Extension of the transcriptional and translational map of the left end of the vaccinia virus genome to 21 kilobase pairs

Ribosome Profiling Reveals Translational Upregulation of Cellular Oxidative Phosphorylation mRNAs during Vaccinia Virus-Induced Host Shutoff

Vaccinia virus infection causes a host shutoff that is marked by global inhibition of host protein synthesis. Though the host shutoff may facilitate reallocation of cellular resources for viral replication and evasion of host antiviral immune responses, it poses a challenge for continuous synthesis of cellular proteins that are important for viral replication. It is, however, unclear whether and how certain cellular proteins may be selectively synthesized during the vaccinia virus-induced host shutoff. Using simultaneous RNA sequencing and ribosome profiling, two techniques quantifying genome-wide levels of mRNA and active protein translation, respectively, we analyzed the responses of host cells to vaccinia virus infection at both the transcriptional and translational levels. The analyses showed that cellular mRNA depletion played a dominant role in the shutoff of host protein synthesis. Though the cellular mRNAs were significantly reduced, the relative translation efficiency of a subset of cellular mRNAs increased, particularly those involved in oxidative phosphorylation that are responsible for cellular energy production. Further experiments demonstrated that the protein levels and activities of oxidative phosphorylation increased during vaccinia virus infection, while inhibition of the cellular oxidative phosphorylation function significantly suppressed vaccinia virus replication. Moreover, the short 5' untranslated region of the oxidative phosphorylation mRNAs contributed to the translational upregulation. These results provide evidence of a mechanism that couples translational control and energy metabolism, two processes that all viruses depend on host cells to provide, to support vaccinia virus replication during a host shutoff.IMPORTANCE Many viral infections cause global host protein synthesis shutoff. While host protein synthesis shutoff benefits the virus by relocating cellular resources to viral replication, it also poses a challenge to the maintenance of cellular functions necessary for viral replication if continuous protein synthesis is required. Here we measured the host mRNA translation rate during a vaccinia virus-induced host shutoff by analyzing total and actively translating mRNAs in a genome-wide manner. This study revealed that oxidative phosphorylation mRNAs were translationally upregulated during vaccinia virus-induced host protein synthesis shutoff. Oxidative phosphorylation is the major cellular energy-producing pathway, and we further showed that maintenance of its function is important for vaccinia virus replication. This study highlights the fact that vaccinia virus infection can enhance cellular energy production through translational upregulation in the context of an overall host protein synthesis shutoff to meet energy expenditure.

Recombinant modified vaccinia virus Ankara generating excess early double-stranded RNA transiently activates protein kinase R and triggers enhanced innate immune responses

Double-stranded RNA (dsRNA) is an important molecular pattern associated with viral infection and is detected by various extra- and intracellular recognition molecules. Poxviruses have evolved to avoid producing dsRNA early in infection but generate significant amounts of dsRNA late in infection due to convergent transcription of late genes. Protein kinase R (PKR) is activated by dsRNA and triggers major cellular defenses against viral infection, including protein synthesis shutdown, apoptosis, and type I interferon (IFN-I) production. The poxviral E3 protein binds and sequesters viral dsRNA and is a major antagonist of the PKR pathway. We found that the highly replication-restricted modified vaccinia virus Ankara (MVA) engineered to produce excess amounts of dsRNA early in infection showed enhanced induction of IFN-β in murine and human cells in the presence of an intact E3L gene. IFN-β induction required a minimum overlap length of 300 bp between early complementary transcripts and was strongly PKR dependent. Excess early dsRNA produced by MVA activated PKR early but transiently in murine cells and induced enhanced systemic levels of IFN-α, IFN-γ, and other cytokines and chemokines in mice in a largely PKR-dependent manner. Replication-competent chorioallantois vaccinia virus Ankara (CVA) generating excess early dsRNA also enhanced IFN-I production and was apathogenic in mice even at very high doses but showed no in vitro host range defect. Thus, genetically adjuvanting MVA and CVA to generate excess early dsRNA is an effective method to enhance innate immune stimulation by orthopoxvirus vectors and to attenuate replicating vaccinia virus in vivo.

IMPORTANCE

Efficient cellular sensing of pathogen-specific components, including double-stranded RNA (dsRNA), is an important prerequisite of an effective antiviral immune response. The prototype poxvirus vaccinia virus (VACV) and its derivative modified vaccinia virus Ankara (MVA) produce dsRNA as a by-product of viral transcription. We found that inhibition of cellular dsRNA recognition established by the virus-encoded proteins E3 and K3 can be overcome by directing viral overexpression of dsRNA early in infection without compromising replication of MVA in permissive cells. Early dsRNA induced transient activation of the cellular dsRNA sensor protein kinase R (PKR), resulting in enhanced production of interferons and cytokines in cells and mice. Enhancing the capacity of MVA to activate the innate immune system is an important approach to further improve the immunogenicity of this promising vaccine vector.

African swine fever virus transcription

African swine fever virus (ASFV), a large, enveloped, icosahedral dsDNA virus, is currently the only known DNA-containing arbovirus and the only recognized member of the family Asfarviridae. Its genome encodes more than 150 open reading frames that are densely distributed, separated by short intergenic regions. ASFV gene expression follows a complex temporal programming. Four classes of mRNAs have been identified by its distinctive accumulation kinetics. Gene transcription is coordinated with DNA replication that acts as the main switch on ASFV gene expression. Immediate early and early genes are expressed before the onset of DNA replication, whereas intermediate and late genes are expressed afterwards. ASFV mRNAs have a cap 1 structure at its 5'-end and a short poly(A) tail on its 3'-end. Transcription initiation and termination occurs at very precise positions within the genome, producing transcripts of definite length throughout the expression program. ASFV devotes approximately 20% of its genome to encode the 20 genes currently considered to be involved in the transcription and modification of its mRNAs. This transcriptional machinery gives to ASFV a remarkable independence from its host and an accurate positional and temporal control of its gene expression. Here, we review the components of the ASFV transcriptional apparatus, its expression strategies and the relevant data about the transcriptional cis-acting control sequences.

Pervasive initiation and 3'-end formation of poxvirus postreplicative RNAs

Poxviruses are large DNA viruses that replicate within the cytoplasm and encode a complete transcription system, including a multisubunit RNA polymerase, stage-specific transcription factors, capping and methylating enzymes, and a poly(A) polymerase. Expression of the more than 200 open reading frames by vaccinia virus, the prototype poxvirus, is temporally regulated: early mRNAs are synthesized immediately after infection, whereas intermediate and late mRNAs are synthesized following genome replication. The postreplicative transcripts are heterogeneous in length and overlap the entire genome, which pose obstacles for high resolution mapping. We used tag-based methods in conjunction with high throughput cDNA sequencing to determine the precise 5'-capped and 3'-polyadenylated ends of postreplicative RNAs. Polymerase slippage during initiation of intermediate and late RNA synthesis results in a 5'-poly(A) leader that allowed the unambiguous identification of true transcription start sites. Ninety RNA start sites were located just upstream of intermediate and late open reading frames, but many more appeared anomalous, occurring within coding and non-coding regions, indicating pervasive transcription initiation. We confirmed the presence of functional promoter sequences upstream of representative anomalous start sites and demonstrated that alternative start sites within open reading frames could generate truncated isoforms of proteins. In an analogous manner, poly(A) sequences allowed accurate mapping of the numerous 3'-ends of postreplicative RNAs, which were preceded by a pyrimidine-rich sequence in the DNA coding strand. The distribution of postreplicative promoter sequences throughout the genome provides enormous transcriptional complexity, and the large number of previously unmapped RNAs may have novel functions.

