Characterization of intracellular and extracellular vaccinia virus variants: N1-isonicotinoyl-N2-3-methyl-4-chlorobenzoylhydrazine interferes with cytoplasmic virus dissemination and release.

Infectious vaccinia virus can be purified from whole cells by experimentally induced lysis (intracellular virus) or from supernatant growth medium (extracellular virus). Extracellular virus and intracellular virus differed by buoyant density (1.237 versus 1.272 g/cm3), phospholipid content and composition, and polypeptide pattern. Differences in structural polypeptides on the virus surface could be detected by lactoperoxidase-catalyzed radioiodination or Brij treatment. Characteristic of extracellular virus was an additional polypeptide, with a molecular weight of 37,000 (37K), which represented 5 to 7% of the total particle protein. Antibodies to the 37K protein detected only some of the cell-associated particles late in normal infection. Upon treatment of infected cultures with N1-isonicotinoyl-N2-3-methyl-4-chlorobenzoylhydrazine, a drug which prevents vaccinia virus release, no particle-associated 37K protein could be detected. In all other properties tested so far, except for a slight difference in phospholipid composition, the virus obtained in the presence of the drug resembled the normal intracellular virus. N1-Isonicotinoyl-N2-3-methyl-4-chlorobenzoylhydrazine prevented vesicularization of intracellular viral particles. Lack of vesicularization was accompanied by the absence of particle-associated 37K viral protein and seemed to correlate with an inhibition of virus dissemination to the cell periphery.     

Insertional inactivation of the vaccinia virus 32-kilodalton gene is associated with attenuation in mice and reduction of viral gene expression in polarized epithelial cells.

The mechanism of poxvirus attachment to cells is poorly understood. We have identified a 32-kDa envelope protein of vaccinia virus which binds to the surface of cultured cells. This binding is specific and selective (J.-S. Maa, J. F. Rodriguez, and M. Esteban, J. Biol. Chem. 265:22174-22180, 1990; C. Lai, S. Gong, and M. Esteban, J. Virol. 65:499-504, 1991). In this investigation, we studied the effect of inactivating the 32-kDa gene (32K gene) on the biology of vaccinia virus. We show that inactivation of the 32K gene decreases by 80% the mortality of mice infected with 32K- vaccinia virus. This reduction in mortality correlates with diminished viral gene expression in target tissues. In highly polarized epithelial cells, viral gene expression of 32K- virus was reduced (50 to 60%) at both the apical and basolateral surfaces in comparison with a 32K+ virus. Restriction of virus gene expression in polarized cell surfaces occurs for both intracellular and extracellular forms of infectious 32K- vaccinia virus. The two infectious forms of vaccinia virus 32K+ infect polarized cells preferentially by the basolateral surface. Our findings provide evidence of the importance of the 32-kDa protein in viral pathogenesis.     

Delay of vaccinia virus-induced apoptosis in nonpermissive Chinese hamster ovary cells by the cowpox virus CHOhr and adenovirus E1B 19K genes.

The infection of vaccinia virus in Chinese hamster ovary (CHO) cells produces a rapid shutdown in protein synthesis, and the infection is abortive (R.R. Drillien, D. Spehner, and A. Kirn, Virology 111:488-499, 1978; D.E. Hruby, D.L. Lynn, R. Condit, and J.R. Kates, J. Gen. Virol. 47:485-488, 1980). Cowpox virus, which can productively infect CHO cells, had previously been shown to contain a host range gene, CHOhr, which confers on vaccinia virus the ability to replicate in CHO cells (D. Spehner, S. Gillard, R. Drillien, and A. Kirn, J. Virol. 62:1297-1304, 1988). We found that CHO cells underwent apoptosis when infected with vaccinia virus. The expression of the CHOhr gene in vaccinia virus allowed for the expression of late virus genes. CHOhr also delayed or prevented vaccinia virus-induced apoptosis in CHO cells such that there was sufficient time for replication of the virus before the cell died. The E1B 19K gene from adenovirus also delayed vaccinia virus-induced apoptosis; however, there was no detectable expression of late virus genes. Furthermore, E1B 19K also delayed cell death in CHO cells which had been productively infected with vaccinia virus. This study identifies a new antiapoptotic gene from cowpox virus, CHOhr, for which the protein contains an ankyrin-like repeat and shows no significant homology to other proteins. This work also indicates that an antiapoptotic gene from one virus family can delay cell death in an infection of a virus from a different family.     

