617), A*24:02 (0.1590), A*02:07 (0.1281); B*46:01 (0.1502), B*40:01 (0.1409) and B*58:01 (0.0616); C*01:02 (0.2023), C*07:02 (0.1691) and C*03:04 (0.1175); and DQB1*03:01 (0.2000), DQB1*03:03 (0.1900), DQB1*06:01 (0.1187); DRB1*09:01 (0.1790), DRB1*15:01 (0.1062) and DRB1*12:02 (0.0841), respectively. Meanwhile, the three most frequent two‐loci haplotypes were A*02:07‐C*01:02 (0.0929), B*46:01‐C*01:02 (0.1366) and DQB1*03:03‐DRB1*09:01 (0.1766). The three most frequent three‐loci haplotypes were A*02:07‐B*46:01‐C*01:02 (0.0883), B*46:01‐DQB1*03:03‐DRB1*09:01 (0.0808) and C*01:02‐DQB1*03:03‐DRB1*09:01 (0.0837). The three most frequent four‐loci haplotypes were A*02:07‐B*46:01‐C*01:02‐DQB1*03:03 (0.0494), B*46:01‐DRB1*09:01‐C*01:02‐DQB1*03:03 (0.0729) and A*02:07‐B*46:01‐DQB1*03:03‐DRB1*09:01 (0.0501). The most frequent five‐loci haplotype was A*02:07‐B*46:01‐C*01:02‐DQB1*03:03‐DRB1*09:01 (0.0487). Heat maps and multiple correspondence analysis based on the frequencies of HLA specificity indicated that the Hubei Han population might be described into Southern Chinese populations. Our results lay a certain foundation for future population studies, disease association studies and donor recruitment strategies.     

HLA‐A, ‐B and ‐DRB1 allele and haplotype frequencies of 8333 Chinese Han from the Zhejiang province,China

The distribution of human leucocyte antigen (HLA) allele and haplotype is varied among different ethnic populations. In this study, HLA‐A, ‐B and ‐DRB1 allele and haplotype frequencies were determined in 8333 volunteer bone marrow donors of Zhejiang Han population using the polymerase chain reaction sequence‐based typing. A total of 52 HLA‐A, 96 HLA‐B and 61 HLA‐DRB1 alleles were found. Of these, the top three frequent alleles in HLA‐A, HLA‐B and HLA‐DRB1 loci, respectively, were A*11:01 (24.53%), A*24:02 (17.35%), A*02:01 (11.58%); B*40:01 (15.67%), B*46:01 (11.87%), B*58:01 (9.05%); DRB1*09:01 (17.54%),DRB1*12:02 (9.64%) and DRB1*08:03 (8.65%). A total of 171 A‐B‐DRB1 haplotypes with a frequency of >0.1% were presented and the five most common haplotypes were A*33:03‐B*58:01‐ DRB1*03:01, A*02:07‐B*46:01‐DRB1*09:01, A*30:01‐B*13:02‐DRB1*07:01, A*33:03‐B*58:01‐RB1*13:02 and A*11:01‐B*15:02‐DRB1*12:02. The information will be useful for selecting unrelated bone marrow donors and for anthropology studies and pharmacogenomics analysis.     

Identification of the novel HLA‐B*13:02:13 allele in a Taiwanese haematopoietic stem cell donor and the probable HLA haplotype in association with B*13:02:13

Using sequence‐based typing method, we found a new HLA‐B*13:02 variant, B*13:02:13, in a Taiwanese haematopoietic stem cell donor. The DNA sequence of B*13:02:13 is identical to the sequence of B*13:02:01 in exons 2 and 3 except the nucleotide at position 588 where G is replaced by T (codon 172; CTG→CTT). The DNA sequence variation did not alter the amino acid sequence of B*13:02:01. The generation of B*13:02:13 is thought to derive from B*13:02:01 as a result of a silence mutation. The probable HLA‐A, HLA‐B and HLA‐DRB1 haplotype in association with B*13:02:1 may be deduced as HLA‐A*24‐B*13:02:13‐DRB1*07:01 or HLA‐A*02‐B*13:02:13‐DRB1*07:01. The discovery of B*13:02:13 furthers the polymorphism of HLA‐B*13 and HLA‐B*13:02.     

