Tandemly repeated sequences are present at the ends of the DNA of raccoonpox virus

The genomes of three North American orthopoxviruses

The complete genomes of a skunkpox, volepox, and raccoonpox virus were sequenced and annotated. Phylogenetic analysis of these genomes indicates that although these viruses are all orthopoxviruses, they form a distinct clade to the other known species. This supports the ancient divergence of the North American orthopoxviruses from other members of the orthopoxviruses. Only two open reading frames appear to be unique to this group of viruses, but a relatively small number of insertions/deletions contribute to the varied gene content of this clade. The availability of these genomes will help determine whether skunkpox and volepox viruses share the characteristics that make raccoonpox a useful vaccine vector.

Raccoonpox in a Canadian cat

Poxvirus infections affecting the skin of cats are extremely rare in North America, in contrast to Europe where cowpox virus is well recognized as an accidental pathogen in cats that hunt small rodents. The virus or viruses responsible for the anecdotal cases in North America have never been characterized. This paper reports a case of raccoonpox infection in a Canadian cat. Biopsy of the initial ulcerative lesion on the forepaw revealed ballooning degeneration of surface and follicular keratinoctyes. Infected cells contained large eosinophilic type A inclusions. Electron microscopic examination revealed virions of an orthopoxvirus, subsequently identified as raccoonpox by polymerase chain reaction and gene sequencing. The cat made a full recovery.

The sequence of camelpox virus shows it is most closely related to variola virus, the cause of smallpox

Camelpox virus (CMPV) and variola virus (VAR) are orthopoxviruses (OPVs) that share several biological features and cause high mortality and morbidity in their single host species. The sequence of a virulent CMPV strain was determined; it is 202182 bp long, with inverted terminal repeats (ITRs) of 6045 bp and has 206 predicted open reading frames (ORFs). As for other poxviruses, the genes are tightly packed with little non-coding sequence. Most genes within 25 kb of each terminus are transcribed outwards towards the terminus, whereas genes within the centre of the genome are transcribed from either DNA strand. The central region of the genome contains genes that are highly conserved in other OPVs and 87 of these are conserved in all sequenced chordopoxviruses. In contrast, genes towards either terminus are more variable and encode proteins involved in host range, virulence or immunomodulation. In some cases, these are broken versions of genes found in other OPVs. The relationship of CMPV to other OPVs was analysed by comparisons of DNA and predicted protein sequences, repeats within the ITRs and arrangement of ORFs within the terminal regions. Each comparison gave the same conclusion: CMPV is the closest known virus to variola virus, the cause of smallpox.

Further analyses of the orthopoxviruses volepox virus and raccoon poxvirus

Volepox virus (VPX) from skin lesions on a vole and a piñon mouse caught in California and raccoon poxvirus (RCN) from raccoons trapped in Maryland were examined to begin elucidating their relationship to other orthopoxviruses, most of which are not known to be indigenous to the Americas. VPX and RCN produced pinpoint, nonhemorrhagic pocks on chick embryo chorioallantoic membranes. In cell cultures both viruses produced 1-mm diameter, irregular plaques, A-type inclusions (ATIs), and despite production of hemagglutinin, both viruses caused syncytia formation. Considerable cross-hybridization was seen between VPX and RCN DNA and the DNAs of other orthopoxviruses; however, HindIII cleavage site maps showed marked central and terminal region differences between VPX (222.8 kbp) and RCN (224.8 kbp) DNA and mapped DNAs of other orthopoxviruses. Cognate DNAs of the ATI 160-kDa protein and 38-kDa serine protease inhibitor homologue of cowpox virus (CPV) and the 14-kDa fusion protein of vaccinia virus (VAC) were present within the right end of VPX and RCN DNA, matching their location in CPV and VAC. VPX and RCN, respectively, expressed a 150- and a 155-kDa ATI major protein and a 20- and an 18-kDa fusion protein. Low stringency annealing suggested that cognate DNAs for the VAC growth factor and the alpha-amanitin target protein were present within the left end of VPX and RCN DNA, matching their location in VAC. Terminal tandem repeat sequences of VAC and RCN did not cross-hybridize with each other or with VPX DNA end fragments. Together, the data suggested that VPX and RCN are phylogenetically rather distant from orthopoxviruses not indigenous to the Americas, although genetic information is arranged as in other examined orthopoxviruses.

