Genome-Wide Mutagenesis of Hepatitis C Virus Reveals Ability of Genome To Overcome Detrimental Mutations

To gain insight into the impact of mutations on the viability of the hepatitis C virus (HCV) genome, we created a set of full-genome mutant libraries, differing from the parent sequence as well as each other, by using a random mutagenesis approach; the proportion of mutations increased across these...

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Veröffentlicht in:	Journal of virology 2020-01, Vol.94 (3), Article 01327
Hauptverfasser:	Singh, Deepak, Soni, Shalini, Khan, Shaheen, Sarangi, Aditya N., Yennamalli, Ragothaman M., Aggarwal, Rakesh, Veerapu, Naga Suresh
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Schlagworte:	Genetic Diversity and Evolution Life Sciences & Biomedicine Science & Technology Virology
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description	To gain insight into the impact of mutations on the viability of the hepatitis C virus (HCV) genome, we created a set of full-genome mutant libraries, differing from the parent sequence as well as each other, by using a random mutagenesis approach; the proportion of mutations increased across these libraries with declining template amount or dATP concentration. The replication efficiencies of full-genome mutant libraries ranged between 71 and 329 focus-forming units (FFU) per 10(5) Huh7.5 cells. Mutant libraries with low proportions of mutations demonstrated low replication capabilities, whereas those with high proportions of mutations had their replication capabilities restored. Hepatoma cells transfected with selected mutant libraries, with low (4 mutations per 10,000 bp copied), moderate (33 mutations), and high (66 mutations) proportions of mutations, and their progeny were subjected to serial passage. Predominant virus variants (mutants) from these mutant libraries (Mutant(l), Mutant(m), and Mutant(h), respectively) were evaluated for changes in growth kinetics and particle-to-FFU unit ratio, virus protein expression, and modulation of host cell protein synthesis. Mutantm and Mutantl variants produced >3.0-log-higher extracellular progeny per ml than the parent, and Mutanth produced progeny at a rate 1.0-log lower. More than 80% of the mutations were in a nonstructural part of the mutant genomes, the majority were nonsynonymous, and a moderate to large proportion were in the conserved regions. Our results suggest that the HCV genome has the ability to overcome lethal/deleterious mutations because of the high reproduction rate but highly selects for random, beneficial mutations. IMPORTANCE Hepatitis C virus (HCV) in vivo displays high genetic heterogeneity, which is partly due to the high reproduction and random substitutions during errorprone genome replication. It is difficult to introduce random substitutions in vitro because of limitations in inducing mutagenesis from the 5' end to the 3' end of the genome. Our study has overcome this limitation. We synthesized full-length genomes with few to several random mutations in the background of an HCV clone that can recapitulate all steps of the life cycle. Our study provides evidence of the capability of the HCV genome to overcome deleterious mutations and remain viable. Mutants that emerged from the libraries had diverse phenotype profiles compared to the parent, and putative adaptive mutations mapped t
doi_str_mv	10.1128/JVI.01327-19
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The replication efficiencies of full-genome mutant libraries ranged between 71 and 329 focus-forming units (FFU) per 10(5) Huh7.5 cells. Mutant libraries with low proportions of mutations demonstrated low replication capabilities, whereas those with high proportions of mutations had their replication capabilities restored. Hepatoma cells transfected with selected mutant libraries, with low (4 mutations per 10,000 bp copied), moderate (33 mutations), and high (66 mutations) proportions of mutations, and their progeny were subjected to serial passage. Predominant virus variants (mutants) from these mutant libraries (Mutant(l), Mutant(m), and Mutant(h), respectively) were evaluated for changes in growth kinetics and particle-to-FFU unit ratio, virus protein expression, and modulation of host cell protein synthesis. Mutantm and Mutantl variants produced >3.0-log-higher extracellular progeny per ml than the parent, and Mutanth produced progeny at a rate 1.0-log lower. 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The replication efficiencies of full-genome mutant libraries ranged between 71 and 329 focus-forming units (FFU) per 10(5) Huh7.5 cells. Mutant libraries with low proportions of mutations demonstrated low replication capabilities, whereas those with high proportions of mutations had their replication capabilities restored. Hepatoma cells transfected with selected mutant libraries, with low (4 mutations per 10,000 bp copied), moderate (33 mutations), and high (66 mutations) proportions of mutations, and their progeny were subjected to serial passage. Predominant virus variants (mutants) from these mutant libraries (Mutant(l), Mutant(m), and Mutant(h), respectively) were evaluated for changes in growth kinetics and particle-to-FFU unit ratio, virus protein expression, and modulation of host cell protein synthesis. Mutantm and Mutantl variants produced >3.0-log-higher extracellular progeny per ml than the parent, and Mutanth produced progeny at a rate 1.0-log lower. 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Our study provides evidence of the capability of the HCV genome to overcome deleterious mutations and remain viable. Mutants that emerged from the libraries had diverse phenotype profiles compared to the parent, and putative adaptive mutations mapped to segments of the conserved nonstructural genome. 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Our study provides evidence of the capability of the HCV genome to overcome deleterious mutations and remain viable. Mutants that emerged from the libraries had diverse phenotype profiles compared to the parent, and putative adaptive mutations mapped to segments of the conserved nonstructural genome. We demonstrate the potential utility of our system for the study of sequence variation that ensures the survival and adaptation of HCV.</abstract><cop>WASHINGTON</cop><pub>Amer Soc Microbiology</pub><pmid>31723027</pmid><doi>10.1128/JVI.01327-19</doi><tpages>21</tpages><orcidid>https://orcid.org/0000-0002-3327-1582</orcidid><orcidid>https://orcid.org/0000-0001-9689-494X</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Genetic Diversity and Evolution Life Sciences & Biomedicine Science & Technology Virology
title	Genome-Wide Mutagenesis of Hepatitis C Virus Reveals Ability of Genome To Overcome Detrimental Mutations
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