Genome-wide analysis of the 5' and 3' ends of vaccinia virus early mRNAs delineates regulatory sequences of annotated and anomalous transcripts

Poxviruses are large DNA viruses that encode a multisubunit RNA polymerase, stage-specific transcription factors, and enzymes that cap and polyadenylate mRNAs within the cytoplasm of infected animal cells. Genome-wide microarray and RNA-seq technologies have been used to profile the transcriptome of vaccinia virus (VACV), the prototype member of the family. Here, we adapted tag-based methods in conjunction with SOLiD and Illumina deep sequencing platforms to determine the precise 5' and 3' ends of VACV early mRNAs and map the putative transcription start sites (TSSs) and polyadenylation sites (PASs). Individual and clustered TSSs were found preceding 104 annotated open reading frames (ORFs), excluding pseudogenes. In the majority of cases, a 15-nucleotide consensus core motif was present upstream of the ORF. This motif, however, was also present at numerous other locations, indicating that it was insufficient for transcription initiation. Further analysis revealed a 10-nucleotide AT-rich spacer following functional core motifs that may facilitate DNA unwinding. Additional putative TSSs occurred in anomalous locations that may expand the functional repertoire of the VACV genome. However, many of the anomalous TSSs lacked an upstream core motif, raising the possibility that they arose by a processing mechanism as has been proposed for eukaryotic systems. Discrete and clustered PASs occurred about 40 nucleotides after an UUUUUNU termination signal. However, a large number of PASs were not preceded by this motif, suggesting alternative polyadenylation mechanisms. Pyrimidine-rich coding strand sequences were found immediately upstream of both types of PASs, signifying an additional feature of VACV 3'-end formation and polyadenylation.

Simultaneous high-resolution analysis of vaccinia virus and host cell transcriptomes by deep RNA sequencing

Deep RNA sequencing was used to simultaneously analyze vaccinia virus (VACV) and HeLa cell transcriptomes at progressive times following infection. VACV, the prototypic member of the poxvirus family, replicates in the cytoplasm and contains a double-stranded DNA genome with approximately 200 closely spaced open reading frames (ORFs). The acquisition of a total of nearly 500 million short cDNA sequences allowed construction of temporal strand-specific maps of the entire VACV transcriptome at single-base resolution and analysis of over 14,000 host mRNAs. Before viral DNA replication, transcripts from 118 VACV ORFs were detected; after replication, transcripts from 93 additional ORFs were characterized. The high resolution permitted determination of the precise boundaries of many mRNAs including read-through transcripts and location of mRNA start sites and adjacent promoters. Temporal analysis revealed two clusters of early mRNAs that were synthesized in the presence of inhibitors of protein as well as DNA synthesis, indicating that they do not correspond to separate immediate- and delayed-early classes as defined for other DNA viruses. The proportion of viral RNAs reached 25-55% of the total at 4 h. This rapid change, resulting in a relative decrease of the vast majority of host mRNAs, can contribute to the profound shutdown of host protein synthesis and blunting of antiviral responses. At 2 h, however, a minority of cellular mRNAs was increased. The overrepresented functional categories of the up-regulated RNAs were NF-kappaB cascade, apoptosis, signal transduction, and ligand-mediated signaling, which likely represent the host response to invasion.

Transcriptional analysis of a major capsid protein gene from Spodoptera exigua ascovirus 5a

The major capsid protein (mcp) gene of Spodoptera exigua ascovirus 5a (SeAV-5a) was confirmed by aphidicolin viral DNA replication inhibition analysis to be a late gene. The 5' and 3' ends of mcp gene transcripts have been mapped. Primer extension analyses indicated that transcription of the mcp gene initiates from a cytosine 25 nucleotides (nt) upstream of the translation start codon. Two independent approaches by 3' rapid amplification of cDNA ends (3' RACE) and oligo (dT) cellulose binding assay suggested that SeAV-5a mcp mRNA is polyadenylated. Analyses by 3' RACE also revealed that mcp transcripts terminate at a U, either at 26 or 38 nt downstream of the translation stop codon. The putative 5' transcription control region of the SeAV-5a mcp gene shares similarities with other ascoviruses and Chilo iridescent virus (CIV), containing a conserved TATA-box-like motif (TAATTAAA) and an ATTTGATCTT motif upstream of it. The 3' downstream regions of the mcp gene of all the ascoviruses examined and CIV can form a stem-loop structure, and the ends of the mcp gene transcripts of SeAV-5a are within the predicted stem-loop region. This suggests that the stem-loop structure of the mcp gene might be involved in transcription termination.

Mapping and phenotypic analysis of spontaneous isatin-beta-thiosemicarbazone resistant mutants of vaccinia virus

Treatment of wild type vaccinia virus infected cells with the anti-poxviral drug isatin-beta-thiosemicarbazone (IBT) induces the viral postreplicative transcription apparatus to synthesize longer-than-normal mRNAs through an unknown mechanism. Previous studies have shown that virus mutants resistant to or dependent on IBT affect genes involved in control of viral postreplicative transcription elongation. This study was initiated in order to identify additional viral genes involved in control of vaccinia postreplicative transcription elongation. Eight independent, spontaneous IBT resistant mutants of vaccinia virus were isolated. Marker rescue experiments mapped two mutants to gene G2R, which encodes a previously characterized postreplicative gene positive transcription elongation factor. Three mutants mapped to the largest subunit of the viral RNA polymerase, rpo147, the product of gene J6R. One mutant contained missense mutations in both G2R and A24R (rpo132, the second largest subunit of the RNA polymerase). Two mutants could not be mapped, however sequence analysis demonstrated that neither of these mutants contained mutations in previously identified IBT resistance or dependence genes. Phenotypic and biochemical analysis of the mutants suggests that they possess defects in transcription elongation that compensate for the elongation enhancing effects of IBT. The results implicate the largest subunit of the RNA polymerase (rpo147) in the control of elongation, and suggest that there exist additional gene products which mediate intermediate and late transcription elongation in vaccinia virus.