Transcription of the terminal loop region of vaccinia virus DNA is initiated from the telomere sequences directing DNA resolution

The telomeres of vaccinia virus DNA are transcribed at late times after infection. Analysis of cDNAs of RNA transcripts of the terminal loop region of the viral DNA shows that both inverted and complementary forms of the terminal loop region are transcribed. These late RNAs, which contain 5' poly(A) sequences, do not appear to encode any proteins. The transcriptional start sites for most of these RNAs are within the sequences that direct the resolution of concatemeric DNA replication intermediates (M. Merchlinsky and B. Moss, 1989, J. Virol. 63, 4354-4361). This suggests that the process of DNA resolution may involve transcription initiated from the telomere sequences required for resolution.

Stability of molluscum contagiosum virus DNA among 184 patient isolates: evidence for variability of sequences in the terminal inverted repeats

The stability of the Molluscum contagiosum virus Type 1 genome (188 kbp) was studied in 184 DNA isolates from 131 patients. Variability of up to 1.5 kbp at both ends of the genome symmetrically was observed using restriction analysis of the DNA isolates and by Southern Blot experiments using cloned and labeled HindIII terminal DNA fragments of MCV-1 prototype DNA. The variable sequences were mainly confined to the terminal fragments and parts of the MCV-1 terminal repeats. Labeled probes did not detect terminal sequences of MCV Type 2 under the applied stringency. A less marked instability of the central MCV-1 BamHI DNA fragment F was observed within the genome coordinates 0.431 to 0.454 mu. Reiteration of tandem repeats similar to those described for vaccinia virus might explain the variability of the terminal sequences and might be involved in viral replication.

Mutational analysis of the resolution sequence of vaccinia virus DNA: essential sequence consists of two separate AT-rich regions highly conserved among poxviruses

In replicative forms of vaccinia virus DNA, the unit genomes are connected by palindromic junction fragments that are resolved into mature viral genomes with hairpin termini. Bacterial plasmids containing the junction fragment for vaccinia virus or Shope fibroma virus were converted into linear minichromosomes of vector sequence flanked by poxvirus hairpin loops after transfection into infected cells. Analysis of a series of symmetrical deletion mutations demonstrated that in vaccinia virus the presence of the DNA sequence ATTTAGTGTCTAGAAAAAAA on both sides of the apical segment of the concatemer junction is crucial for resolution. To determine the precise architecture of the resolution site, a series of site-directed mutations within this tract of nucleotides were made and the relative contribution of each nucleotide to the efficaciousness of resolution was determined. The nucleotide sequence necessary for the resolution of the vaccinia virus concatemer junction, (A/T)TTT(A/G)N7-9AAAAAAA, is highly conserved among poxviruses and found proximal to the hairpin loop in the genomes of members of the Leporipoxvirus, Avipoxvirus, and Capripoxvirus genera.

Sequence analysis of the inverted terminal repetition in the genome of the parapoxvirus, orf virus

Two BamHI fragments from the right-hand terminal region of the orf virus genome have been sequenced. The bulk of the inverted terminal repetition (ITR) sequence is contained within these fragments and makes up 3388 bp of the 4425-bp sequence reported. The overall base composition of the larger sequence is 59.4% G + C and of the ITR, 60.2% G + C. An extremely G/C-rich (83.2%) block of sequence was found spanning the ITR/unique sequence junction. The bulk of the ITR could be divided into three blocks of directly repeated sequences. One block begins about 250 nucleotides from the terminus and is a direct repeat 15 bp long, repeated 14 times. The other blocks contain seven sequence sets ranging from 16 to 36 nucleotides which are repeated 2 to 4 times, interspersed with one another, interrelated in sequence, and sometimes separated by unique sequence. Eight open reading frames (ORFs), each with the potential to code for polypeptides of 50 residues or more, were identified. Three were found within the ITR, four spanned the ITR/unique sequence junction and one was found outside the ITR. A search for putative poxvirus transcriptional control signals indicated that three of the eight ORFs are likely to be transcribed early, all in the same direction toward the right end of the genome. Sequences of the type T(A)3-5T were found only twice in the sequence and only one preceded an ORF.

