HLA class I diversity in Kolla Amerindians

Human leukocyte antigen (HLA) class I polymorphism was studied within a population of 70 unrelated Kolla Amerindians from the far northwest of Argentina close to the Bolivian border. The results indicate that the HLA-A, -B, and -C alleles typical of other Amerindian populations also predominate in the Kolla. These alleles belong to the following allele groups: HLA-A*02, *68, *31, *24, HLA-B*35, *15, *51, *39, *40, *48, and Cw*01, *03, *04, *07, *08, and *15. For the HLA-A locus, heterogeneity was seen for HLA-A*02 with A*0201, *0211, and *0222; and for A*68 with *68012 and *6817, the latter being a novel allele identified in this population. Analysis of HLA-B identified heterogeneity for all Amerindian allele groups except HLA-B*48, including the identification of the novel B*5113 allele. For HLA-C heterogeneity was identified within the Cw*07, *04, and *08 groups with Cw*0701/06, *0702, *04011, *0404, *0803, and *0809 identified. The most frequent "probable" haplotype found in this population was B*3505-Cw*04011. This study supports previous studies, which demonstrate increased diversity at HLA-B compared with HLA-A and -C. The polymorphism identified within the Kolla HLA-A, -B, and -C alleles supports the hypothesis that HLA evolution is subject to positive selection for diversity within the peptide binding site.     

HLA class I polymorphism in Mongolian and Hui ethnic groups from Northern China

HLA-A, -B, and -C alleles were genotyped by sequencing-based typing (SBT) in 102 unrelated ethnic Mongolian individuals living in Inner Mongolia and 110 Hui individuals inhabiting the Qihai plateau in Northern China. In all, 28 HLA-A, 49 HLA-B, and 27 HLA-C alleles in Mongolians and 29 HLA-A, 41 HLA-B, and 27 HLA-C alleles in Hui were detected in this study. A*24G1, A*110101/1121N and A*02G1 are the three most frequent HLA-A alleles both in Mongolians and Hui. At the HLA-B locus, only B*51G1 was found with a frequency of more than 10% in Hui. Cw*070201G1 is the most common HLA-C allele both in Mongolian and Hui. The most frequent HLA-A:C:B, HLA-A:C, and HLA-C:B haplotypes are A*330301-Cw*030201/030202-B*5801, A*330301-Cw*030201/030202, and Cw*030201/030202-B*5801 in Mongolian and A*0207/0215N-Cw*010201/010202-B*4601, A*02G1-Cw*070201G1, and Cw*010201/010202-B*4601 in Hui, respectively. The genetic distance (GD) estimated according to HLA-A, -B, and -C allele frequency indicates that Mongolian and Hui have the closest relationship, and both are closer to Northern Han rather than Southern Han, suggesting that the two ethnicities might have been subjected to intensive gene exchange with Northern Han in history. The dendrogram based on the GD measurements further demonstrates that Mongolian and Hui cluster as a branch with Northern Han Chinese and Northeast Asians. Our results may lead to better understanding of the origins and relationships of Chinese ethnic groups and provide the genetic background for disease association studies.     

Strong association between HLA-Cw*0706 and HLA-B*44032 in the Bubi population from Equatorial Guinea

Unrelated Bubi, native to the island of Bioko (Equatorial Guinea), were previously typed by low-resolution polymerase chain reaction using sequence-specific primers (PCR-SSP) and serology for HLA-A, -B and -C. HLA-B*44 was found frequently and associated with Cw*07. We have studied the HLA subtypes of 20 B*44pos/Cw*07pos Bubi individuals. HLA-B and -C were typed by sequencing exons 2 and 3. To distinguish the alleles Cw*1701/02/03, Cw*07011/012/06 and Cw*1801/02 additional sequencing of exon 1 or 5 was performed. All 20 B*44pos/Cw*07pos individuals of the Bubi population were typed Cw*0706 positive. Nineteen of them carried the B*44032 allele and one B*4407. In addition, 19 B*44neg/ Cw*07pos Bubi individuals were typed for HLA-C and none of them proved Cw*0706 positive. To determine whether the association between Cw*0706 and B*44032 was limited to the Bubi, 19 individuals from Dutch Caucasian families were typed in which B44 and Cw7 segregated on one haplotype. None of these individuals showed the presence of B*44032 or Cw*0706. The haplotypes found in the Dutch Caucasians were B*4402-Cw*0704, B*44031-Cw*07011 and B*44031-Cw*0702. The present observation indicates a strong association between B*44032 and Cw*0706 in the Bubi population.     

