Resistance analysis of genotype 3 hepatitis C virus indicates subtypes inherently resistant to nonstructural protein 5A inhibitors

David Smith, Andrea Magri, David Bonsall, Camilla L C Ip, Amy Trebes, Anthony Brown, Palo Piazza, Rory Bowden, Dung Nguyen, M Azim Ansari, Peter Simmonds, Eleanor Barnes, STOP-HCV Consortium, David Smith, Andrea Magri, David Bonsall, Camilla L C Ip, Amy Trebes, Anthony Brown, Palo Piazza, Rory Bowden, Dung Nguyen, M Azim Ansari, Peter Simmonds, Eleanor Barnes, STOP-HCV Consortium

Abstract

Hepatitis C virus (HCV) genotype (gt) 3 is highly prevalent globally, with non-gt3a subtypes common in Southeast Asia. Resistance-associated substitutions (RASs) have been shown to play a role in treatment failure. However, the role of RASs in gt3 is not well understood. We report the prevalence of RASs in a cohort of direct-acting antiviral treatment-naive, gt3-infected patients, including those with rarer subtypes, and evaluate the effect of these RASs on direct-acting antivirals in vitro. Baseline samples from 496 gt3 patients enrolled in the BOSON clinical trial were analyzed by next-generation sequencing after probe-based enrichment for HCV. Whole viral genomes were analyzed for the presence of RASs to approved direct-acting antivirals. The resistance phenotype of RASs in combination with daclatasvir, velpatasvir, pibrentasvir, elbasvir, and sofosbuvir was measured using the S52 ΔN gt3a replicon model. The nonstructural protein 5A A30K and Y93H substitutions were the most common at 8.9% (n = 44) and 12.3% (n = 61), respectively, and showed a 10-fold and 11-fold increase in 50% effect concentration for daclatasvir compared to the unmodified replicon. Paired RASs (A30K + L31M and A30K + Y93H) were identified in 18 patients (9 of each pair); these combinations were shown to be highly resistant to daclatasvir, velpatasvir, elbasvir, and pibrentasvir. The A30K + L31M combination was found in all gt3b and gt3g samples. Conclusion: Our study reveals high frequencies of RASs to nonstructural protein 5A inhibitors in gt3 HCV; the paired A30K + L31M substitutions occur in all patients with gt3b and gt3g virus, and in vitro analysis suggests that these subtypes may be inherently resistant to all approved nonstructural protein 5A inhibitors for gt3 HCV. (Hepatology 2018).

© 2018 The Authors. Hepatology published by Wiley Periodicals, Inc. on behalf of American Association for the Study of Liver Diseases.

Figures

Figure 1
Figure 1
Summary of daclatasvir and sofosbuvir RASs identified in the literature. Key RAS positions for daclatasvir and sofosbuvir are shown (not to scale) along the NS5A domain 1 and NS5B (polymerase) proteins, respectively, labeled according to the H77 gt1 HCV reference protein sequence. The WT amino acid for gt3 is shown above. and the relevant RASs are indicated below. Data taken from Nelson et al.,7 Leroy V et al.,21 Lontok E et al.,25 and Itakura J et al.39 Abbreviation: aa, amino acid.
Figure 2
Figure 2
Prevalence of RASs to daclatasvir and sofosbuvir. (A) The prevalence of individual daclatasvir and sofosbuvir RASs, categorized by frequency within viral quasi‐species. (B) Histograms with a bin size of 10% showing the distribution of substitution frequency within individual patient viral quasi‐species for the daclatasvir RASs A30K, P58S, and Y93H.
Figure 3
Figure 3
(A) Replication capacity of S52 ΔN replicon carrying candidate RASs. The top dashed and bottom dotted lines indicate the replication capacity of the unmodified WT S52 ΔN replicon and the pSGR‐JFH1/GND replicon, respectively. (B) Fold changes in resistance (based on EC50 measurements) for daclatasvir or sofosbuvir against S52 ΔN replicons carrying candidate RASs. The dotted line indicates WT susceptibility; the dashed line indicates a 5‐fold increase in EC50 when compared to the WT S52 ΔN replicon. Error bars show standard error of the mean calculated from at least two experiments.
Figure 4
Figure 4
Prevalence of RAS combinations to daclatasvir. Each column represents a RAS site, and each row is a patient. The frequency of the substitution within the viral quasi‐species is shown in each block.
Figure 5
Figure 5
(A) Replication capacity of S52 ΔN replicon carrying candidate NS5A RAS combinations. The top dashed and bottom dotted lines indicate the replication capacity of the unmodified WT S52 ΔN replicon and the pSGR‐JFH1/GND replicon, respectively. (B) EC50 fold change for daclatasvir, velpatasvir, elbasvir, or pibrentasvir against S52 ΔN replicon carrying candidate RAS combinations. The dotted line indicates no change in EC50 compared to WT; the dashed line indicates a 5‐fold increase in EC50 when compared to the WT S52 ΔN replicon.
Figure 6
Figure 6
The distribution of RASs within gt3 subtypes. Each column represents an individual RAS, and each row is a patient; each block is colored according to the gt3 subtype of the virus.
Figure 7
Figure 7
Whole‐genome phylogeny of gt3 subtypes labeled with NS5A position 30 and 31 amino acids. A neighbor‐joining, midpoint rooted phylogenetic tree was estimated using the whole‐genome sequence of the gt3b, gt3g, and gt3i subtypes from our cohort and the gt3a, gt3d, gt3e, gt3k, gt3h, gt3i, gt3g, and gt3b sequences downloaded from the National Center for Biotechnology Information database and annotated with the NS5A position 30 and 31 amino acids. The A30K + L31M RASs are in bold and italics.

