HPV E6 and MAGUK protein interactions: determination of the molecular basis for specific protein recognition and degradation

It has recently been shown that the high-risk human papillomavirus (HPV) E6 proteins can target the PDZ-domain containing proteins, Dlg, MUPP-1, MAGI-1 and hScrib for proteasome-mediated degradation. However, the E6 proteins from HPV-16 and HPV-18 (the two most common high-risk virus types) differ in their ability to target these proteins in a manner that correlates with their malignant potential. To investigate the underlying mechanisms for this, we have mutated HPV-16 and HPV-18 E6s to give each protein the other's PDZ-binding motif. Analysis of these mutants shows that the greater ability of HPV-18 E6 to bind to these proteins and to target them for degradation is indeed due to a single amino acid difference. Using a number of assays, we show that the E6 proteins interact specifically with only one of the five PDZ domains of MAGI-1, and this is the first interaction described for this particular PDZ domain. We also show that the guanylate kinase homology domain and the regions of MAGI-1 downstream of amino acid 733 are not required for the degradation of MAGI-1. Finally, in a series of comparative analyses, we show that the degradation of MAGI-1 occurs through a different mechanism from that used by the E6 protein to induce the degradation of Dlg and p53.     

Chimaeric HPV E6 proteins allow dissection of the proteolytic pathways regulating different E6 cellular target proteins

The ability of HPV E6 oncoproteins to induce the degradation of PDZ domain-containing MAGUK proteins correlates with their malignant potential. We previously showed that the HPV-6 E6 protein, when provided with the PDZ-binding domain from HPV-18 E6, acquires the ability to bind the Discs Large (Dlg) tumour suppressor and target it for degradation. Based on this finding we have extended this analysis to E6 proteins from a variety of different papillomavirus types. Cloning a PDZ-binding sequence onto the C-terminus of E6 proteins derived from low-risk mucosal, and low and high-risk cutaneous papillomavirus types, enables them to bind Dlg and a second MAGUK family member, MAGI-1. This renders the mucosally-derived low-risk chimaeric HPV E6 proteins capable of targeting Dlg for degradation, but they are unable to induce significant levels of degradation of MAGI-1. In contrast, none of the E6 proteins derived from cutaneous papillomavirus types induce significant degradation of either MAGI-1 or Dlg when provided with a PDZ-binding domain. These results demonstrate significant differences, both between mucosal and cutaneous HPV E6 proteins and in the pathways required for Dlg and MAGI-1 degradation.     

HPV E6 specifically targets different cellular pools of its PDZ domain-containing tumour suppressor substrates for proteasome-mediated degradation

The high-risk HPV E6 proteins have been shown to direct the degradation of a variety of cellular proteins that contain PDZ domains. Although some of these proteins are involved in regulating processes of cell growth and polarity in Drosophila, little is known about their function in higher eukaryotic epithelial cells. In HPV-containing cells derived from cervical tumours, we find that the patterns of expression of the E6 targets hDlg (discs large), hScrib (Scribble), and MUPP1 are consistent with their being substrates for E6-induced degradation. It is also clear that, in the case of hDlg, E6 is specifically targeting nuclear pools of the protein rather than membrane-bound forms. We have also analysed the activity of a subset of E6 target proteins in the suppression of oncogene-induced cell transformation. Interestingly, Dlg, MAGI-1 and MUPP1 efficiently suppressed cell transformation, while MAGI-2 and MAGI-3 were ineffective in this assay. These results suggest that in the context of HPV-induced transformation Dlg, MAGI-1 and MUPP1 can function as tumour suppressors.     

Human and primate tumour viruses use PDZ binding as an evolutionarily conserved mechanism of targeting cell polarity regulators

A unique feature of the cancer-causing mucosotropic human papillomaviruses (HPVs) is the ability of their E6 proteins to interact with a number of PDZ domain-containing cellular substrates, including the cell polarity regulators hDlg and hScrib. These interactions are essential for the ability of these viruses to induce malignant progression. Rhesus papillomaviruses (RhPV) are similar to their human counterparts in that they also cause anogenital malignancy in their host, the Rhesus Macaque. However, unlike HPV E6, the RhPV E6 has no PDZ-binding motif. We now show that such a motif is present on the RhPV E7 oncoprotein. This motif specifically confers PDZ-binding activity and directs the interaction of RhPV E7 with the cell polarity regulator Par3, which it targets for proteasome-mediated degradation. These results demonstrate an amazing evolutionary conservation of function between the RhPV and the HPV oncoproteins, where both target proteins of the same cell polarity control network, although through different components and pathways.     

