High-resolution HLA typing for the DQB1 gene by sequence-based typing

The prevalence of HPA-1a alloimmunization and the potential risk of FNAIT depend on both the DRB3*01:01 allele and associated DR-DQ haplotypes

Alloimmunization against human platelet antigen (HPA)-1a during pregnancy can cause foetal/neonatal alloimmune thrombocytopenia (FNAIT) and severe bleeding in the foetus or newborn and likely depends on several factors. HPA-1a alloimmunization is associated with DRB3*01:01, which is associated with several DR-DQ haplotypes. However, it is not known to what extent these haplotypes contribute to the prevalence of HPA-1a alloimmunization. HPA-1a-alloimmunized women, identified in a prospective study, and random donors were typed for selected DRB3, DRB4, DRB1, DQA1 and DQB1 alleles to determine allele and DR-DQ haplotype frequencies. DRB3*01:01 was carried by 94% HPA-1a-immunized women compared to 27% in the general population. In the first population, the DR3-DQ2 haplotype was overrepresented (P < .003). The prevalence of HPA-1a alloimmunization was estimated to be about twice as frequent with DR3-DQ2 compared to DR13-DQ6, together accounting for about 90% of DRB3*01:01-positive individuals. Further, we examined DQB1*02 and DRB4*01:01 alleles for their reported association with HPA-1a alloimmunization, in the context of DR-DQ haplotypes. Since ~ 80% of DQB1*02 alleles are linked to the DR3-DQ2 haplotype, the association might be coincidental. However, the DQB1*02:02-associated DR7-DQ2 haplotype was also overrepresented in alloimmunized women, suggesting a role for this allele or haplotype in HPA-1a alloimmunization. As DRB4*01:01 is predominantly associated with the DR7-DQ2 haplotype in HPA-1a-alloimmunized individuals, the reported association with FNAIT may be coincidental. Typing for DR-DQ haplotypes revealed important genetic associations with HPA-1a alloimmunization not evident from typing individual alleles, and the presence of different DRB3-associated DR-DQ haplotypes showed different prevalence of HPA-1a alloimmunization.

High-Resolution HLA-Typing by Next-Generation Sequencing of Randomly Fragmented Target DNA

PCR- or probe-based targeted capturing enables the enrichment of specific genomic loci prior to Next-Generation Sequencing (NGS). Here, we describe a probe-based protocol, which allows for high-resolution HLA typing of DNA samples by NGS. We also describe existing software tools that can be used for the subsequent HLA data analysis. Key prerequisites that warrant an accurate HLA calling are specific mappings of the sequencing reads, phasing of the mapped reads, and the possibility to perform a manual inspection/curation of the read mapping.

Human leukocyte antigen typing using buccal swabs as accurate and non-invasive substitute for venipuncture in children at risk for celiac disease

BACKGROUND AND AIM

Human leukocyte antigen (HLA) typing is an important step in the diagnostic algorithm for celiac disease (CD) and is also used for screening purposes. Collection of blood is invasive and accompanied with emotional impact especially in children. Genetic technological progress now enables HLA typing from buccal cell samples. This study evaluated the reliability and feasibility of HLA typing for CD-associated HLA polymorphisms using buccal swabs as routine test in high-risk individuals.

METHODS

Blood and buccal swabs of 77 children and adolescents with high risk for CD were prospectively collected in this cohort study. Buccal swab collection was performed either by the investigator at the outpatient clinic or by the patient or its parents at home. To evaluate the possibility of self-administration, three families performed the test at home. DNA was extracted using an adapted QIAamp method. Quantity, quality, and purity of DNA were recorded. HLA-DRB1, HLA-DQA1, and HLA-DQB1 typing was examined on buccal cell-derived and blood-derived DNA at low and, if necessary, high resolution level, using sequence-specific oligonucleotide and sequence-based typing, respectively.

RESULTS

DNA isolation using buccal swabs yielded a good quality and sufficient quantity of DNA to perform HLA-DQ typing in all individuals. HLA typing results on buccal cell-derived DNA were identical to typing on blood-derived DNA, also for the self-administered samples.

CONCLUSION

Introduction of the buccal swab test for HLA typing of CD risk in routine diagnostics can omit the current venipuncture and enables self-administration at home. Therefore, the buccal swab test is beneficial for individuals with a clinical suspicion for CD, as well as for screening purposes in high-risk populations.

Development of a high-resolution NGS-based HLA-typing and analysis pipeline

The human leukocyte antigen (HLA) complex contains the most polymorphic genes in the human genome. The classical HLA class I and II genes define the specificity of adaptive immune responses. Genetic variation at the HLA genes is associated with susceptibility to autoimmune and infectious diseases and plays a major role in transplantation medicine and immunology. Currently, the HLA genes are characterized using Sanger- or next-generation sequencing (NGS) of a limited amplicon repertoire or labeled oligonucleotides for allele-specific sequences. High-quality NGS-based methods are in proprietary use and not publicly available. Here, we introduce the first highly automated open-kit/open-source HLA-typing method for NGS. The method employs in-solution targeted capturing of the classical class I (HLA-A, HLA-B, HLA-C) and class II HLA genes (HLA-DRB1, HLA-DQA1, HLA-DQB1, HLA-DPA1, HLA-DPB1). The calling algorithm allows for highly confident allele-calling to three-field resolution (cDNA nucleotide variants). The method was validated on 357 commercially available DNA samples with known HLA alleles obtained by classical typing. Our results showed on average an accurate allele call rate of 0.99 in a fully automated manner, identifying also errors in the reference data. Finally, our method provides the flexibility to add further enrichment target regions.

Sequence-based typing of HLA: an improved group-specific full-length gene sequencing approach

Matching for HLA at the allele level is crucial for stem cell transplantation. The golden standard approach for allele definition of full gene polymorphism, the so-called high-resolution HLA typing, is sequence-based typing (SBT). Although the majority of the polymorphism for class I is located in exons 2 and 3 and for class II in exon 2, for allele definition it is necessary to unravel the complete coding and intron sequences leading to an ultrahigh HLA typing resolution at the allele level, i.e., a full-length gene polymorphism identification.This chapter describes our recently developed SBT method for HLA-A, -B, -C, and -DQB1, that is based on full-length hemizygous Sanger sequencing of the alleles, separated by group-specific amplification using the low-resolution typing result as reference starting point. Group-specific amplification has already been established for DRB. This method enables a cost-efficient, user-friendly SBT approach resulting in a timely unambiguous HLA typing to an ultrahigh resolution level with minimal hands-on time.