HLA-C sequence based typing: nucleotide analysis from exon 1 through exon 8. Identification of a new allele: Cw*0718

At present, 128 HLA-Cw alleles have been described. Twenty-four of 128 display critical polymorphisms in contributing to allele identification outside exons 2 and 3. As a matter of fact, complete resolution of Cw*030201, Cw*030202, Cw*0409N, Cw*0501, Cw*0503, Cw*070101, Cw*070102, Cw*070401, Cw*0706, Cw*0711, Cw*0718, Cw*120201, Cw*120202, Cw*150501, Cw*150502, Cw*1701, Cw*1702, Cw*1703, Cw*1801 and Cw*1802 alleles requires nucleotide analysis of exons 1, 4, 5, 6 and 7. Moreover, some alleles (Cw*04010101, Cw*04010102, Cw*07020101 and Cw*07020102) showing nucleotide differences outside the coding regions of HLA-C gene (intron 2) have been reported. High resolution sequence based typing (SBT) developed in this study involves two DNA amplifications and 12 direct sequencing reactions and allows the analysis of HLA-C polymorphisms from exon 1 through exon 8, including intron 2. This typing procedure identifies all 128 Cw alleles described so far. Nevertheless, a number of ambiguous heterozygous typing results may be expected, this being the major drawback of SBT methods. A total of 201 samples were HLA-C typed using SBT strategy here described. The sequence of exons 6, 7 and 8 of HLA-Cw*070102 allele was elucidated. A novel HLA-Cw*07 allele, Cw*0718, was identified in two samples. Cw*0718 differs from the Cw*070101 allele by a unique nucleotide position within exon 6, resulting in an amino acid substitution at codon 324 (Ala-->Val) in the cytoplasmic region of the molecule.     

Full-length extension of HLA allele sequences by HLA allele-specific hemizygous Sanger sequencing (SSBT)

The gold standard for typing at the allele level of the highly polymorphic Human Leucocyte Antigen (HLA) gene system is sequence based typing. Since sequencing strategies have mainly focused on identification of the peptide binding groove, full-length sequence information is lacking for >90% of the HLA alleles. One of the goals of the 17th IHIWS workshop is to establish full-length sequences for as many HLA alleles as possible. In our component “Extension of HLA sequences by full-length HLA allele-specific hemizygous Sanger sequencing” we have used full-length hemizygous Sanger Sequence Based Typing to achieve this goal. We selected samples of which full length sequences were not available in the IPD-IMGT/HLA database. In total we have generated the full-length sequences of 48 HLA-A, 45 -B and 31 -C alleles. For HLA-A extended alleles, 39/48 showed no intron differences compared to the first allele of the corresponding allele group, for HLA-B this was 26/45 and for HLA-C 20/31. Comparing the intron sequences to other alleles of the same allele group revealed that in 5/48 HLA-A, 16/45 HLA-B and 8/31 HLA-C alleles the intron sequence was identical to another allele of the same allele group. In the remaining 10 cases, the sequence either showed polymorphism at a conserved nucleotide or was the result of a gene conversion event. Elucidation of the full-length sequence gives insight in the polymorphic content of the alleles and facilitates the identification of its evolutionary origin.     

Increased HLA class I and II diversity as 72 novel alleles are identified in volunteers for the National Marrow Donor Program Registry in 2010

Seventy-two novel human leukocyte antigen (HLA) class I and class II alleles are described from volunteers for the 'Be The Match Registry?': 17 HLA-A alleles, 12 HLA-C alleles, 31 HLA-B alleles and 12 HLA-DRB1 alleles. Forty-six (≈ 64%) of the 72 novel alleles are single-nucleotide substitution variants when compared with their most homologous allele. Five of these single-nucleotide variants are silent substitutions and one creates a non-expressed allele (B*44:108N). The remaining novel alleles differ from their most similar allele by two to five nucleotide substitutions. One of the novel HLA-C alleles (C*07:150Q) is of questionable expression due to an insertion of 21 nucleotides starting at codon 143 that adds seven amino acids to exon 3. An inter-locus gene conversion may have created the novel allele HLA-A*23:31 that shares its codon differences with HLA-B*07:28. Some of the new alleles encode novel codons and unique amino acid changes at polymorphic positions in the HLA-A (codons 116 and 150), HLA-C (codon 114), HLA-B (codons 11, 21, 35, 42, 48, 73, 98 and 170) and HLA-DRB1 (codon 29) loci.     

