Interaction of Sindbis virus glycoproteins during morphogenesis

Membrane Glycoproteins of Enveloped Viruses

This chapter focuses on the recent information of the glycoprotein components of enveloped viruses and points out specific findings on viral envelopes. Although enveloped viruses of different major groups vary in size and shape, as well as in the molecular weight of their structural polypeptides, there are general similarities in the types of polypeptide components present in virions. The types of structural components found in viral membranes are summarized briefly in the chapter. All the enveloped viruses studied to date possess one or more glycoprotein species and lipid as a major structural component. The presence of carbohydrate covalently linked to proteins is demonstrated by the incorporation of a radioactive precursor, such as glucosamine or fucose, into viral polypeptides, which is resolved by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis. Enveloped viruses share many common features in the organization of their structural components, as indicated by several approaches, including electron microscopy, surface-labeling, and proteolytic digestion experiments, and the isolation of subviral components. The chapter summarizes the detailed structure of the glycoproteins of four virus groups: (1) influenza virus glycoproteins, (2) rhabdovirus G protein, (3) togavirus glycoprotein, and (4) paramyxovirus glycoproteins The information obtained includes the size and shape of viral glycoproteins, the number of polypeptide chains in the complete glycoprotein structure, and compositional data on the polypeptide and oligosaccharide portions of the molecules.

Inhibition of the membrane fusion machinery prevents exit from the TGN and proteolytic processing by furin

The Semliki Forest virus (SFV) glycoprotein precursor p62 is processed to the E2 and E3 during the transport from the trans-Golgi network (TGN) to the cell surface. We have studied the regulation of the membrane fusion machinery (Rab/N-ethylmaleimide (NEM)-sensitive fusion protein (NSF)/soluble NSF attachment protein (SNAP)-SNAP receptor) in this processing. Activation of the disassembly of this complex with recombinant NSF stimulated the cleavage of p62 in permeabilized cells. Inactivation of NSF with a mutant alpha-SNAP(L294A) or NEM treatment inhibited processing of p62. Rab GDP dissociation inhibitor inhibited the cleavage. Inactivation of NSF blocks the transport of SFV glycoproteins and vesicular stomatitis virus G-glycoprotein from the TGN membranes to the cell surface. The results support the conclusion that inhibition of membrane fusion arrests p62 in the TGN and prevents its processing by furin.

The formation of intramolecular disulfide bridges is required for induction of the Sindbis virus mutant ts23 phenotype

The Sindbis virus envelope protein spike is a hetero-oligomeric complex composed of a trimer of glycoprotein E1-E2 heterodimers. Spike assembly is a multistep process which occurs in the endoplasmic reticulum (ER) and is required for the export of E1 from the ER. PE2 (precursor to E2), however, can transit through the secretory pathway and be expressed at the cell surface in the absence of E1. Although oligomer formation does not appear to be required for the export of PE2, there is evidence that defects in E1 folding can affect PE2 transit from the ER. Temperature-sensitive mutant ts23 of Sindbis virus contains two amino acid substitutions in E1, while PE2 and capsid protein have the wild-type sequence; however, at the nonpermissive temperature, both E1 and PE2 are retained within the ER and can be isolated in protein aggregates with the molecular chaperone GRP78-BiP. We previously demonstrated that the temperature sensitivity for ts23 was lost as oligomer formation took place at the permissive temperature, suggesting that temperature sensitivity is initiated early in the process of viral spike assembly (M. Carleton and D. T. Brown, J. Virol. 70:952-959, 1996). Experiments described herein investigated the defects in envelope protein maturation that occur in ts23-infected cells and which result in retention of both envelope proteins in the ER. The data demonstrate that in ts23-infected cells incubated at the nonpermissive temperature, E1 folding is disrupted early after synthesis, resulting in the rapid incorporation of both E1 and PE2 into disulfide-stabilized aggregates. Furthermore, the aberrant E1 conformation which is responsible for induction of the ts phenotype requires the formation of intramolecular disulfide bridges formed prior to E1 association with PE2 and the completion of E1 folding.

