Poxvirus DNA

Poxvirus Vaccines: Past, Present, and Future

Smallpox was a significant cause of mortality for over three thousand years, amounting to 10% of deaths yearly. Edward Jenner discovered smallpox vaccination in 1796, which rapidly became a smallpox infection preventive practice throughout the world and eradicated smallpox infection by 1980. After smallpox eradication, monkeypox vaccines have been used primarily in research and in outbreaks in Africa, where the disease is endemic. In the present, the vaccines are being used for people who work with animals or in high-risk areas, as well as for healthcare workers treating patients with monkeypox. Among all orthopoxviruses (OPXV), monkeypox viral (MPXV) infection occurs mainly in cynomolgus monkeys, natural reservoirs, and occasionally causes severe multi-organ infection in humans, who were the incidental hosts. The first case of the present epidemic of MXPV was identified on May 7, 2022, and rapidly increased the number of cases. In this regard, the WHO declared the outbreak, an international public health emergency on July 23, 2022. The first monkeypox vaccine was developed in the 1960s by the US Army and was based on the vaccinia virus, which is also used in smallpox vaccines. In recent years, newer monkeypox vaccines have been developed based on other viruses such as Modified Vaccinia Ankara (MVA). These newer vaccines are safer and can provide longer-lasting immunity with fewer side effects. For the future, there is ongoing research to improve the current vaccines and to develop new ones. One notable advance has been the development of a recombinant vaccine that uses a genetically modified vaccinia virus to express monkeypox antigens. This vaccine has shown promising results in pre-clinical trials and is currently undergoing further testing in clinical trials. Another recent development has been the use of a DNA vaccine, which delivers genetic material encoding monkeypox antigens directly into cells. This type of vaccine has shown effectiveness in animal studies and is also undergoing clinical testing in humans. Overall, these recent advances in monkeypox vaccine development hold promise for protecting individuals against this potentially serious disease.

Atomic force microscopy investigation of vaccinia virus structure

Vaccinia virus was treated in a controlled manner with various combinations of nonionic detergents, reducing agents, and proteolytic enzymes, and successive products of the reactions were visualized using atomic force microscopy (AFM). Following removal of the outer lipid/protein membrane, a layer 20 to 40 nm in thickness was encountered that was composed of fibrous elements which, under reducing conditions, rapidly decomposed into individual monomers on the substrate. Beneath this layer was the virus core and its prominent lateral bodies, which could be dissociated or degraded with proteases. The core, in addition to the lateral bodies, was composed of a thick, multilayered shell of proteins of diverse sizes and shapes. The shell, which was readily etched with proteases, was thoroughly permeated with pores, or channels. Prolonged exposure to proteases and reductants produced disgorgement of the viral DNA from the remainders of the cores and also left residual, flattened, protease-resistant sacs on the imaging substrate. The DNA was readily visualized by AFM, which revealed some regions to be "soldered" by proteins, others to be heavily complexed with protein, and yet other parts to apparently exist as bundled, naked DNA. Prolonged exposure to proteases deproteinized the DNA, leaving masses of extended, free DNA. Estimates of the interior core volume suggest moderate but not extreme compaction of the genome.

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.

Characterization of vaccinia virus early promoters and evaluation of their informational content

We have reported the isolation of cis-acting regulatory DNA sequences promoting expression of the herpes virus thymidine kinase gene in vaccinia virus recombinants. In this work we show that each of the inserts from recombinants VpT25, 28, 36 and 56 contains a vaccinia virus early promoter. The position of each of the early RNA start sites in the nucleotide sequence of these four vaccinia virus inserts was precisely mapped by an S1 nuclease mapping procedure. Among the four recombinants analysed only VpT56-infected cells also contained a substantial amount of a transcript with the same 5' end at late period. The insert present in VpT25 contained a new late RNA start site 50 nucleotides upstream from that of the early RNA. The four inserts were mapped on the vaccinia virus genome. We also localized the 5' end of the mRNA of a vaccinia virus host-range gene, whose DNA nucleotide sequence has recently been established. The 45 nucleotides preceding the RNA start site from most of 19 known vaccinia virus early promoters were found to be A + T-rich (at least 80%) and contained shorter A-rich (at least 60%) regions, beginning approximately 25 nucleotides upstream from the RNA start site. The information content, as expressed by the parameter Rsequence, of early vaccinia virus promoters revealed ten bits of information in the sequence of 28 nucleotides upstream from the early RNA start sites. Most of the information needed to locate an early promoter is contained within the nucleotide sequence upstream from an RNA start site. A consensus sequence consists of two blocks: the sequence AA(A/T)N(T/A)N(A/G)AAAANAANA starting at position -27 and the sequence (T/A)(C/T)N(A/T)T(A/G) starting at position -5. It was concluded that vaccinia virus early promoters may be characterized by an A + T-rich region of approximately 45 nucleotides preceding the RNA start site and include a specific 3'-terminal sequence of 28 nucleotides containing at least ten bits of information. A procedure for localizing putative early RNA start sites in nucleotide sequences is proposed.

