Abstract
Grazoprevir is a potent pan-genotype and macrocyclic inhibitor of hepatitis C virus (HCV) NS3/4A protease and was developed for treating chronic HCV infection. In HCV genotype (GT) 1a, grazoprevir maintains potent activity against a majority of NS3 resistance-associated amino acid substitutions, including the highly prevalent and naturally occurring Q80K polymorphism that impacts simeprevir, another NS3/4A protease inhibitor. The basis for an unexpected difference in the clinical impact of some NS3 substitutions was investigated. Phenotypic analysis of resistance-associated substitutions identified in NS3 from GT1a-infected patients who failed therapy with grazoprevir (in combination with elbasvir, an inhibitor of HCV NS5A protein) showed that positions 56, 156, and 168 in NS3 were most impactful because they diminished protein-inhibitor interactions. Although an amino acid substitution from aspartic acid to alanine at position 168 (D168A) reduced the potency of grazoprevir, its combination with R155K unexpectedly nullified this effect. Molecular dynamics and free-energy surface studies indicated that Asp-168 is important in anchoring Arg-155 for ligand binding but is not critical for Lys-155 because of the inherent flexibility of its side chain. Moreover, modeling studies supported a strong direct cation-heterocycle interaction between the Lys-155 side chain of the double substitution, R155K/D168A, and the lone pair on the quinoxaline in grazoprevir. This unique interaction provides a structural basis for grazoprevir's higher potency than simeprevir, an inhibitor to which the double substitution confers a significant reduction in potency. Our findings are consistent with the detection of R155K/D168A in NS3 from virologic failures treated with simeprevir but not grazoprevir.
Highlights
Grazoprevir is a potent pan-genotype and macrocyclic inhibitor of hepatitis C virus (HCV) NS3/4A protease and was developed for treating chronic HCV infection
Phenotypic analysis of resistance-associated substitutions identified in NS3 from GT1a-infected patients who failed therapy with grazoprevir showed that positions 56, 156, and 168 in NS3 were most impactful because they diminished protein-inhibitor interactions
In 2011, the introduction of protease inhibitors used in combination with pegylated interferon-␣ and ribavirin significantly improved sustained virologic response (SVR) rates compared with pegylated interferon/ribavirin alone [3]
Summary
2000 Galloping Hill Rd., Kenilworth, NJ 07033. Tel.: 908-740-4026; E-mail: Ernest_asanteappiah@ merck.com. NS3/4A catalyzes four specific cleavages in the viral polyprotein precursor to release the nonstructural NS3, NS4A, NS4B, NS5A, and NS5B proteins Inhibition of this activity prevents maturation of the polyprotein into its functional components thereby blocking viral replication. Grazoprevir is a novel quinoxaline macrocyclic NS3/4A protease inhibitor that contains a P2 to P4 macrocyclic constraint (Fig. 1) It is broadly active against HCV genotypes in vitro and maintains potent activity against many clinically relevant resistance-associated substitutions, including those selected by the linear inhibitors. The clinical activity of grazoprevir in combination with elbasvir, an HCV NS5A replicase complex inhibitor, has been studied in HCV-infected patients. We discuss the impact of clinically relevant NS3 resistance-associated amino acid substitutions in NS3/4A and the structural basis for their effects on grazoprevir potency. 0.007 Ϯ 0.001 0.004 Ϯ 0.001 0.067 Ϯ 0.024 0.135 Ϯ 0.051 0.690 Ϯ 0.194 0.062 Ϯ 0.031 0.067 Ϯ 0.022 0.034 Ϯ 0.007 a The strain and GenBankTM accession numbers for the HCV reference sequences are indicated in parentheses. b The standard deviation is n Ն 3. c This is the patient sequence identifier
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