An equine iPSC-based phenotypic screening platform identifies pro- and anti-viral molecules against West Nile virus - Virologie - Maladies animales, zoonoses et risques infectieux Access content directly
Journal Articles Veterinary Research Year : 2024

An equine iPSC-based phenotypic screening platform identifies pro- and anti-viral molecules against West Nile virus

Marielle Cochet
  • Function : Author
Virologie UMR1161
François Piumi
  • Function : Author
Virologie UMR1161
Kamila Gorna
  • Function : Author
Virologie UMR1161
Noémie Berry
  • Function : Author
Virologie UMR1161
Gaëlle Gonzalez
Virologie UMR1161
Anne Danckaert
BioImagerie Photonique – Photonic BioImaging
Nathalie Aulner
BioImagerie Photonique – Photonic BioImaging
Odile Blanchet
  • Function : Author
Centre Universitaire de Ressources Biologiques
Stéphan Zientara
Virologie UMR1161
CV
Francesc Xavier Donadeu
  • Function : Author
University of Edinburgh
Hélène Munier-Lehmann
Criblage chémogénomique et biologique (Plateforme) - Chemogenomic and Biological Screening Platform
Jennifer Richardson
  • Function : Author
Virologie UMR1161
Alexandra Benchoua
  • Function : Author
Institut des cellules souches pour le traitement et l'étude des maladies monogéniques
Muriel Coulpier
Connectez-vous pour contacter l'auteur
Virologie UMR1161

Abstract

Outbreaks of West Nile virus (WNV) occur periodically, affecting both human and equine populations. There are no vaccines for humans, and those commercialised for horses do not have sufficient coverage. Specific antiviral treatments do not exist. Many drug discovery studies have been conducted, but since rodent or primate cell lines are normally used, results cannot always be transposed to horses. There is thus a need to develop relevant equine cellular models. Here, we used induced pluripotent stem cells to develop a new in vitro model of WNV-infected equine brain cells suitable for microplate assay, and assessed the cytotoxicity and antiviral activity of forty-one chemical compounds. We found that one nucleoside analog, 2'C-methylcytidine, blocked WNV infection in equine brain cells, whereas other compounds were either toxic or ineffective, despite some displaying anti-viral activity in human cell lines. We also revealed an unexpected proviral effect of statins in WNV-infected equine brain cells. Our results thus identify a potential lead for future drug development and underscore the importance of using a tissue- and species-relevant cellular model for assessing the activity of antiviral compounds.

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Life Sciences [q-bio]
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licence : CC BY - Attribution

Gaelle Gonzalez  : Connect in order to contact the contributor

https://hal.science/hal-04568823

Submitted on : Sunday, May 5, 2024-9:43:56 PM

Last modification on : Wednesday, May 8, 2024-3:19:42 AM

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hal-04568823 , version 1 (05-05-2024)

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Marielle Cochet, François Piumi, Kamila Gorna, Noémie Berry, Gaëlle Gonzalez, et al.. An equine iPSC-based phenotypic screening platform identifies pro- and anti-viral molecules against West Nile virus. Veterinary Research, 2024, 55 (1), pp.32. ⟨10.1186/s13567-024-01290-1⟩. ⟨hal-04568823⟩

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PASTEUR ANSES CNRS UNIV-EVRY ARINRAE-VR COMUE-NORMANDIE INC-CNRS I-STEM INTEGRARE UNIV-PARIS-SACLAY UNICAEN ENVA INRAE ARINRAE ANR GS-LIFE-SCIENCES-HEALTH GS-HEALTH-DRUG-SCIENCES VIRO SAPS
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