Clustering and alignment of polymorphic sequences for HLA-DRB1 genotyping

Located on Chromosome 6p21, classical human leukocyte antigen genes are highly polymorphic. HLA alleles associate with a variety of phenotypes, such as narcolepsy, autoimmunity, as well as immunologic response to infectious disease. Moreover, high resolution genotyping of these loci is critical to achieving long-term survival of allogeneic transplants. Development of methods to obtain high resolution analysis of HLA genotypes will lead to improved understanding of how select alleles contribute to human health and disease risk. Genomic DNAs were obtained from a cohort of n = 383 subjects recruited as part of an Ulcerative Colitis study and analyzed for HLA-DRB1. HLA genotypes were determined using sequence specific oligonucleotide probes and by next-generation sequencing using the Roche/454 GSFLX instrument. The Clustering and Alignment of Polymorphic Sequences (CAPSeq) software application was developed to analyze next-generation sequencing data. The application generates HLA sequence specific 6-digit genotype information from next-generation sequencing data using MUMmer to align sequences and the R package diffusionMap to classify sequences into their respective allelic groups. The incorporation of Bootstrap Aggregating, Bagging to aid in sorting of sequences into allele classes resulted in improved genotyping accuracy. Using Bagging iterations equal to 60, the genotyping results obtained using CAPSeq when compared with sequence specific oligonucleotide probe characterized 4-digit genotypes exhibited high rates of concordance, matching at 759 out of 766 (99.1%) alleles.

Extensive haplotype diversity in African American mothers and their cord blood units

HLA-A, -B, -C, -DRB1, -DQB1 assignments were obtained for 374 pairs of African American mothers and their umbilical cord blood units (CBU) by DNA sequencing. An algorithm developed by the National Marrow Donor Program was used to assign 1122 haplotypes by segregation. Seventy percent of the haplotypes carried assignments at all five loci. In the remainder, alleles at various loci, most often DQB1 in 48% of the haplotypes with a missing assignment, could not be assigned due to sharing of both alleles by mother and CBU. There were 652 haplotypes carrying a unique combination of alleles at the five loci; the majority (74%) were singletons. Novel B∼C and DRB1~DQB1 associations were observed. The results show the genetic diversity in this population and provide validation for a publically available tool for pedigree analysis. Our observations underscore the need for procurement of increased numbers of units in the national cord blood inventory in order to identify matching donors for all patients requiring hematopoietic stem cell transplantation.

HLA typing by direct DNA sequencing

Sequencing-based typing is a high resolution method for the identification of HLA polymorphisms. The majority of HLA Class I alleles can be discriminated by their exon 2 and 3 sequence, and for Class II alleles, exon 2 is generally sufficient. There are polymorphic positions in other exons which may require additional sequencing to exclude certain alleles with differences outside exon 2 and 3, depending on the clinical requirement and relevant accredition guidelines. The process involves selective amplification of target alleles by PCR, agarose gel electrophoresis of the PCR products to assess the quantity and quality, followed by purification of PCR amplicons to remove excess primer and dNTPs. Cycle sequencing reactions using Applied Biosystems™ BigDye(®) Terminator Ready Reaction v1.1 or v3.1 Kit are performed, then purification of sequence reactions before electrophoresing using Applied Biosystems™ 3730 or 3730XL Genetic Analyser (or similar). Data is processed by specialised software packages, which compare the sample sequence to the sequences of all possible theoretical allele combinations to assign an accurate genotype. Examination of all nucleotides, both at conserved and polymorphic positions enables the direct identification of new alleles, which may not be possible with techniques such as SSP and SSO typing.

Methods for diagnostic HLA typing in disease association and drug hypersensitivity

This chapter describes the application of diagnostic HLA typing for disease association and five methods used for specific HLA genotypes. The methods utilise a combination of polymerase chain reaction (PCR) amplification to detect sequence polymorphism by the presence or absence of amplification, nucleotide sequencing of the PCR product, and hybridisation of the PCR product with labelled probes. The probes are specific for sequence polymorphism associated with the genotype and are attached to either a Micro Bead or a Solid Phase. In addition, the detection of single nucleotide polymorphism(s) which "tag" for the genotype using a real-time PCR is described.

Use of PCR with sequence-specific primers for high-resolution human leukocyte antigen typing of patients with narcolepsy

Background

Narcolepsy is a neurologic disorder characterized by excessive daytime sleepiness, symptoms of abnormal rapid eye movement (REM) sleep, and a strong association with HLA-DRB1^*1501, -DQA1^*0102, and -DQB1^*0602. Here, we investigated the clinico-physical characteristics of Korean patients with narcolepsy, their HLA types, and the clinical utility of high-resolution PCR with sequence-specific primers (PCR-SSP) as a simple typing method for identifying DRB1^*15/16, DQA1, and DQB1 alleles.

Methods

The study population consisted of 67 consecutively enrolled patients having unexplained daytime sleepiness and diagnosed narcolepsy based on clinical and neurological findings. Clinical data and the results of the multiple sleep latency test and polysomnography were reviewed, and HLA typing was performed using both high-resolution PCR-SSP and sequence-based typing (SBT).

Results

The 44 narcolepsy patients with cataplexy displayed significantly higher frequencies of DRB1^*1501 (Pc= 0.003), DQA1^*0102 (Pc=0.001), and DQB1^*0602 (Pc=0.014) than the patients without cataplexy. Among patients carrying DRB1^*1501-DQB1^*0602 or DQA1^*0102, the frequencies of a mean REM sleep latency of less than 20 min in nocturnal polysomnography and clinical findings, including sleep paralysis and hypnagogic hallucination were significantly higher. SBT and PCR-SSP showed 100% concordance for high-resolution typing of DRB1^*15/16 alleles and DQA1 and DQB1 loci.

Conclusions

The clinical characteristics and somnographic findings of narcolepsy patients were associated with specific HLA alleles, including DRB1^*1501, DQA1^*0102, and DQB1^*0602. Application of high-resolution PCR-SSP, a reliable and simple method, for both allele- and locus-specific HLA typing of DRB1^*15/16, DQA1, and DQB1 would be useful for characterizing clinical status among subjects with narcolepsy.

Clinical and genetic characteristics of patients with autoimmune thyroid disease with anti-islet autoimmunity

In contrast to the large number of studies on autoimmunity against the thyroid gland in patients with type 1 diabetes mellitus, little is known about the anti-islet autoimmune status in patients with autoimmune thyroid diseases (AITDs). We therefore studied the anti-islet autoimmune status in patients with AITD and the clinical and genetic characteristics of AITD patients with anti-islet autoimmunity. The positivity and titer of glutamic acid decarboxylase antibody (GAD Ab) were studied in 866 Japanese patients with AITD (546 with Graves disease and 320 with Hashimoto thyroiditis), 221 patients with thyroid disease of nonautoimmune origin, and 282 control subjects. The clinical characteristics and genotypes of HLA-DRB1, DQB1, and CTLA4 were compared between AITD patients with and without GAD Ab. The prevalence of GAD Ab was significantly higher in AITD patients than in control subjects (5.8% vs 2.1%, P = .01), particularly in Graves disease (7.1% vs 2.1%, P = .0019). The prevalence of diabetes mellitus was significantly higher in AITD patients with GAD Ab than in those without (40.0% vs 10.1%, P < .0001), particularly in those with a high titer of GAD Ab (high vs low titer: 64% vs 16%, P = .001) and also in those positive for insulinoma-associated antigen 2 (IA-2) Ab (IA-2 positive vs negative: 75.0% vs 31.3%, P = .016). The AITD patients with GAD Ab were characterized by younger age at onset of diabetes, lower body mass index, higher hemoglobin A(1c) level, and higher frequency of insulin therapy than those without GAD Ab. The frequency of the DRB1*0405-DQB1*0401 haplotype was significantly higher in AITD patients with GAD Ab than in those without GAD Ab and control subjects. A single nucleotide polymorphism (rs3087243) of CTLA4 was significantly associated with AITD, but not with positivity of GAD Ab. These results indicate that patients with AITD, and in particular Graves disease, are prone to develop β-cell autoimmunity and insulin-requiring diabetes, particularly those with a high titer of GAD Ab and/or positive for both GAD and IA-2 Ab. Glutamic acid decarboxylase Ab positivity in AITD patients was associated with HLA, conferring susceptibility to type 1 diabetes mellitus.

