Structure and assembly of alphaviruses

Mechanism of function of viral channel proteins and implications for drug development

Viral channel-forming proteins comprise a class of viral proteins which, similar to their host companions, are made to alter electrochemical or substrate gradients across lipid membranes. These proteins are active during all stages of the cellular life cycle of viruses. An increasing number of proteins are identified as channel proteins, but the precise role in the viral life cycle is yet unknown for the majority of them. This review presents an overview about these proteins with an emphasis on those with available structural information. A concept is introduced which aligns the transmembrane domains of viral channel proteins with those of host channels and toxins to give insights into the mechanism of function of the viral proteins from potential sequence identities. A summary of to date investigations on drugs targeting these proteins is given and discussed in respect of their mode of action in vivo.

The first step: activation of the Semliki Forest virus spike protein precursor causes a localized conformational change in the trimeric spike

The structure of the particle formed by the SFVmSQL mutant of Semliki Forest virus (SFV) has been defined by cryo-electron microscopy and image reconstruction to a resolution of 21 A. The SQL mutation blocks the cleavage of p62, the precursor of the spike proteins E2 and E3, which normally occurs in the trans-Golgi. The uncleaved spike protein is insensitive to the low pH treatment that triggers membrane fusion during entry of the wild-type virus. The conformation of the spike in the SFVmSQL particle should correspond to that of the inactive precursor found in the early stages of the secretory pathway. Comparison of this "precursor" structure with that of the mature, wild-type, virus allows visualization of the changes that lead to activation, the first step in the pathway toward fusion. We find that the conformational change in the spike is dramatic but localized. The projecting domains of the spikes are completely separated in the precursor and close to generate a cavity in the mature spike. E1, the fusion peptide-bearing protein, interacts only with the p62 in its own third of the trimer before cleavage and then collapses to form a trimer of heterotrimers (E1E2E3)3 surrounding the cavity, poised for the pH-induced conformational change that leads to fusion. The capsid, transmembrane regions and the spike skirts (thin layers of protein that link spikes above the membrane) remain unchanged by cleavage. Similarly, the interactions of the spikes with the nucleocapsid through the transmembrane domains remain constant. Hence, the interactions that lead to virus assembly are unaffected by the SFVmSQL mutation.

Characterization of an endoplasmic reticulum retention signal in the rubella virus E1 glycoprotein

Rubella virus contains three structural proteins, capsid, E2, and E1. E2 and E1 are type I membrane glycoproteins that form a heterodimer in the endoplasmic reticulum (ER) before they are transported to and retained in the Golgi complex, where virus assembly occurs. The bulk of unassembled E2 and E1 subunits are not transported to the Golgi complex. We have recently shown that E2 contains a Golgi-targeting signal that mediates retention of the E2-E1 complex (T. C. Hobman, L. Woodward, and M. G. Farquhar, Mol. Biol. Cell 6:7-20, 1995). The focus of this study was to determine if E1 glycoprotein also contains intracellular targeting information. We constructed a series of chimeric reporter proteins by fusing domains from E1 to the ectodomains of two other type I membrane proteins which are normally transported to the cell surface, vesicular stomatitis virus G protein (G) and CD8. Fusion of the E1 transmembrane and cytoplasmic regions, but not analogous domains from two control membrane proteins, to the ectodomains of G and CD8 proteins caused the resulting chimeras to be retained in the ER. Association of the ER-retained chimeras with known ER chaperone proteins was not detected. ER localization required both the transmembrane and cytoplasmic regions of E1, since neither of these domains alone was sufficient to retain the reporter proteins. Increasing the length of the E1 cytoplasmic domain by 10 amino acids completely abrogated ER retention. This finding also indicated that the chimeras were not retained as a result of misfolding. In summary, we have identified a new type of ER retention signal that may function to prevent unassembled E1 subunits and/or immature E2-E1 dimers from reaching the Golgi complex, where they could interfere with viral assembly. Accordingly, assembly of E2 and E1 would mask the signal, thereby allowing transport of the heterodimer from the ER.

Preformed cytoplasmic nucleocapsids are not necessary for alphavirus budding

According to the present model for assembly of alphaviruses, e.g. Semliki Forest virus (SFV), the viral genome is first encapsidated into a nucleocapsid (NC) in cytoplasm and this is then used for budding at plasma membrane (PM). The preformed NC is thought to act as a template on which the viral envelope can be organized. In the present work we have characterized two SFV deletion mutants which did not assemble NCs in the cytoplasm but which instead appeared to form NCs at the PM simultaneously with virus budding. The deletions were introduced in a conserved 14 residue long linker peptide that joins the amino-terminal RNA-binding domain with the carboxy-terminal serine-protease domain of the capsid protein. Despite the deletions and the change in morphogenesis, wild-type (wt)-like particles were produced with almost wt efficiency. It is suggested that the NC assembly defect of the mutants is rescued through spike-capsid interactions at PM. The results show that the preassembly of NCs in the cytoplasm is not a prerequisite for alphavirus budding. The apparent similarities of the morphogenesis pathways of wt and mutant SFV with those of type D and type C retroviruses are discussed.

Glycoproteins E2 of the Venezuelan and eastern equine encephalomyelitis viruses contain multiple cross-reactive epitopes

Enzyme immunoassay (EIA) with sixty types of monoclonal antibodies (MAbs) was used to study cross-reactive epitopes on the attenuated and virulent strains of the Eastern equine encephalomyelitis (EEE) and Venezuelan equine encephalomyelitis (VEE) viruses. All three structural proteins of the EEE and VEE viruses were demonstrated to have both cross-reactive and specific antigenic determinants. The glycoprotein E1 of EEE and VEE viruses possesses three cross-reactive epitopes for binding to MAbs. The glycoprotein E2 has a cluster of epitopes for 20 cross-reacting MAbs produced to EEE and VEE viruses. Cross-reactive epitopes were localised within five different sites of glycoprotein E2 of VEE virus and within four sites of that of the EEE virus. There are no cross-neutralising MAbs to the VEE and EEE viruses. Only one type of the protective Mabs was able to cross-protect mice against lethal infection by the virulent strains of the VEE and EEE viruses. Eight MAbs blocked the hemagglutination activity (HA) of both viruses. Antigenic alterations of neutralising and protective sites were revealed for all attenuated strains of the VEE and EEE viruses. Comparative studies of the E2 proteins amino acid sequences show that the antigenic modifications observed with the attenuated strains of the VEE virus may be caused by multiple amino acid changes in positions 7, 62, 120, 192 and 209-213. The escape-variants of the VEE virus obtained with cross-reactive MAbs 7D1, 2D4 and 7A6 have mutations of the E2 protein at positions 59, 212-213 and 232, respectively. Amino acid sequences in these regions of the VEE and EEE viruses are not homologous. These observations indicate that cross-reactive MAbs are capable of recognising discontinuous epitopes on the E2 glycoprotein.

