Abstract
Understanding how non-enveloped viruses breach host cell membranes is critical for developing strategies to block viral entry, a key step in infection. Despite extensive study, how viral capsids and host lipid membranes dynamically cooperate during membrane penetration remains poorly defined. Here, using reovirus as a model non-enveloped virus and planar model membranes, we identify previously unrecognized non-Brownian membrane motions of infectious subvirion particles (ISVPs) by single-virus tracking. We then integrate experiments with computational modeling to dissect the stepwise, processive capsid-membrane interactions encoded in these distinct dynamics. We show that ISVP motion transitions from an initial phase of directed translocation to progressively confined diffusion. This behavior reflects a multistep entry mechanism in which initial capsid-membrane contact triggers release of the membrane-active μ1N peptide. As μ1N accumulates within the bilayer, it generates membrane-associated viral retention sites that promote further virus adsorption and increasingly constrain particle mobility. By directly visualizing these motion signatures, we resolve transient and cooperative capsid-membrane interactions that are difficult to capture using conventional biochemical approaches. Together, these findings provide new insight into early membrane penetration events of non-enveloped viruses.