Common and well-documented HLA alleles: 2012 update to the CWD catalogue.

We have updated the catalogue of common and well-documented (CWD) human leukocyte antigen (HLA) alleles to reflect current understanding of the prevalence of specific allele sequences. The original CWD catalogue designated 721 alleles at the HLA-A, -B, -C, -DRB1, -DRB3/4/5, -DQA1, -DQB1, and -DPB1 loci in IMGT (IMmunoGeneTics)/HLA Database release 2.15.0 as being CWD. The updated CWD catalogue designates 1122 alleles at the HLA-A, -B, -C, -DRB1, -DRB3/4/5, -DQA1, -DQB1, -DPA1 and -DPB1 loci as being CWD, and represents 14.3% of the HLA alleles in IMGT/HLA Database release 3.9.0. In particular, we identified 415 of these alleles as being 'common' (having known frequencies) and 707 as being 'well-documented' on the basis of ~140,000 sequence-based typing observations and available HLA haplotype data. Using these allele prevalence data, we have also assigned CWD status to specific G and P designations. We identified 147/151 G groups and 290/415 P groups as being CWD. The CWD catalogue will be updated on a regular basis moving forward, and will incorporate changes to the IMGT/HLA Database as well as empirical data from the histocompatibility and immunogenetics community. This version 2.0.0 of the CWD catalogue is available online at cwd.immunogenomics.org, and will be integrated into the Allele Frequencies Net Database, the IMGT/HLA Database and National Marrow Donor Program's bioinformatics web pages.

A computerized method to predict the discriminatory properties for class II sequencing based typing.

Accurate identification of alleles or groups of alleles is obtained using DNA techniques for HLA class II typing. In PCR-SSP and PCR-SSO the typing resolution is dependent on the location of the amplification primers and the number of oligonucleotide probes used for hybridization. These primers are developed based upon the known allele sequences. However, the number of published allele sequences increases rapidly. Periodic reconsideration of the discriminatory properties of the methods used is necessary and often leads to the addition of primers, and an increase of ambiguous genotypes. SBT is a high-resolution class II typing method which utilizes the second exon sequence at all positions for typing. Using a generic amplification and sequencing approach, a limited number of ambiguous heterozygotes can be expected. However, the number of ambiguities is dependent on the location of the primers. These ambiguities can be solved by the use of group-specific primers in either the amplification or sequencing reaction. To identify the applicability of a SBT approach with respect to typing resolution, it is important to identify these ambiguities and develop strategies to solve them. We developed software that predicts the ambiguous heterozygotes, and analyzes their sequences for group specific primers, solving these ambiguities. The location of the primers is considered as well as the use of generic vs group-specific amplification or sequencing reactions. Allele sequences of all class II genes, as accepted by the WHO nomenclature committee for factors of the HLA system and submitted to the EMBL/Genbank databases, are analyzed to define the allelic discrimination level of HLA-DQB1, -DQA1, -DFB1, -DPA1, -DRB1, -DRB3, -DRB4, and -DRB5.

Assignment of HLA-DPB alleles by computerized matching based upon sequence data.

Routine HLA typing by serology has been supported by DNA or protein analysis of the respective molecules in cases when serologic typing was inconclusive or difficult to perform. DNA analysis by RFLP, SSO, or PCR amplification with SSP is a reliable tool for the identification of alleles. Because DNA sequences may now be determined routinely, we developed software based on sequence data from known sequences for allele assignment of polymorphic gene systems. We describe the assignment of HLA-DPB alleles based upon sequence data obtained after PCR amplification and subsequent sequencing of exon 2. Our software includes a database containing all known HLA-DPB sequences, which offers the possibility of analyzing heterozygous individuals by combinatorial comparison through all alleles and thus identifying the one or two alleles involved. Quality control of the sequence has been included by the alignment of constant regions of the sequence combined with related polymorphism of known polymorphic nucleotides and the identification of the positions crucial for the allele assignment. The ability to type for HLA-DPB alleles routinely by automatic sequence determination and subsequent automated analysis offers new perspectives for HLA-DNA typing.

A generic sequencing based typing approach for the identification of HLA-A diversity.

