Vesicular Stomatitis Virus Fusion Research Articles

Modulation of Epstein-Barr Virus Glycoprotein B (gB) Fusion Activity by the gB Cytoplasmic Tail Domain

ABSTRACTEpstein-Barr virus (EBV), along with other members of the herpesvirus family, requires a set of viral glycoproteins to mediate host cell attachment and entry. Viral glycoprotein B (gB), a highly conserved glycoprotein within the herpesvirus family, is thought to be the viral fusogen based on structural comparison of EBV gB and herpes simplex virus (HSV) gB with the postfusion crystal structure of vesicular stomatitis virus fusion protein glycoprotein G (VSV-G). In addition, mutational studies indicate that gB plays an important role in fusion function. In the current study, we constructed a comprehensive library of mutants with truncations of the C-terminal cytoplasmic tail domain (CTD) of EBV gB. Our studies indicate that the gB CTD is important in the cellular localization, expression, and fusion function of EBV gB. However, in line with observations from other studies, we conclude that the degree of cell surface expression of gB is not directly proportional to observed fusion phenotypes. Rather, we conclude that other biochemical or biophysical properties of EBV gB must be altered to explain the different fusion phenotypes observed.

Promotion of vesicular stomatitis virus fusion by the endosome-specific phospholipid bis(monoacylglycero)phosphate (BMP)

Vesicular stomatitis virus (VSV) is a prototypic virus commonly used in studies of endocytosis and membrane trafficking. One proposed mechanism for VSV entry involves initial fusion with internal vesicles of multivesicular endosomes followed by back-fusion of these vesicles into the cytoplasm. One feature of endosomal internal vesicles is that they contain the lipid bis(monoacylglycero)phosphate (BMP). Here, we show that the presence of BMP significantly increases the rate of VSV G-mediated membrane fusion. The increased fusion was selective for VSV and was not evident for another enveloped virus, influenza virus. Our data provide a biological rationale for a two-step infection reaction during VSV entry, and suggest that BMP preferentially affects the ability of VSV G to mediate lipid mixing during membrane fusion.

Cell-specific targeting of lentiviral vectors mediated by fusion proteins derived from Sindbis virus, vesicular stomatitis virus, or avian sarcoma/leukosis virus

BackgroundThe ability to efficiently and selectively target gene delivery vectors to specific cell types in vitro and in vivo remains one of the formidable challenges in gene therapy. We pursued two different strategies to target lentiviral vector delivery to specific cell types. In one of the strategies, vector particles bearing a membrane-bound stem cell factor sequence plus a separate fusion protein based either on Sindbis virus strain TR339 glycoproteins or the vesicular stomatitis virus G glycoprotein were used to selectively transduce cells expressing the corresponding stem cell factor receptor (c-kit). An alternative approach involved soluble avian sarcoma/leukosis virus receptors fused to cell-specific ligands including stem cell factor and erythropoietin for targeting lentiviral vectors pseudotyped with avian sarcoma/leukosis virus envelope proteins to cells that express the corresponding receptors.ResultsThe titers of unconcentrated vector particles bearing Sindbis virus strain TR339 or vesicular stomatitis virus G fusion proteins plus stem cell factor in the context of c-kit expressing cells were up to 3.2 × 105 transducing units per ml while vector particles lacking the stem cell factor ligand displayed titers that were approximately 80 fold lower. On cells that lacked the c-kit receptor, the titers of stem cell factor-containing vectors were approximately 40 times lower compared to c-kit-expressing cells.Lentiviral vectors pseudotyped with avian sarcoma/leukosis virus subgroup A or B envelope proteins and bearing bi-functional bridge proteins encoding erythropoietin or stem cell factor fused to the soluble extracellular domains of the avian sarcoma/leukosis virus subgroup A or B receptors resulted in efficient transduction of erythropoietin receptor or c-kit-expressing cells. Transduction of erythropoietin receptor-expressing cells mediated by bi-functional bridge proteins was found to be dependent on the dose, the correct subgroup-specific virus receptor and the correct envelope protein. Furthermore, transduction was completely abolished in the presence of anti-erythropoietin antibody.ConclusionsOur results indicate that the avian sarcoma/leukosis virus bridge strategy provides a reliable approach for cell-specific lentiviral vector targeting. The background levels were lower compared to alternative strategies involving Sindbis virus strain TR339 or vesicular stomatitis virus fusion proteins.