Butyrophilin-like 2 in pulmonary sarcoidosis: a factor for susceptibility and progression?

The aims of this study were to assess the association of BTNL2G16071A with the course of pulmonary sarcoidosis and to verify the association with disease predisposition. In addition, the linkage between BTNL2G16071A and certain human leukocyte antigen (HLA)-DRB1/DQB1 types was investigated. In a retrospective case-control study BTNL2G16071A, HLA-DQB1, and HLA-DRB1 were typed in 632 sarcoidosis patients. These patients were classified into 304 patients with persistent sarcoidosis and 328 patients with nonpersistent sarcoidosis. The BTNL2 16071A variant allele was present significantly more often in patients with persistent disease (92.4%; 281/304) compared with patients demonstrating a nonpersistent course (86.6%; 284/328; odds ratio (OR) = 1.89 with 95% confidence interval (95% CI) 1.11-3.22). Furthermore, BTNL2 16071A variant allele carriers have an increased risk (OR = 1.85, 95% CI 1.19-2.88) of developing sarcoidosis. Moreover, the strong linkage between variant allele and HLA-DRB1*15 presence (OR = 8.43, 95% CI 3.02-23.5) was confirmed. The presence of a BTNL2G16071A variant allele almost doubles the risk of progressing to persistent pulmonary sarcoidosis in addition to increasing the risk of developing sarcoidosis. Presumably, these increased risks are caused by the strong linkage between BTNL2G16071A and DRB1*15. The choice between determining BTNL2G16071A SNP or the HLA-DRB1 type depends on the ability and/or availability to perform either test.

HLA class II amino acid epitopes as susceptibility markers of sarcoidosis

Sarcoidosis is a multisystemic disorder of unknown etiology, affecting primarily the lung and characterized by epithelioid granulomas. Disease association studies showed human leukocyte antigen (HLA) class II to be related to sarcoidosis. Initially, we studied the association of sarcoidosis with DQB1, and in the present study, we evaluated all amino acid variants of the HLA-DPB1, -DQB1, -DRB1, -DRB3, -DRB4 and -DRB5 genes to identify possible polymorphisms associated with the disease. Patients and controls were typed for class II genes to the allele level by sequence-based typing. Multiple logistic regression models showed DRAla71 and DQPhe9 to be independently associated with the disease. Subdivision of patients according to their radiographic stage resulted in identification of DRArg74 as independent associated residue in the RS I group, whereas DRAla71 and DQTyr30 were associated with RS II-IV groups. Polymorphic residues specifically associated with sarcoidosis shed new light on the characteristics of sarcoidosis-triggered peptides. Overall, pocket 9 of DQ and pocket 4 of DR seem to be the most important areas involved in the association with sarcoidosis.

HLA-DQB1 sequencing-based typing updated

The use of direct sequencing as a typing strategy is well acknowledged. Direct sequencing identifies all sequence motifs including new polymorphisms in heterozygous sequences. The earlier protocols for human leukocyte antigen HLA-DQB1 Sequencing-Based Typing (SBT) frequently encounter preferential amplification of one of the alleles that can lead to unreliable sequences or even to allelic dropout. In our new approach, the quality of the exon 2 sequences, now including both alleles to the same extend, was achieved by amplifying the HLA-DQB1*05/06 group into two groups by changing the common 3' amplification primer. In combination with exon 3 this updated HLA-DQB1 protocol provides a reliable approach for heterozygous sequencing.

Sequence-based typing of HLA-DQA1: comprehensive approach showed molecular heterogeneity

Within the human leukocyte antigen-DQA1 workshop project the level of molecular heterogeneity of the DQA1 gene was investigated. An improved sequence-based typing protocol was used, enabling analysis of the complete coding sequence, comprising exons 1-4. The participating laboratories implemented the amplification and sequencing primers in their own sequence-based typing approach. The method proved to be sufficiently robust to handle the differences in protocols. All reference samples used for validation were correctly typed for DQA1 by all participating laboratories. Three different populations with a total of 736 individuals were investigated: a population of Korean origin (n= 467), a British Caucasian (n= 114), and a Dutch Caucasian (n= 155) population. Sixteen of the known 28 DQA1 alleles were detected and six new alleles were identified. All novel alleles showed a nucleotide substitution outside exon 2. Comparison of the calculated allele frequencies revealed major differences between the Korean and the Caucasian populations but also between Dutch and British Caucasians. A tight association between DQA1 and DRB1/DQB1 alleles was observed in all three populations.

Role of human leucocyte antigen DQ in the presentation of T cell epitopes in the major cow's milk allergen alphas1-casein

BACKGROUND

Little is known about the association between human leucocyte antigen (HLA) and cow's milk allergy (CMA). The aim of the present study was to determine the HLA restriction of T cell clones (TCCs) specific to alphas1-casein, the most abundant milk protein, and to study possible HLA class II allele associations with CMA.

METHODS

alphas1-Casein-specific TCCs were derived from 6 children with CMA, 9 atopic children without CMA and 5 non-atopic children. T cell epitope specificity was defined by stimulation with overlapping peptides, spanning the alphas1-casein molecule. HLA restriction was determined in proliferation assays using antibodies blocking either HLA-DP, HLA-DQ or HLA-DR. HLA genotyping was performed in 32 subjects with CMA, 23 atopic and 22 non-atopic individuals.

RESULTS

Ten TCCs were restricted to HLA-DQ, 6 TCCs to HLA-DR and 4 TCCs to HLA-DP. The sequence in alphas1-casein that was most immunogenic to T cells from children with CMA contained T cell epitopes restricted to DQB1*0201, DPB1*0401 and DRB1*1501. The DQB1*0501 allele frequency was lower in children with CMA than in non-atopic children, but this difference could not be confirmed in an additional group of subjects with and without CMA.

CONCLUSIONS

HLA-DQ plays a substantial role in the presentation of T cell epitopes in alphas1-casein. However, HLA class II allele frequencies do not show major differences between cow's milk allergic, atopic and non-atopic subjects. T cell epitopes in the most immunogenic region are presented by various abundantly present HLA genotypes. Therefore, this sequence may be a suitable target for peptide immunotherapy.

