Viral Origin Of Replication Research Articles

The Bovine Papilloma Virus E1 Protein Has ATPase Activity Essential to Viral DNA Replication and Efficient Transformation in Cells

The bovine papilloma virus (BPV) E1 protein essential to viral DNA replication has recently been shown to associate via direct protein DNA interactions with the viral origin of replication and to be an ATP-dependent helicase. We show here that in accordance with the latter function, the E1 gene product has intrinsic ATPase activity. Mutations placed throughout the nucleotide binding consensus element abolish the ATPase activity of E1 and render BPV genomes harboring such mutations defective for episomal replication and impaired for oncogenic transformation.

E1 protein of human papillomavirus type 1a is sufficient for initiation of viral DNA replication.

Previous studies on transient replication of papillomaviruses have shown an absolute requirement for the viral E1 and E2 proteins in DNA replication. Here we demonstrate that for human papillomavirus type 1a (HPV-1a) DNA, the E1 protein alone is sufficient for in vivo replication of plasmids containing the viral origin of replication. Replication was origin-specific and required the presence of a DNA sequence containing a putative E1 binding site, but the E2 binding sites were dispensable. In the presence of the E1 protein, E2 stimulated replication of plasmids containing the E1 and E2 binding sites, but no stimulation was observed when the origin plasmids lacked E2 binding sites. Conversely, in the presence of E1 alone, the E2 binding sites did not affect replication. Plasmids containing the replication origins of HPV-6b, HPV-18, and bovine papillomavirus type 1 (BPV-1) also replicated efficiently in the presence of the HPV-1a E1 and E2 proteins. However, plasmids containing the origins of HPV-6b and HPV-18 failed to replicate in the presence of HPV-1a E1 alone, whereas a plasmid containing the BPV-1 origin replicated to lower levels than the HPV-1a origin-containing plasmid. These results suggest that replication from papillomaviral origins in the presence of E1 alone is presumably dependent on the strength of E1-origin interactions. Additionally, E1-dependent replication is stimulated by the E2 protein in the presence of E2 binding sites.

Induction of structural changes in the bovine papillomavirus type 1 origin of replication by the viral E1 and E2 proteins.

Chemical and enzymatic probing techniques were used to examine the interaction of the bovine papillomavirus type 1 E1 and E2 proteins with the viral origin of replication (ori). E1 was found to generate significant distortions to the structure of ori, as assayed by KMnO4 oxidation of DNA. The primary site of ori distortion was located within and adjacent to the AT-element of the core replicator sequence, although a number of minor structural transitions were also detected. The induction of these structural changes required ATP and appeared to require ATP hydrolysis. E2 was found to decrease the amount of E1 required for ori distortion but did not significantly alter the pattern of structural distortion. In contrast, the presence of E2 resulted in a biphasic mechanism for E1 binding to ori, as assayed by nuclease protection. Under these conditions, E1 bound preferentially to the dyad symmetry region containing the conserved Hpa I site. Higher levels of E1 were required for binding to the adjacent ori AT-rich region. Thus, these data suggest that E2 can order the stepwise binding of E1 to ori.

The cellular DNA polymerase alpha-primase is required for papillomavirus DNA replication and associates with the viral E1 helicase.

Persistent infection by papillomaviruses involves the maintenance of viral DNA as a nuclear plasmid, the replication of which requires host DNA polymerases. The role of the cellular DNA polymerase alpha-primase holoenzyme was probed by using soluble extracts from rodent cells that replicate bovine papilloma virus 1 and human papilloma virus 6b DNA in the presence of the viral E1 helicase and the E2 transcription factor. Monoclonal antibodies directed against the catalytic 180-kDa subunit of polymerase alpha inhibit DNA synthesis in this system. Addition of purified human polymerase alpha-primase holoenzyme to neutralized extracts restores their DNA synthetic activity. The amino-terminal 424 amino acids of E1 forms a specific protein complex with the p180 polymerase subunit. Immune complexes can be isolated with antibodies directed against E1 that contain a DNA polymerase activity. Moreover, this polymerase activity can be neutralized by anti-polymerase alpha antibodies. Permissivity barriers were not encountered in this in vitro system, as bovine E1 can interface with the murine and human replication apparatus. Although the large tumor antigens encoded by simian virus 40 and polyoma share limited primary sequence homology with the papillomavirus E1 proteins, the organization of functional motifs at the level of primary protein structure is remarkably similar. In addition to their origin-specific DNA-binding activity, each of these helicases may function to help recruit the cellular polymerase alpha-primase complex to the viral replication origin.

