Replication of bovine papillomavirus type 1 origin-containing DNA in crude extracts and with purified proteins

DNA damage-induced phosphorylation of a replicative DNA helicase results in inhibition of DNA replication through attenuation of helicase function

A major function of the DNA damage responses (DDRs) that act during the replicative phase of the cell cycle is to inhibit initiation and elongation of DNA replication. It has been shown that DNA replication of the polyomavirus, SV40, is inhibited and its replication fork is slowed by cellular DDR responses. The inhibition of SV40 DNA replication is associated with enhanced DDR kinase phosphorylation of SV40 Large T-antigen (LT), the viral DNA helicase. Mass spectroscopy was used to identify a novel highly conserved DDR kinase site, T518, on LT. In cell-based assays expression of a phosphomimetic form of LT at T518 (T518D) resulted in dramatically decreased levels of SV40 DNA replication, but LT-dependent transcriptional activation was unaffected. Purified WT and LT T518D were analyzed in vitro. In concordance with the cell-based data, reactions using SV40 LT-T518D, but not T518A, showed dramatic inhibition of SV40 DNA replication. A myriad of LT protein-protein interactions and LT's biochemical functions were unaffected by the LT T518D mutation; however, LT's DNA helicase activity was dramatically decreased on long, but not very short, DNA templates. These results suggest that DDR phosphorylation at T518 inhibits SV40 DNA replication by suppressing LT helicase activity.

The human papillomavirus DNA helicase E1 binds, stimulates, and confers processivity to cellular DNA polymerase epsilon

The papillomavirus (PV) helicase protein E1 recruits components of the cellular DNA replication machinery to the PV replication fork, such as Replication Protein A (RPA), DNA polymerase α-primase (pol α) and topoisomerase I (topo I). Here we show that E1 binds to DNA polymerase ϵ (pol ϵ) and dramatically stimulates the DNA synthesis activity of pol ϵ. This stimulation of pol ϵ by E1 is highly specific and occurs even in the absence of the known pol ϵ cofactors Replication Factor C (RFC), Proliferating Cell Nuclear Antigen (PCNA) and RPA. This stimulation is due to an increase in the processivity of pol ϵ and occurs independently of pol ϵ’s replication cofactors. This increase in processivity is dependent on the ability of the E1 helicase to hydrolyze ATP, suggesting it is dependent on E1’s helicase action. In addition, RPA, thought to be vital for processive DNA synthesis by both pol ϵ and pol δ, was found to be dispensable for processive synthesis by pol ϵ in the presence of E1. Overall, E1 appears to be conferring processivity to pol ϵ by directly tethering pol ϵ to the DNA parental strand and towing ϵ behind the E1 helicase as the replication fork progresses; and thereby apparently obviating the need for RPA for leading strand synthesis. Thus far only pol α and pol δ have been implicated in the DNA replication of mammalian viruses; this is the first reported example of a virus recruiting pol ϵ. Furthermore, this demonstrates a unique capacity of a viral helicase having evolved to stimulate a cellular replicative DNA polymerase.

Computational investigation on effect of mutations in PCNA resulting in structural perturbations and inhibition of mismatch repair pathway

From bacteria to mammals, DNA mismatch repair (MMR) pathway plays an essential role in eliminating mismatched nucleotides and insertion-deletion mismatches during the process of DNA replication. Among many of the proteins which participate in the mismatch repair process, proliferating cell nuclear antigen (PCNA) remains the principal conductor at the replication fork. The pol30-201 and pol30-204 are the two mutated alleles which encode for C22Y and C81R mutant forms of PCNA proteins. We performed long term molecular dynamics (MD) simulations analysis (0.8 μs) to understand the dynamic behavior and alterations in the structure of wild type and mutated forms of PCNA at the atomic level. We observed changes in the structural characteristics like length, radius, rise per residue of alpha helices in both the mutated forms of PCNA. Apart from it, disfigurement of the charge distribution which effects binding with the dsDNA due to mutant C22Y and other structural perturbations were also seen in regions significant for the formation of a biologically active trimeric form of PCNA due to mutant C81R. Our analysis of native and mutated forms of PCNA provides an insight into the essential structural and functional features required for proper and well-coordinated DNA mismatch repair process and consequences of the mutation leading to an impaired process of MMR. These structural characteristics are fundamental for the MMR process and hence our analysis likely contributes to or presents the novel mechanism involved in the process of MMR.Communicated by Ramaswamy H. Sarma.

