Reverse Transcriptase Drug Research Articles

Virtual Screening for Potential Hepatitis B Virus Non-Nucleoside Reverse Transcriptase Inhibitors

<b>Abstract ID 23309</b> <b>Poster Board 292</b> Hepatitis B virus (HBV) is a major global health problem. Current HBV therapies are not curative, so improved therapeutics are urgently needed to develop combinations of novel drugs to achieve a cure. HBV replication is catalyzed by the viral polymerase (P) protein with reverse transcriptase and ribonuclease H activities. The P protein is vital for HBV replication and provides a great target for new therapies against HBV. We recently predicted and validated the structure of P for the first time (Tajwar et&nbsp;al., <i>Protein Science</i> 31:e4421). Using SiteMap from the Schrödinger Suite software, we found three potential non-active site targets on the HBV P protein analogous to the targets for HIV non-nucleoside reverse transcriptase (NNRTI) drugs. We conducted a three-tier high throughput virtual screen using the Chembridge CORE library of 830,000+ compounds against the three target sites. The top scoring 300 compounds per site were re-scored using induced-fit docking. Docking scores were as low as -12.6 kCal/mol. We then examined the top hits for ligand uniqueness, binding poses, compound conformational stability and rigidity, cLogP values, and chemotype clustering, followed by manual selection of ∼50 compounds per target site for wet-bench testing. The chosen compounds are being assayed for toxicity and ability to inhibit HBV replication in cells. The long-term goals are to launch medicinal chemistry optimization campaigns to generate novel HBV NNRTI drugs and to develop tool compounds for mechanistic analysis of HBV reverse transcription. Support/Funding Information: Seed grant from the Saint Louis University Liver Center

Synergistic antiviral activity against drug-resistant HIV-1 by naturally occurring dipeptide and A single-stranded oligonucleotide

The novel dipeptide WG-am and single-stranded oligonucleotide combination (WG-am:ssON) showed synergistic antiviral activity against HIV-1 integrase-, protease- or reverse transcriptase drug resistant isolates, with over 95% reduction. The highest selectivity indexes were for integrase resistant isolates. WG-am:ssON can be a future option for treatment of HIV drug-resistant strains.

No transmitted drug resistance to HIV integrase strand-transfer inhibitors after their scale-up in Estonia in 2017

In Eastern Europe HIV-1 transmitted drug resistance (TDR) data, especially in integrase (IN) region is limited. In Estonia INSTI (Integrase Strand Transfer Inhibitors) TDR has been studied only prior to the INSTI scale-up in late 2010s. Current study aimed to determine the levels of protease (PR), reverse transcriptase (RT) and IN surveillance drug resistance mutations (SDRMs) among newly diagnosed patients in Estonia in 2017. Study included 216 newly diagnosed HIV-1 individuals from January 1 until December 31, 2017 in Estonia. Demographic and clinical data were obtained from the Estonian Health Board, Estonian HIV Cohort Study (E-HIV) and clinical laboratories' databases. The PR-RT and IN regions were sequenced and analyzed for SDRMs and subtype determination. Seventy-one percent (151/213) of available HIV-positive samples were successfully sequenced. The overall level of TDR was 7.9% (12/151; 95% CI 4.4-13.8%); no dual or triple class resistance was detected. No major INSTI mutations were found. The distribution of SDRMs for NNRTI, NRTI and PI was 5.9% (9/151), 1.3% (2/151) and 0.7% (1/151), respectively. The predominant NNRTI mutation was K103N. CRF06_cpx was predominant variant (59%) in Estonian HIV-1 population followed by subtype A (9%) and subtype B (8%). Although no major INSTI mutations were found, close monitoring of INSTI SDRMs is needed considering the extensive use of the first and second-generation INSTIs. PR-RT TDR is slowly rising in Estonia indicating the need for continuous surveillance in the future. Low genetic barrier NNRTIs should be avoided in the treatment regimens.