Oncogenic human papillomavirus E6 proteins target the discs large tumour suppressor for proteasome-mediated degradation.

Previous studies have shown that the oncogenic HPV E6 proteins form a complex with the human homologue of the Drosophila tumour suppressor protein, discs large (Dlg). This is mediated by the carboxy terminus of the E6 proteins and involves recognition of at least one PDZ domain of Dlg. This region of E6 is not conserved amongst E6 proteins from the low risk papillomavirus types and, hence, binding of HPV E6 proteins to Dlg correlates with the oncogenic potential of these viruses. We have performed studies to investigate the consequences of the interaction between E6 and Dlg. Mutational analysis of both the HPV18 E6 and Dlg proteins has further defined the regions of E6 and Dlg necessary for complex formation. Strikingly, co-expression of wild type HPV18 E6 with Dlg in vitro or in vivo results in a dramatic decrease in the amount of Dlg protein, whereas mutants of E6 which fail to complex with Dlg have minimal effect on Dlg protein levels. The oncogenic HPV16 E6 also decreased the Dlg levels, but this was not observed with the low risk HPV11 E6 protein. Moreover, a region within the first 544 amino acids of Dlg containing the three PDZ domains confers susceptibility to E6 mediated degradation. Finally, treatment of cells with a proteasome inhibitor overrides the capacity of E6 to degrade Dlg. These results demonstrate that Dlg is targeted by high risk HPV E6 proteins for proteasome mediated degradation.     

Differential regulation of human papillomavirus E6 by protein kinase A: conditional degradation of human discs large protein by oncogenic E6

The protein Kinase A (PKA) pathway was found to selectively regulate the function of oncogenic but not non-oncogenic E6 proteins. High risk E6 proteins are phosphorylated at their Dlg/PDZ binding motif at the C-terminus by a PKA like activity. This PKA and PDZ binding module is found only for human PV, is strictly conserved in all the transforming HPVs and is absent in all the low risk HPV types. We present evidence of a conditional regulation of E6 induced degradation of Dlg. HPV18E6 positive but not HPV negative keratinocytes exhibit increased Dlg steady state levels under conditions of high PKA activity, with a concomitant increase in the presence of Dlg at tight junctions. In vitro binding experiments show that E6 phosphorylation by PKA reduces its binding to Dlg and molecular modelling can explain this observation in a structural context. E6 dependent degradation of Dlg in cells with high PKA levels is inhibited and this is dependent on phosphorylation of the PDZ binding site in E6. In contrast, the degradation of p53 induced by E6 is not affected by PKA. We propose a differential regulation of E6 for the ubiquitin mediated degradation of specific E6 target proteins.     

HPV E6 degradation of p53 and PDZ containing substrates in an E6AP null background

Human papillomavirus (HPV) type 16 and 18 E6 proteins target many of their cellular substrates for proteasome-mediated degradation. In the case of p53, this is mediated by the E6AP ubiquitin ligase. However it is still unclear whether other E6 substrates, in particular those containing PDZ domains, are also degraded in a similar manner. To investigate this, we established an epithelial cell line from E6AP-null mice and used these cells as a background to perform E6-mediated in vivo degradation assays. We show that the PDZ domain-containing substrates of E6, including Scribble, MAGI-1 and MAGI-3, are all subject to E6-mediated degradation in these cells. Strikingly, we also found that p53 could be degraded by E6 within these cells in a proteasome-dependent manner. These results demonstrate that HPV-16 and -18 E6 can target substrates for degradation in a manner independent of the E6AP ubiquitin ligase.     

