HLA-A*2416: a new allele of the HLA-A19 lineage

We here report on a new HLA-A19 allele (A*2416) found in a German kidney recipient. Serological class I typing revealed HLA-A11,19 without clear definition of the A19 split antigen. As with serology, polymerase chain reaction (PCR)-based typing also revealed inconclusive results. We therefore sequenced the gene from the 5' flanking region through the 3'-end of exon 4 of this allele after haplotype-specific PCR amplification. The sequence analysis revealed a new HLA-A allele which is identical to A*3101 with the exception of the 3' half of exon 2 which is identical to the common A9 alleles. The phylogenetic analysis constructed with the nearest-neighbor algorithm and based on exons 1-4 or introns 1-3 clearly indicated, that A*2416 belongs unequivocally to the A19 lineage.     

Identification and sequence characterization of a novel HLA-A11 serological variant (HLA-A*1108)

In this report we describe the identification of a novel HLA-A*11 allele, HLA-A*1108, found in two individuals of a Spanish family. This new allele was detected during routine HLA typing by an atypical serological reactivity pattern and by inconclusive patterns obtained in DNA-based typing methods. The nucleotide sequence of exons 2 and 3 of HLA-A*1108 was identical to HLA-A*11011 except for two nucleotide substitutions at codons 152 (GCG-->GAG) and 156 (CAG-->CGG). These mutations change the non-charged amino acid alanine, at codon 152, to negative glutamic acid, and also non-charged glutamine, at codon 156, to positive arginine, which may explain its anomalous serological reactivity.     

A Generic Sequencing Based Typing Approach for the Identification of HLA-A Diversity

ABSTRACT: 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.     

A new HLA-A*02 allele, A*0234, detected by polymerase chain reaction using sequence-specific primers (PCR-SSP)

A novel HLA-A*02 allele, A*0234, was identified in a potential unrelated bone marrow donor typed by polymerase chain reaction using sequence-specific primers (PCR-SSP). Positive reactions obtained upon testing with PCR-SSP did not fit any known combination of alleles indicating the possible presence of a novel allele. Sequencing of clones from this individual revealed the presence of a novel allele, HLA-A*0234. The sequence of exons 2, 3 and part of exon 4 showed that A*0234 differed from A*02011 by a single nucleotide in exon 2 at position 282 (C to G). The nucleotide substitution results in an amino acid change at residue 70 (Histidine to Glutamine) in the alpha1 domain.     

Expression defect of an HLA-A*24 allele associated with DNA methylation in a normal individual

Non-expressed HLA alleles become a potential problem in the transition of the HLA typing methodology from serologic typing to more accurate DNA typing. In this study, a novel nonexpressed A*24 allele identified from two members of a Korean family was characterized. At the DNA sequence level, the nonexpressed allele (A*24023) is apparently normal; the complete genomic sequence was identical to HLA-A*2402101, from the 5'-upstream region to the 3'-downstream region, except for a single silent substitution at codon 211 (GCG-->GCA) in exon 4. A DNA methylation analysis using methylation-sensitive restriction enzymes, however, showed that the nonexpressed A*24023 allele from an apparently normal individual was highly methylated in regions covering exons and introns as well as the 5'-upstream region. This result suggests that hypermethylation of the HLA-A gene may induce gene inactivation in the normal individuals.     

New HLA-A*11 allele,A*1112, identified by sequence-based typing

In this report, we describe the identification of HLA-A*1112, a novel HLA-A*11 allele found in two Italian families. The new allele was detected during routine HLA typing by a polymerase chain reaction sequence-specific primer and was confirmed by high-resolution sequencing-based typing. The nucleotide sequences of HLA-A*1112 exons 2 and 3 are identical to HLA-A*11011 except for a single nucleotide substitution in codon 90 (GAC-->GCC).     

Identification of two new HLA-A alleles,A*2419 and A*3011, by sequence-based typing

In this report, we describe two new HLA-A alleles, A*2419 and A* 3011, that were initially recognized by an aberrant serological pattern. Sequence-based typing revealed sequence differences with other known HLA-A alleles. Allele A*2419 showed 4 nucleotide differences with A*2404, resulting in 4 amino acid differences at codons 70, 76, 77 and 90. Compared with other A*24 alleles, A*2419 lacks the Bw4 motif, as do A*2404 and A*2428. The A*3011 allele showed 2 mismatches with A*3001, resulting in one amino acid difference at codon 80.     