Human Immunodeficiency Virus (HIV)-Infected Human Blood Monocytes and Peritoneal Macrophages Have Reduced Anticryptococcal Activity whereas HIV-Infected Alveolar Macrophages Retain Normal Activity

Human immunodeficiency virus type 1 (HIV-1) infection causes immune dysfunction. Mononuclear phagocytes (MNP) are immune effector cells against some intracellular pathogens and reservoirs for HIV-1. This study determined effects of HIV-1 on MNP-mediated antifungal function. MNP from seronegative volunteers were inoculated with HIVBal or HIVIIIB. MNP were infected with an avirulent clone of Cryptococcus neoformans; 48 h later, MNP were lysed and yeasts were counted. Viral replication was determined by reverse transcriptase and by visualization of cytopathic effects. Monocytes and peritoneal macrophages exhibited reduced anticryptococcal activity 14 days after infection with HIVBal but retained normal activity when infected with HIVIIIB. Loss of anticryptococcal activity correlated with viral replication. Alveolar macrophages retained normal anticryptococcal activity whether infected with HIVBal or HIVIIIB. In vitro MNP-mediated antifungal activity may be altered by HIV-1 infection; this altered activity appears to depend on viral tropism, viral replication, and MNP tissue origin.

Herpes simplex virus DNA replication: a spacer sequence directs the ATP-dependent formation of a nucleoprotein complex at oriS.

The origin-binding protein (OBP) from herpes simplex virus 1 is a member of the SF2 helicase superfamily and is required for the initiation of DNA synthesis from a viral origin of DNA replication (oriS). The high-affinity binding sites for OBP in oriS, boxes I and II, are separated by an A+T-rich spacer. We used the gel retardation technique to examine the influence of this spacer sequence on the formation of a specific complex, referred to as complex II, between OBP and oriS. The formation of this OBP-oriS complex was greatly promoted by adenosine 5'-[gamma-thio]triphosphate and other nucleotide cofactors. Surprisingly, oriS constructs where the spacer sequence had been altered with approximately half of a helical turn (+4 or -6 base pairs) supported the formation of a more stable complex II than the wild-type origin. DNase I footprinting experiments showed that the cooperative binding of OBP to boxes I and II was affected by the length of the spacer sequence in the same way. In contrast, the ability of oriS-containing plasmids to replicate was most efficient with wild-type oriS. This paradox can be resolved if it is assumed that an ATP-dependent cooperative binding of OBP to properly spaced recognition sequences in oriS is required to induce a conformational change of DNA, thereby facilitating initiation of DNA replication.

Interaction between a geminivirus replication protein and origin DNA is essential for viral replication.

The geminivirus, tomato golden mosaic virus (TGMV), encodes one protein, AL1, that is absolutely required for viral DNA replication. AL1 interacts with the TGMV DNA genome by binding specifically to the viral origin of replication. We have investigated the nature and significance of AL1/origin interactions in vitro and in vivo by using competitive DNA binding and transient replication assays. Competition assays established that a 13-base pair (bp) element (5'-GGTAGTAAGGTAG) containing two 5-bp direct repeat motifs separated by a 3-bp central core constitutes a high affinity AL1 binding site. DNAs containing intact 3' repeat sequences plus core (TAAGGTAG and ccTAGTAAGGTAG) were stronger competitors for AL1 binding than DNAs containing intact 5' repeat sequences plus core (GGTAGTAA and GGTAGTA-AccTAG), thereby demonstrating that AL1 interacts differently with the repeat motifs. Replication in tobacco protoplasts established that the AL1 binding site is an essential cis-acting element for viral replication. No replication was detected for DNAs containing mutations in either of the repeat motifs of the AL1 recognition sequence when AL1 was provided in trans from a plant gene expression vector. In contrast, a DNA with a mutation in the 5' repeat motif (ccTAGTAAGGTAG) replicated when both AL1 and AL3, a TGMV protein involved in viral DNA accumulation, were provided in trans. No replication was detected for a DNA containing a mutation in the 3' repeat motif (GGTAGTAAccTAG) in the presence of AL1 and AL3. The in vitro and in vivo results suggest that binding of AL1 to the 3' repeat element is an essential step in DNA replication, while binding to the 5' repeat element may serve to enhance viral replication.

