A bovine papillomavirus E1-related protein binds specifically to bovine papillomavirus DNA

Is viral E6 oncoprotein a viable target? A critical analysis in the context of cervical cancer

An understanding of the pathology of cervical cancer (CC) mediated by E6/E7 oncoproteins of high-risk human papillomavirus (HPV) was developed by late 80's. But if we look at the present scenario, not a single drug could be developed to inhibit these oncoproteins and in turn, be used specifically for the treatment of CC. The readers are advised not to presume the "viability of E6 protein" as mentioned in the title relates to just druggability of E6. The viability aspect will cover almost everything a researcher should know to develop E6 inhibitors until the preclinical stage. Herein, we have analysed the achievements and shortcomings of the scientific community in the last four decades in targeting HPV E6 against CC. Role of all HPV proteins has been briefly described for better perspective with a little detailed discussion of the role of E6. We have reviewed the articles from 1985 onward, reporting in vitro inhibition of E6. Recently, many computational studies have reported potent E6 inhibitors and these have also been reviewed. Subsequently, a critical analysis has been reported to cover the in vitro assay protocols and in vivo models to develop E6 inhibitors. A paragraph has been devoted to the role of public policy to fight CC employing vaccines and whether the vaccine against HPV has quenched the zeal to develop drugs against it. The review concludes with the challenges and the way forward.

In vitro and Animal Models for Antiviral Therapy in Papillomavirus Infections

The need for antiviral therapies for papillomavirus infections is well recognized but the difficulties of reproducing the infectious cycle of papillomaviruses in vitro has hindered our understanding of virus-cell interactions and the regulation of viral gene expression during permissive growth. Recent advances in understanding the temporal expression and function of papillomavirus proteins has enabled consideration of a targeted approach to papillomavirus chemotherapy and in particular the inhibition of viral replication by targeting the E1 and E2 proteins. There are in vitro culture systems available for the screening of new chemotherapeutic agents, since significant advances have been made with culture systems which promote epithelial differentiation in vitro. However, to date, there are no published data which show that virions generated in vitro can infect keratinocytes and initiate another round of replication in vitro. In vivo animal models are therefore necessary to assess the efficacy of antivirals in preventing and treating viral infection, particularly for the low-risk genital viruses which are on the whole refractory to culture in vitro. Although papillomaviruses affect a wide variety of hosts in a species-specific manner, the animals most useful for modelling papillomavirus infections include the rabbit, ox, mouse, dog, horse, primate and sheep. The ideal animal model should be widely available, easy to house and handle, be large enough to allow for adequate tissue sampling, develop lesions on anatomical sites comparable with those in human diseases and these lesions should be readily accessible for monitoring and ideally should yield large amounts of infectious virus particles for use in both in vivo and in vitro studies. The relative merits of the various papillomavirus animal models available in relation to these criteria are discussed.

A superfamily 3 DNA helicase encoded by plasmid pSSVi from the hyperthermophilic archaeon Sulfolobus solfataricus unwinds DNA as a higher-order oligomer and interacts with host primase

Replication proteins encoded by nonconjugative plasmids from the hyperthermophilic archaea of the order Sulfolobales show great diversity in amino acid sequence. We have biochemically characterized ORF735, a replication protein from pSSVi, an integrative nonconjugative plasmid from Sulfolobus solfataricus P2. We show that ORF735 is a DNA helicase of superfamily 3. It unwound double-stranded DNA (dsDNA) in a 3'-to-5' direction in the presence of ATP over a wide range of temperatures, from 37 degrees C to 75 degrees C, and possessed DNA-stimulated ATPase activity. ORF735 existed in solution as a salt-stable dimer and was capable of assembling into a salt-sensitive oligomer that was significantly larger than a hexamer in the presence of a divalent cation (Mg(2+)) and an adenine nucleotide (ATP, dATP, or ADP) or its analog (ATPgammaS or AMPPNP). Both N-terminal and C-terminal portions of ORF735 (87 and 160 amino acid residues, respectively, in size) were required for protein dimerization but dispensable for the formation of the higher-order oligomer. The protein unwound DNA only as a large oligomer. Yeast two-hybrid and coimmunoprecipitation assays revealed that ORF735 interacted with the noncatalytic subunit of host primase. These findings provide clues to the functional role of ORF735 in pSSVi DNA replication.

AAA+ ATPases in the initiation of DNA replication

All cellular organisms and many viruses rely on large, multi-subunit molecular machines, termed replisomes, to ensure that genetic material is accurately duplicated for transmission from one generation to the next. Replisome assembly is facilitated by dedicated initiator proteins, which serve to both recognize replication origins and recruit requisite replisomal components to the DNA in a cell-cycle coordinated manner. Exactly how imitators accomplish this task, and the extent to which initiator mechanisms are conserved among different organisms have remained outstanding issues. Recent structural and biochemical findings have revealed that all cellular initiators, as well as the initiators of certain classes of double-stranded DNA viruses, possess a common adenine nucleotide-binding fold belonging to the ATPases Associated with various cellular Activities (AAA+) family. This review focuses on how the AAA+ domain has been recruited and adapted to control the initiation of DNA replication, and how the use of this ATPase module underlies a common set of initiator assembly states and functions. How biochemical and structural properties correlate with initiator activity, and how species-specific modifications give rise to unique initiator functions, are also discussed.

Human papillomaviruses and cervical cancer

Carcinoma of the uterine cervix, a leading cause of cancer death in women worldwide, is initiated by infection with high-risk types of human papillomaviruses (HPVs). This review summarizes laboratory studies over the past 20 years that have elucidated the major features of the HPV life cycle, identified the functions of the viral proteins, and clarified the consequences of HPV infection for their host cells. This information has allowed the development of various strategies to prevent or treat infections, including prophylactic vaccination with virus-like particles, therapeutic vaccination against viral proteins expressed in cancer cells, and antiviral approaches to inhibit virus replication, spread, or pathogenesis. These strategies have the potential to cause a dramatic reduction in the incidence of cervical carcinoma and serve as the prototype for comprehensive efforts to combat virus-induced tumors.

Cellular topoisomerase I modulates origin binding by bovine papillomavirus type 1 E1

In addition to viral proteins E1 and E2, bovine papillomavirus type 1 (BPV1) depends heavily on host replication machinery for genome duplication. It was previously shown that E1 binds to and recruits cellular replication proteins to the BPV1 origin of replication, including DNA polymerase alpha-primase, replication protein A (RPA), and more recently, human topoisomerase I (Topo I). Here, we show that Topo I specifically stimulates the origin binding of E1 severalfold but has no effect on nonorigin DNA binding. This is highly specific, as binding to nonorigin DNA is not stimulated, and other cellular proteins that bind E1, such as RPA and polymerase alpha-primase, show no such effect. The stimulation of E1's origin binding by Topo I is not synergistic with the stimulation by E2. Although the enhanced origin binding of E1 by Topo I requires ATP and Mg2+ for optimal efficiency, ATP hydrolysis is not required. Using an enzyme-linked immunosorbent assay, we showed that the interaction between E1 and Topo I is decreased in the presence of DNA. Our results suggest that Topo I participates in the initiation of papillomavirus DNA replication by enhancing E1 binding to the BPV1 origin.

