Differential regulation of cutaneous oncoprotein HPVE6 by wtp53, mutant p53R248W and ΔNp63α is HPV type dependent.

UV exposure and p53 mutations are major factors in non-melanoma skin cancer, whereas a role for HPV infections has not been defined. Previous data demonstrated the wtp53-mediated degradation of cutaneous HPV20E6 by caspase-3. ΔNp63α and hot-spot mutant p53R248W conveyed a protective effect on HPV20E6 under these conditions. We demonstrate a differential regulation by wtp53 of the E6 genes of cutaneous types HPV4, HPV5, HPV7, HPV27, HPV38, HPV48, HPV60 and HPV77. Caspase- or proteasome-mediated down-regulation was HPV type dependent. Mutant p53R248W up-regulated expression of all these E6 proteins as did ΔNp63α except for HPV38E6 which was down-regulated by the latter. None of these cellular proteins affected HPV41E6 expression. Ectopic expression of both mutp53R248W and ΔNp63α in the normal NIKS keratinocyte cell line harbouring endogenous p53 and p63however led to a down-regulation of HPV20E6. We demonstrate that HPV20E6 expression in these cells is modulated by additional, yet unidentified, cellular protein(s), which are not necessarily involved in apoptosis or autophagy. We further demonstrate proliferation of HPV20E6-expressing keratinocytes. Levels of proteins involved in cell cycle control, cyclin-D1, cdk6 and p16(INK4a), phosphorylated pRB, as well as c-Jun and p-c-Jun, were all increased in these cells. HPV20E6 did not compete for the interaction between p16(INK4a) with cyclin-D1 or cdk6. Phosphorylation of pRB in the HPV20E6 expressing cells seems to be sufficient to override the cytokenetic block induced by the p16(INK4a)/pRB pathway. The present study demonstrates the diverse influence of p53 family members on individual cutaneous HPVE6 proteins. HPV20E6 expression also resulted in varying protein levels of factors involved in proliferation and differentiation.

The diversity of torque teno viruses: in vitro replication leads to the formation of additional replication-competent subviral molecules.

The family Anelloviridae comprises torque teno viruses (TTVs) diverse in genome structure and organization. The isolation of a large number of TTV genomes (TTV Heidelberg [TTV-HD]) of 26 TTV types is reported. Several isolates from the same type indicate sequence variation within open reading frame 1 (ORF1), resulting in considerably modified open reading frames. We demonstrate in vitro replication of 12 full-length genomes of TTV-HD in 293TT cells. Propagation of virus was achieved by several rounds of infections using supernatant and frozen whole cells of initially infected cells. Replication of virus was measured by PCR amplification and transcription analyses. Subgenomic molecules (µTTV), arising early during propagation and ranging in size from 401 to 913 bases, were cloned and characterized. Propagation of these µTTV in in vitro cultures was demonstrated in the absence of full-length genomes.

E7 oncoprotein of novel human papillomavirus type 108 lacking the E6 gene induces dysplasia in organotypic keratinocyte cultures.

The genome organization of the novel human papillomavirus type 108 (HPV108), isolated from a low-grade cervical lesion, deviates from those of other HPVs in lacking an E6 gene. The three related HPV types HPV103, HPV108, and HPV101 were isolated from cervicovaginal cells taken from normal genital mucosa (HPV103) and low-grade (HPV108) and high-grade cervical (HPV101) intraepithelial neoplasia (Z. Chen, M. Schiffman, R. Herrero, R. DeSalle, and R. D. Burk, Virology 360:447-453, 2007, and this report). Their unusual genome organization, against the background of considerable phylogenetic distance from the other HPV types usually associated with lesions of the genital tract, prompted us to investigate whether HPV108 E7 per se is sufficient to induce the above-mentioned clinical lesions. Expression of HPV108 E7 in organotypic keratinocyte cultures increases proliferation and apoptosis, focal nuclear polymorphism, and polychromasia. This is associated with irregular intra- and extracellular lipid accumulation and loss of the epithelial barrier. These alterations are linked to HPV108 E7 binding to pRb and inducing its decrease, an increase in PCNA expression, and BrdU incorporation, as well as increased p53 and p21(CIP1) protein levels. A delay in keratin K10 expression, increased expression of keratins K14 and K16, and loss of the corneal proteins involucrin and loricrin have also been noted. These modifications are suggestive of infection by a high-risk papillomavirus.

Degradation of HPV20E6 by p53: Delta Np63 alpha and mutant p53R248W protect the wild type p53 mediated caspase-degradation.

The E6 and E7 proteins of human papillomaviruses (HPV) play a crucial role in the pathogenesis of malignant tumors. E6 protein of high-risk mucosal papillomaviruses targets a number of proteins for proteosomal degradation through complex formation with ubiquitin ligase E6AP. These proteins include, amongst others, p53, paxillin and PDZ-domain proteins e.g. Dlg and MAGUK. The mechanism by which the E6 protein of cutaneous HPV types interacts with cellular proteins to induce either benign or malignant cutaneous lesions, has not been elucidated, although extensive ultraviolet exposure and mutated p53 (hot-spot mutations) are known to be associated with non-melanoma skin cancer. We demonstrate two mechanisms in which HPV20E6 may be involved in the infected cell. One pathway is the wtp53 mediated degradation of HPV20E6 through caspase-3. Mutated p53R248W and Delta Np63 alpha, as well as other unknown proteins involved in proteosome-dependent degradation, convey a protective effect on HPV20E6 under these conditions. This unveils a remarkable opposite regulation to the well-known mechanism of E6-E6AP mediated degradation of p53 for mucosal HPV types. In a second interaction, ectopically expressed HPV20E6 induces cleavage of procaspase-3 to active caspase-3. We demonstrate, in addition, in vivo binding of HPV20E6 to the intermediate filament vimentin.

Differential enhancement of a cutaneous HPV promoter by DeltaNP63alpha, Jun and mutant p53.

The mechanism through which cutaneous papillomaviruses induce lesions is largely unknown. Ectopic expression of the DeltaNp63alpha isoform highly increased the viral promoter activity. The co-expression of c-Jun mediated and increased the DeltaNp63alpha activity by binding to the AP-1 site in an enhancer region of the HPV 20 URR. This strong activation by DeltaNp63alpha is diminished in the presence of wtp53 and abolished by the simultaneous expression of "hot-spot" mutant p53 R248W. We demonstrate that c-Jun is responsible for the viral promoter activation through its direct interaction with both DeltaNp63alpha and wtp53. The downregulation by p53 mutant R248W is accompanied by reduced protein levels of DeltaNp63alpha and phosphorylated c-Jun. The data presented in this study provide insight into a possible mechanism through which these cellular proteins may modulate a cutaneous papillomavirus genome to induce viral replication, latent infection or malignant transformation.