Sequence-based typing of the complete coding sequence of DQA1 and phenotype frequencies in the Dutch Caucasian population

Typing of DQA1 by sequencing has been a challenge because of a 3-nucleotide deletion in exon 2 in half of the alleles. Furthermore, 19 of the 28 alleles cannot be identified on basis of exon 2 alone, but need additional exon information. With the sequencing strategy presented here the complete exons 1-4 are sequenced heterozygously, enabling identification of all DQA1 alleles by sequence-based typing (SBT). Exons 1-4 were amplified and sequenced separately, the combined sequences were used for automated allele assignment. The method was validated by typing 21 individuals with all possible different allele group combinations. In addition 26 quality control samples were correctly typed by this method. To determine the phenotype frequencies 155 unrelated Dutch Caucasian individuals were DQA1 typed. In total 15 known and two new DQA1 alleles were identified. DQA1*0103 and *0505 were the most frequent alleles with phenotype frequencies of 30% and 29%, respectively. The SBT method presented here is an improvement compared to already existing protocols in that the complete exon sequence is obtained for all coding exons, using identical polymerase chain reaction conditions. Furthermore, all exons are sequenced heterozygously, facilitating allele assignment and reducing the number of amplification reactions.

High-resolution typing for chicken BF2 (MHC class I) alleles by automated sequencing

Sequence-based typing (SBT) was developed for major histocompatibility complex (MHC) class I and class II alleles in humans. We report here the development and application of a SBT method for alleles of the chicken BF2 locus (the more polymorphic of the two MHC class I loci in chickens). Exon 2 of the BF2 gene was selectively amplified from genomic DNA using a BF2 locus-specific PCR primer. Exon 2 sequences were sufficient to identify the 21 distinct BF2 alleles described in standard B haplotypes of Leghorns and in commercial broiler-breeder lines. Sixty-six samples from MHC typed, pedigreed chickens were tested, including 50 different heterozygous combinations. BF2 sequences from all B homozygotes were successfully amplified, and all combinations of BF2 alleles in heterozygotes were co-amplified equally. The two different BF2 alleles in heterozygotes could be identified unambiguously by distinct sequence motif patterns. In tests of samples of unknown B genotype in commercial broiler-breeder flocks, we identified expected BF2 alleles as well as an allele not previously encountered in one of the lines.

Identification of a new HLA-C allele, Cw*0316, by sequence-based typing

The presence of a new allele, Cw*0316, was detected in a Caucasian individual through an unusual association. Molecular typing of the individual by sequence-specific primers and sequence-specific oligonucleotides showed the presence of B*58, B*41 and Cw*17. Sequence-based typing revealed the additional presence of another human leucocyte antigen-C allele. The new allele showed four nucleotide differences with Cw*030202 at positions 559, 560, 589 and 594 in exon 3, leading to three codon changes, codons 187, 197 and 198. This resulted in two amino acid substitutions at positions 163 (L-T) and 173 (K-E) of the mature protein, which proved sufficient to abrogate serological reactivity with Cw3-specific sera.

Severe Pulmonary Sarcoidosis Is Strongly Associated With the Haplotype HLA-DQB1*0602–DRB1*150101

Sarcoidosis is a multiorgan granulomatous disease of unknown etiology. Several lines of evidence suggest a genetic predisposition and associations have been demonstrated with HLA antigens. HLA-DQB1 has been proposed as one of the candidate genes. To investigate the relationship between DQB1 and sarcoidosis at the allele level, we typed 149 Dutch Caucasian sarcoidosis patients for DQB1 by sequence-based typing as the ultimate technique to identify all DQB1 alleles. Phenotype frequencies were compared with controls. Both groups were also typed for HLA-A, -B, and -DRB1 at the low-resolution level. To decide on the possible linkage with DR, all DRB1*15-positive patients were subsequently sequence-based typed. Results showed a statistically significant increase of DQB1*0602 in sarcoidosis patients. The increase was also proven for DRB1*150101. Because of the high linkage disequilibrium between DRB1*1501 and DQB1*0602 in Caucasians, it could not be decided which one was the primary association. The increase was most pronounced in patients with severe pulmonary sarcoidosis indicated by radiographic stages II-IV. Although not statistically significant, DRB1*03 and DQB1*0201 were increased in radiographic stage I compared with II-IV. This study provides evidence that the combination DQB1*0602/DRB1*150101 is a strong positive marker for severe pulmonary sarcoidosis.

Sequence-Based Typing of the HLA-A10/A19 Group and Confirmation of a Pseudogene Coamplified With A*3401

The strategy for sequencing human leukocyte antigen (HLA)-A was based on separate amplification of exons 2 and 3, followed by forward and reverse heterozygous sequencing of the alleles. Validation of the method was obtained by sequencing 11 individuals carrying alleles from all different HLA-A allele groups, except *43. All alleles could be correctly identified except A*3401. Unexpected polymorphic positions were identified in exon 3, even in individuals homozygous for A*3401. In addition, the pseudogene HLA-COQ or HLA-DEL linked to A*3401 was coamplified and sequenced. The problem was solved by using different amplification primers for exon 3 with mismatches for the two pseudogenes. A total of 252 unrelated individuals with at least one allele belonging to the A10 or A19 group were typed for HLA-A by this strategy. Ten different alleles were identified in the A10 group and 14 in the A19 group. As second allele a further 30 different subtypes from all different groups were sequenced. In 21 individuals, sequencing exon 1 was necessary to distinguish A*7401 from A*7402. The sequencing strategy, with separate amplification of the exons, has proven to be a robust method, resulting in reliable and efficient high-resolution HLA-A typing.

Elucidation of Exon 1, 4, and 5 Sequences of 39 Infrequent HLA-B Alleles

More than 590 human leukocyte antigen (HLA)-B alleles have been identified by sequence analysis. Although the polymorphic exon 2 and 3 sequences of all HLA-B alleles are described, the sequences of the other exons of a number of infrequent B-alleles are unknown. In this study, the exon 1, 4, and 5 sequences of 39 different HLA-B alleles were elucidated by allele-specific sequencing. Overall, these exon sequences showed identity with the majority of the known sequences from the corresponding allele groups, except for four alleles B*4010, B*4415, B*4416, and B*5606. The exon 1 sequence of B*4010 had nucleotide differences with all B*40 alleles, but was identical to the B*54, *55, *56, and *59 allele groups. B*4416 differed from B*440201 at position 988, which was previously considered a conserved position. B*4415 showed exon 1, 4, and 5 sequences deviating from the other B*44 alleles, but identical to B*4501. The exon 1 and 4 sequences of B*5606 differed from other B*56 alleles, but were in complete agreement with B*7801. The deviating exon sequences of B*4415 and B*5606 confirmed the evolutionary origin of these alleles suggested by the sequences of exons 2 and 3. The polymorphism observed in exons 1, 4, and 5 merely reflects the lineage-specificity of HLA-B.