Sequencing Based Typing (SBT) is a generic approach for the identification of HLA-A polymorphism. This approach includes the high resolution typing of the HLA-A broad reacting groups, HLA-A subtypes and will identify new alleles directly. The SBT approach described here uses a locus specific amplification of DNA from exon 1 to exon 5. The resulting 2,022 bp PCR product serves as a template for the subsequent sequencing reactions. Amplification is followed by direct sequencing of exons 2, 3 and 4 in both orientations with fluorescently labeled primers to define all polymorphic positions leading to a high resolution typing result. In this study the sequence of exons 2 and 3 of a panel of 49 cell lines was determined. In addition, the exon 4 region of 35 cell lines was also sequenced to evaluate the exon 4 polymorphism. The HLA-A type of most of the cells could be identified by sequencing only exons 2 and 3. However, the sequence of exon 4 was required to discriminate A*0201 from A*0209 and A*0207 from A*0215N. In this panel, an identical new "HLA-A*0103" was identified in two Caucasian samples.

NK-KIR ligand identification: a quick Q-PCR approach for HLA-C epitope typing.

Interaction of donor natural killer (NK)-cell-associated killer cell immunoglobulin-like receptors (KIRs) with the patient's human leukocyte antigen-C (HLA-C) ligands can result in an alloreactive NK response after haematopoietic stem cell transplantation. In many retrospective studies, additional HLA-C-typing data are required to predict NK-cell alloreactivity. We developed a Taqman assay using the quantitative polymerase chain reaction (Q-PCR) technique that facilitates HLA-C epitope typing, allowing the assignment of HLA-C group 1 or 2 alleles based on the dimorphism at residues 77 and 80 rather than based on the sequence specific priming (SSP) and sequence-based typing allele types. Q-PCR analysis for HLA-C epitope detection showed three clusters reflecting homozygous group 1 or 2 and heterozygous samples. This new approach introduces a quick HLA-C epitope screening method to define the presence of the ligand for the KIR-HLA-C interaction.

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.

Bioinformatics: analysis of HLA sequence data.

High resolution HLA typing is a requirement for the selection of matched donors in hematopoietic cell transplantation. The high resolution typing method that provides the most accurate and complete identification of HLA genotypes is sequencing-based typing (SBT). For each sample being tested, SBT defines the exact nucleotide sequence of the coding regions of both alleles at a given HLA locus. Identification of the underlying genotype of the sample can then be made by computerized sequence comparison with all possible HLA allele combinations at that locus. The use of SBT to identify the complete nucleotide sequence of a given HLA gene also enables the direct detection of previously undefined alleles. Since different HLA alleles may differ by a single nucleotide, the accurate assignment of an HLA genotype by SBT is absolutely dependent on the correct identification of the nucleotide at each position for a given sample. However, automated sequence analysis of heterozygous samples may result in the ambiguous assignment of nucleotides at a given position. In addition, ambiguous assignments may result from the sequencing of two different samples that express different HLA alleles but whose sequence profiles appear exactly the same. Both of these ambiguous situations can be resolved by the application of the multi-sequence analysis (MSA) method described here.

DPB1*8501, a novel DPB1 variant in the US Black population.

We describe a new DPB1 allele, DPB1*8501, which was identified by sequencing-based typing (SBT) in the UCLA exchange. DPB1*8501 is similar to DPB1*2701 with a difference at position 272, (G to A). This difference leads to an amino-acid change of codon 91 from arginine (CGC) to histidine (CAC). Until now this position has been considered conserved. This substitution is located at the 3' site of exon 2, and may interfere with typing strategies using primers or probes located in this region.

Going back to the roots: effective utilisation of HLA typing information for bone marrow registries requires full knowledge of the DNA sequences of the oligonucleotide reagents used in the testing.

Information obtained by DNA-based HLA typing assays is more detailed and of higher quality than that obtained by conventional serological techniques. Nevertheless, it is common for data acquired in this way to be presented in the more familiar serological format. In many cases this representation can lead to significant loss of information, which may only become apparent at a later time, with the discovery of novel allele sequences. DNA-based typing methods, such as sequence-specific oligonucleotide probing (SSOP) or sequence-specific priming (SSP) generate fragmentary sequence data which is information rich. An alternative to assigning allele names to these fragments is to simply store the sequence data itself without interpretation. Bone marrow donor repositories can then be searched directly with sequence information, which though complex is more complete, rather than searching by derivative allele names.

