scholarly journals New Biophysical Approaches Reveal the Dynamics and Mechanics of Type I Viral Fusion Machinery and Their Interplay with Membranes

Viruses ◽  
2020 ◽  
Vol 12 (4) ◽  
pp. 413 ◽  
Author(s):  
Mark A. Benhaim ◽  
Kelly K. Lee
Keyword(s):  
Membrane Fusion ◽  
Conformational Changes ◽  
Viral Entry ◽  
Fusion Proteins ◽  
Structural Changes ◽  
Fusion Reaction ◽  
Type I ◽  
Viral Fusion ◽  
Technological Advances ◽  
Viral Fusion Proteins

Protein-mediated membrane fusion is a highly regulated biological process essential for cellular and organismal functions and infection by enveloped viruses. During viral entry the membrane fusion reaction is catalyzed by specialized protein machinery on the viral surface. These viral fusion proteins undergo a series of dramatic structural changes during membrane fusion where they engage, remodel, and ultimately fuse with the host membrane. The structural and dynamic nature of these conformational changes and their impact on the membranes have long-eluded characterization. Recent advances in structural and biophysical methodologies have enabled researchers to directly observe viral fusion proteins as they carry out their functions during membrane fusion. Here we review the structure and function of type I viral fusion proteins and mechanisms of protein-mediated membrane fusion. We highlight how recent technological advances and new biophysical approaches are providing unprecedented new insight into the membrane fusion reaction.

scholarly journals Viral Membrane Fusion and the Transmembrane Domain

Viruses ◽  
2020 ◽  
Vol 12 (7) ◽  
pp. 693 ◽  
Author(s):  
Chelsea T. Barrett ◽  
Rebecca Ellis Dutch
Keyword(s):  
Membrane Fusion ◽  
Host Cell ◽  
Fusion Proteins ◽  
Transmembrane Domain ◽  
Critical Role ◽  
Viral Fusion ◽  
Transmembrane Region ◽  
Host Cell Membrane ◽  
The Past ◽  
Viral Fusion Proteins

Initiation of host cell infection by an enveloped virus requires a viral-to-host cell membrane fusion event. This event is mediated by at least one viral transmembrane glycoprotein, termed the fusion protein, which is a key therapeutic target. Viral fusion proteins have been studied for decades, and numerous critical insights into their function have been elucidated. However, the transmembrane region remains one of the most poorly understood facets of these proteins. In the past ten years, the field has made significant advances in understanding the role of the membrane-spanning region of viral fusion proteins. We summarize developments made in the past decade that have contributed to the understanding of the transmembrane region of viral fusion proteins, highlighting not only their critical role in the membrane fusion process, but further demonstrating their involvement in several aspects of the viral lifecycle.

scholarly journals Reevaluating Herpes Simplex Virus Hemifusion

2010 ◽  
Vol 84 (22) ◽  
pp. 11814-11821 ◽  
Author(s):  
Julia O. Jackson ◽  
Richard Longnecker
Keyword(s):  
Herpes Simplex Virus ◽  
Herpes Simplex ◽  
Fusion Protein ◽  
Membrane Fusion ◽  
Fusion Proteins ◽  
Fusion Pore ◽  
Viral Fusion ◽  
Viral Fusion Protein ◽  
Viral Fusion Proteins ◽  
Simplex Virus

