Quantifying mixed populations of drug-resistant human immunodeficiency virus type 1

Genetic alphabet expansion technology by creating unnatural base pairs

Recent advancements in the creation of artificial extra base pairs (unnatural base pairs, UBPs) are opening the door to a new research area, xenobiology, and genetic alphabet expansion technologies. UBPs that function as third base pairs in replication, transcription, and/or translation enable the site-specific incorporation of novel components into DNA, RNA, and proteins. Here, we describe the UBPs developed by three research teams and their application in PCR-based diagnostics, high-affinity DNA aptamer generation, site-specific labeling of RNAs, semi-synthetic organism creation, and unnatural-amino-acid-containing protein synthesis.

Evaluation of HBV DNA decay kinetics in patients containing both rtM204V/I mutant and wild-type HBV subpopulations during tenofovir DF (TDF) monotherapy or combination therapy with emtricitabine (FTC)/TDF

Tenofovir disoproxil fumarate (TDF) is recommended as treatment for chronic hepatitis B patients harboring lamivudine-associated resistance mutations (LAM-R, rtM204V/I ± rtL180M). This study evaluated the clinical response of rtM204V and rtM204I subpopulations to TDF by comparing their early viral load decay kinetics to wild-type (WT) subpopulations in chronic hepatitis B patients harboring rtM204V/I prior to initiating TDF or emtricitabine (FTC)/TDF therapy. Allele-specific PCR assays capable of detecting rtM204V or rtM204I subpopulations as low as 0.5% were developed and used to assess patient samples from a Phase 3b study evaluating TDF and FTC/TDF treatment in LAM-R patients. Baseline samples (n = 280) were quantified for rtM204V/I subpopulations and rtM204V or rtM204I subpopulations were detected in 269/273 (98.5%) baseline samples with a range of 0.7% to >95%. On-treatment analyses were conducted for seventeen patients (TDF, n = 8; FTC/TDF, n = 9) that harbored baseline WT and either rtM204V or rtM204I (no rtM204V/I mixtures) and HBV DNA ≥1,000 copies/ml at/after week 4. The median change in HBV DNA through week 12 for WT and rtM204V/I subpopulations was similar, -2.64 and -3.30 log10  copies/ml, respectively, with no significant difference between TDF and FTC/TDF treatment. In conclusion, rtM204V/I subpopulations demonstrate similar early HBV DNA decline kinetics to WT subpopulations during treatment with either TDF or FTC/TDF. These results demonstrate that TDF is similarly active against both WT and rtM204V/I subpopulations in vivo.

Using expanded genetic alphabets to simplify high-throughput genetic testing

DNA is the only chemistry that allows for molecular recognition on demand. Unlike any other molecular recognition chemistry, DNA enables the simple design and rapid synthesis of molecule sets that will recognize each other and self-assemble into nanostructures. In molecular diagnostics, DNA is used to capture complementary sequences in order to decode complex mixes. Expanding DNA chemistry to include additional base pairs enables a more precise manipulation of nanostructures constructed with DNA. MultiCode technology is that type of expanded DNA chemistry. The technology exploits DNA hydrogen bonding patterns that differ from natural DNA, thereby enabling a simple means of transcending problems that are otherwise unsolvable. Made up of additional base pairs (not simply single bases), MultiCode technology is used today to decode sequences in an orthogonal manner to natural DNA. This review will discuss MultiCode technology and specifically focus on how the technology can be used to build molecular testing platforms.

Impact of primary elvitegravir resistance-associated mutations in HIV-1 integrase on drug susceptibility and viral replication fitness

Elvitegravir (EVG) is an effective HIV-1 integrase (IN) strand transfer inhibitor (INSTI) in advanced clinical development. Primary INSTI resistance-associated mutations (RAMs) at six IN positions have been identified in HIV-1-infected patients failing EVG-containing regimens in clinical studies: T66I/A/K, E92Q/G, T97A, S147G, Q148R/H/K, and N155H. In this study, the effect of these primary IN mutations, alone and in combination, on susceptibility to the INSTIs EVG, raltegravir (RAL), and dolutegravir (DTG); IN enzyme activities; and viral replication fitness was characterized. Recombinant viruses containing the six most common mutations exhibited a range of reduced EVG susceptibility: 92-fold for Q148R, 30-fold for N155H, 26-fold for E92Q, 10-fold for T66I, 4-fold for S147G, and 2-fold for T97A. Less commonly observed primary IN mutations also showed a range of reduced EVG susceptibilities: 40- to 94-fold for T66K and Q148K and 5- to 10-fold for T66A, E92G, and Q148H. Some primary IN mutations exhibited broad cross-resistance between EVG and RAL (T66K, E92Q, Q148R/H/K, and N155H), while others retained susceptibility to RAL (T66I/A, E92G, T97A, and S147G). Dual combinations of primary IN mutations further reduced INSTI susceptibility, replication capacity, and viral fitness relative to either mutation alone. Susceptibility to DTG was retained by single primary IN mutations but reduced by dual mutation combinations with Q148R. Primary EVG RAMs also diminished IN enzymatic activities, concordant with their structural proximity to the active site. Greater reductions in viral fitness of dual mutation combinations may explain why some primary INSTI RAMs do not readily coexist on the same HIV-1 genome but rather establish independent pathways of resistance to EVG.

