In Vitro Resistance Profile of the Hepatitis C Virus NS3/4A Protease Inhibitor TMC435
TMC435 is a small-molecule inhibitor of the NS3/4A serine protease of hepatitis C virus (HCV) currently in phase 2 development. The in vitro resistance profile of TMC435 was characterized by selection experiments with HCV genotype 1 replicon cells and the genotype 2a JFH-1 system. In 80% (86/109) of the sequences from genotype 1 replicon cells analyzed, a mutation at NS3 residue D168 was observed, with changes to V or A being the most frequent. Mutations at NS3 positions 43, 80, 155, and 156, alone or in combination, were also identified. A transient replicon assay confirmed the relevance of these positions for TMC435 inhibitory activity. The change in the 50% effective concentrations (EC 50 s) observed for replicons with mutations at position 168 ranged from <10-fold for those with the D168G or D168N mutation to ϳ2,000-fold for those with the D168V or D168I mutation, compared to the EC 50 for the wild type. Of the positions identified, mutations at residue Q80 had the least impact on the activity of TMC435 (<10-fold change in EC 50 s), while greater effects were observed for some replicons with mutations at positions 43, 155, and 156. TMC435 remained active against replicons with the specific mutations observed after in vitro or in vivo exposure to telaprevir or boceprevir, including most replicons with changes at positions 36, 54, and 170 (<3-fold change in EC 50 s). Replicons carrying mutations affecting the activity of TMC435 remained fully susceptible to alpha interferon and NS5A and NS5B inhibitors. Finally, combinations of TMC435 with alpha interferon and NS5B polymerase inhibitors prevented the formation of drug-resistant replicon colonies.Hepatitis C is a blood-borne infection that can ultimately result in severe liver diseases, including fibrosis, cirrhosis, and hepatocellular carcinoma (7). The chronic nature of the disease and the significant possibility of long-term liver damage have led to the current global health burden, with an estimated 180 million people being infected, of whom 130 million are chronic hepatitis C virus (HCV) carriers (54).The current standard-of-care therapy for HCV-infected patients consists of a combination of weekly injected pegylated alpha interferon (Peg-IFN-␣) and twice-daily oral ribavirin. Treatment of HCV genotype 1-infected patients with this regimen for 48 weeks has a limited success rate (a 40 to 50% sustained virological response [SVR]) and is associated with a wide range of side effects, including flu-like symptoms, anemia, and depression, leading to treatment discontinuation in a significant proportion of patients (31, 48). Therefore, specifically targeted antiviral therapies for hepatitis C (STAT-C) have been a major focus of drug discovery efforts. Treatments with several NS3/4A protease inhibitors and NS5A and NS5B polymerase inhibitors, alone or in combination with Peg-IFN-␣-ribavirin, have recently shown encouraging results in clinical trials (17,36).HCV NS3 is an essential, bifunctional, multidomain protein that possesses protease and RNA helicase activiti...
Hepatitis B virus (HBV) capsid assembly is a critical step in the propagation of the virus and is mediated by the core protein. Due to its multiple functions in the viral life cycle, core became an attractive target for new antiviral therapies. Capsid assembly modulators (CAMs) accelerate the kinetics of capsid assembly and prevent encapsidation of the polymerase-pregenomic RNA (Pol-pgRNA) complex, thereby blocking viral replication. CAM JNJ-632 is a novel and potent inhibitor of HBV replication in vitro across genotypes A to D. It induces the formation of morphologically intact viral capsids, as demonstrated by size exclusion chromatography and electron microscopy studies. Antiviral profiling in primary human hepatocytes revealed that CAMs prevented formation of covalently closed circular DNA in a dosedependent fashion when the compound was added together with the viral inoculum, whereas nucleos(t)ide analogues (NAs) did not. This protective effect translated into a dose-dependent reduction of intracellular HBV RNA levels as well as reduced HBe/cAg and HBsAg levels in the cell culture supernatant. The same observation was made with another CAM (BAY41-4109), suggesting that mechanistic rather than compound-specific effects play a role. Our data show that CAMs have a dual mechanism of action, inhibiting early and late steps of the viral life cycle. These effects clearly differentiate CAMs from NAs and may translate into higher functional cure rates in a clinical setting when given alone or in combination with the current standard of care.
