The 23-kilodalton E1 phosphoprotein of bovine papillomavirus type 1 is nonessential for stable plasmid replication in murine C127 cells

CK2 phosphorylation inactivates DNA binding by the papillomavirus E1 and E2 proteins

Papillomaviruses have complex life cycles that are understood only superficially. Although it is well established that the viral E1 and E2 proteins play key roles in controlling viral transcription and DNA replication, how these factors are regulated is not well understood. Here, we demonstrate that phosphorylation by the protein kinase CK2 controls the biochemical activities of the bovine papillomavirus E1 and E2 proteins by modifying their DNA binding activity. Phosphorylation at multiple sites in the N-terminal domain in E1 results in the loss of sequence-specific DNA binding activity, a feature that is also conserved in human papillomavirus (HPV) E1 proteins. The bovine papillomavirus (BPV) E2 protein, when phosphorylated by CK2 on two specific sites in the hinge, also loses its site-specific DNA binding activity. Mutation of these sites in E2 results in greatly increased levels of latent viral DNA replication, indicating that CK2 phosphorylation of E2 is a negative regulator of viral DNA replication during latent viral replication. In contrast, mutation of the N-terminal phosphorylation sites in E1 has no effect on latent viral DNA replication. We propose that the phosphorylation of the N terminus of E1 plays a role only in vegetative viral DNA replication, and consistent with such a role, caspase 3 cleavage of E1, which has been shown to be necessary for vegetative viral DNA replication, restores the DNA binding activity to phosphorylated E1.

Replication and partitioning of papillomavirus genomes

Papillomaviruses establish persistent infection in the dividing, basal epithelial cells of the host. The viral genome is maintained as a circular, double-stranded DNA, extrachromosomal element within these cells. Viral genome amplification occurs only when the epithelial cells differentiate and viral particles are shed in squames that are sloughed from the surface of the epithelium. There are three modes of replication in the papillomavirus life cycle. Upon entry, in the establishment phase, the viral genome is amplified to a low copy number. In the second maintenance phase, the genome replicates in dividing cells at a constant copy number, in synchrony with the cellular DNA. And finally, in the vegetative or productive phase, the viral DNA is amplified to a high copy number in differentiated cells and is destined to be packaged in viral capsids. This review discusses the cis elements and protein factors required for each stage of papillomavirus replication.

Regulation of bovine papillomavirus type 1 gene expression by RNA processing

Bovine papillomavirus type 1 (BPV-1) has served as a prototype for studying the molecular biology and pathogenesis of papillomaviruses. The expression of BPV-1 early and late genes is highly regulated at both transcription and post-transcriptional levels and strictly tied to the differentiation of keratinocytes. BPV-1 infects keratinocytes in the basal layer of the skin and replicates in the nucleus of infected cells in a differentiation-dependent manner. Although viral early genes begin to be expressed from the infected, undifferentiated basal cells, viral late genes are not expressed until the infected cells enter the terminal differentiation stage. Both BPV-1 early and late transcripts are intron-containing bicistronic or polycistronic RNAs, bearing more than one open reading frame and are polyadenylated at either an early or late poly (A) site. Nuclear RNA processing of these transcripts by RNA splicing and poly (A) site selection has been extensively analyzed in the past decade and various viral cis-elements and cellular factors involved in regulation of viral RNA processing were discovered, leading to our better understanding of the gene expression and biology of human papillomaviruses.

A novel splice donor site at nt 1534 is required for long-term maintenance of HPV31 genomes

Human papillomaviruses (HPV) are small double-stranded DNA viruses that replicate as low copy number nuclear plasmids during the persistent phase. HPV only possess nine open reading frames but extend their coding capabilities by alternative RNA splicing. We have identified in cell lines with replicating HPV31 genomes viral transcripts that connect the novel splice donor (SD) sites at nt 1426 and 1534 within the E1 replication gene to known splice acceptors at nt 3295 or 3332 within the E2/E4 region. These transcripts are polyadenylated and are present at low amounts in the non-productive and productive phase of the viral life cycle. Mutation of the novel splice sites in the context of HPV31 genomes revealed that the inactivation of SD1534 had only minor effects in short-term replication assays but displayed a low copy number phenotype in long-term cultures which might be due to the expression of alternative E1;E4 or yet unknown viral proteins. This suggests a regulatory role for minor splice sites within E1 for papillomavirus replication.

