Principles of Virology. Jane Flint. Читать онлайн. Newlib. NEWLIB.NET

Автор: Jane Flint
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Биология
Год издания: 0
isbn: 9781683673583
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flexibility to permit the RNA to leave the protein shell.

      The viral genome is released from the endosome, and it is usually assumed that the 5′ end of (+) strand RNAs is the first to leave the capsid, to allow immediate initiation of translation by ribosomes. This assumption is incorrect for rhinovirus type 2: exit of viral RNA starts from the 3′ end. This directionality is a consequence of how the viral RNA is packaged in the virus particle, with the 3′ end near the location of pore formation in the altered particle. Whether such directionality is a general feature of nonenveloped (+) strand RNA viruses is unknown.

      Similar to picornaviruses, another family of nonenveloped (+) strand RNA viruses, caliciviruses, also form pores in the endosomal membrane. Binding to the receptor triggers conformational changes in the viral capsid, and following endocytosis, the capsid protein VP2 forms a large portal at the 3-fold axis of symmetry. This portal would allow delivery of the RNA genome to the cytoplasm.

       Disrupting the Lysosomal Membrane

      Most virus particles that enter cells by receptor-mediated endocytosis leave the pathway before the vesicles reach the lysosomal compartment. This departure is not surprising, for lysosomes contain proteases and nucleases that would degrade virus particles. However, these enzymes play an important role during the uncoating of members of the Reoviridae.

      Infection of cells by reoviruses is sensitive to bafilomycin A1, an inhibitor of the endosomal proton pump, indicating that acidification is required for entry. Disassembly occurs in multiple steps while the virus particle travels within endosomes to the lysosome (Fig. 5.23A). The process is initiated with the acid-induced proteolysis that releases the 600 σ3 subunits of the capsid. The μ1 protein changes from a compact form to an extended flexible fiber, producing an infectious subviral particle (ISVP). The μ1 protein undergoes significant conformational changes and is cleaved at three sites, one of which releases the myristoylated N terminus, μ1N, which can insert into membranes (Fig. 5.23B). Both μ1N and μ1C are required for membrane penetration. Isolated ISVPs cause cell membranes to become permeable to toxins and produce pores in artificial membranes. These can also initiate an infection by penetrating the plasma membrane, entering the cytoplasm directly. Their infectivity is not sensitive to bafilomycin A1, further supporting the idea that these particles are primed for membrane entry and do not require further acidification for this process.

      The core particles generated from infectious subviral particles after penetration into the cytoplasm adopt a third morphology and carry out viral mRNA synthesis. The core is produced by the release of 12 σ1 fibers and 600 μ1 subunits. In the transition from ISVP to core, domains of λ2 rotate upward and outward to form a turret-like structure (Fig. 5.23A).

      The reproduction of most DNA viruses, and some RNA viruses including retroviruses and influenza viruses, begins in the cell nucleus. The genomes of these viruses must therefore be imported from the cytoplasm. One way to accomplish this movement is via the cellular pathway for protein import into the nucleus. An alternative, observed in cells infected by some retroviruses, is to enter the nucleus after the nuclear envelope breaks down during cell division.

      The nuclear pore complex allows passage of cargo in and out of the nucleus by either passive diffusion or facilitated translocation. Passive diffusion does not require interaction between the cargo and components of the nuclear pore complex and becomes inefficient as molecules approach 9 nm in diameter. Objects as large as 39 nm in diameter can pass through nuclear pore complexes by facilitated translocation via specific interactions between the cargo and components of the nuclear pore complex. Many subviral particles are too large to pass through the nuclear pore complex, but several strategies overcome this limitation.