Genetic map of the vaccinia virus HindIII D Fragment

LINE-1 retrotransposons facilitate horizontal gene transfer into poxviruses

There is ample phylogenetic evidence that many critical virus functions, like immune evasion, evolved by the acquisition of genes from their hosts through horizontal gene transfer (HGT). However, the lack of an experimental system has prevented a mechanistic understanding of this process. We developed a model to elucidate the mechanisms of HGT into vaccinia virus, the prototypic poxvirus. All identified gene capture events showed signatures of long interspersed nuclear element-1 (LINE-1)-mediated retrotransposition, including spliced-out introns, polyadenylated tails, and target site duplications. In one case, the acquired gene integrated together with a polyadenylated host U2 small nuclear RNA. Integrations occurred across the genome, in some cases knocking out essential viral genes. These essential gene knockouts were rescued through a process of complementation by the parent virus followed by nonhomologous recombination during serial passaging to generate a single, replication-competent virus. This work links multiple evolutionary mechanisms into one adaptive cascade and identifies host retrotransposons as major drivers for virus evolution.

Poxvirus Recombination

Genetic recombination is used as a tool for modifying the composition of poxvirus genomes in both discovery and applied research. This review documents the history behind the development of these tools as well as what has been learned about the processes that catalyze virus recombination and the links between it and DNA replication and repair. The study of poxvirus recombination extends back to the 1930s with the discovery that one virus can reactivate another by a process later shown to generate recombinants. In the years that followed it was shown that recombinants can be produced in virus-by-virus crosses within a genus (e.g., variola-by-rabbitpox) and efforts were made to produce recombination-based genetic maps with modest success. The marker rescue mapping method proved more useful and led to methods for making genetically engineered viruses. Many further insights into the mechanism of recombination have been provided by transfection studies which have shown that this is a high-frequency process associated with hybrid DNA formation and inextricably linked to replication. The links reflect the fact that poxvirus DNA polymerases, specifically the vaccinia virus E9 enzyme, can catalyze strand transfer in in vivo and in vitro reactions dependent on the 3′-to-5′ proofreading exonuclease and enhanced by the I3 replicative single-strand DNA binding protein. These reactions have shaped the composition of virus genomes and are modulated by constraints imposed on virus–virus interactions by viral replication in cytoplasmic factories. As recombination reactions are used for replication fork assembly and repair in many biological systems, further study of these reactions may provide new insights into still poorly understood features of poxvirus DNA replication.

Vaccinia virus particles mix inefficiently, and in a way that would restrict viral recombination, in coinfected cells

It is well established that poxviruses are subjected to genetic recombination, but attempts to map vaccinia virus genes using classical genetic crosses were historically confounded by high levels of experimental noise and a poor correlation between physical and genetic map distances. These virus-by-virus crosses also never produced the 50% recombinant progeny that should be seen in experiments involving distant markers. Poxviruses replicate in membrane-wrapped cytoplasmic structures called virosomes (or factories) and we have developed a method for tracking the development of these structures using live cell imaging and cells expressing phage lambda Cro protein fused to enhanced green fluorescent protein (EGFP). The EGFP-cro protein binds nonspecifically to DNA and permits live cell imaging of developing vaccinia virus factories. Using this method, we see virosomes first appearing about 4 to 5 h postinfection. The early virosomes exhibit a compact appearance and then, after a period of exponential growth lasting several hours, blur and start to dissipate in a process presumably linked to viral packaging. During the growth period, the virosomes migrate toward the nuclear periphery while colliding and fusing at a rate dependent upon the numbers of infecting particles. However, even at high multiplicities of infection (10 PFU/cell), we estimate approximately 20% of the virosomes never fuse. We have also used fluorescence in situ hybridization (FISH) methods to study virosomes formed by the fusion of viruses carrying different gene markers. FISH showed that DNA mixes rather poorly within fused virosomes and the amount of mixing is inversely dependent on the time between virosome appearance and fusion. Our studies suggest that the intracellular movement and mixing of virosomes create constraints that reduce opportunities for forming recombinants and that these phenomena create outcomes reflected in classical poxvirus genetics.

Products and substrate/template usage of vaccinia virus DNA primase

Vaccinia virus encodes a 90-kDa protein conserved in all poxviruses, with DNA primase and nucleoside triphosphatase activities. DNA primase products, synthesized with a single stranded varphiX174 DNA template, were resolved as dinucleotides and long RNAs on denaturing polyacrylamide and agarose gels. Following phosphatase treatment, the dinucleotides GpC and ApC in a 4:1 ratio were identified by nearest neighbor analysis in which (32)P was transferred from [alpha-(32)P]CTP to initiating purine nucleotides. Differences in the nucleotide binding sites for initiation and elongation were suggested by the absence of CpC and UpC dinucleotides as well as the inability of deoxynucleotides to mediate primer synthesis despite their incorporation into mixed RNA/DNA primers. Strong primase activity was detected with an oligo(dC) template. However, there was only weak activity with an oligo(dT) template and none with oligo(dA) or oligo(dG). The absence of stringent template specificity is consistent with a role for the enzyme in priming DNA synthesis at the replication fork.

Determinants of vaccinia virus early gene transcription termination

Vaccinia virus early gene transcription requires the vaccinia termination factor, VTF, nucleoside triphosphate phosphohydrolase I, NPH I, ATP, the virion RNA polymerase, and the motif, UUUUUNU, in the nascent RNA, found within 30 to 50 bases from the poly A addition site, in vivo. In this study, the relationships among the vaccinia early gene transcription termination efficiency, termination motif specificity, and the elongation rate were investigated. A low transcription elongation rate maximizes termination efficiency and minimizes specificity for the UUUUUNU motif. Positioning the termination motif over a 63 base area upstream from the RNA polymerase allowed efficient transcript release, demonstrating a remarkable plasticity in the transcription termination complex. Efficient transcript release was observed during ongoing transcription, independent of VTF or UUUUUNU, but requiring both NPH I and either ATP or dATP. This argues for a two step model: the specifying step, requiring both VTF and UUUUUNU, and the energy-dependent step employing NPH I and ATP. Evaluation of NPH I mutants for the ability to stimulate transcription elongation demonstrated that ATPase activity and a stable interaction between NPH I and the Rap94 subunit of the viral RNA polymerase are required. These observations demonstrate that NPH I is a component of the elongating RNA polymerase, which is catalytically active during transcription elongation.