Transcription of orthopoxvirus telomeres at late times during infection

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

Genomic characterization of Molluscum contagiosum virus type 1: identification of the repetitive DNA sequences in the viral genome

The genomes (188 kbp) of the prototype Molluscum contagiosum virus type 1 (MCV-1) and a variant strain (MCV-1v) were characterized by construction of the physical maps of the viral DNA for the restriction enzymes BamHI, ClaI, EcoRI, and HindIII using a defined gene library harboring the DNA sequences of the MCV-1 genome and by DNA-DNA hybridizations. It was found that the genomes of both MCV strains are identical, with the exception of very few changes in the DNA fragmentation patterns of restriction endonuclease BamHI as a consequence of naturally occurring nucleotide exchanges in the genome of the variant strain. Detailed hybridization experiments revealed the existence of repetitive DNA sequences, which are located within the terminal regions of the viral genome at the map coordinates 0 to 0.027 and 0.973 to 1.

Nucleotide sequence required for resolution of the concatemer junction of vaccinia virus DNA

The mature form of the vaccinia virus genome consists of a linear, 185,000-base-pair (bp) DNA molecule with a 10,000-bp inverted terminal repetition and incompletely base-paired 104-nucleotide hairpin loops connecting the two strands at each end. In concatemeric forms of intracellular vaccinia virus DNA, the inverted terminal repetitions of adjacent genomes form an imperfect palindrome. The apex of this palindrome corresponds in sequence to the double-stranded form of the hairpin loop. Circular plasmids containing palindromic concatemer junction fragments of 250 bp or longer are converted into linear minichromosomes with hairpin ends when they are transfected into vaccinia virus-infected cells, providing a model system with which to study the resolution process. To distinguish between sequence-specific and structural requirements for resolution, plasmids with symmetrical insertions, deletions, and oligonucleotide-directed mutations within the concatemer junction were constructed. A sequence (ATTTAGTGTCTAGAAAAAAA) located on both sides of the apex segment was found to be critical for resolution. Resolution was more efficient when additional nucleotides, TGTG, followed the run of A residues. Both the location and sequence of the proposed resolution signal are highly conserved among poxviruses.

Studies on Tanapox virus

Virus characterization studies were performed to meliorate the taxonomic status of three currently unclassified, serologically related viruses: Tanapox virus (causes vesicular skin lesions in humans), Yaba-like disease (YLD) virus (causes vesicular skin lesions in monkeys), and Yaba monkey tumor virus (YMTV, causes epidermal histiocytoma). These studies included (1) microscopic observations of Tanapox virus cytopathic effect and morphogenesis during its 6-day cytolytic-type growth at 35 degrees in CV-1 monkey kidney cells; (2) resolution of Tanapox virion proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of nonenveloped and double-enveloped virus particles purified by velocity sedimentation in sucrose and CsCl density gradients; and (3) restriction endonuclease DNA comparison of the three viruses. DNA analysis showed that six recent Tanapox virus isolates from patients in Zaire, Africa, were identical to Tanapox virus, Kenya strain, from 1957 from a patient in the Tana River Valley. In addition, BamHI, MluI, and PstI cleavage sites mapped on the DNA of Kenya Tanapox virus, and PstI sites mapped on DNA of YLD virus differentiated YLD and Tanapox viruses as separate strains. On the other hand, YMTV shared few restriction endonuclease sites with Tanapox and YLD viruses, although all three cross-hybridized extensively. These studies along with published viral characteristics, support the formation of a new poxvirus genus: the suggested name is Yatapoxvirus, and the genus currently comprises two species, Tanapox virus and YMTV.

Successful oral rabies vaccination of raccoons with raccoon poxvirus recombinants expressing rabies virus glycoprotein

Two infectious raccoon poxvirus (RCN) recombinants for expressing rabies virus surface spike glycoprotein (G) were produced by homologous recombination between raccoon poxvirus DNA and chimeric plasmids previously used for production of vaccinia virus recombinants. Expression of G protein was controlled by vaccinia virus promoter P7.5 (early/late class) or by P11 (late class). Immunoprecipitation of infected cell extracts indicated that both of the RCN recombinants directed faithful expression of G protein. Raccoons that were fed polyurethane baits loaded with either recombinant quickly developed high levels of rabies virus neutralizing antibodies and were protected when challenged with lethal raccoon rabies street virus.