The E1 proteins

E1, an ATP-dependent DNA helicase, is the only enzyme encoded by papillomaviruses (PVs). It is essential for replication and amplification of the viral episome in the nucleus of infected cells. To do so, E1 assembles into a double-hexamer at the viral origin, unwinds DNA at the origin and ahead of the replication fork and interacts with cellular DNA replication factors. Biochemical and structural studies have revealed the assembly pathway of E1 at the origin and how the enzyme unwinds DNA using a spiral escalator mechanism. E1 is tightly regulated in vivo, in particular by post-translational modifications that restrict its accumulation in the nucleus. Here we review how different functional domains of E1 orchestrate viral DNA replication, with an emphasis on their interactions with substrate DNA, host DNA replication factors and modifying enzymes. These studies have made E1 one of the best characterized helicases and provided unique insights on how PVs usurp different host-cell machineries to replicate and amplify their genome in a tightly controlled manner.

Targeting human papillomavirus genome replication for antiviral drug discovery

Human papillomavirus (HPV) infections are a major human health problem; they are the cause of recurrent benign warts and of several cancers of the anogenital tract and head and neck region. Although there are two prophylactic HPV vaccines that could, if used universally, prevent as many as two-thirds of HPV-induced cancers, as well as several cytotoxic and immunomodulatory agents for localized treatment of infections, there are currently no HPV antiviral drugs in our arsenal of therapeutic agents. This review examines the status of past and ongoing research into the development of HPV antivirals, focused primarily upon approaches targeting the replication of the viral genome. The only HPV enzyme, E1, is a DNA helicase that interfaces with the cellular DNA replication machinery to replicate the HPV genome. To date, searches for small molecule inhibitors of E1 for use as antivirals have met with limited success. The lack of other viral enzymes has meant that the search for antivirals has shifted to a large degree to the modulation of protein-protein interactions. There has been some success in identifying small molecule inhibitors targeting interactions between HPV proteins but with activity against a small subset of viral types only. As noted in this review, it is thought that targeting E1 interactions with cellular replication proteins may provide inhibitors with broader activity against multiple HPV types. Herein, we outline the steps in HPV DNA replication and discuss those that appear to provide the most advantageous targets for the development of anti-HPV therapeutics.

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.

Interactions of the cellular CCAAT displacement protein and human papillomavirus E2 protein with the viral origin of replication can regulate DNA replication

Previously, we and others have shown that CCAAT displacement protein (CDP) negatively regulates the papillomavirus promoters. Overexpression of CDP has been shown to inhibit high-risk human papillomavirus virus (HPV) and bovine papillomavirus DNA replication in vivo presumably through reduction in expression of viral replication proteins, E1 and E2. Sequence analysis of the HPV origin indicates several potential CDP-binding sites with one site overlapping the E1-binding site. Therefore, CDP could also negatively regulate papillomavirus replication directly by preventing the loading of the initiation complex. We show here that purified CDP inhibits in vitro HPV DNA replication. Footprint analysis demonstrated that CDP binds the E1-binding site and the TATA box, and that the binding of purified CDP to the E1-binding site is decreased by the addition of purified E2 protein. Consistent with this, E2-independent in vitro HPV replication is inhibited by CDP to a greater extent than E2-dependent replication. These results suggest that binding of E2 at the E2-binding site may play an important role in overcoming the inhibition of E1 initiation complex formation caused by the binding of negative regulators like CDP to the origin of replication.

Recruitment of replication protein A by the papillomavirus E1 protein and modulation by single-stranded DNA

With the exception of viral proteins E1 and E2, papillomaviruses depend heavily on host replication machinery for replication of their viral genome. E1 and E2 are known to recruit many of the necessary cellular replication factors to the viral origin of replication. Previously, we reported a physical interaction between E1 and the major human single-stranded DNA (ssDNA)-binding protein, replication protein A (RPA). E1 was determined to bind to the 70-kDa subunit of RPA, RPA70. In this study, using E1-affinity coprecipitation and enzyme-linked immunosorbent assay-based interaction assays, we show that E1 interacts with the major ssDNA-binding domain of RPA. Consistent with our previous report, no measurable interaction between E1 and the two smaller subunits of RPA was detected. The interaction of E1 with RPA was substantially inhibited by ssDNA. The extent of this inhibition was dependent on the length of the DNA. A 31-nucleotide (nt) oligonucleotide strongly inhibited the E1-RPA interaction, while a 16-nt oligonucleotide showed an intermediate level of inhibition. In contrast, a 10-nt oligonucleotide showed no observable effect on the E1-RPA interaction. This inhibition was not dependent on the sequence of the DNA. Furthermore, ssDNA also inhibited the interaction of RPA with papillomavirus E2, simian virus 40 T antigen, human polymerase alpha-primase, and p53. Taken together, our results suggest a potential role for ssDNA in modulating RPA-protein interactions, in particular, the RPA-E1 interactions during papillomavirus DNA replication. A model for recruitment of RPA by E1 during papillomavirus DNA replication is proposed.

