Orthopoxvirus genetics

Poxvirus under the eyes of electron microscope

Zoonotic poxvirus infections pose significant threat to human health as we have witnessed recent spread of monkeypox. Therefore, insights into molecular mechanism behind poxvirus replication cycle are needed for the development of efficient antiviral strategies. Virion assembly is one of the key steps that determine the fate of replicating poxviruses. However, in-depth understanding of poxvirus assembly is challenging due to the complex nature of multi-step morphogenesis and heterogeneous virion structures. Despite these challenges, decades of research have revealed virion morphologies at various maturation stages, critical protein components and interactions with host cell compartments. Transmission electron microscopy has been employed as an indispensable tool for the examination of virion morphology, and more recently for the structure determination of protein complexes. In this review, we describe some of the major findings in poxvirus morphogenesis and the contributions of continuously advancing electron microscopy techniques.

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.

In a nutshell: structure and assembly of the vaccinia virion

Poxviruses comprise a large family of viruses characterized by a large, linear dsDNA genome, a cytoplasmic site of replication and a complex virion morphology. The most notorious member of the poxvirus family is variola, the causative agent of smallpox. The laboratory prototype virus used for the study of poxviruses is vaccinia, the virus that was used as a live, naturally attenuated vaccine for the eradication of smallpox. Both the morphogenesis and structure of poxvirus virions are unique among viruses. Poxvirus virions apparently lack any of the symmetry features common to other viruses such as helical or icosahedral capsids or nucleocapsids. Instead poxvirus virions appear as "brick shaped" or "ovoid" membrane-bound particles with a complex internal structure featuring a walled, biconcave core flanked by "lateral bodies." The virion assembly pathway involves a remarkable fabrication of membrane-containing crescents and immature virions, which evolve into mature virions in a process that is unparalleled in virology. As a result of significant advances in poxvirus genetics and molecular biology during the past 15 years, we can now positively identify over 70 specific gene products contained in poxvirus virions, and we can describe the effects of mutations in over 50 specific genes on poxvirus assembly. This review summarizes these advances and attempts to assemble them into a comprehensible and thoughtful picture of poxvirus structure and assembly.

The A20R protein is a stoichiometric component of the processive form of vaccinia virus DNA polymerase

In vitro analysis of the catalytic DNA polymerase encoded by vaccinia virus has demonstrated that it is innately distributive, catalyzing the addition of <10 nucleotides per primer-template binding event in the presence of 8 mM MgCl(2) or 40 mM NaCl (W. F. McDonald and P. Traktman, J. Biol. Chem. 269:31190-31197, 1994). In contrast, cytoplasmic extracts isolated from vaccinia virus-infected cells contain a highly processive form of DNA polymerase, able to catalyze the replication of a 7-kb template per binding event under similar conditions. To study this holoenzyme, we were interested in purifying and characterizing the vaccinia virus processivity factor (VPF). Our previous studies indicated that VPF is expressed early after infection and has a native molecular mass of approximately 48 kDa (W. F. McDonald, N. Klemperer, and P. Traktman, Virology 234:168-175, 1997). Using these criteria, we established a six-step chromatographic purification procedure, in which a prominent approximately 45-kDa band was found to copurify with processive polymerase activity. This species was identified as the product of the A20 gene. By use of recombinant viruses that direct the overexpression of A20 and/or the DNA polymerase, we verified the physical interaction between the two proteins in coimmunoprecipitation experiments. We also demonstrated that simultaneous overexpression of A20 and the DNA polymerase leads to a specific and robust increase in levels of processive polymerase activity. Taken together, we conclude that the A20 gene encodes a component of the processive DNA polymerase complex. Genetic data that further support this conclusion are presented in the accompanying report, which documents that temperature-sensitive mutants with lesions in the A20 gene have a DNA(-) phenotype that correlates with a deficit in processive polymerase activity (A. Punjabi et al, J. Virol. 75:12308-12318, 2001).

