Your search keyword '"Viral Fusion Proteins physiology"' showing total 6 results

1. Distinct structural rearrangements of the VSV glycoprotein drive membrane fusion.

Author

Libersou S, Albertini AA, Ouldali M, Maury V, Maheu C, Raux H, de Haas F, Roche S, Gaudin Y, and Lepault J

Subjects

Crystallography, X-Ray, Hydrogen-Ion Concentration, Liposomes ultrastructure, Membrane Glycoproteins chemistry, Protein Structure, Tertiary, Vesicular stomatitis Indiana virus metabolism, Vesicular stomatitis Indiana virus ultrastructure, Viral Fusion Proteins chemistry, Viral Proteins chemistry, Virion metabolism, Virion pathogenicity, Virion ultrastructure, Membrane Fusion physiology, Membrane Glycoproteins physiology, Vesicular stomatitis Indiana virus pathogenicity, Viral Fusion Proteins physiology, Viral Proteins physiology, Virus Internalization

Abstract

The entry of enveloped viruses into cells requires the fusion of viral and cellular membranes, driven by conformational changes in viral glycoproteins. Many studies have shown that fusion involves the cooperative action of a large number of these glycoproteins, but the underlying mechanisms are unknown. We used electron microscopy and tomography to study the low pH-induced fusion reaction catalyzed by vesicular stomatitis virus glycoprotein (G). Pre- and post-fusion crystal structures were observed on virions at high and low pH, respectively. Individual fusion events with liposomes were also visualized. Fusion appears to be driven by two successive structural rearrangements of G at different sites on the virion. Fusion is initiated at the flat base of the particle. Glycoproteins located outside the contact zone between virions and liposomes then reorganize into regular arrays. We suggest that the formation of these arrays, which have been shown to be an intrinsic property of the G ectodomain, induces membrane constraints, achieving the fusion reaction.

Published

2010

2. Membrane fusion mediated by baculovirus gp64 involves assembly of stable gp64 trimers into multiprotein aggregates.

Author

Markovic I, Pulyaeva H, Sokoloff A, and Chernomordik LV

Subjects

Animals, Cell Fusion physiology, Cell Line, Cell Membrane chemistry, Cross-Linking Reagents, Disulfides chemistry, Dithiothreitol, Erythrocytes physiology, Hydrogen-Ion Concentration, In Vitro Techniques, Macromolecular Substances, Models, Molecular, Molecular Weight, Protein Conformation, Protein Folding, Spodoptera, Baculoviridae pathogenicity, Baculoviridae physiology, Membrane Fusion physiology, Viral Fusion Proteins chemistry, Viral Fusion Proteins physiology

Abstract

The baculovirus fusogenic activity depends on the low pH conformation of virally-encoded trimeric glycoprotein, gp64. We used two experimental approaches to investigate whether monomers, trimers, and/or higher order oligomers are functionally involved in gp64 fusion machine. First, dithiothreitol (DTT)- based reduction of intersubunit disulfides was found to reversibly inhibit fusion, as assayed by fluorescent probe redistribution between gp64-expressing and target cells (i.e., erythrocytes or Sf9 cells). This inhibition correlates with disappearance of gp64 trimers and appearance of dimers and monomers in SDS-PAGE. Thus, stable (i.e., with intact intersubunit disulfides) gp64 trimers, rather than independent monomers, drive fusion. Second, we established that merger of membranes is preceded by formation of large (greater than 2 MDa), short-lived gp64 complexes. These complexes were stabilized by cell-surface cross-linking and characterized by glycerol density gradient ultracentrifugation. The basic structural unit of the complexes is stable gp64 trimer. Although DTT-destabilized trimers were still capable of assuming the low pH conformation, they failed to form multimeric complexes. The fact that formation of these complexes correlated with fusion in timing, and was dependent on (a) low pH application, (b) stable gp64 trimers, and (c) cell-cell contacts, suggests that such multimeric complexes represent a fusion machine.

Published

1998

3. Truncation of the COOH-terminal region of the paramyxovirus SV5 fusion protein leads to hemifusion but not complete fusion.

