Promote Membrane Fusion Research Articles

Retinal and retinol promote membrane fusion

Disk membranes from the bovine retinal rod outer segments (ROS) were found to fuse with vesicles made of lipids extracted from unbleached ROS disk membranes, using a lipid mixing assay for membrane fusion (relief of self-quenching of R 18, octadecylrhodamine B chloride). If the retinal chromophore of rhodopsin was reductively linked to opsin before lipid extraction, the vesicles made of the extracted lipids were not suitable targets for fusion of the disk membranes. The addition of retinal and retinool to these vesicles restored their ability to fuse. Therefore, the presence of all- trans retinal was implicated in promoting membrane fusion in this system. To test this possibility, the ability of retinal and retinol to influence the phase behavior and the fusion capability of large unilamellar vesicles (LUV) of N-methyl dioleoylphosphatidylethanolamine ( N-methyl-DOPE) was examined. Both retinal and retinaol stimulated the fusion of vesicles of N-methyl-DOPE (contents mixing with ANTS, 1-aminoaphthalene-3,6,8-trisulfonic acid; DPX, p-xylxylene bis(pyridinium bromide)). Both compounds reduced the onset temperature for isotropic resonances in the 31P-NMR spectra of N-methyl-DOPE dispersions and the onset temperature, T H, for formation of hexagonal II phase. These results were consistent with previous studies in which the onset temperature for the 31P-NMR isotropic resonances were correlated with stimulation of membrane fusion. These data suggested that both retinal and retinol may stimulate membrane fusion by destabilizing the bilayers of membranes.

Intermonomer disulfide bonds impair the fusion activity of influenza virus hemagglutinin.

At a low pH, the influenza virus hemagglutinin (HA) undergoes conformational changes that promote membrane fusion. While the critical role of fusion peptide release from the trimer interface has been demonstrated previously, the role of globular head dissociation in the overall fusion mechanism remains unclear. To investigate this question, we have analyzed in detail the fusion activity and low pH-induced conformational changes of a mutant, Cys-HA, in which the globular head domains are locked together by engineered intermonomer disulfide bonds (L. Godley, J. Pfeifer, D. Steinhauer, B. Ely, G. Shaw, R. Kaufmann, E. Suchanek, C. Pabo, J. J. Skehel, D. C. Wiley, and S. Wharton, Cell 68:635-645, 1992). In this paper, we show that Cys-HA expressed on the cell surface is predominantly a disulfide-bonded trimer. Cell surface Cys-HA is impaired in its membrane fusion activity, as demonstrated by both content-mixing and lipid-mixing fusion assays. It is also impaired in its ability to change conformation at a low pH, as assessed by proteinase K sensitivity. The fusion activity and low pH-induced conformational changes of cell surface Cys-HA are, however, restored to nearly wild-type levels upon reduction of the intermonomer disulfide bonds. By using a set of conformation-specific monoclonal and anti-peptide antibodies, we found that purified Cys-HA trimers are impaired in changes that occur in the globular head domain interface. In addition, changes that occur at a great distance from the engineered intermonomer disulfide bonds, notably release of the fusion peptides, are also impaired. Our results are discussed with respect to current views of the fusion-active conformation of the HA trimer.

Peptide models for the membrane destabilizing actions of viral fusion proteins.

The fusion of enveloped viruses to target membranes is promoted by certain viral fusion proteins. However, many other proteins and peptides stabilize bilayer membranes and inhibit membrane fusion. We have evaluated some characteristics of the interaction of peptides that are models of segments of measles and influenza fusion proteins with membranes. Our results indicate that these models of the fusogenic domains of viral fusion proteins promote conversion of model membrane bilayers to nonbilayer phases. This is opposite to the effects of peptides and proteins that inhibit viral fusion. A peptide model for the fusion segment of the HA protein of influenza increased membrane leakage as well as promoted the formation of nonbilayer phases upon acidification from pH 7-5. We analyze the gross conformational features of the peptides, and speculate on how these conformational features relate to the structures of the intact proteins and to their role in promoting membrane fusion.

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

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.