Insights into HIV-1 Reverse Transcriptase (RT) Inhibition and Drug Resistance from Thirty Years of Structural Studies.

The enzyme reverse transcriptase (RT) plays a central role in the life cycle of human immunodeficiency virus (HIV), and RT has been an important drug target. Elucidations of the RT structures trapping and detailing the enzyme at various functional and conformational states by X-ray crystallography have been instrumental for understanding RT activities, inhibition, and drug resistance. The structures have contributed to anti-HIV drug development. Currently, two classes of RT inhibitors are in clinical use. These are nucleoside/nucleotide reverse transcriptase inhibitors (NRTIs) and non-nucleoside reverse transcriptase inhibitors (NNRTIs). However, the error-prone viral replication generates variants that frequently develop resistance to the available drugs, thus warranting a continued effort to seek more effective treatment options. RT also provides multiple additional potential druggable sites. Recently, the use of single-particle cryogenic electron microscopy (cryo-EM) enabled obtaining structures of NNRTI-inhibited HIV-1 RT/dsRNA initiation and RT/dsDNA elongation complexes that were unsuccessful by X-ray crystallography. The cryo-EM platform for the structural study of RT has been established to aid drug design. In this article, we review the roles of structural biology in understanding and targeting HIV RT in the past three decades and the recent structural insights of RT, using cryo-EM.

Insight investigation of rilpivirine and compounds from mushrooms as feline immunodeficiency virus reverse transcriptase inhibitors using molecular dynamics simulations and quantum chemical calculations

ABSTRACT Because the pathogenesis of feline immunodeficiency virus (FIV) is similar to the human immunodeficiency virus (HIV) infection, FIV is also used as a model for the drug discovery of HIV. A known HIV reverse transcriptase (RT) drug, i.e. rilpivirine, was found to inhibit FIV RT. However, there is no potent vaccine and drug for FIV treatment. In this work, the binding of rilpivirine in FIV RT is investigated. Moreover, virtual screening was applied to search from an in-house mushroom database namely ‘Bacmushbase’ to look for the new candidates from mushrooms. Two compounds from cordyceps, cordyceamides A and B, were found to be possible to bind with FIV RT which were supported by the previous report about their potential extracts for inhibiting FIV RT. Consequently, molecular dynamics simulations and quantum chemical calculations were applied to confirm their binding capabilities. From MM-PBSA and QM/MM calculations, the average binding free energies of cordyceamide A are better than those of rilpivirine. Moreover, residual interaction energies revealed the important H-bond, H-pi and pi-pi interactions to residues in the binding pocket. From the results, the binding interaction to FIV RT will be useful for FIV drug development in the future.

Repurposing an HIV Drug for Zika Virus Therapy.

Repurposing an HIV Drug for Zika Virus Therapy.

A viral genome wide association study and genotypic resistance testing in patients failing first line antiretroviral therapy in the first large countrywide Ethiopian HIV cohort

BackgroundAntiretroviral therapy (ART) was rolled-out in Ethiopia in 2005, but there are no reports on outcome of ART and human immunodeficiency virus drug resistance (HIVDR) at national level. We described acquired drug resistance mutations in pol gene and performed a viral genome wide association study in virologic treatment failure patients who started first line ART during 2009–2011 in the first large countrywide HIV cohort in Ethiopia.MethodsThe outcome of tenofovir (TDF)- and zidovudine (ZDV)-based ART was defined in 874 ART naïve patients using the on-treatment (OT) and intention-to-treat (ITT) analyses. Genotypic resistance testing was done in patients failing ART (> 1000 copies/ml) at month 6 and 12. Near full-length genome sequencing (NFLG) was used to assess amino acid changes in HIV-1 gag, pol, vif, vpr, tat, vpu, and nef genes between paired baseline and month 6 samples.ResultsHigh failure rates were found in ITT analysis at month 6 and 12 (23.3%; 33.9% respectively). Major nucleoside and non-nucleoside reverse transcriptase (NRTI/NNRTI) drug resistance mutations were detected in most failure patients at month 6 (36/47; 77%) and month 12 (20/30; 67%). A high rate of K65R was identified only in TDF treated patients (35.7%; 50.0%, respectively). No significant difference was found in failure rate or extent of HIVDR between TDF- and ZDV- treated patients. All target regions of interest for HIVDR were described by NFLG in 16 patients tested before initiation of ART and at month 6.ConclusionIn this first Ethiopian national cohort, a high degree of HIVDR was seen among ART failure patients, independent on whether TDF- or ZDV was given. However, the major reason to ART failure was lost-to-follow-up rather than virologic failure. Our NFLG assay covered all relevant target genes for antiretrovirals and is an attractive alternative for HIVDR surveillance.