No HLA-A gene detectable on one of the haplotypes in a Caucasian family

An unusual haplotype was detected in a family of a caucasian transplant patient. Human leukocyte antigen (HLA) analysis of the family demonstrated the absence of HLA-A on one of the haplotypes present in two family members. One was serologically typed A24, the other A2. Because they had one haplotype in common, the HLA-A allele of the shared haplotype was supposed to be a null allele. Different molecular typing methods identified only one allele in both individuals. The results suggest a deletion of the complete HLA-A gene or a major part of it. For confirmation, microsatellite analysis of the HLA-A region was performed with six microsatellite markers. Both family members were heterozygous for all markers, and a deletion of HLA-A could not be proven. Fluorescent in situ hybridization (FISH) was performed with cosmid and PAC probes encompassing the HLA-A gene. Both probes demonstrated an identical normal distribution pattern for diploid results. The absence of any serologic and molecular reaction with the results of the microsatellite and FISH analysis make a deletion of a narrow region, encompassing the HLA-A gene, the most plausible explanation.

Allelic polymorphism in introns 1 and 2 of the HLA-DQA1 gene

Human leukocyte antigen (HLA) class II antigens are highly polymorphic membrane glycoproteins, encoded by the A and B genes of DR, DQ, and DP. The polymorphism is mainly located in exon 2, with the exception of DQA1. Of the 27 DQA1 alleles presently known, 18 cannot be identified on the basis of exon 2 alone, but need additional information from the other exons. DQA1 has been reported to be the most ancient class II gene. For evolutionary comparison and to assess the degree of polymorphism outside the exons, the sequences of introns 1 and 2 were determined from 30 different cell lines, encompassing 15 different DQA1 alleles. The sequences revealed major nucleotide differences between the different lineages, whereas within each lineage few differences were present. Phylogenetic analysis of intron and exon sequences confirmed this lineage specificity. Altogether, the present data indicate that the HLA-DQA1 lineages represent ancient entities. The observed variation of the introns in alleles with identical exon sequences implicates conservative selection of the exons within a given lineage. Intron sequences may provide the means to set up an accurate typing system.

GAD-Reactive T Cells Were Mainly Detected in Autoimmune-Related Type 1 Diabetic Patients with HLA DR9

Type 1 diabetes mellitus (T1DM) is considered to be a T cell-mediated disease, and many reports suggest that some HLA types, especially HLA DR4 and DR9, convey susceptibility to T1DM in Japanese. We investigated the association between T cell reactivity against GAD and HLA types in "islet-associated autoantibody-positive" T1DM in Japanese. Blood samples were obtained from 36 "autoantibody-positive" type 1 diabetic patients with HLA DR4 or DR9 and 23 type 2 diabetic patients with HLA DR4 or DR9 as controls. They were divided into three groups, DR4/9, DR4/X, and DR9/X groups. In each HLA type group, GAD-reactive IFN-gamma-producing CD4(+) cells were assessed by means of intracellular cytokine staining for flow cytometry. Type 1 diabetic patients with HLA DR9/X had significantly higher numbers of GAD-reactive IFN-gamma-producing CD4(+) cells as compared to type 1 diabetic patients with DR4/X or DR4/9 (P < 0.05) and all type 2 diabetic patients. There was no significant difference in the number of GAD-reactive IFN-gamma-producing CD4(+) cells between type 1 diabetic and type 2 diabetic patients belonging to the DR4/X and DR4/9 groups. There was an association between T cell reactivity against GAD and HLA DR9 in Japanese type 1 diabetes.

Ambiguities of human leukocyte antigen-B resolved by sequence-based typing of exons 1, 4, and 5

The elucidation of the sequences of human leukocyte antigen-B (HLA-B)-exons 1 through 5 has led to an increase of ambiguities with alleles having identical exon 2 and 3 sequences, but differences in other exons. At the moment, 26 HLA-B alleles show such ambiguities which can be resolved by sequencing the exons in which the differences are located. Here we report a sequence-based typing (SBT) strategy for heterozygous sequencing of exons 1, 4, and 5, in addition to the previously described exons 2 and 3. The strategy was validated against a panel of 25 individuals, carrying HLA-B alleles from 33 different allele groups. Correct assignment of all HLA-B alleles was obtained for exons 1 through 5. In addition, the SBT protocol was used to resolve ambiguities in 50 individuals. The ambiguous combinations studied were B*0705/06, B*0801/19N, B*1512/19, B*180101/17N, B*270502/13/0504, B*350101/42/40N, B*390101/0103, B*400102/0101, B*440201/19N/27, and B*510101/11N/0105/30/32. In all cases, sequencing revealed the first allele to be present, except for three individuals with B*07. One of them typed B*0705; the other two were B*0706. The described SBT protocol for sequencing exons 1, 4, and 5 is a valuable tool for resolving ambiguities of HLA-B alleles with differences in these exons, as well as for studying the polymorphism of HLA-B outside exons 2 and 3.

Establishment of a sequence-based typing system for BoLA-DRB3 exon 2

A rapid, high-resolution sequence-based typing (SBT) system for BoLA-DRB3 exon 2 was developed. Amplification of the entire exon was achieved by a fully nested PCR with locus-specific primers and sequencing was performed directly on the PCR product. Heterozygous sequence data were obtained by automated sequence analysis of both alleles. Forward and reverse sequence data were assembled to improve identification of all heterozygous positions. Specific software (Haplofinder, Roslin Institute Software, Roslin, UK) was designed for allele assignment. Fifty-four females from a Holstein-Charolais resource herd cross, their 12 sires and five unrelated Holstein animals were used to establish the method. In parallel, these animals were typed by DRB3 polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) to confirm the results. Polymerase chain reaction-RFLP analysis defined 15 known types in the 71 animals, while SBT of the same animals showed 19 known alleles. Subsequently, 72 more animals from the same resource herd were typed by the established SBT method without PCR-RFLP typing. This SBT strategy and the Haplofinder software can be applied to the analysis of any polymorphic locus for which suitable locus-specific primers and allelic sequences are available.

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.

Identification of three new DRB1 alleles, DRB1*0107, *0425 and *13012 and confirmation of DRB4*01033

The characterization of three novel DRB1 alleles is described, DRB1*0107, DRB1*0425 and DRB1*13012 as well as confirmation of DRB4*01033. Two alleles, DRB1*0107 and *0425, showed amino acid differences with previously identified HLA molecules. In DRB1*0107, the glutamine at position 10 was substituted by a glutamic acid. DRB1*0425 showed one amino acid difference with DRB1*0418 (I to F) at position 67, and five amino acid differences with DRB1*04011 at positions 67 (L to F), 70 (Q to D), 71 (K to R), 74 (A to L) and 86 (G to V). The alleles DRB1*13012 and DRB4*01033 had protein sequences identical to DRB1*13011 and DRB4*01031/01032, respectively. Nucleotide differences were present at position 306 for DRB1*13012 and at position 321 for DRB4*01033.

Identification of a new HLA-B*40 variant, B*4035

In this report, the novel allele B*40351 is presented. The allele was identified in a Caucasian individual by sequence-based typing. B*4035 is identical to B*4002 in exon 2, but differs in exon 3 at position 463, where it has an A in stead of a C. This results in an amino acid change from arginine to serine at codon 131 of the mature protein. The haplotype carrying the B*4035 was A3 B*4035 Cw2 DR11 DQ3.

