Biogenesis of vaccina: interrelationship between post-translational cleavage, virus assembly, and maturation

Vaccinia virus proteolysis--a review

It is well known that viruses, as obligate intracellular parasites, must use their hosts' metabolic machinery in order to replicate their genomes and form infectious progeny virions. What is less well known are the details of how viruses make sure that once all the necessary proteins are made, that they assume the correct configuration at the proper time in order to catalyse the efficient assembly of infectious virions. One of the methods employed by viruses to regulate this process is the proteolytic cleavage of viral proteins. Over the past several decades, studies in numerous laboratories have demonstrated that morphogenic proteolysis plays a major and essential role during the assembly and maturation of infectious poxvirus virions. In this review we describe the history of vaccinia virus proteolysis as a prototypic viral system.

Development of an in vitro cleavage assay system to examine vaccinia virus I7L cysteine proteinase activity

Through the use of transient expression assays and directed genetics, the vaccinia virus (VV) I7L gene product has been implicated as the major maturational proteinase required for viral core protein cleavage to occur during virion assembly. To confirm this hypothesis and to enable a biochemical examination of the I7L cysteine proteinase, an in vitro cleavage assay was developed. Using extracts of VV infected cells as the source of enzyme, reaction conditions were developed which allowed accurate and efficient cleavage of exogenously added core protein precursors (P4a, P4b and P25K). The cleavage reaction proceeded in a time-dependent manner and was optimal when incubated at 25°C. I7L-mediated cleavage was not affected by selected inhibitors of metalloproteinases, aspartic acid proteinases or serine proteinases (EDTA, pepstatin, and PMSF, respectively), but was sensitive to several general cysteine proteinase inhibitors (E-64, EST, Iodoacetic acid, and NEM) as well as the I7L active site inhibitor TTP-6171 [C. Byrd et al., J. Virol. 78:12147–12156 (2004)]. Finally, in antibody pull down experiments, it could be demonstrated that monospecific αI7L serum depleted the enzyme activity whereas control sera including αG1L, directed against the VV metalloproteinase, did not. Taken together, these data provide biochemical evidence that I7L is a cysteine proteinase which is directly involved in VV core protein cleavage. Furthermore, establishment of this I7L-mediated in vitro cleavage assay should enable future studies into the enzymology and co-factor requirements of the proteolysis reaction, and facilitate antiviral drug development against this essential target.

Molecular dissection of the vaccinia virus I7L core protein proteinase

The vaccinia virus I7L gene product is predicted to be a cysteine proteinase and is demonstrated in this study to be responsible for cleavage of each of the three major core protein precursors (P4a, P4b, and P25K) in vivo. Mutagenesis of the putative catalytic triad of I7L or of the cleavage sites in the core protein precursors inhibits processing. A truncated protein lost the ability to cleave the core protein precursors.

Identification by electron microscopy of the maturation steps in vaccinia virus morphogenesis inhibited by the interferon-induced enzymes, protein kinase (PKR), 2-5A synthetase, and nitric oxide synthase (iNOS)

Interferons (IFN) play a major role as a first-line host defense mechanism against viral infections. As treatment of animal cells with IFN induces a large number of genes, it has been difficult to assign the role of these genes in the antiviral action of IFN. Vaccinia virus (VV) is an ideally suited system to study IFN action because all steps in viral morphogenesis can be followed easily by electron microscopy (EM) of ultrathin sections from infected cells. To define the role of IFN-induced genes in viral morphogenesis, we have independently expressed from VV recombinants in primary chicken embryo fibroblast (CEF) cells each of the three IFN-induced genes encoding protein kinase (PKR), 2-5A synthetase, and inducible nitric oxide synthase (iNOS). By EM analysis, we have identified the steps in VV morphogenesis that are affected by each of the IFN-induced enzymes in comparison with untreated and IFN-treated cells. We found that in cells pretreated with IFN and infected with VV, immature virus (IV) is formed, but further stages of maturation are blocked. In cells infected with a VV recombinant expressing PKR (VV-PKR), there is severe inhibition on virus factories, and only few IV are formed. In cells infected with a VV recombinant expressing 2-5A synthetase (VV-2-5A), VV assembly is inhibited at or after IV formation. In cells infected with a VV recombinant expressing iNOS (VV-iNOS), all stages in VV morphogenesis are observed but with aberrant forms. In addition to the effects on viral assembly, in cells infected with either VV-PKR, VV-2-5AS, or VV-iNOS, there is nucleus condensation characteristic of apoptosis. Our findings have identified the steps in VV morphogenesis inhibited by PKR, 2-5A, and iNOS, provided a distinction between these effects, and highlighted a functional redundancy of the IFN system to block viral infection and to induce apoptosis.

