Visualization of the two-step fusion process of the retrovirus avian sarcoma/leukosis virus by cryo-electron tomography.

Retrovirus infection starts with the binding of envelope glycoproteins to host cell receptors. Subsequently, conformational changes in the glycoproteins trigger fusion of the viral and cellular membranes. Some retroviruses, such as avian sarcoma/leukosis virus (ASLV), employ a two-step mechanism in which receptor binding precedes low-pH activation and fusion. We used cryo-electron tomography to study virion/receptor/liposome complexes that simulate the interactions of ASLV virions with cells. Binding the soluble receptor at neutral pH resulted in virions capable of binding liposomes tightly enough to alter their curvature. At virion-liposome interfaces, the glycoproteins are ∼3-fold more concentrated than elsewhere in the viral envelope, indicating specific recruitment to these sites. Subtomogram averaging showed that the oblate globular domain in the prehairpin intermediate (presumably the receptor-binding domain) is connected to both the target and the viral membrane by 2.5-nm-long stalks and is partially disordered, compared with its native conformation. Upon lowering the pH, fusion took place. Fusion is a stochastic process that, once initiated, must be rapid, as only final (postfusion) products were observed. These fusion products showed glycoprotein spikes on their surface, with their interiors occupied by patches of dense material but without capsids, implying their disassembly. In addition, some of the products presented a density layer underlying and resolved from the viral membrane, which may represent detachment of the matrix protein to facilitate the fusion process.

RSV capsid polymorphism correlates with polymerization efficiency and envelope glycoprotein content: implications that nucleation controls morphogenesis.

We used cryo-electron tomography to visualize Rous sarcoma virus, the prototypic alpharetrovirus. Its polyprotein Gag assembles into spherical procapsids, concomitant with budding. In maturation, Gag is dissected into its matrix, capsid protein (CA), and nucleocapsid moieties. CA reassembles into cores housing the viral RNA and replication enzymes. Evidence suggests that a correctly formed core is essential for infectivity. The virions in our data set range from approximately 105 to approximately 175 nm in diameter. Their cores are highly polymorphic. We observe angular cores, including some that are distinctively "coffin-shaped" for which we propose a novel fullerene geometry; cores with continuous curvature including, rarely, fullerene cones; and tubular cores. Angular cores are the most voluminous and densely packed; tubes and some curved cores contain less material, suggesting incomplete packaging. From the tomograms, we measured the surface areas of cores and, hence, their contents of CA subunits. From the virion diameters, we estimated their original complements of Gag. We find that Rous sarcoma virus virions, like the human immunodeficiency virus, contain unassembled CA subunits and that the fraction of CA that is assembled correlates with core type; angular cores incorporate approximately 80% of the available subunits, and open-ended tubes, approximately 30%. The number of glycoprotein spikes is variable (approximately 0 to 118) and also correlates with core type; virions with angular cores average 82 spikes, whereas those with tubular cores average 14 spikes. These observations imply that initiation of CA assembly, in which interactions of spike endodomains with the Gag layer play a role, is a critical determinant of core morphology.