Marker rescue mapping of the combined Condit/Dales collection of temperature-sensitive vaccinia virus mutants

Complementation analysis of the combined Condit/Dales collection of vaccinia virus temperature-sensitive mutants has been reported (Lackner, C.A., D'Costa, S.M., Buck, C., Condit, R.C., 2003. Complementation analysis of the Dales collection of vaccinia virus temperature-sensitive mutants. Virology 305, 240-259), however not all complementation groups have previously been assigned to single genes on the viral genome. We have used marker rescue to map at least one representative of each complementation group to a unique viral gene. The final combined collection contains 124 temperature-sensitive mutants affecting 38 viral genes, plus five double mutants.

Expansion of poxvirus RNA polymerase subunits sharing homology with corresponding subunits of RNA polymerase II

Poxvirus-encoded RNA polymerases were known previously to share extensive sequence homology in their two largest subunits with the corresponding subunits of cellular RNA polymerases and a modest alignment between the smallest poxvirus subunit and RBP10 of RNA polymerase II. The remaining subunits had no apparent cellular homologs. In this study, the HHpred program that combines amino acid sequence alignments with secondary structure predictions was used to search for homologs to the poxvirus RNA polymerase subunits. Significant matches of vaccinia RNA polymerase 22-, 19-, and 18-kDa subunits to RNA polymerase II subunits RPB5, 6, and 7, respectively, were identified. These results strengthen the concept that poxviral RNA polymerases likely evolved from cellular RNA polymerases.

Poxvirus DNA primase

Poxviruses are large enveloped viruses that replicate in the cytoplasm of vertebrate or invertebrate cells. At least six virus-encoded proteins are required for synthesis and processing of the double-stranded DNA genome of vaccinia virus, the prototype member of the family. One of these proteins, D5, is an NTPase that contains an N-terminal archaeoeukaryotic primase domain and a C-terminal superfamily III helicase domain. Here we report that individual conserved aspartic acid residues in the predicted primase active site were required for in vivo complementation of infectious virus formation as well as genome and plasmid replication. Furthermore, purified recombinant D5 protein synthesized oligoribonucleotides in vitro. Incorporation of label from [alpha-(32)P]CTP or [alpha-(32)P]UTP into a RNase-sensitive and DNase-resistant product was demonstrated by using single-stranded circular bacteriophage DNA templates and depended on ATP or GTP and a divalent cation. Mutagenesis studies showed that the primase and NTPase activities of the recombinant D5 protein could be independently inactivated. Highly conserved orthologs of D5 are present in all poxviruses that have been sequenced, and more diverged orthologs are found in members of all other families of nucleocytoplasmic large DNA viruses. These viral primases may have roles in initiation of DNA replication or lagging-strand synthesis and represent potential therapeutic targets.

The cowpox virus host range gene, CP77, affects phosphorylation of eIF2 alpha and vaccinia viral translation in apoptotic HeLa cells

Host restriction of vaccinia virus has been previously described in CHO and RK13 cells in which a cowpox virus CP77 gene rescues vaccinia virus growth at the viral protein translation level. Here we investigate the restrictive stage of vaccinia virus in HeLa cells using a vaccinia mutant virus (VV-hr) that contains a deletion of 18-kb genome sequences resulting in no growth in HeLa cells. Insertion of CP77 gene into VV-hr generated a recombinant virus (VV-36hr) that multiplied well in HeLa cells. Both viruses could enter cells, initiate viral DNA replication and intermediate gene transcription. However, translation of viral intermediate gene was only detected in cells infected with VV-36hr, indicating that CP77 relieves host restriction at the intermediate gene translation stage in HeLa cells. Caspase-2 and -3 activation was observed in HeLa cells infected with VV-hr coupled with dramatic morphological alterations and cleavage of the translation initiation factor eIF4G. Caspase activation was reduced in HeLa cells infected with VV-36hr, indicating that CP77 acts upstream of caspase activation. Enhanced phosphorylation of PKR and eIF2alpha was also observed in cells infected with VV-hr and was suppressed by CP77. Suppression of eIF4G cleavage with the caspase inhibitor ZVAD did not rescue virus translation, whereas expression of a mutant eIF2alpha protein with an alanine substitution of serine at amino acid position 51 (eIF2alphaS51A) partially restored viral translation and moderately increased virus growth in HeLa cells.

Complementation analysis of the dales collection of vaccinia virus temperature-sensitive mutants

A collection of randomly generated temperature-sensitive (ts) vaccinia virus (strain IHD-W) mutants were reported by S. Dales et al., (1978, Virology, 84, 403-428) in 1978 and characterized by electron microscopy. We have performed further genetic analysis on the Dales collection of mutants to make the mutants more useful to the scientific community. We obtained the entire Dales collection, 97 mutants, from the American Type Culture Center (ATCC). All 97 mutants were grown and reassessed for temperature sensitivity. Of these, 16 mutants were either very leaky or showed unacceptably high reversion indices even after plaque purification and therefore were not used for further analysis. The remaining 81 ts mutants were used to perform a complete complementation analysis with each other and the existing Condit collection of ts vaccinia virus (strain WR) mutants. Twenty-two of these 81 Dales mutants were dropped during complementation analysis due to erratic or weak behavior in the complementation test. Of the 59 mutants that were fit for further investigation, 30 fall into 13 of Condit's existing complementation groups, 5 comprise 3 previously identified complementation groups independent of the Condit collection, and 24 comprise 18 new complementation groups. The 59 mutants which were successfully characterized by complementation will be accessioned by and made available to the scientific community through the ATCC.