The bovine papillomavirus type 1 (BPV1) replication protein E1 modulates transcriptional activation by interacting with BPV1 E2

The study of bovine papillomavirus type 1 (BPV1) DNA replication has shown that E1 and E2 are the only viral proteins required for this process. Both E1 and E2 interact with the viral origin of replication (ori). The BPV1 E2 protein is also a well-characterized transcriptional regulator. We show in this report that E1 can modulate transcription by interactions with E2. At low concentrations, E1 enhanced the E2-mediated transactivation of heterologous promoters containing the BPV1 ori by promoting cooperative binding of both E1 and E2 to the DNA. In contrast, in the presence of excess E1, transactivation by E2 is repressed. This last process, however, does not require cooperative DNA binding of the two proteins. These results imply that the balance between these two distinct types of interaction is crucial both for control of replication and for early viral transcription.

Structures of large T antigen at the origin of SV40 DNA replication by atomic force microscopy

For inorganic crystals such as calcite (CaCO3), Atomic Force Microscopy (AFM) has provided surface structure at atomic resolution (Ohnesorge and Binnig, 1993). As part of a broad effort to obtain high resolution for an individual protein or protein assembly (Binnig et al., 1986; Rugar and Hansma, 1990; Radmacher et al., 1992), we applied AFM to study the ATP-dependent double hexamer of SV40 large T antigen, which assembles around the viral origin of DNA replication. Multimeric mass has been determined in two-dimensional projected images by Scanning Transmission Electron Microscopy (STEM) (Mastrangelo et al., 1989). By AFM, if the DNA-protein preparation has been stained positively by uranyl acetate, the contour at the junction between hexamers is visible as a cleft, 2-4 nm deep. The cleft, whether determined as a fraction of height by AFM or as a fraction of mass thickness by STEM, is of comparable magnitude. On either side of the cleft, hexamers attain a maximum height of 13-16 nm. Monomers found in the absence of ATP show heights of 5-7 nm. Taken together, the z coordinates provide a surface profile of complete and partial replication assemblies consistent with the spatial distribution of recognition pentanucleotides on the DNA, and they contribute direct geometrical evidence for a ring-like hexamer structure.

Phosphorylation-dependent interaction of adenovirus preterminal protein with the viral origin of DNA replication.

Adenovirus preterminal protein (pTP) exists as a heterodimer with the viral DNA polymerase (AdPol) and becomes covalently linked to a dCMP residue during initiation of DNA replication. The in vivo phosphorylation of pTP could be demonstrated when pTP is overproduced using recombinant vaccinia viruses, or by a large scale metabolic labeling of adenovirus 2 (Ad2)-infected HeLa cells. Phosphoserine was the only phosphoamino acid obtained by acid hydrolysis of 32P-labeled pTP immunoprecipitated from metabolically labeled HeLa cells infected with either Ad2 or recombinant vaccinia virus. Tryptic peptide maps of pTP expressed using recombinant vaccinia virus system in HeLa cells revealed that phosphorylation of pTP occurred on multiple sites. Dephosphorylation of pTP with calf intestinal alkaline phosphatase resulted in a significant decrease in its activity in the in vitro DNA replication initiation assays. Further characterization of the phosphatase-treated pTP indicated that although dephosphorylation did not affect its interaction with AdPol, the specific recognition of the DNA replication origin by pTP was significantly reduced as determined by gel electrophoresis-based DNA mobility shift assays.

T-antigen kinase inhibits simian virus 40 DNA replication by phosphorylation of intact T antigen on serines 120 and 123.