Communication of post-Golgi elements with early endocytic pathway: regulation of endoproteolytic cleavage of Semliki Forest virus p62 precursor

A number of cellular proteins and viral spike proteins are cleaved at a basic recognition sequence. To characterize the membrane traffic step at which this proteolysis occurs we have studied the intracellular processing site of Semliki Forest virus (SFV) spike precursor p62 in BHK21 cells. The p62 is endoproteolytically cleaved at a tetrabasic Arg-His-Arg-Arg recognition sequence. Previously, it has been shown that the SFV p62 remains uncleaved when accumulated to the trans-Golgi network (TGN/20 degrees C block site). We show here that exit from the trans-Golgi is required for the cleavage of p62. Proteolytic processing was inhibited in synchronized assays when the 20 degrees C transport block was released in the presence of brefeldin A, energy inhibitors (azide and deoxyglucose; carbonyl cyanide m-chlorophenylhydrazone, CCCP) or an effector of trimeric G proteins, AlFn. Endocytosed antibodies against the SFV spike glycoproteins or antibodies against a peptide corresponding to the enzymatically active motif of furin inhibited cleavage of p62 at a post-TGN location. The results indicate a post-TGN communication step between exocytic and endocytic elements. Kinetic experiments suggested that this communication may involve an early compartment of the endocytic pathway.

The alphaviruses: gene expression, replication, and evolution

The alphaviruses are a genus of 26 enveloped viruses that cause disease in humans and domestic animals. Mosquitoes or other hematophagous arthropods serve as vectors for these viruses. The complete sequences of the +/- 11.7-kb plus-strand RNA genomes of eight alphaviruses have been determined, and partial sequences are known for several others; this has made possible evolutionary comparisons between different alphaviruses as well as comparisons of this group of viruses with other animal and plant viruses. Full-length cDNA clones from which infectious RNA can be recovered have been constructed for four alphaviruses; these clones have facilitated many molecular genetic studies as well as the development of these viruses as expression vectors. From these and studies involving biochemical approaches, many details of the replication cycle of the alphaviruses are known. The interactions of the viruses with host cells and host organisms have been exclusively studied, and the molecular basis of virulence and recovery from viral infection have been addressed in a large number of recent papers. The structure of the viruses has been determined to about 2.5 nm, making them the best-characterized enveloped virus to date. Because of the wealth of data that has appeared, these viruses represent a well-characterized system that tell us much about the evolution of RNA viruses, their replication, and their interactions with their hosts. This review summarizes our current knowledge of this group of viruses.

The alphaviruses: gene expression, replication, and evolution

The alphaviruses are a genus of 26 enveloped viruses that cause disease in humans and domestic animals. Mosquitoes or other hematophagous arthropods serve as vectors for these viruses. The complete sequences of the +/- 11.7-kb plus-strand RNA genomes of eight alphaviruses have been determined, and partial sequences are known for several others; this has made possible evolutionary comparisons between different alphaviruses as well as comparisons of this group of viruses with other animal and plant viruses. Full-length cDNA clones from which infectious RNA can be recovered have been constructed for four alphaviruses; these clones have facilitated many molecular genetic studies as well as the development of these viruses as expression vectors. From these and studies involving biochemical approaches, many details of the replication cycle of the alphaviruses are known. The interactions of the viruses with host cells and host organisms have been exclusively studied, and the molecular basis of virulence and recovery from viral infection have been addressed in a large number of recent papers. The structure of the viruses has been determined to about 2.5 nm, making them the best-characterized enveloped virus to date. Because of the wealth of data that has appeared, these viruses represent a well-characterized system that tell us much about the evolution of RNA viruses, their replication, and their interactions with their hosts. This review summarizes our current knowledge of this group of viruses.

Protein-protein interactions in an alphavirus membrane

Using homobifunctional chemical cross-linkers with various span distances, we have determined the near-neighbor associations and planar organization of the E1 and E2 envelope glycoproteins which compose the icosahedral surface of Sindbis virus. We have found that E1-E2 heterodimers, which form the virus protomeric units, exist in two conformationally distinct forms, reflecting their nonequivalent positions in the icosahedron. Three of these heterodimers form the trimeric morphologic units (capsomeres) which are held together by central E1-E1 interactions. In addition, we present data which suggest that E2-E2 interactions organize the capsomeres into pentameric and hexameric geometric units and that E1-E1 interactions between capsomeres maintain the icosahedral lattice in mature virions.