Double-stranded RNA-binding protein E3 controls translation of viral intermediate RNA, marking an essential step in the life cycle of modified vaccinia virus Ankara

Infection of human cells with modified vaccinia virus Ankara (MVA) activates the typical cascade-like pattern of viral early-, intermediate- and late-gene expression. In contrast, infection of human HeLa cells with MVA deleted of the E3L gene (MVA-DeltaE3L) results in high-level synthesis of intermediate RNA, but lacks viral late transcription. The viral E3 protein is thought to bind double-stranded RNA (dsRNA) and to act as an inhibitor of dsRNA-activated 2'-5'-oligoadenylate synthetase (2'-5'OA synthetase)/RNase L and protein kinase (PKR). Here, it is demonstrated that viral intermediate RNA can form RNase A/T1-resistant dsRNA, suggestive of activating both the 2'-5'OA synthetase/RNase L pathway and PKR in various human cell lines. Western blot analysis revealed that failure of late transcription in the absence of E3L function resulted from the deficiency to produce essential viral intermediate proteins, as demonstrated for vaccinia late transcription factor 2 (VLTF 2). Substantial host cell-specific differences were found in the level of activation of either RNase L or PKR. However, both rRNA degradation and phosphorylation of eukaryotic translation initiation factor-2alpha (eIF2alpha) inhibited the synthesis of VLTF 2 in human cells. Moreover, intermediate VLTF 2 and late-protein production were restored in MVA-DeltaE3L-infected mouse embryonic fibroblasts from Pkr(0/0) mice. Thus, both host-response pathways may be involved, but activity of PKR is sufficient to block the MVA molecular life cycle. These data imply that an essential function of vaccinia virus E3L is to secure translation of intermediate RNA and, thereby, expression of other viral genes.

An isatin-beta-thiosemicarbazone-resistant vaccinia virus containing a mutation in the second largest subunit of the viral RNA polymerase is defective in transcription elongation

The vaccinia virus RNA polymerase is a multi-subunit enzyme that contains eight subunits in the postreplicative form. A prior study of a virus called IBT(r90), which contains a mutation in the A24 gene encoding the RPO132 subunit of the RNA polymerase, demonstrated that the mutation results in resistance to the anti-poxvirus drug isatin-beta-thiosemicarbazone (IBT). In this study, we utilized an in vitro transcription elongation assay to determine the effect of this mutation on transcription elongation. Both wild type and IBT(r90) polymerase complexes were studied with regard to their ability to pause during elongation, their stability in a paused state, their ability to release transcripts, and their elongation rate. We have determined that the IBT(r90) complex is specifically defective in elongation compared with the WT complex, pausing longer and more frequently than the WT complex. We have built a homology model of the RPO132 subunit with the yeast pol II rpb2 subunit to propose a structural mechanism for this elongation defect.

Regulation of viral transcription elongation and termination during vaccinia virus infection

Vaccinia virus provides a useful genetic and biochemical tool for studies of the basic mechanisms of eukaryotic transcription. Vaccinia genes are transcribed in three successive gene classes during infection, early, intermediate, and late. Vaccinia transcription is regulated primarily by virus gene products not only during initiation, but also during elongation and termination. The factors and mechanisms regulating early elongation and termination differ from those regulating intermediate and late gene expression. Control of transcription elongation and termination in vaccinia virus bears some similarity to the same process in other prokaryotic and eukaryotic systems, yet features some novel mechanisms as well.

Analysis of the monkeypox virus genome

Monkeypox virus (MPV) belongs to the orthopoxvirus genus of the family Poxviridae, is endemic in parts of Africa, and causes a human disease that resembles smallpox. The 196,858-bp MPV genome was analyzed with regard to structural features and open reading frames. Each end of the genome contains an identical but oppositely oriented 6379-bp terminal inverted repetition, which similar to that of other orthopoxviruses, includes a putative telomere resolution sequence and short tandem repeats. Computer-assisted analysis was used to identify 190 open reading frames containing >/=60 amino acid residues. Of these, four were present within the inverted terminal repetition. MPV contained the known essential orthopoxvirus genes but only a subset of the putative immunomodulatory and host range genes. Sequence comparisons confirmed the assignment of MPV as a distinct species of orthopoxvirus that is not a direct ancestor or a direct descendent of variola virus, the causative agent of smallpox.

Fowlpox virus encodes a novel DNA repair enzyme, CPD-photolyase, that restores infectivity of UV light-damaged virus

Fowlpox virus (FPV), a pathogen of poultry, can persist in desiccated scabs shed from infected hosts. Although the mechanisms which ensure virus survival are unknown, it is likely that some type of remedial action against environmentally induced damage is required. In this regard, we have identified an open reading frame (ORF) coding for a putative class II cyclobutane pyrimidine dimer (CPD)-photolyase in the genome of FPV. This enzyme repairs the UV light-induced formation of CPDs in DNA by using blue light as an energy source and thus could enhance the viability of FPV during its exposure to sunlight. Based on transcriptional analyses, the photolyase gene was found to be expressed late during the FPV replicative cycle. That the resultant protein retained DNA repair activity was demonstrated by the ability of the corresponding FPV ORF to complement functionally a photolyase-deficient Escherichia coli strain. Interestingly, insertional inactivation of the FPV photolyase gene did not impair the replication of such a genetically altered virus in cultured cells. However, greater sensitivity of this mutant than of the parental virus to UV light irradiation was evident when both were subsequently photoreactivated in the absence of host participation. Therefore, FPV appears to incorporate its photolyase into mature virions where the enzyme can promote their survival in the environment. Although expression of a homologous protein has been predicted for some chordopoxviruses, this report is the first to demonstrate that a poxvirus can utilize light to repair damage to its genome.

Transcription elongation activity of the vaccinia virus J3 protein in vivo is independent of poly(A) polymerase stimulation

Prior genetic analysis suggests that the vaccinia virus J3 gene product, previously characterized as a bifunctional (nucleoside-2'-O-)-methyltransferase and poly(A) polymerase stimulatory factor, is a postreplicative positive transcription elongation factor. To test this hypothesis, viruses bearing mutations in the J3 gene were characterized with respect to viral protein and RNA synthesis in infected cells. The analysis reveals that compared to wt virus infections, J3 mutants synthesize reduced amounts of large late viral proteins and shorter-than-normal intermediate and late mRNAs. Structural analysis of one late mRNA shows that it is specifically truncated from the 3' end, thus accounting for its shorter than normal chain length. Thus J3 mutant viruses are defective in elongation of transcription of postreplicative viral genes, strongly suggesting that the J3 gene product normally acts as a positive transcription elongation factor. Biochemical analysis of one J3 missense mutant demonstrates that it retains poly(A) stimulatory activity but is defective in (nucleoside-2'-O-)-methyltransferase activity. Thus the elongation factor activity of the J3 gene product is independent of the poly(A) stimulatory activity. It remains to be determined whether the (nucleoside-2'-O-)-methyltransferase and elongation factor activities of the J3 protein are linked or can be uncoupled by mutation.