The mitotic chromosome binding activity of the papillomavirus E2 protein correlates with interaction with the cellular chromosomal protein, Brd4

The papillomavirus transcriptional activator, E2, is involved in key functions of the viral life cycle. These include transcriptional regulation, viral DNA replication, and viral genome segregation. The transactivation domain of E2 is required for each of these functions. To identify the regions of the domain that mediate binding to mitotic chromosomes, a panel of mutations has been generated and their effect on various E2 functions has been analyzed. A structural model of the bovine papillomavirus type 1 (BPV1) E2 transactivation domain was generated based on its homology with the solved structure of the human papillomavirus type 16 (HPV16) domain. This model was used to identify distinct surfaces of the domain to be targeted by point mutation to further delineate the functional region of the transactivation domain responsible for mitotic chromosome association. The mutated E2 proteins were assessed for mitotic chromosome binding and, in addition, transcriptional activation and transcriptional repression activities. Mutation of amino acids R37 and I73, which are located on a surface of the domain that in HPV16 E2 is reported to mediate self-interaction, completely eliminated mitotic chromosome binding. Mitotic chromosome binding activity was found to correlate well with the ability to interact with the cellular chromosomal associated factor Brd4, which has recently been proposed to mediate the association between BPV1 E2 and mitotic chromosomes.

Structural Polymorphism of Methanothermobacter thermautotrophicus MCM

The minichromosome maintenance (MCM) proteins are essential for replication initiation and elongation in eukarya and archaea. There are six MCM proteins in eukaryotes, and MCM complexes are believed to unwind DNA during chromosomal DNA replication. However, the mechanism and structure of the MCM complexes are not known. Only one MCM is found in the archaeon Methanothermobacter thermautotrophicus (mtMCM), and this provides a simpler system for study. The crystal structure of a mtMCM N-terminal fragment has been solved, but surprisingly only subtle structural changes were seen between the wild-type protein and one having a mutation corresponding to the yeast MCM5 bob1 mutation. The bob1 mutation bypasses the phosphorylation required for activation of MCM in yeast. We have used electron microscopy and three-dimensional reconstruction to examine a number of different fragments of mtMCM, and can visualize a large conformational change within the N-terminal fragment. This offers new insight into the conformational dynamics of MCM and the phosphorylation-bypass phenotype in yeast.

Purification and biochemical characterization of the E1 replication initiation protein of the cutaneous human papillomavirus type 1

The E1 and E2 proteins encoded by papillomaviruses are required for viral DNA replication. Although E1 is the replication initiator protein, previous studies have shown that the full-length E1 protein binds to the origin weakly and with low sequence specificity. The E2 protein facilitates binding of the E1 protein to the origin, triggering the initiation of replication. The E1 protein contains ATPase, helicase and DNA unwinding activities. In vivo studies with mucosal human papillomavirus (HPV) types 11 and 18 have shown that while E1 is absolutely essential for replication, the E1 binding site is dispensable. However, both the E2 protein and E2 binding sites are required for their replication. In contrast to these HPVs, transient replication of HPV type 1, which infects cutaneous tissue, requires only the viral E1 protein and E1 binding site. To understand the basis for these differences, we have overexpressed and purified the HPV-1 E1 and E2 proteins and studied their biochemical properties. The purified E1 protein was shown to have an ATPase activity with a very low K(m) value, similar to that of the SV40 large T antigen. The E1 protein bound to the HPV-1 origin in the absence of the E2 protein and without the use of any cross-linking agents. Our results suggest that the ability of the HPV-1 E1 protein to initiate DNA replication in vivo in the absence of the E2 protein may be due to its stable interaction with the HPV-1 origin.

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.

Hydrophobic residue contributions to sequence-specific DNA binding by the bovine papillomavirus helicase E1

Previously, mutational analyses of the DNA binding domain of the bovine papillomavirus E1 protein (E1DBD) identified several hydrophobic residues that are critical for DNA binding activity (M. West, D. Flanery, K. Woytek, D. Rangasamy, and V. G. Wilson, 2001, J. Virol. 75, 11948-11960). Hydrophobic interactions of nonpolar amino acid side chains can contribute to the function of DNA binding proteins through both conformational effects and direct interaction with nucleotides. To further investigate the role of hydrophobic residues in E1DBD function, a more extensive site-directed mutational analysis of hydrophobic amino acids was conducted. Alanine substitutions were made at residues V196, F197, F217, F, 237, V246, L249, and F276, and the mutants were tested for DNA binding activity in vitro and in vivo. The E1 F237A and F276A mutants were completely defective for site-specific DNA binding, while the other mutants retained partial to full wild-type binding activity. Consistent with their DNA binding defect, the F237A and F276A mutants were severely impaired for the ability to support transient in vivo replication of an origin plasmid. Combined with our previous study, five critical hydrophobic residues have been identified: F175, V193, F237, V246, and F276. These five residues localize to two internal clusters in the E1DBD structure designated hydrophobic clusters A (HCA; includes F175, V193, and F276) and B (HCB; includes F237 and V246). Amino acid side chains from residues in HCA and HCB have little surface accessibility and it is unlikely that they are involved in direct contact with DNA. HCA is distal to the DNA binding surface and presumably contributes to global conformational organization of the E1DBD. HCB is positioned beneath the DNA contact surface and we propose that it serves as an anchor or platform device to stabilize the DNA-binding element. A comparable hydrophobic cluster is present in the corresponding position in the T antigen DBD and likely serves a similar function.

E1 protein of bovine papillomavirus type 1 interferes with E2 protein-mediated tethering of the viral DNA to mitotic chromosomes

Eukaryotic viruses can maintain latency in dividing cells as extrachromosomal plasmids. It is therefore of vital importance for viruses to ensure nuclear retention and proper segregation of their viral DNA. The bovine papillomavirus (BPV) E2 enhancer protein plays a key role in these processes by tethering the viral DNA to the host cell chromosomes. Viral genomes that harbor phosphorylation mutations in the E2 gene are transformation defective, and for these mutant genomes, neither the viral DNA nor the E2 protein is detected on mitotic chromosomes, while other key functions of E2 in transcription and replication were wild type. Moreover, secondary mutations in both the E2 and E1 proteins lead to suppression of the phosphorylation mutant phenotype and resulted in reattachment of the viral DNA and the E2 protein onto mitotic chromosomes, suggesting that E1 also plays a role in viral genome partitioning. The E1 protein was cytologically always excluded from mitotic chromatin, either as a suppressor allele or as the wild type. In the absence of other viral proteins, an E2 protein containing alanine substitutions for phosphorylation substrates in the hinge region (E2-A4) was detected as wild-type on mitotic chromosomes. However, when wild-type E1 protein levels were increased in cells expressing either the A4 mutant E2 proteins or wild-type E2, the E2-A4 protein was much more sensitive to chromosomal dislocation than was the wild-type protein. In contrast, suppressor alleles of E1 were not capable of such abrogation of E2 binding (A4 or wild-type) to chromosomes. These results suggest that wild-type E1 can be a negative regulator of the chromosomal attachment of E2.

Functional analysis of a carboxyl-terminal phosphorylation mutant of the bovine papillomavirus E1 protein

The papillomavirus E1 protein is essential for viral DNA replication, and phosphorylation of E1 appears to regulate protein function and DNA replication. Serine 584 of bovine papillomavirus E1 is in a conserved motif resembling a CK2 consensus site, and is phosphorylated by CK2 in vitro. Mutation of serine 584 to alanine eliminates replication of the viral genome in transient replication assays. Wild-type and mutant E1 proteins were expressed from recombinant baculoviruses and used to assess biochemical functions of the amino acid 584 substitution. Helicase enzyme activity, E1 binding to the viral E2 protein and to cellular DNA polymerase alpha-primase were all unaffected in the mutant protein. Binding of E1 to viral replication origin DNA sequences was reduced in the mutant, but not eliminated. The carboxyl-terminal region of the protein appears to play a role in regulating E1 function, and adds to a complex picture emerging for papillomavirus DNA replication control.