Cloning the vaccinia virus genome as a bacterial artificial chromosome in Escherichia coli and recovery of infectious virus in mammalian cells

The ability to manipulate the vaccinia virus (VAC) genome, as a plasmid in bacteria, would greatly facilitate genetic studies and provide a powerful alternative method of making recombinant viruses. VAC, like other poxviruses, has a linear, double-stranded DNA genome with covalently closed hairpin ends that are resolved from transient head-to-head and tail-to-tail concatemers during replication in the cytoplasm of infected cells. Our strategy to construct a nearly 200,000-bp VAC-bacterial artificial chromosome (BAC) was based on circularization of head-to-tail concatemers of VAC DNA. Cells were infected with a recombinant VAC containing inserted sequences for plasmid replication and maintenance in Escherichia coli; DNA concatemer resolution was inhibited leading to formation and accumulation of head-to-tail concatemers, in addition to the usual head-to-head and tail-to-tail forms; the concatemers were circularized by homologous or Cre-loxP-mediated recombination; and E. coli were transformed with DNA from the infected cell lysates. Stable plasmids containing the entire VAC genome, with an intact concatemer junction sequence, were identified. Rescue of infectious VAC was consistently achieved by transfecting the VAC-BAC plasmids into mammalian cells that were infected with a helper nonreplicating fowlpox virus.

Histidine codons appended to the gene encoding the RPO22 subunit of vaccinia virus RNA polymerase facilitate the isolation and purification of functional enzyme and associated proteins from virus-infected cells

Vaccinia virus encodes a eukaryotic-like RNA polymerase composed of two large and six small subunit protein species. A replication-competent virus with 10 histidine codons added to the single endogenous J4R open reading frame was constructed. The altered migration of the 22-kDa subunit of RNA polymerase on SDS-polyacrylamide gel electrophoresis confirmed that J4R encoded the RPO22 subunit and that the mutant virus was genetically stable. The histidine-tagged RNA polymerase bound quantitatively to metal-affinity resins and was eluted in an active form upon addition of imidazole. Glycerol gradient sedimentation of the eluted fraction indicated that most of the RPO22 in infected cells is associated with RNA polymerase. Using stringent washing conditions, metal-affinity chromatography resulted in a several hundred-fold increase in RNA-polymerase-specific activity, and substantially pure enzyme was obtained with an additional conventional chromatography step. When mild conditions were used for washing the metal-affinity resin, the vaccinia virus-encoded capping enzyme, early transcription factor, and nucleoside triphosphate phosphohydrolase I specifically co-eluted with the tagged RNA polymerase, consistent with their physical association. The ability to selectively bind RNA polymerase to an affinity column provided a simple and rapid method of concentrating and purifying active enzyme and protein complexes.

Vaccinia virus nucleoside triphosphate phosphohydrolase I is an essential viral early gene transcription termination factor

Deng and Shuman (J. Biol Chem. 271, 29386 (1996)) reported that an ATPase different from the known viral termination factor, VTF, is required for vaccinia virus early gene transcription termination. Properties of this ATPase were similar to those of a known vaccinia virus enzyme, nucleoside triphosphate phosphohydrolase I (NPH I) the product of gene D11L. Transcription-competent cell-free extracts were prepared from A549 cells infected with wild-type or mutant vaccinia virus harboring ts mutations in gene D11L. These extracts were employed to investigate the role of NPH I in early gene transcription termination. Extracts prepared under nonpermissive conditions from both wild-type virus and ts mutant virus-infected cells exhibited high levels of early and intermediate gene transcription activity but were incapable of supporting late gene transcription. ts mutant extract lacked signal-dependent early gene transcription termination activity, which was restored by the addition of either free NPH I or a GST-NPH I fusion protein. A comparison of the NPH I amino acid sequence to the protein databases revealed the presence of a set of sequences characteristic of nucleic acid helicase superfamily II members. A series of site-specific mutations in the helicase motifs and N-terminal and C-terminal deletion mutations were expressed as GST fusion proteins and their activities assessed. Of the mutations in helicase motifs I to VI, alteration of all but motif III reduced the ATPase activity. Removal of as few as 24 amino acids from the N-terminal end eliminated ATPase activity, while deletion of 68 C-terminal amino acids exhibited only a modest decrease in ATP hydrolysis. Larger C-terminal deletions eliminated ATPase activity. Each deletion mutation, and site-specific mutations other than the motif III mutation, failed to support transcription termination in vitro. Mutations in motifs I, II, V, and VI inhibit wild-type NPH I transcription termination activity. However, deletion of up to 68 amino acids from the C-terminal end eliminates this inhibitory property. This observation is particularly interesting since these C-terminal deletions retain both ATPase activity and single-stranded DNA binding activity. Their failure to inhibit transcription termination suggests that these C-terminal deletion mutations eliminate a site required for a function other than from DNA binding or ATP hydrolysis.

Analysis of the nucleotide sequence of 48 kbp of the variola major virus strain India-1967 located on the right terminus of the conservative genome region

Computer analysis of a variola major virus (VAR) genomic fragment bounded by the open reading frames (ORFs) D1R and A33L, which is 47,961 bp long, revealed 46 potential ORFs. The VAR proteins were compared to the analogous proteins of vaccinia virus strain Copenhagen. The subunits of DNA-dependent RNA polymerase, as well as the transcription factors, mRNA-capping enzymes, and proteins necessary for the virion morphogenesis proved to be highly conservative within orthopoxviruses. The most pronounced differences between the VAR genome fragment under study and the corresponding vaccinia virus fragment were revealed in the vicinity of the gene encoding the A-type inclusion bodies protein. Possible functions of the analysed viral proteins are discussed.

