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  3. 10.4274/balkanmedj.galenos.2023.2023-4-55
HLA Alleles, Genotype and Haplotype Analyzes from Central Anatolia Region of Turkey
Emel Yantır1, Eren Gündüz2, Ertuğrul Çolak3
1Department of Immunology, Eskişehir Osmangazi University Faculty of Medicine, Eskişehir, Turkey
2Department of Internal Medicine, Division of Hematology, Eskişehir Osmangazi University Faculty of Medicine, Eskişehir, Turkey
3Department of Biostatistics, Eskişehir Osmangazi University Faculty of Medicine, Eskişehir, Turkey
DOI : 10.4274/balkanmedj.galenos.2023.2023-4-55
Pages : 358-366

Abstract

Background: Although human leukocyte antigen (HLA) data for the Turkish population has been reported, there are no statistics on the HLA-DPB1 locus, which has recently received significant attention, particularly in hematopoietic stem cell transplantation. In addition, there is no study that has reported the 2-6 loci HLA haplotype distribution, 8-digit HLA allele frequency, and genotype frequency in the Turkish population.
Aims: To evaluate the low and high resolution (2-4-8 digits) HLA-A, -B, -C, -DRB1, -DQB1, -DPB1 allele data using the data of 6100 healthy individuals from the Central Anatolian region of Turkey.
Study Design: Retrospective cross-sectional study.
Methods: All tests were performed using molecular HLA techniques: low-resolution DNA-based sequence-specific oligonucleotides, low/high-resolution DNA-based sequence-specific primer, and high-resolution next generation sequencing. A total of 6100 healthy donors with a minimum of 3 loci (HLA-A, -B, -DRB1) were analyzed for their HLA-A, -B, -C, -DRB1, -DQB1, and -DPB1 data. Pypop and HLA-net GENE[RATE] were used to analyze the data.
Results: Among the HLA class I alleles, the following were the most frequently observed alleles: for HLA-A, A*02, A*24, A*03, and A*01; for HLA-B, B*35, B*51, and B*44; and for HLA-C, C*07, C*04, and C*12. Among the HLA class II alleles, the following alelles were the most frequently observed: for HLA-DRB1, DRB1*11, DRB1*04, and DRB1*13; for HLA-DQB1, DQB1*03, DQB1*05, and DQB1*06; and for HLA- DPB1, DPB1*04, DPB1*02, and DPB1*03. The most common alleles among HLA-DPB1 in the 4-digit evaluation were DPB1*04:01, DPB1*02:01, and DPB1*04:02. Among the HLA classes I and II, the following were the most frequently observed 8-digit alleles in HLA-A, -B, -C, -DRB1, -DQB1 and -DPB1 were A*02:01:01:01, B*49:01:01:01, C*04:01:01:06, DRB1*07:01:01:01, DQB1*03:01:01:02, and DPB1*02:01:02:05, respectively. The most common 6 loci haplotype was A*02~B*35~C*04~DRB1*11~DQB1*03~DPB1*04 (2.71%).
Conclusion: In this study, low and high resolution HLA-DPB1 allele frequency, 6 locus haplotype frequency and genotype frequency were reported for the first time in Turkish population. These new data can be used to map HLA in our country and may provide ideas for potential future studies.

INTRODUCTION

The human leukocyte antigen (HLA) system has the most polymorphic structure. Currently, a total of 35,821 HLA alleles (Class I, n = 25,228; Class II, n = 10,592) are listed in the IMGT/HLA database (version 3.50 version; http://hla.alleles.org/nomenclature/stats.html). Historically, HLA-A, -B, -C, -DRB1 and -DQB1 loci have been studied before transplantation. Recently, studies have established the importance of HLA-DPB1 in hematopoietic stem cell transplantation (HSCT), especially in the selection of unrelated donors.1

Previously, typing of HLA genes was determined using 2-digit low-resolution (LR) molecular techniques. Nowadays, with the diversification of molecular methods and widespread use of next generation sequence (NGS) systems, high resolution (HR) 8-digit HLA data can be evaluated, especially before HSCT. With these advancements, it has become important to examine the HLA polymorphism in more detail. The number of studies reporting the 8-digit HLA gene distribution of populations is gradually increasing.

