Virus propagation linked to exceedingly rare gene-expression errors

Abstract

AbstractViruses are obligate parasites that establish extensive interactions with proteins and other biomolecules of their hosts. About 20% of protein molecules bear phenotypic mutations due to errors during gene expression. Phenotypic mutations are not inherited and are not purged/amplified by natural selection. Therefore, protein variants harboring phenotypic mutations remain at very low levels. Here, we show that proteins at exceedingly low levels may enable virus propagation. Bacteriophage T7 recruits the host thioredoxin as an essential processivity factor for its replisome. Thioredoxin constitutive expression yields 10000-20000 molecules perE. colicell. We inserted early stop codons in the thioredoxin gene and appended to its end the sequence encoding for a photoconvertible fluorescent protein. Virus propagation was not abolished, indicating that some thioredoxin molecules were produced through mistranscription or mistranslation. Single-molecule localization microscopy detected 12±5 molecules per cell when an ochre codon was inserted. This work demonstrates that crucial virus-host biomolecular interactions may need occur only a few times to trigger virus propagation and supports that viruses may exploit the wide diversity of host and viral protein variants arising from gene-expression errors to establish such interactions. Immediate implications of this notion for the mechanisms of cross-species transmission and antibody evasion are discussed.