Structural requirements for low-pH-induced rearrangements in the envelope glycoprotein of tick-borne encephalitis virus

The exposure of the flavivirus tick-borne encephalitis (TBE) virus to an acidic pH is necessary for virus-induced membrane fusion and leads to a quantitative and irreversible conversion of the envelope protein E dimers to trimers. To study the structural requirements for this oligomeric rearrangement, the effect of low-pH treatment on the oligomeric state of different isolated forms of protein E was investigated. Full-length E dimers obtained by solubilization of virus with the detergent Triton X-100 formed trimers at low pH, whereas truncated E dimers lacking the stem-anchor region underwent a reversible dissociation into monomers without forming trimers. These data suggest that the low-pH-induced rearrangement in virions is a two-step process involving a reversible dissociation of the E dimers followed by an irreversible formation of trimers, a process which requires the stem-anchor portion of the protein. This region contains potential amphipathic alpha-helical and conserved structural elements whose interactions may contribute to the rearrangements which initiate the fusion process.

[1]  Alphavirus and flavivirus glycoproteins: Structures and functions , 1995, Cell.

[2]  S. Harrison,et al.  The envelope glycoprotein from tick-borne encephalitis virus at 2 Å resolution , 1995, Nature.

[3]  F. Guirakhoo,et al.  A model study of the use of monoclonal antibodies in capture enzyme immunoassays for antigen quantification exploiting the epitope map of tick-borne encephalitis virus. , 1986, Journal of biological standardization.

[4]  F. Wild,et al.  Leucine zipper motif extends , 1989, Nature.

[5]  F. Heinz,et al.  Homogeneity of the structural glycoprotein from European isolates of tick-borne encephalitis virus: comparison with other flaviviruses. , 1981, The Journal of general virology.

[6]  R. Lamb Paramyxovirus fusion: a hypothesis for changes. , 1993, Virology.

[7]  C. Mandl,et al.  Oligomeric rearrangement of tick-borne encephalitis virus envelope proteins induced by an acidic pH , 1995, Journal of virology.

[8]  C. Mandl,et al.  Structural changes and functional control of the tick-borne encephalitis virus glycoprotein E by the heterodimeric association with protein prM. , 1994, Virology.

[9]  I. Wilson,et al.  Structure of the haemagglutinin membrane glycoprotein of influenza virus at 3 Å resolution , 1981, Nature.

[10]  F. Heinz,et al.  Chemical crosslinking of tick-borne encephalitis virus and its subunits. , 1980, The Journal of general virology.

[11]  Kay Hofmann,et al.  Tmbase-A database of membrane spanning protein segments , 1993 .

[12]  J. Skehel,et al.  Structure of influenza haemagglutinin at the pH of membrane fusion , 1994, Nature.

[13]  F. Heinz,et al.  Formation of polymeric glycoprotein complexes from a flavivirus: tick-borne encephalitis virus. , 1980, The Journal of general virology.

[14]  C. Mandl,et al.  Recombinant and virion-derived soluble and particulate immunogens for vaccination against tick-borne encephalitis. , 1995, Vaccine.

[15]  J. White,et al.  Viral and cellular membrane fusion proteins. , 1990, Annual review of physiology.

[16]  M. Buchmeier,et al.  Alteration of the pH dependence of coronavirus-induced cell fusion: effect of mutations in the spike glycoprotein , 1991, Journal of virology.

[17]  Stephen C. Blacklow,et al.  A trimeric structural domain of the HIV-1 transmembrane glycoprotein , 1995, Nature Structural Biology.

[18]  J. Lenstra,et al.  Evidence for a coiled-coil structure in the spike proteins of coronaviruses☆ , 1987, Journal of Molecular Biology.

[19]  J. Roehrig,et al.  Synthetic peptides derived from the deduced amino acid sequence of the E-glycoprotein of Murray Valley encephalitis virus elicit antiviral antibody. , 1989, Virology.

[20]  A. Helenius,et al.  Virus Entry into Animal Cells , 1989, Advances in Virus Research.

[21]  R. Ruigrok,et al.  Low-pH induced conformational changes in viral fusion proteins: implications for the fusion mechanism. , 1995, The Journal of general virology.

[22]  C. Mandl,et al.  Sequence of the structural proteins of tick-borne encephalitis virus (western subtype) and comparative analysis with other flaviviruses. , 1988, Virology.

[23]  C. Pringle,et al.  Heptad repeat sequences are located adjacent to hydrophobic regions in several types of virus fusion glycoproteins. , 1990, The Journal of general virology.

[24]  B. Rost,et al.  Combining evolutionary information and neural networks to predict protein secondary structure , 1994, Proteins.

[25]  P. S. Kim,et al.  A spring-loaded mechanism for the conformational change of influenza hemagglutinin , 1993, Cell.

[26]  R. Garry,et al.  A general model for the transmembrane proteins of HIV and other retroviruses. , 1989, AIDS research and human retroviruses.

[27]  J. Roehrig,et al.  Antibodies to dengue 2 virus E-glycoprotein synthetic peptides identify antigenic conformation. , 1990, Virology.

[28]  F. Guirakhoo,et al.  Epitope model of tick-borne encephalitis virus envelope glycoprotein E: analysis of structural properties, role of carbohydrate side chain, and conformational changes occurring at acidic pH. , 1989, Virology.

[29]  S. Harrison,et al.  The flavivirus envelope protein E: isolation of a soluble form from tick-borne encephalitis virus and its crystallization , 1991, Journal of virology.

[30]  M. Kielian,et al.  Mechanisms of enveloped virus entry into cells. , 1990, Molecular biology & medicine.