Mechanism of altered Sindbis virus neurovirulence associated with a single-amino-acid change in the E2 Glycoprotein

The mechanism by which amino acid changes in the E1 and E2 surface glycoproteins of Sindbis virus affect neurovirulence is unknown. We have studied two recombinant viruses which differ in virulence. One (TE) contains Gly and the other (TES) contains Arg at position 172 in E2. TE causes more rapid death than TES in newborn mice. Both viruses replicate similarly in nonneuronal cells, but TE replicates more rapidly in the brains of newborn mice and in neuroblastoma cells. TE also induces earlier viral RNA synthesis in neuroblastoma cells. 35S-labeled TE binds more efficiently to brain and neuroblastoma cells, but not to nonneuronal cells, than TES. We propose that a region of the E2 glycoprotein affected by the amino acid occupying position 172 is important for binding to an alphavirus receptor on neurons and influences neurovirulence by this mechanism.

The heterodimeric association between the membrane proteins of Semliki Forest virus changes its sensitivity to low pH during virus maturation

The budding and the fusion processes of the enveloped animal virus Semliki Forest virus serve the purpose of transporting its nucleocapsid, containing its genome, from the cytoplasm of an infected cell into that of an uninfected one. We show here that, in the infected cell, the viral membrane (spike) proteins p62 and E1 are organized as heterodimers which are very resistant to dissociation in acidic conditions. In contrast, the mature form of the heterodimer, E2E1, which is found in the virus particle and which is generated by proteolytic processing of p62, is very prone to dissociate upon treatment with mildly acidic buffers. We discuss the possibility that this difference in behavior of the intracellular precursor form and the mature form of the spike protein complex represents an important regulatory mechanism for the processes involving membrane binding around the nucleocapsid during budding and membrane release from the nucleocapsid at the stage of virus fusion.

The role of monovalent cation transport in Sindbis virus maturation and release

Alterations in intracellular monovalent cation concentrations in Sindbis virus-infected avian cells result, in part, from a reduction in Na+/K+ ATPase (Na+ pump) activity. Inhibition of Na+ pump activity was shown previously to temporally correlate with the appearance of viral envelope proteins on the cell surface and the release of virus particles. Cells infected with envelope-defective temperature-sensitive mutants exhibited reduced Na+ pump activity at the nonpermissive temperature, where viral particles are not released. By contrast, Na+ pump activity was not inhibited in Sindbis virus-infected cells treated with tunicamycin or with antiviral serum, which block virus maturation and release. Diuretic-sensitive transport of 86Rb+, aK+ tracer, was stimulated in cells which express virus envelope proteins, but fail to release virus particles. In these cells, the furosemide-sensitive 86Rb+ influx exhibited an increase in Vmax and was responsive to changes in the extracellular concentration of NaCl. Furosemide inhibited the rapid release of virus from low salt-inhibited cells after shift to isotonic conditions. Alterations in ion transport during alphavirus infection may, therefore, facilitate the efficient release of progeny virus particles.

Intracellular transport and processing of Sindbis virus glycoproteins

The intracellular transport and processing of Sindbis virus envelope glycoproteins were studied in cells infected with Sindbis virus using the mannose-specific enzyme, endoglycosidase H (endo H). In pulse/chase labeling experiments of hamster cells with [35S]methionine, Sindbis glycoproteins PE2 and E1 became endo H resistant in two steps at 12.5 and 20.0 min after a 5-min pulse, suggesting that the glycoproteins required this period of time to be transported to the Golgi compartments containing the enzymes which process the high mannose side chains acquired in the endoplasmic reticulum. E2 could be detected at the end of a 5-min pulse and the E2 produced early was found to be endo H sensitive. The rate at which PE2 was converted to E2, relative to the acquisition of endo H resistance, suggests the independence of this proteolytic event from cellular protein transport and raises the possibility that the proteolytic function is of viral origin.