Recognition of HLA‐A*24:137 allele in a Taiwanese unrelated bone marrow stem cell donor and the plausible HLA haplotype associated with A*24:137

We detected a rare HLA‐A*24:137 allele in an unrelated Taiwanese haematopoietic stem cell donor during a routine SBT (sequence‐based typing) HLA typing exercise. The DNA sequence of A*24:137 is identical to the sequence of A*24:02:01:01 in exons 2 and 3 except at codon 21 where CGC was replaced with CAA. The DNA variation caused an amino acid alteration at amino acid residue 21 (R‐>Q). The HLA haplotype in association with A*24:137 may be deduced as A*24:137‐B*15‐DRB1*14. The formation of A*24:137 was probably the result of a nucleotide point mutation involving A*24:02:01:01. It remains to be determined whether A*24:137 is restricted to Taiwanese/Chinese ethnicity.     

Recognition of a Caucasoid HLA‐B locus allele,B*44:55, in a Taiwanese/Chinese bone marrow stem cell donor

We detected a Caucasoid HLA‐B allele, HLA‐B*44:55, in a potential Taiwanese/Chinese bone marrow hematopoietic stem cell donor during our routine HLA SBT (sequence‐based typing) practice. The sequence of B*44:55 varies with B*44:02:01:01 with one nucleotide in exon 2 at position 97 (T‐>C), while it differs from B*44:03:01 with one nucleotide in exon 2 at position 97 (T‐>C) and three nucleotides in exon 3 at residues 538–540 (CTG‐>GAC). The nucleotide replacements caused one amino acid variation with B*44:02:01:01 at residue 9 (Y‐>H) and two amino acid variations with B*44:03:01 at residue 9 (Y‐>H) and residue 156 (L‐>D). The formation of B*44:55 is probably the result of a nucleotide substitution involving B*44:02:01:01 at position 97 (T‐>C). The Taiwanese/Chinese donor with B*44:55 claims having no kinship with Caucasian. Our speculations on the origin of the Taiwanese/Chinese B*44:55 will be presented.     

Analysis of high‐resolution HLA‐A, ‐B, ‐Cw, ‐DRB1, and ‐DQB1 alleles and haplotypes in 718 Chinese marrow donors based on donor–recipient confirmatory typings

High‐resolution human leucocyte antigen (HLA)‐A, ‐B, ‐Cw, ‐DRB1, and ‐DQB1 alleles and haplotype frequencies were analysed from 718 Chinese healthy donors selected from the Chinese Marrow Donor Program registry based on HLA donor–recipient confirmatory typings. A total of 28 HLA‐A, 61 HLA‐B, 30 HLA‐Cw, 40 HLA‐DRB1 and 18 HLA‐DQB1 alleles were identified, and HLA‐A*1101, A*2402, A*0201, B*4001, Cw*0702, Cw*0102, Cw*0304, DRB1*0901, DRB1*1501, DQB1*0301, DQB1*0303 and DQB1*0601 were found with frequencies higher than 10% in this study population. Multiple‐locus haplotype analysis by the maximum‐likelihood method revealed 45 A–B, 38 Cw–B, 47 B–DRB1, 29 DRB1–DQB1, 24 A–B–DRB1, 38 A–Cw–B, 23 A–Cw–B–DRB1, 33 Cw–B–DRB1–DQB1 and 22 A–Cw–B–DRB1–DQB1 haplotypes with frequencies >0.5%. The most common two‐, three‐, four‐ and five‐locus haplotypes in this population were: A*0207–B*4601 (7.34%), Cw*0102–B*4601 (8.71%), B*1302–DRB1*0701 (6.19%), DRB1*0901–DQB1*0303 (14.27%), A*3001–B*1302–DRB1*0701 (5.36%), A*0207–Cw*0102–B*4601 (7.06%), A*3001–Cw*0602–B*1302–DRB1*0701 (5.36%), Cw*0602–B*1302–DRB1*0701–DQB1*0202 (6.12%) and A*3001–Cw*0602–B*1302–DRB1*0701–DQB1*0202 (5.29%). Presentation of the high‐resolution alleles and haplotypes data at HLA‐A, ‐B, ‐Cw, ‐DRB1 and ‐DQB1 loci will be useful for HLA matching in transplantation as well as for other medical and anthropological applications in the Chinese population.     

