应用SBT直接测序分型法研究中国南方汉族人群HLA五个基因座单倍型

目的 研究中国南方汉族人群HLA-A、B、Cw、DRBl、DQBl等位基因多态性及单倍型的分布特征.方法 应用聚合酶链反应-直接测序分型(polymerase chain reaction sequence-based typing,PCR-SBT)法对186名中国南方汉族健康人群HLA-A、B、Cw、DRBl、DQBl进行基因分型.结果 检出的HLA-A、B、Cw、DRBl、DQBl等位基因分别有28、49、24、29、20种.经统计分析A*0207-B*4601(10.81%),A*3303-B*5801(6.14%),B*4601-DRBl*0901(6.22%),B*4001*DRBl*0901(3.78%),DRBl*0901-DQBl*0303(12.16%)和DRBl*1202-DQBl*0301(8.38%)单倍型呈强连锁不平衡单倍型(RLF≥0.5,X<'2>>3.84,P<0.05);A*0207-B*4601-Cw*0102(10.75%),A*3303-B*5801-Cw*0302(5.14%),A*0207-B*4601-DR*0901(5.07%),A*3303-B*5801-DRBl*0301(2.96%),A*0207-B*4601-Cw*0102-DRBl*0901-DQBl*0303(4.87%)和A*1101-B*1301-Cw*0304-DRBl*1501-DQBl*0601(2.43%)单倍型分别是中国南方汉族人群常见单倍型.结论 中国南方汉族人群HLA 5个基因座单倍型分布具有高度的遗传多态性且有其自身分布特点.本研究获得的较完整的HLA 5个基因座单倍型分布数据,将为人类学、HLA疾病相关性和器官移植等研究提供遗传学参考数据.     

Allelic distribution of HLA class I genes in the Tibetan ethnic population of China

Tibetans live in Qinghai-Tibet Plateau rising about 4000 m a.s.l. in south-west China. Archaeological evidences suggested that there have been humans living in Tibet at least 5000 years ago. However, Tibetan earlier history remains elusive. In the present study, allelic distribution of human leucocyte antigen (HLA)-A, -B and -Cw in 158 unrelated Tibetan Chinese was investigated using sequencing-based typing methods, and a total of 25 HLA-A, 45 HLA-B and 20 HLA-Cw alleles were identified. A*24G1 (27.2%), B*51G1 (16.8%), Cw*04G1 (13.3%) and Cw*070201G1 (13.3%) are the most common HLA-A, -B and -Cw alleles. The most frequently detected haplotypes were A*24G1-B*51G1-Cw*140201 (3.6%), A*24G1-B*51G1 (6.8%), A*02G1-Cw*070201G1 (6.5%) and B*51G1-Cw*140201 (5.0%). Chi-squared test suggested that all three loci fitted the Hardy-Weinberg expectations. No evidence for a departure from selective neutrality at the HLA-A and -B loci was observed. However, significant departure of the observed homozygosity from the expected values was found for HLA-Cw. Though the contemporary Tibetans inhabit the south-west China, Nei's genetic distance measure based on frequencies of HLA-A, -B and -Cw indicated that Tibetans were closer to northern Han Chinese, Mongolian Chinese, Koreans and Japanese rather than to southern Han Chinese. The corresponding dendrogram constructed according to the neighbour-joining method supported that Tibetans separated from southern Han and located in North-East Asian cluster which included northern Han Chinese and Mongolian Chinese. These data were in good agreement with language classification and with a recent hypothesis that Tibetan might originate from northern China along Yellow river.     

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.     

Diversity of HLA-B17 alleles and haplotypes in East Asians and a novel Cw6 allele (Cw*0604) associated with B*5701

