Dissociation of progeny vaccinia virus from the cell membrane is regulated by a viral envelope glycoprotein: effect of a point mutation in the lectin homology domain of the A34R gene.

Vaccinia virus strains vary considerably in the amounts of extracellular enveloped virus (EEV) that they release from infected cells. The IHD-J strain produces up to 40 times more EEV than does the related WR strain and consequently generates elongated comet-shaped virus plaques instead of sharply defined round ones in susceptible monolayer cells under liquid medium. The difference in EEV formation is due to the retention of enveloped WR virions on the cell surface (R. Blasco and B. Moss, J. Virol. 66:4170-4179, 1992). By using WR and IHD-J DNA fragments for marker transfer and analyzing the progeny virus by the comet formation assay, we determined that gene A34R and at least one other gene regulate the release of cell-associated virions. Replacement of the A34R gene of WR with the corresponding gene from IHD-J increased the amount of EEV produced by 10-fold and conferred the ability to form distinctive comet-shaped plaques. Gene A34R encodes an EEV-specific glycoprotein with homology to C-type animal lectins (S.A. Duncan and G.L. Smith, J. Virol. 66:1610-1621, 1992). The nucleotide sequences of the A34R genes of WR and IHD-J strains differed in six positions, of which four were silent. One of the codon mutations (Lys-151-->Glu), which is located in the putative carbohydrate recognition domain, was sufficient to transfer a comet-forming phenotype to WR virus. These data indicate that the A34R-encoded glycoprotein is involved, through its lectin homology domain, in the retention of progeny virus on the surface of parental cells and raise the possibility that the protein also has a role in virus attachment to uninfected cells.     

Deletion of the vaccinia virus B5R gene encoding a 42-kilodalton membrane glycoprotein inhibits extracellular virus envelope formation and dissemination.

The structure, formation, and function of the virion membranes are among the least well understood aspects of vaccinia virus replication. In this study, we investigated the role of gp42, a glycoprotein component of the extracellular enveloped form of vaccinia virus (EEV) encoded by the B5R gene. The B5R gene was deleted by homologous recombination from vaccinia virus strains IHD-J and WR, which produce high and low levels of EEV, respectively. Isolation of recombinant viruses was facilitated by the insertion into the genome of a cassette containing the Escherichia coli gpt and lacZ genes flanked by the ends of the B5R gene to provide simultaneous antibiotic selection and color screening. Deletion mutant viruses of both strains formed tiny plaques, and those of the IHD-J mutant lacked the characteristic comet shape caused by release of EEV. Nevertheless, similar yields of intracellular infectious virus were obtained whether cells were infected with the B5R deletion mutants or their parental strains. In the case of IHD-J, however, this deletion severely reduced the amount of infectious extracellular virus. Metabolic labeling studies demonstrated that the low extracellular infectivity corresponded with a decrease in EEV particles in the medium. Electron microscopic examination revealed that mature intracellular naked virions (INV) were present in cells infected with mutant virus, but neither membrane-wrapped INV nor significant amounts of plasma membrane-associated virus were observed. Syncytium formation, which occurs in cells infected with wild-type WR and IHD-J virus after brief low-pH treatment, did not occur in cells infected with the B5R deletion mutants. By contrast, syncytium formation induced by antibody to the viral hemagglutinin occurred, suggesting that different mechanisms are involved. When assayed by intracranial injection into weanling mice, both IHD-J and WR mutant viruses were found to be significantly attenuated. These findings demonstrate that the 42-kDa glycoprotein of the EEV is required for efficient membrane enwrapment of INV, externalization of the virus, and transmission and that gp42 contributes to viral virulence in strains producing both low and high levels of EEV.     

Role of cell-associated enveloped vaccinia virus in cell-to-cell spread.

