Emerging resistance mutations in PI-naive patients failing an atazanavir-based regimen (ANRS multicentre observational study).

Background: Atazanavir is a PI widely used as a third agent in combination ART. We aimed to determine the prevalence and the patterns of resistance in PI-naive patients failing on an atazanavir-based regimen. Methods: We analysed patients failing on an atazanavir-containing regimen used as a first line of PI therapy. We compared the sequences of reverse transcriptase and protease before the introduction of atazanavir and at failure [two consecutive viral loads (VLs) >50 copies/mL]. Resistance was defined according to the 2014 Agence Nationale de Recherche sur le SIDA et les Hépatites Virales (ANRS) algorithm. Results: Among the 113 patients, atazanavir was used in the first regimen in 71 (62.8%) patients and in the first line of a PI-based regimen in 42 (37.2%). Atazanavir was boosted with ritonavir in 95 (84.1%) patients and combined with tenofovir/emtricitabine or lamivudine (n = 81) and abacavir/lamivudine or emtricitabine (n = 22). At failure, median VL was 3.05 log10 copies/mL and the median CD4+ T cell count was 436 cells/mm3. The median time on atazanavir was 21.2 months. At failure, viruses were considered resistant to atazanavir in four patients (3.5%) with the selection of the following major atazanavir-associated mutations: I50L (n = 1), I84V (n = 2) and N88S (n = 1). Other emergent PI mutations were L10V, G16E, K20I/R, L33F, M36I/L, M46I/L, G48V, F53L, I54L, D60E, I62V, A71T/V, V82I/T, L90M and I93L/M. Emergent NRTI substitutions were detected in 21 patients: M41L (n = 2), D67N (n = 3), K70R (n = 1), L74I/V (n = 3), M184V/I (n = 16), L210W (n = 1), T215Y/F (n = 3) and K219Q/E (n = 2). Conclusions: Resistance to atazanavir is rare in patients failing the first line of an atazanavir-based regimen according to the ANRS. Emergent NRTI resistance-associated mutations were reported in 18% of patients.

Prevalence of HIV-1 drug resistance in treated patients with viral load >50 copies/mL: a 2014 French nationwide study.

Background: Surveillance of HIV-1 resistance in treated patients with a detectable viral load (VL) is important to monitor, in order to assess the risk of spread of resistant viruses and to determine the proportion of patients who need new antiretroviral drugs with minimal cross-resistance. Methods: The HIV-1 protease and reverse transcriptase (RT) and integrase genes were sequenced in plasma samples from 782 consecutive patients on failing antiretroviral regimens, seen in 37 specialized centres in 2014. The genotyping results were interpreted using the ANRS v24 algorithm. Prevalence rates were compared with those obtained during a similar survey conducted in 2009. Results: The protease and RT sequences were obtained in 566 patients, and the integrase sequence in 382 patients. Sequencing was successful in 60%, 78%, 78% and 87% of patients with VLs of 51-200, 201-500, 501-1000 and >1000 copies/mL, respectively. Resistance to at least one antiretroviral drug was detected in 56.3% of samples. Respectively, 3.9%, 8.7%, 1.5% and 3.4% of patients harboured viruses that were resistant to any NRTI, NNRTI, PI and integrase inhibitor (INI). Resistance rates were lower in 2014 than in 2009. Resistance was detected in 48.5% of samples from patients with a VL between 51 and 200 copies/mL. Conclusion: In France in 2014, 90.0% of patients in AIDS care centres were receiving antiretroviral drugs and 12.0% of them had VLs >50 copies/mL. Therefore, this study suggests that 6.7% of treated patients in France might transmit resistant strains. Resistance testing may be warranted in all treated patients with VL > 50 copies/mL.

Stimulation of the human RAD51 nucleofilament restricts HIV-1 integration in vitro and in infected cells.

Stable HIV-1 replication requires the DNA repair of the integration locus catalyzed by cellular factors. The human RAD51 (hRAD51) protein plays a major role in homologous recombination (HR) DNA repair and was previously shown to interact with HIV-1 integrase (IN) and inhibit its activity. Here we determined the molecular mechanism of inhibition of IN. Our standard in vitro integration assays performed under various conditions promoting or inhibiting hRAD51 activity demonstrated that the formation of an active hRAD51 nucleofilament is required for optimal inhibition involving an IN-DNA complex dissociation mechanism. Furthermore we show that this inhibition mechanism can be promoted in HIV-1-infected cells by chemical stimulation of the endogenous hRAD51 protein. This hRAD51 stimulation induced both an enhancement of the endogenous DNA repair process and the inhibition of the integration step. Elucidation of this molecular mechanism leading to the restriction of viral proliferation paves the way to a new concept of antiretroviral therapy based on the enhancement of endogenous hRAD51 recombination activity and highlights the functional interaction between HIV-1 IN and hRAD51.

Structure-analysis of the HIV-1 integrase Y143C/R raltegravir resistance mutation in association with the secondary mutation T97A.