The vaccinia virus 39-kDa protein forms a stable complex with the p4a/4a major core protein early in morphogenesis

The vaccinia virus (VV) 39-kDa protein, the product of the A4L gene, is a highly antigenic protein of the viral core. Pulse-chase and immunoprecipitation experiments have shown that the 39-kDa protein interacts with p4a (encoded by the A10L gene), the precursor of the most abundant virion protein. This interaction is maintained with the processed 4a form that arises during virion maturation. The controlled disruption of mature viral particles showed that the 39-kDa and 4a proteins are tightly bound within the virion. Immunoelectron microscopy showed that both proteins first localize within the cytoplasm and later accumulate inside the viral factories, reaching these locations via a mechanism apparently unrelated to cellular membranes. Double labeling experiments showed a colocalization of both proteins in all virus-induced structures.

Vaccinia virus WR gene A5L is required for morphogenesis of mature virions

The vaccinia virus WR A5L open reading frame (corresponding to open reading frame A4L in vaccinia virus Copenhagen) encodes an immunodominant late protein found in the core of the vaccinia virion. To investigate the role of this protein in vaccinia virus replication, we have constructed a recombinant virus, vA5Li, in which the endogenous gene has been deleted and an inducible copy of the A5 gene dependent on isopropyl-beta-D-thiogalactopyranoside (IPTG) for expression has been inserted into the genome. In the absence of inducer, the yield of infectious virus was dramatically reduced. However, DNA synthesis and processing, viral protein expression (except for A5), and early stages in virion formation were indistinguishable from the analogous steps in a normal infection. Electron microscopy revealed that the major vaccinia virus structural form present in cells infected with vA5Li in the absence of inducer was immature virions. Viral particles were purified from vA5Li-infected cells in the presence and absence of inducer. Both particles contained viral DNA and the full complement of viral proteins, except for A5, which was missing from particles prepared in the absence of inducer. The particles prepared in the presence of IPTG were more infectious than those prepared in its absence. The A5 protein appears to be required for the immature virion to form the brick-shaped intracellular mature virion.

A vaccinia virus core protein, p39, is membrane associated

We describe herein the characterization of p39, the product of the A4L gene of vaccinia virus. By immunolabelling of thawed cryosections from infected HeLa cells, we show that this protein is initially located in the central region, or viroplasm, of the viral factories, as well as in the immature virions, with very small amounts of labelling observed on the surrounding membranes. The localization of p39 changes dramatically during the transition of the immature virion to the intracellular mature virus (IMV), coincident with the appearance of the core structure in the center of the IMV, with p39 located between this core and the surrounding membranes. Complementary biochemical data, such as partitioning into the Triton X-114 detergent phase and stripping of the viral membranes with Nonidet P-40 and dithiothreitol, suggest that p39 is associated with the innermost of the two membranes surrounding the core. Sodium carbonate treatment also indicates that p39 is associated with membranes, even at the early stages of viral assembly. However, following in vitro translation of p39 in the presence of microsomal membranes, we failed to detect any association of the independently expressed protein with membranes. We also failed to detect any posttranslational acylation of p39 with myristate or palmitate, suggesting that p39 does not achieve its membrane association through lipid anchors. Therefore, p39 is most likely membrane associated through an interaction with an integral membrane protein(s) present in the innermost of the two membranes surrounding the IMV. These data, together with our recent data showing that p39 colocalizes with the spike-like protrusions on the IMV core (N. Roos, M. Cyrklaff, S. Cudmore, R. Blasco, J. Krijnse-Locker, and G. Griffiths, EMBO J. 15:2343-2355, 1996), suggest that p39 may form part of this spike and that it possibly functions as a matrix-like linker protein between the core and the innermost of the two membranes surrounding the IMV.