Polymorphism of HLA‐A, ‐B, ‐DRB1, ‐DQA1 and ‐DQB1 haplotypes in a Croatian population

We describe for the first time extended haplotypes in a Croatian population. The present study gives the HLA‐A, ‐B, ‐DRB1, ‐DQA1 and ‐DQB1 allele and haplotype frequencies in 105 families with at least two offspring. All individuals were studied by conventional serology for HLA class I antigens (A and B), while class II alleles (DRB1, DQA1, DQB1) were typed using the PCR–SSOP method. HLA genotyping was performed by segregation in all 105 families. For extended haplotype analysis, 420 independent parental haplotypes were included. Fourteen HLA‐A, 18 HLA‐B, 28 DRB1, 9 DQA1 and 11 DQB1 alleles were found in the studied population. Most of the DRB1 alleles in our population had an exclusive association with one specific DQA1‐DQB1 combination. This strong linkage disequilibrium within the HLA class II region is often extended to the HLA‐B locus. A total of 10 HLA‐A, ‐B, ‐DRB1, ‐DQA1, ‐DQB1 haplotypes were observed with a frequency ≤ 1.0%. The three most frequent haplotypes were HLA‐A1, B8, DRB1*0301, DQA1*0501, DQB1*0201; HLA‐A3, B7, DRB1*1501, DQA1*0102, DQB1*0602 and HLA‐A24, B44, DRB1*0701, DQA1*0201, DQB1*02. These results should provide a useful reference for further anthropological studies, transplantation studies, and studies of associations between HLA and diseases.     

Immunogenetics of three novel HLA‐Class II alleles: DRB1*03:112, DQB1*03:02:16 and DQB1*03:139

Three novel HLA‐Class II alleles, DRB1*03:112, DQB1*03:02:16 and DQB1*03:139, are described with predicted bearing haplotypes of A*02:01, B*40:01, C*03:04, DRB1*03:112, DQB1*02:01; A*23:01, B*15:01, C*03:03, DRB1*04:01, DQB1*03:02:16 and A*01:01, B*44:02, C*05:01/03, DRB1*04:01, DQB1*03:139. Serological tests showed that the DRB1*03:112 and DQB1*03:139 specificities failed to react as expected with some well‐documented monoclonal antibodies. Subsequent examination of published HLA‐Class II epitopes and inspection of amino acid motifs suggested that epitopes exist that include the positions of their single substitutions (F31C between DRB1*03:01:01:01 and DRB1*03:112, and R48P between DQB1*03:01:01:01 and DQB1*03:139 specificities). This suggests that the reactivity of the monoclonal antibodies used was dependent on these epitopes and that their loss from these rare allele products resulted in their aberrant serology. The new alleles were found after the sequence‐based typing of 32 530 random UK European routine blood donors suggesting that each has a maximum carriage frequency of 0.0031% in the blood donor population resident in Wales.     

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.     

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.     

Evaluation of Ion Torrent sequencing technology for rapid clinical human leucocyte antigen typing

The development of techniques to define the human leucocyte antigen (HLA) region has proven to be challenging due to its high level of polymorphism. Within a clinical laboratory, a technique for high‐resolution HLA typing, which is rapid and cost effective is essential. NGS has provided a rapid, high‐resolution HLA typing solution, which has reduced the number of HLA ambiguities seen with other typing methods. In this study, the One Lambda NXType NGS kit was tested on the Ion Torrent PGM platform. A total of 362 registry donors from four ethnic populations (Europeans, South Asians, Africans and Chinese) were NGS HLA typed across 9‐loci (HLA‐A, ‐B, ‐C, ‐DRB1,‐DRB345 ‐DQB1 and ‐DPB1). Concordance rates of 91%–98% were obtained (for HLA‐A, ‐B, ‐C, ‐DRB1, ‐DQB1 and ‐DPB1) when compared to historical PCR‐SSO HLA types, and the identification of uncommon alleles such as A*24:07:01 and C*04:82 were observed. A turnaround time of four days was achieved for typing 44 samples. However, some limitations were observed; primer locations did not allow all ambiguities to be resolved for HLA Class II where Exon I and IV amplification are needed (HLA‐DRB1*04:07:01/04:92, HLA‐DRB1*09:01:02/*09:21 and HLA‐DRB1*12:01:01/*12:10). This study has demonstrated high‐resolution typing by NGS can be achieved in an acceptable turnaround time for a clinical laboratory; however, the Ion Torrent workflow has some technical limitations that should be addressed.