Oncogenic human papillomavirus E6 proteins target the MAGI-2 and MAGI-3 proteins for degradation

The E6 proteins from the high-risk human papillomavirus (HPV) types have previously been shown to target a number of PDZ domain-containing proteins for proteasome-mediated degradation. These include the hDlg tumour suppressor and the MAGI-1 protein. In this study we show that high-risk HPV E6 proteins also target the related MAGI-2 and MAGI-3 proteins for degradation. Moreover, we show that the interaction is specific to one PDZ domain, and that co-expression of this domain can protect each of the full-length MAGI proteins from E6-mediated degradation. These data provide clear indicators for the potential design of compounds that could specifically inhibit the interaction of oncogenic HPV E6 proteins with an important class of target proteins.     

Phosphorylation of the discs large tumour suppressor protein controls its membrane localisation and enhances its susceptibility to HPV E6-induced degradation

The Discs Large (Dlg) protein is intimately involved in regulating cell polarity and cell proliferation, and is targeted by the high-risk Human Papillomavirus (HPV) E6 proteins for proteasome-mediated degradation. We show here that exposure of cells to osmotic shock induces the hyperphosphorylation of Dlg and its concomitant accumulation within the cell membrane at sites of cell contact, a process that requires an intact actin filament network. In addition, hyperphosphorylation of Dlg also renders it more susceptible to degradation induced by the HPV-18 E6 oncoprotein. Mutational analysis of Dlg identifies a region within the first 185 amino acids as being important for this, with phosphorylation on residue S158 being responsible for its enhanced targeting by the E6 oncoprotein. Using specific kinase inhibitors, we show that Jun N-terminal kinase (JNK) is in part responsible for this phosphorylation, and for the subsequent Dlg accumulation at sites of cell contact. These results further support the notion of a complex phosphorylation-dependent regulation of Dlg, both with respect to its precise cellular localisation and to its susceptibility to proteasome-mediated degradation.     

Interactions of the PDZ-protein MAGI-1 with adenovirus E4-ORF1 and high-risk papillomavirus E6 oncoproteins

The oncoproteins of small DNA tumor viruses promote tumorigenesis by complexing with cellular factors intimately involved in the control of cell proliferation. The major oncogenic determinants for human adenovirus type 9 (Ad9) and high-risk human papillomaviruses (HPV) are the E4-ORF1 and E6 proteins, respectively. These seemingly unrelated viral oncoproteins are similar in that their transforming activities in cells depend, in part, on a carboxyl-terminal PDZ domain-binding motif which mediates interactions with the cellular PDZ-protein DLG. Here we demonstrated that both Ad9 E4-ORF1 and high-risk HPV E6 proteins also bind to the DLG-related PDZ-protein MAGI-1. These interactions resulted in MAGI-1 being aberrantly sequestered in the cytoplasm by the Ad9 E4-ORF1 protein or being targeted for degradation by high-risk HPV E6 proteins. Transformation-defective mutant viral proteins, however, were deficient for these activities. Our findings indicate that MAGI-1 is a member of a select group of cellular PDZ proteins targeted by both adenovirus E4-ORF1 and high-risk HPV E6 proteins and, in addition, suggest that the tumorigenic potentials of these viral oncoproteins depend, in part, on an ability to inhibit the function of MAGI-1 in cells.     

Human Papilloma Virus (HPV) and Host Cellular Interactions

Viral-induced carcinogenesis has been attributed to the ability of viral oncoproteins to target and interact with the host cellular proteins. It is generally accepted that Human papilloma virus (HPV) E6 and E7 function as the dominant oncoproteins of ‘high-risk’ HPVs by altering the function of critical cellular proteins. Initially it was shown that HPV E6 enhances the degradation of p53, while HPV E7 inactivates the function of the retinoblastoma tumor suppressor protein Rb. However, recent studies during the last decade have identified a number of additional host cellular targets of both HPV E6 and E7 that may also play an important role in malignant cellular transformation. In this review we present the interactions of HPV E6 and E7 with the host cellular target proteins. We also present the role of DNA integration in the malignant transformation of the epithelial cell.     

