Characterization of the novel HLA-C*07:195 allele in an Italian hematopoietic stem cell volunteer donor, detected by sequence-based typing.

The new allele shows one nucleotide change from C*07:02:01:01 at 351 nt from C to A, resulting in an amino acid change at codon 93 of exon 3 from H to Q.

Resolution of HLA class I sequence-based typing ambiguities by group-specific sequencing primers.

The increasing demand for allele-level human leukocyte antigen (HLA) typing has led the sequence-based typing (SBT) to become the preferred method. In turn, the steady increase in the number of HLA alleles driven by the adoption of SBT as the ultimate typing method leads to the ever increasing number of cis/trans ambiguities. Over the last few years, additional sequencing with the commercially available group-specific sequencing primers (GSSPs) has replaced sequence-specific primer-polymerase chain reaction and group-specific amplification as the means of resolving cis/trans ambiguities in many laboratories. Here we summarize our 3-year experience in designing and utilizing GSSPs for resolution of HLA class I ambiguities. The panel of GSSPs used in our laboratory includes 14 primers for HLA-A, 18 for HLA-B, and 13 primers for HLA-C. The panel resolves 99.9% of all ambiguities.

Improved KIR gene and HLA-C KIR ligand sequence-specific primer polymerase chain reaction genotyping using whole genome amplification.

Molecular analysis of genetic polymorphism for clinical or research purposes may be compromised by genomic DNA of limited quality and quantity. In this study, we have successfully tested the feasibility of using whole genome amplification (WGA) to allow genotyping for killer cell immunoglobulin-like receptor (KIR) genes and human leucocyte antigen (HLA)-C KIR ligand dimorphism on HLA-C. WGA was achieved by multiple displacement amplification (MDA) using bacteriophage phi29 polymerase. For KIR genotyping, a revised sequence-specific primer polymerase chain reaction protocol consisting of 23 primer pairs was used avoiding hitherto undetected cross-priming involving KIR2DL1, KIR2DS1, KIR3DL1 and KIR3DS1 alleles. Similarly, MDA-amplified genomic DNA was analyzed for the detection of the HLA-C KIR ligand groups C1 and C2, based on the amino acid K/N dimorphism in position 80.

A one-step real-time PCR assay for detection of DQA1*05, DQB1*02 and DQB1*0302 to aid diagnosis of celiac disease.

Celiac disease is an autoimmune disorder that develops after dietary exposure of the small intestine to gluten peptides in cereals. Celiac disease has a strong genetic component associated with HLA-DQ2 and HLA-DQ8, and testing for absence of these genetic markers is useful when serological tests and biopsies are indeterminate, as it renders celiac disease highly unlikely. We have developed a new real-time PCR assay, using sequence-specific primers (PCR-SSP) and TaqMan probes, for detection of DQB1*05, DQB1*02 (coding for DQ2) and DQB1*0302 (coding for DQ8). PCR amplification and detection of DQ2 and DQ8 was accurately and unambiguously performed from genomic DNA isolated from cell lines and human DNA. Amplification was scored digitally, without laboratory manipulation of amplified PCR products and with a higher accuracy than PCR-SSP. This assay should increase accuracy and throughput, and reduce risks of contamination in laboratories where testing for HLA DQ2 and DQ8 is performed as part of diagnosis of celiac disease.

Validation of sensitive human leukocyte antigen-sequence-specific primer and probe typing in forensic DNA examination.

Validation studies were carried out with the commercially available HLA typing kit using a PCR-SPP (sequence-specific primer and probe) technique. This technique has made it possible to type class I (HLA-A and -B) and class II (HLA-DRB1 and -DQB1) alleles at low-resolution level with total 10 ng of template DNA, in addition to amplify directly from various forms of blood samples without DNA isolation procedure. Experimental examinations with bloodstains smeared on cotton cloth that were a week to 3 months old, bloodstains on gauze stored for 18 years, and buccal cells revealed that this HLA-SPP typing kit is a sensitive and reliable method for forensic investigations.