Temperature-sensitive mutations in the gene encoding the small subunit of the vaccinia virus early transcription factor impair promoter binding, transcription activation, and packaging of multiple virion components

The vaccinia virus D6R open reading frame encodes the small subunit of the heterodimeric vaccinia virus early transcription factor (VETF) that activates transcription of early genes in vitro. VETF binds early gene promoters and has a DNA-dependent ATPase activity that is essential for activation of transcription. To examine the relationship between the structure and function of VETF, we have localized the mutations in two temperature-sensitive viruses whose lesions previously were mapped to the D6R gene. For both mutants, a single G-to-A nucleotide change that would alter protein coding potential was identified. In mutant E93, the codon for alanine 25 was changed to that of threonine, and in mutant S4 the codon for valine 278 was replaced with that for methionine. The molecular phenotype of each mutant was assessed by expressing mutant transcription factors in HeLa cells by using a vaccinia virus-T7 system and characterizing the proteins' activities in vitro. The A25T mutant activated transcription to a lesser extent than wild-type VETF, and the V278M mutant had no demonstrable transcription factor activity. Both mutant proteins were shown to be defective for promoter binding, accounting for their impairment in transcription activation. The functional defects for both mutants were observed at permissive as well as nonpermissive temperatures. The mutant proteins retained ATPase activity but required higher DNA concentrations to activate the ATPase. These results indicate that the small subunit of VETF is essential for its promoter binding activity and likely contacts the promoter DNA. Immunoblotting experiments showed that the virion particles from the two mutant viruses contained about half the VETF of wild-type virus, suggesting that promoter binding may contribute to packaging of VETF into the virion particle. RNA polymerase, mRNA capping enzyme, and nucleoside triphosphate phosphohydrolase I were found at similarly reduced levels in the virion, indicating that packaging of some virion core enzymes may be interdependent.

Vaccinia virus nucleoside triphosphate phosphohydrolase I controls early and late gene expression by regulating the rate of transcription

We have carried out a detailed analysis of viral mRNAs and proteins produced in cultured cells infected with a temperature-sensitive vaccinia virus mutant (ts36) containing a modified nucleoside triphosphate phosphohydrolase I (NPH-I), a nucleic acid-dependent ATPase. Using a recombinant virus (ts36LUC) which expresses the luciferase marker, we showed in seven different cell lines that early expression of the receptor gene is strongly inhibited (73.8 to 98.7%) at the nonpermissive temperature. The steady-state levels of different early viral polypeptides were also severely reduced. Analysis of steady-state mRNA levels for two early genes (DNA polymerase and D5) showed that inhibition of early polypeptide synthesis correlated with a reduction in the levels of mRNA accumulated at the nonpermissive temperature. Analysis of steady-state levels of late viral polypeptides and of mRNAs indicated that NPH-I regulation of intermediate and late gene expression is direct and not simply a consequence of its role in inhibiting early gene expression. Characterization of a rescued virus (R36) demonstrated that the temperature-sensitive phenotype of ts36 is due solely to the point mutation in the NPH-I gene. The mutant phenotype is not due to reduced levels of NPH-I present in ts36 virions or to the differential stability of this enzyme in cells infected at the nonpermissive temperature but to inhibition of normal enzymatic activity for this protein. Measurement of viral transcriptional activity in permeabilized purified virions demonstrated that NPH-I is required for normal rates of transcription in vaccinia virus. Our findings show ts36 to be a strongly defective early mutant of vaccinia virus and prove that NPH-I plays a key role in the control of early and late virus gene expression, possibly by way of an auxiliary function which regulates mRNA transcription during the virus growth cycle.

Vaccinia virus morphogenesis is blocked by a temperature-sensitive mutation in the I7 gene that encodes a virion component

The ts16 mutation of vaccinia virus WR (R. C. Condit, A. Motyczka, and G. Spizz, Virology 128:429-443, 1983) has been mapped by marker rescue to the I7L open reading frame located within the genomic HindIII I DNA fragment. The I7 gene encodes a 423-amino-acid polypeptide. Thermolabile growth was attributed to an amino acid substitution, Pro-344-->Leu, in the predicted I7 protein. A normal temporal pattern of viral protein synthesis was elicited in cells infected with ts16 at the nonpermissive temperature (40 degrees C). Electron microscopy revealed a defect in virion assembly at 40 degrees C. Morphogenesis was arrested at a stage subsequent to formation of spherical immature particles. Western immunoblot analysis with antiserum directed against the I7 polypeptide demonstrated an immunoreactive 47-kDa polypeptide accumulating during the late phase of synchronous vaccinia virus infection. Immunoblotting of extracts of wild-type virions showed that the I7 protein is encapsidated within the virus core. The I7 polypeptide displays amino acid sequence similarity to the type II DNA topoisomerase of Saccharomyces cerevisiae.

DNA strand exchange catalyzed by proteins from vaccinia virus-infected cells

Vaccinia virus infection induces expression of a protein which can catalyze joint molecule formation between a single-stranded circular DNA and a homologous linear duplex. The kinetics of appearance of the enzyme parallels that of vaccinia virus DNA polymerase and suggests it is an early viral gene product. Extracts were prepared from vaccinia virus-infected HeLa cells, and the strand exchange assay was used to follow purification of this activity through five chromatographic steps. The most highly purified fraction contained three major polypeptides of 110 +/- 10, 52 +/- 5, and 32 +/- 3 kDa. The purified protein requires Mg2+ for activity, and this requirement cannot be satisfied by Mn2+ or Ca2+. One end of the linear duplex substrate must share homology with the single-stranded circle, although this homology requirement is not very high, as 10% base substitutions had no effect on the overall efficiency of pairing. As with many other eukaryotic strand exchange proteins, there was no requirement for ATP, and ATP analogs were not inhibitors. Electron microscopy was used to show that the joint molecules formed in these reactions were composed of a partially duplex circle of DNA bearing a displaced single-strand and a duplex linear tail. The recovery of these structures shows that the enzyme catalyzes true strand exchange. There is also a unique polarity to the strand exchange reaction. The enzyme pairs the 3' end of the duplex minus strand with the plus-stranded homolog, thus extending hybrid DNA in a 3'-to-5' direction with respect to the minus strand. Which viral gene (if any) encodes the enzyme is not yet known, but analysis of temperature-sensitive mutants shows that activity does not require the D5R gene product. Curiously, v-SEP appears to copurify with vaccinia virus DNA polymerase, although the activities can be partially resolved on phosphocellulose columns.