Intron sequences of HLA-B*73

Molecular typing methods of HLA-B, like sequence-specific oligonucleotide hybridization and sequence-based typing, are based on gene-specific amplifications of exons 2 and 3 followed by probe hybridization or sequence determination. The necessary gene-specific amplification primers are often located in rather conserved regions of the introns. In several of these procedures HLA-B*73 was not amplified, resulting in drop-out of the allele. To investigate the reason for the allelic drop-out, the sequences of introns 1, 2 and 3 of HLA-B*7301 were determined. Comparison of the intron sequence of B*7301 with other HLA-B and HLA-C alleles revealed several remarkable features. The overall sequence resembles the sequence of other HLA-B alleles, although 35 differences were found with a consensus intron sequence. The insertions and deletions shown in intron 2 of B*73 were strikingly similar with the sequences of the HLA-C alleles, as was the 5' end of intron 3. Furthermore, a unique deletion was observed in the middle of intron 3, not noticed in other HLA-B or C alleles. The HLA-B-specific primers, widely used for sequence-specific oligonucleotide hybridization and sequence-based typing purposes, showed mismatches with the B*73 intron sequences, causing the allelic drop-out. Correct amplification of complete exons 2 and 3 of B*7301 was enabled by the design of new primers in intron 2 and 3.     

造血干细胞移植受-供者HLA抗原识别部位的核苷酸匹配研究

目的 研究中国人群等待造血干细胞移植受-供者人类白细胞抗原(human leukocyte antigens,HLA)-A、-B、-Cw、-DRBl、-DQB1 5个位点的等位基因及核苷酸匹配情况,从单核苷酸水平探讨最佳供选择方案.方法 采用聚合酶链反应测序分型法(polymerase chain reaction-sequence-based typing,PCR-SBT),对537对中国人群等待造血干细胞移植受-供者HLA-A、-B、-Cw、-DRB1、-DQB1位点的等位基因进行序列分型,应用BLAST工具分析受-供者HLA核苷酸差异.结果 37对受-供者中HLA-A、-B、-Cw、-DRB1、-DQB1五位点核苷酸完全匹配占16.20%,单个等位基因错配的受-供者对分别占8.38%,0.74%,12.29%,2.42%和2.79%,两个或两个以上等位基因错配比率占42.65%.检出A*02:01-A*02:06,A*02:06-A*02:07,Cw*03:04-Cw*15:02,Cw*03:03-Cw*04:01,Cw*03:04-Cw*14:02,Cw *03:03-Cw*08:01,DRB1*04:03:01-DRB1*04:05不容许错配等位基因对.两对受-供者B*07:05:01-B*07:06,Cw*07:01:01-Cw*07:06抗原识别区外核苷酸错配.结论 在造血干细胞移植选择HLA错配的无关供者时注意受-供核苷酸匹配差异,对HLA抗原识别区内的核苷酸匹配差异和抗原识别区外的核苷酸匹配差异应当加以区别.本研究结果为优化供者选择顺序提供科学参考数据.     

An unusual insertion in intron 2 of apparently functional MHC class I alleles in rhesus macaques

Here we describe a nucleotide insertion in intron 2 of two rhesus major histocompatibility complex (MHC) class I alleles, Mamu-A*05 and Mamu-A*07. This resulted in an intron 2 that was nearly twice the length of any other intron 2 of primate MHC class I genes sequenced to date. This insertion was most similar (93% identity) to the beginning of intron 3 of HLA-A alleles. It was also similar to intron 3 of several human MHC class I pseudogenes and MHC class I pseudogenes from cotton top tamarin and cat. The finding of this insertion in two rhesus MHC class I genes is surprising given the uniformity in length and sequence of introns of functional HLA-A, -B and -C genes.     

