Oligomerization-dependent folding of the membrane fusion protein of Semliki Forest virus.

The spikes of alphaviruses are composed of three copies of an E2-E1 heterodimer. The E1 protein possesses membrane fusion activity, and the E2 protein, or its precursor form, p62 (sometimes called PE2), controls this function. Both proteins are, together with the viral capsid protein, translated from a common C-p62-E1 coding unit. In an earlier study, we showed that the p62 protein of Semliki Forest virus (SFV) dimerizes rapidly and efficiently in the endoplasmic reticulum (ER) with the E1 protein originating from the same translation product (so-called heterodimerization in cis) (B.-U. Barth, J. M. Wahlberg, and H. Garoff, J. Cell Biol. 128:283-291, 1995). In the present work, we analyzed the ER translocation and folding efficiencies of the p62 and E1 proteins of SFV expressed from separate coding units versus a common one. We found that the separately expressed p62 protein translocated and folded almost as efficiently as when it was expressed from a common coding unit, whereas the independently expressed E1 protein was inefficient in both processes. In particular, we found that the majority of the translocated E1 chains were engaged in disulfide-linked aggregates. This result suggests that the E1 protein needs to form a complex with p62 to avoid aggregation. Further analyses of the E1 aggregation showed that it occurred very rapidly after E1 synthesis and could not be avoided significantly by the coexpression of an excess of p62 from a separate coding unit. These latter results suggest that the p62-E1 heterodimerization has to occur very soon after E1 synthesis and that this is possible only in a cis-directed reaction which follows the synthesis of p62 and E1 from a common coding unit. We propose that the p62 protein, whose synthesis precedes that of the E1 protein, remains in the translocon of the ER and awaits the completion of E1. This strategy enables the p62 protein to complex with the E1 protein immediately after the latter has been made and thereby to control (suppress) its fusion activity.     

Membrane fusion of Semliki Forest virus involves homotrimers of the fusion protein.

Infection of cells with enveloped viruses is accomplished through membrane fusion. The binding and fusion processes are mediated by the spike proteins in the envelope of the virus particle and usually involve a series of conformational changes in these proteins. We have studied the low-pH-mediated fusion process of the alphavirus Semliki Forest virus (SFV). The spike protein of SFV is composed of three copies of the protein heterodimer E2E1. This structure is resistant to solubilization in mild detergents such as Nonidet P-40 (NP40). We have recently shown that the spike structure is reorganized during virus entry into acidic endosomes (J. M. Wahlberg and H. Garoff, J. Cell Biol. 116:339-348, 1992). The original NP40-resistant heterodimer is dissociated, and the E1 subunits form new NP40-resistant protein oligomers. Here, we show that the new oligomer is represented by an E1 trimer. From studies that use an in vitro assay for fusion of SFV with liposomes, we show that the E1 trimer is efficiently expressed during virus-mediated membrane fusion. Time course studies show that both E1 trimer formation and fusion are fast processes, occurring in seconds. It was also possible to inhibit virus binding and fusion with a monoclonal antibody directed toward the trimeric E1. These results give support for a model in which the E1 trimeric structure is involved in the SFV-mediated fusion reaction.     

An epitope of the Semliki Forest virus fusion protein exposed during virus-membrane fusion

