Identification of the DNA sequences encoding the large subunit of the mRNA-capping enzyme of vaccinia virus

FAST Proteins: Development and Use of Reverse Genetics Systems for Reoviridae Viruses

Reverse genetics systems for viruses, the technology used to generate gene-engineered recombinant viruses from artificial genes, enable the study of the roles of the individual nucleotides and amino acids of viral genes and proteins in infectivity, replication, and pathogenicity. The successful development of a reverse genetics system for poliovirus in 1981 accelerated the establishment of protocols for other RNA viruses important for human health. Despite multiple efforts, rotavirus (RV), which causes severe gastroenteritis in infants, was refractory to reverse genetics analysis, and the first complete reverse genetics system for RV was established in 2017. This novel technique involves use of the fusogenic protein FAST (fusion-associated small transmembrane) derived from the bat-borne Nelson Bay orthoreovirus, which induces massive syncytium formation. Co-transfection of a FAST-expressing plasmid with complementary DNAs encoding RV genes enables rescue of recombinant RV. This review focuses on methodological insights into the reverse genetics system for RV and discusses applications and potential improvements to this system.

Thermostability, Tunability, and Tenacity of RNA as Rubbery Anionic Polymeric Materials in Nanotechnology and Nanomedicine-Specific Cancer Targeting with Undetectable Toxicity

RNA nanotechnology is the bottom-up self-assembly of nanometer-scale architectures, resembling LEGOs, composed mainly of RNA. The ideal building material should be (1) versatile and controllable in shape and stoichiometry, (2) spontaneously self-assemble, and (3) thermodynamically, chemically, and enzymatically stable with a long shelf life. RNA building blocks exhibit each of the above. RNA is a polynucleic acid, making it a polymer, and its negative-charge prevents nonspecific binding to negatively charged cell membranes. The thermostability makes it suitable for logic gates, resistive memory, sensor set-ups, and NEM devices. RNA can be designed and manipulated with a level of simplicity of DNA while displaying versatile structure and enzyme activity of proteins. RNA can fold into single-stranded loops or bulges to serve as mounting dovetails for intermolecular or domain interactions without external linking dowels. RNA nanoparticles display rubber- and amoeba-like properties and are stretchable and shrinkable through multiple repeats, leading to enhanced tumor targeting and fast renal excretion to reduce toxicities. It was predicted in 2014 that RNA would be the third milestone in pharmaceutical drug development. The recent approval of several RNA drugs and COVID-19 mRNA vaccines by FDA suggests that this milestone is being realized. Here, we review the unique properties of RNA nanotechnology, summarize its recent advancements, describe its distinct attributes inside or outside the body and discuss potential applications in nanotechnology, medicine, and material science.

Interplay between coronavirus, a cytoplasmic RNA virus, and nonsense-mediated mRNA decay pathway

Coronaviruses (CoVs) are important pathogens for humans and domestic animals. The development of effective countermeasures against CoVs requires an understanding of the host pathways that regulate viral gene expression and the viral subversion mechanisms. However, little is known about how the stability of viral mRNAs is controlled. We show that the nonsense-mediated decay (NMD) pathway, which primarily targets aberrant cellular mRNAs for degradation, also induced the degradation of CoV mRNAs that are of cytoplasmic origin. Our study further suggests the importance of CoV-induced inhibition of the NMD pathway, mediated by a viral protein, for efficient CoV replication. The present study highlights an interplay between the NMD pathway and CoVs that modulates viral replication by controlling the stability of viral mRNAs.

Coronaviruses (CoVs), including severe acute respiratory syndrome CoV and Middle East respiratory syndrome CoV, are enveloped RNA viruses that carry a large positive-sense single-stranded RNA genome and cause a variety of diseases in humans and domestic animals. Very little is known about the host pathways that regulate the stability of CoV mRNAs, which carry some unusual features. Nonsense-mediated decay (NMD) is a eukaryotic RNA surveillance pathway that detects mRNAs harboring aberrant features and targets them for degradation. Although CoV mRNAs are of cytoplasmic origin, the presence of several NMD-inducing features (including multiple ORFs with internal termination codons that create a long 3′ untranslated region) in CoV mRNAs led us to explore the interplay between the NMD pathway and CoVs. Our study using murine hepatitis virus as a model CoV showed that CoV mRNAs are recognized by the NMD pathway as a substrate, resulting in their degradation. Furthermore, CoV replication induced the inhibition of the NMD pathway, and N protein (a viral structural protein) had an NMD inhibitory function that protected viral mRNAs from rapid decay. Our data further suggest that the NMD pathway interferes with optimal viral replication by degrading viral mRNAs early in infection, before sufficient accumulation of N protein. Our study presents clear evidence for the biological importance of the NMD pathway in controlling the stability of mRNAs and the efficiency of replication of a cytoplasmic RNA virus.