Membrane Fusion Induced by Vesicular Stomatitis Virus Depends on Histidine Protonation

Entry of enveloped animal viruses into their host cells always depends on a step of membrane fusion triggered by conformational changes in viral envelope glycoproteins. Vesicular stomatitis virus (VSV) infection is mediated by virus spike glycoprotein G, which induces membrane fusion at the acidic environment of the endosomal compartment. VSV-induced membrane fusion occurs at a very narrow pH range, between 6.2 and 5.8, suggesting that His protonation is required for this process. To investigate the role of His in VSV fusion, we chemically modified these residues using diethylpyrocarbonate (DEPC). We found that DEPC treatment inhibited membrane fusion mediated by VSV in a concentration-dependent manner and that the complete inhibition of fusion was fully reversed by incubation of modified virus with hydroxylamine. Fluorescence measurements showed that VSV modification with DEPC abolished pH-induced conformational changes in G protein, suggesting that His protonation drives G protein interaction with the target membrane at acidic pH. Mass spectrometry analysis of tryptic fragments of modified G protein allowed the identification of the putative active His residues. Using synthetic peptides, we showed that the modification of His-148 and His-149 by DEPC, as well as the substitution of these residues by Ala, completely inhibited peptide-induced fusion, suggesting the direct participation of these His in VSV fusion.

Low pH-induced Conformational Changes in Vesicular Stomatitis Virus Glycoprotein Involve Dramatic Structure Reorganization

Membrane fusion is the key step in the entry of enveloped animal viruses into their host cells. Fusion of vesicular stomatitis virus with membranes occurs at acidic pH and is mediated by its envelope glycoprotein, the G protein. To study the structural transitions induced by acidic pH on G protein, we have extracted the protein from purified virus by incubation with nonionic detergent. At pH 6.0, purified G protein was able to mediate fusion of either phospholipid vesicles or Vero cells in culture. Intrinsic fluorescence studies revealed that changes in the environment of Trp residues occurred as pH decreases. In the absence of lipidic membranes, acidification led to G protein aggregation, whereas protein-protein interactions were substituted by protein-lipid interactions in the presence of liposomes. 1,1'-Bis(4-aniline-5-naphthalene sulfonate) (bis-ANS) binding was utilized to probe the degree of exposure of hydrophobic regions of G protein during acidification. Bis-ANS binding was maximal at pH 6.2, suggesting that a hydrophobic segment is exposed to the medium at this pH. At pH 6.0, a dramatic decrease in bis-ANS binding was observed, probably due to loss of tridimensional structure during the conformational rearrangement. This hypothesis was confirmed by circular dichroism analysis at different pH values, which showed a great decrease in alpha-helix content at pH values close to 6.0, suggesting that a reorganization of G protein secondary structure occurs during the fusion reaction. Our results indicate that G protein undergoes dramatic structural changes at acidic pH and acquires a conformational state able to interact with the target membrane.

Characterization of Cholesterol-Free Insect Cells Infectible by Baculoviruses: Effects of Cholesterol on VSV Fusion and Infectivity and on Cytotoxicity Induced by Influenza M2 Protein

The patented cell line from the cabbage looperTrichoplusia ni(High Five from Invitrogen) was found to grow readily under cholesterol-free (CF) culture conditions. Cellular cholesterol became undetectable by CF passage 4, while growth rate and overall cell morphology remained unaffected for at least 59 CF passages. The Golgi apparatus in CF cells was significantly smaller than in control cells, and the CF cells also concentrated a ceramide-based fluorescent Golgi marker to a greater extent, but endoplasmic reticulum morphology appeared unaffected. Two proteins were expressed in High Five cells from recombinant baculoviruses under CF and control conditions: the vesicular stomatitis virus (VSV) fusion glycoprotein G and the influenza virus ion channel M2. Both proteins were expressed in comparable amounts in CF and control cells. Both were properly assembled and transported to the plasma membrane in CF cells, indicating the presence of functional Golgi. Wild-type G protein expression resulted in extensive syncytia formation in both CF and control cells, showing that cholesterol is not required for VSV fusion. However, a mutant G protein lacking six transmembrane domain residues was inactive in both CF and control cells. Influenza M2 protein was functional in control cells, as indicated by its amantadine-inhibitable cytotoxicity, but cytotoxicity was absent in CF cells expressing this protein, indicating a cholesterol-dependence for the cytotoxic action of this protein. CF and control cells were both infectible with VSV. However, infected cell centers were modestly decreased (ca. 3.5-fold) in CF cells. CF cells offer a convenient and novel approach to the study of specific cholesterol functions.