Semliki Forest virus (SFV) is an enveloped alphavirus that infects cells via a membrane fusion reaction triggered by acidic pH in the endocytic pathway. Fusion is mediated by the spike protein E1 subunit, an integral membrane protein that contains the viral fusion peptide and forms a stable homotrimer during fusion. We have characterized four monoclonal antibodies (MAbs) specific for the acid conformation of E1. These MAbs did not inhibit fusion, suggesting that they bind to an E1 region different from the fusion peptide. Competition analyses demonstrated that all four MAbs bound to spatially related sites on acid-treated virions or isolated spike proteins. To map the binding site, we selected for virus mutants resistant to one of the MAbs, E1a-1. One virus isolate, SFV 4-2, showed reduced binding of three acid-specific MAbs including E1a-1, while its binding of one acid-specific MAb as well as non-acid-specific MAbs to E1 and E2 was unchanged. The SFV 4-2 mutant was fully infectious, formed the E1 homotrimer, and had the wild-type pH dependence of infection. Sequence analysis demonstrated that the relevant mutation in SFV 4-2 was a change of E1 glycine 157 to arginine (G157R). Decreased binding of MAb E1a-1 was observed under a wide range of assay conditions, strongly suggesting that the E1 G157R mutation directly affects the MAb binding site. These data thus localize an E1 region that is normally hidden in the neutral pH structure and becomes exposed as part of the reorganization of the spike protein to its fusion-active conformation.     

Spike protein oligomerization control of Semliki Forest virus fusion.

We have recently shown, using cleavage-deficient mutants of the p62-E1 membrane protein complex of Semliki Forest virus that p62 cleavage to E2 is necessary for the activation of the fusion function of the complex at pH 5.8 (a pH optimal for virus fusion) (M. Lobigs and H. Garoff, J. Virol. 64:1233-1240, 1990). In this study, we show that the mutant precursor complexes can be induced to activate membrane fusion when treated with more acidic buffers (pH 5.0 and 4.5), which also appear to dissociate most of the p62-E1 complexes and change the conformation of the E1 subunit (the supposed fusion protein of Semliki Forest virus into a form which is resistant to trypsin digestion. These data suggest that p62 cleavage is not essential for membrane fusion per se but that the crucial event activating this process seems to be the apparent dissociation of the heterodimer, which in turn is facilitated by the spike precursor cleavage.     

Functions of the stem region of the Semliki Forest virus fusion protein during virus fusion and assembly

Membrane fusion of the alphaviruses is mediated by the E1 protein, a class II virus membrane fusion protein. During fusion, E1 dissociates from its heterodimer interaction with the E2 protein and forms a target membrane-inserted E1 homotrimer. The structure of the homotrimer is that of a trimeric hairpin in which E1 domain III and the stem region fold back toward the target membrane-inserted fusion peptide loop. The E1 stem region has a strictly conserved length and several highly conserved residues, suggesting the possibility of specific stem interactions along the trimer core and an important role in driving membrane fusion. Mutagenesis studies of the alphavirus Semliki Forest virus (SFV) here demonstrated that there was a strong requirement for the E1 stem in virus assembly and budding, probably reflecting its importance in lateral interactions of the envelope proteins. Surprisingly, however, neither the conserved length nor any specific residues of the stem were required for membrane fusion. Although the highest fusion activity was observed with wild-type E1, efficient fusion was mediated by stem mutants containing a variety of substitutions or deletions. A minimal stem length was required but could be conferred by a series of alanine residues. The lack of a specific stem sequence requirement during SFV fusion suggests that the interaction of domain III with the trimer core can provide sufficient driving force to mediate membrane merger.     

The oligomerization reaction of the Semliki Forest virus membrane protein subunits

The Semliki Forest virus (SFV) spike is composed of three copies of a membrane protein heterodimer. The two subunits of this heterodimer (p62 and E1) are synthesized sequentially from a common mRNA together with the capsid (C) in the order C-p62-E1. In this work heterodimerization of the spike proteins has been studied in BHK 21 cells. The results indicate that: (a) the polyprotein is cotranslationally cleaved into individual chains; (b) the two membrane protein subunits are initially not associated with each other in the endoplasmic reticulum (ER); (c) heterodimerization occurs predominantly between subunits that originate from the same translation product (heterodimerization in cis); (d) the kinetics of subunit association are very fast (t1/2 = 4 min); and (e) this heterodimerization is highly efficient. To explain the cis- directed heterodimerization reaction we suggest that the p62 protein, which is made before E1 during 26S mRNA translation, is retained at its translocation site until also the E1 chain has been synthesized and translocated at this same site. The mechanism for p62 retention could either be that the p62 anchor sequence cannot diffuse out from an "active" translocation site or that the p62 protein is complexed with a protein folding facilitating machinery that is physically linked to the translocation apparatus.     