Entirely plasmid-based reverse genetics system for rotaviruses

Rotaviruses (RVs) are highly important pathogens that cause severe diarrhea among infants and young children worldwide. The understanding of the molecular mechanisms underlying RV replication and pathogenesis has been hampered by the lack of an entirely plasmid-based reverse genetics system. In this study, we describe the recovery of recombinant RVs entirely from cloned cDNAs. The strategy requires coexpression of a small transmembrane protein that accelerates cell-to-cell fusion and vaccinia virus capping enzyme. We used this system to obtain insights into the process by which RV nonstructural protein NSP1 subverts host innate immune responses. By insertion into the NSP1 gene segment, we recovered recombinant viruses that encode split-green fluorescent protein-tagged NSP1 and NanoLuc luciferase. This technology will provide opportunities for studying RV biology and foster development of RV vaccines and therapeutics.

Cellular 5'-3' mRNA exonuclease Xrn1 controls double-stranded RNA accumulation and anti-viral responses

By accelerating global mRNA decay, many viruses impair host protein synthesis, limiting host defenses and stimulating virus mRNA translation. Vaccinia virus (VacV) encodes two decapping enzymes (D9, D10) that remove protective 5′ caps on mRNAs, presumably generating substrates for degradation by the host exonuclease Xrn1. Surprisingly, we find VacV infection of Xrn1-depleted cells inhibits protein synthesis, compromising virus growth. These effects are aggravated by D9 deficiency and dependent upon a virus transcription factor required for intermediate and late mRNA biogenesis. Considerable double-stranded RNA (dsRNA) accumulation in Xrn1-depleted cells is accompanied by activation of host dsRNA-responsive defenses controlled by PKR and 2′-5′ oligoadenylate synthetase (OAS), which respectively inactivate the translation initiation factor eIF2 and stimulate RNA cleavage by RNase L. This proceeds despite VacV-encoded PKR and RNase L antagonists being present. Moreover, Xrn1 depletion sensitizes uninfected cells to dsRNA treatment. Thus, Xrn1 is a cellular factor regulating dsRNA accumulation and dsRNA-responsive innate immune effectors.

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Vaccinia virus (VacV) replication requires the host Xrn1 mRNA decay enzyme

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The 5′-3′ mRNA exonuclease Xrn1 limits dsRNA accumulation

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In the absence of Xrn1, host dsRNA-responsive innate immune defenses are activated

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VacV antagonists of dsRNA-responsive host defenses are Xrn1 dependent

Biochemical analysis of the multifunctional vaccinia mRNA capping enzyme encoded by a temperature sensitive virus mutant

Prior biochemical analysis of the heterodimeric vaccinia virus mRNA capping enzyme suggests roles not only in mRNA capping but also in early viral gene transcription termination and intermediate viral gene transcription initiation. Prior phenotypic characterization of Dts36, a temperature sensitive virus mutant affecting the large subunit of the capping enzyme was consistent with the multifunctional roles of the capping enzyme in vivo. We report a biochemical analysis of the capping enzyme encoded by Dts36. Of the three enzymatic activities required for mRNA capping, the guanylyltransferase and methyltransferase activities are compromised while the triphosphatase activity and the D12 subunit interaction are unaffected. The mutant enzyme is also defective in stimulating early gene transcription termination and intermediate gene transcription initiation in vitro. These results confirm that the vaccinia virus mRNA capping enzyme functions not only in mRNA capping but also early gene transcription termination and intermediate gene transcription initiation in vivo.

Role of metalloproteases in vaccinia virus epitope processing for transporter associated with antigen processing (TAP)-independent human leukocyte antigen (HLA)-B7 class I antigen presentation

The transporter associated with antigen processing (TAP) translocates the viral proteolytic peptides generated by the proteasome and other proteases in the cytosol to the endoplasmic reticulum lumen. There, they complex with nascent human leukocyte antigen (HLA) class I molecules, which are subsequently recognized by the CD8(+) lymphocyte cellular response. However, individuals with nonfunctional TAP complexes or tumor or infected cells with blocked TAP molecules are able to present HLA class I ligands generated by TAP-independent processing pathways. Herein, using a TAP-independent polyclonal vaccinia virus-polyspecific CD8(+) T cell line, two conserved vaccinia-derived TAP-independent HLA-B*0702 epitopes were identified. The presentation of these epitopes in normal cells occurs via complex antigen-processing pathways involving the proteasome and/or different subsets of metalloproteinases (amino-, carboxy-, and endoproteases), which were blocked in infected cells with specific chemical inhibitors. These data support the hypothesis that the abundant cellular proteolytic systems contribute to the supply of peptides recognized by the antiviral cellular immune response, thereby facilitating immunosurveillance. These data may explain why TAP-deficient individuals live normal life spans without any increased susceptibility to viral infections.