Vaccinia mature virus fusion regulator A26 protein binds to A16 and G9 proteins of the viral entry fusion complex and dissociates from mature virions at low pH

Vaccinia mature virus enters cells through either endocytosis or plasma membrane fusion, depending on virus strain and cell type. Our previous results showed that vaccinia virus mature virions containing viral A26 protein enter HeLa cells preferentially through endocytosis, whereas mature virions lacking A26 protein enter through plasma membrane fusion, leading us to propose that A26 acts as an acid-sensitive fusion suppressor for mature virus (S. J. Chang, Y. X. Chang, R. Izmailyan R, Y. L. Tang, and W. Chang, J. Virol. 84:8422-8432, 2010). In the present study, we investigated the fusion suppression mechanism of A26 protein. We found that A26 protein was coimmunoprecipitated with multiple components of the viral entry-fusion complex (EFC) in infected HeLa cells. Transient expression of viral EFC components in HeLa cells revealed that vaccinia virus A26 protein interacted directly with A16 and G9 but not with G3, L5 and H2 proteins of the EFC components. Consistently, a glutathione S-transferase (GST)-A26 fusion protein, but not GST, pulled down A16 and G9 proteins individually in vitro. Together, our results supported the idea that A26 protein binds to A16 and G9 protein at neutral pH contributing to suppression of vaccinia virus-triggered membrane fusion from without. Since vaccinia virus extracellular envelope proteins A56/K2 were recently shown to bind to the A16/G9 subcomplex to suppress virus-induced fusion from within, our results also highlight an evolutionary convergence in which vaccinia viral fusion suppressor proteins regulate membrane fusion by targeting the A16 and G9 components of the viral EFC complex. Finally, we provide evidence that acid (pH 4.7) treatment induced A26 protein and A26-A27 protein complexes of 70 kDa and 90 kDa to dissociate from mature virions, suggesting that the structure of A26 protein is acid sensitive.     

Complementation of a poliovirus defective genome by a recombinant vaccinia virus which provides poliovirus P1 capsid precursor in trans.

Defective interfering (DI) RNA genomes of poliovirus which contain in-frame deletions in the P1 capsid protein-encoding region have been described. DI genomes are capable of replication and can be encapsidated by capsid proteins provided in trans from wild-type poliovirus. In this report, we demonstrate that a previously described poliovirus DI genome (K. Hagino-Yamagishi and A. Nomoto, J. Virol. 63:5386-5392, 1989) can be complemented by a recombinant vaccinia virus, VVP1 (D. C. Ansardi, D. C. Porter, and C. D. Morrow, J. Virol. 65:2088-2092, 1991), which expresses the poliovirus capsid precursor polyprotein, P1. Stocks of defective polioviruses were generated by transfecting in vitro-transcribed defective genome RNA derived from plasmid pSM1(T7)1 into HeLa cells infected with VVP1 and were maintained by serial passage in the presence of VVP1. Encapsidation of the defective poliovirus genome was demonstrated by characterizing poliovirus-specific protein expression in cells infected with preparations of defective poliovirus and by Northern (RNA) blot analysis of poliovirus-specific RNA incorporated into defective poliovirus particles. Cells infected with preparations of defective poliovirus expressed poliovirus protein 3CD but did not express capsid proteins derived from a full-length P1 precursor. Poliovirus-specific RNA encapsidated in viral particles generated in cells coinfected with VVP1 and defective poliovirus migrated slightly faster on formaldehyde-agarose gels than wild-type poliovirus RNA, demonstrating maintenance of the genomic deletion. By metabolic radiolabeling with [35S]methionine-cysteine, the defective poliovirus particles were shown to contain appropriate mature-virion proteins. This is the first report of the generation of a pure population of defective polioviruses free of contaminating wild-type poliovirus. We demonstrate the use of this recombinant vaccinia virus-defective poliovirus genome complementation system for studying the effects of a defined mutation in the P1 capsid precursor on virus assembly. Following removal of residual VVP1 from defective poliovirus preparations, processing and assembly of poliovirus capsid proteins derived from a nonmyristylated P1 precursor expressed by a recombinant vaccinia virus, VVP1 myr- (D. C. Ansardi, D. C. Porter, and C. D. Morrow, J. Virol. 66:4556-4563, 1992), in cells coinfected with defective poliovirus were analyzed. Capsid proteins generated from nonmyristylated P1 did not assemble detectable levels of mature virions but did assemble, at low levels, into empty capsids.(ABSTRACT TRUNCATED AT 400 WORDS)     

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 virus-coded nonstructural polypeptides in bunyavirus-infected cells.

