The Canine Papillomavirus E5 Protein Signals from the Endoplasmic Reticulum

The recently discovered Canis familiaris papillomavirus (PV) type 2 (CfPV2) provides a unique opportunity to study PV gene functions in vitro and in vivo. Unlike the previously characterized canine oral PV, CfPV2 contains an E5 open reading frame and is associated with progression to squamous cell carcinoma. In the current study, we have expressed and characterized the CfPV2-encoded E5 protein, a small, hydrophobic, 41-amino-acid polypeptide. We demonstrate that, similar to the E5 protein from high-risk human PV type 16, the CfPV2 E5 protein is localized in the endoplasmic reticulum (ER) and that its expression decreases keratinocyte proliferation and cell life span. E5 expression also increases the percentage of cells in the G₁ phase of the cell cycle, with a concomitant decrease in the percentage of cells in S phase. To identify a potential mechanism for E5-mediated growth inhibition from the ER, we developed a real-time PCR method to quantify the splicing of XBP1 mRNA as a measure of ER stress. We found that the CfPV2 E5 protein induced ER stress and that this, as well as the observed growth inhibition, is tempered significantly by coexpression of the CfPV2 E6 and E7 genes. It is possible that the spatial/temporal regulation of E6/E7 gene expression during keratinocyte differentiation might therefore modulate E5 activity and ER stress.Papillomaviruses (PVs) are a large group of DNA tumor viruses that infect differentiated cutaneous and mucosal epithelia in a wide variety of mammalian species. There are nearly 200 types of human PVs (HPVs) (61), some of which are termed high risk (e.g., HPV type 16 [HPV-16]) and have the potential to immortalize primary cells and facilitate malignant progression to cervical cancer (52). An estimated 20 million cases of HPV infection occur each year in the United States alone, and cervical cancer is the second most common cause of cancer deaths among women worldwide. In general, PV infections are species specific, making it impossible to study the in vivo life cycle of HPV and the roles of its encoded proteins in viral replication and tumorigenesis. However, a few animal models do exist and the canine oral PV (COPV) has been helpful in mimicking certain biological properties of the high-risk mucosatropic HPVs, leading to the development of highly effective prophylactic vaccines (39, 49, 56). Although COPV mimics the mucosal tropism of the high-risk HPVs, it rarely progresses to cancer and lacks one of the early viral genes that may play an important role in tumorigenesis, E5. Recently, a new canine PV (Canis familiaris PV type 2 [CfPV2]) was isolated from the footpads of dogs (43). Unlike COPV, CfPV2 induces epidermal tumors and, when persistent, these benign infections progress to squamous cell carcinoma and metastasize widely. CfPV2 also encodes an E5 protein. In general, PV E5 proteins are small hydrophobic oncoproteins that localize to the endoplasmic reticulum (ER) or Golgi membranes (11, 16) but have limited amino acid sequence homology. Numerous cellular binding partners have been described for HPV-16 E5 proteins, including the V-ATPase 16-kDa subunit (1, 16), the nuclear import protein karyopherin beta 3 (25), the ER-resident protein Bap31 (40), proteins involved in zinc transport (ZnT1, EVER1, and EVER2) (27, 35), erbB4 (24), and HLA I (2). The HPV-16 E5 protein alters signaling pathways, predominantly the epidermal growth factor receptor (EGFR) pathway (17, 21, 46, 58); induces koilocytosis in cooperation with the E6 protein (26); and alters the plasma membrane expression of caveolin (47), HLA (3), and ganglioside GM1 (47). The last two changes might explain the ability of HPV-16-infected cells to circumvent detection by the host immune response and initiate tumor formation (3, 4, 21, 36, 46, 47).To provide a foundation for future in vivo studies, we initiated a series of in vitro experiments to define the intracellular localization and biological activity of CfPV2 E5. The current study demonstrates that CfPV2 E5 exhibits several properties of the HPV-16 E5 protein, including ER localization and inhibition of cell proliferation. A novel finding is that CfPV2 E5 activates the ER stress-signaling pathway, which may explain some of E5''s growth-related activities.     

The Human Papillomavirus Type 16 E5 Oncoprotein Inhibits Epidermal Growth Factor Trafficking Independently of Endosome Acidification

