The biological properties of E6 and E7 oncoproteins from human papillomaviruses

More than 100 different human papillomavirus (HPV) types have been isolated so far, and they can be sub-grouped in cutaneous or mucosal according to their ability to infect the skin or the mucosa of the genital or upper-respiratory tracts. A sub-group of human mucosal HPVs, referred to as high-risk HPV types, is responsible for approximately 5% of all human cancers, which represents one-third of all the tumours induced by viruses. Epidemiological and biological studies have shown that HPV16 is the most oncogenic type within the high-risk group. Emerging lines of evidence suggest that, in addition to the high-risk mucosal HPV types, certain cutaneous HPVs are involved in skin cancer. HPV-associated cancers are intimately linked to HPV persistence and the accumulation of chromosomal rearrangements. The products of the early genes, E6 and E7, of the high-risk mucosal HPV types play a key role in both events. Indeed, these proteins have developed a number of strategies to evade host immuno-surveillance allowing viral persistence, and to alter cell cycle and apoptosis control, facilitating the accumulation of DNA damage/mutations. Often, the two oncoproteins target the same cellular pathways with different mechanisms, showing a strong synergism in promoting cellular transformation and neutralizing the immune response. Here, we review most of the findings on the biological properties and molecular mechanisms of the oncoproteins E6 and E7 from mucosal and cutaneous HPV types.     

Classification of papillomaviruses

One hundred eighteen papillomavirus (PV) types have been completely described, and a yet higher number of presumed new types have been detected by preliminary data such as subgenomic amplicons. The classification of this diverse group of viruses, which include important human pathogens, has been debated for three decades. This article describes the higher-order PV taxonomy following the general criteria established by the International Committee on the Taxonomy of Viruses (ICTV), reviews the literature of the lower order taxa, lists all known "PV types", and interprets their phylogenetic relationship. PVs are a taxonomic family of their own, Papillomaviridae, unrelated to the polyomaviruses. Higher-order phylogenetic assemblages of PV types, such as the "genital human PVs", are considered a genus, the latter group, for example, the genus "Alpha-Papillomavirus". Lower-order assemblages of PV types within each genus are treated as species because they are phylogenetically closely related, but while they have distinct genomic sequences, they have identical or very similar biological or pathological properties. The taxonomic status of PV types, subtypes, and variants remains unchanged and is based on the traditional criteria that the sequence of their L1 genes should be at least 10%, 2-10%, and maximally 2% dissimilar from one another.     

Cloning and genomic characterization of Felis domesticus papillomavirus type 1

A novel papillomavirus was cloned from hyperkeratotic cutaneous lesions of a Persian domestic cat. The Felis domesticus papillomavirus (FdPV-1) genome counts 8300 bp and has a typical genome structure with an early region (E1, E2, E4, E6, E7), a late region (L1, L2), and a noncoding upstream regulatory region (URR or NCR1) between the end of L1 and the beginning of E6. The FdPV-1 also shows an unusual second noncoding region (NCR2) of 1.3 kb, situated between the end of E2 and the beginning of L2. This NCR2 is uniquely related to a similar region in the canine oral papillomavirus (COPV). Phylogenetic analysis places FdPV-1 together with COPV, the cottontail rabbit papillomavirus, human papillomavirus type 1 (HPV-1), and HPV-63 in the group of the benign cutaneous papillomaviruses. The position of FdPV-1 in the phylogenetic tree allows us to hypothesize that already in an early phase of the papillomavirus molecular evolution, a split occurred into viruses with a dual tropism primarily for cutaneous epithelia but also secondarily for mucosal surfaces, and viruses with a specific monotropism for mucosal surfaces. The close relationship between FdPV-1 and COPV, and between their Canidae and Felidae hosts, supports the hypothesis that papillomaviruses have speciated and coevolved together with their hosts throughout vertebrate evolution. A papillomavirus mutation rate of 0.73 to 0.96 x 10(-8) nucleotide substitutions per base per year was calculated.     