Identification of HLA-A*0111N: a synonymous substitution, introducing an alternative splice site in exon 3, silenced the expression of an HLA-A allele

A new variant of the HLA-A*010101 allele designated as HLA-A*0111N, previously known as HLA-A*010101var, was identified in a patient requiring a stem-cell transplantation. The patient was typed by serologic methods as HLA-A2 homozygous and by sequence-based typing (SBT) as A*010101,020601. Flow-cytometric (FCM) analysis with 11 human monoclonal antibodies (mAbs) for the A1 molecule confirmed lack of any cell membrane expression of the A*0111N allele. One-dimensional isoelectric focusing (1D-IEF) of total cell lysate from the patient's cells revealed no cell surface and cytoplasmic A1 protein expression, whereas the HLA-A2 molecule was identified by both FCM analysis and 1D-IEF. DNA sequence analysis showed the presence of a synonymous substitution from G to T at position 597 in codon 175. RNA SBT revealed a deletion of 24 bp in exon 3, position 596 through 619, encoding codons 175 through 182 of the HLA-A*0111N allele. The synonymous substitution introduced a new splice site, resulting in an efficient splicing, because no classical A1 protein could be detected in the patient. This alternative splicing prevented the translation into a correct and stable class I molecule expression on the cell surface.     

HLA-A*02010102L: a laborious assignment

In the present report we describe the laborious identification of the A*02010102L allele found in three healthy individuals of a French family who have shown a reduced A2 antigen expression using serological tests since the 1980s. PCR-SSP typing showed a classical A*0201 allele. Sequencing of exons 2, 3 and 4 confirmed this assignment. Sequencing of the whole gene (promoter, introns and exons 1-8) revealed one single point mutation (T to C) at position -101 in the enhancer B element region compared to the A*02010101 allele. This single mutation appears to be related to the reduced expression of the A2 antigen. This allele segregates with the haplotype Cw*12, B44, DR7, DQ2, which is different to the one described earlier.     

Novel HLA-A*31 allele, A*3111 identified by sequence-based typing

In this report, we describe the identification of an HLA-A*31 nucleotide sequence variant, a new HLA-A*3111, in three members of a Korean family by using sequence-based typing (SBT). The new allele was detected during routine HLA typing by high-resolution SBT. Allele A*3111 showed one nucleotide difference with A*310102 at codon 165 (GTG-->CTG) resulting in an amino acid change from valine to leucine (V165L). Serologic reactivity was shorter than normally expected.     

Recognition of HLA-A*0248 in a Chinese donor.

HLA-A*0248, a rare allele originally found in an individual of Filipino background, was detected in a Chinese donor. We confirmed the novel sequence and analysed its serological reaction pattern. The exon 2 sequence of A*0248 was apparently generated in a gene conversion event with an A2 gene, receiving a sequence segment comprising codons 56 to 74 from an A*24 donor gene. Serological typing showed a clear-cut A2 reaction pattern, indicating that the three amino acid positions 62, 65 and 74, are probably not a critical part of the A2 epitope. Our typing experience also demonstrated that different typing technologies often complement each other in fine HLA typing.     

Novel HLA-A*11 allele, A*1120, identified by sequence-based typing

In this report, we describe the identification of a human leucocyte antigen-A*11 (HLA-A*11) nucleotide sequence variant, a new HLA-A*1120 by using sequence-based typing (SBT). The new allele was detected during routine HLA typing by high-resolution SBT. Allele A*1120 showed one nucleotide difference with A*110101 at codon 152 (GCG-->GAG) resulting in an amino acid change from alanine to glutamate. Residue 152 is located on alpha(2)-helix of HLA class I molecule and involved in peptide binding by constructing E pocket of peptide-binding groove, implying that the change of the residue 152 would affect the binding affinity of peptides to A*1120 allele.     

A nucleotide insertion in exon 4 is responsible for the absence of expression of an HLA-A*01 allele

HLA class I typing performed in parallel by molecular biology and serology has revealed cases where an HLA class I allele was identified whereas the corresponding antigen was not detected on the cell surface. In the present report, we describe four members of a family in whom an HLA-A 1 allele identified at the molecular level was typed as A "blank" by lymphocytotoxicity. This serologically blank antigen was undetectable by isoelectric focusing (IEF). Sequencing of the HLA-A*01 allele from the promoter region to the eighth exonic region revealed insertion of a "C" nucleotide at the beginning of the fourth exon as compared to the common HLA-A*0101 allele. This mutation causes a frame shift, giving rise to an early stop codon in the fourth exon.     

An intronic mutation responsible for a low level of expression of an HLA-A*24 allele

HLA class I typing performed in parallel by molecular biology and serology has revealed cases where an HLA class I allele was identified but the corresponding antigen on the cell surface was not detected. In the present report, we describe three members of a family in whom an HLA-A24 allele identified at the molecular level was typed as A "blank" by lymphocytotoxicity. This serologically blank antigen was nevertheless faintly detectable by isoelectric focusing (IEF) and FACS analyses. Sequencing of the HLA-A*24 allele from the promoter region to the eighth exonic region revealed a point mutation in the acceptor site of the second intron as compared to the normal HLA-A*24 allele. This mutation could lead to incorrect processing of mRNA through a cryptic acceptor site located at the beginning of the third exon and hence to alternative splicing with a frame shift introducing an early stop codon into the fourth exon.     