African swine fever virus DNA: deletions and additions during adaptation to growth in monkey kidney cells

Restriction enzyme cleavage maps for the fragments produced by Cla I, Sal I and Sma I have been constructed for African swine fever virus (ASFV) DNA grown in pig leukocytes (strain E70 L6) and after adaptation to growth in MS monkey kidney cells (strain E70MS14). The mapping data revealed that before adaptation to growth in MS cells, the size of the DNA from ASFV strain E70 L6 was l73 Kbp and after adaptation it was only l56 Kbp. The decrease in size was produced by deletions and additions mainly in the terminal regions of the genome. These genetic variations were located between 0.0 to 0.01 m.u. (Cla I-M1 fragment), 0.04 to 0.14 m.u. (Sma I-B1, Sal I-A1 fragments), 0.51 to 0.52 m.u. (Cla I-O fragment), 0.84 to 0.86 m.u. (Sma I-H1), 0.95 to 0.97 m.u. (Cla I-A1, Cla I-G1 fragments) and 0.99 to 1.0 m.u. (Cla I-G1) on viral genome of ASFV grown in pig leukocytes.

Tumorigenic poxviruses: genomic organization and DNA sequence of the telomeric region of the Shope fibroma virus genome

Shope fibroma virus (SFV), a tumorigenic poxvirus, has a 160-kb linear double-stranded DNA genome and possesses terminal inverted repeats (TIRs) of 12.4 kb. The DNA sequence of the terminal 5.5 kb of the viral genome is presented and together with previously published sequences completes the entire sequence of the SFV TIR. The terminal 400-bp region contains no major open reading frames (ORFs) but does possess five related imperfect palindromes. The remaining 5.1 kb of the sequence contains seven tightly clustered and tandemly oriented ORFs, four larger than 100 amino acids in length (T1, T2, T4, and T5) and three smaller ORFs (T3A, T3B, and T3C). All are transcribed toward the viral hairpin and almost all possess the consensus sequence TTTTTNT near their 3' ends which has been implicated for the transcription termination of vaccinia virus early genes. Searches of the published DNA database revealed no sequences with significant homology with this region of the SFV genome but when the protein database was searched with the translation products of ORFs T1-T5 it was found that the N-terminus of the putative T4 polypeptide is closely related to the signal sequence of the hemagglutinin precursor from influenza A virus, suggesting that the T4 polypeptide may be secreted from SFV-infected cells. Examination of other SFV ORFs shows that T1 and T2 also possess signal-like hydrophobic amino acid stretches close to their N-termini. The protein database search also revealed that the putative T2 protein has significant homology to the insulin family of polypeptides. In terms of sequence repetitions, seven tandemly repeated copies of the hexanucleotide ATTGTT and three flanking regions of dyad symmetry were detected, all in ORF T3C. A search for palindromic sequences also revealed two clusters, one in ORF T3A/B and a second in ORF T2. ORF T2 harbors five short sequence domains, each of which consists of a 6-bp short palindrome and a 10- to 18-bp larger palindrome. The significance of these palindromic domains in this ORF is unclear but the coincidence of the end of one larger palindrome with the end of the translated protein sequence that has homology with the B chain of insulin suggests that the palindromes may divide the T2 protein into several functional units. The salient organizational features of the complete SFV TIR are also discussed in light of what is known about other poxviral TIRs.

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.

DNA sequence homology between the terminal inverted repeats of Shope fibroma virus and an endogenous cellular plasmid species

DNA hybridization experiments indicate that the genome of a tumorigenic poxvirus. Shope fibroma virus (SFV), possesses sequence homology with DNA isolated from uninfected rabbit cells. Southern blotting experiments, either with high-complexity rabbit DNA as probe and SFV restriction fragments as targets or with high-specific activity, 32P-labeled, cloned SFV sequences as probes and rabbit DNA as target, indicate that the homologous sequences map at two locations within the viral genome, one in each copy of the terminal inverted repeat sequences. Unexpectedly, Southern blots revealed that the homologous host sequences reside in a rabbit extrachromosomal DNA element. This autonomous low-molecular-weight DNA species could be specifically amplified by cycloheximide treatment and was shown by isopycnic centrifugation in cesium chloride-ethidium bromide to consist predominantly of covalently closed circular DNA molecules. DNA sequencing of pSIC-9, a cloned 1.9-kilobase fragment of the rabbit plasmid species, indicated extensive homology at the nucleotide level over a 1.5-kilobase stretch of the viral terminal inverted repeat. Analysis of open reading frames in both the plasmid and SFV DNA revealed that (i) the N-terminal 157-amino acid sequence of a potential 514-amino acid SFV polypeptide is identical to the N-terminal 157 amino acids of one pSIC-9 open reading frame, and (ii) a second long pSIC-9 open reading frame of 361 amino acids, although significantly diverged from the comparable nucleotide sequence in the virus, possessed considerable homology to a family of cellular protease inhibitors, including alpha 1-antichymotrypsin, alpha 1-antitrypsin, and antithrombin III. The potential role of such cellular plasmid-like DNA species as a mediator in the exchange of genetic information between the host cell and a cytoplasmically replicating poxvirus is discussed.