The human papillomavirus type 16 E5 oncoprotein (16E5) enhances acute, ligand-dependent activation of the epidermal growth factor receptor (EGFR) and concomitantly alkalinizes endosomes, presumably by binding to the 16-kDa “c” subunit of the V-ATPase proton pump (16K) and inhibiting V-ATPase function. However, the relationship between 16K binding, endosome alkalinization, and altered EGFR signaling remains unclear. Using an antibody that we generated against 16K, we found that 16E5 associated with only a small fraction of endogenous 16K in keratinocytes, suggesting that it was unlikely that E5 could significantly affect V-ATPase function by direct inhibition. Nevertheless, E5 inhibited the acidification of endosomes, as determined by a new assay using a biologically active, pH-sensitive fluorescent EGF conjugate. Since we also found that 16E5 did not alter cell surface EGF binding, the number of EGFRs on the cell surface, or the endocytosis of prebound EGF, we postulated that it might be blocking the fusion of early endosomes with acidified vesicles. Our studies with pH-sensitive and -insensitive fluorescent EGF conjugates and fluorescent dextran confirmed that E5 prevented endosome maturation (acidification and enlargement) by inhibiting endosome fusion. The E5-dependent defect in vesicle fusion was not due to detectable disruption of actin, tubulin, vimentin, or cytokeratin filaments, suggesting that membrane fusion was being directly affected rather than vesicle transport. Perhaps most importantly, while bafilomycin A₁ (like E5) binds to 16K and inhibits endosome acidification, it did not mimic the ability of E5 to inhibit endosome enlargement or the trafficking of EGF. Thus, 16E5 alters EGF endocytic trafficking via a pH-independent inhibition of vesicle fusion.High-risk human papillomaviruses (HPVs) are the causative agent of cervical cancer (63) and HPV type 16 (HPV-16) is associated with a majority of cervical malignancies worldwide (13). HPV-16 encodes three oncoproteins: E5, E6, and E7. While the contributions of E6 and E7 to cellular immortalization and transformation have been characterized in detail (20), the role of HPV-16 E5 (16E5) is poorly understood (53). Nevertheless, a number of studies suggest that 16E5 does contribute to the development of cervical cancer. Most high-risk HPV types encode an E5 protein (48), and targeted expression of the three HPV-16 oncogenes in basal epithelial cells of transgenic mice (4) leads to a higher incidence of cervical cancer than does the expression of E6 and E7 alone (44). In addition, targeted epithelial expression of 16E5 (without E6 and E7) in transgenic mice induces skin tumors (21). It may be noteworthy that unlike high-risk HPV-18, which integrates into the host DNA and potentially disrupts E5 gene expression (20, 64), the HPV-16 genome often persists in episomal form in malignant lesions (12, 16, 24, 36, 42).Biological activities of 16E5 that may facilitate carcinogenesis include evading host immune detection by interfering with the transport of antigen-presenting major histocompatibility complex (MHC) class I molecules to the cell surface (6), promoting anchorage-independent growth (33, 41, 52) and disrupting gap junctions responsible for cell-cell communication (37, 58). The 16E5 phenotype most frequently linked to the development of cancer is enhanced ligand-dependent activation of the epidermal growth factor receptor (EGFR) (15, 41, 46, 52). 16E5 stimulates EGF-dependent cell proliferation in vitro (7, 33, 40, 41, 52, 60) and in vivo (21), which might expand the population of basal or stemlike keratinocytes and thereby increase the probability that some of these cells would undergo malignant transformation. A number of studies indicate that 16E5 may enhance ligand-dependent EGFR activation by interfering with the acidification of early endosomes containing EGF bound to activated EGFRs (17, 51, 57). It has been hypothesized that 16E5 inhibits the H⁺ V-ATPase responsible for maintaining an acidic luminal pH in late endosomes and lysosomes (28) by associating with the V-ATPase 16-kDa “c” subunit (16K) (1, 5, 14, 22, 46) and disrupting assembly of the V-ATPase integral (V_o) and peripheral (V_i) subcomplexes (10). In contrast, Thomsen et al. (57) reported that 16E5 inhibits early endosome trafficking in fibroblasts by completely depolymerizing actin microfilaments.Due to the unavailability of antibodies that recognize native 16E5 and 16K, direct association of 16E5 with 16K has only been observed by overexpressing epitope-tagged forms of both proteins in vitro (5, 46) or in vivo (1, 14, 22). It is uncertain, therefore, whether these associations occur when the proteins are expressed at “physiological” levels. In yeast, both wild-type 16E5 (10) and several 16E5 mutants that associate with 16K in COS cells (1) inhibit vacuolar acidification, although another study in yeast concludes the opposite (5). 16K is a component of the V-ATPase V_o subcomplex, which is assembled in the endoplasmic reticulum (ER) (28), and 16E5 localizes to the ER and nuclear envelope in epithelial cells (32, 54). Thus, the export of V_o from the ER could potentially be inhibited by a significant level of 16K binding to 16E5, although the differential alkalinization of endosomes rather than the Golgi apparatus (17) would require specificity for those proton pumps directed to those sites.In the present study, we generated an antibody against native 16K and used it to determine whether 16K/16E5 complexes formed in primary keratinocytes. We also synthesized a new pH-sensitive fluorescent EGF conjugate to evaluate whether there was a correlation between E5-induced EGFR activation, trafficking and endosome alkalinization. Finally, we simultaneously monitored EGFR endocytic trafficking (using pH-insensitive fluorescent EGF), endosome fusion (using fluorescent EGF and dextran), and the status of cellular filaments and microtubules to evaluate whether E5 might disrupt some of these structures that mediate vesicle transport.     

Abrogation of the Postmitotic Checkpoint Contributes to Polyploidization in Human Papillomavirus E7-Expressing Cells