Human papillomavirus (HPV) types 101 and 103 isolated from cervicovaginal cells lack an E6 open reading frame (ORF) and are related to gamma-papillomaviruses

Complete genomes of HPV101 and HPV103 were PCR amplified and cloned from cervicovaginal cells of a 34-year-old female with cervical intraepithelial neoplasia grade 3 (CIN 3) and a 30-year-old female with a normal Pap test, respectively. HPV101 and HPV103 contain 4 early genes (E7, E1, E2, and E4) and 2 late genes (L2 and L1), but both lack the canonical E6 ORF. Pairwise alignment similarity of the L1 ORF nucleotide sequences of HPV101 and HPV103 indicated that they are at least 30% dissimilar to each other and all known PVs. However, similarities of the other ORFs (E7, E1, E2, and L2) indicated that HPV101 and HPV103 are most related to each other. Phylogenetic analyses revealed that these two types form a monophyletic clade, clustering together with the gamma- and pi-PV groups. These data demonstrated that HPV genomes closely related to papillomaviruses identified from cutaneous epithelia can be isolated from the genital mucosal region. Moreover, this is the first report of HPVs lacking an E6 ORF and phylogenetic evidence suggests this occurred subsequent to their emergence from the gamma-/pi-PVs.     

Genomic characterisation of Felis catus papillomavirus 4, a novel papillomavirus detected in the oral cavity of a domestic cat

Three papillomaviruses (PVs) from the domestic cat have been fully sequenced so far including Felis domesticus PV-1 (FdPV-1), FdPV-2, and a recently described Felis catus PV-3 (FcaPV-4). In the current article, we describe the full genomic sequence of a fourth PV from the domestic cat. This PV was amplified from the oral cavity of a cat with severe gingivitis. However, the aetiological involvement of FcaPV-4 in development of lesions observed in this cat remains uncertain. The complete genome of the novel virus comprised 7,616 bp and was predicted to encode five early (E1, E2, E4, E6 and E7) and two late (L1 and L2) genes, with the organisation typical for PVs. The L1 showed 65.1 % nucleotide sequence identity to L1 of FcaPV-3 and approximately 60 % identity to L1 of canine tau-papillomaviruses CPV-2 and CPV-7. The novel virus clustered with FcaPV-3, CPV-2 and CPV-7 on a phylogenetic tree constructed from a concatenated alignment of 3,013 bp from E1, E2, L1 and L2. Based on the genomic and phylogenetic data, we propose that the novel virus is classified as a distinct species within the same genus as FcaPV-3. We also propose that both viruses are classified within the genus Taupapillomavirus, although this classification may need to be re-visited after more tau-PV genomes become available.     

Search for cellular partners of human papillomavirus type 16 E2 protein

Human papillomaviruses (HPVs) are small, double-stranded DNA viruses that infect cutaneous and mucosal epithelia. Type 16 (HPV16) displays tropism to genital epithelia, giving rise to genital warts and cervical intraepithelial neoplasia (CIN), which is a precursor lesion to invasive carcinoma of the cervix. The great majority of human cervical cancers contain integrated HPV DNA where the E2 gene is usually disrupted, suggesting that the loss of the E2 protein is an important step in HPV-induced carcinogenesis. The HPV16 E2 protein is a regulatory protein that seems to be essential for creating favourable conditions for establishment of infection and proper completion of the viral life cycle. Recently, diverse activities of the E2 proteins have been described, but the molecular basis of these processes has not beenfully elucidated. Using a yeast two-hybrid system, we have identified epithelial cellular proteins that bind to the E2 protein of HPV16.     

Detection of HPV-2 and identification of novel mutations by whole genome sequencing from biopsies of two patients with multiple cutaneous horns.

BACKGROUND: Human papillomavirus-2 (HPV-2) is generally associated with common warts. The association of cutaneous horns with HPV-2 infection has never been reported. OBJECTIVES: To identify the papillomavirus (PV) type(s) involved in cutaneous horns and analysis the genomes of these viruses. STUDY DESIGN: We screened biopsies from two patients with multiple cutaneous horns using PV type-specific PCR assays, and sequenced the whole genomes of the viruses by a PCR-by-PCR strategy. Sequence comparison with the reference genome and its closely related PVs in the same phylogenetic group was performed to identify sequence variation across the genome(s) of newly detected PV(s). RESULTS: Two strains of HPV-2 were identified from the biopsies of two patients respectively. No double or multiple infections were detected. Novel mutations were found in the HPV-2 genome, located both in the coding and non-coding regions. Amino acid changes occurred only in E1 and E7 ORFs. The two strains also shared several mutations at the same positions. CONCLUSIONS: Each patient was infected with a single strain of HPV-2 that developed unique mutations; HPV-2 may play a role in the onset and development of cutaneous horns; amino acid changes in functionally significant viral proteins may confer differential pathogenic risks.     