Effects of mutations within two hydrophilic regions of the bovine papillomavirus type 1 E1 DNA-binding domain on E1-E2 interaction

The interaction between papillomavirus E1 and E2 proteins is essential for viral genome replication. Using both in vivo and in vitro assays to evaluate the regions of the two proteins necessary for the E1-E2 interaction, three independent interactions were identified for bovine papillomavirus E1: the N terminus of E1 (E1N, residues 1-311) interacts with the E2 transactivation domain (E2TAD) and the E2 DNA-binding domain (E2DBD) and the C terminus of E1 (E1C, residues 315-605) interacts with E2. Nine mutations within E1N were evaluated for their effects on E2 interaction. Five mutations eliminated interaction with the E2TAD; four of these were located within two previously identified conserved, hydrophilic regions, HR1 and HR3. Since HR1 and HR3 residues appear to comprise the origin of replication recognition element for E1, simultaneous interaction with the E2TAD during initiation complex formation would seem unlikely. Consistent with this inference is the fact that three of the five mutants defective for E2TAD binding exhibited wild-type levels of replication. The replication-positive phenotype of these mutants suggests that the E1N-E2TAD interaction is not essential for replication function and is probably involved in some other E1-E2 function, such as regulating transcription. Only one of the five mutations defective for E2TAD binding also prevented E2DBD interaction, indicating that the regions of E1N that interact with the E2TAD and the E2DBD are not identical. The ability of E1N to cooperatively interact with E2 bound to E2-binding site (E2BS) 11 versus E2BS12 was also examined, and cooperative binding was only observed when E2 was bound to E2BS12.

Regulation of human papillomavirus type 1 replication by the viral E2 protein

The E1 and E2 proteins encoded by papillomaviruses are required for viral replication. Earlier studies have shown that the viral E2 protein plays an important role in replication by targeting the E1 helicase to the origin of replication (ori). We have previously shown that the E1 protein of human papillomavirus (HPV) type 1 is sufficient for the in vivo replication of ori plasmids, although the E2 protein stimulates replication. In this study, we have further analyzed the role of the E2 protein in HPV-1 replication. The optimal ori of HPV-1 contains one putative E1 binding site (E1BS) and two putative E2 binding sites, E2BS-3 and E2BS-4. Plasmid pori171, containing the optimal ori, replicates to much higher levels than plasmid pori312, which includes an additional upstream E2 binding site, E2BS-2, located 75 nucleotides upstream of E2BS-3. To study the possible role of E2BS-2 and other upstream sequences in E2-dependent downregulation of replication, transient replication analysis was done in the presence of increasing levels of the E2 protein. Interestingly, inhibition of pori312 replication was more severe at higher levels of E2, suggesting that this protein may also negatively regulate HPV-1 replication. Deletion of sequences from pori312 containing an additional putative E2BS, E2BS-2A, relieved the repression of replication to a significant extent, while replacement of E2BS-2 with a different sequence of the same length had a modest effect. These results suggest that E2BS-2A plays a major and E2BS-2 a minor role in the negative regulation of HPV-1 replication at high E2 levels. Electrophoretic mobility-shift assays showed that the purified E2 protein bound with high affinity to E2BS-3 and weakly to the other putative E2BSs located within the viral long control region. EMSA using various ori fragments showed the formation of multiple E2-DNA complexes which likely represent binding of E2 to multiple E2BSs present within the HPV-1 ori. Our data are consistent with the assembly of ori-protein complexes at high E2 levels that are impaired for replication and further suggest that E2 may regulate HPV-1 replication by a mechanism involving interaction between the E2 protein bound to E2BSs at a distance.

Characterization of recombinant HPV6 and 11 E1 helicases: effect of ATP on the interaction of E1 with E2 and mapping of a minimal helicase domain

To better characterize the enzymatic activities required for human papillomavirus (HPV) DNA replication, the E1 helicases of HPV types 6 and 11 were produced using a baculovirus expression system. The purified wild type proteins and a version of HPV11 E1 lacking the N-terminal 71 amino acids, which was better expressed, were found to be hexameric over a wide range of concentrations and to have helicase and ATPase activities with relatively low values for K(m)(ATP) of 12 microm for HPV6 E1 and 6 microm for HPV11 E1. Interestingly, the value of K(m)(ATP) was increased 7-fold in the presence of the E2 transactivation domain. In turn, ATP was found to perturb the co-operative binding of E1 and E2 to DNA. Mutant and truncated versions of in vitro translated E1 were used to identify a minimal ATPase domain composed of the C-terminal 297 amino acids. This fragment was expressed, purified, and found to be fully active in ATP hydrolysis, single-stranded DNA binding, and unwinding assays, despite lacking the minimal origin-binding domain.

Structure and function of hexameric helicases

Helicases are motor proteins that couple the hydrolysis of nucleoside triphosphate (NTPase) to nucleic acid unwinding. The hexameric helicases have a characteristic ring-shaped structure, and all, except the eukaryotic minichromosomal maintenance (MCM) helicase, are homohexamers. Most of the 12 known hexameric helicases play a role in DNA replication, recombination, and transcription. A human genetic disorder, Bloom's syndrome, is associated with a defect in one member of the class of hexameric helicases. Significant progress has been made in understanding the biochemical properties, structures, and interactions of these helicases with DNA and nucleotides. Cooperativity in nucleotide binding was observed in many, and sequential NTPase catalysis has been observed in two proteins, gp4 of bacteriophage T7 and rho of Escherichia coli. The crystal structures of the oligomeric T7 gp4 helicase and the hexamer of RepA helicase show structural features that substantiate the observed cooperativity, and both are consistent with nucleotide binding at the subunit interface. Models are presented that show how sequential NTP hydrolysis can lead to unidirectional and processive translocation. Possible unwinding mechanisms based on the DNA exclusion model are proposed here, termed the wedge, torsional, and helix-destabilizing models.

SUMO-1 modification of bovine papillomavirus E1 protein is required for intranuclear accumulation

The E1 protein is a multifunctional, origin-binding helicase that is essential for replication of papillomaviruses. Recently, bovine papillomavirus E1 was shown to be post-translationally modified by the addition of the SUMO-1 polypeptide. Here we show that the site of sumoylation maps to lysine residue 514. This lysine and the flanking sequences are well conserved in human papillomavirus (HPV) E1 proteins. Both HPV1a and HPV18 E1 proteins are substrates for sumoylation in vitro, which is consistent with this modification being a general property of E1 proteins. Mutations, which impair the sumoylation of bovine papillomavirus E1, prevent normal nuclear accumulation of E1 with a concomitant loss of replication capacity. These results suggest that sumoylation plays a role in nuclear transport and could regulate the E1 replication function by controlling access to the nuclear replication domains.

