Detection of HLA polymorphisms by ligase detection reaction and a universal array format: a pilot study for low resolution genotyping (original) (raw)
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Multiplex single nucleotide extension: a robust and high throughput method for HLA-A locus typing
Human Immunology, 2003
This report describes a typing method that can identify all known human leukocyte antigen A (HLA-A) alleles by determining nucleotides present at polymorphic sites using single nucleotide extension. Allele specific primers are bound to capture oligonucleotides which allows for a multiplex approach during single nucleotide extension (SNE) reactions. Eleven group-specific polymerase chain reaction amplifications were performed to obtain the templates to be analyzed with sets of primers designed to investigate the polymorphisms. Extension of biotin-labeled ddNTPs onto allele-specific primers was catalyzed by a DNA polymerase and each primer was hybridized to a specific capture oligonucleotide covalently bound to a bead. After staining with streptavidin-PE, incorporated fluorescence was determined with a flow cytometer. Fluorescence intensities were interpreted by computer and the nucleotide sequence was translated into HLA-A genotypes. Group-specific amplification reactions and primer sets for SNE were validated with 42 reference samples of known HLA-A alleles. In addition, 296 samples from three populations (N. A. Caucasian, African-American, Terena S. A. Indian) were analyzed and results compared to previous typing by SSOP. Reproducibility between repeated typings was 100% and ambiguities were quite rare. The method has been found to be accurate, relatively simple to perform and fast. It is our method of choice for high resolution clinical HLA-A typing.
HLA-A towards a high-resolution DNA typing
Tissue Antigens, 1998
Sequencing-based typing (SBT) and sequence-specific oligonucleotide probing (PCRSSOP) are DNA-based typing approaches to identlfy HLA-A alleles. In this study PCR-SOP SBT have been evaluated and considered to reach a high-resolution typing. Based upon serological typing, 32 genomic samples were typed by SBT and FCR-SOP. Three main clusters of resolution could be defined. The advantage of the FCR-SOP 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.
Physical separation of HLA-A alleles by denaturing high-performance liquid chromatography
Tissue Antigens, 2003
Genomic typing of polymorphic loci may be hampered by ambiguous typing results. Moreover, robust methods for simultaneous sequencing of two alleles present in a given sample may be difficult to establish. We used denaturing high-performance liquid chromatography (DHPLC) for physical separation of HLA-A alleles before sequence-based genomic typing (SBT). Physical separation was achieved by resolution of heteroduplexes between the sample alleles and a modified reference probe by DHPLC followed by selective reamplification of the sample alleles present in heteroduplexes. Complementary strands of the reference probe and sample alleles for heteroduplex induction were obtained by l-exonuclease digestion. HLA-A genotyping of 101 individuals using DHPLC-SBT yielded better typing resolution compared with serological typing and genotyping by the sequence-specific primer-polymerase chain reaction (SSP-PCR) method. Physical separation of alleles using a modified reference probe allows for development of fully automated methods for genomic typing of highly polymorphic loci such as HLA.
A Generic Sequencing Based Typing Approach for the Identification of HLA-A Diversity
Human Immunology, 1997
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.
Journal of Clinical & Cellular Immunology
Human Leukocyte Antigen (HLA) encoding genes are part of the major histocompatibility complex (MHC) on human chromosome 6. This region is one of the most polymorphic regions in the human genome. Prior knowledge of HLA allelic polymorphisms is clinically important for matching donor and recipient during organ/tissue transplantation. HLA allelic information is also useful in predicting immune responses to various infectious diseases, genetic disorders and autoimmune conditions. India harbors over a billion people and its population is untapped for HLA allelic diversity. In this study, we explored and compared three HLA typing methods for South Indian population, using Sequence-Specific Primers (SSP), NGS (Roche/454) and single-molecule sequencing (PacBio RS II) platforms. Over 1020 DNA samples were typed at low resolution using SSP method to determine the major HLA alleles within the South Indian population. These studies were followed up with medium resolution HLA typing of 80 samples based on exonic sequences on the Roche/454 sequencing system and high-resolution (6-8 digit) typing of 8 samples for HLA alleles of class I genes (HLA-A, B and C) and class II genes (HLA-DRB1 and DQB1) using PacBio RS II platform. The long reads delivered by SMRT technology, covered the full-length class I and class II genes/alleles in contiguous reads including untranslated regions, exons and introns, which provided phased SNP information. We have identified three novel alleles from PacBio data that were verified by Roche 454 sequencing. This is the first case study of HLA typing using second and third generation NGS technologies for an Indian population. The PacBio platform is a promising platform for large-scale HLA typing for establishing an HLA database for the untapped ethnic populations of India.
