Effect of tenofovir subtraction on HIV plasma viraemia, CD4+ T-cell count and resistance in a patient with baseline K65R and M184V mutations.

In vitro, the reverse transcriptase mutation K65R can simultaneously reduce drug susceptibility, replicative capacity and restrict HIV-1 replication. Here, we assessed the effect of tenofovir discontinuation for a patient receiving antiretroviral therapy whose HIV-1 had a dominant K65R/M184V genotype. Although limited by the single-case nature, the data support a hypothesis that there is no HIV viral RNA or CD4+ T-cell count benefit of taking tenofovir for experienced patients with genotypic evidence of K65R/M184V.

Differential impact of thymidine analogue mutations on emtricitabine and lamivudine susceptibility.

The impact of drug resistance-associated mutations on subsequent antiretroviral therapy is an important consideration in managing treatment-experienced, HIV-1-infected patients. Lamivudine (3TC) and emtricitabine (FTC) are structurally related nucleoside reverse transcriptase inhibitors (NRTIs) approved for use in HIV-1-infected individuals. To evaluate whether susceptibility differences exist between lamivudine and emtricitabine, the phenotypic impact of common NRTI resistance-associated mutations was compared in HIV-1 from patient samples with paired FTC and 3TC susceptibility results. FTC phenotypic susceptibility was more greatly impacted than 3TC susceptibility in the presence of thymidine analogue mutations (TAMs), as the mean fold-change values were higher for FTC than for 3TC in groups of samples containing TAMs (P < 0.001 for 6 of 7 groups). For samples with K65R, L74I/V, or Q151M mutations, the phenotypic impact was similar, as the mean fold-change was not significantly different between drugs. Although the long-term clinical significance of these differences is unclear, they may suggest differential efficacy in some patients with prior NRTI experience, especially those with HIV harboring TAMs.

Nucleoside and nucleotide analogue reverse transcriptase inhibitors: a clinical review of antiretroviral resistance.

Although advances in highly active antiretroviral therapy (HAART) have made long-term suppression of HIV an achievable goal of therapy, a substantial proportion of first-line regimens will eventually fail. Successful longterm treatment requires consideration of downstream treatment options at the time of initiating or changing regimens. An understanding of the patterns and interactions of resistance mutations, and the appropriate use of genotypic and phenotypic testing is an important component of successful drug sequencing. Resistance to multiple nucleoside reverse transcriptase inhibitors (NRTIs) may result from several genotypically distinct pathways, including the Q151M (151 complex), the 69 insertion complex, two distinct thymidine analogue mutational pathways and the K65R mutation. Knowledge of the clinical implications of these and other resistance pathways, as well as the antagonism or synergy between mutations, helps guide individualized treatment choices from initial therapy in the treatment-naive patient to salvage therapy in the highly treatment-experienced individual. The development of effective sequencing strategies will depend upon the continued understanding of drug resistance mutation patterns and their associations with specific HAART combinations. This review summarizes research advances that further the understanding of nucleoside and nucleotide analogue resistance mutations, and their interplay.