Gilead Sciences, 333 Lakeside Drive, Foster City, CA 94404, USA
Keywords: HIV, antiretrovirals, tenofovir, resistance
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Resistance background |
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A recent addition to the antiretroviral armamentarium is the nucleotide analogue tenofovir disoproxil fumarate (Viread), approved for use in the USA and the European Union. Tenofovir is unique among the NRTIs in that it is an acyclic nucleoside phosphonate, analogous to the monophosphate form of the other NRTIs.4 Tenofovir disoproxil fumarate is an oral prodrug of tenofovir that is rapidly converted into tenofovir upon absorption.5,6 Tenofovir has activity in vitro against both HIV-1 and HIV-2,7,8 and in resting and activated T cells, monocytes and macrophages.8,9 Cross-resistance within the NRTI class of drugs has important clinical consequences for patients who are highly treatment experienced, or for those patients in whom primary HIV infection is associated with the transmission of a resistant virus.10 In this article, we will discuss some of the features of tenofovir disoproxil fumarate that highlight its utility in the treatment of NRTI-resistant HIV-1.
Resistance to the six previously approved NRTIs has been observed both in vitro and in vivo. Each NRTI induces a relatively defined set of resistance mutations that are located in or near the substrate-binding pocket of RT. Two mechanisms of resistance have been defined; the first mechanism involves steric hindrance, in which the resistance mutation directly interferes with the binding and incorporation of the NRTI, as observed for lamivudine and its signature mutation M184V.11 The second mechanism involves ATP-mediated excision of the newly incorporated NRTI that is removed by the RT, in a reaction that is the reverse of the incorporation reaction.12 The resistance mutations [known as thymidine analogue mutationsor TAMs (M41L, D67N, K70R, L210W, T215F/Y and K219Q/E/N)] that accumulate with continuing zidovudine or stavudine exposure appear to mediate resistance via this mechanism.13 In addition to their effects on zidovudine and stavudine susceptibility, the TAMs can mediate cross-resistance to a number of other NRTIs. Cross-resistance to didanosine and zalcitabine, due to the TAMs, has been observed, even though these NRTIs do not usually select for TAMs. Cross-resistance to lamivudine, in the presence of TAMs, has also been documented in lamivudine-naive patients, despite the absence of the M184V mutation.14 Susceptibility to abacavir is also reduced in the presence of TAMs, and resistance rises notably with the addition of M184V.15 The clinical significance of these reductions in abacavir susceptibility has been confirmed in multiple clinical trials.16,17 TAMs can therefore affect susceptibility to all six NRTIs. Other mutations, such as the Q151M multidrug resistance complex and T69 insertions, although rare, cause high-level resistance to all six NRTIs.18,19
From analyses in vitro, tenofovir appears active against a wide variety of NRTI-resistant strains, including viruses with some TAMs (D67N + K70R + T215Y), didanosine (L74V) or zalcitabine (T69D) resistance mutations.20,21 Susceptibility to tenofovir can also be enhanced by the presence of the M184V mutation induced by lamivudine.20,22 Unlike other NRTIs, tenofovir retains activity against the Q151M complex of mutations, whereas isolates carrying the T69SS insertion mutations show high-level resistance to tenofovir.23 Tenofovir can select for the K65R mutation in vitro, as can zalcitabine, didanosine and abacavir, and this mutation results in a three- to four-fold decreased susceptibility to tenofovir.15,20,24,25 However, K65R has a very low prevalence (<2%) in the antiretroviral-experienced population.26
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Clinical virology analyses of tenofovir disoproxil fumarate: study 902 |
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In a virology substudy,27 patients with HIV-1 containing TAMs, or the M184V mutation at baseline, demonstrated statistically significant reductions in HIV-1 RNA, compared with the placebo group. Patients carrying the M184V mutation showed stronger responses to tenofovir disoproxil fumarate 300 mg than patients without M184V (mean DAVG24s were 0.64 log10 and 0.35 log10 copies/mL, respectively), but subtracting the response of the placebo group negated this effect, suggesting it was not specific to tenofovir disoproxil fumarate therapy. The HIV RNA response in patients with TAMs (0.52 log10 copies/mL) was notable as these patients had a mean of 2.8 TAMs. Statistically significant reductions in HIV-1 RNA were also observed in those patients whose HIV-1 carried the TAM that is associated with the highest level of zidovudine resistance, T215Y/F.