A literature review revealed that studies from our country2-10 or involving the Turkish population11 have described the distribution of HLA -A, -B, -C, -DRB1 and -DQB1 alleles and haplotypes. Our study is the first detailed HLA data analysis report from Turkey regarding LR and HR HLA-DPB1 allele frequency, genotype frequency, HR (4- or 8-digit) 6 loci alleles frequency, and 2-6 loci A:B:C:DRB1:DQB1:DPB1 haplotype frequencies in healthy individuals.

MATERIALS AND METHODS

Population

The data of 6100 healthy bone marrow or solid organ donors who underwent HLA typing at Eskişehir Osmangazi University Tissue Typing Laboratory between 2001 and 2021 were evaluated retrospectively. A total of 6 loci data, including HLA-A, -B, -C, -DRB1, -DQB1 and -DPB1, were assessed in all donors with at least 3 loci (HLA-A, -B, -DRB1) data. In the first step, 2-digit molecular laboratory data from HLA-A, -B, -DRB1 6100, HLA -C 1841, HLA-DQB1 615 and HLA-DPB1 546 donors were evaluated. In the second step, 75 donors within the same group with HR 8-digit HLA data were evaluated. Our study population included 46.7% female and 53.3% male participants; there was no significant sex difference (p > 0.05). The mean age of the participants was 40.53 ± 16.81 years.

The study was conducted in accordance with the principles of the Declaration of Helsinki and was approved by the local ethics committee (no: 2021-18).

HLA Class I and Class II typing

The LR 2-digit HLA typing was studied using DNA-based sequence-specific oligonucleotides (PCR-SSO) and DNA-based sequence-specific primers (PCR-SSP) as previously described.12 The 4-digit alleles of each individual were typed using PCR-SSP and/or NGS with an HLA typing kit (MIA FORA NGS FLEX; Bio Array Solution Ltd., New Jersey, USA), and the 8-digit alleles were typed using NGS. The sequenced data were analyzed using MIA FORA NGS FLEX HLA Genotyping Software (version 3.0;). The IMGT/HLA database (version 3.43.0) was used as a reference. All HLA data before 2010 were evaluated after renaming them according to the current nomenclature (https://www.ebi.ac.uk).

Statistical analysis

All HLA data were validated before statistical analysis and analyzed using both GENE[RATE]13 (https://hla-net.eu/tools/) and PyPop (version 0.7.0;).14 Linkage disequilibrium (LD) was calculated in PyPop for each loci pair. One thousand permutations were used to test for significance, and the LD was measured as Wn, D, D’ and p values, a multiallelic extension of the correlation measure. 6 loci were tested for Slatkin’s implementation of the Ewens-Watterson homozygosity test of neutrality, Hardy-Weinberg Equilibrium (HWE) proportions, and common heterozygotes by allele. The common genotypes were assessed using chi-square test implemented in Pypop and GENE[RATE]. SPSS (version 25) was used to analyze the demographic data.

RESULTS

HLA allele frequencies

The HLA results of 6100 donors were first evaluated using the 2-digit LR data. A total of 21 HLA-A, 41 HLA-B, 16 HLA-C, 14 HLA-DRB1, 5 HLA-DQB1, and 34 HLA-DPB1 alleles were identified. Table 1 shows the allele frequency for the 6 loci.

Among the Class I HLA the most frequently encountered alleles in HLA-A were A*02, A*24, A*03, and A*01; in HLA-B were B*35, B*51, and B*44; and in HLA-C were C*07, C*04, and C*12. Among the Class II HLA the most frequently encountered alleles in HLA-DRB1 were DRB1*11, DRB1*04, and DRB1*13; in HLA-DQB1 were DQB1*03, DQB1*05, and DQB1*06; and in HLA-DPB1 were DPB1*04, DPB1*02, and DPB1*03. A total of 36 HLA-DPB1 alleles were identified in the evaluation of 396 donors with HR 4-digit HLA-DPB1 data. The most common alleles encountered were DPB1*04:01, DPB1*02:01 and HLA-DPB1*04:02 (Supplementary File 1).