The roles of intracellular naked (INV), cell-associated enveloped (CEV), and extracellular enveloped (EEV) forms of vaccinia virus in cell-to-cell and longer-range spread were investigated by using two closely related strains of vaccinia virus, WR and IHD-J. We confirmed previous results that WR and IHD-J produced similar amounts of INV and formed similar-size primary plaques but that IHD-J produced 10 to 40 times more EEV and spread to distant cells much more efficiently than did WR. Nevertheless, cells infected with WR and IHD-J had similar amounts of CEV, indicating that wrapping and transport of WR virions were unimpaired. A WR mutant with a deletion in VP37, the major outer envelope protein, formed normal amounts of INV; however, the generation of CEV was blocked and plaque formation was inhibited. These results suggested that CEV is the form of virus that mediates cell-to-cell spread. Marker rescue experiments indicated that the differences in EEV production by WR and IHD-J were not due to sequence differences in VP37. The low amount of WR EEV could be attributed to retention of CEV on the cell membrane. In support of this hypothesis, mild treatment with trypsin released as much or more infectious virus from cells infected with WR as it did with cells infected with IHD-J. Most of the virus released by trypsin sedimented with the buoyant density of EEV. Also, addition of trypsin to cells following inoculation with WR led to a comet-shaped distribution of secondary plaques characteristic of IHD-J. These results demonstrated that the release of CEV from the cell surface was limiting for extracellular virus formation and affirmed the role of EEV in long-range spread.     

Fusion of intra- and extracellular forms of vaccinia virus with the cell membrane.

The membrane fusion activities of the isolated single-envelope intracellular form of vaccinia virus (INV) and the double-envelope extracellular (EEV) form were studied by using a lipid-mixing assay based on the dilution of a fluorescent probe. Fluorescently labeled INV and EEV from both the IHD-J and WR strains of vaccinia virus fused with HeLa cells at neutral pH, suggesting that fusion occurs with the plasma membrane during virus entry. EEV fused more efficiently and with faster kinetics than INV: approximately 50% of bound EEV particles fused over the course of 1 h, compared with only 25% of the INV particles. Fusion of INV and EEV was strongly temperature dependent, being decreased by 50% at 34 degrees C and by 90% at 28 degrees C. A monoclonal antibody to a 14-kilodalton envelope protein of INV that has been implicated in the fusion reaction (J. F. Rodriguez, E. Paez, and M. Esteban, J. Virol. 61:395-404, 1987) completely suppressed the initial rate of fusion of INV but had no effect on the fusion activity of EEV, suggesting that vaccinia virus encodes two or more membrane fusion proteins. Finally, cells infected with the WR strain of vaccinia virus formed syncytia when briefly incubated at pH 6.4 or below, indicating that an acid-activated viral fusion protein is expressed on the cell surface. However, WR INV and EEV did not display increased fusion activity at acid pH, suggesting that the acid-dependent fusion factor is not incorporated into virions or that its activity there is masked.     

Identification of the vaccinia hemagglutinin polypeptide from a cell system yielding large amounts of extracellular enveloped virus.

HeLa, SIRC, and RK-13 cells were compared as to their production of intracellular naked vaccinia virus (INV) and extracellular enveloped vaccinia virus (EEV) after infection with vaccinia strains WR and IHD-J. IHD-J produced more EEV from all three cell lines than did WR, although both strains produced approximately the same quantity of INV. The most efficient EEV release was from RK-13 cells infected with IHD-J, which was 200 times more than from WR-infected SIRC cells. This permitted for the first time the purification of milligram quantities of EEV that contained much fewer cell protein contaminants than could be obtained from HeLa or SIRC cells. The INV surface proteins 200K, 95K, 65K, and 13K were present in both HeLa and RK-13 cell-derived INV but were absent in SIRC cell INV. These proteins were absent in EEV from all three cell lines. Four glycoproteins of molecular weights 210 x 10(3) (210K), 110K, 89K, and 42K and five glycoproteins in the 23K to 20K range plus a nonglycosylated protein of 37K were detected in EEV from the hemagglutinin-positive IHD-J vaccinia strain. The 89K glycoprotein was not present in EEV or membranes from cells infected with the hemagglutinin-negative vaccinia strain IHD-W. Antisera to IHD-W lacking hemagglutinin-inhibiting antibodies did not precipitate the 89K glycoprotein of IHD-J. The only glycoprotein that specifically attached to rooster erythrocytes was the 89K glycoprotein. This evidence indicates that the 89K glycoprotein is the vaccinia hemagglutinin.     