Development of Analytical Method by RP-HPLC Method for Validation of Emtricitabine in API and Pharmaceutical Dosage Form

A novel reverse phase liquid chromatographic method was developed and validated for estimation of perinatal HIV-1 reverse transcriptase drug, emtricitabine which also active against Hepatitis B virus in its dosage form i.e. tablets. The reverse phase HPLC analysis was carried out with isocratic system. The column was Peerless basic C18 (50mm x 4.6mm, 3μm) with ambient temperature. The mobile phase consisted of buffer: methanol in proportion 90:10% (v/v). The flow rate was maintained at 1 ml/min. The detection was carried out at wavelength 280 nm. The method was validated as per ICH guidelines for system suitability, linearity, accuracy and precision. The linear ranges were 50–150 μg/ml for emtricitabine. The accuracy and precision were found to be well within the acceptable limit. The method was successfully applied for determination emtricitabine in dosage form with good recoveries.

High discordance in blood and genital tract HIV-1 drug resistance in Indian women failing first-line therapy.

Examine HIV-1 plasma viral load (PVL) and genital tract (GT) viral load (GVL) and drug resistance in India. At the YRG Centre for AIDS Research and Education, Chennai, we tested: PVL in women on first-line ART for ≥6 months; GVL when PVL >2000 copies/mL; and plasma, genital and proviral reverse transcriptase drug resistance when GVL >2000 copies/mL. Wilcoxon rank-sum and Fisher's exact tests were used to identify failure and resistance associations. Pearson correlations were calculated to evaluate PVL-GVL associations. Inter-compartmental resistance discordance was evaluated using generalized estimating equations. Of 200 women, 37% had detectable (>400 copies/mL) PVL and 31% had PVL >1000 copies/mL. Of women with detectable PVL, 74% had PVL >2000 copies/mL, of which 74% had detectable GVL. Higher PVL was associated with higher GVL. Paired plasma and genital sequences were available for 21 women; mean age of 34 years, median ART duration of 33 months, median CD4 count of 217 cells/mm3, median PVL of 5.4 log10 copies/mL and median GVL of 4.6 log10 copies/mL. Drug resistance was detected in 81%-91% of samples and 67%-76% of samples had dual-class resistance. Complete three-compartment concordance was seen in only 10% of women. GT-proviral discordance was significantly larger than plasma-proviral discordance. GT or proviral mutations discordant from plasma led to clinically relevant resistance in 24% and 30%, respectively. We identified high resistance and high inter-compartmental resistance discordance in Indian women, which might lead to unrecognized resistance transmission and re-emergence compromising treatment outcomes, particularly relevant to countries like India, where sexual HIV transmission is predominant.

Low prevalence of transmitted HIV-1 drug resistance detected by a dried blood spot (DBS)-based next-generation sequencing (NGS) method in newly diagnosed individuals in Cameroon in the years 2015-16.