In the second phase of our study, evaluation of the 8-digit HLA data of 75 donors in the group revealed 31 HLA-A, 50 HLA-B, 35 HLA-C, 38 HLA-DRB1, 30 HLA-DQB1 and 18 HLA-DPB1 alleles. The most frequently encountered 8-digit alleles in HLA-A were A*02:01:01:01, A*24:02:01:01, and A*01:01:01:01; in HLA-B were B*49:01:01:01, B*35:01:01:02, and B*51:01:01:01; in HLA-C were C*04:01:01:06, C*06:02:01:01, and C*07:01:01:01; in HLA-DRB1 were DRB1*07:01:01:01, DRB1*11:04:01:01, and DRB1*03:01:01:01; in HLA-DQB1 were DQB1*03:01:01:02, DQB1*02:02:01:01, and DQB1*02:01:01:01; and in HLA-DPB1 were DPB1*02:01:02:05, DPB1*04:01:01:06, and DPB1*04:02:01:02. The subgroups of the most frequently observed HLA alleles are summarized in Table 2; the full list is provided in Supplementary File 2.

Haplotype frequencies

Haplotype frequencies were evaluated at 2-6 loci using both Pypop and GENE[RATE]. We identified 2318 A*~B*~C*, 480 DRB1*~DQB1*~DPB1*, 9180 A*~B*~C*~DRB1*, 6,687 A*~B*~C*~DRB1*~DQB1*, and 10987 A*~B*~C*~DRB1*~DQB1*~DPB1* haplotypes. When calculating the 2-digit HLA haplotype data, due to the limitation of not being able to calculate > 5,000 haplotypes using PyPop, A*~B*, A*~DRB1*, B*~DRB1* and A*~B*~DRB1* haplotypes were calculated using GENE[RATE] alone; the other haplotypes were calculated using both programs. The most commonly observed haplotypes are summarized in Tables 3, 4, 5, and the full list is provided in Supplementary File 3.

Genotype analysis

The genotypes were the most frequently encountered in HLA-A were A*02:02 and A*02:24; in HLA-B were B *35:51 and B*35:35; in HLA-C were C*04:07 and C*07:07; in HLA-DRB1 were DRB1*04:11 and DRB1*11:11; in HLA-DQB1 were DQB1* 03:03 and DQB1*03:05; and in HLA-DPB1 were DPB1*04:04 and DPB1*02:04 (Table 6). A complete list of the observed genotypes is provided in Supplementary File 4.

Test for neutrality and HWE analysis

The heterozygosity of the most frequently observed alleles is shown in Table 7. The complete list of the heterozygosity assessment is provided in Supplementary File 5.

The result for the Slatskin’s implementation of Ewens-Watterson homozygosity test of neutrality are given in Suplementary File 6 Table S1. The result showed negative and significant Fnd values for all loci 2-digit HLA data expected DPB1 locus. This indicates homozygosity, which is suggestive of a balanced selection at these loci.

There was no detectable deviation of the HWE proportion for heterozygosity in all loci, except at HLA-A and HLA-C (Supplementary File 6 Table S2).

The haplotype/LD statistics used in the multilocus analysis are listed in Supplementary File 6 Table S3-S4. Pairwise LD measured by Log-likelihood under linkage equilibrium [ln(L_0)], Log-likelihood obtained via the EM algorithm [ln(L_1)], Hedrick’s D′ and Cramer’s V Statistics (Wn) were significant (p < 0.05) for all loci, except for the A:DQB1 loci pairs.