References

    1. World Health Organization . Global hepatitis report, 2017. Geneva, Switzerland: World Health Organization; 2017.
    1. Kowdley KV, Gordon SC, Reddy KR, Rossaro L, Bernstein DE, Lawitz E, et al. Ledipasvir and sofosbuvir for 8 or 12 weeks for chronic HCV without cirrhosis. N Engl J Med 2014;370:1879‐1888.
    1. Feld JJ, Jacobson IM, Hézode C, Asselah T, Ruane PJ, Gruener N, et al. Sofosbuvir and velpatasvir for HCV genotype 1, 2, 4, 5, and 6 infection. N Engl J Med 2015;373:2599‐2607.
    1. Sulkowski MS, Gardiner DF, Rodriguez‐Torres M, Reddy KR, Hassanein T, Jacobson I, et al. Daclatasvir plus sofosbuvir for previously treated or untreated chronic HCV infection. N Engl J Med 2014;370:211‐221.
    1. Wyles DL, Ruane PJ, Sulkowski MS, Dieterich D, Luetkemeyer A, Morgan TR, et al. Daclatasvir plus sofosbuvir for HCV in patients coinfected with HIV‐1. N Engl J Med 2015;373:714‐725.
    1. Hézode C, Lebray P, De Ledinghen V, Zoulim F, Di Martino V, Boyer N, et al. Daclatasvir plus sofosbuvir, with or without ribavirin, for hepatitis C virus genotype 3 in a French early access programme. Liver Int 2017;37:1314‐1324.
    1. Nelson DR, Cooper JN, Lalezari JP, Lawitz E, Pockros PJ, Gitlin N, et al. All‐oral 12‐week treatment with daclatasvir plus sofosbuvir in patients with hepatitis C virus genotype 3 infection: ALLY‐3 phase III study. Hepatology 2015;61:1127‐1135.
    1. Ampuero J, Romero‐Gómez M, Reddy KR. Review article: HCV genotype 3—the new treatment challenge. Aliment Pharmacol Ther 2014;39:686‐698.
    1. Sarwar S, Khan AA, Tarique S. Response guided interferon therapy for genotype 3 of chronic hepatitis C: compliance and outcome. Pak J Med Sci 2015;31:843‐847.
    1. Bourlière M, Gordon SC, Flamm SL, Cooper CL, Ramji A, Tong M, et al. Sofosbuvir, velpatasvir, and voxilaprevir for previously treated HCV infection. N Engl J Med 2017;376:2134‐2146.
    1. Foster GR, Afdhal N, Roberts SK, Bräu N, Gane EJ, Pianko S, et al. Sofosbuvir and velpatasvir for HCV genotype 2 and 3 infection. N Engl J Med 2015;373:2608‐2617.
    1. Jacobson IM, Lawitz E, Gane EJ, Willems BE, Ruane PJ, Nahass RG, et al. Efficacy of 8 weeks of sofosbuvir, velpatasvir, and voxilaprevir in patients with chronic HCV infection: 2 phase 3 randomized trials. Gastroenterology 2017;153:113‐122.
    1. Pianko S, Flamm SL, Shiffman ML, Kumar S, Strasser SI, Dore GJ, et al. Sofosbuvir plus velpatasvir combination therapy for treatment‐experienced patients with genotype 1 or 3 hepatitis C virus infection. Ann Intern Med 2015;163:809.
    1. Foster GR, Agarwal K, Cramp M, Moreea S, Barclay S, Collier J, et al. C‐ISLE: grazoprevir/elbasvir plus sofosbuvir in treatment‐naive and treatment‐experienced HCV GT3 cirrhotic patients treated for 8, 12 or 16 weeks [Abstract]. In: 67th Meeting of the American Association for the Study of Liver Diseases: Liver Meeting; November 11‐15, 2016; Boston, MA. Abstract 74.
    1. Ge D, Fellay J, Thompson AJ, Simon JS, Shianna KV, Urban TJ, et al. Genetic variation in IL28B predicts hepatitis C treatment‐induced viral clearance. Nature 2009;461:399‐401.
    1. Thomas DL, Thio CL, Martin MP, Qi Y, Ge D, O'Huigin C, et al. Genetic variation in IL28B and spontaneous clearance of hepatitis C virus. Nature 2009;461:798‐801.