Anchored PCR cloning of the novel HLA-Cw*0704 allele detected by PCR-SSP

Abstract: The novel HLA-Cw*0704 allele, previously detected as the PCR-SSP variant Cw7/8v, has been cloned and sequenced from the homozygous typing cell KR03/4 after amplification by anchored PCR. The nucleotide sequence of Cw*0704 is closely related to those of other Cw*07 alleles, but carries specific changes in exon 3 consistent with its serological behavior - a short Cw7 cross-reactive with antibodies directed against HLA-Cw8. Some of the substitutions of Cw*0704 have not been previously described for HLA-C but are found in HLA-B alleles and in published C sequences of non-human primates. The new allele carries a novel polymorphism in its 5' untranslated region (5'ut) that could be shared by all Cw*07 alleles. By PCR-SSP, Cw*0704 is a relatively common allele in English Caucasoids at a frequency of 4.6%. It is most often observed on HLA-B44 haplotypes previously described as HLA-C "blank", although linkage disequilibria with other HLA-B specificities have been found.     

The association of human leucocyte antigen (HLA) alleles with COVID-19 severity: A systematic review and meta-analysis

Due to their pivotal role in orchestrating the immune response, HLA loci were recognized as candidates for genetic association studies related to the severity of COVID-19. Since the findings on the effects of HLA alleles on the outcome of SARS-CoV-2 infection remain inconclusive, we aimed to elucidate the potential involvement of genetic variability within HLA loci in the molecular genetics of COVID-19 by classifying the articles according to different disease severity/outcomes and by conducting a systematic review with meta-analysis. Potentially eligible studies were identified by searching PubMed, Scopus and Web of Science literature databases. A total of 28 studies with 13,073 participants were included in qualitative synthesis, while the results of 19 studies with 10,551 SARS-CoV-2-positive participants were pooled in the meta-analysis. According to the results of quantitative data synthesis, association with COVID-19 severity or with the lethal outcome was determined for the following alleles and allele families: HLA-A*01, HLA-A*03, HLA-A*11, HLA-A*23, HLA-A*31, HLA-A*68, HLA-A*68:02, HLA-B*07:02, HLA-B*14, HLA-B*15, HLA-B*40:02, HLA-B*51:01, HLA-B*53, HLA-B*54, HLA-B*54:01, HLA-C*04, HLA-C*04:01, HLA-C*06, HLA-C*07:02, HLA-DRB1*11, HLA-DRB1*15, HLA-DQB1*03 and HLA-DQB1*06 (assuming either allelic or dominant genetic model). We conclude that alleles of HLA-A, -B, -C, -DRB1 and -DQB1 loci may represent potential biomarkers of COVID-19 severity and/or mortality, which needs to be confirmed in a larger set of studies.     

HLA class I diversity among rural rainforest inhabitants in Cameroon: identification of A*2612-B*4407 haplotype

The population distribution of alleles of the classical HLA class I loci in Cameroon has not been well studied but is of particular interest given the AIDS and malarial epidemics afflicting this population. We investigated the genetic diversity of HLA-A, HLA-B and HLA-C alleles in remote populations of Cameroon. Subjects from seven small, isolated, indigenous populations (N = 274) in the rainforest of southern Cameroon were typed for HLA-A, HLA-B and HLA-C alleles using a polymerase chain reaction/sequence-specific oligonucleotide probe assay and sequence analysis. Multiple alleles of the HLA-A (N = 28), HLA-B (N = 41) and HLA-C (N = 21) loci were identified, of which A*2301[allele frequency (AF) = 12.8%], B*5802 (AF = 10.9%) and Cw*0401 (AF = 16.6%) were the most frequent individual alleles and A*02 (AF = 19.0%), B*58 (AF = 15.9%) and Cw*07 (AF = 22.4%) the most common serologically defined groups of alleles. Twenty-six (28.9%) alleles with a frequency of less than 1% (AF < 1%), 39 (43%) with a frequency of 2.0-15.0% (AF = 2.0-15.0%), three globally uncommon alleles [A*2612 (AF = 2.0%), B*4016 (AF = 0.7%) and B*4407 (AF = 1.4%)], and the A*2612-Cw*0701/06/18-B*4407 haplotype (haplotype frequency = 1.3%) were also identified. Heterozygosity values of 0.89, 0.92 and 0.89 were determined for HLA-A, HLA-B and HLA-C, respectively. The extensive allelic and haplotypic diversity observed in this population may have resulted from varied natural selective pressures on the population, as well as intermingling of peoples from multiple origins. Thus, from an anthropologic perspective, these data highlight the challenges in T-cell-based vaccine development, the identification of allogeneic transplant donors and the understanding of infectious disease patterns in different populations.     