DISCUSSION

Our study is the first report from Turkey that has evaluated the haplotype frequency of 6 loci A*~B*~C*~DRB1*~DQB1*~DPB1*, genotype frequency, and frequency distribution of the HR 8-digit HLA-A, -B, -C, -DRB1,-DQB1 and -DPB1 alleles. Our study has included the highest number of healthy cases in Turkey till date. Since our results were obtained healthy donors from Central Anatolia and surrounding provinces, it was understood that our study results would not reflect that of the entire population of Turkey. The allele and some haplotype frequencies of our study were similar to those of most previous studies conducted in our country.3-10 A comparison of the 8-digit HLA data frequency could not be conducted due to the lack of previous studies reporting the same in our nation.

In our study, the frequency of six alleles was > 5% at the A locus. The most common 2-digit alleles were A*02, A*24, and A*03. The most common 4-digit alleles were A*02:01, A*24:02, and A*01:01, and the most common 8-digit alleles were A*02:01:01:01, A*24:02:01:01 and A*01:01:01:01. The A*02 was the most frequently identified allele, which is consistent with the findings of previous studies.3-10 The A*24 allele was the second most frequently observed allele. This was finding was consistent with those of most previous studies, except those of the study conducted by Pala et al.7 in the Thracian population. Six A*02 allele subtypes were observed for 4-digit alleles; A*02:01 was the most common subtype. Nine A*02 allele subtypes were observed in the 8-digit alleles; A*02:01:01:01 was the most common subtype. Our study findings are similar to those of studies by Oguz et al.15 and Uyar et al.9 for the HLA-A alleles. Furthermore, Pingel et al.11 determined that A*02:01, A*24:02, and A*01:01g were often observed among Turkish donors at a German bone marrow bank; this finding was similar to that of our study finding.

The B locus was found to be the most polymorphic locus; only four allele frequencies were > 5%. In our study, the 2-digit B*35, B*51, and B*44 alleles, 4-digit B*51:01, B*35:01, and B*49:01 alleles, and 8-digit B*49:01:01:01, B*35:01:01:02, and B*51:01:01:01 were the most frequently observed. Four B*35 allele subtypess were observed among the 4-digit alleles; B*35:01 was the most common. Eight B*35 allele subtypes were observed among the 8-digit alleles; B*35:01:01:02 was the most common. B*35 has been previously reported as the most frequently observed allele.3-10 In the study by Pingel et al.,11 the most frequently observed 2-digit alleles were B*35, B*51, and B*44 and 4-digit alleles were B*51:01, B*35:01, and B*18:01; these results are similar to those of our study.

In the C locus, the frequency of five alleles was > 5%. In our study, the 2-digit C*07, C*04, and C*12 alleles, 4-digit C*07:01, C*04:01, C*06:02, and C*12:03 alleles, and 8-digit C*04:01:01:06, C*06:02:01:01, and C*07:01:01:01 alleles were the most common alleles observed. Three C*07 allele subtypes were observed among the 4-digit alleles; C*07:01 was the most common subtype. Eight C*07 allele subtypes were observed among the 8-digit alleles; C*07:01:01:01 was the most common subtype. In two studies conducted in our country,3,5 C*04 was the most common allele; in two other studies.9,4 C*07 was the most common. Oguz et al.15 determined that the top three alleles were C*04:01, C*07:01, and C*12:03.9 The most frequently observed alleles in the study by Pingel et al.11 were the 2-digit C*07, C*04, and C*12 alleles and 4-digit C*04:01, C*07:01, and C*12:03 alleles.

At the DRB1 locus, eight allele frequencies were > 5%. The DRB1*11 allele was the most frequently observed allele, which is consistent with the findings of previous studies.3-10 In our study, the 2-digit DRB1*11, DRB1*04, and DRB1*13 alleles, 4-digit DRB1*11:04, DRB1*07:01g, DRB1*03:01, and DRB1*15:01 alleles, and 8-digit DRB1*07:01:01:01, DRB1*11:04:01:01, and DRB1*03:01:01:01 alleles were the most common alleles detected. Three DRB1*11 allele subtypes were observed among the 4-digit allele; DRB1*11:04 was the most common. Five DRB1*11 allele subtype were observed among the 8-digit alleles; DRB1*11:04:01:01 was the most common. DRB1*11:01/12 was the most frequently observed allele in one study2 from our country; in another study it was DRB1*07:01.15 Similar to our study findings, Pingel et al.11 determined that DRB1*11, DRB1*04, and DRB1*13 were the most frequently observed 2-digit alleles, while DRB1*11:04, DRB1*07:01, and DRB1*11:01g were the most frequently observed 4-digit alleles.