A rabbitpox virus serpin gene controls host range by inhibiting apoptosis in restrictive cells

Poxviruses are unique among viruses in encoding members of the serine proteinase inhibitor (serpin) superfamily. Orthopoxviruses contain three serpins, designated SPI-1, SPI-2, and SPI-3. SPI-1 encodes a 40-kDa protein that is required for the replication of rabbitpox virus (RPV) in PK-15 or A549 cells in culture (A. N. Ali, P. C. Turner, M. A. Brooks, and R. W. Moyer, Virology 202:305-314, 1994). Examination of nonpermissive human A549 cells infected with an RPV mutant disrupted in the SPI-1 gene (RPV delta SPI-1) suggests there are no gross defects in protein or DNA synthesis. The proteolytic processing of late viral structural proteins, a feature of orthopoxvirus infections associated with the maturation of virus particles, also appears relatively normal. However, very few mature virus particles of any kind are produced compared with the level found in infections with wild-type RPV. Morphological examination of RPV delta SPI-1-infected A549 cells, together with an observed fragmentation of cellular DNA, suggests that the host range defect is associated with the onset of apoptosis. Apoptosis is seen only in RPV delta SPI-1 infection of nonpermissive (A549 or PK-15) cells and is absent in all wild-type RPV infections and RPV delta SPI-2 mutant infections examined to date. Although the SPI-1 gene is expressed early, before DNA replication, the triggering apoptotic event occurs late in the infection, as RPV delta SPI-1-infected A549 cells do not undergo apoptosis when infections are carried out in the presence of cytosine arabinoside. While the SPI-2 (crmA) gene, when transfected into cells, has been shown to inhibit apoptosis, our experiments provide the first indication that a poxvirus serpin protein can inhibit apoptosis during a poxvirus infection.

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.

A transcriptionally controlled trans-processing assay: putative identification of a vaccinia virus-encoded proteinase which cleaves precursor protein P25K

Vaccinia virus maturation into infectious particles appears to be dependent on the proteolytic processing of at least five viral proteins, each containing a conserved AG*X cleavage motif and each requiring proper association with the previrion particle. To identify the responsible proteinase, a transcriptionally controlled trans-processing assay was developed to monitor cleavage at the permissive AG*S site of the P25K core protein precursor. This assay led to the putative identification of a VV proteinase encoded by open reading frame G1L. The predicted protein contains an HXXEH sequence which is a direct inversion of the active site consensus sequence present in thermolysin and other metalloendopeptidases. Site-directed mutation of this consensus sequence suggests that the G1L protein may be a novel, virus-encoded metalloendoproteinase, although confirmation of this activity must await the development of a suitable cell-free processing assay.

Isolation and analysis of vaccinia virus previrions

Vaccinia virus (VV) virion morphogenesis is a complex sequence of events that occurs late in viral infection that is essential for the production of mature progeny. Electron microscopy studies have identified multiple morphogenic forms of virus particles, apparently assembled in a sequence from immature to mature particles that correlates with distinct physical changes. This assembly process is, however, rather poorly understood at the molecular level. To better characterize the multiple forms of VV previrions, sucrose log gradient fractionation of VV-infected cells was used to separate radiolabeled immature and mature forms of the virus. Depending on time postinfection that the infected cells were harvested, four distinct peaks of acid-precipitable counts could be detected that displayed different rates of sedimentation. Using pulse-chase analysis procedures, the labeled peaks were shown to have precursor-product relationships as slower sedimenting entities chased to faster sedimenting ones with time. These peaks were referred to as A, B, C, and V particles, with A being the initial precursor form found near the top of the gradient and V being the fastest sedimenting product. As the previrions mature, they migrated faster in the gradient and became infectious and resistant to treatment with DNase I. The core protein composition of the A particles was predominantly uncleaved precursors, with only small amounts of the mature core proteins 4a, 4b, 25K, and 23K evident. However, as the sedimentation rate of the particles increased, proteolytic maturation proceeded such that C particles were composed almost exclusively of mature core proteins. Together these results indicate that several distinct and separable forms of VV previrions exist, that VV core protein precursors are associated with the previrions prior to cleavage, and that maturation of the core proteins is coordinately linked to the conversion from noninfectious previrions to infectious viral particles.