High-risk types of human papillomavirus (HPV) are considered the major causative agents of cervical carcinoma. The transforming ability of HPV resides in the E6 and E7 oncogenes, yet the pathway to transformation is not well understood. Cells expressing the oncogene E7 from high-risk HPVs have a high incidence of polyploidy, which has been shown to occur as an early event in cervical carcinogenesis and predisposes the cells to aneuploidy. The mechanism through which E7 contributes to polyploidy is not known. It has been hypothesized that E7 induces polyploidy in response to mitotic stress by abrogating the mitotic spindle assembly checkpoint. It was also proposed that E7 may stimulate rereplication to induce polyploidy. We have tested these hypotheses by using human epithelial cells in which E7 expression induces a significant amount of polyploidy. We find that E7-expressing cells undergo normal mitoses with an intact spindle assembly checkpoint and that they are able to complete cytokinesis. Our results also exclude DNA rereplication as a major mechanism of polyploidization in E7-expressing cells upon microtubule disruption. Instead, we have shown that while normal cells arrest at the postmitotic checkpoint after adaptation to the spindle assembly checkpoint, E7-expressing cells replicate their DNA and propagate as polyploid cells. Thus, abrogation of the postmitotic checkpoint leads to polyploidy formation in E7-expressing human epithelial cells. Our results suggest that downregulation of pRb is important for E7 to induce polyploidy and abrogation of the postmitotic checkpoint.An important hallmark of human cancers is aneuploidy, the state in which a cell has extra or missing chromosomes (12, 25). Polyploidy is the state in which cells have more than two equal sets of chromosomes and is thought to be an early event in multistep carcinogenesis that can lead to aneuploidy (1, 24), as exemplified in Barrett''s esophagus (11). Polyploidy has recently been shown to occur as an early event in cervical carcinogenesis and to predispose the cells to aneuploidy (26). Other recent studies have shown that tetraploid but not diploid mouse or human cells induce tumor formation in mice (3, 9). These studies highlight the potential importance of polyploidy in carcinogenesis.The cellular mechanisms responsible for this polyploidy formation are as of yet undetermined, but several models have been proposed. First, abrogation of the spindle assembly checkpoint followed by cleavage failure may lead to polyploidy formation (36, 40). A second proposed model is rereplication, a process of multiple rounds of DNA replication without an intervening mitosis. Third, cells that adapt to the mitotic spindle checkpoint halt in a G₁-like state with 4C DNA content. Abrogation of this postmitotic checkpoint allows the cells to replicate their 4C DNA content, leading to polyploidy formation. This has been shown in cells that express the human papillomavirus type 16 (HPV-16) E6 oncogene that degrades p53 (21). Finally, cleavage failure, which yields binucleate cells with 4C DNA content, is also a potential mechanism for polyploidy formation (31).The postmitotic checkpoint becomes activated when cells with an intact spindle assembly checkpoint become arrested during mitosis for a prolonged period of time and eventually adapt to the checkpoint, exit mitosis without cleavage, and progress into a G₁-like state with 4C DNA content (19, 22). The cells are prevented from continuing through the cell cycle and replicating their DNA by a proposed p53- and pRb-dependent postmitotic checkpoint (18, 19).High-risk types of HPV (of which HPV-16 is the most prevalent) are commonly associated with lesions that can progress to cervical carcinoma, which is one of the leading causes of cancer death in women worldwide (42). The transforming properties of high-risk HPVs primarily reside in the E6 and E7 oncogenes (reviewed in reference 7). The ability of high-risk HPV E6 and E7 proteins to promote the degradation of p53 and pRb, respectively, has been suggested as a mechanism by which HPV induces cellular transformation (6, 30). Expression of the high-risk HPV E6 and E7 oncogenes in human keratinocytes leads to polyploidy, which is enhanced by DNA damage and by activation of the spindle checkpoint through microtubule disruption (15, 27, 37, 38).Previously, it was thought but not directly shown that high-risk E6 and E7 induce polyploidy in response to microtubule disruption by abrogating the spindle checkpoint and that degradation of the tumor suppressor p53 by E6 is the mechanism by which E6 accomplishes this polyploidy formation (27, 37, 38). Others have proposed that E7 may play a role in stimulating DNA rereplication that occurs prior to mitosis initiation and polyploidy formation (20). Our recent studies demonstrate that E6 does not affect the mitotic spindle checkpoint (21). Instead, E6 abrogates the postmitotic checkpoint to induce polyploidy after microtubule disruption. Interestingly, E6 mutant proteins defective in inducing p53 degradation also induce polyploidy (21). The mechanism by which HPV E7 induces polyploidy remains to be determined. In this study, we investigate these possible mechanisms through which HPV-16 E7 induces polyploidy formation.     

The Ubiquitin-Specific Peptidase USP15 Regulates Human Papillomavirus Type 16 E6 Protein Stability

Proteomic identification of human papillomavirus type 16 (HPV16) E6-interacting proteins revealed several proteins involved in ubiquitin-mediated proteolysis. In addition to the well-characterized E6AP ubiquitin-protein ligase, a second HECT domain protein (HERC2) and a deubiquitylating enzyme (USP15) were identified by tandem affinity purification of HPV16 E6-associated proteins. This study focuses on the functional consequences of the interaction of E6 with USP15. Overexpression of USP15 resulted in increased levels of the E6 protein, and the small interfering RNA-mediated knockdown of USP15 decreased E6 protein levels. These results implicate USP15 directly in the regulation of E6 protein stability and suggest that ubiquitylated E6 could be a substrate for USP15 ubiquitin peptidase activity. It remains possible that E6 could affect the activity of USP15 on specific cellular substrates, a hypothesis that can be tested as more is learned about the substrates and pathways controlled by USP15.Human papillomaviruses (HPVs) are associated with several human cancers, most notably human cervical cancer, the second most common cancer among women worldwide (43). Papillomaviruses cause proliferative squamous epithelial lesions, and more than 100 HPV types have been described (14). The HPV types associated with mucosal squamous epithelial lesions have been further classified into high- or low-risk types based on the propensity for the lesions with which they are associated to progress to cancer. Among the high-risk HPV types, HPV type 16 (HPV16) and HPV18 account for approximately 70% of cervical cancers (43). The high-risk HPV types carry two genes, the E6 and E7 genes, which have oncogenic properties and are always expressed in HPV-positive cancers. E6 and E7 interfere with the p53 and retinoblastoma (pRB) tumor suppressor pathways, respectively, and contribute directly to cell cycle alterations, protection from apoptosis, and transformation (14). The dysregulated expression of the E6 and E7 oncoproteins is an important step in the progression from a preneoplastic stage to cancer in HPV-infected cells and is often a consequence of the integration of the viral genome into the host chromosome.The interaction between E6 and p53 is mediated by the E3 ubiquitin ligase E6AP (15). E6, p53, and E6AP form a complex in which E6 directs the ligase activity of E6AP to p53, thereby targeting p53 for ubiquitin-mediated degradation (36). E6, however, has a number of other cellular partners and other functions. For instance, the C terminus of the high-risk E6 protein contains a PDZ binding motif (20, 25) that mediates the interaction with several PDZ domain-containing proteins, including discs large (Dlg), Scribble (Scrib), the MAGI family of proteins, MUPP1, and PATJ (9, 10, 29). Some of these proteins are also targeted for degradation in an E6AP-dependent manner (22, 29). While the major mechanism of oncogenesis revolves around E6''s ability to inhibit the proapoptotic effects of p53, recent work involving the PDZ domain proteins indicates that these interactions are also important to the oncogenic potential of E6 (38, 41). Furthermore, E6 has been reported to bind a number of other cellular proteins, including but not limited to Bak, CBP/p300, c-Myc, E6TP1, hADA3, IRF3, MCM7, PTPH1, and TNF-R1 (7, 8, 17, 23, 24, 32, 35, 39, 40). The importance of the binding of several of these proteins with regard to the transformation or other functions of E6 remains to be established. E6 itself is thought to be targeted for degradation by an ubiquitin-proteasome pathway (18), although how E6 protein stability is regulated has not been well studied.Many of the E6 binding partners have been identified using purified bacterially expressed E6 fusion proteins and cell lysates from various cell types or using yeast two-hybrid screenings. While some of these interactions with E6 have been validated, the physiologic relevance of a number of proposed E6 targets remains undetermined. In an effort to identify E6-interacting proteins, perhaps under more physiologic conditions, we employed tandem affinity purification (TAP) using tagged HPV16 E6 stably expressed in the HPV16-positive cervical cancer cell line SiHa. We have discovered several new interacting proteins, including an interaction between E6 and the cellular deubiquitylating enzyme (DUB) USP15. USP15 is not targeted for degradation by E6, but we found that USP15 stabilizes E6 protein levels, suggesting that E6 may itself be a target for USP15 DUB activity.     