Real-time PCR using fluorescent resonance emission transfer probes for HLA-B typing.

HLA genotyping by polymerase chain reaction (PCR) has some inherent labor-intensive and effort-demanding limitations. To overcome them, we have developed a real-time PCR with hybridization probes approach able to obtain a medium-low resolution HLA-B genotyping with fewer tubes and probes and with a shorter time requirement. Our strategy used 18 simultaneous reactions amplifying HLA-B alleles and an internal control. Monitorization of both amplifications in each tube is performed by the simultaneous application of two fluorescent resonance emission transfer probes: the first probe, different for each tube, is specific for the HLA-B locus and the second probe detects the control gene. A medium-low resolution (300 HLA-B allelic groups) typing is obtained for each sample by analyzing the melting curve patterns. Because some alleles may be determined without using the complete set of reactions, we present an alternative strategy: a first round of seven reactions and, according to the result, a second (or third) round of PCRs to solve the ambiguities. This method was validated in pretyped clinical samples and the results were completely concordant. Moreover, fewer ambiguous results were obtained. In summary, we present a new, faster, and more accurate method than currently used PCR techniques to type HLA-B alleles.

Identification of new HLA-C alleles by polymerase chain reaction-sequence specific oligonucleotide typing: Cw*0314 and Cw*1511*.

In this article, we report two new human leukocyte antigen-C (HLA-C) alleles, HLA-Cw*0314 and Cw*1511, which were identified during routine tissue typing of donors for the Australian Bone Marrow Donor Registry and Australian Cord Blood Bank. HLA-Cw*0314 shows six codon changes in exon 3 compared to Cw*030401 and shares some sequence homology with Cw*07 alleles. Cw*1511 has two nucleotide changes compared with Cw*150201 in exon 2, both resulting in amino acid changes in the protein sequence.

Identification of three novel HLA class I alleles: HLA-B*3928, HLA-B*400104 and HLA-B*4437.

Three new human leukocyte antigen (HLA) class I alleles have been identified in the Tissue Typing Laboratory in Sydney, Australia. Sequence analysis of exon 2 and exon 3 of the HLA-B gene revealed the novel polymorphism. A silent substitution of C to T at nucleotide position 369 has been identified for the HLA-B*400104 allele when compared to the closest matched allele, HLA-B*400101. The HLA-B*3928 allele was identified with a nucleotide substitution of G to C at position 362 when compared to the closest matched allele, HLA-B*390101, resulting in an amino acid substitution of Arginine to Threonine. A nucleotide substitution of C to G at position 572 resulting in the amino acid change Serine to Tryptophan was identified in the new allele HLA-B*4437, when compared to the closest matched allele HLA-B*440301. Both amino acid substitutions implicate a different specificity and affinity of antigen binding for the alleles HLA-B*3928 and HLA-B*4437.

Ambiguities of human leukocyte antigen-B resolved by sequence-based typing of exons 1, 4, and 5.

The elucidation of the sequences of human leukocyte antigen-B (HLA-B)-exons 1 through 5 has led to an increase of ambiguities with alleles having identical exon 2 and 3 sequences, but differences in other exons. At the moment, 26 HLA-B alleles show such ambiguities which can be resolved by sequencing the exons in which the differences are located. Here we report a sequence-based typing (SBT) strategy for heterozygous sequencing of exons 1, 4, and 5, in addition to the previously described exons 2 and 3. The strategy was validated against a panel of 25 individuals, carrying HLA-B alleles from 33 different allele groups. Correct assignment of all HLA-B alleles was obtained for exons 1 through 5. In addition, the SBT protocol was used to resolve ambiguities in 50 individuals. The ambiguous combinations studied were B*0705/06, B*0801/19N, B*1512/19, B*180101/17N, B*270502/13/0504, B*350101/42/40N, B*390101/0103, B*400102/0101, B*440201/19N/27, and B*510101/11N/0105/30/32. In all cases, sequencing revealed the first allele to be present, except for three individuals with B*07. One of them typed B*0705; the other two were B*0706. The described SBT protocol for sequencing exons 1, 4, and 5 is a valuable tool for resolving ambiguities of HLA-B alleles with differences in these exons, as well as for studying the polymorphism of HLA-B outside exons 2 and 3.