Characterization of vaccinia virus DNA replication mutants with lesions in the D5 gene

The vaccinia virus D5 gene encodes a 90 kDa early protein that is essential for viral DNA replication. In this report we map and explore the phenotypes of the temperature sensitive mutants bearing lesions in this gene: ts17, ts24, ts69 (WR strain) and ts6389 (IHD strain). Viral DNA synthesis was virtually undetectable during non-permissive infections performed with ts17, and incorporation of 3H-thymidine ceased rapidly when cultures were shifted to the non-permissive temperature in the midst of replication. The D5 protein may therefore be involved in DNA synthesis at the replication fork. The lesions of the four mutants were localized within the D5 orf by marker rescue, and the single nucleotide changes responsible for the ts phenotype of the three WR mutants were identified. Unexpectedly, the three alleles with N-terminal mutations were impaired in marker rescue when homologous recombination with small (< 2 kb), intragenic DNA fragments at 39.5 degrees C was required. This deficiency was not due to degradation of transfected DNA under non-permissive conditions. Efficient marker rescue could be restored by incubation at the permissive temperature for a brief period after transfection, suggesting a requirement for functional D5 in genome/plasmid recombination. Marker rescue under non-permissive conditions could alternatively be restored by co-transfection of unlinked but contiguous DNA sequences.

Transcription of viral late genes is dependent on expression of the viral intermediate gene G8R in cells infected with an inducible conditional-lethal mutant vaccinia virus

There are three temporal classes of vaccinia virus genes: early, intermediate, and late. The object of this study was to determine the effects on virus replication of regulating the expression of G8R, an intermediate gene that encodes a late transcription factor. We inserted the lac operator adjacent to the RNA start site of the G8R gene in a recombinant vaccinia virus that constitutively expresses the Escherichia coli lac repressor to make expression of the G8R gene dependent on the inducer isopropyl-beta-D-thiogalactopyranoside (IPTG). In case repression would not be complete, we also weakened the promoter of the G8R gene by making a single-nucleotide substitution designed to reduce its basal level of transcription. The mutant virus replicated well in the presence of the inducer, although synthesis of the G8R-encoded 30,000-M(r) protein was only 10% of that of the wild-type virus. In the absence of IPTG, (i) synthesis of the G8R protein was inhibited by more than 99% relative to that of the wild-type virus, (ii) synthesis of early and intermediate mRNAs appeared to be unaffected, (iii) intermediate proteins accumulated to higher than normal levels, (iv) synthesis of late mRNA and protein was reduced by about 90%, (v) viral DNA was replicated but incompletely resolved concatemeric molecules accumulated, (vi) not even the earliest stages of virion assembly were detectable by transmission electron microscopy, and (vii) virus yield under one-step growth conditions and plaque formation were 10(-3) and 10(-4) times the wild-type values, respectively. The defect in late gene expression could be overcome by transfection of a G8R gene that was not under lac operator control, as well as by addition of IPTG, further demonstrating the specificity of the repression. The correlation between decreased expression of the G8R intermediate gene and inhibition of late mRNA synthesis is consistent with the notion that the G8R product serves as an essential late transcription factor and supports a cascade mechanism of vaccinia virus gene regulation. In addition, the inducer-dependent vaccinia virus mutant provided a tool for selective inhibition of late gene expression while allowing synthesis of early and intermediate mRNAs and proteins.

Temperature-sensitive mutations in the vaccinia virus H4 gene encoding a component of the virion RNA polymerase

Four previously isolated temperature-sensitive (ts) mutants of vaccinia virus WR (ts1, ts31, ts55, and ts58) comprising a single complementation group (R. C. Condit, A. Motyczka, and G. Spizz, Virology 128:429-443, 1983) have been mapped by marker rescue to the H4L open reading frame located within the genomic HindIII-H DNA fragment. The H4 gene is predicted to encode a 93.6-kDa polypeptide expressed at late times during infection. Nucleotide sequence alterations responsible for thermolabile growth lead to amino acid substitutions in the H4 gene product. All four ts alleles display "normal" patterns of early and late viral protein synthesis at the nonpermissive temperature (40 degrees C). Mature virion particles, microscopically indistinguishable from wild-type virions, are produced in the cytoplasm of cells infected with ts1 at 40 degrees C. Western immunoblot analysis localizes the H4 protein to the virion core. After solubilization from cores, the H4 protein is associated during purification with transcriptionally active vaccinia virus DNA-dependent RNA polymerase.