Role of Conserved Cysteines in the Alphavirus E3 Protein

Alphavirus particles are covered by 80 glycoprotein spikes that are essential for viral entry. Spikes consist of the E2 receptor binding protein and the E1 fusion protein. Spike assembly occurs in the endoplasmic reticulum, where E1 associates with pE2, a precursor containing E3 and E2 proteins. E3 is a small, cysteine-rich, extracellular glycoprotein that mediates proper folding of pE2 and its subsequent association with E1. In addition, cleavage of E3 from the assembled spike is required to make the virus particles efficiently fusion competent. We have found that the E3 protein in Sindbis virus contains one disulfide bond between residues Cys19 and Cys25. Replacing either of these two critical cysteines resulted in mutants with attenuated titers. Replacing both cysteines with either alanine or serine resulted in double mutants that were lethal. Insertion of additional cysteines based on E3 proteins from other alphaviruses resulted in either sequential or nested disulfide bond patterns. E3 sequences that formed sequential disulfides yielded virus with near-wild-type titers, while those that contained nested disulfide bonds had attenuated activity. Our data indicate that the role of the cysteine residues in E3 is not primarily structural. We hypothesize that E3 has an enzymatic or functional role in virus assembly, and these possibilities are further discussed.Alphaviruses are members of the Togaviradae family and are single-stranded, positive-sense RNA, enveloped viruses (17). The lipid membranes of the viruses have 80 glycoprotein spikes which are required for viral entry. Each spike is comprised of three copies of a heterodimer which consists of the E2 and E1 proteins (22, 54). E2 and E1 are glycoproteins with a single transmembrane helix that traverses the host-derived lipid bilayer. E2 interacts with the nucleocapsid core at the C terminus (12, 16, 27, 43) and contains the receptor binding site at the N terminus (5, 21, 45). E1 is the viral fusion protein responsible for mediating fusion between the virus membrane and the host cell membrane during an infection (13, 39, 47). Specific interactions in both the ectodomain and transmembrane regions are critical for heterodimer formation (30, 35, 46, 54). The assembly of each heterodimer, its subsequent assembly into a spike, and the interaction of the cytoplasmic tail of the spike with the nucleocapsid core are all essential for the efficient production of infectious particles.Glycoprotein spike assembly requires four structural proteins, E3, E2, 6K, and E1, which are expressed as a single polyprotein. E3 is a small, 64-amino-acid protein (Sindbis virus [SINV] numbering) and contains a signal sequence that translocates the protein into the endoplasmic reticulum (ER) (3, 4, 15). Early in translation, glycosylation of N14 (SINV numbering) occurs and this promotes E3''s release from the ER membrane into the lumen. As a result, the signal sequence is not cleaved from the E3 protein (14). Cellular enzymes cleave the polyprotein to yield pE2 (an uncleaved protein consisting of E3 and E2), 6K, and E1 (23, 55) proteins. In the ER, E1 is found in several conformations, only one of which will form a functional heterodimer with pE2, allowing its transport to the Golgi apparatus (1, 2, 6, 7, 36). After pE2-E1 heterodimerization, self-association between three heterodimers occurs and each individual spike is formed (25, 26, 36). As observed with Semliki Forest virus, disulfide bonds reshuffle within pE2 during protein folding (34), possibly forming intermolecular disulfide bonds between E3 and E2 residues. However, no intermolecular disulfide bonds between pE2 and E1 have been identified (34). Once the viral spikes have been assembled, they are transported to the plasma membrane (11) and are thus exposed to subcellular changes of pH, from pH 7.2 in the ER to pH 5.7 in the vesicles constitutively transporting the spikes to the plasma membrane. In the trans-Golgi network, the E3 protein is cleaved from pE2 by the cellular protein furin (18, 44, 55). E3 remains noncovalently attached to the released virus particle, while in other species E3 is found in the medium of virus-infected cells (32, 49).E3 is required for efficient particle assembly, both in mediating spike folding and in spike activation for viral entry. When an ER signal sequence was substituted for the E3 protein, heterodimerization of pE2 and E1 was abolished (26). Furthermore, when E2 and E1 were expressed individually, low levels of E2 were transported to the cell surface while E1 remained in the ER, suggesting that heterodimerization with pE2 is necessary for E1 to be transported to the cell surface (24, 26, 46). These results are consistent with E3 playing a critical role in mediating the folding of pE2 and the association of pE2 and E1 proteins during spike assembly (7, 38). In viruses where the furin cleavage site was mutated, the virus particles were correctly assembled but severely reduced in infectivity, presumably because the fusion protein was unable to dissociate from pE2 and initiate fusion (44, 55).A comparison of an amino acid sequence alignment of E3 proteins from different alphaviruses (Fig. ​(Fig.1)1) shows that the E3 protein is a small protein with four conserved cysteine (Cys) residues. A subset of E3 proteins contains an additional two Cys residues in a narrow cysteine/proline-rich region, PPCXPCC (Fig. ​(Fig.1).1). We have purified recombinant E3 protein from SINV and have determined that a disulfide bond is present and, furthermore, that these Cys residues are important in virus assembly. Within the alphavirus E3 proteins, we have identified a region that is important for mediating spike transport to the plasma membrane and thus is critical for spike assembly.Open in a separate windowFIG. 1.E3 amino acid sequence alignment from a representative group of alphaviruses. The cysteines marked with asterisks are conserved in all alphavirus species. The ⋄ indicates the conserved but nonessential glycosylation site. The PPCXPCC motif present in ∼50% of alphaviruses is underlined. SFV, Semliki Forest virus; RRV, Ross River virus; BFV, Barmah Forest virus; EEE, eastern equine encephalitis virus; ONN, O''nyong nyong virus; IGB, Igbo Ora virus; OCK, Ockelbo virus; WEE, western equine encephalitis virus; AUR, Aura virus; VEE, Venezuelan equine encephalitis virus.     