The distribution of HLA-B17 alleles and their association with HLA-A, -C and -DRB1 alleles were investigated in seven East Asian populations Japanese, South Korean, Chinese-Korean, Man, Northern Han, Mongolian and Buryat populations). The B17 alleles were identified from genomic DNA using group-specific polymerase chain reaction (PCR) followed by hybridization with sequence-specific oligonucleotide probes (SSOP). In all of these East Asian populations, except Japanese and Chinese-Koreans, B*5701 was detected and strongly associated with A*0101, Cw*0602 and DRB1*0701. In contrast, B*5801 was detected in all the seven populations and strongly associated with A*3303, Cw*0302, DRB1*0301 and DRB1*1302. The A*3303-Cw*0302-B*5801-DRB1*1302 haplotype was observed in South Korean, Chinese-Korean, Buryat and Japanese populations, while A*3303-Cw*0302-B*5801-DRB1*0301 was predominantly observed in the Mongolian population. A similar haplotype, A*0101-Cw*0302-B*5801-DRB1*1302, was observed in the Buryat population. A novel Cw6 allele, Cw*0604, was identified in the Man population. This Cw allele was observed on the haplotype A*0101-B*5701-DRB1*0701. Thus, we confirmed, at the sequence level, that the common haplotypes carrying B*5701 and B*5801 have been conserved and shared in East Asian populations.     

Description of two new HLA-C alleles in a black South African population

Two new HLA-C alleles, Cw*0333 and Cw*0217, were identified in a Black South African population. HLA-Cw*0333 differs from Cw*030201 by an A-->G substitution at nucleotide 323, yielding an unusual missense substitution of Cys for the conserved Tyr-84 at the antigen cleft terminus. Molecular modeling suggests that this alters the predicted interactions of this critical residue with the opposite alpha(2)-helix, the peptide COOH terminus and possibly KIR2DL2. The second allele, Cw*0217, differs from Cw*0205 by an A-->T substitution at nucleotide 368, resulting in a Tyr-->Phe substitution at residue 99 of the HLA-C beta-pleated sheet that likely influences peptide side-chain binding. Both Cw*0333 and Cw*0217 appear to have arisen by missense mutations, respectively, from the HLA-B*5801-Cw*0302 and B*080101-Cw*0205 haplotypes.     

Polymorphism of HLA class I genes in Meizhou Han population of Guangdong, China

Human leukocyte antigen (HLA) is an invaluable marker for anthropological studies because of its extreme polymorphism. Most of the studies carried out in Chinese populations are about HLA class II genes, but few about class I genes. In the present study, we investigated HLA class I polymorphism using polymerase chain reaction-sequencing-based typing (PCR-SBT) method in 104 unrelated Han individuals in Meizhou of Guangdong, southern China. Twenty-three HLA-A, 43 HLA-B and 27 HLA-C alleles were identified and allele frequencies and two-locus (C/B) and three-locus (A/C/B) haplotypes were statistically analysed. The most frequent HLA-A allele is A*110101 with a frequency of 30.3%, followed by A*24020101 (22.2%) and A*2420 (11.6%). Among the 43 detected HLA-B alleles, B*5801 (17.0%), B*400101 (15.5%) and B*4601 (10.0%) were frequently observed. Among the 27 detected C alleles, the most predominant one is Cw*07020101 (25.8%), followed by Cw*0717 (14.7%). The most frequent HLA-C/B two-locus haplotype is Cw*07020101/B*400101 (10.1%). The most common HLA-A/C/B three-locus haplotype in Meizhou Han is A*110101/Cw*07020101/B*400101 (3.4%). Phylogenetic tree based on HLA class I allele frequencies genetically suggested that Meizhou Han has an affinity to southern Asian populations. The result may also reflect an admixture of Han and ethnic minorities of southern China.     

HLA class I (A, B, C) and class II (DRB1, DQA1, DQB1, DPB1) alleles and haplotypes in the Han from southern China