Comparative whole genome sequence analysis of wild-type and cidofovir-resistant monkeypoxvirus

We performed whole genome sequencing of a cidofovir {[(S)-1-(3-hydroxy-2-phosphonylmethoxy-propyl) cytosine] [HPMPC]}-resistant (CDV-R) strain of Monkeypoxvirus (MPV). Whole-genome comparison with the wild-type (WT) strain revealed 55 single-nucleotide polymorphisms (SNPs) and one tandem-repeat contraction. Over one-third of all identified SNPs were located within genes comprising the poxvirus replication complex, including the DNA polymerase, RNA polymerase, mRNA capping methyltransferase, DNA processivity factor, and poly-A polymerase. Four polymorphic sites were found within the DNA polymerase gene. DNA polymerase mutations observed at positions 314 and 684 in MPV were consistent with CDV-R loci previously identified in Vaccinia virus (VACV). These data suggest the mechanism of CDV resistance may be highly conserved across Orthopoxvirus (OPV) species. SNPs were also identified within virulence genes such as the A-type inclusion protein, serine protease inhibitor-like protein SPI-3, Schlafen ATPase and thymidylate kinase, among others. Aberrant chain extension induced by CDV may lead to diverse alterations in gene expression and viral replication that may result in both adaptive and attenuating mutations. Defining the potential contribution of substitutions in the replication complex and RNA processing machinery reported here may yield further insight into CDV resistance and may augment current therapeutic development strategies.

Phenotypic analysis of a temperature sensitive mutant in the large subunit of the vaccinia virus mRNA capping enzyme

The heterodimeric vaccinia virus mRNA capping enzyme is a multifunctional enzyme, encoded by genes D1R and D12L. Published biochemical experiments demonstrate that, in addition to mRNA capping, the enzyme is involved in early viral gene transcription termination and intermediate viral gene transcription initiation. This paper presents the phenotypic characterization of Dts36, a temperature sensitive mutant in the large subunit of the mRNA capping enzyme (G705D), encoded by gene D1R. At the non-permissive temperature, Dts36 displays decreased steady state levels of some early RNAs, suggesting a defect in mRNA capping. Mutant infections also show decreased steady state levels of some early proteins, while DNA replication and post-replicative gene expression are absent. Under non-permissive conditions, the mutant directs synthesis of longer-than-normal early mRNAs from some genes, demonstrating that early gene transcription termination is defective. If mutant infections are initiated at the permissive temperature and shifted to the non-permissive temperature late during infection, steady state levels of intermediate gene transcripts decrease while the levels of late gene transcripts remain constant, consistent with a defect in intermediate gene transcription initiation. In addition to its previously described role in mRNA capping, the results presented in this study provide the first in vivo evidence that the vaccinia virus mRNA capping enzyme plays a role in early gene transcription termination and intermediate gene transcription.

Protein composition of the vaccinia virus mature virion

The protein content of vaccinia virus mature virions, purified by rate zonal and isopycnic centrifugations and solubilized by SDS or a solution of urea and thiourea, was determined by the accurate mass and time tag technology which uses both tandem mass spectrometry and Fourier transform-ion cyclotron resonance mass spectrometry to detect tryptic peptides separated by high-resolution liquid chromatography. Eighty vaccinia virus-encoded proteins representing 37% of the 218 genes annotated in the complete genome sequence were detected in at least three analyses. Ten proteins accounted for approximately 80% of the virion mass. Thirteen identified proteins were not previously reported as components of virions. On the other hand, 8 previously described virion proteins were not detected here, presumably due to technical reasons including small size and hydrophobicity. In addition to vaccinia virus-encoded proteins, 24 host proteins omitting isoforms were detected. The most abundant of these were cytoskeletal proteins, heat shock proteins and proteins involved in translation.

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.

Pox proteomics: mass spectrometry analysis and identification of Vaccinia virion proteins

BACKGROUND

Although many vaccinia virus proteins have been identified and studied in detail, only a few studies have attempted a comprehensive survey of the protein composition of the vaccinia virion. These projects have identified the major proteins of the vaccinia virion, but little has been accomplished to identify the unknown or less abundant proteins. Obtaining a detailed knowledge of the viral proteome of vaccinia virus will be important for advancing our understanding of orthopoxvirus biology, and should facilitate the development of effective antiviral drugs and formulation of vaccines.

RESULTS

In order to accomplish this task, purified vaccinia virions were fractionated into a soluble protein enriched fraction (membrane proteins and lateral bodies) and an insoluble protein enriched fraction (virion cores). Each of these fractions was subjected to further fractionation by either sodium dodecyl sulfate-polyacrylamide gel electophoresis, or by reverse phase high performance liquid chromatography. The soluble and insoluble fractions were also analyzed directly with no further separation. The samples were prepared for mass spectrometry analysis by digestion with trypsin. Tryptic digests were analyzed by using either a matrix assisted laser desorption ionization time of flight tandem mass spectrometer, a quadrupole ion trap mass spectrometer, or a quadrupole-time of flight mass spectrometer (the latter two instruments were equipped with electrospray ionization sources). Proteins were identified by searching uninterpreted tandem mass spectra against a vaccinia virus protein database created by our lab and a non-redundant protein database.

CONCLUSION

Sixty three vaccinia proteins were identified in the virion particle. The total number of peptides found for each protein ranged from 1 to 62, and the sequence coverage of the proteins ranged from 8.2% to 94.9%. Interestingly, two vaccinia open reading frames were confirmed as being expressed as novel proteins: E6R and L3L.