Further characterization of an adenosine-containing modification of vaccinia virus proteins

Three vaccinia virus (VV) core proteins which become labeled when virus is grown in the presence of radiolabeled adenosine or orthophosphate were identified as the major viral core proteins 4A, 4B, and 25K on the basis of comigration with [35S]methionine-labeled viral proteins and immunoprecipitation with monospecific polyclonal antisera. Boronate affinity chromatography and HPLC analysis suggested that a cis-diol-containing adenosine compound is present on this set of viral proteins. The replication of VV in tissue culture cells was prevented by the ADP-ribosylation inhibitors nicotinamide (NIC), 3-aminobenzamide (3-AB), and meta-iodobenzylguanidine (MIBG). None of these compounds significantly affected viral DNA synthesis at lower drug concentrations, although at higher concentrations of the three drugs a reduction in viral DNA synthesis was evident. Total VV protein synthesis also decreased at higher inhibitor levels, and the proteolytic processing of the major virion core proteins was greatly diminished as well. The three inhibitors also affected labeling of viral core proteins and cellular histone proteins by [8-14C]adenosine. In addition, mature, infectious virus particles were not formed in the presence of either 60 mM NIC or 3-AB, or 0.6 mM MIBG. These results provide evidence that the major VV core proteins are subject to modification by an adenosine compound, and suggest the possibility that this modification might represent ADP-ribosylation.

A temperature-sensitive lesion in the small subunit of the vaccinia virus-encoded mRNA capping enzyme causes a defect in viral telomere resolution

Using pulsed-field gel electrophoresis, we demonstrated that the temperature-sensitive (ts) conditional lethal mutant ts9383 is, at the nonpermissive temperature, defective in the resolution of concatemeric replicative intermediate DNA to linear 185-kb monomeric DNA genomes. The resolution defect was shown to be the result of a partial failure of the mutant virus to convert the replicated form of the viral telomere to hairpin termini. In contrast to other mutants of this phenotype, pulse-labeling of viral proteins at various times postinfection revealed no obvious difference in the quantity or temporal appearance of members of the late class of polypeptides. Using the marker rescue technique, we localized the ts lesion in ts9383 to an approximately 1-kb region within the HindIII D fragment. Both the ts phenotype and the resolution defect were shown to be caused by a single-base C----T point mutation resulting in the conversion of the amino acid proline to serine in codon 23 of open reading frame D12. This gene encodes a 33-kDa polypeptide which is known to be the small subunit of the virus-encoded mRNA capping enzyme (E. G. Niles, G. J. Lee-Chen, S. Shuman, B. Moss, and S. S. Broyles, Virology 172:513-522, 1989). The data are consistent with a role for this capping enzyme subunit during poxviral telomere resolution.

A single nucleotide substitution in the 5'-untranslated region of the vaccinia N2L gene is responsible for both alpha-amanitin-resistant and temperature-sensitive phenotypes

The locus responsible for encoding resistance to alpha-amanitin was previously mapped to the vaccinia virus (VV) HindIII N fragment by using cloned wild-type VV DNA fragments to rescue the ability of an alpha-amanitin-resistant/temperature-sensitive VV mutant (alpha rts7) to replicate under nonpermissive conditions. DNA sequencing and transcriptional analyses of this region identified two leftward-reading open reading frames (ORFs), N2L and M1L, as candidates to encode the protein responsible for eliciting both phenotypes. In the present study, high-resolution marker rescue mapping and genomic sequencing techniques have been applied to identify the nature of the mutation within the HindIII N region of the alpha rts7 genome. Interestingly, a single G to T transversion mutation was noted at position -10 relative to the initiator ATG of the N2L ORF. Since transcription of the N2L gene starts at position -12/-13, this places the alpha rts7 mutation within the 5'-untranslated leader of the N2L transcript expressed early in infection and suggests that the transcriptional efficiency, mRNA stability, or translational efficiency must be altered in the mutant RNA. These results identify the N2L ORF as the gene responsible for conferring resistance to alpha-amanitin in the alpha rts7 mutant and suggest that the N2L gene product is the viral function that interacts with the host cell nucleus during VV infection.