Molecular and serological identification of the HLA-A*3404 allele

In this report we describe a novel HLA-A*34 allele, A*3404, which was initially detected by an unusual serological pattern in two unrelated individuals. Sequencing revealed that the new allele was identical to A*3402 in exons 2 and 3, except for a single nucleotide difference at position 238, changing codon 56 from glycine to arginine. The codon change resulted in positive serological reactions with several sera recognizing A30 and/or A31, implicating an important role for this position in epitope recognition. The allele was identified twice on the haplotype A*3404, B*1402, Cw*0802, DRB1*14, DQB1*05.

Sequence analysis of exons 1, 2, 3, 4 and 5 of the HLA-B5/35 cross-reacting group

The HLA-B5/35 cross-reacting group (CREG) is a set of closely related antigens including HLA-B35, B51, B52, B53 and B78. The nucleotide sequences of exon 1 through 5 of the B5/35 CREG were determined to assess the level of polymorphism. For exons 2 and 3, the previously described sequence-based typing (SBT) strategy was applied, the nucleotide sequences of exon 1, 4 and 5 were determined by allele-specific sequencing. A total of 225 unrelated individuals were HLA-B typed by heterozygous sequencing of exons 2 and 3. In the B5/35 CREG, 26 different alleles were identified, whereas 63 non-B5/35 CREG alleles were sequenced. The SBT strategy was proven to be reliable and efficient for high resolution typing of the B5/35 CREG. The nucleotide sequences of exon 1, 4 and 5 were determined for the 26 different B5/35 CREG alleles to establish the level of polymorphism. For seven different alleles, of which the exon 1, 4 and 5 sequences were hitherto unknown, the sequences were elucidated and in agreement with the known B5/35 sequences. Nineteen HLA-B5/35 CREG alleles with previously published exon 1, 4 and 5 sequences were sequenced in at least two individuals. Three new alleles were identified. The first, B*5204, showed a difference at position 200 compared to B*52011, which was previously considered a conserved position. The other two alleles, B*3542 and B*51015, showed exon 2 and 3 sequences identical to B*35011 and B*51011, but differences in exons 1 and 4, respectively. B*3542 had differences at position 25 and 72 and B*51015 showed a difference at position 636. More polymorphism might be present outside exons 2 and 3 than previously thought.

B*27 in molecular diagnostics: impact of new alleles and polymorphism outside exons 2 and 3

HLA-B*27 is known to be associated with ankylosing spondylitis and several methods have been applied to determine its presence or absence. In this report two molecular methods were used for detection of B*27. The polymerase chain reaction sequence-specific primer (PCR-SSP) method was performed to detect the presence or absence of B*27, whereas the sequence-based typing method (SBT) was used to identify the B*27 subtype. The PCR-SSP method used to detect B*27 was updated to enable the detection of all B*27 alleles. The typing results obtained by this method were compared with the serological typings of 262 individuals. Fifty of them were found to be B*27 positive by PCR-SSP and 46 also showed positive serological reactions with B27-specific sera. The four discrepancies were the result of the presence of B*2712 in three individuals and B*2715 in one individual; both alleles showed no serological reactions with B27-specific antisera. With SBT the sequences of exons 1 through 4 were determined to unequivocally assign the B*27 alleles. Eleven different subtypes were detected in 78 individuals, including three new B*27 alleles: B*27054, B*2715 and B*2717. The allele B*27054 showed an allelic drop out when exon 3 was amplified. Three differences with B*27052 were demonstrated; one in exon 1, one in intron 1 and one in intron 2, the latter being responsible for the allelic drop out. The B*2715 allele was serologically not detectable with several B27-specific sera, but showed Bw4-positive reactions. The sequence of B*2715 showed two mismatches with B*2704. The sequence of B*2717 showed one mismatch with B*27052 at position 248 (A-->T), which was considered to be a conserved position in all B alleles.

HLA-DRB1 and HLA-DQB1 polymorphisms in Pacific Islands populations

Allele frequency distributions of the HLA-DRB1 and HLA-DQB1 genes were investigated in four Pacific Islands populations from the Cook Islands, Samoa, Tokelau and Tonga. Limited diversity was observed for both the HLA-DRB1 and HLA-DQB1 loci. Five HLA-DRB1 alleles were observed to be the most frequent amongst all the studied Pacific Islands populations. They were: HLA-DRB1*0403, HLA-DRB1*08032, HLA-DRB1*09012, HLA-DRB1*11011 and HLA-DRB1*1201. Cook Islanders had the largest number of low frequency DRB1 alleles followed by Samoans, Tokelauans and Tongans, most of which may be attributed to reported non-Polynesian admixture. The most frequently observed DQB1 alleles in the four studied Pacific Islands populations were those of the DQ3 subgroup of alleles HLA-DQB1*03011, HLA-DQB1*0302 and HLA-DQB1*03032 as well as HLA-DQB1*05031 and HLA-DQB1*06011. Cook Islanders had the highest number of rare HLA-DQB1 alleles, the distibution being similar to that of the HLA-DRB1 allele. While, in general, the values of homozygosity for DRB1 and DQB1 were observed to be lower then expected under neutrality, a statistical significance was observed in Tongans, Samoans and Tokelauans for the DQB1 locus and in Tongans for the DRB1 locus. Differences were observed between allele frequency distributions for Tokelauans compared to the other three populations. This was also demonstrated by principal component analysis of DRB1 and DQB1 allele frequencies, which separated the Tokelauan population from Cook Islanders, Tongans and Samoans. Tongans and Samoans were separate from the other Polynesian populations in the phylogenetic trees. Observed allele and haplotype frequencies were found to be in agreement with previously published HLA-DRB and HLA-DQB Polynesian data.

A strategy for high throughput HLA-DQ typing

We have developed a high throughput HLA typing methodology that is a modification of the standard sequence-specific primer method. This approach is distinct from other methods using an automated DNA analyzer, as more than one gene is typed in a single lane. We have optimized the method for use on an ABI 373 automated genotyping machine. Primers were designed to preferentially amplify DNA fragments of the generic allelic groups of the DQA1 and DQB1 loci. PCR products representing alleles at the DQA1 locus were amplified using a different fluorescent dye than the PCR products from the DQB1 locus. Only three PCR reactions are required for low resolution typing of DQA1 and DQB1. Use of different labeled primers enables genotyping for both loci in a single gel lane, allowing for 64 samples to be typed at low resolution for both DQA1 and DQB1 on a single gel. Automated allele assignments were determined based on DNA migration distance through a polyacrylamide gel using a standard genotype allele-calling program. Accuracy of this method is greater than 98% for both loci. The strategy described here may be adapted to include more loci or to produce higher resolution typing of alleles encoded by these loci. It can be readily optimized for use on other slab gel or capillary electrophoresis systems.