We have discovered a novel class of human immunodeficiency virus (HIV) reverse transcriptase (RT) inhibitors that block the polymerization reaction in a mode distinct from those of the nucleoside or nucleotide RT inhibitors (NRTIs) and nonnucleoside RT inhibitors (NNRTIs). For this class of indolopyridone compounds, steady-state kinetics revealed competitive inhibition with respect to the nucleotide substrate. Despite substantial structural differences with classical chain terminators or natural nucleotides, these data suggest that the nucleotide binding site of HIV RT may accommodate this novel class of RT inhibitors. To test this hypothesis, we have studied the mechanism of action of the prototype compound indolopyridone-1 (INDOPY-1) using a variety of complementary biochemical tools. Time course experiments with heteropolymeric templates showed "hot spots" for inhibition following the incorporation of pyrimidines (T>C). Moreover, binding studies and site-specific footprinting experiments revealed that INDOPY-1 traps the complex in the posttranslocational state, preventing binding and incorporation of the next complementary nucleotide. The novel mode of action translates into a unique resistance profile. While INDOPY-1 susceptibility is unaffected by mutations associated with NNRTI or multidrug NRTI resistance, mutations M184V and Y115F are associated with decreased susceptibility, and mutation K65R confers hypersusceptibility to INDOPY-1. This resistance profile provides additional evidence for active site binding. In conclusion, this class of indolopyridones can occupy the nucleotide binding site of HIV RT by forming a stable ternary complex whose stability is mainly dependent on the nature of the primer 3 end.The reverse transcriptase (RT) enzyme of human immunodeficiency virus type 1 (HIV-1) remains a major target in antiretroviral therapy, with the current standard of care being the use of two nucleoside or nucleotide analogue reverse transcriptase inhibitors (NRTIs), combined with one nonnucleoside reverse transcriptase inhibitor (NNRTI) or protease inhibitor (32).Upon entry into the cell, the virus is uncoated, and the viral RT enzyme converts its single-stranded RNA genome into double-stranded proviral DNA. Inhibition of this crucial event in the early viral life cycle ultimately precludes the virus from proliferating. Following the intracellular phosphorylation of NRTIs, NRTI-triphosphates compete with natural deoxyribonucleoside triphosphate (dNTP) pools and bind to the RT active site. They act as chain terminators due to the lack of a 3Ј-hydroxyl group (31). In contrast, NNRTIs represent a chemically diverse class of compounds that bind to a pocket in the vicinity of the catalytic site (25,29,30). Binding of these inhibitors is noncompetitive with respect to both dNTPs and template/primer (16).Despite the potency of combinations of NRTIs and NNRTIs, the emergence of mutations conferring resistance remains a major cause for treatment failure. The advent of novel RT inhibitors with a different mechani...
A Novel Human Immunodeficiency Virus Type 1 Reverse Transcriptase Mutational Pattern Confers Phenotypic Lamivudine Resistance in the Absence of Mutation 184V
We describe a new human immunodeficiency virus type 1 (HIV-1) mutational pattern associated with phenotypic resistance to lamivudine (3TC) in the absence of the characteristic replacement of methionine by valine at position 184 (M184V) of reverse transcriptase. Combined genotypic and phenotypic analyses of clinical isolates revealed the presence of moderate levels of phenotypic resistance (between 4-and 50-fold) to 3TC in a subset of isolates that did not harbor the M184V mutation. Mutational cluster analysis and comparison with the phenotypic data revealed a significant correlation between moderate phenotypic 3TC resistance and an increased incidence of replacement of glutamic acid by aspartic acid or alanine and of valine by isoleucine at residues 44 and 118 of reverse transcriptase, respectively. This occurred predominantly in those isolates harboring zidovudine resistance-associated mutations (41L, 215Y). The requirement of the combination of mutations 41L and 215Y with mutations 44D and 44A and/or 118I for phenotypic 3TC resistance was confirmed by site-directed mutagenesis experiments. These data support the assumption that HIV-1 may have access to several different genetic pathways to escape drug pressure or that the increase in the frequency of particular mutations may affect susceptibility to drugs that have never been part of a particular regimen.The emergence of drug-resistant human immunodeficiency virus type 1 (HIV-1) variants is almost always observed during the course of treatment of patients with antiretroviral drugs (3, 10, 14-16, 18, 21, 27 Strategies, abstr. 19, p. 15, 1998). The mutational profile of the resistant viruses generally is characteristic for the particular drug(s) taken. For example, mutations at codons 41, 67, 70, 210, 215, and 219 of reverse transcriptase (RT) typically confer resistance to zidovudine (ZDV) (6,12,13,27). Similarly, mutation M184V in RT has been shown to be specifically associated with high-level (Ն50-fold) phenotypic resistance to lamivudine (3TC) (1,22,28). No "specific" mutation(s) associated with moderate levels of phenotypic resistance (4-to Ͻ50-fold) to 3TC has been described before. Those mutations that confer moderate (4-to Ͻ50-fold) levels of phenotypic resistance to 3TC reported previously always appeared in the context of a constellation of mutations that confer resistance to multiple nucleoside analogues or as a cross-resistance phenomenon that appears with the emergence of resistance to another nucleoside analogue. This has been the case for the nucleoside multidrug resistance complex of mutations Q151M, F77L, F116Y, A62V, and V75I, although the increase in the level of phenotypic resistance to 3TC in viruses that harbor those mutations is slight (9,20,24,25). In the case of the insertion mutations near position 69 of RT, a notable increase in the frequency of 3TC resistance has been reported together with an increased frequency of phenotypic resistance to other nucleosides (2, 17, 29). The K65R mutation appears infrequently during the course of tr...
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