Author

Bagai S and Lamb RA

Subjects

Amino Acid Sequence, Biological Transport, CD4-Positive T-Lymphocytes, Carbohydrate Metabolism, Cell Fusion, Cell Membrane chemistry, Cell Membrane physiology, Cytoplasm, Dimerization, Erythrocyte Membrane physiology, Fluorescent Dyes, Golgi Apparatus metabolism, HeLa Cells, Hexosaminidases, Humans, Kinetics, Membrane Lipids physiology, Molecular Sequence Data, Sequence Deletion, Viral Fusion Proteins analysis, Viral Fusion Proteins chemistry, Viral Fusion Proteins genetics, Membrane Fusion physiology, Paramyxoviridae physiology, Viral Fusion Proteins physiology

Abstract

The role of the simian virus 5 (SV5) fusion (F) protein 20 residue COOH-terminal region, thought to represent the cytoplasmic tail, in fusion activity was examined by constructing a series of COOH-terminal truncation mutants. When the altered F proteins were expressed in eukaryotic cells, by using the vaccinia virus-T7 transient expression system, all the F proteins exhibited similar intracellular transport properties and all were expressed abundantly on the cell surface. Quantitative and qualitative cell fusion assays indicated that all of the F protein COOH-terminal truncation mutants mediated lipid mixing with similar kinetics and efficiency as that of wild-type F protein. However, the cytoplasmic content mixing activity decreased in parallel with the extent of the deletion in the F protein COOH-terminal truncation mutants. These data indicate that it is possible to separate the presumptive early step in the fusion reaction, hemifusion, and the final stage of fusion, content mixing, and that the presence of the F protein COOH-terminal region is important for the final steps of fusion.

Published

1996

4. GPI-anchored influenza hemagglutinin induces hemifusion to both red blood cell and planar bilayer membranes.

Author

Melikyan GB, White JM, and Cohen FS

Subjects

Animals, CHO Cells physiology, Cell Fusion physiology, Coloring Agents pharmacokinetics, Cricetinae, Electrophysiology, Ethidium, Humans, Hydrogen-Ion Concentration, Lipid Bilayers, Lipid Metabolism, Orthomyxoviridae chemistry, Osmosis physiology, Porins metabolism, Viral Fusion Proteins physiology, Cell Membrane physiology, Erythrocytes physiology, Glycosylphosphatidylinositols physiology, Hemagglutinins, Viral physiology

Abstract

Under fusogenic conditions, fluorescent dye redistributed from the outer monolayer leaflet of red blood cells (RBCs) to cells expressing glycophosphatidylinositol-anchored influenza virus hemagglutinin (GPI-HA) without transfer of aqueous dye. This suggests that hemifusion, but not full fusion, occurred (Kemble, G. W., T. Danieli, and J. M. White. 1994. Cell. 76:383-391). We extended the evidence for hemifusion by labeling the inner monolayer leaflets of RBCs with FM4-64 and observing that these inner leaflets did not become continuous with GPI-HA-expressing cells. The region of hemifusion-separated aqueous contents, the hemifusion diaphragm, appeared to be extended and was long-lived. But when RBCs hemifused to GPI-HA-expressing cells were osmotically swollen, some diaphragms were disrupted, and spread of both inner leaflet and aqueous dyes was observed. This was characteristic of full fusion: inner leaflet and aqueous probes spread to cells expressing wild-type HA (wt-HA). By simultaneous video fluorescence microscopy and time-resolved electrical admittance measurements, we rigorously demonstrated that GPI-HA-expressing cells hemifuse to planar bilayer membranes: lipid continuity was established without formation of fusion pores. The hemifusion area became large. In contrast, for cells expressing wt-HA, before lipid dye spread, fusion pores were always observed, establishing that full fusion occurred. We present an elastic coupling model in which the ectodomain of wt-HA induces hemifusion and the transmembrane domain, absent in the GPI-HA-expressing cells, mediates full fusion.