ABSTRACT Membrane fusion induced by enveloped viruses proceeds through the actions of viral fusion proteins. Once activated, viral fusion proteins undergo large protein conformational changes to execute membrane fusion. Fusion is thought to proceed through a “hemifusion” intermediate in which the outer membrane leaflets of target and viral membranes mix (lipid mixing) prior to fusion pore formation, enlargement, and completion of fusion. Herpes simplex virus type 1 (HSV-1) requires four glycoproteins—glycoprotein D (gD), glycoprotein B (gB), and a heterodimer of glycoprotein H and L (gH/gL)—to accomplish fusion. gD is primarily thought of as a receptor-binding protein and gB as a fusion protein. The role of gH/gL in fusion has remained enigmatic. Despite experimental evidence that gH/gL may be a fusion protein capable of inducing hemifusion in the absence of gB, the recently solved crystal structure of HSV-2 gH/gL has no structural homology to any known viral fusion protein. We found that in our hands, all HSV entry proteins—gD, gB, and gH/gL—were required to observe lipid mixing in both cell-cell- and virus-cell-based hemifusion assays. To verify that our hemifusion assay was capable of detecting hemifusion, we used glycosylphosphatidylinositol (GPI)-linked hemagglutinin (HA), a variant of the influenza virus fusion protein, HA, known to stall the fusion process before productive fusion pores are formed. Additionally, we found that a mutant carrying an insertion within the short gH cytoplasmic tail, 824L gH, is incapable of executing hemifusion despite normal cell surface expression. Collectively, our findings suggest that HSV gH/gL may not function as a fusion protein and that all HSV entry glycoproteins are required for both hemifusion and fusion. The previously described gH 824L mutation blocks gH/gL function prior to HSV-induced lipid mixing.

scholarly journals Role of Electrostatic Repulsion in Controlling pH-Dependent Conformational Changes of Viral Fusion Proteins

Structure ◽  
2013 ◽  
Vol 21 (7) ◽  
pp. 1085-1096 ◽  
Author(s):  
Joseph S. Harrison ◽  
Chelsea D. Higgins ◽  
Matthew J. O’Meara ◽  
Jayne F. Koellhoffer ◽  
Brian A. Kuhlman ◽  
...  
Keyword(s):  
Conformational Changes ◽  
Fusion Proteins ◽  
Electrostatic Repulsion ◽  
Viral Fusion ◽  
Viral Fusion Proteins ◽  
Ph Dependent

scholarly journals A Discrete Stage of Baculovirus GP64-mediated Membrane Fusion

1999 ◽  
Vol 10 (12) ◽  
pp. 4191-4200 ◽  
Author(s):  
David H. Kingsley ◽  
Ali Behbahani ◽  
Afshin Rashtian ◽  
Gary W. Blissard ◽  
Joshua Zimmerberg
Keyword(s):  
Fusion Protein ◽  
Membrane Fusion ◽  
Conformational Changes ◽  
Fusion Proteins ◽  
Critical Role ◽  
Low Ph ◽  
Heptad Repeat ◽  
Viral Fusion ◽  
Viral Fusion Protein ◽  
Heptad Repeats

Viral fusion protein trimers can play a critical role in limiting lipids in membrane fusion. Because the trimeric oligomer of many viral fusion proteins is often stabilized by hydrophobic 4-3 heptad repeats, higher-order oligomers might be stabilized by similar sequences. There is a hydrophobic 4-3 heptad repeat contiguous to a putative oligomerization domain of Autographa californica multicapsid nucleopolyhedrovirus envelope glycoprotein GP64. We performed mutagenesis and peptide inhibition studies to determine if this sequence might play a role in catalysis of membrane fusion. First, leucine-to-alanine mutants within and flanking the amino terminus of the hydrophobic 4-3 heptad repeat motif that oligomerize into trimers and traffic to insect Sf9 cell surfaces were identified. These mutants retained their wild-type conformation at neutral pH and changed conformation in acidic conditions, as judged by the reactivity of a conformationally sensitive mAb. These mutants, however, were defective for membrane fusion. Second, a peptide encoding the portion flanking the GP64 hydrophobic 4-3 heptad repeat was synthesized. Adding peptide led to inhibition of membrane fusion, which occurred only when the peptide was present during low pH application. The presence of peptide during low pH application did not prevent low pH–induced conformational changes, as determined by the loss of a conformationally sensitive epitope. In control experiments, a peptide of identical composition but different sequence, or a peptide encoding a portion of the Ebola GP heptad motif, had no effect on GP64-mediated fusion. Furthermore, when the hemagglutinin (X31 strain) fusion protein of influenza was functionally expressed in Sf9 cells, no effect on hemagglutinin-mediated fusion was observed, suggesting that the peptide does not exert nonspecific effects on other fusion proteins or cell membranes. Collectively, these studies suggest that the specific peptide sequences of GP64 that are adjacent to and include portions of the hydrophobic 4-3 heptad repeat play a dynamic role in membrane fusion at a stage that is downstream of the initiation of protein conformational changes but upstream of lipid mixing.