Patients were monitored for the emergence of new resistance mutations during the trial. Post-baseline genotypic analyses obtained on 159 patients suggested that background therapy, and not tenofovir disoproxil fumarate, was driving the appearance of the majority of new mutations during the trial. Seventy-nine patients developed new NRTI-associated mutations by week 48, and the majority were TAMs (n = 63, 34%) in patients taking the thymidine analogues zidovudine or stavudine. Four patients (2%) developed K65R by week 48; these four patients were also receiving didanosine+stavudine (n = 2), didanosine (n =1) or abacavir (n = 1). It was unclear which drug drove the selection of K65R, but phenotypic analysis confirmed a decrease in susceptibility to tenofovir (2.83.9-fold). Phenotypic analyses were performed for all patients originally treated with tenofovir disoproxil fumarate 300 mg. For the 53 patients for whom baseline results were obtained, the mean susceptibility to tenofovir was 1.9-fold above wild-type. In contrast, mean susceptibility at baseline to zidovudine and lamivudine was 13.8-fold and greater than 24-fold above wild-type, respectively, indicating significant resistance to zidovudine and lamivudine. Patients with up to four-fold reduced susceptibility to tenofovir at baseline had reductions in HIV-1 RNA from 0.55 to 0.71 log10 copies/mL. Greater than a four-fold reduction in tenofovir susceptibility at baseline was rare, occurring in four patients, but these patients did not appear to respond to tenofovir disoproxil fumarate. One of these patients had K65R and the others had extensive TAMs and other mutations. Post-baseline phenotypic analyses confirmed that only development of K65R was associated with decreased susceptibility to tenofovir by 48 weeks.
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Study 907 |
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Analysis of responses by baseline genotype showed that patients with HIV carrying one to two TAMs, or three or more TAMs without M41L or L210W, responded similarly to those without TAMs.30 There was reduced susceptibility to tenofovir disoproxil fumarate in those patients with HIV-1 expressing three or more TAMs at baseline, which included M41L or L210W. As in study 902, development of new NRTI mutations was predominantly due to the background therapy, and tenofovir disoproxil fumarate did not appear to select for the development of TAMs.31 Over the 48 week course of the trial, eight patients out of 253 (3%) analysed developed the K65R mutation. In contrast, 79 patients (31%) developed one or more TAM while taking a thymidine analogue in their background regimen. In addition to either a PI or NNRTI, the eight patients who developed K65R were taking lamivudine together with zidovudine (n = 3), stavudine (n = 2) or abacavir (n = 3). There was a highly variable response to tenofovir disoproxil fumarate among these eight patients, with week 48 HIV-1 RNA changes ranging from 1.15 log10 to +0.86 log10 copies/mL (mean 0.28 log10 copies/mL). Three of the patients who developed K65R maintained a 0.68 log10 HIV-1 RNA suppression.31 Phenotypic analysis showed only a mean 1.7-fold change in tenofovir susceptibility from baseline among these patients (n = 8), suggesting the effects of the K65R mutation on tenofovir susceptibility may vary depending on the genetic background of a particular isolate. Furthermore, all patients developing K65R retained full susceptibility to zidovudine and stavudine.31
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Conclusions and commentary |
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These studies have shown that tenofovir disoproxil fumarate does not select for the appearance of new TAMs; however, evidence was noted for a reduced response to tenofovir disoproxil fumarate therapy if three or more TAMs with the mutations M41L or L210W were present at baseline. In patients whose HIV had three or more TAMs, but which did not include the mutations M41L or L210W, there was no significant reduction in response. The mechanisms leading to this reduced response in the presence of M41L or L210W is currently unknown, but is likely to involve chain terminator removal. However, given that tenofovir does not select for TAMs, it provides a rationale for using tenofovir in a thymidine analogue-sparing regimen. A thymidine analogue-sparing regimen may be beneficial for both treatment-experienced and treatment-naive patients where use of tenofovir disoproxil fumarate will not result in the development of TAMs, thereby providing further therapy options to both patients and physicians.
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Footnotes |
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References |
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27 . Margot, N. A., Isaacson, E., McGowan, I., Cheng, A. K., Schooley, R. T. & Miller, M. D. (2002). Genotypic and phenotypic analyses of HIV-1 in antiretroviral-experienced patients treated with tenofovir DF. AIDS 16, 122735.[CrossRef][ISI][Medline]
28 . Schooley, R. T., Ruane, P., Myers, R. A., Beall, G., Lampiris, H., Berger, D. et al. (2002). Tenofovir DF in antiretroviral-experienced patients: results from a 48-week, randomized, double-blind study. AIDS 16, 125763.[CrossRef][ISI][Medline]
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30 . Miller, M. D., Margot, N. A. & Lu, B. (2002). Effect of baseline nucleoside-associated resistance on response to tenofovir DF (TDF) therapy: integrated analyses of studies 902 and 907. In Program and Abstracts of the Ninth Conference on Retroviruses and Opportunistic Infections, Seattle, WA, USA, 2002. Abstract 43, p. 68. Foundation for Retrovirology and Human Health, Alexandria, VA, USA.
31 . Margot, N. A., Johnson, A., Coakley, D. F., Cheng, A. & Miller, M. D. (2002). Final 48 week genotypic and phenotypic analyses of study 907: tenofovir DF (TDF) added to stable background regimens. In Program and Abstracts of the Ninth Conference on Retroviruses and Opportunistic Infections, Seattle, WA, USA, 2002. Abstract 414-W, p. 209. Foundation for Retrovirology and Human Health, Alexandria, VA, USA.
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White, K. L., Margot, N. A., Wrin, T., Petropoulos, C. J., Miller, M. D. & Naeger, L. K. (2002). Molecular mechanisms of resistance to human immunodeficiency virus type 1 with reverse transcriptase mutations K65R and K65R+M184V and their effects on enzyme function and viral replication capacity. Antimicrobial Agents and Chemotherapy 46, 343746.