Analysis of a temperature-sensitive vaccinia virus mutant in the viral mRNA capping enzyme isolated by clustered charge-to-alanine mutagenesis and transient dominant selection

We have previously reported the successful development of a targeted genetic method for the creation of temperature-sensitive vaccinia virus mutants [D. E. Hassett and R. C. Condit (1994) Proc. Natl. Acad. Sci. USA 91, 4554-4558]. This method has now been applied to the large subunit of the multifunctional vaccinia virus capping enzyme, encoded by gene D1R. Ten clustered charge-to-alanine mutations were created in a cloned copy of D1R. Four of these mutations were successfully transferred into the viral genome using transient dominant selection, and each of these four mutations yielded viruses with plaque phenotypes different from that of wild-type virus. Two of the mutant viruses, 516 and 793, were temperature sensitive in a plaque assay. Mutant 793 was also temperature sensitive in a one-step growth experiment. Phenotypic characterization of the 793 virus under both permissive and nonpermissive conditions revealed nearly normal patterns of viral protein and mRNA synthesis. Under nonpermissive conditions the 793 virus was defective in telomere resolution and blocked at an intermediate stage of viral morphogenesis. In vitro assays of various capping enzyme activities revealed that in permeabilized virions, enzyme guanylylate intermediate formation was reduced and methyltransferase activity was thermolabile, while in solubilized virion extracts enzyme guanylylate activity was reduced and both guanylyltransferase and methyltransferase activities were absent. Thus, the 793 mutation affects at least two separate enzymatic activities of the capping enzyme, guanylyltransferase and methyltransferase, and when incorporated into the virus genome, the mutation yields a virus that is temperature sensitive for growth, telomere resolution, and virion morphogenesis.

Cellular processing limits the heterologous expression of secretory component in mammalian cells

Recombinant vaccinia-virus-based expression systems are very popular for the overproduction of proteins in mammalian cell lines. Both the double virus T7/vaccinia hybrid system and the single recombinant strategy based on the p11 K late promoter were evaluated for their ability to govern expression and secretion of recombinant human secretory component (SC), a glycoprotein associated with IgA in mucosal secretions. We report here that, while the T7 promoter is transcriptionally 3.4-fold more active than the p11 K promoter, no difference in levels of secreted recombinant human SC is observed using either vaccinia system to infect CV-1 cells. High transcription, and thus translation levels, lead to saturation of early processing steps involved in protein export. Both systems exhibit transient accumulation of comparable amount of recombinant human SC in the endoplasmic reticulum and/or the cis Golgi network, as demonstrated by immunofluorescence and endoglycosidase H (EndoH) sensitivities. Exposure of infected cells to tunicamycin results in similar inhibition of recombinant human SC export, further arguing that N-linked glycosylation is necessary for proper folding and subsequent secretion. Moreover, pulse-chase experiments indicate that newly synthesized recombinant human SC is not completely processed in a mature glycoprotein and that a portion of overexpressed SC might be degraded before it can be secreted. Recombinant human SC behaves identically to native SC in terms of kinetics of secretion and IgA-binding capacity. Our results indicate that optimization of expression systems should not only rely on the design of effective vectors, but also on the identification and clearance of the cellular bottlenecks associated with maturation of the secreted proteins.

Analysis of the nucleotide sequence of 23.8 kbp from the left terminus of the genome of variola major virus strain India-1967

Sequencing and computer analysis of the nucleotide sequence of variola major virus strain India-1967 (VAR-IND) DNA segment (23 786 bp) covering the left variable region of the viral genome has been carried out. Twenty-nine potential open reading frames were identified. Structure-function organization of the VAR-IND DNA segment was compared with previously reported sequences from analogous genome regions of vaccinia virus strains Copenhagen (VAC-COP) and Western Reserve (VAC-WR). Multiple structural differences between the VAR-IND and genome regions were analysed and both VAC-COP and VAC-WR have been found. Possible molecular factors of virulence, virus host range genes as well as differences revealed in the structure of these genes of VAR and VAC will be discussed.

Functional organization of variola major and vaccinia virus genomes

Comparison of the genomic organization of variola and vaccinia viruses has been carried out. Molecular factors of virulence of these viruses is the focus of this review. Possible roles of the genes of soluble cytokine receptors, complement control proteins, factors of virus replication, and dissemination in vivo for variola virus pathogenesis are discussed. The existence of "buffer" genes in the vaccinia virus genome is proposed.

Mapping and investigation of the role in pathogenesis of the major unique secreted 35-kDa protein of rabbitpox virus

Following infection, many secreted poxvirus proteins are able to modulate the host immune response through interactions with cytokines or components of the complement pathway. A comparison of the secreted protein profiles from cells infected with vaccinia Western Reserve (VV-WR), cowpox virus Brighton strain, or rabbitpox virus (RPV) showed an abundant 35-kDa protein present only in the supernatants from RPV-infected cells. The gene encoding this protein was identified and mapped by N-terminal sequencing of the protein. Examination of the predicted amino acid sequence showed it to be identical to the 35-kDa secreted protein of the Lister strain of vaccinia virus described by Patel et al. (1990, J. Gen. Virol. 71, 2013-2021). The counterpart of this gene in the commonly studied VV-WR strain is truncated and encodes a 7.5-kDa protein under control of the well-characterized p7.5 promoter. While nonessential for replication in cell culture, conservation of this gene in at least two orthopoxvirus strains suggested that this protein might play an important role in vivo. Following intranasal inoculation of Balb/c mice at several doses (10(3), 10(4), or 10(5) PFU), a mutant of RPV lacking a functional 35-kDa gene (RPV delta 35) appeared to induce an earlier onset and more severe illness at low, sublethal doses (10(3) PFU) than was observed with wild-type (wt) RPV. At higher doses (10(4) or 10(5) PFU), the behavior of wt RPV and RPV delta 35 became indistinguishable and the overall LD50 values were similar. Intradermal infection of rabbits simultaneously, at separate sites, with RPV and RPV delta 35 showed no gross or microscopic differences between either primary skin lesions or viremic extension of each virus into the lungs. Therefore, this abundant secreted protein does not appear to play a major role in the virulence of the virus.

Characterization and temporal regulation of mRNAs encoded by vaccinia virus intermediate-stage genes

The steady-state levels of mRNAs encoded by three intermediate-stage genes of vaccinia virus, A1L, A2L, and G8R, were compared with those encoded by well-characterized early- and late-stage genes. After synchronous infection of HeLa cells, the early mRNA was detected within 20 min and peaked at about 100 min; all three intermediate mRNAs were detected at 100 min and peaked at about 120 min; and the late mRNA was detected at 140 min and increased thereafter. Upon reaching maximum levels, the early and intermediate mRNAs declined at rates consistent with half-lives of about 30 min, providing the basis for rapid changes in gene expression. Intermediate mRNA was not detected when viral DNA synthesis was prevented, whereas its accumulation was enhanced by blocking translation after removal of the replication inhibitor. The 5' ends of the mRNAs initiated within a TAAAT or TAAAAT sequence in the coding DNA strand but contained a poly(A) leader of up to 30 additional bases. Diffuse bands of A1L and G8R RNA, equal to and longer than the coding region, were resolved by agarose gel electrophoresis, suggesting preferred sites of 3'-end formation that did not correlate with early gene termination signals. The cis-regulatory sequences were investigated by constructing recombinant viruses containing mutated intermediate promoters preceding the beta-galactosidase reporter gene. The effects of mutations on expression were similar to those previously obtained by transfection studies (C.J. Baldick, Jr., J.G. Keck, and B. Moss, J. Virol. 66:4710-4719, 1992), providing further evidence for functional core, spacer, and initiator regions. In addition, an up-regulated bifunctional early/intermediate promoter was created by making four single-base substitutions in the G8R promoter.