A New Approach to Measure Fusion Activity of Cloned Viral Envelope Proteins: Fluorescence Dequenching of Octadecylrhodamine-Labeled Plasma Membrane Vesicles Fusing with Cells Expressing Vesicular Stomatitis Virus Glycoprotein

Fusion between fluorescently labeled plasma membrane vesicles (PMV) and cells expressing vesicular stomatitis virus (VSV) glycoprotein (G-protein) was investigated by utilizing a lipid mixing assay based on fluorescence dequenching of octadecyl rhodamine (R18). The PMVs were prepared from Vero cells by hypotonic lysis. The G-protein was expressed on the cell surface either following infection with intact VSV or with an adenovirus vector (AdG12) containing the gene for the G-protein. Fusion was temperature and pH dependent and was inhibited by VSV G-antiserum. The pH dependence of PMV fusion paralleled that observed for VSV-cell fusion and VSV-induced syncytia formation. The kinetics of fusion followed an exponential dependence on time without an observable time lag after lowering pH. These findings indicate that dequenching R18-labeled PMV reliably represents the basic features of fusion of VSV with cells and can be used as a new tool in the study of fusion activity of virus envelope proteins expressed in cells.

Enhancement of viral fusion by nonadsorbing polymers

Nonadsorbing polymers such as dextran and poly(ethylene glycol) enhance binding as well as extents of fusion of influenza virus with erythrocytes. Kinetics and extent of viral membrane fusion were measured using an assay based on lipid mixing of a fluorescent dye. The effects of nonadsorbing polymers were in the concentration range from 0 to 10 wt%, far below the concentration required to overcome hydration repulsion forces. The enhancing effects were dependent on the molecular weight of nonadsorbing polymer, and only occurred at molecular weight > 1500; this links the phenomena we observe to the so-called "excluded volume effect" of nonadsorbing polymers. The time delay between triggering and the onset of influenza virus fusion was significantly reduced in the presence of nonadsorbing polymers. High molecular weight poly(ethylene glycol) also induced fusion of vesicular stomatitis virus with intact erythrocytes, which do not serve as target of vesicular stomatitis virus fusion in the absence of the polymer. The forces between membranes which determine rate-limiting processes in viral fusion and how they are affected by nonadsorbing polymers are discussed.

Polarity and Fusion of JAR Choriocarcinoma Cells as Assessed by Enveloped Viral Glycoproteins

Placental trophoblasts are epithelial cells which undergo physiological fusion and generate syncytia. In this study, a placental choriocarcinoma cell line JAR was infected with two enveloped viruses, Parainfluenza type 3 (P3) or vesicular stomatitis virus (VSV). Both viruses posses a fusion glycoprotein known to be able to induce polykaryon formation in nonpolarized cells. The P3 virus fusion protein was localized on the apical as well as on the basal plasmamembrane domains of the infected JAR cells. Infection of the JAR cell monolayer with P3 virus, whose fusion protein is active at pH 7.0, resulted in syncytia formation. Furthermore, the actin ring structure surrounding individual cells disappeared during the P3 virus induced cell-cell fusion. On the contrary, the VSV glycoprotein was found preferentially on the apical plasma membrane domain. To activate the VSV fusogen, the cells were subjected to pH 5.0. However, no syncytia formation peculiar to VSV-infected fibroblasts was observed, and the actin ring structures remained intact. We conclude that in JAR cells the VSV fusion protein exhibits a polarized expression while the P3 virus fusion glycoprotein is distributed between the two membrane domains. Our results suggest that an apically situated fusogen is not sufficient to mediate cell-cell fusion of JAR cells.