There is more to HLA-C than exons 2 and 3: sequencing of exons 1, 4 and 5

HLA-C was shown to be a highly polymorphic gene which can be accurately typed for by sequencing methodologies. Most HLA-C sequence-based typing protocols described so far are based on analysis of sequence data of exons 2 and 3. Nonetheless, exons 1, 4 and 5 also contain nucleotide substitutions which contribute to the polymorphisms of the HLA-C locus. Ten alleles contain polymorphic positions in exons 1, 4 and 5, Cw*0701/06, Cw*1202112, Cw*15051/2, Cw*1701/02, and Cw*1801/02. Here we describe a reliable solid-phase sequence-based typing strategy for sequencing exons 1, 4 and 5, which is an extended protocol of our previous HLA-C study. A panel of 16 individuals, carrying 27 different Cw-alleles, was typed for exons 1, 4 and 5 to check the newly designed primers. No allelic dropout or preferential amplification was noticed in these individuals. The panel was also sequenced in order to check the known polymorphisms present in exons 1, 4 and 5. For exon 5 the sequences of the alleles Cw*0302, *0501 and *07011 did not correspond with the published data. In addition, exons 1, 4 and 5 were sequence-based typing typed in 28, 17 and 59 individuals, respectively. Two new alleles were detected which contain polymorphic positions outside exons 2 and 3, Cw*07012 and Cw*1703. The unknown sequence data of exons 1, 4 and 5 of the alleles Cw*02024, *0308, *1506 and *16041 were elucidated. The described high-resolution sequence-based typing protocol for sequencing exons 1, 4 and 5 will be a valuable tool to study the HLA-C locus for polymorphisms outside exons 2 and 3 and for identification of the presently known HLA-C alleles with polymorphic positions in these exons.     

Polymorphism of HLA class I genes in the Brazilian population from the Northeastern State of Pernambuco corroborates anthropological evidence of its origin

The allelic distribution of human leukocyte antigen (HLA) class I genes (HLA-A, HLA-B, and HLA-Cw) of the population from the State of Pernambuco in Northeastern Brazil was studied in a sample of 101 healthy unrelated individuals. Low to medium resolution HLA class I typing was performed using polymerase chain reaction-amplified DNA hybridized to sequence specific primers (PCR-SSPs). Twenty allele groups were detected for HLA-A, 28 for HLA-B, and 14 for HLA-Cw. The most frequent alleles were HLA-A*02(0.2871), HLA-B*15(0.1238), and HLA-Cw*04(0.2277), and the most frequent genotypes were A*02/A*02(0.0990), B*15/B*15(0.0594), and Cw*04/Cw*04 and Cw*07/Cw*07, both with a frequency of 0.0792. The observed heterozygosity for the studied loci was 79.21% for HLA-A, 87.13% for HLA-B, and 77.23% for HLA-Cw. The most frequent haplotype was A*02-Cw*04-B*35(0.0485), which is also present in Western European, Amerindian, and Brazilian Mulatto populations, but absent in African populations. Taken together, these data corroborate the historic anthropological evidences of the origin of the Northeastern Brazilian population from Pernambuco.     

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.     

HLA-A, -B, -C, -DRB1 allele and haplotype frequencies in an African American population

Sequence-based typing was used to identify human leukocyte antigen (HLA)-A, -B, -C, and -DRB1 alleles from 564 consecutively recruited African American volunteers for an unrelated hematopoietic stem cell registry. The number of known alleles identified at each locus was 42 for HLA-A, HLA-B 67, HLA-C 33, and HLA-DRB1 44. Six novel alleles (A*260104, A*7411, Cw*0813, Cw*1608, Cw*1704, and DRB1*130502) not observed in the initial sequence-specific oligonucleotide probe testing were characterized. The action of balancing selection, shaping more 'even' than expected allele frequency distributions, was inferred for all four loci and significantly so for the HLA-A and DRB1 loci. Two-, three-, and four-locus haplotypes were estimated using the expectation maximization algorithm. Comparisons with other populations from Africa and Europe suggest that the degree of European admixture in the African American population described here is lower than that in other African American populations previously reported, although HLA-A:B haplotype frequencies similar to those in previous studies of African American individuals were also noted.     