Membrane fusion of Semliki Forest virus requires sphingolipids in the target membrane.

Enveloped animal viruses, such as Semliki Forest virus (SFV), utilize a membrane fusion strategy to deposit their genome into the cytosol of the host cell. SFV enters cells through receptor-mediated endocytosis, fusion of the viral envelope occurring subsequently from within acidic endosomes. Fusion of SFV has been demonstrated before to be strictly dependent on the presence of cholesterol in the target membrane. Here, utilizing a variety of membrane fusion assays, including an on-line fluorescence assay involving pyrene-labeled virus, we demonstrate that low-pH-induced fusion of SFV with cholesterol-containing liposomal model membranes requires the presence of sphingomyelin or other sphingolipids in the target membrane. The minimal molecular characteristics essential for supporting SFV fusion are encompassed by a ceramide. The action of the sphingolipids is confined to the actual fusion event, cholesterol being necessary and sufficient for low-pH-dependent binding of the virus to target membranes. Complex formation of the sphingolipids with cholesterol is unlikely to be important for the induction of SFV--liposome fusion, as sphingolipids that do not interact appreciably with cholesterol, such as galactosylceramide, effectively support the process. The remarkably low levels of sphingomyelin required for half-maximal fusion (1-2 mole%) suggest that sphingolipids do not play a structural role in the SFV fusion process, but rather act as a cofactor, possibly activating the viral fusion protein in a specific manner.     

The fusion peptide of Semliki Forest virus associates with sterol-rich membrane domains

Semliki Forest virus (SFV) is an enveloped alphavirus whose membrane fusion is triggered by low pH and promoted by cholesterol and sphingolipid in the target membrane. Fusion is mediated by E1, a viral membrane protein containing the putative fusion peptide. Virus mutant studies indicate that SFV's cholesterol dependence is controlled by regions of E1 outside of the fusion peptide. Both E1 and E1*, a soluble ectodomain form of E1, interact with membranes in a reaction dependent on low pH, cholesterol, and sphingolipid and form highly stable homotrimers. Here we have used detergent extraction and gradient floatation experiments to demonstrate that E1* associated selectively with detergent-resistant membrane domains (DRMs or rafts). In contrast, reconstituted full-length E1 protein or influenza virus fusion peptide was not associated with DRMs. Methyl beta-cyclodextrin quantitatively extracted both cholesterol and E1* from membranes in the absence of detergent, suggesting a strong association of E1* with sterol. Monoclonal antibody studies demonstrated that raft association was mediated by the proposed E1 fusion peptide. Thus, although other regions of E1 are implicated in the control of virus cholesterol dependence, once the SFV fusion peptide inserts in the target membrane it has a high affinity for membrane domains enriched in cholesterol and sphingolipid.     

Mutagenesis of the putative fusion domain of the Semliki Forest virus spike protein.

Semliki Forest virus (SFV), an alphavirus, infects cells via a low pH-triggered membrane fusion reaction that takes place within the cellular endocytic pathway. Fusion is mediated by the heterotrimeric virus spike protein, which undergoes conformational changes upon exposure to low pH. The SFV E1 spike subunit contains a hydrophobic domain of 23 amino acids that is highly conserved among alphaviruses. This region is also homologous to a domain of the rotavirus outer capsid protein VP4. Mutagenesis of an SFV spike protein cDNA was used to evaluate the role of the E1 domain in membrane fusion. Mutant spike proteins were expressed in COS cells and assayed for cell-cell fusion activity. Four mutant phenotypes were identified: (i) substitution of Gln for Lys-79 or Leu for Met-88 had no effect on spike protein fusion activity; (ii) substitution of Ala for Asp-75, Ala for Gly-83, or Ala for Gly-91 shifted the pH threshold of fusion to a more acidic range; (iii) mutation of Pro-86 to Asp, Gly-91 to Pro, or deletion of amino acids 83 to 92 resulted in retention of the E1 subunit within the endoplasmic reticulum; and (iv) substitution of Asp for Gly-91 completely blocked cell-cell fusion activity without affecting spike protein assembly or transport. These results argue that the conserved hydrophobic domain of SFV E1 is closely involved in membrane fusion and suggest that the homologous region in rotavirus VP4 may be involved in the entry pathway of this nonenveloped virus.     