Adeno-associated virus type 2 rep protein inhibits human papillomavirus type 16 E2 recruitment of the transcriptional coactivator p300

Infection by human adeno-associated virus type 2 (AAV2) is a possible protective factor in the development of cervical carcinomas associated with human papillomaviruses (HPV). The replicative proteins of AAV2 (Rep) have been implicated in the inhibition of papillomavirus replication and transforming activities, although the molecular events underlying these effects are poorly understood. We observed that each of the four forms of AAV2 Rep inhibited the E1- and E2-driven replication of oncogenic HPV type 16 (HPV16). Rep40, corresponding to the C-terminal domain of all Rep proteins, inhibited both HPV DNA replication and HPV16 E2-mediated transactivation. Rep40 specifically bound the N-terminal transactivation domain of HPV16 E2 both in vitro and in vivo. This interaction was found to specifically disrupt the binding of E2 to the cellular transcriptional coactivator p300. Accordingly, the inhibitory effect of Rep on HPV16 E2 transactivation was rescued by the overexpression of p300. These data indicate a novel role of Rep in the down-regulation of papillomaviruses through inhibition of complex formation between the HPV16 E2 transcriptional activator and its cellular coactivator, p300.

Bovine papillomavirus E1 protein is sumoylated by the host cell Ubc9 protein

Papillomavirus E1 protein is the replication initiator that recognizes and binds to the viral origin and initiates DNA strand separation through its ATP-dependent helicase activity. The E1 protein also functions in viral DNA replication by recruiting several cellular proteins to the origin, including host DNA polymerase alpha and replication protein A. To identify other cellular proteins that interact with bovine papillomavirus E1, an HeLa cDNA library was screened using a yeast two-hybrid assay. The host cell sumoylating enzyme, Ubc9, was found to interact specifically with E1 both in vitro and in vivo. Mapping studies localized critical E1 sequences for interaction to amino acids 315-459 and strongly implicated leucine 420 as critical for E1.Ubc9 complex formation. In addition to binding E1, Ubc9 catalyzed the covalent linkage of the ubiquitin-like protein, SUMO-1, to E1. An E1 mutant unable to bind Ubc9 showed normal intracellular stability, but was impaired for intranuclear distribution. Failure to accumulate in appropriate nuclear subdomains may account for the previously demonstrated replication defect of a human papillomavirus 16 E1 protein that was also unable to bind Ubc9 and suggests that sumoylation is a functionally important modification with regulatory implications for papillomavirus replication.

Contribution of bovine papillomavirus type 1 E1 protein residue 48 to replication function

The E1 protein of bovine papillomavirus type 1 (BPV-1) is the origin recognition protein and is essential for the initiation of viral DNA replication. We reported previously that there is a conserved motif between residues 25 and 60 of all papillomavirus E1 proteins that resembles a casein kinase II (CKII) phosphorylation site. The corresponding serine in BPV-1, serine-48, is an efficient substrate for CKII in vitro. To examine the functional role of this potential phosphorylation site, three amino acid substitutions were constructed at serine-48. Conversion of serine-48 to a glycine (S48G) resulted in a BPV-1 genome that was unable to replicate and had reduced transformation capacity. The S48G E1 protein also failed to support replication of a BPV-1 origin-containing plasmid when expressed from a heterologous vector rather than the viral genome, indicating a direct replication defect. In contrast, conversion of serine-48 to acidic residues (S48D or S48E), which mimic the charge and structure of phosphoserine, maintained the wild-type replication phenotype. These mutational results are consistent with a replication requirement for a negative charge at serine-48, presumably supplied by in vivo phosphorylation. The mechanistic basis for the negative charge requirement was examined by testing several activities of the S48G mutant E1 protein in vivo using yeast one- and two-hybrid systems. No gross defect was observed for stability, origin binding or interaction with E2 or for E1-E1 interaction, although subtle defects in these activities would not likely be detected. Overall, the results suggest that important phosphoregulatory control of E1 replication function is mediated through the N-terminal region of this protein.

A ring-opening mechanism for DNA binding in the central channel of the T7 helicase-primase protein

We have investigated the mechanism of binding single-stranded DNA (ssDNA) into the central channel of the ring-shaped T7 gp4A' helicase-primase hexamer. Presteady-state kinetic studies show a facilitated five-step mechanism and provide understanding of how a ring-shaped helicase can be loaded on the DNA during the initiation of replication. The effect of a primase recognition sequence on the observed kinetics suggests that binding to the helicase DNA-binding site is facilitated by transient binding to the primase DNA-binding site, which is proposed to be a loading site. The proposed model involves the fast initial binding of the DNA to the primase site on the outside of the helicase ring, a fast conformational change, a ring-opening step, migration of the DNA into the central channel of the helicase ring, and ring closure. Although an intermediate protein-DNA complex is kinetically stable, only the last species in the five-step mechanism is poised to function as a helicase at the unwinding junction.

The E1 helicase of human papillomavirus type 11 binds to the origin of replication with low sequence specificity

Expression of the human papillomavirus type 11 E1 and E2 genes is necessary and sufficient to support viral DNA replication. The full-length E2 protein is a transcriptional modulator that also interacts with the E1 helicase to form an E1/E2 complex at the viral origin of replication. Previous studies indicated that efficient binding of this complex to the replication origin is site-specific and that the E2 homodimer was required for efficient E1 binding. Human papillomavirus type 11 E2 and E1 proteins have been purified and their cooperative binding to the HPV type 11 viral replication origin has been characterized. Low-affinity E1 binding to the HPV type 11 replication origin was demonstrated and found to be largely nonspecific. DNA binding by E1 does not require complex formation with E2 and appears to be independent of ATP binding or hydrolysis. E1 binding quantitatively increased with the addition of increasing amounts of E2 and mutations in the E2 binding site demonstrated that the E2BS site is required for E1 and E2 to specifically bind as a high-affinity complex at the replication origin. Analysis of the A/T-rich E1 binding site via mutation showed that it was nonessential for high-affinity E1/E2 complex formation. Thus, although the replication functions between the animal and the human papillomaviruses are well conserved, there are subtle differences in the DNA binding requirements for E1, which may portend mechanistic differences among the DNA replication systems of various papillomavirus types.

Interaction of the papillomavirus E2 protein with mitotic chromosomes

The bovine papillomavirus E2 transactivator protein is a multifunctional protein that activates viral transcription, cooperates in initiation of viral DNA replication, and is required for long-term episomal maintenance of viral genomes. We have shown previously that the E2 transactivator protein and bovine papillomavirus type 1 genomes are associated with mitotic chromosomes and have proposed that E2 links the genomes to cellular chromosomes to ensure segregation to daughter nuclei. In this study, we show that E2 is associated with cellular chromosomes at all stages of mitosis. We also further map the regions of E2 that are required for this association. The transactivation domain of E2 is necessary and sufficient to mediate the interaction with mitotic chromosomes; the DNA binding domain, and the flexible hinge region that separates the two domains, is not required. Furthermore, mutation of previously identified phosphorylation sites (serine residues 235, 298, and 301) has no effect on the ability of the E2 protein to bind mitotic chromosomes.