PCR-SSOP molecular typing of HLA-C alleles in an Iranian population.

HLA-C alleles were characterized by a polymerase chain reaction-sequence specific oligonucleotide probe (PCR-SSOP) hybridization protocol in a sample of 120 Iranians from Tehran. A total of 23 alleles were identified with the four most predominant--Cw*0401, Cw*0602, Cw*1202, and Cw*0701/06--accounting for almost 50% of HLA-C alleles. A comparison of HLA-C diversity among several populations indicates that Iranians stand at an intermediate genetic position between Europeans and Africans, an observation that may be related to their geographical location at a continental crossroads. The results also reveal a very high correlation between genetic and geographic distances on a global scale. A total of 30 HLA-C-DRB1 haplotypes were found in the Iranians, with the highest frequencies of 6.6% and 6.04 % being for Cw*0602-DRB1*0701 and Cw*1202-DRB1*1502, respectively.

Identification of DRB alleles in rhesus monkeys using polymerase chain reaction-sequence-specific primers (PCR-SSP) amplification.

Major histocompatibility complex (MHC) class In molecules play a vital role in the regulation of T-cell functions in the mammalian immune system. Two key features characterize the polymorphism of MHC haplotypes in humans and non-human primates: the existence of a large number of alleles, and the high degree of genetic diversity between those alleles. Rhesus monkeys and Chimpanzees have been extensively used as relevant models for human diseases and transplantation We have investigated DRB genes in 19 macaques, members of 3 families, using polymerase chain reaction with sequence-specific primers (PCR-SSP) and denaturing gradient gel electrophoresis (DGGE). After amplification PCR products were purified and subjected direct sequencing. Seven animals (Madison #1) were typed by DDGE also. We report that the DRB haplotypes defined by PCR-SSP exhibit a high degree of concordance with the data obtained by DGGE and direct sequening. Our data show prominent variability in the number of DRB1 alleles ranging from 1-4 per genotype within these families. This analysis demonstrated that most of the amplicons were identical to Mamu-DRB alleles that our PCR primers were to amplify. However, 98-99% similarity was noticed in the case of Mamu-DRB1*0303, Mamu-DRB6*0103 and Mamu-DRB*W201 alleles. The observed mismatches were located in non-polymorphic regions. Thus, family studies in rhesus macaques performed by molecular methods confirmed the multiplicity of Mamu-DRB1 alleles per haplotype and the existence of allelic associations published earlier. In addition, we propose 3 more DRB allele associations (haplotypes): Mamu-DRB1*04-DRB5*03; Mamu-DRB1*04-*DRB*W5; Mamu-DRB1*04*W2. The proposed medium-resolution PCR-SSP technique appears to be a highly reproducible and discriminatory typing method for detecting polymorphisms of DRB genes in rhesus monkeys.

Paternity assessment in rhesus macaques (Macaca mulatta): multilocus DNA fingerprinting and PCR marker typing.