Vaccinia virus proteome: identification of proteins in vaccinia virus intracellular mature virion particles

Vaccinia virus is a large enveloped poxvirus with more than 200 genes in its genome. Although many poxvirus genomes have been sequenced, knowledge of the host and viral protein components of the virions remains incomplete. In this study, we used gel-free liquid chromatography and tandem mass spectroscopy to identify the viral and host proteins in purified vaccinia intracellular mature virions (IMV). Analysis of the proteins in the IMV showed that it contains 75 viral proteins, including structural proteins, enzymes, transcription factors, and predicted viral proteins not known to be expressed or present in the IMV. We also determined the relative abundances of the individual protein components in the IMV. Finally, 23 IMV-associated host proteins were also identified. This study provides the first comprehensive structural analysis of the infectious vaccinia virus IMV.

Diversity in the acute CD8 T cell response to vaccinia virus in humans

Orthopoxviruses have complex proteomes. Infection provokes a brisk CD8 response, which is required in some systems for recovery from primary infection. Little is known concerning the Ags and epitopes recognized by CD8 T cells. We examined the fine specificity of cloned and bulk human vaccinia-specific CD8 CTL by expressing polypeptide fragments from a library of vaccinia genomic DNA. This epitope discovery method emphasizes virus-specific biological activity, as the responder cells are all reactive with whole vaccinia virus. Sixteen novel epitopes, restricted by several HLA A and B alleles, were defined to the nomamer peptide level in diverse vaccinia open reading frames. An additional seven epitope were mapped to short regions of vaccinia proteins. Targets of the CD8 response included proteins assigned to structural, enzymatic, transcription factor, and immune evasion functions, and included members of all viral kinetic classes. Most epitopes were conserved in other orthopoxviruses. Responses to at least 18 epitopes were detected within a single blood sample, revealing a surprising degree of diversity. These epitopes will be useful in natural history studies of CD8 responses to vaccinia, a nonpersisting virus with long-term memory, and in the design and evaluation of attenuated and replication-incompetent vaccinia strains being tested for variola and monkeypox prevention and for the delivery of heterologous Ags.

Vaccinia virus transcription

Vaccinia virus replication takes place in the cytoplasm of the host cell. The nearly 200 kbp genome owes part of its complexity to encoding most of the proteins involved in genome and mRNA synthesis. The multisubunit vaccinia virus RNA polymerase requires a separate set of virus-encoded proteins for the transcription of the early, intermediate and late classes of genes. Cell fractionation studies have provided evidence for a role for host cell proteins in the initiation and termination of vaccinia virus intermediate and late gene transcription. Vaccinia virus resembles nuclear DNA viruses in the integration of viral and host proteins for viral mRNA synthesis, yet is markedly less reliant on host proteins than its nuclear counterparts.

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.

Vaccinia virus inhibitors as a paradigm for the chemotherapy of poxvirus infections

Poxviruses continue to pose a major threat to human health. Monkeypox is endemic in central Africa, and the discontinuation of the vaccination (with vaccinia virus) has rendered most humans vulnerable to variola virus, the etiologic agent of smallpox, should this virus be used in biological warfare or terrorism. However, a large variety of compounds have been described that are potent inhibitors of vaccinia virus replication and could be expected to be active against other poxviruses as well. These compounds could be grouped in different classes: (i) IMP dehydrogenase inhibitors (e.g., EICAR); (ii) SAH hydrolase inhibitors (e.g., 5'-noraristeromycin, 3-deazaneplanocin A, and various neplanocin A derivatives); (iii) OMP decarboxylase inhibitors (e.g., pyrazofurin) and CTP synthetase inhibitors (e.g., cyclopentenyl cytosine); (iv) thymidylate synthase inhibitors (e.g., 5-substituted 2'-deoxyuridines); (v) nucleoside analogues that are targeted at viral DNA synthesis (e.g., Ara-A); (vi) acyclic nucleoside phosphonates [e.g., (S)-HPMPA and (S)-HPMPC (cidofovir)]; and (vii) polyanionic substances (e.g., polyacrylic acid). All these compounds could be considered potential candidate drugs for the therapy and prophylaxis of poxvirus infections at large. Some of these compounds, in particular polyacrylic acid and cidofovir, were found to generate, on single-dose administration, a long-lasting protective efficacy against vaccinia virus infection in vivo. Cidofovir, which has been approved for the treatment of cytomegalovirus retinitis in immunocompromised patients, was also found to protect mice, again when given as a single dose, against a lethal aerosolized or intranasal cowpox virus challenge. In a biological warfare scenario, it would be advantageous to be able to use a single treatment for an individual exposed to an aerosolized poxvirus. Cidofovir thus holds great promise for treating human smallpox, monkeypox, and other poxvirus infections. Anecdotal experience points to the efficacy of cidofovir in the treatment of the poxvirus infections molluscum contagiosum and orf (ecthyma contagiosum) in immunosuppressed patients.