Analyses of bunyavirus-infected cell extracts identified at least two virus-induced nonstructural polypeptides. With snowshoe hare (SSH), La Crosse (LAC), and six SSH-LAC reassortant viruses, it was shown that one of these nonstructural polypeptides (NSs, approximate molecular weight, 7.4 X 10(3)) is coded by the SSH small (S)-size viral RNA species. This nonstructural polypeptide was not detected (at least in the same relative abundancies) in LAC virus-infected cells or in cells infected with reassortants having LAC S RNA. For SSH virus, tryptic peptide analyses of either [3H]leucine- or [3H]arginine-labeled NSs indicated that it contains unique sequences not present in the SSH nucleocapsid (N) polypeptide (also coded by the S RNA; J. R. Gentsch and D. H. L. Bishop, J. Virol. 28:417-419, 1978). Analyses of SSH virus-infected cell extracts and extracts of cells infected with SSH-LAC reassortants having SSH medium (M)-size RNA species indicated that a nonstructural polypeptide (NSM; approximate molecular weight, 12 X 10(3)) is coded by the SSH M RNA species. In extracts of LAC virus-infected cells (or cells infected with SSH-LAC reassortants having LAC M RNA), a polypeptide with an electrophoretic mobility slightly faster than that of the SSH NSM polypeptide was observed (approximate molecular weight, 11 X 10(3)); it has been designated LAC NSM. The relationships of the NSM polypeptides to the other M RNA-coded polypeptides (G1 and G2; J. R. Gentsch and D. H. L. Bishop, J. Virol. 30;767-770, 1979) have not been determined. Two additional polypeptides present in both LAC- and SSH-infected cell extracts also appear to be virus induced (one with an approximate molecular weight of 10 X 10(3), p10; the other with an approximate molecular weight of 18 X 10(3), p18). Whether these polypeptides are virus coded has not been determined.     

Wiskott-Aldrich syndrome protein is needed for vaccinia virus pathogenesis

Smallpox, caused by variola virus, was a devastating disease in humans, but how the virus evolved a strategy to spread to tissue remains unknown. Through the use of microarrays, we identified the gene encoding the Wiskott-Aldrich syndrome protein (WASP), one of the five known WASP family members, which has been induced in the course of infection of human cells with different strains of vaccinia virus (VV) (S. Guerra, L. A. Lopez-Fernandez, A. Pascual-Montano, M. Munoz, K. Harshman, and M. Esteban, J. Virol. 77:6493-6506, 2003; S. Guerra, L. A. Lopez-Fernandez, R. Conde, A. Pascual-Montano, K. Harshman, and M. Esteban, J. Virol. 78:5820-5834, 2004). In a mouse model, we evaluated the role of WASP in infection with VV, a close relative of variola virus. WASP(-/-) (KO) mice infected intranasally and intraperitoneally with VV showed reduced weight loss and mortality compared to wild-type (WT) mice. WASP expression correlated with VV replication in the ovaries but not in the liver or spleen. WT mouse macrophages express WASP but not N-WASP; after VV infection, WASP levels increase threefold. KO macrophages lack N-WASP expression and, when VV infected, are incapable of inducing actin tails and producing extracellular virus. These functions were rescued in KO macrophages after ectopic WASP expression. Overall, our findings demonstrate that WASP has a role in orthopoxvirus infections. Use of WASP proteins for virus spread via the actin tail provides a selective advantage for VV, and probably variola virus, dissemination to distant tissues.     

Identification and characterization of an extracellular envelope glycoprotein affecting vaccinia virus egress.

Sequence analysis of the vaccinia virus strain Western Reserve genome revealed the presence of an open reading frame (ORF), SalL4R, which has the potential to encode a transmembrane glycoprotein with homology to C-type animal lectins (G. L. Smith, Y. S. Chan, and S. T. Howard, J. Gen. Virol. 72:1349-1376, 1991). Here we show that the SalL4R gene is transcribed late during infection from a TAAATG motif at the beginning of the ORF. Antisera raised against a TrpE-SalL4R fusion protein identified three glycoprotein species of Mr 22,000 to 24,000 in infected cells. Immunogold electron microscopy demonstrated that SalL4R protein is present in purified extracellular enveloped virus particles but not in intracellular naked virus (INV). A mutant virus was constructed by placing a copy of the SalL4R ORF downstream of an isopropyl-beta-D-thiogalactopyranoside (IPTG)-inducible vaccinia virus promoter within the thymidine kinase locus and subsequently deleting the endogenous SalL4R gene. The growth kinetics of this virus demonstrated that SalL4R was nonessential for the production of infectious INV but was required for virus dissemination. Consistent with this finding, the formation of wild-type-size plaques by this mutant was dependent on the presence of IPTG. Electron microscopy showed that without SalL4R expression, the inability of the virus to spread is due to a lack of envelopment of INV virions by Golgi-derived membrane, a morphogenic event required for virus egress.     