Second-site revertants of a Semliki Forest virus fusion-block mutation reveal the dynamics of a class II membrane fusion protein

The alphavirus Semliki Forest virus (SFV) infects cells through low-pH-induced membrane fusion mediated by the E1 protein, a class II virus membrane fusion protein. During fusion, E1 inserts into target membranes via its hydrophobic fusion loop and refolds to form a stable E1 homotrimer. Mutation of a highly conserved histidine (the H230A mutation) within a loop adjacent to the fusion loop was previously shown to block SFV fusion and infection, although the mutant E1 protein still inserts into target membranes and forms a homotrimer. Here we report on second-site mutations in E1 that rescue the H230A mutant. These mutations were located in a cluster within the hinge region, at the membrane-interacting tip, and within the groove where the E1 stem is believed to pack. Together the revertants reveal specific and interconnected aspects of the fusion protein refolding reaction.     

Role of spike protein conformational changes in fusion of Semliki Forest virus.

The alphavirus Semliki Forest virus (SFV) and a number of other enveloped animal viruses infect cells via a membrane fusion reaction triggered by the low pH within endocytic vesicles. In addition to having a low pH requirement, SFV fusion and infection are also strictly dependent on the presence of cholesterol in the host cell membrane. A number of conformational changes in the SFV spike protein occur following low-pH treatment, including dissociation of the E1-E2 dimer, conformational changes in the E1 and E2 subunits, and oligomerization of E1 to a homotrimer. To allow the ordering of these events, we have compared the kinetics of these conformational changes with those of fusion, using pH treatment near the fusion threshold and low-temperature incubation to slow the fusion reaction. Dimer dissociation, the E1 conformational change, and E1 trimerization all occur prior to the mixing of virus and cell membranes. Studies of cells incubated at 20 degrees C showed that as with virus fusion, E1 trimerization occurred in the endosome before transport to lysosomes. However, unlike the strictly cholesterol-dependent membrane fusion reaction, the E1 homotrimer was produced in vivo during virus uptake by cholesterol-depleted cells or in vitro by low-pH treatment of virus in the presence of artificial liposomes with or without cholesterol. Purified, lipid-free spike protein rosettes were assayed to determine the requirement for virus membrane cholesterol in E1 homotrimer formation. Spike protein rosettes were found to undergo E1 oligomerization upon exposure to low pH and target liposomes and showed an enhancement of oligomerization with cholesterol-containing membranes. The E1 homotrimer may represent a perfusion complex that requires cholesterol to carry out the final coalescence of the viral and target membranes.     

Membrane and protein interactions of a soluble form of the Semliki Forest virus fusion protein.