In this study, polymerase chain reaction-sequence-specific oligonucleotide prode (SSOP) typing results for the human leukocyte antigen (HLA) class I (A, B, and C) and class II (DRB1, DQA1, DQB1, and DPB1) loci in 264 individuals of the Han ethnic group from the Canton region of southern China are presented. The data are examined at the allele, genotype, and haplotype level. Common alleles at each of the loci are in keeping with those observed in similar populations, while the high-resolution typing methods used give additional details about allele frequency distributions not shown in previous studies. Twenty distinct alleles are seen at HLA-A in this population. The locus is dominated by the A*1101 allele, which is found here at a frequency of 0.266. The next three most common alleles, A*2402, A*3303, and A*0203, are each seen at frequencies of greater than 10%, and together, these four alleles account for roughly two-thirds of the total for HLA-A in this population. Fifty alleles are observed for HLA-B, 21 of which are singleton copies. The most common HLA-B alleles are B*4001 (f= 0.144), B*4601 (f= 0.119), B*5801 (f= 0.089), B*1301 (f= 0.068), B*1502 (f= 0.073), and B*3802 (f= 0.070). At the HLA-C locus, there are a total of 20 alleles. Four alleles (Cw*0702, Cw*0102, Cw*0801, and Cw*0304) are found at frequencies of greater than 10%, and together, these alleles comprise over 60% of the total. Overall, the class II loci are somewhat less diverse than class I. Twenty-eight distinct alleles are seen at DRB1, and the most common three, DRB1*0901, *1202, and *1501, are each seen at frequencies of greater than 10%. The DR4 lineage also shows extensive expansion in this population, with seven subtypes, representing one quarter of the diversity at this locus. Eight alleles are observed at DQA1; DQA1*0301 and 0102 are the most common alleles, with frequencies over 20%. The DQB1 locus is dominated by four alleles of the 03 lineage, which make up nearly half of the total. The two most common DQB1 alleles in this population are DQB1*0301 (f= 0.242) and DQB1*0303 (f= 0.15). Eighteen alleles are observed at DPB1; DPB1*0501 is the most common allele, with a frequency of 37%. The class I allele frequency distributions, expressed in terms of Watterson's (homozygosity) F-statistic, are all within expectations under neutrality, while there is evidence for balancing selection at DRB1, DQA1, and DQB1. Departures from Hardy-Weinberg expectations are observed for HLA-C and DRB1 in this population. Strong individual haplotypic associations are seen for all pairs of loci, and many of these occur at frequencies greater than 5%. In the class I region, several examples of HLA-B and -C loci in complete or near complete linkage disequilibrium (LD) are present, and the two most common, B*4601-Cw*0102 and B*5801-Cw*0302 account for more than 20% of the B-C haplotypes. Similarly, at class II, nearly all of the most common DR-DQ haplotypes are in nearly complete LD. The most common DRB1-DQB1 haplotypes are DRB1*0901-DQB1*0303 (f= 0.144) and DRB1*1202-DQB1*0301 (f= 0.131). The most common four locus class I and class II combined haplotypes are A*3303-B*5801-DRB1*0301-DPB1*0401 (f= 0.028) and A*0207-B*4601-DRB1*0901-DPB1*0501 (f= 0.026). The presentation of complete DNA typing for the class I loci and haplotype analysis in a large sample such as this can provide insights into the population history of the region and give useful data for HLA matching in transplantation and disease association studies in the Chinese population.     

Allelic and haplotypic diversity of HLA-A, -B, -C, -DRB1, and -DQB1 genes in the Korean population

High-resolution human leukocyte antigen (HLA) typing exposes the unique patterns of HLA allele and haplotype frequencies in each population. In this study, HLA-A, -B, -C, -DRB1, and -DQB1 genotypes were analyzed in 485 apparently unrelated healthy Korean individuals. A total of 20 HLA-A, 43 HLA-B, 21 HLA-C, 31 HLA-DRB1, and 14 HLA-DQB1 alleles were identified. Eleven alleles (A*0201, A*1101, A*2402, A*3303, B*1501, Cw*0102, Cw*0302, Cw*0303, DQB1*0301, DQB1*0302, and DQB1*0303) were found in more than 10% of the population. In each serologic group, a maximum of three alleles were found with several exceptions (A2, B62, DR4, DR14, and DQ6). In each serologic group exhibiting multiple alleles, two major alleles were present at 62-96% (i.e. A*0201 and A*0206 comprise 85% of A2-positive alleles). Multiple-locus haplotypes estimated by the maximum likelihood method revealed 51 A-C, 43 C-B, 52 B-DRB1, 34 DRB1-DQB1, 48 A-C-B, 42 C-B-DRB1, 46 B-DRB1-DQB1, and 30 A-C-B-DRB1-DQB1 haplotypes with frequencies of more than 0.5%. In spite of their high polymorphism in B and DRB1, identification of relatively small numbers of two-locus (B-C and DRB1-DQB1) haplotypes suggested strong associations of those two loci, respectively. Five-locus haplotypes defined by high-resolution DNA typing correlated well with previously identified serology-based haplotypes in the population. The five most frequent haplotypes were: A*3303-Cw*1403-B*4403-DRB1*1302-DQB1*0604 (4.2%), A*3303-Cw*0701/6-B*4403-DRB1*0701-DQB1*0201/2 (3.0%), A*3303-Cw*0302-B*5801-DRB1*1302-DQB1*0609 (3.0%), A*2402-Cw*0702-B*0702-DRB1*0101-DQB1*0501 (2.9%), and A*3001-Cw*0602-B*1302-DRB1*0701-DQB1*0201/2 (2.7%). Several sets of allele level haplotypes that could not be discriminated by routine HLA-A, -B, and -DRB1 low-resolution typing originated from allelic diversity of A2, B61, DR4, and DR8 serologic groups. Information obtained in this study will be useful for medical and forensic applications as well as in anthropology.     