Cellular steady-state levels of "high risk" but not "low risk" human papillomavirus (HPV) E6 proteins are increased by inhibition of proteasome-dependent degradation independent of their p53- and E6AP-binding capabilities

The group of mucosal epithelia-infecting human papillomaviruses (HPV) can be subdivided in "low" and "high risk" HPV types. Both types induce benign neoplasia (condyloma), but only the infection with a "high risk" HPV type is causally associated with an increased risk of developing anogenital tumors. The oncogenic potential of high risk HPVs resides at least partially in the viral E6 protein. The E6 protein targets the cellular p53 protein for proteasome-dependent degradation, which is associated with the immortalizing and transforming functions of these viruses. Recently the E6-dependent proteasome-mediated destabilization of additional cellular proteins (E6TP1, c-myc, Bak, hMCM7, human scribble, E6AP, MAGI-1) has been described, but the cellular mechanisms controlling the viral E6 protein stability itself have been so far not analyzed. In this study, we transiently expressed the E6 genes of the high risk HPV type 16, the low risk HPV types 6a and 11, and the cutaneous epithelia-infecting HPV types 5 and 8 from a eucaryotic expression vector and compared the cellular steady-state levels of the expressed E6 proteins. We demonstrated that the high risk HPV 16 E6 protein possesses the lowest steady-state level in comparison to the low risk HPV type E6 proteins and the cutaneous epithelia-infecting HPV type E6 proteins. Inhibition of cellular proteasome-dependent protein degradation led to an increase in steady-state levels of high risk but not of low risk E6 proteins. Analysis of functionally deficient HPV 16 E6 proteins in p53 null- and p53 wild-type-expressing cell lines revealed that the cellular steady-state level of this protein is influenced neither by its p53- nor its E6AP-binding abilities.     

The human papillomaviruses

The human papillomaviruses (HPVs) have long been recognized as the etiologic agents of a variety of benign cutaneous and mucosal proliferative entities. Currently, 11 distinct HPVs have been described, and each seems preferentially associated with a distinct clinical entity. In animal species, some papillomaviruses (PVs) are associated with lesions that can become malignant. What role specific HPVs may play in cutaneous or mucosal malignant squamous cell neoplasms is under investigation in a number of different laboratories. There is a subgroup of PVs that can malignantly transform fibroblasts of heterologous species. This system provides a model for studying the malignant potential of the PVs and for determining the cellular and viral events associated with PV-induced malignant transformation. A unique characteristic of this system is that the HPV genome exists exclusively nonintegrated as a DNA plasmid in transformed cells.     

Evidence of recombination and positive selection in cetacean papillomaviruses

Papillomaviruses (PVs) are small DNA viruses that have been associated with increased epithelial proliferation. Over one hundred PV types have been identified in humans; however, only three have been identified in bottlenose dolphins (Tursiops truncatus) to date. Using rolling circle amplification and degenerate PCR, we identified four novel PV genomes of bottlenose dolphins. TtPV4, TtPV5 and TtPV6 were identified in genital lesions while TtPV7 was identified in normal genital mucosa. Bayesian analysis of the full-length L1 genes found that TtPV4 and TtPV7 group within the Upsilonpapillomavirus genus while TtPV5 and TtPV6 group with Omikronpapillomavirus. However, analysis of the E1 gene did not distinguish these genera, implying that these genes may not share a common history, consistent with recombination. Recombination analyses identified several probable events. Signals of positive selection were found mostly in the E1 and E2 genes. Recombination and diversifying selection pressures constitute important driving forces of cetacean PV evolution.     

The phylogenetic relationship and complete nucleotide sequence of human papillomavirus type 35.

The 7851-bp nucleotide sequence of human papillomavirus (HPV) type 35 was determined. HPV 35 is associated with high-grade cervical intraepithelial neoplasia and invasive carcinomas. From the HPV 35 sequence, open reading frames encoding putative proteins E6, E7, E1, E2, E4, E5, L2, and L1, common to other mucosal HPV types, were identified. Structural and control elements present in the long control region (LCR) conserved among other mucosal HPV types were also present in HPV 35. Analysis of the LCR revealed an additional 20-bp sequence element present in all HPV types associated with malignant proliferation. To further classify HPV 35 with regard to oncogenic potential, phylogenetic analysis of the E6 and E7 proteins from the anogenital HPV types 6, 11, 16, 18, 31, 33, 35, 39, 43, 44, 45, and 51 was performed. This analysis indicated three distinct HPV subgroups; those associated with benign lesions and two branches of those HPV types more often associated with malignant proliferation. HPV 35 is most closely related to HPV types 31 and 16.     