Role of pseudorabies virus glycoprotein gI in virus release from infected cells.

The Bartha vaccine strain of pseudorabies virus has a deletion in the short unique (Us) region of its genome which includes the genes that code for glycoproteins gI and gp63 (E. Petrovskis, J. G. Timmins, T. M. Gierman, and L. E. Post, J. Virol. 60:1166-1169, 1986). Restoration of an intact Us to the Bartha strain enhances its ability to be released from infected rabbit kidney cells and increases the size of the plaques formed on these cells (T. Ben-Porat, J. M. DeMarchi, J. Pendrys, R. A. Veach, and A. S. Kaplan, J. Virol. 57:191-196, 1986). To determine which gene function plays a role in virus release from rabbit kidney cells, deletions were introduced into the genomes of both wild-type virus and the "rescued" Bartha strain (Bartha strain to which an intact Us had been restored) that abolish the expression of either the gI gene alone or both gI and gp63 genes. The effect of these deletions on the phenotype of the viruses was studied. Deletion mutants of wild-type virus defective in either gI or gI and gp63 behave like wild-type virus with respect to virus release and plaque size on rabbit kidney cells. Deletion of gI from the rescued Bartha strain, however, strongly affects virus release and causes a decrease in plaque size. We conclude that gI affects virus release but that at least one other viral function also affects this process. This function is defective in the Bartha strain but not in wild-type virus; in its absence gI is essential to efficient release of the virus from rabbit kidney cells.     

Depletion of glycoprotein gp85 from virosomes made with Epstein-Barr virus proteins abolishes their ability to fuse with virus receptor-bearing cells.

Entry of an enveloped virus such as Epstein-Barr virus (EBV) into host cells involves fusion of the virion envelope with host cell membranes either at the surface of the cell or within endocytic vesicles. Previous work has indirectly implicated the EBV glycoprotein gp85 in this fusion process. A neutralizing monoclonal antibody to gp85, F-2-1, failed to inhibit binding of EBV to its receptor but interfered with virus fusion as measured with the self-quenching fluorophore octadecyl rhodamine B chloride (R18) (N. Miller and L. M. Hutt-Fletcher, J. Virol. 62:2366-2372, 1988). To test further the hypothesis that gp85 functions as a fusion protein, EBV virion proteins including or depleted of gp85 were incorporated into lipid vesicles to form virosomes. Virosomes were labeled with R18, and those that were made with undepleted protein were shown to behave in a manner similar to that of R18-labeled virus. They bound to receptor-positive but not to receptor-negative cells and fused with Raji cells but not with receptor-positive, fusion-incompetent Molt 4 cells; monoclonal antibodies that inhibited binding or fusion of virus inhibited binding and fusion of virosomes, and virus competed with virosomes for attachment to cells. In contrast, virosomes made from virus proteins depleted of gp85 by immunoaffinity chromatography remained capable of binding to receptor-positive cells but failed to fuse. These results are compatible with the hypothesis that gp85 is actively involved in the fusion of EBV with lymphoblatoid cell lines and suggest that the ability of antibody F-2-1 to neutralize infectivity of EBV represents a direct effect on the function of gp85 as a fusion protein.     

Characterization of a vaccinia virus-encoded 42-kilodalton class I membrane glycoprotein component of the extracellular virus envelope.

