Intrapatient viral diversity and treatment outcome in patients with genotype 3a hepatitis C virus infection on sofosbuvir-containing regimens.

Treatment with the direct-acting antiviral agent (DAA) sofosbuvir (SOF), an NS5B inhibitor, and velpatasvir (VEL), an NS5A inhibitor, demonstrates viral cure rates of ≥95% in hepatitis C virus (HCV) genotypes (GT) 1-6. Here, we investigated intrapatient HCV diversity in NS5A and NS5B using Shannon entropy to examine the relationship between viral diversity and treatment outcome. At baseline, HCV diversity was lowest in patients infected with HCV GT3 as compared to the other GTs, and viral diversity was greater in NS5A than NS5B (P < .0001). Treatment outcome with SOF/VEL or the comparator regimen of SOF with ribavirin (RBV) was not correlated with baseline diversity. However, among persons treated with SOF/VEL, a decrease in diversity from baseline was observed at relapse in the majority virologic failures, consistent with a viral bottleneck event at relapse. In contrast, an increase in diversity was observed in 27% of SOF+RBV virologic failures. We investigated whether the increase in diversity was due to an increase in the transition rate, one mode of potential RBV-mediated mutagenesis; however, we found no evidence of this mechanism. Overall, we did not observe that viral diversity at baseline influenced treatment outcome, but the diversity changes observed at relapse can improve our understanding of RBV viral suppression in vivo.

Resistance Analyses of Japanese Hepatitis C-Infected Patients Receiving Sofosbuvir or Ledipasvir/Sofosbuvir Containing Regimens in Phase 3 Studies.

High rates of sustained virologic response (SVR) has been achieved in Japanese patients with chronic hepatitis C virus (HCV) genotype (GT)1 and GT2 infection treated with ledipasvir/sofosbuvir (LDV/SOF) ±ribavirin (RBV) and SOF+RBV, respectively. We evaluated the effect of baseline HCV NS5A and NS5B resistance-associated variants (RAVs) on treatment outcome and characterized variants at virologic failure. Baseline deep sequencing for NS5A and NS5B genes was performed for all GT1 patients. Deep sequencing of NS5A (GT1 only) and NS5B (GT1 and GT2) was performed for patients who failed treatment or discontinued early with detectable HCV RNA (i.e., >25 IU/mL). In patients with HCV GT1 infection, 22.3% (GT1a: 2/11; GT1b: 74/330) had ≥1 baseline NS5A RAV. The most frequent NS5A RAVs in GT1b were Y93H (17.9%, 59/330) and L31M (2.4%, 8/330). Despite the presence of NS5A RAVs at baseline, 100% and 97% of patients achieved SVR12, compared with 100% and 99% for those with no NS5A RAVs with LDV/SOF and LDV/SOF+RBV, respectively. All patients with NS5B RAVs at baseline achieved SVR12. Of the 153 patients with GT2 infection (GT2a 60.1%, GT2b 39.9%), 3.3% (5/153) experienced viral relapse. No S282T or other NS5B RAVs were detected at baseline or relapse; no change in susceptibility to SOF or RBV was observed at relapse. In conclusion, LDV/SOF and SOF+RBV demonstrate a high barrier to resistance in Japanese patients with HCV GT1 and GT2 infection. The presence of baseline NS5A RAVs did not impact treatment outcome in GT1 Japanese patients treated with LDV/SOF for 12 weeks.

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.

Dynamic copy choice: steady state between murine leukemia virus polymerase and polymerase-dependent RNase H activity determines frequency of in vivo template switching.

We recently proposed a dynamic copy-choice model for retroviral recombination in which a steady state between the rates of polymerization and RNA degradation determines the frequency of reverse transcriptase (RT) template switching. The relative contributions of polymerase-dependent and polymerase-independent RNase H activities during reverse transcription and template switching in vivo have not been determined. We developed an in vivo trans-complementation assay in which direct repeat deletion through template switching reconstitutes a functional green fluorescent protein gene in a retroviral vector. Complementation in trans between murine leukemia virus Gag-Pol proteins lacking polymerase and RNase H activities restored viral replication. Because only polymerase-independent RNase H activity is present in this cell line, the relative roles of polymerase-dependent and -independent RNase H activities in template switching could be determined. We also analyzed double mutants possessing polymerase and RNase H mutations that increased and decreased template switching, respectively. The double mutants exhibited low template switching frequency, indicating that the RNase H mutations were dominant. Trans-complementation of the double mutants with polymerase-independent RNase H did not restore the high template switching frequency, indicating that polymerase-dependent RNase H activity was essential for the increased frequency of template switching. Additionally, trans-complementation of RNase H mutants in the presence and absence of hydroxyurea, which slows the rate of reverse transcription, showed that hydroxyurea increased template switching only when polymerase-dependent RNase H activity was present. This is, to our knowledge, the first demonstration of polymerase-dependent RNase H activity in vivo. These results provide strong evidence for a dynamic association between the rates of DNA polymerization and polymerase-dependent RNase H activity, which determines the frequency of in vivo template switching.

Role of murine leukemia virus reverse transcriptase deoxyribonucleoside triphosphate-binding site in retroviral replication and in vivo fidelity.