The genome sequence of Yaba-like disease virus, a yatapoxvirus

The genome sequence of Yaba-like disease virus (YLDV), an unclassified member of the yatapoxvirus genus, has been determined. Excluding the terminal hairpin loops, the YLDV genome is 144,575 bp in length and contains inverted terminal repeats (ITRs) of 1883 bp. Within 20 nucleotides of the termini, there is a sequence that is conserved in other poxviruses and is required for the resolution of concatemeric replicative DNA intermediates. The nucleotide composition of the genome is 73% A+T, but the ITRs are only 63% A+T. The genome contains 151 tightly packed open reading frames (ORFs) that either are > or =180 nucleotides in length or are conserved in other poxviruses. ORFs within 23 kb of each end are transcribed toward the termini, whereas ORFs within the central region of the genome are encoded on either DNA strand. In the central region ORFs have a conserved position, orientation, and sequence compared with vaccinia virus ORFs and encode many enzymes, transcription factors, or structural proteins. In contrast, ORFs near the termini are more divergent and in seven cases are without counterparts in other poxviruses. The YLDV genome encodes several predicted immunomodulators; examples include two proteins with similarity to CC chemokine receptors and predicted secreted proteins with similarity to MHC class I antigen, OX-2, interleukin-10/mda-7, poxvirus growth factor, serpins, and a type I interferon-binding protein. Phylogenic analyses indicated that YLDV is very closely related to yaba monkey tumor virus, but outside the yatapoxvirus genus YLDV is more closely related to swinepox virus and leporipoxviruses than to other chordopoxvirus genera.

Identification of the guanylyltransferase region and active site in reovirus mRNA capping protein lambda2

The 144-kDa lambda2 protein of mammalian reovirus catalyzes a number of enzymatic activities in the capping of reovirus mRNA, including the transfer of GMP from GTP to the 5' end of the 5'-diphosphorylated nascent transcript. This reaction proceeds through a covalently autoguanylylated lambda2-GMP intermediate. The smaller size of RNA capping guanylyltransferases from other organisms suggested that the lambda2-associated guanylyltransferase would be only a part of this protein. Limited proteinase K digestion of baculovirus-expressed lambda2 was used to generate an amino-terminal M(r) 42,000 fragment that appears to be both necessary and sufficient for guanylyltransferase activity. Although lysine 226 was identified by previous biochemical studies as the active-site residue that forms a phosphoamide bond with GMP in autoguanylylated lambda2, mutation of lysine 226 to alanine caused only a partial reduction in guanylyltransferase activity at the autoguanylylation step. Alanine substitution for other lysines within the amino-terminal region of lambda2 identified lysine 190 as necessary for autoguanylylation and lysine 171 as an important contributor to autoguanylylation. A novel active-site motif is proposed for the RNA guanylyltransferases of mammalian reoviruses and other Reoviridae members.

Alastrim smallpox variola minor virus genome DNA sequences

Alastrim variola minor virus, which causes mild smallpox, was first recognized in Florida and South America in the late 19th century. Genome linear double-stranded DNA sequences (186,986 bp) of the alastrim virus Garcia-1966, a laboratory reference strain from an outbreak associated with 0.8% case fatalities in Brazil in 1966, were determined except for a 530-bp fragment of hairpin-loop sequences at each terminus. The DNA sequences (EMBL Accession No. Y16780) showed 206 potential open reading frames for proteins containing >/=60 amino acids. The amino acid sequences of the putative proteins were compared with those reported for vaccinia virus strain Copenhagen and the Asian variola major strains India-1967 and Bangladesh-1975. About one-third of the alastrim viral proteins were 100% identical to correlates in the variola major strains and the remainder were >/=95% identical. Compared with variola major virus DNA, alastrim virus DNA has additional segments of 898 and 627 bp, respectively, within the left and right terminal regions. The former segment aligns well with sequences in other orthopoxviruses, particularly cowpox and vaccinia viruses, and the latter is apparently alastrim-specific.

The complete genomic sequence of the modified vaccinia Ankara strain: comparison with other orthopoxviruses

The complete genomic DNA sequence of the highly attenuated vaccinia strain modified vaccinia Ankara (MVA) was determined. The genome of MVA is 178 kb in length, significantly smaller than that of the vaccinia Copenhagen genome, which is 192 kb. The 193 open reading frames (ORFs) mapped in the MVA genome probably correspond to 177 genes, 25 of which are split and/or have suffered mutations resulting in truncated proteins. The left terminal genomic region of MVA contains four large deletions and one large insertion relative to the Copenhagen strain. In addition, many ORFs in this region are fragmented, leaving only eight genes structurally intact and therefore presumably functional. The inserted DNA codes for a cluster of genes that is also found in the vaccinia WR strain and in cowpox virus and includes a highly fragmented gene homologous to the cowpox virus host range gene, providing further evidence that a cowpox-like virus was the ancestor of vaccinia. Surprisingly, the central conserved region of the genome also contains some fragmented genes, including ORF F5L, encoding a major membrane protein, and ORFs F11L and O1L, encoding proteins of 39.7 and 77.6 kDa, respectively. The right terminal genomic region carries three large deletions all classical poxviral immune evasion genes and all ankyrin-like genes located in this region are fragmented except for those encoding the interleukin-1 beta receptor and the 68-kDa ankyrin-like protein B18R. Thus, the attenuated phenotype of MVA is the result of numerous mutations, particularly affecting the host interactive proteins, including the ankyrin-like genes, but also involving some structural proteins.

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.