Structure-function relation of the NH2-terminal domain of the Semliki Forest virus capsid protein

The capsid (C) protein of alphaviruses consists of two protein domains: a serine protease at the COOH terminus and an NH2-terminal domain which is thought to interact with RNA in the virus nucleocapsid (NC). The latter domain is very rich in positively charged amino acid residues. In this work, we have introduced large deletions into the corresponding region of a full-length cDNA clone of Semliki Forest virus, expressed the transcribed RNA in BHK-21 cells, and monitored the autoprotease activity of C, the formation of intracellular NCs, and the release of infectious virus. Our results show that if the gene region encoding the whole NH2-terminal domain is removed, the expressed C protein fragment cannot assemble into NCs and virus particles but it is still able to function as an autoprotease. Thus, these results underline the general importance of the NH2-terminal domain in the virus assembly process and furthermore show that the serine protease domain can function independently of the NH2 terminus. Surprisingly, analysis of additional C protein deletion variants showed that not all of the NH2-terminal domain is required for virus assembly, but large deletions involving up to one-third of its positively charged residues are still compatible with NC and virus formation. The fact that so much flexibility is allowed in the structure of the NH2-terminal domain of C suggests that most of this region is involved in nonspecific interactions with the encapsidated RNA, probably through its positively charged amino acid residues.

Localization of four antigenic sites involved in Venezuelan equine encephalomyelitis virus protection

Stable neutralization and protection escape variants of a virulent strain (Trinidad Donkey) of the VEE virus were selected by monoclonal antibodies (MAbs). Determination of nucleotide sequences of nine variants revealed a clustering of single mutations in four regions of the E1 and E2 glycoproteins. Involvement of amino acid residues 206 (site E1-1), 57 and 59 (site E2-2), 180, 182, 213, 214 and 216 (site E2-6) and 232 (site E2-3) in protective epitopes was demonstrated.

Assembly and entry mechanisms of Semliki Forest virus

The alphavirus Semliki Forest (SFV) is an enveloped virus with a positive single-stranded RNA genome. The genome is complexed with 240 copies of a capsid protein into a nucleocapsid structure. In the membrane the virus carries an equal number of copies of a membrane protein heterodimer. The latter oligomers are grouped into clusters of three. These structures form the spikes of the virus and carry its entry functions, that is receptor binding and membrane fusion activity. The membrane protein heterodimer is synthesized as a p62E1 precursor protein which upon transport to the cell surface is cleaved into the mature E2E1 form. Recent studies have given much new information on the assembly and entry mechanism of this simple RNA virus. Much of this work has been possible through the construction of a complete cDNA clone of the SFV genome which can be used for in vitro transcription of infectious RNA. One important finding has been to show that a spike deletion variant and a capsid protein deletion variant are budding-negative when expressed separately but can easily complement each other when transfected into the same cell. This shows clearly that enveloped viruses use different budding strategies: one which depends on a nucleocapsid-spike interaction as exemplified by SFV and another one which is based on a direct core-lipid bilayer interaction as shown before to be the case with retroviruses. Another important finding concerns the activation process of the presumed fusion protein of SFV, the E1 subunit. In the original p62E1 heterodimer E1 is completely inactive. Activation proceeds in several steps. First p62 cleavage activates the potential for low pH inducible fusion. Next the low pH which surrounds incoming virus in endosomes induces dissociation of the heterodimeric structure. This is followed by a rearrangement of E1 subunits into homotrimers which are fusion active.

Semliki Forest virus capsid protein expressed by a baculovirus recombinant

We have constructed a recombinant baculovirus which expressed the Semliki Forest (SFV) capsid (C) gene as a fusion protein under the control of the polyhedrin gene promoter. The sequence coding for C and part of the envelope E3 region were expressed as a polyprotein precursor. Spodoptera frugiperda (Sf9) insect cells infected with the recombinant virus produced a protein reacting with polyclonal rabbit antiserum that had been raised against the 33 kDa authentic C protein purified from SFV. Primer extension analyses showed that transcription from the polyhedrin promoter started in the late/very late consensus initiation motif. Due to its autoprotease activity, the recombinant C protein was contranslationally cleaved within its C-terminus and the mature protein remained undegraded for long periods of time. Spodoptera frugiperda cells infected with recombinant virus synthesized large amounts of C protein. The recombinant protein was karyophilic as is authentic SFV C protein and it was translocated into the nucleus; there, it was associated with nucleolus-like structures.

Alphavirus assembly and entry: role of the cytoplasmic tail of the E1 spike subunit

The alphavirus Semliki Forest virus (SFV) matures by budding at the cell surface. This process is driven by interactions of its membrane protein heterodimer E2-E1 and the nucleocapsid. The virus penetrates into new cells by an E1-mediated membrane fusion event. The E1 subunit has a short, strongly positively charged cytoplasmic tail peptide (Arg-Arg) which is very conserved among different alphavirus E1 proteins. In this work, we have used in vitro mutagenesis of a full-size cDNA clone of SFV to study the role of the tail peptide of the E1 subunit in virus budding and fusion processes in baby hamster kidney cell culture. Our results suggest that the E1 tail plays no major role in SFV multiplication in animal cell culture.

Role of cell surface spikes in alphavirus budding

Alphaviruses mature by budding at cell surfaces. According to a prevailing hypothesis, the viral membrane protein, which is a heterodimeric protein unit, is transported to the plasma membrane (PM), where it awaits binding to the viral nucleocapsid (NC). This hypothesis predicts that the viral membrane protein heterodimers accumulate at the cell surface when expressed in the absence of NCs. We have tested this prediction by analyzing the spike protein expression phenotype of a Semliki Forest virus (SFV) variant which contains a capsid gene deletion. We found that viral membrane protein heterodimers were formed and transported to the cell surface normally. However, instead of accumulating at the PM as expected, the membrane proteins were rapidly degraded. In the case of the E1 subunit, degradation resulted in the release of a soluble E1 fragment into the medium. The fact that this pathway of protein degradation is mostly inhibited during wild-type virus infection suggests that viral membrane proteins are very efficiently captured by NCs into budding complexes and that normally no sizeable pool of free membrane protein complexes exists at the PM.

Spike protein-nucleocapsid interactions drive the budding of alphaviruses

Semliki Forest virus (SFV) particles are released from infected cells by budding of nucleocapsids through plasma membrane regions that are modified by virus spike proteins. The budding process was studied with recombinant SFV genomes which lacked the nucleocapsid protein gene or, alternatively, the spike genes. No subviral particles were released from cells which expressed only the nucleocapsid protein or the spike proteins. Virus release was found to be strictly dependent on the coexpression of the nucleocapsid and the spike proteins. These results provide direct proof for the hypothesis that the alphavirus budding is driven by nucleocapsid-spike interactions. The importance of the viral 42S RNA for virus assembly and budding was investigated by using the heterologous vaccinia virus-T7 expression system for the synthesis of the SFV structural proteins. The results demonstrate that the viral genome is not absolutely required for formation of budding competent nucleocapsids, since small amounts of viruslike particles were assembled in the absence of 42S RNA.