Use of octadecylrhodamine fluorescence dequenching to study vesicular stomatitis virus fusion with human aged red blood cells.

Human erythrocytes were separated into five fractions representing different age groups. In each group phospholipid inside-outside translocation was determined by quantitation of the amino phospholipids phosphatidylserine and phosphatidylethanolamine and their lyso-derivatives by thin layer chromatography. To assess the role of transbilayer phospholipid distribution in the recognition and fusion of vesicular stomatitis virus (VSV) and human aged erythrocytes, we monitored the fusion kinetics using the octadecylrhodamine dequenching assay. Fusion of VSV with each single group of red blood cells (RBC) was not detectable with the youngest cells (F1 group) but increased with RBC aging (F2-F5 groups). The same increase in fusion was observed with microvesicles generated from RBC in which aging was mimicked by incubating the cells with Ca2+ in the presence of the Ca2+ ionophore A23187. Conversion of the aminophospholipids to the trinitrophenyl derivative by reaction with trinitrobenzensulfonate completely inhibits fusion on ghosts in which aging was artificially induced by translocation of aminophospholipids in the outer leaflet (symmetric ghosts). These results indicate that RBC become susceptible to VSV fusion during aging and in all pathology related to the aging process.

Use of the fluorescent probe Laurdan to investigate structural organization of the vesicular stomatitis virus (VSV) membrane.

We have used 6-dodecanoil-2-dimethylaminonaphtalene (Laurdan) to study the membrane fluidity of Vesicular Stomatitis Virus (VSV) during virus activation at acidic pH 5.8). The fluorescence properties of Laurdan provide a unique possibility to study lipid organization because of the different excitation and emission spectra of this probe in the gel and liquid crystalline phase. Acidification to pH 5.8 (the pH which triggers VSV fusion with target membranes) generates a decrease in VSV membrane fluidity that could be reversed perfectly after neutralization. We conclude that lipid reorganization of the VSV membrane in the endocytic vesicles is needed for virus activation.

Role of viral envelope sialic acid in membrane fusion mediated by the vesicular stomatitis virus envelope glycoprotein.

Fusion of vesicular stomatitis virus (VSV) with cells and liposomes before and after treatment with neuraminidase was studied using the R18 dequenching assay. Desialylation of VSV significantly enhanced the extent of fusion with Vero cells but affected neither the pH dependence nor the binding of VSV to Vero cells. The enhanced fusion of asialo-VSV was observed both at the plasma membrane as well as via the endocytic pathway. Both VSV and asialo-VSV fused with liposomes made of neutral phospholipid, but only asialo-VSV fused with liposomes containing a 1:1 mixture of neutral and negatively charged phospholipid. To examine factors which contribute to the extent of fusion, we analyzed the various activation and inactivation reactions that take place as a result of low-pH triggering of VSV prebound to the target membrane. Lag times for the onset of fusion were similar for VSV and asialo-VSV, indicating that desialylation did not affect the activation reactions. However, exposure of VSV bound to target membranes at pH 6.5 for 400 s led to considerable inactivation, whereas little inactivation was seen after desialylation of VSV. These results are analyzed in terms of a model which allows us to determine which components of the overall fusion process are dominated by viral envelope sialic acid.

Effect of erythrocyte transbilayer phospholipid distribution on fusion with vesicular stomatitis virus

To identify the specific component(s) in the target membrane involved in fusion of vesicular stomatitis virus (VSV), we examined the interaction of the virus with human erythrocyte membranes with asymmetric and symmetric bilayer distributions of phospholipids. Fusion was monitored spectrofluorometrically by the octadecylrhodamine dequenching assay. Fusion of VSV with lipid-symmetric erythrocyte ghosts was rapid at 37 degrees C and low pH, whereas little or no fusion was observed with lipid-asymmetric ghosts. Conversion of phosphatidylserine in the lipid-symmetric ghost membrane to phosphatidylethanolamine by means of the enzyme phosphatidylserine decarboxylase did not alter the target membrane's susceptibility to VSV fusion. Spin-labeled phospholipid analogues with phosphatidylserine, phosphatidylethanolamine, and phosphatidylcholine headgroups incorporated into the outer leaflet of lipid-asymmetric erythrocytes did not render those membranes fusogenic. Electron spin resonance spectra showed an increased mobility of a phosphatidylcholine spin-label incorporated into the outer leaflet of lipid-symmetric erythrocyte ghosts as compared to that of lipid-asymmetric ghosts. These results indicate that the susceptibility to VSV fusion is not dependent on any particular phospholipid but rather is related to packing characteristics of the target membrane.