Tumorigenic poxviruses: analysis of viral DNA sequences implicated in the tumorigenicity of Shope fibroma virus and malignant rabbit virus

The DNA sequence has been determined for a 7-kb region within the terminal inverted repeats (TIR) of Shope fibroma virus (SFV), a poxvirus which induces benign fibromas in rabbits. This region of the SFV TIR, which flanks the junction of the TIR with the unique internal sequences of the viral genome, had previously been shown to be also present in the genome of malignant rabbit virus (MRV), a hybrid poxvirus derived from a recombination event between SFV and a related leporipoxvirus, myxoma. Unlike SFV, the recombinant MRV induces an invasive profile of tumors in infected rabbits, but the capacity to induce proliferant fibromas appears to have been derived from SFV. These SFV DNA sequences have been analyzed and their genetic organization shows a unique tandem arrangement of three large open reading frames (ORFs) which share considerable homology with each other. Very short spacer sequences are present between the majority of ORFs, all of which are transcribed toward the terminal hairpins of SFV. Unusual dyad symmetries flank two of the most closely related ORFs and evidence is presented that one SFV ORF (T9-L) which maps precisely at the TIR/unique sequence boundary was truncated during transposition to the left terminus from a progenitor copy (T9-R) at the right terminus. The origin of these putative viral genes is considered in light of the recent observation (C. Upton and G. McFadden, 1986, Mol. Cell. Biol. 6, 265-276) that a subset of this region of the SFV genome is closely related to, and may have been originally derived from, an endogenous covalently closed circular plasmid species detected in uninfected rabbit cells.

DNA sequence homology between the terminal inverted repeats of Shope fibroma virus and an endogenous cellular plasmid species

DNA hybridization experiments indicate that the genome of a tumorigenic poxvirus. Shope fibroma virus (SFV), possesses sequence homology with DNA isolated from uninfected rabbit cells. Southern blotting experiments, either with high-complexity rabbit DNA as probe and SFV restriction fragments as targets or with high-specific activity, 32P-labeled, cloned SFV sequences as probes and rabbit DNA as target, indicate that the homologous sequences map at two locations within the viral genome, one in each copy of the terminal inverted repeat sequences. Unexpectedly, Southern blots revealed that the homologous host sequences reside in a rabbit extrachromosomal DNA element. This autonomous low-molecular-weight DNA species could be specifically amplified by cycloheximide treatment and was shown by isopycnic centrifugation in cesium chloride-ethidium bromide to consist predominantly of covalently closed circular DNA molecules. DNA sequencing of pSIC-9, a cloned 1.9-kilobase fragment of the rabbit plasmid species, indicated extensive homology at the nucleotide level over a 1.5-kilobase stretch of the viral terminal inverted repeat. Analysis of open reading frames in both the plasmid and SFV DNA revealed that (i) the N-terminal 157-amino acid sequence of a potential 514-amino acid SFV polypeptide is identical to the N-terminal 157 amino acids of one pSIC-9 open reading frame, and (ii) a second long pSIC-9 open reading frame of 361 amino acids, although significantly diverged from the comparable nucleotide sequence in the virus, possessed considerable homology to a family of cellular protease inhibitors, including alpha 1-antichymotrypsin, alpha 1-antitrypsin, and antithrombin III. The potential role of such cellular plasmid-like DNA species as a mediator in the exchange of genetic information between the host cell and a cytoplasmically replicating poxvirus is discussed.