Major histocompatibility locus genetic markers of beryllium sensitization and disease

Hypersensitivity to beryllium (Be) is found in 1-16% of exposed workers undergoing immunological screening for beryllium disease using the beryllium lymphocyte proliferation test (BeLPT). However, only approximately 50% of BeLPT-positive workers present with lung granulomas (i.e. berylliosis). As berylliosis is associated with the human leukocyte antigen (HLA)-DP supratypic marker DPGlu69, the authors asked whether this marker is differentially associated with disease presentation. A population of 639 workers from a beryllium factory undergoing BeLPT screening was evaluated in a nested case-control study for the prevalence of HLA-DPGlu69, the HLA-DPB1, HLA-DQ and HLA-DR alleles and of the biallelic tumour necrosis factor (TNF)-alpha polymorphism TNF-alpha-308 in 23 individuals presenting as "sensitized" (i.e. BeLPT-positive without lung granulomas) and in 22 presenting as "diseased" (i.e. BeLPT-positive with granulomas in the lung biopsy). The HLA-DPGlu69 marker was associated with "disease" (odds ratio (OR) 3.7, p=0.016, 95% confidence interval (CI) 1.4-10.0), whilst the high TNF-alpha production-related TNF-alpha-308*2 marker was associated with both a positive BeLPT (OR 7.8, corrected p<0.0001, 95% CI 3.2-19.1) with no difference between "sensitization" and "disease". Furthermore, the HLA-DRArg74 marker was associated with "sensitization" without disease (OR 3.96, p=0.005, 95%, CI 1.5-10.1). The data indicate that tumour necrosis factor-alpha, human leukocyte antigen-DR and human leukocyte antigen-DP markers play different roles in beryllium sensitization and granuloma formation in beryllium-exposed workers.

Short tandem repeat (STR) haplotypes in HLA: an integrated 50-kb STR/linkage disequilibrium/gene map between the RING3 and HLA-B genes and identification of STR haplotype diversification in the class III region

We present a dense STR/linkage disequilibrium(LD)/gene map between the RING3 and HLA-B loci, reference allelic sizes on the most prevalent HLA haplotypes and their allelic frequencies in pedigree founders. This resource will facilitate LD, evolution and gene mapping studies, including comparisons of HLA and STR haplotypes and identification of HLA recombinants. The map was constructed by testing novel and previously reported STRs using a panel of 885 individuals in 211 families and 60 DNA samples from cell lines and bone marrow donors homozygous in the HLA-A, -B and -DR loci selected from over 15 000 entries into the registry of Swedish bone marrow donors. We have also analysed the variability of STR alleles/haplotypes on the most prevalent HLA haplotypes to identify STRs useful for fine mapping of disease genes in the region previously implicated in susceptibility to many disorders. The analysis of 40 HLA-A*01, B*0801, DRB1*03011, DQB1*0201 haplotypes in homozygous donors showed a surprising stability in 23 STRs between the class II recombination hot spot and HLA-B, with the average of 1.9% (16/838) variant alleles. However, 40% variant alleles were found at the D6S2670 locus in intron 19 of the tenascin-X gene both in the families and homozygous donors. The nucleotide sequence analysis of this STR showed a complex polymorphism consisting of tetra- (CTTT)(8-18) and penta-nucleotide (CTTTT)(1-2) repeats, separated by an intervening non-polymorphic sequence of 42 bp. The HLA-A1, B*0801, DRB1*03011, DQB1*0201 haplotypes had five (CTTT)(14-18)/(CTTTT)(2) variants with a predominant (CTTT)(16) allele, implicating the tetranucleotide component as the source of this ancestral haplotype diversification, which may be due to the location of D6S2670 in the region of the highest GC content in the human MHC.

Identification of two new HLA-B22 variants, HLA-B*5509 and B*5606

In our recent study using high-resolution HLA-B locus typing by sequence-based typing (SBT) we identified 9 new alleles in a total of 355 unrelated individuals (4). Three of them concerned an allele belonging to the B22 group. One of them, B*5607, showed the unusual presence of a Bw4 sequence motif, as described previously (5). In this report the other two B22 variants are described; one belonging to the B55 specificity and named B*5509; the other one being a B*56 allele and assigned B*5606, which brings the total number of alleles belonging to the B22 group to 18.

Rett syndrome from quintuple and triple deletions within the MECP2 deletion hotspot region

Rett syndrome results from mutations in the X-linked methyl-CpG-binding protein 2 (MECP2) gene, which are nearly always lethal in males and lead to regression and reduced life expectancy in females. Herein we report one propositus with five tandem deletions and a second propositus with three tandem deletions within MECP2 exon 4 that encode truncated protein products resulting in classic Rett syndrome. These deletion breakpoints and single deletions in 3 other patients were all found within a 185-bp region along with 64 of 69 other reported deletion breakpoints in the MECP2 gene. Illegitimate recombination resulting in deletion at a substantial proportion of the shared MECP2 sites is enhanced by repeated guanosine (G) DNA sequences in the antisense direction, consistent with reports at other gene loci that polypurine (multiple guanosine or adenosine (A)) basepairs enhance sequence deletion. Multiple deletions at the same poly G recombination sites confirm the existence of deletion hotspots in this gene region with numerous repeated antisense sites that are enriched 26- to 161-fold. Deletion by illegitimate recombination within a single allele can occur during mitotic or meiotic cell cycles. Although prone to disease-causing deletion, this region is unique in humans and highly conserved among mammals for the last 75 000 000 years to maintain the MECP2 gene's critical function.

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.

Unexpected Bw4 and Bw6 reactivity patterns in new alleles

The Bw4 and Bw6 epitopes were the first HLA-B differences to be recognized by serological methods. Since then 44 serological groups have been identified and more than 250 alleles assigned by molecular typing methods. In general each serological HLA-B group is associated with the presence of either the Bw4 or the Bw6 epitope. There are several exceptions to this rule. Four alleles, B*4601, *7301, *5503 and *1806, show no serological reactivity with either Bw4 or Bw6. Although the Bw6 motif at residues 77-83 is present in these alleles the Bw6 epitope is modified by a valine at residue 76. One or more alleles from the B8, B40 and B62 groups are identified as Bw4 positive, whereas all others are Bw6 positive. In the groups B27, B44 and B47 several alleles are found to be Bw6 positive, while the majority is Bw4 positive. Histocompatibility testing of dialysis patients and their families revealed the serological presence of an unexpected Bw4 epitope associated with B18 in one patient and B56 in another. Allele-specific amplification and sequencing of exons 2 and 3 of these HLA-B alleles revealed the presence of the Bw4 sequence motif for both. The new alleles were assigned B*1809 and B*5607, respectively. In 2 other patients the presence of a new B*07 allele was determined by sequence based typing. Although the new allele, B*0715, showed the Bw6 sequence motif at positions 77 to 83, a substitution of amino acid 76 from glutamic acid to valine was identified. This change resulted in an aberrant Bw6 serological reaction pattern.

