S. Heron

Next-generation sequencing: the solution for high-resolution, unambiguous human leukocyte antigen typing

Human leukocyte antigen (HLA) typing has been a challenge for more than 50 years. Current methods (Sanger sequencing, sequence-specific primers [SSP], sequence-specific oligonucleotide probes [SSOP]) continue to generate ambiguities that are time-consuming and expensive to resolve. However, next-generation sequencing (NGS) overcomes ambiguity through the combination of clonal amplification, which provides on-phase sequence and a high level of parallelism, whereby millions of sequencing reads are produced enabling an expansion of the HLA regions sequenced. We explored HLA typing using NGS through a three-step process. First, HLA-A, -B, -C, -DRB1, and -DQB1 were amplified with long-range PCR. Subsequently, amplicons were sequenced using the 454 GS-FLX platform. Finally, sequencing data were analyzed with Assign-NG software. In a single experiment, four individual samples and two mixtures were sequenced producing >75 Mb of sequence from >300,000 individual sequence reads (average length, 244 b). The reads were aligned and covered 100% of the regions amplified. Allele assignment was 100% concordant with the known HLA alleles of our samples. Our results suggest this method can be a useful tool for complete genomic characterization of new HLA alleles and for completion of sequence for existing, partially sequenced alleles. NGS can provide complete, unambiguous, high-resolution HLA typing; however, further evaluation is needed to explore the feasibility of its routine use.

Determining performance characteristics of an NGS-based HLA typing method for clinical applications

This study presents performance specifications of an in‐house developed human leukocyte antigen (HLA) typing assay using next‐generation sequencing (NGS) on the Illumina MiSeq platform. A total of 253 samples, previously characterized for HLA‐A, ‐B, ‐C, ‐DRB1 and ‐DQB1 were included in this study, which were typed at high‐resolution using a combination of Sanger sequencing, sequence‐specific primer (SSP) and sequence‐specific oligonucleotide probe (SSOP) technologies and recorded at the two‐field level. Samples were selected with alleles that cover a high percentage of HLA specificities in each of five different race/ethnic groups: European, African‐American, Asian Pacific Islander, Hispanic and Native American. Sequencing data were analyzed by two software programs, Omixons target and GenDxs NGSengine. A number of metrics including allele balance, sensitivity, specificity, precision, accuracy and remaining ambiguity were assessed. Data analyzed by the two software systems are shown independently. The majority of alleles were identical in the exonic sequences (third field) with both programs for HLA‐A, ‐B, ‐C and ‐DQB1 in 97.7% of allele determinations. Among the remaining discrepant genotype calls at least one of the analysis programs agreed with the reference typing. Upon additional manual analysis 100% of the 2530 alleles were concordant with the reference HLA genotypes; the remaining ambiguities did not exceed 0.8%. The results demonstrate the feasibility and significant benefit of HLA typing by NGS as this technology is highly accurate, eliminates virtually all ambiguities, provides complete sequencing information for the length of the HLA gene and forms the basis for utilizing a single methodology for HLA typing in the immunogenetics labs.

Identification of a novel HLA-DQB1*02 variant allele, DQB1*02:01:06.

The new HLA-DQB1 allele most closely resembles DQB1*02:01:01, differing at a single position 141 (exon 2, codon 15.3).

Identification of a novel HLA-A*23 variant allele, A*23:50.

HLA-A*23:50 differs from HLA-A*23:01:01 by one nucleotide at position 112 resulting in an amino acid change, Arginine to Tryptophan, at codon 14 of exon 2.

Characterization of a new HLA-C*04 allele, C*04:112.

HLA-C*04:112 differs from HLA-C*04:01:01:01 by one nucleotide at position 270 resulting in an amino acid change, Lysine to Asparagine, at codon 66 of exon 2.