Clustered charge-to-alanine mutagenesis of the vaccinia virus A20 gene: temperature-sensitive mutants have a DNA-minus phenotype and are defective in the production of processive DNA polymerase activity

Although the vaccinia virus DNA polymerase is inherently distributive, a highly processive form of the enzyme exists within the cytoplasm of infected cells (W. F. McDonald, N. Klemperer, and P. Traktman, Virology 234:168-175, 1997). In the accompanying report we outline the purification of the 49-kDa A20 protein as a stoichiometric component of the processive polymerase complex (N. Klemperer, W. McDonald, K. Boyle, B. Unger, and P. Traktman, J. Virol. 75:12298-12307, 2001). To complement this biochemical analysis, we undertook a genetic approach to the analysis of the structure and function of the A20 protein. Here we report the application of clustered charge-to-alanine mutagenesis of the A20 gene. Eight mutant viruses containing altered A20 alleles were isolated using this approach; two of these, tsA20-6 and tsA20-ER5, have tight temperature-sensitive phenotypes. At the nonpermissive temperature, neither virus forms macroscopic plaques and the yield of infectious virus is <1% of that obtained at the permissive temperature. Both viruses show a profound defect in the accumulation of viral DNA at the nonpermissive temperature, although both the A20 protein and DNA polymerase accumulate to wild-type levels. Cytoplasmic extracts prepared from cells infected with the tsA20 viruses show a defect in processive polymerase activity; they are unable to direct the formation of RFII product using a singly primed M13 template. In sum, these data indicate that the A20 protein plays an essential role in the viral life cycle and that viruses with A20 lesions exhibit a DNA(-) phenotype that is correlated with a loss in processive polymerase activity as assayed in vitro. The vaccinia virus A20 protein can, therefore, be considered a new member of the family of proteins (E9, B1, D4, and D5) with essential roles in vaccinia virus DNA replication.

Role of vaccinia virus A20R protein in DNA replication: construction and characterization of temperature-sensitive mutants

Previous analyses of randomly generated, temperature-sensitive vaccinia virus mutants led to the mapping of DNA synthesis negative complementation groups to the B1R, D4R, D5R, and E9L genes. Evidence from the yeast two-hybrid system that the D4R and D5R proteins can interact with the A20R protein suggested that A20R was also involved in DNA replication. We found that the A20R gene was transcribed early after infection, consistent with such a role. To investigate the function of the A20R protein, targeted mutations were made by substituting alanines for charged amino acids occurring in 11 different clusters. Four mutants were not isolated, suggesting that they were lethal, two mutants exhibited no temperature sensitivity, two mutants exhibited partial temperature sensitivity, and two mutants formed no plaques or infectious virus at 39 degrees C. The two mutants with stringent phenotypes were further characterized. Temperature shift-up experiments indicated that the crucial period was between 6 and 12 h after infection, making it unlikely that the defect was in virus entry, early gene expression, or a late stage of virus assembly. Similar patterns of metabolically labeled viral early proteins were detected at permissive and nonpermissive temperatures, but one mutant showed an absence of late proteins under the latter conditions. Moreover, no viral DNA synthesis was detected when cells were infected with either stringent mutant at 39 degrees C. The previous yeast two-hybrid analysis together with the present characterization of A20R temperature-sensitive mutants suggested that the A20R, D4R, and D5R proteins are components of a multiprotein DNA replication complex.

Construction of a vaccinia virus deficient in the essential DNA repair enzyme uracil DNA glycosylase by a complementing cell line

The vaccinia virus D4R open reading frame, encoding the essential DNA repair enzyme uracil DNA glycosylase, was expressed in two permanent cell lines, the rabbit kidney cell line RK13 and the human fibroblast cell line 293. The temperature-sensitive vaccinia virus mutant ts4149, which maps within D4R, was able to grow under restrictive conditions in both of these transformed cell lines. Cell clones complemented D4R function to various degrees, demonstrating complementation of an essential vaccinia virus gene by a cell line constitutively expressing the essential function. Thus, the complementing host cells allowed the rescue of a virus defective in the D4R gene, demonstrating that this system may be used for the propagation of defective cytoplasmic DNA viruses. The defective virus grew to high yields only in the engineered cell lines. The data support the hypothesis that early gene products, such as uracil DNA glycosylase, supplied in trans can fully complement essential viral functions.