Identification of a short, hydrophilic amino acid sequence critical for origin recognition by the bovine papillomavirus E1 protein

The E1 protein of bovine papillomavirus (BPV) is a site-specific DNA binding protein that recognizes an 18-bp inverted repeat element in the viral origin of replication. Sequence-specific DNA binding function maps to the region from approximately amino acids 140 to 300, and isolated polypeptides containing this region have been shown to retain origin binding in vitro. To investigate the sequence and structural characteristics which contribute to sequence-specific binding, the primary sequence of this region was examined for conserved features. The BPV E1 DNA binding domain (E1DBD) contains three major hydrophilic domains (HR1, amino acids 179-191; HR2, amino acids 218 to 230; and HR3, amino acids 241 to 252), of which only HR1 and HR3 are conserved among papillomavirus E1 proteins. E1DBD proteins with lysine-to-alanine mutations in HR1 and HR3 were severely impaired for DNA binding function in vitro, while a lysine-to-alanine mutation in HR2 had a minimal effect on DNA binding. Mutation of adjacent threonine residues in HR1 (T187 and T188) revealed that these two amino acids made drastically different contributions to DNA binding, with the T187 mutant being severely defective for origin binding whereas the T188 mutant was only mildly affected. Helical wheel projections of HR1 predict that T187 is on the same helical face as the critical lysine residues whereas T188 is on the opposing face, which is consistent with their respective contributions to DNA binding activity. To examine E1 binding in vivo, a yeast one-hybrid system was developed. Both full-length E1 and the E1DBD polypeptide were capable of specifically interacting with the E1 binding site in the context of the yeast genome, and HR1 was also critical for this in vivo interaction. Overall, our results indicate that HR1 is essential for origin binding by E1, and the features and properties of HR1 suggest that it may be part of a recognition sequence that mediates specific E1-nucleotide contacts.

Role of the ATP-binding domain of the human papillomavirus type 11 E1 helicase in E2-dependent binding to the origin

Replication of the genome of human papillomaviruses (HPV) is initiated by the recruitment of the viral E1 helicase to the origin of DNA replication by the viral E2 protein, which binds specifically to the origin. We determined, for HPV type 11 (HPV-11), that the C-terminal 296 amino acids of E1 are sufficient for interaction with the transactivation domain of E2 in the yeast two-hybrid system and in vitro. This region of E1 encompasses the ATP-binding domain. Here we have examined the role of this ATP-binding domain, and of ATP, on E2-dependent binding of E1 to the origin. Several amino acid substitutions in the phosphate-binding loop (P loop), which is implicated in binding the triphosphate moiety of ATP, abolished E2 binding, indicating that the structural integrity of this domain is essential for the interaction. The structural constraints imposed on the E1 P loop may differ between HPV-11 and bovine papillomavirus type 1 (BPV-1), since the P479S substitution that inactivates BPV-1 E1 is tolerated in the HPV-11 enzyme. Other substitutions in the E1 P loop, or in two other conserved motifs of the ATP-binding domain, were tolerated, indicating that ATP binding is not essential for interaction with E2. Nevertheless, ATP-Mg stimulated the E2-dependent binding of E1 to the origin in vitro. This stimulation was maximal at the physiological temperature (37 degrees C) and did not require ATP hydrolysis. In contrast, ATP-Mg did not stimulate the E2-dependent binding to the origin of an E1 protein containing only the C-terminal domain (353 to 649) or that of mutant E1 proteins with alterations in the DNA-binding domain. These results are discussed in light of a model in which the E1 ATP-binding domain is required for formation of the E2-binding surface and can, upon the binding of ATP, facilitate and/or stabilize the interaction of E1 with the origin.

DNA replication specificity and functional E2 interaction of the E1 proteins of human papillomavirus types 1a and 18 are determined by their carboxyl-terminal halves

Replication of most papillomaviruses (PVs) requires the viral-encoded E1 and E2 proteins that bind to the origin of replication (ori) containing the E1- and E2-binding sites and help recruit host replication factors during the initiation of DNA replication. We studied the ability of heterologous E1 and E2 proteins to interact in vivo and support replication, using the human papillomavirus (HPV) types 1a and 18 as model systems. The E1 protein of HPV-1a in combination with HPV-18 E2 supported high-level replication of various ori plasmids. In contrast, the HPV-18 E1 protein interacted weakly with HPV-1a E2 during the replication of ori plasmids. We have previously shown that the E1 protein of HPV-1a alone is sufficient for replication of HPV-1a ori plasmids, whereas HPV-18 replication requires both the E1 and E2 proteins. However, in the latter case, E2-binding sites alone in the absence of the E1-binding site can function as the minimal ori. Based on the above observations, we generated hybrids between HPV-1a and HPV-18 E1 proteins in an effort to identify their "replication specificity" domains using a transient replication assay. These hybrids were also used to localize the domains in the E1 proteins that are involved in their functional interaction with the E2 protein during replication. Our results suggest that the "replication specificity" and functional E2 interaction domains of the HPV-1a and HPV-18 E1 proteins are located in their carboxyl-terminal halves.

Human papillomavirus DNA replication compartments in a transient DNA replication system

Many DNA viruses replicate their genomes at nuclear foci in infected cells. Using indirect immunofluorescence in combination with fluorescence in situ hybridization, we colocalized the human papillomavirus (HPV) replicating proteins E1 and E2 and the replicating origin-containing plasmid to nuclear foci in transiently transfected cells. The host replication protein A (RP-A) was also colocalized to these foci. These nuclear structures were identified as active sites of viral DNA synthesis by bromodeoxyuridine (BrdU) pulse-labeling. Unexpectedly, the great majority of RP-A and BrdU incorporation was found in these HPV replication domains. Furthermore, E1, E2, and RP-A were also colocalized to nuclear foci in the absence of an origin-containing plasmid. These observations suggest a spatial reorganization of the host DNA replication machinery upon HPV DNA replication or E1 and E2 expression. Alternatively, viral DNA replication might be targeted to host nuclear domains that are active during the late S phase, when such domains are limited in number. In a fraction of cells expressing E1 and E2, the promyelocytic leukemia protein, a component of nuclear domain 10 (ND10), was either partially or completely colocalized with E1 and E2. Since ND10 structures were recently hypothesized to be sites of bovine papillomavirus virion assembly, our observation suggests that HPV DNA amplification might be partially coupled to virion assembly.

Human papillomavirus DNA replication. Interactions between the viral E1 protein and two subunits of human dna polymerase alpha/primase

Papovaviruses are valuable models for the study of DNA replication in higher eukaryotic organisms, as they depend on host factors for replication of their DNA. In this study we investigate the interactions between the human papillomavirus type 11 (HPV-11) origin recognition and initiator protein E1 and human polymerase alpha/primase (pol alpha/primase) subunits. By using a variety of physical assays, we show that both 180- (p180) and 70-kDa (p70) subunits of pol alpha/primase interact with HPV-11 E1. The interactions of E1 with p180 and p70 are functionally different in cell-free replication of an HPV-11 origin-containing plasmid. Exogenously added p180 inhibits both E2-dependent and E2-independent cell-free replication of HPV-11, whereas p70 inhibits E2-dependent but stimulates E2-independent replication. Our experiments indicate that p70 does not physically interact with E2 and suggest that it may compete with E2 for binding to E1. A model of how E2 and p70 sequentially interact with E1 during initiation of viral DNA replication is proposed.

