Ítem
Solo Metadatos
Mutations in the chikungunya virus non-structural proteins cause resistance to favipiravir (T-705), a broad-spectrum antiviral
Título de la revista
Autores
Delang, Leen
Guerrero, Nidya Segura
Tas, Ali
Quérat, Gilles
Pastorino, Boris
Froeyen, Mathy
Dallmeier, Kai
Jochmans, Dirk
Herdewijn, Piet
Bello, Felio
Fecha
2014
Directores
ISSN de la revista
Título del volumen
Editor
Oxford University Press
Buscar en:
Métricas alternativas
Resumen
Abstract
Objectives: T-705, also known as favipiravir, is a small-molecule inhibitor that is currently in clinical development for the treatment of influenza virus infections. This molecule also inhibits the replication of a broad spectrum of other RNA viruses. The objective of this study was to investigate the antiviral effect of favipiravir on chikungunya virus (CHIKV) replication and to contribute to unravelling the molecular mechanism of action against this virus. Methods: The anti-CHIKV effect of favipiravir was examined in cell culture and in a mouse model of lethal infection. A five-step protocol was used to select for CHIKV variants with reduced susceptibility to favipiravir. The resistant phenotype was confirmed in cell culture and the whole genome was sequenced. The identified mutations were reverse-engineered into an infectious clone to confirm their impact on the antiviral efficacy of favipiravir. Results: Favipiravir inhibits the replication of laboratory strains and clinical isolates of CHIKV, as well as of a panel of other alphaviruses. Several favipiravir-resistant CHIKV variants were independently selected and all of them in particular acquired the unique K291R mutation in the RNA-dependent RNA polymerase (RdRp). Reverse-engineering of this K291R mutation into an infectious clone of CHIKV confirmed the link between the mutant genotype and the resistant phenotype. Interestingly, this particular lysine is also highly conserved in the RdRp of positivestranded RNA viruses in general. Conclusions: This study provides an important insight into the precise molecular mechanism by which favipiravir exerts its antiviral activity against (alpha)viruses, which may be of help in designing other potent broad-spectrum antivirals.
Palabras clave
Keywords
Antivirus agent , animal , Favipiravir , Lysine , Nonstructural protein , Rna directed rna polymerase , T 1005 , Unclassified drug , Viral protein , Amide , Antivirus agent , Favipiravir , Pyrazine derivative , Virus protein , Alphavirus , Animal cell , Animal experiment , Animal model , Antiviral activity , Article , Barmah forest virus , Chikungunya , Chikungunya virus , Controlled study , Drug efficacy , Eastern equine encephalitis virus , Ec50 , Genotype , Mouse , Mutation , Nonhuman , O nyong nyong virus , Phenotype , Reverse engineering , Ross river virus , Semliki forest virus , Sindbis virus , Venezuelan equine encephalitis virus , Virus cell interaction , Virus genome , Virus infectivity , Virus isolation , Virus load , Virus replication , Virus strain , Animal , Antiviral resistance , Cell line , Chemistry , Chikungunya fever , Chikungunya virus , Cytopathogenic effect , Disease model , Dose response , Drug effects , Genetics , Microbial sensitivity test , Reproducibility , Virology , Amides , Animals , Antiviral agents , Cell line , Chikungunya fever , Chikungunya virus , Cytopathogenic effect , Disease models , Dose-response relationship , Drug resistance , Mice , Microbial sensitivity tests , Mutation , Phenotype , Pyrazines , Reproducibility of results , Viral nonstructural proteins , Virus replication , Alphavirus , Nsp4 , Polymerase
