Principles of Virology. Jane Flint

Principles of Virology - Jane Flint


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the symmetry with which the structural units interact is that of an icosahedron.

      In solid geometry, each of the 20 faces of an icosahedron is an equilateral triangle, and five such triangles interact at each of the 12 vertices (Fig. 4.9A). In the simplest protein shells, a trimer of a single viral protein (the subunit) corresponds to each triangular face of the icosahedron: as shown in Fig. 4.9B, such trimers interact with one another at the five-, three-, and twofold axes of rotational symmetry that define an icosahedron. As an icosahedron has 20 faces, 60 identical subunits (3 per face × 20 faces) is the minimal number needed to build a capsid with icosahedral symmetry.

      Large capsids and quasiequivalent bonding. In the simplest icosahedral packing arrangement, each of the 60 subunits (structural or asymmetric units) consists of a single molecule in a structurally identical environment (Fig. 4.9B). Consequently, all subunits interact with their neighbors in an identical (or equivalent) manner, just like the subunits of helical particles such as that of tobacco mosaic virus. As the viral proteins that form such closed shells are generally <~100 kDa in molecular mass, the size of the viral genome that can be accommodated in this simplest type of particle is restricted severely. To make larger capsids, additional subunits must be included. Indeed, the capsids of the majority of animal viruses are built from many more than 60 subunits and can house very large genomes. In 1962, Donald Caspar and Aaron Klug developed a theoretical framework accounting for the properties of larger particles with icosahedral symmetry. This theory has had enormous influence on the way virus architecture is described and interpreted.

      Quasiequivalence. A second cornerstone of the theory developed by Caspar and Klug was the proposition that when a capsid contains >60 subunits, each occupies a quasiequivalent position; that is, the noncovalent bonding properties of subunits in different structural environments are similar, but not identical. This property is illustrated in Fig. 4.9C for a particle with 180 identical subunits. In the small, 60-subunit structure, 5 subunits make fivefold symmetric contact at each of the 12 vertices (Fig. 4.9B). In the larger assembly with 180 subunits, this arrangement is retained at the 12 vertices, but the additional subunits are interposed to form clusters with sixfold symmetry (hexamers). In such a capsid, each subunit can be present in one of three different structural environments (designated A, B, or C in Fig. 4.9C). Nevertheless, all subunits bond to their neighbors in similar (quasiequivalent) ways, for example, via head-to-head and tail-to-tail interactions.

      BACKGROUND

      The triangulation number, T, and


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