HPV E6 targeted degradation of the discs large protein: evidence for the involvement of a novel ubiquitin ligase

The Discs Large (DLG) tumour suppressor protein is targeted for ubiquitin mediated degradation by the high risk human papillomavirus (HPV) E6 proteins. In this study we have used a mutational analysis of E6 in order to investigate the mechanism by which this occurs. We first show that the differences in the affinities of HPV-16 and of HPV-18 E6 proteins for binding DLG is reflected in their respective abilities to target DLG for degradation. A mutational analysis of HPV-18 E6 has enabled us to define regions within the carboxy terminal half of the protein which are essential for the ability of E6 to direct the degradation of DLG. Mutants within the amino terminal portion of E6 which have lost the ability to bind the E6-AP ubiquitin ligase, as measured by their ability to degrade p53, nonetheless retain the ability to degrade DLG. Significant levels of DLG degradation are also obtained using wheat germ extracts which lack E6-AP. Finally, we show that the transfer of the DLG binding domain onto the low risk HPV-6 E6 confers DLG binding activity to that protein and, most significantly, allows HPV-6 E6 to target DLG for degradation. These results indicate that E6 mediated degradation of DLG does not involve the E6-AP ubiquitin ligase and, in addition, shows that the high and low risk HPV E6 proteins most likely share a common cellular intermediary in the ubiquitin pathway.     

HPV-18 E6*I modulates HPV-18 full-length E6 functions in a cell cycle dependent manner

The E6 ORFs of the high-risk Human Papillomavirus (HPV) Types 16 and 18 have been shown to encode (besides the full-length product) several truncated forms, termed E6*. We have reported previously that the HPV-18 E6*I protein interacts with the full-length E6 protein as well as with the ubiquitin ligase E6-AP and, as a result of this, E6* can inhibit E6-mediated degradation of p53. Moreover, ectopic expression of the HPV-18 E6*I protein has an antiproliferative effect in cervical cancer-derived cell lines. These results led us to investigate further the modulatory functions of E6*I on E6. Using epitope tagged versions of the 2 proteins we have analyzed the sub-cellular distribution of the full-length HPV18 E6 and HPV18 E6*I, as well as their respective cellular abundance during the cell cycle, and show specific upregulation of E6*I during G2/M. We also investigated the effect of E6*I overexpression in cell lines derived from cervical tumors, with respect to the expression levels of E6 target proteins, such as p53, hDlg and Scribble and find a corresponding increase in p53 expression also during G2/M. In addition we show that the overexpression of E6*I reduces the amount of E6 in the insoluble nuclear and membrane fractions of the cell. E6 levels can, however, be restored by the addition of a specific proteasome inhibitor, suggesting that the interaction between E6 and E6*I leads to the destabilization of a subset of the E6 protein. These results suggest that the E6*I protein can function as a fine regulator of the full-length E6 protein by direct interaction that leads both to changes in its cellular abundance as well as its distribution during particular phases of the cell cycle.     

Human homolog of Drosophila tumor suppressor Scribble negatively regulates cell-cycle progression from G1 to S phase by localizing at the basolateral membrane in epithelial cells

Drosophila tumor suppressor Scribble has been identified as an apical-basolateral polarity determinant in epithelia. A human homolog of Drosophila Scribble, human Scribble (hScrib), has been identified as a protein targeted by human papillomavirus E6 for the ubiquitin-mediated degradation dependent on E6AP, a cellular ubiquitin-protein ligase. Human Scribble is classified as a LAP protein, having leucine-rich repeats (LRRs) and PDZ domains. We investigated whether hScrib, which is thought to have a role in polarity determination based on the data of its Drosophila homolog, is involved in cell-cycle regulation and proliferation control of epithelia. Transfection of hScrib inhibits cell-cycle progression from G1 to S phase, and it up- and down-regulates expression of adenomatous polyposis coli and cyclins A and D1, respectively. Knockdown of hScrib expression by siRNA leads to cell-cycle progression from G1 to S phase. We explored functional domain mapping to reveal which domains of hScrib are critical for its cellular proliferation control and localization at the basolateral membrane. We found that LRRs and PDZ domain 1 are indispensable for hScrib to inhibit cell growth by blocking cell-cycle progression and to keep its proper localization. These data indicate that basolateral membrane localization of hScrib is closely related to its proliferation control. Our findings suggest the possibility that hScrib is involved in signal transduction to negatively regulate cell proliferation by localizing at the basolateral membrane of epithelial cells through LRRs and PDZ domains.     