Identification and differential expression of novel human cervical cancer oncogene HCCR-2 in human cancers and its involvement in p53 stabilization

Basic studies of oncogenesis have demonstrated that either the elevated production of particular oncogene proteins or the occurrence of qualitative abnormalities in oncogenes can contribute to neoplastic cellular transformation. The purpose of this study was to identify unique oncogenes that are differentially expressed in human cancers and characterize their functions in tumorigenesis. To discover new putative oncogenes, the differential display RT-PCR method was applied using normal cervical tissues, cervical cancer cell lines, cervical cancer tissues, and metastatic tissues. We identified a new human cervical cancer oncogene HCCR-2 that was overexpressed in various human tumors including leukemia, lymphoma, and carcinomas of the breast, kidney, ovary, stomach, colon, and uterine cervix. Ectopic expression of HCCR-2 resulted in direct tumorigenic conversions of NIH/3T3 and Rat1 fibroblasts. Nude mice injected with NIH/3T3 cells stably transfected with HCCR-2 formed tumors in 4 weeks. The resultant tumors display characteristics of an epithelial carcinoma. In HCCR-2 transfected NCI-H460 cells and RKO cells, stabilization of the p53 tumor suppressor occurred without genetic mutation and correlated with functional impairment, as indicated by the defective induction of p53-induced p21(WAF1), MDM2, and bax. These results indicate that HCCR-2 probably represents a new oncogene that is related to tumorigenesis, functioning as a negative regulator of the p53 tumor suppressor.

Papillomavirus E1 proteins: form, function, and features

The E1 proteins are the essential origin recognition proteins for papillomavirus (PV) replication. E1 proteins bind to specific DNA elements in the viral origin of replication and assemble into hexameric helicases with the aid of a second viral protein, E2. The resultant helicase complex initiates origin DNA unwinding to provide the template for subsequent syntheses of progeny DNA. In addition to ATP-dependent helicase activity, E1 proteins interact with and recruit several host cell replication proteins to viral origin, including DNA polymerase alpha and RPA. This review will compare the basic structures and features of the human (HPV) and bovine (BPV1) papillomaviruses with an emphasis on mechanisms of replication function.

Interaction of the papillomavirus transcription/replication factor, E2, and the viral capsid protein, L2

The minor capsid protein L2 of papillomaviruses (PVs) likely plays a role in the selective encapsidation of PV DNA in viral capsids and in the infectivity of PV virions. The L2 protein also can cause the relocalization of the PV early protein, E2TA, to nuclear subdomains known as promyelocytic leukemia oncogenic domains (PODs) in which it is localized. E2TA is a transcriptional transactivator that also plays a critical role in viral DNA replication. In this study, we investigated whether L2, in causing the relocalization of E2TA, alters the activities of E2TA. We provide evidence that L2 inhibits the transcriptional transactivation function of E2, but it does not specifically inhibit the capacity of E2 to support viral DNA replication. We also investigated whether the colocalization of E2 and L2 to PODs and the ability of L2 to inhibit the transcriptional transactivation activity of E2TA might be mediated through a direct interaction between these two proteins. Using an in vitro protein-protein association assay, we found that L2 binds to E2TA. Two regions in E2TA were found to mediate this interaction. One of those domains is present in an alternative E2 gene product, E2TR, which is an antagonist to E2TA. Here we show that the L2 protein also relocalizes the E2 transcriptional repressor, E2TR, to the nuclear subdomains. These data suggest that the ability of L2 to relocalize E2 proteins to PODs is mediated through a direct interaction with L2.