Regulation of bovine papillomavirus replicative helicase e1 by the ubiquitin-proteasome pathway

Papillomaviruses maintain their genomes in a relatively constant copy number as stable extrachromosomal plasmids in the nuclei of dividing host cells. The viral initiator of replication, E1, is not detected in papillomavirus-infected cells. Here, we present evidence that E1 encoded by bovine papillomavirus type 1 is an unstable protein that is degraded through the ubiquitin-proteasome pathway. In a cell-free system derived from Xenopus egg extracts, E1 degradation is regulated by both cyclin E/Cdk2 binding and E1 replication activity. Free E1 is readily ubiquitinated and degraded by the proteasome, while it becomes resistant to this degradation pathway when bound to cyclin E/Cdk2 complexes before the start of DNA synthesis. This stabilization is reversed in a process involving E1-dependent replication activity. In transiently transfected cells, E1 is also polyubiquitinated and accumulates when proteasome activity is inhibited. Thus, the establishment and maintenance of a stable number of papillomavirus genomes in latently infected cells are in part a function of regulated ubiquitin-mediated degradation of E1.

Human TATA binding protein inhibits human papillomavirus type 11 DNA replication by antagonizing E1-E2 protein complex formation on the viral origin of replication

The human papillomavirus (HPV) protein E2 possesses dual roles in the viral life cycle. By interacting directly with host transcription factors in basal keratinocytes, E2 promotes viral transcription. As keratinocyte differentiation progresses, E2 associates with the viral helicase, E1, to activate vegetative viral DNA replication. How E2's major role switches from transcription to replication during keratinocyte differentiation is not understood, but the presence of a TATA site near the viral origin of replication led us to hypothesize that TATA-binding protein (TBP) could affect HPV replication. Here we show that the C-terminal domain of TBP (TBPc) is a potent inhibitor of E2-stimulated HPV DNA replication in vitro (50% inhibitory concentration = 0.56 nM). Increasing the E1 concentration could not overcome TBPc inhibition in replication assays, indicating that TBPc is a noncompetitive inhibitor of E1 binding. While direct E2-TBPc association could be demonstrated, this interaction could not fully account for the mechanism of TBPc-mediated inhibition of viral replication. Because E2 supports sequence-specific binding of E1 to the viral ori, we proposed that TBPc antagonizes E1-ori association indirectly through inhibition of E2-DNA binding. Indeed, TBPc potently antagonized E2 binding to DNA in the absence (K(i) = 0.5 +/- 0.1 nM) and presence (K(i) = 0.6 +/- 0.3 nM) of E1. Since E2 and TBPc cannot be coadjacent on viral sequences, direct DNA-binding competition between TBPc and E2 was responsible for replication inhibition. Given the ability of TBPc to inhibit HPV DNA replication in vitro and data indicating that TBPc antagonized E2-ori association, we propose that transcription factors regulate HPV DNA replication as well as viral transcription.

High and low levels of cottontail rabbit papillomavirus E2 protein generate opposite effects on gene expression

The papillomavirus E2 protein plays an important role in viral transcriptional regulation and replication. We chose to study the cottontail rabbit papillomavirus (CRPV) E2 protein as a transcriptional regulator because of the availability of an animal model for papilloma formation, which may be relevant for human papillomavirus (HPV) infection and replication. We studied the effect of expression levels of E2 on the long control region, which contains transcriptional promoter and enhancer elements, and synthetic E2-dependent artificial promoters in which the E2 was the dominant factor in the transcriptional activation. These experiments indicated that high levels of E2 were inhibitory and low levels were stimulatory for transactivation. In addition, we showed that the complex formed between CRPV E2 and the cognate binding site was less stable than the complex formed between HPV E2 and the same cognate binding site. Furthermore, we showed that CRPV E2 binding to its transcriptional regulatory sequence was stabilized by other proteins such as E1, which produced increments in transcriptional activation of E2-dependent genes. The data may be used to define conditions in which the rabbit model can be used for the screening of drugs which are inhibitory to the HPV and CRPV replication and gene expression.

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.