Orthopoxvirus DNA: a comparison of restriction profiles and maps

Characteristic DNA endonuclease digest fragment electropherograms and restriction site maps permitted differentiation and genome structure analysis of 38 orthopoxviruses that included isolates of monkeypox virus from humans and animals, monkeypox white variants, variola, vaccinia, ectromelia, Tatera (gerbil) and raccoon poxviruses, and cowpox and camelpox viruses. HindIII cleavage sites mapped on the 38 virus genome DNAs plus SmaI, BglI, SacI, KpnI, XhoI, and SalI maps for variola (Harvey) and monkeypox (Copenhagen) virus DNAs were derived essentially by cross-hybridizations with monkeypox, vaccinia, and variola virus-cloned DNA restriction fragments, thus digest fragments could be assigned homologous regions on previously established genome maps. Salient of our observations, the DNA HindIII maps correlated to a high degree, but variations in middle and especially terminal DNA region cleavage sites provided a basis for discerning species, strains and variants. The extent of the inverted terminal repetitions (ITRs) for 37 DNAs were determined with HindIII, PvuI, SalI, and ClaI, plus nine more restriction enzymes for Bangladesh variola virus DNA by hybridizations with either the terminal tandemly repeated 70-bp segment or an EcoRI-PvuI near hairpin-end 75-bp segment from WR vaccinia virus. The opposite terminal regions of variola DNA were considerably asymmetrical compared to the large symmetrical ITRs of the other species examined. An apparent DNA inversion and concurrent deletion (1 kbp) with subsequent repair of DNA to original structure was suggested from right terminal region maps of four viruses chosen from a variola virus passage series in monkeys. Correlative with virus geographic distribution, two strains of monkeypox virus, each containing two variants, were differentiated by DNA profiles of isolates from smallpox-like disease (SLD) patients of the African rainforest region. The DNAs of five monkeypox viruses isolated from laboratory and zoo animals resembled most DNAs from SLD monkeypox viruses from Sierra Leone. A poxvirus from an American raccoon contained 40% DNA that did not cross-hybridize with orthopoxvirus DNA probes. The DNAs of recent isolates from a gerbil and from a camel each mapped as unique African orthopoxvirus species and differed from variola virus.

Tumorigenic poxviruses: construction of the composite physical map of the Shope fibroma virus genome

The sites for the restriction enzymes BamHI, Bg/I, HindIII, PstI, PvuII, and SstI on the linear DNA genome of Shope fibroma virus, a tumorigenic poxvirus of rabbits, have been determined by digestions of the cloned BamHI and HindIII restriction fragments and by hybridization of 32P-labeled cloned fragments to Southern blots of Shope fibroma virus DNA cleaved partially or completely with the various enzymes. The linear genome is shown to be 160 kilobases in length and to possess terminal inverted repeat sequences of between 12.2 and 12.5 kilobases extending inwards from the cross-linked DNA telomeres. The fine map of the Shope fibroma virus terminal inverted repeats has been constructed and shown to be distinctly different from that of members of the orthopoxvirus group, such as vaccinia, by the absence of detectable tandemly repeated sequences near the termini and by the lack of detectable sequence homology with vaccinia termini.

Physical characterization and molecular cloning of the Shope fibroma virus DNA genome

DNA from several independent strains of Shope fibroma virus, a tumorogenic leporipoxvirus of rabbits, was isolated and analyzed by restriction endonuclease digestion and Southern blotting. The restriction profiles indicated a high degree of sequence conservation among the isolates but blotting under standard stringencies revealed no detectable cross homology with a member of the orthopoxvirus group, vaccinia. The genome of the fibroma virus was calculated to be in excess of 160 kilobases and shown to possess two features analogous to the orthopoxvirus group: (1) the terminal restriction fragments possess covalently closed hairpin structures; and (2) the terminal sequences are present as inverted repeats of greater than 10 kilobases. The terminal 3.6 kilobase BamHI restriction fragment was cloned in pBR322 after removal of the hairpin structure with mung bean single strand-specific endonuclease and addition of BamHI linkers. SFV sequences within this terminal region were shown, using 32P SFV cloned terminal probe, to have none of the sequence heterogeneity characteristic of vaccinia DNA termini. The remaining 20 internal SFV BamHI restriction fragments were propagated in bacterial plasmids either as intact fragments, or after secondary digestion with HindIII, and together constitute the complete cloned SFV sequence library.

Electron microscopic studies of transcriptional complexes released from vaccinia cores during RNA-synthesis in vitro: methods for fractionation of transcriptional complexes

Electron microscopic (EM) and biochemical methods were employed to study the transcriptional complexes present in detergent lysates of vaccinia virus cores actively synthesizing RNA in vitro. When processed and examined in the EM, 14 'transcriptional sites' could be observed on full-length DNA templates. Fractionation of lysates by equilibrium density centrifugation in CsSO4, chromatography on hydroxyapatite columns or by sedimentation in sucrose gradients, allowed isolation of DNA templates associated with transcripts but these manipulations often resulted in fragmentation of the DNA template or promoted the release of transcripts from the template. It is suggested that RNA transcripts remain associated with the template in regions of supercoiling. These regions, in turn, may be maintained by DNA-protein interactions which are compromised as the transcriptional complexes are fractionated and purified.