A Proteomic Approach To Identify Candidate Substrates of Human Adenovirus E4orf6-E1B55K and Other Viral Cullin-Based E3 Ubiquitin Ligases

It has been known for some time that the human adenovirus serotype 5 (Ad5) E4orf6 and E1B55K proteins work in concert to degrade p53 and to regulate selective export of late viral mRNAs during productive infection. Both of these functions rely on the formation by the Ad5 E4orf6 protein of a cullin 5-based E3 ubiquitin ligase complex containing elongins B and C. E1B55K is believed to function as the substrate recognition module for the complex and, in addition to p53, Mre11 and DNA ligase IV have also been identified as substrates. To discover additional substrates we have taken a proteomic approach by using two-dimensional difference gel electrophoresis to detect cellular proteins that decrease significantly in amount in p53-null H1299 human lung carcinoma cells after expression of E1B55K and E4orf6 using adenovirus vectors. Several species were detected and identified by mass spectroscopy, and for one of these, integrin α3, we went on in a parallel study to confirm it as a bone fide substrate of the complex (F. Dallaire et al., J. Virol. 83:5329-5338, 2009). Although the system has some limitations, it may still be of some general use in identifying candidate substrates of any viral cullin-based E3 ubiquitin ligase complex, and we suggest a series of criteria for substrate validation.During the past decade protein degradation has become increasingly recognized as a critical mechanism by which cells regulate a number of fundamental processes (reviewed in references 37, 57, and 59). Degradation frequently involves one of a variety of E3 ubiquitin ligase complexes in which a substrate recognition component introduces the target protein for ubiquitination and subsequent degradation by proteasomes (reviewed in reference 59). Several types of these complexes involve a member of the cullin family (reviewed in reference 59), and a considerable amount of information is known about those containing Cul2 or Cul5. In these cases the substrate recognition module is linked via elongins B and C to a subcomplex containing Cul2 or Cul5 and the RING protein Rbx1 (34, 58). This complex interacts with an E2 conjugating enzyme, often either Cdc34 or Ubc5, to conjugate ubiquitin chains to the substrate (44). With both Cul2- and Cul5-based complexes interaction with elongins B and C occurs via a single BC box sequence (42). The presence of either Cul2 or Cul5 is generally determined through the presence in the substrate recognition protein of specific Cul2- or Cul5-box sequences (35).Many viruses have evolved to encode products that inhibit cellular E3 ligases to protect important viral or cellular species or, in some cases, that highjack these cellular complexes to target key substrates for degradation, including components of cellular host defenses, to facilitate the infectious cycle (reviewed in reference 4). These strategies are quite common among the small DNA tumor viruses (7), and one of the most studied examples is the complex formed by the human adenovirus E4orf6 and E1B55K proteins. These proteins have been known for some time to interact (69) and to reduce the levels of the p53 tumor suppressor in infected cells (14, 47, 48, 62, 72, 73). In addition, they were shown to function in concert to block nuclear export of cellular mRNAs late in infection (2, 6, 29, 60) and to enhance the selective export of late viral mRNAs (2, 26, 29, 60, 78). Our group showed that the human adenovirus serotype 5 (Ad5) E4orf6 product interacts with several proteins (13), including components of what was at the time a unique Cul5-based E3 ubiquitin ligase containing elongins B and C and Rbx1 that degrades p53 (61). Curiously, Ad5 E4orf6 contains three BC boxes that we believe make it highly efficient in highjacking cellular elongin B/C complexes (8, 17, 41). The mechanism of selective recruitment of Cul5 by the Ad5 complex remains unknown as E4orf6 lacks a Cul5-box (17, 41). E1B55K seems to function as the substrate recognition module and, of considerable interest, both its association with E4orf6 and induction of selective late viral mRNA transport was found to depend on formation of the E3 ubiquitin ligase complex, suggesting that additional degradation substrates must exist (8, 9). This idea is not surprising since viruses, especially the small DNA tumor viruses, often evolve gene products that target multiple critical cellular pathways (32). In fact two additional E1B55K-binding substrates have now been identified, Mre11 from the MRN DNA repair complex (8, 75), and DNA ligase IV (3), the degradation of which prevent formation of viral genome concatemers, thus enhancing packaging of progeny DNA. Degradation of p53 has been suggested to promote enhanced progeny virus production by preventing the early apoptotic death of infected cells due to the stabilization of p53 by the viral E1A products (reviewed in reference 66). Nevertheless, degradation of these substrates seems unlikely to explain the observed effects on mRNA transport, suggesting that still more substrates remain to be identified. Although the studies described in the present report were in part launched to identify such substrates, as will become clear below, these targets remain to be identified.In an attempt to identify new substrates of the Ad5 E4orf6/E1B55K E3 ubiquitin ligase complex, a proteomics-based approach was initiated involving two-dimensional difference gel electrophoresis (2D-DIGE) analysis and subsequent mass spectrometry. As is well known, this technique has the advantage of improved sensitivity and accuracy provided by its ability to separate samples under two different conditions on a single gel together with a reference sample, thus reducing significantly the analytical coefficient of variation. It allows the quantification of differentially abundant proteins in complex biological samples, providing a tool to detect decreases in the levels of proteins in the cell due to targeted proteolytic degradation. We report here our attempts to identify substrates of the Ad5 E4orf6/E1B55K complex by comparing the proteomes of human non-small cell lung carcinoma H1299 cells expressing, by means of adenovirus vectors, both E1B55K and E4orf6 proteins or E4orf6 protein alone. Ten candidate proteins were identified, most having functions seemingly unrelated to our current understanding of the roles of the E4orf6/E1B55K complex. At least three showed promising features characteristic of substrates, and one has now been confirmed in a parallel study to be a bone fide E4orf6/E1B55K substrate (20). We suggest that this approach could be utilized to identify candidate substrates, among relatively high abundance proteins, that are degraded by other viral cullin-based E3 ubiquitin ligase complexes.     