Fusion properties of cells persistently infected with human parainfluenza virus type 3: participation of hemagglutinin-neuraminidase in membrane fusion

Cells persistently infected with human parainfluenza virus type 3 (HPF3) exhibit a novel phenotype. They are completely resistant to fusion with each other but readily fuse with uninfected cells. We demonstrate that the inability of these cells to fuse with each other is due to a lack of cell surface neuraminic acid. Neuraminic acid is the receptor for the HPF3 hemagglutinin-neuraminidase (HN) glycoprotein, the molecule responsible for binding of the virus to cell surfaces. Uninfected CV-1 cells were treated with neuraminidase and then tested for their ability to fuse with the persistently infected (pi) cells. Neuraminidase treatment totally abolished cell fusion. To extend this result, we used a cell line deficient in sialic acid and demonstrated that these cells, like the neuraminidase-treated CV-1 cells, were unable to fuse with pi cells. We then tested whether mimicking the agglutinating function of the HN molecule with lectins would result in cell fusion. We added a panel of five lectins to the neuraminic acid-deficient cells and showed that binding of these cells to the pi cells did not result in fusion; the lectins could not substitute for interaction of neuraminic acid with the HN molecule in promoting membrane fusion. These results provide compelling evidence that the HN molecule of HPF3 and its interaction with neuraminic acid participate in membrane fusion and that cell fusion is mediated by an interaction more complex than mere juxtaposition of the cell membranes.

Synexin (annexin VII): A cytosolic calcium-binding protein which promotes membrane fusion and forms calcium channels in artificial bilayer and natural membranes

Synexin (annexin VII): A cytosolic calcium-binding protein which promotes membrane fusion and forms calcium channels in artificial bilayer and natural membranes

Membrane capacity, measurements suggest a calcium-dependent insertion of synexin into phosphatidylserine bilayers

The mechanism by which synexin mediates calcium-dependent aggregation of medullary cell chromaffin granules and fusion of granule ghosts involves specific interactions with the lipid component of the membrane. To study the details of these interactions we measured synexin-induced changes in capacitance of phosphatidylserine bilayers formed at the tip of a patch pipet using the double-dip method. Provided calcium was present in the solution filling the pipet (10–50 mM) stable phosphatidylserine bilayers were easily formed. Addition of synexin (0.1 μg/ml) to an external medium lacking added calcium induced no measurable changes in either bilayer resistance (10–30 GΩ) or displacement current across the membrane. However, addition of calcium (0.1–2.5 mM) in the presence of synexin in the external solution caused a marked increase in the size and time constant of decay of the displacement current. From the steady-state value of the current we calculated a 5-fold decrease in resistance and from the charge displaced during the voltage-clamp pulses we calculated a 10-fold increase in membrane capacitance (from 20 to 200 fF). The size of the synexin-specific charge displacement in one direction during a pulse was always equal to the charge returning to the original configuration after the pulse. The synexin-specific transfer of charge reached saturation when the pipet potential was taken to a sufficient positive or negative value. These properties of the extra charge movement support our view that in the presence of calcium the cytosolic protein synexin penetrates into the bilayer. It is possible that these properties may be related to the mechanism by which synexin promotes membrane fusion in natural membranes.

Membrane-membrane interactions associated with rapid transfer of liposomal bilirubin to microsomal UDP-glucuronyltransferase. Relevance for hepatocellular transport and biotransformation of hydrophobic substrates

Bilirubin may be transported within intracellular membranes of the hepatocyte and may undergo membrane-membrane transfer to gain access to the conjugating enzyme UDP-glucuronyltransferase in the endoplasmic reticulum. We have demonstrated previously that the lipid composition of liposomal membranes incorporating bilirubin substrate influences the rate of transfer and glucuronidation of bilirubin by hepatic microsomes. To examine the mechanism(s) of substrate transfer, we incorporated radiolabelled bilirubin into small unilamellar model membranes of egg phosphatidylcholine or natural phospholipids in the proportions present in native hepatic microsomes. The rate at which bilirubin was transferred to rat liver microsomes and glucuronidated was then examined in the presence of various endogenous compounds that promote membrane fusion. For bilirubin substrate in membranes of egg phosphatidylcholine, the addition of Ca2+ (2 mM) increased the microsomal glucuronidation rate, whereas retinol enhanced microsomal conjugation rates for bilirubin in membranes of both lipid compositions. When the transfer of [3H]bilirubin from dual-labelled liposomes to microsomes was enhanced by Ca2+ or retinol, there was no associated increase in [14C]phospholipid transfer. Thus it appears likely that bilirubin is transferred to the endoplasmic reticulum by rapid cytosolic diffusion or membrane-membrane collisions, rather than by membrane fusion; this process may be modulated by changes in the lipid microenvironment of the substrate or the effective intracellular concentrations of Ca2+ or retinol. The observation that polymyxin B induced concomitant membrane-membrane transfer of [3H]bilirubin and [14C]phospholipid suggests that under certain circumstances membrane fusion or aggregation may promote the movement of lipophilic substrates in hepatocytes.