Genetic and biochemical characterization of vaccinia virus genes D2L and D3R which encode virion structural proteins

Polyclonal antisera raised against fusion proteins containing portions of the vaccinia virus D2L and D3R proteins were prepared. Immunoprecipitation of pulse-labeled infected cell extracts and Western blot analysis demonstrated that genes D2L and D3R encode 16.9- and 27-kDa proteins, respectively. Both are synthesized late during infection and there is no evidence for proteolytic processing of either protein. Western blots of purified virus and subvirion fractions showed that D2L and D3R are virion components, residing in a detergent-insoluble fraction, containing viral core structural proteins. Trypsin sensitivity experiments suggest that each is found in an equivalent position within the virus core. Pulse-chase analysis showed that both proteins exhibit biphasic stability in which an unstable nascent component is replaced by a stable form. This observation suggests that the stable component results from the insertion of D2L and D3R into an immature core structure. The DNA sequence of four ts mutants previously mapped to genes D2L and D3R is reported. Analysis of the ability of each mutant to synthesize and process viral proteins showed that protein synthetic patterns were indistinguishable from wild type, however, three of the four mutants were defective in the processing of the major virion structural precursor, p4a. Unlike the biphasic stability observed in wild-type infected cells, D2L and D3R were totally degraded in cells infected at 40 degrees with any of the four ts mutants. Stability of the D2L and D3R proteins, in cells treated with rifampicin, is unaffected which demonstrates that a block in morphogenesis is not directly responsible for the observed instability of the mutant proteins.

Phenotypic characterization of a vaccinia virus temperature-sensitive complementation group affecting a virion component

Genetic and biochemical evidence is presented which shows that the product of the vaccinia virus gene 18R is a virion protein. Western blot analysis of virion proteins using anti-18R serum detects a 78,000-Da protein, localized in the virus core. Of five ts mutants which map to gene 18R, two mutants, ts 10 and ts 44, possess thermolabile virions. Temperature shifts performed during single-step growth of ts 44 suggest that precursors required for virion maturation accumulate during nonpermissive infections with ORF 18R mutants and that protein synthesis is required for recovery from nonpermissive condition.

The complete DNA sequence of vaccinia virus

The complete DNA sequence of the genome of vaccinia virus has been determined. The genome consisted of 191,636 bp with a base composition of 66.6% A + T. We have identified 198 "major" protein-coding regions and 65 overlapping "minor" regions, for a total of 263 potential genes. Genes encoded by the virus were located by examination of DNA sequence characteristics and compared with existing vaccinia virus mapping analyses, sequence data, and transcription data. These genes were found to be compactly organized along the genome with relatively few regions of noncoding sequences. Whereas several similarities to proteins of known function were discerned, the function of the majority of proteins encoded by these open reading frames is as yet undetermined.

Vaccinia virus gene D7R encodes a 20,000-dalton subunit of the viral DNA-dependent RNA polymerase

The polypeptide encoded by the vaccinia virus open reading frame D7R was synthesized in bacteria. Immunization of rabbits with the polypeptide resulted in antibodies that specifically recognized a virion polypeptide of 20,000 daltons. The immunoreactivity with the 20,000-dalton polypeptide was found to coincide with the virion-associated DNA-dependent RNA polymerase through DEAE-cellulose chromatography and glycerol gradient sedimentation. These results argue that the product of the vaccinia open reading frame D7R is a subunit of the viral RNA polymerase.

Early transcription factor subunits are encoded by vaccinia virus late genes

The vaccinia virus early transcription factor (VETF) was shown to be a virus-encoded heterodimer. The gene for the 82-kDa subunit was identified as open reading frame (ORF) A8L, based on the N-terminal sequence of factor purified by using DNA-affinity magnetic beads. The 70-kDa subunit of VETF was refractory to N-terminal analysis, and so N-terminal sequences were obtained for three internal tryptic peptides. All three peptides matched sequences within ORF D6R. ORFs A8L and D6R are located within the central region of the vaccinia virus genome and are separated by about 13,600 base pairs. Proteins corresponding to the 3' ends of ORFs A8L and D6R were overexpressed in Escherichia coli and used to prepare antisera that bound to the larger and smaller subunits, respectively, of affinity-purified VETF. Immunoblot analysis of proteins from infected cells indicated that both subunits are expressed exclusively in the late phase of infection, just prior to their packaging in virus particles. The two subunits of VETF have no significant local or overall amino acid sequence homology to one another, to other entries in biological sequence data bases including bacterial sigma factors, or to recently determined sequences of some eukaryotic transcription factors. The 70-kDa subunit, however, has motifs in common with a super-family of established and putative DNA and RNA helicases.

Identification of the vaccinia virus gene encoding an 18-kilodalton subunit of RNA polymerase and demonstration of a 5' poly(A) leader on its early transcript

The DNA-dependent RNA polymerase of vaccinia virus contains 8 to 10 virus-encoded polypeptides. We have mapped the gene encoding an 18-kilodalton RNA polymerase subunit to D7R, the seventh open reading frame of the HindIII D genomic subfragment. Localization of this gene was achieved by using antibody to the purified RNA polymerase for immunoprecipitation of the in vitro translation products of in vivo-synthesized early mRNA selected by hybridization to cloned DNA fragments. The identification was confirmed by translation of D7R transcripts made in vitro with bacteriophage T7 RNA polymerase. The phenotypes of two previously isolated conditionally lethal temperature-sensitive mutants that map to D7R (J. Seto, L. M. Celenza, R. C. Condit, and E. G. Niles, Virology 160:110-119, 1987) are consistent with an essential role of this subunit in late transcription. This polymerase gene, designated rpo18, predicts a polypeptide of 161 amino acids with a molecular mass of 17,892. The rpo18 gene is transcribed early in infection, even though the 5'-TAAATG-3' motif, which is conserved among many genes of the late class, is present near the RNA start site. Characterization of the 5' end of the early transcript by several different methods, including cDNA cloning, revealed a poly(A) leader with up to 14 adenylate residues, whereas only 3 are present in the corresponding location of the DNA template. Similar but somewhat longer poly(A) leaders have previously been observed in mRNAs of late genes. We noted a TAAATG motif near the initiation site of several other early genes, including the viral DNA polymerase, and carried out additional experiments to demonstrate that their early transcripts also have 5' poly(A) leaders. Thus, formation of the poly(A) leader is not exclusively a late function but apparently depends on sequences around the transcription initiation site.

