Abstract
Parainfluenza virus 5 (PIV5) can establish persistent infections in host cells despite encountering innate immune defenses, including the complement (C') system. The host determinants that enable persistently infected cells (PI) to evade C'-mediated clearance remain largely undefined. Here, we identify the mitochondrial antiviral signaling (MAVS) protein, a central adaptor in double-stranded RNA-triggered antiviral and pro-survival signaling pathways, as a critical mediator of both PIV5 persistence and acquired resistance to C' lysis. Wild-type (WT) PIV5-infected A549 cells were initially sensitive to C'-directed killing, but these cells rapidly establish a PI in culture with ~25% of the cell population becoming resistant to C' lysis by day 2 and ~75% by day 4. In contrast, PIV5-infected A549 MAVS-deficient (MAVS KO) cells exhibited elevated viral gene expression, increased deposition of C3 and the membrane attack complex, and were more susceptible than WT cells to C' killing. PIV5-infected MAVS KO cells showed rapid cytopathic effects and never established a stable PI. While pharmacological suppression of viral gene expression with ribavirin (RBV) restored the survival of PIV5-infected MAVS KO cells into a long-term PI-like state, these RBV-induced PI cells remained sensitive to C' lysis. Collectively, these findings demonstrate a role of MAVS in modulating a PIV5 infection in culture, to facilitate both the conversion of a PIV5 acute infection to a PI and development of resistance to C' killing.