Amino acid sequence and structural properties of protein p12, an African swine fever virus attachment protein

The gene encoding the African swine fever virus protein p12, which is involved in virus attachment to the host cell, has been mapped and sequenced in the genome of the Vero-adapted virus strain BA71V. The determination of the N-terminal amino acid sequence and the hybridization of oligonucleotide probes derived from this sequence to cloned restriction fragments allowed the mapping of the gene in fragment EcoRI-O, located in the central region of the viral genome. The DNA sequence of an EcoRI-XbaI fragment showed an open reading frame which is predicted to encode a polypeptide of 61 amino acids. The expression of this open reading frame in rabbit reticulocyte lysates and in Escherichia coli gave rise to a 12-kDa polypeptide that was immunoprecipitated with a monoclonal antibody specific for protein p12. The hydrophilicity profile indicated the existence of a stretch of 22 hydrophobic residues in the central part that may anchor the protein in the virus envelope. Three forms of the protein with apparent molecular masses of 17, 12, and 10 kDa in sodium dodecyl sulfate-polyacrylamide gel electrophoresis have been observed, depending on the presence of 2-mercaptoethanol and alkylation with 4-vinylpyridine, indicating that disulfide bonds are responsible for the multimerization of the protein. This result was in agreement with the existence of a cysteine-rich domain in the C-terminal region of the predicted amino acid sequence. The protein was synthesized at late times of infection, and no posttranslational modifications such as glycosylation, phosphorylation, or fatty acid acylation were detected.

Misfolding and aggregation of newly synthesized proteins in the endoplasmic reticulum

As a part of our studies on the folding of glycoproteins in the ER, we analyzed the fate of viral glycoproteins that have misfolded either spontaneously or through inhibition of N-linked glycosylation. Newly synthesized Semliki Forest virus spike glycoproteins E1 and p62 and influenza hemagglutinin were studied in infected and transfected tissue culture cells. Misfolded proteins aggregated in less than 1 min after release from polysomes and aberrant interchain disulfide bonds were formed immediately. When more than one protein was misfolded, mixed aggregates were generated. This indicated that the formation of complexes was nonspecific, random, and not restricted to products from single polysomes. The size of the aggregates varied from small oligomers to complexes of several million daltons. BiP was associated noncovalently with the aggregates and with some of the nonaggregated products. We conclude that aggregation reflects the poor solubility of incompletely folded polypeptide chains.

Membrane fusion process of Semliki Forest virus. I: Low pH-induced rearrangement in spike protein quaternary structure precedes virus penetration into cells

The Semliki Forest virus (SFV) directs the synthesis of a heterodimeric membrane protein complex which is used for virus membrane assembly during budding at the surface of the infected cell, as well as for low pH-induced membrane fusion in the endosomes when particles enter new host cells. Existing evidence suggests that the E1 protein subunit carries the fusion potential of the heterodimer, whereas the E2 subunit, or its intracellular precursor p62, is required for binding to the nucleocapsid. We show here that during virus uptake into acidic endosomes the original E2E1 heterodimer is destabilized and the E1 proteins form new oligomers, presumably homooligomers, with altered E1 structure. This altered structure of E1 is specifically recognized by a monoclonal antibody which can also inhibit penetration of SFV into host cells as well as SFV-mediated cell-cell fusion, thus suggesting that the altered E1 structure is important for the membrane fusion. These results give further support for a membrane protein oligomerization- mediated control mechanism for the membrane fusion potential in alphaviruses.

A new generation of animal cell expression vectors based on the Semliki Forest virus replicon

We have developed a novel DNA expression system, based on the Semliki Forest virus (SFV) replicon, which combines a wide choice of animal cell hosts, high efficiency and ease of use. DNA of interest is cloned into SFV plasmid vectors that serve as templates for in vitro synthesis of recombinant RNA. The RNA is transfected with virtually 100% efficiency into animal tissue culture cells by means of electroporation. Within the cell, the recombinant RNA drives its own replication and capping and leads to massive production of the heterologous protein while competing out the host protein synthesis. The expression system also includes an in vivo packaging procedure whereby recombinant RNA is packaged into infectious virus particles using cotransfection with packaging-deficient helper RNA molecules. The resulting high titer recombinant virus stock can be used to infect a wide range of animal cells with subsequent high expression of the heterologous gene product, but without expression of any structural proteins of the helper. The infected cells produce protein for up to 75 hours post infection after which the heterologous product can constitute as much as 25% of the total cell protein. The general utility of the system is demonstrated through the expression of human transferrin receptor, mouse dihydrofolate reductase, chick lysozyme and Escherichia coli beta-galactosidase.

Oligomerization of the structural proteins of rubella virus

Rubella virus contains, in addition to its RNA genome, a nucleocapsid protein (C) and two membrane proteins (E2 and E1). We have studied the association of these proteins during viral assembly and when expressed from cDNA constructs. The C protein was found to dimerize very shortly after synthesis; this dimer became disulfide-linked in the virion. Formation of the dimer was independent of the presence of other RV proteins. The membrane glycoproteins formed an E2E1 heterodimer, a minor fraction of which was also found to be disulfide-linked in the virion. This heterodimer also formed when the two proteins were coexpressed from cloned cDNA. Formation of the heterodimer preceded the transport of E2 to the Golgi, as judged by modification of the protein by Golgi-located enzymes. In the absence of E2, the E1 protein was slowly converted to high molecular weight aggregates.

In vitro mutagenesis of a full-length cDNA clone of Semliki Forest virus: the small 6,000-molecular-weight membrane protein modulates virus release

We report on the construction of a full-length cDNA clone of Semliki Forest virus (SFV). By placing the cDNA under the SP6 promoter, infectious RNA can be produced in vitro and used to transfect cells to initiate virus infection. To achieve efficient transfections, a new protocol for electroporation of RNA was developed. This method gave up to 500-fold improvement over the traditional DEAE-dextran transfection procedure. Since virtually 100% of the cells can be transfected by electroporation, this method is a useful tool for detailed biochemical studies of null mutations of SFV that abolish production of infections virus particles. We used the cDNA clone of SFV to study what effects a deletion of the 6,000-molecular-weight membrane protein (6K membrane protein) had on virus replication. The small 6K protein is part of the structural precursor molecule (C-p62-6K-E1) of the virus. Our results conclusively show that the 6K protein is not needed for the heterodimerization of the p62 and E1 spike membrane proteins in the endoplasmic reticulum, nor is it needed for their transport out to the cell surface. The absence of the 6K protein did, however, result in a dramatic reduction in virus release, suggesting that the protein exerts its function late in the assembly pathway, possibly during virus budding.