The vaccinia virus H5R gene encodes late gene transcription factor 4: purification, cloning, and overexpression

The vaccinia virus late stage-specific transcription factor P3 was purified to homogeneity from HeLa cells that were infected in the presence of an inhibitor of viral DNA replication. The purified 36-kDa protein was digested with trypsin, and the peptides were analyzed by mass spectroscopy and amino-terminal sequencing. The purified factor was identified as the product of the vaccinia virus H5R open reading frame by both methods. A recombinant baculovirus was engineered to express the H5R open reading frame. The partially purified recombinant protein could replace the vaccinia virus P3 factor in transcription assays. On the basis of these findings, we assigned the H5R gene product the name viral late gene transcription factor 4 (VLTF-4). Unlike VLTF-1, -2, and -3, which are synthesized exclusively after viral DNA replication, VLTF-4 is synthesized before and after viral DNA synthesis. Indirect immunofluorescence of infected cells with anti-H5R protein antiserum demonstrated that VLTF-4 is diffusely distributed in the cytoplasm when DNA replication is blocked but is localized to discrete viral DNA-containing factories during a productive infection. Its expression pattern and subcellular distribution suggest that the H5R gene product may have multiple roles in the viral life cycle.

Domain structure of the vaccinia virus mRNA capping enzyme. Expression in Escherichia coli of a subdomain possessing the RNA 5'-triphosphatase and guanylyltransferase activities and a kinetic comparison to the full-size enzyme

The RNA 5'-triphosphatase, nucleoside triphosphate phosphohydrolase, and guanylyltransferase activities of the vaccinia virus mRNA capping enzyme were previously localized to an NH2-terminal 60-kDa domain of the D1R subunit. Measurement of the relative ATPase and guanylyltransferase activities remaining in D1R carboxyl-terminal deletion variants expressed in Escherichia coli BL21(DE3)plysS localizes the carboxyl terminus of the active domain to between amino acids 520 and 545. Failure to obtain a deletion mutant with the loss of one activity indicates that the catalysis of both reactions requires a common domain structure. Based on these results, a truncated D1R protein terminating at amino acid 545 was expressed in E. coli and purified to homogeneity. D1R1-545 was found to be kinetically equivalent to the holoenzyme in regard to ATPase, RNA 5'-triphosphatase, and guanylyltransferase activities. Measurement of RNA binding by mobility shift and UV photo-cross-linking analyses also demonstrates the ability of this domain to bind RNA independent of the methyltransferase domain, comprised of the carboxyl terminus of D1R from amino acids 498-844 and the entire D12L subunit. RNA binding to D1R1-545 is substantially weaker than binding to either the methyltransferase domain or the holoenzyme. Binding is inhibited by 5'-OH RNA and to a lesser extent by DNA oligonucleotides in a concentration dependent manner which correlates with the inhibition of RNA 5'-triphosphatase activity by these same oligonucleotides. We conclude that D1R1-545 represents a functionally independent domain of the mRNA capping enzyme, fully competent in substrate binding and catalysis at both the triphosphatase and guanylyltransferase active sites.

The vaccinia virus D5 protein, which is required for DNA replication, is a nucleic acid-independent nucleoside triphosphatase

The vaccinia virus D5 gene encodes a 90-kDa protein that is transiently expressed at early times after infection. Temperature-sensitive mutants with lesions in the D5 gene exhibit a fast-stop DNA- phenotype and are also impaired in homologous recombination. Here we report the overexpression of the D5 protein within the context of a vaccinia virus infection and its purification to apparent homogeneity. The purified protein has an intrinsic nucleoside triphosphatase activity which is independent of, and not stimulated by, any common nucleic acid cofactors. All eight common ribo- and deoxyribonucleoside triphosphates are hydrolyzed to the diphosphate form in the presence of a divalent cation. Implications for the role of D5 in viral DNA replication are addressed.

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.

A cellular factor is required for transcription of vaccinia viral intermediate-stage genes

The cytoplasmic location of vaccinia virus replication and evidence that the multisubunit DNA-dependent RNA polymerase, early and late stage transcription factors, capping and methylating enzymes, and poly(A) polymerase are virus encoded raised the possibility that all of the proteins needed for viral mRNA synthesis are of viral origin. Previous studies showed that four components from infected cells, the viral RNA polymerase and capping enzyme and two factors called vaccinia virus intermediate transcription factors (VITFs) 1 and 2, can reconstitute transcription of vaccinia virus intermediate-stage genes in vitro. Here, we demonstrate that VITF-2 can be isolated from the nuclei of uninfected HeLa cells as well as from the cytoplasm of infected cells. The proteins with VITF-2 activity from uninfected and infected cells cochromatographed and cosedimented, suggesting that they are identical. VITF-2 activity was found in extracts of other uninfected human and monkey cells but not in nonpermissive Trichoplusia ni insect cells or in conditionally permissive rabbit kidney 13 cells. VITF-2 activity was present, however, in a permissive line of rabbit kidney 13 cells that had been stably transfected with the vaccinia virus K1L host range gene. We suggest that the VITF-2 level acts as a gauge of the permissive state of the cell and thereby regulates the length of the early prereplicative phase of the infection.

