Adaptation to host cell environment during experimental evolution of Zika virus

Zika virus (ZIKV) infection can cause developmental and neurological defects and represents a threat for human health. Type I/III interferon responses control ZIKV infection and pathological processes, yet the virus has evolved various mechanisms to defeat these host responses. Here, we established a pipeline to delineate at high-resolution the genetic evolution of ZIKV in a controlled host cell environment. We uncovered that serially passaged ZIKV acquired increased infectivity, defined as the probability for one virus to initiate infection, and simultaneously developed a resistance to TLR3-induced restriction. We built a mathematical model that suggests that the increased infectivity is due to a reduced time-lag between infection and viral replication. We found that this adaptation is cell-type specific, suggesting that different cell environments may drive viral evolution along different routes. Deep-sequencing of ZIKV quasi-species pinpointed mutations whose increased frequencies temporally coincide with the acquisition of the adapted phenotype. We functionally validated a point-mutation in ZIKV envelope (E) protein recapitulating the adapted phenotype. Its positioning on the E structure suggests a putative function in protein refolding/stability. Altogether, our results uncovered ZIKV adaptations to the cell environment leading to an accelerated replication onset coupled with resistance to TLR3-induced antiviral response. Our work provides insights into viral escape mechanisms and interactions with host cell and can serve as a framework to study other viruses.