Using a reverse genetic approach, we have demonstrated that the product of the B5R open reading frame (ORF), which has homology with members of the family of complement control proteins, is a membrane glycoprotein present in the extracellular enveloped (EEV) form of vaccinia virus but absent from the intracellular naked (INV) form. An antibody (C'-B5R) raised to a 15-amino-acid peptide from the translated B5R ORF reacted with a 42-kDa protein (gp42) found in vaccinia virus-infected cells and cesium chloride-banded EEV but not INV. Under nonreducing conditions, an 85-kDa component, possibly representing a hetero- or homodimeric form of gp42, was detected by both immunoprecipitation and Western immunoblot analysis. Metabolic labeling with [3H]glucosamine and [3H]palmitate revealed that the B5R product is glycosylated and acylated. The C-terminal transmembrane domain of the protein was identified by constructing a recombinant vaccinia virus that overexpressed a truncated, secreted form of the B5R ORF product. By N-terminal sequence analysis of this secreted protein, the site of signal peptide cleavage of gp42 was determined. A previously described monoclonal antibody (MAb 20) raised to EEV, which immunoprecipitated a protein with biochemical characteristics similar to those of wild-type gp42, reacted with the recombinant, secreted product of the B5R ORF. Immunofluorescence of wild-type vaccinia virus-infected cells by using either MAb 20 or C'-B5R revealed that the protein is expressed on the cell surface and within the cytoplasm. Immunogold labeling of EEV and INV with MAb 20 demonstrated that the protein was found exclusively on the EEV membrane.     

The cytoplasmic and transmembrane domains of the vaccinia virus B5R protein target a chimeric human immunodeficiency virus type 1 glycoprotein to the outer envelope of nascent vaccinia virions.

The outer envelope of the extracellular form of vaccinia virus (EEV) is derived from the Golgi membrane and contains at least six viral proteins. Transfection studies indicated that the EEV protein encoded by the B5R gene associates with Golgi membranes when synthesized in the absence of other viral products. A domain swapping strategy was then used to investigate the possibility that the B5R protein contains an EEV targeting signal. We constructed chimeric genes encoding the human immunodeficiency virus (HIV) type 1 glycoprotein with the cytoplasmic and transmembrane domains replaced by the corresponding 42-amino-acid C-terminal segment of the B5R protein. Recombinant vaccinia viruses that stably express a chimeric B5R-HIV protein or a control HIV envelope protein with the original cytoplasmic and transmembrane domains were isolated. Cells infected with recombinant vaccinia viruses that expressed either the unmodified or the chimeric HIV envelope protein formed syncytia with cells expressing the CD4 receptor for HIV. However, biochemical and microscopic studies demonstrated that the HIV envelope proteins with the B5R cytoplasmic and transmembrane domains were preferentially targeted to the EEV. These data are consistent with the presence of EEV localization signals in the cytoplasmic and transmembrane domains of the B5R protein.     

Intracellular localization of vaccinia virus extracellular enveloped virus envelope proteins individually expressed using a Semliki Forest virus replicon

The extracellular enveloped virus (EEV) form of vaccinia virus is bound by an envelope which is acquired by wrapping of intracellular virus particles with cytoplasmic vesicles containing trans-Golgi network markers. Six virus-encoded proteins have been reported as components of the EEV envelope. Of these, four proteins (A33R, A34R, A56R, and B5R) are glycoproteins, one (A36R) is a nonglycosylated transmembrane protein, and one (F13L) is a palmitylated peripheral membrane protein. During infection, these proteins localize to the Golgi complex, where they are incorporated into infectious virus that is then transported and released into the extracellular medium. We have investigated the fates of these proteins after expressing them individually in the absence of vaccinia infection, using a Semliki Forest virus expression system. Significant amounts of proteins A33R and A56R efficiently reached the cell surface, suggesting that they do not contain retention signals for intracellular compartments. In contrast, proteins A34R and F13L were retained intracellularly but showed distributions different from that of the normal infection. Protein A36R was partially retained intracellularly, decorating both the Golgi complex and structures associated with actin fibers. A36R was also transported to the plasma membrane, where it accumulated at the tips of cell projections. Protein B5R was efficiently targeted to the Golgi region. A green fluorescent protein fusion with the last 42 C-terminal amino acids of B5R was sufficient to target the chimeric protein to the Golgi region. However, B5R-deficient vaccinia virus showed a normal localization pattern for other EEV envelope proteins. These results point to the transmembrane or cytosolic domain of B5R protein as one, but not the only, determinant of the retention of EEV proteins in the wrapping compartment.     