Simian virus 40 (SV40) DNA replication begins after two large T-antigen hexamers assemble on the viral minimal origin of replication and locally unwind the template DNA. The activity of T antigen in this reaction is regulated by its phosphorylation state. A form of casein kinase I purified from HeLa nuclear extracts (T-antigen kinase) phosphorylates T antigen on physiologic sites and inhibits its activity in the unwinding reaction (A. Cegielska and D. M. Virshup, Mol. Cell. Biol. 13:1202-1211, 1993). Using a series of mutant T antigens expressed by recombinant baculoviruses in Sf9 cells, we find that the origin unwinding activities of both TS677-->A and TS677,679-->A are inhibited by the T-antigen kinase, as is wild-type T antigen. In contrast, mutants TS120-->A and TS123,679-->A are resistant to inhibition by the kinase. Thus, phosphorylation of serines 120 and 123 is necessary for inhibition of T-antigen activity. Previous studies of casein kinase I substrate specificity have suggested that acidic residues or a phosphorylated amino acid amino terminal to the target residue are required to create a casein kinase I recognition site. However, we find that the T-antigen kinase can add more than 3 mol of Pi per mol to full-length bacterially produced T antigen and that it inhibits the unwinding activity of p34cdc2-activated bacterially produced T antigen. Since no prior phosphorylation is present in this bacterially produced T antigen, and no acidic residues are present immediately amino terminal to serines 120 and 123, other structural elements of T antigen must contribute to the recognition signals for T-antigen kinase. In support of this conclusion, we find that while T-antigen kinase phosphorylates amino-terminal residues in bacterially produced full-length T antigen, it cannot phosphorylate bacterially produced truncated T antigen containing amino acids 1 to 259, a 17-kDa amino-terminal tryptic fragment of T antigen, nor can it phosphorylate denatured T antigen. These findings strongly suggest that the carboxy-terminal domain of T antigen is an important modifier of the recognition signals for phosphorylation of the critical amino-terminal sites by the T-antigen kinase. This conclusion is consistent with previous studies suggesting close apposition of amino- and carboxy-terminal domains of T antigen in the native protein. The three-dimensional conformation of the substrate appears to make a significant contribution to T-antigen kinase substrate specificity.

Phosphorylation and active ATP hydrolysis are not required for SV40 T antigen hexamer formation.

ATP induces structural alterations in SV40 large T antigen and promotes changes in its interaction with the viral replication origin. We have analyzed nucleotide-induced changes in T antigen structure in the absence of origin DNA. Most preparations of immunopurified T antigen contain several discrete species ranging in size from monomers through oligomers larger than hexamers. The predominant species consist of monomers and dimers. Incubation of T antigen with ATP or dATP leads to a dramatic and rapid increase in the appearance of T antigen hexamers. Weakly and nonhydrolyzable analogs of ATP are effective as well, indicating that hexamer formation does not require active ATP hydrolysis. After incubation of T antigen with [gamma-35S]ATP, stable association of the labeled nucleotide with all detectable forms occurs. Removal of greater than 80% of the T antigen phosphate residues does not significantly affect the formation of T antigen hexamers, although changes in the distribution and mobility of the other species of T antigen are apparent. Furthermore, T antigen synthesized in and purified from Escherichia coli and, therefore, presumably un- or underphosphorylated, is capable of forming hexamers. Nucleotide-induced T antigen hexamer formation thus appears to require neither protein phosphorylation nor active ATP hydrolysis.

The mechanism of sequence-specific DNA cleavage and strand transfer by phi X174 gene A* protein.

We have examined the biological role and catalytic function of two juxtaposed tyrosyl residues in the bacteriophage phi X174 gene A protein, Tyr-343 and Tyr-347, which have been implicated in the catalysis of sequence-specific DNA strand transfer. Site-directed mutagenesis changing either tyrosine to phenylalanine abolishes phage viability. The biochemical basis of this inviability was studied using purified A* protein containing the carboxyl-terminal 341 amino acids of the A protein, as well as purified A* protein with a Y343F or Y347F mutation. All three proteins can cleave the phi X174 replication origin and perform strand transfer between oligodeoxynucleotides bearing the recognition sequence of the A protein; however, both Tyr-343 and Tyr-347 appear to be required for coordinated DNA strand transfer by a single A* protein molecule. The chirality of a phosphorothioate group at the site of strand transfer in the DNA was found to be retained following the strand-transfer reaction, which argues against transfer of Tyr-343-linked DNA to Tyr-347 on the same protein molecule or vice versa. These results support the current model of gene A protein function in which the two tyrosines of a single protein molecule alternate in catalyzing DNA strand transfer at the viral replication origin.

The replication functions of polyomavirus large tumor antigen are regulated by phosphorylation.

Polyomavirus (Py) large T antigen (T Ag) contains two clusters of phosphorylation sites within the amino-terminal half of the protein. To characterize possible regulatory effects of phosphorylation on viral DNA replication, Py T Ag was treated with calf intestinal alkaline phosphatase (CIAP). Incubation of the protein with a range of phosphatase concentrations caused progressive loss of phosphate without affecting its stability. Treatment with smaller quantities of CIAP stimulated the ability of the viral protein to mediate replication of constructs containing the viral replication origin, while higher concentrations of CIAP caused a marked diminution of this replication function. Several biochemical activities of Py T Ag were examined after CIAP treatment. Py T Ag DNA unwinding and nonspecific DNA binding were only slightly affected by dephosphorylation. However, as determined by DNase I footprinting experiments, treatment with smaller amounts of CIAP stimulated specific binding to the Py replication origin by Py T Ag, while treatment with larger amounts of CIAP caused marked inhibition of origin-specific binding by the viral protein. Phosphotryptic maps of Py T Ag before or after treatment with CIAP revealed changes in individual phosphopeptides that were uniquely associated with either the stimulation or the inhibition of replication. Our data therefore suggest that Py T Ag is regulated by both repressing and activating phosphates.