A multicenter international evaluation of single-tube amplification protocols for sequencing-based typing of HLA-DRB1 and HLA-DRB3,4,5.

We have described previously a novel single-tube polymerase chain reaction (PCR) amplification (STAmp) protocol for the efficient sequencing-based typing (SBT) of human leukocyte antigen (HLA)-DRB1. The PCR amplification mix includes primers to each of seven allele group-sequence motifs. We have applied this principle to the simultaneous SBT of HLA-DRB3, -DRB4, and -DRB5 using locus specific primers. We report here a multicenter international evaluation of the STAmp protocols performed as a component of the 13th International Histocompatibility Workshop. Identical amplification primer mixes, sequencing primers, and DNA were sent to participating laboratories. The primer mixes contained the amplification primers and the PCR buffer. Each laboratory was requested to amplify the DNA with the primer mixes and perform SBT on the resulting PCR protocols, using their own protocols, and return the typing results for analysis. The reported results indicated that the expected sequence could be obtained with a variety of PCR amplification and sequencing platforms and protocols. There were difficulties but these seemed unrelated to STAmp reagents and suggest that optimal SBT results can be obtained if bi-directional sequencing is performed and software is used for sequence verification and editing. This indicates that SBT by STAmp can be applied in many laboratories for high-throughput HLA-DRB1 and HLA-DRB3,4,5 SBT.

HLA-A towards a high-resolution DNA typing.

Sequencing-based typing (SBT) and sequence-specific oligonucleotide probing (PCR-SSOP) are DNA-based typing approaches to identify HLA-A alleles. In this study PCR-SSOP SBT have been evaluated and considered to reach a high-resolution typing. Based upon serological typing, 32 genomic samples were typed by SBT and PCR-SSOP Three main clusters of resolution could be defined. The advantage of the PCR-SSOP approach is the possibility to type numerous samples in a short time. SBT minimizes the number of ambiguous heterozygous combinations and often allows direct detection and identification of new alleles.

HLA-A*3306, a novel variant in the Indian population.

We describe a new HLA-A allele, A*3306, which was identified by sequencing based typing (SBT) in an individual of Indian origin. A*3306 is similar to A*3303, with a difference at position 228 (A to G). This difference leads to an amino-acid change at codon 52 from Ile (ATA) to Met (ATG). Until now this position has been considered conserved.

An evaluation of a multicenter study on HLA-DPB1 typing using solid-phase Taq-cycle sequencing chemistry.

In HLA Class II genes, polymorphism is mainly located in the second exon. Most DNA based typing methods are confined to the identification of specific sequence motifs in the second exon. In contrast, Sequencing Based Typing (SBT) elucidates the entire exon 2 sequence for typing. Comparison of the obtained exon 2 sequence with an allele sequence library results in allele assignment. We tested the applicability of SBT using a protocol for amplification followed by solid phase Taq-cycle sequencing for HLA-DPB1 typing. A panel of 32 samples were typed by SBT at five test sites which are participating in the Sequencing Based Typing component of the 12th International Histocompatibility Workshop. The panel represents the existing polymorphism at all known polymorphic positions of exon 2, both in homozygous and heterozygous combinations. In this multicenter study we focused on the reliability of analyzing heterozygous sequences for HLA typing. A multi-sequence analysis approach, Polall, was developed to evaluate sequences obtained. The assignment of homozygosity and heterozygosity was validated by cluster analysis of chromatographic data of all sequences. Sequence characteristics were examined and considered for appropriate assignment. Differences in sequence characteristics that occurred between the test sites are considered in detail. The evaluation of data of 5 test sites reveals that Taq-cycle sequencing can reliably be performed for HLA-DPB1 SBT.

Sequencing-based typing reveals new insight in HLA-DPA1 polymorphism.