The E2 signal sequence of rubella virus remains part of the capsid protein and confers membrane association in vitro

The capsid (C) protein of rubella virus is translated from a 24S subgenomic mRNA as the first part of a polyprotein containing all three structural proteins of the virus. It is separated from the following protein (E2) by signal peptidase, which cleaves after the E2 signal sequence. We raised an antipeptide antiserum directed against the signal sequence and used the antiserum to show that this sequence is still a part of the C protein in the mature virion. Furthermore, we also showed that, when the C protein is synthesized by in vitro transcription and translation, the resultant protein is membrane associated. This association is not seen with a variant C protein which lacks the signal sequence, and a normally soluble protein (dihydrofolate reductase) becomes membrane associated when the signal sequence is placed at its carboxy terminus.

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.

Processing and intracellular transport of rubella virus structural proteins in COS cells

Plasmids encoding rubella virus (RV) structural proteins C-E2-E1, E2-E1, E2, and E1 have been constructed in the eukaryotic expression vector pCMV5. The processing and intracellular transport of these proteins have been examined by transient expression of the cDNAs in COS cells. Compared to alphaviruses, processing of RV glycoprotein moieties occurred relatively slowly and the transport of glycoproteins E2 and E1 to the plasma membrane was inefficient. Indirect immunofluorescence revealed that the majority of RV antigen in transfected and infected COS cells was localized to the Golgi region, including the capsid protein. Accumulation of capsid protein in the juxtanuclear region was determined to be RV glycoprotein dependent. Unlike alphaviruses, RV E1 did not require E2 for targeting to the Golgi where it was retained. E2 was however necessary for cell surface expression of E1. This study revealed that the processing and transport of RV structural proteins is quite different from alphaviruses and that the accumulation of antigens in the Golgi region may be significant in light of previous reports which suggest that RV buds from the internal membranes in some cell types.

The signal sequence of the p62 protein of Semliki Forest virus is involved in initiation but not in completing chain translocation

So far it has been demonstrated that the signal sequence of proteins which are made at the ER functions both at the level of protein targeting to the ER and in initiation of chain translocation across the ER membrane. However, its possible role in completing the process of chain transfer (see Singer, S. J., P. A. Maher, and M. P. Yaffe. Proc. Natl. Acad. Sci. USA. 1987. 84:1015-1019) has remained elusive. In this work we show that the p62 protein of Semliki Forest virus contains an uncleaved signal sequence at its NH2-terminus and that this becomes glycosylated early during synthesis and translocation of the p62 polypeptide. As the glycosylation of the signal sequence most likely occurs after its release from the ER membrane our results suggest that this region has no role in completing the transfer process.

Function of Semliki Forest virus E3 peptide in virus assembly: replacement of E3 with an artificial signal peptide abolishes spike heterodimerization and surface expression of E1

The Semliki Forest virus spike glycoproteins E1 and p62 form a heterodimeric complex in the endoplasmic reticulum (ER) and are transported as such to the cell surface. In the mature virus particle, the heterodimeric association of E1 and E2 (the cleavage product of p62) is maintained, but as a more labile and acid-sensitive oligomer than the E1-p62 complex. The E3 peptide forms the N-terminal part of the p62 precursor and carries the signal for the translocation of p62 into the lumen of the ER. The question of whether E3 is also important in the formation and stabilization of the E1-p62 heterodimer has been addressed here with the aid of an E3 deletion mutant cDNA. In this construct, the entire E3 was replaced with a cleavable, artificial signal sequence which preserved the membrane topology of an authentic E2. The E3 deletion, when expressed via a recombinant vaccinia virus, abolished heterodimerization of the spike proteins. It also resulted in the complete retention of E1 in the ER and almost total inhibition of E2 transport to the plasma membrane. The oligomerization and transport defect of E1 expressed from the E3 deletion mutant could be complemented with a wild-type p62 provided from a separate coding unit in double infections. These results point to a central role of E3 in complex formation and transport of the viral structural components to the site of budding. In conjunction with earlier work (M. Lobigs and H. Garoff, J. Virol. 64:1233-1240, 1990; J. Wahlberg, W. A. M. Boere, and H. Garoff, J. Virol. 63:4991-4997, 1989), the data support a model of spike protein oligomerization control of Semliki Forest virus assembly and disassembly which may be mediated by the presence of E3 in the uncleaved p62 precursor and release of E3 after cleavage.

Variants of Venezuelan equine encephalitis virus that resist neutralization define a domain of the E2 glycoprotein

Stable neutralization (N) escape variants of Venezuelan equine encephalitis (VEE) virus were selected by anti-E2 glycoprotein monoclonal antibodies (MAbs) that neutralize viral infectivity, block viral hemagglutination, and passively protect mice. The nucleotide sequence of the E1, E2, and E3 genes of four variants revealed a clustering of single mutations in a domain spanning E2-182 to E2-207. The conformation of this short linear sequence affects antigenicity in the N domain because reduction and alkylation of virus disrupted binding of some E2 neutralizing MAbs. Serologic evidence for interaction of E2 epitopes also was obtained. Mutations in the N domain of VEE virus did not alter the kinetics of binding to Vero cells. They did, in some cases, produce attenuation of virulence in mice.

Molecular cloning and nucleotide sequence of hog cholera virus strain Brescia and mapping of the genomic region encoding envelope protein E1

Genomic RNA of hog cholera virus (HCV) strain Brescia was cloned and sequenced. The nucleotide sequence was deduced from overlapping cDNA clones and comprises 12,283 nucleotides. We cloned the complete 3' end of the HCV genome, but could not unequivocally prove that the cDNA sequence also completely covers HCV RNA at the 5' end. The HCV genome contained one large open reading frame, which spans the viral plus strand RNA and encodes an amino acid sequence of 3898 residues with a calculated molecular weight of 438,300. To identify structural HCV glycoproteins, we prepared rabbit antisera against three synthetic peptides deduced from the sequence. Because one of these antisera reacted with a 51- to 54-kDa glycoprotein (envelope protein E1 of HCV) on Western blot, the genomic position of the sequence encoding gp51-54 could be clearly established. The amino acid sequence of Brescia was compared with that of HCV strain Alfort and that of BVDV strains NADL and Osloss. The degree of homology between the two HCV strains was 93%, and between Brescia and the BVDV strains about 70%. NADL contained an inserted sequence of 90 amino acids that was absent from the sequences of Brescia, Alfort, and Osloss, whereas Osloss contained an inserted sequence of 76 amino acids that was absent from the sequences of Brescia, Alfort, and NADL. Sequences in p80, the most homologous protein among pestiviruses, showed similarity to six sequence motifs found conserved in helicase-like proteins represented by eIF-4A. Furthermore, a trypsin-like serine protease domain detected in p80 of BVDV was also found conserved in HCV, suggesting that pestivirus p80 may be bifunctional.