Published

1995

5. Membrane fusion process of Semliki Forest virus. II: Cleavage-dependent reorganization of the spike protein complex controls virus entry.

Author

Salminen A, Wahlberg JM, Lobigs M, Liljeström P, and Garoff H

Subjects

Animals, Cell Line, Chloroquine pharmacology, Cricetinae, DNA Mutational Analysis, Endocytosis, Fluorescent Antibody Technique, Hydrogen-Ion Concentration, In Vitro Techniques, Macromolecular Substances, Protein Conformation, Trypsin pharmacology, Viral Envelope Proteins ultrastructure, Viral Fusion Proteins ultrastructure, Virus Replication, Membrane Fusion, Semliki forest virus physiology, Viral Envelope Proteins physiology, Viral Fusion Proteins physiology

Abstract

The envelope of the Semliki Forest virus (SFV) contains two transmembrane proteins, E2 and E1, in a heterodimeric complex. The E2 subunit is initially synthesized as a precursor protein p62, which is proteolytically processed to the mature E2 form before virus budding at the plasma membrane. The p62 (E2) protein mediates binding of the heterodimer to the nucleocapsid during virus budding, whereas E1 carries the entry functions of the virus, that is, cell binding and low pH-mediated membrane fusion activity. We have investigated the significance of the cleavage event for the maturation and entry of the virus. To express SFV with an uncleaved p62 phenotype, BHK-21 cells were transfected by electroporation with infectious viral RNA transcribed from a full-length SFV cDNA clone in which the p62 cleavage site had been changed. The uncleaved p62E1 heterodimer was found to be used for the formation of virus particles with an efficiency comparable to the wild type E2E1 form. However, in contrast to the wild type virus, the mutant virus was virtually noninfectious. Noninfectivity resulted from impaired uptake into cells, as well as from the inability of the virus to promote membrane fusion in the mildly acidic conditions of the endosome. This inability could be reversed by mild trypsin treatment, which converted the viral p62E1 form into the mature E2E1 form, or by treating the virus with a pH 4.5 wash, which in contrast to the more mild pH conditions of endosomes, effectively disrupted the p62E1 subunit association. We conclude that the p62 cleavage is not needed for virus budding, but regulates entry functions of the E1 subunit by controlling the heterodimer stability in acidic conditions.

Published

1992

6. Membrane fusion process of Semliki Forest virus. I: Low pH-induced rearrangement in spike protein quaternary structure precedes virus penetration into cells.

Author

Wahlberg JM and Garoff H

Subjects

Animals, Antibodies, Monoclonal immunology, Antibodies, Viral immunology, Cell Line, Cricetinae, Endocytosis, Epitopes, Fluorescent Antibody Technique, Hydrogen-Ion Concentration, In Vitro Techniques, Macromolecular Substances, Monensin pharmacology, Protein Conformation, Semliki forest virus immunology, Semliki forest virus ultrastructure, Trypsin pharmacology, Viral Envelope Proteins immunology, Viral Envelope Proteins ultrastructure, Membrane Fusion, Semliki forest virus physiology, Viral Envelope Proteins physiology, Viral Fusion Proteins physiology

Abstract

The Semliki Forest virus (SFV) directs the synthesis of a heterodimeric membrane protein complex which is used for virus membrane assembly during budding at the surface of the infected cell, as well as for low pH-induced membrane fusion in the endosomes when particles enter new host cells. Existing evidence suggests that the E1 protein subunit carries the fusion potential of the heterodimer, whereas the E2 subunit, or its intracellular precursor p62, is required for binding to the nucleocapsid. We show here that during virus uptake into acidic endosomes the original E2E1 heterodimer is destabilized and the E1 proteins form new oligomers, presumably homooligomers, with altered E1 structure. This altered structure of E1 is specifically recognized by a monoclonal antibody which can also inhibit penetration of SFV into host cells as well as SFV-mediated cell-cell fusion, thus suggesting that the altered E1 structure is important for the membrane fusion. These results give further support for a membrane protein oligomerization-mediated control mechanism for the membrane fusion potential in alphaviruses.

Published

1992