Hepatitis B virus wild-type and rtN236T populations show similar early HBV DNA decline in adefovir refractory patients on a tenofovir-based regimen

Hepatitis B virus (HBV) pol/RT mutations that confer clinical resistance to tenofovir disoproxil fumarate (TDF) have not been detected to date. In vitro, the rtN236T adefovir dipivoxil (ADV)-associated resistance mutation confers low-level cross-resistance to tenofovir: 3- to 13-fold changes in EC(50) from wild type. This study evaluated the clinical response of rtN236T mutant viruses by comparing their early viral load decay kinetics to wild-type viruses in chronic HBV monoinfected patients harbouring rtN236T prior to initiating TDF or emtricitabine (FTC)/TDF therapy. Baseline samples (n = 105) from adefovir refractory patients were tested for the presence of rtN236T using a highly sensitive allele-specific PCR assay with an rtN236T detection cut-off of 0.5%. The rtN236T mutation was detected at baseline in 14.3% (14/98) of analysable patient samples (0.5-93.2%, rtN236T percentage range). The median change in total HBV DNA at week 24 was comparable for patients with rtN236T detected at baseline (-3.7 log(10) copies/mL, n = 14) as compared to patients with wild-type HBV (-3.2 log(10) copies/mL, n = 90). In patients with rtN236T, wild-type and rtN236T mutant virus showed similar rates of HBV DNA decline with no statistically significant difference observed at week 4. Moreover, the proportion of rtN236T remained unchanged in patients in either arm of the study during treatment. In conclusion, the rtN236T mutant virus showed similar HBV DNA decline kinetics to wild-type virus in adefovir refractory patients who switched to TDF or FTC/TDF. Despite low levels of cross-resistance in vitro, TDF similarly suppresses wild-type and rtN236T mutant viruses in vivo.

Highly specific unnatural base pair systems as a third base pair for PCR amplification

Toward the expansion of the genetic alphabet of DNA, we present highly efficient unnatural base pair systems as an artificial third base pair for PCR. Hydrophobic unnatural base pair systems between 7-(2-thienyl)imidazo[4,5-b]pyridine (Ds) and 2-nitro-4-propynylpyrrole (Px) were fine-tuned for efficient PCR, by assessing the amplification efficiency and fidelity using different polymerases and template sequence contexts and modified Px bases. Then, we found that some modifications of the Px base reduced the misincorporation rate of the unnatural base substrates opposite the natural bases in templates without reducing the Ds–Px pairing selectivity. Under optimized conditions using Deep Vent DNA polymerase, the misincorporation rate was extremely low (0.005%/bp/replication), which is close to that of the natural base mispairings by the polymerase. DNA fragments with different sequence contexts were amplified ∼10¹⁰-fold by 40 cycles of PCR, and the selectivity of the Ds–Px pairing was >99.9%/replication, except for 99.77%/replication for unfavorable purine-Ds-purine motifs. Furthermore, >97% of the Ds–Px pair in DNA survived in the 10²⁸-fold amplified products after 100-cycle PCR (10 cycles repeated 10 times). This highly specific Ds–Px pair system provides a framework for new biotechnology.

Allele-specific real-time PCR system for detection of subpopulations of genotype 1a and 1b hepatitis C NS5B Y448H mutant viruses in clinical samples

The Y448H mutation in NS5B has been selected by GS-9190 as well as several benzothiadiazine hepatitis C virus (HCV) polymerase inhibitors in vitro and in vivo. However, the level and the evolution kinetics of this resistance mutation prior to and during treatment are poorly understood. In this study, we developed an allele-specific real-time PCR (AS-PCR) assay capable of detecting Y448H when it was present at a level down to 0.5% within an HCV population of genotype 1a or 1b. No Y448H mutation was detected above the assay cutoff of 0.5% in genotype 1b-infected Con-1 replicons prior to in vitro treatment. However, the proportion of replicons with the Y448H mutation rapidly increased in a dose-dependent manner upon treatment with GS-9190. After 3 days of treatment, 1.2%, 6.8%, and >50% of the replicon population expressed Y448H with the use of GS-9190 at 1, 10, and 20 times its 50% effective concentration, respectively. In addition, plasma from 65 treatment-naïve HCV-infected patients (42 and 23 with genotype 1a and 1b, respectively) was tested for the presence of Y448H by AS-PCR and population sequencing. As expected, all patient samples were wild type at NS5B Y448 by population sequencing. AS-PCR results were obtained for 62/65 samples tested, with low levels of Y448H ranging from 0.5% to 3.0% detected in 5/62 (8%) treatment-naïve patient samples. These findings suggest the need for combination therapy with HCV-specific inhibitors to avoid viral rebound of preexisting mutant HCV.