The UL11 gene of herpes simplex virus 1 encodes a function that facilitates nucleocapsid envelopment and egress from cells.

The UL11 gene of herpes simplex virus 1 was reported to encode a myristylated protein (C. A. MacLean, B. Clark, and D. J. McGeoch, J. Gen. Virol. 70:3147-3157, 1989). To determine the function of the gene product, a recombinant virus (R7219) lacking 61% of the codons (176 bp of the 288-bp coding domain) was genetically engineered. The deletion mutant replicated in all cell lines tested, albeit to titers 30- to 250-fold lower than those obtained from cells infected with wild-type virus. Electron microscopic analyses indicated that both full and empty capsids accumulated in the nuclei, juxtaposed with the inner lamellae of the nuclear membranes, and that increased numbers of naked particles were present in the cytoplasm of cells infected with the mutant virus. There was a greater than 1,000-fold decrease in the amount of infectious extracellular virus released from Vero cells infected with the deletion mutant compared with that from cells infected with wild-type virus. Furthermore, the onset of release of infectious virus from cells infected with the UL11- mutant was significantly delayed: levels of extracellular UL11- virus increased 15-fold between 20 and 26 h after infection, while levels of wild-type extracellular virus increased 500-fold between 8 and 14 h after infection. A virus in which the UL11 gene was restored produced wild-type levels of total and extracellular virus and was indistinguishable from wild-type virus upon analysis by electron microscopy. Taken together, the data indicate that the absence of the UL11 gene causes a reduced capacity to envelope and transport virions into the extracellular space.     

Double-labeled rabies virus: live tracking of enveloped virus transport

Here we describe a strategy to fluorescently label the envelope of rabies virus (RV), of the Rhabdoviridae family, in order to track the transport of single enveloped viruses in living cells. Red fluorescent proteins (tm-RFP) were engineered to comprise the N-terminal signal sequence and C-terminal transmembrane spanning and cytoplasmic domain sequences of the RV glycoprotein (G). Two variants of tm-RFP were transported to and anchored in the cell surface membrane, independent of glycosylation. As shown by confocal microscopy, tm-RFP colocalized at the cell surface with the RV matrix and G protein and was incorporated into G gene-deficient virus particles. Recombinant RV expressing the membrane-anchored tm-RFP in addition to G yielded infectious viruses with mosaic envelopes containing both tm-RFP and G. Viable double-labeled virus particles comprising a red fluorescent envelope and a green fluorescent ribonucleoprotein were generated by expressing in addition an enhanced green fluorescent protein-phosphoprotein fusion construct (S. Finke, K. Brzozka, and K. K. Conzelmann, J. Virol. 78:12333-12343, 2004). Individual enveloped virus particles were observed under live cell conditions as extracellular particles and inside endosomal vesicles. Importantly, double-labeled RVs were transported in the retrograde direction over long distances in neurites of in vitro-differentiated NS20Y neuroblastoma cells. This indicates that the typical retrograde axonal transport of RV to the central nervous system involves neuronal transport vesicles in which complete enveloped RV particles are carried as a cargo.     

Essential function of the pseudorabies virus UL36 gene product is independent of its interaction with the UL37 protein