To determine the most recent prevalence, transmission patterns and risk factors of transmitted drug-resistance mutations (TDRMs) in Cameroon, we initiated a multicentre study monitoring HIV-1 drug resistance in newly HIV-1-diagnosed individuals using a novel next-generation sequencing (NGS) assay applicable to fingerprick dried blood spot (DBS) samples. Fingerprick DBS samples and questionnaires were collected from 360 newly HIV-1-diagnosed individuals in four hospitals in urban areas in Cameroon in the years 2015-16. We developed an HIV-1 protease and reverse transcriptase drug resistance genotyping assay applicable to DBS samples and HIV-1 genomes of groups M, N and O. The WHO 2009 list of mutations for surveillance of transmitted drug-resistant HIV strains was used to analyse TDRMs. Applying our 'DBS-NGS-genotypic resistance test', baseline HIV-1 drug resistance data were successfully obtained from 82.8% (298/360) of newly diagnosed individuals. At nucleotide frequencies >15%, TDRMs to NRTIs were observed in 3.0% (9/298), to NNRTIs in 4.0% (12/298) and to PIs in 1.3% (3/240). The NNRTI mutation K103N was most commonly detected (2.7%). Expanding the analysis to low-abundance TDRMs, i.e. 3%-15%, 12 additional individuals (4.0%) harbouring TDRMs were identified. Having unprotected sex with a known HIV-1-positive person was significantly associated with the transmission of DRMs (adjusted OR 9.6; 95% CI 1.79-51.3). The prevalence of transmitted HIV-1 drug resistance is currently low in the study sites in Cameroon. Evidence of some risky sexual behaviours depicts a public health problem with possible implications for the prevention of new HIV-1 infections.

Combination of the R263K and M184I/V resistance substitutions against dolutegravir and lamivudine decreases HIV replicative capacity.

We investigated the effect of combining the dolutegravir-specific R263K integrase resistance substitution with either M184I or M184V, two reverse transcriptase drug resistance substitutions that are frequently detected in individuals failing therapeutic regimens containing either lamivudine or emtricitabine. The presence of R263K and M184I/V in a single virus resulted in substantial further decreases in the viral replicative capacity compared to that in the presence of single substitutions alone.

Mechanisms of Anti-retroviral Drug Resistance: Implications for Novel Drug Discovery and Development

Anti-retroviral drug resistance evolves as an inevitable consequence of expanded combination Anti-retroviral Therapy (cART). According to each drug class, resistance mutations may occur due to the infidel nature of HIV reverse transcriptase (RT) and inadequate drug pressures. Correspondingly, resistance to Nucleoside Reverse Transcriptase Inhibitors (NRTIs) occurs due to incorporation impairment of the agent or its removal from the elongating viral DNA chain. With regard to Non-Nucleoside Reverse Transcriptase Inhibitors (NNRTIs), resistance mutations may alter residues of the RT hydrophobic pocket and demonstrate high level of cross resistance. However, resistance to Protease Inhibitors requires complex accumulation of primary and secondary mutations that substitute amino acids in proximity to the viral protease active site. Resistance to novel entry inhibitors may also evolve as a result of mutations that affect the interactions between viral glycoprotein and CD4 or the chemokine receptors. According to the current studies, future drug initiative programs should consider agents that possess higher genetic barrier toward resistance for ascertaining adequate drug efficacy among patients who have failed first-line regimens.

Sequence and structure based models of HIV-1 protease and reverse transcriptase drug resistance.

