In vitro human immunodeficiency virus type 1 resistance selections with combinations of tenofovir and emtricitabine or abacavir and lamivudine.

Human immunodeficiency virus type 1 (HIV-1) resistance development was evaluated in vitro by using combinations of the drugs tenofovir and emtricitabine or abacavir and lamivudine, as well as by using the compounds individually. Emtricitabine- and lamivudine-resistant HIV-1 isolates with the M184I or M184V mutation in reverse transcriptase were readily selected in the cultures with emtricitabine alone, lamivudine alone, and the two drug combinations and conferred high-level resistance to emtricitabine and lamivudine. Tenofovir-resistant HIV-1 isolates with the K65R mutation occurred in both the culture with tenofovir alone and the culture with the combination of emtricitabine and tenofovir. The S68N and S68K mutations were also observed in the tenofovir cultures, with no detectable impact on resistance, suggesting a possible compensatory role in viral fitness. At low concentrations of emtricitabine and tenofovir, the M184I mutation appeared first, followed by the K65R mutation, in a subset of viruses. At intermediate concentrations of emtricitabine and tenofovir, viruses harboring the K65R mutation or a novel K65N and K70R double mutation grew before they gave rise to mutants with K65R and M184V/I double mutations at higher emtricitabine concentrations. Abacavir resistance was characterized by the accumulation of the M184V, Y115F, and K65R mutations in the abacavir culture, while the M184V and L74V mutations were selected in combination with lamivudine. In the presence of the abacavir resistance mutations, viral growth was strong even in the presence of high concentrations of abacavir. In contrast, viral growth was markedly impaired in the cultures with high tenofovir concentrations, even in the presence of K65R. In conclusion, these studies show that HIV-1 mutants with a K65R and M184V genotype are generated under maximum selection pressure from the combination of tenofovir and emtricitabine.

Resistance development over 144 weeks in treatment-naive patients receiving tenofovir disoproxil fumarate or stavudine with lamivudine and efavirenz in Study 903.

OBJECTIVE: Study 903 was a 144-week, randomized, double-blind, active-controlled study of tenofovir disoproxil fumarate (TDF) therapy in treatment-naive HIV-1-infected patients. Patients received either TDF (n = 299) or stavudine (d4T) (n = 301) with lamivudine (3TC) and efavirenz (EFV). Resistance analyses were performed at baseline and at virological failure to determine the effects of baseline resistance and the patterns of resistance at virological failure. METHODS: Plasma HIV-1 from patients at baseline and at virological failure (>400 HIV-1 RNA copies/mL at week 144 or early discontinuation) was analysed phenotypically and by population sequencing. RESULTS: Sixteen per cent of patients were classified as having virological failure (47 on TDF and 49 on d4T; P = 0.91). Patients with non-B HIV-1 subtypes or baseline nucleoside reverse transcriptase inhibitor (NRTI)-associated mutations responded similarly to the overall population. Resistance to EFV (K103N and others) or 3TC (M184V) developed most frequently (8.3% and 5.8%, respectively) and similarly in the two arms. In the d4T arm, a variety of NRTI mutations developed: K65R (n = 2), L74V (n = 2), V75M (n = 1), and T69A + Y115H (n = 1). K65R developed in eight TDF patients (2.7%); in seven of these eight patients, within 48 weeks. All eight patients began new regimens with a protease inhibitor (PI) and NRTIs, including two patients who remained on TDF; five of the eight patients achieved HIV RNA <50 copies/mL in second-line therapy with the remaining patients having no follow-up or being nonadherent. CONCLUSIONS: Treatment of HIV-1 with TDF, 3TC and EFV was highly effective, with <3% of patients developing resistance to TDF over 144 weeks.

Antiviral activity of tenofovir (PMPA) against nucleoside-resistant clinical HIV samples.

The presence of the lamivudine-associated M184V RT mutation increases tenofovir susceptibility in multiple HIV genotypes. Tenofovir is uniquely active against multinucleoside-resistant HIV expressing the Q151M mutation, but shows reduced susceptibility to the T69S insertion mutations. HIV with common forms of zidovudine and lamivudine resistance are susceptible to tenofovir, corroborating phase II clinical results demonstrating the activity of tenofovir DF in treatment-experienced patients.