Vaccinia virus gene encoding a component of the viral early transcription factor

The gene product of the vaccinia virus open reading frame D6R was synthesized in bacteria and used to raise antiserum against the protein. Using the antiserum as a probe, we demonstrated that the D6R protein is a component of the virion particle, localized to the virus core structure. The D6R protein, purified from virions, has been shown to copurify with the vaccinia virus early transcription factor (VETF). The apparent molecular weight of the D6R polypeptide is identical to that of the smaller of the two VETF-associated polypeptides. Antibodies directed against D6R block both the early promoter-binding and DNA-dependent ATPase activities of VETF, supporting the identity of D6R as a VETF-associated polypeptide. An ATP-binding site was inferred near the amino terminus of the derived D6R amino acid sequence. Thus, the D6R polypeptide could be the source of the ATPase activity associated with VETF. The D6R gene was shown previously to belong to the late class of vaccinia virus genes. Synthesis of the VETF at late times after infection suggests a cascade model for vaccinia virus gene regulation in which class-specific transcription factors are synthesized at the previous phase of the infectious cycle.

Identification of the point mutations in two vaccinia virus nucleoside triphosphate phosphohydrolase I temperature-sensitive mutants and role of this DNA-dependent ATPase enzyme in virus gene expression

The biological function of the nucleoside triphosphate phosphohydrolase I (NTPase I) enzyme of vaccinia virus is not yet known. In this investigation we have identified the genetic lesion of two temperature-sensitive mutants of vaccinia virus, ts50 and ts36, as single point mutations contained within the 5'615 nucleotides of the NTPase I gene (ts50, G to A at position 131; ts36, C to T at position 556). The point mutations result in amino acid substitutions of Gly to Glu-44 (ts50) and Pro to Ser-186 (ts36). In monkey BSC-40 cells, ts50 and ts36 behave phenotypically like wild-type virus with respect to replication and synthesis of viral DNA but are defective in late polypeptide synthesis. However, these two ts mutants displayed a drastically different phenotype in virus-infected human HeLa cells at the restrictive temperature; viral DNA replication did not occur and late polypeptide synthesis was absent. Moreover, if the early block was overcome by a temperature shift-up, then HeLa cells infected with the ts mutants displayed a profile characteristic of defective late viral polypeptide synthesis. Our results reveal that vaccinia NTPase I enzyme functions early and late in the viral replication cycle and that the phenotype of these ts mutants is dependent upon the cell type.

Superinfection exclusion of vaccinia virus in virus-infected cell cultures

Vaccinia virus-infected BSC 40 cells do not permit the replication of superinfecting vaccinia virus. The extent of superinfecting virus propagation depends on the time of superinfection; there is 90% exclusion by 4 hr after the initial infection, and more than 99% by 6 hr. When superinfection is attempted at 6 hr after infection, the superinfecting virus is incapable of carrying out DNA replication or early gene transcription, demonstrating that an early event in the virus life cycle is inhibited. The rate of adsorption of the superinfecting virus is unaltered which shows that exclusion is affected at a point between adsorption and early gene transcription. In order to exclude superinfection, the primary infecting virus does not require replication of its DNA or expression of its late genes but it must express one or more early genes.

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.

Vaccinia virus gene D12L encodes the small subunit of the viral mRNA capping enzyme

Vaccinia virus gene D12L, which lies between nucleotides 14,350 and 13,487 in the HindIII D fragment, is transcribed at early times in infection and is capable of encoding a protein 287 amino acids in length with a predicted molecular mass of 33,331. A polyclonal antiserum was raised in rabbits to a fusion protein containing 279 amino acids of the D12L protein, and this serum was used to investigate both the time of synthesis and the function of the D12L protein. A combination of Western blot analysis and immunoprecipitation from pulse-labeled and pulse-chased cell extracts demonstrated that the synthesis of a 31-kDa protein begins early in infection, that it reaches a plateau by about 4 hr, and that it is stable in the infected cell. The D12L protein was localized by Western blot analysis of detergent-solubilized virions to the sodium deoxycholate soluble fraction which suggested that it may be a virion core-associated enzyme. Due to the similarity in apparent molecular weight between the D12L protein and the small subunit of the vaccinia mRNA capping complex the anti-D12L antiserum was employed in Western blot analysis of fractions generated during the purification of the virion mRNA capping enzyme. The 31-kDa D12L protein copurified with the virus capping enzyme through chromatography on heparin-agarose and phosphocellulose and also cosedimented with the capping enzyme through a glycerol density gradient. In addition, the anti-D12L antiserum coprecipitated the large subunit of the capping enzyme, confirming that gene D12L encodes the small subunit of the viral mRNA capping enzyme. An insertion mutation which destroys the gene D12L coding sequence was constructed in a plasmid containing a portion of both genes D11L and D12L and this plasmid was used to rescue a ts mutation, in a single step, in the adjacent gene D11L. Southern blot analysis of the re-plaque-purified virus permitted the identification of the mutant virus only when the mutant was propagated in the presence of wild-type helper virus. We concluded from these data that gene D12L is essential for virus propagation in tissue culture.

Identification of temperature-sensitive mutants of vaccinia virus that are defective in conversion of concatemeric replicative intermediates to the mature linear DNA genome

Pulsed-field gel electrophoresis was used to screen temperature-sensitive mutants of vaccinia virus for the ability to convert replicated viral DNA into mature linear 185-kilobase hairpin-terminated genomes. Of 30 mutually noncomplementing mutants tested, 5 displayed a temperature-sensitive defect in the resolution of the telomere fusion configuration within concatemeric replicative intermediates, resulting in a failure to convert such intermediates to the linear monomeric genome. Adjacent genomic units in the concatemeric arrays generated in these mutants were arranged in both tandem and inverted orientations. The observation that four of the five mutants had a severe general defect in the synthesis of the late class of viral proteins suggests that at least one late protein is directly required to resolve the telomere fusion intermediate to hairpin termini. The identification of such telomere resolution proteins should be facilitated by genetic and molecular characterization of resolution-defective mutants, such as C63, in which late protein synthesis is not severely affected.