Vaccinia virus A34 glycoprotein determines the protein composition of the extracellular virus envelope

The outer envelope of the extracellular form of vaccinia virus contains five virus-encoded proteins, F13, A33, A34, A56, and B5, that, with the exception of A56, are implicated in virus egress or infectivity. A34, a type II transmembrane glycoprotein, is involved in the induction of actin tails, the release of enveloped virus from the surfaces of infected cells, and the disruption of the virus envelope after ligand binding prior to virus entry. To investigate interactions between A34 and other envelope proteins, a recombinant vaccinia virus (vA34R_HA) expressing an epitope-tagged version of A34 (A34_HA) was constructed by appending an epitope from influenza virus hemagglutinin to the C terminus of A34. Complexes of A34_HA with B5 and A36, but not with A33 or F13, were detected in vA34R_HA-infected cells. A series of vaccinia viruses expressing mutated versions of the B5 protein was used to investigate the domain(s) of B5 required for interaction with A34. Both the cytoplasmic and the transmembrane domains of B5 were dispensable for binding to A34. Most of the extracellular domain of B5, which contains four short consensus repeats homologous to complement control proteins, was sufficient for A34 interaction, indicating that both proteins interact through their ectodomains. Immunofluorescence experiments on cells infected with A34-deficient virus indicated that A34 is required for efficient targeting of B5, A36, and A33 into wrapped virions. Consistent with this observation, the envelope of A34-deficient virus contained normal amounts of F13 but decreased amounts of A33 and B5 with respect to the parental WR virus. These results point to A34 as a major determinant in the protein composition of the vaccinia virus envelope.     

An attenuated LC16m8 smallpox vaccine: analysis of full-genome sequence and induction of immune protection

The potential threat of smallpox bioterrorism has made urgent the development of lower-virulence vaccinia virus vaccines. An attenuated LC16m8 (m8) vaccine was developed in 1975 from the Lister strain used in the World Health Organization smallpox eradication program but was not used against endemic smallpox. Today, no vaccines can be tested with variola virus for efficacy in humans, and the mechanisms of immune protection against the major intracellular mature virion (IMV) and minor extracellular enveloped virion (EEV) populations of poxviruses are poorly understood. Here, we determined the full-genome sequences of the m8, parental LC16mO (mO), and grandparental Lister (LO) strains and analyzed their evolutionary relationships. Sequence data and PCR analysis indicated that m8 was a progeny of LO and that m8 preserved almost all of the open reading frames of vaccinia virus except for the disrupted EEV envelope gene B5R. In accordance with this genomic background, m8 induced 100% protection against a highly pathogenic vaccinia WR virus in mice by a single vaccination, despite the lack of anti-B5R and anti-EEV antibodies. The immunogenicity and priming efficacy with the m8 vaccine consisting mainly of IMV were as high as those with the intact-EEV parental mO and grandparental LO vaccines. Thus, mice vaccinated with 10(7) PFU of m8 produced low levels of anti-B5R antibodies after WR challenge, probably because of quick clearance of B5R-expressing WR EEV by strong immunity induced by the vaccination. These results suggest that priming with m8 IMV provides efficient protection despite undetectable levels of immunity against EEV.     

The middle hepatitis B virus envelope protein is not necessary for infectivity of hepatitis delta virus.

The hepatitis delta virus (HDV) envelope contains the large (L), middle (M), and small (S) surface proteins encoded by coinfecting hepatitis B virus. Although HDV-like particles can be assembled with only the S protein in the envelope, the L protein is essential for infectivity in vitro (C. Sureau, B. Guerra, and R. Lanford, J. Virol. 67:366-372, 1993). Here, we demonstrate that the M protein, previously described as carrying a site for binding to polymerized human albumin, is not necessary for infectivity. HDV-like particles coated with the S plus L or the S plus M plus L proteins are infectious in primary cultures of chimpanzee hepatocytes. We conclude that the S and L proteins serve two essential functions in the HDV replication cycle; the S protein ensures the export of the HDV genome from an infected cell by forming a particle, and the L protein ensures its import into a human hepatocyte.     