Vaccinia virus gene A18R encodes an essential DNA helicase

The vaccinia virus A18R protein is a DNA-dependent ATPase that contains the canonical sequence motifs associated with the DEXH group of DNA and RNA helicases. Investigation of A18R protein function during infection indicated it functions in the early and late phases of vaccinia virus transcription. The A18R protein shares sequence similarity with the mammalian DNA helicase ERCC3. The ERCC3 protein has a dual function: it is a component of the transcription factor TFIIH and is an essential participant in the cellular nucleotide excision repair pathway. Here we present evidence that the A18R protein is a DNA helicase that unwinds duplex DNA in a 3'-to-5' direction. The A18R helicase was inactive on RNA-DNA and RNA-RNA hybrids. The A18R unwinding activity was most efficient on DNA substrates with lengths of 20 nucleotides or less, and its unwinding activity was not stimulated by the addition of Escherichia coli single-strand-binding protein (SSB), the bacteriophage T4 gene 32 SSB, or the vaccinia virus I3L protein, a putative SSB. We have used an electrophoretic gel mobility shift assay to show that the A18R protein forms a stable complex with single-stranded DNA, and to a lesser extent RNA, in a reaction that does not require ATP.

Vaccinia virus morphogenesis is blocked by temperature-sensitive mutations in the F10 gene, which encodes protein kinase 2

Four previously isolated temperature-sensitive (ts) mutants of vaccinia virus WR (ts28, ts54, ts61, and ts15) composing a single complementation group have been mapped by marker rescue to the F10 open reading frame located within the genomic HindIII F DNA fragment. Sequencing of the F10 gene from wild-type and mutant viruses revealed single-amino-acid substitutions in the F10 polypeptide responsible for thermolabile growth. Although the ts mutants displayed normal patterns of viral protein synthesis, electron microscopy revealed a profound morphogenetic defect at the nonpermissive temperature (40 degrees C). Virion assembly was arrested at an early stage, with scant formation of membrane crescents and no progression to normal spherical immature particles. The F10 gene encodes a 52-kDa serine/threonine protein kinase (S. Lin and S. S. Broyles, Proc. Natl. Acad. Sci. USA 91:7653-7657, 1994). We expressed a His-tagged version of the wild-type, ts54, and ts61 F10 polypeptides in bacteria and purified these proteins by sequential nickel affinity and phosphocellulose chromatography steps. The wild-type F10 protein kinase activity was characterized in detail by using casein as a phosphate acceptor. Whereas the wild-type and ts61 kinases displayed similar thermal inactivation profiles, the ts54 kinase was thermosensitive in vitro. These findings suggest that protein phosphorylation plays an essential role at an early stage of virion assembly.

Conditional lethal expression of the vaccinia virus L1R myristylated protein reveals a role in virion assembly

Within vaccinia virus-infected cells, the product of the L1R open reading frame is covalently modified by myristic acid at the penultimate NH2-terminal glycine residue. Previously we have shown that while the L1R protein is a constituent of both intracellular mature virus particles and extracellular enveloped virions which are released from the infected cell, it is associated exclusively with the primary membranes surrounding the virion core. Given this rather specific localization, it was of interest to study the potential role of this essential gene in virus replication and morphogenesis. To this end, we have constructed a recombinant vaccinia virus in which expression of the L1R gene can be transcriptionally repressed. Without the inducer isopropylthiogalactopyranoside (IPTG), synthesis of the L1R protein was blocked, resulting in a total inhibition of plaque formation. Velocity sedimentation of viral particles labeled in the presence of [3H]thymidine, grown in the absence of IPTG, revealed a substantial reduction in viral DNA incorporation into virions. Likewise, proteolysis of the major core proteins p4a, p4b, and p25K, believed to occur during the final stages of virion maturation, was severely impaired. In the absence of L1R expression, only immature virions could be detected by electron microscopy. Transient expression of a plasmid containing the full-length L1R gene driven by its own promoter was able to complement and rescue the defective phenotype. However, a plasmid bearing a mutation in the myristyl acceptor glycine residue was unable to biologically rescue the recombinant, and the protein was not detected in purified virions.trans complementation using a truncated, myristylated form of the L1R protein partially rescued the defective mutant. Collectively, these data suggest that myristic acid mediates essential interactions of the L1R protein with viral membranes and/or other virion components that lead to the productive assembly, maturation, and release of particles.