No resistance to tenofovir disoproxil fumarate detected after up to 144 weeks of therapy in patients monoinfected with chronic hepatitis B virus

Tenofovir disoproxil fumarate (TDF) is a nucleotide analogue with potent activity against human immunodeficiency virus type 1 and hepatitis B virus (HBV). To date, no reports of HBV clinical resistance to TDF have been confirmed. In two phase 3 studies (GS-US-174-0102 and GS-US-174-0103), 375 hepatitis B e antigen-negative (HBeAg(-) ) patients and 266 HBeAg(+) patients with chronic hepatitis B (some nucleoside-naive and some lamivudine-experienced) were randomized 2:1 to receive TDF (n = 426) or adefovir dipivoxil (ADV; n = 215) for 48 weeks. After week 48, eligible patients received open-label TDF with no interruption. The studies are being continued through week 384/year 8; week 144 data are presented here. Per protocol, viremic patients (HBV DNA level ≥ 400 copies/mL or 69 IU/mL) had the option of adding emtricitabine (FTC) at or after week 72. Resistance analyses of HBV polymerase/reverse transcriptase (pol/RT) were based on population dideoxy sequencing. Phenotypic analyses were conducted in HepG2 cells with recombinant HBV derived from patient serum. Most patients maintained TDF monotherapy treatment across both studies (607/641, 95%). A resistance analysis of HBV pol/RT was performed at the baseline for all patients, for viremic patients at week 144 or at the last time when they were on TDF monotherapy (34 on TDF and 19 on ADV-TDF), and for patients who remained viremic after the addition of FTC (7/20 on TDF and 5/14 on ADV-TDF). No patient developed amino acid substitutions associated with resistance to TDF. Virological breakthrough on TDF monotherapy was infrequent over 144 weeks (13/426, 3%) and was attributed to documented nonadherence in most cases (11/13, 85%). Persistent viremia (≥400 copies/mL) through week 144 was rare (5/641, 0.8%) and was not associated with virological resistance to TDF by population or clonal analyses.

CONCLUSION

No nucleoside-naive or nucleoside-experienced patient developed HBV pol/RT mutations associated with TDF resistance after up to 144 weeks of exposure to TDF monotherapy.

Minority variants of drug-resistant HIV

Minor drug-resistant variants exist in every patient infected with human immunodeficiency virus (HIV). Because these minority variants are usually present at very low levels, they cannot be detected and quantified using conventional genotypic and phenotypic tests. Recently, several assays have been developed to characterize these low-abundance drug-resistant variants in the large, genetically complex population that is present in every HIV-infected individual. The most important issue is what results generated by these assays can predict clinical or treatment outcomes and might guide the management of patients in clinical practice. Cutoff values for the detection of these low-abundance viral variants that predict an increased risk of treatment failure should be determined. These thresholds may be specific for each mutation and treatment regimen. In this review, we summarize the attributes and limitations of the currently available detection assays and review the existing information about both acquired and transmitted drug-resistant minority variants.

Highly sensitive and quantitative detection of the H274Y oseltamivir resistance mutation in seasonal A/H1N1 influenza virus

A C-to-T transition mutation in the neuraminidase gene from seasonal A/H1N1 causes a His-to-Tyr mutation at amino acid position 275 (H274Y, universal N2 numbering), conferring resistance against oseltamivir (Tamiflu). This mutation was first detected in clinical samples in Europe during the 2007-2008 influenza season. Viruses with this mutation reached a prevalence of ∼11% by the end of the season in North American isolates tested by the CDC. We developed a highly sensitive and specific quantitative real-time reverse transcriptase PCR assay to detect the H274Y mutation. This assay utilizes a 5'-methyl-isocytosine (isoC) residue and fluorescent reporters on genotype-specific primers. During PCR, a quencher coupled to isoguanine (isoG) is site-specifically incorporated complementary to the isoC/dye, resulting in loss of fluorescence. Optimization of primers and assay conditions produced a limit of detection of 100 gene copies per reaction for both wild-type and H274Y genotypes. In samples with mixed populations, it can reliably detect as little as a 1% wild-type or 0.1% H274Y component. This high sensitivity makes the assay usable on samples with viral loads too low for dideoxy or pyrosequencing analysis. Additionally, the assay distinguishes seasonal A/H1N1 from A/H3N2, influenza B, or 2009 pandemic A/H1N1, making it useful for influenza virus subtyping as well as for drug resistance detection. We probed seasonal A/H1N1 samples from the 2005-2006, 2006-2007, and 2007-2008 influenza seasons. Data from the new assay closely matched available drug resistance genotype data previously determined by dideoxy sequencing. The H274Y mutation was only found in samples from the 2007-2008 season.