Molecular typing of HLA genes using whole genome amplified DNA
Transfusion, 2009
The outcome of clinical transplantation and a number of disease susceptibilities show very strong associations with genetic variants within the major histocompatibility complex, particularly in the human leukocyte antigen (HLA) genes. A problem with many association studies is the lack of sufficient DNA to perform multiple genetic analyses, particularly with transplantation outcomes where donor and recipient DNA are often in short supply. This study assesses whether a multiple-strand displacement whole genome amplification (WGA) method could generate sufficient template of high quality to perform unbiased amplification for analysis of the HLA-A, -B, -C, -DRB1, and -DQB1 genes. STUDY DESIGN AND METHODS: A panel of DNA samples from various biological sources was subjected to WGA reaction using F29 DNA polymerase. The HLA genotypes were subsequently determined using standard polymerase chain reaction (PCR)-based methods including sequence-specific oligonucleotide probes (PCR-SSOP, Luminex, Luminex Corp.) and sequencebased typing (PCR-SBT). WGA products and original DNA samples were used to determine the sensitivity of the Luminex assay; in addition, reamplified WGA products were also genotyped. RESULTS: The WGA templates, as well as serially amplified DNA for two successive rounds, yielded HLA genotypes fully concordant with those determined for the original DNA samples. WGA products and original DNA gave reproducible HLA-DQB1 genotypes with 100 to 10 ng of template. Purification of the WGA products was required for successful PCR-SBT, but not for the PCR-SSOP method. CONCLUSION: Our study suggests that WGA can be a reliable method for generating unlimited DNA for medium-or high-resolution HLA typing using the techniques described above. ABBREVIATIONS: MDA = multiple displacement amplification; SBT = sequence-based typing; SSOP = sequence-specific oligonucleotide probes; WGA = whole genome amplification.
Ultraspecific probes for high throughput HLA typing
BMC Genomics, 2009
The variations within an individual's HLA (Human Leukocyte Antigen) genes have been linked to many immunological events, e.g. susceptibility to disease, response to vaccines, and the success of blood, tissue, and organ transplants. Although the microarray format has the potential to achieve high-resolution typing, this has yet to be attained due to inefficiencies of current probe design strategies.
A multi-site study using high-resolution HLA genotyping by next generation sequencing
Tissue Antigens, 2011
The high degree of polymorphism at HLA class I and class II loci makes high resolution HLA typing challenging. Current typing methods, including Sanger sequencing, yield ambiguous typing results due to incomplete genomic coverage and inability to set phase for HLA haplotype determination. The 454 Life Sciences GS FLX next generation sequencing system coupled with Conexio ATF software can provide very high resolution HLA genotyping. High throughput genotyping can be achieved by use of primers with multiplex identifier (MID) tags to allow pooling of the amplicons generated from different individuals prior to sequencing. We have conducted a double blind study in which eight laboratory sites performed amplicon sequencing using GS FLX standard chemistry and genotyped the same 20 samples for HLA-A,-B,-C, DPB1, DQA1, DQB1, DRB1, and DRB3, DRB4 and DRB5 (DRB3/4/5) in a single sequencing run. The average sequence read length was 250 base pairs (bp) and the average number of sequence reads per amplicon was 672, providing confidence in the allele assignments. Of the 1280 genotypes considered, assignment was possible in 95% of the cases. Failure to assign genotypes was the