The proteolytic cleavage of PE2 to envelope glycoprotein E2 is not strictly required for the maturation of Sindbis virus

The ionophore monensin has been shown previously to block the maturation of Sindbis virus as well as prevent the cleavage of pE2 to E2 when applied to cells in high concentration. We found that a moderate dose of monensin reduced virus titer and inhibited the cleavage of pE2 to E2. Under these conditions, pE2 appeared on the cell surface in a form susceptible to lactoperoxidase-mediated iodination. This pE2 was incorporated into virions, replacing E2. PE2-containing virions had a normal PFU-to-particle ratio, cosedimented with normal virus, and retained a normal morphology when negatively stained preparations were examined by electron microscopy. We conclude that the cleavage of pE2 to form E2 is not an absolute prerequisite for virus maturation. Recently, Russell et al. have reached a similar conclusion (D. L. Russell, J. M. Dalrymple, and R. E. Johnston, J. Virol. 63:1619-1629, 1989).

Sindbis virus mutations which coordinately affect glycoprotein processing, penetration, and virulence in mice

Rapid penetration of baby hamster kidney cells was used as a selective pressure for the isolation of pathogenesis mutants of the S.A.AR86 strain of Sindbis virus. Unlike most Sindbis virus strains, S.A.AR86 is virulent in adult as well as neonatal mice. Two classes of mutants were defined. One class was attenuated in adult mice inoculated intracerebrally as well as in neonatal mice inoculated either intracerebrally or subcutaneously. Sequence analysis of the glycoprotein genes of the parent virus and three such mutant strains revealed a single point mutation which resulted in an amino acid change at position 1 in the E2 glycoprotein. The change from a serine in S.A.AR86 to an asparagine in the mutants created a new site for N-linked glycosylation which appeared to be utilized. This mutation did not retard release of infectious particles; however, mutant virions contained the E2 precursor protein (PE2) rather than the E2 glycoprotein itself. The mutants also lost the ability to bind two E2-specific monoclonal antibodies, R6 and R13. A second class of mutants was attenuated in neonatal mice upon subcutaneous inoculation but remained virulent in adults and in neonates when inoculated intracerebrally. Sequence analysis of three such strains revealed the substitution of an arginine residue for a serine at position 114 in the E2 glycoprotein. Reactivity with monoclonal antibodies R6 and R13 was reduced, yet members of this mutant class were more susceptible than S.A.AR86 to neutralization by these antibodies.

Effect of tunicamycin on the development of the cytopathic effect in Sindbis virus-infected avian fibroblasts

In Sindbis virus-infected avian cells the development of the cytopathic effect is correlated with the disruption of plasma membrane function. Sindbis virus inhibits the activity of the Na+K+ATPase, a membrane-associated enzyme complex which regulates intracellular monovalent cation levels. Tunicamycin, which blocks envelope protein glycosylation, prevents inhibition of Na+K+ATPase activity and the development of morphological changes in Sindbis virus-infected cells. Although inhibition of Na+K+ATPase activity is not essential for the termination of host protein synthesis, membrane-mediated events may favor the selective translation of viral proteins. The termination of host protein synthesis does not contribute to the development of these cytopathic changes in the time frame examined. In tunicamycin-treated, Sindbis virus-infected cells, unglycosylated E1 is inserted into the plasma membrane but virus release is prevented. In productively infected cells, therefore, the inhibition of Na+K+ATPase activity and the development of the cytopathic effect may result from terminal events in virus assembly and/or virus release.

A mutant of sindbis virus with a host-dependent defect in maturation associated with hyperglycosylation of E2

Following serial passage of Sindbis virus (SV) on Aedes albopictus mosquito cells a mutant (SVap15/21) was isolated which in chick cells produced small plaques and was temperature sensitive (ts). At 34.5 degrees this mutant replicated normally in mosquito cells, but only poorly in chick or BHK cells. In the vertebrate cells SVap15/21 was RNA+ at both 34.5 and 40 degrees and on the basis of complementation tests carried out at 40 degrees, was assigned to complementation group E. The block in the replication of this mutant, like that of ts20, the prototype mutant of complementation group E, was at the level of nucleocapsid envelopment. The PE2 and E2 glycoproteins of SVap15/21 were found to be hyperglycosylated relative to the corresponding glycoproteins of the parent virus (SVstd). Analysis of revertants of SVap15/21 suggests a causal relationship between PE2 and E2 hyperglycosylation and the host-specific defect in virus maturation. The association of a host-specific defect in virion assembly with hyperglycosylation of a viral structural protein points to the potential importance of host-specific glycosylation patterns in the determination of viral host range.