A Cosmid-Based System for Constructing Mutants of Herpes Simplex Virus Type 1

Cosmids containing large fragments of herpes simplex virus type 1 DNA were prepared using a vector that allows intact inserts to be excised using the restriction endonuclease Pacl. Two independent sets (A and B) of five cosmids were identified whose inserts overlap and represent the entire viral genome, and set C was obtained by replacing two cosmids in set B. Each set gave rise to viral plaques when digested with Pacl and transfected into cells in culture. Two cosmids common to sets B and C ostensibly contain one of the origins of viral DNA replication ( ori L) in a region of overlap between inserts, but both actually consist of a minority of apparently intact ( ori + L) forms and a majority of deleted ( ori - L) forms. These sets yielded exclusively ori + L viral progeny. When either of these cosmids was replaced by a derivative comprising only ori - L forms, ori + L and ori - L progeny were obtained, and only ori - L progeny were produced when both were replaced. One cosmid in set A contains the ori L locus in a nonoverlapping region and lacks ori + L forms. This set generated only ori - L virus. Viral mutants with lesions in either or both of genes UL2 and UL44, which are not essential for growth in cell culture, were constructed using cosmids containing specifically introduced frameshift mutations. A mutant with a frameshift mutation in an essential gene ( UL33) was isolated by transfecting a complementing cell line. These results indicate that a cosmid-based system will facilitate isolation of large numbers of defined viral mutants.

Mutation of large T-antigen-binding site A, but not site B or C, eliminates stalling by RNA polymerase II in the intergenic region of polyomavirus DNA.

During transcription of the late strand of polyomavirus DNA, RNA polymerase II stalls and accumulates nearby the binding sites on viral DNA recognized by polyomavirus large T antigen. Stalling by RNA polymerases is eliminated when thermolabile large T antigen is inactivated by using a temperature-sensitive virus mutant (J. Bertin, N.-A. Sunstrom, P. Jain, and N. H. Acheson, Virology 189:715-724, 1992). To determine whether stalling by RNA polymerases is mediated through the interaction of large T antigen with one or more of its binding sites, viable polyomavirus mutants that contain altered large-T-antigen-binding sites were constructed. Point mutations were introduced by site-directed mutagenesis into the multiple, clustered G(A/G)GGC pentanucleotides known to be the target sequence for large T-antigen binding. Mutation of the G(A/G)GGC pentanucleotides in the first two binding sites encountered by RNA polymerases in the intergenic region (sites C and B) had no detectable effect on stalling as measured by transcriptional run-on analysis. However, mutation of the two GAGGC pentanucleotides in binding site A, which lies adjacent to the origin of viral DNA replication, eliminated stalling by RNA polymerases. We conclude that binding of large T antigen to site A blocks elongation by RNA polymerase II. Further characterization of virus containing mutated site A did not reveal any effects on early transcription levels or on virus DNA replication. However, the mutant virus gave rise to small plaques, suggesting impairment in some stage of virus growth. Stalling of RNA polymerases by large T antigen bound to the intergenic region of viral DNA may function to prevent transcription from displacing proteins whose binding is required for the normal growth of polyomavirus.

Inhibition of Herpes Simplex Virus Type 1 DNA Replication by Mutant Forms of the Origin-Binding Protein