Transactivation by herpes simplex virus proteins ICP4 and ICP0 in vaccinia virus infected cells

Vaccinia virus recombinants containing the sequences from herpes simplex virus type 1 (HSV-1) encoding the immediate early (IE)(alpha) proteins ICP4 and ICP0, under the control of a mutated vaccinia virus 11K late promoter, were constructed. A cDNA copy of the gene encoding ICPO and an ICP4-encoding genomic segment were each inserted into the vaccinia virus genome at the thymidine kinase (TK) locus by homologous recombination. Steady-state analyses revealed that RNAs homologous to the IE-0 and IE-4 sequences accumulated in cells infected by recombinants with the kinetics of a typical vaccinia late mRNA. Western blot analyses demonstrated that the expression level of both ICPO and ICP4, produced by the recombinant viruses, was comparable to that in HSV-1-infected cells at late times postinfection. Both proteins synthesized in cells infected by the recombinants were located in the nucleus as revealed by immunofluorescence. Although in vitro studies reveal that extracts from vaccinia-virus-infected cells lose the ability to transcribe genes that contain RNA polymerase II promoters (Puckett and Moss (1983), Cell 35, 441-448) both ICPO and ICP4 expressed by the recombinant viruses can transactivate plasmids containing a reporter gene driven by the promoters for the HSV-1 TK and glycoprotein C genes. Nuclear extracts prepared from cells infected with the vaccinia virus vector expressing ICP4 exhibited sequence-specific DNA-binding activity.

Molecular characterization of the vaccinia virus hemagglutinin gene

The vaccinia virus hemagglutinin (HA) is a glycoprotein found on the plasma membrane of infected cells and the envelope of extracellular virus. Two forms of HA (85 and 68 kDa) are detected by immunoblot analysis. Although hemagglutination activity is only readily detectable late in infection, the 85-kDa HA appears early and accumulates throughout infection, whereas the 68-kDa form appears only late in the cycle. Production of the 68-kDa HA but not the 85-kDa HA was inhibited by either cytosine arabinoside or rifampin. Analysis of HA gene expression reveals a complex pattern of expression. The HA gene is transcribed early to yield a 1.65-kb dicistronic early transcript, consisting of the 945-bp HA open reading frame (ORF) fused to a 453-bp downstream ORF. Transcription from this site initiates 7 bases upstream of the AUG initiating codon of the HA ORF. Due to the discrepancy between the calculated size of the HA protein (33 kDa) and that reported for the unglycosylated HA protein derived from in vitro translation (58 kDa), we placed an early transcription termination signal (TTTTTAT) directly downstream of the 945-bp HA ORF. This led to a reduction in size of the early HA mRNA to 1.2 kb, as expected, but had no effect on the formation of either the 85- or 68-kDa protein. Transcripts originating from the early promoter are found throughout the infection cycle. However, after DNA replication, transcription from a second, late promoter ensues. The transcriptional start site of the late promoter is within a consensus TAAATG sequence located 135 bases upstream of the transcriptional start site of the first promoter. The late transcriptional start site is also found within an upstream ORF.

Genetic and molecular biological characterization of a vaccinia virus gene which renders the virus dependent on isatin-beta-thiosemicarbazone (IBT)

We have sequenced and analyzed the transcription of a gene capable of rendering vaccinia virus (VV) dependent upon isatin-beta-thiosemicarbazone (IBT) for growth. Marker rescue analysis of an IBT-dependent mutant of VV, IBTd-1, and a temperature-sensitive mutant of VV, ts56, both of which require IBT to grow at 40 degrees, showed that both lesions mapped to gene G2R. VV mutants with G2R deletions were constructed and shown to also be dependent upon IBT for growth. The nucleotide sequence changes responsible for IBTd-1, ts56, and the gene G2R deletion mutants were determined, and taken together show that IBT dependence results from inactivation of the orf G2R gene product. Gene G2R, which has the capacity to encode a 26-kDa protein, is transcribed solely early during infection. The 1.3-kb mRNA contains a 5' untranslated region of almost 600 nucleotides, and terminates about 20 nucleotides downstream from an early transcription termination signal. Transcription analyses of three flanking genes, as well as the map positions of the VV mutants ts11 and ts60 are also presented.

The molecular biology of swinepox virus. II. The infectious cycle

Studies based on low-stringency hybridizations of radiolabeled swinepox virus (SPV) DNA to Southern blots containing DNA of representative members of the Orthopoxvirus, Leporipoxvirus, and Avipoxvirus genera and the Entomopoxvirus subfamily have revealed no DNA homology at this level of resolution. Antigenic relatedness between SPV and vaccinia was also analyzed using immunoprecipitations and revealed little if any cross-reactivity. The growth characteristics of SPV in tissue culture were examined by light microscopy and revealed both a delayed and a different cytopathology than that of vaccinia virus. SPV causes foci in pig kidney cells that are not evident until at least 4 days postinfection, whereas vaccinia rapidly generates plaques on these cells. The kinetics of DNA accumulation, protein expression, and RNA transcription of SPV have been examined and indicate that each of these facets of the SPV growth cycle is also considerably delayed when compared to vaccinia virus. Our data indicate that swinepox virus is unique from other poxviruses characterized to date and supports the classification of swinepox virus into a separate genus, Suipoxvirus, within the poxvirus family.

Identification, sequence, and expression of the gene encoding the second-largest subunit of the vaccinia virus DNA-dependent RNA polymerase

The gene, rpo 132, encoding the second-largest subunit of the vaccinia virus DNA-dependent RNA polymerase was identified and sequenced. Two complementary approaches, involving antiserum to purified vaccinia virus RNA polymerase, were used to locate the rpo 132 gene. One method involved the screening of a lambda gt11 library of vaccinia virus genome fragments and the other was based on the immunoprecipitation and polyacrylamide gel electrophoresis of the in vitro translation products of mRNA that hybridized to immobilized vaccinia virus DNA. The deduced open reading frame of the rpo 132 gene predicted a polypeptide of 1164 amino acid residues with sequence similarities to the second-largest RNA polymerase subunits of eubacteria, archaebacteria, and eukaryotes as well as to other poxviruses. Transcriptional analyses indicated that rpo 132 has both early and late RNA start sites and is expressed throughout infection.