New HLA-DRB1* nucleotide sequence of Italian origin: HLA-DRB1*13022

High-resolution polymerase chain reaction using sequence-specific primer typing of the HLA-DRB1 gene of an Italian patient waiting for unrelated bone marrow transplantation revealed a new allelic variant of HLA-DRB1*13. Sequencing the exon 2 of DRB1* gene demonstrated a G-->C transition at the nucleotide 216 resulting in a silent mutation at codon 72: CGG-->CGC. The closest sequence was the HLA-DRB1*1302 and the new allele was named HLA-DRB1*13022. This variant was carried by the haplotype HLA-A*24; Cw*0702; B*39; DRB1*13022; DRB3*0301; DQA1*0102; DQB1*0604 as demonstrated by a family study.     

Identification of a new human leukocyte antigen A allele, HLA-A*3020

A new human leukocyte antigen (HLA) A allele, HLA-A*3020, was found during routine HLA genotyping by polymerase chain reaction–sequence specific oligonucleotide probes and sequencing-based typing. The A*3020 allele has one nucleotide change at position 294 of exon 2 from the closest matching allele A*300101, resulting in an amino acid change from D (GAC) to E (GAA) at codon 98.     

Identification of an HLA-A11 serological variant and its characterization by sequencing based typing

We have identified an HLA-A11 variant allele, A*1105, segregating in a Caucasoid family. The variant antigen expressed by this allele failed to cross-react with most Caucasoid anti-HLA-A11 antisera tested. Sequencing based typing has been used to characterize this new allele and this showed that it has a novel mutation at a polymorphic position (502) in exon 3. In comparison with A*1101, the mutation (A-->G) results in an amino acid change from positively-charged lysine to negative glutamate and this may explain the altered HLA-A11 serological profile exhibited by this antigen. The new allele was found in a patient with acute lymphoid leukaemia (ALL), her father and two siblings.     

Identification of two novel HLA-A*02 variants, A*02:319 and A*02:01:64, in two Taiwanese marrow stem cell donors by sequence-based typing

We report here two novel variants of HLA-A*02 allele, A*02:319 and A*02:01:64, discovered in two Taiwanese unrelated volunteer bone marrow donors by sequence-based typing (SBT) method. The DNA sequence of A*02:319 is identical to A*02:07 in exons 2 and 3 but varies with one nucleotide at codon 9 (TTC->TCC). The variation caused one amino acid substitution at residue 9 (F->S). On the other hand, the DNA sequence of A*02:01:64 is identical to the sequence of A*02:01:01:01 in exons 2 and 3 except a silent mutation at codon 114 (CAC->CAT). The probable HLA-A, HLA-B and HLA-DRB1 haplotypes in association with A*02:319 and A*02:01:64 were deduced as A*02:319-B*46:01-DRB1*04 and A*02:01:64-B*38:02-DRB1*16:02, respectively.     

A deletion in exon 3 results in a new HLA-A*01 null allele (A*0115N) in a Martinican woman

We report the identification of a new HLA-A null allele, HLA-A*0115N. This null allele has been identified within the A*01 group by a combination of serological and molecular typing [Polymerase chain reaction (PCR) sequence-specific primers, PCR sequence-specific oligoprobes and sequence-based typing (SBT)] in a potential intrafamilial bone marrow donor from Martinique (French West Indies). To characterize this A*01 null allele, we performed DNA typing by PCR-SBT on genomic DNA from the beginning of exon 2 (position 84) through the end of the exon 4 (position 895) and revealed a nucleotide deletion at the end of the exon 3. This sole difference between the new allele and the HLA-A*0101 generates a premature stop codon (TGA) in the beginning of exon 4. This deletion most likely explains the lack of cell surface expression of the encoded protein despite the presence of A*01 allele. The absence of correct expression of the antigen on the cell surface was confirmed by one-dimensional isoelectric focusing (1D-IEF). To date, this is the fourth null allele described within the A*01 group.     

Confirmation of the detection of HLA-A*0104N in a family: a PCR-SSP reaction for the allelic detection of HLA-A*0104N.

The allele A*0104N has been detected in a family with a patient requiring a bone marrow transplant. The allele was found as a consequence of a discrepant result when family members were typed using serology and polymerase chain reaction using sequence-specific primers (PCR-SSP). Serological typing gave an apparent HLA-A 'blank' while PCR-SSP revealed the presence of an A*01 allele in three family members who were serologically negative for A1. Sequencing-based typing (SBT) was then used to establish that the allele was A*0104N. A PCR-SSP reaction was subsequently designed and used for the allelic detection of A*0104N. The study highlights the potential risks involved if molecular technology is used for typing, unless all non-expressed alleles are specifically detected.