MICA genetic polymorphism and HLA-A,C,B,MICA and DRB1 haplotypic variation in a southern Chinese Han population: identification of two new MICA alleles, MICA*060 and MICA*062

In this study, 201 healthy, unrelated Han subjects in Hunan province, southern China, were investigated by sequence-based typing (SBT) for the allelic variation of the human major histocompatibility complex (MHC) class I chain-related gene A (MICA). Nineteen MICA alleles were observed, among which MICA*008:01 predominated with gene frequency of 30.35%. There was significant linkage disequilibrium (LD) of MICA*012:01 with HLA-B*54 and HLA-B*55, which was not observed in a northern Chinese Han population. Haplotype HLA-A*11-C*07-B60-MICA*008:01 (9.16%) was highly specific to this southern Chinese Han population. The most common five-locus haplotype in this population was HLA-A*02-C*01-B*46-MICA*010-DRB1*09 (8.73%). A new MICA allele, MICA*060, was identified on an HLA-A*02-C*01-B*55:02-DRB1*14 haplotype through extended family analysis. MICA*060 has probably arisen from MICA*012:01. Another new MICA allele, MICA*062, was identified by screening 1432 subjects using polymerase chain reaction-sequence-specific priming technology. MICA*062 has probably derived from MICA*010. Of particular interest is that MICA*062 was carried on an HLA-C*08-B*48:01-DRB1*14 haplotypic segment, as HLA-B*48 has been consistently shown to be primarily linked to MICA gene deletion in east Asian populations. Our results provide new insight into MICA genetic polymorphism in human populations. The findings reported here are of importance for future studies on the potential role of MICA in allogeneic organ transplantation and disease association in populations of Chinese ancestry.     

HLA-A, -B, -C, -DRB1 and -DQB1 alleles and haplotypes in the Kinh population in Vietnam

Allele and haplotype frequencies of the human leukocyte antigens (HLA) were studied in the Kinh Vietnamese population. We analyzed 170 unrelated healthy individuals. DNA-based HLA typing was performed using a microsphere-based array genotyping platform with sequence-specific oligonucleotide probes to distinguish HLA-A, -B, -C, -DRB1 and -DQB1 alleles. A total of 21 HLA-A, 37 HLA-B, 18 HLA-C, 25 HLA-DRB1, and 14 HLA-DQB1 alleles were identified. HLA-A*1101, A*2402, A*3303, B*1502, B*4601, Cw*0102, Cw*0702, Cw*0801, DRB1*1202, DQB1*0301, DQB1*0303, and DQB1*0501 were found with frequencies higher than 10%. Two representative haplotypes bearing two to five HLA loci were A*1101-B*1502 and A*3303-B*5801 for HLA-A-B; Cw*0801-B*1502 and Cw*0102-B*4601 for HLA-C-B; B*1502-DRB1*1202 and B*4601-DRB1*0901 for HLA-B-DRB1; DRB1*1202-DQB1*0301 and DRB1*0901-DQB1*0303 for HLA-DRB1-DQB1; A*1101-Cw*0801-B*1502 and A*3303-Cw*0302-B*5801 for HLA-A-C-B; A*1101-B*1502-DRB1*1202 and A*2901-B*0705-DRB1*1001 for HLA-A-B-DRB1, A*1101-Cw*0801-B*1502-DRB1*1202-DQB1*0301 and A*2901-Cw*1505-B*0705-DRB1*1001-DQB1*0501 for HLA-A-C-B-DRB1-DQB1. Allele distribution and haplotype analysis demonstrated that the Vietnamese population shares HLA patterns with southern Chinese, Thai, Javanese and Micronesians, while it also retains unique characteristics.     

Cloning and sequencing full-length HLA-B and -C genes

Currently most available HLA-A, -B and -C DNA sequences cover exons 2 and 3 with a limited number extending to include other exons and introns. We have developed a method for the accurate determination of full-length genomic DNA sequences for HLA-A, -B and -C alleles. The method involves cloning of PCR amplified full-length HLA genes to separate alleles at heterozygous loci. The approach avoids any ambiguities from sequencing heterozygous PCR products directly and also avoids ambiguities from sequencing overlapping PCR products to achieve full-length sequence. To date we have sequenced full-length genomic sequences from representatives of all the major HLA-B and -C allele groups.