Superinfection exclusion creates spatially distinct influenza virus populations

Influenza viruses can interact during coinfections, allowing viral fitness to be altered by genome complementation and competition, and increasing population diversity through reassortment. However, opportunities for these interactions are limited, as coinfection is blocked shortly after primary infection by a process known as superinfection exclusion (SIE). We asked whether SIE, which occurs at the level of individual cells, could limit within-host interactions between populations of influenza viruses as they spread across regions of cells. We first created a simplified model of within-host spread by infecting monolayers of cells with two isogenic influenza A viruses, each encoding a different fluorophore, and measuring the proportion of coinfected cells. In this system SIE begins within 2-4 hours of primary infection, with the kinetics of onset defined by the dose of primary virus. We then asked how SIE controls opportunities for coinfection as viruses spread across a monolayer of cells. We observed that viruses spreading from a single coinfected focus continued to coinfect cells as they spread, as all new infections were of cells that had not yet established SIE. In contrast, viruses spreading towards each other from separately infected foci could only establish minimal regions of coinfection before SIE blocked further coinfection. This patterning was recapitulated in the lungs of infected mice and is likely to apply to other viruses that exhibit SIE. It suggests that the kinetics of SIE onset separate a spreading infection into discrete regions, within which interactions between virus populations can occur freely, and between which they are blocked. Importance Viral fitness and diversity are altered by genome interactions, which occur when multiple viruses coinfect a cell. This has been extensively studied for influenza A viruses (IAV), which use genome reassortment to adapt to new hosts and create pandemic strains, and whose replication can be compromised by the acquisition of defective-interfering RNAs. Coinfection of an individual cell by IAV is restricted by the gradual onset of superinfection exclusion (SIE). Replication of IAVs within host organisms involve the asynchronous replication of viruses as they spread to infect multiple cells. We found that under these circumstances, SIE creates spatially separated sub-populations of IAV, between which there are limited opportunities for genome interactions. Our work suggests SIE will cause many viruses to segregate into distinct subpopulations within their hosts, constraining the effects of genome interactions on their fitness and evolution.