The DQB1 locus had the least polymorphism. There were five different alleles, of which four had frequencies > 5%. The DQB1*03 allele was the most common allele identified, which is similar to the findings of previous studies.2-5 In our study, the 2-digit DQB1*03, DRB1*05, and DQB1*06 alleles, 4-digit DQB1*03:01, DQB1*05:01, and DQB1*02:02 alleles, and 8-digit DQB1*03:01:01:02, DQB1*02:02:01:01, and DQB1*02:01:01:01 were the most frequently encountered alleles. There were five DQB1*03 subtypes among the 4-digit alleles; DQB1*03:01 was the most prevalent. There were 11 DQB1*03 subtypes among the 8-digit alleles; DQB1*03:01:01:02 was the most common. Saruhan-Direskeneli et al.2 and Oguz et al.15 also reported that DQB1*03:01 as the most frequently observed allele in our country. Similar to our study findings, Pingel et al.11 also determined the 2-digit DQB1*03, DQB1*05, and DQB1*06 alleles and 4-digit DQB1*03:01, DQB1*02:01, and DQB1*03:02 alleles were the most frequently observed alleles.

Our study is the first to report HLA-DPB1 locus information in the Turkish population.

After HLA-B, HLA-DPB1 had the most polymorphic structure, with 34 different alleles detected in our LR group study. Moreover, only three alleles had frequencies > 5%. DPB1*04 (AF = 0.55037) was the most prevalent, followed by DPB1*02 (AF = 0.1859) and DPB1*03 (AF = 0.087). Among the 4-digit DPB1*04 alleles, DPB1*04:01, DPB1*02:01, and DPB1*04:02 were the most frequently observed alleles. Among the 8-digit DPB1*04 alleles, DPB1*04:01:01:06 and DPB1*02:01:02:05, followed by DPB1*04:01:01:05 and DPB1*04:02:01:02 were the most frequently observed alleles. In a study conducted in patients with granulomatosis in Turkey,16 the DPB1*04:01 ratio was 36% higher in the healthy control group than in the disease group, when compared to other alleles. According to the Allele Frequency Net Database (AFND; http://www.allelefrequencies.net/) literature, the most frequently reported DPB1 allele from other countries are as follows: DPB1*02:01:02 (AF = 0.1176-0.6000) and DPB1*04:01 (AF = 0.1078-0.4200) in some regions of Russia; DPB1*04 (AF = 0.560) and DPB1*04:01:01G (AF = 0.445) in Norway;17 DPB1*04:01 (30%–50%) in Europe and beyond;18 DPB1*04:01 (AF = 0.4342) in the UK;19 DPB1*04:01:01 (AF = 0.351851) in Saudi Arabia;20 DPB1*01:01:01 (AF = 0.260) in Guadeloupe;21 DPB1*05:01 (AF = 0.360)22 and 41.87%23 in China; DPB1*05:01:01 (34.1%) in South Korea;24 DPB1*05:01 (AF = 0.4530) in Australia; and DPB1*13:01 in Thailand.25

Our study group data were compatible with those of populations in Europe and its surrounding region, as well as some populations in neighborhoods of Saudi Arabia and Russia.

To clearly analyze the haplotypes, statistical analyses need to be conducted after the haplotypes inherited from both the mother and father have been determined precisely by an HR family study. However, because these analyses are limited by cost and accessibility, haplotype analysis is performed in population genetics analyses using certain programs, and it is commonly used to compare populations. Both of these population genetics programs were used in our study, and the calculations were performed separately using each program. The data from both programs were similar.