The significance of carbohydrate trimming for the antigenicity of the Semliki Forest virus glycoprotein E2

Six groups, designated a-f, of noncompeting murine monoclonal antibodies to the envelope glycoprotein E2 of Semliki Forest virus (SFV) have been used to analyze antigenic changes caused by differences in the carbohydrate chain composition of the envelope glycoprotein E2 in the virion. Deletion of terminal sialic acids as observed in virus progeny from mosquito cells did not affect antigenic properties. Inhibition of the trimming pathway in infected chicken cells by the mannosidase I inhibitor dMM led to infectious virus particles containing mannose-rich oligosaccharides of the composition Man9(GlcNAc)2 in the envelope glycoproteins. This alteration had no effect on antigenicity. If inhibition was, however, performed with MdN which acts on alpha-glucosidase giving rise to virions with glycoproteins containing three additional glucose residues in the carbohydrate chains [Glc3Man7,8,9(GlcNAc)2], significant antigenic changes were observed. The six epitopes were differently affected by the underlying structural change and the pattern of exposition of epitopes was not identical with that observed after cleavage of intramolecular disulfide bonds. Concomitantly, the cleavage rate of gp62, the intracellular precursor molecule of the glycoproteins E2 and E3 of the virus particle, was reduced causing a reduction of virus yield. It is concluded that the existence of untrimmed carbohydrate chains is sufficient to allow SFV maturation. The trimming reactions improve this process in a matter suggesting that the carbohydrate chains influence intracellular traffic (addressing) of the respective glycoprotein.

Fusion function of the Semliki Forest virus spike is activated by proteolytic cleavage of the envelope glycoprotein precursor p62

The precursor protein p62 of the prototype alphavirus Semliki Forest virus (SFV) undergoes during transport to the cell surface a proteolytic cleavage to form the mature envelope glycoprotein E2. To investigate the biological significance of this cleavage event, single amino acid substitutions were introduced at the cleavages site through mutagenesis of cDNA corresponding to the structural region of the SFV genome. The phenotypes of the cleavage site mutants were studied in BHK cells by using recombinant vaccinia virus vectors. Nonconservative substitutions completely abolished p62 cleavage. Uncleaved p62 was transported with normal kinetics to the cell surface, where it became accessible to low concentrations of exogenous trypsin. The proteolytic cleavage of envelope glycoprotein precursors has been shown to activate the membrane fusion potential of viral spikes in several virus families. Here we demonstrate that the fusion function of the SFV spike is activated by the cleavage of p62. Cleavage-deficient p62 expressed at the cell surface did not function in low-pH-triggered (pH 5.5) cell-cell membrane fusion; however, cleavage of the mutated p62 with exogenous trypsin restored the fusion function. We discuss a model for SFV assembly and fusion where p62 cleavage plays a crucial role in the stability of the multimeric association of the viral envelope glycoproteins.

Receptor activity of rotavirus nonstructural glycoprotein NS28

Rotavirus morphogenesis involves the budding of subviral particles through the rough endoplasmic reticulum (RER) membrane of infected cells. During this process, particles acquire the outer capsid proteins and a transient envelope. Previous immunocytochemical and biochemical studies have suggested that a rotavirus nonstructural glycoprotein, NS28, encoded by genome segment 10, is a transmembrane RER protein and that about 10,000 Mr of its carboxy terminus is exposed on the cytoplasmic side of the RER. We have used in vitro binding experiments to examine whether NS28 serves as a receptor that binds subviral particles and mediates the budding process. Specific binding was observed between purified simian rotavirus SA11 single-shelled particles and RER membranes from SA11-infected monkey kidney cells and from SA11 gene 10 baculovirus recombinant-infected insect cells. Membranes from insect cells synthesizing VP1, VP4, NS53, VP6, VP7, or NS26 did not possess binding activity. Comparison of the binding of single-shelled particles to microsomes from infected monkey kidney cells and from insect cells indicated that a membrane-associated component(s) from SA11-infected monkey kidney cells interfered with binding. Direct evidence showing the interaction of NS28 and its nonglycosylated 20,000-Mr precursor expressed in rabbit reticulocyte lysates and single-shelled particles was obtained by cosedimentation of preformed receptor-ligand complexes through sucrose gradients. The domain on NS28 responsible for binding also was characterized. Reduced binding of single-shelled particles to membranes was seen with membranes treated with (i) a monoclonal antibody previously shown to interact with the C terminus of NS28, (ii) proteases known to cleave the C terminus of NS28, and (iii) the Enzymobead reagent. VP6 on single-shelled particles was suggested to interact with NS28 because (i) a monoclonal antibody to the subgroup I epitope on VP6 reduced particle binding, (ii) a purified polyclonal antiserum raised against recombinant baculovirus-produced VP6 reduced ligand binding, and (iii) a monoclonal antibody to a conserved epitope on VP6 augmented ligand binding. These experimental data provide support for the hypothesized receptor role of NS28 before the budding stage of rotavirus morphogenesis.

Entry mechanisms of enveloped viruses. Implications for fusion of intracellular membranes

Enveloped viruses infect cells by a mechanism involving membrane fusion. This process is mediated and triggered by specific viral membrane glycoproteins. Evidence is accumulating that fusion of intracellular membranes, as occurs during endocytosis and transport between intracellular organelles, also requires the presence of specific proteins. The relevance of elucidating the mechanisms of virus fusion for a better understanding of fusion of intracellular membranes is discussed.

Semliki Forest virus particles containing only the E1 envelope glycoprotein are infectious and can induce cell-cell fusion

Hydrophobic interaction chromatography (phenyl- and octyl-Sepharose) was performed with Semliki Forest virus to investigate the effect of low pH on its hydrophobicity. At neutral pH, the virus could be bound to the column and completely eluted by the detergent NP-40. Low pH treatment of virus prior to application to the column resulted in stronger binding as reflected by the increased amount of detergent necessary to totally elute the virus. If, however, the low pH treatment was done after binding of the virus to the column, only 15% of the input virus could be eluted by the detergent, indicating a drastic increase in hydrophobicity. Thus binding of the virus to a hydrophobic environment potentiates the effect of low pH on viral hydrophobicity. Trypsin digestion of column-bound virus after low pH treatment resulted in complete digestion of E2 and E3; however, E1 was totally resistant. From this result, we conclude that E1 alone is responsible for the hydrophobic interaction. We have made use of these observations to produce viral particles which were devoid of E2 and E3 by trypsin digestion in the presence of octyl glucoside. These E1 viral particles were infectious and could induce membrane fusion. We conclude that only E1 is necessary and sufficient to mediate membrane fusion. Acid pH induces a drastic increase in the hydrophobicity of E1 which probably facilitates its interaction with the lipid bilayers during the fusion event in endosomes.