Tenofovir (PMPA) is less susceptible to pyrophosphorolysis and nucleotide-dependent chain-terminator removal than zidovudine or stavudine.

Pyrophosphorolysis, the removal of nucleoside chain-terminators by a pyrophosphate (PPi) acceptor molecule, and a similar mechanism (nucleotide-dependent chain-terminator removal) which uses ATP as an acceptor molecule have been proposed as mechanisms of zidovudine (AZT) resistance. Recombinant HIV-1 wild-type reverse transcriptase (RT) and a mutant RT enzyme containing the AZT/thymidine analog resistance mutations D67N/K70R/T215Y were analyzed for pyrophosphorolysis and nucleotide-dependent chain-terminator removal activities. Our results confirm that pyrophosphorolysis and nucleotide-dependent chain-terminator removal are potential mechanisms of AZT and d4T resistance. However, tenofovir is less efficiently removed by pyrophosphorolysis and by nucleotide-dependent mechanisms. These results are consistent with the minor changes in susceptibility to tenofovir of the AZT/thymidine analog-resistant HIV RT mutants and the corresponding resistance of these mutants to AZT. The inability to remove tenofovir efficiently by these mechanisms may contribute to the durability of the HIV RNA response observed in patients treated with the oral prodrug, tenofovir disoproxil fumarate.

Adefovir and tenofovir susceptibilities of HIV-1 after 24 to 48 weeks of adefovir dipivoxil therapy: genotypic and phenotypic analyses of study GS-96-408.

OBJECTIVE: To determine whether genotypic changes in HIV-1 (HIV) reverse transcriptase (RT) occur during adefovir dipivoxil (ADV) therapy that may alter the susceptibility of HIV to adefovir or the related nucleotide inhibitor, tenofovir. DESIGN AND METHODS: GS-96-408 was a 1:1 randomized, double-blind, phase III clinical trial assessing the safety and efficacy of 120-mg daily ADV compared with placebo for the treatment of HIV when added to stable background antiretroviral therapy (ART). Of 442 patients enrolled, 142 were prospectively selected for a virology substudy. Baseline and posttreatment (weeks 24-48) plasma samples were genotypically analyzed in HIV RT. HIV from ADV-treated patients who developed RT mutations at week 24 were also phenotypically analyzed. RESULTS: Nucleoside-associated RT mutations arose with similar frequency among the ADV-and placebo-treated patients, 32% (n = 23) and 28% (n = 20), respectively, during the 24-week blinded treatment phase. RT mutations previously selected by adefovir in vitro (K70E or K65R) did not develop in any patient. Most mutations were typical zidovudine (ZDV)-resistance mutations (e.g., M41L, D67N, K70R, T215Y) in patients taking ZDV or stavudine (d4T) concomitantly, demonstrating directly in the placebo arm that d4T is able to select for these mutations. There appeared to be more patients developing D67N and K70R mutations in the ADV arm versus more T215Y mutations in the placebo arm. Between weeks 24 and 48, 19 of 50 patients (38%) in the ADV arm developed similar RT mutations. The mean HIV RNA responses at weeks 24 and 48 among the ADV-treated patients developing RT mutations were -0.68 log(10) copies/ml (n = 23) and -0.52 log(10) copies/ml (n = 19), respectively, similar to the overall week-24 and week-48 responses (-0.53 and 0.48 log(10) copies/ml, respectively). Patient-derived HIV expressing the observed RT mutations showed insignificant decreases in adefovir susceptibility compared with wild-type in 12 of 16 cases (< threefold). HIV from 1 patient showed significantly reduced susceptibility to tenofovir, which was in association with a double insertion mutation after codon 69 that was also present at baseline. CONCLUSIONS: HIV RT changes that arose during ADV therapy appear attributable to the patient's background ART. ADV therapy may have influenced the pattern of ZDV-associated resistance mutations that developed, but this did not result in an observed loss of viral load suppression. There was a trend toward decreased phenotypic susceptibility to adefovir in ADV-treated patients, with 4 of 16 analyzed patients showing mild, but significantly decreased susceptibility associated with the additional ZDV-associated mutations. Decreased susceptibility to the related nucleotide analog, tenofovir, was not observed to develop in ADV-treated patients.