Polymorphism of intron 4 in HLA-A, -B and -C genes

The sequence database of HLA class I genes focuses on the coding sequences, the exons. Limited information is available on the non-coding sequences of the different class I alleles. In this study we have determined the intron 4 nucleotide sequence of at least one representative of each major allelic group of HLA-A, -B and -C. The intron 4 sequences were determined for 27 HLA-A, 81 HLA-B and 30 HLA-C alleles by allele-specific sequencing, using primers located in adjacent exons and introns. The sequences revealed that the length of intron 4 varies with a minimum of 93 and a maximum of 124 nucleotides as a result of insertions and deletions. There were remarkable similarities and differences within HLA-A, -B and -C, as well as between them. Within HLA-A, a deletion of three nucleotides was detected in several HLA-A alleles. The HLA-B alleles could be divided into two groups with one group having a deletion of 11 nucleotides compared with the second group. Within HLA-C, all Cw*07 alleles showed remarkable differences with the other Cw alleles. Cw*07 had an insertion of three nucleotides, shared only by the Cw*17 group. Moreover, Cw*07 was found to have an aberrant nucleotide sequence. Differences between HLA-A, -B and -C alleles were also observed. Remarkable was the deletion of 20 nucleotides in all HLA-A and -B alleles compared with HLA-C, whereas the HLA-A alleles showed an insertion of one nucleotide and a deletion of three nucleotides compared with HLA-B and -C. Furthermore, 32 different polymorphic positions were detected between HLA-A, -B and -C.     

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.     

Diversity of HLA-B61 alleles and haplotypes in East Asians and Spanish Gypsies

Abstract: The distribution of HLA-B61 alleles and their association with HLA-C and DRB1 alleles were investigated in six East Asian populations (South Korean, Chinese Korean, Man (Manchu), Northern Han, Mongolian and Buryat) and Spanish Gypsies and compared to our previous report on the Japanese population. The alleles were identified using a group-specific polymerase chain reaction (PCR) and genomic DNA followed by hybridization with sequence-specific oligonucleotide probes (SSOP)- Both HLA-B*4002 and B*4006 were commonly detected in the South Korean, Chinese Korean, Man, Northern Han and Japanese populations, while HLA-B*4002 was predominant in the Mongolian and Buryat populations. Strong associations of B*4002 with Cw*0304 and of B*4006 with Cw*0801 were commonly observed in these East Asian populations. In contrast, in Spanish Gypsies, only HLA-B*4006 was found and the allele exhibited a strong association with Cw*1502. HLA-B*4003 was also identified in the South Korean, Chinese Korean, Northern Han, Mongolian and Japanese populations at relatively low frequencies, and exhibited an association with Cw*0304. Moreover, the association of these B61 alleles with the DRB1 alleles revealed considerable diversity among the different populations. HLA-B*4004 and B*4009 were not observed in these populations. Consequently, the frequencies of the B61 alleles varied among the different East Asian populations, but the individual B61 alleles were carried by specific haplotypes often regardless of the ethnic differences.     