Semliki Forest virus is an enveloped alphavirus that infects cells by a membrane fusion reaction triggered by the low pH present in endocytic vacuoles. Fusion is mediated by the E1 spike protein subunit. During fusion, several conformational changes occur in E1 and E2, the two transmembrane subunits of the spike protein. These changes include dissociation of the E1-E2 dimer, alteration of the trypsin sensitivity and monoclonal antibody binding patterns of E1, and formation of a sodium dodecyl sulfate (SDS)-resistant E1 homotrimer. A critical characteristic of Semliki Forest virus fusion is also its dependence on the presence of both cholesterol and sphingomyelin in the target membrane. We have here examined the conformational changes induced by low pH treatment of E1*, the water-soluble, proteolytically truncated ectodomain of the E1 subunit. Following low pH treatment, E1* was shown to bind efficiently to artificial liposomes. Similar to virus fusion, optimal E1*-liposome binding required low pH, cholesterol, and sphingomyelin. The E1 ectodomain, although monomeric in its neutral pH form, assembled into an SDS-resistant oligomer following treatment at low pH. This low pH-induced oligomerization required target membranes containing both cholesterol and sphingomyelin. Our results demonstrate that the E1 ectodomain responds to low pH similarly to the full-length E1 subunit. The ectodomain facilitates the characterization of conformational changes and membrane binding in the absence of virus fusion or other virus components.     

Structure of Semliki Forest virus core protein

Alphaviruses are enveloped, insect-borne viruses, which contain a positive-sense RNA genome. The protein capsid is surrounded by a lipid membrane, which is penetrated by glycoprotein spikes. The structure of the Sindbis virus (SINV) (the type virus) core protein (SCP) was previously determined and found to have a chymotrypsin-like structure. SCP is a serine proteinase which cleaves itself from a polyprotein. Semliki Forest virus (SFV) is among the most distantly related alphaviruses to SINV. Similar to SCP, autocatalysis is inhibited in SFCP after cleavage of the polyprotein by leaving the carboxy-terminal tryptophan in the specificity pocket. The structures of two different crystal forms (I and II) of SFV core protein (SFCP) have been determined to 3.0 Å and 3.3 Å resolution, respectively. The SFCP monomer backbone structure is very similar to that of SCP. The dimeric association between monomers, A and B, found in two different crystal forms of SCP is also present in both crystal forms of SFCP. However, a third monomer, C, occurs in SFCP crystal form I. While monomers A and B make a tail-to-tail dimer contact, monomers B and C make a head-to-head dimer contact. A hydrophobic pocket on the surface of the capsid protein, the proposed site of binding of the E2 glycoprotein, has large conformational differences with respect to SCP and, in contrast to SCP, is found devoid of bound peptide. In particular, Tyr184 is pointing out of the hydrophobic pocket in SFCP, whereas the equivalent tyrosine in SCP is pointing into the pocket. The conformation of Tyr184, found in SFCP, is consistent with its availability for iodination, as observed in the homologous SINV cores. This suggests, by comparison with SCP, that E2 binding to cores causes major conformational changes, including the burial of Tyr184, which would stabilize the intact virus on budding from an infected cell. The head-to-tail contacts found in the pentameric and hexameric associations within the virion utilize the same monomer surface regions as found in the crystalline dimer interfaces. Proteins 27:345–359, 1997. © 1997 Wiley-Liss, Inc.     

Novel mutations that control the sphingolipid and cholesterol dependence of the Semliki Forest virus fusion protein

The enveloped alphavirus Semliki Forest virus (SFV) infects cells via a membrane fusion reaction mediated by the E1 membrane protein. Efficient SFV-membrane fusion requires the presence of cholesterol and sphingolipid in the target membrane. Here we report on two mutants, srf-4 and srf-5, selected for growth in cholesterol-depleted cells. Like the previously isolated srf-3 mutant (E1 proline 226 to serine), the phenotypes of the srf-4 and srf-5 mutants were conferred by single-amino-acid changes in the E1 protein: leucine 44 to phenylalanine and valine 178 to alanine, respectively. Like srf-3, srf-4 and srf-5 show striking increases in the cholesterol independence of growth, infection, membrane fusion, and exit. Unexpectedly, and unlike srf-3, srf-4 and srf-5 showed highly efficient fusion with sphingolipid-free membranes in both lipid- and content-mixing assays. Both srf-4 and srf-5 formed E1 homotrimers of decreased stability compared to the homotrimers of the wild type and the srf-3 mutant. All three srf mutations lie in the same domain of E1, but the srf-4 and srf-5 mutations are spatially separated from srf-3. When expressed together, the three mutations could interact to produce increased sterol independence and to cause temperature-sensitive E1 transport. Thus, the srf-4 and srf-5 mutations identify novel regions of E1 that are distinct from the fusion peptide and srf-3 region and modulate the requirements for both sphingolipid and cholesterol in virus-membrane fusion.     