The herpes simplex virus type 1 (HSV-1) origin-binding protein (OBP) is a sequence-specific DNA binding protein encoded by gene UL9 which interacts with the viral origins of DNA replication and also exhibits DNA helicase activity. Sequence-specific DNA binding activity has previously been shown to reside within the C-terminal 317 amino acids, and when expressed alone, this domain exerts a dominant inhibitory effect on HSV-1 DNA synthesis. We have tested several UL9 gene mutants for ability to support or interfere with viral DNA replication. Mutants affected in an ATP binding motif presumed to be associated with DNA helicase activity (ATP -), or defective in origin binding (OBP -) were unable to support replication in a transient assay for HSV-1 origin-dependent DNA synthesis. When the products were screened for their ability to interfere with replication, the ATP - but not the OBP - mutant was inhibitory. Introduction of a mutation which abolished origin-binding activity into the isolated C-terminal fragment also removed the ability to interfere. The C-terminal fragment retained inhibitory activity when the wild-type (wt) protein was specified by a plasmid in which an OBP recognition site within the UL9 gene coding region had been mutated so as to prevent binding without affecting the encoded amino acids. These results suggest that in this assay inhibition of DNA synthesis probably results primarily from competition between mutant and wt forms of OBP for binding to the viral replication origins. The infectivity of HSV-1 DNA in co-transfection experiments was greatly reduced by mutant UL9 proteins which interfered with origin-dependent DNA replication and also by high level expression of the wt polypeptide.

The hr5 transcriptional enhancer stimulates early expression from the Autographa californica nuclear polyhedrosis virus genome but is not required for virus replication.

Autographa californica nuclear polyhedrosis virus (AcMNPV) contains five homologous regions (hr1 through hr5) interspersed throughout its genome. Analysis of plasmid transfections indicates that the hrs function as transcriptional enhancers and possible origins of viral DNA replication. The role of these repetitive elements in regulating expression from the AcMNPV genome was examined by constructing a series of recombinant viruses that tested the effect of hr5 on expression of the adjacent p35 gene (p35). When embedded within the viral genome, hr5 stimulated transcription from the early p35 promoter in a position- and orientation-independent manner. Moreover, hr5 and the upstream activating region of p35 were functionally interchangeable. A 28-bp imperfect palindrome, repeated six times within hr5, was the minimal sequence required for p35 promoter activation. hr5 also stimulated another early AcMNPV promoter but not a late promoter or a host-derived promoter, suggesting that enhancement is promoter specific during infection. To investigate its role during AcMNPV replication, hr5 was deleted from its normal position within the viral genome. The resulting hr5 mutants exhibited no apparent defects in replication, as judged by production of budded virus and levels of very late gene expression, even though steady-state levels of p35 RNA were reduced. These results indicated for the first time that hr5 functions as a transcriptional enhancer within the viral genome. However, the element is not required for AcMNPV replication in cultured cells. Thus, loss of one of five possible origins of DNA replication is not deleterious to viral growth. Since p26 was removed from the hr5 deletion mutants, this gene is also nonessential for viral replication.

Amplification mediated by polyomavirus large T antigen defective in replication.

The polyomavirus large T antigen promotes homologous recombination at high rates when expressed in rat cells carrying the viral replication origin and two repeats of viral DNA sequences stably integrated into the cellular genome. Recombination consists of both reciprocal and nonreciprocal events and is promoted by mutants defective in the initiation of viral DNA synthesis (L. St-Onge, L. Bouchard, and M. Bastin, J. Virol. 67:1788-1795, 1993). We have extended our studies to a rat cell line undergoing amplification of the viral insert. We show that large T antigen promotes amplification independently of its replicative function but that its origin-specific DNA binding activity is not sufficient to promote homologous recombination.

Characterization of human papillomavirus type 11 E1 and E2 proteins expressed in insect cells

The study of human papillomavirus replication has been hampered by the lack of an in vitro system which reliably supports virus replication. Recent results from the bovine papillomavirus (BPV) system indicate that the E1 and E2 proteins are the only viral gene products required for replication. By analogy with simian virus 40 large T antigen, E1 is thought to possess ATPase and helicase activity, which may play a direct role in viral DNA replication. The precise role of E2 is unclear, but it may function in part to help localize E1 to the replication origin. We have initiated a study of replication in the human papillomavirus type 11 system which, by analogy to BPV, has focused on the E1 and E2 proteins of this virus. We have expressed the full-length E1 and E2 proteins in Sf9 insect cells by using a baculovirus expression vector. Both the 80-kDa E1 protein and the 42.5-kDa E2 protein are nuclear phosphoproteins. The E1 and E2 proteins form a heteromeric complex within the insect cells, and both proteins localize to a DNA fragment which contains the viral origin of replication. In addition, we have detected an E1-associated ATPase and GTPase activity, which is likely part of an energy-generating system for the helicase activity which is predicted for this protein. The human papillomavirus type 11 E1 and E2 proteins possess the same replication-associated activities exhibited by the corresponding BPV proteins, suggesting that the replication activities of these viruses are tightly conserved.