Mutations within a Conserved Region of the Hepatitis C Virus E2 Glycoprotein That Influence Virus-Receptor Interactions and Sensitivity to Neutralizing Antibodies

Cell culture-adaptive mutations within the hepatitis C virus (HCV) E2 glycoprotein have been widely reported. We identify here a single mutation (N415D) in E2 that arose during long-term passaging of HCV strain JFH1-infected cells. This mutation was located within E2 residues 412 to 423, a highly conserved region that is recognized by several broadly neutralizing antibodies, including the mouse monoclonal antibody (MAb) AP33. Introduction of N415D into the wild-type (WT) JFH1 genome increased the affinity of E2 to the CD81 receptor and made the virus less sensitive to neutralization by an antiserum to another essential entry factor, SR-BI. Unlike JFH1_WT, the JFH1_N415D was not neutralized by AP33. In contrast, it was highly sensitive to neutralization by patient-derived antibodies, suggesting an increased availability of other neutralizing epitopes on the virus particle. We included in this analysis viruses carrying four other single mutations located within this conserved E2 region: T416A, N417S, and I422L were cell culture-adaptive mutations reported previously, while G418D was generated here by growing JFH1_WT under MAb AP33 selective pressure. MAb AP33 neutralized JFH1_T416A and JFH1_I422L more efficiently than the WT virus, while neutralization of JFH1_N417S and JFH1_G418D was abrogated. The properties of all of these viruses in terms of receptor reactivity and neutralization by human antibodies were similar to JFH1_N415D, highlighting the importance of the E2 412-423 region in virus entry.Hepatitis C virus (HCV), which belongs to the Flaviviridae family, has a positive-sense single-stranded RNA genome encoding a polyprotein that is cleaved by cellular and viral proteases to yield mature structural and nonstructural proteins. The structural proteins consist of core, E1 and E2, while the nonstructural proteins are p7, NS2, NS3, NS4A, NS4B, NS5A, and NS5B (42). The hepatitis C virion comprises the RNA genome surrounded by the structural proteins core (nucleocapsid) and E1 and E2 (envelope glycoproteins). The HCV glycoproteins lie within a lipid envelope surrounding the nucleocapsid and play a major role in HCV entry into host cells (21). The development of retrovirus-based HCV pseudoparticles (HCVpp) (3) and the cell culture infectious clone JFH1 (HCVcc) (61) has provided powerful tools to study HCV entry.HCV entry is initiated by the binding of virus particles to attachment factors which are believed to be glycosaminoglycans (2), low-density lipoprotein receptor (41), and C-type lectins such as DC-SIGN and L-SIGN (12, 37, 38). Upon attachment at least four entry factors are important for particle internalization. These include CD81 (50), SR-BI (53) and the tight junction proteins claudin-1 (15) and occludin (6, 36, 51).CD81, a member of the tetraspanin family, is a cell surface protein with various functions including tissue differentiation, cell-cell adhesion and immune cell maturation (34). It consists of a small and a large extracellular loop (LEL) with four transmembrane domains. Viral entry is dependent on HCV E2 binding to the LEL of CD81 (3, 50). The importance of HCV glycoprotein interaction with CD81 is underlined by the fact that many neutralizing antibodies compete with CD81 and act in a CD81-blocking manner (1, 5, 20, 45).SR-BI is a multiligand receptor expressed on liver cells and on steroidogenic tissue. It binds to high-density lipoproteins (HDL), low-density lipoproteins (LDL), and very low-density lipoproteins (VLDL) (31). The SR-BI binding site is mapped to the hypervariable region 1 (HVR-1) of HCV E2 (53). SR-BI ligands, such as HDL and oxidized LDL have been found to affect HCV infectivity (4, 14, 58-60). Indeed, HDL has been shown to enhance HCV infection in an SR-BI-dependent manner (4, 14, 58, 59). Antibodies against SR-BI and knockdown of SR-BI in cells result in a significant inhibition of viral infection in both the HCVpp and the HCVcc systems (5, 25, 32).Although clearly involved in entry and immune recognition, the more downstream function(s) of HCV glycoproteins are poorly understood, as their structure has not yet been solved. Nonetheless, mutational analysis and mapping of neutralizing antibody epitopes have delineated several discontinuous regions of E2 that are essential for HCV particle binding and entry (24, 33, 45, 47). One of these is a highly conserved sequence spanning E2 residues 412 to 423 (QLINTNGSWHIN). Several broadly neutralizing monoclonal antibodies (MAbs) bind to this epitope. These include mouse monoclonal antibody (MAb) AP33, rat MAb 3/11, and the human MAbs e137, HCV1, and 95-2 (8, 16, 44, 45, 49). Of these, MAbs AP33, 3/11, and e137 are known to block the binding of E2 to CD81.Cell culture-adaptive mutations within the HCV glycoproteins are valuable for investigating the virus interaction(s) with cellular receptors (18). In the present study, we characterize an asparagine-to-aspartic acid mutation at residue 415 (N415D) in HCV strain JFH1 E2 that arose during the long-term passaging of infected human hepatoma Huh-7 cells. Alongside N415D, we also characterize three adjacent cell culture adaptive mutations reported previously and a novel substitution generated in the present study by propagating virus under MAb AP33 selective pressure to gain further insight into the function of this region of E2 in viral infection.     

