Figure 4.24 Structure of a simple enveloped virus, Sindbis virus. (A) Cross section through the cryo-EM density map of Sindbis virus, a member of the alphavirus genus of the Togaviridae, at 11-Å resolution. The lipid bilayer of the viral envelope is clearly defined at this resolution, as are the transmembrane domains of the glycoproteins. (B) Different layers of the particle, based on the fitting of a high-resolution structure of the E1 glycoprotein into a 9-Å reconstruction of the virus particle. The nucleocapsid (red) (C protein) surrounds the genomic (+) strand RNA. The RNA is the least well-ordered feature in the reconstruction, although segments (orange) lying just below the capsid protein appear to be ordered by interaction with this protein. The C protein penetrates the inner leaflet of the lipid membrane, where it interacts with the cytoplasmic domain of the E2 glycoprotein (blue). The membrane is spanned by rod-like structures that are connected to the skirt (see panel A) by short stems. (C) The structure of the E1 and E2 glycoproteins, obtained by fitting the crystal structure of the closely related Semliki Forest virus E1 glycoprotein into the 11-Å density map and assigning density unaccounted for to the E2 glycoprotein. The three E2 glycoprotein molecules in a trimeric spike are colored light blue, dark blue, and brown, and the E1 molecules shown as backbone traces colored red, green, and magenta. The portions of the proteins that cross the lipid bilayer are helical. Adapted from Zhang W et al. 2002. J Virol 76:11645–11658, with permission. Courtesy of Michael Rossmann, Purdue University.
Figure 4.25 Conserved topology and regular packing of envelope proteins of small, (+) strand RNA viruses. (A) Ribbon diagrams of the flavivirus envelope (E) protein dimer (top) and the alphavirus E1/E2 heterodimer (bottom), with one E and the E2 subunit shown in gray. Conserved domains of E and E1 are colored red, yellow, and blue with the fusion loops required for entry in orange. The membrane is below the flavivirus dimer, in the plane of the figure, whereas it is perpendicular to the alphavirus E1/E2 heterodimer as indicated. The parallel and angled orientations to the membrane of the flavivirus and alphavirus envelope proteins, respectively, result in the very different appearances of these particles shown in panel B. (B) Surface renderings on the same scale, showing the regular packing of flavivirus and alphavirus envelope protein dimers. The dimers related by two-, three-, and fivefold axes of icosahedral symmetry are colored blue, pale yellow, and mauve, respectively, except for the central dimer depicted, which is colored as in panel A. In the 80 spikes of the alphavirus envelope, E2 is shown gray and E1 colored by domain as in panel A. Adapted from Vaney MC, Rey FA. 2011. Cell Microbiol 13:1451–1459, with permission. Courtesy of F.A. Rey, Institut Pasteur.
Because the internal capsids or nucleocapsids of these multilayered enveloped viruses are not in direct contact with the envelope, the organization and symmetry of internal structures are not evident from the external appearance of the surface glycoprotein layer. Nor does the organization of these proteins reflect the symmetry of the capsid. For example, the outer surface of all retroviruses appears roughly spherical with an array of projecting knobs or spikes, regardless of whether the internal core is spherical, cylindrical, or cone shaped. Likewise, influenza virus particles, which contain helical nucleocapsids, are generally roughly spherical but are highly pleomorphic with long, filamentous forms common in clinical isolates (Box 4.10).
Internal proteins that contact the viral envelope are not embedded within the lipid bilayer but rather bind to its inner face. Such viral proteins are targeted to, and interact with, membranes by means of specific signals, which are described in more detail in Chapter 12.
Large Viruses with Multiple Structural Elements
Virus particles that house large DNA genomes are structurally much more intricate than any considered in previous sections. Such particles comprise obviously distinct components with different symmetries and/or multiple layers and in some cases exhibit architectures that do not appear to be based on helical or icosahedral symmetry. In this section, we illustrate various ways in which multiple structural elements can be combined. As we shall see, some of these elements are dedicated to specific functions.
DISCUSSION
A virus particle with different structures in different hosts
Throughout this chapter, we describe mature virus particles in terms of a single structure: “the” structure. However, it is important to appreciate that the architectures reported are those of particles isolated and examined under a single set of specific conditions, typically far from physiological. Structural studies of the flavivirus dengue virus, an important human pathogen, illustrate the conformational plasticity of some mature virus particles.
The organization of the single dengue virus envelope glycoprotein, E, described in the text (Fig. 4.25) is that observed in particles propagated in cells of the mosquito vector maintained at 28°C. As noted previously, the E protein dimers are tightly packed and icosahedrally ordered. However, the epitopes for binding of antibodies that neutralize the virus at 37°C are either partially or entirely buried, suggesting that the virus particle might undergo temperature-dependent conformational transitions. Indeed, when particles are exposed to temperatures encountered in the mammalian host (e.g., 37°C), they do expand significantly, exposing segments of the underlying membrane, and the E protein interactions are altered (compare the left and right panels in the figure). In fact, particles exposed to higher temperatures are heterogeneous, and the example shown in the figure (right) represents but one of multiple forms, identified during selection of particles for three-dimensional reconstruction. Because a heterogeneous population of particles with less well-ordered E protein dimers represents the form of dengue virus recognized by the human immune system, these observations have important implications for the design of dengue virus vaccines.
Structures of dengue virus particles at 28°C (left) and at ≥34°C (right), with the axes of five-, three-, and twofold rotational symmetry indicated by a pentagon, triangle, and ellipse, respectively. The E protein dimers that lie at the twofold axes are shown in gray and the other dimers with one subunit in green and one in cyan. The two oligosaccharides attached to each E protein monomer are indicated in red and yellow. The particles exposed to higher temperatures are characterized by exposed patches of membrane (purple) and significant reduction of dimer contacts at the threefold axes of icosahedral symmetry. Reprinted from Rey FA. 2013. Nature 497:443–444, with permission. Courtesy of F.A. Rey, Institut Pasteur.
Fibriansah G, Ng TS, Kostyuchenko VA, Lee J, Lee S, Wang J, Lok SM. 2013. Structural changes in dengue virus when exposed to a temperature of 37°C. J Virol 87:7585–7592.
Zhang X, Sheng J, Plevka P, Kuhn RJ, Diamond MS, Rossmann MG. 2013. Dengue structure differs at the temperatures of its human and mosquito hosts. Proc Natl Acad Sci U S A 110:6795–6799.
Particles with Helical or Icosahedral Parts
Bacteriophage T4
Bacteriophage T4, which has been studied for more than 50 years, is the classic example of an architecturally elaborate virus that contains distinct parts that exhibit icosahedral or helical symmetry. The T4 particle, which