Time course of virus-specific macromolecular synthesis during rubella virus infection in Vero cells

Virus specific macromolecular synthesis was studied in Vero cells infected with plaque-purified rubella virus under one-step multiplication conditions. Under these conditions, the rate of virus production was found to increase rapidly until 24 hr postinfection after which time the rate of virus production rose more slowly, reaching a peak level at 48 hr postinfection. This peak rate of virus production was maintained through 72 hr postinfection. A majority of the cells remained alive through 96 hr postinfection, although a 20 to 30% decrease in the number of living cells occurred between 24 and 48 hr postinfection, the time period at which cytopathic effect was first observed. The virus structural proteins were first detected intracellularly at 16 hr postinfection. The rate of synthesis of these proteins was already maximal at 16 hr postinfection and remained constant through 48 hr postinfection. By immunofluorescence, cells expressing virus proteins were first observed at 12 hr postinfection. At 24 hr postinfection, 35 to 50% of the cells in the infected culture were exhibiting immunofluorescence, at 36 hr postinfection, 65 to 90% of the cells were exhibiting immunofluorescence, and at 48 hr postinfection, all of the cells were exhibiting immunofluorescence. The virus genomic and subgenomic RNA species were first detectable by 12 hr postinfection. The rate of synthesis of both of these species peaked at 26 hr postinfection. Rubella virus infection was found to have no effect on total cell RNA synthesis. However, a modest inhibition of total cell protein synthesis which reached 40% by 48 hr postinfection was observed. When Northern analysis of RNA extracted from infected cells was performed, a negative-polarity, virus-specific RNA probe hybridized only to the virus genomic and subgenomic RNA species. A positive-polarity, virus-specific RNA probe hybridized predominantly to a negative-polarity RNA of genome length indicating that both the genomic and subgenomic RNAs are synthesized from a genome-length negative-polarity template. Defective interfering (DI) RNAs were not detected in infected cells through 96 hr postinfection or in cells onto which virus released through 96 hr postinfection was passaged. Thus, the generation of DI particles by rubella virus appears to play no role in the slow, noncytopathic replication of this virus or in the ability of rubella virus-infected cells to survive for extended periods of time.

Constitutive apical secretion of an 80-kD sulfated glycoprotein complex in the polarized epithelial Madin-Darby canine kidney cell line

The biosynthesis, processing, and apical secretion of a group of polypeptides (Kondor-Koch, C., R. Bravo, S. D. Fuller, D. Cutler, and H. Garoff. 1985. Cell. 43:297-306) are studied in MDCK cells using a specific polyclonal antiserum. These polypeptides are synthesized as a precursor protein which has an apparent Mr of 65,000 in its high mannose form. This precursor is converted into a protein with an apparent Mr of 80,000 containing complex carbohydrates and sulfate. After intracellular cleavage of the 80-kD protein, the 35-45-kD subunits are secreted as an 80-kD glycoprotein complex (gp 80) linked together by disulfide bonds. Secretion of the protein complex occurs by a constitutive pathway at the apical surface of the epithelial monolayer. Since the immediate post-translational precursor, the 65-kD protein, is hydrophilic in nature as shown by its partitioning behavior in a phase-separated Triton X-114 solution, gp 80 is segregated into the apical exocytotic pathway as a soluble molecule. The proteolytic maturation of gp 80 is blocked in the presence of chloroquine and its secretion is retarded. The 80-kD precursor is released at the apical cell surface, demonstrating that proteolytic processing is not necessary for the apical secretion of this protein. If N-glycosylation is inhibited by tunicamycin treatment the protein is secreted in equal amounts at both cell surfaces, indicating a role of the carbohydrate moieties in the vectorial transport of this protein.

Glucose trimming and mannose trimming affect different phases of the maturation of Sindbis virus in infected BHK cells

The roles of glucose and mannose trimming in the maturation of Sindbis virus in BHK cells have been investigated using inhibitors of glycoprotein oligosaccharide processing. In the presence of the glucosidase inhibitor N-methyl-1-deoxynojirimycin the viral glycoproteins were equipped with oligosaccharides of the composition Glc3Man8,9(GlcNAc)2 and the yield of virus in the extracellular medium was reduced as a result of a block in the proteolytic cleavage of the precursor (pE2) of the E2 viral envelope glycoprotein. The mannosidase I inhibitor 1-deoxymannojirimycin (dMM) also inhibited the appearance of virus in the medium and the oligosaccharides on the viral glycoproteins had the composition Man9(GlcNAc)2. However, pE2 was cleaved to E2 under these conditions, and it was found that when the yield of virus from the cells and medium together was considered, there was no difference between untreated and dMM-treated cultures, suggesting the presence of intracellular virus particles in the dMM-treated cultures. When examined by electron microscopy, the dMM-treated cultures were found to contain intracellular virus particles. In addition, nucleocapsids were found lining intracellular membranes. These observations taken together with the plaque test data intimate that Sindbis virus preferentially buds from internal membranes in BHK cells treated with dMM. The results confirm the essential role of glucose trimming in the Sindbis virus-BHK cell system and suggest that the initial stages of mannose removal may be important too.

Nucleotide sequence and in vitro expression of rubella virus 24S subgenomic messenger RNA encoding the structural proteins E1, E2 and C

The complete nucleotide sequence of the 24S subgenomic mRNA of wild-type M33 strain rubella virus has been determined. This RNA is 3,383 nucleotides in length excluding the 3'-terminal poly(A) tract. After the three multiple in-phase termination codons clustered in the 5' terminus of this RNA, there are 81 nucleotides of nontranslated nucleic acid followed by a reading frame of 2,978 nucleotides that encodes the 110 kD precursor of the structural proteins. The 3'-untranslated region is 263 nucleotides. The 110 kD polyprotein is processed to produce nucleocapsid C, the glycoproteins E2 and E1 in that order. Sites of post-translational cleavage to produce E2 and E1 were located using available N-terminal amino acid sequences. RNAs synthesized by transcription in vitro are effective messengers in the rabbit reticulocyte cell-free translation system. Post-translational processing of the structural proteins was observed in the cell-free system supplemented with microsomes from dog pancreas.

