Analysis of HIV type 1 protease and reverse transcriptase in antiretroviral drug-naive Ugandan adults.

We analyzed plasma HIV-1 from 27 antiretroviral drug-naive Ugandan adults. Previous subtype analysis of env and gag sequences from these samples identified subtypes A, C, D, and recombinant HIV-1. Sequences of HIV-1 protease and reverse transcriptase (RT) were obtained with a commercial HIV-1 genotyping system. Subtypes based on protease sequences differed from gag subtypes for 5 of 27 samples, demonstrating a high rate of recombination between the gag and pol regions. Protease and RT sequences were analyzed for the presence of amino acid polymorphisms at positions that are sites of previously characterized drug resistance mutations. At those sites, frequent polymorphisms were detected at positions 36 and 69 in protease and positions 179, 211, and 214 in RT. Subtype-specific amino acid motifs were identified in protease. Most of the subtype A sequences had the amino acids DKKM at positions 35, 57, 69, and 89, whereas most subtype D sequences had the amino acids ERHL at those positions. Detection of those polymorphisms may provide a useful approach for rapid identification of subtype A and D isolates in Uganda. This analysis significantly increases the number of Ugandan protease and RT sequences characterized to date and demonstrates successful use of a commercial HIV-1 genotyping system for analysis of diverse non-B HIV-1 subtypes.

HLA-B alleles associated with the B15 serologically defined antigens.

Cells expressing HLA molecules in the B15 family were identified by serologic typing in routine testing of volunteer donors of various ethnic backgrounds for a bone marrow registry. DNA sequencing was used to identify HLA-B15 alleles associated with each serologic type and to examine the diversity within the B15 antigen family. Alleles which appeared predominantly in each B15 serologic cluster included: B15 with no defined serologic subdivision (B*1501), B62 (B*1501), B63 (B*1516, B*1517), B75 (B*1502, B*1521), and B76/77 (B*1513). Other B*15 alleles were also found associated with the serotypes and some of these alleles (e.g., B*1501 and B*1516) were found in two or more serologic clusters illustrating the complexity of this family. The B15 unsplit and B75 groups were the most complex exhibiting 16 and 7 alleles, respectively, within each serotype. Five new B*15 alleles (B*1530, B*1531, B*1533, B*1534, B*1535) and 5 other new HLA-B alleles (B*38022, B*3910, B*4010, B*51012, and B*5108) were also identified.

HLA-A typing: comparison between serology, the amplification refractory mutation system with polymerase chain reaction and sequencing.

In this study we typed HLA-A polymorphisms by a new sequence-based typing (SBT) method, which involved one PCR reaction and four sequencing reactions covering exon 2 and exon 3. This method allowed complete identification of all known HLA-A alleles and revealed the presence of a new allele, named HLA-A*2608. We also introduced sequencing of exon 4 for some samples in order to discriminate the allelic pairs that are identical in exon 2 and 3, thus improving SBT resolution. Finally, we compared the results obtained by SBT with data obtained by serological typing and the amplification refractory mutation system (ARMS-PCR). Together, our results suggest that the SBT here described provides an optimal HLA-A typing technique that may be useful in selecting donor-recipient pairs in bone marrow transplantation between unrelated individuals.

Mismatches for two major and one minor histocompatibility antigen correlate with a patient's rejection of a bone marrow graft from a serologically HLA-identical sibling.

We describe the case of a patient with chronic myeloid leukemia who rejected a bone marrow (BM) graft from a sibling donor believed to be HLA identical. Sequencing of the HLA genes showed the mother to be heterozygous for two closely related HLA haplotypes that could not be resolved by serological typing. The donor and the recipient had each inherited a different maternal haplotype resulting in allelic mismatches for the HLA-B35 and the HLA-DR11 genes. T cell cytotoxicity directed towards the donor's B35 allele was detected in the patient, in addition to CTL specificity for an HLA-B7-restricted minor histocompatibility antigen carried by the donor, resulting in three histocompatibility mismatches between the BM donor and the recipient.

A generic sequencing based typing approach for the identification of HLA-A diversity.

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.

Heterozygote and mutation detection by direct automated fluorescent DNA sequencing using a mutant Taq DNA polymerase.