The E8E2C protein, a negative regulator of viral transcription and replication, is required for extrachromosomal maintenance of human papillomavirus type 31 in keratinocytes

The viral E2 protein is a major regulator of papillomavirus DNA replication. An important way to influence viral replication is through modulation of the activity of the E2 protein. This could occur through the action of truncated E2 proteins, called E2 repressors, whose role in the replication cycle of human papillomaviruses (HPVs) has not been determined. In this study, using cell lines that contain episomal copies of the "high-risk" HPV type 31 (HPV31), we have identified viral transcripts with a splice from nucleotide (nt) 1296 to 3295. These transcripts are similar to RNAs from other animal and human papillomaviruses and have the potential to fuse a small open reading frame (E8) to the C terminus of E2, resulting in an E8E2C fusion protein. E8E2C transcripts were present throughout the complete replication cycle of HPV31. A genetic analysis of E8E2C in the context of the HPV31 genome revealed that mutation of the single ATG of the E8 gene, introduction of a stop codon downstream of the ATG, or disruption of the splice donor site at nt 1296 led to a dramatic 30- to 40-fold increase in the transient DNA replication levels in both normal and immortalized human keratinocytes. High-level expression of E8E2C from heterologous vectors was found to inhibit E1-E2-dependent DNA replication of an HPV31 origin of replication construct as well as to interfere with E2's ability to transactivate reporter gene constructs. In addition, HPV31 E8E2C strongly repressed the basal activity of the major viral early promoter P97 independent of E2. E8E2C may therefore exert its negative effect on viral DNA replication through modulating E2's ability to enhance E1-dependent DNA replication as well as by regulating viral gene expression. Surprisingly, HPV31 genomes that were unable to express E8E2C could not be maintained extrachromosomally in human keratinocytes in long-term assays despite high transient DNA replication levels. This suggests that the E8E2C protein may play a role in copy number control as well as in the stable maintenance of HPV episomes.

Transient viral DNA replication and repression of viral transcription are supported by the C-terminal domain of the bovine papillomavirus type 1 E1 protein

The bovine papillomavirus type 1 E1 protein is important for viral DNA replication and transcriptional repression. It has been proposed that the full-length E1 protein consists of a small N-terminal and a larger C-terminal domain. In this study, it is shown that an E1 polypeptide containing residues 132 to 605 (which represents the C-terminal domain) is able to support transient viral DNA replication, although at a level lower than that supported by the wild-type protein. This domain can also repress E2-mediated transactivation from the P89 promoter as well as the wild-type E1 protein can.

Cis and trans requirements for stable episomal maintenance of the BPV-1 replicator

Papillomavirus genomes are maintained as multicopy nuclear plasmids in transformed cells. To address the mechanisms by which the viral DNA is stably propagated in the transformed cells, we have constructed a cell line CH04.15 expressing constitutively the viral proteins E1 and E2, that are required for initiation of viral DNA replication. We show that these viral proteins are necessary and sufficient for stable extrachromosomal replication. Using the cell line CH04.15, we have shown that the bovine papillomavirus-1 (BPV-1) minimal origin of replication (MO) is absolutely necessary, but is not sufficient for stable extrachromosomal replication of viral plasmids. By deletion and insertion analysis, we identified an additional element (minichromosome maintenance element, MME) in the upstream regulatory region of BPV-1 which assures stable replication of the MO-containing plasmids. This element is composed of multiple binding sites for the transcription activator E2. MME appears to function in the absence of replication but requires E1 and E2 proteins for activity. In contrast to, for example, Epstein-Barr virus oriP, stably maintained BPV-1 plasmids are not subject to once-per-cell cycle replication as determined by density labelling experiments. These results indicate that papillomavirus episomal replicators replicate independently of the chromosomal DNA of their hosts.

Negative regulation of the bovine papillomavirus E5, E6, and E7 oncogenes by the viral E1 and E2 genes

Papillomaviruses induce benign squamous epithelial lesions that infrequently are associated with uncontrolled growth or malignant conversion. The virus-encoded oncogenes are clearly under negative regulation since papillomaviruses can latently infect cells and since different levels of viral oncogene expression are seen within the layers of differentiating infected epitheliomas. We used bovine papillomavirus type 1 (BPV-1) to investigate the mechanisms involved in the negative regulation of transformation. We found that the following two distinct and interacting mechanisms negatively regulate BPV-1 transformation effected by virally encoded trans-acting factors: (i) E2 repressors suppress transformation by the E6 and E7 oncogenes, and (ii) E1 and the E2 transactivator suppress transformation by the E6, E7, and E5 oncogenes. These systems interact in that the E2 repressors function to relieve the transformation suppression effected by the E1 and E2 transactivator genes. A BPV-1 mutant that lacked E2 repressors and E1 had greatly augmented transformation capacity. Analysis of this mutant revealed that the enhanced transformation was due to expression of the E6 and E7 genes in the absence of E5, revealing a previously unappreciated potency and synergy for the BPV-1 E6 and E7 oncogenes.