Structure and expression of the vaccinia virus gene which prevents virus-induced breakdown of RNA

Three noncomplementing vaccinia virus temperature-sensitive mutants, ts4, ts22, and ts23, exhibit an abortive late phenotype characterized by the simultaneous cessation of protein synthesis, the breakdown of rRNA and viral mRNA, and an increase in intracellular concentrations of 2'-5'-linked oligoadenylates late during infection at the nonpermissive temperature (R.F. Pacha and R.C. Condit, J. Virol. 56:395-403, 1985; R.J. Cohrs, R.C. Condit, R.F. Pacha, C.L. Thompson, and O.K. Sharma, J. Virol. 63:948-951, 1989). We have identified the virus gene affected by the abortive late mutants, determined its DNA sequence, and analyzed its transcription. The gene resides in the HindIII A DNA fragment, it has a predicted coding capacity of 57 kilodaltons, and it is transcribed both early and late during infection. The early transcript of the abortive late gene is unusual; it contains a 426-nucleotide 5' untranslated region, and it must be synthesized by transcription through an early transcription termination signal which is located in the middle of the gene in a hairpin loop structure. DNA sequence and transcription analysis of two flanking genes is also presented.

Removal of cryptic poxvirus transcription termination signals from the human immunodeficiency virus type 1 envelope gene enhances expression and immunogenicity of a recombinant vaccinia virus

The in vivo role of the proposed poxvirus early transcription termination signal TTTTTNT was confirmed by analysis of the RNA species made by recombinant vaccinia viruses. Premature transcription termination occurred following each of two TTTTTNT sequences present naturally within the coding region of the human immunodeficiency virus type 1 envelope gene. Alteration of the TTTTTNT sequences, without changing the encoded amino acids, resulted in production of full-length early mRNAs, improved protein expression, and a more consistent immune response.

Transcription of orthopoxvirus telomeres at late times during infection

The telomeres of orthopoxvirus DNAs consists largely of short repeated sequences organized into at least two separate sets. Although the sequence composition of the orthopoxvirus telomeres is highly conserved, these regions do not appear to encode any proteins. At late times during infection, the telomeres of vaccinia virus are transcribed. A promoter in the region between the two sets of repeats directs transcription towards the hairpin-loop end of the viral DNA. This promoter resembles the promoters of other poxvirus late genes, and directs the synthesis of RNAs whose structure is consistent with the presence of 5' poly(A) sequences typical of late RNAs. The lengths of these late transcripts suggest that some transcription extends through the hairpin-loop region. This might occur either when the genome is in a monomeric form or when the genome is in the concatemeric form of the DNA replication intermediate. The function of late transcription of the telomeres is unclear, but similar transcription of the telomeres of vaccinia virus, cowpox virus, and raccoonpox virus suggests that such transcription may have a role in viral replication.

Identification of factors specific for transcription of the late class of vaccinia virus genes

Cytoplasmic extracts made from HeLa cells that have been harvested late after infection with vaccinia virus are capable of specifically transcribing templates containing vaccinia virus late-gene promoters. We applied such an extract to a phosphocellulose column and eluted the proteins with a series of buffers containing successively higher concentrations of NaCl. None of three column fractions alone was capable of specific transcription of a late-gene template. However, specific transcriptase activity could be reconstituted by mixing column fractions, with maximal activity seen when all three fractions were present. The activities present in all fractions were heat labile, resistant to micrococcal nuclease, and present only in extracts from vaccinia virus-infected cells. A quantitative complementation assay was used to further purify one factor, named VLTF-1, over subsequent columns of DEAE-cellulose and hydroxylapatite. VLTF-1 was separated from endogenous RNA polymerase, was a late-promoter-specific transcription factor, and had a sedimentation rate consistent with an apparent Mr of 45,000. The RNA polymerase-containing fraction was not only necessary for transcription with a late-promoter template but alone was capable of specifically transcribing a vaccinia virus early-gene promoter. A further difference between early and late gene transcription in this system was in the ability of the ATP analog beta-8-imidoadenosine-5'-triphosphate (AMP-PNP) to substitute for ATP in supporting specific transcription of only the late-promoter template. The system reconstituted from the various fractions retained the ability to produce the novel poly(A) sequence found on the 5' end of vaccinia virus late messages.

Mapping and insertional mutagenesis of a vaccinia virus gene encoding a 13,800-Da secreted protein

The objective of this study was to identify and characterize the gene encoding a protein of approximately 12 kDa that is secreted from cells infected with the vaccinia virus. The absence of this protein from the medium of cells infected with a spontaneous deletion mutant (6/2) suggested that the open reading frame (ORF) was located within a 12,800-base pair segment near the left end of the genome (G. Kotwal and B. Moss, Nature (London) 335, 176-178, 1988). Antibody to the 12-kDa protein immunoprecipitated an appropriate size in vitro translation product of mRNA that hybridized to a DNA segment containing an ORF (N1L) that could encode a 13.8-kDa polypeptide. The similarity in the sizes of the in vitro translation product and the secreted protein was consistent with the absence of processing. Transcriptional analysis revealed major and minor early RNA start sites preceding the N1L ORF as well as a late RNA start site with an atypical TAAAAT sequence. The N1L gene was interrupted by replacing a segment of the ORF with the Escherichia coli beta-galactosidase gene. When two-dimensional polyacrylamide gel electrophoretic patterns of [35S]methionine-labeled proteins secreted from cells infected with parental and recombinant viruses were compared, a spot missing from the latter corresponded in molecular weigh and isoelectric point with that predicted from the N1L ORF. The latter analysis revealed the presence of other secreted proteins of similar molecular weight but different isoelectric points that also appear to map within the left end of the vaccinia genome. The recombinant virus was attenuated as judged by the increased intracranial LD50 for mice but nevertheless induced antibody and cytotoxic responses after intradermal and intraperitoneal injections. Relative to the parental virus, the recombinant was also more attenuated for immunodeficient nude mice, based on their survival time after infection.

Partial deletion of the human host range gene in the attenuated vaccinia virus MVA

The genome of a strongly attenuated vaccinia virus strain, MVA, was investigated by Southern blot and sequence analyses. Three major deletions, relative to the WR strain, were localized in MVA DNA. The deletions occurred near both ends of the viral genome and one of them affected a 55 K as well as the 32 K human host range gene. Although more than two thirds of the host range gene were eliminated from the MVA, the virus could still multiply in certain human cells.

Capped poly(A) leaders of variable lengths at the 5' ends of vaccinia virus late mRNAs

Evidence for capped poly(A) leaders of variable lengths located immediately upstream of the translation initiation codon was obtained by direct analyses of a major late mRNA species. A decapping-recapping method was used to specifically substitute a radioactively labeled phosphate for an unlabeled one within the cap structure. RNase H-susceptible sites were made by hybridizing synthetic oligodeoxyribonucleotides to the mRNA encoding a late major structural protein of 11 kilodaltons. Sequences of the type m7G(5')pppAmp (Ap)nUpG. . ., where n varies from a few to more than 40 nucleotides, were deduced by analysis of the length and sequence of RNase H, RNase T1, and RNase U2 digestion products.