The HIV-1 integrase (IN) mutations Y143C/R are known as raltegravir (RAL) primary resistance mutations. In a previous study (S. Reigadas et al., PLoS One 5:e10311, 2010), we investigated the genetic pathway and the dynamics of emergence of the Y143C/R mutations in three patients failing RAL-containing regimens. In these patients, the Y143C/R mutation was associated with the T97A mutation. The aim of the present biochemical and molecular studies in vitro was to evaluate whether the secondary mutation, T97A, associated with the Y143C/R mutation could increase the level of resistance to RAL and impact IN activities. Site-directed mutagenesis experiments were performed with expression vectors harboring the region of the pol gene coding for IN. With a 3'-end processing assay, the 50% inhibitory concentrations (IC(50)) were 1.2 µM, 1.2 µM, 2.4 µM (fold change [FC], 2), and 20 µM (FC, 16.7) for IN wild type (WT), the IN T97A mutation, the IN Y143C/T97A mutation, and the IN Y143R/T97A mutation, respectively. FCs of 18 and 100 were observed with the strand transfer assay for IN Y143C/T97A and Y143R/T97A mutations, with IC(50) of 0.625 µM and 2.5 µM, respectively. In the strand transfer assay, the IN Y143C or R mutation combined with the secondary mutation T97A severely impaired susceptibility to RAL compared to results with the IN Y143C or R mutation alone. Assays without RAL suggested that the T97A mutation could rescue the catalytic activity which was impaired by the presence of the Y143C/R mutation. The combination of the T97A mutation with the primary RAL resistance mutations Y143C/R strongly reduces the susceptibility to RAL and rescues the catalytic defect due to the Y143C/R mutation. This result indicates that the emergence of the Y143C/R/T97A double-mutation pattern in patients is a signature of a high resistance level.

Hepatitis C virus (HCV) protease variability and anti-HCV protease inhibitor resistance in HIV/HCV-coinfected patients.

OBJECTIVES: Data on the natural selection of isolates harbouring mutations within the NS3 protease, conferring resistance to hepatitis C virus (HCV) protease inhibitors (PIs), are limited for HIV/HCV-coinfected patients. The aim of this study was to describe the natural prevalence of mutations conferring resistance to HCV PIs in HIV/HCV-coinfected patients compared with HCV-monoinfected patients. METHODS: The natural prevalences of HCV PI resistance mutations in 120 sequences from HIV/HCV-coinfected patients (58 genotype 1a, 18 genotype 1b and 44 genotype 4) and 501 sequences from HCV-monoinfected patients (476 genotype 1 and 25 genotype 4), retrieved from GenBank as a control group, were compared. RESULTS: Of 76 sequences from HIV/HCV genotype 1-coinfected patients, six (7.9%) showed amino acid substitutions associated with HCV PI resistance (V36L, n=1; V36M, n=2; T54S, n=2; R155K, n=1). In 31 of 476 (6.5%) HCV genotype 1 sequences retrieved from the GenBank database, HCV PI resistance mutations were found. The difference was not statistically significant (P=0.6). All of the sequences from HIV/HCV genotype 4-coinfected patients and those retrieved from the GenBank database had amino acid changes at position 36 (V36L). CONCLUSION: Our study suggests that the natural prevalence of strains resistant to HCV PIs does not differ between HCV-monoinfected and HIV/HCV-coinfected patients. Further studies on larger cohorts are needed to confirm these findings and to evaluate the impact of these mutations in clinical practice.

Quantitation of HIV-1 RNA in dried blood and plasma spots.

Dried blood spots (DBSs) and dried plasma spots (DPSs) are an attractive method for serological and molecular diagnosis of HIV infection. Recently, Youngpairoj et al. [Youngpairoj, A.S., Masciotra, S., Garrido, C., Zahonero, N., de Mendoza, C., Garcia-Lerma, J.G., 2008. HIV-1 drug resistance genotyping from dried blood spots stored for 1 year at 4 degrees C. J. Antimicrob. Chemother. 61, 1217-1220] showed that HIV-1 can be genotyped efficiently from DBS specimens stored at 4 degrees C for 1 year. The viral load obtained from DBS and DPS samples was compared with that obtained from plasma samples. A total of 86 samples was prepared from people infected with HIV subtype B or non-B and spotted on 903 filter papers stored with desiccant at 4 degrees C. RNA was extracted using the QIAamp Viral RNA mini kit (Qiagen, Courtaboeuf, France). RNA from DBS or DPS samples was quantified in accordance with the Agence Nationale de Recherche sur le SIDA (ANRS, AC11, Paris, France) assay for HIV-1 quantitation. When the mean viral load of plasma samples and DPS samples or plasma samples and DBS samples were compared, there were no significant differences. The overall data showed that although the sensitivity threshold of the assays was different, there was a correlation between the three specimen types and that DBS and DPS samples can be routinely used for viral load quantification particularly in resource-limited settings.

HCV RNA-dependent RNA polymerase replicates in vitro the 3' terminal region of the minus-strand viral RNA more efficiently than the 3' terminal region of the plus RNA.

The NS5B protein, or RNA-dependent RNA polymerase of the hepatitis virus type C, catalyzes the replication of the viral genomic RNA. Little is known about the recognition domains of the viral genome by the NS5B. To better understand the initiation of RNA synthesis on HCV genomic RNA, we used in vitro transcribed RNAs as templates for in vitro RNA synthesis catalyzed by the HCV NS5B. These RNA templates contained different regions of the 3' end of either the plus or the minus RNA strands. Large differences were obtained depending on the template. A few products shorter than the template were synthesized by using the 3' UTR of the (+) strand RNA. In contrast the 341 nucleotides at the 3' end of the HCV minus-strand RNA were efficiently copied by the purified HCV NS5B in vitro. At least three elements were found to be involved in the high efficiency of the RNA synthesis directed by the HCV NS5B with templates derived from the 3' end of the minus-strand RNA: (a) the presence of a C residue as the 3' terminal nucleotide; (b) one or two G residues at positions +2 and +3; (c) other sequences and/or structures inside the following 42-nucleotide stretch. These results indicate that the 3' end of the minus-strand RNA of HCV possesses some sequences and structure elements well recognized by the purified NS5B.