We describe a method for direct cycle sequencing of PCR fragments amplified from genomic DNA or cDNA. DNA sequencing template is amplified using PCR and oligonucleotide primers flanking the region of interest. The amplified fragment is directly cycle sequenced using fluorescent sequencing primers, Sanger dideoxy sequencing chemistry and an enzyme mixture of a mutant Taq DNA polymerase and thermostable pyrophosphatase. The sequence ladders produced are analyzed on a real-time, automated four-color sequencing system. The method produces sequence ladders from unpurified PCR fragments of sufficiently high quality such that heterozygotes can be reproducibly detected and identified by software that recognizes signal-strength patterns indicative of mixed-base positions.

Sequenase sequence profiles used for HLA-DPB1 sequencing-based typing.

Sequencing-based HLA typing (SBT) is a PCR based high resolution HLA typing method in which polymorphic regions of the gene are sequenced and directly used for typing. Currently, for class II SBT, alleles are identified by comparison of the exon 2 sequence with their corresponding allele sequence library. Routine SBT requires reliable identification of heterozygosity, and automated assignment of the alleles. In sequencing strategies different enzymes can be used for primer extension. The most characteristic difference between sequences obtained by two protocols using Sequenaseregistered, or Taq-cycle sequencing, respectively, is a difference in incorporation of nucleotides in the primer extension leading to different sequence profiles. In Taq-cycling sequencing variable nucleotide incorporation results in irregular, but reproducible peak patterns, whereas Sequenase incorporates nucleotides in nearly equal amounts, resulting in more even peak patterns. In a previously published multi-center study we evaluated HLA-DPB1 SBT using Taq-cycle sequencing, and showed that typing can reliably be performed, considering the specific sequence profiles. In this study the applicability of Sequenase for HLA-DPB1 SBT was tested. A panel of samples were typed by SBT at five test sites which participate in the Sequencing Based Typing component of the 12th International Histocompatibility Workshop. The panel represents the existing polymorphism at all known polymorphic positions of exon 2, both in homozygous and heterozygous combinations. The assignment of homozygosity and heterozygosity was validated by Multi-Sequence Analysis, performing cluster analysis of chromatographic data of all sequences at each position. Sequence characteristics were examined and considered for appropriate assignment. Data reveals that Sequenase sequencing can also reliably be used for HLA-DPB1 typing.

Structural heterogeneity in HLA-B70, a high-frequency antigen of black populations.

Although the B70 antigen exhibits allele frequencies of 8-23% in African and American black populations, it remains poorly defined. Cloning and sequencing of cDNA encoding B70 antigens from six cell lines has identified a group of three closely related alleles: B*1503, B*1509 and B*1510, that form a subgroup of the B15 family. The sequences of these alleles and, in particular, B*1503, are close to that of the HLA-B consensus consistent with the difficulty in their serological definition. The products of the three alleles correspond to three electrophoretically detected variants of the B70 antigen and some correlation with the B71 and B72 subspecificities of the B70 antigen can be made. A fourth allele, B*7901, previously described by Choo et al. (J. Immunol. 147: 174-180, 1991) that was not serologically typed as B70, differs by a single nucleotide substitution from B*1510. The sensitivity of alloantibodies to single differences in peptide binding residues suggest a role for bound peptides in the HLA-B70 alloantigenic specificities. The heavy chains encoded by the four alleles differ at four peptide binding residues of the antigen recognition site, the evolutionary modification of which can be explained in terms of interallelic recombination events.

A new approach to template purification for sequencing applications using paramagnetic particles.

A new method using traditional hybridization methodology, coupled with the new magnetic particle technology, has been developed for DNA purification, specifically for sequencing applications. The method is similar to the reverse hybridization blot system; however, a specific oligonucleotide probe was attached to the paramagnetic particle instead of a sheet membrane. The target DNA containing the complementary sequence of the probe hybridizes to the probe that is attached to the bead and is then magnetically removed from solution, washed and collected. This system eliminates the need of organic extractions and precipitation/concentration steps. The entire hybridization-purification system can be done in a 1.5-ml microcentrifuge tube making the method ideal for automation. M13 phage clones were purified with this method, both by manual means and by using the CATALYST 800 Molecular Biology LabStation fitted with a prototype magnetic station, and then sequenced. DNA sequencing results obtained with this system were reproducible and gave excellent length of read with low background.