BackgroundSuccessful management of chronic human immunodeficiency virus type 1 (HIV-1) infection with a cocktail of antiretroviral medications can be negatively affected by the presence of drug resistant mutations in the viral targets. These targets include the HIV-1 protease (PR) and reverse transcriptase (RT) proteins, for which a number of inhibitors are available on the market and routinely prescribed. Protein mutational patterns are associated with varying degrees of resistance to their respective inhibitors, with extremes that can range from continued susceptibility to cross-resistance across all drugs.ResultsHere we implement statistical learning algorithms to develop structure- and sequence-based models for systematically predicting the effects of mutations in the PR and RT proteins on resistance to each of eight and eleven inhibitors, respectively. Employing a four-body statistical potential, mutant proteins are represented as feature vectors whose components quantify relative environmental perturbations at amino acid residue positions in the respective target structures upon mutation. Two approaches are implemented in developing sequence-based models, based on use of either relative frequencies or counts of n-grams, to generate vectors for representing mutant proteins. To the best of our knowledge, this is the first reported study on structure- and sequence-based predictive models of HIV-1 PR and RT drug resistance developed by implementing a four-body statistical potential and n-grams, respectively, to generate mutant attribute vectors. Performance of the learning methods is evaluated on the basis of tenfold cross-validation, using previously assayed and publicly available in vitro data relating mutational patterns in the targets to quantified inhibitor susceptibility changes.ConclusionOverall performance results are competitive with those of a previously published study utilizing a sequence-based strategy, while our structure- and sequence-based models provide orthogonal and complementary prediction methodologies, respectively. In a novel application, we describe a technique for identifying every possible pair of RT inhibitors as either potentially effective together as part of a cocktail, or a combination that is to be avoided.

Effects of HIV protease, nucleoside/non-nucleoside reverse transcriptase inhibitors on Bax, Bcl-2 and apoptosis in two cervical cell lines

Protease inhibitors (PIs) and reverse transcriptase drugs are important components of highly active antiretroviral therapy (HAART) for treating human acquired immunodeficiency syndrome (AIDS). Long-term clinical therapeutic efficacy and treatment compliance of these agents have been limited by undesirable adverse effects and their oncogenicity has been queried. This study investigated the effects of selected antiretroviral agents on the expression of key apoptotic regulatory genes; Bax and Bcl-2 in two cervical cell lines HCS-2 and NCE16IIA by real-time qPCR gene expression and immunocytochemistry. The anti-apoptotic effects of the PI-LPV/r were investigated by cell death detection ELISA and acridine orange staining. All the antiretroviral drugs and combinations tested had no effects on Bax and Bcl-2 gene expression and protein localisation in both cell lines. The protease inhibitors-LPV/r exhibited significant (P<0.05) inhibition of camptothecin-induced apoptosis in the cervical cancer HCS-2 cell line but not in the normal immortalised NCE16IIA cell line. This anti-apoptotic property of HIV protease inhibitors, although shown so far not to involve protein and RNA synthesis might promote the development of cancer.

Detection of Low-Frequency HIV Type 1 Reverse Transcriptase Drug Resistance Mutations by Ultradeep Sequencing in Naive HIV Type 1-Infected individuals

Genotypic resistance testing is recommended to evaluate the susceptibility of HIV to antiretroviral drugs. These tests are based on bulk population sequencing and thus consider only variants representing more than 20% of the viral population, whereas next generation sequencing methods allow detection below this threshold. We aimed to evaluate the potential use of ultradeep pyrosequencing (UDPS) for genotypic resistance testing in clinical routine at the University Hospital of Bordeaux, France. We performed UDPS on reverse transcriptase (RT) from 47 HIV-1 individuals, naive of antiretroviral treatment and for whom genotypic resistance testing was requested for clinical management in 2011-2012. In 8.5% of the patients, only low-frequency variants harboring RT drug resistance mutations were detected raising the question of their clinical significance. Rilpivirine-associated resistance mutations were detected in 19.1% of our population study. To conclude, UDPS could become a routine tool for the evaluation of HIV-infected patients in hospital laboratories.