Interactions of the papovavirus DNA replication initiator proteins, bovine papillomavirus type 1 E1 and simian virus 40 large T antigen, with human replication protein A

Papovaviruses utilize predominantly cellular DNA replication proteins to replicate their own viral genomes. To appropriate the cellular DNA replication machinery, simian virus 40 (SV40) large T antigen (Tag) binds to three different cellular replication proteins, the DNA polymerase alpha-primase complex, the replication protein A (RPA) complex, and topoisomerase I. The functionally similar papillomavirus E1 protein has also been shown to bind to the DNA polymerase alpha-primase complex. Enzyme-linked immunoassay-based protein interaction assays and protein affinity pull-down assays were used to show that the papillomavirus E1 protein also binds to the cellular RPA complex in vitro. Furthermore, SV40 Tag was able to compete with bovine papillomavirus type 1 E1 for binding to RPA. Each of the three RPA subunits was individually overexpressed in Escherichia coli as a soluble fusion protein. These fusion proteins were used to show that the E1-RPA and Tag-RPA interactions are primarily mediated through the 70-kDa subunit of RPA. These results suggest that different viruses have evolved similar mechanisms for taking control of the cellular DNA replication machinery.

Biochemical and electron microscopic image analysis of the hexameric E1 helicase

DNA replication initiator proteins bind site specifically to origin sites and in most cases participate in the early steps of unwinding the duplex. The papillomavirus preinitiation complex that assembles on the origin of replication is composed of proteins E1 and the activator protein E2. E2 is an ancillary factor that increases the affinity of E1 for the ori site through cooperative binding. Here we show that duplex DNA affects E1 (in the absence of E2) to assemble into an active hexameric structure. As a 10-base oligonucleotide can also induce this oligomerization, it seems likely that DNA binding allosterically induces a conformation that enhances hexamers. E1 assembles as a bi-lobed, presumably double hexameric structure on duplex DNA and can initiate bi-directional unwinding from an ori site. The DNA takes an apparent straight path through the double hexamers. Image analysis of E1 hexameric rings shows that the structures are heterogeneous and have either a 6- or 3-fold symmetry. The rings are about 40-50 A thick and 125 A in diameter. The density of the central cavity appears to be a variable and we speculate that a plugged center may represent a conformational flexibility of a subdomain of the monomer, to date unreported for other hexameric helicases.

Interaction between cyclin-dependent kinases and human papillomavirus replication-initiation protein E1 is required for efficient viral replication

We have identified the human papillomavirus (HPV) DNA replication initiation protein E1 as a tight-binding substrate of cyclin E/cyclin-dependent kinase (Cdk) complexes by using expression cloning. E1, a DNA helicase, collaborates with the HPV E2 protein in ori-dependent replication. E1 formed complexes with cyclin E in insect and mammalian cells, independent of Cdks and E2. Additional cyclins, including A-, B-, and F-type (but not D-type), interacted with the E1/E2 complex, and A- and E-type cyclin kinases were capable of phosphorylating E1 and E2 in vitro. Association with cyclins and efficient phosphorylation of E1 required the presence of a cyclin interaction motif (the RXL motif). E1 lacking the RXL motif displayed defects in E2-dependent HPV ori replication in vivo. Consistent with a role for Cdk-mediated phosphorylation in E1 function, an E1 protein lacking all four candidate Cdk phosphorylation sites still associated with E2 and cyclin E but was impaired in HPV replication in vitro and in vivo. Our data reveal a link between cyclin/Cdk function and activation of HPV DNA replication through targeting of Cdk complexes to the E1 replication-initiation protein and suggest a functional role for E1 phosphorylation by Cdks. The use of cyclin-binding RXL motifs is now emerging as a major mechanism by which cyclins are targeted to key substrates.

Human Hsp70 and Hsp40 chaperone proteins facilitate human papillomavirus-11 E1 protein binding to the origin and stimulate cell-free DNA replication

Human papillomavirus replication initiator, the E1 helicase, binds weakly to the origin of DNA replication. Purified human chaperone proteins Hsp70 and Hsp40 (HDJ-1 and HDJ-2) independently and additively enhanced E1 binding to the origin. The interaction between E1 and Hsp70 was transient and required ATP hydrolysis, whereas Hsp40 bound to E1 directly and remained in the complex. A peptide of 20 residues spanning the HPD loop and helix II of the J domain of YDJ-1 also stimulated E1 binding to the origin, alone or in combination with Hsp70 or Hsp40. A mutated peptide (H34Q) had a reduced activity, while an adjacent or an overlapping peptide had no effect. Neither Hsp70 nor the J peptide altered the E1/DNA ratio in the complex. Electron microscopy showed that E1 mainly bound to DNA as a hexamer. In the presence of Hsp40, E1 primarily bound to DNA as a dihexamer. Preincubation of chaperones with viral E1 and template shortened the lag time and increased replication in a cell-free system. Since two helicases are essential for bidirectional replication of human papillomavirus DNA, these results demonstrate that, as in prokaryotes, chaperones play an important role in the assembly of preinitiation complexes on the origin.