Poxvirus pathogenesis

Poxviruses are a highly successful family of pathogens, with variola virus, the causative agent of smallpox, being the most notable member. Poxviruses are unique among animal viruses in several respects. First, owing to the cytoplasmic site of virus replication, the virus encodes many enzymes required either for macromolecular precursor pool regulation or for biosynthetic processes. Second, these viruses have a very complex morphogenesis, which involves the de novo synthesis of virus-specific membranes and inclusion bodies. Third, and perhaps most surprising of all, the genomes of these viruses encode many proteins which interact with host processes at both the cellular and systemic levels. For example, a viral homolog of epidermal growth factor is active in vaccinia virus infections of cultured cells, rabbits, and mice. At least five virus proteins with homology to the serine protease inhibitor family have been identified and one, a 38-kDa protein encoded by cowpox virus, is thought to block a host pathway for generating a chemotactic substance. Finally, a protein which has homology with complement components interferes with the activation of the classical complement pathway. Poxviruses infect their hosts by all possible routes: through the skin by mechanical means (e.g., molluscum contagiosum infections of humans), via the respiratory tract (e.g., variola virus infections of humans), or by the oral route (e.g., ectromelia virus infection of the mouse). Poxvirus infections, in general, are acute, with no strong evidence for latent, persistent, or chronic infections. They can be localized or systemic. Ectromelia virus infection of the laboratory mouse can be systemic but inapparent with no mortality and little morbidity, or highly lethal with death in 10 days. On the other hand, molluscum contagiosum virus replicates only in the stratum spinosum of the human epidermis, with little or no involvement of the dermis, and does not spread systemically from the site of infection. The host response to infection is progressive and multifactorial. Early in the infection process, interferons, the alternative pathway of complement activation, inflammatory cells, and natural killer cells may contribute to slowing the spread of the infection. The cell-mediated response involving learned cytotoxic T lymphocytes and delayed-type hypersensitivity components appears to be the most important in recovery from infection. A significant role for specific antiviral antibody and antibody-dependent cell-mediated cytotoxicity has yet to be demonstrated in recovery from a primary infection, but these responses are thought to be important in preventing reinfection.

Orthopoxvirus genetics

Genetic analysis of orthopoxviruses has contributed substantially to our understanding of the functional organization of the poxvirus genome, and individual mutants provide invaluable tools for future studies of poxvirus biology. Deletion and transposition mutants, localized primarily in the termini of the genome, may be particularly useful for studying virus host range and pathogenicity. Numerous drug resistant and dependent mutants provide keys to understanding a wide variety of virus genes. A large number of well-characterized ts mutants, clustered in the center of the virus genome, are taking on an increasingly important role in research on the function of essential poxvirus genes. Genetic characterization of orthopoxviruses has progressed rapidly during the past decade, and one can reasonably anticipate a time when mutants will be available for the study of any poxvirus gene. Considerable progress toward this goal can be achieved through organized attempts to integrate and further characterize existing mutant collections and through the continued isolation and characterization of deletion, drug resistant, and ts mutants using established techniques. The most exciting possibility is that soon techniques will be available for directed mutagenesis to conditional lethality of any essential poxvirus gene.

Detailed phenotypic characterization of five temperature-sensitive mutants in the 22- and 147-kilodalton subunits of vaccinia virus DNA-dependent RNA polymerase

We have carried out detailed phenotypic characterization of five temperature-sensitive (ts) mutants of vaccinia virus, the ts lesions of which have previously been mapped to two different subunits of the viral RNA polymerase. We have also attempted to determine the mechanism of temperature sensitivity in these mutants. Phenotypic characterization of each of the mutants showed that at the nonpermissive temperature, all five mutants exhibited normal levels of early viral mRNA and protein synthesis, but for an extended period of time, all mutants accumulated normal levels of DNA in abnormally large pools in the cell cytoplasm; all mutants were defective in the synthesis of late viral mRNA and proteins and in viral morphogenesis. In an attempt to address the mechanism of temperature sensitivity in these mutants, we measured the effect of a temperature shift on the ability of the mutants to direct late viral protein synthesis. If infected cells were shifted down from a nonpermissive temperature late during infection, late protein synthesis was initiated after a lag period of 1 to 2 h. If infected cells were shifted up from a permissive temperature early during infection, late protein synthesis continued to be defective. If infected cells were shifted up to the nonpermissive temperature after late protein synthesis had commenced, late protein synthesis was maintained at the nonpermissive temperature at the level observed when the temperature was shifted up. We interpret these results to mean that once a functional RNA polymerase has been assembled at the permissive temperature during a mutant infection, it remains functional at the nonpermissive temperature, but that the ts mutants are defective in the assembly of a newly synthesized RNA polymerase at the nonpermissive temperature. This interpretation implies that the virion RNA polymerase is responsible for early viral transcription and that a newly synthesized RNA polymerase transcribes late viral genes.