Several differences were identified in the top three alleles detected in our study and in previous studies. Among the A*~B* haplotypes, the 02~51 ranked first in our study; in other studies from different regions it was ranked second,10 third,9 or fourth.8 Among the B*~C* haplotypes, the 35~04 ranked first, which is similar to the finding of another study.9 The most common A*~DRB1* and B*~DRB1* haplotypes in our study were 24~11 and 35~11, respectively; this differed from the findings of a study conducted in a popluation located near the Black Sea.10 In our study, the 11~03 was the most common DRB1*~DQB1* haplotype, which was similar to the finding in another study.2 Our study is the first to report the haplotype frequencies for A*~C*, A*~DQB1*, A*~DPB1, B*~DQB1, B*~DPB1, C*~DRB1*, C*~DQB1*, C*~DPB1*, and DQB1*~DPB1*.

The 24~35~04 was the most frequently identified A*~B*~C* haplotype, which was similar to the finding of another study carried out in our country.9 The 24~35~11 was most the frequently identified A*~B*~DRB1* haplotype, which has been previously reported.4,8 However, this finding differed from the finding conducted in the Black Sea region.10 The most common DRB1*~DQB1*~DPB1* haplotype in our study was 11~03~04, which has never been reported in our country or the Turkish population.

The most common 4 loci A*~B*~C*~DRB1* and 5 loci A*~B*~C*~DRB1*~DQB1* haplotypes in our study were 02~35~04~11 and 02~35~04~11~03, respectively; these findings are similar to those of previous studies.4,11

The most common 6 loci A*~B*~C*~DRB1*~DQB1*~DPB1* haplotypes were 02~35~04~11~03~04 (HF = 0.02711), followed by 23~49~07~11~03~04 (HF = 0.01389). 24~35~04~11~03~04 (HF = 0.01389) had twice the frequency of haplotypes. Our study is significant because it is the first to document the frequencies of 6 loci HLA haplotypes in Turkey. Analysis of AFND data of 6 loci A*~B*~C*~DRB1*~DQB1*~DPB1* haplotypes revealed that 02~35~04~11~03~04 (2.711%) was detected at different frequencies in Russia (0.113%), Germany (0.0462%), Norway (0.0100%), and Brazil (3.3891%). Furthermore, the haplotype 23~49~07~11~03~04 (1,389%) was determined to be the second most prevalent type in our study, and less so in Russia (0.1724%), Germany (0.0979%), and Norway (0.0400%).

A limitation of our study was that there were not enough participants with 8-digit HLA data to calculate the haplotype frequencies. Thus, the results might not adequately reflect the real haplotype frequency in the Turkish population. Future studies with more participants are required to analyze the 8-digit haplotype frequency. The 8-digit haplotypes identified in this study could offer guidance for future studies. According to 4-digit HLA data, the most common haplotypes for the 5 loci A*~B*~C*~DRB1*~DQB1* haplotype were 01:01~08:01~07:01~03:01~02:01 and 24:02~49:01~07:01~11:01~03:01 and that for the 6 loci A*~B*~C*~DRB1*~DQB1*~DPB1* haplotype was 01:01~35:02~06:02~11:04~03:01~04:01. Pingel et al.11 also reported that 01:01~08:01~07:01~03:01~02:01 was the most common 5 loci haplotype in a Turkish population.

The most frequently observed 5 loci A*~B*~C*~DRB1*~DQB1* haplotype and 6 loci A*~B*~C*~DRB1*~DQB1*~DPB1* haplotype were 01:01:01:01~08:01:01:01~07:01:01:01~03:01:01:01~02:01:01:01 and 01:01:01:01~35:02:01:01~03:04:01:02~11:04:01:01~03:03:02:02~04:01:01:06, respectively, according to the 8-digit HLA data analysis in our study.