Biochemical studies of the maturation of the small Sindbis virus glycoprotein E3

A small glycoprotein (E3) was purified from the culture fluid of Sindbis virus-infected primary chick embryo fibroblasts. Tryptic peptide mapping and pulse-chase studies verified that this protein was produced as a by-product of the cleavage of the precursor protein PE2 to produce the envelope glycoprotein E2. A 2600-fold purification was achieved via a procedure which used differential ethanol precipitation, gel filtration, ion-exchange chromatography, and affinity chromatography on a lentil lectin column. Amino acid composition analysis, N-terminal microsequencing, and labeling studies yielded information about the fine structure of E3 and its relationship to E2 and virion maturation. The N-terminal sequence of E3 is identical to that of PE2, including the result that 90% of the molecules appear to be blocked. The first 19 amino acids are uncharged and presumably serve as the signal sequence for the insertion of PE2 into the membrane of the endoplasmic reticulum, but this sequence is unusual in that it is not immediately cleaved from PE2 and is glycosylated at the asparagine at position 14. The two residues at the C-terminus of E3, Lys-Arg, are removed during or shortly after cleavage from PE2. Labeling studies imply that, although the PE2----E2 + E3 cleavage is necessary for virion budding, these two events are not closely coupled. E3 is cleaved and released into the culture fluid under conditions where virions do not bud, and the kinetics of the appearance of E3 in the culture fluid and E2 in virions are quite dissimilar. The maturation of E3 is discussed as it relates to the processing of cellular membrane and secretory glycoproteins.

Semliki Forest virus: a probe for membrane traffic in the animal cell

The traffic among the cellular compartments is thought to be mediated by membrane vesicles, which bud from one compartment and fuse with the next. Despite the continuous exchange of membrane components among them, the organelles maintain their characteristic protein and lipid compositions such that the traffic remains selective, thus, avoiding intermixing of components. This membrane traffic recycles components from the cell surface to the interior of the cell and back to the cell surface again. The membrane traffic between the ER and the cell surface involves a major sorting problem. Little is known of how the animal cell has solved this problem in molecular terms. One experimental tool in this direction is provided by some enveloped animal viruses, which mature at the cell surface of infected cells. Such viruses include influenza virus, Semliki Forest virus (SFV), Sindbis virus, and vesicular stomatitis virus (VSV). They are extremely simple in makeup and hence are very well characterized. The purpose of this article is to illustrate the use of the enveloped viruses as tools in the study of membrane traffic in the animal cell. This is done in the context of the life cycle of the virus in the host cell. The article will be concerned mainly with Semliki Forest virus (SFV), which is the virus that has been worked upon in the chapter. SFV belongs to the alphaviruses, a genus of the togavirus family.

Sequence analysis of two mutants of Sindbis virus defective in the intracellular transport of their glycoproteins

We have sequenced the complementary DNA corresponding to the genes encoding the viral glycoproteins of ts10 and ts23, mutants of Sindbis virus defective in the intracellular transport of their glycoproteins, and of revertants of these mutants. These studies have been augmented by direct amino acid sequencing of the amino-terminal regions of the glycoproteins of several virus strains. By comparing the deduced amino acid sequence with that of Sindbis HR virus, the parental strain of these mutants, and with the sequence of the revertants, we found ts23 to have a double mutation in glycoprotein E1, while ts10 was a single mutant in the same glycoprotein. In each case reversion to temperature insensitivity occurred by changes at the same site as the mutation, in two cases restoring the original amino acid and in the third case substituting an homologous amino acid (arginine in place of lysine). The three mutations were far apart from each other in the protein, suggesting that the three-dimensional conformation is very important for the correct migration of the glycoproteins from the rough endoplasmic reticulum to the plasma membrane. The sequence data also reveal that a number of other changes have occurred in the various virus strains during mutagenesis or passage.