Identification of antigenic determinants by polyclonal and hybridoma antibodies induced during the course of infection by vaccinia virus

In order to extend the understanding of determinants involved in the humoral response in the infected host, mice were subjected to an immunization regimen using both active and uv-killed vaccinia virus. The spectrum of antibody specificity in hyperimmune sera was followed by Western blotting. Comparable studies involving Western blotting and immunofluorescence were conducted with a panel of monoclonal antibodies derived from hybridomas selected from similarly immunized animals. Hyperimmune sera contained circulating antibodies primarily against three polypeptides of 28K, 35K, and 62K. These antigens were shown to be located both at the surface and within the virion. The repertoire of monoclonal antibodies included some that reacted with the 28K and 35K antigens and others that recognized a 32K core complex component or a nonvirion cell surface component, corresponding to the viral hemagglutinin. Within the panel of monoclonal antibodies was a large group which reacted with a 32K antigen found in the IHD-J virion but absent from the IHD-W strain. This finding correlates with the absence of a 32K polypeptide from the IHD-W particle. Overall, the current findings reveal the absence of any particular correlation between the incidence of polyclonal antibodies in the circulation of the immune host and the frequency of selected hybridomas against vaccinia antigens. Application of this type of immunological analysis should provide useful data concerning the detection and mapping of the antigens and their epitopes which are significant for humoral immunity.

The morphogenesis of Yaba monkey tumor virus in a cynomolgus monkey kidney cell line

The morphogenesis of Yaba monkey tumor virus (YMTV) was investigated in a cynomolgus monkey kidney cell line. YMTV has been shown to grow less rapidly in high-passage cells (i.e., 65 passages) than in low-passage cells (i.e., between 30 and 60 passages). This prolonged growth cycle in high-passage cells allows for a more detailed analysis of the events in morphogenesis. Samples of YMTV-infected cells were prepared for analysis at 2, 3, 4, and 5 days postinfection. At least 12 "stages" of virus morphogenesis can be identified.

Isolation, characterization, and physical mapping of temperature-sensitive mutants of vaccinia virus

Thirty-nine new temperature-sensitive mutants of vaccinia virus have been isolated, expanding a previously reported collection of mutants (R. C. Condit and A. Motyczka, Virology 113, 224-241, 1981) to a total of 65. The 65 mutants have been assigned to 32 complementation groups, based primarily on a qualitative spot test described previously (Condit and Motyczka, 1981). Representatives of each complementation group have been assayed for DNA and protein synthesis at the nonpermissive temperature, revealing one new DNA-negative complementation group, three new groups which contain mutants defective in late protein synthesis, and ten new groups containing mutants which synthesize DNA and protein in a normal fashion. Marker rescue has been achieved with 29 of the 65 mutants using cloned DNA fragments from wild-type virus. These 29 mutants together represent 20 of the 32 complementation groups. A preliminary physical map of the mutants is presented.

Biochemical and genetic characterization of vaccinia virus temperature-sensitive mutants with DNA- and DNAf-phenotypes

Eighty temperature-sensitive (ts) mutants of vaccinia virus were examined for defects in synthesis of DNA. Nine ts mutants were incapable of synthesizing DNA at the restrictive temperature of 39.5 degrees C (DNA- mutants). Biochemical and genetic data indicate that all 9 DNA- mutants carry mutations in different genes. Temperature shift-up experiments have shown that 6 ts mutants with the DNA- phenotype have mutations in the genes coding for the proteins directly associated with vaccinia DNA synthesis. Temperature shift-down experiments in the presence of cytosine arabinoside revealed 5 ts mutants capable of synthesizing DNA at the elevated temperature, but this DNA failed to form infectious virions. These ts mutants were designated as DNAf- mutants. Pulse-chase experiments for the DNAf- mutant 1877 revealed that viral DNA produced at 39.5 degrees C was incapable of entering into mature virions or any subviral particles. Based on the data for recombination among ts mutants with the DNA- and DNAf- phenotype a tentative genetic map was constructed.