Establishing kinship relations in primates using modern molecular genetic techniques has enhanced the ability to scrutinize a number of fundamental biological issues. We screened 51 human short tandem repeats (STRs) for cross-species PCR amplification in rhesus macaques (Macaca mulatta) and identified 11 polymorphic loci with heterozygosity rates of at least 0.6. These markers were used for paternity testing in three social groups (M, R, and S) of rhesus macaques from Cayo Santiago, Puerto Rico. Several consecutive birth cohorts were analyzed in which approximately 200 males were tested for paternity against more than 100 mother/ infant pairs. Despite a combined exclusion rate of more than 99.9% in all three groups, some cases could not be solved unequivocally with the STR markers and additional testing of the MHC-associated DQB1 polymorphism. A final decision became possible through multilocus DNA fingerprinting with one or more of the oligonucleotide probes (GATA)4, (CA)8, and (CAC)5. Paternity assessment by multilocus DNA analysis with probe (CAC)5 alone was found to have limitations in rhesus macaques as regards the number of potential sires which might be involved in a given case. Multilocus DNA fingerprinting requires large amounts of DNA, and the ensuing autoradiographic patterns present difficulties in comparisons across gels and even within the same gel across remote lanes. Computer-assisted image analysis was incapable of eliminating this problem. Therefore, a dual approach to DNA typing has been adopted, using STR markers to reduce the number of potential sires to a level where all remaining candidates can be tested by multilocus DNA fingerprinting on a single gel, preferably in lanes adjacent to the mother/infant pair.

Sequence of a new HLA-DR allele, DRB5*0106.

We report here the exon 2 sequence of a new HLA-DRB5 allele, DRB5*0106, that was identified in two volunteer bone marrow donors from the Swiss national registry. This new allele differs from DRB5*0101 by five amino acids at positions 67, 70, 71, 85 and 86. It is associated with DRB1*1501 and DQB1*0602. This unusual DRB1*1501-DRB5*0106 association increases the complexity of the DR2 group, although it appears to be very rare, at least in our population. HLA-DRB5*0106 can be readily detected upon DR generic oligotyping, provided the two probes that mark the major DRB5 subtypes, DRB5*0101 and DRB5*02, respectively, are included in the assay.

Analysis of HLA-A and -B serologic typing of bone marrow registry donors using polymerase chain reaction with sequence-specific oligonucleotide probes and DNA sequencing.

Unrelated volunteer donors (69) recruited by the National Marrow Donor Program were HLA typed by DNA-based methods for both the HLA-A and -B loci. Each donor had been previously typed by serology by at least two independent laboratories. Of the 69 samples, all serologic laboratories were in concordance for HLA-A in 62 typed samples and for HLA-B in 48 typed samples. Of the serologically concordant samples, 5 samples typed for HLA-A and 7 samples typed for HLA-B received DNA and serology types differing in their level of resolution. One sample typed for HLA-A and 3 samples typed for HLA-B by DNA methods gave different results from their serologic assignments. Of the samples exhibiting disparities among the different serologic typing laboratories, the DNA-defined types of 7 samples typed for HLA-A and 18 samples typed for HLA-B were consistent with at least one of the serologic assignments. The DNA types for the remaining 3 HLA-B typed samples did not agree with the serologic assignments and their alleles were subsequently sequenced. One of these sequences was a previously undefined allele, B*1537. Sharing of polymorphic sequences among HLA allelic products creates difficulties for consistent serologic assignments of some types complicating the process of identifying potential donors from bone marrow registries. Thus, the use of DNA-based typing techniques for characterization of donor class I types should allow a more consistent definition of types and should speed the donor selection process.

Accurate typing of HLA-A antigens and analysis of serological deficiencies.

