Allelic diversity within the high frequency Mamu-A2*05/Mane-A2*05 (Mane-A*06)/Mafa-A2*05 family of macaque MHC-A loci.

Macaque species serve as important animal models of human infection and immunity. To more fully scrutinize their potential in both the analysis of disease pathogenesis and vaccine development, it is necessary to characterize the major histocompatibility complex (MHC) class I loci of Macaca mulatta (Mamu), Macaca nemestrina (Mane), and Macaca fascicularis (Mafa) at the genomic level. The oligomorphic Mamu-A2*05/Mane-A2*05 (previously known as Mane-A*06) family of macaque MHC-A alleles has recently been shown to be present at high frequency in both Indian rhesus and pig-tailed macaque populations. Using a locus-specific amplification and direct DNA typing methodology, we have additionally found that the locus encoding this family is very prevalent (75%) among a sampling of 182 Chinese rhesus macaques and has a high prevalence (80%) within a larger, independent cohort of 309 pig-tailed macaques. Interestingly, among the Chinese rhesus macaques, only six alleles previously identified in Indian-origin animals were observed, while three recently identified in Chinese-origin animals and 25 new alleles were characterized. Among the pig-tailed macaques, we observed 1 previously known (Mane-A*06) and 19 new alleles. Examination of the orthologous locus in a preliminary sampling of 30 cynomolgus macaques showed an even higher presence (87%) of Mafa-A2*05 family alleles, with 5 previously identified and 15 new alleles characterized. The continued discovery of novel alleles and thus further diversity within the Mamu-A2*05/Mane-A2*05/Mafa-A2*05 family indicates that this MHC-A locus, although highly conserved across the three species of macaques, has remained a dynamic entity during evolution.

A nonsense mutation in exon 3 results in the HLA-B null allele B*5127N.

A new HLA-B null allele has been identified within the B*51 group by combined serological and molecular typing of an Italian Caucasoid family. Serological data indicated that the proband typed homozygous for A2 and B60. Confirmatory typing using sequence specific oligonucleotide hybridization (SSPOH) detected a second B allele within the B*51 group. Allele specific typing (SSP) for B*51 subtypes, including the known B*5111N allele, was performed, and typing results were consistent with B*5101, suggesting the presence of a new null variant. Cloning and sequencing of this allele identified a B*5101 variant with a nonsense mutation in exon 3. This new null allele has been designated B*5127N. The combined use of serologic and DNA-based typing methods facilitates the identification of null and low-expression alleles. An overview of null alleles of class I HLA is presented.

New HLA-B alleles identified and sequences extended in potential bone marrow donors: B*5804, B*4418, B*1558, and B*4805.

Nucleic acid-based methods for allele identification have revealed more than 470 polymorphic variants at the HLA-B locus. Screening of potential bone marrow donors with sequence specific primer polymerase chain reactions and sequence specific oligonucleotide probe hybridization assays revealed apparent variants within the B*58, *44, *15, and *48 allele groups. DNA sequencing of cloned DNA identified the new alleles B*5804, B*4418, and B*1558 within these groups and observed new sequence information for the previously reported allele B*4805. These findings further extend our knowledge of the substantial genetic variation present at the HLA-B locus within human populations.

Identification and sequencing of HLA-B*0714 and B*2718 alleles and novel exon 1 sequences of B*0709 and B*2714 alleles in potential bone marrow donors.

Sequence specific oligonucleotide probe hybridization and sequence specific primer PCR typing of volunteer bone marrow donors suggested the presence of variants of known HLA-B alleles in two individuals. PCR products encompassing HLA-B locus exons 1, 2, and 3 were prepared, subcloned and sequenced. A Hispanic individual had a novel B*07 allele (B*0714) and a Chinese individual had a novel B*27 allele (B*2718). In two other individuals, a previously unknown sequence of exon 1 was determined for HLA-B*0709 (African American) and B*2714 (Native American). These findings further illustrate the substantial genetic variation present at the HLA-B locus within human populations. We discuss the structural variation in the protein sequence for these HLA-B alleles and its potential functional effects.

Novel HLA-B alleles identified in potential marrow donors: B*3917, B*1405 and B*3528.

Sequence-specific oligonucleotide probe hybridization and sequence-specific primer polymerase chain reaction (PCR) typing of volunteer bone marrow donors suggested the presence of variants of known HLA-B alleles in five individuals. PCR products encompassing HLA-B locus exons 1 through 3 were prepared and subcloned. Three African-American individuals had a novel HLA-B*39 allele (B*3917), and another African-American was found to have a novel HLA-B*14 allele (B*1405). In a third individual of Hispanic origin, a novel HLA-B*35 allele (B*3528) was identified. These findings further illustrate the substantial genetic variation present at the HLA-B locus within human populations.