Membrane Orientation of the Human Papillomavirus Type 16 E5 Oncoprotein

The E5 protein of human papillomavirus type 16 is a small, hydrophobic protein that localizes predominantly to membranes of the endoplasmic reticulum (ER). To define the orientation of E5 in these membranes, we employed a differential, detergent permeabilization technique that makes use of the ability of low concentrations of digitonin to selectively permeabilize the plasma membrane and saponin to permeabilize all cellular membranes. We then generated a biologically active E5 protein that was epitope tagged at both its N and C termini and determined the accessibility of these termini to antibodies in the presence and absence of detergents. In both COS cells and human ectocervical cells, the C terminus of E5 was exposed to the cytoplasm, whereas the N terminus was restricted to the lumen of the ER. Finally, the deletion of the E5 third transmembrane domain (and terminal hydrophilic amino acids) resulted in a protein with its C terminus in the ER lumen. Taken together, these topology findings are compatible with a model of E5 being a 3-pass transmembrane protein and with studies demonstrating its C terminus interacting with cytoplasmic proteins.Human papillomaviruses (HPVs) are small, nonenveloped, double-stranded DNA viruses (25) that are the causative agents of benign and malignant tumors in humans (43). Most cancers of the cervix, vagina, and anus are caused by HPVs, as are a fraction of oropharyngeal cancers (29, 44). HPV type 16 (HPV-16) is the type most frequently found in anogenital cancers (15, 29), including cervical cancer, the most common cancer of women worldwide (44).Some of the biological activities of the HPV-16 E5 protein (16E5) include the augmentation of epidermal growth factor (EGF) signaling pathways (8), stimulation of anchorage-independent growth (38), alkalinization of endosomal pH (11), and alteration of membrane lipid composition (39). 16E5 also exhibits weak transforming activity in vitro (12), induces epithelial tumors in transgenic mice (13), and plays an important role in koilocytosis (20). There are multiple documented intracellular binding targets for 16E5 such as the 16-kDa subunit of the vacuolar H⁺-ATPase (7, 36), the heavy chain of HLA type I (1), EGF receptor family member ErbB4 (6), calnexin (16), the zinc transporter ZnT-1 (21), the EVER1 and EVER2 transmembrane channel-like proteins that modulate zinc homeostasis (21, 31), the nuclear import receptor family member karyopherin β3 (KNβ3) (19), and BAP31, which was previously reported to contribute to B-cell receptor activation (35).16E5 is a small, hydrophobic protein that localizes to intracellular membranes. When overexpressed in COS cells, it is present in the endoplasmic reticulum (ER) and, to a lesser extent, in the Golgi apparatus (7). At a lower level of expression in human foreskin keratinocytes and human ectocervical cells (HECs), 16E5 is present predominantly in the ER (10, 39). 16E5 contains three hydrophobic regions (14, 16, 22, 30, 41), and it was reported previously that the first hydrophobic region determines various biological properties of the protein (16, 22). It was also shown previously that the 16E5 C terminus plays a role in binding to karyopherin β3 (19) and in the formation of koilocytes (20). While theoretical predictions have been made for the topology of E5 in membranes (16), no experimental data exist. However, a recent study suggested that some highly expressed 16E5 localizes to the plasma membrane, with its C terminus exposed externally (18).The aim of the present study was to establish the orientation of 16E5 in the ER membrane. By using immunofluorescence microscopy coupled with differential membrane permeabilization (24, 34), we demonstrate the membrane orientation of an N- and C-terminally tagged, biologically active 16E5 protein. Our results indicate that the N terminus is intralumenal and that the C terminus is cytoplasmic, consistent with a model of E5 being a three-pass transmembrane protein and with current data on the interaction of its C terminus with cytoplasmic proteins.     

The Adenovirus E4orf4 Protein Induces G2/M Arrest and Cell Death by Blocking Protein Phosphatase 2A Activity Regulated by the B55 Subunit