Human leukocyte antigen-A, -B, and -Cw polymorphism in a Berber population from North Morocco using sequence-based typing

Class I human leukocyte antigen (HLA) polymorphism was examined in a Berber population from North Morocco, named Metalsa (ME). All data were obtained at high-resolution level, using sequence-based typing. The most frequent alleles were: HLA-A*0201 and A*0101; HLA-B*44 (B*4403 and B*4402); B*0801 and the B*50 allele group (B*5001 and B*5002); HLA-Cw*0602; and Cw*07 group (Cw*070101, Cw*070102, Cw*0702, Cw*0704, and Cw*0706), and Cw*040101. The novel HLA-B*570302 allele was identified. It differs at position 486 and position 855 from B*570301, resulting in synonymous Thr and Val. The analysis also evidenced some alleles common in Africans (A*3402, A*6802, A*7401, B*1503, B*4102, B*4202, B*7801, B*5802, Cw*1701, and Cw*1703) and some uncommon alleles (A*3004, B*2702, B*2703, B*5001,02, B*3503, and Cw*0706). The predominant HLA-A-Cw-B-DRB1-extended haplotypes in ME population were A*0101-Cw*0501-B*4402-DRB1*0402, A*240201-Cw*0701-B*0801-DRB1*030101, A*2301-Cw*040101-B*4403-DRB1*040501, A*0201-Cw*040101-B*4403-DRB1*1302, and A*3002-Cw*0602-B*5002-DRB1*0406. This study demonstrates a strong relatedness of ME to other Moroccan and North African populations, some characteristics of sub-Saharan Africans and evidenced the influence of various immigrations during centuries. Nevertheless, this study highlights some unique genetic traits of the ME population compared to other ethnic groups within Morocco, which could be of great interest for clinical aims, transplantation, and diseases.     

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 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.     

Differentiation between African populations is evidenced by the diversity of alleles and haplotypes of HLA class I loci

The allelic and haplotypic diversity of the HLA-A, HLA-B, and HLA-C loci was investigated in 852 subjects from five sub-Saharan populations from Kenya (Nandi and Luo), Mali (Dogon), Uganda, and Zambia. Distributions of genotypes at all loci and in all populations fit Hardy-Weinberg equilibrium expectations. There was not a single allele predominant at any of the loci in these populations, with the exception of A*3002 [allele frequency (AF) = 0.233] in Zambians and Cw*1601 (AF = 0.283) in Malians. This distribution was consistent with balancing selection for all class I loci in all populations, which was evidenced by the homozygosity F statistic that was less than that expected under neutrality. Only in the A locus in Zambians and the C locus in Malians, the AF distribution was very close to neutrality expectations. There were six instances in which there were significant deviations of allele distributions from neutrality in the direction of balancing selection. All allelic lineages from each of the class I loci were found in all the African populations. Several alleles of these loci have intermediate frequencies (AF = 0.020-0.150) and seem to appear only in the African populations. Most of these alleles are widely distributed in the African continent and their origin may predate the separation of linguistic groups. In contrast to native American and other populations, the African populations do not seem to show extensive allelic diversification within lineages, with the exception of the groups of alleles A*02, A*30, B*57, and B*58. The alleles of human leukocyte antigen (HLA)-B are in strong linkage disequilibrium (LD) with alleles of the C locus, and the sets of B/C haplotypes are found in several populations. The associations between A alleles with C-blocks are weaker, and only a few A/B/C haplotypes (A*0201-B*4501-Cw*1601; A*2301-B*1503-Cw*0202; A*7401-B* 1503-Cw*0202; A*2902-B*4201-Cw*1701; A*3001-B*4201-Cw*1701; and A*3601-B*5301-Cw*0401) are found in multiple populations with intermediate frequencies [haplotype frequency (HF) = 0.010-0.100]. The strength of the LD associations between alleles of HLA-A and HLA-B loci and those of HLA-B and HLA-C loci was on average of the same or higher magnitude as those observed in other non-African populations for the same pairs of loci. Comparison of the genetic distances measured by the distribution of alleles at the HLA class I loci in the sub-Saharan populations included in this and other studies indicate that the Luo population from western Kenya has the closest distance with virtually all sub-Saharan population so far studied for HLA-A, a finding consistent with the putative origin of modern humans in East Africa. In all African populations, the genetic distances between each other are greater than those observed between European populations. The remarkable current allelic and haplotypic diversity in the HLA system as well as their variable distribution in different sub-Saharan populations is probably the result of evolutionary forces and environments that have acted on each individual population or in their ancestors. In this regard, the genetic diversity of the HLA system in African populations poses practical challenges for the design of T-cell vaccines and for the transplantation medical community to find HLA-matched unrelated donors for patients in need of an allogeneic transplant.     