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

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

Targeting of a multicomponent transcription apparatus into assembling vaccinia virus particles requires RAP94, an RNA polymerase-associated protein

When expression of the vaccinia virus gene encoding RAP94 (a protein that is associated with the viral multisubunit RNA polymerase and confers transcriptional specificity for early promoters) was repressed, the infectious virus yield was reduced by more than 99%. Nevertheless, intermediate- and late-stage viral gene expression and formation of ultrastructurally mature, membrane-enveloped virions occurred under the nonpermissive conditions. The RAP94-deficient particles contained the viral genome, structural proteins, early transcription factor, and certain enzymes but, unlike normal virions, had low or undetectable amounts of the viral RNA polymerase, capping enzyme/termination factor, poly(A) polymerase, DNA-dependent ATPase, RNA helicase, and topoisomerase. The presence of these viral enzymes in the cytoplasm indicated that RAP94 is required for targeting a complex of functionally related proteins involved in the biosynthesis of mRNA.

Transcription initiation factor activity of vaccinia virus capping enzyme is independent of mRNA guanylylation

Cytoplasmic extracts of vaccinia virus-infected HeLa cells blocked in DNA replication were capable of transcribing templates containing the minimal promoter sequences derived from three viral intermediate-stage genes (A1L, A2L, and G8R) but not promoters from early or late genes. One of three isolated components required for transcription copurified with the viral capping enzyme, a heterodimeric protein responsible for forming the 7-methyl-guanosine(5')triphospho(5')nucleoside [m7G(5')ppp(5')N-] structure at the 5' end of mRNAs, as had been reported using a template with another intermediate promoter [Vos, J. C., Sasker, M. & Stunnenberg, H. G. (1991) EMBO J. 10, 2553-2558]. Transcription factor activity was associated with partially, purified capping enzyme from infected cell extracts, homogeneous enzyme from purified virions, and recombinant viral enzyme from Escherichia coli. By transcribing truncated templates of different sizes, we determined that RNA chains of 35 nt were capped whereas those of 15 nt were not. Nevertheless, the capping enzyme was required for formation of short uncapped transcripts, indicating that capping and transcription initiation factor activities are independent functions.

Cap-specific mRNA (nucleoside-O2'-)-methyltransferase and poly(A) polymerase stimulatory activities of vaccinia virus are mediated by a single protein

The vaccinia virus gene for S-adenosyl-L-methionine:mRNA (nucleoside-O2'-)-methyltransferase, an enzyme required for the formation of the 5' cap structure of mRNA, was identified. Protein sequence analysis revealed that this cap-specific methyltransferase is derived from the same open reading frame as that previously shown to encode VP39, a Mr 39,000 dissociable subunit of poly(A) polymerase that stimulates the formation of long poly(A) tails. Consistent with this finding, methyltransferase activity was associated with the heterodimeric poly(A) polymerase, which is composed of VP55 and VP39 subunits, as well as with monomeric VP39 protein isolated from vaccinia virions. In addition, cap-specific nucleoside-O2'-methyltransferase activity is associated with recombinant VP39, which was purified to near homogeneity from mammalian cells. From these data, we concluded that the same protein functions as a methyltransferase and a poly(A) polymerase stimulatory factor to modify the 5' and 3' ends of mRNA, respectively.

Sequence and analysis of a portion of the genomes of Shope fibroma virus and malignant rabbit fibroma virus that is important for viral replication in lymphocytes

The 10.7-kb BamHI "C" restriction fragment of malignant rabbit fibroma virus (MV) contains genes that are important for its immunosuppressive activity. When this fragment is transferred to a related avirulent leporipoxvirus, Shope fibroma virus (SFV), recombinant viruses show clinical features characteristic of MV: they replicate in lymphocytes and alter immune function in vitro, induce disseminated tumors in recipient rabbits, and are immunosuppressive in vivo. The 10.7-kb BamHI "C" restriction fragment of MV was sequenced in its entirety. Its DNA sequence and the 14 ORF's derived from analyzing this sequence are discussed. Analysis of known open reading frames to which the ORF's from MV's Bam "C" fragment show homology permits us to identify some MV ORF's showing high degrees of similarity to known and postulated proteins produced by vaccinia virus. Functions for some of these vaccinia proteins are known, while functions for others are hypothetical or unknown. Further analysis of genetic determinants of MV's virulence has indicated that two overlapping restriction subfragments of the BamHI "C" fragment can transfer MV's virulent behavior to SFV. The 0.7-kb region in which these two subfragments overlap includes the C-terminus of MV orf C-7 and the N terminus of MV orf C-8. These correspond to the C- and N-termini, respectively, of SFV orf's D-9 and D-10 and to vaccinia orf's D-6 (early transcription factor) and D-7 (subunit of RNA polymerase). We sequenced the region of SFV's BamHI "D" fragment in this area and illustrate here the comparative sequences of this portion of SFV's genome and orf's. On the basis of comparisons between MV, SFV, and vaccinia in this area we discuss the potential significance of these observations.