Visualization of the target-membrane-inserted fusion protein of Semliki Forest virus by combined electron microscopy and crystallography

Semliki Forest virus enters cells by receptor-mediated endocytosis. The acidic environment of the endosome triggers a membrane fusion reaction that is mediated by the E1 glycoprotein. During fusion, E1 rearranges from an E1/E2 heterodimer to a highly stable, membrane-inserted E1 homotrimer (E1HT). In this study, we analyzed E1HT by a combination of electron cryomicroscopy, electron crystallography of negatively stained 2D crystals, and fitting of the available X-ray structure of the monomeric E1 ectodomain into the resulting 3D reconstruction. The visualized E1HT reveals that the ectodomain has reoriented vertically and inserted the distal tip of domain II into the lipid bilayer. Our data allow the visualization of a viral fusion protein inserted in its target membrane and demonstrate that insertion is a cooperative process, resulting in rings composed of five to six homotrimers.     

Mutations in the putative fusion peptide of Semliki Forest virus affect spike protein oligomerization and virus assembly.

The two transmembrane spike protein subunits of Semliki Forest virus (SFV) form a heterodimeric complex in the rough endoplasmic reticulum. This complex is then transported to the plasma membrane, where spike-nucleocapsid binding and virus budding take place. By using an infectious SFV clone, we have characterized the effects of mutations within the putative fusion peptide of the E1 spike subunit on spike protein dimerization and virus assembly. These mutations were previously demonstrated to block spike protein membrane fusion activity (G91D) or cause an acid shift in the pH threshold of fusion (G91A). During infection of BHK cells at 37 degrees C, virus spike proteins containing either mutation were efficiently produced and transported to the plasma membrane, where they associated with the nucleocapsid. However, the assembly of mutant spike proteins into mature virions was severely impaired and a cleaved soluble fragment of E1 was released into the medium. In contrast, incubation of mutant-infected cells at reduced temperature (28 degrees C) dramatically decreased E1 cleavage and permitted assembly of morphologically normal virus particles. Pulse-labeling studies showed that the critical period for 28 degrees C incubation was during virus assembly, not spike protein synthesis. Thus, mutations in the putative fusion peptide of SFV confer a strong and thermoreversible budding defect. The dimerization of the E1 spike protein subunit with E2 was analyzed by using either cells infected with virus mutants or mutant virus particles assembled at 28 degrees C. The altered-assembly phenotype of the G91D and G91A mutants correlated with decreased stability of the E1-E2 dimer.     

A conserved histidine in the ij loop of the Semliki Forest virus E1 protein plays an important role in membrane fusion

The enveloped alphavirus Semliki Forest virus (SFV) infects cells via a low pH-triggered membrane fusion reaction mediated by the E1 protein. E1 is a class II fusion protein that contains the hydrophobic fusion peptide loop and converts to a stable homotrimer during the fusion reaction. Intriguingly, the fusion loop is closely associated with a loop connecting the i and j beta-strands. This ij loop plays a role in the cholesterol dependence of membrane fusion and is specifically susceptible to proteolysis in the protease-resistant E1 homotrimer. The SFV ij loop contains a histidine residue at position 230. Sequence comparisons revealed that an analogous histidine is completely conserved in all alphavirus and flavivirus fusion proteins. An E1 H230A mutant was constructed using the SFV infectious clone. Although cells infected with H230A RNA produced virus particles, these virions were completely noninfectious and were blocked in both cell-cell fusion and lipid mixing assays. The H230A virions efficiently bound to cell surface receptors and responded to low pH by undergoing acid-dependent conformational changes including dissociation of the E1/E2 dimer, exposure of the fusion loop, association with target liposomes, exposure of acid-conformation-specific epitopes, and formation of the stable E1 homotrimer. Studies with a soluble fragment of E1 showed that the mutant protein was defective in lipid-dependent conformational changes. Our results indicate that the E1 ij loop and the conserved H230 residue play a critical role in alphavirus-membrane fusion and suggest the presence of a previously undescribed late intermediate in the fusion reaction.     