Biosynthesis and maturation of lactase-phlorizin hydrolase in the human small intestinal epithelial cells

The biosynthesis and maturation of the human intestinal lactase-phlorizin hydrolase (LPH; EC 3.2.1.23-3.2.1.62) has been studied in cultured intestinal biopsies and mucosal explants. Short time pulse labelling revealed on high mannose intermediate of Mr 215,000 which was converted upon endo-beta-N-acetylglucosaminidase H (endo-H) digestion to a polypeptide of Mr 200,000. The brush border form of LPH was revealed after longer pulse periods and has Mr 160,000. It possesses mainly complex oligosaccharide chains and, owing to its partial endo-H sensitivity, at least one chain of the high mannose type. Leupeptin partially inhibited the appearance of the Mr-160,000 polypeptide. Monensin treatment of biopsies resulted in the modification of the Mr-160,000 species to the Mr-140,000 molecule, which was endo-H sensitive. Pulse-chase analysis indicated a slow post-translational processing of the high mannose precursor (Mr 215,000) to yield the mature brush-border form (Mr 160,000) of LPH. Our results further indicate that LPH is synthesized as a single polypeptide precursor which is intracellularly cleaved to yield the mature brush border of LPH. The data presented suggest that this cleavage occurs during the translocation of the molecule across the Golgi complex.

Alteration of the cytoplasmic domain of the membrane-spanning glycoprotein p62 of Semliki Forest virus does not affect its polar distribution in established lines of Madin-Darby canine kidney cells

Expression of the Semliki Forest virus p62/E2 protein was studied in the polarized epithelial cell line Madin-Darby canine kidney (MDCK). After infection this transmembrane protein, together with the other spike subunit E1, accumulates at the basolateral surface of MDCK cells (Fuller, S. D., C.-H. von Bonsdorff, and K. Simons, 1985, EMBO (Eur. Mol. Biol. Organ.) J., 4:2475-2485). The cDNAs encoding truncated forms of the protein were used to stably transform MDCK cells to examine the role of subunit oligomerization (E1-E2) and the cytoplasmic domain of p62/E2 in directed transport to the basolateral surface. The biochemical characteristics and polarity of the expressed proteins were studied using cell monolayers grown on nitrocellulose filters. A wild-type form of p62/E2, in the absence of E1, and two forms having either 15 or 3 of the wild-type 31-amino acid carboxyl cytoplasmic domain were all localized to the basolateral surface. These results indicate that the cytoplasmic domain of E2 does not contain the information essential for directed transport to the plasma membrane, and imply that this information resides in either the lumenal and/or membrane-spanning segments of this transmembrane protein.

Molecular cloning and sequencing of the region of the rubella virus genome coding for glycoprotein E1

The sequence of the 1600 3' terminal nucleotides of the RNA of rubella virus was determined from cDNA synthesized from both virion and intracellular RNA using reverse transcriptase and an oligodeoxythymidine primer and cloned into a bacterial plasmid vector. This sequence contained the complete coding sequence for virion envelope protein E1 and a 57 nucleotide nontranslated region between the stop codon for E1 and the poly A tract. The predicted size for E1 was 481 amino acids and within this sequence were three potential N-linked glycosylation sites and a putative trans-membrane domain near the carboxy terminus. Immediately preceding the E1 coding region was a putative signal sequence. No homology was found at either the amino acid or nucleotide level between the region of the rubella virus genome sequenced and corresponding regions of the genomes of the alphaviruses, the other genus of the family Togaviridae for which sequence information has been obtained.

Alphavirus replication in cultured cells and infected animals is inhibited by antiproteinase agents

The influence of different antiproteinase agents on alphavirus replication was examined. Sindbis virus multicycle replication in cultured cells was suppressed by N-tosyl-phenylalanine chloromethyl ketone (TPCK), an inhibitor of chymotrypsin-like proteinases, and by aprotinin, an inhibitor of a wide spectrum of proteinases. Antiviral activity of TPCK was also demonstrated in Sindbis virus-infected animals. Parenteral injections of TPCK in infected mice reduced virus titers in brain and blood. The possible mechanism(s) of antiviral action of the antiproteinase agents are discussed.

Complete nucleotide sequence of the nonstructural protein genes of Semliki Forest virus

The nucleotide sequence coding for the nonstructural proteins of Semliki Forest virus has been determined from cDNA clones. The total length of this region is 7381 nucleotides, it contains an open reading frame starting at position 86 and ending at an UAA stop codon at position 7379-7381. This open reading frame codes for a 2431 amino acids long polyprotein, from which the individual nonstructural proteins are formed by proteolytic processing steps, so that nsPl is 537, nsP2 798, nsP3 482 and nsP4 614 amino acids. In the closely related Sindbis and Middelburg viruses there is an opal stop codon (UGA) between the genes for nsP3 and nsP4. Interestingly, no stop codon is found in frame in this region of the Semliki Forest virus 42S RNA. In other aspects the amino acid sequence homology between Sindbis, Middelburg and Semliki Forest virus nonstructural proteins is highly significant.

Properties of monospecific antibodies to the glycoprotein of western equine encephalitis virus

Monospecific (MSp-) antisera against E1 and E2 glycoproteins of western equine encephalitis (WEE) virus were prepared and examined for binding activities to whole virions, hemagglutination-inhibition (HI), neutralization (NT) and protection. Both anti-E1 and anti-E2 MSp-Abs protected mice against WEE virus challenge. A competition experiment with monoclonal antibodies showed that these MSp-antisera appear to lack the antibody population for some epitopes involved in viral neutralization.

Antibody-selected variation and reversion in Sindbis virus neutralization epitopes

Sindbis virus variants evidencing a complex and bidirectional tendency toward spontaneous antigenic change were isolated and characterized. Variants were selected on the basis of their escape from neutralization by individual monoclonal antibodies to either of the two envelope glycoproteins, E2 and E1. Multisite variants, including one altered in three neutralization sites, were obtained by selecting mutants consecutively in the presence of different neutralizing monoclonal antibodies. Two phenotypic revertants, each of which reacquired prototype antigenicity, were back-selected on the basis of their reactivity with a neutralizing monoclonal antibody. An incidental oligonucleotide marker distinguished these and the variant from which they arose from parental Sindbis virus and other mutants, thereby confirming that the revertants were true progeny of the antigenic variant. Prototype Sindbis virus and variants derived from it were compared on the basis of their reactivities with each of a panel of monoclonal antibodies; patterns revealed a minimum of five independently mutable Sindbis virus neutralization epitopes, segregating as three antigenic sites (two E2 and one E1).