Human adenovirus E4orf4 protein is toxic in human tumor cells. Its interaction with the Bα subunit of protein phosphatase 2A (PP2A) is critical for cell killing; however, the effect of E4orf4 binding is not known. Bα is one of several mammalian B-type regulatory subunits that form PP2A holoenzymes with A and C subunits. Here we show that E4orf4 protein interacts uniquely with B55 family subunits and that cell killing increases with the level of E4orf4 expression. Evidence suggesting that Bα-specific PP2A activity, measured in vitro against phosphoprotein substrates, is reduced by E4orf4 binding was obtained, and two potential B55-specific PP2A substrates, 4E-BP1 and p70^S6K, were seen to be hypophosphorylated in vivo following expression of E4orf4. Furthermore, treatment of cells with low levels of the phosphatase inhibitor okadaic acid or coexpression of the PP2A inhibitor I₁^PP2A enhanced E4orf4-induced cell killing and G₂/M arrest significantly. These results suggested that E4orf4 toxicity results from the inhibition of B55-specific PP2A holoenzymes, an idea that was strengthened by an observed growth arrest resulting from treatment of H1299 cells with Bα-specific RNA interference. We believe that E4orf4 induces growth arrest resulting in cell death by reducing the global level of B55-specific PP2A activity, thus preventing the dephosphorylation of B55-specific PP2A substrates, including those involved in cell cycle progression.Our research group and others have shown that the 114-residue product of early region E4 of human adenoviruses, termed E4orf4, induces p53-independent cell death in human tumor cells (24, 25, 34-36, 55) and in Saccharomyces cerevisiae (23, 53). E4orf4 protein, which shares no obvious homology with other viral or cellular products, kills a wide range of human cancer cells but is believed to have reduced activity against normal human primary cells (6, 55, 56). Although in some cases E4orf4-expressing cells exhibit characteristics typical of apoptosis, including the presence of irregularly shaped and shrunken nuclei, cytoplasmic vacuolization, and membrane blebbing (24, 25, 50, 55), cell death may more typically be independent of caspase activation (24, 25, 30, 32, 50). With H1299 human non-small-cell lung carcinoma cells, death is characterized by rapid cell rounding, enlargement, release from the surface of culture plates, cell cycle arrest in G₂/M and possibly G₁, and eventually, after an extended period, loss of membrane integrity (30). Both cytoplasmic and nuclear pathways have been observed, the former involving interactions with c-Src family kinases, activation of calpain, and remodeling of the actin cytoskeleton (7, 24, 50, 51, 58). Little is known about the nuclear pathway, which may represent the predominant death-inducing process. Our current evidence suggests that H1299 cells die following prolonged irreversible cell cycle arrest leading to mitotic catastrophe and death by a necrosis-like process (30).E4orf4 is known to associate with the Bα regulatory subunit of protein phosphatase 2A (PP2A) (22, 34), and this interaction appears to be necessary for the majority of E4orf4 toxicity in both yeast (23, 53) and human tumor cells (34, 56). PP2A is an abundant serine-threonine phosphatase involved in regulation of metabolism, splicing, translation, morphogenesis, development, and cell cycle progression (15, 19, 27, 43, 59). PP2A holoenzymes exist as multiple heterotrimeric complexes composed of a catalytic C subunit, an A subunit that functions as a scaffold, and a B-type regulatory subunit. Two forms each of the A and C subunits exist in mammalian cells; however, more than 20 B-type subunits have been identified in three unique classes (B/B55, B′/B56, B″/PR72), plus striatin/SG2NA (sometimes called B‴) (10, 19, 26). Although one group has suggested that E4orf4 protein interacts with one or more members of the B′/B56 class (57), it is generally accepted that interaction with the Bα/B55 subunit (Cdc55 in yeast) is important for induction of cell death in both human tumor cells and yeast (53, 57). Interestingly, a recent report has also suggested that in yeast, growth suppression induced by E4orf4 is mediated only in part by the catalytic C subunit of PP2A (31).In the present report, we show that E4orf4 protein interacts uniquely with members of the B55 class of PP2A B-type subunits, and at sufficient concentrations, it appears to become toxic by reducing dephosphorylation of substrates of B55-containing PP2A holoenzymes. As cell death is preceded by cell cycle arrest, we believe that key substrates may include proteins required for cell cycle progression.     

Adeno-Associated Virus Small Rep Proteins Are Modified with at Least Two Types of Polyubiquitination

Adeno-associated virus (AAV) type 2 and 5 proteins Rep52 and Rep40 were polyubiquitinated during AAV-adenovirus type 5 (Ad5) coinfection and during transient transfection in either the presence or absence of Ad5 E4orf6 and E1b-55k. Polyubiquitination of small Rep proteins via lysine 48 (K48) linkages, normally associated with targeting of proteins for proteasomal degradation, was detected only in the presence of E4orf6. The small Rep proteins were ubiquitinated via lysine 63 (K63) following transfection in either the presence or absence of E4orf6 or following coinfection with Ad5. E4orf6/E1b-55k-dependent K48-specific polyubiquitination of small Rep proteins could be inhibited using small interfering RNA (siRNA) to cullin 5.Together, adenovirus type 5 (Ad5) early gene products E1a, E1b-55k, E2a, E4orf6, and virus-associated (VA) RNA can support efficient replication of adeno-associated virus (AAV) (4, 31). E4orf6 and E1b-55k are known to interact with cellular cullin 5 (cul5), elongins B and C, and the ring box protein Rbx1 to form an E3 ubiquitin ligase complex that specifically targets a small population of cellular proteins for degradation by the proteasome (1, 7, 21, 22, 24, 27). This property has been implicated in a number of functions presumed to be required for both Ad and AAV replication (3, 8-10, 17, 23, 24, 34, 35).Previously, only p53, Mre11, DNA ligase IV, and integrin α3 had been shown to be substrates of the Ad5 E3 ubiquitin ligase complex (1, 7, 21, 22, 24, 27); however, we have recently shown (16, 17) that the small Rep proteins and capsid proteins of AAV5 are also degraded in the presence of Ad E4orf6 and E1b-55k in a proteasome-dependent manner. These proteins were restored to levels required during infection by the action of VA RNA (17). The targeting for degradation of AAV5 protein by the E4orf6/E1b-55k E3 ubiquitin ligase complex required functional BC-box motifs in E4orf6 and could be inhibited by depletion of the scaffolding protein cullin 5 using directed small interfering RNA (siRNA) (16). In addition, the degradation of AAV5 protein was partially prevented by overexpression of pUBR7, a plasmid that generates a dominant-negative ubiquitin (16). The role this targeted degradation plays in the life cycle of AAV has not yet been clarified; however, E4orf6 mutants that cannot function in this regard do not support AAV replication as well as wild-type E4orf6 (R. Nayak and D. J. Pintel, unpublished data). Degradation of Mre11 by the Ad5 E3 ligase has also been implicated in allowing efficient Ad5 and AAV replication (24). Ubiquitination of AAV Rep proteins during viral infection, however, has not previously been reported.