Sensitive Phenotypic Detection of Minor Drug-Resistant Human Immunodeficiency Virus Type 1 Reverse Transcriptase Variants

Detection of drug-resistant variants is important for the clinical management of human immunodeficiency virus type 1 (HIV-1) infection and for studies on the evolution of drug resistance. Here we show that hybrid elements composed of the Saccharomyces cerevisiae retrotransposon Ty1 and the reverse transcriptase (RT) of HIV-1 are useful tools for detecting, monitoring, and isolating drug-resistant reverse transcriptases. This sensitive phenotypic assay is able to detect nonnucleoside reverse transcriptase inhibitor-resistant RT domains derived from mixtures of infectious molecular clones of HIV-1 in plasma and from clinical samples when the variants comprise as little as 0.3 to 1% of the virus population. Our assay can characterize the activities and drug susceptibilities of both known and novel reverse transcriptase variants and should prove useful in studies of the evolution and clinical significance of minor drug-resistant viral variants

Multiple, Linked Human Immunodeficiency Virus Type 1 Drug Resistance Mutations in Treatment-Experienced Patients Are Missed by Standard Genotype Analysis

To investigate the extent to which drug resistance mutations are missed by standard genotyping methods, we analyzed the same plasma samples from 26 patients with suspected multidrug-resistant human immunodeficiency virus type 1 by using a newly developed single-genome sequencing technique and compared it to standard genotype analysis. Plasma samples were obtained from patients with prior exposure to at least two antiretroviral drug classes and who were on a failing antiretroviral regimen. Standard genotypes were obtained by reverse transcriptase (RT)-PCR and sequencing of the bulk PCR product. For single-genome sequencing, cDNA derived from plasma RNA was serially diluted to 1 copy per reaction, and a region encompassing p6, protease, and a portion of RT was amplified and sequenced. Sequences from 15 to 46 single viral genomes were obtained from each plasma sample. Drug resistance mutations identified by single-genome sequencing were not detected by standard genotype analysis in 24 of the 26 patients studied. Mutations present in less than 10% of single genomes were almost never detected in standard genotypes (1 of 86). Similarly, mutations present in 10 to 35% of single genomes were detected only 25% of the time in standard genotypes. For example, in one patient, 10 mutations identified by single-genome sequencing and conferring resistance to protease inhibitors (PIs), nucleoside analog reverse transcriptase inhibitors, and nonnucleoside reverse transcriptase inhibitors (NNRTIs) were not detected by standard genotyping methods. Each of these mutations was present in 5 to 20% of the 20 genomes analyzed; 15% of the genomes in this sample contained linked PI mutations, none of which were present in the standard genotype. In another patient sample, 33% of genomes contained five linked NNRTI resistance mutations, none of which were detected by standard genotype analysis. These findings illustrate the inadequacy of the standard genotype for detecting low-frequency drug resistance mutations. In addition to having greater sensitivity, single-genome sequencing identifies linked mutations that confer high-level drug resistance. Such linkage cannot be detected by standard genotype analysis

<i>Ex vivo</i> activation of CD4⁺ T-cells from donors on suppressive ART can lead to sustained production of infectious HIV-1 from a subset of infected cells

<div><p>The fate of HIV-infected cells after reversal of proviral latency is not well characterized. Simonetti, <i>et al</i>. recently showed that CD4⁺ T-cells containing intact proviruses can clonally expand <i>in vivo</i> and produce low-level infectious viremia. We hypothesized that reversal of HIV latency by activation of CD4⁺ T-cells can lead to the expansion of a subset of virus-producing cells rather than their elimination. We established an <i>ex vivo</i> cell culture system involving stimulation of CD4⁺ T-cells from donors on suppressive antiretroviral therapy (ART) with PMA/ionomycin (day 1–7), followed by rest (day 7–21), and then repeat stimulation (day 21–28), always in the presence of high concentrations of raltegravir and efavirenz to effectively block new cycles of viral replication. HIV DNA and virion RNA in the supernatant were quantified by qPCR. Single genome sequencing (SGS) of p6-PR-RT was performed to genetically characterize proviruses and virion-associated genomic RNA. The replication-competence of the virions produced was determined by the viral outgrowth assay (VOA) and SGS of co-culture supernatants from multiple time points. Experiments were performed with purified CD4⁺ T-cells from five consecutively recruited donors who had been on suppressive ART for > 2 years. In all experiments, HIV RNA levels in supernatant increased following initial stimulation, decreased or remained stable during the rest period, and increased again with repeat stimulation. HIV DNA levels did not show a consistent pattern of change. SGS of proviruses revealed diverse outcomes of infected cell populations, ranging from their apparent elimination to persistence and expansion. Importantly, a subset of infected cells expanded and produced infectious virus continuously after stimulation. These findings underscore the complexity of eliminating reservoirs of HIV-infected cells and highlight the need for new strategies to kill HIV-infected cells before they can proliferate.</p></div

Characteristics of study subjects.

<p>Characteristics of study subjects.</p