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.

Molecular targets for human papillomaviruses: prospects for antiviral therapy

A substantial medical need exists for the development of antiviral medicines for the treatment of diseases associated with infection by human papillomaviruses (HPVs). HPVs are associated with various benign and malignant lesions including benign genital condyloma, common skin warts, laryngeal papillomas and anogenital cancer. Since treatment options are limited and typically not very satisfactory, the development of safe and effective antiviral drugs for HPV could have substantial clinical impact. In the last few years, exciting advances have been made in our understanding of papillomavirus replication and the effects that the virus has on growth of the host cell. Although still somewhat rudimentary, techniques have been developed for limited virion production in vitro offering the promise of more rapid advances in the dissection and understanding of the virus life cycle. Of the 8-10 HPV gene products that are made during infection, only one encodes enzymatic activities, the E1 helicase. Successful antiviral therapies have traditionally targeted viral enzymes such as polymerases, kinases and proteases. In contrast, macromolecular interactions which mediate the functions of E6, E7 and E2 are thought to be more difficult targets for small molecule therapy.

Functional interaction between the bovine papillomavirus virus type 1 replicative helicase E1 and cyclin E-Cdk2

We have found that the replicative helicase E1 of bovine papillomavirus type 1 (BPV-1) interacts with a key cell cycle regulator of S phase, the cyclin E-Cdk2 kinase. The E1 helicase, which interacts with cyclin E and not with Cdk2, presents the highest affinity for catalytically active kinase complexes. In addition, E1, cyclin E, and Cdk2 expressed in Xenopus egg extracts are quantitatively coimmunoprecipitated from crude extracts by either anti-Cdk2 or anti-E1 antibodies. E1 protein is also a substrate of the cyclin E-Cdk2 kinase in vitro. Using the viral components required for in vitro BPV-1 replication and free-membrane cytosol from Xenopus eggs, we show that efficient replication of BPV plasmids is dependent on the addition of E1-cyclin E-Cdk2 complexes. Thus, the BPV initiator of replication and cyclin E-Cdk2 are likely to function together as a protein complex which may be the key to the cell cycle regulation of papillomavirus replication.

p53 protein is a suppressor of papillomavirus DNA amplificational replication

p53 protein was able to block human and bovine papillomavirus DNA amplificational replication while not interfering with Epstein-Barr virus oriP once-per-cell cycle replication. Oligomerization, intact DNA-binding, replication protein A-binding, and proline-rich domains of the p53 protein were essential for efficient inhibition, while the N-terminal transcriptional activation and C-terminal regulatory domains were dispensable for the suppressor activity of the p53 protein. The inhibition of replication was caused neither by the downregulation of expression of the E1 and E2 proteins nor by cell cycle block or apoptosis. Our data suggest that the intrinsic activity of p53 to suppress amplificational replication of the papillomavirus origin may have an important role in the virus life cycle and in virus-cell interactions.

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.

Cell cycle control of DNA replication

The cell cycle is driven by the sequential activation of a family of cyclin-dependent kinases (cdk), which phosphorylate and activate proteins that execute events critical to cell cycle progression. In mammalian cells cdk2-cyclin A has a role in S phase. Many replication proteins are potential substrates for this cdk kinase, suggesting that initiation, elongation and checkpoint control of replication could all be regulated by cdk2. The association of PCNA, a replication protein, with cdk-cyclins during G-1 to S phase transition and with cdk-cyclin inhibitors, adds an interesting complexity to regulation of DNA replication.

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.

Isolation, characterization, and molecular cloning of a protein (Abp2) that binds to a Schizosaccharomyces pombe origin of replication (ars3002)

