A novel immunocomplex capture fluorescence assay (ICFA) using fluorescent beads and transfected cells for specific identification of human neutrophil antigen (HNA)-1a and -1b antibodies.

BACKGROUND: To identify specific human neutrophil antigen (HNA) antibodies, assays using neutrophils such as monoclonal antibody-specific immobilization of granulocyte antigens (MAIGA) are recommended. However, these assays are limited by labor-intensive neutrophil preparation and varying antigen expression levels. METHODS: We evaluated a newly developed immunocomplex capture fluorescence assay (ICFA) for identifying HNA-1 antibodies and compared it to MAIGA and LABScreen Multi (LABM), which utilizes recombinant HNA-coated Luminex beads. For ICFA, HNA-1a or HNA-1b transfected cells replaced neutrophils. Cells incubated with serum were lysed, and immune complexes were captured using five CD16 monoclonal antibody-conjugated Luminex beads. Nine antisera with known specificity and 26 samples suspected of containing HNA antibodies were analyzed by ICFA and MAIGA using neutrophils or transfected cells (ICFA-N or ICFA-T, and MAIGA-N or MAIGA-T, respectively). RESULTS: ICFA-T and MAIGA-N accurately determined the specificity of all antibodies in the nine antiserum samples. The ICFA-T detection limit was 2048-fold for anti-HNA-1a and 256-fold for anti-HNA-1b; the limits of MAIGA-T, MAIGA-N, and LABM were 32-, 4 ~ 64-, and 128-fold for anti-HNA-1a and 64-, 16 ~ 64-, and 32-fold for anti-HNA-1b, respectively. Twelve and 7 of the remaining 26 samples tested negative and positive, respectively, in both ICFA-T and MAIGA-N. Antibody specificity against HNA-1a or HNA-1b determined using ICFA-T agreed with that determined using MAIGA-N and LABM. Another seven samples tested positive in ICFA-T but negative in MAIGA-N. CONCLUSION: The novel ICFA is highly sensitive and exhibits specificity similar to MAIGA and LABM for detecting HNA-1 antibodies.

A novel swab storage gel is superior to dry swab DNA collection, and enables long-range high resolution next generation sequencing HLA typing from buccal cell samples.

HLA sequence-based DNA typing (SBT) by long-range PCR amplification (LR PCR) and next-generation sequencing (NGS) is a high-throughput DNA sequencing method (LR-NGS-SBT) for the efficient and sensitive detection of novel and null HLA alleles to the field-4 level of allelic resolution without phase ambiguity. However, the accuracy and reliability of the HLA typing results using buccal cells (BCs) and saliva as genetic source materials for the LR-NGS-SBT method are dependent largely on the quality of the extracted genomic DNA (gDNA) because a large degree of gDNA fragmentation can result in insufficient PCR amplification with the incorrect assignment of HLA alleles because of allele dropouts. In this study, we developed a new cost-efficient swab storage gel (SSG) for wet swab collection of BCs (BC-SSG) and evaluated its usefulness by performing different DNA analytical parameters including LR-NGS-SBT to compare the quality and quantity of gDNA extracted from BCs (in SSG or air dried), blood and saliva of 30 subjects. The BC-SSG samples after 5 days of storage revealed qualitative and quantitative DNA values equivalent to that of blood and/or saliva and better than swabs that were only air-dried (BC-nSSG). Moreover, all the gDNA extracted from blood, saliva and BC-SSG samples were HLA-typed successfully to an equivalent total of 408 alleles for each sample type. Therefore, the application of BC-SSG collection media for LR-NGS-SBT has benefits over BC dried samples (dry swabs) such as reducing retesting and the number of untestable BC samples because of insufficient DNA amplification.

A new HLA-C allele with an alternative splice site in exon 3: HLA-C*03:23N.

We identified a probable new null HLA-C allele, C*03:23N, which originated from C*03:04:01:02, but does not react with Cw3 antibodies. This allele was identified by sequence analysis, which indicated that a single G-to-A substitution at position 406 in exon 3 created a null allele under a new mechanism: the mutation changes the position of the intron 2-exon 3 splice site to be further into exon 3, leading to a frameshift and a premature stop codon. Sequence analysis of cDNA confirmed the existence of the causative alternative acceptor splice site and the resultant deletion of 64 nucleotides in exon 3. Analysis of 220 blood or bone marrow donors in Japan with C*03:23N demonstrated that Japanese HLA-C*03:23N is on the haplotype A*26:01∼C*03:23N∼B*40:02∼DRB1*09:01.