An HLA-DPA1 sequencing-based typing (SBT) system has been developed to identify DPA1 alleles. Up to now eight DPA1 alleles have been defined. Six can be discriminated based upon exon 2 polymorphism. The three subtypes of DPA1*01: DPA1*0101, DPA1*0102 and DPA1*0103, have identical exon 2 sequences but show differences in exon 4. Exon 4 sequences were known for only the three DPA1*01 subtypes and for DPA1*0201. We now present additional sequence information for exon 4 and the unknown segments at the 3' end of exon 2. Additionally with the use of this sequencing technique it is also possible to identify previously unidentified polymorphism. We have studied the exon 2 and exon 4 polymorphism of DPA1 in 40 samples which include all known DPA1 alleles. A new allele, DPA1*01 new, was identified which differs by one nucleotide in exon 2 from DPA1*0103, resulting in an aspartic acid at codon 28. The DPA1*01 subtypes DPA1*0101 and DPA1*0102 could not be confirmed in samples which previously were used to define these subtypes, and consequently they do not exist. The exon 4 sequence of DPA1*0201 is corrected based on sequence data of DAUDI, the cell line in which DPA1*0202 was originally defined. The exon 4 regions of the remaining four alleles were resolved: the exon 4 regions of the alleles DPA1*02021 and DPA1*02022 were found to be identical to the--corrected--DPA1*0201 whereas the exon 4 region of DPA1*0301 differs by one nucleotide compared to DPA1*0103. The DPA1*0401 exon 4 region differs by one nucleotide compared to the corrected DPA1*0201.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparison of DRB sequence-based typing using different strategies.

Sequence-based typing (SBT) has become an important tool in the identification of HLA alleles. In this study a comparison was made between SBT of DRB1/3/4/5 alleles performed in two laboratories each using a different strategy for SBT. The laboratories in Utrecht and in Maastricht performed direct sequencing of PCR amplified genomic DNA from 30 selected samples. Primers and conditions for PCR amplification were different. Sequencing was either performed with T7 polymerase, using internal sequencing primers, or with cycle sequencing using an M13 tailed system. Two different automated DNA sequencers were used; the ALFexpress from Pharmacia and Applied Biosystems 373A. We concluded that nor the method of sequencing nor the sequencing machine influences typing results. However the PCR reaction used for generating template DNA is the most critical step. Different primers and different conditions can lead to false negative reactions. The fact that these false negative reactions can occur with different alleles in different combinations but not in all, implicates that extensive quality control is needed to assure correct typing results.

Sequenase sequence profiles used for HLA-DPB1 sequencing-based typing.

Sequencing-based HLA typing (SBT) is a PCR based high resolution HLA typing method in which polymorphic regions of the gene are sequenced and directly used for typing. Currently, for class II SBT, alleles are identified by comparison of the exon 2 sequence with their corresponding allele sequence library. Routine SBT requires reliable identification of heterozygosity, and automated assignment of the alleles. In sequencing strategies different enzymes can be used for primer extension. The most characteristic difference between sequences obtained by two protocols using Sequenaseregistered, or Taq-cycle sequencing, respectively, is a difference in incorporation of nucleotides in the primer extension leading to different sequence profiles. In Taq-cycling sequencing variable nucleotide incorporation results in irregular, but reproducible peak patterns, whereas Sequenase incorporates nucleotides in nearly equal amounts, resulting in more even peak patterns. In a previously published multi-center study we evaluated HLA-DPB1 SBT using Taq-cycle sequencing, and showed that typing can reliably be performed, considering the specific sequence profiles. In this study the applicability of Sequenase for HLA-DPB1 SBT was tested. A panel of samples were typed by SBT at five test sites which participate in the Sequencing Based Typing component of the 12th International Histocompatibility Workshop. The panel represents the existing polymorphism at all known polymorphic positions of exon 2, both in homozygous and heterozygous combinations. The assignment of homozygosity and heterozygosity was validated by Multi-Sequence Analysis, performing cluster analysis of chromatographic data of all sequences at each position. Sequence characteristics were examined and considered for appropriate assignment. Data reveals that Sequenase sequencing can also reliably be used for HLA-DPB1 typing.

DPB1*7601, a novel DPB1 variant in the Caucasoid population.

A new DPB1 allele has been identified in a Caucasoid individual, DPB1*7601. The sequence of the complete second exon has been confirmed by cloning and subsequent sequencing. This allele differs by one amino acid, at codon 36, from DPB1*1401, as indicated by SBT and PCR-SSP analysis. The amino-acid motif introduced by the change is shared by DPB1*0401 and some rare alleles. It remains unclear whether the change is due to interallelic microgen conversion or a single point mutation.