Cross-reactive, cell-associated antigen on L929 cells infected with temperature-sensitive mutants of sindbis virus

Temperature-sensitive (ts) mutants of Sindbis virus (SIN) were used to aid in the identification of alphavirus cross-reactive proteins on the surface of infected cells by antibody-dependent, complement-mediated cytolysis. Antisera prepared in rabbits against purified SIN or Semliki Forest viruses were highly cytotoxic for cells infected with wild-type SIN and for cells infected at the permissive temperature with maturation-defective, ts mutants of SIN belonging to several distinct complementation groups. When these SIN mutants were analyzed by antibody-dependent, complement-mediated cytolysis at the restrictive temperature only cells infected with the SIN mutant of complementation group E, ts20, participated in both homologous (with anti-SIN serum) and heterologous (with anti-Semliki Forest virus serum) antibody-dependent, complement-mediated cytolysis reactions. These data and the known defect of ts20 suggested that the cell-associated viral E1 glycoprotein was a functional target antigen for homologous and cross-immunoreactivity in alphavirus-infected cells. At the restrictive temperature there were quantitative differences in antibody-dependent, complement-mediated cytolysis reactivity of ts20- versus wild type-infected cells consistent with the suggestion that ts20-infected cells do not fully express all of the homologous or the cross-reactive antigenic determinants found in wild-type infection. Additional potential sites for antigenic determinants involved in alphavirus-immune cross-reactivity are discussed in relation to events in virus maturation.

Comparison of specific and cross-reactive antigens of alphaviruses on virions and infected cells

Rabbit hyperimmune antisera against Sindbis (SIN) or Semliki Forest (SF) virus were absorbed with purified SIN virus or SIN virus-infected cells, or with SF virus or SF virus-infected cells. Residual antibody titers were determined by hemagglutination inhibition (HAI) and antibody-dependent, complement-mediated cytolysis (ADCMC) assays. It appeared that absorption with virus-infected cells removed ADCMC-detectable cross-reactive antibody much more efficiently than did absorption with either virus. HAI assays with the same absorbed antisera indicated that both virus and virus-infected cells removed HAI-detectable cross-reactive antibody. On the basis of these and other data, there appeared to be a cross-reactive antigen present on virus-infected cells which was detectable by ADCMC and was distinct from the cross-reactive antigen assayed by HAI.

Evidence for a separate signal sequence for the carboxy-terminal envelope glycoprotein E1 of Semliki forest virus

When Semliki Forest virus temperature-sensitive mutant ts-3 was grown at the restrictive temperature an aberrant nascent cleavage of the 130,000-dalton structural polyprotein took place relatively frequently. This cleavage yielded an abnormal 86,000-dalton fusion protein (p86) consisting of the amino-terminal capsid protein linked to the amino acid sequences of envelope protein p62 (a precursor of E3 and E2). The other cleavage product was the carboxy-terminal envelope protein E1. p86 was not glycosylated and was sensitive to the action of protease in the microsomal fraction, whereas E1 was glycosylated and protected from proteases, indicating that it had been segregated into the cysternal side of the microsomal vesicles. All attempts to show the E1 protein at the cell surface have failed so far, suggesting that it remains associated with intracellular membranes. When ts-3-infected cells labeled at the restrictive temperature were shifted to the permissive temperature the only labeled protein released with the virus particles was E1, indicating that E1, synthesized at the restrictive temperature, was competent to participate in the virus assembly. These results suggest strongly that there are two separate signal sequences for the envelope proteins of Semliki Forest virus. One follows the capsid protein as shown previously, and the other is for the carboxy-terminal E1. Even if the insertion of the amino-terminal envelope protein (p62) fails due to a cleavage defect, the other signal sequence can operate independently to guide the E1 through the endoplasmic reticulum membrane.