The large tegument protein encoded by the UL36 gene of pseudorabies virus (PrV) physically interacts with the product of the adjacent UL37 gene (B. G. Klupp, W. Fuchs, H. Granzow, R. Nixdorf, and T. C. Mettenleiter, J. Virol. 76:3065-3071, 2002). To analyze UL36 function, two PrV recombinants were generated by mutagenesis of an infectious PrV full-length clone in Escherichia coli: PrV-DeltaUL36F exhibited a deletion of virtually the complete UL36 coding region, whereas PrV-UL36BSF contained two in-frame deletions of 238 codons spanning the predicted UL37 binding domain. Coimmunoprecipitation experiments confirmed that the mutated gene product of PrV-UL36BSF did not interact with the UL37 protein. Like the previously described PrV-DeltaUL37 (B. G. Klupp, H. Granzow, and T. C. Mettenleiter, J. Virol. 75:8927-8936, 2001) but in contrast to PrV-DeltaUL36F, PrV-UL36BSF was able to replicate in rabbit kidney (RK13) cells, although maximum virus titers were reduced ca. 50-fold and plaque diameters were reduced by ca. 45% compared to wild-type PrV. PrV-DeltaUL36F was able to productively replicate after repair of the deleted gene or in a trans-complementing cell line. Electron microscopy of infected RK13 cells revealed that PrV-UL36BSF and phenotypically complemented PrV-DeltaUL36F were capable of nucleocapsid formation and egress from the nucleus by primary envelopment and deenvelopment at the nuclear membrane. However, reenvelopment of nucleocapsids in the cytoplasm was blocked. Only virus-like particles without capsids were released efficiently from cells. Interestingly, cytoplasmic nucleocapsids of PrV-UL36BSF but not of PrV-DeltaUL36F were found in large ordered structures similar to those which had previously been observed with PrV-DeltaUL37. In summary, our results demonstrate that the interaction between the UL36 and UL37 proteins is important but not strictly essential for the formation of secondary enveloped, infectious PrV particles. Furthermore, UL36 possesses an essential function during virus replication which is independent of its ability to bind the UL37 protein.     

Characterization of ts 16, a temperature-sensitive mutant of vaccinia virus.

We have characterized a temperature-sensitive mutant of vaccinia virus, ts16, originally isolated by Condit et al. (Virology 128:429-443, 1983), at the permissive and nonpermissive temperatures. In a previous study by Kane and Shuman (J. Virol 67:2689-2698, 1993), the mutation of ts16 was mapped to the I7 gene, encoding a 47-kDa protein that shows partial homology to the type II topoisomerase of Saccharomyces cerevisiae. The present study extends previous electron microscopy analysis, showing that in BSC40 cells infected with ts16 at the restrictive temperature (40 degrees C), the assembly was arrested at a stage between the spherical immature virus and the intracellular mature virus (IMV). In thawed cryosections, a number of the major proteins normally found in the IMV were subsequently localized to these mutant particles. By using sucrose density gradients, the ts16 particles were purified from cells infected at the permissive and nonpermissive temperatures. These were analyzed by immunogold labelling and negative-staining electron microscopy, and their protein composition was determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. While the ts16 virus particles made at the permissive temperature appeared to have a protein pattern identical to that of wild-type IMV, in the mutant particles the three core proteins, p4a, p4b, and 28K, were not proteolytically processed. Consistent with previous data the sucrose-purified particles could be labelled with [3H]thymidine. In addition, anti-DNA labelling on thawed cryosections suggested that most of the mutant particles had taken up DNA. On thawed cryosections of cells infected at the permissive temperature, antibodies to I7 labelled the virus factories, the immature viruses, and the IMVs, while under restrictive conditions these structures were labelled much less, if at all. Surprisingly, however, by Western blotting (immunoblotting) the I7 protein was present in similar amounts in the defective particles and in the IMVs isolated at the permissive temperature. Finally, our data suggest that at the nonpermissive temperature the assembly of ts16 is irreversibly arrested in a stage at which the DNA is in the process of entering but before the particle has completely sealed, as monitored by protease experiments.     

Mutations in active-site residues of the uracil-DNA glycosylase encoded by vaccinia virus are incompatible with virus viability.

