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

Автор: Jane Flint
Издательство: John Wiley & Sons Limited
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Жанр произведения: Биология
Год издания: 0
isbn: 9781683673583
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entry. Binding to the receptor triggers conformational changes in the envelope glycoprotein, but completion of fusion requires acid pH and occurs after endocytosis. (B) Murine leukemia virus particle entry. Part of the cytoplasmic tail of the murine leukemia virus envelope glycoprotein, the R peptide, is cleaved by the viral protease during virus particle maturation. This cleavage is necessary for fusion following receptor binding.

       Barnard RJO, Narayan S, Dornadula G, Miller MD, Young JAT. 2004. Low pH is required for avian sarcoma and leukosis virus Env-dependent viral penetration into the cytosol and not for viral uncoating. J Virol 78:10433–10441.

       Rein A, Mirro J, Haynes JG, Ernst SM, Nagashima K. 1994. Function of the cytoplasmic domain of a retroviral transmembrane protein: p15E-p2E cleavage activates the membrane fusion capability of the murine leukemia virus Env protein. J Virol 68:1773–1781.

       The Membrane Fusion Process

      Studies with influenza virus envelope glycoproteins indicate that the initial rate of fusion depends on the surface density of HA, suggesting that clustering of several transmembrane protein trimers is required. The number of envelope trimers required to mediate fusion may vary depending on the virus studied, and is frequently debated. One has to bear in mind that assays measuring fusion rely on the use of artificial membrane-forming lipids in vitro; although they are useful tools to probe the mechanism of fusion, they might not reflect accurately the conditions required for fusion between viral and cellular membranes. Indeed, membrane composition is known to affect the fusion rate.

       Class II Fusion Proteins

      EXPERIMENTS

       Membrane fusion proceeds through a hemifusion intermediate

      Fusion is thought to proceed through a hemifusion intermediate in which the outer leaflets of two opposing bilayers fuse, followed by fusion of the inner leaflets and the formation of a fusion pore. Direct evidence for this mechanism has been obtained with influenza virus HA. Mammalian cells in culture producing wild-type HA (left side of figure) are fused with erythrocytes containing two different types of fluorescent dye, one in the cytoplasm (red) and one in the lipid membrane (green). Upon exposure to low pH, HA undergoes conformational changes, the HA1 subunits tilt, and the fusion peptide is inserted into the erythrocyte membrane. The green dye is transferred from the lipid bilayer of the erythrocyte to the bilayer of the HA-producing cell, but the red die is not. Further conformational changes in the HA2 subunits bring the two membranes close together and fusion pores form. As the fusion pores expand, the red dye within the cytoplasm of the erythrocyte is then transferred to the cytoplasm of the HA-producing cell. An altered form of HA (right side of figure) lacking the transmembrane and cytoplasmic domains and with membrane anchoring provided by linkage to a glycosylphosphatidylinositol (GPI) moiety was produced. Upon exposure to low pH, the HA fusion peptide is inserted into the erythrocyte membrane, and green dye is transferred to the membranes of the HA-producing cell, just as in the wild-type protein. However, because no transmembrane domain is present, fusion pores do not form. The diaphragm becomes larger, but there is no mixing of the contents of the cytoplasm, indicating that complete membrane fusion has not occurred. These results prove that hemifusion, or fusion of only the outer leaflet of the bilayer,