Life cycle process dependencies of positive-sense RNA viruses suggest strategies for inhibiting productive cellular infection

Life cycle processes of positive-strand (+)RNA viruses are broadly conserved across families, yet they employ different strategies to grow in the cell. Using a generalized dynamical model for intracellular (+)RNA virus growth, we decipher these life cycle determinants and their dependencies for seve...

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Bibliographic Details
Published in:Journal of the Royal Society interface 2021-11, Vol.18 (184), p.20210401-20210401
Main Authors: Chhajer, Harsh, Rizvi, Vaseef A, Roy, Rahul
Format: Article
Language:English
Subjects:
Animals
Humans
Life Cycle Stages
Life Sciences–Mathematics interface
Positive-Strand RNA Viruses
RNA Viruses
RNA, Viral - genetics
Virus Replication
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Summary:Life cycle processes of positive-strand (+)RNA viruses are broadly conserved across families, yet they employ different strategies to grow in the cell. Using a generalized dynamical model for intracellular (+)RNA virus growth, we decipher these life cycle determinants and their dependencies for several viruses and parse the effects of viral mutations, drugs and host cell permissivity. We show that poliovirus employs rapid replication and virus assembly, whereas the Japanese encephalitis virus leverages its higher rate of translation and efficient cellular reorganization compared to the hepatitis C virus. Stochastic simulations demonstrate infection extinction if all seeding (inoculating) viral RNA degrade before establishing robust replication critical for infection. The probability of this productive cellular infection, 'cellular infectivity', is affected by virus-host processes and defined by early life cycle events and viral seeding. An increase in cytoplasmic RNA degradation and delay in vesicular compartment formation reduces infectivity, more so when combined. Synergy among these parameters in limiting (+)RNA virus infection as predicted by our model suggests new avenues for inhibiting infections by targeting the early life cycle bottlenecks.
ISSN:1742-5662
1742-5689
1742-5662
DOI:10.1098/rsif.2021.0401