We developed a rapid and highly reproducible assay based on real-time PCR (TaqMan, Applied Biosystems, Foster City, CA) to quantitate simian immunodeficiency virus (SIV) RNA in plasma samples. This assay was compared with the current branched-chain DNA assay (Bayer, Emeryville, CA). Results obtained with the real-time TaqMan PCR assay were comparable to those obtained with the branched-chain DNA assay in overlapping ranges of sensitivities (r = 0.9429, p < 0.05). However, the real-time TaqMan PCR assay was capable of detecting as few as 50 copies of RNA/ml, whereas branched-chain DNA was only sensitive to 1,500 copies of RNA/ml. Therefore, several animals that tested negative by branched-chain DNA were positive by realtime TaqMan PCR. Two false positive tests were also recorded for the branched-chain DNA test. False negative and positive tests were confirmed by cell culture isolation and conventional nested RT-PCR. The SIV TaqMan assay detected a wide range of wild-type, cloned, and recombinant SIV strains with similar amplification efficiency, including SIVmac251, SIVmac239, SIVmac239 containing the 184V mutation in RT, SIV1A11, SIVmac239 delta3, SIVmac-M4, and chimeras (SHIVs) containing specific HIV-1 genes, such as reverse transcriptase (RT-SHIV) or Env (SHIV-E). In conclusion, the high sensitivity, increased specificity, wide dynamic range, simplicity, and reproducibility of the real-time SIV RNA quantitation allow the screening of large numbers of samples and make this method especially suitable for measuring both viral DNA and RNA levels during vaccine and therapy studies.
We have modeled highly active antiretroviral therapy (HAART) for AIDS in rhesus macaques infected with a chimera (RT-SHIV) of simian immunodeficiency virus containing reverse transcriptase from human immunodeficiency virus type-1 (HIV-1). Seven RT-SHIV-infected macaques were treated with a combination of efavirenz (200 mg orally once daily), lamivudine (8 mg/kg subcutaneously once daily), and tenofovir (30 mg/kg subcutaneously once daily). Plasma viral RNA levels in all animals were reduced by more than 1,000-fold after 4 weeks and, in six of the seven animals, were reduced to undetectable levels after 10 weeks. Virus loads increased slightly between 12 and 16 weeks of treatment, associated with problems with the administration of efavirenz. After a change in the method of efavirenz administration, virus loads declined again and remained undetectable in the majority of animals for the duration of therapy. Treatment was stopped for three animals after 36 weeks of therapy, and virus loads increased rapidly. Posttreatment RT-SHIV isolates had no mutations associated with resistance to any of the three drugs. Efavirenz treatment was stopped, but lamivudine and tenofovir treatment for two other macaques was continued. The virus load in one of these two animals rebounded; virus from this animal was initially free of drug-resistance mutations but acquired the K65R mutation in reverse transcriptase at 11 weeks after efavirenz treatment was withdrawn. These results mimic HAART of HIV-1-infected humans. The RT-SHIV/rhesus macaque model should be useful for studies of tissue reservoirs and sites of residual replication that are not possible or practical with humans.
Background: We reported previously on the emergence and clinical implications of simian immunodeficiency virus (SIVmac251) mutants with a K65R mutation in reverse transcriptase (RT), and the role of CD8+ cell-mediated immune responses in suppressing viremia during tenofovir therapy. Because of significant sequence differences between SIV and HIV-1 RT that affect drug susceptibilities and mutational patterns, it is unclear to what extent findings with SIV can be extrapolated to HIV-1 RT. Accordingly, to model HIV-1 RT responses, 12 macaques were inoculated with RT-SHIV, a chimeric SIV containing HIV-1 RT, and started on prolonged tenofovir therapy 5 months later.
