Murine polyomavirus microRNAs promote viruria during the acute phase of infection

Abstract

AbstractPolyomaviruses (PyVs) can cause serious disease in immunosuppressed hosts. Several pathogenic PyVs encode microRNAs (miRNAs), small RNAs that regulate gene expression via RNA silencing. Despite recent advances in understanding the activities of PyV miRNAs, the biological functions of PyV miRNAs duringin vivoinfections are mostly unknown. Studies presented here use murine polyomavirus (MuPyV) as a model to assess the roles of the PyV miRNAs in a natural host. This analysis reveals that a MuPyV mutant that is unable to express miRNAs has enhanced viral DNA loads in select tissues at late times after infection, indicating that during infection of a natural host, PyV miRNAs function to reduce viral replication during the persistent phase of infection. Additionally, MuPyV miRNAs promote viruria during the acute phase of infection as evidenced by a defect in shedding during infection with the miRNA mutant virus. The viruria defect of the miRNA mutant virus could be rescued by infecting Rag2-/-mice. These findings implicate miRNA activity in both the persistent and acute phases of infection and suggest a role for MuPyV miRNA in evading the adaptive immune response.ImportanceMicroRNAs are expressed by diverse viruses, but for only a few is there any understanding of theirin vivofunction. PyVs can cause serious disease in immunocompromised hosts. Therefore, increased knowledge of how these viruses interact with the immune response is of possible clinical relevance. Here we show a novel activity for a viral miRNA in promoting virus shedding. This work indicates that in addition to any role for the PyV miRNA in long-term persistence, that it also has biological activity during the acute phase. As this mutant phenotype is alleviated by infection of mice lacking an effective adaptive immune response, our work also connects thein vivoactivity of a PyV miRNA to the immune response. Given that PyV-associated disease is associated with alterations in the immune response, our findings may help to better understand how the balance between PyV and the immune response becomes altered in pathogenic states.