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.     

Molecular diversity of the HLA-C gene identified in a caucasian population

A DNA typing procedure, based on a two stage polymerase chain reaction-sequence-specific oligonucleotide probe (PCR-SSOP) typing strategy, has been developed and applied to DNA from 1000 healthy individuals from the Northern Ireland region. The two-stage procedure involves human leukocyte antigen (HLA-C) identification through the use of a medium resolution PCR-SSOP system, followed by four secondary group specific PCR-SSOP systems, to enable allele resolution. The PCR-SSOP systems were designed for the identification of HLA-Cw alleles with possible discrimination within exons 2 and 3 of the HLA-C gene, i.e., HLA-Cw*01-Cw*16. PCR-SSP tests were designed for the resolution of HLA-Cw*17 and -Cw*18 alleles. The systems can also be used independently of each other if selective allele resolution is required. HLA-Cw allele frequencies occurring within the Northern Ireland population have been compiled, along with estimations of HLA-B/Cw haplotype frequencies.     

Human leukocyte antigen-A, -B, and -DRB1 haplotypes of cord blood units in the Tzu Chi Taiwan Cord Blood Bank

Cord blood (CB) is considered an alternative resource to bone marrow and peripheral blood stem cells (PBSC) for allogeneic stem cell transplantation. In this study, human leukocyte antigen (HLA)-A, -B, and -DRB1 high-resolution allele types were analyzed from a total of 710 CB units in the Tzu Chi Taiwan Cord Blood Bank. We observed 21 HLA-A alleles, 59 HLA-B alleles, and 28 HLA-DRB1 alleles, whereas 19 unique alleles were present in the CB units of 2,023 individuals selected for confirmatory testing in the Tzu Chi Taiwan Marrow Donor Registry (TCTMDR). The allelic associations between the HLA-A and -B locus were stronger than that of either the HLA-B and -DRB1 loci or the HLA-A and -DRB1 loci. The most common haplotype of CB units in the general Taiwanese population was A*3303-B*5801-DRB1*0301 (6.59%), followed by A*0207-B*4601-DRB1*0901 (3.47%) and then A*1101-B*4001-DRB1*0901 (2.11%). Moreover, two haplotypes, A*2402-B*5201-DRB1*1502 and A*0201-B*1301-DRB1*1202, existed uniquely in the CB units but were not observed in the data of TCTMDR. Although the number of CB units studied for high-resolution of HLA typing in the current study is small, we believe our data should provide useful information to increase the chances of obtaining acceptable HLA-A-, -B-, and -DRB1-matched CB units for patients.     

A high-resolution genotyping method for HLA-C alleles and possible shared HLA-C-B haplotypes between Japanese and Caucasians

A genotyping system for HLA-Cw alleles using methods of PCR-single-strand conformation polymorphism (SSCP) and PCR-sequence-specific primers (SSP) was developed. Genomic DNA from 167 random healthy Japanese individuals were investigated to determine HLA-C allele frequencies and their associations with HLA-A and -B loci. Nine alleles were frequently detected: Cw*0102 (18.3%), Cw*0304 (12.0%), Cw*1202 (11.4%), CW*0303 (10.5%), Cw*1403 (10.5%), Cw*0801 (10.2%), Cw*0702 (9.0%), Cw*1402 (6.0%) and Cw*0401 (5.1%). Several HLA-C-B haplotypes such as Cw*0303-B62, Cw*0304-B60, Cw*0501-B44, Cw*0602-B13, Cw*0602-B37, Cw*0702-B7, CW*1202-B52, Cw*1402-B51 and Cw*1502-B51 were found to be shared by Japanese and Caucasians. With the PCR-SSCP method we could detect differences in each exon of HLA-C alleles, at a low cost and simply. This method is suitable for sequence-level matching with a relatively small number of samples.     

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.