The autonomously replicating sequence (ARS) element ars3002 is associated with the most active replication origin within a cluster of three closely spaced origins on chromosome III of Schizosaccharomyces pombe. A 361-bp portion of ars3002 containing detectable ARS activity includes multiple near matches to the S. pombe ARS consensus sequence previously reported by Maundrell et al. (K. Maundrell, A. Hutchison, and S. Shall, EMBO J. 7:2203-2209, 1988). Using a gel shift assay with a multimer of an oligonucleotide containing three overlapping matches to the Maundrell ARS consensus sequence, we have detected several proteins in S. pombe crude extracts that bind to the oligonucleotide and ars3002. One of these proteins, ARS binding protein 1, was previously described (Abpl [Y. Murakami, J. A. Huberman, and J. Hurwitz, Proc. Natl. Acad. Sci. USA 93:502-507, 1996]). In this report the isolation, characterization, and cloning of a second binding activity, designated ARS binding protein 2 (Abp2), are described. Purified Abp2 has an apparent molecular mass of 75 kDa. Footprinting analyses revealed that it binds preferentially to overlapping near matches to the Maundrell ARS consensus sequence. The gene abp2 was isolated, sequenced, and overexpressed in Escherichia coli. The DNA binding activity of overexpressed Abp2 was similar to that of native Abp2. The deduced amino acid sequence contains a region similar to a proline-rich motif (GRP) present in several proteins that bind A+T-rich DNA sequences. Replacement of amino acids within this motif with alanine either abolished or markedly reduced the DNA binding activity of the mutated Abp2 protein, indicating that this motif is essential for the DNA binding activity of Abp2. Disruption of the abp2 gene showed that the gene is not essential for cell viability. However, at elevated temperatures the null mutant was less viable than the wild type and exhibited changes in nuclear morphology. The null mutant entered mitosis with delayed kinetics when DNA replication was blocked with hydroxyurea, and advancement through mitosis led to the loss of cell viability and aberrant formation of septa. The null mutant was also sensitive to UV radiation, suggesting that Abp2 may play a role in regulating the cell cycle response to stress signals.

Competition for DNA binding sites between the short and long forms of E2 dimers underlies repression in bovine papillomavirus type 1 DNA replication control

Papillomaviruses establish a long-term latency in vivo by maintaining their genomes as nuclear plasmids in proliferating cells. Bovine papillomavirus type 1 encodes two proteins required for viral DNA replication: the helicase E1 and the positive regulator E2. The homodimeric E2 is known to cooperatively bind to DNA with E1 to form a preinitiation complex at the origin of DNA replication. The virus also codes for two short forms of E2 that can repress viral functions when overexpressed, and at least one copy of the repressor is required for stable plasmid maintenance in transformed cells. Employing a tetracycline-regulated system to control E1 and E2 production from integrated loci, we show that the short form of E2 negatively regulates DNA replication. We also found that the short form could repress replication in a cell-free replication system and that the repression requires the DNA binding domain of the protein. In contrast, heterodimers of the short and long forms were activators and, by footprint analysis, were shown to be as potent as homodimeric E2 in loading E1 to its cognate site. DNA binding studies show that when E1 levels are low and are dependent upon E2 for occupancy of the origin site, the repressor can block E1-DNA interactions. We conclude that DNA replication modulation results from competition between the different forms of E2 for DNA binding. Given that heterodimers are active and that the repressor form of E2 shows little cooperativity with E1 for DNA binding, this protein is a weak repressor.

Identification of sequence requirement for the origin of DNA replication in human papillomavirus type 18

DNA replication of human papillomavirus type 18 is dependent on viral proteins E1 and E2 and the subsequent interaction of these proteins with the viral origin of replication. Using a site-directed mutagenesis analysis, we examined the sequence requirement for the DNA replication of the human papillomavirus type 18. We showed that both the E1BS palindrome and E2BS are the major determinants of the HPV replication efficiency. In particular, abolishing E2 binding sites demonstrated that E2BS makes a significant contribution towards HPV-18 DNA replication. Each part of the 18-bp inverted repeat sequence of the E1BS motif showed a clear functional difference between two regions: nt 13-21 (3' half segment) is evidently more important for replication than nt 4-12 (5' half segment). Besides E1BS and E2BS, cis-acting elements such as the poly-A6 track, perhaps the YY1 binding site, and the TATA box sequence within the origin region exhibited some contributions to optimum replication. In addition, inserting an enhancer region to the minimum origin DNA derivatives increased replication approximately 2-fold compared with the wild type levels and showed some compensational effects on loss of the cis-element within the HPV-18 minimum origin, suggesting that an enhancer region is required for efficient replication of the papillomavirus origin. These results suggest that the formation of an E1-E2-ori complex is important for replication, and other sequences near the E1 and E2 binding sites assist E1-E2-ori-mediated DNA replication in vivo.