Gating kinetics of pH-activated membrane fusion of vesicular stomatitis virus with cells: stopped-flow measurements by dequenching of octadecylrhodamine fluorescence

To identify the initial stages of membrane fusion induced by vesicular stomatitis virus, we performed stopped-flow kinetic measurement with fluorescently labeled virus attached to human erythrocyte ghosts that contained symmetric bilayer distributions of phospholipids. Fusion was monitored spectrofluorometrically using an assay based on mixing of the lipid fluorophore octadecylrhodamine. At 37 degrees C and pH values near the threshold for fusion, a lag phase of 2 s was observed. The lag time decreased steeply as the pH decreased, while the initial rate of fusion showed the reverse functional dependence on pH. The observed rapid fluorescence changes resulted from fusion of virus bound to the target, and the time lags were not due to association-dissociation reactions between virus and target. For a given pH value, the temperature dependence of the lag time was similar to that of the initial rate of fusion. The results were fitted to a multistate model similar to that resulting from ion channel gating kinetics. The model allows testing of hypotheses concerning the role of cooperativity and conformational changes in viral spike glycoprotein-mediated membrane fusion.

Activation of vesicular stomatitis virus fusion with cells by pretreatment at low pH.

Fusion of vesicular stomatitis virus (VSV) with Vero cells was measured after exposure of the virus to low pH under a variety of experimental conditions. The method of relief of fluorescence self-quenching of the probe octadecylrhodamine was used to monitor fusion. Incubation of the virus at pH 5.5 prior to binding to cells led to significant enhancement of fusion at the plasma membrane, whereas fusion via the endocytic pathway was inhibited. Fusion of pH 5.5-pretreated VSV showed a similar pH threshold for fusion as nontreated virus, and it was blocked by antibody to VSV G protein. Activation of VSV by pretreatment at low pH was only slightly dependent on temperature. In contrast, when VSV was first bound to target cells and subsequently exposed at 4 degrees C to the low pH, activation of the fusion process did not occur. The pH 5.5-mediated activation of VSV could be reversed by returning the pH to neutral in the absence of target membranes. The low pH pretreatment also led to aggregation of virus; large aggregates could be pelleted by low speed centrifugation and only the effects of the supernatant, which consist of single virions and/or microaggregates, were considered. The data were analyzed in the framework of an allosteric model according to which viral spike glycoproteins undergo a pH-dependent conformational transition to an active (fusion-competent) state. Based on that analysis we conclude that the conformational transition to the active state is rate-limiting for fusion and that the viral spike glycoproteins are fusion-competent only in their protonated form.

Cooperativity in viral fusion

A simple model for membrane fusion mediated by vial spike glycoproteins is presented. The viral proteins are considered to be allosteric proteins that undergo concerted conformational transitions when they bind the ligand. The ligand in this case is H+. The effect of the conformational transition is to bring membranes together and induce their fusion. An equation is derived for the dependence of fusion rates on ligand concentration, for a given dissociation constant (Kd), equilibrium constant for the conformational change (L), and number of cooperating subunits (n). Curves generated by this equation provide a reasonable fit to data on the rates of fusion of Vesicular Stomatitis virus with cells for a pKd of 6.3, L = 1000 and n = 6.

PH-dependent fusion of vesicular stomatitis virus with Vero cells. Measurement by dequenching of octadecyl rhodamine fluorescence.