Role of transcriptional repressors in transformation by bovine papillomavirus type 1

Transformation of rodent cells by bovine papillomavirus type 1 (BPV-1) has been shown to require the direct contribution of the viral oncogenes encoded by the E5, E6, and E7 translational open reading frames (ORFs). It is also known that the viral E1 and E2 ORFs contribute indirectly to cellular transformation through their transcriptional modulation of these viral oncogenes. A mutant BPV-1 disrupted in two of the proteins encoded by the E2 ORF, the E2 transcriptional repressors, has a complex transformation phenotype. In this paper, we provide evidence that (i) this phenotype is not attributable to the absence of other viral genes that overlap the E2 repressor genes, (ii) the acquisition of transformation over time in cells harboring the E2 double-repressor mutant correlates with reversions of the mutations that disrupt one of the E2 repressor genes, E8/E2TR, and (iii) the initial transformation defect in the E2 double-repressor mutant can be rescued by disruption of the full-length protein encoded by the E1 ORF, the E1 transcriptional repressor. We propose a model by which the combination of E1 and E2 transcriptional repressors functions to modulate the transforming capacity of the virus.

Bovine papillomavirus E1 protein affects the host cell cycle phase fractions

C127 murine fibroblast cells were electroporated with a bovine papillomavirus E1 protein expression vector and examined by flow cytometry. E1 expressing cells (E1+) within the total cell population were distinguished from nonexpressing cells (E1-) by immunofluorescent staining with anti-E1 serum and a fluorescein-conjugated second antibody. Under conditions of saturation with the first and second antibodies, the specific green fluorescence reflected the level of intracellular E1 protein. Simultaneous staining with a DNA-specific dye, propidium iodide (PI), enabled the cell cycle distributions for the E1+ and E1- cell populations to be determined. It was found that the E1+ subpopulation had a reduced percentage of cells in G1 phase and an increased percentage of G2+M phase cells, compared to the E1- subpopulation. There was no significant difference in overall doubling time or percentage of noncycling cells in the E1+ vs. E1- populations, indicating that the change in cell cycle distribution was not due to a general activation or inhibition of cell growth by E1. Direct measurement of cell cycle phase fractions confirmed that the G1 phase was decreased and the G2+M phase was increased in E1 expressing cells. As these observations were made in the absence of other viral proteins or viral DNA replication, it suggests that the E1 protein exerts an effect on the host cell independent of its direct role in viral DNA replication. Thus, E1 may interact directly with the host cell cycle regulatory machinery.

DNA-binding domain of bovine papillomavirus type 1 E1 helicase: structural and functional aspects

The E1 protein of bovine papillomavirus type 1 is a multifunctional enzyme required for papillomaviral DNA replication. It assists in the initiation of replication both as a site-specific DNA-binding protein and as a DNA helicase. Previous work has indicated that at limiting E1 concentrations, the E2 protein is required for efficient E1 binding to the replication origin. In this study, we have defined the domain of the E1 protein required for site-specific DNA binding. Experiments with a series of truncated proteins have shown that the first amino-terminal 299 amino acids contain the DNA-binding domain; however, the coterminal M protein, which is homologous to E1 for the first 129 amino acids, does not bind origin DNA. A series of small internal deletions and substitution mutations in the DNA-binding domain of E1 show that specific basic residues in this region of the protein, which are conserved in all E1 proteins of the papillomavirus family, likely play a direct role in binding DNA and that a flanking conserved hydrophobic subdomain is also important for DNA binding. A region of E1 that interacts with E2 for cooperative DNA binding is also retained in carboxy-terminal truncated proteins, and we show that the ability of full-length E1 to complex with E2 is sensitive to cold. The E1 substitution mutant proteins were expressed from mammalian expression vectors to ascertain whether site-specific DNA binding by E1 is required for transient DNA replication in the cell. These E1 proteins display a range of mutant phenotypes, consistent with the suggestion that site-specific binding by E1 is important. Interestingly, one E1 mutant which is defective for origin binding but can be rescued for such activity by E2 supports significant replication in the cell.