Sensitive detection of p53 mutation: analysis by direct sequencing and multisequence analysis.

In a wide variety of tumors, p53 mutations may have prognostic and diagnostic value. However, mutational screening methods often are restricted to the core domain and, therefore, do not detect all mutations. We improved existing sequencing-based mutation analysis methods consisting of direct sequencing of all exons of the p53 gene and RNA. Multisequence analysis software was developed and applied to increase the sensitivity of mutation identification. Multisequence analysis compares a large number of sequences and identifies profiles with additional small peaks, potentially indicating a mutation. Concordance between blood and tumor sequences indicates polymorphism, whereas discordance indicates a mutation. We could detect mutations with a limit of approximately 5% to 10% mutated DNA. In our ongoing studies, we applied sequencing-based mutation analysis for more than 50 patients with head and neck squamous cell carcinoma and identified mutations in more than 95% of all tumors. We encountered some differences between the previously published reference p53 sequence and all our sequences and identified polymorphism in six regions.

High level of chromosome 15 aneuploidy in head and neck squamous cell carcinoma lesions identified by FISH analysis: limited value of beta2-microglobulin LOH analysis.

In cancer research, loss of heterozygosity (LOH), defined by microsatellite markers, is frequently used in the identification of gene loss. Especially, genomic alterations in the human leukocyte antigen (HLA) genes and the beta2-microglobulin (beta2m) gene on chromosome 15 are of interest regarding their function in the immune system. Because LOH analysis detects any allelic imbalance and not just allelic loss, we evaluated the LOH analysis in 11 head and neck squamous cell carcinoma (HNSCC) lesions using fluorescence in situ hybridization (FISH). The 11 tumors were selected out of 53 HNSCC lesions based upon beta2m LOH analysis and beta2m expression. Centromere 1 and 15 FISH were developed to determine the chromosome 15 copy number. Sequence-based mutation analysis of beta2m was conducted on tumors without beta2m expression; no mutations in the coding sequences were found. For five HNSCC lesions with LOH and beta2m expression, centromere 15 FISH indicated gain rather than loss. In the majority of the 11 HNSCC lesions, FISH showed centromere 1 and 15 heterogeneity throughout the tumor. Moreover, FISH indicated a more complex chromosome 1 and 15 distribution than could be concluded from microsatellite LOH analysis. Our results show that microsatellite LOH analysis does not represent the beta2m gene copy number and support the results obtained from comparative genomic hybridization (CGH) studies. Conclusions on genomic alterations in tumors cannot be based on LOH data only but depend on the results of immunohistochemical staining, FISH, and CGH.

Sequencing analysis of RNA and DNA of exons 1 through 11 shows p53 gene alterations to be present in almost 100% of head and neck squamous cell cancers.

Data on p53 alterations in human cancers are mainly based on studies restricted to the core domain (exons 5-9), because mutations outside this region are assumed to be rare. To test this assumption, we studied 25 consecutive patients with primary, untreated head and neck squamous cell carcinoma (HNSCC) with a p53 mutation analysis strategy that consists of sequencing all 11 p53 exons and the complete p53 mRNA. With this method, we encountered p53 mutations in 91% of patients; 33% of these were located outside the core domain. Overexpression of the p53 protein was assessed with staining with antibody Bp 53-12-1. Protein overexpression was found in 64%. In one case, p53 overexpression occurred without p53 gene mutations. Analysis of tumor tissue from two autopsied patients with multiple lesions in the head and neck and at distant sites allowed analysis of the clonal relationship of the different tumor foci. In one patient, the head and neck lesion had a mutation different from the one observed at the distant sites, suggesting two different primary tumors, one of them leading to widespread metastastic disease. In all lesions from the second patient, the same mutation was found, suggesting one primary that had metastatized. It appears that sequencing of all exons of the p53 gene is vital for assessment of the real incidence of p53 mutations in HNSCC, because 33% of all mutations are located outside the core domain, leading to a mutation frequency of almost 100% in HNSCC. In 96% of cases, either presence or absence of p53 protein expression could be explained by the type of p53 gene mutation. When only analyzing the p53 core domain, the incidence of p53 mutations in HNSCC is underestimated.