A poxvirus protein with a RING finger motif binds zinc and localizes in virus factories.

Shope fibroma virus (SFV) is a Leporipoxvirus closely related to the highly virulent myxoma virus. The DNA sequence of the BamHI N fragment of the SFV DNA genome was determined, and the single complete open reading frame (N1R) was characterized. The protein encoded by the N1R gene was found to contain a C3HC4 RING finger motif at the C terminus. This C3HC4 motif is the hallmark of a growing family of proteins, many of which are involved in regulation of gene expression, DNA repair, or DNA recombination. Complete homologs of the SFV N1R gene were also detected in variola virus, myxoma virus, and vaccinia virus strain IHD-W. In contrast, the gene is completely absent from vaccinia virus strain Copenhagen, and in vaccinia virus strain WR, the open reading frame is truncated prior to the zinc binding domain because of an 11-bp deletion, thus producing a frameshift and premature stop codon. Recombinant N1R protein from SFV was expressed in Escherichia coli and shown to bind zinc in a specific manner. Using fluorescence microscopy to visualize a peptide epitope tag (derived from ICP27 of herpes simplex virus) fused to the N terminus of the poxvirus proteins, we observed that the N1R protein of SFV and its homologs in myxoma virus and vaccinia virus IHD-W were localized primarily to the virus factories in the cytoplasm of infected cells and, to a lesser degree, the host cell nucleus. The truncated protein of vaccinia virus strain WR failed to localize in this manner but instead was observed throughout the cytoplasm.     

Viral protein synthesis in mouse hepatitis virus strain A59-infected cells: effect of tunicamycin.

We identified eight protein species in virions of mouse hepatitis virus strain A59. Based on their sizes, prosthetic groups, and locations in virions, these proteins were designated gp180/E2, gp90/E2, pp54/N, gp26.5/E1, gp25.5/E1, p24/E1, p22/X, and p14.5/Y. The positions of the last two proteins in virions are not known. Host protein synthesis in Sac(-) cells infected with mouse hepatitis virus strain A59 was inhibited, and the following novel proteins appeared: gp150, gp90, p54, gp26.5, gp25.5, p24, p22, and p14.5. Except for gp150, these polypeptides all co-electrophoresed with mouse hepatitis virus strain A59 structural proteins. In addition, all of these proteins could be immunoprecipitated with a convalescent mouse serum or a rabbit antiserum raised against purified disrupted virus. After a 15-min pulse of infected cells with radioactive amino acids at 7h postinfection, gp90 was not detected, whereas gp26.5 and gp25.5 were only labeled to a small extent. During a subsequent chase period gp150 was processed to gp90, whereas the radioactivity in gp26.5 and gp25.5 increased concomitantly with a reduction of label in p24. Tunicamycin, an antibiotic which inhibits the synthesis of glycopeptides bearing N glycosidically linked oligosaccharides, prevented the appearance of gp150 in mouse hepatitis virus strain A59-infected cells. Instead, a 110,000-dalton protein accumulated. In contrast, the syntheses of the smaller viral glycoproteins gp26.5 and gp25.5 were resistant to this drug, indicating that these glycosylations were of the O glycosidical type. Although the production of infectious virus in tunicamycin-treated cells was inhibited by more than 99%, release of noninfectious viral particles continued. An analysis of these particles revealed that they lacked the peplomeric glycoproteins gp90/E2 and gp180/E2. Obviously, although the surface projections were not essential for budding of virus particles from the cells, they were required for infectivity.     