Molecular phylogenetics and the classification of honey bee viruses

Summary.  We present the phylogenetic relationships of several picorna-like RNA viruses found in honey bees, with respect to 13 additional plant and animal positive-strand RNA viruses. Most of the honey bee viruses fall into an unnamed family of insect RNA viruses typified by the Drosophila C virus. Different bee viruses are broadly distributed within this group, suggesting either that the ability to infect honey bees has evolved multiple times, or that these viruses are generalistic in their abilities to infect insect hosts. At least one major change in gene order has occurred among the bee viruses, based on their phylogenetic affiliations. At the amino-acid level, the bee viruses differed by 15–28% at three conserved loci. Most differed by greater than 50% at the RNA level, indicating that sequence-based methods for bee virus identification must be tailored to at least three different virus clades independently. Received March 3, 2000 Accepted May 17, 2000     

Molecular and phylogenetic analysis of the HPV 16 E4 gene in cervical lesions from women in Greece

The HPV16 E1(∧)E4 protein is thought to contribute to the release of newly formed viral particles from infected epithelia. In order to investigate amino acid mutations in the HPV16 E1(∧)E4 protein, the complete E4 ORF was amplified by PCR in 27 HPV16-positive cervical samples, and the amplicons were cloned. Fifteen nucleic acid variations were identified in the E4 ORF, including seven silent nucleic acid mutations. In addition, nine amino acid mutations (A7V, A7P, L16I, D45E, L59I, L59T, Q66P, S72F, H75Q) were detected in the E1(∧)E4 protein, and these were associated with the severity of cervical malignancy. A maximum-likelihood phylogenetic tree was constructed based on the E4 ORF, and nucleotide sequence analysis of the E4, E6 and E7 genes from the same samples was conducted in order to determine the phylogenetic origin of the cloned sequences from the amplified HPV16 E4. Based on the nucleotide sequence and phylogenetic analysis it was revealed that even though E4 ORF constitutes a small polymorphic portion of the viral genome (288?bp), it could provide valuable information about the origins of the HPV16 genome. In addition, molecular evolutionary analysis of the E4 coding region revealed that neutral selection is dominant in the overlapping region of the E4 and E2 ORFs.     

Human papillomaviruses and non-melanoma skin cancer: basic virology and clinical manifestations

Human papillomaviruses (HPV) infect cutaneous and mucosal epithelia and induce benign and malignant lesions. Non-melanoma skin cancer (NMSC), encompassing basal cell carcinoma and squamous cell carcinoma (SCC), is the most frequent cancer in the Caucasian population, and the incidence has increased dramatically worldwide. Ultraviolet (UV) radiation is a major risk factor for NMSC, and cutaneous HPV is also considered to play an active role during the pathogenesis of these cancers. The first evidence for the involvement of HPV in NMSC was reported in patients with Epidermodysplasia verruciformis (EV). HPV types detected in skin tumours of these patients are referred to as EV/cutaneous HPV types belonging to the beta- and gamma-papillomaviruses (PV). Epidemiological studies have shown a higher risk of several EV/cutaneous HPV types for NMSC. Furthermore, in vitro and animal models show transforming properties of some PV types. The anti-apoptotic activities, and the delay of DNA repair mechanism caused by some EV/cutaneous HPV E6 proteins in response to UV-induced mutations, may lead to the persistence of DNA-damaged keratinocytes. Thus, specific EV/cutaneous HPV types as co-factors in association with UV-radiation and the immune system seem to be involved in the early pathogenesis of cutaneous SCC.     

Genomic characterization of two novel reptilian papillomaviruses, Chelonia mydas papillomavirus 1 and Caretta caretta papillomavirus 1

In this paper we describe the characterization of the genomes of two sea turtle papillomaviruses, Chelonia mydas PV (CmPV-1) and Caretta caretta PV (CcPV-1). The isolation and sequencing of the first non-avian reptilian PVs extend the evolutionary history of PVs to include all amniotes. PVs have now been described in mammals, birds and non-avian reptiles. The chelonian PVs form a distinct clade most closely related to the avian PVs. Unlike the avian PVs, both chelonian PVs have canonical E6 and E7 ORFs, indicating that these genes were present in the common ancestor to mammalian and non-mammalian amniote PVs. Rates of evolution among the non-mammalian PVs were generally slower than those estimated for mammalian PVs, perhaps due to lower metabolic rates among the ectothermic reptiles.     