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.

Molecular dissection of cis-acting regulatory elements from 5'-proximal regions of a vaccinia virus late gene cluster

Promoter elements responsible for directing the transcription of six tightly clustered vaccinia virus (VV) late genes (open reading frames [ORFs] D11, D12, D13, A1, A2, and A3) from the HindIII D/A region of the viral genome were identified within the upstream sequences proximal to each individual locus. These regions were identified as promoters by excising them from the VV genome, abutting them to the bacterial chloramphenicol acetyl transferase gene, and demonstrating their ability to drive expression of the reporter gene in transient-expression assays in an orientation-specific manner. To delineate the 5' boundary of the upstream elements, two of the VV late gene (A1 and D13) promoter: CAT constructs were subjected to deletion mutagenesis procedures. A series of 5' deletions of the ORF A1 promoter from -114 to -24 showed no reduction in promoter activity, whereas additional deletion of the sequences from -24 to +2 resulted in the complete loss of activity. Deletion of the ORF A1 fragment from -114 to -104 resulted in a 24% increase in activity, suggesting the presence of a negative regulatory region. In marked contrast to previous 5' deletion analyses which have identified VV late promoters as 20- to 30-base-pair cap-proximal sequences, 5' deletions to define the upstream boundary of the ORF D13 promoter identified two positive regulatory regions, the first between -235 and -170 and the second between -123 and -106. Background levels of chloramphenicol acetyltransferase expression were obtained with deletions past -88. Significantly, this places the ORF D13 regulatory regions within the upstream coding sequences of the ORF A1. A high-stringency computer search for homologies between VV late promoters that have been thus far characterized was carried out. Several potential consensus sequences were found just upstream from RNA start sites of temporally related promoter elements. Three major conclusions are drawn from these experiments. (i) The presence of promoters preceding each late ORF supports the hypothesis that each is expressed as an individual transcriptional unit. (ii) Promoter elements can be located within the coding portion of the upstream gene. (iii) Sequence homologies between temporally related promoter elements support the notion of kinetic subclasses of late genes.

The role of the host cell nucleus in vaccinia virus morphogenesis

Despite the fact that cells infected with wild type vaccinia virus synthesize viral DNA and assemble progeny virus particles within the cytoplasm, the host cell nucleus is required for a productive infection. Recent evidence suggests that vaccinia virus selectively recruits components from the host cell nucleus into the cytoplasm for use by the developing virus. One of these components is the largest subunit of the cellular RNA polymerase II (Pol II).

Vaccinia virus produces late mRNAs by discontinuous synthesis

We describe the unusual structure of a vaccinia virus late mRNA. In these molecules, the protein-coding sequences of a major late structural polypeptide are preceded by long leader RNAs, which in some cases are thousands of nucleotides long. These sequences map to different regions of the viral genome and in one instance are separated from the late gene by more than 100 kb of DNA. Moreover, the leader sequences map either upstream or downstream of the late gene, are transcribed from either DNA strand, and are fused to the late gene coding sequence via a poly(A) stretch. This demonstrates that vaccinia virus produces late mRNAs by tagging the protein-coding sequences onto the 3' end of other RNAs.

Tumorigenic poxviruses: transcriptional mapping of the terminal inverted repeats of Shope fibroma virus

A composite transcriptional map for the entire 12.4-kb terminal inverted repeat (TIR) region of the Shope fibroma virus (SFV) genome has been determined. Northern blotting and S1-nuclease mapping were used to determine the regions which are transcribed, their temporal relationships, as well as the transcriptional initiation sites. Sequences representing the entire TIR are transcribed into poly(A)+ mRNA at both early and late times in the infection. Fifteen transcriptional initiation sites were mapped, 12 within the TIRs and 3 within the unique sequences close to the junction between the right TIR and the unique internal sequences. Ten of the 12 transcriptional initiation sites within the TIR and 2 of the 3 sites outside the right TIR correspond to the 5'-ends of the major open reading frames (ORFs) T1 to T9 plus the SFV growth factor gene. The 3 other initiation sites map within ORFs but near potential start codons for shorter polypeptides. All the expressed ORFs are tandemly arranged and transcribed toward the hairpin terminus. At early times during SFV infection of cultured rabbit cells, transcription of each ORF gives rise to a transcript of distinct size, while at late times termination of transcription is imprecise and substantial read-through into downstream sequences occurs. These results are discussed in light of recent observations on the related recombinant leporipoxvirus, malignant rabbit fibroma virus, which suggest that one or more gene products from this region of the SFV genome are implicated in viral tumorigenicity.

Nucleotide sequence and transcript organization of a region of the vaccinia virus genome which encodes a constitutively expressed gene required for DNA replication

A vaccinia virus (VV) gene required for DNA replication has been mapped to the left side of the 16-kilobase (kb) VV HindIII D DNA fragment by marker rescue of a DNA- temperature-sensitive mutant, ts17, using cloned fragments of the viral genome. The region of VV DNA containing the ts17 locus (3.6 kb) was sequenced. This nucleotide sequence contains one complete open reading frame (ORF) and two incomplete ORFs reading from left to right. Analysis of this region at early times revealed that transcription from the incomplete upstream ORF terminates coincidentally with the complete ORF encoding the ts17 gene product, which is directly downstream. The predicted proteins encoded by this region correlate well with polypeptides mapped by in vitro translation of hybrid-selected early mRNA. The nucleotide sequences of a 1.3-kb BglII fragment derived from ts17 and from two ts17 revertants were also determined, and the nature of the ts17 mutation was identified. S1 nuclease protection studies were carried out to determine the 5' and 3' ends of the transcripts and to examine the kinetics of expression of the ts17 gene during viral infection. The ts17 transcript is present at both early and late times postinfection, indicating that this gene is constitutively expressed. Surprisingly, the transcriptional start throughout infection occurs at the proposed late regulatory element TAA, which immediately precedes the putative initiation codon ATG. Although the biological activity of the ts17-encoded polypeptide was not identified, it was noted that in ts17-infected cells, expression of a nonlinked VV immediate-early gene (thymidine kinase) was deregulated at the nonpermissive temperature. This result may indicate that the ts17 gene product is functionally required at an early step of the VV replicative cycle.

Noncoordinate regulation of a vaccinia virus late gene cluster

Identification of a tightly spaced and tandemly oriented late gene cluster within the central conserved region of the vaccinia virus genome suggested the possibility of coordinate regulation of the genes within this domain (S.L. Weinrich and D.E. Hruby, Nucleic Acids Res. 14:3003-3016, 1986). To test this hypothesis, the steady-state levels of transcripts derived from the individual late genes were examined. Cytoplasmic RNA was isolated from infected cells at hourly intervals throughout infection and was used in concert with 5' S1 nuclease mapping procedures to detect transcripts from specific late genes. Among the set of six closely linked late genes, marked differences were observed in both the levels of transcription and the kinetic patterns of expression, providing direct evidence for the existence of differentially regulated gene subsets within the late gene class. Furthermore, these experiments identified one of the genes (encoding a 33,000-molecular-weight polypeptide) as being expressed both early and late postinfection. Interestingly, although transcripts from the constitutively expressed gene were initiated at the same start sites throughout infection, a discrete terminus for these transcripts was detected only at early times. These data suggest that the lack of cis-acting termination signals is not the reason for the late gene transcript heterogeneity observed in vaccinia virus-infected cells.