Previous studies from our country have not reported the frequencies of HLA-A, -B, -C, -DRB1, -DQB1, and -DPB1 loci in 2-8-digit alleles, 2-6 loci haplotypes, and genotypes in our region’s healthy population using the data we evaluated. Polymorphism studies should be conducted with considerably larger populations and data from a broader geographical region. Although our study does not include the complete Turkish population, it can help map HLAs in our country and provided a basis for future studies.

Ethics Committee Approval: The study was conducted in accordance with the principles of the Declaration of Helsinki and was approved by the local ethics committee (no: 2021-18).

Data Sharing Statement: The data that support the findings of this study are available from the corresponding author upon reasonable request.

Authorship Contributions: Concept- E.Y., E.G., E.Ç.; Design- E.Y., E.G., E.Ç.; Analysis or Interpretation- E.Y., E.Ç.; Critical Review- E.Ç.

Conflict of Interest: No conflict of interest was declared by the authors.

Funding: The authors declared that this study received no financial support.

Supplementary File 1.

http://balkanmedicaljournal.org/uploads/pdf/supp-1.pdf

Supplementary File 2.

http://balkanmedicaljournal.org/uploads/pdf/sup-2.pdf

Supplementary File 3.

http://balkanmedicaljournal.org/uploads/pdf/SUPPLEMENT-3.xlsx

Supplementary File 4.

http://balkanmedicaljournal.org/uploads/pdf/sup-4.pdf

Supplementary File 5.

http://balkanmedicaljournal.org/uploads/pdf/sup-5.pdf

Supplementary File 6.