Poly(A) polymerase and a dissociable polyadenylation stimulatory factor encoded by vaccinia virus

mRNA made in eukaryotic cells typically has a 3' poly(A) tail that is added posttranscriptionally. To investigate mechanisms by which 3' poly(A) is formed, we identified the genes for the two vaccina virus-encoded polypeptides, VP55 and VP39. Primer-dependent polyadenylation activity was associated exclusively with purified VP55-VP39 heterodimer, which, although stable to column chromatography and glycerol gradient sedimentation, was readily dissociated by antibody to an N-terminal peptide of VP55. Poly(A) polymerase activity was associated with immunopurified VP55, but not with immunopurified or chromatographically purified VP39. VP39 was, however, required for the formation of long poly(A) molecules, in conjunction with either purified VP55 or low concentrations of the heterodimer, and was shown to bind free poly(A). Thus, a catalytic polypeptide and a dissociable poly(A)-binding stimulatory factor each contribute to poly(A) tail formation. No prokaryotic or eukaryotic homologs of either polypeptide were detected in sequence data bases, consistent with the absence of previously reported poly(A) polymerase genes from any source.

Influence of S-adenosylhomocysteine hydrolase inhibitors on S-adenosylhomocysteine and S-adenosylmethionine pool levels in L929 cells

S-Adenosylhomocysteine hydrolase has been recognized as the target enzyme for the antiviral activity of several carbocyclic and acyclic adenosine analogues. In a previous study [Cools M and De Clercq E, Biochem Pharmacol 38: 1061-1067, 1989], we found a close correlation between the antiviral activity of six adenosine analogues [S)-9-(2,3-dihydroxypropyl)adenine [(S)-DHPA], (RS)-3-adenin-9-yl-2-hydroxypropanoic acid [(RS)-AHPA] (isobutyl ester), 3-deazaneplanocin A, carbocyclic 3-deazaadenosine (C-c3 Ado), adenosine dialdehyde and neplanocin A) against vaccinia virus and vesicular stomatitis virus and the inhibitory effect of these compounds on purified AdoHcy hydrolase isolated from murine L929 cells. We have now examined the effects of the different adenosine analogues on the intracellular pool levels of S-adenosylhomocysteine (AdoHcy) and S-adenosylmethionine (AdoMet). Treatment of vaccinia virus-infected L929 cells for 24 hr with the adenosine analogues at a dose that reduced vaccinia virus growth by 90% (ID90) increased the average AdoHcy pool levels from 0.027 nmol/mg protein to approximately 0.3 nmol/mg protein and the AdoHcy/AdoMet ratio from 0.038 to approximately 0.3. Moreover, the AdoHcy/AdoMet ratio correlated closely with the vaccinia virus yield reduction, both determined over the 24-hr post infection period (correlation coefficient of 0.972). These findings indicate that the activity of the AdoHcy hydrolase inhibitors against vaccinia virus may be related to the raise in intracellular AdoHcy pool levels and AdoHcy/AdoMet ratio.

The complete DNA sequence of vaccinia virus

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

The vaccinia virus HindIII F fragment: nucleotide sequence of the left 6.2 kb

The nucleotide sequence of the left 6.2 kb of the 13.2-kb HindIII F fragment of vaccinia virus was determined. Translation of the sequence revealed nine closely spaced, tandemly oriented open reading frames (ORFs), all reading leftward. The transcriptional organization of this region was determined by Northern blot and S1 nuclease mapping. The analysis suggested that ORFs 1, 2, 4, 5, 6, 7, and 8 are transcribed early in infection, whereas ORFs 3 and 9 are probably late genes. Two of these ORFs have been reported previously. ORF F4L encodes the small subunit of ribonucleotide reductase and ORF F2L is homologous to a retroviral protease-like gene.

Early transcription factor subunits are encoded by vaccinia virus late genes

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

Interaction and mutual stabilization of the two subunits of vaccinia virus mRNA capping enzyme coexpressed in Escherichia coli

The genes D1 and D2, predicted to encode the 95- and 31-kDa subunits of the vaccinia virus mRNA capping enzyme, were coexpressed from the same plasmid in Escherichia coli. Induction with low concentrations of isopropyl beta-D-thiogalactoside was necessary to obtain soluble enzyme. The active heterodimer was purified by column chromatography and was shown to have both RNA guanylyltransferase and mRNA (guanine-N7-)-methyltransferase activities. Formation of the m7G(5')pppG cap structure was verified by enzyme digestion and thin-layer chromatography. Each subunit was also expressed individually in E. coli. Without the large subunit, the small one was very unstable in some bacterial strains and could only be detected by pulse labeling with radioactive amino acids. The individually expressed large subunit contained the guanylyltransferase domain, but the activity from E. coli was less than 2% of that obtained with both subunits. Two other products of the D1 open reading frame were formed: a 55-kDa subfragment with the GMP binding site and a 38-kDa C-terminal fragment that started at amino acid 498. Expression of this heterodimeric enzyme in E. coli may facilitate the analysis of its functional domains and provide a useful reagent for the specific 5' labeling of uncapped or capped RNA and for enhancing RNA translatability in eukaryotic systems.

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

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

Orthopoxvirus genetics

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