Detection of cytomegalovirus in whole blood using three different real-time PCR chemistries

Several different primer-probe chemistries have been produced commercially for real-time PCR detection and quantification of cytomegalovirus, but there are few studies evaluating their relative performance. We assessed three such commercial reagents with respect to analytical and clinical operating characteristics. The samples included 149 clinical whole blood specimens that were de-identified and assayed in parallel with all primer-probe systems. Individual methods used TaqMan, dual fluorescence resonance energy transfer hybridization probes, and labeled primer chemistries. Method comparability was determined both qualitatively, based on pair-wise assessment of concordance, and quantitatively, based on pair-wise linear regression analysis. Analytical sensitivity and the lower end of the linear dynamic range reached 10 target copies per reaction for the TaqMan and labeled primer systems and 100 target copies per reaction for the dual fluorescence resonance energy transfer probe system. Quantitative linearity reached an upper limit of 10(5) copies per reaction for all methods. No assay cross-reactivity was seen with other common viral pathogens (100% analytical specificity). Pair-wise analysis of qualitative results from clinical samples showed no significant differences in sensitivity between the three sets of reagents, and linear regression analysis indicated that the quantitative values achieved were comparable in all positive specimens. The findings demonstrate that similar analytical and clinical performance characteristics can be demonstrated for quantitative detection of cytomegalovirus in clinical whole blood extracts using a wide variety of real-time PCR chemistries.

The A62V and S68G mutations in HIV-1 reverse transcriptase partially restore the replication defect associated with the K65R mutation

BACKGROUND

The K65R mutation in human immunodeficiency virus type 1 reverse transcriptase can be selected by abacavir, didanosine, tenofovir, and stavudine in vivo resulting in reduced susceptibility to these drugs and decreased viral replication capacity. In clinical isolates, K65R is frequently accompanied by the A62V and S68G reverse transcriptase mutations.

METHODS

The role of A62V and S68G in combination with K65R was investigated using phenotypic, viral growth competition, pre-steady-state kinetic, and excision analyses.

RESULTS

Addition of A62V and S68G to K65R caused no significant change in human immunodeficiency virus type 1 resistance to abacavir, didanosine, tenofovir, or stavudine but partially restored the replication defect of virus containing K65R. The triple mutant K65R+A62V+S68G still showed some replication defect compared with wild-type virus. Pre-steady-state kinetic analysis demonstrated that K65R resulted in a decreased rate of incorporation (kpol) for all natural dNTPs, which were partially restored to wild-type levels by addition of A62V and S68G. When added to K65R and S68G, the A62V mutation seemed to restore adenosine triphosphate-mediated excision of tenofovir to wild-type levels.

CONCLUSIONS

A62V and S68G serve as partial compensatory mutations for the K65R mutation in reverse transcriptase by improving the viral replication capacity, which is likely due to increased incorporation efficiency of the natural substrates.

Characterization of mutation spectra with ultra-deep pyrosequencing: application to HIV-1 drug resistance

The detection of mutant spectra within a population of microorganisms is critical for the management of drug-resistant infections. We performed ultra-deep pyrosequencing to detect minor sequence variants in HIV-1 protease and reverse transcriptase (RT) genes from clinical plasma samples. We estimated empirical error rates from four HIV-1 plasmid clones and used them to develop a statistical approach to distinguish authentic minor variants from sequencing errors in eight clinical samples. Ultra-deep pyrosequencing detected an average of 58 variants per sample compared with an average of eight variants per sample detected by conventional direct-PCR dideoxynucleotide sequencing. In the clinical sample with the largest number of minor sequence variants, all 60 variants present in > or =3% of genomes and 20 of 35 variants present in <3% of genomes were confirmed by limiting dilution sequencing. With appropriate analysis, ultra-deep pyrosequencing is a promising method for characterizing genetic diversity and detecting minor yet clinically relevant variants in biological samples with complex genetic populations.

MultiCode-RTx real-time PCR system for detection of subpopulations of K65R human immunodeficiency virus type 1 reverse transcriptase mutant viruses in clinical samples

We report a real-time PCR assay capable of detecting drug-resistant human immunodeficiency virus type 1 reverse transcriptase K65R mutant virus at a level of 0.5% in polymorphic patient plasma specimens. Fifty-three treatment-naïve and 20 treatment-experienced specimens were successfully genotyped with the new method. Results were in agreement with population sequencing and the labor-intensive single-genome sequencing method.