Principles of Virology. Jane Flint
of the proteins encoded in the ~170-kbp double-stranded DNA genome, is a structurally elegant machine tailored for active delivery of the genome to host cells. The most striking feature is the presence of morphologically distinct and functionally specialized structures, notably the head containing the genome and a long tail that terminates in a baseplate from which six long tail fibers protrude (Fig. 4.26A).
The head of the mature T4 particle, an elongated icosahedron, is built from hexamers of a single viral protein (gp23*). In contrast to the other capsids considered so far, two T numbers are needed to describe the organization of gp23* in the two end structures (T = 13) and in the elongated midsection (T = 20). As in adenoviral capsids, the pentamers that occupy the vertices contain a different viral protein, and additional proteins reside on the outer or inner surfaces of the icosahedral shell (Fig. 4.26B). One of the 12 vertices is occupied by a unique structure termed the connector, which joins the head to the tail. Such structures are derived from a nanomachine termed the portal, which pulls DNA into immature heads. Portals are a characteristic feature of the capsids of other families of DNA-containing bacteriophages, as well as of herpesviruses.
DISCUSSION
The extreme pleomorphism of influenza A virus, a genetically determined trait of unknown function
Some enveloped viruses vary considerably in size and shape. For example, the particles of paramyxoviruses, such as measles and Sendai viruses, range in size from 120 to up to 540 nm in diameter and may contain multiple copies of the (−) strand RNA genome in helical nucleocapsids of different pitch. Influenza A virus particles exhibit even more extreme pleomorphism: they appear spherical, elliptical, or filamentous, and all forms come in a wide range of sizes (see the figure). Clinical isolates are primarily filamentous but adopt the spherical morphologies when adapted to propagation in the laboratory, particularly in chicken eggs.
Several lines of evidence indicate that the filamentous phenotype is genetically determined. For example, the particles of some influenza A virus isolates are primarily filamentous, whereas those of other isolates are not. Furthermore, genetic experiments have identified specific residues in the matrix proteins (M1 and M2) required for assembly of filamentous particles. Deletion of the internal domain of the NA glycoprotein also induces formation of elongated particles, a phenotype exacerbated by concurrent removal of the cytoplasmic tail of the major viral glycoprotein HA. These observations imply that matrix-glycoprotein interactions during assembly govern the morphology of influenza A virus particles. However, the mechanism underlying the “choice” between assembly of filamentous versus spherical particles is not well understood and the influence of host cell components remains obscure. Furthermore, the physiological significance of the filamentous particles is not known, despite their predominance in clinical isolates. It has been speculated that these forms might facilitate cell-to-cell transmission of virus particles through the respiratory mucosa of infected hosts.
Badham MD, Rossman JS. 2016. Filamentous influenza viruses. Curr Clin Microbiol Rep 3:155–161.
Cryo-electron tomogram sections of influenza A virus particles (strain PR8). Bar = 50 nm. Reprinted from Nayak DB et al. 2009. Virus Res 143:147–161, with permission. Courtesy of D.B. Nayak, University of California, Los Angeles.
In contrast to the head, the ~100-nm-long tail, which comprises two protein layers, exhibits helical symmetry (Fig. 4.26A). The outer layer is a contractile sheath that functions in injection of the viral genome into host cells. The tail is connected to the head via a hexameric ring and at its other end to a complex, dome-shaped structure termed the baseplate, where it carries the cell-puncturing spike. Both long and short tail fibers project from the baseplate. The former, which are bent, are the primary receptor-binding structures of bacteriophage T4. As discussed in Chapter 5, remarkable conformational changes induced upon receptor binding by the tips of the long fibers are transmitted via the baseplate to initiate injection of the DNA genome.
Herpesviruses
Members of the Herpesviridae exhibit a number of unusual architectural features. More than half of the >80 genes of herpes simplex virus type 1 encode proteins found in the large (~200-nm-diameter) virus particles. These proteins are components of the envelope from which glycoprotein spikes project or of two distinct internal structures. The latter are the nucleocapsid surrounding the DNA genome and the protein-aceous layer encasing this structure, called the tegument (Fig. 4.27A). Until recently we possessed only relatively low-resolution views (at best, ~7 Å) of herpesviral particles. Technical advances in cryo-EM image reconstruction, including relaxation of icosahedral symmetry restraints, produced high-resolution structures of herpes simplex virus type 1 and type 2 particles (3.2 to 3.5 Å), by far the largest virus particles to be visualized in such detail. These remarkable achievements confirmed architectural elements of the nucleocapsid shared with smaller virus particles, but also revealed new features.
A single protein (VP5) forms both the hexons and the pentons of the T = 16 icosahedral capsid of herpes simplex virus type 1 (Fig. 4.27B). Like the structural units of the smaller simian virus 40 capsid, these VP5-containing assemblies make direct contact with one another. However, the segments of VP5 subunits that form the nucleocapsid floor adopt quite different conformations in the pentons and hexons (Fig. 4.27B). Similarly, specific VP5 regions display distinct arrangements in hexons that abut pentons and those surrounded entirely by other hexons. These differences optimize interactions among the structural units. The large herpesviral capsid, like that of adenoviruses, is further stabilized by additional proteins, including two that form triplexes that link the major structural units. A second property shared with polyomaviruses (and papillomaviruses) is stabilization of the particle by disulfide bonds, which covalently link both subunits of the triplexes and triplexes to VP5 subunits of adjacent hexons to impart rigidity. Such a network of covalent bonds must greatly increase the stability of the large nucleocapsid and may also be necessary to counter the high pressure exerted on this protein shell (see “Mechanical Properties of Virus Particles”).
Figure 4.26 Morphological complexity of bacteriophage T4. (A) A model of the virus particle. (B) Structure of the head (22-Å resolution) determined by cryo-EM, with the major capsid proteins shown in blue (gp23*) and magenta (gp24*), the protein that protrudes from the capsid surface in yellow, the protein that binds between gp23* subunits in white, and the beginning of the tail in green. Reprinted from Fokine A et al. 2004. Proc Natl Acad Sci U S A 101:6003–6008, with permission. Courtesy of M. Rossmann, Purdue University.
Although apparently a typical and quite simple icosahedral shell, this viral capsid is in fact an asymmetric structure: 1 of the 12 vertices is occupied not by a VP5 penton but by a unique structure termed the portal. The portal comprises 12 copies of the UL6 protein and is a squat, hollow cylinder that is wider at one end and surrounded by a two-tiered ring at the wider end (Fig. 4.27C). The incorporation of the portal, which is connected to the viral membrane (Fig.