Effect of trifluoperazine and other drugs on matrix vesicle formation by chicken growth plate chondrocytes in primary cell culture

Growth plate chondrocytes in primary culture release alkaline phosphatase (AP)-rich matrix vesicles (MV) into the culture medium. While these are thought to derive from the plasma membrane by a membrane fusion-dependent process, the mechanism is not fully understood. Recently, a cytosolic protein, synexin, has been shown to promote membrane fusion in a number of systems, and thus may be involved in MV formation. Since the action of synexin is selectively inhibited by trifluoperazine (TFP) and other phenothiazines, we examined the effects of these drugs, and imipramine, on cellular AP production and formation of AP-containing MV by cultured chondrocytes. In addition, we studied the effect on cell division, protein biosynthesis, and incorporation of palmitate into cellular and MV lipids. All of the drugs reduced cellular AP in a concentration-dependent manner; however, at the higher levels, chlorpromazine (CPZ) and TFP caused a transient sharp rise in MV AP activity. At IC 50 levels, the drugs were more inhibitory to cellular AP than to MV AP, appearing to enhance significantly the transfer of available cellular AP into MV. In contrast, the drugs stimulated incorporation of [ 3H]palmitate into cellular lipids, but either had no effect on, or actually inhibited, incorporation of the fatty acid into MV. At these levels, the drugs had little effect on cell division and protein biosynthesis. The inhibitory effect of IC 50 levels of CPZ on palmitate incorporation into MV appears to have resulted from impairment of vesicle formation per se, since at these levels the drug stimulated incorporation of the fatty acid into the cells. The transient stimulatory effect of higher levels of CPZ on MV AP levels, and the enhanced transfer of AP into MV by the drugs generally, may result from the effect of the drugs on membrane structure. Since TFP was not inhibitory to MV formation, it is doubtful that synexin was directly involved.

Enhancement of the recognition by cytotoxic T lymphocytes (CTL) of target membrane antigens after fusion with whole cells

Plasma membrane vesicles (R4-PM) prepared from mouse lymphoma cells (RDM4,H2 k) were employed to investigate requirements for recognition of target cell membranes by allogeneic cytotoxic T lymphocytes (CTL). Using immunofluorescent staining and fluorescence microscopy, the R4-PM were tested for binding to CTL and were found to bind to these effector cells in a specific manner. However, this binding was very inefficient compared to the binding of whole RDM4 cells to CTL. The R4-PM were then attached to P388D 1 cells (H-2 d) in the presence of wheat germ agglutinin and polyethylene glycol (PEG), both under conditions which promote membrane fusion (40% PEG) and under conditions which do not (10% PEG). About 1 cell equivalent R4-PM becomes associated per P388D 1 cell in both situations. In the cytotoxicity assays that were carried out, the P388D 1 cells which had R4-PM attached under fusion conditions were lysed by CTL directed against H2 k in a specific manner, while the P388D 1 cells which had R4-PM attached under nonfusion conditions were not lysed above background levels by these CTL. These results suggest that recognition of target cells by allogeneic CTL such that lysis occurs requires more than presentation of the alloantigens as they are expressed in plasma membrane vesicles. However, fusion of these vesicles back into living cells apparently enhances the ability of the alloantigens to be recognized.

Haemagglutinin of influenza virus expressed from a cloned gene promotes membrane fusion.