Sequence-based typing of HLA-B: the B7 cross-reacting group

The large number of polymorphic sites in the HLA-B locus makes sequencing an efficient way of detecting and analysing them. Most polymorphic sites are located in the alpha1 and alpha2 domains of the molecule, encoded by exons 2 and 3 of the gene. An HLA-B-specific sequence-based typing (SBT) strategy was designed for routine application identifying the polymorphic sites in these domains. Exons 2 and 3 were amplified separately using amplification primers located in intron 1, intron 2 and intron 3. Separate amplification of exons 2 and 3 resulted in short polymerase chain reacting (PCR) products and enabled a solid-phase sequencing approach, which made correct assignment of heterozygous positions possible due to low background. A one-step sequencing reaction was performed using fluorescent dye-labelled sequencing primers. One forward sequencing reaction was performed for exon 2, whereas for exon 3, two forward sequencing reactions were needed using two different sequencing primers located in intron 2 and exon 3. The combined sequences of exon 2 and 3 were used for automatic alignment to an HLA-B sequence database and automatic allele assignment. A total of 355 individuals with at least one allele belonging to the B7 cross-reacting group (B7, 13, 22, 27, 40, 41, 42, 47, 48, 81 and 82) were typed for HLA-B by SBT. In the B7 group 48 different alleles were identified, in the non-B7 group a further 59 alleles were sequenced, 9 new alleles were identified. The sequencing strategy described has proven to be reliable and efficient for high-resolution HLA-B typing.

Sequence-based typing of HLA class II DQB1

Due to the expanding number of known HLA class II DQB1 alleles, high-resolution oligotyping is becoming ineffective, therefore a sequence-based typing (SBT) strategy was developed to provide rapid and definitive typing of HLA-DQB1. HLA-DQB1*02, *03, *04, *05, and *06 alleles were individually amplified by polymerase chain reaction (PCR) using exon 2 group-specific primers. Forward and reverse PCR primers were tailed with M13 universal and M13 reverse sequences, respectively. Subsequent bi-directional cycle-sequencing was carried out using Cy5.5-labeled M13 universal primer and Cy5.0-labeled M13 reverse primer. Automated sequencing was performed in 30 min using a Visible Genetics, Inc. (VGI) MicroGene Clipper Sequencer. Full concordance was observed between this SBT method and oligotyping among 151 individuals.

Presence of the DRB4*0103102N null allele in different DRB1*04-positive individuals

The DRB4 gene encoding the DR53 antigen is present in DRB1*04-, DRB1*07- and DRB1*09-positive individuals. Eight allelic variants of DRB4 have been recognized, 5 resulting in an expressed DR53 antigen and 3 belonging to the null alleles. So far the DRB4*0103102N null allele had been found exclusively in individuals carrying the haplotype DR7,-DQ9. High-resolution typing of HLA class II by polymerase chain reaction using sequence-specific primers (PCR-SSP) and/or sequence-based typing of kidney patients and their families revealed the presence of the DRB4*0103102N null allele segregating with DRB1*04 and DQB1*03 in 4 different families. Three different haplotypes on which the null allele was located, were recognized by family studies: DRB1*0401, DQB1*0301; DRB1*0402, DQB1*0302 and DRB1*0404, DQB1*0302. Determination of the DR53 specificity of antisera reacting with DR53-positive individuals has always been difficult due to the simultaneous presence of DR4, 7 or 9. Identification of DR4-positive DR53-negative individuals as described here, provided the serological reactions with DR53-antisera and revealed the antibody specificities in the antisera used.

High-resolution typing for HLA-DRB1*15 amd -DRB1*16 by fluorescence-marked sequence-specific priming (TaqMan assay)

Sequence-specific primed polymerase chain reaction (PCR-SSP) is widely used in HLA laboratories. The TaqMan method, which is described here for high-resolution typing of HLA-DRB1*15 and -DRB1*16, does not require elaborate and time-consuming post-PCR detection steps. In this one-tube assay, conventional PCR-SSP and fluorescence detection of the amplicon with a doubly labeled fluorescent probe are combined: a fluorogenic hybridization probe (FHP) labeled with a spectral resolvable fluorescent reporter dye (FAM or TET) at its 5' terminus and a common quencher dye (TAMRA) at its 3' terminus is cleaved by the 5' nuclease activity of Taq DNA polymerase only if the target sequence is amplified. An increase of fluorescence intensity indicates a successful amplification. For high-resolution typing of HLA-DRB1*15 and -DRB1*16 alleles we designed two FHPs and 14 specific primer mixes (7 for DR15 and 7 for DR16). Amplification of the specific sequence was detected by a FAM-labeled FHP, whereas amplification of the internal control was detected by a TET-labeled FHP. We were able to type all heterozygous DRB1*15/DRB1*16 subtype combinations. For evaluation, 60 HLA-DRB1*15-positive and 40 HLA-DRB1*16-positive individuals were typed and the results were compared with conventional PCR-SSP DR15/16 subtyping. There were no discrepancies between the two methods. The TaqMan method is an alternative to conventional PCR-SSP typing which is suitable for routine use in HLA laboratories.

High resolution HLA-DQB1 typing by combination of PCR-RFLP and PCR-SSCP

A reliable method for high-resolution HLA-DQB1 typing using a combination of PCR- restriction fragment length polymorphism (RFLP) and PCR-single strand conformation polymorphism (SSCP) analysis is described. The second exon of the DQB1 gene was subjected to PCR using generic primers and digested with two restriction enzymes, MspA1I and HaeIII, and the DQB1 alleles were divided into seven groups. According to the RFLP patterns, appropriate group specific primers for DQ5, 6 and DQ2, 3, 4 groups were used to selectively amplify the alleles and the SSCP technique was used to distinguish the individual alleles. A total of 88 quality control samples of various ethnic groups distributed in the International Cell Exchange and HLA DNA Exchange programs and the ASHI/CAP Proficiency Tests were investigated by the PCR-RFLP/SSCP method. The concordance between our typing results and the consensus results of the surveys were 100%, and a total of 14 DQB1 alleles in 49 homozygous and heterozygous combinations were all correctly identified by the method described. This method is accurate, economical and relatively easy to interpret and well suited for routine clinical and research uses.

High-resolution sequence typing of HLA-DQA1 and -DQB1 exon 2 DNA with taxonomy-based sequence analysis (TBSA) allele assignment

High-resolution DNA sequencing of exon 2 of DQA1 and DQB1 genes that uses a taxonomy-based sequence analysis (TBSA) method to assign alleles was developed. The system uses fewer primers for polymerase chain reaction (PCR) amplification and sequencing than other methods and yields accurate DQA1 and DQB1 typing when either homozygous or heterozygous DNA samples are tested. The approach was initially corroborated by the correct typing of 10 blinded samples that had been previously typed by PCR using sequence-specific oligonucleotide probes (PCR-SSOP) or serology, and subsequently confirmed by sequencing of cloned PCR products. DNA from peripheral blood cell samples of 130 individuals enrolled in a case-control analysis of HLA determinants of abdominal aortic aneurysm were subsequently evaluated. Overall, 8 different DQA1 and 19 DQB1 alleles were identified. All 21 DQA1 heterozygous combinations and 45 of 49 DQB1 heterozygous combinations were successfully resolved with TBSA. The two pairs of heterozygous DQB1 combinations that were not unambiguously typed required sequence specific PCR amplification for correct allele identification. We conclude that the method provides precise analysis for HLA-DQ typing.