Characterization of cDNAs of spliced HPV-11 E2 mRNA and other HPV mRNAs recovered via retrovirus-mediated gene transfer

Human papillomaviruses (HPVs) are associated with hyperproliferations of cutaneous or mucosal epithelium. These viruses cannot be propagated in any cell culture system. Because cloning cDNA copies of HPV mRNAs recovered from human lesions has met with only very limited success, the characterization of HPV mRNAs has been problematic. Using the Moloney murine leukemia virus vector system (C.L. Cepko, B.E. Roberts, and R.C. Mulligan, 1984, Cell 37, 1053-1062), we have recovered cDNAs of spliced E2 mRNAs of human papillomavirus type 11 and additional mRNAs of type 11 and type 18 and determined the utilization of open reading frames (ORFs) in the DNA sequences. The recovery of cDNA copies of messages with splice sites identical to those previously described strongly suggests that the newly characterized splice donors and acceptors are also authentic. The HPV-11 E2 cDNA contains the intact E6 and E7 ORFs and the beginning of the E1 ORF in the first exon, which is then spliced from nt 847 to the second exon at nt 2622, 100 nucleotides upstream from the initiation codon for the E2 ORF. The initiation codon in the E1 ORF is followed by four additional in-frame AUG triplets and an in-frame termination codon positioned 30 nucleotides upstream from the initiation codon for the E2 protein. The authenticity of this putative E2 cDNA was shown by its ability to provide enhancer transactivating activity in chloramphenicol acetyltransferase (CAT) assays in several cell lines. A mutation in the genomic DNA at this splice acceptor site eliminates its activity, demonstrating that the splice is essential for the expression of the E2 protein. We conclude that the translation of the HPV-11 E2 protein requires internal initiation.     

A comparative sequence analysis of two human papillomavirus (HPV) types 2a and 57

HPV 2a is commonly associated with verrucae vulgares, whereas HPV 57 was detected in mucosal lesions of the maxillary sinus and the genital tract, as well as in cutaneous lesions. The complete DNA sequences of HPV 2a and HPV 57 were determined. The HPV 2a genome consists of 7860 base pairs and the HPV 57 genome contains 7861 base pairs. On the nucleotide level an 83% homology between the two sequences could be ascertained. Compared to other HPVs they have a high G/C-content (HPV 2a: 48.8%, HPV 57: 50.1%). The genomic organization of both viruses complies with that of other sequenced HPVs. Significant sequence divergence between the HPV 2a and HPV 57 genomes was found in the long control region (LCR), as well as in the early-late-region (ELR). The latter varies in size between the cutaneous (72 to 103 nucleotides) and the mucosal HPVs (252 to 584 nucleotides). According to the sizes of the ELRs of HPV 2a (377 nucleotides) and HPV 57 (478 nucleotides), as well as DNA sequence comparisons, these two viruses could be grouped with the so-called mucosal HPVs. In a search for possible tissue-specific elements, a common amino acid motif, thr-thr/asp-pro-ala-ile/valile/leu was found in the L2 of all mucosal HPVs, as well as in HPV 2a and 57. The L2 of the cutaneous types contain the motif val-ser/thr-arg-thr-gln-tyr.     

Rabbit oral papillomavirus complete genome sequence and immunity following genital infection

Rabbit oral papillomavirus (ROPV) infects mucosal tissues of domestic rabbits. The viral genomic sequence has been determined and the most related papillomavirus type was the cutaneous cottontail rabbit papillomavirus (CRPV). Homologies between the open reading frames (ORFs) of ROPV and CRPV, however, ranged from 68% amino acid identity for L1 to only 23% identity for E4. Shared features unique to the two rabbit viruses included a large E6 ORF and a small E8 ORF that overlapped the E6 ORF. Serological responses to ROPV L1 viruslike particles (VLPs) were detected in rabbits infected at either the genital or oral mucosa with ROPV. The antibody response was specific to intact ROPV L1 VLP antigen, was first detected at the time of late regression, and persisted at high levels for several months after complete regression. Both oral and genital lesions regressed spontaneously, accompanied by a heavy infiltrate of lymphocytes. ROPV infection of rabbit genital mucosa is a useful model to study host immunological responses to genital papillomavirus infections.