Improving Viral Protease Inhibitors to Counter Drug Resistance

Yilmaz, Neşe Kurt; Swanstrom, Ronald; Schiffer, Celia A.

doi:10.1016/j.tim.2016.03.010

Cited by 85 publications

(78 citation statements)

References 88 publications

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“…44,46 In addition to staying within the substrate envelope, inhibitors need to balance the rigidity required for stable target interactions and flexibility to adapt to changes due to resistance mutations and binding site dynamics. 38,49 The network hypothesis explains how changes in conformational dynamics due to mutations, located even away from the active site, can be propagated to the active site to affect inhibitor binding. 51 Thus, target protein and inhibitor dynamics are essential components of molecular mechanisms leading to the emergence of drug resistance in HCV NS3/4A protease.…”

Section: Discussionmentioning

confidence: 99%

Molecular and Dynamic Mechanism Underlying Drug Resistance in Genotype 3 Hepatitis C NS3/4A Protease

et al. 2016

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Hepatitis C virus (HCV), affecting an estimated 150 million people worldwide, is the leading cause of viral hepatitis, cirrhosis and hepatocellular carcinoma. HCV is genetically diverse with six genotypes (GTs) and multiple subtypes of different global distribution and prevalence. Recent development of direct-acting antivirals against HCV including NS3/4A protease inhibitors (PIs) has greatly improved treatment outcomes for GT-1. However, all current PIs exhibit significantly lower potency against GT-3. Lack of structural data on GT-3 protease has limited our ability to understand PI failure in GT-3. In this study the molecular basis for reduced potency of current inhibitors against GT-3 NS3/4A protease is elucidated with structure determination, molecular dynamics simulations and inhibition assays. A chimeric GT-1a3a NS3/4A protease amenable to crystallization was engineered to recapitulate decreased sensitivity of GT-3 protease to PIs. High-resolution crystal structures of this GT-1a3a bound to 3 PIs, asunaprevir, danoprevir and vaniprevir, had only subtle differences relative to GT-1 despite orders of magnitude loss in affinity. In contrast, hydrogen-bonding interactions within and with the protease active site and dynamic fluctuations of the PIs were drastically altered. The correlation between loss of intermolecular dynamics and inhibitor potency suggests a mechanism where polymorphisms between genotypes (or selected mutations) in the drug target confer resistance through altering the intermolecular dynamics of the protein–inhibitor complex.

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Section: Discussionmentioning

confidence: 99%

Molecular and Dynamic Mechanism Underlying Drug Resistance in Genotype 3 Hepatitis C NS3/4A Protease

et al. 2016

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“…39–41 Another approach applied to design PIs with improved resistant profiles involves incorporation of conformational flexibility that can allow the inhibitor to adapt to structural changes in the protease active site due to mutations. 35 Here, we describe a structure-guided strategy that combines these two approaches and, together with our understanding of the mechanisms of drug resistance, led to the design of NS3/4A PIs with exceptional potency profiles against major drug resistant HCV variants.…”

Section: Introductionmentioning

confidence: 99%

Hepatitis C Virus NS3/4A Protease Inhibitors Incorporating Flexible P2 Quinoxalines Target Drug Resistant Viral Variants

et al. 2017

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A substrate envelope-guided design strategy is reported for improving the resistance profile of HCV NS3/4A protease inhibitors. Analogues of 5172-mcP1P3 were designed by incorporating diverse quinoxalines at the P2 position that predominantly interact with the invariant catalytic triad of the protease. Exploration of structure-activity relationships showed that inhibitors with small hydrophobic substituents at the 3-position of P2 quinoxaline maintain better potency against drug resistant variants, likely due to reduced interactions with residues in the S2 subsite. In contrast, inhibitors with larger groups at this position were highly susceptible to mutations at Arg155, Ala156 and Asp168. Excitingly, several inhibitors exhibited exceptional potency profiles with EC50 values ≤ 5 nM against major drug resistant HCV variants. These findings support that inhibitors designed to interact with evolutionarily constrained regions of the protease, while avoiding interactions with residues not essential for substrate recognition, are less likely to be susceptible to drug resistance.

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“…Alternatively, cleavage products may be monitored by analysis of proteolytic products by mass spectrometric methods (Hu et al, 2015;Joshi et al, 2017;Lathia et al, 2011;Rumlová et al, 2003), analytical HPLC (Teruya et al, 2016), or electrochemical methods based on the difference in penetration of substrate and cleavage products through the membrane of a polyionselective sensor (Gemene and Meyerhoff, 2011;Han et al, 1996). To study the specificity of inhibitor binding and to extend the research to rational design of inhibitors, X-ray or NMR structures of proteases in complex with the inhibitor may be determined, as reported in numerous cases for the proteases of HIV-1 [reviewed in (Ghosh et al, 2016)], HCV (Yilmaz et al, 2016), and MERS .…”

Section: Assay and Methods For Screening And Evaluating Viral Maturatmentioning

confidence: 99%

In vitro methods for testing antiviral drugs

Rumlová

Ruml

2018

Biotechnology Advances

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Despite successful vaccination programs and effective treatments for some viral infections, humans are still losing the battle with viruses. Persisting human pandemics, emerging and re-emerging viruses, and evolution of drug-resistant strains impose continuous search for new antiviral drugs. A combination of detailed information about the molecular organization of viruses and progress in molecular biology and computer technologies has enabled rational antivirals design. Initial step in establishing efficacy of new antivirals is based on simple methods assessing inhibition of the intended target. We provide here an overview of biochemical and cell-based assays evaluating the activity of inhibitors of clinically important viruses.

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Improving Viral Protease Inhibitors to Counter Drug Resistance

Cited by 85 publications

References 88 publications

Molecular and Dynamic Mechanism Underlying Drug Resistance in Genotype 3 Hepatitis C NS3/4A Protease

Molecular and Dynamic Mechanism Underlying Drug Resistance in Genotype 3 Hepatitis C NS3/4A Protease

Hepatitis C Virus NS3/4A Protease Inhibitors Incorporating Flexible P2 Quinoxalines Target Drug Resistant Viral Variants

In vitro methods for testing antiviral drugs

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