The D4R gene of vaccinia virus encodes a functional uracil-DNA glycosylase that is essential for viral viability (D. T. Stuart, C. Upton, M. A. Higman, E. G. Niles, and G. McFadden, J. Virol. 67:2503-2513, 1993), and a D4R mutant, ts4149, confers a conditional lethal defect in viral DNA replication (A. K. Millns, M. S. Carpenter, and A. M. DeLange, Virology 198:504-513, 1994). The mutant ts4149 protein was expressed in vitro and assayed for uracil-DNA glycosylase activity. Less than 6% of wild-type activity was observed at permissive temperatures, but the ts4149 protein was completely inactive at the nonpermissive temperature. Mutagenesis of the ts4149 gene back to wild type (Arg-179-->Gly) restored full activity. The ts4149 protein was considerably reduced in lysates of cells infected at the permissive temperature, and its activity was undetectable, even in the presence of the uracil glycosylase inhibitor protein, which inhibits the host uracil-DNA glycosylases but not that of vaccinia virus. Thus the ts4149 protein is thermolabile, correlating uracil removal with vaccinia virus DNA replication. Three active-site amino acids of the vaccinia virus uracil-DNA glycosylase were mutated (Asp-68-->Asn, Asn-120-->Val, and His-181-->Leu), producing proteins that were completely defective in uracil excision but still retained the ability to bind DNA. Each mutated D4R gene was transfected into vaccinia virus ts4149-infected cells in order to assess the recombination events that allowed virus survival at 40 degrees C. Genetic analysis and sequencing studies revealed that the only viruses to survive were those in which recombination eliminated the mutant locus. We conclude that the uracil cleavage activity of the D4R protein is essential for its function in vaccinia virus DNA replication, suggesting that the removal of uracil residues plays an obligatory role.     

The envelope G3L protein is essential for entry of vaccinia virus into host cells

The vaccinia virus G3L/WR079 gene encodes a conserved protein with a predicted transmembrane domain. Our proteomic analyses of vaccinia virus revealed that G3L protein is incorporated into intracellular mature virus; however, the function of G3L protein in the vaccinia virus life cycle has not been investigated. In this study, a recombinant vaccinia virus, viG3L, expressing G3L protein under IPTG (isopropyl-beta-d-thiogalactopyranoside) regulation was constructed. Under permissive conditions when G3L protein was expressed, the vaccinia virus life cycle proceeded normally, resulting in plaque formation in BSC40 cells. In contrast, under nonpermissive conditions when G3L protein expression was repressed, no plaques were formed, showing that G3L protein is essential for vaccinia virus growth in cell cultures. In infected cells when G3L protein was not expressed, the formation of intracellular mature virus (IMV) and cell-associated enveloped virus occurred normally, showing that G3L protein is not required for virion morphogenesis. IMV particles containing (G3L(+)) or lacking (G3L(-)) G3L protein were purified and were found to be indistinguishable on microscopic examination. Both G3L(+) and G3L(-) IMV bound to HeLa cells; however, G3L(-) IMV failed to enter the cells, showing that G3L protein is required for IMV penetration into cells. Finally, G3L protein was required for fusion of the infected cells under low-pH treatment. Thus, our results provide direct evidence that G3L is an essential component of the vaccinia virus fusion complex, in addition to the previously reported A28, H2, L5, A21, and A16 proteins.     

Cloning of the vaccinia virus ribonucleotide reductase small subunit gene. Characterization of the gene product expressed in Escherichia coli.

During its infectious cycle, vaccinia virus expresses a virus-encoded ribonucleotide reductase which is distinct from the host cellular enzyme (Slabaugh, M.B., and Mathews, C.K. (1984) J. Virol. 52, 501-506; Slabaugh, M.B., Johnson, T.L., and Mathews, C.K. (1984) J. Virol. 52, 507-514). We have cloned the gene for the small subunit of vaccinia virus ribonucleotide reductase (designated VVR2) into Escherichia coli and expressed the protein using a T7 RNA polymerase plasmid expression system. After isopropyl beta-D-thiogalactopyranoside induction, accumulation of a 37-kDa peptide was detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and this peptide reacted with polyclonal antiserum raised against a TrpE-VVR2 fusion protein. The 37-kDa protein was purified to homogeneity, and gel filtration of the purified protein revealed that the recombinant protein existed as a dimer in solution. Purified recombinant VVR2 protein was shown to complement the activity of purified recombinant ribonucleotide reductase large subunit, with a specific activity that was similar to native VVR2 from a virus-infected cell extract. A CD spectrum of the recombinant viral protein showed that like the mouse protein, the vaccinia virus protein has 50% alpha-helical structure. Like other iron-containing ribonucleotide reductase small subunits, recombinant VVR2 protein contained a stable organic free radical that was detectable by EPR spectroscopy. The EPR spectrum of purified recombinant VVR2 was identical to that of vaccinia virus-infected mammalian cells. Both the hyperfine splitting character and microwave saturation behavior of VVR2 were similar to those of mouse R2 and distinct from E. coli R2. By using amino acid analysis to determine the concentration of VVR2, we determined that approximately 0.6 radicals were present per R2 dimer. Our results indicate that vaccinia virus small subunit is similar to mammalian ribonucleotide reductases.