Prolonged and Substantial Discordance in Prevalence of Raltegravir-Resistant HIV-1 in Plasma versus PBMC Samples Revealed by 454 “Deep” Sequencing

The evolution of drug resistance mutations in plasma samples is relatively well-characterized. However, the viral population and diversity in other body compartments such as peripheral blood mononuclear cells (PBMC) remains poorly understood. Previous studies have mostly focused on protease and reverse transcriptase drug resistance mutations (DRMs). In this study, we used 454 “deep” sequencing technology to observe and quantify longitudinally the prevalence of resistance mutations associated with the integrase inhibitor, raltegravir, in plasma versus PBMC samples from a San Francisco-based cohort. Four heavily treatment-experienced subjects were monitored in this study over a median of 1.2 years since the initiation of raltegravir-containing regimens. We observed a consistent discordance in the prevalence of DRMs, but not resistance pathway(s), in the plasma versus PBMC viral populations. In the final paired samples that were tested while the subjects were on a raltegravir-containing regimen, DRM prevalence reached 100% in plasma but remained 1% in PBMC on day 177 post-therapy in Subject 3180 (Q148H/G140S), 100% in plasma and 36% in PBMC on day 224 in Subject 3242 (N155H), 78% in plasma and 11–12% in PBMC on day 338 in Subject 3501 (Q148H/G140S), and 100% in plasma and 0% in PBMC on day 197 in Subject 3508 (Y143R). Furthermore, absolute sequence homology comparison between the two compartments revealed that 21% - 99% of PBMC sequences had no match in plasma, whereas 14% - 100% of plasma sequences had no match in PBMC. Overall, our observations suggested that plasma and PBMC hosted drastically different HIV-1 populations even after a prolonged exposure to raltegravir selection pressure.

Development and evaluation of an assay for HIV-1 protease and reverse transcriptase drug resistance genotyping of all major group-M subtypes

High cost and varying sensitivity for non-B HIV-1 subtypes limits application of current commercial kits for HIV-1 drug resistance genotyping of all major HIV-1 group-M subtypes. Our research aimed to develop and validate an assay specific for all major HIV-1 group-M subtypes for use as an alternative to commercial assays for HIV-1 protease (PR) and reverse transcriptase (RT) drug resistance genotyping. A nested RT-PCR encompassing the entire PR and RT up to amino acid 321 of HIV-1 was designed to detect HIV-1 group-M subtypes. Primers compatible with group-M subtypes were defined and analytical sensitivity of the assay evaluated using a panel of reference viruses for subtypes A-H and CRF01_AE. The assay was subsequently evaluated on 246 plasma samples from HIV-1 infected individuals harboring various group-M subtypes and viral loads (VLs). All major group-M HIV-1 subtypes were detected with an overall analytical sensitivity of 1.00E+03 RNA copies/ml. Application of the genotyping assay on 246 primarily African clinical samples comprising subtypes A (n=52; 21.7%), B (n=12; 5.0%), C (n=127; 52.9%), D (n=25; 10.4%), CRF01_AE (n=10; 4.2%), and CRF02_AG (n=10; 4.2%), and unassigned variants (n=10; 4.2%), VL range 4.32E+02-8.63E+06 (median 2.66E+04) RNA copies/ml, was ∼98% successful. A group-M subtype-independent genotyping assay for detection of HIV-1 drug resistance was developed. The described assay can serve as an alternative to commercial assays for HIV-1 drug resistance genotyping in routine diagnostics, and for surveillance and monitoring of drug resistance in resource-limited settings (RLS).

In Vitro Resistance Profile of the Candidate HIV-1 Microbicide Drug Dapivirine

Antiretroviral-based microbicides may offer a means to reduce the sexual transmission of HIV-1. Suboptimal use of a microbicide may, however, lead to the development of drug resistance in users that are already, or become, infected with HIV-1. In such cases, the efficacy of treatments may be compromised since the same (or similar) antiretrovirals used in treatments are being developed as microbicides. To help predict which drug resistance mutations may develop in the context of suboptimal use, HIV-1 primary isolates of different subtypes and different baseline resistance profiles were used to infect primary cells in vitro in the presence of increasing suboptimal concentrations of the two candidate microbicide antiretrovirals dapivirine (DAP) and tenofovir (TFV) alone or in combination. Infections were ongoing for 25 weeks, after which reverse transcriptase genotypes were determined and scrutinized for the presence of any clinically recognized reverse transcriptase drug resistance mutations. Results indicated that suboptimal concentrations of DAP alone facilitated the emergence of common nonnucleoside reverse transcriptase inhibitor resistance mutations, while suboptimal concentrations of DAP plus TFV gave rise to fewer mutations. Suboptimal concentrations of TFV alone did not frequently result in the development of resistance mutations. Sensitivity evaluations for stavudine (d4T), nevirapine (NVP), and lamivudine (3TC) revealed that the selection of resistance as a consequence of suboptimal concentrations of DAP may compromise the potential for NVP to be used in treatment, a finding of potential relevance in developing countries.