Histidine protonation and the activation of viral fusion proteins

2008 ◽  
Vol 36 (1) ◽  
pp. 43-45 ◽  
Author(s):  
Daniela S. Mueller ◽  
Thorsten Kampmann ◽  
Ragothaman Yennamalli ◽  
Paul R. Young ◽  
Bostjan Kobe ◽  
...  
Keyword(s):  
Conformational Changes ◽  
Envelope Protein ◽  
Fusion Proteins ◽  
Side Chain ◽  
Viral Fusion ◽  
Histidine Residues ◽  
Local Environments ◽  
Viral Fusion Proteins ◽  
Dynamics Simulations

Many viral fusion proteins only become activated under mildly acidic condition (pH 4.5–6.5) close to the pKa of histidine side-chain protonation. Analysis of the sequences and structures of influenza HA (haemagglutinin) and flaviviral envelope glycoproteins has led to the identification of a number of histidine residues that are not only fully conserved themselves but have local environments that are also highly conserved [Kampmann, Mueller, Mark, Young and Kobe (2006) Structure 14, 1481–1487]. Here, we summarize studies aimed at determining the role, if any, that protonation of these potential switch histidine residues plays in the low-pH-dependent conformational changes associated with fusion activation of a flaviviral envelope protein. Specifically, we report on MD (Molecular Dynamics) simulations of the DEN2 (dengue virus type 2) envelope protein ectodomain sE (soluble E) performed under varied pH conditions designed to test the histidine switch hypothesis of Kampmann et al. (2006).

scholarly journals Mechanism of membrane fusion induced by vesicular stomatitis virus G protein

2016 ◽  
Vol 114 (1) ◽  
pp. E28-E36 ◽  
Author(s):  
Irene S. Kim ◽  
Simon Jenni ◽  
Megan L. Stanifer ◽  
Eatai Roth ◽  
Sean P. J. Whelan ◽  
...  
Keyword(s):  
Membrane Fusion ◽  
G Protein ◽  
Vesicular Stomatitis Virus ◽  
Fusion Proteins ◽  
Low Ph ◽  
Viral Fusion ◽  
Protein Fusion ◽  
West Nile ◽  
Vesicular Stomatitis ◽  
Viral Fusion Proteins

The glycoproteins (G proteins) of vesicular stomatitis virus (VSV) and related rhabdoviruses (e.g., rabies virus) mediate both cell attachment and membrane fusion. The reversibility of their fusogenic conformational transitions differentiates them from many other low-pH-induced viral fusion proteins. We report single-virion fusion experiments, using methods developed in previous publications to probe fusion of influenza and West Nile viruses. We show that a three-stage model fits VSV single-particle fusion kinetics: (i) reversible, pH-dependent, G-protein conformational change from the known prefusion conformation to an extended, monomeric intermediate; (ii) reversible trimerization and clustering of the G-protein fusion loops, leading to an extended intermediate that inserts the fusion loops into the target-cell membrane; and (iii) folding back of a cluster of extended trimers into their postfusion conformations, bringing together the viral and cellular membranes. From simulations of the kinetic data, we conclude that the critical number of G-protein trimers required to overcome membrane resistance is 3 to 5, within a contact zone between the virus and the target membrane of 30 to 50 trimers. This sequence of conformational events is similar to those shown to describe fusion by influenza virus hemagglutinin (a “class I” fusogen) and West Nile virus envelope protein (“class II”). Our study of VSV now extends this description to “class III” viral fusion proteins, showing that reversibility of the low-pH-induced transition and architectural differences in the fusion proteins themselves do not change the basic mechanism by which they catalyze membrane fusion.

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