Sequence analysis of the membrane protein V3 of the flavivirus West Nile virus and of its gene

Flaviviruses contain a large membrane-associated protein V3, having a mol mass of about 50 kDa which is responsible for hemagglutination. We have isolated the V3 protein from the West Nile (WN) flavivirus and determined its amino-terminal amino acid sequence and amino acid sequences of fragments derived from this protein. We have also transcribed parts of the WN virus genome RNA into cDNA and cloned and sequenced this cDNA. The results of these analyses have allowed us to identify the region of the viral genome coding for the V3 protein. In this report we describe the total nucleotide sequence of the genome region coding for the WN virus V3 protein and the amino acid sequence of the V3 protein derived from these analyses. The exact carboxy terminus of the V3 protein has not been determined in these experiments. These analyses have shown that the V3 protein of WN virus does not contain an Asn-X-Ser/Thr sequence which could allow addition of N-linked carbohydrate chains to this protein. In accordance with this finding, analyses of metabolic labeling of the V3 protein using [3H]glucosamine indicate that the WN virus V3 protein is an unglycosylated protein. Together with our earlier analyses these results show that the viral structural proteins are present on the genome RNA in the order 5'-terminus-core protein (V2)-small membrane-associated protein (NV2)-large membrane-associated protein (V3) and describe the nucleotide sequences coding for all WN virus structural proteins identified so far. A hypothesis concerning the processes involved in the synthesis of all viral structural proteins and the probable orientation of these proteins relative to the endoplasmatic reticulum membrane based on the structure of these proteins is discussed.

One-step separation of the components of Semliki Forest virus by cation exchange chromatography

Although several procedures for isolating viral proteins have been described, the simultaneous separation of all the viral macromolecules in a single step has not yet been reported. We now describe TUA (Triton X-100, urea, acetic acid, pH 4.2)-SP (Sulphopropyl)-Trisacryl cation exchange chromatography, which proved to be ideal for this purpose. Optimal conditions for chromatography were established by screening on TUA-PAGE (polyacrylamide gel electrophoresis) using a horizontal linear 0-8.5 M urea gradient followed by identification of the proteins by SDS-PAGE in the second dimension. Segregation of the constituents of Semliki Forest virus cultivated in two cell lines (chicken embryo fibroblasts and Aedes albopictus cells) was studied, considering that the proteins have identical primary sequences but diverse post-translational modifications, thereby allowing the efficacy of the procedure and its applicability to different viruses to be tested. The results show that the RNA and lipids did not bind to the cation exchange in TUA and were eluted in the flow-through fractions. The proteins were fractionated using 3 linear NaCl gradients in TUA. SDS-PAGE revealed that all the proteins could be purified by this procedure. Furthermore, a direct correlation was obtained between the distance migrated by the proteins in the TUA-PAGE and their order of elution from the TUA-cation exchange column.

Effect of monensin on the assembly of Uukuniemi virus in the Golgi complex

The effect of the carboxylic ionophore monensin on the maturation of Uukuniemi virus, a bunyavirus, and the transport of its two membrane glycoproteins, G1 and G2, were studied in chicken embryo fibroblasts and baby hamster kidney cells. Virus maturation, which occurs in the Golgi complex (E. Kuismanen, K. Hedman, J. Saraste, and R. F. Pettersson, Mol. Cell. Biol. 2:1444-1458, 1982; E. Kuismanen, B. Bång, M. Hurme, and R. F. Pettersson, J. Virol. 51:137-146, 1984), was effectively inhibited by the drug (1 or 10 microM) as studied by electron microscopy and by assaying the release of infectious or radiolabeled virus. Immunoelectron microscopy showed that association of viral nucleocapsids with the cytoplasmic surface of glycoprotein-containing Golgi membranes, a prerequisite for virus budding, was unaffected by monensin. In the presence of the drug, the virus glycoproteins assembled into long, tubular structures extending into the lumen of Golgi-derived vacuoles, suggesting that monensin inhibited a terminal step in the assembly of the virus. Intracellular transport and expression of the virus membrane glycoproteins G1 and G2 at the cell surface were not inhibited by monensin as studied by immunocytochemical and radiolabeling techniques. Pulse-chase experiments in the presence of monensin showed that intracellular G1 acquired only partially endo-H-resistant glycans. The sialylation of G1 appearing on the cell surface in the presence of the drug was decreased, whereas sialylation of G2 apparently was inhibited to a lesser extent, as shown by external labeling of the cells with the periodate-boro[3H]hydride method. Thus, monensin exerted a differential effect on the terminal glycosylation of G1 and G2. Unlike several membrane and secretory glycoproteins, both G1 and G2 could enter a functional transport pathway in the presence of monensin and become expressed at the cell surface.

Properties of monoclonal antibodies against glycoproteins of western equine encephalitis virus

To analyze the biological activities of the alphavirus glycoproteins, eight different monoclonal antibodies against the two glycoproteins of western equine encephalitis virus were isolated. Five of the eight monoclonal antibodies were shown to be specific for E1 and three for E2 protein by an enzyme-linked immunosorbent assay and by radioimmunoprecipitation. Three of the five anti-E1 and all of the anti-E2 monoclonal antibodies inhibited hemagglutination by purified virions. One anti-E1 and two anti-E2 monoclonal antibodies possessed high virus-neutralizing activity.

Sequence analysis of the viral core protein and the membrane-associated proteins V1 and NV2 of the flavivirus West Nile virus and of the genome sequence for these proteins

Cell-associated flaviviruses contain the two membrane proteins V3 and NV2 besides the viral core protein V2 whereas extracellular viruses do contain V2 protein and the two membrane proteins V3 and V1. Since the V1 protein could not be detected in infected cells it has been suggested that V1 is generated from NV2 by proteolytic cleavage during the release of virus from cells (D. Shapiro, W. E. Brandt, and P. K. Russell (1972), Virology 50, 906-911). We have isolated the viral structural proteins V1, V2, and NV2 from the flavivirus West Nile virus and determined their amino-terminal amino acid sequences and amino acid sequences of peptides derived from these proteins. We have also transcribed parts of the viral genome into cDNA and cloned and sequenced this cDNA. The analyses of the protein structure of V1, V2, and NV2 together with the determination of the amino-terminal sequence of V3 (data not shown) have allowed us to identify the nucleotide region coding for the structural proteins V2, NV2, and V1. The primary structure of this nucleotide sequence is presented in this report. The data show that the amino terminus of the viral core protein V2 is followed by the amino termini of the proteins NV2, V1, and V3, respectively. These data for the first time identify the exact order of all structural proteins of a flavivirus identified so far. Our data strongly support the above-mentioned hypothesis that V1 is derived from NV2 by proteolytic cleavage and furthermore indicate that V1 represents the nonglycosylated carboxy-terminal part of NV2 which contains those sequences which anchor NV2 in the viral membrane. A working hypothesis is presented in which two species of cellular enzymes, signalase(s) removing signal sequences and enzymes involved in cleaving polyproteins after a pair of basic amino acids, do generate the proteins V2, NV2, and V1 from the growing peptide chain synthesized during translation of the 42 S genome RNA which functions as mRNA for these proteins.