Retroviral populations exhibit a high evolutionary potential, giving rise to extensive genetic variation. Error-prone DNA synthesis catalyzed by reverse transcriptase (RT) generates variation in retroviral populations. Structural features within RTs are likely to contribute to the high rate of errors that occur during reverse transcription. We sought to determine whether amino acids within murine leukemia virus (MLV) RT that contact the deoxyribonucleoside triphosphate (dNTP) substrate are important for in vivo fidelity of reverse transcription. We utilized the previously described ANGIE P encapsidating cell line, which expresses the amphotropic MLV envelope and a retroviral vector (pGA-1). pGA-1 expresses the bacterial beta-galactosidase gene (lacZ), which serves as a reporter of mutations. Extensive mutagenesis was performed on residues likely to interact with the dNTP substrate, and the effects of these mutations on the fidelity of reverse transcription were determined. As expected, most substitution mutations of amino acids that directly interact with the dNTP substrate significantly reduced viral titers (>10,000-fold), indicating that these residues played a critical role in catalysis and viral replication. However, the D153A and A154S substitutions, which are predicted to affect the interactions with the triphosphate, resulted in statistically significant increases in the mutation rate. In addition, the conservative substitution F155W, which may affect interactions with the base and the ribose, increased the mutation rate 2.8-fold. Substitutions of residues in the vicinity of the dNTP-binding site also resulted in statistically significant decreases in fidelity (1. 3- to 2.4-fold). These results suggest that mutations of residues that contact the substrate dNTP can affect viral replication as well as alter the fidelity of reverse transcription.

Structural determinants of murine leukemia virus reverse transcriptase that affect the frequency of template switching.

Retroviral reverse transcriptases (RTs) frequently switch templates within the same RNA or between copackaged viral RNAs to generate mutations and recombination. To identify structural elements of murine leukemia virus RT important for template switching, we developed an in vivo assay in which RT template switching within direct repeats functionally reconstituted the green fluorescent protein gene. We quantified the effect of mutations in the YXDD motif, the deoxynucleoside triphosphate binding site, the thumb domain, and the RNase H domain of RT and hydroxyurea treatment on the frequencies of template switching. Hydroxyurea treatment and some mutations in RT increased the frequency of RT template switching up to fivefold, while all of the mutations tested in the RNase H domain decreased the frequency of template switching by twofold. Based on these results, we propose a dynamic copy choice model in which both the rate of DNA polymerization and the rate of RNA degradation influence the frequency of RT template switching.

Wild-type and YMDD mutant murine leukemia virus reverse transcriptases are resistant to 2',3'-dideoxy-3'-thiacytidine.

The antiretroviral nucleoside analog 2',3'-dideoxy-3'-thiacytidine (3TC) is a potent inhibitor of wild-type human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT). A methionine-to-valine or methionine-to-isoleucine substitution at residue 184 in the HIV-1 YMDD motif, which is located at the RT active site, leads to a high level of resistance to 3TC. We sought to determine whether 3TC can inhibit the replication of wild-type murine leukemia virus (MLV), which contains V223 at the YVDD active site motif of the MLV RT, and of the V223M, V223I, V223A, and V223S mutant RTs. Surprisingly, the wild type and all four of the V223 mutants of MLV RT were highly resistant to 3TC. These results indicate that determinants outside the YVDD motif of MLV RT confer a high level of resistance to 3TC. Therefore, structural differences among similar RTs might result in widely divergent sensitivities to antiretroviral nucleoside analogs.

Development of an in vivo assay to identify structural determinants in murine leukemia virus reverse transcriptase important for fidelity.

Error-prone DNA synthesis by retroviral reverse transcriptases (RTs) is a major contributor to variation in retroviral populations. Structural features of retroviral RTs that are important for accuracy of DNA synthesis in vivo are not known. To identify structural elements of murine leukemia virus (MLV) RT important for fidelity in vivo, we developed a D17-based encapsidating cell line (ANGIE P) which is designed to express the amphotropic MLV envelope. ANGIE P also contains an MLV-based retroviral vector (GA-1) which encodes a wild-type bacterial beta-galactosidase gene (lacZ) and a neomycin phosphotransferase gene. Transfection of ANGIE P cells with wild-type or mutated MLV gag-pol expression constructs generated GA-1 virus that was able to undergo only one cycle of viral replication upon infection of D17 cells. The infected D17 cell clones were characterized by staining with 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-Gal), and the frequencies of inactivating mutations in lacZ were quantified. Three mutations in the YVDD motif (V223M, V223S, and V223A) and two mutations in the RNase H domain (S526A and R657S) exhibited frequencies of lacZ inactivation 1.2- to 2.3-fold higher than that for the wild-type MLV RT (P < 0.005). Two mutations (V223I and Y598V) did not affect the frequency of lacZ inactivation. These results establish a sensitive in vivo assay for identification of structural determinants important for accuracy of DNA synthesis and indicate that several structural determinants may have an effect on the in vivo fidelity of MLV RT.

[Regulation of translation of the distal lacZ gene in polycistronic mRNA by the ribosome stream from the proximal gene]. / Reguliatsiia transliatsii distal'nogo gena lacZ politsistronnoi mRNK potokom ribosom s proksimal'nogo gena.

Four series of plasmids (pNSI, pNSII, pNLI, and pNLII) with artificial polycistrons containing the lacZ test gene were constructed. These plasmids coded for polycistronic mRNAs with two different types of cistron (orfZ and lacZ) coupling: in pNSI and pNLI, the orfZ termination codon and the lacZ initiation codon overlapped (type I); in pNSII and pNLII, the orfZ termination codon, was located upstream of the lacZ SD sequence. The length of the orfZ cistron was 60 bp in pNSI and pNSII or 300 bp in pNLI and pNLII. Plasmids with the same type of cistron coupling contained the same lacZ translation initiation region, whereas the structure of the orfZ translation initiation region varied, thereby providing varying efficiency of the orfZ gene translation. The effect of these variations on the efficiency of the lacZ gene translation was evaluated by direct measurement of the beta-galactosidase activity in Escherichia coli cells transformed with the corresponding plasmids. We found that the level of translation of the distal lacZ gene depended on the ribosome stream from the proximal gene and was maximal at the optimal ribosome stream level, which, in turn, depended on the type of cistron coupling.