Anne G.M. Bouwens

High-resolution HLA-DPB typing based upon computerized analysis of data obtained by fluorescent sequencing of the amplified polymorphic exon 2.

To differentiate 32 HLA-DPB alleles, conventional techniques such as serology and cellular typing are inadequate for high-resolution DPB typing. The most refined DNA typing until now is SSO typing and new selected oligonucleotides can be added to this system to distinguish new allele sequences. DNA sequencing, however, reveals directly the sequence information of all polymorphic HVRs and has the advantage of being independent from exon polymorphisms. We have developed a new DNA-based typing approach that is rapid, fully automated, and therefore suitable for routine typing. The system is based upon direct sequencing of amplified DNA with fluorescent-labeled primers. The designation of alleles is obtained by a comparison of all polymorphic positions in the determined sequence with all known allele sequences retained in a database along with their heterozygous combinations. Sequence data at both constant and polymorphic positions are used for quality control. In this study, the typing results of a panel of 91 previous SSO-typed DNA samples are described. After comparison with the SSO-typing results, we conclude that with this SBT system allele assignment is reliable. The method is easy to perform since both sequencing and assignment are automated. Furthermore, the system is easily applicable to other gene systems.

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.

Asian Indian HLA-DR2-, DR4-, and DR52-related DR-DQ genotypes analyzed by polymerase chain reaction based nonradioactive oligonucleotide typing unique haplotypes and a novel DR4 subtype

We have employed a PCR-based nonradioactive technique using biotinylated SSOPs to define HLA-DR2-, 4-, DR51-, and DR52-associated DR-DQ genotypes in Asian Indian families. In the DR2 group, most haplotypes described by us in a previous study were confirmed by family analysis. Evidence for one additional haplotype was available in this study. The classic DRB1*1501- and DRB1*1502-associated caucasoid haplotypes occurred with an appreciable frequency in Asian Indians, but two of the DRB1*1601-associated Caucasoid haplotypes were absent. At least six unique and unusual DR2-associated genotypes were encountered. In the DR52 group, the three most common alleles are DRB1*0301, DRB1*1404, and DRB1*1101. The DR6-associated alleles were DRB1*1301, 1302, 1401, and 1404. A few unique haplotypes occurred with low frequency in this group. In the DR4 group, at least three unusual patterns of hybridization were noticed by family analysis. One of these appears to be a novel DR4 subtype upon sequencing. These results demonstrate that, besides HLA-DR2, appreciable complexity occurs in the DR4- and DR52-associated alleles among Asian Indians. The presence of unique DR-DQ haplotypes in addition to those found characteristically among Western Caucasians suggests that the Indian population provides valuable source of many HLA class II haplotypes.

Exon 2, 3, and 4 polymorphism of HLA-DPA1.

Currently HLA-DPB1 typing is mainly performed by using DNA techniques based upon the identification of exon 2 polymorphism. A direct sequencing approach has recently been described for HLA-DPB1. Cellular DP reactivity, however, may also be dependent on HLA-DPA1 polymorphism. Polymorphism of HLA-DPA1 exon 2 and exon 4 has recently been described. In contrast to previous reports all DPA1 alleles can be discriminated on the basis of exon 2 polymorphism. 7 refs., 1 fig.