Reconstitution of a functional bovine papillomavirus type 1 origin of replication reveals a modular tripartite replicon with an essential AT-rich element

A functional replication origin was reconstituted using oligonucleotide cassettes corresponding to three sequence subelements within the Bovine Papillomavirus Type 1 (BPV-1) replication origin: the 23-bp AT-rich region (ATR), the 18-bp binding site for the viral replication initiator protein E1 (E1BS), and a binding site for the viral transcriptional transactivator and replication enhancer protein E2 (E2BS). Replication of the reconstituted origin depended on heterologous expression of both the E1 and E2 proteins and on the presence of both the E1BS and E2BS, indicating that it is functionally analogous to the authentic BPV-1 origin. In addition, pairwise testing of subelement combinations revealed that the ATR was also essential and that a functional origin required at least one copy of all three subelements. While the E1BS and E2BS are sequence-specific elements, the function of the BPV-1 ATR could be at least partially substituted with heterologous AT-rich sequences, suggesting that the role of this element is primarily AT content-dependent rather than sequence-dependent. A stringent requirement for the ATR was also observed in the context of an authentic minimal origin sequence confirming that it is an intrinsic property of the BPV-1 origin and not simply an artifact of the reconstitution system. This study indicates that the minimal functional BPV-1 origin shares the tripartite modular organization characteristic of other simple eukaryotic replication origins. The reconstitution system described now provides a convenient approach to define the physical and functional interrelationships between the three subelements in a systematic fashion.

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.

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.

Purification, gene cloning, and reconstitution of the heterotrimeric single-stranded DNA-binding protein from Schizosaccharomyces pombe

We have purified a single-stranded DNA-binding protein (SSB) from Schizosaccharomyces pombe (Sp) and have shown that it is composed of three subunits of 68, 30, and 12 kDa. The SpSSB supports T antigen-dependent unwinding of SV40 ori containing DNA, but is not functional in the SV40 in vitro replication reaction. All three genes that encode the SpSSB subunit have been isolated. The cloned cDNA of the ssb1(+), encoding the p68 subunit, contains 609 amino acids (68.3 kDa), while that of the ssb2(+), encoding the p30 subunit, contains a 279 amino acids (30.3 kDa). The genomic DNA clone of the p12 subunit gene (ssb3(+)) has 2 introns and an open reading frame of 104 amino acids (11.8 kDa). Significant homology is observed among the largest and middle subunits of eukaryotic SSBs, but there is poor homology among the smallest subunits. In addition, we have reconstituted the SpSSB complex by coexpression of all three subunits in Escherichia coli. The reconstituted complex is active in single-stranded DNA binding and the T antigen-dependent unwinding of SV40 ori DNA. Finally, we observed a cell cycle-dependent phosphorylation pattern of the p30 subunit of SpSSB, which is similar to that observed for the human and Saccharomyces cerevisiae SSB.

Biochemical characterization of p16INK4- and p18-containing complexes in human cell lines

The regulation of the D-type cyclin-dependent kinase (CDK4 and CDK6) activity appears to be the key step in the progression of eukaryotic cells through the G1 cell cycle phase. One of the mechanisms involved in this process is the binding of some small proteic inhibitors, with a molecular mass ranging between 14 and 20 kDa, to these CDKs. We have evaluated the amount of two such inhibitors, namely p16(INK4) and p18, in normal and transformed cells, as well as the biochemical features of the macromolecular complexes containing these proteins. The results obtained indicated that (i) p18 gene expression, unlike p16(INK4) gene, is not regulated by pRb status, (ii) no evident relationship exists between the expression of p16(INK4) and p18 genes, (iii) significant amounts of the two proteins are not bound to CDKs but occur as free molecules, (iv) each inhibitor forms a complex with the CDK protein with a 1:1 stoichiometry, and (v) a competition exists between cyclin D and the inhibitor protein toward the CDK protein resulting in the absence of detectable cellular free kinase. Moreover, employing the human native partially purified p16(INK4)or the pure recombinant protein, we have been able to demonstrate in vitro the dissociation of CDK4-cyclin D1 complex and the formation of CDK4-p16(INK4) bimolecular complex. Our findings suggest that during the cell division cycle the members of the p16(INK4) protein family and cyclin Ds compete for binding to CDK4/CDK6 and that their quantitative ratio is essential for G1 --> S transition.