Semliki Forest virus induced cell-cell fusion at neutral extracellular pH

Semliki Forest virus-induced cell-cell fusion from within was considered to exclusively occur at mildly acidic pH (<6.2). Data of this study show that such cell fusion can also be triggered by transient acidification of the cytoplasm of infected cells at an extracellular, neutral pH. Results were obtained by utilizing NH₄Cl pulses combined with covalent modification of cell surface proteins. The observation implies a revision of the current consensus regarding the mechanism of Semliki Forest virus induced cell-cell fusion. We propose a model in which at least two peptide segments of the viral spike protein E₁ may be involved in triggering the fusion event.     

Subunit composition of the membrane glycoprotein complex of Semliki Forest virus

The quaternary structure of the membrane glycoproteins E1, E2 and E3 of Semliki Forest virus has been determined in intact virus and in the protein complexes obtained after Triton X100 solubilization. Intact and solubilized virus were treated with a cleavable cross-linking reagent and the covalently cross-linked glycoprotein complexes were isolated and characterized using antibodies specific for the E1 and E2 membrane glycoproteins. The isolation and characterization procedure was done in a low sodium dodecyl sulphate concentration which prevented non-covalent association between glycoprotein species, but did not abolish antigen-antibody binding.The major glycoprotein complex seen after cross-linking of either intact or Triton X100 solubilized virus was an approximately 100,000 molecular weight species composed of E1-E2 heterodimers only. These findings show that E1 and E2 form a complex in the virus and that this complex is retained after solubilization with Triton X100. The smallest membrane glycoprotein E3 was not cross-linked to the other proteins and was therefore lost in the isolation procedure. However, the presence of E3 together with E1 and E2 in complexes obtained after Triton X100 solubilization of intact virus suggests that an E1-E2-E3 trimer is present in the virus. It is likely that this trimer forms the spike-like structures seen on the surface of the virus.We have observed that antibody specific for one component of the virus glycoprotein complex can induce rearrangement of uncross-linked complexes in Triton X100 solubilized form. This fact should be considered when using specific antibody for characterization of protein complexes.     

Solubilization of the Semliki Forest virus membrane with sodium deoxycholate.

The effects of increasing concentrations of sodium deoxycholate on Semliki Forest have been studied. Sodium deoxycholate begins to bind to the virus at less than 0.1 mM free equilibrium concentration and causes lysis of the viral membrane at 0.9 +/- 0.1 mM free equilibrium concentration when 2.2 +/- 0.2 - 103 mol of sodium deoxycholate are bound per mol of virus. Liberation of proteins from the membrane begins at 1.5 +/- 0.1 mM sodium deoxycholate and the proteins released are virtually free from phospholipid above 2.0 mM sodium deoxycholate. The overall mechanism of sodium deoxycholate solubilization of the viral membrane resembles that of Triton X-100 and sodium dodecyl sulphate except that with sodium deoxycholate the various stages of membrane disruption occur at about 10-fold higher equilibrium free detergent concentrations. At sodium deoxycholate concentrations higher than 2.3 mM the viral spike glycoproteins can be separated by sucrose gradient centrifugation or gel filtration into constituent polypeptides E1, E2 and E3. E1 carries the haemagglutinating activity of the virus.