Detection of distinct human immunodeficiency virus Type 1 circulating recombinant forms in Northeast Brazil

The extraordinary genetic diversity and immune evasion of human immunodeficiency virus (HIV) pose significant challenges for vaccine development and antiretroviral therapy efficacy. The objective of this study was to characterize the molecular profile of HIV-1 epidemic in Salvador, Bahia, Brazil, determining the genetic subtypes and the presence of antiretroviral resistance mutations. HIV-1 pol DNA sequences from 57 individuals infected with HIV were obtained by PCR, followed by sequencing. The subtypes were determined by phylogenetic analyses and the intersubtype recombination was investigated by bootscanning. The pol subtypes were compared with gag and env subtypes. Antiretroviral susceptibility was evaluated through the Stanford HIV resistance Database. The subtypes frequencies were: 77.2% of subtype B, 1.8% of subtype F1, and 21.0% of BF recombinant forms. Two intergenic and three intragenic BF recombinant patterns were observed. Six (10.5%) viruses were related to CRF28/CRF29, two were related to CRF12 (3.5%), and one (1.8%) was CRF39. Fourteen (24.6%) strains carried one or more mutations associated with at least intermediate resistance: 24.6% had resistance to nucleoside reverse transcriptase inhibitors, 21.0% to non-nucleoside reverse transcriptase inhibitors, and 7% to protease inhibitors. The substitutions I54V (7.0%), M184V (14.0%), and K103N (10.5%) were the most frequent within each class of drugs. The results show a high diversity of BF genotypes and a lower prevalence of major reverse transcriptase and protease drug resistance mutations in Salvador, compared with other regions of Brazil. These findings may contribute to improve treatment strategies of patients infected with HIV-1 from this Brazilian region.

Reverse transcriptase drug resistance mutations in HIV-1 subtype C infected patients on ART in Karonga District, Malawi

BackgroundDrug resistance testing before initiation of, or during, antiretroviral therapy (ART) is not routinely performed in resource-limited settings. High levels of viral resistance circulating within the population will have impact on treatment programs by increasing the chances of transmission of resistant strains and treatment failure. Here, we investigate Drug Resistance Mutations (DRMs) from blood samples obtained at regular intervals from patients on ART (Baseline-22 months) in Karonga District, Malawi. One hundred and forty nine reverse transcriptase (RT) consensus sequences were obtained via nested PCR and automated sequencing from blood samples collected at three-month intervals from 75 HIV-1 subtype C infected individuals in the ART programme.ResultsFifteen individuals showed DRMs, and in ten individuals DRMs were seen from baseline samples (reported to be ART naïve). Three individuals in whom no DRMs were observed at baseline showed the emergence of DRMs during ART exposure. Four individuals who did show DRMs at baseline showed additional DRMs at subsequent time points, while two individuals showed evidence of DRMs at baseline and either no DRMs, or different DRMs, at later timepoints. Three individuals had immune failure but none appeared to be failing clinically.ConclusionDespite the presence of DRMs to drugs included in the current regimen in some individuals, and immune failure in three, no signs of clinical failure were seen during this study. This cohort will continue to be monitored as part of the Karonga Prevention Study so that the long-term impact of these mutations can be assessed. Documenting proviral population is also important in monitoring the emergence of drug resistance as selective pressure provided by ART compromises the current plasma population, archived viruses can re-emerge