    1. Bochud P‐Y, Cai T, Overbeck K, Bochud M, Dufour J‐F, Müllhaupt B, et al. Genotype 3 is associated with accelerated fibrosis progression in chronic hepatitis C. J Hepatol 2009;51:655‐666.
    1. Nkontchou G, Ziol M, Aout M, Lhabadie M, Baazia Y, Mahmoudi A, et al. HCV genotype 3 is associated with a higher hepatocellular carcinoma incidence in patients with ongoing viral C cirrhosis. J Viral Hepat 2011;18:e516‐e522.
    1. Larsen C, Bousquet V, Delarocque‐Astagneau E, Pioche C, Roudot‐Thoraval F; HCV Surveillance Steering Committee . Hepatitis C virus genotype 3 and the risk of severe liver disease in a large population of drug users in France. J Med Virol 2010;82:1647‐1654.
    1. Poynard T, Bedossa P, Opolon P. Natural history of liver fibrosis progression in patients with chronic hepatitis C. The OBSVIRC, METAVIR, CLINIVIR, and DOSVIRC groups. Lancet 1997;349:825‐832.
    1. Leroy V, Angus P, Bronowicki J‐P, Dore GJ, Hezode C, Pianko S, et al. Daclatasvir, sofosbuvir, and ribavirin for hepatitis C virus genotype 3 and advanced liver disease: a randomized phase III study (ALLY‐3+). Hepatology 2016;63:1430‐1441.
    1. European Association for the Study of the Liver . EASL recommendations on treatment of hepatitis C 2016. J Hepatol 2017;66:153‐194.
    1. American Association for the Study of Liver Diseases . HCV Guidance: recommendations for testing, managing, and treating hepatitis C. . Accessed December 8, 2017.
    1. Omata M, Kanda T, Wei L, Yu ML, Chuang WL, Ibrahim A, et al. APASL consensus statements and recommendation on treatment of hepatitis C. Hepatol Int 2016;10:702‐726.
    1. Lontok E, Harrington P, Howe A, Kieffer T, Lennerstrand J, Lenz O, et al. Hepatitis C virus drug resistance‐associated substitutions: state of the art summary. Hepatology 2015;62:1623‐1632.
    1. Sarrazin C, Dvory‐Sobol H, Svarovskaia ES, Doehle B, Pang PS, Chuang S‐M, et al. Prevalence of resistance‐associated substitutions in HCV NS5A, NS5B, or NS3 and outcomes of treatment with ledipasvir and sofosbuvir. Gastroenterology 2016;151:501‐512.
    1. Welzel TM, Bhardwaj N, Hedskog C, Chodavarapu K, Camus G, McNally J, et al. Global epidemiology of HCV subtypes and resistance‐associated substitutions evaluated by sequencing‐based subtype analyses. J Hepatol 2017;67:224‐236.
    1. Lohmann V, Körner F, Koch J, Herian U, Theilmann L, Bartenschlager R. Replication of subgenomic hepatitis C virus RNAs in a hepatoma cell line. Science 1999;285:110‐113.
    1. Witteveldt J, Martin‐Gans M, Simmonds P. Enhancement of the replication of HCV replicons of genotypes 1‐4 by manipulation of CpG and UpA dinucleotide frequencies and use of cell lines expressing SECL14L2—application for antiviral resistance testing. Antimicrob Agents Chemother 2016;60:2981‐2992.
    1. Saeed M, Scheel TKH, Gottwein JM, Marukian S, Dustin LB, Bukh J, et al. Efficient replication of genotype 3a and 4a hepatitis C virus replicons in human hepatoma cells. Antimicrob Agents Chemother 2012;56:5365‐5373.
    1. Bonsall D, Ansari MA, Ip C, Trebes A, Brown A, Klenerman P, et al. ve‐SEQ: robust, unbiased enrichment for streamlined detection and whole‐genome sequencing of HCV and other highly diverse pathogens. F1000Res 2015;4:1062.