Fluorescence photobleaching recovery measurements reveal differences in envelopment of Sindbis and vesicular stomatitis viruses

Fluorescence photobleaching recovery (FPR) measurements of virus glycoproteins on the surfaces of cells infected with vesicular stomatitis virus (VSV) and Sindbis virus showed that the VSV glycoprotein (G) remained mobile throughout the infectious cycle, whereas Sindbis virus glycoproteins (E1, E2) were partially mobile early after infection and immobile at later times when greater amounts of these proteins were on the cell surface. A highly mobile fraction of Sindbis virus glycoproteins was detected throughout the replication cycle of a temperature-sensitive mutant unable to form virus particles. This immobilization of E1 and E2 was the result of increasing surface glycoprotein concentrations and virus budding. Together with other data, which included the detection of E1 and E2 in particles as soon as these proteins were transported to the cell surface, the FPR results suggest that Sindbis virus assembly initiates on intracellular vesicles, where glycoproteins aggregate and bind nucleocapsids. In contrast, our FPR data on VSV support a model previously suggested by others, in which a small fraction of cell-surface G is immobilized into budding sites formed by interactions with virus matrix and nucleoproteins. FPR measurements also provide direct evidence for strong interactions between E1 and E2, as well as between E1 and PE2, the precursor form of E2.

Distribution of virus structural proteins and protein-protein interactions in plasma membrane of baby hamster kidney cells infected with Sindbis or vesicular stomatitis virus

The plasma membrane of baby hamster kidney (BHK-21) cells infected with either Sindbis or vesicular stomatitis virus was isolated by a technique involving the ingestion of latex beads by the cells. Plasma membrane isolated from Sindbis virus-infected cells contained only one (E1) of the three (E1, E2, and C) structural proteins of this virus. When the latex beads were pretreated with either polylysine or DEAE-dextran, plasma membrane obtained from Sindbis virus-infected cells contained all three structural proteins and PE2, a precursor to one of the structural proteins. In pulse-chase radiolabeling experiments with Sindbis virus-infected cells, it was possible to follow the appearance of the precursor protein (PE2) i the plasma membrane and its eventual conversion to E2. The appearance of Sindbis virus membrane proteins PE2 and E1 in the purified plasma membrane was not affected by the drug tunicamycin, an inhibitor of glycosylation. These experiments imply the following: (i) Cleavage of the Sindbis virus precursor polypeptide PE2 to E2 is not a prerequisite for its transport to the cell plasma membrane; (ii) transport of virus membrane proteins to the cell surface does not depend on glycosylation; and (iii) although all Sindbis virus structural proteins are associated with the plasma membrane, a generally accepted pairing of PE2-E1 or E2-E1 in the plasma membrane either does not exist or, if it does exist, involves a very weak interaction. The procedures used in this study also resulted in the successful isolation of plasma membrane from vesicular stomatitis virus-infected cells containing the glycoprotein, the matrix protein, and the nucleocapsid protein, a result that suggests that these proteins are located on the media side of baby hamster kidney cells grown in monolayer.

Intracellular distribution of Sindbis virus membrane proteins in BHK-21 cells infected with wild-type virus and maturation-defective mutants

The association of Sindbis virus proteins with cellular membranes during virus maturation was examined by utilizing a technique for fractionating the membranes of BHK-21 cells into three subcellular classes, which were enriched for rough endoplasmic reticulum, smooth endoplasmic reticulum, and plasma membrane. Pulse-chase experiments with wild-type (strain SVHR) virus-infected cells showed that virus envelope proteins were incorporated initially into membranes of the rough endoplasmic reticulum and subsequently migrated to the smooth and plasma membrane fractions. Large amounts of capsid protein were associated with the plasma membrane fraction even at the earliest times postpulse, and relatively little was found associated with the other membranes, suggesting a rapid and preferential association of nucleocapsids with the plasma membrane. We also examined the intracellular processing of the proteins of two temperature-sensitive Sindbis virus mutants in pulse-chase experiments at the nonpermissive temperature. Labeled virus proteins of mutant ts-20 (complementation group E) first appeared in the rough endoplasmic reticulum and were then transported to the smooth and plasma membrane fractions, as in wild-type (strain SVHR) virus-infected cells. In cells infected with ts-23 (complementation group D), the pulse-labeled virus proteins appeared initially in the rough membrane fraction and were transported to the smooth membrane fraction, but only limited amounts reached the plasma membrane. Thus, in ts-23-infected cells, the transport of the virus-encoded proteins from the smooth membranes seemed to be defective. In both ts-20- and ts-23-infected cells the envelope precursor polypeptide PE2 was not processed to E2, and no label was incorporated into free virus at the nonpermissive temperature.