Temporal and histologic relationships of proliferating cell nuclear antigen and human papillomavirus type 11 in the mouse xenograft system

Proliferating cell nuclear antigen (PCNA) is an accessory protein of DNA polymerase delta. This protein is associated with cell cycle progression and can be detected in the replicating cells of normal tissues. Condylomata acuminata are benign epithelial tumors caused by infection with human papillomaviruses and are characterized by abnormal cell proliferation. The athymic mouse xenograft model of HPV 11 infection was used to test the hypothesis that PCNA is induced early in the course of HPV 11 infection and to study the temporal and histologic relationships between detection of PCNA and HPV DNA. Human foreskin tissue was infected with HPV 11 and implanted under the renal capsules of 10 athymic mice. Pairs of mice were sacrificed every week beginning four weeks after implantation. HPV DNA was detected in sections of foreskin implants by in situ hybridization. PCNA was as or more abundant in implants removed at earlier time points than at later time points, whereas HPV DNA became increasingly more abundant with time. PCNA was detected only in basal cells in areas of histologically normal epithelium that were also negative for HPV DNA. In contrast, PCNA was present throughout the epithelium in regions that were HPV DNA-positive. HPV DNA was detected only in differentiated epithelial cells in implants removed at all five time points, but in HPV DNA-positive regions, PCNA was detected with equal intensity in differentiated and undifferentiated cells. The foci of PCNA-positive cells were well demarcated and were larger than, but included, the foci of HPV DNA-positive cells. PCNA may be induced maximally in differentiated epithelium by HPV 11 prior to significant HPV DNA replication.

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.

DNA polymerase delta holoenzyme: action on single-stranded DNA and on double-stranded DNA in the presence of replicative DNA helicases

DNA polymerase delta requires proliferating cell nuclear antigen and replication factor C to form a holoenzyme efficient in DNA synthesis. We have analyzed three different aspects of calf thymus DNA polymerase delta holoenzyme: (i) analysis of pausing during DNA synthesis, (ii) replication of double-stranded DNA in the absence of additional factors, and (iii) replication of double-stranded DNA in the presence of the two known replicative DNA helicases from simian virus 40 and bovine papilloma virus. DNA polymerase delta holoenzyme replicated primed single-stranded DNA at a rate of 100-300 nucleotides/min, partially overcoming multiple pause sites on DNA. While Escherichia coli single-strand DNA binding protein helped DNA polymerase delta pass through pause sites, the DNA polymerase delta itself appeared to dissociate from the template in the absence of synthesis or when encountering pause sites. Proliferating cell nuclear antigen likely remained on the template. DNA polymerase delta holoenzyme could perform limited strand displacement synthesis on double-stranded gapped circular DNA, and this reaction was not stimulated either by replication protein A or by E. coli single-strand DNA binding protein. DNA polymerase delta holoenzyme could efficiently cooperate with replicative DNA helicases from simian virus 40 (large T antigen) and bovine papilloma virus 1 (protein E1) in replication through double-stranded DNA in a reaction that required replication protein A or E. coli single-strand DNA binding protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Bovine papillomavirus E1 protein binds specifically DNA polymerase alpha but not replication protein A

Extracts prepared from either mouse cells or monkey cells were examined for the ability to support in vitro bovine papillomavirus type 1 (BPV1) DNA replication, and they were used in parallel as a source of host replication proteins for affinity chromatography. DNA synthesis exhibited an absolute requirement for BPV1 E1 protein. In contrast to previous observations, we found that low levels of E1 were highly efficient in initiating DNA replication in the absence of the BPV1 transcription factor E2. Surprisingly, COS-1 cell extract allowed a high rate of BPV1 DNA replication, supporting an efficient production of mature circular DNA molecules, whereas in mouse cell extracts, the replication products mostly consisted of replicative intermediates. Submitting the extracts to affinity chromatography allowed specific binding of DNA polymerase alpha-primase to E1 protein, up to a total depletion of the extract, regardless of the origin of the cell extract. Furthermore, replication protein A was not retained on E1 affinity columns, even when E2 was complexed with E1. These data confirm that the interactions between E1 and DNA polymerase alpha-primase do not exhibit cell-type specificity, as had already been suggested by data from in vivo and in vitro replication assays, but they imply that other cellular proteins may affect the level of E1-dependent replication.

Crystal structure of the eukaryotic DNA polymerase processivity factor PCNA

The crystal structure of the processivity factor required by eukaryotic DNA polymerase delta, proliferating cell nuclear antigen (PCNA) from S. cerevisiae, has been determined at 2.3 A resolution. Three PCNA molecules, each containing two topologically identical domains, are tightly associated to form a closed ring. The dimensions and electrostatic properties of the ring suggest that PCNA encircles duplex DNA, providing a DNA-bound platform for the attachment of the polymerase. The trimeric PCNA ring is strikingly similar to the dimeric ring formed by the beta subunit (processivity factor) of E. coli DNA polymerase III holoenzyme, with which it shares no significant sequence identity. This structural correspondence further substantiates the mechanistic connection between eukaryotic and prokaryotic DNA replication that has been suggested on biochemical grounds.