Increased drug susceptibility of HIV-1 reverse transcriptase mutants containing M184V and zidovudine-associated mutations: analysis of enzyme processivity, chain-terminator removal and viral replication.

The presence of the HIV reverse transcriptase (RT) resistance mutation, M184V, induced by lamivudine and abacavir treatment results in increased tenofovir, adefovir and zidovudine susceptibility for HIV-1 with zidovudine-associated RT mutations in vitro. Treatment with oral prodrugs of tenofovir and adefovir has resulted in substantial HIV-1 RNA reductions in antiretroviral-experienced patient populations who have lamivudine- and zidovudine-resistant HIV-1. An enzymatic analysis was undertaken to elucidate the mechanisms of altered drug susceptibilities of HIV-1 containing zidovudine-associated mutations in the presence or absence of M184V. The inhibition constants (Ki) for the active metabolites of tenofovir, adefovir and zidovudine did not vary significantly between recombinant mutant and wild-type RT enzymes. Although increased removal of chain-terminating inhibitors by pyrophosphorolysis and ATP-dependent unblocking correlated with reduced susceptibility of viruses with zidovudine-associated mutations, a reduction in the removal of chain-terminators was not observed, which would explain the increased drug susceptibility of mutants containing M184V plus zidovudine-associated mutations. However, analyses of single-cycle processivity of the mutant RT enzymes on heteropolymeric RNA templates showed that all M184V-containing mutant RT enzymes were less processive than wild-type RT, most notably for mutants expressing both zidovudine-associated mutations and M184V. Similarly, the in vitro replication capacity of a mutant virus expressing a zidovudine-associated mutation and M184V was significantly reduced compared with wild-type virus. The observed decrease in enzymatic processivity of the M184V-expressing RT enzymes might result in decreased viral replication, which then might contribute to the increased drug susceptibility of HIV-1 expressing these RT mutations.

Prophylactic and therapeutic benefits of short-term 9-[2-(R)-(phosphonomethoxy)propyl]adenine (PMPA) administration to newborn macaques following oral inoculation with simian immunodeficiency virus with reduced susceptibility to PMPA.

Simian immunodeficiency virus (SIV) infection of newborn macaques is a useful animal model of human pediatric AIDS to study pathogenesis and to develop intervention strategies aimed at preventing infection or delaying disease progression. In previous studies, we demonstrated that 9-¿2-(R)-(phosphonomethoxy)propyladenine (PMPA; tenofovir) was highly effective in protecting newborn macaques against infection with virulent wild-type (i.e., drug-susceptible) SIVmac251. In the present study, we determined how reduced drug susceptibility of the virus inoculum affects the chemoprophylactic success. SIVmac055 is a virulent isolate that has a fivefold-reduced in vitro susceptibility to PMPA, associated with a K65R mutation and additional amino acid changes (N69T, R82K, A158S, S211N) in reverse transcriptase (RT). Eight newborn macaques were inoculated orally with SIVmac055. The three untreated control animals became SIVmac055 infected; these animals had persistently high viremia and developed fatal immunodeficiency within 3 months. Five animals were treated once daily with PMPA (at 30 mg/kg of body weight) for 4 weeks, starting 24 h prior to oral SIVmac055 inoculation. Two of the five PMPA-treated animals had no evidence of infection. The other three PMPA-treated infant macaques became infected but had a delayed viremia, enhanced antiviral antibody responses, and a slower disease course (AIDS in 5 to 15 months). No reversion to wild-type susceptibility or loss of the K65R mutation was detected in virus isolates from any of the PMPA-treated or untreated SIVmac055-infected animals. Several additional amino acid changes developed in RT, but they were not exclusively associated with PMPA therapy. The results of this study suggest that prophylactic administration of PMPA to human newborns and to adults following exposure to human immunodeficiency virus will still be beneficial even in the presence of viral variants with reduced susceptibility to PMPA.