Resolution of vaccinia virus DNA concatemer junctions requires late-gene expression

Vaccinia virus replicates in the cytoplasm of infected cells, generating transient replicative intermediates containing the DNA for the terminal sequences as concatemeric junctions. The processing of the terminal sequences for a series of vaccinia virus conditional lethal mutants at the nonpermissive temperature was analyzed by restriction enzyme digestion and Southern blot hybridization of DNA isolated from infected cells. Three phenotypes were observed: DNA replication negative (Rep-), DNA replication positive but concatemer resolution negative (Rep+ Res-), and DNA replication positive and concatemer resolution positive (Rep+ Res+). Interestingly, all six Rep+ Res- mutants from separate complementation groups were defective in late protein synthesis. Isatin beta-thiosemicarbazone, a drug that blocks late protein synthesis, also prevented resolution of concatemers. Orthogonal field gel electrophoresis of the DNA generated by the late defective mutants revealed a distribution of linear genome multimers. The multimers were processed into mature monomers after a shift to the permissive temperature in the presence of cytosine arabinoside for all the Rep+ Res- mutants except ts22, an irreversible mutant which cleaves RNA late in infection (R.F. Pacha and R.C. Condit, J. Virol. 56:395-403, 1985). Genome formation can be divided into two stages: DNA replication, which generates concatemers, and resolution, which processes concatemers into monomers with hairpin termini. Early viral genes are required for the former, and late viral genes are required for the latter.

Fine structure mapping of five temperature-sensitive mutants in the 22- and 147-kilodalton subunits of vaccinia virus DNA-dependent RNA polymerase

We have mapped the temperature-sensitive (ts) lesions of three mutants, ts51, ts53, and ts65, and two other mutants, ts7 and ts20, to regions on the vaccinia virus genome that encode the 147- and 22-kilodalton subunits of the viral DNA-dependent RNA polymerase, respectively. Plasmid and bacteriophage clones from the HindIII J region and the region spanning the HindIII J-H junction were used in marker rescue experiments to map the mutations. Sequence analysis of the region encoding the 22-kilodalton subunit in the wild-type, ts7, and ts20 viruses revealed a single base change in the mutants compared with that in the wild-type virus. The identification of these RNA polymerase mutants provides us with tools to understand transcription and its regulation in vaccinia virus.

Vaccinia virus gene D8 encodes a virion transmembrane protein

Transcription mapping studies and DNA sequence analysis of the vaccinia virus HindIII D fragment predict that gene D8 encodes a protein 304 amino acids in length, with a molecular mass of 35,426 daltons, that is expressed at late times in infection. In order to determine whether the native D8 protein is required for virus propagation, we constructed a frameshift mutation in the D8 coding sequence. Virus containing this mutation were isolated and shown to replicate in a single-step growth experiment with wild type virus growth kinetics, demonstrating that the normal-length D8 protein is not essential for virus propagation in tissue culture. In order to investigate the synthesis of the wild-type and the mutant D8 proteins in virus-infected cells, we raised polyclonal antisera to a fusion protein consisting of a portion of the D8 coding sequence linked to the Escherichia coli trpE gene. Western blot (immunoblot) analysis of the time course of D8 protein synthesis in cells infected with either wild-type or mutant virus demonstrated that D8 protein was synthesized late in infection in each case and accumulated throughout the experiment. To determine whether the D8 protein was incorporated into the mutant or wild-type virus, purified virions were fractionated into Nonidet P-40-soluble, deoxycholate-soluble, and detergent-insoluble fractions. In both the wild-type and the mutant viruses, the D8 protein was an integral viral protein. The wild-type protein partitioned into the Nonidet P-40-soluble fraction, suggesting that it was a viral membrane protein. The mutant protein fractionated into the detergent-insoluble component, demonstrating that although the altered protein was incorporated into the virus, it was found in a abnormal location. In order to determine whether the D8 protein was present on the virion surface, the susceptibility of the D8 protein to proteolysis was tested by analyzing the products of incubation of the wild-type and mutant viruses with either chymotrypsin or trypsin. These studies demonstrated that the wild-type D8 protein was a transmembrane protein with a major extraviral domain that was released largely intact from the virus by trypsin. The mutant D8 protein was relatively refractory to proteolysis, confirming the hypothesis that although it is associated with the virus, it is in a conformation different from that of the wild-type protein. Tryptic digestion of the wild-type virus increased plaque formation severalfold, concomitant with the removal of the extraviral domain of the D8 protein.(ABSTRACT TRUNCATED AT 400 WORDS)

Transcription and translation mapping of the 13 genes in the vaccinia virus HindIII D fragment

The vaccinia virus HindIII D fragment is 160,060 bp in length and encodes 13 complete open reading frames [Niles et al. (1986) Virology 153, 96-112; S. L. Weinrich and D. E. Hruby (1986). Nucleic Acids Res. 14, 3003-3016]. We have employed a two-step Northern hybridization protocol using single-stranded DNA probes from M13 recombinants in order to identify the mRNA products from the 13 genes. Six of these genes are expressed only at early times after infection; six are transcribed only at late times; one gene is expressed at both early and late times after virus infection. The D11 gene is transcribed into two late mRNA species, one full-length and the other derived from the 3' one-third of the coding sequence. Translation of hybrid-selected mRNA was carried out in an attempt to identify the protein products encoded by each mRNA. Protein products were found for each early gene but translation was successful for only two of the eight late mRNAs. With the completion of the physical map it is apparent that the early and late genes in the HindIII D fragment are arranged in order to minimize potential interference caused by the expression of closely packed viral genes.