A fifteen-amino-acid peptide inhibits human papillomavirus E1-E2 interaction and human papillomavirus DNA replication in vitro

Mutation of the conserved glutamic acid residue at position 39 of human papillomavirus type 16 (HPV-16) E2 to alanine (E39A) disrupts its E1 interaction activity and its replication function in transient replication assays but does not affect E2 transcriptional activation. This E39A mutation also disrupts replication activity of HPV-16 E2 in HPV-16 in vitro DNA replication. On this basis, we designed 23- and 15-amino-acid peptides derived from HPV-16 E2 sequences flanking the E39 residue and tested the ability of these peptides to inhibit interaction between HPV-16 E1 and E2 in vitro. The inhibitory activity of these peptides was specific, since analogous peptides in which alanine was substituted for the E39 residue did not inhibit interaction. The 15-amino-acid peptide E2N-WP15 was the smallest peptide tested that effectively inhibited HPV-16 E1-E2 interaction. This peptide also inhibited in vitro replication of HPV-16 DNA. The efficacy of E2N-WP15 was not exclusive to HPV-16: this peptide also inhibited interaction of HPV-11 E1 with the E2 proteins of both HPV-11 and HPV-16 and inhibited in vitro replication with these same combinations of E1 and E2 proteins. These results provide further evidence that E1-E2 interaction is required for papillomavirus DNA replication and constitute the first demonstration that inhibition of this interaction is sufficient to prevent HPV DNA replication in vitro.

The papillomavirus E1 protein forms a DNA-dependent hexameric complex with ATPase and DNA helicase activities

The E1 protein from bovine papillomavirus has site-specific DNA binding activity, DNA helicase activity, and DNA-dependent ATPase activity consistent with the properties of an initiator protein. Here we have identified and characterized a novel oligomeric form of E1 that is associated with the ATPase and DNA helicase activities and whose formation is strongly stimulated by single-stranded DNA. This oligomeric form corresponds to a hexamer of E1.

Transcription factor YY1 represses cell-free replication from human papillomavirus origins

We have established cell-free replication for the human papillomavirus type 18 (HPV-18) origin of replication (ori)-containing DNA by using purified HPV-18 E1 and E2 gene products expressed as fusion proteins in Escherichia coli. The transcription factor YY1 has been shown to regulate RNA transcription by binding to a sequence overlapping the putative E1 protein binding site in the HPV-18 ori. We show that exogenously added YY1 fusion protein inhibited HPV-18 ori replication. Cotransfection of YY1 expression vectors also inhibited transient replication in 293 cells. However, inhibition did not appear to be mediated by binding to its cognate site in the ori as YY1 also inhibited the replication of the HPV-11 ori, which does not have a known or suspected YY1 binding site. Moreover, inhibition was not alleviated by the inclusion of YY1 binding oligonucleotides in the replication reaction mixtures. Rather, we demonstrated a direct interaction between purified fusion E2 protein and fusion YY1 protein by the pull-down assay and a partial restoration of replication activity by an elevated E2 protein concentration. These results suggest that YY1 can inhibit HPV ori replication by interfering with E2 protein functions.

Characterization of the DNA-binding domain of the bovine papillomavirus replication initiator E1

The bovine papillomavirus replication initiator protein E1 is an origin of replication (ori)-binding protein absolutely required for viral DNA replication. In the presence of the viral transcription factor E2, E1 binds to the ori and initiates DNA replication. To understand how the E1 initiator recognizes the ori and how E2 assists in this process, we have expressed and purified a 166-amino-acid fragment which corresponds to the minimal E1 DNA-binding domain (DBD). DNA binding studies using this protein demonstrate that the E1 DBD can bind to the palindromic E1 binding site in several forms but that binding of two monomers, each recognizing one half-site of the E1 palindrome, is the predominant form. This is reminiscent of the binding of the T-antigen DBD to the SV40 ori, and interestingly, the arrangement of E1 binding sites shows striking similarities to the arrangement of T-antigen binding sites in the SV40 ori even though the recognition sequences are unrelated. The E1 DBD is capable of interacting cooperatively with E2; however, the E2 DBD and not the E2 activation domain mediates this interaction. Furthermore, the E2 DBD stimulates binding of two monomers of the E1 DBD to the ori by binding cooperatively with one E1 monomer. Finally, we show that our results concerning the DNA-binding properties of the E1 DBD can be extended to full-length E1.

Identification of single amino acids in the human papillomavirus 11 E2 protein critical for the transactivation or replication functions

The papillomavirus E2 protein is required for viral transcriptional regulation and replication. The E2 protein has a modular structure with two highly conserved domains, a sequence-specific DNA-binding and dimerization domain and a conserved N-terminus which is important for transcriptional transactivation, replication, and interaction with the E1 protein to determine which specific amino acids or regions in the N-terminus were important for the replication or transactivation functions. Single amino acid substitutions were created at highly conserved, highly charged amino acids in the HPV 11 E2 N-terminus. Each amino acid was mutated to a nonpolar alanine residue or a similarly charged amino acid. The mutated E2 proteins were analyzed for their abilities to support transcriptional transactivation and transient DNA replication and to enhance binding of E1 to the origin of replication. Single amino acid substitutions were identified which were defective for either the replication or transactivation functions, which demonstrated that the replication and transactivation functions within the N-terminus are separable. In several cases different amino acid substitutions at the same site had variable effects on transcription or replication, highlighting the importance of hydrophobic interactions or side chain structure at each site. The replication function appeared to correlate with the ability of E2 to enhance binding of E1 to the origin of replication though these studies also suggest that other functions performed by the E2 protein may be important for replication.

Initiation of DNA replication at palindromic telomeres is mediated by a duplex-to-hairpin transition induced by the minute virus of mice nonstructural protein NS1

The linear single-stranded DNA genome of the minute virus of mice (MVM) is replicated via a double-stranded replicative form (RF) intermediate. Amplification of this RF is initiated by the folding-back of palindromic sequences serving as primers for strand-displacement synthesis and formation of dimeric RF DNA. Using an in vitro replication assay and a cloned MVM DNA template, we observed hairpin-primed DNA replication at both MVM DNA termini, with a bias toward right-end initiation. Initiation of DNA replication is favored by nuclear components of A9 cell extract and highly stimulated by the MVM nonstructural protein NS1. Hairpin-primed DNA replication is also observed in the presence of NS1 and the Klenow fragment of the Escherichia coli DNA polymerase I. Addition of ATPgammaS (adenosine 5'-O-(thiotriphosphate)) blocks the initiation of DNA replication but not the extension of pre-existing hairpin primers formed in the presence of NS1 only. The NS1-mediated unwinding of the right-end palindrome may account for the recently reported capacity of NS1 for driving dimer RF synthesis in vitro.

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.

The papillomavirus minor capsid protein, L2, induces localization of the major capsid protein, L1, and the viral transcription/replication protein, E2, to PML oncogenic domains

We have used immunofluorescent staining and confocal microscopy to examine the subcellular localization of structural and nonstructural bovine papillomavirus (BPV) proteins in cultured cells that produce infectious virions. When expressed separately, L1, the major capsid protein, showed a diffuse nuclear distribution while L2, the minor capsid protein, was found to localize to punctate nuclear regions identified as promonocytic leukemia protein (PML) oncogenic domains (PODs). Coexpression of L1 and L2 induced a relocation of L1 into the PODs, leading to the colocalization of L1 and L2. The effect of L2 expression on the distribution of the nonstructural viral proteins E1 and E2, which are required for maintenance of the genome and viral DNA synthesis, was also examined. The localization of the E1 protein was unaffected by L2 expression. However, the pattern of anti-E2 staining was dramatically altered in L2-expressing cells. Similar to L1, E2 was shifted from a dispersed nuclear locality into the PODs and colocalized with L2. The recruitment of full-length E2 by L2 occurred in the absence of other viral components. L2 was shown previously to be essential for the generation of infectious BPV. Our present results provide evidence for a role for L2 in the organization of virion components by recruiting them to a distinct nuclear domain. This L2-dependent colocalization probably serves as a mechanism to promote the assembly of papillomaviruses either by increasing the local concentration of virion constituents or by providing the physical architecture necessary for efficient packaging and assembly. The data also suggest a role for a nonstructural viral protein, E2, in virion assembly, specifically the recruitment of the viral genome to the sites of assembly, through its high-affinity interaction with specific sequences in the viral DNA.