高危型人乳头瘤病毒癌基因E6和E7调节细胞作用靶点的研究进展

高危型人乳头瘤病毒(human papillomavirus,HPV)的感染与多种人类癌症密切相关,其中最典型的是宫颈癌.高危型HPV最重要的两个病毒癌基因为E6和E7,病毒基因组整合到宿主基因组是病毒癌基因E6和E7实现持续表达的一种方式.HPV癌基因E6和E7能够靶向宿主细胞途径,通过这些相互作用,导致HPV发挥其...     

Genetic variants and haplotype analyses of the ZBRK1/ZNF350 gene in high-risk non BRCA1/2 French Canadian breast and ovarian cancer families

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.     

p53 levels in human mammary epithelial cells expressing wild-type and mutant human papillomavirus type 16 (HPV-16) E6 proteins

Human fibroblast cells must overcome both the M1 and the M2 stages of cellular senescence to immortalize, at which point cells almost always express telomerase activity. The human papillomavirus (HPV) oncoproteins, HPV-16 E6 and E7, can block the progression to senescence in fibroblasts by associations with p53 and pRb, respectively. Human mammary epithelial (HME) cells require only HPV-16 E6 to bypass M1, suggesting that pRb may not have a direct role in HME cells senescence. In the present report, we show that only wild-type HPV-16 E6 allows complete degradation of p53, immortalization and reactivation of telomerase activity in HME cells. These results suggest that the ability of HPV-16 wild-type and mutant E6 proteins to degrade p53 in intact HME cells and keratinocytes does not completely correlate with their ability to degrade p53 in a cell-free system. This discrepancy between in vitro and in vivo p53 degradation may be biologically significant and may provide insight into the susceptibility of certain human cells and tissues for reactivation of telomerase and immortalization.     

Human papillomavirus type-16 (HPV-16) major transforming proteins functionally interact with interferon signaling mechanisms

Since the IFN system has been implicated in cell growth and differentiation control mechanisms, we evaluated the influence of the expression of HPV-16 E6 and E7 oncoproteins on IFN signaling by using cotransfection experiments. Both viral oncoproteins differentially interfered with the inducibility of IFN-beta promoter by Sendai virus. The activation by IFN-gamma of a GBP ISRE reporter was dramatically affected by both viral proteins suggesting a disruption of STATs/IRFs function. Further, the inducibility of 6-16 gene ISRE reporter by IFN-alpha was decreased to varying degrees by both viral oncoproteins, implying that ISGF3 function is also impaired. Taken together, these observations suggest that HPV-16 negatively interacts with cellular targets of the IFN system, and these interactions may be implicated in cellular transformation caused by HPVs and their refractory response to IFN treatment.     

HPV-16 E6 oncoprotein impairs the fidelity of DNA end-joining via p53-dependent and -independent pathways

We previously reported that the E6 oncoprotein of high-risk human papillomavirus (HPV) caused genetic instability and oncogenesis by disrupting cellular DNA repair. Here, to investigate the effect of different domains of E6 on DNA double-strand break (DSB) repair, we infected normal human oral fibroblasts (NHOF) with retroviruses expressing wild-type (wt) or mutant (mt) HPV-16 E6 and examined the cellular DNA end-joining (EJ) activity. The cells expressing E6 showed not only a diminution of error-free DNA EJ but also an increase in erroneous DNA EJ capacity if compared with cells without wt E6. Analysis of DNA EJ activities from the cells expressing mt HPV-16 E6 indicated that binding to p53 and the presence of both intact zinc finger domains of E6 are necessary for inducing the E6-mediated aberrant DNA EJ activity. Also, deletion of the PDZ binding C-terminal region reduced this activity by 50%. These findings suggest that E6 can disrupt the fidelity of DSB repair via both p53-dependent and -independent pathways and the impaired fidelity might contribute to the development of genetic instability found in HPV-associated cancer.