Targeted construction of temperature-sensitive mutations in vaccinia virus by replacing clustered charged residues with alanine

The feasibility of using "clustered charge-to-alanine" mutagenesis (replacement by alanine of two or more charged residues clustered in a five- or six-amino acid sequence) to create temperature-sensitive, conditionally lethal mutations in vaccinia virus was examined by creating nine mutations in the vaccinia virus gene G2R. G2R was chosen for this analysis because mutations in this gene confer selectable phenotypes. Specifically, vaccinia viruses that contain a wild-type copy of G2R nare sensitive the effects of the anti-poxvirus drug isatin-beta-thiosemicarbazone (IBT), while mutations in G2R that completely abolish the function of the G2R protein product confer dependence upon IBT for growth. A previously isolated mutant carrying a temperature-sensitive mutation that maps to G2R (Cts56) is resistant to IBT at the permissive temperature and dependent upon IBT at the restrictive temperature. Nine clustered charge-to-alanine mutants were examined. Four of the these mutants (AS1, AS4, AS6, and AS9) display some degree of temperature sensitivity in the function of the G2R gene product. AS1 is temperature sensitive for growth in both a plaque assay and in a one-step growth experiment. AS6 and AS9 form small plaques at the nonpermissive temperature and are temperature sensitive for growth in a one-step growth experiment. AS4 manifests its temperature sensitivity as temperature-dependent IBT resistance. Five of the mutations (AS2, AS3, AS5, AS7, and AS8) appeared to confer phenotypes indistinguishable from that of wild-type vaccinia. These results demonstrate that temperature-sensitive conditionally lethal mutants can be created in vaccinia virus by altering the charge characteristics of essential viral proteins.

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.

Immature viral envelope formation is interrupted at the same stage by lac operator-mediated repression of the vaccinia virus D13L gene and by the drug rifampicin

Specific missense mutations of the vaccinia virus D13L gene confer resistance to the effects of rifampicin on virion morphogenesis. We constructed a recombinant vaccinia virus in which elements of the Escherichia coli lac operator system were used to regulate the D13L gene. Replication of the recombinant vaccinia virus was dependent on addition of the inducer isopropyl beta-D-thiogalactoside (IPTG) and the virus yield was decreased by more than 99% when IPTG was omitted. Under the nonpermissive condition, transcription of the D13L gene was reduced and synthesis of the 65,000-Da protein product was inhibited by more than 95%. Consequently, virion morphogenesis was blocked at an early stage and uncoated membrane precursors of the immature viral envelope and uncleaved precursors of the major core proteins accumulated. The phenotype of the conditional lethal mutant virus, in the absence of IPTG, closely resembled that of wild-type virus in cells treated with rifampicin.

A vaccinia virus isatin-beta-thiosemicarbazone resistance mutation maps in the viral gene encoding the 132-kDa subunit of RNA polymerase

The mutation in a vaccinia virus mutant resistant to inhibition by isatin-beta-thiosemicarbazone was mapped by marker rescue. DNA from the resistant mutant was cloned into cosmid and plasmid vectors and tested for its ability to convert wild-type vaccinia virus to IBT resistant virus in a helper-mediated marker rescue protocol. Resistance was mapped in this way to a 0.9-kb DNA fragment derived from the HindIII A fragment of vaccinia genome. Southern blot hybridization using this DNA as a probe demonstrated that the 0.9-kb fragment is contained within the DNA sequence encoding the second largest subunit of vaccinia RNA polymerase, rpo132. Thus, mutation of rpo132 can cause resistance to IBT in vaccinia virus.

Identification and DNA sequence of the large subunit of the capping enzyme from Shope fibroma virus

A 3.6-kb region of the Shope fibroma virus (SFV) BamHI D fragment located in the central region of the viral genome was sequenced. Three open reading frames (ORFs) were identified, D3R, D4L, and D5R. Each of these ORFs have a counterpart organized identically within the HindIII fragment D of the vaccinia virus genome (D1R, D2L, and D3R). Homology scores and assays of viral cores indicate that SFV D3R encodes the large subunit of the SFV mRNA capping enzyme.

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.