Bovine papillomavirus type 1 E1 and simian virus 40 large T antigen share regions of sequence similarity required for multiple functions

The full-length product of the bovine papillomavirus type 1 (BPV-1) E1 translational open reading frame is required for viral DNA replication in vivo and in vitro. E1 is a multifunctional protein whose properties include ATP binding, acting as an ATPase-dependent DNA helicase, DNA binding to the BPV-1 origin of viral DNA replication, and association with the E2 transcriptional transactivator, E2TA, a second viral protein involved in DNA replication. All of these properties are thought to be important for E1's role in replicating the viral genome. In addition BPV-1 E1 can inhibit activation of the viral P89 promoter by the BPV-1 E2TA. E1 has amino acid homology with eight regions of SV40 large tumor antigen (T-ag), a DNA helicase that is essential for the replication of the SV40 DNA genome. These eight regions of similarity lie within the domain of T-ag that confers DNA helicase activity. We created a series of missense mutations in BPV-1 E1 at codons 295, 344-345, 446, 464, 466, 497-498, 523, and 542, which encode amino acids of identity in seven of the eight regions of similarity between E1 and T-ag, and at codon 370. The activities of these mutant E1 genes were compared to wild-type E1 in multiple assays that measured DNA replication, inhibition of E2TA-dependent transcription, DNA binding, ATP binding, and protein expression. Based upon these analyses, the following conclusions were made: (i) at least five of the eight regions in E1 that are similar to regions in T-ag are functionally important in viral DNA replication; (ii) specific E1 missense mutants, themselves defective for supporting DNA replication, could act in trans to suppress the replication function of wild-type E1; (iii) certain regions of similarity with T-ag that are important for E1's ability to support DNA replication are not necessary for its capacity to inhibit E2TA-dependent transcription; and (iv) efficient DNA binding by E1 is not essential for E1 to inhibit E2TA-dependent transcription.

Bovine papillomavirus type 1 DNA replication: the transcriptional activator E2 acts in vitro as a specificity factor

We previously devised cell-free conditions supporting efficient replication of bovine papillomavirus type 1 (BPV1) DNA (C. Bonne-Andréa, S. Santucci, and P. Clertant, J. Virol. 69:3201-3205, 1995): the use of highly active preparations of viral initiator protein E1, together with extract from a particular cell source, allowed the synthesis of complete DNA circles through successive rounds of replication; this occurred in the absence of the viral transcriptional activator E2, required in vivo for the replication of viral genomes. We now report that adding E2 to cell-free assays produced only slight effects both on the yield of E1-dependent DNA synthesis and on the quality of newly made DNA molecules when a template carrying a wild-type BPV1 replication origin (ori) was used. The performance of mouse cell extracts, unable to sustain efficient BPV1 DNA replication in the presence of E1 only, was likewise not improved by the addition of E2. In a proper in vitro environment, E1 is thus fully capable of efficiently initiating viral DNA synthesis by itself, an activity which is not enhanced by interaction with E2. An important effect, however, was detected: E2 totally suppressed the nonspecific replication of ori-defective DNA templates, otherwise observed in high E1 concentrations. We examined the requirements for building a minimal DNA sequence behaving in vitro as a specific ori sequence under stringent recognition conditions, i.e., in the presence of both E1 and E2. Only two elements, the 18-bp E1 binding palindrome and an AT-rich sequence, were required in cis to allow specific cell-free DNA replication; there seemed to be no need for an E2 binding site to ensure discrimination between specific ori templates and other DNA molecules, even in the presence of E2. This suggests that during the initiation of BPV1 DNA replication, at least in vitro, E2 acts as a specificity factor restricting the action of E1 to a defined ori sequence; this function, likely not demanding the direct binding of E2 to cognate DNA sites, might primarily involve protein-protein interactions.

Functional interactions between papillomavirus E1 and E2 proteins

DNA replication of papillomaviruses requires the viral E1 and E2 proteins. These proteins bind cooperatively to the viral origin of replication (ori), which contains binding sites for both proteins, forming an E1-E2-ori complex which is essential for initiation of DNA replication. To map the domains in E2 that are involved in the interaction with E1, we have used chimeric bovine papillomavirus (BPV)/human papillomavirus type 11 (HPV-11) E2 proteins. The results from this study show that both the DNA binding domain and the transactivation domain from BPV E2 independently can interact with BPV E1. However, the roles of these two interactions are different: the interaction between E1 and the activation domain of E2 is necessary and sufficient for cooperativity in binding and for DNA replication; the interaction between E1 and the DNA binding domain of E2 is required only when the binding sites for E1 and E2 are adjacent to each other, and the function of this interaction appears to be to facilitate the interaction between E1 and the transactivation domain of E2. These results indicate that the cooperative binding of E1 and E2 to the BPV ori takes place via a novel two-stage mechanism where one interaction serves as a trigger for the formation of the second, productive, interaction between the two proteins.

Binding of the E1 and E2 proteins to the origin of replication of bovine papillomavirus

DNA replication of bovine papillomavirus (BPV) requires two viral proteins encoded from the E1 and E2 open reading frames. E1 and E2 are sequence-specific DNA binding proteins that bind to their cognate binding sites in the BPV origin of replication (ori). The E1 and E2 proteins can interact physically with each other, and this interaction results in cooperative binding when binding sites for both proteins are present. We have analyzed the binding of E1 to the ori in the absence and presence of E2, using DNase I footprint analysis, gel mobility shift assays, and interference analysis. We have also generated a large number of point mutations in the E1 binding site and tested them for binding of E1 as well as for activity in DNA replication. Our results demonstrate that E1 binds to the ori in different forms in the absence and presence of E2 and that E2 has both a quantitative and a qualitative effect on the binding of E1. Our results also suggest that the ori contains multiple overlapping individual E1 recognition sequences which together constitute the E1 binding site and that different subsets of these recognition sequences are used for binding of E1 in the presence and absence of E2.

Modulation of bovine papillomavirus DNA replication by phosphorylation of the viral E1 protein

E1 is the DNA replication origin recognition protein for bovine papillomavirus (BPV), and it carries out enzymatic functions required for initiation of viral DNA replication. Cellular mechanisms likely play a role in regulating BPV DNA replication. We are investigating the role of phosphorylation of E1 on viral replication in vivo and on E1 activity in vitro. Serine 109 is a phosphoacceptor in vivo and is targeted by protein kinase A and protein kinase C in vitro. A viral genome carrying a serine 109 to alanine mutation replicates more efficiently than wild-type in vivo in a transient replication assay. Furthermore, purified mutant protein, while having wild-type levels of ATPase activity, is able to bind more origin-containing DNA than wild-type E1. Phosphorylation therefore appears to play a selective role in modulating a specific E1 function during viral DNA replication.