Enveloped animal viruses enter and infect cells by a process involving fusion of the viral membrane with a cellular membrane. In some cases (for example, Sendai virus1), the fusion event occurs at the plasma membrane; for many other viruses including influenza, entry occurs through the membranes of intracellular vesicles such as endosomes or lysosomes, where the fusion is triggered by the endogenous low pH2–6. This pH-dependent fusion activity has been studied in vitro using as targets cultured cells7–9, erythrocytes9,10 and liposomes11–13. Fusion is a function of the viral surface glycoproteins12 and occurs at a threshold pH that is characteristic of each virus species and strain8. In the case of influenza virus, there is strong evidence that the haemagglutinin glycoprotein has a key role in both virus infectivity and fusion activity9,12,14–16. Both processes require a post-translational proteolytic cleavage of the haemagglutinin precursor, HA0, into the active form of the molecule, HA, which consists of two disulphide-bonded subunits, HA1 and HA217,18. A new N-terminus is generated on the HA2 subunit, the C-terminus of which is embedded in the virus membrane19. At the low pH values required for fusion the cleaved HA undergoes a conformational change exposing this previously buried hydrophobic N-terminus of HA220, possibly enabling it to interact with the target membrane. While it has been established that HA is necessary for fusion, it is unclear whether HA alone is sufficient or whether other viral proteins are involved21. Here we use cells expressing HA from a cloned copy of the HA gene inserted into a recombinant simian virus 40 (SV40) vector22 to demonstrate that the HA molecule displays fusion in the absence of any other influenza virus-encoded components. These results open the possibility of using HA-mediated membrane fusion as a system to deliver foreign molecules into mammalian cells.

A virion-associated glycoprotein essential for infectivity of herpes simplex virus type 1

A temperature-sensitive (ts) mutant of herpes simplex virus type 1 (HSV-1), tsJ12, is able to undergo one cycle of replication at the nonpermissive temperature (39°) yielding wild-type quantities of enveloped virus particles. These particles contain viral DNA which is as infectious as wild-type viral DNA; however, they are not infectious. Analysis of [ 14C]glucosamine-labeled mutant-infected cell extracts by one- and two-dimensional polyacrylamide gel electrophoresis demonstrated that at 39° tsJ12 fails to induce the synthesis of both the mature gB glycoprotein and its dimeric form which are normal constituents of the virion envelope. Polyethylene glycol, an agent which promotes membrane fusion, enhances the infectivity of tsJ12 virions by greater than 1000-fold following adsorption of virus to susceptible cells demonstrating that mutant virions are able to attach to cells but not penetrate. Consistent with a defect in the virion envelope, tsJ12 is able to interfere with the production of infectious wild-type virus, presumably by the formation of pseudotypic virions composed of wild-type viral genomes in gB-deficient envelopes. Physical mapping of the is defect in this mutant demonstrates that it lies within the limits of the DNA sequence which specifies gB on the physical map of the genome. A ts + revertant of tsJ12 is as infectious as wild-type virus and synthesizes a gB glycoprotein which is indistinguishable from that of wild-type virus. Thus, biological and biochemical studies of tsJ12 and of a ts+ revertant of this mutant (1) demonstrate that glycoprotein gB is essential for infectivity at the level of penetration and (2) further define the physical map location of the gene for this glycoprotein.

Membrane proteins specified by herpes simplex viruses. III. Role of glycoprotein VP7(B2) in virion infectivity

Experiments done with a temperature"sensitive mutant of herpes simplex virus type 1 (HSV-1) have revealed that one of the virisn glycoproteins, designated VP7(B2), is apparently not required for the production of enveloped virus particles, whereas it does play a critical role in virion infectivity. The mutant, designated HSV-1[HFEM]tsB5, fails to accumulate VP7(B2) at nonpermissive temperature and produces virions that lack detectable quantities of this glycoprotein and that have very low specific infectivity. The poor infectivity of the virions is most readily explained by failure of penetration into the host cell rather than by failure of adsorption to cells because it was shown that the VP7(B2)-deficient virions can bind to cells and that polyethylene glycol, an agent known to promote membrane fusion, can significantly enhance infectivity of the adsorbed virions.

Morphological and biochemical characterization of viral particles produced by the tsO45 mutant of vesicular stomatitis virus at restrictive temperature

The growth at restrictive temperature of tsO45, a group V (glycoprotein) conditional lethal mutant of vesicular stomatitis virus (VSV), was demonstrated to result in the production of large numbers of noninfectious viral particles. The infectivity of these tsO45 particles could be enhanced by procedures known to promote membrane fusion. Morphologically and biochemically these particles differed from wild-type VSV by their lack of viral glycoprotein. The other structural proteins of VSV were present and indistinguishable by size and relative proportion from those of virus grown at the permissive temperature. Examination of glycoprotein maturation at the restrictive temperature (39.5 degrees C) in tsO45-infected cells demonstrated the synthesis of normal viral glycoprotein but failed to demonstrate the presence of this glycoprotein in either the cell membrane or the envelope of free virions. The further absence of soluble viral glycoprotein from the supernatants of such cells strongly suggests that viral glycoprotein may not be necessary for the successful budding of VSV.