Conserved TAAATG sequence at the transcriptional and translational initiation sites of vaccinia virus late genes deduced by structural and functional analysis of the HindIII H genome fragment

The sequence of the 8,600-base-pair HindIII H fragment, located at the center of the vaccinia virus genome, was determined to analyze several late genes. Seven major complete open reading frames (ORFs) and two that started from or continued into adjacent DNA segments were identified. ORFs were closely spaced and present on both DNA strands. Some adjacent ORFs had oppositely oriented overlapping termination codons or contiguous stop and start codons. Nucleotide compositional analysis indicated that the A-T frequency was consistently lowest in the first codon position. The sizes of the polypeptides predicted from the DNA sequence were compared with those determined by polyacrylamide gel electrophoresis of cell-free translation products of mRNAs selected by hybridization to cloned single-stranded DNA segments or synthesized in vitro by bacteriophage T7 RNA polymerase. Six transcripts that initiated within the HindIII H DNA fragment were detected, and of these, four were synthesized only at late times, one was synthesized only early, and one was synthesized early and late. The sites on the genome corresponding to the 5' ends of the transcripts were located by high-resolution nuclease S1 analysis. For late genes, the transcriptional and translational initiation sites mapped within a few nucleotides of each other, and in each case the sequence TAAATGG occurred at the start of the ORF. The extremely short leader and the absence of A or G in the -3 position, relative to the first nucleotide of the initiation codon, distinguishes the majority of vaccinia virus late genes from eucaryotic and vaccinia virus early genes.

Transcriptional mapping of early RNA from regions of the Shope fibroma and malignant rabbit fibroma virus genomes

Malignant rabbit fibroma virus (MV) is a recombinant poxvirus derived from Shope fibroma virus (SFV) and rabbit myxoma virus (D. S. Strayer, E. Skaletsky, G. F. Cabirac, P. A. Sharp, L. B. Corbeil, S. Sell, and J. L. Leibowitz, 1983a, J. Immunol. 130, 399-404; W. Block, C. Upton, and G. McFadden, 1984, Virology 140, 113-124). We report here the transcriptional mapping of early RNAs transcribed from the SFV sequences within MV and from the corresponding regions in SFV. Hybridization analysis and S1 nuclease mapping of RNA using viral DNA probes were used to define 5' and 3' ends of the various transcripts. The RNAs described here are transcribed in one direction in a densely arranged head to tail fashion similar to that described for some vaccinia virus early transcriptional units. At late times of infection the early SFV RNAs are not detected whereas the early MV RNAs are present in minor amounts. The early SFV and MV transcripts range in size from 3170 to 425 nucleotides (nt) long. All of the longer transcripts are produced as a result of read through transcription. Three MV transcripts contain fused SFV and rabbit myxoma virus sequences due to transcription through the recombination junction region in the MV genome. Two other MV transcripts are transcribed from a unique initiation site near another recombination junction region resulting in RNAs that are composed of SFV sequences having unique 5' ends.

Nucleotide sequence and genetic map of the 16-kb vaccinia virus HindIII D fragment

We have determined the nucleotide sequence of the 16,059-bp HindIII D fragment from vaccinia virus strain WR. Translation in all 6 reading frames reveals a set of 22 open reading frames (ORFs), which are capable of encoding proteins ranging from 61 to 844 amino acids in length. With one exception, ORF 12, we have divided them into two primary sets according to their size. The minor group contains eight members ranging in length from 61 to 84 amino acids. The major group has thirteen members varying from 146 to 844 amino acids in length, and, in addition, due to its location on the DNA, one small ORF, 61 amino acids long. The neighboring major ORFs are closely packed along the DNA, being separated by 42 or fewer base pairs. In several instances the ends of adjoining ORFs overlap for up to 11 triplet codons. In three cases, 1 or 2 bases are shared between translation start and stop signals in adjacent ORFs. Regions of both strands of the DNA are transcribed. Two sets of temperature-sensitive mutations, totaling 17, which map to the HindIII D fragment, have been combined into eight complementation groups. The results of marker rescue analysis map one or more member of each group to a site in the HindIII D fragment within a defined open reading frame.

Vaccinia virus proteins on the plasma membranes of infected cells. IV. Studies employing L cells infected with ultraviolet-irradiated vaccinia virions

As measured by in vitro, 51Cr-release assays, the expression on plasma membranes of two, immediate-early, vaccinia virus-specified cell-surface antigens, with mol wt of 25K-27K and 16K-17K, could be directly correlated with the susceptibility of target cells to lysis by vaccinia virus-specific cytotoxic T cells.

A tandemly-oriented late gene cluster within the vaccinia virus genome

The nucleotide sequence of a 5.1 kilobase-pair fragment from the central portion of the vaccinia virus genome has been determined. Within this region, five complete and two incomplete open reading frames (orfs) are tightly-clustered, tandemly-oriented, and read in the leftward direction. Late mRNA start sites for the five complete orfs and one incomplete orf were determined by S1 nuclease mapping. The two leftmost complete orfs correlated with late polypeptides of 65,000 and 32,000 molecular weight previously mapped to this region. When compared with each other and with sequences present in protein data banks, the five complete orfs showed no significant homology matches amongst themselves or any previously reported sequence. The six putative promoters were aligned with three previously sequenced late gene promoters. While all of the nine are A-T rich, the only apparent consensus sequence is TAA immediately preceeding the initiator ATG. Identification of this tandemly-oriented late gene cluster suggests local organization of the viral genome.

Transcriptional and translational mapping and nucleotide sequence analysis of a vaccinia virus gene encoding the precursor of the major core polypeptide 4b

We prepared antiserum that reacted with a major core polypeptide of approximately 62,000 daltons (62K polypeptide), designated 4b, and its 74K precursor, designated P4b. A cell-free translation product of vaccinia virus late mRNA that comigrated with P4b was specifically immunoprecipitated. The late mRNA encoding P4b hybridized to restriction fragments derived from the left end of the HindIII A fragment and to a lesser extent from the right side of the HindIII D fragment. A polypeptide that comigrated with P4a, the precursor of another major core polypeptide, was synthesized by mRNA that hybridized to DNA segments upstream of the P4b gene. Complete nucleotide sequence analysis of the P4b gene revealed an open reading frame, entirely within the HindIII A fragment, that was sufficient to encode a 644-amino-acid polypeptide of 73K. The 5' end of the P4b mRNA was located at or just above the translational initiation site.