Genetic characterization of the first chiropteran papillomavirus, isolated from a basosquamous carcinoma in an Egyptian fruit bat: the Rousettus aegyptiacus papillomavirus type 1.

The complete genomic DNA of a novel papillomavirus (PV) was isolated from a basosquamous carcinoma on the wing of an Egyptian fruit bat (Rousettus aegyptiacus). Initial short sequences of the E1 and L1 genes of this virus were retrieved by PCR with degenerate papillomavirus-specific primers, and the entire R. aegyptiacus papillomavirus type 1 (RaPV-1) DNA was then amplified by long template PCR, cloned and sequenced with a transposon insertion method. The RaPV-1 genome counts 7970 basepairs and contains the typical papillomavirus open reading frames (ORF) (E1, E2, E4, E6, E7, L1 and L2). Based on a concatenated alignment of the E1, E2, L1 and L2 open reading frames of RaPV-1 and 46 other human and animal papillomavirus type species, a neighbor-joining phylogenetic tree was constructed. This phylogenetic analysis shows that RaPV-1 has a close-to-root position in the papillomavirus evolutionary tree. Since RaPV-1 is only distantly related to other papillomaviruses (with maximally 50% nucleotide sequence identity across the L1 open reading frame), it cannot be assigned to one of the existing papillomavirus genera and therefore represents the first member of a novel, as yet unnamed, close-to-root papillomavirus genus. This is the first time a papillomavirus has been isolated and characterized from a member of the Chiroptera order.

Genomic characterization of novel dolphin papillomaviruses provides indications for recombination within the Papillomaviridae.

Phylogenetic analysis of novel dolphin (Tursiops truncatus) papillomavirus sequences, TtPV1, -2, and -3, indicates that the early and late protein coding regions of their genomes differ in evolutionary history. Sliding window bootscan analysis showed a significant a change in phylogenetic clustering, in which the grouped sequences of TtPV1 and -3 move from a cluster with the Phocoena spinipinnis PsPV1 in the early region to a cluster with TtPV2 in the late region. This provides indications for a possible recombination event near the end of E2/beginning of L2. A second possible recombination site could be located near the end of L1, in the upstream regulatory region. Selection analysis by using maximum likelihood models of codon substitutions ruled out the possibility of intense selective pressure, acting asymmetrically on the viral genomes, as an alternative explanation for the observed difference in evolutionary history between the early and late genomic regions of these cetacean papillomaviruses.

Ancient papillomavirus-host co-speciation in Felidae.

BACKGROUND: Estimating evolutionary rates for slowly evolving viruses such as papillomaviruses (PVs) is not possible using fossil calibrations directly or sequences sampled over a time-scale of decades. An ability to correlate their divergence with a host species, however, can provide a means to estimate evolutionary rates for these viruses accurately. To determine whether such an approach is feasible, we sequenced complete feline PV genomes, previously available only for the domestic cat (Felis domesticus, FdPV1), from four additional, globally distributed feline species: Lynx rufus PV type 1, Puma concolor PV type 1, Panthera leo persica PV type 1, and Uncia uncia PV type 1. RESULTS: The feline PVs all belong to the Lambdapapillomavirus genus, and contain an unusual second noncoding region between the early and late protein region, which is only present in members of this genus. Our maximum likelihood and Bayesian phylogenetic analyses demonstrate that the evolutionary relationships between feline PVs perfectly mirror those of their feline hosts, despite a complex and dynamic phylogeographic history. By applying host species divergence times, we provide the first precise estimates for the rate of evolution for each PV gene, with an overall evolutionary rate of 1.95 x 10(-8) (95% confidence interval 1.32 x 10(-8) to 2.47 x 10(-8)) nucleotide substitutions per site per year for the viral coding genome. CONCLUSION: Our work provides evidence for long-term virus-host co-speciation of feline PVs, indicating that viral diversity in slowly evolving viruses can be used to investigate host species evolution. These findings, however, should not be extrapolated to other viral lineages without prior confirmation of virus-host co-divergence.

Analysis of the serotype and genotype correlation of VP1 and the 5' noncoding region in an epidemiological survey of the human enterovirus B species.

The sequence identity of the enterovirus VP1 gene has been shown to correlate with the serotype concept. Enterovirus molecular typing methods are therefore often based on sequencing of the VP1 genomic region and monophyletic clustering of VP1 sequences of a homologous serotype. For epidemiological surveillance, 342 enterovirus samples obtained from patients with aseptic meningitis in Belgium from 1999 to 2002 were first diagnosed as being enterovirus positive by amplification of the 5' noncoding region (5'NCR) by reverse transcription (RT)-PCR. Subsequently, samples were molecularly typed by RT-nested PCR amplification and sequencing of a portion of the VP1 gene. Phylogenetic analyses were performed to investigate enteroviral evolution and to examine the serotype and genotype correlation of the two genomic regions. Our typing results demonstrated echovirus 30, echovirus 13, echovirus 18, and echovirus 6 to be the most predominant types. Echoviruses 13 and 18 were considered to be emerging human serotypes since 2000 and 2001, respectively, as they had been rarely reported before. Several serotypes existed as multiple genotypes (subtypes) from 1999 to 2002, but genomic differences mainly resided at synonymous sites; these results strongly suggest that the subtypes exhibit similar antigenic properties. Phylogenetic analyses confirmed that VP1 is an adequate region for molecular typing. Serotype-specific clusters are not observed commonly in phylogenetic trees based on the 5'NCR, and the phylogenetic signal in the 5'NCR was found to be particularly low. However, some substructure in the 5'NCR tree made a tentative prediction of the enterovirus type possible and was therefore helpful in PCR strategies for VP1 (e.g., primer choice), provided some background knowledge on the local spectrum of enteroviruses already exists.