Your search keyword '"Ip CLC"' showing total 4 results

1. SAT-182-Full length deep sequencing of South African hepatitis B virus isolates reveals increased viral diversity and X-gene deletions in hepatocellular carcinoma patients

Author

Tongai Maponga, Anna L McNaughton, M de Cesare, Philippa C Matthews, Richard H. Glashoff, David Bonsall, Wolfgang Preiser, Ip Clc., Monique Andersson, and M A Ansari

Subjects

Hepatitis B virus, Hepatology, Hepatocellular carcinoma, medicine, Biology, medicine.disease_cause, medicine.disease, Virology, Gene Deletions, Deep sequencing

Published

2019

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

Author

David A. Smith, Andrea Magri, Rory Bowden, David Bonsall, Peter Simmonds, Anthony Brown, Eleanor Barnes, Ip Clc., Paolo Piazza, M A Ansari, D Nguyen, Amy Trebes, Medical Research Council (MRC), and National Institute for Health Research

Subjects

0301 basic medicine, Elbasvir, Daclatasvir, Pyrrolidines, Sofosbuvir, Hepatitis C virus, Viral Hepatitis, Hepacivirus, Biology, Viral Nonstructural Proteins, medicine.disease_cause, Antiviral Agents, Virus, 03 medical and health sciences, 0302 clinical medicine, Genotype, Drug Resistance, Viral, medicine, Humans, Replicon, Hepatology, Gastroenterology & Hepatology, Imidazoles, 1103 Clinical Sciences, Valine, Original Articles, Virology, Hepatitis C, Pibrentasvir, 3. Good health, 030104 developmental biology, 1101 Medical Biochemistry and Metabolomics, Amino Acid Substitution, 030211 gastroenterology & hepatology, Carbamates, STOP-HCV Consortium, medicine.drug

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).

Published

2017

3. Comparison of next-generation sequencing technologies for comprehensive assessment of full-length hepatitis C viral genomes

Author

Thomson, E, Ip, CLC, Badhan, A, Christiansen, MT, Adamson, W, Ansari, MA, Bibby, D, Breuer, J, Brown, A, Bowden, R, Bryant, J, Bonsall, D, Da Silva Filipe, A, Hinds, C, Hudson, E, Klenerman, P, Lythgow, K, Mbisa, JL, McLauchlan, J, Myers, R, Piazza, P, Roy, S, Trebes, A, Sreenu, VB, Witteveldt, J, Barnes, E, and Simmonds, P

Subjects

Genotype, Commentaries, Drug Resistance, Viral, High-Throughput Nucleotide Sequencing, Humans, Genome, Viral, Hepacivirus, Sequence Analysis, DNA, Hepatitis C, United Kingdom

Abstract

Affordable next-generation sequencing (NGS) technologies for hepatitis C virus (HCV) may potentially identify both viral genotype and resistance genetic motifs in the era of directly acting antiviral (DAA) therapies. This study compared the ability of high-throughput NGS methods to generate full-length, deep, HCV sequence data sets and evaluated their utility for diagnostics and clinical assessment. NGS methods using (i) unselected HCV RNA (metagenomics), (ii) preenrichment of HCV RNA by probe capture, and (iii) HCV preamplification by PCR implemented in four United Kingdom centers were compared. Metrics of sequence coverage and depth, quasispecies diversity, and detection of DAA resistance-associated variants (RAVs), mixed HCV genotypes, and other coinfections were compared using a panel of samples with different viral loads, genotypes, and mixed HCV genotypes/subtypes [geno(sub)types]. Each NGS method generated near-complete genome sequences from more than 90% of samples. Enrichment methods and PCR preamplification generated greater sequence depth and were more effective for samples with low viral loads. All NGS methodologies accurately identified mixed HCV genotype infections. Consensus sequences generated by different NGS methods were generally concordant, and majority RAVs were consistently detected. However, methods differed in their ability to detect minor populations of RAVs. Metagenomic methods identified human pegivirus coinfections. NGS provided a rapid, inexpensive method for generating whole HCV genomes to define infecting genotypes, RAVs, comprehensive viral strain analysis, and quasispecies diversity. Enrichment methods are particularly suited for high-throughput analysis while providing the genotype and information on potential DAA resistance.

Published

2016

4. Comparison of next generation sequencing technologies for the comprehensive assessment of full-length hepatitis C viral genomes

Author

Ip, CLC, Ansari, MA, Brown, A, Bowden, R, Bonsall, D, Hudson, E, Klenerman, P, Piazza, P, Trebes, A, Barnes, E, Simmonds, P, and STOP-HCV Consortium

Abstract

Affordable next generation sequencing (NGS) technologies for hepatitis C virus (HCV) may potentially identify both viral genotype and resistance genetic motifs in the era of directly acting anti-viral (DAA) therapies. This study compared the ability of high-throughput NGS methods to generate full-length, deep, HCV viral sequence datasets and evaluated their utility for diagnostics and clinical assessment.NGS methods using (1) unselected HCV RNA (metagenomic); (2) pre-enrichment of HCV RNA by probe capture and (3) HCV pre-amplification by PCR implemented in four UK centres were compared. Metrics of sequence coverage and depth, quasispecies diversity and detection of DAA-resistance associated variants (RAVs), mixed HCV genotype and other co-infections were compared using a panel of samples of varying viral load, genotype and mixed HCV geno(sub)types. Each NGS method generated near complete genome sequences from over 90% of samples. Enrichment methods and PCR pre-amplification generated greater sequence depth and were more effective for low viral load samples. All NGS methodologies accurately identified mixed HCV genotype infections. Consensus sequences generated by different NGS methods were generally concordant and majority RAVs were consistently detected. However, methods differed in their ability to detect minor populations of RAVs. Metagenomic methods identified human pegivirus co-infections. NGS provided a rapid, inexpensive method for generating whole HCV genomes to define infecting genotypes, RAVs, comprehensive viral strain analysis and quasispecies diversity. Enrichment methods are particularly suited for high-throughput analysis while providing genotype and information on potential DAA resistance.

Published

2016