Poliovirus infection requires that the particle undergo a series of conformational transitions that lead to cell entry and genome release. In an effort to understand the conformational changes associated with the release of the RNA genome, we have used cryo-electron microscopy to characterize the structure of the 80S "empty" particles of poliovirus that are thought to represent the final product of the cell entry pathway. Using two-dimensional classification methods, we show that preparations of 80S particles contain at least two structures, which might represent snapshots from a continuous series of conformers. Using three-dimensional reconstruction methods, we have solved the structure of two distinct forms at subnanometric resolution, and we have built and refined pseudoatomic models into the reconstructions. The reconstructions and the derived models demonstrate that the two structural forms are both slightly expanded, resulting in partial disruption of interprotomer interfaces near their particle 2-fold axes, which may represent the site where RNA is released. The models demonstrate that each of the two 80S structures has undergone a unique set of movements of the capsid proteins, associated with rearrangement of flexible loops and amino-terminal extensions that participate in contacts between protomers, between pentamers, and with the viral RNA.Like all members of the picornavirus family, poliovirus has an icosahedral capsid (300 Å in diameter) consisting of 60 copies of each of four coat proteins, VP1, VP2, VP3, and myrVP4, which encapsidates a plus-sense single-stranded RNA genome (Fig. 1A). The poliovirus capsid proteins are responsible for several functions along the infection pathway, including programmed assembly, encapsidation of the viral genome, protection of the genome, host cell recognition, cell entry (involving both membrane binding and penetration), and release and delivery of the viral genome. This variation in function requires both individual capsid proteins and the capsid as a whole to undergo a series of triggered dynamic structural changes.Several structurally unique assembly and disassembly intermediates have been described for poliovirus, which can be distinguished by sedimentation properties on a sucrose gradient and by antigenicity (16,35,42,48). During assembly, all four capsid protein sequences are translated together as a single polypeptide that is cotranslationally myristoylated. This precursor form of the protomer, called myrP1, sediments at 7S. Once the protomer has been cleaved by virally encoded protease to yield myrVP0, VP3, and VP1, subsequent rearrangements of the freed amino and carboxyl termini allow protomers to assemble into pentamers that sediment at 14S. In turn, pentamers can assemble into an empty-capsid intermediate that sediments at 73S, which contains 60 copies of myrVP0, VP3, and VP1. Encapsidation of the viral genome is associated with the autocatalytic cleavage of myrVP0 to yield myrVP4 and VP2. This final cleavage event results in a significant increase in...