We are reporting the results of HLA-A typing by PCR-SSOP complemented by PCR-SSP of samples obtained from the National Marrow Donor Program (NMDP). These samples were a representative group from 2486 tested in duplicate by serology. A total of 390 samples gave HLA-A discrepant results. Comparing the molecular typing results of 238 samples (samples with available DNA) with the serological typing results, 54 homozygotes and 184 heterozygotes produced a total of 422 assignments by molecular methods. We found assignment discrepancies in 147/422 (35%) in laboratory 1 and 144/422 (34%) in laboratory 2 (a combined group of 4 NMDP laboratories; laboratory 1 is not included). The serological discrepancies found were of 3 categories: a) false negatives, b) incomplete typing (discrepancies due to the level of resolution within a cross-reactive or CREG group) and c) false positives. Major problems were identified using serology for typing HLA-A antigens: a) inability to identify all WHO-recognized specificities, more frequently in non-Caucasians or in HLA-A specificities known to be found more frequently in non-Caucasians for laboratory 1 and incorrect assignments of A19 specificities in laboratory 2, b) incorrect assignments in cells with poor viability and c) false-positive assignments in homozygotes. We propose a possible strategy to type HLA-A specificities with two steps: a) a minimum of serology for typing specificities for common CREG groups: A1, A2, A3, A11, A9, A10, A28, A19. However, a given laboratory can determine the level of serological assignments needed as a first step. And b) molecular methods to identify splits: A23, A24, A29, A30, A31, A32, A33, A34, A36, A66, A74 and A80. The technique described is useful for large-scale bone marrow donor typings for cells with poor viability, and for resolving ambiguous results including false-positive assignments of homozygous cells.

Error rate for HLA-B antigen assignment by serology: implications for proficiency testing and utilization of DNA-based typing methods.

Until recently, the majority of HLA class I typing has been performed by serology. Expensive commercial typing trays are frequently used for testing non-Caucasian subjects and new strategies using DNA-based methods have been adopted for improving clinical histocompatibility testing results and adapted as supplements in proficiency testing. A double-blind comparison of the typing of HLA-B specificities in 40 samples was carried out between serology and two polymerase chain reaction (PCR) methods, PCR amplification with sequence-specific primers (PCR-SSP) and PCR amplification and subsequent hybridization with sequence-specific oligonucleotide probes (PCR-SSOP). The results demonstrated 22.5% misassignments of HLA-B antigens by serology. There was complete concordance between the results obtained with the two PCR based typing methods. A second panel of 20 donor samples with incomplete or ambiguous serologic results was analyzed by PCR-SSP and SSOP Both PCR methods identified correctly the HLA-B antigens. Our results suggest that more accurate typing results can be achieved by complementing serologic testing with DNA-based typing techniques. The level of resolution for HLA-B antigen assignment can be obtained by this combination of serology and limited DNA-based typing is equivalent to the HLA-B specificities defined by the WHO-HLA Committee. This level of resolution cannot routinely be achieved in clinical histocompatibility testing or in proficiency testing using serologic reagents only.

Comparison of typing results by serology and polymerase chain reaction with sequence-specific primers for HLA-Cw in 650 individuals.

HLA-Cw typing by standard serological techniques is associated with a high frequency of blanks, and reliable typing reagents for several of the Cw specificities are scarce. We evaluated the PCR-SSP technique for Cw typing in 370 kidney transplant patients and 280 healthy blood donors. Serological typing of all individuals was performed in our laboratory from 1995 to 1997 using commercially available tissue-typing trays. Comparison between serological and PCR-SSP typing revealed a discrepancy rate of 33.6% (n= 94) in blood donors and 32.4%) (n=120) in kidney recipients. Incorrect antigen assignments occurred only rarely (3.6% of the blood donors and 3.2% of the kidney recipients). The vast majority of discrepancies were due to antigens that were not detected serologically. In 26 individuals no Cw antigen was detected by serological typing, whereas PCR-SSP showed 1 allele in 13 and 2 alleles in the other 13 cases. Another 269 individuals were typed serologically with one blank (presumably homozygous). Of these, only 108 were confirmed to be homozygous, whereas an additional Cw allele was found in the remaining 161 cases using the SSP technique. Most of the "missed" specificities (86.5%) were those for which serological reagents were not available (HLA-Cw*12-*17). The most commonly "missed" specificity was HLA-Cw*1203, which occurred in 13.9% of the healthy blood donors. These results indicate that serological HLA-Cw typing is insufficient for examining the clinical importance of HLA-Cw matching in transplantation. Future studies based on molecular typing should allow the proper investigation of HLA-Cw matching in kidney and bone marrow transplantation.