http://balkanmedicaljournal.org/uploads/pdf/sup-6.pdf

REFERENCES

  1. Fleischhauer K, Shaw BE. HLA-DP in unrelated hematopoietic cell transplantation revisited: challenges and opportunities. Blood. 2017;130:1089-1096.
  2. Saruhan-Direskeneli G, Uyar FA, Bakar S, Eraksoy M. Molecular analysis of HLA-DRB1, -DQA1 and -DQB1 polymorphism in Turkey. Tissue Antigens. 2000;55:171-174.
  3. Baştürk B, Kantaroğlu B, Kavuzlu M, Sarıtürk Ç. The Most Common HLA Alleles and Anti-HLA Antibodies to Know for Virtual Cross-Match. Exp Clin Transplant. 2016;14:53-55.
  4. Kaya Z, Gönen S, Çalışkan B, Kemer Z, Ünal AB, Değirmenci E. HLA Genotypes in Turkish Hematopoietic Cell Recipients and Likelihood of Finding a Matched Donor Through Family Searches. Exp Clin Transplant. 2019;17:813-818.
  5. Mete E. Study of HLA antigen distributions in samples sent in a tissue typing laboratory. Pam Med J. 2021;14:742-746.
  6. Balkan E, Yaşar E, Doğan H. The Diagnosis of Human Leukocyte Antigen Class I and Class II Allel in Eastern Anatoia Region. Van Med J. 2019;26:162-166.
  7. Pala FS, Tabakçıoğlu K, Algüneş Ç, Ömürlü İK. Evaluation of Frequencies of HLA-A, B and DR in Thracian Population and Examination of its Relationship With Balkan Populations. Trakya Univ Tıp Fak Derg. 2008;25:189-195.
  8. Kayhan B, Kurtoglu EL, Taskapan H, et al. HLA-A, -B, -DRB1 allele and haplotype frequencies and comparison with blood group antigens in dialysis patients in the East Anatolia region of Turkey. Transplant Proc. 2013;45:2123-2128.
  9. Uyar FA, Dorak MT, Saruhan-Direskeneli G. Human leukocyte antigen-A, -B and -C alleles and human leukocyte antigen haplotypes in Turkey: relationship to other populations. Tissue Antigens. 2004;64:180-187.
  10. Uçar F, Ovali E, Pakdemir A, et al. HLA alleles and haplotypes in the east Black Sea Turkish population. Transplant Proc. 2004;36:2610-2614.
  11. Pingel J, Solloch UV, Hofmann JA, Lange V, Ehninger G, Schmidt AH. High-resolution HLA haplotype frequencies of stem cell donors in Germany with foreign parentage: How can they be used to improve unrelated donor searches? Human Immunology. 2013;74:330-340.
  12. Sahin Tekin M, Yorulmaz G, Yantir E, Gunduz E, Colak E. A Novel Finding of an HLA Allele’s and a Haplotype’s Relationship with SARS-CoV-2 Vaccine-Associated Subacute Thyroiditis. Vaccines (Basel). 2022;10:1986.
  13. Sanchez-Mazas A, Vidan-Jeras B, Nunes JM, et al. Strategies to work with HLA data in human populations for histocompatibility, clinical transplantation, epidemiology and population genetics: HLA-NET methodological recommendations. Int J Immunogenet. 2012;39:459-472; quiz 473-476.
  14. Lancaster AK, Single RM, Solberg OD, Nelson MP, Thomson G. PyPop update--a software pipeline for large-scale multilocus population genomics. Tissue Antigens. 2007;69:192-197.
  15. Oguz FS, Oguz SR, Ogret Y, et al. Distribution of HLA epitope frequencies in Turkish population. Turkish Journal of Biochemistry. 2022;47:289-295.
  16. Ince B, Kamali S, Bektaş M, et al. A shared motif of hla-dpb1 affecting the susceptibility to pr3-anca positive granulomatosis with polyangiitis: comparative analysis of a Turkish cohort with matched healthy controls. Rheumatol Int. 2021;41:1667-1672.
  17. Lande A, Andersen I, Egeland T, Lie BA, Viken MK. HLA -A, -C, -B, -DRB1, -DQB1 and -DPB1 allele and haplotype frequencies in 4514 healthy Norwegians. Hum Immunol. 2018;79:527-529.
  18. Nunes JM, Buhler S, Roessli D, Sanchez-Mazas A. The HLA-net GENE[RATE] pipeline for effective HLA data analysis and its application to 145 population samples from Europe and neighbouring areas. Tissue Antigens. 2014;83:307-323.
  19. Lemin AJ, Foster L. HLA-DPB1 allele frequencies in the West Midlands region of the United Kingdom: A critical evaluation against the common, intermediate and well-documented allele catalogues CWD 2.0.0, EFI CWD and CIWD 3.0.0. HLA. 2021;98:5-13.
  20. Jawdat D, Uyar FA, Alaskar A, Müller CR, Hajeer A. HLA-A, -B, -C, -DRB1, -DQB1, and -DPB1 Allele and Haplotype Frequencies of 28,927 Saudi Stem Cell Donors Typed by Next-Generation Sequencing. Front Immunol. 2020;11:544768.
  21. Voorter CE, Groeneweg M, Joannis MO, Meertens C, Agis F, Tilanus MG. Allele and haplotype frequencies of HLA-DPA1 and -DPB1 in the population of Guadeloupe. Tissue Antigens. 2014;83:147-153.
  22. Trachtenberg E, Vinson M, Hayes E, et al. HLA class I (A, B, C) and class II (DRB1, DQA1, DQB1, DPB1) alleles and haplotypes in the Han from southern China. Tissue Antigens. 2007;70:455-463.
  23. Kwok J, Tang WH, Chu WK, et al. HLA-DQB1, -DQA1, -DPB1, and -DPA1 genotyping and haplotype frequencies for a Hong Kong Chinese population of 1064 individuals. Hum Immunol. 2020;81:3-5.
  24. Baek IC, Choi EJ, Shin DH, Kim HJ, Choi H, Kim TG. Allele and haplotype frequencies of human leukocyte antigen-A, -B, -C, -DRB1, -DRB3/4/5, -DQA1, -DQB1, -DPA1, and -DPB1 by next generation sequencing-based typing in Koreans in South Korea. PLoS One. 2021;16:e0253619.
  25. Chandanayingyong D, Stephens HA, Fan L, et al. HLA-DPB1 polymorphism in the Thais of Southeast Asia. Hum Immunol. 1994;40:20-24.

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