Monensin and FCCP inhibit the intracellular transport of alphavirus membrane glycoproteins

Temperature-sensitive mutants of semliki forest virus (SFV) and sindbis virus (SIN) were used to study the intracellular transport of virus membrane glycoproteins in infected chicken embryo fibroblasts. When antisera against purified glycoproteins and (125)I- labeled protein A from staphylococcus aureus were used only small amounts of virus glycoproteins were detected at the surface of SFV ts-1 and SIN Ts-10 infected cells incubated at the restrictive temperature (39 degrees C). When the mutant-infected cells were shifted to the permissive temperature (28 degrees C), in the presence of cycloheximide, increasing amounts of virus glycoproteins appeared at the cell surface from 20 to 80 min after the shift. Both monensin (10muM) and carbonylcyanide-p- trifluoromethoxyphenylhydrazone (FCCP; 10-20 muM) inhibited the appearance of virus membrane glycoproteins at the cell surface. Vinblastine sulfate (10 mug/ml) inhibited the transport by approximately 50 percent, whereas cytochalasin B (1 mug/ml) had only a marginal effect. Intracellular distribution of virus glycoproteins in the mutant-infected cells was visualized in double-fluorescence studies using lectins as markers for endoplasmic reticulum and Golgi apparatus. At 39 degrees C, the virus membrane glycoproteins were located at the endoplasmic reticulum, whereas after shift to 28 degrees C, a bright juxtanuclear reticular fluorescence was seen in the location of the Golgi apparatus. In the presence of monensin, the virus glycoproteins could migrate to the Golgi apparatus, although transport to the cell surface did not take place. When the shift was carried out in the presence of FCCP, negligible fluorescence was seen in the Golgi apparatus and the glycoproteins apparently remained in the rough endoplasmic reticulum. A rapid inhibition in the accumulation of virus glycoproteins at the cell surface was obtained when FCCP was added during the active transport period, whereas with monensin there was a delay of approximately 10 min. These results suggest a similar intracellular pathway in the maturation of both plasma membrane and secretory glycoproteins.

Effect of low-NaCl medium on the envelope glycoproteins of Sindbis virus

Lowering the NaCl concentration of the medium inhibits the release of Sindbis virus from infected chicks cells at a stage after the nucleocapsids have bound to the membranes of the infected cells. The failure of trypsin treatment to release the inhibited virus and the ratio of the proteins in the inhibited cells make it seem likely that the inhibited virus is all intracellular. Experiments using antisera specific for E1 and E2, the envelope glycoproteins of Sindbis, suggest that the inhibitory effect of low-salt medium is mediated through an effect on E2. Lactoperoxidase radioiodination experiments indicate that, even when cleaved from PE2, E2 is not exposed on the surface of low-NaCl-treated chick cells.

Virus-directed post-translational cleavage in Sindbus virus-infected cells

The viral polypeptides synthesized in cells coinfected with group C and group D or E Sindbis virus mutants were studied. Cleavage of the ts2 protein occurs in cells coinfected with ts2 and ts20. Since the ts2 protein fails to chase in cells infected with ts2 alone, the activity effecting this cleavage must be, at least in part, virus specified.

Envelope antigens of Sindbis virus in cells infected with temperature-sensitive mutants

Indirect fluorescent-antibody studies of living and fixed chick cells infected with temperature-sensitive mutants of Sindbis virus suggest that functional envelope glycoprotein E1 must be inserted through the plasma membrane before E2. PE2 and E2 do not affect the insertion of E1. The experiments also suggest that normal PE2, a glycosylated precursor to E2, reacts with anti-E2 serum; the abnormal PE2 made by a temperature-sensitive PE2 cleavage-defective mutant did not. Abnormal E1 proteins made by E1-defective mutants also failed to react with anti-E1 serum.