    1. Macalalad AR, Zody MC, Charlebois P, Lennon NJ, Newman RM, Malboeuf CM, et al. Highly sensitive and specific detection of rare variants in mixed viral populations from massively parallel sequence data. PLoS Comput Biol 2012;8:e1002417.
    1. Henn MR, Boutwell CL, Charlebois P, Lennon NJ, Power KA, Macalalad AR, et al. Whole genome deep sequencing of HIV‐1 reveals the impact of early minor variants upon immune recognition during acute infection. PLoS Pathog 2012;8:e1002529.
    1. Foster GR, Pianko S, Brown A, Forton D, Nahass RG, George J, et al. Efficacy of sofosbuvir plus ribavirin with or without peginterferon‐alfa in patients with hepatitis C virus genotype 3 infection and treatment‐experienced patients with cirrhosis and hepatitis C virus genotype 2 infection. Gastroenterology 2015;149:1462‐1470.
    1. International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use . ICH harmonised tripartite guideline. Guideline for good clinical practice E6(R1). International Conference on Harmonisation; 1996.
    1. Batty EM, Wong THN, Trebes A, Argoud K, Attar M, Buck D, et al. A modified RNA‐seq approach for whole genome sequencing of RNA viruses from faecal and blood samples. PLoS One 2013;8:e66129.
    1. Magri A, Reilly R, Scalacci N, Radi M, Hunter M, Ripoll M, et al. Rethinking the old antiviral drug moroxydine: discovery of novel analogues as anti‐hepatitis C virus (HCV) agents. Bioorganic Med Chem Lett 2015;25:5372‐5376.
    1. Magri A, Ozerov AA, Tunitskaya VL, Valuev‐Elliston VT, Wahid A, Pirisi M, et al. Exploration of acetanilide derivatives of 1‐(ω‐phenoxyalkyl)uracils as novel inhibitors of hepatitis C virus replication. Sci Rep 2016;6:29487.
    1. Itakura J, Kurosaki M, Hasebe C, Osaki Y, Joko K, Yagisawa H, et al. Complex pattern of resistance‐associated substitutions of hepatitis C virus after daclatasvir/asunaprevir treatment failure. PLoS One 2016;11:e0165339.
    1. Chen Z, Li H, Ren H, Hu P. Global prevalence of pre‐existing HCV variants resistant to direct‐acting antiviral agents (DAAs): mining the GenBank HCV genome data. Sci Rep 2016;6:20310.
    1. Patiño‐Galindo JÁ, Salvatierra K, González‐Candelas F, López‐Labrador FX. Comprehensive screening for naturally occurring hepatitis C virus resistance to direct‐acting antivirals in the NS3, NS5A, and NS5B genes in worldwide isolates of viral genotypes 1 to 6. Antimicrob Agents Chemother 2016;60:2402‐2416.
    1. Vermehren J, Sarrazin C. The role of resistance in HCV treatment. Best Pract Res Clin Gastroenterol 2012;26:487‐503.
    1. Hernandez D, Zhou N, Ueland J, Monikowski A, McPhee F. Natural prevalence of NS5A polymorphisms in subjects infected with hepatitis C virus genotype 3 and their effects on the antiviral activity of NS5A inhibitors. J Clin Virol 2013;57:13‐18.
    1. Wasitthankasem R, Vongpunsawad S, Siripon N, Suya C, Chulothok P, Chaiear K, et al. Genotypic distribution of hepatitis C virus in Thailand and Southeast Asia. PLoS One 2015;10:e0126764.
    1. da Silva Filipe A, Sreenu V, Hughes J, Aranday‐Cortes E, Irving WL, Foster GR, et al. Response to DAA therapy in the NHS England Early Access Programme for rare HCV subtypes from low and middle income countries. J Hepatol 2017;67:1348‐1350.

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