Functional Analysis of Vaccinia Virus B5R Protein: Essential Role in Virus Envelopment Is Independent of a Large Portion of the Extracellular Domain

Vaccinia virus has two forms of infectious virions: the intracellular mature virus and the extracellular enveloped virus (EEV). EEV is critical for cell-to-cell and long-range spread of the virus. The B5R open reading frame (ORF) encodes a membrane protein that is essential for EEV formation. Deletion of the B5R ORF results in a dramatic reduction of EEV, and as a consequence, the virus produces small plaques in vitro and is highly attenuated in vivo. The extracellular portion of B5R is composed mainly of four domains that are similar to the short consensus repeats (SCRs) present in complement regulatory proteins. To determine the contribution of these putative SCR domains to EEV formation, we constructed recombinant vaccinia viruses that replaced the wild-type B5R gene with a mutated gene encoding a B5R protein lacking the SCRs. The resulting recombinant viruses produced large plaques, indicating efficient cell-to-cell spread in vitro, and gradient centrifugation of supernatants from infected cells confirmed that EEV was formed. In contrast, phalloidin staining of infected cells showed that the virus lacking the SCR domains was deficient in the induction of thick actin bundles. Thus, the highly conserved SCR domains present in the extracellular portion of the B5R protein are dispensable for EEV formation. This indicates that the B5R protein is a key viral protein with multiple functions in the process of virus envelopment and release. In addition, given the similarity of the extracellular domain to complement control proteins, the B5R protein may be involved in viral evasion from host immune responses.     

Two major outer envelope glycoproteins of Epstein-Barr virus are encoded by the same gene.

Two major outer envelope glycoproteins of Epstein-Barr virus, gp350 and gp220, are known to be encoded by 3.2- and 2.5-kilobase RNAs which map to the same DNA fragment (M. Hummel, D. Thorley-Lawson, and E. Kieff, J. Virol. 49:413-417). These RNAs have the same 5' and 3' ends. The larger RNA is encoded by a 2,777-base DNA segment which is preceded by TATTAAA, has AATAAA near its 3' end, and contains a 2,721-base open reading frame. The smaller RNA has one internal splice which maintains the same open reading frame. Translation of the 3.2- and 2.5-kilobase RNAs yielded proteins of 135 and 100 kilodaltons (Hummel et al., J. Virol. 49:413-417). The discrepancy between the 907 codons of the open reading frame and the 135-kilodalton size of the gp350 precursor is due to anomalous behavior of the protein in gel electrophoresis, since a protein translated from most of the Epstein-Barr virus open reading frame in Escherichia coli had similar properties. Antisera raised in rabbits to the protein expressed in E. coli specifically immunoprecipitated gp350 and gp220, confirming the mapping and sequencing results and the translational reading frame. The rabbit antisera also reacted with the plasma membranes of cells that were replicating virus and neutralized virus, particularly after the addition of complement. This is the first demonstration that the primary amino acid sequence of gp350 and gp220 has epitopes which can induce neutralizing antibody. We propose a model for the gp350 protein based on the theoretical analysis of its primary sequence.     

Sequence analysis, expression, and deletion of a vaccinia virus gene encoding a homolog of profilin, a eukaryotic actin-binding protein.

A 4,500-bp BamHI fragment, located within the HindIII A segment of the vaccinia virus genome, was found to contain eight potential coding regions for polypeptides of 78 to 346 amino acids. The open reading frames with 133, 346, and 125 codons were homologous to profilin (an actin-binding protein), 3-beta-hydroxysteroid dehydrogenase, and Cu-Zn superoxide dismutase, respectively. Sequence alignments indicated that the vaccinia virus and mammalian profilins were more closely related to each other than to known profilins of other eukaryotes. The expression and possible role of the profilin homolog in the virus replicative cycle were therefore investigated. Antibody raised to Escherichia coli expressed vaccinia virus profilin was used to demonstrate the synthesis of the 15-kDa polypeptide at late times after vaccinia virus infection of mammalian cells. The protein accumulated in the cytoplasm, but only trace amounts remained associated with highly purified virions. The isolation of vaccinia virus mutants (in strains WR and IHD-J), with nearly the entire profilin gene replaced by the E. coli gpt gene, indicated that the protein is not essential for infectivity. The characteristic vaccinia virus-induced changes in actin fibers, seen by fluorescence microscopy, occurred in cells infected with the mutant. Moreover, the virus-encoded profilin homolog was not required for actin-associated events, including intracellular virus movement to the periphery of the cell, formation of specialized microvilli, or release of mature virions, as shown by electron microscopy and yields of infectious intra- and extracellular virus.