Performance of Applied Biosystems ViroSeq HIV-1 Genotyping System for sequence-based analysis of non-subtype B human immunodeficiency virus type 1 from Uganda.

The Applied Biosystems ViroSeq HIV-1 Genotyping System is a commercially available, integrated system for sequence-based analysis of drug resistance mutations in human immunodeficiency virus type 1 (HIV-1) protease and reverse transcriptase (RT). We evaluated the performance of this system for analysis of non-subtype B HIV-1 by analyzing plasma samples from Ugandan women and infants. Plasma samples were obtained from 105 women and 25 infants enrolled in a Ugandan clinical trial. HIV-1 analysis was performed with the ViroSeq system according to the manufacturer's instructions, except that the volume of plasma used for analysis was less than the recommended 0.5 ml for some samples. Viral loads ranged from 2,313 to 2,336,400 copies/ml. PCR products suitable for sequencing were amplified from all samples tested. Complete sequences for protease (amino acids 1 to 99) and RT (amino acids 1 to 320) were obtained for 102 of 105 (97%) of the maternal samples tested and all 25 of the infant samples tested. Complete double-stranded sequences were obtained for 90 of 105 (86%) of the maternal samples tested and 22 of 25 (88%) of the infant samples tested. The sequences obtained with this system were used for HIV-1 subtyping. The subtypes identified were A, C, D, and A/D recombinant HIV-1. The performances of the seven sequencing primers were similar for the subtypes examined. The ViroSeq system performs well for analysis of Ugandan plasma samples with subtypes A, C, D, and A/D recombinant HIV-1. The availability of this genotyping system should facilitate studies of HIV-1 drug resistance in countries where these subtypes are prevalent.

Impact of human immunodeficiency virus type 1 (hiv-1) subtype on women receiving single-dose nevirapine prophylaxis to prevent hiv-1 vertical transmission (hiv network for prevention trials 012 study).

In Uganda, the HIV Network for Prevention Trials (HIVNET) 012 study recently demonstrated that single-dose nevirapine (Nvp) prophylaxis is effective for preventing mother-to-child transmission (MTCT) of human immunodeficiency virus type 1 (HIV-1). This exploratory study examines the relationship between HIV-1 subtype, MTCT, and the development of Nvp resistance (Nvp(R)) in women enrolled in HIVNET 012. For 102 women (32 whose infants were HIV-1 infected by age 6-8 weeks and 70 whose infants were uninfected), HIV-1 subtypes included 50 (49%) subtype A, 35 (34%) subtype D, 4 (4%) subtype C, 12 (12%) recombinant subtype, and 1 unclassified. There was no apparent difference in the rate of MTCT among women with subtype A versus D (adjusted odds ratio [OR], 1.24; 95% confidence interval [CI], 0.45-3.43). Nvp(R) mutations were detected more frequently at 6-8 weeks postpartum in women with subtype D than in women with subtype A (adjusted OR, 4.94; 95% CI, 1.21-20.22). Additional studies are needed to further define the relationship between HIV-1 subtype and Nvp(R) among women receiving Nvp prophylaxis.

Identification of the K103N resistance mutation in Ugandan women receiving nevirapine to prevent HIV-1 vertical transmission.

OBJECTIVE: A recent trial in Uganda demonstrated that a simple, inexpensive regimen of nevirapine (NVP) prophylaxis can dramatically reduce HIV-1 vertical transmission risk. In this regimen, women receive a single dose of NVP at the onset of labor and infants receive a single dose of NVP within 72 h of birth. The objective of this study was to determine whether HIV-1 variants with NVP resistance mutations were selected in Ugandan women who received this regimen in the Phase I/II trial HIVNET 006. METHODS: Reverse transcriptase (RT) sequences from plasma HIV-1 were analyzed from 15 women 6 weeks after NVP dosing. RT sequences from plasma collected prior to NVP dosing were also analyzed. RESULTS: The K103N NVP resistance mutation was detected 6 weeks after NVP administration in three (20%) out of 15 women (95% confidence interval, 0-40%). Pre-dose samples were available from two of the three women; both pre-dose samples lacked the mutation. Other NVP resistance mutations were absent from all 15 women. Women with the K103N mutation had a longer median NVP elimination half-life, decreased median oral clearance, and increased median area under the concentration time curve than those without the mutation. An evaluable sample was obtained from one of these three women 33 months after delivery; the K103N mutation was not detected in that sample. CONCLUSIONS: This preliminary study demonstrates that HIV-1 with the RT K103N mutation can be detected in some Ugandan women following a single dose of NVP. This suggests that non-nucleoside RT inhibitor resistance may be selected in some people by single dose NVP prophylaxis. Pharmacokinetic data suggested that a more prolonged exposure to NVP after dosing may favor selection of NVP-resistant HIV-1.

Identification of diverse HIV type 1 subtypes and dual HIV type 1 infection in pregnant Ugandan women.

Vertical (mother-to-child) transmission accounts for the majority of pediatric HIV-1 infections. Many factors are involved in vertical transmission, however it is not clear which factors are most important for determining whether a mother will transmit HIV-1 to her infant. It has been suggested that HIV-1 subtype may influence vertical transmission and that subtype D viruses may be less likely to be transmitted in this setting. We analyzed HIV-1 gp120 V3 region sequences from the plasma of 20 pregnant Ugandan women of known transmission status who did not receive antiretroviral prophylaxis. V3 regions were cloned, sequenced, and subtyped by phylogenetic analysis. Among 11 women who transmitted HIV-1 to their infants, we detected subtypes A, C, D, and G. Two of the transmitters had dual infection with subtypes A and D. In addition, a third was infected with two distinct strains of subtype G viruses. HIV-1 subtype A and D viruses were found in 9 women who did not transmit the virus to their infants. This study reveals that pregnant Ugandan women harbor diverse HIV-1 subtypes, including women who transmit HIV-1 to their infants. Transmission of HIV-1 with subtype D V3 regions was confirmed in 4 of the 11 transmitters, including 2 who had dual infection with subtype A and D HIV-1.

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.

Improved detection of human immunodeficiency virus type 1 variants by analysis of replicate amplification reactions: relevance to studies of human immunodeficiency virus type 1 vertical transmission.

BACKGROUND: Human immunodeficiency virus type 1 (HIV-1)-infected individuals typically harbor mixtures of HIV-1 variants. For HIV-1 transmission studies, methods used for genotypic analysis should reliably detect variant mixtures. Such studies typically analyze complementary DNAs (cDNAs) from a single polymerase chain reaction (PCR) amplification. This approach may fail to detect variant mixtures in some samples because of analytic bias. METHODS: To evaluate the impact of analytic bias on the detection of HIV-1 variants, we analyzed samples from a mother and infant known to contain both subtypes A and D HIV-1. The env third variable region of HIV-1 gp120 (V3 region) was amplified and cloned in five replicate experiments using a single plasma sample from each individual. Ten cDNAs from each experiment were analyzed. RESULTS: The subtype mixture was detected in only four of 10 amplification experiments (three of five for the mother and one of five for the infant). Sequencing of uncloned PCR products showed that a single subtype, either A or D, was preferentially amplified in each experiment. However, the subtype mixture was detected for each sample by analyzing the five replicate experiments as a group. CONCLUSIONS: This shows that mixtures of HIV-1 variants may be more readily detected when replicate amplification reactions are analyzed. This approach may be useful for characterizing HIV-1 variants for studies of HIV-1 transmission.