In vitro selection and characterization of HIV-1 with reduced susceptibility to PMPA.

9-(2-phosphonomethoxypropyl)adenine (PMPA) has demonstrated remarkable anti-simian immunodeficiency virus (SIV) activity in macaque models of SIV infection and transmission prevention. Recently, PMPA and its oral prodrug, bis-POC PMPA, have also shown potent anti-human immunodeficiency virus type 1 (HIV-1) activity in Phase I clinical studies. In vitro experiments were performed to address the resistance properties of PMPA. After eight passages in increasing concentrations of PMPA, HIV-1IIIB was able to grow in the presence of 2 microM PMPA, fivefold above the IC50 of PMPA for wild-type parental virus. Sequence analysis of the reverse transcriptase (RT) genes from four of 15 RT clones demonstrated the presence of a K65R substitution in RT and recombinant HIV expressing the K65R RT mutation showed a threefold to fourfold increase in IC50 value for PMPA as compared to wild-type. Additional experiments demonstrated that viruses expressing other nucleoside-associated RT resistance mutations all showed wild-type or < threefold reduced susceptibility to PMPA in vitro. Interestingly, lamivudine-resistant viruses expressing the M184V RT mutation showed wild-type to slightly increased susceptibility to PMPA in vitro and addition of the M184V mutation to HIV with the K65R mutation resulted in reversion to wild-type susceptibility for PMPA. In agreement with the cell culture findings, Escherichia coli-expressed K65R RT showed fivefold reduced susceptibility to PMPA diphosphate, the active moiety of PMPA. Furthermore, in combination experiments, PMPA with hydroxyurea showed synergistic inhibition of HIV replication in vitro. The potent antiretroviral activity and favourable resistance profile of PMPA and bis-POC PMPA are being further investigated in ongoing clinical trials.

Human immunodeficiency virus type 1 reverse transcriptase expressing the K70E mutation exhibits a decrease in specific activity and processivity.

Adefovir dipivoxil [9-(2-(bispivaloyloxymethyl)phosphonylmethoxyethyl)adenine (bis-POM PMEA)], an oral prodrug of adefovir (PMEA), is currently in phase III clinical testing for the treatment of human immunodeficiency virus-1 (HIV-1) infection. Previous in vitro experiments have shown that HIV-1 recombinant viruses expressing either a K65R or a K70E mutation in reverse transcriptase (RT) have reduced sensitivity to PMEA and that the K70E mutant also has impaired replication capacity in vitro. Genotypic analyses of samples from patients enrolled in a phase I/II clinical trial of adefovir dipivoxil demonstrated that the K70E RT mutation developed in two of 29 patients during extended therapy. To further investigate the molecular mechanisms involved in the resistance to PMEA, we cloned, expressed, and purified HIV-1 RT enzymes carrying either the K65R or K70E and, for comparison, the M184V mutation. The Km values of dNTPs for these mutant enzymes were not significantly altered from wild-type RT. The Ki values for the K65R mutant were increased from wild-type by 2-5-fold against a variety of inhibitors, whereas the Ki values for the M184V mutant were increased 12-fold specifically for 2', 3'-dideoxy-3'-thiacytidine (3TC) triphosphate. The Ki values for the K70E mutant were increased for PMEA diphosphate and 3TC triphosphate by 2-3-fold. These results are in agreement with antiviral drug susceptibility assay results. The three recombinant enzymes were also evaluated for their specific activities and processivities. All mutants were reduced in specific activity with respect to wild-type RT. In single-cycle processivity studies, the M184V mutant was, as expected, notably impaired. The K70E mutant was also slightly impaired, whereas the K65R mutant was slightly more processive than wild-type. These results with recombinant K70E RT are consistent with the reduced in vitro replication capacity of the K70E RT mutant of HIV-1 and further demonstrate that the K70E mutation confers minor PMEA and 3TC resistance to HIV-1.