We have studied fusion between membranes of vesicular stomatitis virus (VSV) and Vero cells using an assay for lipid mixing based on the relief of self-quenching of octadecylrhodamine (R18) fluorescence. We could identify the two pathways of fusion by the kinetics of R18 dequenching, effects of inhibitors, temperature dependence, and dependence on osmotic pressure. Fusion at the plasma membrane began immediately after lowering the pH below 6 and showed an approximately exponential time course, whereas fusion via the endocytic pathway (pH 7.4) became apparent after a time delay of about 2 min. Fusion via the endocytic pathway was attenuated by treating cells with metabolic inhibitors and agents that raise the pH of the endocytic vesicle. A 10-fold excess of unlabeled virus arrested R18VSV entry via the endocytic pathway, whereas R18 dequenching below pH 6 (fusion at the plasma membrane) was not affected by the presence of unlabeled virus. The temperature dependence for fusion at pH 7.4 (in the endosome) was much steeper than that for fusion at pH 5.9 (with the plasma membrane). Fusion via the endocytic pathway was attenuated at hypo-osmotic pressures, whereas fusion at the plasma membrane was not affected by this treatment. The pH profile of Vero-VSV fusion at the plasma membrane, as measured by the dequenching method, paralleled that observed for VSV-induced cell-cell fusion. Fusion was blocked by adding neutralizing antibody to the Vero-VSV complexes. Activation of the fusion process by lowering the pH was reversible, in that the rate of fusion was arrested by raising the pH back to 7.4. The observation that pH-dependent fusion occurred at similar rates with fragments and with intact cells indicates that pH, voltage, or osmotic gradients are not required for viral fusion.

Characterization of the fusion of enveloped viruses with the plasma membrane of Saccharomyces cerevisiae spheroplasts.

Vesicular stomatitis virus (VSV) was associated at low pH with Saccharomyces cerevisiae spheroplasts. In the cold, the association was characterized as reversible binding to the spheroplast surface. At 37 degrees C, the association became irreversible due to fusion of the viral envelope with the yeast plasma membrane according to the following data. Proteinase K digestion degraded the viral envelope glycoprotein G but left the internal N and M proteins of VSV intact and associated with the spheroplasts. The plasma membrane could be stained by indirect immunofluorescent labeling using antiserum against VSV. By immunoelectron microscopy, no VSV particles could be detected at the spheroplast surface. Instead, the G protein could be visualized at the external aspect of the plasma membrane using specific antiserum and protein A-gold. Fusion of VSV with spheroplasts occurred below pH 4.75 at temperatures of 30-42 degrees C. It was strictly dependent on the prior removal of the yeast cell wall. The fusion process was fast, calcium-independent, and nonleaky, leaving the spheroplasts viable for at least 4 h. On the average, less than 100 VSV particles could be fused per one spheroplast. Similar data were obtained with Semliki Forest virus.

Vesicular stomatitis virus binds and fuses with phospholipid domain in target cell membranes.

Fusion of vesicular stomatitis virus with some cells (HELR 66, KB, and human erythrocytes, both intact and trypsinized) and liposomes made of various natural and synthetic lipids was studied with spin-labeled phospholipid. Binding of virus was assayed separately with radiolabeled and spin-labeled virus. Binding to cells and liposomes was small at neutral pH but enhanced at acidic pHs. Fusion with cells and liposomes was negligibly small at neutral pH but greatly activated at acidic pHs lower than 6.5. Activation of fusion occurred at lower pH values than enhancement of binding. Fusion occurred rapidly and efficiently, reaching a plateau at 50-80% after 3 min at 37 degrees C. Binding and fusion with cells were enhanced by pretreatment of cells with trypsin. Binding to liposomes was dependent on the head group of the phospholipid, stronger to phosphatidylserine than to phosphatidylcholine, but not much dependent on the acyl chain composition. On the other hand, cis-unsaturated acyl chains were required for the efficient fusion, but there was only a small, if any, requirement for the head group. Cholesterol enhanced the fusion further. High fusion efficiency with cis-unsaturated phospholipids cannot be ascribed to the membrane fluidity but may be related to higher tail-to-head volume ratios. Possible mode of interaction of viral G glycoprotein with phospholipid is discussed. The virus cell entry mechanism is suggested as binding to the phospholipid domain in the cell surface membranes, endocytosis, and followed by fusion with the phospholipid domain in endosomes upon acidification.

Fusion of vesicular stomatitis virus with the cytoplasmic membrane of L cells.

At an early stage in infection, vesicular stomatitis viruses were attached to the surface of L cells by fusion of the viral and cell membranes.