Mapping and characterization of the interaction domains of human papillomavirus type 16 E1 and E2 proteins

The papillomavirus E1 and E2 proteins are both necessary and sufficient in vivo for efficient origin-dependent viral DNA replication. The ability of E1 and E2 to complex with each other appears to be essential for efficient viral DNA replication. In this study, we used the yeast two-hybrid system and in vitro binding assays to map the domains of the human papillomavirus type 16 (HPV16) E1 and E2 proteins required for complex formation. The amino-terminal 190-amino-acid domain of HPV16 E2 was both required and sufficient for E1 binding. The carboxyl-terminal 229 amino acids of E 1 were essential for binding E2, and the amino-terminal 143 amino acids of HPV16 E1 were dispensable. Although the ability of the E1 minimal domain (amino acids [aa] 421 to 649) to interact with E2 was strong at 4 degrees C, it was significantly reduced at temperatures above 25 degrees C. A larger domain of E1 from aa 144 to 649 bound E2 efficiently at any temperature, suggesting that aa 144 to 420 of E1 may play a role in the HPV16 E1-E2 interaction at physiological temperatures.

Isolation of an amino-terminal region of bovine papillomavirus type 1 E1 protein that retains origin binding and E2 interaction capacity

In vitro DNA binding results from a series of E1 proteins containing amino-terminal or carboxy-terminal truncations indicated that sequences between amino acids 121 and 284 were critical for origin binding. Additional binding experiments with E1 proteins containing internal, in-frame insertions or deletions confirmed the importance of the region defined by truncated E1 proteins and also demonstrated that downstream sequences were not required for binding activity in the context of the full-length E1 protein. On the basis of mapping results from the E1 mutants, a clone (pE1(121-311)) was constructed that expressed E1 amino acids within the approximate boundaries of the critical sequences for DNA binding. The E1(121-311) protein retained origin-specific DNA binding, confirming that this region was not only necessary but was also sufficient for origin recognition. In addition to origin binding, E1(121-311) bound E2 protein in a cold-sensitive manner. Therefore, DNA binding and E2 binding activities colocalize to a 191-amino-acid functional domain derived from the amino-terminal half of the E1 protein. Finally, three E1 proteins with mutations in this region all lacked DNA binding activity and were all defective for in vivo replication. Two of these E1 mutants retained E2 binding capability, demonstrating that origin recognition by E1 is critical for replication and cannot necessarily be rescued by an interaction with E2 protein.

The genetic program of genital human papillomaviruses in infection and cancer

Human papillomavirus (HPV) infection has been recognized as the major cause of cervical cancer. This article summarizes the functions of HPV gene products that cause abnormal cell growth--E6 and E7--and reviews how cellular and viral factors influence their synthesis. E6 and E7 inactivate two cellular tumor-suppressor gene products, p53 and RB. In cervical cancer, E6-E7 gene control is deranged by mutations in viral control sequences and in integrated HPV fragments by the disruption of the viral repressor E2. Elimination of this sequence makes E6-E7 mRNAs unstable, and deranges cellular regulation at the integration site. It is apparent that an intricate interplay of cellular and viral factors determines whether the outcome is active papillomavirus infection, viral latency, or ultimately, genital cancer.

The initiator protein E1 binds to the bovine papillomavirus origin of replication as a trimeric ring-like structure

The replication initiator protein E1 binds to the origin of replication of bovine papillomavirus in several forms. E1 can bind to its recognition sequence as a monomer together with the viral transcription factor E2, or as a trimeric E1 complex. The trimerization of E1 is mediated by the sequence-specific binding of E1 to DNA, and results in an E1 complex that is linked topologically to the DNA because the three molecules of E1 form a ring-like structure that encircles the DNA. These results demonstrate that E1 utilizes unusual mechanisms for sequence-specific binding to DNA and for the generation of a structure that encircles the DNA. We believe that these forms of E1 bound to the origin of replication represent intermediates in a transition in the function of E1, from a sequence-specific origin of replication recognition protein to a form of E1 that is competent for the initiation of viral DNA replication.

Control of HPV 18 DNA replication by cellular and viral transcription factors

Papillomavirus replication in vivo requires the interaction of the virally encoded proteins E1 and E2 with the origin of replication which is localised in the regulatory region (long control region or LCR) of the viral genome. In genital human papillomaviruses (HPVs), the origin overlaps promoter elements of early transcription. In this study, we analysed the replication of HPV18 DNA using the complete LCR containing mutations in transcription regulatory elements. We found that each of the three E2 binding sites proximal to the AT-rich sequence of the origin contributes to the replication rate of DNA, although not identically. In addition, two sequences important for early transcription, an Sp1 binding site and the TATA box, were also found to play a role in replication. In contrast, two AP1 binding sites required for the enhancer-mediated activation of early transcription did not affect the replication, while other upstream sequences in the LCR did contribute to the replication efficiency. Our results indicate that besides a core origin of replication containing an AT-rich sequence and three E2 binding sites, auxiliary elements affect HPV18 DNA replication in the context of the full length LCR, some of which are important for transcription.

The functions of human papillomavirus type 11 E1, E2, and E2C proteins in cell-free DNA replication

We examined the functions of human papillomavirus type 11 (HPV-11) E1 and E2 proteins purified from Sf9 cells infected with recombinant baculoviruses in cell-free HPV-11 origin (ori) replication. The E1 protein binds specifically to a wild type but not to a mutated sequence in the ori spanning nucleotide position 1. It also has a relatively strong affinity for nonspecific DNA. A neutralizing antiserum directed against the amino-terminal one-third of the E1 protein totally abolishes initiation and elongation, suggesting that it functions as an initiator and a helicase at the replication fork. An antiserum against the carboxyl-terminal portion of E1 protein abolished replication only when added prior to initiation. Thus this portion of E1 is hidden in the replication complexes. The HPV-11 E2 protein appears not to be essential for elongation, but it must be present in the preinitiation complex for the E1 protein to recruit host DNA replication machinery to the ori. E2 antiserum added after preincubation in the absence of the cell extracts totally abolished replication. An identical conclusion is also reached for the bovine papillomavirus type 1 E2 protein. Finally, the HPV-11 E2C protein lacking the transacting domain of the full-length E2 protein partially inhibits E2-dependent ori replication.

Mutational analysis of the 18-base-pair inverted repeat element at the bovine papillomavirus origin of replication: identification of critical sequences for E1 binding and in vivo replication

Replication of bovine papillomavirus requires two viral proteins, E1 and E2-TA. Previously we demonstrated that sequences within an imperfect 18-bp inverted repeat (IR) element were sufficient to confer specific binding of the E1 protein to the origin region (S. E. Holt, G. Schuller, and V. G. Wilson, J. Virol. 68:1094-1102, 1994). To identify critical nucleotides for E1 binding and origin function, a series of individual point mutations was constructed at each nucleotide position in the 18-bp IR. Binding of E1 to these point mutations established that both the position of the mutation and the specific nucleotide change were important for the E1-DNA interaction. Equivalent mutations from each half of the IR exhibited similar binding, suggesting that the halves were functionally symmetric for E1 interactions. Each of these mutations was evaluated also for origin function in vivo by a transient-replication assay. No single point mutation eliminated replication capacity completely, though many mutants were severely impaired, demonstrating an important functional contribution for the E1 binding site. Furthermore, E1 binding was not sufficient for replication, as several origin mutants bound E1 well in vitro but replicated poorly in vivo. This suggests that certain nucleotides within the 18-bp IR may be involved in postbinding events necessary for replication initiation. The results with the point mutations suggest that E1-E1 interactions are important for stable complex formation and also indicate that there is some flexibility with regard to formation of a functional E1 replication complex at the origin.