Effect of marker distance and orientation on recombinant formation in poxvirus-infected cells

Little is known about the mechanism of poxvirus recombination even though construction of recombinant viruses by recombination-dependent methods is a widely adopted technique. We have shown previously that transfected DNAs are efficiently recombined while replicating in cells infected with Shope fibroma virus. Because recombinant DNA can be recovered from infected cells as a high-molecular-weight head-to-tail concatemer, it was possible to transfect genetically marked lambda DNAs into infected cells and assay recombinants as bacteriophage particles following in vitro packaging. This approach was used in this study to examine how marker distance and marker orientation influence recombination in Shope fibroma virus-infected cells. Simple two-factor crosses were readily modelled by using a mapping function derived from classical phage studies and showed low negative interference (I = -2.8 +/- 0.5) in crosses involving markers greater than 100 bp apart. More complex four- and five-factor crosses showed that the recombination frequency per unit distance was not constant (rising as the marker separation was reduced from 100 to 1 bp) and that crosses performed in poxvirus-infected cells are subject to high negative interference. One consequence is that marker orientation does not dramatically influence the outcome of most Shope fibroma virus-catalyzed crosses in clear contrast to what is observed in adenovirus or simian virus 40-infected cells. These results can be interpreted to indicate that similar statistical and physical constraints influence both viral and phage recombination and suggest that heteroduplexes may be important intermediates in the poxvirus recombination process.

Vaccinia virus homologues of the Shope fibroma virus inverted terminal repeat proteins and a discontinuous ORF related to the tumor necrosis factor receptor family

Nucleotide sequencing data from a region extending 35 kb inward from the right inverted terminal repeat (ITR) of the vaccinia virus (VV) genome established the presence of VV homologues of the Shope fibroma virus (SFV) ITR proteins. The nucleotide sequences, comprising a total of 8.6 kb, and the amino acid translations for nine predicted open reading frames (ORFs) (designated SalF4L, SalF 19R, SalF21R, B4R, B8R, B9R, B10R, and B14R) are presented. Eight of the nine VV genes and all the SFV ORFs are transcribed towards their genomic termini. However, the relative positions of the VV genes (genus Orthopoxvirus) are different than those of the corresponding ORFs in SFV (genus Leporipoxvirus), indicating complex rearrangements of DNA in the genome of one or both of these viruses subsequent to their divergence from a common ancestor. Several other features of the VV ORFs were noted. SalF4L, B7R, B8R, and B9R have hydrophobic amino-terminal signal sequences but lack discernible membrane anchor domains suggesting that the proteins may be secreted. VV ORF SalF19R has a single cysteine-rich region homologous to the multiple domains of nerve growth factor receptor (NGFR), CD40, OX40 (a glycoprotein from the surface of activated murine T lymphocytes), and the recently described tumor necrosis factor receptors. Just downstream of the ORF SalF19R and in a different reading frame, there are another two related cysteine-rich domains, indicating that SalF19R was once a larger gene. B4R has homology to the host range gene of cowpox virus and to related genes near the opposite end of the vaccinia virus genome, and contains regions homologous to the repeat domains of erythrocyte ankyrin. In addition, several of the VV ORFs have homology to ORFs from near the opposite end of the VV genome, thus increasing the number of known VV gene families.

IPTG-dependent vaccinia virus: identification of a virus protein enabling virion envelopment by Golgi membrane and egress

A novel method has been developed to study the functional roles of individual vaccinia virus gene products that is neither limited by the possible essentiality of the target gene nor by the availability of conditional lethal mutants. The system utilises the E. coli lac repressor protein, the operator sequence to which it binds and the specific inducer IPTG. It allows the generation of recombinant viruses in which the expression of any chosen gene, and hence virus replication, can be externally controlled. In principle, this system is broadly applicable to the functional analysis of genes in any large DNA virus. This approach has demonstrated that the gene encoding the 14 kDa membrane protein of vaccinia virus is non-essential for the production of infectious intracellular virus particles, but essential for the envelopment of intracellular virions by Golgi membrane and for egress of mature extracellular viral particles. This is the first vaccinia virus protein shown to be specifically required for these processes. In vivo this system may prove useful as a means of attenuating recombinant vaccinia virus vaccines by preventing virus spread without reducing the amount of the foreign antigen expressed in each infected cell. Attenuation of other live virus vaccines may be developed in a similar way.