The specificity of nonnucleoside reverse transcriptase (RT) inhibitors (NNRTIs) for the RT of human immunodeficiency virus type 1 (HIV-1) has prevented the use of simian immunodeficiency virus (SIV) in the study of NNRTIs and NNRTI-based highly active antiretroviral therapy. However, a SIV-HIV-1 chimera (RT-SHIV), in which the RT from SIVmac239 was replaced with the RT-encoding region from HIV-1, is susceptible to NNRTIs and is infectious to rhesus macaques. We have evaluated the antiviral activity of efavirenz against RT-SHIV and the emergence of efavirenz-resistant mutants in vitro and in vivo. RT-SHIV was susceptible to efavirenz with a mean effective concentration of 5.9 ؎ 4.5 nM, and RT-SHIV variants selected with efavirenz in cell culture displayed 600-fold-reduced susceptibility. The efavirenz-resistant mutants of RT-SHIV had mutations in RT similar to those of HIV-1 variants that were selected under similar conditions. Efavirenz monotherapy of RT-SHIV-infected macaques produced a 1.82-log-unit decrease in plasma viral-RNA levels after 1 week. The virus load rebounded within 3 weeks in one treated animal and more slowly in a second animal. Virus isolated from these two animals contained the K103N and Y188C or Y188L mutations. The RT-SHIV-rhesus macaque model may prove useful for studies of antiretroviral drug combinations that include efavirenz.
The methionine-to-valine mutation in codon 184 (M184V) in reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1) or simian immunodeficiency virus (SIV) confers resistance to (؊)-2-deoxy-3-thiacytidine (3TC; lamivudine) and increased sensitivity to 9-[2-(phosphonomethoxy)propyl]adenine (PMPA; tenofovir). We have used the SIV model to evaluate the effect of the M184V mutation on the emergence of resistance to the combination of 3TC plus PMPA. A site-directed mutant of SIVmac239 containing M184V (SIVmac239-184V) was used to select for resistance to both 3TC and PMPA by serial passage in the presence of increasing concentrations of both drugs. Under these selection conditions, the M184V mutation reverted in the majority of the selections. Variants resistant to both drugs were found to have the lysine-to-arginine mutation at codon 65 (K65R), which has previously been associated with resistance to PMPA in both SIV and HIV. Similarly, in rhesus macaques infected with SIVmac239-184V for 46 weeks and treated daily with The rapid emergence of drug-resistant mutants of human immunodeficiency virus (HIV) has proven to be a major obstacle in antiviral therapy for AIDS (7,32,36,63). Even highly active antiretroviral therapy has been limited by the emergence of multidrug-resistant HIV (32,46,61). This has led to efforts to identify drug combinations in which resistance to one drug results in a mutant virus that suppresses normal resistance to a second drug or in a mutant virus that is hypersensitive to other drugs (2,27,28,35,52).One mutation that results in phenotypic changes in HIV type 1 (HIV-1) that are useful in certain drug combinations is the methionine-to-valine mutation in codon 184 (M184V) of reverse transcriptase (RT). This mutation arises rapidly in therapy with the oxathiolane nucleosides, (Ϫ)-2Ј-deoxy-3Ј-thiacytidine (3TC; lamivudine) and (Ϫ)-2Ј-deoxy-5-fluoro-3Ј-thiacytidine [(Ϫ)-FTC], and results in high-level (Ͼ100-fold) resistance to these drugs (49,55). This is often preceded by emergence of a methionine-to-isoleucine mutation in codon 184 (M184I), which is quickly replaced by M184V (22, 50). This M184V mutation is located in the highly conserved YMDD motif of RT, which is directly involved in binding the incoming nucleotide during reverse transcription (19,20,24,53). It results in decreased processivity (1,3,21,23,51) and increased fidelity (11,41,62) of the DNA polymerase activity of RT in biochemical assays. However, the increase in fidelity was less than twofold in an M13 phage-based assay that scored the overall mutation rate after transfection of RT products into bacteria (9). M184V mutants of HIV-1 also have reduced replication rates in certain cell lines (1, 35, 51), and they have a broad array of changes in susceptibility to nucleoside analogs (15,28,35,54,55,64).A major effect of the M184V mutation is to suppress phenotypic resistance to 3Ј-azido-3Ј-deoxythymidine (AZT; zidovudine) when M184V is present along with mutations that normally confer resistance to AZT (28,55). Clinical...
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