Novel HLA-B*15 alleles identified in potential marrow donors.

Several methods for low-resolution class I typing of potential bone marrow donors are available. The National Marrow Donor Program (NMDP) has initiated pilot projects for large-scale DNA-based class I typing to initially characterize donors. Sequence-specific oligonucleotide probe hybridization and sequence-specific primer polymerase chain reaction (PCR) screening of 3,500 NMDP potential donors suggested the presence of variants of known HLA-B*15 variants in 3 donors. PCR products encompassing HLA-B locus exons 1 through 3 were prepared and subcloned. Sequencing revealed 3 alleles differing from known HLA-B*15 alleles by nucleotide substitutions resulting in predicted novel HLA-B antigens. The new alleles occur in distinct ethnic groups. These findings further illustrate the substantial genetic variation present at the HLA-B locus within human populations.

A novel HLA-B*40 allele and novel exon 1 sequences of two B*40 alleles identified in potential marrow donors.

Sequence-specific oligonucleotide probe hybridization and sequence-specific primer polymerase chain reaction (PCR) typing suggested the presence of variants of HLA-B*40 in three individuals. Two were part of 3,500 potential marrow donors being screened for the National Marrow Donor Program, while the third was a clinical specimen. PCR products encompassing HLA-B locus exons 1 through 3 were prepared and subcloned. In one individual, a native of the Pacific Islands, sequencing revealed a novel HLA-B*40 allele (B*4023). In two other individuals, a previously unknown exon 1 sequence was determined for HLA-B*4016 (ethnicity unknown) and B*4020 (Hispanic). These findings further illustrate the substantial genetic variation present at the HLA-B locus within human populations.

Strategy for distinguishing a new DQB1 allele (DQB1*0611) from the closely related DQB1*0602 allele via sequence specific PCR or direct DNA sequencing.

A novel DQ6 allele (DQB1*0611) was identified via direct DNA sequencing in an African-American donor for bone marrow transplantation. The allele was not suspected on the basis of a sequence specific PCR assay which instead indicated the presence of DQB1*0602. DQB1*0602 and DQB1*0611 differ in exon 2 only at codon 9 resulting in a tyrosine substitution for phenylalanine. A modification of current DQB1 sequence specific PCR assays was devised which allows distinction between the closely related DQB1*0602 and DQB1*0611 alleles. Preliminary allele frequency studies suggest that DQB1*0611 is rare both in a non-African American sample and in American of African descent carrying DR11, DQ6 haplotypes. The selection of various DQB1*0611 detection methods is discussed.

Strategies for Unambiguous Detection of Allelic Heterozygosity via Direct DNA Sequencing of PCR Products: Application to the HLA DRB1 Locus.

Background: Many genetic loci exhibit substantial heterogeneity: the human leukocyte antigen (HLA) DRB loci include 139 alleles and the cystic fibrosis transmembrane regulator gene more than 500 known mutations. Identification of alleles at these loci is cumbersome with typical molecular diagnostic methods such as hybridization assays or restriction enzyme analysis. Direct DNA sequencing of polymerase chain reaction (PCR) products is a general approach to complex loci that allows detection of any allele within the nucleotide sequence analyzed. However, direct DNA sequence-based unambiguous identification of heterozygous nucleotide positions using PCR templates is a challenging problem. Methods and Results: The ability of direct DNA sequencing methods to accurately identify HLA DRB alleles was assessed. The authors evaluated the performance of modified T7 and Taq DNA polymerases in isothermal and thermal cycle sequencing of PCR products derived from HLA DRB genes in 235 individuals who were potential donors or recipients of bone marrow transplants. The uniformity of peak intensity and ability to identify heterozygous nucleotide positions was similar when either AmpliTaq FS- or Sequenase DNA polymerase-derived electropherograms were prepared. The modified Taq DNA polymerase allowed the use of unpurified, double-stranded PCR templates. Furthermore, this enzyme could be used in less laborious, less costly cycle sequencing assays coupled with automated fluorescent detection methodology. Direct sequencing performed with either enzyme allowed unambiguous identification of DRB1 alleles, resolution of difficult heterozygous combinations, and recognition of new alleles. Conclusions: The direct DNA sequencing methods employed here for HLA allele identification are relatively efficient and semiautomated, and may be reasonably considered as a general approach to other complex molecular diagnostic problems, especially when coupled to simplified sequencing chemistries allowing cycle sequencing.